ML19259B372
| ML19259B372 | |
| Person / Time | |
|---|---|
| Site: | New England Power |
| Issue date: | 01/26/1979 |
| From: | Boyd R Office of Nuclear Reactor Regulation |
| To: | Harrington J NEW ENGLAND POWER CO. |
| References | |
| NUDOCS 7902090078 | |
| Download: ML19259B372 (42) | |
Text
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UNITED STATES k
NUCLEAR REGULATORY COMMISSION f \\ )Z j
WASHINGTON, D. C. 20555 w
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g, v.....f January 26, 1979 Docket No:
50-568 and 50-565 Joseph Harrington Project Manager New England Power Company 20 Turnpike Road Westborough, Massachusetts 01581
Dear Mr. Harrington:
SUBJECT:
INFORMATION RELATING TO CATEGORIZATION OF RECENT REGULATORY GUIDES BY THE REGULATORY REQUIREMENTS REVIEW COMMITTEE -
NEP NUCLEAR GENERATING STATION, UNITS NOS. 1 AND 2 We have recently advised utilities with plants in the post-CP phase of the reactor licensing process of the status of NRC staff review and use of recently-approved regulatory guides, and have indicated how these guides would be used in the Operating License review of their Final Safety Analysis Reports. Such information, while not directly applicable to you at this time, may nonetheless be useful to you for your future planning. The text of our letter to these utilities is the following:
SUBJECT:
IMPLEMENTATION OF STAFF REVIEW REQUIREMENTS - (Name of Plant) - OPERATING LICENSE REVIEW During the last several years, we have reviewed and approved several new regulatory guides and branch technical positions or other modifications to existing staff positions. Our practice is that substantive changes in staff positions be considered by the NRC's Regulatory Requirements Review Committee (RRRC) which then recommends a course of action to the Director, Office of Nuclear Reactor Regulation (NRR). The recommended action includes an implementation schedule. The Director's approval then is used by the NRR staff as review guidance on individual licensing matters. Some of these actions will affect your application.
This letter is intended to bring you up to date on these changes in staff positions so that you may consider them in your Final Safety Analysis Report (FSAR) preparation.
79020900781
. "The RRRC applies a categorization nomenclature to each of its actions.
(A copy of the summary of RRRC Meeting No. 31 concerning this categorization is attached as Enclosure 1.) Category 1 matters are those to be applied to applicati]ns in accordance with the implementation section of the publisned guide. We have enclosed lists of actions which are either Category 2 or Category 3, which are defined as follows:
Category 2: A new position whose applicability is to be determined on a case-by-case basis. You should describe the extent to which your design conforms, or you should describe an acceptabl<a alternate, or you should demonstrate why conformance is not necessary.
Category 3: Conformance or an acceptable alternative is required.
If you do not conform, or do not have an acceptable alternate, then staff-approved design revisions will be required.
"We believe that providing you with a list of the Category 2 and 3 matters approved to date will be useful in your FSAR preparation, and they will be an essential part of our operating license review. is a list of the Category 2 matters. Enclosure 3 is a list of the Catetory 3 matters.
"In addition to the RRRC categories, there also exists an NRR Category 4 list which are those matters not yet reviewed by the RRRC, but which the Director, NRR, has deemed to have sufficient attributes to warrant their being addressed and considered in ongoing reviews.
These matters will be treated like Category 2 matters until such time as they are reviewed by the RRRC, and a definite implementation program is developed. A current list of Category 4 matters is attached (Enclosure 4). These also should be considered in your FSAR.
"In some instances the items in the enclosures may not be applicable tc your application. Also, we recognize that,our application may, in some instances, already conform to the state: staff positions.
In your FSAR you should note such compliance.
"If you have any questions please lot us know."
, 3 1.
Those applicants issued an OL during the period between March 14, 1978 and a date 12 months thereafter may merely commit to meeting tne position prior to OL issuance but shall, by license condition, be required >to install all required staff-approved modifications prior to plant startup following the first scheduled refueling outage.
2.
Those applicants issued an OL beyond March 14, 1979 shall install all required staff-approved modifications prior to initial plant startup.
3.
Those applicants issued a CP, PDA, or ML during the period between March 14, 1978 and a date 6 months thereaf ter may merely commit to meeting the position but shall, by license condition, be required to amend the acplication, within 6 months of the date of issuance of the CP, PDA, or ML, to include a description of the proposed modifications and the bases for their design, and a request for staff approval.
4 Those acolicants issued a CP, PDA, or ML after September 14, 1978 Shall have staff approval of proposed modifications prior to issuance of the CP, PDA, or ML.
D.
References 1.
NUREG-0138, Staff Discussion of Fif teen Technical Issues Listed in Attachment to November 3, 1976 Memorandum from Director, NRR, to NRR Staff.
ENCL 3 (CONT)
CATEGORY 4 MATTERS A.
Regulatory Guides not categorized Issue Date Number Pevision Title 4/74 1.12 1
Instrumentation for Earthquakes 12/75 1.13 1
Spent Fuel Storage Facility Design Basis 8/75 1.14 1
Reactor Coolant Pump Flywheel Integrity 1/75 1.75 1
Physical Independence of Electric Systems 4/74 1.76 0
Design Basis Tornado for Nuclear Power Plants 9/75 1.79 1
Preoperational Testing of Emergency Core Cooling Systems for Pressurized Water Reactors 6/74 1.80 0
Preoperational Testing of Instrument Air Systems 6/74 1.82 0
Sumps for Emergency Core Cooling and Containment Spray Systems 7/75 1.83 1
Inservice Inspection of Pressurized Water Reactor Steam Generator Tubes 11/74 1.89 0
Qualification of Class IE Equipment for Nuclear Power Plants 12/74 i.93 0
Availability of Electric Power Sources 2/76 1.104 0
Overhead Crane Handling Systems for Nuclear Power Plants ENCLOSURE 4 B.
SRP Criteria Impl ementa-Applicable tion Date Branch SRP Section Title 1.
11/24/75 MTEB 5.4.2.1 BTP MTEB-5-3,. Monitoring of Secondary Side Water Chemistry in PWR Sterad Generators 2.
11/24/75 CSB 6.2.1 BTP CSB-6-1, Minimum 6.2.lA Containment Pressure Model 6.2.lB for PWR ECCS Performance 6.2.1.2 Evaluation 6.2.1.3 6.2.1.4 6.2.1.5 3.
11/24/75 CSB 6.2.5 BTP CSB-6-2, Control of Combustible Gas Concentra-tions in Containment Following a Loss-of-Coolant Accident 4.
11/24/75 CSB 6.2.3 BTP CSB-6-3, Determination of Bypass Leakage Path in Dual Containment Plants 5.
11/24/75 CSB 6.2.4
.BTP CSB-6-4, Containment Purging During Normal Plant Operations 6.
11/24/75 ASB 9.1.4 BTP ASB-9.1, Overhead Handling Systems for Nuclear Power Plants 7.
11/24/75 ASB 10.4.9 BTP ASB-10.1, Design Guidelines for Auxiliary Feedwater System Pump Drive and Power Supply Diversity for PWR's 8.
11/24/75 SEB 3.5.3 Procedures for Composite Section Local Damage Prediction (SRP Section 3.5.3, par. II.l.C)
ENCLOSURE 4 (CONT)
. Impl ementa-Applicable tion Date Branch SRP Section Title 9.
11/24/75 SEB 3.7.1 Development of Design Time History for Soil-Structure Interaction Analysis (SRP Section 3.7.1, par. II.2)
- 12. 11/24/75 SEB 3.8.1 Design and Con-truction of Concrete Containments) SRP Section 3.8.1, par. II)
- 13. 11/24/75 SEB 3.8.2 Design and Construction of Steel Containments (SRP Section 3.8.2, par. II) 14.
11/24/75 SEB 3.8.3 Structural Design Criteria for Category I Structures Inside Contairmnt (SRP Section 3.8.3, par. II)
- 15. 11/24/75 SEB 3.8.4 Structural Design Criteria for Other Seismic Category I Structures (SRP Section 3.8.4, par. II)
11/24/75 SEB 3.7 Seismic Design Requirements for 11.2 Radwaste Sysems and Their Housing 11.3 Structures (SRP Section 11.2, BTP 11.4 ETSB 11-1 par. B.v)
ENCLOSURE 4 (CONT)
. Implementa-Applicable tion Date Branch SRP Section Title
10/01/75 ASB 10.4.7 Water Hacmer for Steal Generators with Preheaters (SRP Section 10.4.7 par. I.2.b) 21.
11/24/75 AB 4.4 Thermal-Hydraulic Stability (SRP Section 4.4, par. II.5)
- 22. 11/24/75 RSB 5.2.5 Intersystem Leakage Detection (SRP Section 5.2.5 par. II.4) and R.G.1.45 23.
11/24/75 RSB 3.2.2 Main Steam Isolation valve Leakage Control System (SRP Section 10.3 par. III.3 and BTP RSB-3.2)
C.
Other Positions Implementa-Applicable tion Date Branch SRP Section Title 1.
12/1/76 SEB 3.5.3 Ductility of Reinforced Concrete and Steel Structural Elements Subjected to Impactive or Impulstve Loads 2.
8/01/76 SE:
3.7.1 Response Spectra in Vertical Direction 3.
4/01/76 SEB 3.8.1 BWR Mark III Containment Pool 3.3.2 Dynamics 4
9/01/76 SEB 3.8.4 Air Blast Loads 5.
10/01/76 SEB 3.5.3 Tornado Missile Impact 6.
6/01/77 RSB 6.3 Passive Failures During Long-Term Cooling Following LOCA ENCLOSURE 4 (CONT)
Implementa-Applicable tion Date Branch SRP Section Title 7.
9/01/77 RSB 6.3 Control doom Position Indica-tion of Manual (Handwheel) Valves in the ECCS 8.
4/01/77 RSB 15.1.5 Long-Term Recovery from Steamline Break: Operator Action to Prevent Overpressurization 9.
12/01/77 RSB 5.4.6 Pump Operability Requirements 5.4.7 6.3
- 10. 3/28/78 RSS 3.5.1 Gravity Missiles, Vessel Seal Ring Missiles Inside Containment
- 11. 1/01/77 AB 4.4 Core Thermal-Hydraulic Analysis
- 12. 1/01/78 PSB 8.3 Dcgraded Grid Voltage Conditions
- 13. 6/01/76 CSB 6.2.1.2 Asymmetric Loads on Components Located Within Containment Sub-compartments
- 14. 9/01/77 CSB 6.2.6 Containment Leak Testing Program
- 15. 1/01/77 CSB 6.2.1.4 Containment Response Due to Main Steam Line Break and Failure of MSLIV to Close
- 16. 11/01/77 ASB 3.6.1 Mair; Steam and Feedwater Pipe 3.6.2 Failures
- 17. 1/01/77 ASB 9.2.2 Design Requirements for Cooling Water to Reactor Coolant Pumps
- 18. 8/01/76 ASB 10.4.7 Cesign Guidelines for Water Hammer in Steam Generators with Top Feedring C? sign (BTP ASB-10.2)
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19.
1/01/76 ICSB 3.11 Environmental Control Systems for Safety-Related Equipment ENCLOSURE 4 (CONT)
DESCRIPTION OF POSITIONS IDENTIFIED AS NRR CATEGORY 4 MATTERS IN ENCLOSURE 4, PARAGRAPH C Ntimbering scheme corresponds to that used in Item C of Enclosure 4.
ENCLOSURE 4 (CONT)
C.l DUCTILITY OF REINFORCED CONCRETE AND STEEL STRUCTURAL ELEMENTS SUBJECTED TO IMPACTIVE OR IMPULSIVE LOADS INTRODUCTION In the evaluation of overall response of rcinforced concrete structural elements (e.g., missile barriers, columns, slabs, etc.) subjected to impactive or impulsive loads, such as impacts due to missiles, assumption of non.-linear response (i.e., ductility ratios greater than unity) of the structural elements is generally acceptable provided that the safety functions of the structural elements and those of safety-related systems and components supported or protected by the elements are maintained.
The following sumarizes specific SEB interim positions for review and acceptance of ductility ratios for reinforced concrete and steel structural elements subjected to impactive and impulsive loads.
SPECIFIC POSITIONS 1.
REINFORCED CONCRETE MEMBERS 1.1 For beams, slabs, and walls where flexure controls design, the pemissible ductility ratio ( u ) under impactive and impulsive loads should be taken as 0.05 for o-o'
_ J005 u
op 10 for p-o'
<.005 u
=
where p and o'are the ratios of tensile and compressive reinforcing as defined in ACI-318-71 Code.
1.2 If use of a ductility ratio greater than 10 (i.e.,
u> 100) is required to demonstrate design adequacy of structural elements against impactive or impulsive loads, e.g., missile impact, such a usage should be identified in the plant SAR.
Information justifying the use of this relatively high ductility value shall be provided for SEB staff review.
ENCLOSURE 4 (CONT) 1.3 For beam-coltsans, walls, and slabs carrying axial compression loads and subject to impulsive or impactive loads producing flexure, the pemissible ductility ratio in flexure should be as follows:
(a) men compression controls the design, as defined by an interaction diagram, the pemissible ductility ratio _
shall be 1.3.
(b) When the compression loads do not exceed 0.l fc 'Ag or one-third of that which would produce balanced conditions, which-ever is smaller, the pemissible ductility ratio can be as given in Secti~. 1.1.
(c) The pemissible dutility ratio shall vary linearly from 1.3 to that given in Section 1.1 for conditions between those specified in (a) and (b). (See Fig 1.)
1.4 For structural elements resisting axial compressive impulsive or impaci.ive loads only, without flexure, the pemissible axial ductility ratio shall be 1.3.
1.5 For shear carried by concrete only u = 1.0 For shear carried by concrete and stirrups or bent bars
= 1.3 u
For shear carried entirely by stirrups u
= 3.0 2.0 STRUCTURAL STEEL MEMBERS 2.1 For flexure compression and shear u
= 10. 0 2.2 For coltrans with slenderness ratio (1/r) equal to or less than 20 p
= 1.3 ENCLOSURE 4 (CONT)
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- 5. i c. y ' S o = 3'
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8[d where 1 = effective length of the member r = the least radius of gyration For columns with slenderness ratio greater than 20 u = 1.0 2.3 For members subje.ted to tension u =.5 where cu= uniform ultimate strain of the material cY = strain at yield of material C.2 RESPONSE SPECTRA IN THE VERTICAL DIRECTION Subsequent to the issuance of Regulatory Guide 1.60, the report
" Statistical Studies of Vertical and Horizontal Earthquake Spectra" was issued in January 1976 by NRC as NUREG-0003. One of the important conclusions of this report is that tile response spectrum for tertical motion can be taken as 2/3 the response spectrum for horizontal motion over the entire range of frequer.cies in the Westerr.
United States. According to Regulatory Guide 1.60, the vertical response spectrum is equal to the horizontal response spectrum between 3.5 cps and 33 cps. For the Western United States only, consistent with the latest available data in NUREG-0003, the option of taking the vertical design design response spectrum as 2/3 the horizontal response spectrum over the entire range of frecuencies will be accepted.
For other locations, the vertical response spectrum will be the same as that given in Regulatory Guide 1.60.
C.3 BWR MARK III CONTAINMENT P0OL DYNAMICS 1.
POOL SWELL a.
Bubble pressure, bulk swell and froth swell loads, drag pressure and other pool swell loads should be treated as abnormal pressure loads, P. Appropriate load combinations a
and load factors should be applied accordingly, b.
The pool swell loads and accident pressure may be combined in accordance with their actual time histories of occurrence.
ENCLOSURE 4 (CONT) 2.
SAFETY RELIEF VALVE (SRV) DISCHARGE a.
The SRV loads should be treated as live loads in all load combinations 1.5Pa where a load factor of 1.25 should be applied *.o the appropriate SRV loads.
b.
A single active failure causing one SP.V discharge must be considered in combination with the Design Basis Accident (DBA).
c.
Appropriate multiple SRV discharge should be considered in combination with the Small Break Accident (SBA) cnd Inter-mediate Break Accident (IBA).
d.
Thermal loads due to SRV discharge should be treated as TO for nomal operation and T for accident conditions.
a e.
The suppression pool liner should be designed in accordance with the ASME Boiler and Pressure Vessel Code, Division 1 Subsection NE to resist the SRV negative pressure, considering strength, buckling and low cycle fatigue.
C.4 AIR BLAST LOADS (Pa, Ta, To as defined in ACI 359-740}
The following interim position on ai-blast loadings on Nuclear Power Plant Structures should be used as guidance in evaluating analyses.
1.
An equivalent static pressure may be used for structural analysis purposes. The equivalent static pressure should be obtained from the air blast reflected pressure or the overpressure by multiplying these pressures by a factor of two. Any proposed use of a dynamic load factor less than two should be treated on a case by case basis.
Whether the reflected pressure or the overpressure is to be used for individual structural elements depends on whether an incident blast wave could strike the surface of the element.
2.
No load factor need be specified for the air blast loads, and the load combination should be:
U=0+L+B where, U is the strength capacity of a section D is dead load L is live load B is air blast load.
3.
~1astic analysis for air blast is required for concrete structures of new plants. For steel structural elements, and also for rein-forced concree elements in existing plants, some inelastic response may be pem
.ed with appropriate limits on ductility ratios.
ENCLOSURE 4 (CONT) 4.
Air blast generated ground shock and air blast wind pressure may be ignored. Air blast generated missiles may be imptrtant in situations where explosions are postulated to occur in vessels which may fragment.
5.
Overturning and sliding stability should be assessed _ by multiplying the structure's full projected area by the equivalent static pressure and assuming only the blast side of the structure is loaded. Justification for reducing the average equivalent static pressure on curved surfaces should be considered on a case by case basis.
6.
Internal supporting structures should also be analyzed for the effects of air blast to determine their ability to carry loads applied directly to exterior panels and slabs. Moreover.in vented structures, interior structures may requira analysis even if they do not support exterior structures.
7.
The equivalent static pressure should be considered as potentially acting both inward and outward.
C.5 TORNADO MISSILE PROTECTION As an interim measure,the minimum concrete wall and roof thickness for tornado missile protection will be as follcws:
Wall Thickness Roof Thickness Concrete Strength (psi)
(inches)
(inches) 3000 27 24 Region I 4000 24 21 5000 21 18 3000 24 21 Region II 4000 21 18 5000 19 16 3000 21 18 Region III 4000 18 16 5000 16 14 These thicknesses are for protection against local effects only. Designers must establish independently the thickness requirements for overall structura response. Reinforcing steel should satisfy the provisions of Appendix C, ACI 349 (that is,.2% minimum, EWEF). The regions are described in Regulatory Guide 1.76.
ENCLOSURE 4 (CONT)
C.6 PASSIVE ECCS FAILURES DURING LONG-TERM COOLING FOLLOWING A LOCA Passive failures in the ECCS, having leak rates equal to or less than those frum the sudden failure of a pump seal and which may occur during the long-term cooling period following a postulated LOCA should be con-7 sidered. To mitigate the effects of such leaks, a leak detection system having design features and bases as described below should be included in the plant design.
The leak detection system should include detectors and alams which would alert the operator of passive ECCS leaks in sufficient time so that appro-priate diagnostic and corrective actions may be taken on a timely basis.
The diagnostic and corrective actions would include the identification and isolation of the faulted ECCS line before the performance of more than one subsystem is degraded. The design bases of the leak detection system should include:
(1)
Identification and justification of the maximum leak rate; (2) Maximum allowable time for operator action and justification therefor; (3) Dec.ostration that the letk detection system is sensitive enough to initiate and alarm on a timely basis, i.e., with sufficient lead time to allow the operator to identify and isolate the fauited line before the leak can create undesireable consequences such as flooding of re-dundant equipment.
The minimum time to be considered is 30 minutes; (4) Demonstration that the leak detection system can identify the faulted ECCS train and that the leak cat. be isolated; and (5) Alarms that confom with the criteria specified for the control room alarms and a leak detection system that conforms with the require-ments of IEEE-279, except that the single failure criterion need not be imposed.
C.7 CONTROL ROOM POSITION INDICATION OF MANUAL (HANDWHEEL) VALVES Regulatory Guide 1.47 spectiles, automatic position indication of each bypass or deliberately induced inoperable condition if the following three conditions are met:
(1) The byoass or intoerable condition affects a system that is designed to perform an automatic safety function.
ENCLOSURE 4 (CONT)
4 (2)
The bypass or inoperable condition can reasonably be expected to occur more frequently than once per year, (3)
The bypass or inoperable condition is expected to occur when the system is normally required to operate.
Revision one of the Standard Review Plan in Section 6.3 requires conformance with Regulatory Guide 1.47 with the intent being that any manual (handwheel) valve which could jeopardize the operation of the ECCS, if inadvertently left in the wrong position, must have position indication in the control room.
In the PDA extension reviews it is 'mportant to confirm that standard designs include this design feature.
Most standard designs do but this matter was probably not speciffcally addressed in some of the first PDA reviews.
C.8 LONG-TERM RECOVERY FROM STEAM LINE BREAK - OPERATOR ACTION TO PREVENT OVERPRE55URIZATION (PWR)
A steam line break causes cooldown of the primary system, shrinkage of RCS inventory and depletion of pressurizer fluid. Subsequent to plant trip, ECCS actuation, and main steam system isolation, the RCS inven-tory increases and expands, refilling the pressurizer. Without operator action, rerlenishment of RCS inventory by the ECCS and expansion at low temperatura could repressurize the reactor to an unacceptable pressure-temperature region thereby compromising reactor vessel integrity. Anal-yses are required to show that following a main eteam line break that (i) no additional fuel failures result from the acc.* dent, and (11) the pressures following the initiation of the break will not compronise the integrity of the reactor coolant pressure boundary giving due considera-tion to the changes in coolant and material temperatures.
The analyses should be based on the assumption that operator action will not be taken until ten minutes after initiation of the ECCS.
C.9 PUMP OPERABILITY RE0VIREMENTS In some reviews, the staff has found reasonable doubt that some types of engineered safety feature pumps would continue to perform their safety function in the long term following an accident.
In such instances there has been followup, including pump redesign in some cases, to assure that long term performance could be met. The following kinds of infor-mation may be sought on a case-by-case basis where such doubt arises.
a.
Describe the tests performed to demonstrate that the pumps are capable of operating for extended periods under post-LOCA conditions, including the effects of debris. Discuss the damage to pump seals caused by debris over an extended period of operation.
ENCLOSURE 4 (CONT) b.
Provide detailed diagrams of all water cooled seals and compo-nents in the pumps.
Provide a description of the composition of the pump shaft c.
seals and the shafts. Provide an evaluation of loss.of shaft seals.
d.
Discuss how debris and post-LOCA environmental conditions were factored into the specifications and design of the pump.
C.10 GRAVITY MISSILES, VESSEL SEAL RING MISSILES INSIDE CONTAINMENT Safety related systems should be protected against loss of fcnction due to internal missiles from sources such as these associated with pressurized components and rotating equipment. Such sources would include but not be limited to retaining bolts, control rod drive assemblien, the vessel seal ring, valve bonnets, and valve stems. A description of the methods used to afford protection against such potential missiles, including the bases therefor, should be provided (e.g., preferential orientation of the poten-tial missile sources, missile barriers, physical separation of redundant safety systems and component:). An analysis of the effects of such poten-tial missiles on safety related systems, including metastably supported equiptrent which could fall upon impingement, should also be provided.
ENCLOSURE 4 (CONT)
9 C.ll CORE THERMAL-HYDRAULIC ANALYSES In evaluating the themal-hydraulic perfomance of the reactor core the following additional areas should be addressed:
1.
The effect of radial pressure gradients at the exit.of open lattice cores.
2.
The effect of radial pressure gradients in the upper plenum.
3.
The effect of fuel rod bowing.
In addition,a commitment to perfom tests to verify the transient analysis methods and codes is required.
C.12 DEGRADED GRID VOLTAGE CONDITIONS As a result of the Millstone Unit Number 2 low grid voltage occurrence, the staff has developed additional requirements concerning (a) sustained degraded voltage conditions at the offsite power source, and (b) inter-action of the offsite and onsite emergency power systems. These additional rewirements are defined in the following staff position.
1.
We require that a second level of voltage protection for the onsite power system be provided and that this second level of voltage pro-tection satisfy the following requirements:
a) The selection of voltage and time set points shall be detemined from an analysis of the voltage requirements of the safety-related loads at all onsite systen distribution levels; b) The voltage protection shall include coincidence logic to preclude spurious trips of the offsite power source; ENCLOSUhE 4 (CONT) c) The time delay selected shall be based on the following conditions:
(i)
The allowable time delay, including margin, shall not exceed the maximum time delay that is assumed in the SAR accident analyses; (ii) The time delay shall minimize the effect of short duration disturbances from reducing the availability of the offsite power source (s); and (iii) The allowable time duration of a degraded voltage condition at all distribution system levels shall not result in failure of safety systems or components; (iv) The voltage sensors shall automatically initiate the disconnection of offsite power sources whenever the voltage set point and time delay limits have been exceeded; (v)
The voltage sensors shall be designed to satisfy the applicable requirements of IEEE Std. 279-1971 " Criteria for Protection Systems for Nuclear Power Generating Stations"; and (vi) The Technical Specifications shall include limiting conditions for operation, surveillance requirements, trip set points with minimum and maximum limits, and allowable values for the second-level voltage protection sensors and associated time delay devices.
2.
We require that the system design automatically prevent Icad shedding of the emergency buses once the onsite sources are supplying power to all sequenced loads on the emergency buses.
The design shall also include the capability of the load shedding feature to be automatically reinstated if the onsite source supply breakers are tripped. The automatic bypass and reinstatement feature shall be verified during the periodic testing identified-in Item 3 of this position.
3.
We require that the Technical Specifications include a test require-ment to demonstrate the full functional operability and independence of the onsite power sources at least once per 18 months during shut-down. The Technical Specifications shall include a raquirement for (a) simulating loss of offsite power; (b) simulating loss tests:
of offsite power in conjunction with a safety injection actuation signal; and (c) simulating interruption and subsequent reconnection of onsite power sources to their respective buses.
ENCLOSURE 4 (CONT) 4 The voltage levels at the safety-related buses should be optimized for the full load and minimum load conditions that are expected throughout the anticipated range of voltage variations of the offsite power source by appropriate adjust--
ment of the voltage tap settings of the intervening transfamers.
We require that the adequacy of the design in this regard be verified by actual measurement, and by correlation-of measured values with analysis results.
C.13 ASYMMETRIC LOADS ON C090NENTS LOCATED WITHIN CONTAINMENT SUBCOMPARTMENTS In the unlikely event of a pipe rupture inside a major component sub-compartment, the initial blowdown transient would lead to pressure loadings on both the structure and the enclosed component (s). The staff's generic Category A Task Action Plan A-2 is designed to develop generic resolutions for this matter. Our present schedule calls for completing A-2 for PWR's during the first quarter,1979. Pending completion of A-2, the staff is implementing the following program:
- 1. For PWRs at the CP/PDA stage of review, the staff requires appli-cants to connit to address the safety issue as part of their appli-cation for an operating license.
2.
For PWRs at the OL/FDA stage of review, the staff requires case-by-case analyses, including implementation of any indicated corrective measusres prior to the issuance of an operating license.
3.
For BWRs, for which this issue is expected to be of lesser safety significance, the asymmetric loading conditions will be evaluated on a case-specific basis prior to the issuance of an operating license.
For those cases which analyses are required, we request the perfomance of a subcompartment, multi-node pressure response analysis of the pressure transient resulting from postulated hot-leg and cold-leg (pump suction and discharge) reactor coolant system pipe ruptures within the reactor cavity, pipe penetrations, and steam generator compartments. Provide similar analyses for the pressurizcr surge and spray lines, and other high energy lines located in containment compartments that may be subject to pressurization. Show how the results of these analyses ara used in the design of structures and component supports.
ENCLOSURE 4 (CONT)
C.14 JONTAINMENT LEAK TESTING PROGRAM To avoid difficulties experienced in this area in recent OL reviews, the staff has increased its scope of inquiry at the CP/PDA stage of review. For this purpose, the following information with regard to the containment leak testing program should be supplied.
Those systems that will remain fluid filled for the Type A test a.
should be identified and justification given.
b.
Show the design provisions that will pemit the personnel air-lock door seals and the entire air lock to be tested.
For each penetration,i.e., fluid system piping, instrument, c.
electrical, and equipment and personnel access penerations, identify the Type B and/or Type C local leak testing that will be done.
d.
Verify that containment penetrations fitted w:th expansion bellows will be tested at Pa.
Identify any penetration fitted with expansion bellows that does not have the design capability for Type B testing and provide justification.
C.15 CONTAINMENT RESPONSE DUE TO MAIN STEAM LINE BREAK AND MSLIV FAILURE In recent CP and OL application reviews, the results of analyses for a postulated main steam line break accident (MSLB) for designs utilizing pressurized water reactors with conventional containments show that the peak calculated containment temperature can exceed for a short time period the environmental qualification temperature-time envelope for safetv related instruments and components. This matter was also discussed in Issue No.1 of NUREG-0138 and Issue No. 25 of NUREG-0153. The signifiance of the matter is that it could result in a requirement for requalifying safety-related equipment to higher time-temperature envelopes.
The staff's ge.neric Category A Task Action Plans A-21 and A-24 are designed to develop gereric resolutions fcr these matters. The presently scheduled completion dates for A-El and A-24 (Short Tem Portion) are first quarter,1979 and fourth quarter,1978, respectively.
Pending completion of A-21 and A-24, some interim guidance will be used as detailed below.
We have developed and are implementing a plan in which all applicants for construction pemits and operating licenses and those already issued con-struction pemits must provide information to establish a conservative temperature-time envelope.
ENCLOSUPE 4 (CONT)
. Therefore, describe and justify the analytical model used to conservatively detemine the maximum containment temperature and pressure for a spectrum of postulated main steam line breaks for various reactor power levels.
Include the following in the discussion.
(1) Provide single active failure analyses which specifically identify those safety grade systems and components relied upon to limit the mass and energy release and containment pressure /
temperature response. The single failure analyses should include, but not necessarily be limited to: main steam and connected systems isolation; feedwater auxiliary feedwater, and connected systems isolation; feedwater, condensate, and auxiliary feedwater pumo trip, and auxiliary feedwater run-out control system; the loss of or availability of offsite power; diesel failure when loss of offsite power is evaluated; and partial loss of containment cooling systems.
(2) Discuss and justify the assumptions made regarding the time at which active containment heat removal systems become effective.
(3) Discuss and justify the heat transfer correlation (s) (e.g., Tagami, Uchida) used to calculate the heat transfer from the containment atmosphere to the passive heat sinks, and provide a plot of the heat transfer ccefficient versus time for the most severe steac line break accident analyzed.
(4) Specify and justify the temperature used in the calculation of condensing heat transfer to the passive heat sinks; i.e.,
specify whether the saturation temperature corresponding to the partial pressure of vapor, or the atmosphere temperature (which may be superheated)was used.
(5) Discuss and justify the analytical model including the themodynamic equations used tc account for the removal of the condensed mass from the containment atmosphere due to condensing heat transfer to the passive heat sinks; (6) Provide a table of the peak values of containment atmosphere temperature and pressure for the spectrum of break areas and power levels analyzed; (7) For the case which results n the maximum containment atmosphere temperature, graphically sh,w the containment atmosphere temperature, the containmeni. liner temperature, and the containment concrete temperature as a function of time. Compare the calculated cor,tain-ment atmosphere temperature response to the temperature profile used in the environmental qualification program for those safety related instruments and mechanical components needed to mitigate the consequences of the assumed main steam line break and effect safe reactor shutdown; ENCLOSURE 4 (CONT)
. (8) For the case which results in maximum containment atmosphere pressure, graphically show the containment pressure as a function of time; and (9) For the case which results in the maximum containment atmosphere pressure and temperature, provide the mass and energy release data in tabular form.
In order to demonstrate that safety-related equipment has been adequately qualified as described above, provide the following information regard-ing its environmental qualification.
(1) Provide a comprehensive list of equipment required to be operational in the event of a main steamline break (MSLB) accident. The list should include, but not necessarily be limited to, the following safety related equipment:
(a) Electrical containment penetrations; (b) Pressure transmitters; (c) Containment isolation valves; (d) Electrical power cables; (e) Electrical instrumentation cable; and (f) Level transmitters.
Describe the qualification testing that was, or will be, done on this equipment.
Include a discussion of the test environment, namely, the temperature, pressure, moisture content, and chemical spray, as a function of time.
(2)
It is our position that the thermal analysis of safety related equipment which may be exposed to the containment atmosphere following a main steam line break accident should be based on the following:
(a) A condensir.g heat transfer coefficient based on the recommendations in Branch Technical Position CSB 6-1,
" Minimum Containment Pressure Model for PWR ECCS Performance Evaluation,"should be used.
(b) A convective heat transfer coefficient should be used when the condensing heat flux is calculated to be less than the convective heat flux. During the blowdown period it is appropriate to use a conservatively evaluated forced convection hed. transfer correlation. For example, ENCLOSURE 4 (CONT)
. Nu = C(Re)
Where Nu = Nusselt No.
Re = Reynolds No.
C
= empirical constants dependent on geometry and Reynolds No.
Since the Reynolds number is dependent on velocity, it is necessary to evaluate the forced flow currents which will be generated by the steam generaar blowdown. The CVTR experiments provide limited data in this regard. Convective currents of from 10 ft/see to 30 ft/sec were measured locally. We reconnend that the CVTR test results be extrapolated conservatively to obtain forced flow currents to detemine the convective heat transfer coefficient during the blowdown period. After the blowdown has ceased or been reduced to a negligibly low value, a natural convection heat transfer cor elation is acceptable.
(3) For each component where themal analysis is done in conjunction with an environmental test at a temperature lower than the peak calculated temperature following a main steam line break accident compare the test themal response of the component with the accide,nt themal analysis of the component. Provide the basis by which the component themal response was developed from the environmental qualification test program. For instance, graphically show the themoccuple data and discuss the themoccuple locations, method of attachment, and perfomance characteristics, or provide a detailed discussion of the analytical model used to evaluate the component thermal response during the test. This evaluation should be perfomed for the potential points of failure such as thin cross-sections and temperature sensitive parts where themal stressing, temperature-related degradation, steam or chemical interaction at elevated temperatures, or other themal eff ects could result in the failure of the component mechanically or electrically.
If the component themal response comparison results in the prediction of a more severe themal transient for 'he accident conditions than for the qualification test, provide justification that the affected component will perfom its intended function during a MSLB accident, or provide protection for the component whch would appropriately limit the themal effects.
ENCLOSURE 4 (CONT)
. C.16 ENVIRONMENTAL EFFECT OF PIPE FAILURES Identify the " break exclusion" regions of the main steam and feedwater lines. Compartments that contain break exclusion regions of main steam and feedwater lines and any safety related equipment in these compartments should be designed to with-stand the environmental effects (pressure, temperature, humidity and flooding) of a crack with a break area equal to the cross sectional area of the ' break excluded' pipe.
C.17 DESIGN REQUIREMENTS FOR COOLING WATER TO REACTOR COOLANT PUMPS Demonstrate that the reactor coolant system (RCS) pump seal injection flow will be automatically maintained for all transients and accidents or that enough, time and information are availahla to par-'it corrective action by an operator.
We have established the following criteria for that portion of the component cooling water (CCW) system which interf4ces with the reactor coolant pumps to supply cooling water to pump seals and bearings during normal operation, anticipated transients, and accidents.
- 1. A single active failure in the component cooling water system shall not result in fuel damage or a breach of the reactor coolant pressure boundary (RCPB) caused by an extended loss of cooling to one or more pumps. Single active failures include operator error, spurious actuation of : rotor-operated valves, and loss of CCW pumps.
- 2. A pipe crack or other accident (unanticipated occurrence) shall not result in either a breach of the RCPB or excessive fuel damage when an extended loss of cooling to two or more RC pumps occurs. A single active falere shall be considered when evaluating the consequences of this accident. Moderate leakage cracks should be detemined in accordance with Brar.ch Technical Position ASB 3-1.
In order to meet the criteria established above, an NSSS inter-f ace requirement should be imposed on the balance-of-plant CCW system that provides cooling water to the RC pump seals and motor and pump bearings, so that the system will meet the following con-ditions:
ENCLOSURE 4 (CONT)
. 1.
That portion of the component cooling water (CCW) system which supplies cooling water to the reactor coolant pumps and motors may be designed to non-seismic Category I requirements and Quality Group D if it can be demonstrated that the reactor coolant pumps will operate without component cooling water for at least 30 minutes without loss of function or the need for operator pro-tective action. In addition, safety grade instrumentation including alams should be provided to detect the loss.of component cooling water to the reactor coolant pumps and motors, and to notify the operator in the control room. The entire instrumentation system, including audible and visual alams, should meet the requirements of IEEE Std 279-1971.
If it is not demonstrated that the reactor coolant pumps and motors will operate at least 30 minutes without loss of function or operator protective action, then the design of the CCW sys tem must meet the following requirements:
1.
Safety grade instrumentation consistent with the criteria for the reactor protection system shall be provided to initiate automatic protection of the plant. For this case, the component cooling water supply to the seals and pump and motor bearings may be designed to non-seismic Ca tegory I require-ments and Quality Group D; or 2.
The component cooling water supply to the pumps and motors shall be capable of withstanding a single active failure or a moderate energy line crack as defined in our Branch Technical Position APCSB 3-1 and be designed to seismic Catecary I, Quality Group D and ASME Section III, Class 3 requirements.
The reactor coolant (RC) pumps and motors are within t.1e NSSS scope of design. Therefore, in order to demonstrate that an RC pump design can operate with loss of component cooling water for at least 30 minutes without loss of function er the need for operator action, the following must be provided:
1.
A detailed description of the events following the loss of component cooling water to the RC pumps and an analysis demon-strating that no consequences important to safety may result from this event.
Include a discussion of the effect that the loss of cooling water to the seal coolers has on the RC pump seals. Show that the loss of cooling water does not result in a LOCA due to seal failure.
ENCLOSURE 4 (CONT)
. ?.
A detailed analysis to show that loss of cooling water to the RC pumps and motors will not cause a loss of the flow coastdown characteristics or cause seizure of the pumps, assuming no administrative action is taken. The response should include a detailed description of the calculation procedure including:
a.
The equations used.
b.
The parameters used in the equations, such as the design parameters for the motor bearings, motor, pump and any other equipment entering into the calculations, and material property values for the oil and metal parts.
c.
A discussion of the effects of possible variations in part dimensions and material properties, such as bearing clearance tolerances and misalignment.
d.
A description of the cooling and lubricating systems (with appropriate figures) associated with the RC pump and motor and their design criteria and standards.
e.
Information to verify the applicability of the ecuations and material properties chosen for the analysis (i.e.,
references should be listed, and if empirical relations are used, provide a comparison of their range of appli-cation to the range used in the analysis).
Should an analysis be provided to demonstrate that loss of component cooling water to the RC pumps and motor assembly is acceptable, we will require certain modifications to the plant Technical Specifications and an RC pump test conducted under operating condtions and with component cooling water terminated for a specified period of time to verify the analysis.
C.18 WATER HAMMER IN STEAM GENERATORS WITH TCP FEEDRING DESIGN Events such as damage to the feedwater system piring at Indian Po'nt Unit No. 2, November 13, 1973, and at other plants, could originate as a consequence of uncovering of the feedwater sparger in the steam generator or uncovering of the steam generator feedwater inlet nozzles. Subsequent events may in turn lead to the generation of a pressure wave that is propagated through the pipes and could result in unacceptable 6. mage.
ENCLOSURE 4 (CONT)
. For CP/PDA and OL/FDA applications, provide the following for steam generators utilizing top feed:
1.
Grevent or delay water draining from the feedring following a drop in steam generator water level by means such as,,J-Tubes; 2.
Minimize the volume of feedwater piping external to the steam generator whch could pocket steam using the shortest possible (iess than seven feet) horizontal run of inlet piping to the steam generater feedring; and 3.
Perform tests acceptable to the staff to verify that unacceptable feed-water hamer will not occur using the plant operating procedures for normal and emergency restoration of steam generator water level following loss of nomal feedwater and possible draining of the feedring. Provide the procedures for these tests for staff approval before conducting the tests.
Furthemore, we request that the following be provided:
a.
Describe normal operating occurrences of transients that could cause the water level in the steam generator to drop below the sparger or nozzles to cause uncovering and allow steam to enter the sparger and f2edwater piping.
b.
Describe your criteria or show by isometric diagrace, the routing of the feedwater piping from the steam generators outwards to beyond the containment structure up to the outer isolation valve and restraint.
c.
Describe any analysis on the piping system including any forcing functions that will be performed or the results of tes; programs to verify that,either uncovering of feedwater lines could not occur or that, if it dia occur, unacceptable damage such as the experience at the Indian Point Unit No. 2 facility would not result with your design.
ENCLO URE 4 (CONT)
S
C.19 ENVIRONMENTAL CONTROL SYSTEMS FOR SAFETY RELATED E0llIpMENT Most plant areas that contain safety related equipment depend on the continuous operation of environmental control systems to maintain the environment in those areas within the range of environmentai qualification of the safety related equipment installed in those areas. It appears that there are no requireme'nts for maintaining these environmental control systems in operation while the plant is shutdown or in hot standby conditions. During periods when these environmental control systems are shutdown, the safety related equipment could be exposed to environmental conditions for which it has not been qualified. Therefore, the safety related equipment shoeld be qualified to the extreme environmental conditions that could occur when the control equipment is shutdown or thase environmental control systems should operate continuousiy to maintain the environmental conditions within the qualification limits of the safety related equipment. In the second case an environmental monitoring system that will alarm when the environmental conditions exceed those for which safety related equipment is qualified shall be provided. This environmental monitoring system shall (1) be of high quality, (2) be periodically tested and calibrated to verify its continued functioning, (3) be energized from continuous power sources, and (4) provide a cantinuous record of tne environmental parameters during the time the environmental conditions exceed the ncreal limits.
ENCLOSURE 4 (CONT)
Lee V. Gossick 3.
The Committee reviewed the proposed Regulatory Guide 1.XX:
I!4STRU 4EtiT SPAtlS AllD SETPOI:lTS and recomended approval subject to the following comment:
Paragraph 5 of Section C (page 4 of the proposed Guide) should be reworded in light of Committee comments, to the satisfaccion of the Director, Office of Standards Developnent.
This guide was characterized by the Comnittee as Category 1 - no backfit.
4.
The Committee reviewed Proposed Regulatory Guide 1.97.
If1STRU:'.EllTATI0t! FOR LIGHT UATER COOLED f:UCLEAR PO'.lER PLAT'TS TO ASSESS PLAT:T C0ilDITIO;iS D' P.It!G A!'D F0LLO'.fli:G A:( ACCIDEtiT J
and deferred further consideration to a later meeting in order to permit incorporation of recent comments by the Division of Technical Review.
/
Edson G.
ase, Chairman Regulatory Requirements Review Committee ENCLOSURE 1 (CONT'D)
Lee V. Gossick Category 2 - Further staff consideration of the need for back-fitting appears to be required for certain identified items of the regulatory position--these individual issues are such that existing plants need to be evaluited to determine their status with regard to these safety issues in order to determine the need for backfitting.
Category 3 - Clearly backfit.
Existing plants should be evaluated to determine whether identified items of the regulatory position are resolved in accordance with the guide or by some equivalent alternative.
From time to time, for a specific guide, there will probisly be some variation amcng these categories or even within a category, and these three broad category characterizations will be qualified as required to meet a particular situation.
d.
It is not intended that the Committee categorization appear in the guide itself.
The purpose of the categorization is to indicate those itens cf the regulatory position for which the Committee can make a specific backfit recommendation without additional staff work (Categories 1 and 3), and to indicate those items for which additional staff work is required in order to determine backfit considerations (Category 2).
e.
The Committee recommends that for approved guides in Category 2, staff efforts be initiated in parallel with the process leading to publication of the guide in order that specific backfit requirements for existing plants be determined within a reasonable period of time after publication of the guide.
f.
The Committee observed that more atten-ion needs to be given to the identification of acceptable alternatives to the positions outlined in the guides in order to provide additional options and flexibility to applicants and licensees, with the possible benefits of additional innovation and exploration in the solution of safety issues.
2.
The Committee reviewed the proposed Regulatory Guide 1.XX:
THERMAL OVERLOAD PROTECTION FOR MOTORS 0" MOTOR-0PERATED VALVES and recommended approval.
This guide was characterized by the Committee as Category 1 - no backfitting, with the stipulation that as an appropriate occasion presented itself in conjunction with the review of some particular aspect of existing plants, the thermal overload protection provisions be audited.
ENCLOSURE 1 (CONT'D)
r UNITED STATES NUCLEAR REGULATORY COMMisS..
W ASHINGTON. D.
C.
20555 SEP 2 4 575 Lee V. Gossick Executive Director for Operations REGULATORY REQUIREfENTS REVIEW COMMITTEE MEETING N0. 31, JULi 11, 1975 1.
The Committee discussed issues related to the implementation of Regulatory Guides on existing plants and the concerns expressed in the June 24, 1974 memorandum, A. Giambusso to E. G. Case, subject: REGULATORY GUIDE II4PLEi1ENTATION, and made the following recommendations and observations:
Approval of new Regulatory Guides and approval of revisions a.
of existing guides should move forward expeditiously in order that the provisions of these regulatory guides be available for use as soon as possible in on-going or future staff reviews of license applications.
The Committee noted that over the recent past, the approval of proposed regulatory guides whose content is acceptable for these purposes has experienced significant delays in RRRC review pending the determination of the applicability of the guide to existing plants, often requiring significant staff effort.
To avoid these delays, the Comnittee concluded that, henceforth, approval of proposed regulatory guides should be uncoupled from the consideration of their backfit applicability.
b.
The implementation section of new regulatory' guides should address, in general, only the applicability of the guide to applications in the licensing review process using, in so far as possible, a standard approach of applying the guide to those applications docketed 8 months after the issuance date of the guide for comment.
Exceptions to this general approach will be handled on a case-by-case basis.
The regulatory position of each approved proposed guide (or c.
proposed guide revision) will be characterized by the Committee as to its backfitting pot'ential, by placing it in one of three categories :
Category 1 - Clearly forward fit only.
No further staff consideration of possible backfitting is required.
ENCLOSUPI 1
I Joseph Harrington cc: Archibald B. Kenyon, Jr., Esq.
John P. Toscano, Jr., Esq.
Town Solicitor, Town of South 23 Canal Street Kingston Westerly, Rhode Island 02891 51 Tower Mill Road Wakefield, Rhode Island 02879 Karin P. Sheldon, Esq.
Harmon, Sheldon & Roisman Physicians Concerned About 1025 15th Street, N. W.
Nuclear Power Washington, D. C.
20005 c/o Robert L. Conrad 130 Kenyon Avenue Anthony J. Brosco, Esq.
Wakefield, Rhode Island 02879 Town Solicitor Town of Exeter Eric 0. Schneider 293 South Main Street Claudine C. Schneider Previdence, Rhode Island 02903 56 Central Street Narraganset, Rhode Island 02882 John T. Scanlon, Executive Director Save the Bay, Inc.
655 Main Street East Greenwich, Rhode Island 02818 Samuel Seeley, President Concerned Citizens of Rhode Island Box 525 Charlestown, Rhode Island 02813 Edward H. Newman, Esq.
Town Solicitor Town of Richmond 42 Granite Street Westerly, Rhode Island 02891 Raynond L. Thorp, Jr.
Chairman for Intervention The Taxpayers and Voters of Charlestown RFD Bradford, Rhode Island 02808 James D. Thornton, Esq.
Thornton & Thornton, Inc.
Washington Trust Building Westerly, Rhode Island 02891 Sean Kelleher Energy Advisor Office of the Governor State House Providence, Rhode Island 02903
Joseph Harrington cc: Mr. G. Frank Cole Project Manager United Engineers and Constructors, Inc.
V. James Santaniello, Esq.
30 South 17th Street Town Solicitor, Town of West P. O. Box 8223 Greenwich Philadelphia, Pennsylvania 19101 Manning, West, Santaniello & Pari 711 Industrial Bank Building Mr. W. E. Wright Providence, Rhode Island 02903 NEPC0 Project Manager Westinghouse Electric Corporation Sister Arlene Violet Box 355 187 Westminster Mall Pittsburgh, Pennsylvania 15230 Suite 507 Providence, Rhode Island 02903 Thomas 6. Dignan,.Jr., Esq.
John A. Ritsher, Esq.
Harrison A. Fitch, Esq.
R. K. Gad III, Esq.
Peter D. Kinder, Esq.
Ropes and Gray New England Legal Foundation 225 Franklin Street 110 Tremont Street Boston, Massachusetts 02110 Boston, Massachusetts 02108 Joseph T. Tura, Esq.
Philip W. Noel, Esq.
Towa Solicitor for the 15 Westminster Street Town of Westerly Providence, Rhode Island 02913 47 High Street Westerly, Rhode Island 02891 Henry Shelton, Esq.
Coalition for Consumer Justice Rhode Islanders for Safe Power 410 Broad Street c/o Ms. Emma Sacco Central Falls, Rhode Island 02863 Box 69 Wakefield, Rhode Island 02880 Cynthia Collins, Esq.
Doorley, Gifford & Paci Ms. Katerine Spencer Doherty 40 Westminster Street Aquidneck Island Ecology Providence, Rhode Island 02903 Box 573 Newport, Rhode Island 02840 Urso & Adamo, Esqs.
42 Granite Street Richard A. Poirier, President Westerly, Rhode Island 02891 Rhode Island Asscciation of Conservation Commissioners James 0. Watts, Esq.
Pole 95, Stillwater Road Town Solicitor, Town of Charlestown Smithfield, Rhode Island 02917 567 Main Street Wakefield, Rhode Island 028/9
. For your information, I am enclosing a set of the enclosures that accompanied these individual letters. These enclosures list the present Category 1-4 matters discussed in the letter.
Sincerely, Roger S. Bo, Director Division of Project Man #gement Office of Nuclear Reactor Regulation
Enclosures:
As stated cc:
See next page
September 15, 1978 CATEGORY 2 MATTERS Document Number Revision Date Title RG 1.27 2
1/76 Ultimate Heat Sink for Nuclear Power Plants RG 1.52 1
7/76 Design, Testing, and Maintenance Criteria for Engineered-Safety-Feature Atmosphere Cleanup System Air Filtration and Adsorption Units of Light Water Cooled Nuclear Power Plants (Revision 2 has been published but the changes from Revision 1 to Revision 2 may, but need not, be considered.
RG 1.59 2
8/77 Design Basis Floods for Nuclear Power Plants RG 1,63 2
7/78 Electric Penetration Assemblies in Containment Structures for Light Water Cooled Nuclear Power Plants RG 1.91 1
2/78 Evaluation of Explosions Postulated to Occur on Transportation Routes Near Nuclear Power Plant Sites RG 1.102 1
9/76 Flood Protection for Nuclear Power Plants RG 1.105 1
11/76 Instrument Setpoints RG 1.108 1
8/77 Periodic Testing of Diesel Generator Units Used as Onsite Electric Power Systand 3t Nuclear Power Plants RG 1.115 1
7/77 Protection Against Low-Trajectory Turbine Missiles RG 1.117 1
4/78 Tornado Design Classification RG 1.124 1
1/78 Service Limits and Loading Combinations for Class 1 Linear Type Component Supports RG 1.130 0
7/77 Design Limits and Loading Combinations for Class 1 Plate-and Shell-Type Component Supports (Continued)
ENCLOSURE 2
CATEGORY 2 MATTERS (CONT'D)
Continued Document Number Revision Date Title RG 1.137 0
1/78 Fuel Oil Systems for Standby Diesel Generators (Paragraph C.2)
RG 8.8 2
3//7 Information Relevant to Ensuring that Occupational Radiation Exposures at Nuclear Power Stations Will be as Low as is Reasonably Achievable (Nuclear Power Reactors)
BTP ASB Guidelines for Fire Protection for 9.5-1 1
Nuclear Power Plants (See Implementation Section, Section D)
BTP MTEB 5-7 4/77 Material Selection and Processing Guidelines for BWR Coolant Pressure Boundary Piping RG 1.141 0
4/78 Containment Isolation Provisions for Fluid Systems ENCLOSURE 2 (CONT'D)
September 15, 1978 CATEGORY 3 MATTERS Document Number Revision Date Title RG 1.99 1
4/77 Effects of Residual Elements on Predicted Radiation Damage to Reactor Vessel Materials (Paragraphs C.1 and C.2.
RG 1.101 1
3/77 Emergency Planning'for Nuclear Power Plants RG 1.114 1
11/76 Guidance on Being Operator at the Controls of a Nuclear Power Plant RG 1.121 0
8/76 Bases for Plugging Degraded PWR Steam Generator Tubes RG 1.127 1
3/78 Inspection of Water-Control Structures Associated with Nuclear Power Plants RSB S-1 1
1/78 Branch Technical Position: Design Require-ments of the Residual Heat Removal System RSB 5-2 0
3/78 Branch Technical Position: Reactor Coolant System Overpressurization Protectian (Draft copf attached)
RG 1.97 1
8/77 Instrumentation for Light Water Cooled Nuclear Power Plants to Assess Plant Conditions During and Following an Accident (Paragraph C.3 - with additional guidance on paragraph C.3.d to be provided later)
RG l.68.2 1
7/78 Initial Startup Test Program to Demonstrate Remote Shutdown Capability for Water-Cooled Nuclear Power Plants RG l.06 1
7/78 Maintenance of Water Purity in Boiling Water Reactors
Attachment:
BIP RSB S-2 (Draf t)
ENCLOSURE 3
=
=
yi1
,t BRANCH TECHNICAL POSITION RSB 5-2 OVERPRESSURIZATION PROTECTION CF PRESSURIZED WATER REACTORS WHILE OPERATING AT LOW TEMPERATURES A.
Background
General Design Criterion 15 of Appendix A,10 CFR 50, requires that "the Reactor Ccolant System and associated auxiliary, control, and proteccion systems shall be designed with sufficient margin to assure that the design conditions of the reactor coolant pressure boundary are not exceeded during any condition of normal operation, including anticipated operational occurrences."
Antic 1oated operational occurrences, as defined in Apoendix A of 10 CFR 50, are "those conditions of normal operation which are expected to occur one or more times during the life of the nuclear pcwer unit and include but are not limitec to loss of power to all recirculaticn pumps, tripping of the turbine generator set, isolation of tne main condenser, and loss of all offsite power."
Aopercix G of 10 CFR 50 provides the fracture tougnness requirements for reactor pressure vessels uncer all conditions.
To assure that the Accenoix G limits of the reactor coolant oressure boundary are not exceeded during any anticipated coerational occurrences, Technical Specification pressure-temperature limits are provided for operating the plant.
The primary concern of tnis position is that during startup and shutdown conditiens at icw temperature, especially in a water-solid condition, the reactor coolant system pressure might exceed the reactor vessel pressure-temperature limitations in the Technical Specifications established for protection against brittle fracture.
ibis inadvertent overpressurization could be generated by any one of a variety of mal-functions cr coerator errors. Many incider.ts have occurred in operating plants as described in Reference 1.
Additional discussion on the background of this position is contained in Reference 1.
ENCL 3 (CONT)
IJh!!!ri B.
Branch Position 1.
A system should be designed and installed which will prevent exceeding the applicable Technical Specifications and Appendix G limits for the reactor coolant system while operation at low temperatures.
The system should be capable of relieving pressure during all anticipated overpressurization events at a rate sufficient to satisfy the Technical Specification limits, particularly while the reactor coolant system is in a water-solid condition.
2.
The system must be able to perform its function assuming any single active component failure.
Analyses using appropriate calculational techniques P Jst be provided which demonstrate that the system will provide the required pressure relief capacity assuming the most limiting single active failure.
The cause for initiation of the event, e.g., operator error, component mal function, will not be considered as the single active failure.
The analysis should ass _ume the most limiting allowable enerating conditions and systems configuration at tne time of tne costulateo cause of the overoressure event.
All potential overpressur1:ation events must be considered wnen establishina tne worst case event.
Snme events may be preventoo hv protective interlocks or by locking out power.
at.se events should be reviewed on an individual basis If the inter 1nck/pnwer lod nut is acceptable, i t car. tie excluded from fto'.u'alyses provicied the controls tn prevent the event are in the plant Technical Specifications.
3.
The system must meet the design requirements of IEEE 279 (see Implementation).
Tne system Tay be manually enabled, however, the electrical instrumentation anc control system must provice alarms to alert the operator to:
a.
procerlv enable the system at the correct plant concition during cooldaan, b.
indicate if a pressure transient is occurring.
4.
To assure ocerational readiness, the overpressure protection system must be tested in the following manner:
a.
A test must be cerformed to assure operability of the system electronics prior to each shutdown.
b.
A test for valve operability must, as a minimum be conducted as specified in the ASME Code Section XI, c.
Subsequent to sjstem, valve, or electronics maintenance, a test on that portion (s) of the system mus t be performed prior to declaring tne system operational.
ENCL 3 (CONT)
kb ! 5.
The system must meet the requirements of Regulatory Guide 1.26.
" Quality Group Classifications and Standards for Water, Steam,
and Radioactive-Waste-Containing Ccmponents of Nuclear Power Plants" and Section III of the ASME Code.
6.
The overpressure protection system must be designed to function during an Operating Basis Earthquake.
It must not compromise the design criteria of any other safety-grade system with which it would interface, such that the requirements of Regulatory Guide 1.29, " Seismic Design Classification" are met.
7.
The overpressure protection system must not depend on the availability of offsite power to perform its function.
8.
Overpressure protection systems which take credit for an active ccmponent(s) to mitigate the consecuences of an overpressurization event must include additional analyses considering inadvertent system initiation / actuation or provice justification to show that existing analyses bound such an event.
C.
Imolementation The Branch Technical Position, as specified in Section B, will be used in tne review of all Preliminary Design Approval (PDA), Final Design Approval (FDA), Manufacturing License (ML), Coerating License (OL), and Construction permit (CP) applications involving plant designs incorporating pressurized water reactors.
All aspects of tne position will be applicable to all applications, including CP applications utilizing the replication option of the Commission's standardization program, that are docketed after March 14, 1978.
All aspects of the position, with the exception of reasonable and justified deviations from IEEE 279 requirements, will be applicable to CF, OL, ML, PDA, and FDA applications docketed prior to March 14, 1978 but for which the licensing action has not been completed as of March 14, 1978.
Holders of acoropriate PDA's will be informed by letter that all aspects of the position with the exception of IEEE 279 will be apolicable to their approved standard designs and that sucn designs should be modified, as necessary, to conform to the position.
Staff approval of proposed modifications can be applied for either by application by the PDA-nolder on the PDA-docket or by each CP applicant referencing the standard design on its docket.
The follcwing guidelines may be used, if necessary, to alleviate impacts on licensing schedules for plants involved in licensing proceedings nearing ccmpletion on Merch 14, 1978:
ENCL 3 (CONT)