ML17151B013

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Revision 30 to Updated Final Safety Analysis Report, Chapter 14.0, Initial Test Program
ML17151B013
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Site: Wolf Creek Wolf Creek Nuclear Operating Corporation icon.png
Issue date: 03/09/2017
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WOLF CREEK CHAPTER 14.0 TABLE OF CONTENTS INITIAL TEST PROGRAM

Section Title Page

14.1 SPECIFIC INFORMATION TO BE INCLUDED 14.1-1 IN THE PSAR

14.2 INITIAL TEST PROGRAM 14.2-1

14.2.1

SUMMARY

OF TEST PROGRAM AND OBJECTIVES 14.2-1

14.2.1.1 Preoperational Test Program 14.2-1

14.2.1.2 Initial Startup Test Program 14.2-2

14.2.2 ORGANIZATION AND STAFFING 14.2-3 14.2.2.1 General Description 14.2-3

14.2.2.2 Startup Organization 14.2-4

14.2.2.3 Operating Staff 14.2-6

14.2.2.4 Major Participating Organizations 14.2-6 14.2.2.5 Quality Assurance 14.2-8 14.2.2.6 Qualifications of Key Personnel 14.2-8

14.2.3 TEST PROCEDURES 14.2-8

14.2.3.1 Startup Test Procedures 14.2-8 14.2.3.2 Procedure Review and Approval 14.2-10

14.2.4 CONDUCT OF TEST PROGRAM 14.2-12

14.2.4.1 Administrative Procedures 14.2-12

14.2.4.2 Turnover From Construction to KG&E 14.2-13 Startup 14.2.4.3 Component and Prerequisite Testing 14.2-14

14.2.4.4 Preoperational Testing 14.2-14

14.2.4.5 Initial Startup Testing 14.2-14

14.2.4.6 Test Prerequisites 14.2-15 14.2.4.7 Test Evaluation 14.2-15 14.2.4.8 Design Modifications 14.2-15

14.2.5 REVIEW, EVALUATION, AND APPROVAL OF 14.2-15

TEST RESULTS 14.2.6 TEST RECORDS 14.2-16

14.2.7 CONFORMANCE OF TEST PROGRAMS WITH 14.2-16

REGULATORY GUIDES

14.2.8 UTILIZATION OF REACTOR OPERATING AND 14.2-16 TESTING EXPERIENCE IN DEVELOPMENT

OF TEST PROGRAMS

14.2.9 TRIAL USE OF PLANT OPERATING AND EMERGENCY 14.2-18 PROCEDURES

14.0-i Rev. 29 WOLF CREEK TABLE OF CONTENTS (CONTINUED)

Section Title Page 14.2.10 INITIAL FUEL LOADING CRITICALITY AND POWER 14.2-18

ASCENSION

14.2.10.1 Fuel Loading 14.2-19 14.2.10.2 Initial Criticality 14.2-22 14.2.10.3 Low Power Testing 14.2-23

14.2.10.4 Power Level Ascension 14.2-23

14.2.11 TEST PROGRAM SCHEDULE 14.2-24 14.2.12 INDIVIDUAL TEST DESCRIPTIONS 14.2-25

14.2.12.1 Safety-Related Preoperational Test 14.2-25

Procedures

14.2.12.2 Nonsafety-related Preoperational Test 14.2-121 Procedures

14.2.12.3 Startup Test Procedures 14.2-158

14.0-ii Rev. 29 WOLF CREEK TABLE OF CONTENTS (CONTINUED)

LIST OF TABLES Table No. Title

14.2-1 Safety-Related Preoperational Test Procedures 14.2-2 Non-Safety-Related Preoperational Test Procedures

14.2-3 Initial Startup Test

14.0-iii Rev. 0

WOLF CREEK CHAPTER 14.0 INITIAL TEST PROGRAM

14.1 SPECIFIC INFORMATION TO BE INCLUDED IN PRELIMINARY SAFETY ANALYSIS REPORTS This section is not applicable to a USAR.

14.1-1 Rev. 1 WOLF CREEK CHAPTER 14.0 INITIAL TEST PROGRAM 14.2 INITIAL TEST PROGRAM 14.2.1

SUMMARY

OF TEST PROGRAM AND OBJECTIVES

The Initial Test Program encompassed the scope of events following completion of construction and construction-related inspections and tests and terminating

with Power Ascension Testing. The Initial Test Program was conducted in two

separate and sequential subprograms: the Preoperational Test Program and the

Initial Startup Test Program. At the conclusion of these subprograms, the

plant was ready for normal power operation. Testing during the Initial Test

Program was accomplished in four sequential phases:

Preoperational Test Program

Phase I - Preoperational Testing Initial Startup Test Program

Phase II - Initial Fuel Loading and Zero Power Testing

Phase III - Low Power Physics Testing

Phase IV - Power Ascension Testing

Prior to preoperational testing of a particular system, certain prerequisite

and construction tests were conducted in order to verify the integrity, proper

installation, cleanliness, and functional operability of the system components.

14.2.1.1 Preoperational Test Program The Preoperational Test Program is defined as that part of the Initial Test

Program that commences with the completion of construction and construction-

related inspections and tests and terminates with commencement of nuclear fuel loading.

The Preoperational Test Program included both safety-related and nonsafety-

related preoperational tests. The Preoperational Test Program used a graded

approach to determine the extent of testing to be performed. The safety-

related preoperational tests (Table 14.2-1) demonstrated the capability of

safety-related structures, systems, and components to meet performance

requirements and to satisfy design criteria. The nonsafety-related

preoperational tests (Table 14.2-2) were conducted on nonsafety-related systems

and components to satisfy reliability and availability. Preoperational tests were conducted on those systems that:

14.2-1 Rev. 0 WOLF CREEK

a. Are relied upon for safe shutdown and cooldown of the reactor under normal plant conditions and for

maintaining the reactor in a safe condition for an

extended shutdown period;

b. Are relied upon for safe shutdown and cooldown of the

reactor under transient and postulated accident

conditions and for maintaining the reactor in a safe

condition for an extended shutdown period following such

conditions;

c. Are relied upon for establishing conformance with safety

limits or limiting conditions for operations that are

included in the technical specifications;

d. Are classified as engineered safety features actuation systems or are relied upon to support or ensure

operation of engineered safety features actuation

systems within design limits;

e. Are assumed to function during an accident or for which

credit is taken in the accident analysis;

f. Are used to process, store, control, or limit the

release of radioactive materials.

The objectives of the Preoperational Test Program were to:

a. Verify that plant components and systems, including

alarms and indications, are constructed and fulfill their design intent;

b. Demonstrate, to the extent practicable, proper

system/component response to postulated accidents;

c. Familiarize plant staff operating, technical, and

maintenance personnel with plant operation.

The completion of preoperational testing constituted the completion of Phase I

of the Initial Test Program.

14.2.1.2 Initial Startup Test Program The Initial Startup Test Program is defined as that part of the Initial Test

Program that commences with the start of nuclear fuel loading and terminates

with the completion of power ascension testing. The initial startup tests (Table 14.2-3) ensured that fuel loading was accomplished in a safe manner, confirmed the

14.2-2 Rev.0 WOLF CREEK design basis, demonstrated, where practical, that the plant operates and responds properly to anticipated transients and postulated accidents, and

ensured that the plant can be safely brought to rated capacity and sustained

power operation.

The objectives of the Initial Startup Test Program were to:

a. Accomplish a controlled, orderly, and safe initial core

loading;

b. Accomplish a controlled, orderly, and safe initial

criticality;

c. Conduct low power testing sufficient to ensure that

design parameters are satisfied and safety analysis assumptions are conservative;

d. Perform a controlled, orderly, and safe power ascension

with testing terminating at plant rated conditions;

e. Provide sufficient testing of transient and accident

conditions to verify safe operation during transient or

accident conditions.

The completion of initial startup testing constituted the completion of Phases

II, III, and IV of the Initial Test Program.

14.2.2 ORGANIZATION AND STAFFING

14.2.2.1 General Description The Operating Agent, as defined in Section 1.4, was responsible for the overall

administration and technical direction of the WCGS startup program. In

recognition of this responsibility, the Director of Nuclear Operations, under the direction of the Vice President - Nuclear, established a startup

organization to coordinate and direct the comprehensive planning, development, implementation and performance of the test program. The Startup Organization

was headed by the Startup Manager who reported to the Plant Manager both

administratively and technically.

During the preoperational startup program, the Startup Manager acted to

coordinate activities between the Startup Organization, the construction staff, and the operating staff.

Prior to commencing preoperational testing activities, a Joint Test Group (JTG) as described in Section 14.2.3.2.2 was formed to review and recommend for

approval startup administrative procedures, preoperational test procedures, and

preoperational test

14.2-3 Rev. 0 WOLF CREEK results. A Plant Safety Review Committee (PSRC) as described in Section 14.2.3.2.3 was organized with the Plant Manager acting as chairman and it

reviewed and recommended for approval initial startup test procedures and

results.

14.2.2.2 Startup Organization

The Startup Organization was directly responsible for the conduct of the WCGS

preoperational test program. The duties and responsibilities of the startup

organization also included:

a. Familiarization of support personnel with specific

tests.

b. Direction to support personnel and others during performance of tests including appropriate interface with station operators.
c. Authority to disallow or terminate testing due to

conditions which could endanger personnel or equipment.

d. Identification of deficiencies that could adversely

affect test performance.

e. Assembly of test data and preparation of test reports

for evaluation of test results by others.

The Startup Organization was composed of system startup engineers, technicians, planners, craft labor, and other support personnel. The Operating Agent

provided these personnel and used contractors to supply manpower for those positions that it could not staff. The staffing level for the Startup Organization increased as the test program progressed and construction

activities decreased. Typical schedules for the test program are given in

Section 14.2.11. Staffing and training of personnel involved in testing at

WCGS were planned to provide sufficient manpower to support the testing

schedule.

The Startup Organization reported administratively and technically to the

Startup Manager; the duties performed by key individuals within the Startup

Organization are summarized below.

14.2.2.2.1 Startup Manager

The Startup Manager had the authority and responsibility, as delegated by the

Plant Manager, for the overall direction and administration of the functions

and activities required to conduct the Startup Program. The responsibilities

and duties of the Startup Manager also included:

14.2-4 Rev. 0 WOLF CREEK

a. Development of plans and schedules regarding the status of the startup program.
b. Review and approval of administrative and technical test

procedures and results.

c. Continuing analysis of construction and equipment

installation schedules for compatibility with testing

schedules and recommendations for corrective actions to

minimize conflict.

d. Review and submittal of design related problems

requiring engineering resolution, encountered by the

Startup Organization in accordance with the appropriate

Startup Administrative Procedures.

e. Maintaining liaison with all organizations supporting

Startup and coordinating their activities.

14.2.2.2.2 Startup Section

The Startup Section was comprised primarily of the System Test Group, the

Electrical Test Group and the Instrumentation and Control Group which had

primary responsibility within the Startup Organization to perform testing.

This section also reviewed and recommended the acceptance of system or

subsystem turnover documentation from Construction and coordinated system

turnover and any subsequent system rework. It was responsible for preparing the

test procedures, conducting the tests, and reporting the test results. For

preoperational testing, this section documented the test results and presented

them before the Joint Test Group for its review and recommendation for approval.

14.2.2.2.3 Operations Technical Support Section

The Operations Technical Support Section was responsible for providing

technical support to the Startup Section during testing. The areas in which

this support was given were instrumentation and control, chemistry, computer, health physics and reactor engineering.

This section was a permanent part of the WCGS operating staff until these functions were incorporated into other sections. They were involved in training, procedure preparation, and general preparation for support of plant operations.

14.2.2.2.4 Startup Scheduling Section

The Startup Scheduling Section prepared and updated the Startup Schedule, utilizing input from cognizant system startup engineers and the construction

organizations.

14.2-5 Rev.7 WOLF CREEK 14.2.2.2.5 Quality Control Section

The Quality Control Section formulated and implemented the Startup Quality

Control Program. This program monitored the conduct of the Startup

Organization's testing activities by reviewing administrative and technical test procedures, by witnessing major evolutions and selected flushes, hydros, and preoperational tests and by reviewing turnover packages. The Quality

Control Section was under the direction of the Director - Quality. They

provided support to the Startup Manager.

14.2.2.2.6 Startup Technical Support Section

The Startup Technical Support Section was responsible for providing technical

support to the Startup Organization during the conduct of the Startup Program.

Their responsibilities included test procedure and test results review and approval, technical planning of major milestone activities, startup organization training and startup program compliance to FSAR commitments.

14.2.2.3 Operating Staff The WCGS operating staff was involved in the startup program in several

capacities throughout preoperational and initial startup testing. This

involvement included review of test procedures and results and the direct participation in test activities. Operating staff personnel were utilized by

the startup organization as required for performance of testing under the

direction of system startup engineers. Station operators assisted system

startup engineers in performing tests and in the routine operations of systems.

The operating staff directed the fuel loading and was responsible for plant

operation during initial startup testing.

The operating staff was divided into sections headed by the Superintendent

Operations, Superintendent of Maintenance, Superintendent of Plant Support, Superintendent of Technical Support, Nuclear Training Manager and Superintendent Regulatory Quality and Administrative Services. These section

superintendents reported administratively and technically to the Plant Manager.

The duties and responsibilities of the operating staff during plant operations

are described in Chapter 13.0.

14.2.2.4 Major Participating Organizations 14.2.2.4.1 Bechtel

Bechtel provided engineering input into the startup program. Bechtel was contacted to provide personnel experienced in nuclear plant startup to augment

the startup organization for WCGS. Bechtel employees were assigned consistent

with the startup program schedules.

14.2-6 Rev. 12 WOLF CREEK 14.2.2.4.2 Daniel International Corporation (DIC)

DIC, as contractor for WCGS, was responsible for the construction completion, and orderly release of components and turnover of systems to KG&E consistent

with the startup program schedules. This responsibility included:

a. Certification that documentation for components, systems

and structures, as required by purchase and installation

specifications, is complete and available; and the

maintenance of these certification files which provide

the documentary evidence, and

b. Provision of dedicated craft manpower support as

required for performance of the startup program.

14.2.2.4.3 Westinghouse Electric Corporation

Westinghouse, as the Nuclear Steam Supply System (NSSS) supplier, was

responsible for providing technical assistance to KG&E during preoperational

and initial startup testing performed on the NSSS equipment and systems.

Technical assistance is defined as technical guidance, advice and counsel based

on current engineering, installation, and testing practices. Westinghouse

employees were assigned consistent with the Startup Program schedules. This

responsibility included:

a. Assignment of personnel to provide advice and assistance

to KG&E for test and operation of all equipment and

systems in the Westinghouse area of responsibility.

b. Supportive engineering services, including special assistance during the initial fuel loading.
c. Providing test procedure outlines and technical

assistance for tests of Westinghouse furnished

components and systems.

14.2.2.4.4 General Electric (GE)

GE is the supplier and installer of the turbine generator. GE supplied

technical support for the startup and testing of the turbine generator. Some

of the prerequisite testing (i.e., turbine oil flush) was performed by the GE

personnel. GE has supplied recommended procedures for starting, operating, and

shutting down equipment in their technical manuals for the turbine generator.

14.2-7 Rev. 0 WOLF CREEK 14.2.2.5 Quality Assurance The KG&E Quality Branch was responsible for assuring the quality of

construction, plant testing, and operations activities in accordance with the

WCGS Quality Program which is described in the Quality Program Manual.

14.2.2.6 Qualifications of Key Personnel

The qualifications for key plant operating personnel are described in Chapter

13.0.

The qualification requirements for startup personnel involved in the WCGS

startup program conformed to capability levels per ANSI N45.2.6 and Regulatory

Guide 1.8 recommendations.

All test personnel were indoctrinated in the startup administrative procedures, methods and controls.

14.2.3 TEST PROCEDURES

The Initial Test Program was conducted in accordance with detailed preoperational and initial startup test procedures. KG&E maintained the overall responsibility for test procedure preparation, review, and approval

during the preparational stages. KG&E was responsible for final procedure

revision, review, and approval. These activities were completed in a timely

fashion to ensure that the approved procedures for satisfying FSAR testing

equipment commitments were available for review approximately 60 days prior to

scheduled implementation or fuel load for preoperational and initial startup

tests, respectively. Preoperational and initial start-up testing commitments

not available for review approximately 60 days prior to scheduled

implementation or fuel load, respectively, were handled on a case- by-case

basis.

The following sections describe the general methods employed to control

procedure development and review, and they also describe the responsibilities

of the various organizations which participated in this process. The detailed controls and methods were described in the startup administrative procedures.

14.2.3.1 Procedure Preparation Test procedures for the powerblock systems and components were developed by

Westinghouse and Bechtel. Bechtel also prepared test procedures for the site

safety-related systems and components. Test procedures for the site nonsafety-related systems and components were developed by various entities as

coordinated by KG&E.

14.2-8 Rev. 21 WOLF CREEK The format and content of the test procedures developed for the standard plant and safety-related site systems and components reflected the guidance provided

in Regulatory Guide 1.68. The procedures contained as a minimum the following

sections:

1.0 Objectives

The objectives section identified the general results to

be accomplished by the test.

2.0 Acceptance Criteria

The acceptance criteria section clearly defined

quantitative and/or qualitative criteria against which

the success or failure of the test procedure is judged.

3.0 References

The references section identified those FSAR sections, vendor manuals, drawings, etc. that were pertinent to

the performance and/or development of the test

procedure.

4.0 Test Equipment

The test equipment section identified temporary

equipment required to conduct the test procedure and/or

collect data.

5.0 Notes and Precautions The notes and precautions sections listed limitations

and precautions necessary to ensure personnel and

equipment safety. Additional instructions needed to

clarify the test procedure were also listed in this

section.

6.0 Prerequisites

The prerequisites section identified those prerequisite

tests and initial conditions that had to be completed

and/or satisfied prior to the performance of the test

procedure.

7.0 Test Procedure

The test procedure section provided a detailed step-by-

step test method and instructions for data collection.

All nonstandard arrangements required by the test

procedure section were restored either in the test

procedure section or the system restoration section.

14.2-9 Rev. 0 WOLF CREEK 8.0 Test Data Sheets

The test data sheet section provided specific forms for

data collection. Additional instructions, if necessary, were also identified for each data sheet.

9.0 System Restoration

The system restoration section returned the system to a

safe operating or standby condition. Instructions for

the removal and/or return of system temporary

modifications required by the prerequisite and/or test

procedure sections were clearly defined.

The procedural sections included, as applicable, appropriate requirements for initials and/or signatures to control the performance and sequencing of the test.

The test procedures were prepared using the latest design information available

and functional requirements provided by the design engineers. This information

was utilized in developing the detailed test methods which verified the ability

of systems and components to function within their design specifications. The

procedure preparation efforts were started more than 2 years before the first

procedure to be performed. This early start allows for an orderly development

of the test procedure program and of the test procedures.

The test procedures were reviewed by the cognizant design organization to

ensure that the test procedure objectives and acceptance criteria are

consistent with current design document requirements. Subsequent changes to

test procedure objectives or acceptance criteria during the preparational stage were based on approved changes to design documents with the design organization's concurrence.

14.2.3.2 Procedure Review and Approval Following initial procedure preparation, and prior to submittal to the JTG for

review and approval recommendation, the test procedures were reviewed by the

SNUPPS utilities (KG&E and Union Electric). Review comments were resolved between the SNUPPS utilities and the writing organization.

A final revision was made by the writing organization, incorporating all

applicable design changes, and was submitted to the utilities for their review

and approval.

14.2-10 Rev. 0 WOLF CREEK Each utility had various organizations, groups, and committees, such as a startup organization, initial test group, and a plant safety review committee, comprised of individuals having appropriate technical backgrounds and

experience. Individuals within these organizations, groups, and committees

were responsible for:

a. Reviewing procedures for accuracy and technical content;
b. Verifying that the procedure has been revised to

incorporate known design changes;

c. Verifying procedure compatibility with field

installation of equipment;

d. Verifying procedure conformance with FSAR requirements and plant operating technical specifications;
e. Reviewing procedures against reactor operating and

testing experiences of similar power plants.

14.2.3.2.2 Joint Test Group (JTG)

A subcommittee of the PSRC, the JTG was organized by the Operating Agent to

review preoperational test procedures and preoperational test results.

The primary JTG functions were to:

a. Review preoperational test procedures and recommend

their approval by the Startup Manager.

b. Evaluate and authorize changes to preoperational test procedures as detailed in the Startup Administrative

Manual.

c. Evaluate preoperational test procedure results and

recommend their approval to the Startup Manager and

Plant Manager.

d. Review safety-related aspects of the startup

administrative procedures.

Membership in the JTG included the following personnel or their designated

representatives:

a. Superintendent Operations - Chairman
b. Superintendent of Plant Support

14.2-11 Rev. 12 WOLF CREEK

c. Superintendent of Regulatory, Quality and Administrative Services
d. Startup Technical Support Supervisor
e. Assistant Startup Manager
f. Operations Quality Assurance (non-voting member)
g. Bechtel Power Corporation-Engineering (non-voting

member)

h. Westinghouse-Engineering (non-voting member)

Others were requested to provide technical support to the JTG. This support was based on the procedure being reviewed, required technical expertise or other applicable factors. Participation in the JTG meeting was with the concurrence

of the JTG and was limited to technical input only.

14.2.3.2.3 Plant Safety Review Committee (PSRC)

The PSRC was organized by the Operating Agent to ensure effective coordination

of the engineering, construction, and operations activities affecting the

startup program.

The appropriate PSRC members ensured sufficient review of initial startup test

procedures and results.

The primary PSRC startup functions were:

a. Review all initial startup test procedures and make recommendations to the Plant Manager.
b. Evaluation and authorization of changes to initial

startup test procedures.

c. Evaluation of initial startup test procedure results.

Membership in the PSRC is given in the Quality Program Manual.

14.2.4 CONDUCT OF TEST PROGRAM

14.2.4.1 Administrative Procedures

The conduct of the preoperational startup program was controlled by

administrative procedures. The preparation, maintenance, and implementation

of these procedures was the responsibility of the Startup Manager. The startup administrative procedures prescribed controls for startup activities such as:

14.2-12 Rev. 21 WOLF CREEK

a. Organization and interfaces;
b. Indoctrination and training;
c. Preparation, review, approval, and modification of test procedures;
d. Format and content of test procedures;
e. Tagging procedures;
f. Test scheduling and test conduct;
g. Test deficiencies and resolution;
h. Startup quality control; and
i. Startup document control.

14.2.4.2 Turnover from Construction to KG&E Startup Construction completion was scheduled in accordance with engineered system or

subsystem boundaries. As systems or sub- systems were completed to support

Startup testing, a turnover of the system or subsystem to KG&E Startup was processed. Turnover was conducted in accordance with established

administrative procedures.

As part of the turnover process, each safety-related system or subsystem

received physical walkdowns to provide assurance of readiness for Startup

testing and verification that installation requirements had been met.

Walkdowns were performed jointly by KG&E Startup and KG&E Construction

personnel under the direction of the KG&E Construction Manager. Discrepancies

identified during the walkdowns were tracked and resolved in accordance with

established administrative and quality procedures.

The system or subsystem Turnover Package prepared by the constructor was

reviewed by KG&E Construction and KG&E Startup personnel for accuracy, completeness and acceptability for Startup testing. In conjunction with the

Turnover Package review, Startup personnel verified that the system or

subsystem procurement and installation documentation review had been performed

by Construction, and that discrepancies had been addressed. Acceptance of the

Turnover Package by Startup followed satisfactory completion of the Turnover

Package review. The Startup Manager was responsible for the approval and

acceptance of the system or subsystem and the associated Turnover Package.

14.2-13 Rev. 0 WOLF CREEK Individual components could be released to Startup for calibration, testing or temporary operation prior to turnover.

All components released in this manner were incorporated into the scope of a

subsequent system or subsystem turnover.

14.2.4.3 Component and Prerequisite Testing Upon Startup acceptance of a turned-over system, subsystem, or released

component, prerequisite-type testing was performed to demonstrate proper

operability and functional ability in support of, and prior to, the performance of preoperational testing. Local containment leak rate testing, as described in

Section 14.2.12.2.13, was performed at WCGS as part of the prerequisite test

program.

Administrative procedures were established to ensure that all prerequisites

were met before testing was initiated. Upon completion of all prerequisite

tests applicable to a system or subsystem, a documented review was conducted by

Startup personnel to verify that appropriate documentation was able and that

required prerequisite tests had been satisfactorily completed. All deficiencies

which would prevent performance of preoperational tests or generate negative test results were identified and dispositioned prior to implementation of the preoperational tests.

14.2.4.4 Preoperational Testing Technical direction and administration, including test execution and data

recording, of the preoperational testing were the responsibility of the startup

organization. The system startup engineers were responsible for the performance of tests and providing appropriate interface with station

operators. The Startup Manager was responsible for the administration and

surveillance of all testing activities during the preoperational test program.

14.2.4.5 Initial Startup Testing During the initial startup testing phase, the Plant Manager had overall

authority and responsibility for the startup program. The Startup Organization

provided support to the plant operating staff which had responsibility for performing equipment operations and maintenance in accordance with the

provisions of the plant operating license. The WCGS operating staff was also

responsible for ensuring that the conduct of testing did not place the plant in

an unsafe condition at any time.

The shift supervisors had the authority to terminate or disallow testing at any

time.

14.2-14 Rev. 0 WOLF CREEK 14.2.4.6 Test Prerequisites Each test procedure contained a set of prerequisites and initial conditions as

prescribed by the startup administrative procedures. The system startup

engineer ensured that all specified prerequisites were met prior to performing the test. The format for test procedures is described in Section 14.2.3.1.

14.2.4.7 Test Evaluation Upon completion of system preoperational testing, the test results were

submitted to the JTG for its review and subsequent recommendation for approval

to the Startup Manager and Plant Manager.

Between each major phase of the initial startup test program, the test results

for all tests that were performed were reviewed by the PSRC. This review

ensured that all required systems were tested satisfactorily and that test

results were approved before proceeding to the next stage of testing.

These reviews are described in Section 14.2.5.

14.2.4.8 Design Modifications Modifications to the design of the equipment during the test program could be

initiated in order to correct deficiencies discovered as a result of testing.

Any such modifications were either developed by the original design organization or other designated organizations. Modifications made to

components or systems after completion of preoperational or initial startup

testing were reviewed for retesting requirements on affected portions of the

system.

14.2.5 REVIEW, EVALUATION, AND APPROVAL OF TEST RESULTS

The responsibility for review, evaluation, and recommendation for approval of

test results from all preoperational tests rested with the JTG. In the case of

all initial start-up tests, it rested with the PSRC.

Following completion of a preoperational test, the responsible system startup

engineer assembled the test data package for submittal to the members of the

JTG for evaluation. Each test data package was reviewed to ensure that the

test has been performed in accordance with the approved procedure and that all

required data, checks, and signatures were properly recorded and that system

performance met the approved acceptance criteria.

14.2-15 Rev. 0 WOLF CREEK Members of the JTG reviewed the evaluation findings and recommended corrective action to be taken to resolve any outstanding deficiencies. If the

deficiencies were not resolved to the satisfaction of the JTG, then appropriate

retesting was required. If the evaluation indicated that deficiencies in the

test method were responsible for unsatisfactory test results, the test procedure was revised accordingly before retesting was initiated. The review

and approval process for procedure revisions was carried out in the manner

described in Section 14.2.3. Whenever an evaluation of test results indicated

deficiencies in system performance, the JTG referred the problem to the

responsible engineering organization for evaluation.

If the test documentation and system performance were acceptable, the JTG

recommended approval of the test by the Startup Manager and the Plant Manager.

Following each major phase of the initial startup test program, the PSRC verified that all required tests were performed and that the test results were approved. This verification ensured that all required systems were operating

properly and that testing for the next major phase was conducted in a safe and

efficient manner. This type of review was performed to the extent required

before major initial startup test phases such as fuel load, initial

criticality, and power ascension. During the power ascension phase, review and

approval of initial startup test procedure results was completed as described

in KMLNRC-84-235.

14.2.6 TEST RECORDS

Test procedures and test data relating to preoperational and initial startup

testing are retained in accordance with the measures described in the Quality Program Manual.

14.2.7 CONFORMANCE OF TEST PROGRAMS WITH REGULATORY GUIDES

The regulatory guides applicable to the test program are listed, with

positions, in Appendix 3A, Conformance to NRC Regulatory Guides.

14.2.8 UTILIZATION OF REACTOR OPERATING AND TESTING EXPERIENCE IN

DEVELOPMENT OF TEST PROGRAMS

Available information on reactor operating experiences was utilized in the

development of the Initial Test Program, as follows:

14.2-16 Rev. 21 WOLF CREEK

a. Bechtel reviewed and distributed pertinent Licensee Event Reports for use in the development of

preoperational test procedures as follows:

1. The Licensee Event Summary Reports and other pertinent information were reviewed on a periodic

basis, and those reports deemed to be useful for

updating test procedures and items of a generic

nature were cataloged. A summary of these reports

was distributed within Bechtel.

2. Copies of the specific reports were then made and

distributed for use in the preparation of

procedures. In addition, these reports were coded

and filed in a computer retrieval system.

b. The operating experience assessment for Wolf Creek

Generating Station Unit No. 1 (WCGS) was conducted by

the nuclear divisions and plant staff who possess the

appropriate experience in the area of concern. The

sources of operating experience information included the

use of the NETWORK and the INPO/NSAC SEEIN system. An

administrative system which controlled the flow of

information from NETWORK, INPO/NSAC SEEIN, etc., to the

cognizant organizations including the Independent Safety

Engineering Group (ISEG) was developed and functioning

prior to fuel load.

The Licensing Section was responsible for coordinating

the review of the NRC Information and Enforcement (IE)

Bulletins, Circulars, and Information Notices.

The Startup Group reviewed information provided by the

other KG&E Nuclear Divisions and information provided by

Bechtel and Westinghouse to determine its effect on the

Wolf Creek Initial Test Program, making revisions to

test and administrative procedures as required.

An instrumented auxiliary feedwater water-hammer test was performed only at

Wolf Creek. (This test was not required to be performed. It was being

performed for the purpose of gathering engineering data only.) Procedure S-

O3AL04, Auxiliary Feedwater System Water Hammer Test, required a visual and

audible water hammer test and was completed prior to the issuance of an

operating license. See new Section 14.2.12.1.10.

Procedure S-070017, Loss of Heater Drain Pump Test, was performed on Callaway

only. This test was conducted to verify analytical assumptions. No

additional loss of heater drain pump tests are

14.2-17 Rev. 0 WOLF CREEK required, since the data obtained from the first unit test is equally valid for subsequent units. See Section 14.2.12.3.41.

Procedure S-07SF09 RCCA or Bank Worth Measurement at Power, was performed at 50

percent power only at Callaway. Wolf Creek and Callaway have the same core and Nuclear instrumentation system design and the test at Callaway is considered a

prototypical test for Wolf Creek. This position was accepted by the NRC in a

July 3, 1985 letter to KG&E.

A natural circulation test was performed at Callaway only to demonstrate the

length of time to stabilize natural circulation, core flow distribution, and

the ability to establish and maintain natural circulation. Operators

participating in the tests were able to recognize when natural circulation had

stabilized and were able to control saturation margin, RCS pressure, and heat

removal rate without exceeding specified operating limits. These tests were conducted insofar as possible to include all available licensed operators.

Licensed operators were trained in these same areas on the simulator. The

simulator has full capability of simulating natural circulation, using

Westinghouse data initially. When the above tests were accomplished on the

Callaway plant, actual data was incorporated into the Wolf Creek simulator

program. See Chapter 18, item I.G.1, and Section 14.2.12.3.43.

14.2.9 TRIAL USE OF PLANT OPERATING AND EMERGENCY PROCEDURES

The plant operating procedures were utilized, where applicable during the test

program, to support testing, maintain plant conditions, and facilitate

training. The trial use of operating procedures served to familiarize

operating personnel with systems and plant operation during the testing phase

and also served to ensure the adequacy of the procedures under actual or

simulated operating conditions before plant operation begins. The emergency procedures were verified during startup as plant conditions, testing, and training warrant. Surveillance tests were performed as conditions warrant

during the testing program, to demonstrate their adequacy.

Plant operating procedures were developed in approximately the same time frame

as the preparation of preoperational and initial startup tests. The operating

procedures were revised as necessary to reflect experience gained during the

testing program.

14.2.10 INITIAL FUEL LOADING, CRITICALITY, AND POWER

ASCENSION

Prior to the commencement of fuel loading, required preoperational test

procedures were evaluated, and appropriate remedial action

14.2-18 Rev. 0 WOLF CREEK was taken if the acceptance criteria was not satisfied. At the completion of fuel loading, the reactor upper internals and pressure vessel head were

installed, and additional mechanical and electrical tests were performed to

prepare the plant for nuclear operation. After final precritical tests, nuclear operation of the reactor began. This phase of testing included initial criticality, low power testing, and power level ascension. The purpose of

these tests was to establish the operational characteristics of the unit and

core, to acquire data for the proper calibration of setpoints, and to ensure

that operation is within license requirements. Section 14.2.12.3 summarizes

the tests which are performed from fuel load to rated power. The fuel loading

and post loading tests are described below.

14.2.10.1 Fuel Loading The Plant Manager or his designated representative with technical assistance

provided by Westinghouse, was responsible for the coordination of initial core

loading. The overall process of initial core loading was, in general, directed from the operating floor of the containment structure by a licensed senior

reactor operator. The licensed senior reactor operator had no additional

responsibilities other than core load operations.

The core configuration was specified as part of the core design studies

conducted well in advance of fuel loading. In the event mechanical damage was

sustained during core loading operations to a fuel assembly of a type for which

no spare was available onsite, an alternate core loading scheme could have been

determined. Any such changes would have been approved by the appropriate

Westinghouse personnel.

Core loading procedures specified the condition of fluid systems to prevent

inadvertent changes in boron concentration of the reactor coolant; the movement

of fuel to preclude the possibility of mechanical damage; the conditions under

which loading could proceed; and the responsibility and authority for

continuous and complete fuel and core component accountability.

The following conditions were met prior to core loading:

a. The reactor containment structure was complete and

containment integrity had been demonstrated.

b. Fuel handling tools and equipment were checked out and

operators familiarized in the use and operation of

equipment. Inspections of fuel assemblies, rod cluster control assemblies, and reactor vessel were satisfactorily completed.

14.2-19 Rev. 0 WOLF CREEK

c. The reactor vessel and associated components were in a state of readiness to receive fuel. The water level was

maintained above the bottom of the nozzles and

recirculation maintained to ensure the required boron

concentration could be increased via the recirculation path or directly to the open vessel.

Criteria for safe loading required that loading operations stop immediately if

any of the following conditions occur.

a. An unanticipated increase in the neutron count rates by a

factor of two occurs on all responding nuclear channels

during any single loading step after the initial nucleus

of eight fuel assemblies is loaded.

b. An unanticipated increase in the count rate by a factor of five on any individual responding nuclear channel

during any single loading step after the initial nucleus

of eight fuel assemblies is loaded.

c. An unanticipated decrease in boron concentration greater

than 20 ppm is determined from two successive samples of

the reactor coolant.

Loading operations could not be restarted until the situation was evaluated.

An alarm in the containment and main control room was coupled to the source

range channels with a setpoint equal to or less than five times the current

count rate. This alarm automatically alerts the loading operation personnel of

high count rate, and an immediate stop of all operations would be required

until the situation was evaluated. In the event the evacuation alarm was actuated during core loading and after it has been determined that no hazards to personnel exist, preselected personnel would be permitted to reenter the

containment to evaluate the cause and determine future action.

The core was assembled in the reactor vessel and submerged in the reactor grade

water containing sufficient dissolved boric acid to maintain a calculated core

effective multiplication factor of 0.95 or lower. The refueling pool could be

wet or dry during initial core loading. Core moderator, chemistry conditions (particularly boron concentration) were prescribed in the core loading

procedure document and verified by chemical analysis of moderator samples taken

prior to and during core loading operations.

At least two artificial neutron sources were introduced into the core at

specified points in the core during the loading program to ensure a detector

response of at least 2 counts per second attributable to neutrons.

14.2-20 Rev. 0 WOLF CREEK Core loading instrumentation consisted of two permanently installed source range (pulse type) nuclear channels and two temporary incore source range

channels. A third temporary channel could also be used as a spare. The

permanent channels, when responding, were monitored in the main control room, and the temporary channels were installed and monitored in the containment. At least one permanent channel was equipped with an audible count rate indicator.

Both plant channels have the capability of displaying the neutron flux level on

a strip chart recorder. The temporary channels indicated on scalers, and a

minimum of one channel was recorded on a strip chart recorder. Normally minimum

count rates of two counts per second attributable to core neutrons were

required on at least two of the four (i.e. two temporary and two permanent

source range detectors) available nuclear source channels at all times

following installation of the initial nucleus of eight fuel assemblies. A

response check of nuclear instruments to a neutron source was performed within

8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> prior to loading of the core, or upon resumption of loading if delay was for more than 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br />.

Fuel assemblies, together with inserted components (control rod assemblies, burnable, poison assemblies, source spider, or thimble plugging devices) were

placed in the reactor vessel one at a time, according to a previously

established and approved sequence developed to provide reliable core monitoring

with minimum possibility of core mechanical damage. The core loading procedure

documents prescribed the successive movements of each fuel assembly and its

specified inserts from its initial position in the storage racks to its final

position in the core. Fuel assembly status boards were maintained throughout

the core loading operation.

An initial nucleus of eight fuel assemblies, one containing a neutron source, is the minimum source-fuel nucleus which permitted subsequent meaningful

inverse count rate monitoring. This initial nucleus was determined by calculation to be markedly subcritical (K eff 0.95) under the required conditions of loading.

Each subsequent fuel addition was accompanied by detailed neutron count rate

monitoring to determine that the just-loaded fuel assembly did not excessively

increase the count rate and that the extrapolated inverse count rate ratio was

behaving as expected. These results for each loading step were evaluated before

the next fuel assembly was loaded. The final, as loaded, core configuration

was subcritical (K eff < 0.95) under the required loading conditions.

14.2-21 Rev. 0 WOLF CREEK 14.2.10.2 Initial Criticality Prior to initial criticality, the following tests were performed and the

results evaluated.

a. At the completion of core loading, the reactor upper

internals and pressure vessel head were installed. A

pressure test was conducted after filling, and venting

was completed to check the leaktightness of the vessel

head installation.

b. Mechanical and electrical tests were performed on the

control rod drive mechanisms. These tests included a

complete operational checkout of the mechanisms and

calibration of the individual rod position indicators.

c. Tests were performed on the reactor trip circuits to

test manual trip operation, and actual control rod

assembly drop times were measured for each control rod

assembly. At all times that the control rod drive

mechanisms were being tested, the boron concentration in

the coolant was maintained so that the shutdown margin

requirements specified in the Technical Specifications

were met. During individual RCCA or RCC bank motion, source range instrumentation was monitored for

unexpected changes in core reactivity.

d. The reactor control and reactor protection systems were

checked with simulated inputs to produce trip signals

for various trip conditions.

e. A functional electrical and mechanical check was made of

the incore nuclear flux mapping system near normal

operating temperature and pressure.

Initial criticality was achieved by a combination of shutdown and control bank

withdrawal and reactor coolant system boron concentration dilution. The plant

conditions, precautions, and specific instructions for the approach to

criticality were specified by approved procedures.

Initially, the shutdown and control banks of control rods were withdrawn

incrementally in the normal withdrawal sequence, leaving the last withdrawn

control bank partially inserted in the core to provide effective control when

criticality was achieved. The boron concentration in the reactor coolant

system was reduced and criticality achieved by boron dilution or by subsequent

rod withdrawal following boron dilution. Throughout this period, samples of

the primary coolant were obtained and analyzed for boron concentration.

14.2-22 Rev. 0 WOLF CREEK Inverse count rate ratio monitoring using data from the normal plant source range instrumentation was used as an indication of the proximity and rate of

approach to criticality. Inverse count rate ratio data was plotted as a

function of rod bank position during rod motion and as a function of reactor

makeup water addition during reactor coolant system boron concentration reduction.

14.2.10.3 Low Power Testing Following initial criticality, a program of reactor physics measurements was

undertaken to verify that the basic static and kinetic characteristics of the

core were as expected and that the values of the kinetic coefficients assumed in the safeguards analysis were conservative.

Procedures specified the sequence of tests and measurements to be conducted and

the conditions under which each was performed in order to ensure both safety of

operation and the validity and consistency of the results obtained. If test

results deviated significantly from design predictions, if unacceptable

behavior had been revealed, or if unexplained anomalies had developed, the

plant would have been brought to a safe stable condition and the situation

reviewed to determine the course of subsequent plant operation.

These measurements were made at low power and primarily at or near normal operating temperature and pressure. Measurements were made in order to verify

the calculated values of control rod bank reactivity worths, the isothermal

temperature coefficient under various core conditions, differential boron

concentration reactivity worth, and critical boron concentrations as functions

of control rod configuration. In addition, measurements of the relative power

distributions were made, and concurrent tests were conducted on the

instrumentation, including source and intermediate range nuclear channels.

Gamma and neutron radiation surveys were performed at selected points

throughout the station. Periodic sampling was performed to verify chemical and

radio-chemical analysis of the reactor coolant.

14.2.10.4 Power Level Ascension After the operating characteristics of the reactor were verified by low power

testing, a program of power level ascension brought the unit to its full rated

power level in successive stages. At each successive stage, hold points were provided to evaluate and approve test results prior to proceeding to the next

stage. The minimum test requirements for each successive stage of power

ascension were specified in the initial startup test procedures.

14.2-23 Rev. 0 WOLF CREEK Measurements were made to determine the relative power distribution in the core as functions of power level and control assembly bank position.

Secondary system heat balance measurements ensured that the indications of

power level were consistent and provide bases for calibration of the power range nuclear channels. The ability of the reactor coolant system to respond

effectively to signals from primary and secondary instrumentation under a

variety of conditions encountered in normal operations was verified.

At prescribed power levels, the dynamic response characteristics of the primary

and secondary systems were evaluated. System response characteristics were

measured for design step load changes, rapid load reduction, and plant trips.

Adequacy of radiation shielding was verified by gamma and neutron radiation

surveys at selected points throughout the station at various power levels.

Periodic sampling was performed to verify the chemical and radio-chemical analysis of the reactor coolant.

14.2.11 TEST PROGRAM SCHEDULE

Detailed schedules for testing were prepared, reviewed, and revised on a

continuing basis as plant construction progressed.

Preoperational tests which were not performed according to schedule were

reviewed on a case-by-case basis. Administrative procedures were established

to ensure that all prerequisites were met before testing was initiated. Upon

completion of all prerequisite tests applicable to a system or subsystem, a

documented review was conducted by Start-up personnel to verify that

appropriate documentation was available and that required prerequisite tests

were satisfactorily completed. All deficiencies which would have prevented performance of preoperational tests or generated negative test results were identified and dispositioned prior to implementation of the preoperational

tests.

Preoperational testing was scheduled to commence approximately 18 months prior

to fuel loading. The preoperational tests were performed and sequenced during

this period as a function of system turnover, system interrelationships, and

acceptance for testing.

Initial startup testing was scheduled to be conducted over a period of

approximately 3 to 5 months, commencing with fuel loading. The sequential

schedule for initial startup tests ensured, insofar as practicable, that test

requirements were completed

14.2-24 Rev. 0 WOLF CREEK prior to exceeding 25-percent power for all plant structures, systems, and components that are relied upon to prevent, limit, or mitigate the consequences

of postulated accidents.

The development of the test procedures was an ongoing process consisting of preparation, review, and revision. Preoperational test procedures were

available for NRC review approximately 60 days prior to the performance of an

individual test. If an individual test procedure was not available 60 days

prior to the test, the NRC was notified of the test date and the date the test

procedure was available. Initial startup test procedures were available for

NRC review at least 60 days prior to fuel loading.

14.2.12 INDIVIDUAL TEST DESCRIPTIONS

Test abstracts were provided for both safety-related and selected nonsafety-related preoperational tests. The abstracts included test prerequisites and summaries of test methods, objectives, and acceptance criteria.

14.2.12.1 Safety-Related Preoperational Test Procedures The following sections contain test abstracts used for safety- related

preoperational tests. Table 14.2-1 provides an index of these tests.

The preoperational test procedures were designated SO3 (Safety- Related/Common

to WCGS and Callaway), SU3 (Safety-Related/WCGS Specific), SO4 thru SO9 (Nonsafety-Related/Common to WCGS and Callaway) and SU4 thru SU9 (Nonsafety-

Related/WCGS Specific) as appropriate.

14.2.12.1.1 Steam Dump System Preoperational Test (S-03AB01)

14.2.12.1.1.1 Objectives

a. To demonstrate the operability of the steam dump control system control circuits in both the average temperature and steam pressure modes of operation.
b. To demonstrate the operation of the main steam dump

valves and main steam cooldown valves, including valve

response to safety signals.

c. To verify the operation of the main steam line drain

valves' control circuits, including valve response to a

turbine trip signal.

14.2-25 Rev. 0 WOLF CREEK

d. To verify the operation of the main steam to turbine-driven feedwater pump supply valves' control logics, including valve response to an auxiliary feedwater

actuation signal (AFAS).

e. To verify the operation of the main steam atmospheric relief valves' control circuits.

14.2.12.1.1.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are completed.

b. Required electrical power supplies and control circuits

are operational.

14.2.12.1.1.3 Test Method

a. Operability of the steam dump control system control

circuits is verified in both the average temperature and

steam pressure modes.

b. Operability of the main steam dump valves' and main steam cooldown valves' control circuits is verified, including valve response to turbine impulse low

pressure, low-low average temperature, and condenser

shell high pressure signals.

c. Operability of the main steam line drain valves' control

circuits is verified, including valve response to a

turbine trip signal.

d. Operability of the main steam to turbine-driven

auxiliary feedwater pump supply valves' control logics

is verified, including valve response to an AFAS.

e. Operability of the main steam atmospheric relief valves' control circuits is verified.

14.2.12.1.1.4 Acceptance Criteria

a. The response of the main steam dump valves and the main steam cooldown valves to the associated turbine impulse

low pressure, low-low average temperature, and condenser

shell high pressure signals is in accordance with system

design.

b. The main steam line drain valves open on receipt of a

turbine trip signal.

14.2-26 Rev. 13 WOLF CREEK

c. The main steam to turbine-driven auxiliary feedwater pump supply valves open on receipt of an AFAS.
d. The response of the main steam atmospheric relief valves to pressure signals is in accordance with system

design.

14.2.12.1.2 Main Steam Safety Valve Test (SU3-AB02)

14.2.12.1.2.1 Objectives

To verify the pressure relief setpoints of the main steam

safety valves.

NOTE: This objective may be accomplished either by bench

testing or with a pneumatic test device.

14.2.12.1.2.2 Prerequisites

The following prerequisites apply when a pneumatic test device is used.

a. Required instrument calibration is complete.
b. Hot Functional Testing is in progress.
c. A Source of compressed air is available to provide air

to the air set pressure device installed on the valve

under test.

The following prerequisites apply when bench testing is

performed.

a. Bench testing facility is available.
b. An approved WCGS procedure is available to accomplish

bench testing.

c. A source of compressed gas is available to provide

pressure to the valve under test.

14.2.12.1.2.3 Test Method

The following test method applied when a pneumatic test

device is used.

Main steam pressure is adjusted within the required range, and air is admitted to the air set pressure device on the

safety valve under test. Actual lift pressure is calculated, using the steam pressure and converted air pressure at the

time of lift.

14.2-27 Rev. 13 WOLF CREEK The following test applies when bench testing is performed.

With the main steam safety valve mounted on the bench test

facility, the spring assembly is preheated and the safety

valve is pressurized with compressed gas. Actual set pressure is determined at the time of lift.

14.2.12.1.2.4 Acceptance Criteria

Each main steam safety valve lifts within its respective

setpoint tolerance.

14.2.12.1.3 Main Steam Line Isolation Valve Test (S-03AB03)

14.2.12.1.3.1 Objectives

a. To verify the response of the main steam bypass, drain, and auxiliary feedwater turbine warmup valves to steam

line isolation signals.

b. To demonstrate the operability of the main steam

isolation valve control circuits, including control

circuit response to a steam line isolation signal

(SLIS).

14.2.12.1.3.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits are operational.
c. The main steam line isolation valve accumulators are

charged, and the associated hydraulic systems are

operational.

14.2.12.1.3.3 Test Method

An SLIS is initiated, and the response of the main steam bypass, main steam

drain, and auxiliary feedwater turbine warmup valves is verified.

14.2.12.1.3.4 Acceptance Criteria

a. The main steam bypass, drain, and auxiliary feedwater

turbine warmup valves close on receipt of an SLIS.

14.2.12.1.4 Main Steam System Preoperational Test (S-03AB04)

14.2-28 Rev. 0 WOLF CREEK 14.2.12.1.4.1 Objectives

a. To determine, during hot functional testing, the

operating times of the main steam isolation valves, main steam bypass valves, main steam dump valves, main steam cooldown valves, and the main steam atmospheric relief valves.

b. To verify the response of the main steam isolation

valves to steam line isolation signals.

14.2.12.1.4.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. Hot functional testing is in progress.
d. The condenser is available to receive steam from the main steam system.

14.2.12.1.4.3 Test Method

a. The main steam isolation valves, main steam bypass

valves, main steam dump valves, main steam cooldown

valves, and the main steam atmospheric relief valves are operated, and operating times are recorded.

b. An SLIS is initiated, and the response of the main steam

isolation valves is verified.

14.2.12.1.4.4 Acceptance Criteria

a. The operating times of the main steam isolation valves, main steam dump valves, main steam bypass valves, main

steam cooldown valves, and the main steam atmospheric relief valves are within design specifications.

b. The main steam isolation valves close on receipt of a

steam line isolation signal.

14.2.12.1.5 Main Feedwater System Preoperational Test (S-03AEO1)

14.2.12.1.5.1 Objectives

a. To demonstrate the operation of the feedwater system

valves and to verify the response of the feedwater

system valves to a feedwater isolation signal (FIS).

14.2-29 Rev. 13 WOLF CREEK

b. To perform the initial operation of the steam generator feedwater pumps (SGFP).

14.2.12.1.5.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The closed cooling water system is available to provide

cooling water to the SGFP lube oil coolers.

d. The compressed air system is available to provide air to system air-operated valves.
e. The steam seal system is available to provide seal steam

and packing exhaust for the SGFPs.

f. The main turbine is available for turning gear

operation.

g. The condensate system is available to supply suction for

the SGFPs.

h. The main condenser is available to receive SGFP turbine

exhaust.

i. The auxiliary steam system is available to provide steam flow to the SGFP turbines.

14.2.12.1.5.3 Test Method

a. Feedwater system valves are operated, and the proper

response of required system valves to an FIS is

verified.

b. The turbine-driven SGFPs are operated as limited by

steam, and operating data are recorded.

c. The motor-driven SGFP is operated, and operating data

are recorded.

14.2.12.1.5.4 Acceptance Criteria

a. The feedwater control valves, steam generator feedwater

isolation valves, feedwater chemical injection isolation

valves, and feedwater bypass control valves close on

receipt of an FIS.

14.2-30 Rev. 0 WOLF CREEK

b. The closing time of the feedwater isolation valves is within design specifications.
c. The performance of the motor-driven SGFP is within

design specifications.

14.2.12.1.6 Steam Generator Level Control Test (S-03AE02)

14.2.12.1.6.1 Objectives

a. To demonstrate the operability of the feedwater control

valves (FWCVs).

b. To demonstrate the operability of the FWCV bypass

valves.

c. To demonstrate the response of the FWCVs and bypass

valves to signals generated by the steam generator level

control system.

14.2.12.1.6.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2.12.1.6.3 Test Method

a. The FWCVs are operated from their respective controllers, and the FWCVs' response to feedwater flow, steamline flow, and steam generator level is verified.
b. The FWCV bypass valves are operated from their

respective controllers, and their response to steam

generator level and neutron flux signal is verified.

14.2.12.1.6.4 Acceptance Criteria

a. The response of the FWCVs to feedwater flow, steamline

flow, and steam generator level is in accordance with

system design.

b. The response of the FWCV bypass valves to steam

generator level and neutron flux signal is in accordance

with system design.

14.2-31 Rev. 0 WOLF CREEK 14.2.12.1.7 Auxiliary Feedwater Motor-Driven Pump and Valve Preoperational Test (S-03ALOl)

14.2.12.1.7.1 Objectives

To demonstrate the operability of the motor-driven auxiliary feedwater pumps, determine by flow test their ability to supply water to the steam generators, and verify their response to safety signals. The operation of system motor-

operated valves, including their response to safety signals, is also verified.

14.2.12.1.7.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits are operational.
c. The condensate storage tank contains an adequate supply

of demineralized water for the performance of this test.

d. The steam generators are available to receive water from

the auxiliary feedwater system.

14.2.12.1.7.3 Test Method

a. Performance characteristics of the motor-driven

auxiliary feedwater pumps are verified while discharging

to the steam generators.

b. System component control circuits are verified, including the operation of the motor-driven auxiliary

feedwater pumps and system valves on receipt of safety

signals.

14.2.12.1.7.4 Acceptance Criteria

a. Motor-driven auxiliary feedwater pump performance

characteristics must be within design specifications.

b. Motor-driven auxiliary feedwater pumps automatically

start on receipt of an engineered safety features

actuation signal (ESFAS) in the absence of an SIS signal

and a Class IE 4.16 kV bus undervoltage signal.

c. Auxiliary feedwater suction valves from essential

service water system open, and suction valves from

condensate storage tank close, on condensate storage

tank low-suction-pressure signals, coincident with an

auxiliary feedwater pump ESFAS.

14.2-32 Rev. 0 WOLF CREEK 14.2.12.1.8 Auxiliary Feedwater Turbine-Driven Pump and Valve Preoperational Test (SU3-AL02)

14.2.12.1.8.1 Objectives

a. To verify the auxiliary feedwater pump turbine

mechanical trip and throttle valve automatic operation

on an auxiliary feedwater actuation signal (AFAS).

b. To perform the initial coupled operation of the turbine-

driven auxiliary feedwater pump. Full flow

characteristics of the turbine-driven pump will be

demonstrated during hot functional testing.

c. To perform five consecutive, successful, cold starts of the turbine-driven auxiliary feedwater pumps.

14.2.12.1.8.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b Required electrical power supplies and control circuits

are operational.

c. The steam generators are available to receive water from

the auxiliary feedwater pumps.

d. The steam generator blowdown system is available to

maintain the normal operating levels in the steam generators during auxiliary feedwater pump operation.

e. The auxiliary steam system is available to supply steam

to the auxiliary feedwater pump turbine.

f. For the performance characteristic test of this pump, hot functional testing (HFT) is in progress.

14.2.12.1.8.3 Test Method

a. An AFAS is simulated, and opening of the mechanical trip

and throttle valve is verified.

b. The turbine-driven auxiliary feedwater pump is operated

during HFT, and performance characteristics are

recorded.

c. The ability of the turbine-driven auxiliary feedwater

pumps to start successfully five consecutive times from

cold conditions is verified.

14.2-33 Rev. 0 WOLF CREEK 14.2.12.1.8.4 Acceptance Criteria

a. The auxiliary feedwater pump mechanical trip and

throttle valve opens automatically on an AFAS.

b. Operating characteristics of the turbine-driven

auxiliary feedwater pump are in accordance with design.

c. The turbine driven auxiliary feedwater pump starts

successfully five consecutive times from a cold start.

14.2.12.1.9 Auxiliary Feedwater Motor-Driven Pump Endurance Test

(SU3-AL03)

14.2.12.1.9.1 Objectives

a. To demonstrate that the motor-driven auxiliary feedwater

pumps can operate for 48 continuous hours without

exceeding any of their limiting design specifications.

b. To demonstrate that the motor-driven auxiliary feedwater

pumps can operate for 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> after a cooldown from the

48-hour test.

c. To demonstrate that the room environmental conditions

are not exceeded during the 48-hour test.

14.2.12.1.9.2 Prerequisites

a. Required component testing, instrument calibration and system flushing/cleaning are complete.
b. Required electrical power supplies and control circuits

are operational.

c. The appropriate auxiliary feedwater pump room coolers

are operational.

d. The condensate storage tank is available as a water

source and to receive recirculation flow.

14.2.12.1.9.3 Test Method

Each motor-driven pump is started and operated for 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> after reaching

rated speed and rated discharge pressure and flow, or a greater pressure and

less flow. During the endurance run, pump- operating data and the pump room

environmental conditions are recorded. At the completion of each endurance

test, the pump is cooled for 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> and until pump data returns to within 20 F

of the original pretest data. The pump is then started and operated for 1

hour.

14.2-34 Rev. 0 WOLF CREEK 14.2.12.1.9.4 Acceptance Criteria

a. The operating parameters (vibration, bearing

temperatures, etc.) of each motor-driven auxiliary

feedwater pump do not exceed the design specifications.

b. The environmental conditions of each motor-driven

auxiliary feedwater pump room do not exceed the design

specifications.

14.2.12.1.10 Auxiliary Feedwater System Water Hammer Test (S-

03AL04)

14.2.12.1.10.1 Objectives

To demonstrate that the injection of auxiliary feedwater at rated flow into a steam generator at or near normal operating temperatures will not cause

damaging water hammer to the steam generators and/or feedwater system.

14.2.12.1.10.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The steam generators are at or near normal operating

temperature.

d. The condensate storage tank is available as a water source.

14.2.12.1.10.3 Test Method

Auxiliary feedwater is injected into each steam generator. The feedwater system

piping and the steam generators are monitored visually and audibly to verify

that no damaging water hammer occurs.

14.2.12.1.10.4 Acceptance Criteria

No damaging water hammer occurs.

14.2.12.1.11 Auxiliary Feedwater Turbine-Driven Pump Endurance

Test (SU3-AL05)

14.2.12.1.11.1 Objectives

14.2-35 Rev. 0 WOLF CREEK

a. To demonstrate that the turbine-driven auxiliary feedwater pump can operate for 48 continuous hours

without exceeding any of its limiting design

specifications.

b. To demonstrate that the turbine-driven auxiliary

feedwater pump can operate for 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> after a cool down

from the 48-hour test.

c. To demonstrate that the room environmental conditions

are not exceeded during the 48-hour test.

14.2.12.1.11.2 Prerequisites

a. Required component testing, instrument calibration and system flushing/cleaning are complete.
b. Required electrical power supplies and control circuits

are operational.

c. The appropriate auxiliary feedwater pump room coolers

are operational.

d. The condensate storage tank is available as a water

source and to receive recirculation flow.

e. A steam source is available.

14.2.12.1.11.3 Test Method

The pump is started and operated for 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> after reaching rated speed and rated discharge pressure and flow, or a greater pressure and less flow. The

turbine-driven auxiliary feedwater pump operating steam is as close to normal

operating temperature as possible and is at least 400 F. During the endurance

run, pump-operating data and the pump room environmental conditions are

recorded. At the completion of the endurance test, the pump is cooled for 8

hours and until pump data returns to within 20 F of the original pretest data.

The pump is then started and operated for 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br />.

14.2.12.1.11.4 Acceptance Criteria

a. The operating parameters (vibration, bearing

temperatures, etc.) do not exceed the design

specifications.

b. The environmental conditions of the turbine-driven

auxiliary feedwater pump room do not exceed the design

specifications.

14.2-36 Rev. 0 WOLF CREEK 14.2.12.1.12 Reactor Coolant Pump Initial Operation (S-03BB01)

14.2.12.1.12.1 Objectives

To demonstrate the operating characteristics of the reactor coolant pumps and verify the operation of their associated oil lift pumps.

14.2.12.1.12.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The chemical and volume control system is available to provide seal water to the reactor coolant pump seals.
d. The component cooling water system is available to

supply cooling water to the reactor coolant pumps.

14.2.12.1.12.3 Test Method

The reactor coolant pumps and associated oil lift pumps are operated, and pump

operating data are recorded.

14.2.12.1.12.4 Acceptance Criteria

Reactor coolant pump and oil lift pump operating characteristics are within

design specifications.

14.2.12.1.13 Pressurizer Relief Tank Cold Preoperational Test

(SU3-BB02)

14.2.12.1.13.1 Objectives

To demonstrate that the reactor makeup water system can supply design

pressurizer relief tank (PRT) spray flow against design backpressure. The

operation of the PRT nitrogen isolation valves, including their response to a

containment isolation signal, is also verified.

14.2.12.1.13.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2-37 Rev. 0 WOLF CREEK

c. The reactor makeup water system is available to supply water to the PRT.
d. The service gas system is available to pressurize the

PRT.

14.2.12.1.13.3 Test Method

a. With a design backpressure in the PRT, a reactor makeup

water pump is operated to obtain the spray flow to the

PRT.

b. The response of the PRT nitrogen isolation valves to a

containment isolation signal is verified.

14.2.12.1.13.4 Acceptance Criteria

a. The reactor makeup water system supplies the design

spray flow to the PRT with design backpressure in the

PRT.

b. PRT nitrogen isolation valves close on receipt of a

containment isolation signal. Valve closure times are

within design specifications.

14.2.12.1.14 RTD Bypass Flow Measurement (SU3-BB03)

At WCGS, test S-07BB01 (USAR Section 14.2.12.3.3) was used to satisfy the

requirement for verification of design specifications.

14.2.12.1.15 Pressurizer Pressure Control Test (S-03BB04)

14.2.12.1.15.1 Objectives

To demonstrate the stability and response of the pressurizer pressure control

system, including the verification of pressurizer pressure alarm and control

functions.

14.2.12.1.15.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The plant is at normal operating temperature and

pressure with all reactor coolant pumps running, and hot

functional testing is in progress.

14.2-38 Rev. 0 WOLF CREEK 14.2.12.1.15.3 Test Method

a. Pressurizer pressure is varied, and the ability of the

pressurizer pressure control system to automatically

control and stabilize pressurizer pressure is verified.

b. Pressurizer pressure is varied, and pressurizer pressure

control system alarm and control setpoints are verified.

14.2.12.1.15.4 Acceptance Criteria

a. The pressurizer pressure control system responds, in

accordance with system design, to an increase and

decrease in system pressure.

b. Pressurizer pressure control system alarm and control setpoints are within design specifications.

14.2.12.1.16 Reactor Coolant System Hot Preoperational Test

(S-03BB05)

14.2.12.1.16.1 Objectives

a. To operate the reactor coolant system at full flow

conditions for a minimum of 240 hours0.00278 days <br />0.0667 hours <br />3.968254e-4 weeks <br />9.132e-5 months <br /> to provide the

necessary vibration cycles on the vessel's internal

components prior to their inspection at core loading.

b. To provide coordination and initial conditions necessary

for the conduct of those preoperational tests to be performed during heatup, normal operating temperature and pressure, and cooldown of the reactor coolant

system.

14.2.12.1.16.2 Prerequisites

a. The reactor coolant system cold hydrostatic test is

complete.

b. The reactor vessel internals and head are installed, and

the vessel is available to support this test.

c. All systems and components required to support heatup, operations at normal temperature and pressure, and

cooldown of the reactor coolant system are available.

d. Required instrument calibration is complete.

14.2-39 Rev. 0 WOLF CREEK

e. The examination of the reactor internals in accordance with Section 3.9(N).2.4, is complete

14.2.12.1.16.3 Test Method

a. The reactor coolant system is operated at full flow

conditions for a minimum of 240 hours0.00278 days <br />0.0667 hours <br />3.968254e-4 weeks <br />9.132e-5 months <br />.

b. Those preoperational tests required to be performed

during heatup, normal operating temperature and

pressure, and cooldown of the reactor coolant system are

completed, as coordinated by this test.

14.2.12.1.16.4 Acceptance Criteria

The reactor coolant system has operated at full flow conditions for a minimum of 240 hours0.00278 days <br />0.0667 hours <br />3.968254e-4 weeks <br />9.132e-5 months <br />.

Notes: 1. The acceptance criteria for individual systems are a

part of the individual test procedures sequenced by

this procedure.

2. A post-hot functional examination of the reactor

internals is performed as described in Section

3.9(N).2.4.

14.2.12.1.17 Thermal Expansion (S-03BB06)

14.2.12.1.17.1 Objectives

To verify that during heatup and cooldown of the reactor coolant system the associated components, piping, support, and restraint deflections are

unobstructed and within design specifications.

14.2.12.1.17.2 Prerequisites

a. This test is conducted in conjunction with hot

functional testing.

b. Supports, restraints, and hangers are installed and

reference points and predicted movements established.

c. Required instrument calibration is complete.

14.2.12.1.17.3 Test Method

During the reactor coolant system heatup and cooldown, deflection data are

recorded.

14.2-40 Rev. 0 WOLF CREEK 14.2.12.1.17.4 Acceptance Criteria

a. Unrestricted expansion and movements are verified to be

within design specifications.

b. Components, piping, supports, and restraints return to

their baseline cold position in accordance with system

design.

14.2.12.1.18 Pressurizer Level Control Test (S-03BB07)

14.2.12.1.18.1 Objectives

To demonstrate the stability and response of the pressurizer level control

system, including the verification of pressurizer level alarm and control functions.

14.2.12.1.18.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The letdown and charging portions of the chemical and

volume control system are available to vary pressurizer

level.

d. The plant is at normal operating temperature and pressure, and hot functional testing is in progress.

14.2.12.1.18.3 Test Method

a. Pressurizer level is varied and the ability of the

pressurizer level control system to automatically

control and stabilize pressurizer level is verified.

b. Pressurizer level is varied, and pressurizer level

control system alarm and control setpoints are verified.

14.2.12.1.18.4 Acceptance Criteria

a. The response and stability of the pressurizer level

control system are within design specifications.

b. The pressurizer level control system alarm and control

functions are within design specifications.

14.2-41 Rev. 0 WOLF CREEK 14.2.12.1.19 Pressurizer Heater and Spray Capability Test (SU3-BB08)

14.2.12.1.19.1 Objectives

To determine the electrical capacity of the pressurizer heaters, and the rate

of pressure increase from the operation of all pressurizer heaters.

14.2.12.1.19.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The plant is at normal operating temperature and

pressure with all reactor coolant pumps running, and hot

functional testing is in progress.

14.2.12.1.19.3 Test Method

a. Pressurizer heaters are energized, and heater capacity

is calculated.

b. With the pressurizer spray valves closed, all

pressurizer heaters are energized, and the time to reach

a 2,300 psig system pressure is measured and recorded.

14.2.12.1.19.4 Acceptance Criteria

a. The capacity of the pressurizer heaters is within design

limits.

b. The pressurizer pressure response to the actuation of

all pressurizer heaters is within design limits.

14.2.12.1.20 Reactor Coolant System Flow Measurement Test

(SU3-BB09)

At WCGS, Test S-07BB03 (USAR Section 14.2.12.3.5) is used to satisfy the

requirements for verification of design specifications.

14.2.12.1.21 Reactor Coolant System Flow Coastdown Test

(SU3-BB10)

14.2-42 Rev. 0 WOLF CREEK At WCGS, Test S-07BB04 (USAR Section 14.2.12.3.6) is used to satisfy the requirements for verification of design specifications.

14.2.12.1.22 Reactor Coolant System Hydrostatic Test (S-03BBll)

14.2.12.1.22.1 Objectives

To verify the integrity and leaktightness of the reactor coolant system and the

high-pressure portions of associated systems.

14.2.12.1.22.2 Prerequisites

a. Required system flushing/cleaning are complete.
b. The reactor coolant pumps are available to support this test.
c. The reactor vessel's lower internals, upper internals, filter assembly, and the closure head are installed.

The studs are tensioned to design value for the

associated hydrostatic test pressure

d. Temporary temperature instrumentation is installed for

measuring the temperature of the steam generator tube

sheets, the bottom of the pressurizer, and the closure

flange of the reactor vessel.

e. A charging pump or test pump is available to pressurize

the system.

f. Required instrument calibration is complete.

14.2.12.1.22.3 Test Method

The minimum temperature for pressurizing the system is established. The

reactor coolant pumps are operated as required to establish the required

temperature. The system is then pressurized to test pressure, and system

welds, flanges, piping, and components are monitored for leakage.

14.2.12.1.22.4 Acceptance Criteria

The reactor coolant system and associated high-pressure systems are verified

leaktight in accordance with the requirements of the ASME Boiler and Pressure

Vessel Code,Section III, "Nuclear Components," through the Winter 1975

Addenda.

14.2.12.1.23 Pressurizer Continuous Spray Flow Verification Test

(SU3-BB12)

14.2-43 Rev. 0 WOLF CREEK At WCGS, Test S-07BB05 (USAR Section 14.2.12.3.7) was used to satisfy the requirements for verification of design specifications.

14.2.12.1.24 Pressurizer Relief Valve and PRT Hot Preoperational

Test (S-03BB13)

14.2.12.1.24.1 Objectives

To demonstrate that the operating times of the pressurizer power- operated

relief valves are within design specifications. The ability of the reactor

coolant drain tank portion of the liquid radwaste system to cool down the

pressurizer relief tank (PRT) at the design rate is also verified.

14.2.12.1.24.2 Prerequisites

a. Required component testing and instrument calibration are complete.
b. Required electrical power supplies and control circuits

are operational.

c. The PRT is at a normal operating level and is aligned

for normal operation.

d. The liquid radwaste system is available to cool down the

PRT via the reactor coolant drain tank heat exchanger.

e. The plant is at normal operating temperature and pres-

sure, and hot functional testing is in progress.

14.2.12.1.24.3 Test Method

a. Pressurizer power-operated relief valves are operated, and opening times recorded.
b. Following the operation of the pressurizer power-

operated relief valves, the PRT is cooled down via the

reactor coolant drain tank heat exchanger, and the

cooldown rate is calculated and recorded.

14.2.12.1.24.4 Acceptance Criteria

a. Power-operated relief valve operating times are within

design specifications.

14.2-44 Rev. 0 WOLF CREEK

b. The reactor coolant drain tank portion of the liquid radwaste system cools down the PRT at a rate within

design specifications.

14.2.12.1.25 Reactor Coolant Loop Vibration Surveillance Test (S-03BB14)

14.2.12.1.25.1 Objectives

To verify that the dynamic effects experienced during reactor coolant loop

steady flow and reactor coolant loop pump transients as measured during hot

functional testing (HFT) do not exceed acceptance criteria for the primary loop

piping and components.

14.2.12.1.25.2 Prerequisites

a. Hot functional testing is in progress.
b. Reference points for vibrational measurement of the

reactor coolant piping and components are established.

c. All subject systems are available for the specified

dynamic operation.

d. Required instrument calibration is complete.

14.2.12.1.25.3 Test Method

a. The systems are aligned for the specified dynamic

operation.

b. The specified dynamic event is initiated and the reactor

coolant piping and component responses are monitored.

14.2.12.1.25.4 Acceptance Criteria

The measured deflections for each of the test measurement points are within a

specified percent of the calculated reference deflections.

14.2.12.1.26 Leak Detection System Preoperational Test

(SU3-BB15A)

14.2.12.1.26.1 Objectives

a. To determine, during hot functional testing, the amount

of identified and unidentified leakage from the reactor

coolant system and verify that the leakage is within

design limits.

14.2-45 Rev. 0 WOLF CREEK

b. To demonstrate the ability to detect an increase in reactor coolant system leakage.

14.2.12.1.26.2 Prerequisites

a. Required instrument calibration is complete.
b. Hot functional testing is in progress, and the reactor

coolant system is at normal operating temperature and

pressure.

c. The volume control tank contains an adequate supply of

water to support this test.

d. The reactor coolant drain tank and associated pumps are available to support this test.

14.2.12.1.26.3 Test Method

a. The reactor coolant system identified and unidentified

leakage rates are determined by monitoring the reactor

coolant system water inventory.

b. A known leakage rate is initiated, and the ability to

detect an increase in leakage is verified.

14.2.12.1.26.4 Acceptance Criteria

a. Reactor coolant system identified and unidentified

leakage is within design limits.

b. The ability to detect an increase in reactor coolant

system leakage is verified.

14.2.12.1.27 Leak Detection System Preoperational Test

(SU3-BB15B)

14.2.12.1.27.1 Objectives

a. To demonstrate the operation of the leak detection

system and to verify the ability of the system to detect

leakage within the required time limit as specified by

design.

b. The operation of the containment particulate and

radioactive gas monitoring portions of the Leak

Detection System are verified in SU4-SP01, Process

Radiation Monitoring System Preoperational Test.

14.2-46 Rev. 0 WOLF CREEK 14.2.12.1.27.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. The containment normal sumps, instrument tunnel sump, floor drain tank, auxiliary building sump and associated

pumps are available to support this test.

14.2.12.1.27.3 Test Method

a. A known simulated leakage is initiated, and the ability

of the system to detect the leakage within the design

time is verified.

14.2.12.1.27.4 Acceptance Criteria

a. The ability of the leak detection system to detect a

leak within the design time is verified.

14.2.12.1.28 RTD/TC Cross Calibration (S-03BB16)

14.2.12.1.28.1 Objectives

To provide a functional checkout of the reactor coolant system resistance

temperature detectors (RTDs) and incore thermocouples and to generate

isothermal cross-calibration data for subsequent correction factors to

indicated temperatures.

14.2.12.1.28.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. Initial plant heatup, during hot functional testing, is

in progress, and all reactor coolant pumps are

operating.

14.2.12.1.28.3 Test Method

At various temperature plateaus, RTD and incore thermocouple data are recorded.

Isothermal cross-calibration correction factors for individual thermocouples

and the installation corrections for individual RTDs are determined.

14.2-47 Rev. 0 WOLF CREEK 14.2.12.1.28.4 Acceptance Criteria

a. Individual RTD readings are within the design

specifications.

b. The installation corrections of the RTDs are within

design specifications.

14.2.12.1.29 Chemical and Volume Control System Major Component

Test (S-03BG01)

14.2.12.1.29.1 Objectives

To demonstrate the operation of the centrifugal charging pumps and associated minimum flow valves, including their response to safety signals.

14.2.12.1.29.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The refueling water storage tank contains an adequate

supply of demineralized water for the performance of

this test.

d. The component cooling water system is available to provide cooling water to the centrifugal charging pump oil coolers.

14.2.12.1.29.3 Test Method

a. Centrifugal charging pumps are operated, and performance

characteristics are verified.

b. Centrifugal charging pump and minimum flow valve control

logics are verified, including their response to safety

signals.

14.2.12.1.29.4 Acceptance Criteria

a. Centrifugal charging pump performance characteristics

are within design specifications.

b. Each centrifugal charging pump receives a start signal

from the load sequencer.

14.2-48 Rev. 0 WOLF CREEK

c. If a safety injection signal is present, a centrifugal charging pump minimum flow valve will open if the

associated pump flow is low and will close if the

associated pump flow is above the minimum flow

requirement of the pump.

14.2.12.1.30 Seal Injection Preoperational Test (SU3-BG02)

14.2.12.1.30.1 Objective

To demonstrate the ability of the chemical and volume control system to supply

adequate seal water injection flow to the reactor coolant pumps and verify the

operation of the seal water return containment isolation valves, including

their response to a CIS.

14.2.12.1.30.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The volume control tank contains an adequate supply of

demineralized water for the performance of this test.

d. Cooling water is available to the charging pumps.

14.2.12.1.30.3 Test Method

a. With a charging pump in operation, seal water throttle valves are adjusted to maintain the required flow to

each reactor coolant pump.

b. Seal water return containment isolation valves control

logics are verified, including their response to a CIS.

14.2.12.1.30.4 Acceptance Criteria

a. Seal water injection flow to each reactor coolant pump

is within design specifications.

b. Seal water return containment isolation valves close on

receipt of a CIS. Valve closure times are within design

specifications.

14.2-49 Rev. 0 WOLF CREEK 14.2.12.1.31 Charging System Preoperational Test (SU3-BG03)

14.2.12.1.31.1 Objective

To demonstrate positive displacement charging pump (replaced by the normal charging pump per DCP 04590) operating characteristics and to verify the operation of the regenerative heat exchanger inlet isolation valves and the

letdown isolation valves, including their response to a safety injection signal (SIS).

14.2.12.1.31.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The volume control tank contains an adequate supply of

demineralized water for the performance of this test.

d. Cooling water is available to the positive displacement charging pump (replaced by the normal charging pump per DCP 04590).
e. The reactor coolant system is available to receive

charging system flow.

14.2.12.1.31.3 Test Method

a. The positive displacement charging pump (replaced by the normal charging pump per DCP 04590)is operated, and pump operating data are recorded.
b. Regenerative heat exchanger inlet isolation valve and

letdown system isolation valve control circuits are

verified, including valve response to safety injection signals.

14.2.12.1.31.4 Acceptance Criteria

a. Positive displacement charging pump (replaced by the normal charging pump per DCP 04590)operating characteristics are within design specifications.
b. Charging pump to regenerative heat exchanger inlet

isolation valves close on receipt of an SIS. Valve

closure times are within design specifications.

c. The letdown line containment isolation valves close on

receipt of a containment isolation signal. Valve

closure times are within design specifications.

14.2-50 Rev. 12 WOLF CREEK 14.2.12.1 32 Boron Thermal Regeneration System Preoperational Test (SU3-BG04)

14.2.12.1.32.1 Objective

To verify the operation of the boron thermal regeneration system, and

associated control circuits. Performance characteristics of the chemical and

volume control system chiller pumps are also verified.

14.2.12.1.32.2 Prerequisites

a. Required component testing, instrument calibration and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits are operational.
c. The volume control tank contains an adequate supply of

demineralized water for the performance of this test.

d. The chemical and volume control system chiller surge

tank contains an adequate supply of demineralized water

for the performance of this test.

14.2.12.1.32.3 Test Method

a. The chemical and volume control system chiller pumps are

operated and performance characteristics are verified.

b. Boron thermal regeneration system component control circuits are verified.

14.2.12.1.32.4 Acceptance Criteria

a. The chemical and volume control system chiller pumps'

operating characteristics are within design

specifications.

b. The chemical and volume control system chiller pumps

start automatically when the boron thermal regeneration

system is placed in the borate or dilute mode of

operation.

14.2.12.1.33 Boric Acid Blending System Preoperational Test (SU3-

BG05)

14.2.12.1.33.1 Objectives

a. To demonstrate the operating characteristics of boron

injection makeup and boric acid transfer pumps and

14.2-51 Rev. 0 WOLF CREEK verify the ability of the boric acid blending system to make up at design flow rates to the chemical and volume

control system (CVCS).

b. To verify the operation of system component control circuits in all modes of operation.
c. To demonstrate by flow test the ability of the reactor

makeup water system to supply water to the boric acid

blender.

d. To demonstrate by flow test the ability of the boric

acid system to supply an emergency boration flow to the

charging pump suction.

e. To verify the operation of volume control tank valves and associated control circuits, including valve

response to safety signals.

14.2.12.1.33.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The reactor makeup water system is available to supply

water to the boric acid blender and boric acid batching

tank.

d. A charging pump is available to receive and discharge

flow from the boric acid transfer pumps.

e. The volume control tank (VCT) contains an adequate

supply of demineralized water for the performance of

this test.

14.2.12.1.33.3 Test Method

a. The boron injection makeup and boric acid pumps are

operated, performance data recorded, and the ability of

the system to make up to the CVCS at design flow rates

is verified.

b. System component control circuits are verified in all

modes of operation.

14.2-52 Rev. 0 WOLF CREEK

c. With a reactor makeup water pump in operation, flow is verified to the boric acid blender and boric acid

batching tank.

d. With both boric acid transfer pumps in operation and a charging pump taking a suction from the VCT and

discharging to the reactor coolant loops, the emergency

boration flow rate from the transfer pumps to the

charging pump suction is recorded.

e. The emergency boration flow rate via gravity feed from

the boric acid tanks to the charging pump suction is

recorded.

f. Proper operation of the reactor makeup water system is verified when the reactor makeup control system (RMCS) is operated in the manual, dilute, alternate dilute, and

automatic modes.

g. The operation of the VCT outlet valves control circuits

is verified, including their response to a safety

injection signal.

14.2.12.1.33.4 Acceptance Criteria

a. The boron injection makeup and boric acid transfer pump

operating characteristics are within design

specifications.

b. The flow rate to the boric acid blender from the reactor makeup water system is within design specifications.
c. The emergency boration flow rates to the charging pump

suction are within design specifications.

d. The boric acid transfer pumps and the reactor makeup

water pumps start automatically on a low level in the

volume control tank when the RMCS is in the automatic

mode.

e. VCT outlet valves close on receipt of a safety injection

signal when the associated charging pump supply valve

from the refueling water storage tank is open.

f. Refueling water storage tank to charging pump suction

valves open on receipt of a safety injection signal.

g. The boric acid transfer pumps stop on receipt of a load

shed signal.

14.2-53 Rev. 0 WOLF CREEK

h. The boric acid filter to charging pump valve supply breaker trips open on receipt of a load shed signal.

14.2.12.1.34 Chemical and Volume Control System Hot

Preoperational Test (S-03BG06)

14.2.12.1.34.1 Objectives

a. To determine by flow test that all letdown and cleanup

flow rates are within design specifications.

b. To determine, by comparison of boron concentrations, that boric acid addition to the reactor coolant system

has occurred, using the normal and emergency flow paths.

c. To determine by flow test the ability of the chemical and volume control system (CVCS) to make up at design

flow rates and boron concentrations to the reactor

coolant system in all modes of operation.

d. To determine by operational test that the letdown

containment isolation valve closure times are within

design specifications.

e. To demonstrate the ability of the pump room coolers to

maintain room temperatures within design limits.

14.2.12.1.34.2 Prerequisites

a. Required component testing, instrument calibration, and system flushing/cleaning are complete.
b. Required electrical power supplies and control circuits

are operational.

c. The plant is at normal operating temperature and

pressure, and hot functional testing is in progress.

d. The CVCS pump rooms are closed, and their associated

pump room coolers are operational.

14.2.12.1.34.3 Test Method

a. The letdown throttle valves are adjusted to establish

letdown flow within design specifications.

b. Boric acid addition to the reactor coolant system is

verified, using the normal and emergency flow paths, by

comparing the change in boron concentrations.

14.2-54 Rev. 0 WOLF CREEK

c. With a charging pump in operation, the ability of the CVCS, in all modes of operation, to make up at design

flow rates and boron concentrations to the reactor

coolant system is verified.

d. With letdown flow established, the letdown containment

isolation valves are operated, and operating times are

recorded.

e. During CVCS pump operation, pump room temperature data

are recorded.

14.2.12.1.34.4 Acceptance Criteria

a. All letdown and cleanup flow rates are within design specifications
b. The boric acid addition system is capable of adding

boron to the reactor coolant system via both the normal

and emergency flow paths.

c. The CVCS makeup flow rates and boron additions to the

reactor coolant system are within design specifications

in all modes of operation.

d. The letdown containment isolation valves' closure times

are within design specifications.

e. The CVCS pump room coolers maintain the room temperature

within design limits.

f. The boron thermal regeneration system (BTRS) can vary

the reactor coolant boron concentration as required for

daily load cycle at 85 percent core life.

14.2.12.1.35 Fuel Pool Cooling and Cleanup System Preoperational

Test (SU3-EC01)

14.2.12.1.35.1 Objectives

a. To demonstrate the operating characteristics of the fuel

pool cooling, fuel pool cleanup, and pool skimmer pumps

and to verify that the associated instrumentation and

controls are functioning properly.

b. To verify that the fuel pool cleanup pump refueling

water storage tank (RWST) suction isolation valves close

on receipt of a safety injection signal (SIS).

14.2-55 Rev. 0 WOLF CREEK

c. To verify that each fuel pool cooling pump room cooler starts when the associated fuel pool cooling pump

starts.

14.2.12.1.35.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. Cooling water is available to the fuel pool cooling and

cleanup system heat exchangers.

d. The liquid radwaste system is available to drain the refueling pool to the RWST.
e. The essential service water system is available to

provide cooling water to the spent fuel pool pump room

coolers.

f. The spent fuel pool and fuel transfer canals are filled

to their normal operating levels.

14.2.12.1.35.3 Test Method

a. The fuel pool cooling, fuel pool cleanup, and pool

skimmer pumps are operated in their various modes, and

pump operating data are recorded.

b. System component control circuits are verified, including the operation of system pumps and valves on

receipt of safety signals.

c. The ability of each fuel pool cooling pump room cooler

to start when the associated fuel pool cooling pump

starts is verified.

14.2.12.1.35.4 Acceptance Criteria

a. The operating characteristics of the fuel pool cooling, fuel pool cleanup, and pool skimmer pumps are within

design specifications.

b. The fuel pool cleanup pumps RWST suction isolation

valves close on receipt of an SIS.

14.2-56 Rev. 0 WOLF CREEK

c. Each fuel pool cooling pump trips on a low spent fuel pool level signal.
d. Each fuel pool cooling pump trips on receipt of a load

shed signal.

e. Each fuel pool cooling pump room cooler starts when the

associated fuel pool cooling pump starts.

14.2.12.1.36 Spent Fuel Pool Leak Test (S-03EC02)

14.2.12.1.36.1 Objectives

a. To demonstrate the integrity of the spent fuel pool, cask loading pit, and fuel transfer canal.
b. To demonstrate the leaktightness of the cask loading pit

gate and the fuel transfer canal gate.

14.2.12.1.36.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The spent fuel pool is filled to the normal operating

level.

d. The cask loading pit level is below the level of the fuel pool gate.
e. The fuel transfer canal level is below the level of the

fuel pool gate.

f. The reactor makeup water system is available to provide

demineralized water to the spent fuel pool.

g. A source of compressed air is available to pressurize

the system standpipes.

14.2.12.1.36.3 Test Method

The cask loading pit gate and fuel transfer canal gate are visually inspected

for leakage. A leak test is performed on the spent fuel pool, cask loading

pit, and fuel transfer canal, using the associated leak chase standpipes.

14.2-57 Rev. 0 WOLF CREEK 14.2.12.1.36.4 Acceptance

No leakage is observed from the spent fuel pool, cask loading pit, fuel

transfer canal, cask loading pit gate, and fuel transfer canal gate.

14.2.12.1.37 Essential Service Water System Preoperational Test

(SU3-EF01)

Test SU3-EF02 combined with Test SU3-EF01, Essential

Service Water System Preoperational Test.

14.2.12.1.37.1 Objectives

a. To demonstrate the capability of the essential service

water system to provide cooling water flow during the LOCA mode of operation. The operation and response of system valves to align the system in the LOCA flow mode

on safety injection signals, load sequence signals, and

low suction pressure signals are also verified.

b. To demonstrate the operating characteristics of the

essential service water (ESW) pumps and verify their

response to safety signals.

c. To demonstrate the operability of the backpressure

control valves, including their response to safety

signals.

14.2.12.1.37.2 Prerequisites

a. Required component testing, instrument calibration, and system flushing/cleaning are complete.
b. Required electrical power supplies and control circuits

are operational.

c. The compressed air system is available to the system

air-operated valves.

14.2.12.1.37.3 Test Method

a. System operating characteristics are verified in the

LOCA mode of operation.

b. Safety signals are simulated, and the responses of the

system valves and the ESW pumps are verified.

c. The ESW pumps are operated and pump operating data are

recorded.

14.2-58 Rev. 0 WOLF CREEK

d. The operability of the backpressure control valves, including their response to safety signals is verified.

14.2.12.1.37.4 Acceptance Criteria

a. Components supplied by the essential service water

system receive flows that are within design

specifications in the LOCA mode of system operation.

b. System valve operation in response to safety signals is

within design requirements.

c. System valve operating times are within design

specifications.

d. The ESW pumps' operating characteristics are within design specifications.
e. Each ESW pump responds properly to load sequence and

load shed signals.

f. The time required for each ESW pump to reach rated flow

is within design specifications.

g. System backpressure valves close upon receipt of a LOCA

sequencer or safety injection signal.

h. An auxiliary feedwater pump low suction pressure signal

will close the ESW pump breakers if a zero sequencer

signal is not present.

14.2.12.1.38 Component Cooling Water System Preoperational Test

(S-03EG01)

14.2.12.1.38.1 Objectives

a. To demonstrate the capability of the component cooling

water system to provide cooling water during the normal, shutdown, and post-LOCA modes of operation.

b. To demonstrate the operating characteristics of the

component cooling water pumps and to verify that the

associated instrumentation and controls are functioning

properly, including system response to safety signals.

14.2.12.1.38.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

14.2-59 Rev. 0 WOLF CREEK

b. Required electrical power supplies and control circuits are operational.

14 2.12.1.38.3 Test Method

a. System operating characteristics are verified in the

normal, shutdown, and post-LOCA modes of operation.

b. Safety signals are simulated, and the response of system

pumps and valves is verified.

14.2.12.1.38.4 Acceptance Criteria

a. The performance characteristics of each component

cooling water pump are within design specifications.

b. Components supplied by the component cooling water

system receive flows that are within design

specifications with the system operating in the normal, shutdown, and post-LOCA modes.

c. Component cooling water pump and valve responses to load

sequence, containment isolation, and safety injection

signals are within design specifications.

d. Closure times for the component cooling water supply and

return valves to the reactor coolant system are within

design specifications.

e. Component cooling water pump response to centrifugal charging pump start signals is in accordance with system design.

14.2.12.1.39 Residual Heat Removal System Cold Preoperational

Test (SU3-EJ01)

14.2.12.1.39.1 Objective

To demonstrate the operability of the Residual Heat Removal (RHR) pumps, demonstrate by flow test their ability to supply water at rated pressure and

flow, and verify their response to safety signals. The operation of system

motor-operated valves, including their response to safety signals, are also

verified. The RWST control and alarm circuits are also verified.

14.2.12.1.39.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

14.2-60 Rev. 0 WOLF CREEK

b. Required electrical power supplies and control circuits are operational.
c. The reactor vessel head is removed and the water level

is above the nozzles.

d. The refueling water storage tank contains an adequate

supply of demineralized water for the performance of

this test.

e. Cooling water is available to the RHR pumps and heat

exchangers.

f. The instrument air system is available to supply air to

system air-operated valves.

14.2.12.1.39.3 Test Method

a. Performance characteristics of the RHR pumps are

verified during discharge to the reactor coolant hot and

cold loops and test recirculation.

b. RWST and RHR system component control circuits are

verified, including the operation of the RHR pumps and

system valves on receipt of safety signals.

14.2.12.1.39.4 Acceptance Criteria

a. RHR pump performance characteristics are within design

specifications.

b. RHR system components align or actuate in accordance

with system design to safety injection, containment

isolation, load sequencing, load shed, and tank level

signals.

c. The time required for each RHR pump to reach rated speed

is within design specifications.

d. RHR system motor-operated valve closure times are within

design specifications.

14.2.12.1.40 Residual Heat Removal System Hot Preoperational Test

(S-U3-EJ02)

14.2.12.1.40.1 Objectives

a. To demonstrate the ability of the residual heat removal

(RHR) system to cool down the reactor coolant system

(RCS) at its design rate.

14.2-61 Rev. 0 WOLF CREEK

b. To demonstrate the ability of the RHR pump room coolers to maintain room temperature within design limits.

14.2.12.1.40.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The component cooling water system is supplying water to

each RHR heat exchanger.

d. The RCS is being cooled down during hot functional testing.
e. The RHR pump rooms are closed, and their associated pump

room coolers are operational.

14.2.12.1.40.3 Test Method

a. While the RCS is being cooled down with the RHR system, the heat transfer is obtained by performing a heat

balance across each RHR heat exchanger.

b. When RHR pump room temperatures have stabilized, room

temperature data is recorded.

14.2.12.1.40.4 Acceptance Criteria

a. The RHR system is capable of cooling down the reactor

coolant system at its design rate.

b. The RHR pump room coolers can maintain room temperature

within design limits.

14.2.12.1.41 Safety Injection System Cold Preoperational Test

(SU3-EM01)

14.2.12.1.41.1 Objectives

To demonstrate the response of the safety injection pumps and associated valves

to safety signals.

14.2.12.1.41.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete

14.2-62 Rev. 0 WOLF CREEK

b. Required electrical power supplies and control circuits are operational.

14.2.12.1.41.3 Test Method

The response of the safety injection pumps and associated valves to safety

signals is verified

14.2.12.1.41.4 Acceptance Criteria

a. The safety injection pumps and associated valves align

or actuate in accordance with system design to

containment isolation signals, load shedding signals, and load sequencing signals.

14.2.12.1.42 Safety Injection Flow Verification Test (SU3-EM02)

14.2.12.1.42.1 Objectives

a. To demonstrate the operating characteristics of the

safety injection pumps and the centrifugal charging

pumps.

b. To demonstrate the capability of the safety injection

pumps to provide balanced flow to the reactor coolant

system and prevent runout flow in the cold leg and hot

leg injection modes.

c. To demonstrate the capability of the charging pumps to

provide balanced flow to the reactor coolant system and prevent runout flow in the boron injection mode.

d. To demonstrate the capability of the residual heat

removal pumps to provide required net positive suction

head to the safety injection pumps and the centrifugal

charging pumps.

e. To demonstrate that the safety injection and centrifugal

charging pump room coolers maintain room temperature

within design limits.

f. To demonstrate that associated system valve operating

times are within specified limits.

14.2.12.1.42.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

14.2-63 Rev. 0 WOLF CREEK

b. Required electrical power supplies and control circuits are operational.
c. The CVCS is available to supply rated flow to the

reactor coolant system via the boron injection path, while simultaneously supplying other required loads.

d. The residual heat removal system is available to supply

adequate suction head to the safety injection and

centrifugal charging pumps during required injection

modes.

e. The borated refueling water storage tank contains an

adequate supply of demineralized water for this test.

f. The reactor vessel is available to receive water, and the temporary reactor vessel pumpdown system is

operational (if required).

g. The auxiliary building HVAC system is available to cool

the pump rooms and verify associated pump interlocks.

h. The accumulator safety injection system piping from the

safety injection system to the reactor coolant system is

available, and an accumulator tank is capable of

receiving water.

i. Cooling water is available to required pumps and heat

exchangers.

j. The compressed air system is available to supply air to associated system valves.
k. The residual heat removal system hot leg and cold leg

flow orifices have been sized for required flow.

14.2.12.1.42.3 Test Method

a. The safety injection pumps are operated in the cold leg

flow mode to verify pump performance characteristics and

to identify the weaker pump.

b. The safety injection cold leg branch lines are balanced

using the weaker safety injection pump and the balance

checked with the stronger pump. The balance is

performed so that injection flow is maximized while

preventing pump runout.

14.2-64 Rev. 0 WOLF CREEK

c. The safety injection hot leg branch lines are balanced, using their respective safety injection pump. The

balance is performed so that injection flow is maximized

while preventing pump runout.

d. The centrifugal charging pumps are operated in the boron

injection mode to determine pump performance

characteristics and to identify the weaker pump.

e. The boron injection branch lines are balanced, using the

weaker centrifugal charging pump and the balance checked

with the stronger pump. The balance is performed such

that injection flow is maximized while preventing pump

runout.

f. Each residual heat removal pump is operated in series with the centrifugal charging pumps and safety injection

pumps to verify that the residual heat removal pumps can

supply adequate suction head.

g. With each centrifugal charging pump and safety injection

pump operating, pump room temperatures are allowed to

stabilize, and room temperature data are recorded.

14.2.12.1.42.4 Acceptance Criteria

a. The safety injection and centrifugal charging pump

response times and valve operating times are within

design specifications.

b. The safety injection pump room coolers start with their respective pump.
c. The NPSH provided by the residual heat removal pumps to

the centrifugal charging pumps and safety injection

pumps is within system design specifications.

d. Safety injection cold leg, hot leg, and safety injection

pump flows are within design specifications.

e. Boron injection and centrifugal charging pump flows are

within design specifications.

f. The safety injection and centrifugal charging pump room

coolers can maintain room temperature within design

limits.

14.2-65 Rev. 0 WOLF CREEK 14.2.12.1.43 Safety Injection Check Valve Test (SU3-EM03)

14.2.12.1.43.1 Objectives

To demonstrate the integrity of accumulator outlet line and loop safety injection line check valves and backup check valves by performing backleakage

tests. The operability of the various safety injection line check valves under

their design pressure conditions is also verified.

14.2.12.1.43.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits are operational.
c. The reactor coolant system is at normal operating

pressure.

14.2.12.1.43.3 Test Method

a. Check valve leak testing is performed with the reactor

coolant system at normal operating pressure.

b. Check valve operability is performed by verifying flow

through the check valves at reduced reactor coolant

pressure.

14.2.12.1.43.4 Acceptance Criteria

a. Check valve leakage rates are within limits established

by Technical Specifications Section 3.4.6.2f.

b. Injection line check valve operability is demonstrated

by verification of flow through the check valves in each

of the safety injection lines to the reactor coolant

system.

14.2.12.1.44 Boron Injection Tank and Recirculation Pump Test

(SU3-EM04)

This test has been deleted at Wolf Creek since the boron injection requirements

have been eliminated due to the decrease in required boron concentration.

14.2-66 Rev. 0 WOLF CREEK 14.2.12.1.45 Containment Spray System Nozzle Air Test (S-03EN01)

14.2.12.1.45.1 Objectives

To demonstrate that the spray nozzles in the containment spray header are clear of obstructions.

14.2.12.1.45.2 Prerequisites

A source of compressed air is available to pressurize the spray headers.

14.2.12.1.45.3 Test Method

Air flow is initiated through the containment spray headers, and unobstructed

flow is verified through each nozzle.

14.2.12.1.45.4 Acceptance Criteria

All containment spray nozzles are clear and unobstructed, as evidenced by air

passing through each nozzle.

14.2.12.1.46 Containment Spray System Preoperational Test

(SU3-EN02)

14.2.12.1.46.1 Objectives

a. To demonstrate the operation of system components, including their response to safety signals, and verify

that the associated instrumentation and controls are

functioning properly. System flow characteristics in the test and simulated accident modes are also verified.

b. To demonstrate the ability of the pump room coolers to

maintain room temperatures within design limits.

14.2.12.1.46.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The refueling water storage tank contains an adequate

supply of demineralized water for the performance of

this test.

d. The auxiliary building HVAC system is available to cool

the pump rooms and verify associated pump interlocks.

14.2-67 Rev. 0 WOLF CREEK

e. The containment spray pump rooms are closed.

14.2.12.1.46.3 Test Method

a. Performance characteristics of the containment spray pumps are verified in the test mode, recirculating to

the refueling water storage tank, and in the simulated

accident mode.

b. System component control circuits are verified, including the operation of system pumps and valves on

receipt of load sequence/shedder and CSAS/CIS signals, respectively.

c. During system operations, spray additive eductor operating characteristics are verified.
d. During containment spray pump operation, pump room

temperature data are recorded.

14.2.12.1.46.4 Acceptance Criteria

a. Containment spray pump performance characteristics are

within design specifications for the tested modes of

operation.

b. Containment spray pump and valve response to load

sequence/shedder and CSAS/CIS is verified, and the

associated response times are within design

specifications.

c. Spray additive eductor operating characteristics are

within design specifications.

d. The containment spray pump room coolers maintain the

room temperature within design limits.

14.2.12.1.47 Accumulator Testing (S-03EP01)

14.2.12.1.47.1 Objectives

To determine the operability of each safety injection accumulator and obtain, by flow test, each accumulator's discharge line resistance to flow. The

ability of the accumulator discharge line isolation valves to open under

maximum differential pressure conditions is verified, as is the response of

accumulator system valves to safety signals.

14.2-68 Rev. 0 WOLF CREEK 14.2.12.1.47.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The reactor vessel head and reactor internals are not

installed, and the vessel is available to receive water.

d. A source of compressed air and nitrogen is available.
e. The refueling water storage tank contains an adequate

supply of demineralized water for the performance of this test.

14.2.12.1.47.3 Test Method

a. Each accumulator is filled and partially pressurized with

the discharge valves closed. The discharge valves are

opened, discharging the accumulators to the reactor

vessel, and performance data are recorded.

b. Each accumulator discharge line isolation valve is

operated under maximum differential pressure conditions

of normal accumulator precharge pressure and zero reactor

coolant pressure, and the valve operating times are

recorded.

c. Accumulator system valve control circuits are verified, including their response to safety injection and

containment isolation signals.

14.2.12.1.47.4 Acceptance Criteria

a. Each accumulator's discharge line resistance to flow

(L/D) is in accordance with design specifications.

b. Each accumulator's discharge line isolation valve

opening time under maximum differential pressure

conditions is within design specifications.

c. The accumulator system nitrogen supply containment

isolation valve closes on receipt of a containment

isolation signal. Valve closure time is within design

specifications.

d. Each accumulator discharge isolation valve opens on

receipt of a safety injection signal.

14.2-69 Rev. 0 WOLF CREEK 14.2.12.1.48 Auxiliary Feedwater Pump Turbine Preoperational Test (SU3-FC01)

14.2.12.1.48.1 Objectives

a. To demonstrate the operation of the auxiliary feedwater

pump (AFWP) turbine and its support equipment, while

uncoupled from the pump.

b. To demonstrate control of the AFWP turbine from the

control room as well as the auxiliary shutdown panel.

14.2.12.1.48.2 Prerequisites

a. Required component testing, instrument calibration and system flushing/cleaning are complete.
b. Steam is available to the AFWP turbine.

14.2.12.1.48.3 Test Method

a. AFWP turbine system valves are operated and required

response to various signals is verified.

b. The turbine is operated and proper control is verified

from the control room as well as the auxiliary shutdown

panel, and operating data are recorded.

c. The turbine is brought to high speed at which time the

mechanical and electronic overspeed trips are verified.

14.2.12.1.48.4 Acceptance Criteria

a. The AFWP turbine can be controlled from the control room

panel and the auxiliary shutdown panel.

b. The mechanical and electronic overspeed trips actuate to

shut down the turbine in accordance with the design.

14.2.12.1.49 Essential Service Water Pumphouse HVAC

Preoperational Test (SU3-GD01)

14.2.12.1.49.1 Objectives

a. To demonstrate the capacity of the essential service

water (ESW) pumproom supply fans.

b. To demonstrate ESW pumproom unit heater response to a

load shed signal.

14.2-70 Rev. 0 WOLF CREEK 14.2.12.1.49.2 Prerequisites

a. Required component testing and instrument calibration

are completed.

b. Required electrical power supplies and control circuits

are operational.

c. The ESW pumphouse HVAC system is air balanced.

14.2.12.1.49.3 Test Methods

a. The ESW pumphouse supply fans are operated and flow data

are recorded.

b. Response of the ESW pumproom unit heaters to load shed signal is verified.

14.2.12.1.49.4 Acceptance Criteria

a. The ESW pumphouse supply fan capacities are within

design specification.

b. A load shed signal will trip the ESW pumproom unit

heaters' circuit breaker.

14.2.12.1.50 Miscellaneous Building HVAC System Preoperational

Tests (SU3-GF01, SU3-GF02, SU3-GF03)

14.2.12.1.50.1 Objectives To demonstrate the capacity of; 1) the auxiliary feedwater pump room cooler

fans, 2) the main steam enclosure building supply and exhaust fans and 3) the

tendon access gallery transfer fans and to verify that the associated

instrumentation and controls are functioning properly. The responses of the

main steam enclosure building dampers and tendon access gallery dampers to

safety signals are also verified.

(At Wolf Creek Generating Station, this test was performed in three independent

parts. In addition, the auxiliary boiler room fan was treated as part of

preoperational test SU4-GF01.)

14.2.12.1.50.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2-71 Rev. 0 WOLF CREEK

c. The miscellaneous building HVAC system is air balanced.

14.2.12.1.50.3 Test Method

a. Flow data are recorded while the fans are operating.
b. The response of system dampers to a safety injection

signal (SIS) is verified.

14.2.12.1.50.4 Acceptance Criteria

a. System fan capacities are within design specifications.
b. The main steam enclosure building and tendon access

gallery dampers close on receipt of a SIS.

14.2.12.1.51 Fuel Building HVAC System Preoperational Test

(S-03GG01)

14.2.12.1.51.1 Objectives

To demonstrate that the emergency exhaust fans are capable of maintaining a

negative pressure in the fuel building or the auxiliary building during

accident conditions with the buildings isolated. To demonstrate the capacities

of the fuel building supply unit fans, emergency exhaust fans, and the spent

fuel pool pump room cooler fans. The operability of system instrumentation and

controls, including the components' response to safety signals, is also

verified.

14.2.12.1.51.2 Prerequisites

a. Required component testing, instrument calibration, and

system air balancing are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The compressed air system is available to supply the

air-operated dampers in the fuel building.

d. Required portions of the auxiliary building HVAC system

have been air balanced and are available to support this

test.

14.2.12.1.51.3 Test Method

a. With the fuel building closed, the system is operated in

its normal configuration, and the fuel building supply

14.2-72 Rev. 0 WOLF CREEK unit fan and spent fuel pool pump room cooler fan capacities are verified.

b. With a fuel building isolation signal (FBIS) present, the emergency exhaust fan capacities and negative fuel building pressures are verified.
c. With a safety injection signal (SIS) present and the

auxiliary building isolated, the emergency exhaust fan

capacities and negative auxiliary building pressures are

verified.

14.2.12.1.51.4 Acceptance Criteria

a. The auxiliary building and fuel building pressures maintained by the emergency exhaust fans are within design specifications.
b. The fuel building supply fans, emergency exhaust fans, and spent fuel pool pump room cooler fans' capacities

are within design specifications.

c. The fuel building ventilation system fans and dampers

properly respond to FBIS and SIS, in accordance with

system design.

14.2.12.1.52 Control Building HVAC System Preoperational Test

(SU3-GK01)

14.2.12.1.52.1 Objectives To demonstrate the capacities of the control building supply air unit, control

building exhaust fans, access control exhaust fans, control room pressurization

fans, control room filtration fans, control room air conditioning units, access

control fan coil units, counting room fan coil unit, and Class IE electrical

equipment ac units. To demonstrate that the control room pressurization fans

are capable of maintaining a positive pressure in the control room following a

control room ventilation isolation signal (CRVIS). The system instrumentation

and controls, including the components' responses to safety signals, are also

verified. To demonstrate that the ventilation to battery rooms 1 through 4 is

in accordance with system design.

14.2.12.1.52.2 Prerequisites

a. Required component testing, instrument calibration, and

system air balancing are complete.

14.2-73 Rev. 0 WOLF CREEK

b. Required electrical power supplies and control circuits are operational.
c. The compressed air system is available to supply air to

system air-operated dampers.

14.2.12.1.52.3 Test Method

a. The control building system fans are operated, and fan

capacities are verified.

b. Proper response of system components to control room

ventilation isolation signals (CRVIS) and safety

injection signals (SIS) is verified.

c. With a CRVIS present, the ability of each control room pressurization fan to maintain the control room at a

positive pressure is verified.

d. The air flow to battery rooms 1 through 4 is verified.

14.2.12.1.52.4 Acceptance Criteria

a. The control building HVAC system fan capacities are

within design specifications.

b. The control building HVAC system fans and dampers

properly respond to CRVIS and SIS in accordance with

system design.

c. The control room pressure maintained by the control room pressurization fans is within design specification.
d. The air flow to battery rooms 1 through 4 is in

accordance with system design.

14.2.12.1.53 Auxiliary Building HVAC System Preoperational Test

(SU3-GL01)

14.2.12.1.53.1 Objectives

To demonstrate the capacities of the auxiliary building supply unit fans, auxiliary/fuel building normal exhaust fans, the auxiliary building fan coil

units, pump room coolers, penetration room coolers, decon tank exhaust scrubber

fans, access tunnel transfer fan, and penetration cooling fan. The system

instrumentation and controls, including components' response to safety and fire

signals, are also verified.

14.2-74 Rev. 0 WOLF CREEK 14.2.12.1.53.2 Prerequisites

a. Required component testing, instrument calibration, and

system air balancing are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The compressed air system is available to supply the

air-operated dampers in the auxiliary building.

d. The fuel building HVAC system has been air balanced, and

is available to support this test.

14.2.12.1.53.3 Test Method

a. The system is operated in its normal configuration, and

the system fan capacities are verified.

b. Proper responses of system components to safety

injection and fire signals are verified.

14.2.12.1.53.4 Acceptance Criteria

a. The auxiliary building fan capacities are within design

specifications.

b. The auxiliary building fans and dampers properly respond

to safety injection and fire signals, in accordance with

system design.

14.2.12.1.54 Diesel Generator Building HVAC Preoperational Test

(S-03GM01)

14.2.12.1.54.1 Objectives

To demonstrate the capacities of the diesel generator room supply fans and to

verify that the system instrumentation and controls function properly, including the response of fans and associated dampers to a diesel generator run

signal and room temperature signals.

14.2.12.1.54.2 Prerequisites

a. Required component testing and instrument calibration

are completed.

b. Required electrical power supplies and control circuits

are operational.

14.2-75 Rev. 0 WOLF CREEK

c. The diesel generator building HVAC system is air balanced.
d. The respective diesel generator is not operating while

the room is under test.

14.2.12.1.54.3 Test Method

a. Flow data are recorded, while the diesel generator room

supply fans are operating.

b. The responses of the diesel generator room supply fans

and exhaust dampers to a diesel generator run signal and

to room temperature signals are verified.

14.2.12.1.54.4 Acceptance Criteria

a. The capacities of the diesel generator room supply fans

are within design specifications.

b. The diesel generator room exhaust dampers open on

receipt of a diesel generator run signal.

c. The diesel generator room supply fans start on a high

room temperature signal and stop on a low room

temperature signal.

14.2.12.1.55 Containment Cooling System Preoperational Test

(SU3-GN01)

14.2.12.1.55.1 Objectives

To demonstrate the capacities of the hydrogen mixing, containment cooling, and

pressurizer cooling fans and verify their associated instrumentation and

controls function properly, including fan response to safety signals.

14.2.12.1.55.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The essential service water system is available to

supply water to the containment coolers.

d. The containment cooling system has been air balanced.

14.2-76 Rev. 0 WOLF CREEK 14.2.12.1.55.3 Test Method

a. The hydrogen mixing, containment cooling, and

pressurizer cooling fans are operated, flow data

recorded, and fan capacities calculated.

b. The response of the hydrogen mixing and containment

cooling fans to safety signals is verified.

14.2.12.1.55.4 Acceptance Criteria

a. The capacities of the hydrogen mixing, containment

cooling, and pressurizer cooling fans are within design

specifications.

b. The hydrogen mixing and containment cooling fans align or actuate in response to safety injection, shutdown

sequencer, and LOCA sequencer signals, in accordance

with system design.

14.2.12.1.56 CRDM Cooling Preoperational Test (S-03GN02)

14.2.12.1.56.1 Objectives

To demonstrate the operating characteristics of the cavity cooling, control rod

drive mechanism (CRDM), and the elevator machine room exhaust fans and verify

their associated instrumentation and controls, including their response to

safety signals.

14.2.12.1.56.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The CRDM and cavity cooling portions of the containment

cooling system are air balanced.

14.2.12.1.56.3 Test Method

a. The cavity cooling, elevator machine room exhaust, and

CRDM fans are operated, flow data recorded, and fan

capacities calculated.

b. The response of the CRDM fans to a safety injection

signal is verified.

14.2-77 Rev. 0 WOLF CREEK 14.2.12.1.56.4 Acceptance Criteria

a. The capacities of the cavity cooling, elevator machine

room exhaust, and CRDM fans are within design

specifications.

b. The appropriate CRDM fans supply breakers open on

receipt of a safety injection signal.

14.2.12.1.57 Integrated Containment Leak Rate Test (SU3-GP01)

14.2.12.1.57.1 Objective

To demonstrate that the total leakage from the containment does not exceed the

maximum allowable leakage rate at the calculated peak containment internal pressure. The operability of the containment cooling fans at design accident pressure is also verified.

14.2.12.1.57.2 Prerequisites

a. The containment penetration leakage rate tests (type B

tests) and containment isolation valve leakage tests

(type C tests) are complete and the containment has been

pressurized to 115 percent of the design pressure.

b. All containment isolation valves are closed by normal

actuation methods.

c. Containment penetrations, including equipment hatches

and personnel airlocks, are closed.

d. Portions of fluid systems that are part of the

containment boundary, that may be opened directly to the

containment or outside atmosphere under post-accident

conditions, are opened or vented to the appropriate

atmosphere to place the containment in as close to post-

accident conditions as possible.

e. Required instrument calibration is complete.

14.2.12.1.57.3 Test Method

a. The integrated containment leak rate test (type A test)

is conducted, using the absolute method, described in

the ANSI/ANS 56.8-1981 Containment System Leakage

Testing Requirements. Measurements of containment

atmosphere dry-bulb temperature, dew point and pressure

are taken to calculate the leakage rate. A standard

14.2-78 Rev. 0 WOLF CREEK statistical analysis of data is conducted, using a linear least squares fit regression analysis to

calculate the leakage rate.

b. On completion of the leak rate test, a verification test is conducted to confirm the capability of the data

acquisition and reduction system to satisfactorily

determine the calculated integrated leakage rate. The

verification test is accomplished by imposing a known

leakage rate on the containment, or by pumping back a

known quantity of air into the containment through a

calibrated flow measurement device.

c. While at the design accident pressure, data is recorded

for the containment cooling fans.

14.2.12.1.57.4 Acceptance Criteria

The containment integrated leakage does not exceed the maximum allowable

leakage rate at a calculated peak containment internal pressure, as defined in

10 CFR 50, Appendix J.

The containment cooling fan operation at design accident pressure is in

accordance with design.

14.2.12.1.58 Reactor Containment Structural Integrity Acceptance

Test (SU3-GP02)

14.2.12.1.58.1 Objectives

To demonstrate the structural integrity of the reactor containment building.

14.2.12.1.58.2 Prerequisites

a. Containment penetrations are installed, and penetration

leak tests are completed.

b. Containment penetrations, including equipment hatches

and personnel airlocks, are closed.

c. Required instrument calibration is complete.

14.2.12.1.58.3 Test Method

The containment is pressurized at 115 percent of the design pressure, and

deflection measurements and concrete crack inspections are made to determine

that the actual structural response is within the limits predicted by the

design analyses.

14.2-79 Rev. 0 WOLF CREEK 14.2.12.1.58.4 Acceptance Criteria

The containment structural response is within the limits predicted by design

analyses.

14.2.12.1.59 Post-Accident Hydrogen Removal System

Preoperational Test (S-03GS01)

14.2.12.1.59.1 Objectives

a. To demonstrate that the hydrogen recombiner performance

characteristics are within design specifications.

b. To determine the operation of system dampers and valves, including the response of hydrogen purge and hydrogen monitoring containment isolation valves to a CIS.
c. To demonstrate the operability of the hydrogen analyzers

and their ability to sample the containment atmosphere.

14.2.12.1.59.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2.12.1.59.3 Test Method

a. Performance characteristics are recorded, while the hydrogen recombiners are operating.
b. System valve and damper control circuits are verified, including the response of hydrogen purge and hydrogen

monitoring containment isolation valves to a CIS.

c. The hydrogen analyzers are operated, and performance

data recorded.

14.2.12.1.59.4 Acceptance Criteria

a. Hydrogen recombiner performance characteristics are

within design specifications.

b. Hydrogen purge and hydrogen monitoring containment

isolation valves close on receipt of a CIS. Valve

closure times are within design specifications.

14.2-80 Rev. 0 WOLF CREEK 14.2.12.1.60 Containment Purge System HVAC Preoperational Test (S-03GT01)

14.2.12.1.60.1 Objectives

To demonstrate the capacities of the containment minipurge supply and exhaust, shutdown purge supply and exhaust, and containment atmospheric control fans.

The operation of system instrumentation and controls, including the response of

system fans and dampers to safety signals, is also verified.

14.2.12.1.60.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits are operational.
c. The containment purge HVAC system has been air balanced.
d. The compressed air system is available to supply air to

system valves and dampers.

14.2.12.1.60.3 Test Method

a. The containment minipurge supply and exhaust, shutdown

purge supply and exhaust, and containment atmospheric

control fans are operated, flow data recorded, and fan

capacities calculated.

b. The response of system fans and dampers to safety signals is verified.

14.2.12.1.60.4 Acceptance Criteria

a. The capacities of the containment minipurge supply and

exhaust, shutdown purge supply and exhaust, and

containment atmospheric control fans are within design

specifications.

b. System fans and dampers align or actuate in response to

containment purge isolation and safety injection

signals, in accordance with system design. Damper

closure times are within design specifications.

14.2-81 Rev. 0 WOLF CREEK 14.2.12.1.61 Gaseous Radwaste System Preoperational Test (S-03HA01)

14.2.12.1.61.1 Objectives

a. To demonstrate the performance characteristics of the

gas decay tank drain pump, waste gas compressors, and

catalytic hydrogen recombiners, including their response

to safety signals.

b. To verify the operability of system valves, including

the response of the waste gas discharge valve to a high-

radiation signal.

c. To verify that system instrumentation and controls function properly.

14.2.12.1.61.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The component cooling water system is available to

supply cooling water to the waste gas compressors and

catalytic hydrogen recombiners.

d. The service gas system is available to provide nitrogen, hydrogen, and oxygen to the catalytic hydrogen recombiners.
e. The reactor makeup water system is available to provide

water to the waste gas compressors, catalytic hydrogen

recombiners, and the waste gas decay tank drain header.

14.2.12.1.61.3 Test Method

a. Performance characteristics of the gas decay tank drain

pump, and waste gas compressors are verified.

b. Hydrogen is introduced to the system and the catalytic

hydrogen recombiners performance are verified.

c. System component control circuits are verified, including component response to safety signals.

14.2.12.1.61.4 Acceptance Criteria

a. Performance characteristics of the gas decay tank drain

pump, waste gas compressors, and catalytic hydrogen

recombiners are within design specifications.

14.2-82 Rev. 0 WOLF CREEK

b. The waste gas discharge valve automatically closes on a high-radiation signal.
c. The waste gas compressors trip on a high-high or low-low

moisture separator level, high or low moisture separator pressure, low compressor suction pressure, or low

component cooling water flow.

d. The hydrogen recombiner oxygen feed valve closes on

high-high hydrogen concentration in the recombiner feed, high-high oxygen concentration in the recombiner

discharge, high cooler-condenser discharge temperature, high-high recombiner discharge temperature, low-low

recombiner flow, and high-high recombiner reactor inlet

temperature.

e. The hydrogen recombiner oxygen feed valve signal is

blocked on high oxygen concentration in the recombiner

feed and high catalyst bed temperature.

f. The volume control tank vent valve closes on a hydrogen

recombiner trip, low volume control tank pressure, and

low waste gas compressor suction pressure.

14.2.12.1.62 Emergency Fuel Oil System Preoperational Test

(S-03JE01)

14.2.12.1.62.1 Objectives

To demonstrate the capability of the system to provide an adequate fuel supply to the emergency diesel generator fuel oil day tanks and verify that the associated instrumentation and controls are functioning properly.

14.2.12.1.62.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2.12.1.62.3 Test Method

a. Fuel oil is transferred from the fuel oil storage tank

to the fuel oil day tanks by means of the transfer

pumps. Flow and pressure characteristics are recorded.

b. Fuel oil day tank levels are varied to verify the

transfer pump automatic operations.

14.2-83 Rev. 0 WOLF CREEK

c. Response to fire and emergency diesel generator start signals are verified.

14.2.12.1.62.4 Acceptance Criteria

a. The transfer pump flow capacity is verified for later

comparison to the fuel consumption rate (S-03NF02).

b. Control circuit automatic operation from fuel oil day

tank levels, fire signals, and diesel generator start

signals is within design specifications.

14.2.12.1.63 Spent Fuel Pool Crane Preoperational Test

(SU3-KE01)

14.2.12.1.63.l Objectives

a. To demonstrate proper operation of the spent fuel pool

bridge crane control circuits and associated interlocks.

b. To document the data obtained during testing of the

spent fuel pool bridge crane at 125 percent of rated

load.

c. To verify the ability of the spent fuel pool bridge

crane and associated fuel handling tools to transfer a

dummy fuel assembly.

14.2.12.1.63.2 Prerequisites

a. Required component testing and instrument calibration are completed.
b. Required electrical power supplies and control circuits

are operational.

c. A dummy fuel assembly is available.

14.2.12.1.63.3 Test Method

a. Operability of the spent fuel pool bridge crane control

circuits and associated interlocks is verified.

b. Ability of the spent fuel pool bridge crane and

associated fuel handling tools to transfer a dummy fuel

assembly is verified.

14.2-84 Rev. 0 WOLF CREEK 14.2.12.1.63.4 Acceptance Criteria

a. The spent fuel pool bridge crane electric and manual

hoists support 125 percent of their rated load.

b. The spent fuel pool bridge crane monorail center span

deflection at rated load is within design

specifications.

c. The spent fuel pool crane bridge, trolley and hoist

speeds at rated loads are within design specifications.

d. All control circuits and interlocks associated with the

spent fuel pool bridge crane operate in accordance with

system design.

e. While transferring a dummy fuel assembly, the spent fuel

pool bridge crane and associated fuel handling tools

operate in accordance with system design.

14.2.12.1.64 New Fuel Elevator Preoperational Test (SU3-KE02)

14.2.12.1.64.1 Objectives

a. To demonstrate proper operation of the new fuel elevator

control circuits and associated interlocks.

b. To verify the ability of the new fuel elevator to raise

and lower a dummy fuel assembly.

14.2.12.1.64.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. A dummy fuel assembly is available.

14.2.12.1.64.3 Test Method

Operability of the new fuel elevator including control circuits and associated

interlocks is verified.

14.2.12.1.64.4 Acceptance Criteria

a. All control circuits and interlocks associated with the

new fuel elevator operate in accordance with system

design.

14.2-85 Rev. 0 WOLF CREEK

b. While raising and lowering a dummy fuel assembly, the new fuel elevator operates in accordance with system

design.

14.2.12.1.65 Fuel Handling and Storage Preoperational Test (SU3-KE03)

14.2.12.1.65.1 Objectives

a. To verify the ability of the spent fuel cask handling

crane, and associated fuel handling tools to transfer a

dummy fuel assembly.

b. To demonstrate proper operation of the spent fuel cask

handling crane control circuits and associated interlocks.

c. To document the data obtained during testing of the

spent fuel cask handling crane at 125 percent of rated

load.

14.2.12.1.65.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. A dummy fuel assembly is available.

14.2.12.1.65.3 Test Method

a. During the transfer of a dummy fuel assembly, the

operability of the spent fuel cask handling crane and

associated fuel handling tools is verified.

b. Operability of the spent fuel cask handling crane

control circuits and associated interlocks is verified.

14.2.12.1.65.4 Acceptance Criteria

a. While transferring a dummy fuel assembly, the spent fuel

cask handling crane and associated fuel handling tools

operate in accordance with system design.

b. All control circuits and interlocks associated with the

spent fuel cask handling crane operate in accordance

with system design.

14.2-86 Rev. 0 WOLF CREEK

c. The spent fuel cask handling crane hoist supports 125 percent of rated load.
d. The spent fuel cask handling crane bridge center span

deflection at rated load is within design specifications.

e. The spent fuel cask handling crane bridge, trolley and

hoist speeds at rated loads are within design

specifications.

14.2.12.1.66 Fuel Transfer System Preoperational Test

(SU3-KE04)

14.2.12.1.66.l Objectives

a. To demonstrate proper operation of the fuel transfer

system control circuits and associated interlocks.

b. To verify the ability of the fuel transfer system and

associated handling tools to transfer a dummy fuel

assembly.

14.2.12.1.66.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. A dummy fuel assembly is available.

14.2.12.1.66.3 Test Method

a. Operability of the fuel transfer system control circuits

and associated interlocks is verified.

b. During the transfer of a dummy fuel assembly, the

operability of the fuel transfer system and associated

handling tools is verified.

14.2.12.1.66.4 Acceptance Criteria

a. All control circuits and interlocks associated with the

fuel transfer system operate in accordance with system

design.

14.2-87 Rev. 0 WOLF CREEK

b. While transferring a dummy fuel assembly, the fuel transfer system and associated handling tools operate in

accordance with system design.

14.2.12.1.67 Refueling Machine and RCC Change Fixture Preoperational Test (SU3-KE05)

14.2.12.1.67.1 Objectives

a. To demonstrate proper operation of the refueling

machine, rod cluster control change fixture and

containment building polar crane control circuits and

associated interlocks.

b. To document the data obtained during testing of the containment building polar crane at 125 percent of rated load.
c. To verify the ability of the refueling machine to

transfer a dummy fuel assembly.

14.2.12.1.67.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. A dummy fuel assembly is available.
d. A dummy control rod assembly is available.

14.2.12.1.67.3 Test Method

a. Operability of the refueling machine and rod cluster

control change fixture control circuits and associated

bridge, trolley, hoist and gripper interlocks is

verified.

b. Operability of the containment building polar crane

control circuits and associated interlocks is verified.

14.2.12.1.67.4 Acceptance Criteria

a. All control circuits and interlocks associated with the

refueling machine and rod cluster control change fixture

operate in accordance with system design.

14.2-88 Rev. 0 WOLF CREEK

b. The control circuits and interlocks associated with the containment building polar crane operate in accordance

with system design.

c. The containment polar crane main and auxiliary hoists support 125 percent of their rated load.
d. The containment polar crane bridge center span

deflection at rated load is within design

specifications.

e. The containment polar crane bridge, trolley, and hoist

speeds at rated loads are within design specifications.

f. While transferring a dummy fuel assembly, the refueling machine operates in accordance with system design.

14.2.12.1.68 Refueling Machine Indexing Test (S-03KE06)

14.2.12.1.68.1 Objectives

a. To verify the indexing of the refueling machine and

establish bridge rail reference points for future

operations.

b. To demonstrate the ability to transfer the dummy fuel

assembly to the reactor vessel.

14.2.12.1.68.2 Prerequisites

a. Required component testing and instrument calibration are complete.
b. Required electrical power supplies and control circuits

are operational.

c. A dummy fuel assembly is available.

14.2.12.1.68.3 Test Method

a. While transferring a dummy fuel assembly with the

refueling machine, the bridge rail is marked at key

transfer points.

14.2.12.1.68.4 Acceptance Criteria

a. The refueling machine can load a dummy fuel assembly in

each of the reactor vessel fuel loading locations.

14.2.12.1.69 Fuel Handling System Integrated Preoperational Test

(SU3-KE07)

14.2-89 Rev. 0 WOLF CREEK 14.2.12.1.69.1 Objective

To verify the ability of the refueling machine, new fuel elevator, fuel

transfer system, spent fuel bridge crane, spent fuel cask handling crane and

associated fuel handling tools to transfer a dummy fuel assembly.

14.2.12.1.69.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The reactor vessel, refueling pool, refueling canal and spent fuel pool are filled with demineralized water.
d. A dummy fuel assembly is available.

14.2.12.1.69.3 Test Method

During the transfer of a dummy fuel assembly, the operability of the refueling

machine, new fuel elevator, fuel transfer system, spent fuel bridge crane, spent fuel cask handling crane and associated fuel handling tools is verified.

14.2.12.1.69.4 Acceptance Criteria

While transferring a dummy fuel assembly, the refueling machine, new fuel

elevator, fuel transfer system, spent fuel bridge crane, spent fuel cask

handling crane and associated fuel handling tools operate in accordance with system design.

14.2.12.1.70 Diesel Generator Mechanical Preoperational Test

(S-03KJ01)

14.2.12.1.70.1 Objectives

a. To demonstrate the performance characteristics of the

diesel generators and associated auxiliaries, and verify

that each diesel reaches rated speed within the required

time.

b. To verify the operability of all control circuits

associated with the diesel generator and diesel

auxiliaries, including the control circuits response to

safety signals.

14.2-90 Rev. 0 WOLF CREEK

c. To demonstrate the capability of each air storage tank to provide five diesel cranking cycles without being

recharged.

14.2.12.1.70.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The essential service water system is available to

provide cooling water to the diesel engine intercooler

heat exchanger.

d. The emergency fuel oil system is available to provide

fuel oil to the diesel generators.

e. The fire protection system is available to support this

test.

14.2.12.1.70.3 Test Method

a. The diesel generators are started, and the time required

to reach rated speed is recorded.

b. With the diesel generators and associated auxiliaries

operating, performance characteristics are verified.

c. The operability of all control circuits associated with the diesel generator and diesel auxiliaries, including

the control circuits' response to safety signals, is

verified.

d. The ability of each air storage tank to provide five

diesel cranking cycles, without being recharged, is

verified.

14.2.12.1.70.4 Acceptance Criteria

a. The time required for each diesel generator to reach

rated speed is within design specifications.

b. The performance characteristics of the diesel generators

and associated auxiliaries are within design

specifications.

c. Each diesel generator starts automatically on receipt of

a safety injection signal or a bus under-voltage signal.

14.2-91 Rev. 0 WOLF CREEK

d. Each diesel generator trips automatically on receipt of each of the following signals:

Lube oil pressure low

Jacket coolant temperature high Crankcase pressure high

Start failure

Engine overspeed

Diesel generator ground overcurrent

Diesel generator differential current

e. The diesel generator neutral ground overcurrent trip

signal is bypassed when the diesel generator is

operating in the emergency mode.

f. Each air storage tank is capable of providing five diesel cranking cycles, without being recharged.
g. Each starting air compressor has the ability to charge

its respective air tank from minimum to normal pressure

within the required time.

14.2.12.1.71 4160-V (Class IE) System Preoperational Test

(S-03NB01)

14.2.12.1.71.1 Objectives

a. To demonstrate that the 4,160-V Class IE busses can be

energized from their normal and alternate sources.

b. To verify that a 4,160-V Class IE bus digital undervoltage signal trips the associated incoming feeder

breakers.

c. To verify that a degraded bus voltage condition will

trip the associated incoming feeder breakers.

d. To verify proper operation of system instrumentation and

alarms.

14.2.12.1.71.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2-92 Rev. 0 WOLF CREEK 14.2.12.1.71.3 Test Method

a. The 4,160-V Class IE busses are energized from their

normal source, and bus voltages are recorded.

b. The 4,160-V Class IE busses are energized from their

alternate source, and bus voltages are recorded.

c. 4,160-V Class IE bus undervoltage signals are simulated, and proper operation of the 4,160-V Class IE feeder

breakers is verified.

14.2.12.1.71.4 Acceptance Criteria

a. The voltage of each 4,160-V Class IE bus, when supplied from its normal source, is within design specifications.
b. The voltage of each 4,160-V Class IE bus, when supplied

from its alternate source, is within design

specifications.

c. A 4,160-V Class IE bus digital undervoltage signal will

trip the appropriate bus incoming feeder breakers.

d. A degraded voltage condition on either 4,160-V Class IE

bus will cause an alarm and, if it continues, trip the

appropriate bus incoming feeder breakers.

e. A degraded voltage condition on either 4,160-V Class IE

bus coincident with a safety injection actuation signal will immediately trip the bus incoming feeder breakers.

14.2.12.1.72 Diesel Generator Electric Preoperational Test

(S-03NE01)

14.2.12.1.72.1 Objectives

a. To demonstrate that each diesel generator is capable of

35 consecutive valid starts with no failure.

b. To demonstrate the ability of each diesel generator to

carry the design load for the time required to reach

equilibrium temperature plus l hour, without exceeding

design limits.

c. To demonstrate the ability of each diesel generator to

attain and stabilize frequency and voltage within the

design limits and time.

14.2-93 Rev. 0 WOLF CREEK

d. To demonstrate the capability of each diesel generator to withstand a full-load rejection without exceeding

speeds or voltages that cause tripping or damage.

e. To demonstrate the operability of each diesel generator feeder breaker and associated interlocks.
f. To demonstrate the ability of the diesel cooling water

system to maintain the diesel temperature within design

specifications, while the diesel generators are

operating at full load.

g. To demonstrate the ability of each diesel generator to

start and shed the largest single motor while supplying

all other sequenced loads, maintaining voltage and frequency within design limits.

14.2.12.l.72.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The essential service water system is available to

provide cooling water to the diesel generator

intercooler heat exchanger.

d. The emergency fuel oil system is available to provide fuel oil to the diesel generators.
e. The fire protection system is available to support this

test.

f. The 4.16-kV busses are available for loading to support

this test.

14.2.12.1.72.3 Test Method

a. The ability of each diesel generator to undergo 35

consecutive starts with no failure is verified.

b. The ability of each diesel generator to carry the design

load for the time required to reach equilibrium

temperature, plus 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br />, without exceeding design

limits, is verified.

14.2-94 Rev. 0 WOLF CREEK

c. The ability of each diesel generator to attain and stabilize frequency and voltage within the design limits

and time is verified.

d. The ability of each diesel generator to withstand a full-load rejection, without exceeding speeds or

voltages that cause tripping, is verified.

e. The operability of each diesel generator feeder breaker

and associated interlocks is verified.

f. While operating each diesel generator at full-load

conditions, the ability of the diesel cooling water

system to maintain diesel temperatures within design

specifications is verified.

g. The ability of each diesel generator to start and shed

the largest fully loaded single motor while supplying

all other sequenced loads and maintain voltage and

frequency within design limits is verified.

14.2.12.1.72.4 Acceptance Criteria

a. Each diesel generator is capable of carrying the design

load for the time required to reach equilibrium

temperature, plus 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br />, without exceeding design

limits.

b. Each diesel generator can attain and stabilize frequency

and voltage within design limits and time.

c. Each diesel generator is capable of withstanding a full-

load rejection without exceeding speeds or voltages that

cause tripping.

d. When a diesel generator is operating in the nonemergency

(test) mode, the associated diesel generator feeder

breaker trips on receipt of any of the following

signals:

Generator overcurrent

Reverse power

Loss of field

Underfrequency

e. The diesel generator stops and the associated diesel

generator feeder breaker trips on receipt of any of the

following signals:

Generator differential current

Neutral ground overcurrent

14.2-95 Rev. 0 WOLF CREEK

f. When a diesel generator is operating in the emergency mode, the following trip signals are bypassed:

Neutral ground overcurrent

Generator overcurrent Reverse power

Loss of field

Underfrequency

g. Each diesel generator cooling water system, with the

diesel generators operating at full-load, maintains the

diesel temperatures within design specifications.

h. Each diesel generator has the capability of starting and

shedding the largest fully loaded single motor while supplying all other sequenced loads, maintaining voltage and frequency within design limits.

i. Diesel generators are capable of 35 consecutive valid

starts with no failure.

14.2.12.1.73 Integrated Control Logic Test (SU3-NF01)

14.2.12.1.73.1 Objectives

a. To demonstrate that the actuation of the LOCA sequencer, shutdown sequencer, safety-related load shed, and

nonsafety-related load shed circuits on receipt of the

appropriate undervoltage, safety injection, containment

spray actuation, diesel generator breaker position, and normal and alternate 4,160-V feeder breaker position signals is in accordance with system design.

b. To demonstrate that the LOCA sequencer, shutdown

sequencer, safety-related load shed, and nonsafety-

related load shed circuits shed and sequence loads in

accordance with system design.

14.2.12.1.73.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2.12.1.73.3 Test Method

a. Undervoltage, safety injection, containment spray

actuation, diesel generator breaker position, and

normal and

14.2-96 Rev. 0 WOLF CREEK alternate 4,160-V feeder breaker position signals are initiated, and the actuation of the LOCA sequencer, shutdown sequencer, safety-related load shed, and

nonsafety-related load shed circuits is verified.

b. Signals are initiated to actuate the LOCA sequencer, shutdown sequencer, safety-related load shed, and

nonsafety-related load shed circuits, and proper load

shed and load sequencing are verified.

14.2.12.1.73.4 Acceptance Criteria

a. Actuation of the LOCA sequencer, shutdown sequencer, safety-related load shed, and nonsafety-related load

shed circuits on receipt of under-voltage, safety injection, containment spray actuation, diesel generator breaker position, and normal and alternate 4,160-V

feeder breaker position signals is in accordance with

system design.

b. The LOCA sequencer, shutdown sequencer, safety-related

load shed, and nonsafety-related load shed circuits shed

and sequence loads in accordance with system design.

14.2.12.1.74 LOCA Sequencer Preoperational Test (S-03NF02)

14.2.12.1.74.1 Objectives

a. To demonstrate that initiation of a safety injection

signal (SIS) will shed the nonsafety-related loads, start the diesel generator, and sequence the associated equipment. The ability of each 4,160-V Class IE load

group to supply the sequenced loads while maintaining

voltage within design specifications is also verified.

b. To demonstrate that a loss of offsite power concurrent

with SIS will shed the safety-related loads, start the

diesel generator, close the diesel generator feeder

breaker, and sequence the associated equipment. The

ability of each diesel generator to supply the sequenced

loads while maintaining voltage and frequency within

design specifications is also verified.

c. To demonstrate the ability of each diesel generator to

carry the short-time rating load for 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> and the

continuous rated load for 22 hours2.546296e-4 days <br />0.00611 hours <br />3.637566e-5 weeks <br />8.371e-6 months <br />, without exceeding

design limits.

d. To demonstrate that each diesel generator, following

operation for 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> at the short-time rated load and

14.2-97 Rev. 0 WOLF CREEK 22 hours2.546296e-4 days <br />0.00611 hours <br />3.637566e-5 weeks <br />8.371e-6 months <br /> at the continuous rated load, will start automatically on a loss of ac voltage concurrent with an

SIS, attain voltage and frequency within design limits

and time, and accept the LOCA sequenced loads, while

maintaining voltage and frequency within design limits.

c. To demonstrate the ability of the diesel cooling water

system to maintain the diesel temperature within design

specifications, while the diesel generators are

operating for 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> at the short-time rating load and

22 hours2.546296e-4 days <br />0.00611 hours <br />3.637566e-5 weeks <br />8.371e-6 months <br /> at the continuous rating load.

f. To determine the fuel oil consumption of each diesel, while operating for 22 hours2.546296e-4 days <br />0.00611 hours <br />3.637566e-5 weeks <br />8.371e-6 months <br /> at the continuous rating

load.

g. To demonstrate the ability of the 125 V dc system to

perform its design functions while at minimum voltage.

h. To demonstrate the independence between the redundant on

ac and dc power sources.

14.2.12.1.74.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Each diesel generator and its associated auxiliaries are

available.

c. All components actuated by the LOCA sequencer and safety-related and nonsafety-related load shed circuits

are available.

14.2.12.1.74.3 Test Method

a. A train A SIS is initiated, and the following are

verified:

1. Group l nonsafety-related loads are shed.
2. Group 1 diesel generator starts.
3. Group 1 LOCA sequencer is actuated, and associated

components are sequenced. The times for sequenced

pumps to reach full flow are verified.

4. With bus NB01 supplying the sequenced loads from its

normal source, bus voltage is recorded.

14.2-98 Rev. 0 WOLF CREEK

b. With group 2 dc load group isolated from its power source and group 1 dc load group voltage set to minimum, a loss of offsite power is initiated concurrent with a

train A SIS, and the following are verified:

1. Safety-related group 1 loads are shed.
2. Group 1 diesel generator starts, and its feeder

breaker closes.

3. Group 1 LOCA sequencer is actuated, and associated

components are sequenced. The times for sequenced

pumps to reach full flow are verified.

4. With the group 1 diesel generator supplying the sequenced loads, bus voltage and frequency are recorded.
5. The group 2 ac and dc busses are monitored to

verify the absence of voltage on these busses and

loads, indicating no interconnection at load

groups.

c. The ability of the group 1 diesel generator to carry the

short-time rating load for 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> without exceeding

design limits is verified.

d. The ability of the group 1 diesel generator to carry the

continuous rated load for 22 hours2.546296e-4 days <br />0.00611 hours <br />3.637566e-5 weeks <br />8.371e-6 months <br /> without exceeding

design limits is verified. Group l diesel fuel oil consumption is also determined.

e. Following group 1 diesel generator operation for 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br />

at the short-time rated load and 22 hours2.546296e-4 days <br />0.00611 hours <br />3.637566e-5 weeks <br />8.371e-6 months <br /> at the

continuous rated load, the group 1 diesel generator is

shutdown, a loss of group 1 ac voltage is initiated

concurrent with a train A SIS, and the ability of the

group l diesel generator to start, attain voltage and

frequency within design limits and time, and accept the

loads resulting from the design accident loading

sequence while maintaining voltage and frequency within

design limits is verified. If this test is not

satisfactorily completed, it is not necessary to repeat

the tests of items c and d prior to rerunning this

test. Instead, prior to rerunning this test, the diesel

generator may be operated at the continuous rated load

for l hour or until operating temperature has

stabilized.

14.2-99 Rev. 0 WOLF CREEK

f. A train B SIS is initiated, and the following are verified:
1. Group 2 nonsafety-related loads are shed.
2. Group 2 diesel generator starts.
3. Group 2 LOCA sequencer is actuated, and associated

components are sequenced. The times for sequenced

pumps to reach full flow are verified.

4. With Bus NB02 supplying the sequenced loads from

its normal source, bus voltage is recorded.

g. With group 1 dc load group isolated from its power source and group 2 dc load group voltage set to minimum, a loss of offsite power is initiated concurrent with a

train B SIS, and the following are verified:

1. Safety-related group 2 loads are shed.
2. Group 2 diesel generator starts, and its feeder

breaker closes.

3. Group 2 LOCA sequencer is actuated, and associated

components are sequenced. The times for sequenced

pumps to reach full flow are verified.

4. With the group 2 diesel generator supplying the

sequenced loads, bus voltage and frequency are recorded.

5. The group l ac and dc busses are monitored to

verify the absence of voltage on these busses and

loads, indicating no interconnection of load

groups.

h. The ability of the group 2 diesel generator to carry the

short-time rating load for 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> without exceeding

design limits is verified.

i. The ability of the group 2 diesel generator to carry the

continuous rated load for 22 hours2.546296e-4 days <br />0.00611 hours <br />3.637566e-5 weeks <br />8.371e-6 months <br /> without exceeding

design limits is verified. Group 2 diesel fuel oil

consumption is also determined.

14.2-100 Rev. 0 WOLF CREEK

j. Following group 2 diesel generator operation for 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> at the short-time rated load and 22 hours2.546296e-4 days <br />0.00611 hours <br />3.637566e-5 weeks <br />8.371e-6 months <br /> at the

continuous rated load, the group 2 diesel generator is

shutdown, a loss of group 2 ac voltage is initiated

concurrent with a train B SIS, and the ability of the group 2 diesel generator to start, attain voltage and

frequency within design limits and time, and accept the

LOCA sequenced loads, while maintaining voltage and

frequency within design limits, is verified. If this

test is not satisfactorily completed, it is not necessary

to repeat the tests of items h and i prior to rerunning

this test. Instead, prior to rerunning this test, the

diesel generator may be operated at the continuous rated

load for l hour or until operating temperature has

stabilized.

k. The ability of the diesel cooling water system to

maintain the diesel temperature within design

specifications, while the diesel generators are operating

for 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> at the short-time rating load and 22 hours2.546296e-4 days <br />0.00611 hours <br />3.637566e-5 weeks <br />8.371e-6 months <br /> at

the continuous rating load, is verified.

14.2.12.1.74.4 Acceptance Criteria

a. A train A SIS initiates the following, in accordance

with system design:

1. Group 1 nonsafety-related loads are shed.
2. Group 1 diesel generator starts.
3. Group l LOCA sequencer actuates, and the associated

components are sequenced. Sequenced pumps reach

full flow within the required times.

b. Bus NB01, while powered from its normal source, supplies

the sequenced loads while maintaining voltage within

design specifications.

c. With the group 2 dc load group isolated from its power

source and the group 1 dc load group voltage at minimum, a loss of offsite power concurrent with a train A SIS

initiates the following, in accordance with system

design:

1. Safety-related group 1 loads are shed.
2. Group 1 diesel generator starts, and its feeder

breaker closes.

14.2-101 Rev. 0 WOLF CREEK

3. Group l LOCA sequencer actuates, and the associated components are sequenced. Sequenced pumps reach

full flow within design times.

d. Group l diesel generator supplies the sequenced loads, while maintaining voltage and frequency within design

specifications.

e. With load group 1 supplying loads following a loss of

offsite power concurrent with a train A SIS, the group 2

ac and dc busses are verified de-energized, indicating

no interconnection of load groups.

f. Following group 1 diesel generator operation for 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br />

at the short-time rated load and 22 hours2.546296e-4 days <br />0.00611 hours <br />3.637566e-5 weeks <br />8.371e-6 months <br /> at the continuous rated load, the group 1 diesel generator starts, attains voltage and frequency within design

limits and time, and accepts the LOCA sequenced loads

while maintaining voltage and frequency within design

limits, on loss of group 1 ac voltage concurrent with a

train A SIS.

g. A train B SIS initiates the following, in accordance

with the system design:

1. Group 2 nonsafety-related loads are shed.
2. Group 2 diesel generator starts.
3. Group 2 LOCA sequencer actuates, and the associated components are sequenced. Sequenced pumps reach full flow within design times.
h. Bus NB02, while powered from its normal source, supplies

the required loads while maintaining the voltage within

design specifications.

i. With the group 1 dc load group isolated from its power

source and the group 2 dc load group voltage at minimum, a loss of offsite power concurrent with a train B SIS

initiates the following, in accordance with system

design:

1. Safety-related group 2 loads are shed.
2. Group 2 diesel generator starts, and its feeder

breaker closes.

14.2-102 Rev. 0 WOLF CREEK

3. Group 2 LOCA sequencer actuates, and the associated components are sequenced. Sequenced pumps reach

full flow within design times.

j. Group 2 diesel generator supplies the required loads, while maintaining voltage and frequency within design

specifications.

k. With load group 2 supplying loads following a loss of

offsite power concurrent with a train B SIS, the group 1

ac and dc busses are verified de-energized, indicating

no interconnection of load groups.

l. Following group 2 diesel generator operation for 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br />

at the short-time rated load and 22 hours2.546296e-4 days <br />0.00611 hours <br />3.637566e-5 weeks <br />8.371e-6 months <br /> at continuous rated load, group 2 diesel generator starts, attains voltage and frequency within design limits and time, and

accepts the LOCA sequenced loads while maintaining

voltage and frequency within design limits, on loss of

group 2 ac voltage concurrent with a train B SIS.

m. Each diesel generator is capable of carrying the short-

time rating load for 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> and the continuous rated

load for 22 hours2.546296e-4 days <br />0.00611 hours <br />3.637566e-5 weeks <br />8.371e-6 months <br />, without exceeding design limits.

n. Fuel oil consumption of each diesel, while operating at

the continuous rated load, is within design

specifications.

o. Each diesel generator cooling water system, with the diesel generators operating for 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> at the short-time rating load and 22 hours2.546296e-4 days <br />0.00611 hours <br />3.637566e-5 weeks <br />8.371e-6 months <br /> at the continuous rating

load, maintains the diesel temperatures within design

specifications.

p. The controls required for the loss of offsite power

concurrent with a SIS (shedding, sequencing, etc.)

function with minimum dc voltage available.

14.2.12.1.75 Shutdown Sequencer Preoperational Test (S-03NF03)

14.2.12.1.75.1 Objectives

a. To demonstrate that de-energization of either 4,160-V

Class IE load group will start the associated diesel

generator, close the diesel generator feeder breaker, actuate the associated group load shed, and actuate the

shutdown sequencer. All sequenced components are

verified to start within required design times.

14.2-103 Rev. 0 WOLF CREEK

b. To demonstrate that each diesel generator will maintain voltage and frequency within design specifications while

supplying the design shutdown loads.

c. To demonstrate the ability of the emergency 4.16-kV loads to start at maximum and minimum design voltages.

14.2.12.1.75.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. Each diesel generator and its associated auxiliaries are available.
d. All components actuated by the shutdown sequencer are

available.

14.2.12.1.75.3 Test Method

a. Class IE 4,160-V load group 1 is de-energized and the

following are verified:

1. Group 1 load shedder actuates.
2. Group 1 diesel generator starts, and its feeder

breaker closes.

3. Group 1 shutdown sequencer is actuated, and

associated components are sequenced. Components

are verified to actuate within the required design

times.

b. Class IE 4,160-V load group 2 is de-energized and the

following are verified:

1. Group 2 load shedder actuates.
2. Group 2 diesel generator starts, and its feeder

breaker closes.

3. Group 2 shutdown sequencer is actuated, and

associated components are sequenced. Components

are verified to actuate within the required design

times.

14.2-104 Rev. 0 WOLF CREEK

c. Emergency 4.16-kV loads are started while their respective diesel generators are supplying:
1. Minimum rated voltage
2. Maximum rated voltage
d. The ability of each diesel generator to maintain voltage

and frequency within the design specifications while

supplying the design shutdown loads is verified.

14.2.12.1.75.4 Acceptance Criteria

a. De-energization of Class IE 4,160-V load group 1

initiates the following, in accordance with system design:

1. Group 1 diesel generator starts, and its feeder

breaker closes.

2. Group 1 shutdown sequencer actuates, and associated

components are sequenced. Components actuate

within required design times.

3. Group 1 load shedder actuates.
b. De-energization of Class IE 4,160-V load group 2

initiates the following, in accordance with system

design:

1. Group 2 diesel generator starts, and its feeder breaker closes.
2. Group 2 shutdown sequencer actuates, and associated

components are sequenced. Components actuate

within required design times.

3. Group 2 load shedder actuates.
c. The emergency 4.16-kV loads start and reach rated speed

within design times, with minimum and maximum design

voltage.

d. Each diesel generator maintains voltage and frequency

within design specifications, while supplying the design

shutdown loads.

14.2.12.1.76 480-V (Class IE) System Preoperational Test

(S-03NG01)

14.2.12.1.76.1 Objectives

To demonstrate that the 480-V Class IE load centers can be energized from

their normal and alternate sources and verify the

14.2-105 Rev. 0 WOLF CREEK operability of system breaker protective interlocks. Proper operation of system instrumentation and controls is also verified.

14.2.12.1.76.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2.12.1.76.3 Test Method

a. The 480-V Class IE load centers are energized from their

normal source, and voltages are recorded.

b. The 480-V Class IE load centers are energized from their

alternate source, and voltages are recorded.

c. System breakers are operated, and breaker interlocks

verified.

14.2.12.1.76.4 Acceptance Criteria

a. The voltage for each 480-V Class IE load center, when

supplied from its normal source, is within design

specifications.

b. The voltage for each 480-V Class IE load center, when

supplied from its alternate source, is within design specifications.

c. System breaker interlocks operate in accordance with the

system design.

14.2.12.1.77 480-V Class IE System (ESW) Preoperational Test

(SU3-NG02).

14.2.12.1.77.1 Objectives

To demonstrate that the nonpower block 480-V Class IE MCC can be energized from

their normal source and to verify their bus voltage phase sequence. Proper

operation of system instrumentation and controls is also verified.

14.2.12.1.77.2 Prerequisites

a. Required component testing and instrument calibration

are completed.

14.2-106 Rev. 0 WOLF CREEK

b. Required electrical power supplies and control circuits are operational.

14.2.12.1.77.3 Test Method

The nonpower block 480-V Class IE MCC are energized, voltages are recorded, and

phase sequence is verified.

14.2.12.1.77.4 Acceptance Criteria

a. The voltage for each nonpower block 480-V Class IE MCC

is within design specification.

b. The bus voltage phase sequence of the nonpower block

480-V Class IE MCC is in accordance with design.

14.2.12.1.78 125-V (Class IE) DC System Preoperational Test

(S-03NK01)

14.2.12.1.78.1 Objectives

To demonstrate the ability of the batteries and chargers to provide power

during normal operations and the battery to provide power during abnormal

conditions. The battery chargers' ability to recharge their respective battery

is also demonstrated. Proper operation of the system instrumentation and

controls is also verified.

14.2.12.1.78.2 Prerequisites

a. Required component testing and instrument calibration are complete.
b. Required electrical power supplies and control circuits

are operational.

c. Ventilation for the battery rooms is available.

14.2.12.1.78.3 Test Method

a. Each battery is discharged, using a test load at the

design duty cycle discharge rate.

b. Each battery is fully discharged to determine its

capacity factor.

c. Each battery charger will charge its respective battery

to normal conditions, after the battery has undergone a

design duty cycle, while simultaneously supplying power

at a rate equivalent to the design emergency loading.

14.2-107 Rev. 0 WOLF CREEK 14.2.12.1.78.4 Acceptance Criteria

a. Each battery is capable of maintaining output voltage

above the design minimum, during a design duty cycle.

b. Each battery has a capacity factor greater than or equal

to design.

c. The battery chargers are able to recharge the batteries

to normal conditions, after the battery has undergone a

design duty cycle, while simultaneously supplying power

at a rate equivalent to the design emergency loading.

14.2.12.1.79 Instrument AC System (Class IE) Preoperational Test

(S-03NN01) 14.2.12.1.79.1 Objectives

To demonstrate that the 120-V Class IE ac distribution panel- boards can be fed

from their normal source inverters and from their backup source transformers by

manual transfer. The operability of system instrumentation and controls, including breaker protective interlocks, is also verified.

14.2.12.1.79.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2.12.1.79.3 Test Method

a. The 120-V Class IE ac distribution panelboards are

energized from their normal source inverters, and

panelboard voltages are recorded.

b. The 120-V Class IE ac distribution panelboards are

energized from their backup source transformers by

manual transfer, and panelboard voltages are recorded.

c. The system breakers are operated, and breaker interlocks

are verified.

14.2.12.1.79.4 Acceptance Criteria

a. Each 120-V Class IE ac distribution panelboard voltage, when supplied from the normal source inverters of the

panelboards, is within design specifications.

14.2-108 Rev. 0 WOLF CREEK

b. Each 120-V Class IE ac distribution panelboard voltage, when supplied from the backup source transformers, is

within design specifications.

c. System breaker interlocks operate in accordance with system design.

14.2.12.1.80 Engineered Safeguards (NSSS) Preoperational Test

(SU3-SA01)

14.2.12.1.80.1 Objectives

a. To demonstrate the ability of the NSSS to initiate

safety injection, containment isolation, containment

spray actuation, main feedwater isolation, and steam line isolation signals on receipt of the associated input signals.

b. To verify NSSS ESFAS loop response times.
c. To demonstrate the ability of each solid-state

protection system test panel to adequately test the

associated NSSS ESFAS and reactor protection logic

trains.

d. To demonstrate the coincidence and redundancy of the

NSSS ESFAS.

e. To verify the operability of ESFAS block and permissive

interlocks.

14.2.12.1.80.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies are operational.

14.2.12.1.80.3 Test Method

a. The ability of the NSSS ESFAS to actuate safety

injection, containment isolation, containment spray

actuation, main feedwater isolation, and steam line

isolation signals on receipt of the required coincidence

of the following input signals for each redundant

channel is verified:

. High steam line pressure rate

. Low steam line pressure

. Low pressurizer pressure

14.2-109 Rev. 0 WOLF CREEK

. High containment pressure (Hi-1, Hi-2, and Hi-3)

. High-high steam generator level

. Low Tavg

. Low-low steam generator water level

b. Input signals are initiated, and loop response times are

verified.

c. The ability of each solid-state protection system test

panel to test the NSSS ESFAS logic trains is verified.

d. ESFAS block and permissive interlocks are verified.

14.2.12.1.80.4 Acceptance Criteria

a. The NSSS ESFAS actuates safety injection, containment isolation, containment spray actuation, main feedwater

isolation, and steam line isolation signals when their

associated input signals are received from the following

signals for each applicable channel:

. High steam line pressure rate

. Low steam line pressure

. Low pressurizer pressure

. High containment pressure (Hi-1, Hi-2, and Hi-3)

. High-high steam generator level

. Low Tavg

. Low-low steam generator water level

b. NSSS ESFAS loop response times are within design specifications.
c. ESFAS block and permissive interlocks operate in

accordance with system design.

14.2.12.1.81 Engineered Safeguards (BOP) Preoperational Test

(SU3-SA02)

14.2.12.1.81.1 Objectives

a. To demonstrate the operability of the BOP ESFAS to

initiate containment purge isolation, control room

ventilation isolation, fuel building ventilation

isolation, auxiliary feedwater pump actuation, auxiliary

feedwater suction valve switchover to essential service

water (ESW), and steam generator blowdown and sample

isolation signals on receipt of the associated input

signals.

14.2-110 Rev. 0 WOLF CREEK

b. To verify BOP ESFAS loop response times.
c. To demonstrate the ability of the BOP ESFAS test panel

to adequately test the associated BOP ESFAS logic

trains.

d. To demonstrate the coincidence and redundancy of the BOP

ESFAS.

14.2.12.1.81.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies are operational.

14.2.12.1.81.3 Test Method

a. The ability of the BOP ESFAS to actuate containment

purge isolation, control room ventilation isolation, fuel building ventilation isolation, auxiliary feedwater

pump actuation, auxiliary feedwater suction valve

switchover to ESW, and steam generator blowdown and

sample isolation signals on receipt of the required

coincidence of the following input signals for each

redundant channel is verified.

o Containment isolation (phase A)

o High atmospheric radiation

o High chlorine concentration o Loss of main feedwater flow o Low-low steam generator level

o Loss of offsite power

o Low feedwater pump suction pressure

o Safety injection

b. Input signals are initiated, and loop response times are

verified.

c. The ability of the BOP ESFAS test panel to test the BOP

ESFAS logic trains is verified.

14.2.12.1.81.4 Acceptance Criteria

a. The BOP ESFAS actuates containment purge isolation, control room ventilation isolation, fuel building

ventilation isolation, auxiliary feedwater pump

actuation, auxiliary feedwater suction valve switchover

to ESW, and

14.2-111 Rev. 0 WOLF CREEK steam generator blowdown and sample isolation signals

when their associated input signals are received from

the following signals for each applicable channel:

o Containment isolation (phase A)

o High atmospheric radiation

o High chlorine concentration

o Loss of main feedwater flow

o Low-low steam generator level

o Loss of offsite power

o Low feedwater pump suction pressure

o Safety injection

b. BOP ESFAS loop response times are within design specifications.

14.2.12.1.82 Engineered Safeguards Verification Test (SU3-SA03)

14.2.12.1.82.1 Objectives

To demonstrate the proper response of actuated components resulting from the

following safety signals: Safety injection, containment spray actuation, main

feedwater isolation, steam line isolation, containment isolation, containment

purge isolation, control room ventilation isolation, fuel building ventilation

isolation, auxiliary feedwater pump actuation, auxiliary feedwater suction

valve switch over to ESW, and steam generator blowdown and sample isolation.

14.2.12.1.82.2 Prerequisites

a. Required component testing and instrument calibration are complete.
b. Required electrical power sources and control circuits

are operational.

c. Components actuated by the NSSS and BOP ESFAS are

available.

14.2.12.1.82.3 Test Method

NSSS and BOP ESFAS signals are initiated manually and the proper response and

response times of the actuated components are verified.

14.2-112 Rev. 0 WOLF CREEK 14.2.12.1.82.4 Acceptance Criteria

Components required to actuate on receipt of safety signals respond properly in

accordance with design specifications and within the times specified by design

requirements.

14.2.12.1.83 Reactor Protection System Logic Test (S-03SB01)

14.2.12.1.83.1 Objectives

a. To demonstrate the ability of the reactor protection

system to initiate a reactor trip on input of the

associated input signals.

b. To verify reactor protection loop response times.
c. To verify the operability of the reactor protection

system block and permissive interlocks.

d. To demonstrate the coincidence, redundancy, and fail

safe (power loss) design of the reactor protection

system.

14.2.12.1.83.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2.12.1.83.3 Test Method

a. The ability of the reactor protection system to initiate

a reactor trip on receipt of the proper coincidence of

the following trip signals for each redundant channel is

verified:

o Source range high neutron flux

o Intermediate range high neutron flux

o Power range high neutron flux (low setpoint and

high setpoint)

o Power range high positive neutron flux rate

o Power range high negative neutron flux rate o Overtemperature T o Overpower T o Low primary coolant flow o Reactor coolant pump bus undervoltage

o Reactor coolant pump bus underfrequency

14.2-113 Rev. 0 WOLF CREEK o High pressurizer pressure o Low pressurizer pressure

o High pressurizer level

o Safety injection signal

o Turbine trip signal

b. Loop response times are measured for the above listed

trip signals.

c. Reactor protection system block and permissive

interlocks are verified.

d. Power is isolated from the system, and the safe failure

of the system is verified.

14.2.12.1.83.4 Acceptance Criteria

a. The reactor protection system initiates a reactor trip

on receipt of the proper coincidence of the following

signals for each applicable channel:

o Source range high neutron flux

o Intermediate range high neutron flux

o Power range high neutron flux (low setpoint and

high setpoint)

o Power range high positive neutron flux rate

o Power range high negative neutron flux rate o Overtemperature T o Overpower T o Low primary coolant flow o Reactor coolant pump bus undervoltage o Reactor coolant pump bus underfrequency

o High pressurizer pressure

o Low pressurizer pressure

o High pressurizer level

o Safety injection signal

o Turbine trip signal

b. Loop response times for the following trip signals are

within design limits.

o Power range high neutron flux (low setpoint and

high setpoint)

o Power range high negative neutron flux rate o Overtemperature T o Overpower T o Low primary coolant flow o Reactor coolant pump bus undervoltage

o Reactor coolant pump bus underfrequency

14.2-114 Rev. 0 WOLF CREEK o High pressurizer pressure o Low pressurizer pressure

c. Reactor protection system block and permissive

interlocks operate in accordance with system design.

d. The reactor protection system functions in accordance

with system design on a loss of power.

14.2.12.1.84 Primary Sampling System Preoperational Test

(S-03SJ01)

14.2.12.1.84.1 Objectives

a. To set sample panels' flow rates and to verify the operability of the sample system containment isolation valves. Proper operation of system instrumentation and

controls is also verified.

b. To verify that the post-accident sampling system (PASS)

containment isolation valves operate properly.

14.2.12.1.84.2 Prerequisites

a. Required component testing instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operable.

c. Plant conditions are established, and systems are available, as necessary, to facilitate drawing samples

from the sample points.

d. The component cooling water system is available to

provide cooling water to the auxiliary building sample

station.

e. The chemical and volume control system is available to

receive discharge from the nuclear sampling station.

f. The chemical and detergent waste system is available to

receive discharge from the nuclear sampling station.

14.2.12.1.84.3 Test Method

a. Sample panel flows are adjusted, and flow data are

recorded.

14.2-115 Rev. 0 WOLF CREEK

b. Operability of the sample containment isolation valves is verified, including their response to an isolation

signal. Valve operating times are recorded.

14.2.12.1.84.4 Acceptance Criteria

a. The sample containment isolation valves close on receipt

of an isolation signal.

b. The sample containment isolation valves' closure times

are within design specifications.

14.2.12.1.85 Process Radiation Monitoring System Preoperational

Test (S-03SP01)

14.2.12.1.85.1 Objectives

To demonstrate the operation of the process radiation monitors and to verify

the ability of the process radiation monitoring system to provide alarm and

isolation signals, as applicable, upon receipt of high radiation signals.

Operability of the radioactivity monitoring control room microprocessor is also

verified.

14.2.12.1.85.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operable.

14.2.12.1.85.3 Test Method

a. The check source for each monitor is remotely

positioned, and the actuation of each monitor and the

operability of its associated alarms and isolation

signals are verified.

b. Operability of the radioactivity monitoring control room

microprocessor is verified.

14.2.12.1.85.4 Acceptance Criteria

The process radiation monitoring system provides alarm and isolation signals, in accordance with system design specifications.

14.2-116 Rev. 0 WOLF CREEK 14.2.12.1.86 Power Conversion and ECCS Thermal Expansion Test (SU3-0004)

14.2.12.1.86.1 Objective

To demonstrate snubber operability on all safety-related systems whose

operating temperature exceeds 250 F.

14.2.12.1.86.2 Prerequisites

a. Preservice examinations as specified in the Tedesco

letter to KG&E dated 2/10/81 have been completed on the

systems being checked within the last 6 months.

b. Other required component testing and instrument calibration are completed.
c. Required electrical power supplies and control circuits

are operational.

d. Preoperational testing is in progress.

14.2.12.1.86.3 Test Method

a. During initial system heatup and cooldown, at specified

temperature intervals, verify the expected snubber

movement for any system which attains operating

temperature.

b. For those systems which do not attain operating temperature, verify by observation and/or calculation that the snubber will accommodate the projected thermal

movement.

c. Observe snubber swing clearances at specified heat-up

and cooldown intervals.

14.2.12.1.86.4 Acceptance Criteria

a. The expected snubber movement for any system that

attains operating temperature is within design

specifications.

b. The expected snubber movement determined by observation

and/or calculation for any system that does not attain

operating temperature is within design specifications.

c. Snubber swing clearance observed at specified heatup and

cooldown intervals is within design specifications.

14.2-117 Rev. 0 WOLF CREEK 14.2.12.1.87 Power Conversion and ECCS Systems Dynamic Test (S-030005)

14.2.12.1.87.1 Objectives

To demonstrate during specified transients that the systems' monitored points

respond in accordance with design.

14.2.12.1.87.2 Prerequisites

a. Reference points for measurement of the systems are

established.

b. Hot functional testing is in progress.
c. All subject systems are available for the specified dynamic operations.
d. Required instrument calibration is complete.

14.2.12.1.87.3 Test Method

a. The systems are aligned for the specified dynamic

operation.

b. The specified dynamic event of pump operation, valve

operation, etc., is initiated, and the system is

monitored for response.

14.2.12.1.87.4 Acceptance Criteria

a. The total stress shall not exceed applicable code

limits.

14.2.12.1.88 HEPA Filter Test (SU3-0006).

14.2.12.1.88.1 Objectives

To demonstrate the leaktightness and particulate removal efficiency of all HEPA

filters and to verify the leaktightness of their associated charcoal adsorbers.

14.2.12.1.88.2 Prerequisites

a. The ventilation systems containing HEPA filters and

charcoal adsorbers have been air balanced and are

operational and available to support this test.

14.2-118 Rev. 0 WOLF CREEK

b. Required electrical power supplies and control circuits are operational.
c. Required instrument calibration is complete.

14.2.12.1.88.3 Test Method

a. HEPA filters are inplace tested with cold poly-dispersed

DOP, in accordance with the procedures set forth in ANSI

N510.

b. Charcoal adsorbers are inplace tested with a suitable

refrigerant, in accordance with the procedures set forth

in ANSI N510.

14.2.12.1.88.4 Acceptance Criteria

a. The airflow of each filter adsorber unit is equal to the

design flow.

b. Air flow distribution downstream of each HEPA filter is

within 20 percent of the average velocity through the

unit.

c. HEPA DOP penetration is less than one percent at the

design air flow.

d. Charcoal adsorber bypass leakage is less than .05

percent at the design air flow.

14.2.12.1.89 Cooldown from Hot Standby External to the Control Room (S-030008)

14.2.12.1.89.1 Objectives

To demonstrate, using a plant procedure, the potential capability to cooldown

the plant from the hot standby to the cold shutdown condition, using

instrumentation and controls external to the control room verifying that:

a. The reactor coolant temperature and pressure can be

lowered to permit the operation of the residual heat

removal (RHR) system.

b. The RHR system can be operated and controlled.
c. The reactor coolant temperature can be reduced 50 F, using the RHR system, without exceeding technical specification limits.

14.2-119 Rev. 0 WOLF CREEK 14.2.12.1.89.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The plant is in a hot standby condition.
d. The authority and responsibility of the control room

observers has been established and is specified in this

procedure.

14.2.12.1.89.3 Test Method

a. The plant is cooled from hot standby, RHR is initiated, and a >

50°F cooldown is performed with the RHR system transferring heat to the ultimate heat sink, using instrumentation and controls external to the control room.

b. All actions performed by the control room observers are documented within this procedure for use in evaluating

their impact on the test results.

14.2.12.1.89.4 Acceptance Criteria

The following actions are capable of being performed, external to the control

room:

a. The reactor coolant temperature and pressure can be

lowered to permit the operation of the RHR system.

b. The reactor coolant temperature can be reduced 50 F, using the RHR system, without exceeding technical specification limits.

14.2.12.1.90 Compressed Gas Accumulator Testing (S-030009)

14.2.12.1.90.1 Objectives

To demonstrate the ability of the auxiliary feedwater control valve/mainsteam

atmospheric relief valve and main feedwater control valve accumulators to

provide the design backup supply of compressed gas for continued design valve

operation following a loss of the normal motive source.

14.2-120 Rev. 0 WOLF CREEK 14.2.12.1.90.2 Prerequisites

Required component testing, instrument calibration and system flushing/cleaning

are complete.

14.2.12.1.90.3 Test Method

The accumulators are isolated from the compressed gas supply header and the

associated valves are operated to demonstrate the ability of the accumulators

to provide design motive force for the required valve cycles.

14.2.12.1.90.4 Acceptance Criteria

The auxiliary feedwater control valve/mainsteam atmospheric relief valve, and

main feedwater control valve accumulators provide the design backup supply of compressed gas to their associated valves.

14.2.12.2 Nonsafety-Related Preoperational Test Procedures The following sections are the test abstract for each nonsafety- related

preoperational test. Table 14.2-2 provides an index of these tests.

14.2.12.2.1 Turbine Trip Test (S-04AC02)

14.2.12.2.1.1 Objectives

a. To demonstrate the ability of the turbine trip and

monitoring system to initiate a turbine trip on input of

the associated input signals.

b. To demonstrate the response of the moisture separator

reheater drain valves, feedwater heater extraction check valves, turbine main stop valves, turbine main stop valve above seat drain valves, turbine control valves, turbine control valve above seat drain valves, intermediate stop valves, main steamline drain valves, startup drain valves, and intercept valves to a turbine

trip signal.

c. To demonstrate that a turbine trip signal initiates a

reactor trip signal.

d. To demonstrate that the turbine main stop valves

operating times are within design specifications.

14.2-121 Rev. 0

WOLF CREEK 14.2.12.2.1.2 Prerequisites

a. Required component testing and instrument calibration is

complete.

b. Required electrical power supplies and control circuits

are operational.

c. The main turbine control oil and lube oil systems are

available to provide oil to the turbine auxiliaries.

d. The compressed air system is available to provide air to

system air-operated valves.

14.2.12.2.1.3 Test Method

a. The ability of the turbine trip and monitoring system to

initiate a turbine trip signal on receipt of each of the

following input signals is verified:

o Manual trip pushbutton depressed

o Manual trip handle pulled

o Generator trip (EHC vital trip)

o Generator trip (unit trip)

o Reactor trip

o Loss of stator coolant

o Low lube oil pressure

o Loss of EHC 125 V dc power with turbine speed

below 75 percent

o High turbine vibration o High exhaust hood temperature o Low hydraulic fluid pressure

o Moisture separator high level

o Low bearing oil pressure

o Low condenser vacuum

o Excessive thrust bearing wear

o Backup overspeed (Electrical)

o Loss of EHC 24-volt dc power

b. A turbine trip signal is initiated, and the response of

the following valves is verified:

o Moisture separator reheater drain valves

o Feedwater heater extraction check valves

o Turbine main stop valves

o Turbine control valves

o Intermediate stop valves

o Turbine intercept valves

o Startup drain valves

o Main steam line drain valves

14.2-122 Rev. 0 WOLF CREEK o Turbine main stop valve above seat drain valves o Turbine control valve above seat drain valves

c. A turbine trip signal is initiated, and a reactor trip

input signal is verified.

14.2.12.2.1.4 Acceptance Criteria

a. The turbine trip and monitoring system initiates a

turbine trip on receipt of each of the following

signals:

o Manual trip pushbutton depressed

o Manual trip handle pulled

o Generator trip (EHC vital trip) o Generator trip (unit trip) o Reactor trip

o Loss of stator coolant

o Low lube oil pressure

o Loss of EHC 125 V dc power with turbine speed

below 75 percent

o High turbine vibration

o High exhaust hood temperature

o Low hydraulic fluid pressure

o Moisture separator high level

o Low bearing oil pressure

o Low condenser vacuum

o Excessive thrust bearing wear

o Backup overspeed (electrical)

o Loss of EHC 24-volt dc power

b. The following valves open on receipt of a turbine trip

signal:

o Turbine main stop valve above seat drain valves

o Turbine control valve above seat drain valves

o Main steam line drain valves

o Moisture separator reheater drain valves

o Startup drain valves

c. The following valves close on receipt of a turbine trip

signal:

o Low pressure heater extraction check valves

o Main stop valves

o Turbine control valves

o Intercept valves

o Intermediate stop valves

14.2-123 Rev. 0 WOLF CREEK

d. A turbine trip signal initiates a reactor trip signal.
e. The turbine main stop valves operating times are within

design specifications.

14.2.12.2.2 Turbine System Cold Test (S-04AC03)

14.2.12.2.2.1 Objectives

a. To demonstrate the operability of the turning gear and

associated control circuits.

b. To demonstrate the operability of the electro-hydraulic

control system.

14.2.12.2.2.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The main turbine control oil and lube oil systems are

available to supply the turbine auxiliaries.

14.2.12.2.2.3 Test Method

a. The operability of the turning gear and associated

control circuits is verified.

b. A turbine simulator is utilized to verify the ability of

the electro-hydraulic control system to perform its

control functions.

14.2.12.2.2.4 Acceptance Criteria

a. The turning gear motor trips on loss of bearing oil

pressure, loss of all bearing lift pumps, or closure of

the main transformer switchyard breaker.

b. The turbine control and intercept valves close on a

power load unbalance signal.

c. The turbine load set is run back on a reactor overtemperature T signal when in the manual mode.
d. The turbine load set is run back on a reactor overpower T signal when in the manual mode.

14.2-124 Rev. 0 WOLF CREEK

e. The turbine load is set back on a loss of circulating water pump signal.
f. Turbine loading is inhibited on a C-16 control interlock

signal.

14.2.12.2.3 Condensate System Preoperational Test (S-04ADOl)

14.2.12.2.3.1 Objectives

To demonstrate the condensate pumps' operating characteristics and verify the

operation of system valves and associated control circuits. The operability of

the condensate storage and transfer system and associated components is also

verified.

14.2.12.2.3.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The feedwater system is available to receive flow from

the condensate pump discharge header.

d. The demineralized water system is available to provide

water to the condensate pump seals and a source of

makeup to the condensate storage tank.

e. The condensate storage tank is available to provide makeup to the condenser hotwell.
f. The closed cooling water system is available to provide

cooling water to the condensate pump motor bearing oil

coolers.

14.2.12.2.3.3 Test Method

a. Condensate pumps are operated, and performance

characteristics are verified.

b. The response of each condensate pump to a condenser low-

low level trip signal is verified.

c. The operability of the condensate pump recirculation

valves is verified.

14.2-125 Rev. 0 WOLF CREEK 14.2.12.2.3.4 Acceptance Criteria

a. The operating characteristics of the condensate pumps

are within design specifications.

b. Each condensate pump will receive a trip signal on a 2/3

condenser low-low level signal.

c. Each condensate pump recirculation valve operates in

accordance with design specifications.

14.2.12.2.4 Secondary Vent and Drain System Preoperational

Test (S-04AF01)

14.2.12.2.4.1 Objectives

a. To demonstrate the operating characteristics of the

heater drain pumps.

b. To demonstrate the operability of system valve and pump

control circuits.

14.2.12.2.4.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The compressed air system is available to the system air-operated valves.
d. The closed cooling water system is available to supply

cooling water to the heater drain pumps.

14.2.12.2.4.3 Test Method

a. The heater drain pumps are operated, and performance

characteristics are verified.

b. The operability of system valve and pump control

circuits is verified.

14.2.12.2.4.4 Acceptance Criteria

The operating characteristics of the heater drain pumps are within design

specifications.

14.2-126 Rev. 0 WOLF CREEK 14.2.12.2.5 Condensate and Feedwater Chemical Feed System Preoperational Test (S-04AQ01)

14.2.12.2.5.1 Objectives

a. To demonstrate the operating characteristics of the

condensate oxygen control chemical addition pumps, condensate pH control chemical addition pumps, condensate oxygen control chemical circulating pumps, condensate pH control chemical circulating pumps, feedwater chemical addition pumps, and feedwater chemical addition circulating pump and verify the operation of the associated control circuits.

b. To demonstrate the operability of the drum dispensing

pumps.

14.2.12.2.5.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The demineralized water storage and transfer system is

available to provide a source of demineralized water to the oxygen and pH control chemical supply and mixing tanks.

d. The compressed air system is available to provide air to

the drum dispensing pumps.

e. The service gas system is available to provide a source

of nitrogen to the oxygen and pH control chemical supply, measuring, and mixing tanks.

14.2.12.2.5.3 Test Method

a. System pumps are operated, and performance characteristics are verified.
b. The response of the condensate oxygen control chemical circulating pumps, condensate pH control chemical circulating pumps, and the feedwater chemical addition feed pumps to a low level in their associated tank is verified.

14.2-127 Rev. 12 WOLF CREEK 14.2.12.2.5.4 Acceptance Criteria

a. The operating characteristics of the condensate

oxygen control chemical addition pumps, condensate pH control chemical addition pumps, condensate oxygen control chemical circulating pumps, condensate ph control chemical circulating pumps, feedwater chemical addition pumps, feedwater chemical addition circulating pump, and the drum dispensing pumps are within design specifications.

b. The condensate oxygen control chemical circulating pumps, condensate pH control chemical circulating pumps, feedwater

chemical addition feed pumps, and the feedwater chemical addition circulating pump trip on a low level signal from their associated tanks.

14.2.12.2.6 Reactor Makeup Water System Preoperational Test

(S-04BL01)

14.2.12.2.6.1 Objectives

a. To demonstrate the operating characteristics of the

reactor makeup water transfer pumps and verify that the

associated control circuits are functioning properly.

b. To demonstrate the operation of the system automatic

valves, including the response of the reactor makeup

water system containment supply valve to a CIS.

14.2.12.2.6.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The demineralized water storage and transfer system is

available to provide a source of water to the reactor

makeup water storage tank.

14.2.12.2.6.3 Test Method

a. The reactor makeup water transfer pumps are operated, and pump operating data are recorded.
b. Reactor makeup water transfer pumps and system automatic

valves control logics are verified, including their

response to safety signals.

14.2-128 Rev. 12 WOLF CREEK

c. The reactor makeup water containment supply valve is operated under flow conditions and operating times

recorded.

14.2.12.2.6.4 Acceptance Criteria

a. The operating characteristics of the reactor makeup

water transfer pumps are within design specifications.

b. Each reactor makeup water transfer pump trips on receipt

of a reactor makeup water storage tank low level signal.

c. Each reactor makeup water transfer pump starts, after a

time delay, with the other pump running and the receipt

of a low header pressure signal.

d. The reactor makeup water containment supply valve

closure time is within design specifications.

e. The reactor makeup containment supply valve closes on

receipt of a CIS.

14.2.12.2.7 Condenser Air Removal System Preoperational Test

(S-04CG01)

14.2.12.2.7.1 Objectives

a. To demonstrate the operation of the condenser air

removal portion of the turbine building HVAC system

motoroperated dampers, including automatic operation on a safety injection signal.

b. To demonstrate the capacities of the condenser air

removal filtration fans and verify the operation of

their associated control circuits.

c. To demonstrate the operability of the condenser air

removal system vacuum pumps, control valves, and their

associated control circuits.

14.2.12.2.7.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2-129 Rev. 0 WOLF CREEK

c. The condenser air removal filtration system portion of the turbine building HVAC system is available to support

this test.

d. The condensate storage tank is available to provide a source of water to the vacuum pump seal water

reservoirs.

e. The service water system is available to provide cooling

water to the mechanical vacuum pump seal water coolers.

14.2.12.2.7.3 Test Method

a. The condenser air removal filtration fans are operated, and fan capacities are verified.
b. Operation of the condenser air removal filtration

dampers is verified, including their response to a

safety injection signal.

c. The ability of the mechanical vacuum pumps to reduce

condenser pressure during startup operation is verified.

d. Operability of the mechanical vacuum pumps and their

associated control valves' control circuits is verified, including their response to a low condenser vacuum

signal.

14.2.12.2.7.4 Acceptance Criteria

a. The condenser air removal filtration fans' capacities are within design specifications.
b. The condenser air removal filtration dampers close on

receipt of a safety injection signal.

c. The rate at which the mechanical vacuum pumps reduce

condenser pressure is within design specifications.

d. The mechanical vacuum pumps start automatically on

receipt of a low condenser vacuum signal.

14.2.12.2.8 Circulating Water System Preoperational Test (SU4-

DA01)

14.2.12.2.8.1 Objective

a. To demonstrate the operating characteristics of the

circulating water pumps, water box venting pumps, and

14.2-130 Rev. 0 WOLF CREEK the condenser drain pump and verify the operation of their associated control circuits.

b. To demonstrate by operational test that the circulating

water pump discharge valves operating times are within design specifications.

c. To demonstrate that the gland water system flow to the

circulating water pumps is within design specifications.

14.2.12.2.8.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are completed.

b. Required electrical power supplies and control circuits are operational.
c. The circulatng water system and condenser are available

to receive flow from the circulating water pumps.

14.2.12.2.8.3 Test Method

a. The circulating water pumps, water box venting pumps, and the condenser drain pump are operated and pump

operating data is recorded.

b. The response of the circulating water pumps and the

condenser drain pump to control signals is verified.

c. Circulating water pump discharge valve operating times are recorded.

14.2.12.2.8.4 Acceptance Criteria

a. The circulating water pumps operating characteristics

are within design specifications.

b. The water box venting pumps operating characteristics

are within design specifications.

c. The condenser drain pump operating characteristics are

within design specifications

d. The condenser drain pump stops on receipt of a standpipe

low-level signal.

e. Each circulating water pump trips on receipt of a two

out of three condenser pit high level signal.

14.2-131 Rev. 0 WOLF CREEK

f. Low gland seal water pressure or low gland seal flow will prevent start of the circulating water pumps.
g. The gland seal water flow to each circulating water pump

is within design specifications.

h. The operating times of the circulating water pump

discharge valves are within design specifications.

14.2.12.2.9 Service Water System Preoperational Test (S-04EA01).

14.2.12.2.9.1 Objectives

a. To demonstrate the capability of the service water

system and essential service water system to provide rated cooling water flow during the normal and normal-shutdown modes of operation to their respective loads.

b. To demonstrate the operating characteristics of the

Service Water (SW) Pumps.

c. To verify proper operation of site service water system

controls and instrumentation.

14.2.12.2.9.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits are operational.
c. The essential service water system has been flow

balanced in the LOCA mode.

d. Site system controls and instruments are calibrated.
e. The SW system is available to receive flow from the SW

pumps.

14.2.12.2.9.3 Test Method

a. Service water and essential service water system flows

are verified in the normal and normal-shutdown modes.

(The service water pumps provide the motive force.)

b. The SW pumps are operated and pump operating data is

recorded.

14.2-132 Rev. 0 WOLF CREEK 14.2.12.2.9.4 Acceptance Criteria

a. Components supplied by the service water system and

essential service water system receive flows that are

within design specifications with the system operating in the normal and normal-shutdown modes.

b. The SW pumps operating characteristics are within design

specifications.

14.2.12.2.10 Closed Cooling Water System Preoperational Test

(S-04EB01)

14.2.12.2.10.1 Objectives

a. To demonstrate the capability of the closed cooling water system to provide cooling water flow to its

associated components.

b. To demonstrate the operating characteristics of the

closed cooling water pumps and to verify that the

associated instrumentation and controls are functioning

properly.

14.2.12.2.10.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits are operational.

14.2.12.2.10.3 Test Method

Performance characteristics of the closed cooling water pumps and flow data to

supplied components are verified.

14.2.12.2.10.4 Acceptance Criteria

a. The performance characteristics of each closed cooling

water pump are within design specifications.

b. Flow to all components supplied by the closed cooling

water system is verified.

14.2-133 Rev. 0 WOLF CREEK 14.2.12.2.11 Fire Protection System Preoperational Test (SU4-FP03)

14.2.12.2.11.1 Objectives

a. To demonstrate the operating characteristics of the Fire

Protection (FP) system jockey pump, motor-driven fire

pump and the diesel-driven fire pump and verify the

operation of their associated control circuits.

b. To demonstrate the operability of the diesel oil system, including system instrumentation and controls.

14.2.12.2.11.2 Prerequisites

a. Required component testing, instrument calibration, and system flushing/cleaning are completed.
b. Required electrical power supplies and control circuits

are operational.

14.2.12.2.11.3 Test Method

a. The jockey pump, the motor-driven fire pump and the

diesel-driven fire pump are operated and operating data

are recorded.

b. The response of the motor-driven fire pump and diesel-

driven fire pump to automatic start signals are

verified.

c. With the diesel-driven fire pump operating at rated

capacity, the capacity of the diesel oil day tank is

verified.

14.2.12.2.11.4 Acceptance Criteria

a. The FP pumps operating characteristics are within design

specifications.

b. The motor-driven fire pump and the diesel-driven fire

pump automatically start upon receipt of their

associated decreasing fire protection system pressure

signal.

c. With the diesel fire pump operating at rated capacity, the capacity of the diesel oil day tank is within design

specifications.

14.2-134 Rev. 0 WOLF CREEK

d. With the diesel fire pump operating at rated capacity and upon receipt of a diesel oil day tank low level

alarm, the remaining capacity of the diesel oil day tank

is within design specifications.

14.2.12.2.12 Radwaste Building HVAC System Preoperational Test

(S-04GH01)

14.2.12.2.12.1 Objectives

a. To verify the radwaste building supply and exhaust fans'

control circuits, including automatic transfer between

exhaust fans.

b. To demonstrate the fan capacities of the radwaste building supply and exhaust fans, recycle evaporator room fan coil unit, waste evaporator room fan coil unit, control room (solidification) fan coil unit, sample

laboratory fan coil unit, ground floor fan coil unit, basement floor fan coil unit, SLWS evaporator fan coil

unit, and control room fan coil unit, and to verify that

the associated instrumentation and controls function

properly.

14.2.12.2.12.2 Prerequisites

a. Required component testing, instrument calibration, and

system air balancing are complete.

b. Required electrical power supplies and control circuits are operational.

14.2.12.2.12.3 Test Method

a. The radwaste building system fans are operated, and fan

capacities are verified.

b. Operability of the radwaste building supply and exhaust

fans' control circuits is verified.

14.2.12.2.12.4 Acceptance Criteria

a. The radwaste building system fan capacities are within

design specifications.

b. The radwaste building supply air unit will not operate

unless either radwaste exhaust fan is operating.

14.2-135 Rev. 0 WOLF CREEK

c. A low flow on the operating radwaste building exhaust fan will cause the operating fan to stop and the standby

fan to start.

14.2.12.2.13 Local Containment Leak Rate Test (SU8-GP01)

14.2.12.2.13.1 Objectives

To determine the leakage rate of the containment penetrations and the leakage

rate of the containment isolation valves.

14.2.12.2.13.2 Prerequisites

a. All containment isolation valves are closed by normal

actuation methods.

b. Associated piping is drained, and vent paths for leakage

are established.

c. Required instrument calibration is complete.

14.2.12.2.13.3 Test Method

The containment penetrations and containment isolation valves are leak tested

by performing type B and type C tests, in accordance with 10 CFR 50, Appendix

J.

14.2.12.2.13.4 Acceptance Criteria

The combined leakage from containment penetrations and containment isolation valves is within design limits.

14.2.12.2.14 Liquid Radwaste System Preoperational Test (S-

04HB01).

14.2.12.2.14.1 Objectives

a. To demonstrate the operating characteristics of the

liquid radwaste system pumps and to verify the operation

of their associated control circuits.

b. To demonstrate the operation of the liquid radwaste

system containment isolation valves, including their

response to a CIS.

c. To determine by operational test that the liquid

radwaste system containment isolation valves' closure

times are within design specifications.

14.2-136 Rev. 0 WOLF CREEK 14.2.12.2.14.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The component cooling water system is available to

provide cooling water to the reactor coolant drain tank

heat exchanger.

14.2.12.2.14.3 Test Method

a. The liquid radwaste system pumps are operated, and performance characteristics are recorded.
b. The operability of the system pump and valve control

circuits is verified.

c. The liquid radwaste system containment isolation valves

are operated under flow conditions, and operating times

are recorded.

14.2.12.2.14.4 Acceptance Criteria

a. The performance characteristics of the liquid radwaste

system pumps are within design specifications.

b. Each pump trips on receipt of a low-level signal from its respective tank.
c. The liquid radwaste system containment isolation valves

close on receipt of a CIS.

d. The liquid radwaste system containment isolation valves'

closure times are within design specifications.

e. The liquid radwaste effluent discharge valve closes on a

high process radiation signal.

14.2.12.2.15 Waste Evaporator Preoperational Test (SU4-HB02)

14.2.12.2.15.1 Objectives

To demonstrate the operability of the waste evaporator and its associated

pumps, valves, and control circuits.

14.2-137 Rev. 0 WOLF CREEK 14.2.12.2.15.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. Cooling water is available to the waste evaporator.
d. The auxiliary steam system is available to supply steam

to the waste evaporator.

e. The waste evaporator condensate tank and the primary

evaporator bottoms tank are available to receive waste evaporator effluent.

14.2.12.2.15.3 Test Method

a. The waste evaporator is operated, and performance data

is recorded.

b. With the waste evaporator in operation, a low feed inlet

pressure signal is initiated, and the evaporator is

verified to shift to the recycle mode.

c. The waste evaporator distillate pump is verified to trip

on a low evaporator condenser level.

14.2.12.2.15.4 Acceptance Criteria

a. The waste evaporator process flow is within design

specifications.

b. The waste evaporator goes into the recycle mode on low

feed inlet pressure.

c. The waste evaporator distillate pump trips on a low

evaporator condenser level.

14.2.12.2.16 Solid Waste System Preoperational Test (S-04HC01)

14.2.12.2.16.1 Objectives

a. To demonstrate the operating characteristics of the

solid waste system pumps and to verify the operation of

their associated control circuits.

14.2-138 Rev. 0 WOLF CREEK

b. To demonstrate the ability of the decant station, drumming station, cement filling station, and the

solid radwaste bridge crane to process, solidify, and

handle waste and to verify the operation of their

associated control circuits.

c. To demonstrate the ability of the dry waste compactors

to process compressible wastes and to verify the

operation of their associated control circuits.

14.2.12.2.16.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits are operable.
c. Reactor makeup water is available to provide a source of

water to the decanting station.

14.2.12.2.16.3 Test Method

a. The solid waste system pumps are operated, and the pump

operating data are recorded.

b. The system component control circuits are verified, and

the ability of the solid radwaste system to process, solidify, and handle waste is verified.

14.2.12.2.16.4. Acceptance Criteria

a. The operating characteristics of the evaporator bottoms

tank pumps (primary and secondary) are within design

specifications.

b. There are no free liquids present in the packaged waste.
c. The evaporator bottoms tank pumps (primary and

secondary) trip on their respective tank low level

signal.

14.2.12.2.17 Solid Waste Filter Handling System Preoperational

Test (S-04HC02)

14.2.12.2.17.1 Objectives

To demonstrate the ability of the solid radwaste filter handling system to

remove, transfer, and install a spent resin sluice filter assembly.

14.2-139 Rev. 0 WOLF CREEK 14.2.12.2.17.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2.12.2.17.3 Test Method

a. Operability of the solid radwaste monorail hoist and

handling cask winch and associated control circuits is

verified.

b. The ability of the solid radwaste filter handling system to remove, transfer, and install a spent resin sluice filter assembly is verified.

14.2.12.2.17.4 Acceptance Criteria

The filter handling system functions in accordance with design specifications.

14.2.12.2.18 Resin Transfer Preoperational Test (SU4-HC03)

14.2.12.2.18.1 Objectives

a. To demonstrate the ability to charge resins and

activated charcoal to those systems containing

potentially contaminated demineralizers or adsorbers.

The ability of the spent resin sluice pumps to transfer resins and charcoal from demineralizers and adsorbers is also verified.

b. To demonstrate the operating characteristics of the

spent resin sluice pumps, chemical addition metering

pumps, and chemical drain tank pumps.

c. To demonstrate the operability of system valve and pump

control circuits.

14.2.12.2.18.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2-140 Rev. 0 WOLF CREEK

c. Those systems containing potentially contaminated demineralizers and adsorbers are available to support

this test.

d. The reactor makeup water system is available to provide a source of water for resin charging.
e. A means of bulk disposal is available to receive waste

at the bulk disposal station.

14.2.12.2.18.3 Test Method

a. Resins and charcoal are charged and transferred from

selected potentially contaminated demineralizers and

adsorbers.

b. The spent resin sluice pumps, chemical addition metering

pumps, and chemical drain tank pumps are operated, and

performance characteristics are obtained.

c. The response of the spent resin sluice pumps, chemical

addition metering pumps, and the chemical drain tank

pumps to a low-level trip signal from their respective

tanks is verified.

14.2.12.2.18.4 Acceptance Criteria

a. The operating characteristics of the spent resin sluice

pumps, chemical addition metering pumps, and the

chemical drain tank pump are within design specifications.

b. The spent resin sluice pumps, chemical addition metering

pumps, and the chemical drain tank pump trip on receipt

of a low-level trip signal from their respective tanks.

14.2.12.2.19 Fire Protection System (Water) Preoperational Test

(SU4-KC01A, SU4-KC01B)

14.2.12.2.19.1 Objectives

a. To demonstrate the operability of the preaction

sprinkler system, wet-pipe sprinkler system, and the

automatic water spray system, including system

instrumentation, alarms, and interlocks.

b. To demonstrate the operability of system valves, including their response to safety signals.

14.2-141 Rev. 0 WOLF CREEK

c. To verify spray to the applicable electrical system transformers.

14.2.12.2.19.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operable.

c. The fire water pumps are available to provide a source

of water to the fire protection system headers.

14.2.12.2.19.3 Test Method

a. Response of the preaction sprinkler system, wet-pipe

sprinkler system, and automatic water spray system to

fire detection signals is verified, including the

operability of associated alarms, instrumentation, and

interlocks.

b. The fire protection system containment isolation valves

are operated under flow conditions and operating times

recorded.

c. Response of the fire protection system containment

isolation valves to a CIS is verified.

d. Spray to the applicable electrical transformers is verified.

14.2.12.2.19.4 Acceptance Criteria

a. The preaction sprinkler system, wet-pipe sprinkler

system, automatic water spray system and associated

alarms, and instrumentation and interlocks operate in

accordance with system design specifications.

b. The fire protection system containment isolation valves'

closure time is within design specifications.

c. The fire protection system containment isolation valves

close on receipt of a CIS.

d. The spray to applicable electrical transformers is

within design specifications.

14.2-142 Rev. 0 WOLF CREEK 14.2.12.2.20 Fire Protection System (Halon) Preoperational Test (S-04KC02)

14.2.12.2.20.1 Objectives

To demonstrate the operability of the halon system, including the associated

instrumentation, control circuits, and alarms.

14.2.12.2.20.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operable.

14.2.12.2.20.3 Test Method

The operability of the halon system, including the associated instrumentation

and alarms, is verified. System response to fire detection signals is also

verified.

14.2.12.2.20.4 Acceptance Criteria

The halon fire protection system operates in accordance with system design

specifications.

14.2.12.2.21 Fire Protection System Detection and Alarm

Preoperational Test (S-04KC03)

14.2.12.2.21.1 Objectives

To demonstrate the operability of the fire protection system detectors and

alarms not verified during the performance of the halon and water system

preoperational tests.

14.2.12.2.21.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operable.

14.2.12.2.21.3 Test Method

Actuation of system alarms upon receipt of fire detection signals is verified.

14.2-143 Rev. 0 WOLF CREEK 14.2.12.2.21.4 Acceptance Criteria

Fire protection system detectors and alarms operate in accordance with system

design specifications.

14.2.12.2.22 Oily Waste System Preoperational Test (S-04LE01)

14.2.12.2.22.1 Objectives

To demonstrate the sump pumps and miscellaneous condensate drain tank pumps'

operating characteristics and response to sump/tank, level signals. The

operation of system valves and associated control circuits and sump/tank level

alarms are also verified.

14.2.12.2.22.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The compressed air system is available to supply air to

system valves and pumps.

d. A water source (fire system) and a collection receptacle

(oil/water separator, main condenser) are available for

the testing of each sump/tank.

14.2.12.2.22.3 Test Method

a. The sump pumps and miscellaneous condensate drain tank

pumps are operated, and performance characteristics are

verified.

b. The response of each pump and associated alarms to sump/

tank high and low level signals is verified.

c. The operability of system air-operated valves is

verified, including the response to a process radiation

signal.

14.2.12.2.22.4 Acceptance Criteria

a. The performance characteristics of the system pumps are

within design specifications.

b. The turbine building oily waste header discharge valve

closes on a high-radiation signal.

14.2-144 Rev. 0 WOLF CREEK 14.2.12.2.23 Floor and Equipment Drain System Preoperational Test (SU4-LF01)

14.2.12.2.23.1 Objectives

To demonstrate the sump pumps and hot machine shop oil interceptor pump's

capacities and response to sump/tank level signals. The operation of system

valves, their response to safety signals, and sump/tank level alarms are also

verified.

14.2.12.2.23.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required electrical power supplies and control circuits are operational.
c. The compressed air system is available to supply air to

system valves and pumps.

d. A water source (fire system or ESW) and a collection

receptacle (holdup tank, radwaste system, etc.) are

available for the testing of each sump/tank.

14.2.12.2.23.3 Test Method

a. The sump pumps and hot machine shop oil interceptor pumps

are operated, and their capacities are verified.

b. The response of each system pump, system indication, and alarms, to sump/tank high and low level signals is

verified.

c. The operability of system air- and motor-operated valves

is verified, including their response to safety signals.

14.2.12.2.23.4 Acceptance Criteria

a. The capacities of the floor and equipment drain system

pumps are within design specifications.

b. System valves properly respond to safety injection

signals and containment isolation signals.

c. The valve response times are within design

specifications.

14.2-145 Rev. 0 WOLF CREEK 14.2.12.2.24 13.8-kV System Preoperational Test (S-04PA01)

14.2.12.2.24.1 Objectives

a. To demonstrate that the 13.8-kV busses can be energized from the startup transformer.
b. To demonstrate that automatic fast transfer of the

busses from the unit auxiliary source to the startup

source is within design specifications.

c. To demonstrate that the unit auxiliary source or startup

source feeder breakers will trip on a stuck breaker

condition.

d. To demonstrate proper operation of system instrumentation and controls.

14.2.12.2.24.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The 13.8-kV system has been energized.

14.2.12.2.24.3 Test Method

a. The 13.8-kV busses are energized from the startup transformer, and bus voltages are recorded.
b. Automatic fast transfer from the unit auxiliary source

to the startup source is verified.

c. Stuck breaker conditions are simulated, and proper

operation of the 13.8-kV auxiliary source and startup

source feeder breakers is verified.

14.2.12.2.24.4 Acceptance Criteria

a. The 13.8-kV bus voltages are within design

specifications, when energized from the startup

transformer.

b. Automatic fast transfer of the busses from the unit

auxiliary source to the startup source is within design

specifications.

14.2-146 Rev. 0 WOLF CREEK

c. The 13.8-kV auxiliary source and startup source feeder breakers trip on receipt of a stuck breaker signal.

14.2.12.2.25 4,160-V (Non-Class IE) System Preoperational Test

(S-04PB01)

14.2.12.2.25.1 Objectives

a. To demonstrate that the 4,160-V busses can be energized

from their normal and alternate sources, and to verify

the operability of supply breaker and bus tie breaker

protective interlocks.

b. To demonstrate that automatic transfer is achieved

through the tie breaker from the normal source to the alternate source in the event of an electrical fault.

c. To demonstrate proper operation of system

instrumentation and controls.

14.2.12.2.25.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The 4,160-V (non-Class IE) system has been energized.

14.2.12.2.25.3 Test Method

a. The 4,160-V non-Class IE busses are energized from their

normal and alternate source, and bus voltages are

recorded.

b. System supply breakers and bus tie breakers are

operated, and breaker interlocks are verified.

c. System electrical fault signals are simulated, and

automatic transfer is verified through the tie breaker

from the normal source to the alternate source for each

4,160-V bus.

14.2.12.2.25.4 Acceptance Criteria

a. The voltage of each 4,160-V non-Class IE bus, when

supplied from its normal source and alternate source, is

within design specifications.

14.2-147 Rev. 0 WOLF CREEK

b. System supply breaker and bus tie breaker interlocks operate in accordance with the system design.
c. Automatic transfer is achieved through the tie breaker

from the normal source to the alternate source, for each 4,160-V bus, upon receipt of an electrical fault signal.

14.2.12.2.26 480-Volt (Non-Class IE) System Preoperational Test

(S-04PG01)

14.2.12.2.26.1 Objectives

a. To demonstrate that the 480-V non-Class IE load centers

can be energized from their normal sources and alternate

sources, as applicable, and verify the operability of feeder breaker and bus tie breaker protective interlocks.

b. To demonstrate that the 480-V busses supplied by 4160-V

(Class IE) source breakers are shed on receipt of a load

shed signal.

c. To demonstrate proper operation of system

instrumentation and controls.

14.2.12.2.26.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits are operational.
c. The 480-V (non-Class IE and Class IE) systems have been

energized.

14.2.12.2.26.3 Test Method

a. The 480-V non-Class IE load centers are energized from

their normal source and alternate source, as applicable

and voltages are recorded.

b. System feeder breakers and bus tie breakers are

operated, and breaker interlocks verified.

c. A load shed signal is simulated, and the 480-V busses

supplied by the 4,160-V (Class IE) source breakers are

verified to shed.

14.2-148 Rev. 0 WOLF CREEK 14.2.12.2.26.4 Acceptance Criteria

a. The voltage for each 480-V non-Class IE load center, when supplied from its normal source and alternate

source, as applicable, is within design specifications.

b. System feeder breaker and bus tie breaker interlocks

operate in accordance with the system design.

c. The 480-V busses supplied by the 4160-V (Class IE)

source breakers shed on receipt of a load shed signal.

14.2.12.2.27 250-V DC System Preoperational Test (S-04PJ01)

14.2.12.2.27.1 Objectives To demonstrate the ability of the battery and battery chargers to provide power

to the busses. The battery chargers' ability to recharge their respective

battery is also demonstrated. Proper operation of system instrumentation and

controls is also verified.

14.2.12.2.27.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. Ventilation for the battery room is available.
d. The 250-V dc system has been energized.

14.2.12.2.27.3 Test Method

a. The battery is discharged, using a test load at the

design duty cycle discharge rate.

b. The battery is fully discharged to determine its

capacity factor.

c. The ability of each battery charger to charge the

battery to normal conditions, after the battery has

undergone a design duty cycle, while simultaneously

supplying power at a rate equivalent to the largest

motor current load is verified.

d. A load shed signal is initiated, and the battery charger

PJ31 ac supply breaker is verified to trip.

14.2-149 Rev. 0 WOLF CREEK 14.2.12.2.27.4 Acceptance Criteria

a. The battery is capable of maintaining output voltage

above the design minimum, during a design duty cycle.

b. The battery capacity factor is in accordance with design

requirements.

c. The battery chargers are able to recharge the battery to

normal conditions, after the battery has undergone a

design duty cycle, while simultaneously supplying power

at a rate equivalent to the largest motor current load.

d. Battery charger PJ31 ac supply breaker trips on receipt

of a load shed signal.

14.2.12.2.28 125-V (Non-Class IE) DC System Preoperational Test

(S-04PK01, S-04PK02)

14.2.12.2.28.1 Objectives

To demonstrate the ability of the batteries and chargers to provide power to

the busses. The battery chargers' ability to recharge their respective battery

is also demonstrated. Proper operation of system instrumentation and controls

is also verified.

14.2.12.2.28.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. Ventilation for the battery room is available.

14.2.12.2.28.3 Test Method

a. Each battery is discharged, using a test load at the

design duty cycle discharge rate.

b. Each battery is fully discharged to determine its

capacity factor.

c. The ability of each battery charger to charge its

respective battery to normal conditions, after the

battery has undergone a design duty cycle, while

simultaneously supplying power at a rate equivalent to

the design instrumentation loading.

14.2-150 Rev. 0 WOLF CREEK

d. A safety injection load shed signal is initiated, and the battery charger PK21, PK22, PK23, and PK24 supply

breaker is verified to trip.

14.2.12.2.28.4 Acceptance Criteria

a. Each battery is capable of maintaining output voltage

above the design minimum, during a design duty cycle.

b. Each battery capacity factor is in accordance with

design requirements.

c. The battery chargers are able to recharge the batteries

to normal conditions, after the battery has undergone a

design duty cycle, while simultaneously supplying power at a rate equivalent to the design load.

d. Battery charger PK21, PK22, PK23, and PK24 supply

breaker trips on receipt of a safety injection load shed

signal.

14.2.12.2.29 Instrument AC (Non-Class IE) System Preoperational

Test (S-04PN01)

14.2.12.2.29.1 Objectives

To demonstrate that the 120-V non-Class IE ac distribution panels can be fed

from their associated supply transformers. Proper operation of system

instrumentation and controls is also verified.

14.2.12.2.29.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2.12.2.29.3 Test Method

The 120-V non-Class IE ac distribution panels are energized from their

associated supply transformers, and the panel voltages are recorded.

14.2.12.2.29.4 Acceptance Criteria

Each 120-V non-Class IE ac distribution panel voltage is within design

specifications.

14.2-151 Rev. 0 WOLF CREEK 14.2.12.2.30 Emergency Lighting System Preoperational Test (S-04QD01)

14.2.12.2.30.1 Objectives

To demonstrate the capability of the emergency lighting system to provide

adequate lighting. Proper operation of system instrumentation and controls is

also verified.

14.2.12.2.30.2 Prerequisites

Required electrical power supplies and control circuits are operable.

14.2.12.2.30.3 Test Method

The ability of the emergency lighting system to provide adequate lighting is verified. The operability of associated instrumentation and control circuits

is also verified.

14.2.12.2.30.4 Acceptance Criteria

The emergency lighting system operates in accordance with system design

specifications.

14.2.12.2.31 Public Address System Preoperational Test (S-04QF01)

14.2.12.2.31.1 Objectives

To demonstrate the capability of the public address system to provide adequate

intraplant communications and to verify the operability of the evacuation alarm system.

14.2.12.2.31.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operable.

14.2.12.2.31.3 Test Method

a. The public address system is operated from all

locations, and adequate communications verified.

b. Operability of the evacuation alarm system is verified.

14.2-152 Rev. 0 WOLF CREEK 14.2.12.2.31.4 Acceptance Criteria

a. The evacuation alarm system operates in accordance with

system design specifications.

14.2.12.2.32 Heat Tracing Freeze Protection System Preoperational

Test (S-04QJ01)

14.2.12.2.32.1 Objectives

To demonstrate the ability of the freeze protection system to automatically

control the associated heat tracing circuits in accordance with system design.

The operation of system instrumentation and controls is also verified.

14.2.12.2.32.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2.12.2.32.3 Test Method

Temperature signals are varied and the energization/ deenergization of the

associated heat tracing circuits is verified.

14.2.12.2.32.4 Acceptance Criteria

The freeze protection system automatically controls the associated heat tracing circuits, in accordance with system design.

14.2.12.2.33 Secondary Sampling System Preoperational Test

(S-04RM01)

14.2.12.2.33.1 Objectives

a. To demonstrate the operating characteristics of the

steam generator blowdown sample drain tank pump, sample

chiller pump, and the condenser sample pumps, and verify

the operability of their associated control circuits.

b. To demonstrate that the system sample flows are within

design specifications.

14.2.12.2.33.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

14.2-153 Rev. 0 WOLF CREEK

b. Required electrical power supplies and control circuits are operable.
c. Plant conditions are established, and systems are

available, as necessary, to facilitate drawing samples from the sample points.

d. The steam generator blowdown system is available to

receive effluent from the steam generator blowdown

sample drain tank.

e. The closed cooling water system is available to provide

cooling water to the system sample coolers and chiller

package.

14.2.12.2.33.3 Test Method

a. The steam generator blowdown sample drain tank pump, sample chiller pump, and the condenser sample pumps are

operated, and pump performance data recorded.

Operability of their associated control circuits is also

verified.

b. System samples are obtained, and flows are recorded.

14.2.12.2.33.4 Acceptance Criteria

a. The steam generator blowdown sample drain tank pump, sample chiller pump, and condenser sample pump

performance characteristics are within design specifications.

b. Sample system flows are within design specifications.

14.2.12.2.34 Area Radiation Monitoring Preoperational Test

(S-04SD01)

14.2.12.2.34.1 Objectives

To demonstrate the operation of the area radiation monitors and to verify that

a high radiation signal at each monitor will initiate an alarm.

14.2.12.2.34.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2-154 Rev. 0 WOLF CREEK 14.2.12.2.34.3 Test Method

A calibration source is utilized to actuate the area radiation monitors, and

their operability and associated alarms are verified.

14.2.12.2.34.4 Acceptance Criteria

Each area radiation monitor actuates the associated alarms, on receipt of a

high radiation signal.

14.2.12.2.35 Seismic Monitoring Instrumentation System

Preoperational Test (S-04SG01)

14.2.12.2.35.1 Objectives

To demonstrate the operability of the seismic triggers and switches and strong motion accelerometers, including their associated alarms and recording and

playback systems.

14.2.12.2.35.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2.12.2.35.3 Test Method

A test signal is initiated, and the operability of the seismic triggers and switches and strong motion accelerometers, including their associated alarms and recording and playback systems, is verified.

14.2.12.2.35.4 Acceptance Criteria

The seismic triggers and switches and strong motion accelerometers, including

their associated alarms and recording and playback systems, operate in

accordance with system design specifications.

14.2.12.2.36 Loose Parts Monitoring System Test (SU4-SQ02).

14.2.12.2.36.1 Objective

To demonstrate the operability of the accelerometers, signal conditioning

devices and diagnostic equipment, including associated alarms and recording and

playback systems.

14.2-155 Rev. 0 WOLF CREEK 14.2.12.2.36.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. Reactor coolant system is filled with water.
d. Reactor coolant system is at normal operating

temperature and pressure with all reactor coolant pumps

running, and hot functional testing is in progress (for

those portions of the testing to be performed during hot

functional testing).

e. Reactor coolant system is at normal operating

temperature and pressure with all reactor coolant pumps

running after fuel loading during startup testing (for

those portions of the testing to be performed during

startup testing).

14.2.12.2.36.3 Test Method

a. Test signals are initiated and the operability of the

accelerometers, signal conditioners, and diagnostic

circuitry, including alarms and recording and playback

systems, is verified.

b. Channel audio outputs are also recorded during hot functional testing and after fuel loading during startup testing to obtain a record of the reactor coolant system

noise "signature."

14.2.12.2.36.4 Acceptance Criteria

The accelerometers, signal conditioners, and diagnostic circuitry, including

alarms and recording and playback systems operate to detect loose parts as

specified in USAR Section 4.4.6.4.

14.2.12.2.37 Plant Performance Test (SU8-0007)

14.2.12.2.37.1 Objectives

a. To monitor the balance-of-plant and electrical systems

under loaded conditions during hot functional and power

ascension testing. The ability of the ventilation

systems to maintain ambient temperatures within design

limits is also verified. To monitor the concrete

temperatures surrounding hot penetrations and to verify

evacuation alarm audibility in high noise areas.

14.2-156 Rev. 0 WOLF CREEK 14.2.12.2.37.2 Prerequisites

a. Required component testing, instrument calibration, and

system flushing/cleaning are complete.

b. Required HVAC systems have been balanced.
c. Required electrical power supplies and control circuits

are operational.

14.2.12.2.37.3 Test Method

This procedure does not provide a test method. It provides a monitoring and

data collection function only, with the resultant datum evaluated against

provided design values, as applicable.

14.2.12.2.37.4 Acceptance Criteria

a. Evacuation alarm audibility in high noise areas is

verified.

b. The containment coolers maintain containment temperature

within design.

Note: Each monitored point is evaluated throughout the test to verify that the

applicable system or component is functioning per design.

14.2.12.2.38 Electrical Distribution System Voltage Verification

Test (S-090023)

14.2.12.2.38.1 Objectives

To record actual loaded electrical distribution parameters during various

steady-state and transient conditions.

14.2.12.2.38.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

14.2.12.2.38.3 Test Method

The bus voltages and loadings of the electrical distribution system (down to

the Class lE 120/208 V ac system) are recorded for

14.2-157 Rev. 0 WOLF CREEK various steady state configurations. Data is also recorded during the starting of the largest Class 1E and non-Class lE motors. All monitored busses are

loaded to at least 30 percent.

14.2.12.2.38.4 Acceptance Criteria

Not applicable.

Note: The data obtained from this test procedure are used to verify electrical

system voltage analysis.

14.2.12.3 Startup Test Procedures The following sections are the test abstracts for each startup test. Table

14.2-3 provides an index of these tests.

14.2.12.3.1 Automatic Steam Generator Level Control (S-07AB01)

14.2.12.3.1.1 Objectives

a. To verify the stability of the automatic steam generator

level control following simulated transients at low

power conditions and the proper operation of the

variable speed feature of the feedwater pumps.

b. To demonstrate the performance characteristics of the steam generator feedwater pumps.

14.2.12.3.1.2 Prerequisites

a. The steam generator level control system has been

checked and calibrated.

b. Steam generator level instruments and set points have

been set and calibrated.

c. Main feedwater is operational.

14.2.12.3.1.3 Test Method

a. Induce simulated steam generator level transients to verify proper steam generator level control response.
b. Verify the variable speed features of the steam

generator feedwater pumps by manipulation of controllers

and test input signals, and verify the performance

characteristics of the steam generator feedwater pumps.

14.2-158 Rev. 0 WOLF CREEK 14.2.12.3.1.4 Acceptance Criteria

a. Automatic steam generator level control system response

must be in accordance with the vendor's technical

manual.

b. The steam generator feedwater pump's performance

characteristics are within design specifications.

14.2.12.3.2 Dynamic Automatic Steam Dump Control (SU7-AB02)

14.2.12.3.2.1 Objectives

To verify automatic operation of the T average steam dump control system, demonstrate controller setpoint adequacy, and obtain final settings for steam pressure control of the condenser dump valves.

14.2.12.3.2.2 Prerequisites

a. The reactor coolant system is at normal operating

pressure and temperature.

b. The reactor is critical.
c. The steam dump system has been checked and calibrated.
d. Main feedwater and the condenser are operational.

14.2.12.3.2.3 Test Method

a. Reactor power is increased by rod withdrawal and steam dump to condenser to demonstrate setpoint adequacy.
b. Pressure controller setpoint is increased prior to

switching to T average control, which will rapidly

modulate open condenser dump valves.

c. Simulate turbine operating conditions with reactor at

power, then simulate turbine trip, resulting in the

rapid opening of the steam dump valves.

14.2.12.3.2.4 Acceptance Criteria

The steam dump system controllers must maintain stable reactor coolant system

T average at the controllers set point with no divergent oscillations.

14.2.12.3.3 RTD Bypass Flow Measurement (S-07BB01)

14.2.12.3.3.1 Objectives

To determine the flow rate necessary to achieve the design reactor coolant

transport time in each resistance temperature detector

14.2-159 Rev. 0 WOLF CREEK (RTD) bypass loop and to measure the flow rate in each RTD bypass loop to ensure that the transport times are acceptable.

14.2.12.3.3.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The reactor core is installed, and the plant is at

normal operating temperature and pressure with all

reactor coolant pumps running.

14.2.12.3.3.3 Test Method

The flow rate necessary to achieve the design reactor coolant transport time

for each hot and cold leg bypass loop is calculated, utilizing the hot and cold

leg RTD bypass loop piping lengths. Hot and cold RTD bypass loop flow data are

recorded.

14.2.12.3.3.4 Acceptance Criteria

The flow rate in each hot and cold leg RTD bypass loop, required to achieve the

design reactor coolant transport time, is within design specifications.

14.2.12.3.4 Pressurizer Heater and Spray Capability Test

(S-07BB02)

14.2.12.3.4.1 Objectives

To determine the rate of pressure reduction caused by fully opening the

pressurizer spray valves and the rate of pressure increase from the operation

of all pressurizer heaters.

14.2.12.3.4.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The reactor core is installed with the plant in the hot

shutdown condition at normal operating temperature and

pressure with all reactor coolant pumps running.

14.2-160 Rev. 0 WOLF CREEK

d. The final setting of the continuous spray flow valves is complete.
e. The reactor coolant system is borated to the value

required for fuel loading.

f. This test is performed prior to initial criticality.

14.2.12.3.4.3 Test Method

a. With the pressurizer spray valves closed, all

pressurizer heaters are energized, and the time to reach

a 2,300 psig system pressure is measured and recorded.

b. With the pressurizer heaters deenergized, both spray valves are fully opened, and the time to reach a 2,000 psig system pressure is measured and recorded.

14.2.12.3.4.4 Acceptance Criteria

The pressurizer pressure response to the opening of the pressurizer spray

valves and to the actuation of all pressurizer heaters is within design limits.

14.2.12.3.5 Reactor Coolant System Flow Measurement (S-07BB03)

14.2.12.3.5.1 Objectives

a. To confirm, after core installation but before initial

critical operation, that reactor coolant system (RCS)

flow rate as measured by loop elbow differential pressure readings is greater than or equal to 90 percent of the thermal design flow rate.

b. To confirm during initial power operation that RCS flow

rate as computed from calorimetric data is greater than

or equal to the thermal design flow rate.

14.2.12.3.5.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The reactor core is installed, and the plant is at

normal operating temperature and pressure.

14.2-161 Rev. 0 WOLF CREEK 14.2.12.3.5.3 Test Method

a. Before critical operation, loop elbow differential

pressure readings are taken with all reactor coolant

pumps running, and RCS flow rate is calculated.

b. During initial power operation, calorimetric data are

taken from Procedure S-07SC03, "Thermal Power

Measurement and Statepoint Data Collection," and RCS

flow rate is calculated.

14.2.12.3.5.4 Acceptance Criteria

RCS flow rate by loop elbow differential pressure measurement is greater than

or equal to 90 percent of the thermal design value and by calculation from calorimetric data is greater than or equal to the thermal design value.

14.2.12.3.6 Reactor Coolant System Flow Coastdown Test (SU7-BB04)

14.2.12.3.6.1 Objectives

a. To measure the rate at which reactor coolant flow

changes, subsequent to simultaneously tripping all

reactor coolant pumps.

b. To determine that the reactor coolant system low-flow

delay time is less than or equal to the total low-flow

delay time assumed in the safety analysis for loss of

flow.

14.2.12.3.6.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The reactor core is installed, and the plant is at

normal operating temperature and pressure with all

reactor coolant pumps running.

14.2.12.3.6.3 Test Method

Flow coastdown stabilization and loss of coolant delay-time data are recorded

while tripping reactor coolant pumps.

14.2-162 Rev. 0 WOLF CREEK 14.2.12.3.6.4 Acceptance Criteria

a. The rate of change of reactor coolant flow is within

design specifications.

b. The reactor coolant system low-flow delay time is less

than or equal to the total low-flow delay time assumed

in the safety analysis for loss of flow.

14.2.12.3.7 Pressurizer Continuous Spray Flow Verification

(S-07BB05)

14.2.12.3.7.1 Objectives

To establish a setting for the pressurizer continuous spray flow valves to obtain an optimum continuous spray flow.

14.2.12.3.7.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits

are operational.

c. The reactor core is installed with the plant in the hot

shutdown condition at normal operating temperature and

pressure with all reactor coolant pumps running.

d. The reactor coolant system is borated to the value required for fuel loading.
e. This test shall be performed prior to initial

criticality.

f. The preliminary setting of the continuous spray flow

valves has been completed during hot functional testing.

14.2.12.3.7.3 Test Method

Continuous spray flow valves are adjusted to establish the optimum continuous

spray flow, and the valve throttle positions are recorded.

14.2.12.3.7.4 Acceptance Criteria

The continuous spray flow valves are throttled to establish the optimum

continuous spray flow to keep the spray line warm and minimize normal steady-

state pressurizer heater loads.

14.2-163 Rev. 0 WOLF CREEK 14.2.12.3.8 RTD/TC Cross Calibration (S-07BB06)

14.2.12.3.8.1 Objectives

a. To provide a functional checkout of the reactor coolant system resistance temperature detectors (RTDs) and

incore thermocouples and to generate isothermal cross-

calibration data for subsequent correction factors to

indicated temperatures.

NOTE This portion of the test need be performed only if the

data collected in S-03BB16, RTD/TC Cross Calibration, during hot functional testing, so warrants.

b. To provide a functional checkout of the core subcooling

monitor system including the detecting thermocouples.

14.2.12.3.8.2 Prerequisites

a. Required component testing and instrument calibration

are complete.

b. Required electrical power supplies and control circuits are operational.
c. Plant heatup, following core loading, is in progress, and all reactor coolant pumps are operating.

14.2.12.3.8.3 Test Method

a. At various temperature plateaus RTD and incore

thermocouple data are recorded. Isothermal

cross-calibration correction factors for individual

thermocouples and the installation corrections for

individual RTDs are determined.

b. At normal operating temperature, the thermocouple core

subcooling monitors' operational and programmable functions are verified, including associated alarms, displays, and printouts.

14.2.12.3.8.4 Acceptance Criteria

a. Individual RTD readings are within the design

specifications.

b. The installation corrections of the RTDs are within

design specifications.

14.2-164 Rev. 0 WOLF CREEK

c. The thermocouple core subcooling monitor alarms, displays, and printouts function in accordance with

design specifications.

14.2.12.3.9 Core Loading Instrumentation and Neutron Source Requirements (S-07SC01)

14.2.12.3.9.1 Objectives

To verify proper alignment, calibration, and neutron response of the temporary

core loading instrumentation prior to start of fuel- loading; to check the

neutron response of the nuclear instrumentation system (NIS) source range

channels prior to start of fuel-loading; and to check the neutron response of

the temporary and NIS source range instrumentation prior to resumption of fuel-

loading following any delay of 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> or more. To verify the signal to noise ratio is greater than 2.

14.2.12.3.9.2 Prerequisites

a. Hot functional testing is completed.
b. The nuclear instrumentation system is installed and

calibrated.

14.2.12.3.9.3 Test Method

a. A portable neutron source (1-5 curie), plus preshipment

equipment checkout data, is used to verify proper

alignment, calibration, and neutron response of the

temporary core-loading instrumentation.

b. A portable neutron source (1-5 curie) is used to check

the neutron response of the NIS source range detectors.

c. A portable neutron source (1-5 curie) or movement of a

source-bearing fuel element to produce the desired

change in neutron level to verify the neutron response

of the temporary and NIS source range instrumentation

prior to resumption of fuel-loading following any delay

of 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> or more.

d. Perform a statistical evaluation of 10 observations for

each channel, to verify operability of the equipment.

14.2.12.3.9.4 Acceptance Criteria

Neutron instrumentation is operational, calibrated, and indicates a

positive/negative change in count rate as the neutron level is increased and/or

decreased. The signal to noise ratio is greater than 2.

14.2-165 Rev. 0 WOLF CREEK 14.2.12.3.10 Thermal Power Measurement and Statepoint Data Collection (S-07SC03)

14.2.12.3.10.1 Objectives

To measure core thermal power and obtain data for instrumentation calibration.

14.2.12.3.10.2 Prerequisites

a. Calorimetric instrumentation is installed.
b. This test is performed at 30-percent, 50-percent, 75-

percent, 90-percent, and 100-percent power.

14.2.12.3.10.3 Test Method Collect data and calculate thermal power. Obtain statepoint data, compute the

average for each parameter measured, convert to the appropriate units, and

summarize the data for each RCS loop.

14.2.12.3.10.4 Acceptance Criteria

This test is for the collection of data.

14.2.12.3.11 Nuclear Instrumentation System Test (SU7-SE01)

14.2.12.3.11.1 Objectives

The purpose of this test is to verify that the nuclear instrumentation system

performs the required indications and control functions through the source, intermediate, and power ranges of operation prior to core loading.

14.2.12.3.11.2 Prerequisites

a. The nuclear instrumentation system is installed, calibrated, aligned, and operational for a period of at

least 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br />.

b. The plant is at ambient temperature and pressure.

14.2.12.3.11.3 Test Method

a. The source and intermediate range channels are subjected

to various test signals to verify that the appropriate

indicators alarm, illuminate, or actuate, and the source

range local and remote speakers function.

14.2-166 Rev. 0 WOLF CREEK

b. The power range channels are subjected to various test signals to observe proper meter reading and function of

the comparator and rate circuitry.

c. The high voltage circuitry of the source and intermediate range channels is tested.

14.2.12.3.11.4 Acceptance Criteria

The control and indication functions and the reactor trip set points of the

nuclear instrumentation system source, intermediate, and power range channels

have been verified.

14.2.12.3.12 Operational Alignment of Nuclear Instrumentation

(S-07SE02) 14.2.12.3.12.1 Objectives

To establish and determine voltage settings, trip settings, operational

settings, alarm settings, and overlap of channels on source range, intermediate

range, and power range instrumentation from prior to initial criticality to at

or near full reactor power.

14.2.12.3.12.2 Prerequisites

a. The nuclear instrumentation system has been aligned.
b. This test is conducted prior to criticality, during

power escalation, and at or near full power.

14.2.12.3.12.3 Test Method

a. All functions are calibrated, tested, and verified, utilizing permanently installed controls and adjustment

mechanisms.

b. Operational modes of the source range, intermediate

range, and power range channels are set for their proper

functions, as per the test instructions.

14.2.12.3.12.4 Acceptance Criteria

The overlap between the source, intermediate, and power range channels must be

at least 1-1/2 decades, and the power range channels are capable of being

adjusted to agree with the results of plant calorimetric calculations.

14.2-167 Rev. 0 WOLF CREEK 14.2.12.3.13 Axial Flux Difference Instrumentation Calibration (S-07SE03)

14.2.12.3.13.1 Objectives

To derive calibration factors for overpower, overtemperature, and

T setpoints, based on incore flux data, calorimetric data, and excore nuclear

instrumentation detector currents.

14.2.12.3.13.2 Prerequisites

a. The axial flux difference instrumentation system has

been aligned.

b. Data has been obtained from flux maps taken at 30-percent and 50-percent power.

14.2.12.3.13.3 Test Method

Collect data, as required by test instruction, at 50-percent and 75-percent power, perform FI calculations to calibration factors, and extrapolate results for use at the 100-percent power plateau.

14.2.12.3.13.4 Acceptance Criteria

Calibration factors agree with Technical Specifications.

14.2.12.3.14 Control Rod Drive Mechanism Operational Test (S-

07SF01)

14.2.12.3.14.1 Objectives

To demonstrate the proper operation of the rod drive mechanisms under both cold

and hot plant conditions and to provide verification of proper slave cycler

timing.

14.2.12.3.14.2 Prerequisites

a. The control rod drive mechanisms are installed.
b. The rod drive motor-generator sets are installed and

power is available.

c. For the control rod drive mechanism timing test, the

core is installed, rod position indication is installed, and the control rod driving mechanism cooling fans are

operational.

d. Nuclear instrumentation channels operable and operating.

14.2-168 Rev. 0 WOLF CREEK

e. A fast speed oscillograph (Visicorder or equivalent) to monitor test parameters is available.

14.2.12.3.14.3 Test Method

a. With the reactor core installed and reactor in the cold

shutdown condition, confirm that the slave cycler

devices supply operating signals to the proper CRDM

stepping magnet coils.

b. Verify proper operation of all CRDMs under both cold and

hot shutdown conditions. CRDM magnet coil currents and

audio noise signals are recorded.

14.2.12.3.14.4 Acceptance Criteria The control rod drive mechanisms conform to the requirements for proper

mechanism operation and timing as described in the magnetic control rod drive

mechanism instruction manual.

14.2.12.3.15 Rod Control System (S-07SF02)

14.2.12.3.15.1 Objectives

To demonstrate and document that the rod control system performs the required

control and indication functions just prior to initial criticality. To

demonstrate operation of the rod inhibit functions.

14.2.12.3.15.2 Prerequisites

a. The reactor coolant system is at normal operating pressure and temperature.
b. The rod control system is installed and aligned.
c. The source range nuclear instruments are operable.
d. The rods are capable of withdrawal.
e. The rod position indication system is operable.

14.2.12.3.15.3 Test Method

a. With the reactor at no load operating temperature and

pressure, and just prior to initial criticality, the

control is checked for each applicable position of the

bank selector switch for proper operation.

14.2-169 Rev. 0 WOLF CREEK

b. Status lights, alarms, and indicators are verified.

14.2.12.3.15.4 Acceptance Criteria

The control and indication functions in accordance with the rod position indication system and rod control system manuals. Rod motion is inhibited upon

application of an inhibit function.

14.2.12.3.16 Rod Drop Time Measurement (SU7-SF03)

14.2.12.3.16.1 Objectives

To determine the rod drop time of each rod cluster control assembly under no-

flow and full-flow conditions, with the reactor in the cold shutdown condition

and at normal operating temperature and pressure.

14.2.12.3.16.2 Prerequisites

a. Initial core loading is completed.
b. Rod control system is installed and tested.
c. Individual rod position indication is installed and

checked.

14.2.12.3.16.3 Test Method

Withdraw each rod cluster control assembly, interrupt the electrical power to

the associated rod drive mechanism, and measure and record the rod drop time.

This test is performed with the reactor at cold and hot conditions and at no-flow and full- flow.

14.2.12.3.16.4 Acceptance Criteria

The rod drop times are acceptable in accordance with plant technical

specifications.

14.2.12.3.17 Rod Position Indication System (SU7-SF04)

14.2.12.3.17.1 Objectives

To verify that the rod position indication system satisfactorily performs

required indication functions for each individual rod and that each rod

operates satisfactorily over its entire range of travel.

14.2-170 Rev. 0 WOLF CREEK 14.2.12.3.17.2 Prerequisites

a. Plant system conditions are established as follows:
1. Test performed at T avg <200°F, nominal RCS pressure for T avg noted 2. Test results verified at T avg nominally 557°F, RCS pressure nominally 2235 psig and at least one reactor coolant pump in service.

14.2.12.3.17.3 Test Method

a. All shutdown rod banks are fully withdrawn by bank

stopping at 18,210 and 228 steps to record the rod

position, the Digital Rod Position Indication display

(DRPI), and the group step position indication.

b. All control rod banks are fully withdrawn by bank in 24

step increments while recording rod position as

indicated by the plant control room DRPI readout, and

the group step position indication.

c. In addition, the pulse-to-analog converter chassis bank

position digital readout is recorded for all control rod

banks.

14.2.12.3.17.4 Acceptance Criteria

The rod position indication system performs the required indication functions, and each rod operates over its entire range of travel within the limits of the

rod position indication instruction manual and the plant precautions, limitations,setpoints manual, and WCGS Technical Specifications.

14.2.12.3.18 Automatic Reactor Control System (S-07SF05)

14.2.12.3.18.1 Objectives

To demonstrate the capability of the reactor control system to respond properly

to input signals and to transmit proper control signals to other plant control

systems and components.

14.2.12.3.18.2 Prerequisites

a. The reactor is at approximately 30-percent power.

14.2-171 Rev. 0 WOLF CREEK

b. Pressurizer level and pressure, steam dump, steam generator level, and main feed pump speed control

systems are in automatic.

14.2.12.3.18.3 Test Method

T average will be successively varied from the T ref set point to verify the transient recovery capabilities of the auto reactor control system.

14.2.12.3.18.4 Acceptance Criteria

a. No manual intervention should be required to bring the

plant conditions to equilibrium values following

initiation of a 6 F temperature transient.

b. T avg should return to within +

1.5 F of T ref following initiation of a 6 F temperature transient.

c. Rod motion is inhibited by application of the

appropriate inhibit inputs.

14.2.12.3.19 Incore Flux Mapping (S-07SR01, S-07SR02)

14.2.12.3.19.1 Objectives

To obtain core power and temperature profiles for evaluating core performance.

14.2.12.3.19.2 Prerequisites

a. The incore monitoring system has been functionally

tested.

b. This test is performed at low power, 30-, 50-, 75-, 90-,

and 100-percent power.

c. The reactor is stabilized prior to taking a map.

14.2.12.3.19.3 Test Method

The movable detectors are inserted into the core, data is obtained, and

thermocouples are monitored while at a stable power. The obtained data is

retained for evaluation.

14.2.12.3.19.4 Acceptance Criteria

Flux and temperature data is obtained at the various power levels.

14.2-172 Rev. 0 WOLF CREEK 14.2.12.3.20 Incore Instrumentation Test (S-07SR03, S-07SR04)

14.2.12.3.20.1 Objectives

To set up and demonstrate operation of the incore instrumentation system.

14.2.12.3.20.2 Prerequisites

a. The incore instrumentation system is installed.
b. Proper rotation and limit switch operation has been

verified.

c. Testing is performed at cold shutdown and hot standby.

14.2.12.3.20.3 Test Method

At cold shutdown a dummy cable is inserted into each thimble, and proper

rotation and limit switch operation is verified. At hot standby the detectors

are inserted into the thimbles to demonstrate performance in all operational

modes.

14.2.12.3.20.4 Acceptance Criteria

The incore instrumentation system is capable of taking a flux map.

14.2.12.3.21 Operational Alignment of Process Temperature

Instrumentation (S-07SF06)

14.2.12.3.21.1 Objectives To align T and T avg process instrumentation under isothermal conditions, prior to criticality and at power.

14.2.12.3.21.2 Prerequisites

a. This alignment is performed prior to initial criticality

and again at 75-percent power. Alignment is checked at

100-percent power.

b. All reactor coolant pumps shall be operating.

14.2.12.3.21.3 Test Method

a. Align T and Tavg per test instructions under isothermal conditions prior to criticality and at approximately 75

14.2-173 Rev. 0 WOLF CREEK percent power. Extrapolate the 75-percent power data to determine T and T avg values for the 100-percent power plateau.

b. At or near full power, check the alignment of the T and T avg channels for agreement with the results of thermal power measurement. Realign any channels, as necessary, to meet test specifications.

14.2.12.3.21.4 Acceptance Criteria

The 100 percent power indications for T and T avg channels must be within the maximum design values as specified in vendor design documents.

14.2.12.3.22 Startup Adjustments of Reactor Control System (S-07SF07)

14.2.12.3.22.1 Objectives

To obtain the optimum plant efficiency.

14.2.12.3.22.2 Prerequisites

a. The reactor coolant system is at normal operating

pressure and temperature.

b. Plant instrumentation shall have been aligned according

to Operational Alignment of Process Temperature

Instrumentation.

c. The turbine control system shall have been aligned.

14.2.12.3.22.3 Test Method

a. Obtain system temperature and steam pressure data at

steady-state conditions for zero power and at hold

points during power escalations.

b. Evaluation of these data will provide the basis for

adjustments to the reactor control system.

14.2.12.3.22.4 Acceptance Criteria

The Tavg controller must be capable of maintaining full load steam pressure

within turbine pressure limitations specified in the vendor's technical manual.

14.2-174 Rev. 0 WOLF CREEK 14.2.12.3.23 RCCA or Bank Worth Measurement at Zero Power (S-07SF08)

14.2.12.3.23.1 Objectives

To determine the differential and integral reactivity worth of a rod cluster

control bank (RCC) or an individual rod cluster control assembly (RCCA).

14.2.12.3.23.2 Prerequisites

a. The reactor is critical with the neutron flux level

within the range established for zero power physics

testing.

b. The reactor coolant system is at normal operating pressure and temperature.

14.2.12.3.23.3 Test Method

RCC and RCCA worth are validated by constant addition and/or dilution of boron

in the reactor coolant system, causing rod movement to compensate for the boron

addition and/or dilution. This rod movement will cause step changes in

reactivity which are used to compute the worths.

14.2.12.3.23.4 Acceptance Criteria

The integral reactivity worth of the RCC or RCCA over its entire range of

travel agrees with acceptance criteria given in the Nuclear Design Report

within tolerance values specified in vendor design documents.

14.2.12.3.24 RCCA or Bank Worth Measurement at Power (SU7-SF09)

14.2.12.3.24.1 Objectives

a. To measure RCCA worth for a rod ejected from the HFP rod

insertion limit position.

b. To determine in-core response resulting from a dropped

rod with all other control rods near fully withdrawn.

14.2-175 Rev. 0 WOLF CREEK 14.2.12.3.24.2 Prerequisites

Testing will be performed at 30-percent power with the reactor stable.

  • 14.2.12.3.24.3 Test Method
a. Ejected rod - Compute the change in reactivity

associated with the change in RCCA position.

b. Dropped rod - Determine the quadrant power tilt ratio

and hot channel factors by use of the in-core flux

mapping system.

14.2.12.3.24.4 Acceptance Criteria

a. Ejected rod - The rod worth of the ejected rod is within tolerance values specified in vendor design documents.
b. Dropped rod - The peaking factors are within the limits

specified in vendor design documents.

14.2.12.3.25 Reactor Systems Sampling for Core Load (S-07SJ01)

14.2.12.3.25.1 Objectives

To verify uniform boron concentration, prior to core load, in the reactor

coolant system and directly connected auxiliary systems.

14.2.12.3.25.2 Prerequisites

a. Boric acid tanks, pumps, and transfer lines are all filled with 4 percent boric acid solution.
b. Reactor coolant system is filled with reactor grade

water which has been borated to a concentration as

specified in the technical specifications.

14.2.12.3.25.3 Test Method

a. Filling and circulating the reactor coolant system with

borated water should be accomplished, utilizing normal

flow paths as much as possible.

_______________________

  • This test was performed at 50 percent power at Callaway.

Callaway has the same core and Nuclear Instrumentation System

as Wolf Creek. Wolf Creek Core parameters measured prior to

the pseudo rod drop test were compared with the corresponding

results for Callaway to verify that the plant response was the

same. This exemption was approved in a July 3, 1985 letter

from the NRC.

14.2-176 Rev. 0 WOLF CREEK

b. Collect and analyze four samples taken at equidistant depths in the reactor vessel simultaneously with one

sample from the operating residual heat removal loop to

check uniform boron concentration.

14.2.12.3.25.4 Acceptance Criteria

Boron concentration of the samples obtained from the designated sample points

must be within a 30-ppm range of values.

14.2.12.3.26 Initial Core Loading (SU7-0001)

14.2.12.3.26.1 Objectives

a. To load fuel in a controlled manner.
b. To measure boron concentration.

14.2.12.3.26.2 Prerequisites

a. Sufficient preoperational testing has been completed to

ensure the necessary equipment and attendant

instrumentation is functional.

b. Required technical specification surveillance is

completed and the necessary systems are operable.

14.2.12.3.26.3 Test Method

Instruction includes a core-loading sequence which specifies the loading in a step-by-step fashion with the appropriate data collection records.

14.2.12.3.26.4 Acceptance Criteria

A permanent record of the final as-loaded core configuration has been made, and

the configuration is consistent with the fuel assembly core loading plan.

Boron concentration is as specified in the Technical Specifications.

14.2.12.3.27 Inverse Count Rate Ratio Monitoring For Core Loading

(S-070002)

14.2.12.3.27.1 Objectives

a. To obtain nuclear monitoring data during initial core

loading.

b. To prevent criticality during core loading.

14.2-177 Rev. 0 WOLF CREEK 14.2.12.3.27.2 Prerequisites

a. Temporary and plant source range nuclear instrumentation

has been operational for a minimum of 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> to achieve

stable operation.

b. Plant is prepared for initial core loading.

14.2.12.3.27.3 Test Method

Data from the nuclear monitoring channels is used to assess the safety with

which core loading operations may be conducted. Inverse count rate ratio is

plotted and evaluated to prevent any unexpected deviation from subcriticality.

The core is monitored and maintained in a subcritical configuration throughout

the core loading.

14.2.12.3.27.4 Acceptance Criteria

The core is loaded without achieving criticality.

14.2.12.3.28 Inverse Count Rate Ratio Monitoring for Approach to

Initial Criticality (S-070003)

14.2.12.3.28.1 Objectives

a. To obtain nuclear monitoring data during initial

criticality.

b. To anticipate and determine criticality.

14.2.12.3.28.2 Prerequisites

a. Both source range and intermediate range nuclear

channels alarm, trip functions, and indicating devices

have been checked out and calibrated.

b. Both source range and intermediate range nuclear

channels have been energized a minimum of 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> to

insure stable operation.

14.2.12.3.28.3 Test Method

a. Obtain base line count rates prior to rod withdrawal and

boron dilution. After each increment of rod withdrawal, and periodically during boron dilution, count rates are

obtained, and inverse count rate ratio is evaluated.

b. Core reactivity is monitored during the approach to

criticality.

14.2-178 Rev. 0 WOLF CREEK 14.2.12.3.28.4 Acceptance Criteria

To determine criticality.

14.2.12.3.29 Initial Criticality (S-070004)

14.2.12.3.29.1 Objectives

To achieve initial criticality in a controlled manner.

14.2.12.3.29.2 Prerequisites

a. Initial core loading is completed.
b. Required technical specification surveillance is completed and the necessary systems operable.
c. Sufficient post-core loading precritical testing has

been completed to ensure the necessary equipment and

attendant instrumentation is functional.

14.2.12.3.29.3 Test Method

a. At preselected points during rod withdrawal and/or boron

dilution, data is taken and inverse count rate plots

made to enable extrapolation to be carried out to the

expected critical point.

b. Initial criticality is achieved by boron dilution or, if

desired, by withdrawing control rods.

14.2.12.3.29.4 Acceptance Criteria

The reactor is critical with the flux level established at approximately 1 x 10-8 amps on the intermediate range nuclear channels.

14.2.12.3.30 Determination of Core Power Range for Physics

Testing (S-070005)

14.2.12.3.30.1 Objectives

To determine the reactor power level at which effects from fuel heating is

detectable and to establish the range of neutron flux in which zero power

reactivity measurements are to be performed.

14.2.12.3.30.2 Prerequisites

a. The reactor is critical and stable in the intermediate

range.

14.2-179 Rev. 0 WOLF CREEK

b. Control rods are sufficiently deep in the core to allow positive reactivity insertion by rod withdrawal.
c. Reactor coolant temperature is established at a value

that minimizes the moderator temperature coefficient reactivity feedback.

14.2.12.3.30.3 Test Method

a. Withdraw control rod bank and allow the neutron flux

level to increase until nuclear heating effects are

indicated by the reactivity computer.

b. Record the reactivity computer picoammeter flux level

and, if possible, the corresponding IR channel currents at which nuclear heating occurs, to obtain zero power testing range.

14.2.12.3.30.4 Acceptance Criteria

The power level at which zero power testing is conducted is determined.

14.2.12.3.31 Boron Endpoint Determination (S-070006)

14.2.12.3.31.1 Objectives

To determine the critical reactor coolant system boron concentration

appropriate to an endpoint configuration (RCC configuration).

14.2.12.3.31.2 Prerequisites

a. The reactor is critical within the range for zero power

testing and stable.

b. The reactor coolant is at normal operating pressure and

temperature.

c. Rods are at the approximate end point configuration.

14.2.12.3.31.3 Test Method

Boron endpoints are measured by determining the boron concentration of the

reactor coolant system with the rods close to or at the desired configuration.

If not, the rods are then quickly moved to the desired configuration with no

boron adjustment. The change in reactivity is measured, and this reactivity is

converted to an equal amount of boron to yield the endpoint at that particular

rod configuration.

14.2-180 Rev. 1 WOLF CREEK 14.2.12.3.31.4 Acceptance Criteria

The results of the boron endpoint calculations meet the requirements of the

Nuclear Design Report within tolerance values specified in vendor design

documents.

14.2.12.3.32 Isothermal Temperature Coefficient Measurement

(S-070007)

14.2.12.3.32.1 Objectives

To determine isothermal temperature coefficient, then derive the moderator

temperature coefficient from the isothermal data.

14.2.12.3.32.2 Prerequisites

a. The reactor is critical within the range for zero power

testing and stable.

b. The reactor coolant is at normal operating pressure and

temperature.

c. Control rods are at the approximate end point

configuration.

14.2.12.3.32.3 Test Method

The isothermal temperature coefficient is determined by heating/cooling the

reactor coolant system at a constant rate and plotting temperature versus

reactivity. The moderator temperature coefficient may be derived from isothermal data, if desired.

14.2.12.3.32.4 Acceptance Criteria

The average of the measured values of the isothermal and, if desired, the

derived moderator temperature coefficient agrees with acceptance criteria given

in the Nuclear Design Report within tolerance values specified in vendor design

documents.

14.2.12.3.33 Power Coefficient Determination (S-070008)

14.2.12.3.33.1 Objectives

To verify the power coefficient of reactivity.

14.2.12.3.33.2 Prerequisites

a. Reactor power level, reactor coolant temperature and

pressures, and RCCA and RCC bank configuration are as

follows:

14.2-181 Rev. 1 WOLF CREEK

1. RCS pressure - nominal 2235 psig
2. RCCA, RCC bank configuration - nominally all rods

out, D at bite position

3. Reactor power level - nominally 30, 50, 75, and 90

percent RTP

4. T avg - consistent with the nominal value corresponding to the T avg program at the identified nominal power levels.
b. All subsystems which affect overall plant transient

response should be in automatic mode of operation with

the exception of the rod control system and automatic makeup. The CVCS demineralizer shall be bypassed.

14.2.12.3.33.3 Test Method

a. As generator electrical load is changed, the primary side

is permitted to freely respond without any control rod

motion.

b. The power coefficient verification factor is calculated

by measuring the change in RCS temperature and the

corresponding change in core power.

14.2.12.3.33.4 Acceptance Criteria

The average value of the measured verification factor agrees with that obtained

from design predictions of the isothermal temperature coefficient and doppler

power coefficient. This agreement is within limits given in the test

instructions.

14.2.12.3.34 Load Swing Tests (S-070009)

14.2.12.3.34.1 Objectives

To verify proper nuclear plant transient response, including automatic control

system performance, when load changes are introduced at the turbine generator.

14.2.12.3.34.2 Prerequisites

Step load changes are initiated from steady state conditions at approximately

30-, 75-, and 100-percent power.

14.2-182 Rev. 1 WOLF CREEK 14.2.12.3.34.3 Test Method

a. Manually reduce the turbine generator output as rapidly

as possible to achieve an approximate 10-percent load

decrease/increase.

b. Plant variables are recorded, along with values observed

on the normal plant instrumentation, during the load

transient for those parameters required.

14.2.12.3.34.4 Acceptance Criteria

The following acceptance criteria are to be used to determine successful test

completion. Failure to meet these criteria does not constitute a need for

stopping the test program, but correction of any deficiences should be accomplished, as required, consistent with the current plant schedule.

a. Reactor and turbine must not trip.
b. Safety injection is not initiated.
c. Neither steam generator atmospheric relief valves nor safety valves shall lift.
d. Neither pressurizer relief valves nor safety valves shall

lift.

e. No manual intervention shall be required to bring plant conditions to steady state.
f. Nuclear power overshoot (undershoot) must be less than 3

percent for load increase (decrease).

14.2.12.3.35 Large Load Reduction Test (S-070010)

14.2.12.3.35.1 Objectives

To demonstrate satisfactory plant transient response to various specified load changes, to monitor the reactor control systems during these transients, and, if necessary, optimize the reactor control system setpoints.

14.2.12.3.35.2 Prerequisites

Step load reduction changes of 50 percent are initiated from steady state

conditions at approximately 75- and 100-percent power.

14.2-183 Rev. 13 WOLF CREEK 14.2.12.3.35.3 Test Method

a. Manually reduce the turbine generator output to achieve

an approximate 50-percent load reduction.

b. Monitor plant response during the transient and record

plant variables, as required.

c. If necessary, adjust the reactor control system setpoints

until optimal response is obtained.

14.2.12.3.35.4 Acceptance Criteria

The following acceptance criteria are to be used to determine successful test

completion. Failure to meet these criteria does not constitute a need for stopping the test program, but correction of any deficiencies should be accomplished, as required, consistent with the current plant schedule.

a. Reactor and turbine must not trip.
b. Safety injection is not initiated.
c. Steam generator safety valves shall not lift.
d. Pressurizer safety valves shall not lift.
e. No manual intervention shall be required to bring plant

conditions to steady state.

14.2.12.3.36 Plant Trip From 100 Percent Power (S-070011) 14.2.12.3.36.1 Objectives

To verify the ability of the plant automatic control systems to sustain a trip

from 100 percent and to bring the plant to stable conditions following the

transient, to determine the overall response time of the hot leg resistance

temperature detectors, and to evaluate the data resulting from the trip to

determine if changes in the control system setpoints are warranted to improve

transient response based on actual plant operations.

14.2.12.3.36.2 Prerequisites

a. The rod control system, steam generator level, pressurizer pressure and level, and the steam dump system

are in the automatic control mode.

b. The plant is operating at normal steady state full power.
c. Diesel generators in standby idling condition.

14.2-184 Rev. 1 WOLF CREEK 14.2.12.3.36.3 Test Method

a. Initiate a plant trip by opening the main generator

output breaker, monitor plant response, and record plant

variables, as required.

b. If necessary, adjust the control system setpoints to

obtain optimal response.

14.2.12.3.36.4 Acceptance Criteria

The system parameters must stay within the limitations specified in the

vendor's design transient analysis document.

14.2.12.3.37 Rods Drop and Plant Trip (S-070012) 14.2.12.3.37.1 Objectives

To demonstrate that the negative rate trip circuit will trip the reactor and to

monitor plant response.

14.2.12.3.37.2 Prerequisites

a. The rod control system, steam generator level, pressurizer pressure and level, and the feedwater pump

speed control are in the automatic control mode. Steam

dump control system is in the Tavg mode.

b. The plant is operating at a steady state power of 30 to

50 percent.

c. The rod group and the selected rods to be dropped have

been identified.

14.2.12.3.37.3 Test Method

a. Drop two RCCAs from a common group which, because of

their worth and location, are the most difficult to

detect by the nuclear instrumentation system (NIS).

b. Monitor systems behavior and plant response to trip from

an intermediate power level prior to the plant trip test

from full power.

14.2.12.3.37.4 Acceptance Criteria

The following acceptance criteria are to be used to determine successful test

completion:

14.2-185 Rev. 1 WOLF CREEK

a. The reactor shall have tripped as a result of the negative rate trip.
b. All RCCAs shall release and bottom on receipt of a trip

signal.

c. The pressurizer safety valves shall not lift.
d. Steam generator safety valves shall not lift.
e. Safety injection is not initiated.

14.2.12.3.38 Shutdown and Maintenance of Hot Standby External to

the Control Room (S-070014)

14.2.12.3.38.1 Objectives

To demonstrate, using a plant procedure, that the plant can be taken from >

10 percent power to hot standby conditions, and verify that the plant can be maintained in hot standby for at least 30 minutes with a minimum shift crew, using controls and instrumentation external to the control room.

14.2.12.3.38.2 Prerequisites

a. Required component testing and instrument calibration are

complete.

b. Required electrical power supplies and control circuits

are operational.

c. The plant is at normal operating conditions at >

10 percent power.

d. The authority and responsibility of the control room

observers has been established and is specified in this procedure.

14.2.12.3.38.3 Test Method

a. The plant is taken from >

10 percent power to hot standby conditions, using a plant procedure, minimum shift crew, and controls and instrumentation external to the control

room.

b. Hot standby conditions are maintained for at least 30

minutes.

14.2-186 Rev. 1 WOLF CREEK

c. All actions performed by the control room observers is documented within this procedure for use in evaluating

their impact on the test results.

14.2.12.3.38.4 Acceptance Criteria

The plant can be taken from >

10 percent power to hot standby conditions which are maintained for >

30 minutes, using a plant procedure, minimum shift crew, and controls and instrumentation external to the control room.

14.2.12.3.39 Power Ascension Thermal Expansion and Dynamic Test (S-070015)

14.2.12.3.39.1 Objectives

a. To demonstrate during specified power ascension

transients that the systems' monitored points respond in

accordance with design.

b. To demonstrate during the heatup to full power

temperature that the systems' piping can expand without obstruction and that the expansion is in accordance with design. Also, during the subsequent cooldown to ambient

temperature, the piping returns to its cold position in

accordance with system design.

14.2.12.3.39.2 Prerequisites

a. Reference points for measurement of the systems are

established.

b. Power ascension testing is in progress.
c. All subject systems are available for the specified

dynamic operations.

d. Required instrument calibration is complete.
e. A preservice inspection of the associated piping snubbers

has been completed within 6 months.

14.2.12.3.39.3 Test Method

a. Record cold baseline data.
b. Obtain measurement data at various specified temperature

plateaus.

14.2-187 Rev. 1 WOLF CREEK

c. The systems are aligned for the specified dynamic operation.
d. The specified dynamic event of pump operation, valve

operation, etc., is initiated, and the system is monitored for response.

e. On completion of cooldown to ambient temperature, obtain

measurement data.

14.2.12.3.39.4 Acceptance Criteria

a. There shall be no evidence of blocking of the thermal

expansion of any piping or components, other than by

design.

b. The total stresses shall not exceed applicable code

limits.

c. Spring hanger movement must remain within the hot and

cold set points, snubber swing clearance remains

satisfactory., and snubbers must not become fully

retracted or expanded.

d. Piping and components must return to their baseline

position on cooldown in accordance with system design.

e. The measured thermal movement shall be within 25 percent

of the analytical value or +

0.25 inch, whichever is greater.

14.2.12.3.40 Biological Shield Testing (S-070016)

14.2.12.3.40.1 Objectives

a. To measure and record the neutron and gamma ray radiation

levels in accessible areas of the plant where radiation

levels above background are anticipated.

b. To determine locations if any, where shielding is

deficient.

c. To ensure that plant personnel are not subjected to overexposure from radiation as a result of inadequate shielding.

14.2.12.3.40.2 Prerequisites

a. Required instrument calibration is complete.

14.2-188 Rev. 1

WOLF CREEK

b. Appropriate reactor power levels are attained.

14.2.12.3.40.3 Test Method

Neutron and gamma ray surveys are conducted in each of the following reactor power level ranges.

Test  % Reactor Power Range Preoperational Shield Tests <

0 Low Power Tests 0-5

Intermediate Power Tests 5-50

High Power Tests 50-100

14.2.12.3.40.4 Acceptance Criteria

Neutron and gamma ray radiation surveys in all accessible areas of the plant

where radiation levels above background are anticipated reveal no shielding

deficiencies; or identify and implement appropriate administrative controls in

accordance with 10 CFR 20 for the areas determined to be radiation areas.

14.2.12.3.41 Loss of Heater Drain Pump Test (S-070017)*

14.2.12.3.41.1 Objectives To verify proper nuclear plant response to a loss of heater drain pump

accident.

14.2.12.3.41.2 Prerequisites

The plant is operating at steady state conditions at 90-percent power.

14.2.12.3.41.3 Test Method

The heater drain pumps are tripped and plant variables are recorded, along with

values observed on the normal plant instrumentation, during the transient for

those parameters required.

_______________________

  • This test was performed at Callaway only, with the consent of

the NRC, as Callaway and Wolf Creek have identical Heater Drain

Systems.

14.2-189 Rev. 1 WOLF CREEK 14.2.12.3.41.4 Acceptance Criteria

The following acceptance criteria are to be used to determine successful test

completion. Failure to meet these criteria does not constitute a need for

stopping the test program, but correction of any deficiencies should be accomplished as required, consistent with the current plant schedule.

a. Reactor and turbine must not trip.
b. Safety injection is not initiated.
c. Neither steam generator atmospheric relief valves nor safety valves shall lift.
d. Neither pressurizer relief valves nor safety valves shall

lift.

e. No manual intervention shall be required to bring plant conditions to steady state.

14.2.12.3.42 Calibration of Steam and Feedwater Flow

Instrumentation at Power Test (S-070018)

14.2.12.3.42.1 Objectives

a. To calibrate the steam flow transmitters against feed-

water flow.

b. To perform a cross-check verification of all signals indicating feedwater and steam flow.

14.2.12.3.42.2 Prerequisites

a. Test equipment, including transmitters, has been

calibrated for expected ranges of plant conditions.

b. The plant shall be at steady state conditions for each

power level at which testing is performed.

14.2.12.3.42.3 Test Method

At 30 and 50 percent power, perform Step a if the steam flow/ feedwater flow

mismatch alarm actuates. At 75 and 100 percent power, perform Steps a and b.

a. Verify calibration of the steam flow by comparing steam

flow signal to referenced feedwater flow.

14.2-190 Rev. 13 WOLF CREEK

b. Compare, using plots, the steam and feedwater flow values to determine if recalibration is necessary prior to the

next power escalation.

14.2.12.3.42.4 Acceptance Criteria

a. Steam flow/feedwater flow mismatch alarm does not actuate

at 30, 50, 75, and 100 percent power.

b. Steam flow indication should be within +

4 percent of feedwater flow panel indicator at 75 and 100 percent power.

c. The test feedwater flow instrument versus plant feed-water flow instrument and plant steam flow instrument

curves should be within +

2.5 percent and +

3.0 percent of their respective ideal curves at 75 and 100 percent power.

14.2.12.3.43 Natural Circulation Test (S-090024)*

14.2.12.3.43.1 Objectives

To demonstrate the length of time required to stabilize natural circulation; to

demonstrate core flow distribution during natural circulation using incore

thermocouples.

14.2.12.3.43.2 Prerequisites

a. Required low power physics testing has been completed.
b. Required instrumentation is installed and calibration

complete.

c. The plant is operating at steady state conditions at 3

percent power.

14.2.12.3.43.3 Test Method

All reactor coolant pumps are simultaneously tripped while at 3 percent rated

power. The transients are monitored and establishment of natural circulation

verified.

  • Due to similar plant design for Callaway and Wolf Creek, the

NRC allowed WCGS to use Callaway Natural Circulation test data

and pertinent results.

14.2-191 Rev. 1 WOLF CREEK 14.2.12.3.43.4 Acceptance Criteria Natural circulation has been demonstrated. The measured core T as a function of core power under natural circulation conditions is no greater than the

limiting reactor coolant system T based on design requirements.

14.2-192 Rev. 1

WOLF CREEK TABLE 14.2-1 SAFETY-RELATED PREOPERATIONAL TEST PROCEDURES Test Abstract Test Number Title USAR Section S-03AB01 Steam Dump System Preoperational Test 14.2.12.1.1

SU3-AB02 Main Steam Safety Valve Test 14.2.12.1.2

S-03AB03 Main Steam Line Isolation Valve Test 14.2.12.1.3 S-03AB04 Main Steam System Preoperational Test 14.2.12.1.4 S-03AE01 Main Feedwater System Preoperational

Test 14.2.12.1.5 S-03AE02 Steam Generator Level Control Test 14.2.12.1.6 S-03AL01 Auxiliary Feedwater Motor-Driven Pump

and Valve Preoperational Test 14.2.12.1.7 SU3-AL02 Auxiliary Feedwater Turbine-Driven Pump and Valve Preoperational Test 14.2.12.1.8

SU3-AL03 Auxiliary Feedwater Motor-Driven Pump Endurance Test 14.2.12.1.9 S-03AL04 Auxiliary Feedwater System Water

Hammer Test 14.2.12.1.10 SU3-AL05 Auxiliary Feedwater Turbine-Driven Pump Endurance Test 14.2.12.1.11

S-03BB01 Reactor Coolant Pump Initial Operation 14.2.12.1.12 SU3-BB02 PRT Cold Preoperational Test 14.2.12.1.13 SU3-BB03 RTD Bypass Flow Measurement 14.2.12.1.14

S-03BB04 Pressurizer Pressure Control Test 14.2.12.1.15 S-03BB05 Reactor Coolant System Hot Preoperational Test 14.2.12.1.16

S-03BB06 Thermal Expansion 14.2.12.1.17 d-03BB07 Pressurizer Level Control Test 14.2.12.1.18 SU3-BB08 Pressurizer Heater and Spray Capability

Test 14.2.12.1.19 SU3-BB09 Reactor Coolant System Flow Measurement Test 14.2.12.1.20

SU3-BB10 Reactor Coolant System Flow Coastdown Test 14.2.12.1.21 S-03BB11 Reactor Coolant System Hydrostatic Test 14.2.12.1.22

SU3-BB12 Pressurizer Continuous Spray Flow Verification Test 14.2.12.1.23 S-03BB13 Pressurizer Relief Valve and PRT Hot

Preoperational Test 14.2.12.1.24 S-03BB14 Reactor Coolant Loop Vibration Surveillance Test 14.2.12.1.25

SU3-BB15A Leak Detection System Preoperational Test 14.2.12.1.26 SU3-BB15B Leak Detection System Preoperational

Test 14.2.12.1.27 S-03BB16 RTD/TC Cross Calibration 14.2.12.1.28 Rev. 0 WOLF CREEK TABLE 14.2-1 (Sheet 2)

Test Number Title USAR Section S-03BG01 Chemical and Volume Control System Major Component Test 14.2.12.1.29 SU3-BG02 Seal Injection Preoperational Test 14.2.12.1.30 SU3-BG03 Charging System Preoperational Test 14.2.12.1.31 SU3-BG04 Boron Thermal Regeneration System Preoperational Test 14.2.12.1.32

SU3-BG05 Boric Acid Blending System Preopera-tional Test 14.2.12.1.33 S-03BG06 Chemical and Volume Control System

Hot Preoperational Test 14.2.12.1.34 SU3-EC01 Fuel Pool Cooling and Cleanup System Preoperational Test 14.2.12.1.35

S-03EC02 Spent Fuel Pool Leak Test 14.2.12.1.36 SU3-EF01 Essential Service Water System Pre-operational Test 14.2.12.1.37

SU3-EF02 Essential Service Water Pump Preopera-tional Test 14.2.12.1.37 S-03EG01 Component Cooling Water System Pre-

operational Test 14.2.12.1.38 SU3-EJ01 Residual Heat Removal System Cold Pre-operational Test 14.2.12.1.39

SU3-EJ02 Residual Heat Removal System Hot Preoperational Test 14.2.12.1.40 SU3-EM01 Safety Injection System Cold Pre-

operational Test 14.2.12.1.41 SU3-EM02 Safety Injection Flow Verification Test 14.2.12.1.42 SU3-EM03 Safety Injection Check Valve Test 14.2.12.1.43 SU3-EM04 Boron Injection Tank and Recirculation Pump Test 14.2.12.1.44 S-03EN01 Containment Spray System Nozzle Air Test 14.2.12.1.45 SU3-EN02 Containment Spray System Preoperational Test 14.2.12.1.46

S-03EP01 Accumulator Testing 14.2.12.1.47 SU3-FC01 Auxiliary Feedwater Pump Turbine Preoperational Test 14.2.12.1.48

SU3-GD01 Essential Service Water Pumphouse HVAC Preoperational Test 14.2.12.1.49 SU3-GF01 Miscellaneous Building HVAC System

SU3-GF02 Preoperational Tests SU3-GF03 14.2.12.1.50 S-03GG01 Fuel Building HVAC System Preoperational

Test 14.2.12.1.51 SU3-GK01 Control Building HVAC System Preopera-tional Test 14.2.12.1.52

SU3-GL01 Auxiliary Building HVAC System Pre-operational Test 14.2.12.1.53 S-03GM01 Diesel Generator Building HVAC Pre-

operational Test 14.2.12.1.54 Rev. 3 WOLF CREEK TABLE 14.2-1 (Sheet 3)

Test Number Title USAR Section SU3-GN01 Containment Cooling System Preoperational Test 14.2.12.1.55 S-03GN02 CRDM Cooling Preoperational Test 14.2.12.1.56 SU3-GP01 Integrated Containment Leak Rate Test 14.2.12.1.57 SU3-GP02 Reactor Containment Structural Integ-

rity Acceptance Test 14.2.12.1.58 S-03GS01 Post-Accident Hydrogen Removal System Preoperational Test 14.2.12.1.59

S-03GT01 Containment Purge System HVAC Pre-operational Test 14.2.12.1.60 S-03HA01 Gaseous Radwaste System Preoperational

Test 14.2.12.1.61 S-03JE01 Emergency Fuel Oil System Preoperational Test 14.2.12.1.62

SU3-KE01 Spent Fuel Pool Crane Preoperational Test 14.2.12.1.63 SU3-KE02 New Fuel Elevator Preoperational Test 14.2.12.1.64

SU3-KE03 Fuel Handling and Storage Preoperational Test 14.2.12.1.65 SU3-KE04 Fuel Transfer System Preoperational

Test 14.2.12.1.66 SU3-KE05 Refueling Machine and RCC Change Fixture Preoperational Test 14.2.12.1.67

S-03KE06 Refueling Machine Indexing Test 14.2.12.1.68 SU3-KE07 Fuel Handling System Integrated Preoperational Test 14.2.12.1.69

S-03KJ01 Diesel Generator Mechanical Preopera-tional Test 14.2.12.1.70 S-03NB01 4160-V (Class IE) System Preoperational

Test 14.2.12.1.71 S-03NE01 Diesel Generator Electrical Preopera-tional Test 14.2.12.1.72

SU3-NF01 Integrated Control Logic Test 14.2.12.1.73 S-03NF02 LOCA Sequencer Preoperational Test 14.2.12.1.74 S-03NF03 Shutdown Sequencer Preoperational Test 14.2.12.1.75

S-03NG01 480-V (Class IE) System Preoperational Test 14.2.12.1.76 SU3-NG02 480-V Class IE System (ESW) Preopera-

tional Test 14.2.12.1.77 S-03NK01 125-V (Class IE) DC System Preopera-tional Test 14.2.12.1.78

S-03NN01 Instrument AC System (Class IE) Pre-operational Test 14.2.12.1.79 SU3-SA01 Engineered Safeguards (NSSS) Preopera-

tional Test 14.2.12.1.80 Rev. 0 WOLF CREEK TABLE 14.2-1 (Sheet 4)

Test Number Title USAR Section SU3-SA02 Engineered Safeguards (BOP) Pre-operational Test 14.2.12.1.81 SU3-SA03 Engineered Safeguards Verification Test 14.2.12.1.82 S-03SB01 Reactor Protection System Logic Test 14.2.12.1.83 S-03SJ01 Primary Sampling System Preoperational Test 14.2.12.1.84

S-03SP01 Process Radiation Monitoring System Preoperational Test 14.2.12.1.85 SU3-0004 Power conversion and ECCS Systems

Thermal Expansion Test 14.2.12.1.86 S-030005 Power Conversion and ECCS Systems Dynamic Test 14.2.12.1.87

SU3-0006 HEPA Filter Test 14.2.12.1.88 S-030008 Cooldown from Hot Standby External to the Control Room 14.2.12.1.89

S-030009 Compressed Gas Accumulator Testing 14.2.12.1.90 Rev. 0 WOLF CREEK TABLE 14.2-2 NONSAFETY-RELATED PREOPERATIONAL TESTS Test Number Title USAR Section S-04AC02 Turbine Trip Test 14.2.12.2.1 S-04AC03 Turbine System Cold Test 14.2.12.2.2 S-04AD01 Condensate System Preoperational Test 14.2.12.2.3 S-04AF01 Secondary Vent and Drain System Pre-operational Test 14.2.12.2.4 S-04AQ01 Condensate and Feedwater Chemical Feed System Preoperational Test 14.2.12.2.5 S-04BL01 Reactor Makeup Water System Preopera-tional Test 14.2.12.2.6 S-04CG01 Condenser Air Removal System Pre-operational Test 14.2.12.2.7

SU4-DA01 Circulating Water System Preoperational Test 14.2.12.2.8 S-04EA01 Service Water System Preoperational Test 14.2.12.2.9 S-04EB01 Closed Cooling Water System Preopera-tional Test 14.2.12.2.10 SU4-FP03 Fire Protection System Preoperational Test 14.2.12.2.11 S-04GH01 Radwaste Building HVAC System Pre-operational Test 14.2.12.2.12 SU8-GP01 Local Containment Leak Rate Test 14.2.12.2.13 S-04HB01 Liquid Radwaste System Preoperational Test 14.2.12.2.14

SU4-HB02 Waste Evaporator Preoperational Test 14.2.12.2.15 S-04HC01 Solid Waste System Preoperational Test 14.2.12.2.16 S-04HC02 Solid Waste Filter Handling System Preoperational Test 14.2.12.2.17 SU4-HC03 Resin Transfer Preoperational Test 14.2.12.2.18 SU4-KC01A Fire Protection System (Water) Pre-

SU4-KC01B operational Test 14.2.12.2.19 S-04KC02 Fire Protection System (Halon) Pre-operational Test 14.2.12.2.20 S-04KC03 Fire Protection System Detection and Alarm Preoperational Test 14.2.12.2.21 S-04LE01 Oily Waste System Preoperational Test 14.2.12.2.22

SU4-LF01 Floor and Equipment Drain System Pre-operational Test 14.2.12.2.23 S-04PA01 13.8-kV System Preoperational Test 14.2.12.2.24

S-04PB01 4,160-V (Non-Class IE) System Pre-operational Test 14.2.12.2.25 S-04PG01 480-Volt (Non-Class IE) System Pre-

operational Test 14.2.12.2.26 Rev. 0 WOLF CREEK TABLE 14.2-2 (Sheet 2)

Test Number Title USAR Section S-04PJ01 250-V DC System Preoperational Test 14.2.12.2.27 S-04PK01 125-V (Non-Class IE) DC System Pre-

S-04PK02 operational Test 14.2.12.2.28 S-04PN01 Instrument AC (Non-Class IE) System Pre-operational Test 14.2.12.2.29 S-04QD01 Emergency Lighting System Preopera-tional Test 14.2.12.2.30 S-04QF01 Public Address System Preoperational Test 14.2.12.2.31 S-04QJ01 Heat Tracing Freeze Protection System Preoperational Test 14.2.12.2.32 S-04RM01 Secondary Sampling System Preoperational Test 14.2.12.2.33 S-04SD01 Area Radiation Monitoring Preoperational Test 14.2.12.2.34 S-04SG01 Seismic Monitoring Instrumentation System Preoperational Test 14.2.12.2.35 SU4-SQ02 Loose Parts Monitoring System Test 14.2.12.2.36 SU8-0007 Plant Performance Test 14.2.12.2.37 S-090023 Electrical Distribution System Voltage

Verification Test 14.2.12.2.38 Rev. 0 WOLF CREEK TABLE 14.2-3 INITIAL STARTUP TEST Test Number Title USAR Section S-07AB01 Automatic Steam Generator Level Control 14.2.12.3.1 SU7-AB02 Dynamic Automatic Steam Dump Control 14.2.12.3.2 S-07BB01 RTD Bypass Flow Measurement 14.2.12.3.3 S-07BB02 Pressurizer Heater and Spray Capability Test 14.2.12.3.4 S-07BB03 Reactor Coolant System Flow Measurement 14.2.12.3.5 SU7-BB04 Reactor Coolant System Flow Coastdown Test 14.2.12.3.6 S-07BB05 Pressurizer Contiuous Spray Flow Verification 14.2.12.3.7 S-07BB06 RTD/TC Cross Calibration 14.2.12.3.8

S-07SC01 Core Loading Instrumentation and Neutron Source Requirements 14.2.12.3.9 S-07SC03 Thermal Power Measurement and Statepoint Data Collection 14.2.12.3.10 SU7-SE01 Nuclear Instrumentation System Test 14.2.12.3.11 S-07SE02 Operational Alignment of Nuclear Instru-mentation 14.2.12.3.12 S-07SE03 Axial Flux Difference Instrumentation Calibration 14.2.12.3.13 S-07SF01 Control Rod Drive Mechanism Operational Test 14.2.12.3.14 S-07SF02 Rod Control System 14.2.12.3.15

SU7-SF03 Rod Drop Time Measurement 14.2.12.3.16 SU7-SF04 Rod Position Indication System 14.2.12.3.17 S-07SF05 Automatic Reactor Control System 14.2.12.3.18 S-07SR01/ Incore Flux Mapping S-07SR02 14.2.12.3.19 S-07SR03/ Incore Instrumentation Test

S-07SR04 14.2.12.3.20 S-07SF06 Operational Alignment of Process Temperature Instrumentation 14.2.12.3.21 S-07SF07 Startup Adjustments of Reactor Control System 14.2.12.3.22 S-07SF08 RCCA or Bank Worth Measurement at

Zero Power 14.2.12.3.23 SU7-SF09 RCCA or Bank Worth Measurement at Power 14.2.12.3.24

S-07SJ01 Reactor Systems Sampling for Core Load 14.2.12.3.25 SU7-0001 Initial Core Loading 14.2.12.3.26

S-070002 Inverse Count Rate Ratio Monitoring for Core Loading 14.2.12.3.27 Rev. 0 WOLF CREEK TABLE 14.2-3 (Sheet 2)

Test Number Title USAR Section S-070003 Inverse Count Rate Ratio Monitoring for Approach to Initial Criticality 14.2.12.3.28

S-070004 Initial Criticality 14.2.12.3.29 S-070005 Determination of Core Power Range for Physics Testing 14.2.12.3.30 S-070006 Boron Endpoint Determination 14.2.12.3.31 S-070007 Isothermal Temperature Coefficient Measurement 14.2.12.3.32 S-070008 Power Coefficient Determination 14.2.12.3.33 S-070009 Load Swing Tests 14.2.12.3.34 S-070010 Large Load Reduction Test 14.2.12.3.35 S-070011 Plant Trip from 100 Percent Power 14.2.12.3.36 S-070012 Rods Drop and Plant Trip 14.2.12.3.37 S-070014 Shutdown and Maintenance of Hot Standby External to the Control Room 14.2.12.3.38 S-070015 Power Ascension Thermal Expansion and Dynamic Test 14.2.12.3.39 S-070016 Biological Shield Testing 14.2.12.3.40 S-070017 Loss of Heater Drain Pump Test 14.2.12.3.41 S-070018 Calibration of Steam and Feedwater

Flow Instrumentation at Power Test 14.2.12.3.42 S-090024 Natural Circulation Test 14.2.12.3.43 Rev. 0