See also: IR 07200010/2037012

Text

UNITED STATES

NUCLEAR REGULATORY COMMISSION

REGION III

2443 Warrenville Road, Suite 210

Lisle, IL 60532-4362

November 20, 2013

Mr. Patrick T. Daly

Senior Vice-President

and General Manager

ZionSolutions, LLC

101 Shiloh Boulevard

Zion, IL 60099

SUBJECT: NRC INSPECTION REPORT NOS. 05000295/2013012(DNMS);

05000304/2013012(DNMS); 07201037/2012001(DNMS) ZION NUCLEAR

POWER STATION

Dear Mr. Daly:

On November 5, 2013, the U.S. Nuclear Regulatory Commission (NRC) completed its

inspection of the independent spent fuel storage installation (ISFSI) construction activities at the

permanently shut-down Zion Nuclear Power Station in Zion, Illinois. At the conclusion of the

inspection on November 5, 2013, during an exit meeting, the NRC inspectors discussed the

preliminary inspection findings with members of your staff. The enclosed report presents the

results of this inspection.

The inspection examined the independent spent fuel storage installation pad, and vertical

concrete cask design and construction, as it relates to the safe storage of dry fuel and

compliance with the Commissions rules, regulations, and the conditions of your license.

Specific areas examined during the inspection are identified in the enclosed report. Within

these areas, the inspection consisted of selected examinations of procedures and

representative records, and interviews with personnel.

The inspection was conducted per NRC Inspection Manual 2690, Inspection Program for Dry

Storage of Spent Reactor Fuel at Independent Spent Fuel Storage Installations and Guidance

for Title 10 of the Code of Federal Regulations (CFR) Part 71 Transportation Packages, and

used Inspection Procedures (IP) 60853 and IP 60856.

Based on the results of these inspections, the inspectors did not identify any violations of NRC

requirements.

P. T. Daly -2-

In accordance with Title 10 of the Code of Federal Regulations (CFR) 2.390 of the NRC's

"Rules of Practice," a copy of this letter and the enclosed report will be made available

electronically for public inspection in the NRC Public Document Room or from the NRC's

Agencywide Document Access and Management System (ADAMS), accessible from the NRCs

website at http://www.nrc.gov/reading-rm/adams.html.

We will gladly discuss any questions you may have regarding this inspection.

Sincerely,

/RA/

Robert J. Orlikowski, Chief

Materials Control, ISFSI, and

Decommissioning Branch

Division of Nuclear Materials Safety

Docket Nos. 050-00295; 050-00304; 072-01037

License Nos. DPR-39; DPR-48

Enclosure:

Inspection Report Nos. 05000295/2013012;

05000304/2013012; 07201037/2012001

cc w/encl: Patrick Thurman, ZionSolutions, LLC

Gary Bouchard, ZionSolutions, LLC

Alan Parker, EnergySolutions

John Christian, EnergySolutions

Russ Workman, EnergySolutions

cc w/o encl: Zion Distribution Service List

P. T. Daly -2-

In accordance with Title 10 of the Code of Federal Regulations (CFR) 2.390 of the NRC's

"Rules of Practice," a copy of this letter and the enclosed report will be made available

electronically for public inspection in the NRC Public Document Room or from the NRC's

Agencywide Document Access and Management System (ADAMS), accessible from the NRCs

website at http://www.nrc.gov/reading-rm/adams.html.

We will gladly discuss any questions you may have regarding this inspection.

Sincerely,

/RA/

Robert J. Orlikowski, Chief

Materials Control, ISFSI, and

Decommissioning Branch

Division of Nuclear Materials Safety

Docket Nos. 050-00295; 050-00304; 072-01037

License Nos. DPR-39; DPR-48

Enclosure:

Inspection Report Nos. 05000295/2013012(DNMS);

05000304/2013012(DNMS); 07201037/2012001(DNMS)

cc w/encl: Patrick Thurman, ZionSolutions, LLC

Gary Bouchard, ZionSolutions, LLC

Alan Parker, EnergySolutions

John Christian, EnergySolutions

Russ Workman, EnergySolutions

cc w/o encl: Zion Distribution Service List

DISTRIBUTION w/encl: Harral Logaras Tammy Tomczak

Bruce Watson Alan Barker Paul Pelke

John Hickman Patricia Buckley MCID Branch

Patrick Louden Carol Ariano

Ann Marie Stone Linda Linn

ADAMS Accession Number: ML13325A898

DOCUMENT NAME: G:\DNMSIII\Work in progress\IR - Zion ISFSI Pad Construction Final.docx

Publicly Available Non-Publicly Available Sensitive Non-Sensitive

To receive a copy of this document, indicate in the concurrence box "C"= Copy without attach/encl "E = Copy with attach/encl "N"= No copy

OFFICE RIII DNMS N RIII DNNMS N

NAME MLearn:ps*MCL ROrlikowski *RJO

DATE 11/20/13 11/20/13

OFFICIAL RECORD COPY

U.S. NUCLEAR REGULATORY COMMISSION

REGION III

Docket Nos.: 050-00295; 050-00304; 072-01037

License Nos.: DPR-39; DPR-48

Report Nos.: 05000295/2013012(DNMS)

05000304/2013012(DNMS)

07201037/2012001(DNMS)

Licensee: ZionSolutions, LLC

Facility: Zion Nuclear Power Station

(permanently shut-down)

Location: 101 Shiloh Boulevard

Zion, IL 60099

Dates: Onsite Inspection on June 12, October 29

through November 1, November 14,

November 15, December 14, 2012; in-office

review through November 5, 2013

NRC Inspector: Matthew C. Learn, Reactor Engineer

Vijay L. Meghani, Reactor Inspector

Approved by: Robert J. Orlikowski, Chief

Materials Control, ISFSI, and

Decommissioning Branch

Division of Nuclear Materials Safety

Enclosure

EXECUTIVE SUMMARY

Zion Nuclear Power Station,

NRC Inspection Report 05000295/2013012; 05000304/2013012;

07201037/2012001

The purpose of the inspection was to evaluate the design and construction of a new

Independent Spent Fuel Storage Installation (ISFSI) storage pad and Vertical Concrete

Casks (VCC), at the Zion Nuclear Power Station, to ensure compliance with regulations and

design specifications.

Site Characterization and Design of the Independent Spent Fuel Storage Installation Pad

• The licensees soil and ISFSI pad engineering design evaluations were performed in

accordance with the Certificate of Compliance, Title 10 of the Code of Federal

Regulations (CFR) Part 72 requirements, and applicable industry standards.

(Section 1.1)

ISFSI Pad and VCC Construction

• The licensees site characterization and soil compaction activities were performed in

accordance with specifications, design drawings, and industry standards. (Section 2.1)

• The inspectors concluded that the construction activities for the ISFSI concrete storage

pad complied with specifications contained in the licensees approved engineering

change package, design drawings, civil construction specifications, work orders, and

applicable industry standards. The licensee provided justifications for any discrepancies

which were verified with the designer of the pad. (Section 2.2)

• The inspectors concluded that the construction activities for the VCC complied with

specifications contained in the licensees vendors, design drawings, civil construction

specifications, work orders, and applicable industry standards. The licensee provided

justifications for any discrepancies. (Section 2.3)

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Report Details

1.0 Review of 10 CFR 72.212(b) Evaluations, Appendix A, Review of Independent

Spent Fuel Storage Installation Storage Pad Design (60856)

1.1 Site Characterization and Design of the Independent Spent Fuel Storage Installation Pad

a. Inspection Scope

The inspectors evaluated the licensees soil and independent spent fuel storage

installation (ISFSI) pad engineering design evaluations for an ISFSI pad to verify the

licensees compliance with the Certificate of Compliance, Title 10 Code of Federal

Regulations (CFR) Part 72 requirements, and industry standards. Title

10 CFR 72.212(b)(5)(ii) requires that licensees perform written evaluations, before use

which establish that cask storage pads and areas have been designed to adequately

support the static and dynamic loads of the stored casks, considering potential

amplification of earthquakes through soil-structure interaction, and soil liquefaction

potential or other soil instability due to vibratory ground motion.

b. Observations and Findings

The licensee is utilizing the NAC MAGNASTOR dry cask storage system. Two separate

three foot thick reinforced concrete pads are provided, each one capable of supporting

36 Vertical Concrete Casks (VCC) in a 4 x 9 array. Each pad is 68 feet wide and

148 feet long. The licensee designed and constructed the ISFSI pad as an important to

safety category C structure. A 35 feet wide x 148 feet long, 18 inch thick concrete apron

area is located between the two pads. The concrete pads were installed on top of a

five to seven feet granular fill above the existing grade.

Soil Analysis and Soil Liquefaction Analysis

The inspectors reviewed licensee calculations documenting the engineering properties

and design soil profile of the ISFSI site based on geotechnical data obtained from soil

borings. The design subsurface profiles were developed based on more than

20 borings, some of which extended to depths of more than 100 feet and into the bed

rock. The ground water was found at approximately seven to eight feet below the top of

the pads. Properties of soil layers were determined and documented in calculation

ZION001-CALC-004. Inspectors also reviewed licensees evaluation of soil liquefaction

potential and soil stability in the pad areas. The liquefaction evaluation performed in

accordance with RG 1.198 included screening level assessment, quantitative

assessment of liquefaction factor of safety using the Standard Penetration Test (SPT),

and quantitative assessment of seismically induced ground settlement. The slope

stability evaluations generally indicated a factor of safety of two. Synthetic geo-grid soil

reinforcement was installed as recommended in the evaluation for certain areas where

the lower safety factors between 1.6 and 1.8 were found. Inspectors noted that the soil

bearing capacity and the total and differential settlement were evaluated in calculation

ZION001-CALC-007. The lowest factor of safety against bearing capacity was found to

be 7.5. The total and differential settlements under static loads were found to be less

than an inch.

3

Seismic Soil Structure Analysis and ISFSI Pad Structural Analysis

The inspectors reviewed the licensees seismic analysis evaluation to determine if the

sites safe shutdown earthquake accelerations were correctly considered at the ISFSI

site. The Licensee developed acceleration time histories from the seismic spectra

provided in the Decommissioning Safety Analysis Report (DSAR) in accordance with the

requirements of NRC Standard Review Plan 3.7.1. These time histories and the ISFSI

site soil profiles (best estimate, lower bound, and upper bound) were used to develop

the strain compatible properties for use in the soil structure analysis. The Soil Structure

Interaction (SSI) analysis determined the maximum accelerations at the base and at the

center of gravity of the storage casks. The SSI analysis considered eight different

loading configurations to account for various partial and full loading conditions and also

addressed three sets of soil properties (including the best estimate, upper bound and

lower bound) for each loading configuration. The analysis also verified adequate safety

factors against cask sliding and overturning. During review of the SSI analysis

ZION001-CALC-018, the inspectors identified that the licensee assumed un-cracked

concrete section properties for the pad while the calculated bending moments indicated

that the concrete would crack under seismic loads. American Society of Civil Engineers

(ASCE) 4-98, which is referenced in the calculation, in Section 3.1.3.1, requires that the

concrete sections be modeled as cracked or un-cracked depending on the stress levels

due to the most critical seismic load combination. During calculation revision to address

the inspectors questions, the licensee made an error in calculation of the cracking

moment and incorrectly concluded that the seismic load condition would not exceed the

cracking moment. In response to further comments by the inspectors, the licensee

again revised the calculation to correct the error. The final revised calculation indicated

a reduction in concrete section properties due to the cracking, however, due to the

conservatism included in the calculation, the error did not affect the conclusions

regarding adequacy of the pad. The inspectors also had a concern regarding mesh size

used in the pad finite element model. The inspectors concern was that the element

dimensions used in the analysis may not adequately capture effects of pad flexibility as

discussed in the technical paper titled Influence of ISFSI Design Parameters on the

Seismic Response of Dry Storage Casks, by Bjorkman and Moore. NUREG 1536,

Section 3.5.1.4.i (3) (g) identifies the importance of pad flexibility considerations and

refers to the paper. The licensee in response to the inspectors concern provided

additional sensitivity analyses to demonstrate adequacy of the pad SSI.

The inspectors reviewed the licensees structural evaluation of the ISFSI reinforced

concrete pad. The pad was designed in accordance with the requirements of American

Concrete Institute (ACI) 318-08, Building Code Requirements for Structural Concrete

and, where the ACI 318 is silent, the guidance from ACI 349-06, Code Requirements for

Nuclear Safety Related Concrete Structures was used. The specified concrete design

strength was 4000 pounds per square inch (psi). Load combinations including static and

dynamic loads per the requirements of ACI 349 and Table 3.3 of the NRC NUREG 1536

were used. Seismic accelerations obtained from the SSI analyses were conservatively

applied to the casks so as to maximize the applied forces and moment. Eight pad and

cask models representing fully loaded and partially loaded pad configurations were

analyzed using the finite element method to account for partial and sequential loading of

the pad. Settlement effects were also included in the pad analysis.

The inspectors reviewed the licensees site specific cask tip-over analysis. This analysis

was required because the concrete pad and sub-soil parameters at the ISFSI site were

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not bounded by the tip-over analysis in the MAGNASTOR cask Final Safety Analysis

Report (FSAR). The analysis was performed using the finite element program LS-DYNA

using the same methodology as described in the cask FSAR. The initial design

documents required the pad concrete 28-day compressive strength to be less than

5000 psi. However, due to the concrete test results indicating strengths exceeding

6000 psi in some cases, the tip-over calculation was revised to address a bounding

strength of 7000 psi. The analysis determined that in the event of a tip-over, with the

ISFSI site specific soil parameters and the bounding concrete properties, the maximum

accelerations at the top of the fuel basket and at the top of the canister would not exceed

the FSAR limits.

ISFSI Pad Impact on Flooding Analysis

The top surface of the ISFSI pads are at an elevation of 592.1 feet above mean sea

level (MSL) and have been constructed above the probable maximum surge and seiche

flood level of 592.05 feet above MSL for the site as discussed in DSAR Section 2.4.5.

Therefore, the ISFSI pads are enveloped by the NAC MAGNASTOR design basis. The

flood water velocity limit is not applicable in this case because no part of a cask would

be submerged during the probable maximum flood.

c. Conclusion

The licensees soil and ISFSI pad engineering design evaluations were performed in

accordance with the Certificate of Compliance, 10 CFR Part 72 requirements, and

industry standards.

2.0 Independent Spent Fuel Storage Installation Pad Construction (60853)

2.1 Excavation and Soil Compaction Activities

a. Inspection Scope

The inspectors evaluated the licensees site characterization for the new ISFSI pad to

verify the licensees compliance with its specifications, design drawings, and industry

standards.

b. Observations and Findings

The licensee constructed the reinforced concrete ISFSI storage pads south of the plant

switchyard. The licensee graded the site and removed the top several feet of existing

soil, ensuring removal of topsoil, organic, and all undesirable material. The licensee

performed proof-rolling of the underlying in-situ material to ensure that a suitable sub-

grade existed under the pad area. Following receipt of satisfactory compaction results

for the sub-grade, the licensee backfilled the area with a minimum of two feet of non-

frost susceptible granular base material (gravel/sand) and compacted the fill in

accordance with American Society for Testing and Materials (ASTM) D1557.

c. Conclusion

The licensees site excavation and soil compaction activities were performed in

accordance with specifications, design drawings, and industry standards.

5

2.2 Pad Construction Activities

a. Inspection Scope

The inspectors evaluated whether construction activities for the ISFSI concrete storage

pad complied with specifications contained in the licensees approved design evaluation,

design drawings, work orders, and applicable industry standards. The inspectors also

reviewed select material, concrete documentation, and personnel certification records.

b. Observations and Findings

The inspectors reviewed ZION001-PS-002, Project Specification for the ISFSI and FHB

Upgrades Cast-in-Place Concrete, Revision 1. ZION-001-PS-002 described the

minimum requirements for construction activities related to installation of the ISFSI pad.

The inspector reviewed ZS ISFSI - Project Instruction No. 3 Cast-in Place Concrete

Construction Revision 3 which further established cast-in-place concrete construction

and material testing requirements for the ISFSI pad.

Placement of Reinforcing Steel

After placement and satisfactory compaction of the engineered fill, the licensee placed a

4-inch mudmat which provided a work surface to facilitate reinforcement bar (rebar)

installation and concrete placement. The licensee then installed forms and placed rebar.

The licensees design specification chose to utilize rebar that conformed to either

ASTM A615 Grade 60 or ASTM A706 Grade 60 steel.

After placing the rebar and securing the forms for each section, the licensee performed

inspections of the rebar and the pad general areas prior to concrete placement. The

NRC inspectors reviewed the design drawings and performed an independent walk

down of both pads. The pad areas were free of debris and excessive moisture. The

rebar was placed in two upper and lower layers joined by U-shaped bars. The licensee

placed the correct size of rebar. The inspectors measured the spacing between the

rebar and found it to be per the design specifications and industry standards.

Concrete Mix Design

The inspectors reviewed the licensees concrete mix design to ensure compliance with

the applicable codes and standards committed to in the licensees design.

The inspectors reviewed the licensees exposure classifications of the ISFSI pad to

ensure compliance with the durability requirements of ACI 318-08. The licensee

characterized the pad as F1, concrete exposed to freezing and thawing cycles and

occasional exposure to moisture; S0, SO4 < 0.10% by weight in soil and < 150 ppm in

water; P0, contact with water where low permeability is not required; and C1, concrete

exposed to moisture, but not external sources of chlorides. The inspectors reviewed the

licensees specified strength, water to cement ratio, slump, and air content. The

inspectors reviewed the licensees technical justification for these exposure

classifications. The licensees design contained explicit specifications for both concrete

strength and air content that were lower and higher respectively than the durability

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requirements of the ACI-318-08 in order to comply with the FSAR cask tip-over analysis

strength requirements.

The inspectors reviewed the licensees selection and testing of mix design components

including cement, potable water, fine aggregate, course aggregate, and admixtures.

The licensee utilized aggregates that were resistant to the affects of alkali-silicate

reactions.

Prior to concrete placement the licensee tested their concrete mixture to ensure it met

the specified requirements.

Placement of Concrete for Storage Pad

The storage pad was constructed in accordance with ACI 318-08 and ACI 301-10. The

ISFSI pads were constructed in four segments per pad allowing separate continuous

placements of concrete. The inspectors observed concrete placement for

sections 1 and 4 of the south storage pad.

The inspectors observed that the concrete was transported by conveyor belt and

deposited in the areas of placement within the forms. The inspectors noted that the

contractor staff maintained careful control of the discharge hose and ensured that

concrete had an unrestricted vertical drop to the point of placement to prevent

segregation of the aggregate. The contractor used a systematic pattern of vibration to

ensure proper consolidation, thereby preventing voids in the concrete slab. The licensee

finished the pad with a roller paver screed with paving rollers. The licensee applied a

broom finish as required by the design to the pad after placement in order to achieve the

appropriate surface friction factor.

The licensee enacted cold weather concrete curing measures when necessary to ensure

that concrete minimum temperature was above 50 degrees Fahrenheit during the first

seven days of curing. Concrete temperature was measured with the use of surface

thermometers and embedded thermocouples when necessary.

Concrete Field Tests

The licensee checked the concrete batch tickets for every truck to confirm that each

concrete batch was mixed as specified in the mix design and the mixing time and

number of drum revolutions satisfied code requirements to ensure the concrete was

suitable for placement. The licensees contractor obtained concrete samples every

1st and 5th truck and every 100 cubic yards thereafter for each segment to test air

content, temperature, weight and slump tests.

In addition to the field tests, the qualified individuals collected concrete samples in

cylinders, a minimum of one set of four cylinders every 1st and 5th truck and every 100

cubic yards thereafter for each segment, for the concrete strength tests. The cylinders

were cured and tested after 28 days by an independent laboratory to measure the

compressive strength of the concrete.

The inspectors reviewed the 28 day concrete compressive strength test results taken

from the storage pad to ensure they met the minimum strength of 4,000 psi and

maximum of 5,000 psi as specified by the design requirements. The lower bound

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strength limit ensures durability and strength of the ISFSI pad. The upper bound

strength limit ensures a ductile enough surface during a postulate non-mechanistic cask

tip-over event.

Several 28-day test results exceeded the 6,000 psi maximum strength, these results

were provided to NAC for review and justification for acceptance as discussed in

Section 1.1.

c. Conclusion

The inspectors concluded that the construction activities for the ISFSI concrete storage

pad complied with specifications contained in the licensees approved design package,

design drawings, civil construction specifications, work orders, and applicable industry

standards. The licensee provided justifications for any discrepancies which were verified

with the designer of the pad.

2.3 Dry Cask Storage System Construction Activities

a. Inspection Scope

The inspectors reviewed the licensees vendor perform on site construction activities

associated with VCC.

b. Observations and Findings

The VCC is the storage overpack for the fuel canister and provides structural support,

shielding, protection from environmental conditions, and natural convection cooling of

the canister during long-term storage. The concrete cask is a reinforced concrete

structure with a carbon steel inner liner. The VCC does not include a confinement

barrier, rather the canister housed within the VCC provides a confinement barrier.

VCC fabrication activities were performed by NAC International under contract with

Zionsolutions at the Zion Station between May and August 2012.

During fabrication activities, the NRC performed two site inspections specifically focused

on VCC fabrication activities.

Following completion of fabrication activities the NRC inspectors performed two

additional walkdowns of VCC condition. The inspectors noted that several casks on the

construction pad had hairline cracks (very fine) in their outer surface. The inspectors

noted that cask # 21 had the most visible external flaws. Cosmetic repairs were made to

the lower portion of these cracks as necessary.

Inspectors reviewed quality control documentation associated with individual VCC

fabrication. Specifically inspectors reviewed documentation associated with cask #21.

Throughout the fabrication process NAC International performs inspection of fabrication

activities important to quality in 630073-P-01, Vertical Concrete Cask Work Record and

Inspection Forms on Zion MAGNASTOR Spent Fuel Storage Project, Revision 0. Step

47 of 630073-P-01 instructs the NAC inspector to inspect for cask concrete surface

defects including cracks. Specifically the document instructs that surface cracks that

exceed 0.013 inch in maximum width shall be documented in the comments section of

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this form, and a nonconformance report (NCR) shall be prepared for cracks that

exceed 0.040 inches in width

630073-P-01 Step 47 includes provision for inspection for both NAC International, and

also Zionsolutions. Zionsolutions completes an independent review of step 47 through

their independent quality assurance program.

Upon completion of fabrication activities the cask is issued a Certificate of Conformance

from NAC International to Zionsolutions that certifies that the cask was designed,

fabricated, constructed, tested, and repaired, if needed, in accordance with

NAC International QA Program as accepted by the USNRC in conformance with

USNRC NUREG/CR-6407. NAC International also certifies that inspection were

performed in accordance with 10 CFR 72.236(j) requirements and found satisfactory.

Upon receipt of the fabricated component Zionsolutions performs a receipt inspection of

the cask utilizing ZS-QA-110, Inspections, Revision 0.

The licensee indicated that all 64 casks had been tested in accordance with their quality

program as described above. The construction acceptance testing was performed

between August and November 2012, with the final cask acceptance completed on

November 8, 2012. The inspectors reviewed the licensees quality program as

described above and determined that the licensee was appropriately incorporating

industry standards into procedures to ensure adequate acceptance criteria for concrete

condition. Specifically the inspectors noted that the licensee utilized ACI 349.3R-02,

Evaluation of Existing Nuclear Safety Related Concrete Structures to evaluate

VCC concrete cracks.

c. Conclusion

The licensees vendor performed on site construction activities associated with vertical

concrete casks (VCC) at the ISFSI pad in accordance with their design drawings, civil

construction specifications, and applicable industry standards. The licensee maintained

adequate oversight over contractor activities.

3.0 Exit Meeting Summary

On November 5, 2013, the inspectors conducted an exit meeting to present the results

of the inspection.

Attachment: SUPPLEMENTAL INFORMATION

9

SUPPLEMENTAL INFORMATION

PARTIAL LIST OF PERSONS CONTACTED

Licensee and Contractor Employees

• Jack Bailey, ISFSI Senior Licensing Consultant

Bruce Holmgren, Dry Cask Storage Vice President

Richard Netzel, ISFSI Construction Manager

• Brian Wood, Dry Cask Storage Vice President

• Persons present during the November 5, 2013 exit meeting.

INSPECTION PROCEDURES USED

IP 60853 Construction of an Independent Spent Fuel Storage Installation

IP 60856 Review of 10 CFR 72.212 (b) Evaluations, Appendix A, Review of Independent

Spent Fuel Storage Installation Storage Pad Design

ITEMS OPENED, CLOSED, AND DISCUSSED

Opened Type Summary

None

Closed

None

LIST OF DOCUMENTS REVIEWED

630073-2025; Zion Solution Magnastor VCC Tip-Over Analysis; Revisions 0, 1, 2

630073-R-01; Design Interface and Operational Requirements for the Magnastor System and

the Zion Nuclear Power Station ISFSI

Certificate No. 1031; Certificate of Compliance for Spent Fuel Storage Cask, Issued to NAC

International; Amendment 2

CR-2012-001312; Calculation Package Internal Reference Error, 12/10/2012

CR-2012-001313; Calculation Package External Reference Error; 12/10/2012

CR-2013-000954; Error in CALC-018 Zion ISFSI Soil-Structure Interaction analysis of Support

Pad; 9/4/2013

DWG ZION001-C-001; ISFSI Project, ISFSI Plot Plan, Civil; Revision 8

DWG ZION001-C-011; ISFSI Project, Basemat and Apron Plan, Civil; Revision 2

DWG ZION001-C-012; ISFSI Project, Basemat and Apron Reinforcing Sections, Civil;

Revision 0

DWG ZION001-C-037; ISFSI Project, Sections and Related Details, Civil; Revision 1

Magnastor System FSAR; Docket No. 72-1031; Revision 10B

Attachment

Meyer Material Company Project Mix Design; October 15, 2012

Project Instruction Number 3 Cast-in-Place Concrete Construction Important to Safety;

Revision 3

ZION001-CALC-004; Engineering Properties and Design Subsurface Properties of the Zion

ISFSI Site; Revision 0

ZION001-CALC-005; Liquefaction analysis of the Zion ISFSI site; Revision 0

ZION001-CALC-006; Slope Stability Analysis: Zion Nuclear Power Station ISFSI Site;

Revision 0

ZION001-CALC-007; Settlement and Bearing Capacity of the Zion ISFSI Pads; Revision 0, 1

ZION001-CALC-017; Zion ISFSI Development of Time Histories; Revision 0

ZION001-CALC-018; Zion ISFSI Soil-Structure Interaction Analysis of Support Pad;

Revision 1, 2, 3

ZION001-CALC-019; Zion ISFSI development of Strain Compatible Soil Properties; Revision 0

ZION001-CALC-024; ISFSI Pad; Revision 0

ZION-001-PS-002; Cast-in-Place Concrete; Revision 1

ZION-001-PS-003; Excavation and Backfill; Revision 1

ZION001-RPT-005; Geotechnical Site Investigation and Evaluation; Revision 0

ZS-QA-11-F-1 Nonconformance Report; Criteria for Concrete Strength not Met; April 29, 2013

LIST OF ACRONYMS USED

ACI American Concrete Institute

ADAMS Agencywide Documents Access and Management System

ASCE American Society of Civil Engineering

ASTM American Society for Testing and Materials

CFR Code of Federal Regulations

DNMS Division of Nuclear Materials Safety

DSAR Decommissioning Safety Analysis Report

FSAR Final Safety Analysis Report

IP Inspection Procedure

ISFSI Independent Spent Fuel Storage Installation

MSL Mean Sea Level

NCR Nonconformance Report

NRC U. S. Nuclear Regulatory Commission

psi Pounds per Square Inch

SPT Standard Penetration Test

SSI Soil Structure Interaction

VCC Vertical Concrete Cask

2