ML21037A007

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Alpha-Omega Services, Inc. - Radioactive Material Transport Packaging System Safety Analysis Report
ML21037A007
Person / Time
Site: 07109316
Issue date: 01/31/2021
From:
Alpha Omega Services
To:
Office of Nuclear Material Safety and Safeguards
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AOS-FM9054
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Text

AOS-FM9054 Rev. J, January 31, 2021 (Docket No. 71-9316)

Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages Prepared by Alpha-Omega Services, Inc.

Bellflower, CA

NOTICE AND DISCLAIMER Alpha-Omega Services, Inc., solely for the use of the U.S. Nuclear Regulatory Commission (NRC) in licensing the AOS Radioactive Material Transport Packaging System (AOS Transport Packaging System), prepared this report. Alpha-Omega Services, Inc., and/or its Contractor assume no responsibility for liability nor damage, which may result from any other use of the information disclosed in this report.

The information contained in this report is believed to be an accurate and true representation of the facts known by or provided to Alpha-Omega Services, Inc., and/or its Contractor at the time this report was prepared. Alpha-Omega Services, Inc., and/or its contractor and the individual contributors to this report make no express nor implied warranty with respect to the accuracy, completeness, or usefulness of the information contained in this report, other than for the licensing of the AOS Transport Packaging System or that the use of any information disclosed in this report may not infringe privately owned rights, including patent rights.

The printed copy of this report, as submitted to the NRC, contains PDF files, one or more of which contains hyperlinks to other files (within the report) or to the Internet. These hyperlinks are either inoperable or are not essential to the use of the filing. Any material referenced by hyperlinks to the Internet that was essential for use of this filing has been submitted as part of the filing. Any material referenced by a hyperlink to another PDF that was essential for the use of this filing has either been included by reference or submitted as part of this filing.

Revision History Revision Date Description of Changes A

January 11, 2008 Preliminary release.

B June 20, 2009 Preliminary release.

C September 11, 2009 Preliminary release.

D September 28, 2010 Preliminary release.

E October 11, 2011 Preliminary release.

F February 1, 2012 Initial Release.

G July 27, 2012 Update to include cask lid elastomeric seal, and included text so the cask lid metallic seal is differentiated from the new elastomeric seal.

Applied miscellaneous corrections (table of changes included with cover page of the submittal).

H December 30, 2012 Updated in response to NRC RAIs.

Applied miscellaneous corrections (table of changes included with cover page of the submittal).

H-1 March 11, 2016 Updated to add new isotope, Ir-194.

General update to correct errors and incorporate changes communicated to NRC in letters dated April 4, May 14, and September 26, 2013, and May 6, June 5, and August 5, 2015.

Applied miscellaneous updates and corrections (table of changes included with cover page of the submittal).

H-2 June 27, 2016 Updated in response to NRC RAI.

H-3 May 3, 2017 Clarified Special Form material shipment requirements and applied miscellaneous corrections.

H-4 November 28, 2017 Updated Cask Thread Sealant-related information.

H-5 July 20, 2018 Chapter 1 - Revised Subsection 1.2.2 (added discussion relating to isotope mixtures); revised Table 1-2 (deleted footnote e and renumbered remaining footnotes); added Table 1-2b; updated Table 1-5 drawing revisions Chapter 2 - Replaced Paragraph 2.5.3.1.4; added Appendix 2.12.16 Chapter 5 - Added Appendix 5.5.5, Appendix 5.5.6, and Appendix 5.5.7 Chapter 7 - Added Appendix 7.5.1 Applied miscellaneous corrections (table of changes included with cover page of the submittal)

H-6 December 10, 2018 Update in response to NRC RAI (10-09-2018) addressing changes and clarifications in SAR Chapters 1, 5, 7, and 8 Applied miscellaneous corrections (table of changes included with cover page of the submittal)

H-7 January 25, 2019 Updated in response to NRC questions (email dated 01-15-2019) addressing changes and clarifications in SAR Chapters 1, 2, 5, and 7 Table of changes included with the cover page of the submittal

J January 31, 2021 Consolidation of Revisions H - H7 (Revision I intentionally skipped)

Subsection 1.2.2 and Section 7.1 - Clarified that the shoring materials are structural Paragraphs 2.5.3.1.2 through 2.5.3.1.4 - Calculations revised to correct minor errors and typos Subsection 2.6.7 - Removed stale note created in Revision H-5 Figures 3-18 through 3 Replaced thermal transient plots for AOS Model-025 fire condition Figure 4 Changed port cover torque requirement Chapter 9 - Updated with current requirements, approval letter, and certificate Updated ANSI N14.5 references to 2014 edition Applied miscellaneous corrections (table of changes included with cover page of the submittal)

Revision Date Description of Changes

Radioactive Material Transport Packaging System Safety Analysis Report v

for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

CONTENTS

1. General Information.............................................................1-1 1.1. INTRODUCTION............................................................... 1-1 1.2. PACKAGE DESCRIPTION....................................................... 1-7 1.2.1. Packaging................................................................. 1-8 1.2.2. Contents................................................................. 1-12 1.2.3. Special Requirements for Plutonium........................................... 1-17 1.2.4. Operational Features....................................................... 1-17 1.2.5. Fabrication Codes, Standards, and Acceptance Tests............................. 1-17 1.3. APPENDIX.................................................................. 1-23 1.3.1. AOS Transport Packaging System, Certification Drawings.......................... 1-23 1.4. REFERENCES............................................................... 1-45
2. Structural Evaluation............................................................2-1 2.1. DESCRIPTION OF STRUCTURAL DESIGN......................................... 2-2 2.1.1. Discussion................................................................ 2-2 2.1.2. Design Criteria............................................................. 2-8 2.1.3. Weights and Centers of Gravity............................................... 2-23 2.1.4. Identification of Codes and Standards for Package Design.......................... 2-27 2.2. MATERIALS................................................................. 2-29 2.2.1. Material Properties and Specifications.......................................... 2-29 2.2.2. Chemical, Galvanic, and/or Other Reactions..................................... 2-36 2.2.3. Effects of Radiation on Materials.............................................. 2-37 2.3. FABRICATION AND EXAMINATION.............................................. 2-38 2.3.1. Fabrication............................................................... 2-38 2.3.2. Examination.............................................................. 2-42 2.4. GENERAL REQUIREMENTS FOR ALL PACKAGES.................................. 2-43 2.4.1. Minimum Package Size..................................................... 2-43 2.4.2. Tamper-Indicating Feature................................................... 2-43 2.4.3. Positive Closure........................................................... 2-43 2.5. LIFTING AND TIE-DOWN STANDARDS FOR ALL PACKAGES......................... 2-44 2.5.1. Lifting Devices............................................................ 2-44 2.5.2. Tie-Down Devices......................................................... 2-51 2.5.3. Other Devices............................................................. 2-51 2.6. NORMAL CONDITIONS OF TRANSPORT.......................................... 2-74 2.6.1. Heat.................................................................... 2-74 2.6.2. Cold.................................................................... 2-79 2.6.3. Reduced External Pressure.................................................. 2-80 2.6.4. Increased External Pressure................................................. 2-80 2.6.5. Vibration................................................................. 2-81 2.6.6. Water Spray.............................................................. 2-82 2.6.7. Free Drop................................................................ 2-82 2.6.8. Corner Drop.............................................................. 2-83 2.6.9. Compression............................................................. 2-83 2.6.10. Penetration.............................................................. 2-83 2.6.11. Structural Evaluation Results Summary and Minimum Margins of Safety under Normal Conditions of Transport...................................... 2-86 2.7. HYPOTHETICAL ACCIDENT CONDITIONS........................................ 2-92 2.7.1. Free Drop................................................................ 2-93 2.7.2. Crush.................................................................. 2-145 2.7.3. Puncture................................................................ 2-145 2.7.4. Thermal................................................................ 2-147 2.7.5. Immersion - Fissile Material................................................. 2-152 2.7.6. Immersion - All Packages.................................................. 2-152

vi Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316) 2.7.7. Deep Water Immersion Test (for Type B Packages Containing More than 105 A2)..................................................... 2-152 2.7.8. Summary of Damages..................................................... 2-153 2.8. ACCIDENT CONDITIONS FOR AIR TRANSPORT OF PLUTONIUM.................... 2-158 2.9. ACCIDENT CONDITIONS FOR FISSILE MATERIAL PACKAGE FOR AIR TRANSPORT.... 2-158 2.10. SPECIAL FORM............................................................ 2-158 2.11. FUEL RODS............................................................... 2-158 2.12. APPENDIX................................................................ 2-159 2.12.1. Data CDs.............................................................. 2-160 2.12.2. Structural Evaluation Results - Models AOS-025, AOS-050, and AOS-100........... 2-161 2.12.3. LIBRA Finite Element Analysis Program and Verification Problems................. 2-696 2.12.4. Description of LIBRA Files and Post-Processors: AOS Safety Analysis Report........ 2-727 2.12.5. Selected Material Properties References...................................... 2-753 2.12.6. Impact (Free-Drop) Test Report............................................. 2-805 2.12.7. Dimensional Inspection Report.............................................. 2-881 2.12.8. Analysis of Content-Cask Lid Impact......................................... 2-891 2.12.9. Comparison of Libra Static and Dynamic Impact Analysis......................... 2-895 2.12.10. Effect of Ribs on Stress at Foam-Cask Interface............................... 2-913 2.12.11. Analysis of 30-Ft. Drops with Shipping Cages................................. 2-917 2.12.12. Analysis of Tie-Down Devices............................................. 2-926 2.12.13. Certificate of Conformance, General Plastics FR-3700 Series Foam -

AOS-165A Prototype.................................................. 2-947 2.12.14. Analysis of Shipping Cage Lifting Bars - Models AOS-050A and AOS-100.......... 2-949 2.12.15. Shielding/Spacer Component Evaluation -

Models AOS-050A, AOS-100A, and AOS-100A-S............................ 2-967 2.13. REFERENCES............................................................. 2-985

3. Thermal Evaluation..............................................................3-1 3.1. DESCRIPTION OF THERMAL DESIGN............................................. 3-1 3.1.1. Design Features............................................................ 3-1 3.1.2. Contents Decay Heat........................................................ 3-2 3.1.3. Summary Tables of Temperatures.............................................. 3-3 3.1.4. Summary Tables of Maximum Pressures........................................ 3-11 3.2. MATERIAL PROPERTIES AND COMPONENT SPECIFICATIONS....................... 3-12 3.2.1. Material Properties......................................................... 3-12 3.2.2. Component Specifications................................................... 3-19 3.3. THERMAL EVALUATION UNDER NORMAL CONDITIONS OF TRANSPORT.............. 3-20 3.3.1. Heat and Cold............................................................. 3-20 3.3.2. Maximum Normal Operating Pressure.......................................... 3-21 3.3.3. Thermal Finite Element Model................................................ 3-21 3.3.4. Normal Conditions of Transport Thermal Results.................................. 3-45 3.4. THERMAL EVALUATION UNDER HYPOTHETICAL ACCIDENT CONDITIONS............ 3-46 3.4.1. Initial Conditions........................................................... 3-48 3.4.2. Fire Test Conditions........................................................ 3-48 3.4.3. Maximum Temperatures and Pressures......................................... 3-48 3.4.4. Maximum Thermal Stresses.................................................. 3-48 3.4.5. Accident Conditions for Fissile Material Packages for Air Transport................... 3-48 3.4.6. Hypothetical Accident Conditions of Transport Thermal Results...................... 3-49 3.5. APPENDIX.................................................................. 3-51 3.5.1. Data CDs................................................................ 3-52 3.5.2. Thermal Evaluation Results - Models AOS-025, AOS-050, and AOS-100.............. 3-53 3.5.3. LIBRA Finite Element Program Heat Transfer Module............................. 3-262 3.5.4. Analysis Modeling Data.................................................... 3-268 3.5.5. LIBRA File Input Showing Material Property Assignation........................... 3-388 3.5.6. Justification for Use of Uniformly Distributed Decay Heat throughout Cask Cavity....... 3-411 3.5.7. Thermal Tests............................................................ 3-425 3.5.8. Heat Test Report - AOS-165A Prototype....................................... 3-439

Radioactive Material Transport Packaging System Safety Analysis Report vii for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316) 3.5.9. Copper Seal Locations with Analytical Model (with Cask Lid Metallic Seal)............. 3-861 3.5.10. Garlock Helicoflex Report, Helicoflex Seal Temperature Limit - Cask Lid Metallic Seal.. 3-865 3.6. REFERENCES.............................................................. 3-881

4. Containment...................................................................4-1 4.1. DESCRIPTION OF THE CONTAINMENT SYSTEM.................................... 4-1 4.1.1. Containment Boundary....................................................... 4-1 4.1.2. Containment Penetrations (Port Plugs).......................................... 4-4 4.1.3. Cask Lid Seal.............................................................. 4-6 4.1.4. Closure................................................................... 4-8 4.1.5. Keensert Device Evaluation.................................................. 4-18 4.2. CONTAINMENT UNDER NORMAL CONDITIONS OF TRANSPORT..................... 4-29 4.2.1. Containment of Radioactive Material........................................... 4-29 4.2.2. Pressurization of Containment Boundary........................................ 4-29 4.2.3. Containment Criterion....................................................... 4-30 4.3. CONTAINMENT UNDER HYPOTHETICAL ACCIDENT CONDITIONS.................... 4-31 4.3.1. Containment of Radioactive Material........................................... 4-32 4.3.2. Containment Criterion....................................................... 4-32 4.3.3. Fission Gas Products....................................................... 4-32 4.4. LEAKAGE RATE TESTS FOR TYPE B PACKAGES.................................. 4-32 4.5. APPENDIX.................................................................. 4-33 4.5.1. Garlock Helicoflex Cask Lid Metallic Seal and AOS Cask Lid Elastomeric Seal Drawings.. 4-35 4.5.2. Fortran Program Used to Analyze Cask Lid Attachment Bolts (Reference [4.6]).......... 4-43 4.5.3. Cask Lid Attachment Bolt Fortran Program Input/Output Files........................ 4-55 4.6. REFERENCES.............................................................. 4-216
5. Shielding Evaluation.............................................................5-1 5.1. DESCRIPTION OF SHIELDING DESIGN............................................ 5-1 5.1.1. Design Features............................................................ 5-1 5.1.2. Summary Table of Maximum Radiation Levels.................................... 5-5 5.2. SOURCE SPECIFICATION....................................................... 5-6 5.2.1. Gamma Source............................................................ 5-7 5.2.2. Neutron Source............................................................ 5-8 5.3. SHIELDING MODEL............................................................ 5-9 5.3.1. Configuration of Source and Shielding........................................... 5-9 5.3.2. Material Properties......................................................... 5-16 5.4. SHIELDING EVALUATION...................................................... 5-17 5.4.1. Methods................................................................. 5-17 5.4.2. Input and Output Data...................................................... 5-19 5.4.3. Flux-to-Dose-Rate Conversion................................................ 5-19 5.4.4. External Radiation Levels.................................................... 5-20 5.5. APPENDIX.................................................................. 5-29 5.5.1. AOS Cask Isotopic Heat Load Calculations...................................... 5-29 5.5.2. Isotope Values for Calculations............................................... 5-31 5.5.3. MCNP6 Input and Output Files for Dose Calculations.............................. 5-42 5.5.4. Cobalt-60-C Volume Source Calculation Study................................... 5-42 5.5.5. Shipments of Multiple Isotopes under 10 CFR 71.47(a)............................. 5-45 5.5.6. Isotopes Insignificant to External Dose Rates.................................... 5-49 5.5.7. 10 CFR 71.47(b) Exclusive Use Activity Limits for Models AOS-100A and AOS-100A-S... 5-52 5.5.8. Evaluation of Dose Rate Tally Locations........................................ 5-58 5.6. REFERENCES............................................................... 5-82

viii Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

6. Criticality Evaluation.............................................................6-1
7. Package Operations.............................................................7-1 7.1. PACKAGE LOADING........................................................... 7-6 7.1.1. Preparation for Loading...................................................... 7-6 7.1.2. Loading of Contents......................................................... 7-8 7.1.3. Preparation for Transport.................................................... 7-10 7.2. PACKAGE UNLOADING........................................................ 7-18 7.2.1. Receipt of Package from Carrier.............................................. 7-19 7.2.2. Removal of Contents....................................................... 7-20 7.2.3. Installing the Cask Lid...................................................... 7-20 7.2.4. Removing the Cask from the Staging Area...................................... 7-21 7.2.5. Securing the Cask Lid...................................................... 7-21 7.3. PREPARATION OF EMPTY PACKAGE FOR TRANSPORT............................ 7-22 7.3.1. Inspecting the Cask Cavity................................................... 7-22 7.3.2. Installing and Securing the Cask Lid........................................... 7-22 7.3.3. Leak Testing to Verify the Assembly........................................... 7-23 7.3.4. Preparing the Empty Cask for Transport........................................ 7-23 7.4. OTHER OPERATIONS......................................................... 7-24 7.4.1. Records and Reporting Requirements.......................................... 7-24 7.5. APPENDIX.................................................................. 7-25 7.5.1. Dose Rate and Decay Heat Limit Compliance.................................... 7-25 7.6. REFERENCES............................................................... 7-28
8. Acceptance Tests and Maintenance Program........................................8-1 8.1. ACCEPTANCE TESTS.......................................................... 8-1 8.1.1. Visual Inspections and Measurements........................................... 8-3 8.1.2. Weld Examinations.......................................................... 8-3 8.1.3. Structural and Pressure Tests................................................. 8-3 8.1.4. Leakage Tests............................................................. 8-4 8.1.5. Component and Material Tests................................................ 8-4 8.1.6. Shielding Tests............................................................ 8-14 8.1.7. Thermal Tests............................................................. 8-15 8.1.8. Miscellaneous Tests........................................................ 8-16 8.2. MAINTENANCE PROGRAM..................................................... 8-17 8.2.1. Structural and Pressure Tests................................................ 8-17 8.2.2. Leakage Tests [8.4]........................................................ 8-17 8.2.3. Component and Material Tests............................................... 8-19 8.2.4. Thermal Tests............................................................. 8-19 8.2.5. Miscellaneous Tests........................................................ 8-19 8.3. APPENDIX (NONE)............................................................ 8-20 8.4. REFERENCES............................................................... 8-21
9. Quality Assurance Program.......................................................9-1 9.1. U.S. QUALITY ASSURANCE PROGRAM REQUIREMENTS............................ 9-1 9.2. IAEA QUALITY ASSURANCE PROGRAM REQUIREMENTS............................ 9-1 9.3. APPENDIX................................................................... 9-2 9.3.1. U.S. Nuclear Regulatory Commission Quality Assurance Program Approval for Radioactive Material Packages No. 0086, Revision 9, Dated August 7, 2015.......................................... 9-2 9.4. REFERENCES................................................................ 9-5

Radioactive Material Transport Packaging System Safety Analysis Report ix for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

FIGURES

1. General Information Figure 1-1.

Isometric View - Model AOS-025A............................................... 1-3 Figure 1-2.

Isometric View - Model AOS-050A............................................... 1-4 Figure 1-3.

Isometric View - Models AOS-100A and AOS-100B................................. 1-5 Figure 1-4.

Isometric View - Model AOS-100A-S............................................. 1-6

2. Structural Evaluation Figure 2-1.

Assembled Transport Package Cutaway - Model AOS-025A.......................... 2-3 Figure 2-2.

Assembled Transport Package Cutaway - Model AOS-050A.......................... 2-4 Figure 2-3.

Assembled Transport Package Cutaway - Models AOS-100A and AOS-100B............. 2-5 Figure 2-4.

Isometric View - Typical Cask.................................................. 2-6 Figure 2-5.

Isometric View - Typical Impact Limiter........................................... 2-7 Figure 2-6.

Axisymmetric (2D) Model - Models AOS-025, AOS-050, and AOS-100................. 2-15 Figure 2-7.

3D Model - Models AOS-025, AOS-050, and AOS-100.............................. 2-16 Figure 2-8.

3D Rendered Model - Models AOS-025, AOS-050, and AOS-100..................... 2-16 Figure 2-9.

Pm and Pb Stress Monitoring Points - All Models................................... 2-17 Figure 2-10.

Center of Gravity - Model AOS-025............................................. 2-24 Figure 2-11.

Center of Gravity - Model AOS-050............................................. 2-25 Figure 2-12.

Center of Gravity - Model AOS-100............................................. 2-26 Figure 2-13.

Trunnion Area Cross-Section and Force Diagram Associated with Lifting Loads........... 2-44 Figure 2-14.

Mesh Diagonal Tension....................................................... 2-52 Figure 2-15.

Side Drop Impact Forces...................................................... 2-59 Figure 2-16.

Cask and Impact Limiter FEA Model - Model AOS-100.............................. 2-61 Figure 2-17.

Cask and Impact Limiter Deformed FEA Model - Model AOS-100...................... 2-61 Figure 2-18.

Critical Stress at Skin and J-Bolt Box Connection - Model AOS-025.................... 2-66 Figure 2-19.

Critical Stress at Rib Connector Pins Bearing - Models AOS-050 and AOS-100.......... 2-67 Figure 2-20.

LIBRA Liner Model - Model AOS-025............................................ 2-70 Figure 2-21.

Equivalent Stress Due to Longitudinal Acceleration - Model AOS-025.................. 2-71 Figure 2-22.

Equivalent Stress Due to Transverse Acceleration - Model AOS-025................... 2-72 Figure 2-23.

DELETED................................................................. 2-73 Figure 2-24.

DELETED................................................................. 2-73 Figure 2-25.

Typical Corner Cask Cavity Shell Weld Joint Configuration - All Models................. 2-78 Figure 2-26.

Fixed Points for Shock and Vibration Analyses..................................... 2-81 Figure 2-27.

Head-On, Side, and Slap-Down Free-Drop Orientations............................. 2-83 Figure 2-28.

Rod Impact Analysis Load Distribution - Model AOS-100............................ 2-84 Figure 2-29.

Rod Impact Time History Displacement at Impact Node - Model AOS-100............... 2-85 Figure 2-30.

Head-On, Side, and Slap-Down Free-Drop Orientations............................. 2-94 Figure 2-31.

Test Setup (Head-On Orientation Shown) - AOS-165A Prototype...................... 2-96 Figure 2-32.

Finite Element Model of Impact Limiter - Model AOS-100............................ 2-98 Figure 2-33.

Head-On Drop Force and Energy - Model AOS-100................................ 2-98 Figure 2-34.

Head-On Drop, Maximum Foam Displacement (Deformed Model) - Model AOS-100....... 2-99 Figure 2-35.

Head-On Drop, Maximum Equivalent Stress in Foam - Model AOS-100................. 2-99 Figure 2-36.

Head-On Drop Analysis Load Distribution - All Models............................. 2-100 Figure 2-37.

Sectioned Impact Limiter Used in Head-On Drop - AOS-165A Prototype............... 2-103 Figure 2-38.

Impact Limiter after Head-On Drop - AOS-165A Prototype.......................... 2-104 Figure 2-39.

Rendered LIBRA Deformed Head-On Drop - AOS-165A Prototype.................... 2-105 Figure 2-40.

Photograph Frames from High-Speed Video of Head-On Drop - AOS-165A Prototype.... 2-106 Figure 2-41.

Impact Response for Damping, = 0.06 - AOS-165A Prototype....................... 2-107 Figure 2-42.

Head-On Drop Force and Energy - AOS-165A Prototype........................... 2-108 Figure 2-43.

Side Drop Force and Energy - Model AOS-100................................... 2-109 Figure 2-44.

Side Drop, Maximum Foam Displacement (Deformed Model) - Model AOS-100......... 2-110 Figure 2-45.

Side Drop, Maximum Equivalent Stress in Foam - Model AOS-100................... 2-110 Figure 2-46.

Side Drop, Maximum Principal Strain in Foam - Model AOS-100..................... 2-111 Figure 2-47.

Side Drop Analysis Load Distribution - All Models................................. 2-113

x Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Figure 2-48.

Slap Finite Element Model - AOS-165A Prototype................................. 2-116 Figure 2-49.

Maximum Support Displacement versus Offset - AOS-165A Prototype................. 2-117 Figure 2-50.

Slap-Down Analysis Support Displacements versus Time - AOS-165A Prototype........ 2-117 Figure 2-51.

Cg/Corner Drop Analysis Load Distribution - All Models............................ 2-119 Figure 2-52.

Head-On Drop Cask Model................................................... 2-122 Figure 2-53.

Side+Slap-Down and Cg/Corner Drop Cask Model................................ 2-123 Figure 2-54.

Force-Displacement for Head-On Drop at 75°F - Model AOS-025.................... 2-124 Figure 2-55.

Force-Displacement for Side Drop at 75°F - Model AOS-025........................ 2-125 Figure 2-56.

Force-Displacement for Cg/Corner Drop at 75°F - Model AOS-025................... 2-126 Figure 2-57.

Force-Displacement for Head-On Drop at 75°F - Model AOS-050.................... 2-127 Figure 2-58.

Force-Displacement for Side Drop at 75°F - Model AOS-050........................ 2-128 Figure 2-59.

Force-Displacement for Cg/Corner Drop at 75°F - Model AOS-050................... 2-129 Figure 2-60.

Force-Displacement for Head-On Drop at 75°F - Model AOS-100.................... 2-130 Figure 2-61.

Force-Displacement for Head-On Drop at -40°F - Model AOS-100.................... 2-131 Figure 2-62.

Force-Displacement for Side Drop at 75°F - Model AOS-100........................ 2-132 Figure 2-63.

Force-Displacement for Cg/Corner Drop at 75°F - Model AOS-100................... 2-133 Figure 2-64.

Impact Load Distributions.................................................... 2-134 Figure 2-65.

Circumferential Impact Load Distribution for Side and Cg/Corner Drops................ 2-134 Figure 2-66.

Side Impact Slap-Down Analysis.............................................. 2-138 Figure 2-67.

FEA Model of Puncture Drop................................................. 2-146 Figure 2-68.

Generalized Model of Impact I................................................ 2-891 Figure 2-69.

Dynamic Analysis FEA Model................................................. 2-896 Figure 2-70.

Cask Displacement Time-History.............................................. 2-897 Figure 2-71.

Ground Impact Forces in Dynamic Model........................................ 2-898 Figure 2-72.

Total Ground Impact Force in Dynamic Model.................................... 2-899 Figure 2-73.

Deformed Dynamic Model at Maximum Displacement.............................. 2-900 Figure 2-74.

Displacement Contours n Deformed Dynamic Model............................... 2-900 Figure 2-75.

Foam Static Analysis FEA Model.............................................. 2-901 Figure 2-76.

Deformed Foam Static Model at Maximum Displacement........................... 2-901 Figure 2-77.

Energy and Force Plots for Static Analysis....................................... 2-902 Figure 2-78.

Energy and Force Plots for Static Analysis with Bi-Linear Stress-Strain................. 2-903 Figure 2-79.

foam-cask.t5 LIBRA Model................................................... 2-910 Figure 2-80.

FEA Model Used in Rib Study................................................. 2-913 Figure 2-81.

FEA Model Section Showing Rib.............................................. 2-914 Figure 2-82.

Z-Cask Section Z-Displacements.............................................. 2-915 Figure 2-83.

Cask Section Z-Stress....................................................... 2-916 Figure 2-84.

Configuration of Cask and Pallet Impact......................................... 2-917 Figure 2-85.

AGS Model and Typical Input File.............................................. 2-918 Figure 2-86.

Bilinear Representation of Head-On Force-Displacement - Model AOS-100............. 2-920 Figure 2-87.

Trilinear Representation of Cg/Corner Force-Displacement - Model AOS-100........... 2-921 Figure 2-88.

Model AOS-100 Cg/Corner Pallet and Cask Displacements.......................... 2-924 Figure 2-89.

Model AOS-100 Cg/Corner Pallet and Ground Impact Forces........................ 2-924 Figure 2-90.

Tie-Down Schematic........................................................ 2-926 Figure 2-91.

Bearing Traction Along Line = 0 - 180......................................... 2-927 Figure 2-92.

Schematic of Lateral Bearing Forces........................................... 2-929 Figure 2-93.

Tension Cables - Model AOS-100............................................. 2-931 Figure 2-94.

Bearing Pressure and Cable Forces............................................ 2-933 Figure 2-95.

FEA Model of Tie-Down Ring................................................. 2-935 Figure 2-96.

Lateral (Z) Displacement in Conical Shell - Model AOS-100......................... 2-937 Figure 2-97.

Maximum Principal Membrane Stress - Model AOS-100............................ 2-937 Figure 2-98.

Maximum Principal Membrane Stress - Model AOS-050............................ 2-944 Figure 2-99.

Tie-Down Strap Load - Model AOS-025......................................... 2-945 Figure 2-100. Lateral (Z) Displacement in Conical Shell - Model AOS-050......................... 2-946 Figure 2-101. Shipping Cage and Lifting Bar - Model AOS-050A................................. 2-950 Figure 2-102. Lifting Bar - Model AOS-050A................................................ 2-950 Figure 2-103. Deformation of Frame and Lifting Bar under Inertia Loading - Model AOS-050A......... 2-952 Figure 2-104. Equivalent Stress within Shipping Cage Frame and Lifting Bar - Model AOS-050A....... 2-953 Figure 2-105. Lifting Bar First Buckling Mode - Model AOS-050A................................ 2-955 Figure 2-106. Shipping Cage and Lifting Bar - Model AOS-100.................................. 2-957

Radioactive Material Transport Packaging System Safety Analysis Report xi for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Figure 2-107. Lifting Bar - Model AOS-100.................................................. 2-957 Figure 2-108. Model of Lifting Bar Bolted Connection - Model AOS-100........................... 2-957 Figure 2-109. Shipping Cage Vertical Displacements - Model AOS-100........................... 2-960 Figure 2-110. Shipping Cage von Mises Equivalent Stress - Model AOS-100....................... 2-960 Figure 2-111. Lifting Bar von Mises Equivalent Stress - Model AOS-100........................... 2-961 Figure 2-112. Deformation of Frame and Lifting Bar Under Inertia Loading - Model AOS-100.......... 2-962 Figure 2-113. Lifting Bar First Buckling Mode - Model AOS-100................................. 2-966 Figure 2-114. Lifting Bar Second Buckling Mode - Model AOS-100............................... 2-966 Figure 2-115. Model AOS-100A-S Co-60-C Configuration with Axial Shielding Plates and Cavity Spacer Plates............................... 2-968 Figure 2-116. Axial Shielding Plate ANSYS Model - Model AOS-050A............................ 2-971 Figure 2-117. Axial Shielding Plate End Drop ANSYS Stress Results - Model AOS-050A............. 2-973 Figure 2-118. Axial Shielding Plate Side Drop ANSYS Stress Results - Model AOS-050A............. 2-974 Figure 2-119. Axial Shielding Plate Corner Drop ANSYS Stress Results - Model AOS-050A........... 2-974 Figure 2-120. Axial Shielding Plate - Models AOS-100A and AOS-100A-S......................... 2-975 Figure 2-121. ANSYS Model Contact Elements - Models AOS-100A and AOS-100A-S............... 2-976 Figure 2-122. ANSYS Surface Effect Elements - Models AOS-100A and AOS-100A-S............... 2-977 Figure 2-123. Axial Shielding Plate Hypothetical Accident Conditions of Transport End Drop Stress Intensity Results (psi) - Model AOS-100A and AOS-100A-S........... 2-979 Figure 2-124. Axial Shielding Plate Hypothetical Accident Conditions of Transport Side Drop Stress Intensity Results (psi) - Model AOS-100A and AOS-100A-S........... 2-980 Figure 2-125. Axial Shielding Plate Hypothetical Accident Conditions of Transport Corner Drop Stress Intensity Results (psi) - Model AOS-100A and AOS-100A-S......... 2-980 Figure 2-126. Cavity Spacer Plate Stress ANSYS Model - Models AOS-100A and AOS-100A-S........ 2-981 Figure 2-127. Cavity Spacer Plate End Drop ANSYS Stress Results -

Models AOS-100A and AOS-100A-S........................................... 2-983 Figure 2-128. Cavity Spacer Plate Side Drop ANSYS Stress Results -

Models AOS-100A and AOS-100A-S........................................... 2-984 Figure 2-129. Cavity Spacer Plate Corner Drop ANSYS Stress Results -

Models AOS-100A and AOS-100A-S........................................... 2-984

3. Thermal Evaluation Figure 3-1.

Analytical FEA Model - Normal Conditions of Transport............................. 3-22 Figure 3-2.

Cask Assembly External Surface Identification, Normal Conditions of Transport -

All Models (Typical; Surfaces 5, 6, 7, and 8 are not used on Model AOS-025)............ 3-32 Figure 3-3.

Cask Assembly External Surface Identification, Fire Condition -

All Models (Typical; Surfaces 5, 6, 7, and 8 are not used on Model AOS-025)............ 3-34 Figure 3-4.

Expanded View of Thermal Model Defining Component Interfaces..................... 3-44 Figure 3-5.

Thermal Finite Element Model - Fire Conditions................................... 3-47 Figure 3-6.

Selected Nodal Locations for Normal Conditions of Transport - Model AOS-025A......... 3-57 Figure 3-7.

Load Case 101, 100°F Ambient, Maximum Decay Heat, Entire Model - Model AOS-025A... 3-60 Figure 3-8.

Load Case 101, 100°F Ambient, Maximum Decay Heat, Cask Model - Model AOS-025A... 3-61 Figure 3-9.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-025A............................................... 3-64 Figure 3-10.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-025A................................................ 3-65 Figure 3-11.

Load Case 103, -20°F Ambient, Zero Decay Heat, Zero Insolation, Entire Model - Model AOS-025A............................................... 3-67 Figure 3-12.

Load Case 104, -40°F Ambient, Zero Decay Heat, Zero Insolation, Entire Model - Model AOS-025A............................................... 3-69 Figure 3-13.

Load Case 105, -40°F Ambient, Maximum Decay Heat, Entire Model - Model AOS-025A... 3-72 Figure 3-14.

Load Case 105, -40°F Ambient, Maximum Decay Heat, Cask Model - Model AOS-025A.... 3-73 Figure 3-15.

Load Case 106, -20°F Ambient, Maximum Decay Heat, Entire Model - Model AOS-025A... 3-76 Figure 3-16.

Load Case 106, -20°F Ambient, Maximum Decay Heat, Cask Model - Model AOS-025A.... 3-77 Figure 3-17.

Selected Nodal Locations for Fire Condition - Model AOS-025A....................... 3-79 Figure 3-18.

Fire for 30 Minutes and Post Fire Cool Down for 7.5 Hours, Temperature versus Time, for Cask Cavity Shell, Cask Lid, Cask Lid Plug, Bottom Plate, and Tungsten Alloy - Model AOS-025A.......................................... 3-80

xii Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Figure 3-19.

Fire for 30 Minutes and Post Fire Cool Down for 7.5 Hours, Temperature versus Time, for Cask Lid Seal Area, Cask Vent Port, Cask Drain Port, and Test Port - Model AOS-025A............................................... 3-81 Figure 3-20.

Fire for 30 Minutes and Post Fire Cool Down for 7.5 Hours, Temperature versus Time, for Cask Outer Shell and Impact Limiter - Model AOS-025A.... 3-82 Figure 3-21.

Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Entire Model - Model AOS-025A............................................... 3-85 Figure 3-22.

Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Cask Model - Model AOS-025A................................................ 3-86 Figure 3-23.

Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-025A.............................. 3-89 Figure 3-24.

Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-025A............................... 3-90 Figure 3-25.

Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-025A.............................. 3-93 Figure 3-26.

Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-025A............................... 3-94 Figure 3-27.

Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-025A.............................. 3-97 Figure 3-28.

Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-025A............................... 3-98 Figure 3-29.

Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-025A............................. 3-101 Figure 3-30.

Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-025A.............................. 3-102 Figure 3-31.

Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-025A............................. 3-105 Figure 3-32.

Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-025A.............................. 3-106 Figure 3-33.

Selected Nodal Locations for Normal Conditions of Transport - Model AOS-050A........ 3-110 Figure 3-34.

Load Case 101, 100°F Ambient, Maximum Decay Heat, Entire Model - Model AOS-050A.. 3-113 Figure 3-35.

Load Case 101, 100°F Ambient, Maximum Decay Heat, Cask Model - Model AOS-050A.. 3-114 Figure 3-36.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-050A.............................................. 3-117 Figure 3-37.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-050A............................................... 3-118 Figure 3-38.

Load Case 103, -20°F Ambient, Zero Decay Heat, Zero Insolation, Entire Model - Model AOS-050A.............................................. 3-120 Figure 3-39.

Load Case 104, -40°F Ambient, Zero Decay Heat, Zero Insolation, Entire Model - Model AOS-050A.............................................. 3-122 Figure 3-40.

Load Case 105, -40°F Ambient, Maximum Decay Heat, Entire Model - Model AOS-050A.. 3-125 Figure 3-41.

Load Case 105, -40°F Ambient, Maximum Decay Heat, Cask Model - Model AOS-050A... 3-126 Figure 3-42.

Load Case 106, -20°F Ambient, Maximum Decay Heat, Entire Model - Model AOS-050A.. 3-129 Figure 3-43.

Load Case 106, -20°F Ambient, Maximum Decay Heat, Cask Model - Model AOS-050A... 3-130 Figure 3-44.

Selected Nodal Locations for Fire Condition - Model AOS-050A...................... 3-132 Figure 3-45.

Fire for 30 Minutes and Post Fire Cool Down for 7.5 Hours, Temperature versus Time, for Cask Cavity Shell, Cask Lid, Cask Lid Plug, Bottom Plate, and Tungsten Alloy - Model AOS-050A......................................... 3-133 Figure 3-46.

Fire for 30 Minutes and Post Fire Cool Down for 7.5 Hours, Temperature versus Time, for Cask Lid Seal Area, Cask Vent Port, Cask Drain Port, and Test Port - Model AOS-050A.............................................. 3-134 Figure 3-47.

Fire for 30 Minutes and Post Fire Cool Down for 7.5 Hours, Temperature versus Time, for Cask Outer Shell and Impact Limiter - Model AOS-050A... 3-135 Figure 3-48.

Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Entire Model - Model AOS-050A.............................................. 3-138 Figure 3-49.

Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Cask Model - Model AOS-050A............................................... 3-139 Figure 3-50.

Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-050A............................. 3-142

Radioactive Material Transport Packaging System Safety Analysis Report xiii for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Figure 3-51.

Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-050A.............................. 3-143 Figure 3-52.

Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-050A............................. 3-146 Figure 3-53.

Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-050A.............................. 3-147 Figure 3-54.

Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-050A............................. 3-150 Figure 3-55.

Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-050A.............................. 3-151 Figure 3-56.

Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-050A............................. 3-154 Figure 3-57.

Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-050A.............................. 3-155 Figure 3-58.

Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-050A............................. 3-158 Figure 3-59.

Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-050A.............................. 3-159 Figure 3-60.

Selected Nodal Locations for Normal Conditions of Transport - Model AOS-100......... 3-163 Figure 3-61.

Load Case 101, 100°F Ambient, Maximum Decay Heat, Entire Model -

Models AOS-100A and AOS-100A-S........................................... 3-166 Figure 3-62.

Load Case 101, 100°F Ambient, Maximum Decay Heat, Cask Model -

Models AOS-100A and AOS-100A-S........................................... 3-167 Figure 3-63.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Entire Model - Models AOS-100A and AOS-100A-S............................... 3-170 Figure 3-64.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Cask Model - Models AOS-100A and AOS-100A-S................................ 3-171 Figure 3-65.

Load Case 103, -20°F Ambient, Zero Decay Heat, Zero Insolation, Entire Model - Models AOS-100A and AOS-100A-S............................... 3-173 Figure 3-66.

Load Case 104, -40°F Ambient, Zero Decay Heat, Zero Insolation, Entire Model - Models AOS-100A and AOS-100A-S............................... 3-175 Figure 3-67.

Load Case 105, -40°F Ambient, Maximum Decay Heat, Entire Model -

Models AOS-100A and AOS-100A-S........................................... 3-178 Figure 3-68.

Load Case 105, -40°F Ambient, Maximum Decay Heat, Cask Model -

Models AOS-100A and AOS-100A-S........................................... 3-179 Figure 3-69.

Load Case 106, -20°F Ambient, Maximum Decay Heat, Entire Model -

Models AOS-100A and AOS-100A-S........................................... 3-182 Figure 3-70.

Load Case 106, -20°F Ambient, Maximum Decay Heat, Cask Model -

Models AOS-100A and AOS-100A-S........................................... 3-183 Figure 3-71.

Selected Nodal Locations for Fire Condition - Model AOS-100....................... 3-185 Figure 3-72.

Fire for 30 Minutes and Post Fire Cool Down for 7.5 Hours, Temperature versus Time, for Cask Cavity Shell, Cask Lid, Cask Lid Plug, Bottom Plate, and Tungsten Alloy - Models AOS-100A and AOS-100A-S.......................... 3-186 Figure 3-73.

Fire for 30 Minutes and Post Fire Cool Down for 7.5 Hours, Temperature versus Time, for Cask Lid Seal Area, Cask Vent Port, Cask Drain Port, and Test Port - Models AOS-100A and AOS-100A-S.............................. 3-187 Figure 3-74.

Fire for 30 Minutes and Post Fire Cool Down for 7.5 Hours, Temperature versus Time, for Cask Outer Shell and Impact Limiter -

Models AOS-100A and AOS-100A-S........................................... 3-188 Figure 3-75.

Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Entire Model - Models AOS-100A and AOS-100A-S............................... 3-191 Figure 3-76.

Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Cask Model - Models AOS-100A and AOS-100A-S................................ 3-192 Figure 3-77.

Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Models AOS-100A and AOS-100A-S.............. 3-195 Figure 3-78.

Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Models AOS-100A and AOS-100A-S............... 3-196 Figure 3-79.

Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Models AOS-100A and AOS-100A-S.............. 3-199

xiv Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Figure 3-80.

Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Models AOS-100A and AOS-100A-S............... 3-200 Figure 3-81.

Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Models AOS-100A and AOS-100A-S.............. 3-203 Figure 3-82.

Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Models AOS-100A and AOS-100A-S............... 3-204 Figure 3-83.

Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Models AOS-100A and AOS-100A-S.............. 3-207 Figure 3-84.

Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Models AOS-100A and AOS-100A-S............... 3-208 Figure 3-85.

Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Models AOS-100A and AOS-100A-S.............. 3-211 Figure 3-86.

Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Models AOS-100A and AOS-100A-S............... 3-212 Figure 3-87.

Load Case 101, 100°F Ambient, Maximum Decay Heat, Entire Model - Model AOS-100B.. 3-216 Figure 3-88.

Load Case 101, 100°F Ambient, Maximum Decay Heat, Cask Model - Model AOS-100B.. 3-217 Figure 3-89.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-100B.............................................. 3-220 Figure 3-90.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-100B............................................... 3-221 Figure 3-91.

Load Case 103, -20°F Ambient, Zero Decay Heat, Zero Insolation, Entire Model - Model AOS-100B.............................................. 3-223 Figure 3-92.

Load Case 104, -40°F Ambient, Zero Decay Heat, Zero Insolation, Entire Model - Model AOS-100B.............................................. 3-225 Figure 3-93.

Load Case 105, -40°F Ambient, Maximum Decay Heat, Entire Model - Model AOS-100B.. 3-228 Figure 3-94.

Load Case 105, -40°F Ambient, Maximum Decay Heat, Cask Model - Model AOS-100B... 3-229 Figure 3-95.

Load Case 106, -20°F Ambient, Maximum Decay Heat, Entire Model - Model AOS-100B.. 3-232 Figure 3-96.

Load Case 106, -20°F Ambient, Maximum Decay Heat, Cask Model - Model AOS-100B... 3-233 Figure 3-97.

Fire for 30 Minutes and Post Fire Cool Down for 7.5 Hours, Temperature versus Time, for Cask Cavity Shell, Cask Lid, Cask Lid Plug, Bottom Plate, and Carbon Steel - Model AOS-100B.......................................... 3-235 Figure 3-98.

Fire for 30 Minutes and Post Fire Cool Down for 7.5 Hours, Temperature versus Time, for Cask Lid Seal Area, Cask Vent Port, Cask Drain Port, and Test Port - Model AOS-100B.............................................. 3-236 Figure 3-99.

Fire for 30 Minutes and Post Fire Cool Down for 7.5 Hours, Temperature versus Time, for Cask Outer Shell and Impact Limiter - Model AOS-100B... 3-237 Figure 3-100. Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Entire Model - Model AOS-100B.............................................. 3-240 Figure 3-101. Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Cask Model - Model AOS-100B............................................... 3-241 Figure 3-102. Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-100B............................. 3-244 Figure 3-103. Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-100B.............................. 3-245 Figure 3-104. Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-100B............................. 3-248 Figure 3-105. Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-100B.............................. 3-249 Figure 3-106. Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-100B............................. 3-252 Figure 3-107. Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Cask Model - Model AOS-100B.............................. 3-253 Figure 3-108. Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-100B............................. 3-256 Figure 3-109. Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Cask - Model AOS-100B.............................. 3-257 Figure 3-110. Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Model - Model AOS-100B............................. 3-260

Radioactive Material Transport Packaging System Safety Analysis Report xv for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Figure 3-111. Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Entire Cask - Model AOS-100B.............................. 3-261 Figure 3-112. SS304 Stainless Steel Thermal Conductivity..................................... 3-270 Figure 3-113. SS304 Stainless Steel Specific Heat............................................ 3-271 Figure 3-114. Tungsten Alloy Conductivity.................................................. 3-272 Figure 3-115. Tungsten Alloy Specific Heat................................................. 3-273 Figure 3-116. SA-105 Carbon Steel Conductivity............................................. 3-275 Figure 3-117. SA-105 Carbon Steel Specific Heat............................................ 3-276 Figure 3-118. Air Conductivity............................................................ 3-278 Figure 3-119. Air Specific Heat........................................................... 3-279 Figure 3-120. Air Density................................................................ 3-280 Figure 3-121. Normal Conditions of Transport Model Dimensions - Model AOS-025................. 3-281 Figure 3-122. Normal Conditions of Transport Model Dimensions - Model AOS-050................. 3-282 Figure 3-123. Normal Conditions of Transport Model Dimensions - Model AOS-100................. 3-283 Figure 3-124. Applied 30-ft. Drop Deformations - Model AOS-025............................... 3-284 Figure 3-125. Applied 30-ft. Drop Deformations - Model AOS-050............................... 3-285 Figure 3-126. Applied 30-ft. Drop Deformations - Model AOS-100............................... 3-285 Figure 3-127. Hypothetical Accident Conditions of Transport Model Dimensions - Model AOS-025...... 3-286 Figure 3-128. Hypothetical Accident Conditions of Transport Model Dimensions - Model AOS-050...... 3-287 Figure 3-129. Hypothetical Accident Conditions of Transport Model Dimensions - Model AOS-100...... 3-288 Figure 3-130. Cask Assembly External Surface Identification, Normal Conditions of Transport - Model AOS-025................................. 3-289 Figure 3-131. Cask Assembly External Surface Identification, Normal Conditions of Transport - Model AOS-050................................. 3-290 Figure 3-132. Cask Assembly External Surface Identification, Normal Conditions of Transport - Model AOS-100................................. 3-291 Figure 3-133. Cask Assembly External Surface Identification, Hypothetical Accident Conditions of Transport - Model AOS-025..................... 3-292 Figure 3-134. Cask Assembly External Surface Identification, Hypothetical Accident Conditions of Transport - Model AOS-050..................... 3-293 Figure 3-135. Cask Assembly External Surface Identification, Hypothetical Accident Conditions of Transport - Model AOS-100..................... 3-294 Figure 3-136. Configuration 1, Impact Limiters with 30-Ft. Head-On Drop Deformation -

Model AOS-100A FEA Model................................................. 3-297 Figure 3-137. Configuration 2, Impact Limiters with No Deformations -

Model AOS-100A FEA Model................................................. 3-298 Figure 3-138. Configuration 3, Impact Limiters with Full Crush Deformations from Three (3) Directions of Drop Applied Simultaneously - Model AOS-100A FEA Model...................... 3-299 Figure 3-139. Analysis FEA Model, Normal Conditions of Transport - Model AOS-025................ 3-302 Figure 3-140. Analysis FEA Model, Normal Conditions of Transport - Model AOS-050................ 3-303 Figure 3-141. Analysis FEA Model, Normal Conditions of Transport - Model AOS-100A.............. 3-304 Figure 3-142. Analysis FEA Model, Hypothetical Accident Conditions of Transport - Model AOS-025.... 3-305 Figure 3-143. Analysis FEA Model, Hypothetical Accident Conditions of Transport - Model AOS-050.... 3-306 Figure 3-144. Analysis FEA Model, Hypothetical Accident Conditions of Transport - Model AOS-100A... 3-307 Figure 3-145. Equivalent Conductivity at Enclosed Gaps 0.0118, 0.0124, 0.0176, 0.0147, 0.0403, and 0.0108 in. - Model AOS-025A............. 3-310 Figure 3-146. Equivalent Conductivity at Enclosed Gaps 0.0140, 0.0150, 0.0250, 0.0190, 0.0710, and 0.0120 in. - Model AOS-050A............. 3-312 Figure 3-147. Equivalent Conductivity at Enclosed Gaps 0.0170, 0.0200, 0.0290, and 0.0130 in. - Model AOS-100A.......................... 3-314 Figure 3-148. Equivalent Conductivity at Enclosed Gaps 0.0400 and 0.1310 in. - Model AOS-100A....................................... 3-315 Figure 3-149. Equivalent Conductivity at Enclosed Gaps 0.0170, 0.0200, 0.0290, and 0.0130 in. - Model AOS-100B.......................... 3-318 Figure 3-150. Equivalent Conductivity at Enclosed Gaps 0.0400 and 0.1310 in. - Model AOS-100B....................................... 3-319 Figure 3-151. Air Kinematic Viscosity...................................................... 3-321 Figure 3-152. Cask Assembly External Surface Identification, Normal Conditions of Transport - Model AOS-025................................. 3-326

xvi Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Figure 3-153. Surface Convective Coefficients at 100°F Ambient Temperature, Normal Conditions of Transport - Model AOS-025................................. 3-328 Figure 3-154. Surface Convective Coefficients at -20°F Ambient Temperature, Normal Conditions of Transport - Model AOS-025................................. 3-330 Figure 3-155. Surface Convective Coefficients at -40°F Ambient Temperature, Normal Conditions of Transport - Model AOS-025................................. 3-332 Figure 3-156. Cask Assembly External Surface Identification, Normal Conditions of Transport - Model AOS-050................................. 3-334 Figure 3-157. Surface Convective Coefficients at 100°F Ambient Temperature for Surfaces 1, 2, 3, and 11, Normal Conditions of Transport - Model AOS-050.......... 3-336 Figure 3-158. Surface Convective Coefficients at 100°F Ambient Temperature for Surfaces 4, 5, and 6, Normal Conditions of Transport - Model AOS-050............. 3-337 Figure 3-159. Surface Convective Coefficients at -20°F Ambient Temperature for Surfaces 1, 2, 3, and 11, Normal Conditions of Transport - Model AOS-050.......... 3-339 Figure 3-160. Surface Convective Coefficients at -20°F Ambient Temperature for Surfaces 4, 5, and 6, Normal Conditions of Transport - Model AOS-050............. 3-340 Figure 3-161. Surface Convective Coefficients at -40°F Ambient Temperature for Surfaces 1, 2, 3, and 11, Normal Conditions of Transport - Model AOS-050.......... 3-342 Figure 3-162. Surface Convective Coefficients at -40°F Ambient Temperature for Surfaces 4, 5, and 6, Normal Conditions of Transport - Model AOS-050............. 3-343 Figure 3-163. Cask Assembly External Surface Identification, Normal Conditions of Transport - Models AOS-100A and AOS-100B.................. 3-345 Figure 3-164. Surface Convective Coefficients at 100°F Ambient Temperature, Normal Conditions of Transport - Models AOS-100A and AOS-100B.................. 3-347 Figure 3-165. Surface Convective Coefficients at -20°F Ambient Temperature, Normal Conditions of Transport - Models AOS-100A and AOS-100B.................. 3-349 Figure 3-166. Surface Convective Coefficients at -40°F Ambient Temperature, Normal Conditions of Transport - Models AOS-100A and AOS-100B.................. 3-351 Figure 3-167. Cask Assembly External Surface Identification, Hypothetical Accident Conditions of Transport - Model AOS-025..................... 3-352 Figure 3-168. Surface Convective Coefficients at 100°F Ambient Temperature, Fire Condition - Model AOS-025.............................................. 3-354 Figure 3-169. Cask Assembly External Surface Identification, Hypothetical Accident Conditions of Transport - Model AOS-050..................... 3-356 Figure 3-170. Surface Convective Coefficients at 100°F Ambient Temperature for Surfaces 3, 4, 5, 6, 8, and 11, Hypothetical Accident Conditions of Transport - Model AOS-050................................................ 3-358 Figure 3-171. Cask Assembly External Surface Identification, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100B....... 3-360 Figure 3-172. Surface Convective Coefficients at 100°F Ambient Temperature, Fire Condition - Models AOS-100A and AOS-100B................................ 3-362 Figure 3-173. Surface Convective Coefficients under Fire Condition at 1,475°F Environment - All Models........................................... 3-364 Figure 3-174. Maximum Decay Heat, 100°F Ambient, 24-Hour Transient with 12-Hour Solar Heat and 12-Hour Cool-Down Cycle, Maximum Temperature for Foam Inside Impact Limiter, Node 9952 - Model AOS-025A...................... 3-371 Figure 3-175. Maximum Decay Heat, 100°F Ambient, 24-Hour Transient with 12-Hour Solar Heat and 12-Hour Cool-Down Cycle, Maximum Temperature for Foam Inside Impact Limiter, Node 9413 - Model AOS-050A...................... 3-372 Figure 3-176. Maximum Decay Heat, 100°F Ambient, 24-Hour Transient with 12-Hour Solar Heat and 12-Hour Cool-Down Cycle, Maximum Temperature for Foam Inside Impact Limiter, Node 9079 - Model AOS-100A...................... 3-373 Figure 3-177. Maximum Decay Heat, 100°F Ambient, 24-Hour Transient with 12-Hour Solar Heat and 12-Hour Cool-Down Cycle, Maximum Temperature for Foam Inside Impact Limiter, Node 9079 - Model AOS-100B...................... 3-374 Figure 3-178. Case 1 - Temperature...................................................... 3-419 Figure 3-179. Case 2 - Temperature...................................................... 3-420 Figure 3-180. Case 3 - Temperature...................................................... 3-421

Radioactive Material Transport Packaging System Safety Analysis Report xvii for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Figure 3-181. Case 1 - Maximum Principal Stress at Cask Lid Corner............................. 3-422 Figure 3-182. Case 2 - Maximum Principal Stress at Cask Lid Corner............................. 3-423 Figure 3-183. Case 3 - Maximum Principal Stress at Cask Lid Corner............................. 3-424 Figure 3-184. Typical Thermal Test Setup.................................................. 3-426 Figure 3-185. Test Cask Modeling Features................................................. 3-428 Figure 3-186. Instrument Cask Inside Pit................................................... 3-429 Figure 3-187. Temperature versus Time - Heat Cycle for Thermocouples 3 through 12............... 3-431 Figure 3-188. Temperature versus Time - Heat Cycle for Thermocouples 10 through 16.............. 3-431 Figure 3-189. Temperature versus Time - Cooling Cycle for Thermocouples 3 through 12............. 3-432 Figure 3-190. Temperature versus Time - Cooling Cycle for Thermocouples 10 through 16............ 3-432 Figure 3-191. Verification Analysis - Axisymmetric (2D) Model of Test Cask........................ 3-433 Figure 3-192. Verification Analysis - Heat Cycle Boundary Conditions............................ 3-434 Figure 3-193. Verification Analysis - Cooling Cycle Boundary Conditions.......................... 3-434 Figure 3-194. Comparison Test Data versus Analytical Results - Center, Cask Bottom............... 3-435 Figure 3-195. Comparison Test Data versus Analytical Results - Center, Inside Cask Lid Surface....... 3-435 Figure 3-196. Comparison Test Data versus Analytical Results - Center, Outside Cask Lid Surface..... 3-436 Figure 3-197. Comparison Test Data versus Analytical Results - Middle, Cask Cavity Wall............ 3-436 Figure 3-198. Comparison Test Data versus Analytical Results - Middle, Outside Wall................ 3-437 Figure 3-199. Comparison Test Data versus Analytical Results - Cask Drain Port Area............... 3-437 Figure 3-200. Comparison Test Data versus Analytical Results - Cask Vent Port Area................ 3-438 Figure 3-201. Comparison Test Data versus Analytical Results - Test Port Area.................... 3-438 Figure 3-202. Boundary Nodes Excerpt, Copper Seal Locations - Model AOS-100................... 3-861 Figure 3-203. Cask Lid Metallic Seal, Test Port, Cask Vent Port, Cask Vent Port Seal, and Cask Vent Port Conical Seal Boundary Node Detail - Model AOS-100............. 3-862 Figure 3-204. Cask Drain Port, Cask Drain Port Seal, and Cask Drain Port Conical Seal Boundary Node Detail - Model AOS-100........................................ 3-863

4. Containment Figure 4-1.

Containment Boundary (Cask Lid Metallic Seal Shown)............................... 4-2 Figure 4-2.

Typical Corner Cask Cavity Shell Weld Joint Configuration - All Models.................. 4-3 Figure 4-3.

Typical Port Plug Configuration.................................................. 4-5 Figure 4-4.

Cask Lid Elastomeric and Metallic Seals.......................................... 4-6 Figure 4-5.

Cask Lid Showing the Cask Lid Metallic Seal Installed -

Attachment by way of Four (4) Screws, and Leak-Testing Hole......................... 4-7 Figure 4-6.

Cask Lid, Cask Lid Attachment Bolt, and Cask Temperature Evaluation Nodes............ 4-8

5. Shielding Evaluation Figure 5-1.

Cross-Sectional View of Cask Components........................................ 5-1 Figure 5-2.

Cask Component Half-Height - All Models......................................... 5-3 Figure 5-3.

MCNP6 Geometry Model...................................................... 5-9 Figure 5-4.

MCNP6 Point Source Locations................................................ 5-12 Figure 5-5.

Shielding Model Tallies for Top Source Location................................... 5-13 Figure 5-6.

Shielding Model Tallies for Side Source Location................................... 5-14 Figure 5-7.

Shielding Model Tallies for Corner Source Location................................. 5-14 Figure 5-8.

MCNP6 Volume Source Location/Geometries..................................... 5-44 Figure 5-9.

Exclusive Use MCNP Tally Locations............................................ 5-57 Figure 5-10.

Simplified 1D Dose Rate Calculations............................................ 5-58 Figure 5-11.

Impact Limiter Gap Dose Rate Locations - Model AOS-050A......................... 5-61 Figure 5-12.

Impact Limiter Gap Dose Rate Locations -

Models AOS-100A, AOS-100A-S, and AOS-100B.................................. 5-61 Figure 5-13.

Impact Limiter Gap Dose Rate Locations -

Ir-194 (Model AOS-050A) and Co-60-C (Models AOS-100A and AOS-100A-S)........... 5-65 Figure 5-14.

Example Cross-Sectional View Showing Impact Limiter Recessed Regions -

Models AOS-100A and AOS-100B Shown........................................ 5-66 Figure 5-15.

Transport Package Surface Tallies - Model AOS-025A.............................. 5-69 Figure 5-16.

Transport Package Surface Tallies - Model AOS-050A.............................. 5-71 Figure 5-17.

Recessed Region Model - Model AOS-050A...................................... 5-74

xviii Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Figure 5-18.

1-m TI Tallies - Models AOS-100A and AOS-100A-S............................... 5-76 Figure 5-19.

1-m TI Tallies - Model AOS-100B............................................... 5-79

6. Criticality Evaluation There are no figures in Chapter 6.
7. Package Operations Figure 7-1.

Isometric View - Model AOS-025A............................................... 7-2 Figure 7-2.

Isometric View - Model AOS-050A............................................... 7-3 Figure 7-3.

Isometric View - Models AOS-100A and AOS-100B................................. 7-4 Figure 7-3a.

Isometric View - Model AOS-100A-S............................................. 7-5 Figure 7-4.

Typical Vacuum Drying System Setup and Equipment............................... 7-11 Figure 7-5.

Latch Pin Security Seal....................................................... 7-15 Figure 7-6.

Turnbuckle Security Seal..................................................... 7-16 Figure 7-7.

Shipping Cage Security Seal................................................... 7-17 Figure 7-8.

Example Dose Rate/Decay Heat Calculation Sheet (Model AOS-100A Non-Exclusive Shipment Version Shown).......................... 7-27

8. Acceptance Tests and Maintenance Program Figure 8-1.

Typical Thermal Test Setup................................................... 8-16 Figure 8-2.

Cask Lid Showing the Cask Lid Metallic Seal Installed -

Attachment by way of Four (4) Screws, and Leak-Testing Hole........................ 8-18

9. Quality Assurance Program There are no figures in Chapter 9.

Radioactive Material Transport Packaging System Safety Analysis Report xix for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

TABLES

1. General Information Table 1-1.

AOS Transport Packaging System Dimensions and Maximum Authorized Package Weight - All Models.................................. 1-7 Table 1-2.

10 CFR 71.47(a) Activity Limits (All Isotopes Except Ir-192 and Ir-194) - All Models........ 1-14 Table 1-2a.

10 CFR 71.47(a) Ir-192 and Ir-194 Activity Limits - All Models......................... 1-15 Table 1-2b.

10 CFR 71.47(b) Activity Limits - Model AOS-100A and AOS-100A-S.................. 1-16 Table 1-3.

Content Limitations - All Models................................................ 1-16 Table 1-4.

AOS Transport Packaging System Analyses Summary - All Models.................... 1-18 Table 1-5.

AOS Transport Packaging System Certification Drawing List - All Models............... 1-23

2. Structural Evaluation Table 2-1.

Summary of Load Combinations for Normal and Hypothetical Accident Conditions of Transport....................................................... 2-10 Table 2-2.

Buckling Stress Values - All Models............................................. 2-14 Table 2-3.

Pm and Pb Stress Monitoring Section Elements - All Models.......................... 2-18 Table 2-4.

Load Cases................................................................ 2-19 Table 2-5.

Load Case Designation Summary............................................... 2-20 Table 2-6.

Load Combinations.......................................................... 2-21 Table 2-7.

AOS Transport Packaging System Maximum Authorized Package Weight and Cg Locations - All Models................................................. 2-23 Table 2-8.

Applicable Codes and Standards for Design, Fabrication, and Testing of the AOS Transport Packaging System......................................... 2-27 Table 2-9.

Stainless Steel Mechanical Properties (Reference [2.5])............................. 2-30 Table 2-10.

Cask Lid Attachment Bolt Mechanical Properties (Reference [2.5])..................... 2-31 Table 2-11.

Tungsten Alloy Material Mechanical Properties.................................... 2-32 Table 2-12.

Carbon Steel (SA-105) Material Mechanical Properties (Reference [2.5])................ 2-32 Table 2-13.

Trunnion Screw Mechanical Properties (Reference [2.5]) - All Models.................. 2-33 Table 2-14.

LAST-A-FOAM FR-3700 Series Foam Dynamic Strength, psi, Parallel to Direction of Rise - All Models.......................................... 2-34 Table 2-15.

LAST-A-FOAM FR-3700 Series Foam Dynamic Strength, psi, Perpendicular to Direction of Rise - All Models.................................... 2-35 Table 2-16.

Permanent Dissimilar Metal Joints within Cask Component........................... 2-36 Table 2-17.

Temporary Dissimilar Metal Joints within Cask Component........................... 2-36 Table 2-18.

Material Selection of Major AOS Transport Packaging System Components (Typical)...... 2-39 Table 2-19.

Examination Program Summary................................................ 2-42 Table 2-20.

Lifting Load Analysis - All Models............................................... 2-47 Table 2-21.

Average Bearing Stress - All Models............................................ 2-49 Table 2-22.

Maximum Shear Stress, SV - All Models......................................... 2-50 Table 2-23.

Calculation of Shipping Cage Margins of Safety - All Models.......................... 2-53 Table 2-24.

Boundary Forces - Model AOS-025............................................. 2-62 Table 2-25.

Boundary Forces - Model AOS-050............................................. 2-63 Table 2-26.

Boundary Forces - Model AOS-100............................................. 2-64 Table 2-27.

Mechanical Connector Impact Load Summary - All Models........................... 2-65 Table 2-28.

Mechanical Connector Loads for 10g Inertia Force - All Models....................... 2-65 Table 2-29.

Transport Package Thermal Environment Conditions - All Models..................... 2-74 Table 2-30.

Temperature Summary of Normal Conditions of Transport - All Models................. 2-76 Table 2-31.

Maximum Cask Cavity Pressure Due to Normal Conditions of Transport - All Models...... 2-76 Table 2-32.

Stresses Resulting from Load Combinations Associated with Heat Environment under Normal Conditions of Transport - All Models................................. 2-79 Table 2-33.

Stresses Resulting from Load Combinations Associated with Cold Environment under Normal Conditions of Transport - All Models................................. 2-79 Table 2-34.

Free-Drop Distance - All Models................................................ 2-82 Table 2-35.

Maximum Displacements in Free Drops, Normal Conditions of Transport - All Models...... 2-82 Table 2-36.

Load Cases under Normal Conditions of Transport Structural Evaluation Results - All Models........................................ 2-87

xx Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 2-37.

Load Combinations under Normal Conditions of Transport Structural Evaluation Results - All Models........................................ 2-88 Table 2-38.

Min MS for Normal Conditions of Transport - Model AOS-025A....................... 2-90 Table 2-39.

Min MS for Normal Conditions of Transport - Model AOS-050A....................... 2-90 Table 2-40.

Min MS for Normal Conditions of Transport - Model AOS-100A and AOS-100A-S......... 2-91 Table 2-41.

Min MS for Normal Conditions of Transport - Model AOS-100B....................... 2-91 Table 2-42.

Side-Drop Analysis and Test, Radial Displacement at Impact Limiters 1 and 2 - AOS-165A Prototype................................. 2-114 Table 2-43.

Support Displacements - AOS-165A Prototype................................... 2-115 Table 2-44.

Slap-Down Drop Analysis and Test, Radial Displacement at Impact Limiters 1 and 2 - AOS-165A Prototype................ 2-118 Table 2-45.

9-m (30-ft.) Drop Analyses Conducted upon Each Cask Model....................... 2-121 Table 2-46.

Shipping Cage Weights Used in LIBRA-AGS Dynamic Response Analyses............. 2-137 Table 2-47.

Loads and Accelerations Determined in Drop Analysis Impact - Model AOS-025......... 2-139 Table 2-48.

Loads and Accelerations Applied in Cask Stress Analyses - Model AOS-025............ 2-140 Table 2-49.

Loads Determined in Drop Impact Analyses - Model AOS-050....................... 2-141 Table 2-50.

Loads and Accelerations Applied in Cask Stress Analyses - Model AOS-050............ 2-142 Table 2-51.

Loads Determined in Drop Analysis - Model AOS-100.............................. 2-143 Table 2-52.

Loads and Accelerations Applied in Cask Stress Analyses - Model AOS-100............ 2-144 Table 2-53.

Temperature Summary of Fire Condition - All Models.............................. 2-148 Table 2-54.

Maximum Cask Cavity Pressure Due to Fire Condition - All Models................... 2-148 Table 2-55.

Load Cases Associated with Thermal Stresses under Hypothetical Accident Conditions of Transport - All Models.......................... 2-150 Table 2-56.

Load Combinations Associated with Thermal Stresses under Hypothetical Accident Conditions of Transport - All Models..................... 2-151 Table 2-57.

Stresses Resulting from Additional Increased External Pressure under Hypothetical Accident Conditions of Transport - All Models..................... 2-152 Table 2-58.

Load Cases Associated with Allowable Stresses under Hypothetical Accident Conditions of Transport - All Models.......................... 2-154 Table 2-59.

Load Combinations Associated with Allowable Stresses under Hypothetical Accident Conditions of Transport - All Models..................... 2-155 Table 2-60.

Min MS for Hypothetical Accident Conditions of Transport - Model AOS-025A........... 2-156 Table 2-61.

Min MS for Hypothetical Accident Conditions of Transport - Model AOS-050A........... 2-156 Table 2-62.

Min MS for Hypothetical Accident Conditions of Transport -

Models AOS-100A and AOS-100A-S........................................... 2-157 Table 2-63.

Min MS for Hypothetical Accident Conditions of Transport - Model AOS-100B........... 2-157 Table 2-64.

Load Cases Associated with Allowable Stresses under Normal Conditions of Transport - Model AOS-025A.......................... 2-162 Table 2-65.

Load Combinations Associated with Allowable Stresses under Normal Conditions of Transport - Model AOS-025A.......................... 2-163 Table 2-66.

Load Case 101, 100°F Ambient, Maximum Decay Heat, Normal Conditions of Transport - Model AOS-025A................................ 2-164 Table 2-67.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Normal Conditions of Transport - Model AOS-025A................................ 2-166 Table 2-68.

Load Case 103, -20°F Ambient, Zero Decay Heat, Zero Insolation, Normal Conditions of Transport - Model AOS-025A................................ 2-168 Table 2-69.

Load Case 104, -40°F Ambient, Zero Decay Heat, Zero Insolation, Normal Conditions of Transport - Model AOS-025A................................ 2-170 Table 2-70.

Load Case 105, -40°F Ambient, Maximum Decay Heat, Normal Conditions of Transport - Model AOS-025A................................ 2-172 Table 2-71.

Load Case 106, -20°F Ambient, Maximum Decay Heat, Normal Conditions of Transport - Model AOS-025A................................ 2-174 Table 2-72.

Load Case 201, Internal Design Pressure, 207 kPa (30 psia),

Normal Conditions of Transport - Model AOS-025A................................ 2-176 Table 2-73.

Load Case 202, Minimum External Pressure, 24 kPa (3.5 psia),

Normal Conditions of Transport - Model AOS-025A................................ 2-178 Table 2-74.

Load Case 203, Maximum Increased External Pressure, 140 kPa (20 psia),

Normal Conditions of Transport - Model AOS-025A................................ 2-180

Radioactive Material Transport Packaging System Safety Analysis Report xxi for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 2-75.

Load Case 204, Additional Increased External Pressure, 2 MPa (290 psia),

Normal Conditions of Transport - Model AOS-025A................................ 2-182 Table 2-76.

Load Case 211, Fabrication Stress, Normal Conditions of Transport - Model AOS-025A................................ 2-184 Table 2-77.

Load Case 215, Compression Load (5x weight),

Normal Conditions of Transport - Model AOS-025A................................ 2-186 Table 2-78.

Load Case 216, Rod Drop onto Cask, Normal Conditions of Transport - Model AOS-025A................................ 2-188 Table 2-79.

Load Case 221, Forward 10g Vibration Inertia Load, Normal Conditions of Transport - Model AOS-025A................................ 2-190 Table 2-80.

Load Case 222, Lateral 5g Vibration Inertia Load, Normal Conditions of Transport - Model AOS-025A................................ 2-192 Table 2-81.

Load Case 223, Vertical 2g Vibration Inertia Load, Normal Conditions of Transport - Model AOS-025A................................ 2-194 Table 2-82.

Load Case 231, 4-ft. Head-On Drop, Normal Conditions of Transport - Model AOS-025A................................ 2-196 Table 2-83.

Load Case 232, 30-ft. Head-On Drop Impact Test, Normal Conditions, Normal Conditions of Transport - Model AOS-025A................................ 2-198 Table 2-84.

Load Combination 101, Hot Environment, Normal Conditions of Transport - Model AOS-025A................................ 2-200 Table 2-85.

Load Combination 102, Cold Environment, Normal Conditions of Transport - Model AOS-025A................................ 2-202 Table 2-86.

Load Combination 103, Increased External Pressure, Normal Conditions of Transport - Model AOS-025A................................ 2-204 Table 2-87.

Load Combination 104, Minimum External Pressure, Normal Conditions of Transport - Model AOS-025A................................ 2-206 Table 2-88.

Load Combination 105, Cold Environment with Maximum Decay Heat, Normal Conditions of Transport - Model AOS-025A................................ 2-208 Table 2-89.

Load Combination 106, Maximum Pressure, Hot Environment, Normal Conditions of Transport - Model AOS-025A................................ 2-210 Table 2-90.

Load Combination 107, Maximum Pressure, Cold Environment, Normal Conditions of Transport - Model AOS-025A................................ 2-212 Table 2-91.

Load Combination 215, Compression Load, Normal Conditions of Transport - Model AOS-025A................................ 2-214 Table 2-92.

Load Combination 216, Rod Drop, Normal Conditions of Transport - Model AOS-025A................................ 2-216 Table 2-93.

Load Combination 217, Rod Drop, Cold Environment, Normal Conditions of Transport - Model AOS-025A................................ 2-218 Table 2-94.

Load Combination 221, Forward Vibration, Normal Conditions of Transport - Model AOS-025A................................ 2-220 Table 2-95.

Load Combination 222, Lateral Vibration, Normal Conditions of Transport - Model AOS-025A................................ 2-222 Table 2-96.

Load Combination 223, Vertical Vibration, Normal Conditions of Transport - Model AOS-025A................................ 2-224 Table 2-97.

Load Combination 224, Forward Vibration at Cold Temperature, Normal Conditions of Transport - Model AOS-025A................................ 2-226 Table 2-98.

Load Combination 225, Lateral Vibration at Cold Temperature, Normal Conditions of Transport - Model AOS-025A................................ 2-228 Table 2-99.

Load Combination 226, Vertical Vibration at Cold Temperature, Normal Conditions of Transport - Model AOS-025A................................ 2-230 Table 2-100.

Load Combination 231, 4-ft. Head-On Drop, Normal Conditions, Normal Conditions of Transport - Model AOS-025A................................ 2-232 Table 2-101.

Load Combination 232, 30-ft. Head-On Drop, Normal Conditions (Impact Test),

Normal Conditions of Transport - Model AOS-025A................................ 2-234 Table 2-102.

Load Combination 233, 4-ft. Drop at Cold Temperature, Normal Conditions of Transport - Model AOS-025A................................ 2-236

xxii Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 2-103.

Load Cases Associated with Allowable Stresses under Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-238 Table 2-104.

Load Combinations Associated with Allowable Stresses under Hypothetical Accident Conditions of Transport - Model AOS-025A............... 2-239 Table 2-105.

Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-240 Table 2-106.

Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport - Model AOS-025A... 2-242 Table 2-107.

Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport - Model AOS-025A... 2-244 Table 2-108.

Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport - Model AOS-025A... 2-246 Table 2-109.

Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport - Model AOS-025A... 2-248 Table 2-110.

Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport - Model AOS-025A... 2-250 Table 2-111.

Load Case 301, 30-ft. Head-On Drop, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-252 Table 2-112.

Load Case 302, 30-ft. Side Drop + Slap-Down, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-254 Table 2-113.

Load Case 303, 30-ft. Cg/Corner Drop, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-256 Table 2-114.

Load Case 304, 30-ft. Head-On Drop at -40°F, Low Temperature, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-258 Table 2-115.

Load Case 305, 30-ft. Side Drop + Slap-Down at -40°F, Low Temperature, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-260 Table 2-116.

Load Case 306, 30-ft. Cg/Corner Drop at -40°F, Low Temperature, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-262 Table 2-117.

Load Case 311, 4-ft. Drop onto Rod, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-264 Table 2-118.

Load Combination 301, Head-On Drop Orientation, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-266 Table 2-119.

Load Combination 302, Side Drop Orientation, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-268 Table 2-120.

Load Combination 303, Cg/Corner Drop Orientation, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-270 Table 2-121.

Load Combination 304, Head-On Drop Orientation at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-272 Table 2-122.

Load Combination 305, Side Drop Orientation at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-274 Table 2-123.

Load Combination 306, Cg/Corner Drop Orientation at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-276 Table 2-124.

Load Combination 310, Additional Increased External Pressure (290 psi),

Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-278 Table 2-125.

Load Combination 311, 4-ft. Drop onto Rod, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-280 Table 2-126.

Load Combination 312, 4-ft. Drop onto Rod at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-282 Table 2-127.

Load Combination 350, Fire at 30 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-284 Table 2-128.

Load Combination 351, Post Fire at 60 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-286 Table 2-129.

Load Combination 352, Post Fire at 90 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-288 Table 2-130.

Load Combination 353, Post Fire at 120 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-290 Table 2-131.

Load Combination 354, Post Fire at 150 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-292

Radioactive Material Transport Packaging System Safety Analysis Report xxiii for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 2-132.

Load Combination 355, Post Fire at 180 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-025A.................... 2-294 Table 2-133.

Load Cases Associated with Allowable Stresses under Normal Conditions of Transport - Model AOS-050A.......................... 2-296 Table 2-134.

Load Combinations Associated with Allowable Stresses under Normal Conditions of Transport - Model AOS-050A.......................... 2-297 Table 2-135.

Load Case 101, 100°F Ambient, Maximum Decay Heat, Normal Conditions of Transport - Model AOS-050A................................ 2-298 Table 2-136.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Normal Conditions of Transport - Model AOS-050A................................ 2-300 Table 2-137.

Load Case 103, -20°F Ambient, Zero Decay Heat, Zero Insolation, Normal Conditions of Transport - Model AOS-050A................................ 2-302 Table 2-138.

Load Case 104, -40°F Ambient, Zero Decay Heat, Zero Insolation, Normal Conditions of Transport - Model AOS-050A................................ 2-304 Table 2-139.

Load Case 105, -40°F Ambient, Maximum Decay Heat, Normal Conditions of Transport - Model AOS-050A................................ 2-306 Table 2-140.

Load Case 106, -20°F Ambient, Maximum Decay Heat, Normal Conditions of Transport - Model AOS-050A................................ 2-308 Table 2-141.

Load Case 201, Internal Design Pressure, 414 kPa (60 psia),

Normal Conditions of Transport - Model AOS-050A................................ 2-310 Table 2-142.

Load Case 202, Minimum External Pressure, 24 kPa (3.5 psia),

Normal Conditions of Transport - Model AOS-050A................................ 2-312 Table 2-143.

Load Case 203, Maximum Increased External Pressure, 140 kPa (20 psia),

Normal Conditions of Transport - Model AOS-050A................................ 2-314 Table 2-144.

Load Case 204, Additional Increased External Pressure, 2 MPa (290 psia),

Normal Conditions of Transport - Model AOS-050A................................ 2-316 Table 2-145.

Load Case 211, Fabrication Stress, Normal Conditions of Transport - Model AOS-050A................................ 2-318 Table 2-146.

Load Case 215, Compression Load (5x weight),

Normal Conditions of Transport - Model AOS-050A................................ 2-320 Table 2-147.

Load Case 216, Rod Drop onto Cask, Normal Conditions of Transport - Model AOS-050A................................ 2-322 Table 2-148.

Load Case 221, Forward 10g Vibration Inertia Load, Normal Conditions of Transport - Model AOS-050A................................ 2-324 Table 2-149.

Load Case 222, Lateral 5g Vibration Inertia Load, Normal Conditions of Transport - Model AOS-050A................................ 2-326 Table 2-150.

Load Case 223, Vertical 2g Vibration Inertia Load, Normal Conditions of Transport - Model AOS-050A................................ 2-328 Table 2-151.

Load Case 231, 4-ft. Head-On Drop, Normal Conditions of Transport - Model AOS-050A.. 2-330 Table 2-152.

Load Case 232, 30-ft. Head-On Drop Impact Test, Normal Conditions, Normal Conditions of Transport - Model AOS-050A................................ 2-332 Table 2-153.

Load Combination 101, Hot Environment, Normal Conditions of Transport - Model AOS-050A................................ 2-334 Table 2-154.

Load Combination 102, Cold Environment, Normal Conditions of Transport - Model AOS-050A................................ 2-336 Table 2-155.

Load Combination 103, Increased External Pressure, Normal Conditions of Transport - Model AOS-050A................................ 2-338 Table 2-156.

Load Combination 104, Minimum External Pressure, Normal Conditions of Transport - Model AOS-050A................................ 2-340 Table 2-157.

Load Combination 105, Cold Environment with Maximum Decay Heat, Normal Conditions of Transport - Model AOS-050A................................ 2-342 Table 2-158.

Load Combination 106, Maximum Pressure, Hot Environment, Normal Conditions of Transport - Model AOS-050A................................ 2-344 Table 2-159.

Load Combination 107, Maximum Pressure, Cold Environment, Normal Conditions of Transport - Model AOS-050A................................ 2-346 Table 2-160.

Load Combination 215, Compression Load, Normal Conditions of Transport - Model AOS-050A................................ 2-348 Table 2-161.

Load Combination 216, Rod Drop, Normal Conditions of Transport - Model AOS-050A................................ 2-350

xxiv Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 2-162.

Load Combination 217, Rod Drop, Cold Environment, Normal Conditions of Transport - Model AOS-050A................................ 2-352 Table 2-163.

Load Combination 221, Forward Vibration, Normal Conditions of Transport - Model AOS-050A................................ 2-354 Table 2-164.

Load Combination 222, Lateral Vibration, Normal Conditions of Transport - Model AOS-050A................................ 2-356 Table 2-165.

Load Combination 223, Vertical Vibration, Normal Conditions of Transport - Model AOS-050A................................ 2-358 Table 2-166.

Load Combination 224, Forward Vibration at Cold Temperature, Normal Conditions of Transport - Model AOS-050A................................ 2-360 Table 2-167.

Load Combination 225, Lateral Vibration at Cold Temperature, Normal Conditions of Transport - Model AOS-050A................................ 2-362 Table 2-168.

Load Combination 226, Vertical Vibration at Cold Temperature, Normal Conditions of Transport - Model AOS-050A................................ 2-364 Table 2-169.

Load Combination 231, 4-ft. Head-On Drop, Normal Conditions, Normal Conditions of Transport - Model AOS-050A................................ 2-366 Table 2-170.

Load Combination 232, 30-ft. Head-On Drop, Normal Conditions (Impact Test),

Normal Conditions of Transport - Model AOS-050A................................ 2-368 Table 2-171.

Load Combination 233, 4-ft. Drop at Cold Temperature, Normal Conditions of Transport - Model AOS-050A................................ 2-370 Table 2-172.

Load Cases Associated with Allowable Stresses under Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-372 Table 2-173.

Load Combinations Associated with Allowable Stresses under Hypothetical Accident Conditions of Transport - Model AOS-050A............... 2-373 Table 2-174.

Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-374 Table 2-175.

Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport - Model AOS-050A... 2-376 Table 2-176.

Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport - Model AOS-050A... 2-378 Table 2-177.

Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport - Model AOS-050A... 2-380 Table 2-178.

Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport - Model AOS-050A... 2-382 Table 2-179.

Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport - Model AOS-050A... 2-384 Table 2-180.

Load Case 301, 30-ft. Head-On Drop, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-386 Table 2-181.

Load Case 302, 30-ft. Side Drop + Slap-Down, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-388 Table 2-182.

Load Case 303, 30-ft. Cg/Corner Drop, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-390 Table 2-183.

Load Case 304, 30-ft. Head-On Drop at -40°F, Low Temperature, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-392 Table 2-184.

Load Case 305, 30-ft. Side Drop + Slap-Down at -40°F, Low Temperature, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-394 Table 2-185.

Load Case 306, 30-ft. Cg/Corner Drop at -40°F, Low Temperature, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-396 Table 2-186.

Load Case 311, 4-ft. Drop onto Rod, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-398 Table 2-187.

Load Combination 301, Head-On Drop Orientation, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-400 Table 2-188.

Load Combination 302, Side Drop Orientation, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-402 Table 2-189.

Load Combination 303, Cg/Corner Drop Orientation, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-404 Table 2-190.

Load Combination 304, Head-On Drop Orientation at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-406

Radioactive Material Transport Packaging System Safety Analysis Report xxv for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 2-191.

Load Combination 305, Side Drop Orientation at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-408 Table 2-192.

Load Combination 306, Cg/Corner Drop Orientation at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-410 Table 2-193.

Load Combination 310, Additional Increased External Pressure (290 psi),

Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-412 Table 2-194.

Load Combination 311, 4-ft. Drop onto Rod, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-414 Table 2-195.

Load Combination 312, 4-ft. Drop onto Rod at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-416 Table 2-196.

Load Combination 350, Fire at 30 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-418 Table 2-197.

Load Combination 351, Post Fire at 60 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-420 Table 2-198.

Load Combination 352, Post Fire at 90 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-422 Table 2-199.

Load Combination 353, Post Fire at 120 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-424 Table 2-200.

Load Combination 354, Post Fire at 150 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-426 Table 2-201.

Load Combination 355, Post Fire at 180 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-428 Table 2-202.

Load Cases Associated with Allowable Stresses under Normal Conditions of Transport - Models AOS-100A and AOS-100A-S........... 2-431 Table 2-203.

Load Combinations Associated with Allowable Stresses under Normal Conditions of Transport - Models AOS-100A and AOS-100A-S........... 2-432 Table 2-204.

Load Case 101, 100°F Ambient, Maximum Decay Heat, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-433 Table 2-205.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-435 Table 2-206.

Load Case 103, -20°F Ambient, Zero Decay Heat, Zero Insolation, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-437 Table 2-207.

Load Case 104, -40°F Ambient, Zero Decay Heat, Zero Insolation, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-439 Table 2-208.

Load Case 105, -40°F Ambient, Maximum Decay Heat, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-441 Table 2-209.

Load Case 106, -20°F Ambient, Maximum Decay Heat, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-443 Table 2-210.

Load Case 201, Internal Design Pressure, 1,930 kPa (280 psia),

Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-445 Table 2-211.

Load Case 202, Minimum External Pressure, 24 kPa (3.5 psia),

Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-447 Table 2-212.

Load Case 203, Maximum Increased External Pressure, 140 kPa (20 psia),

Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-449 Table 2-213.

Load Case 204, Additional Increased External Pressure, 2 MPa (290 psia),

Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-451 Table 2-214.

Load Case 211, Fabrication Stress, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-453 Table 2-215.

Load Case 215, Compression Load (5x weight),

Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-455 Table 2-216.

Load Case 216, Rod Drop onto Cask, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-457 Table 2-217.

Load Case 221, Forward 10g Vibration Inertia Load, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-459 Table 2-218.

Load Case 222, Lateral 5g Vibration Inertia Load, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-461 Table 2-219.

Load Case 223, Vertical 2g Vibration Inertia Load, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-463

xxvi Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 2-220.

Load Case 231, 3-ft. Head-On Drop, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-465 Table 2-221.

Load Case 232, 30-ft. Head-On Drop Impact Test, Normal Conditions, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-467 Table 2-222.

Load Combination 101, Hot Environment, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-469 Table 2-223.

Load Combination 102, Cold Environment, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-471 Table 2-224.

Load Combination 103, Increased External Pressure, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-473 Table 2-225.

Load Combination 104, Minimum External Pressure, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-475 Table 2-226.

Load Combination 105, Cold Environment with Maximum Decay Heat, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-477 Table 2-227.

Load Combination 106, Maximum Pressure, Hot Environment, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-479 Table 2-228.

Load Combination 107, Maximum Pressure, Cold Environment, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-481 Table 2-229.

Load Combination 215, Compression Load, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-483 Table 2-230.

Load Combination 216, Rod Drop, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-485 Table 2-231.

Load Combination 217, Rod Drop, Cold Environment, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-487 Table 2-232.

Load Combination 221, Forward Vibration, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-489 Table 2-233.

Load Combination 222, Lateral Vibration, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-491 Table 2-234.

Load Combination 223, Vertical Vibration, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-493 Table 2-235.

Load Combination 224, Forward Vibration at Cold Temperature, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-495 Table 2-236.

Load Combination 225, Lateral Vibration at Cold Temperature, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-497 Table 2-237.

Load Combination 226, Vertical Vibration at Cold Temperature, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-499 Table 2-238.

Load Combination 231, 3-ft. Head-On Drop, Normal Conditions, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-501 Table 2-239.

Load Combination 233, 3-ft. Drop at Cold Temperature, Normal Conditions of Transport - Models AOS-100A and AOS-100A-S................ 2-503 Table 2-240.

Load Cases Associated with Allowable Stresses under Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-505 Table 2-241.

Load Combinations Associated with Allowable Stresses under Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-506 Table 2-242.

Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-507 Table 2-243.

Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport -

Models AOS-100A and AOS-100A-S........................................... 2-509 Table 2-244.

Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport -

Models AOS-100A and AOS-100A-S........................................... 2-511 Table 2-245.

Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport -

Models AOS-100A and AOS-100A-S........................................... 2-513 Table 2-246.

Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport -

Models AOS-100A and AOS-100A-S........................................... 2-515

Radioactive Material Transport Packaging System Safety Analysis Report xxvii for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 2-247.

Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport -

Models AOS-100A and AOS-100A-S........................................... 2-517 Table 2-248.

Load Case 301, 30-ft. Head-On Drop, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-519 Table 2-249.

Load Case 302, 30-ft. Side Drop + Slap-Down, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-521 Table 2-250.

Load Case 303, 30-ft. Cg/Corner Drop, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-523 Table 2-251.

Load Case 304, 30-ft. Head-On Drop at -40°F, Low Temperature, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-525 Table 2-252.

Load Case 305, 30-ft. Side Drop + Slap-Down at -40°F, Low Temperature, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-527 Table 2-253.

Load Case 306, 30-ft. Cg/Corner Drop at -40°F, Low Temperature, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-529 Table 2-254.

Load Case 311, 4-ft. Drop onto Rod, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-531 Table 2-255.

Load Combination 301, Head-On Drop Orientation, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-533 Table 2-256.

Load Combination 302, Side Drop Orientation, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-535 Table 2-257.

Load Combination 303, Cg/Corner Drop Orientation, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-537 Table 2-258.

Load Combination 304, Head-On Drop Orientation at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-539 Table 2-259.

Load Combination 305, Side Drop Orientation at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-541 Table 2-260.

Load Combination 306, Cg/Corner Drop Orientation at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-543 Table 2-261.

Load Combination 310, Additional Increased External Pressure (290 psi),

Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-545 Table 2-262.

Load Combination 311, 4-ft. Drop onto Rod, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-547 Table 2-263.

Load Combination 312, 4-ft. Drop onto Rod at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-549 Table 2-264.

Load Combination 350, Fire at 30 Minutes, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-551 Table 2-265.

Load Combination 351, Post Fire at 60 Minutes, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-553 Table 2-266.

Load Combination 352, Post Fire at 90 Minutes, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-555 Table 2-267.

Load Combination 353, Post Fire at 120 Minutes, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-557 Table 2-268.

Load Combination 354, Post Fire at 150 Minutes, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-559 Table 2-269.

Load Combination 355, Post Fire at 180 Minutes, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-561 Table 2-270.

Load Cases Associated with Allowable Stresses under Normal Conditions of Transport - Model AOS-100B.......................... 2-564 Table 2-271.

Load Combinations Associated with Allowable Stresses under Normal Conditions of Transport - Model AOS-100B.......................... 2-565 Table 2-272.

Load Case 101, 100°F Ambient, Maximum Decay Heat, Normal Conditions of Transport - Model AOS-100B................................ 2-566 Table 2-273.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Normal Conditions of Transport - Model AOS-100B................................ 2-568 Table 2-274.

Load Case 103, -20°F Ambient, Zero Decay Heat, Zero Insolation, Normal Conditions of Transport - Model AOS-100B................................ 2-570 Table 2-275.

Load Case 104, -40°F Ambient, Zero Decay Heat, Zero Insolation, Normal Conditions of Transport - Model AOS-100B................................ 2-572

xxviii Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 2-276.

Load Case 105, -40°F Ambient, Maximum Decay Heat, Normal Conditions of Transport - Model AOS-100B................................ 2-574 Table 2-277.

Load Case 106, -20°F Ambient, Maximum Decay Heat, Normal Conditions of Transport - Model AOS-100B................................ 2-576 Table 2-278.

Load Case 201, Internal Design Pressure, 1,930 kPa (280 psia),

Normal Conditions of Transport - Model AOS-100B................................ 2-578 Table 2-279.

Load Case 202, Minimum External Pressure, 24 kPa (3.5 psia),

Normal Conditions of Transport - Model AOS-100B................................ 2-580 Table 2-280.

Load Case 203, Maximum Increased External Pressure, 140 kPa (20 psia),

Normal Conditions of Transport - Model AOS-100B................................ 2-582 Table 2-281.

Load Case 204, Additional Increased External Pressure, 2 MPa (290 psia),

Normal Conditions of Transport - Model AOS-100B................................ 2-584 Table 2-282.

Load Case 211, Fabrication Stress, Normal Conditions of Transport - Model AOS-100B................................ 2-586 Table 2-283.

Load Case 215, Compression Load (5x weight),

Normal Conditions of Transport - Model AOS-100B................................ 2-588 Table 2-284.

Load Case 216, Rod Drop onto Cask, Normal Conditions of Transport - Model AOS-100B................................ 2-590 Table 2-285.

Load Case 221, Forward 10g Vibration Inertia Load, Normal Conditions of Transport - Model AOS-100B................................ 2-592 Table 2-286.

Load Case 222, Lateral 5g Vibration Inertia Load, Normal Conditions of Transport - Model AOS-100B................................ 2-594 Table 2-287.

Load Case 223, Vertical 2g Vibration Inertia Load, Normal Conditions of Transport - Model AOS-100B................................ 2-596 Table 2-288.

Load Case 231, 3-ft. Head-On Drop, Normal Conditions of Transport - Model AOS-100B................................ 2-598 Table 2-289.

Load Case 232, 30-ft. Head-On Drop Impact Test, Normal Conditions, Normal Conditions of Transport - Model AOS-100B................................ 2-600 Table 2-290.

Load Combination 101, Hot Environment, Normal Conditions of Transport - Model AOS-100B................................ 2-602 Table 2-291.

Load Combination 102, Cold Environment, Normal Conditions of Transport - Model AOS-100B................................ 2-604 Table 2-292.

Load Combination 103, Increased External Pressure, Normal Conditions of Transport - Model AOS-100B................................ 2-606 Table 2-293.

Load Combination 104, Minimum External Pressure, Normal Conditions of Transport - Model AOS-100B................................ 2-608 Table 2-294.

Load Combination 105, Cold Environment with Maximum Decay Heat, Normal Conditions of Transport - Model AOS-100B................................ 2-610 Table 2-295.

Load Combination 106, Maximum Pressure, Hot Environment, Normal Conditions of Transport - Model AOS-100B................................ 2-612 Table 2-296.

Load Combination 107, Maximum Pressure, Cold Environment, Normal Conditions of Transport - Model AOS-100B................................ 2-614 Table 2-297.

Load Combination 215, Compression Load, Normal Conditions of Transport - Model AOS-100B................................ 2-616 Table 2-298.

Load Combination 216, Rod Drop, Normal Conditions of Transport - Model AOS-100B................................ 2-618 Table 2-299.

Load Combination 217, Rod Drop, Cold Environment, Normal Conditions of Transport - Model AOS-100B................................ 2-620 Table 2-300.

Load Combination 221, Forward Vibration, Normal Conditions of Transport - Model AOS-100B................................ 2-622 Table 2-301.

Load Combination 222, Lateral Vibration, Normal Conditions of Transport - Model AOS-100B................................ 2-624 Table 2-302.

Load Combination 223, Vertical Vibration, Normal Conditions of Transport - Model AOS-100B................................ 2-626 Table 2-303.

Load Combination 224, Forward Vibration at Cold Temperature, Normal Conditions of Transport - Models AOS-100B............................... 2-628 Table 2-304.

Load Combination 225, Lateral Vibration at Cold Temperature, Normal Conditions of Transport - Models AOS-100B............................... 2-630

Radioactive Material Transport Packaging System Safety Analysis Report xxix for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 2-305.

Load Combination 226, Vertical Vibration at Cold Temperature, Normal Conditions of Transport - Models AOS-100B............................... 2-632 Table 2-306.

Load Combination 231, 3-ft. Head-On Drop, Normal Conditions, Normal Conditions of Transport - Model AOS-100B................................ 2-634 Table 2-307.

Load Combination 233, 3-ft. Drop at Cold Temperature, Normal Conditions of Transport - Models AOS-100B............................... 2-636 Table 2-308.

Load Cases Associated with Allowable Stresses under Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-638 Table 2-309.

Load Combinations Associated with Allowable Stresses under Hypothetical Accident Conditions of Transport - Model AOS-100B............... 2-639 Table 2-310.

Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-640 Table 2-311.

Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport - Model AOS-100B... 2-642 Table 2-312.

Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport - Model AOS-100B... 2-644 Table 2-313.

Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport - Model AOS-100B... 2-646 Table 2-314.

Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport - Model AOS-100B... 2-648 Table 2-315.

Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation, Hypothetical Accident Conditions of Transport - Model AOS-100B... 2-650 Table 2-316.

Load Case 301, 30-ft. Head-On Drop, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-652 Table 2-317.

Load Case 302, 30-ft. Side Drop + Slap-Down, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-654 Table 2-318.

Load Case 303, 30-ft. Cg/Corner Drop, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-656 Table 2-319.

Load Case 304, 30-ft. Head-On Drop at -40°F, Low Temperature, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-658 Table 2-320.

Load Case 305, 30-ft. Side Drop + Slap-Down at -40°F, Low Temperature, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-660 Table 2-321.

Load Case 306, 30-ft. Cg/Corner Drop at -40°F, Low Temperature, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-662 Table 2-322.

Load Case 311, 4-ft. Drop onto Rod, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-664 Table 2-323.

Load Combination 301, Head-On Drop Orientation, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-666 Table 2-324.

Load Combination 302, Side Drop Orientation, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-668 Table 2-325.

Load Combination 303, Cg/Corner Drop Orientation, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-670 Table 2-326.

Load Combination 304, Head-On Drop Orientation at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-672 Table 2-327.

Load Combination 305, Side Drop Orientation at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-674 Table 2-328.

Load Combination 306, Cg/Corner Drop Orientation at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-676 Table 2-329.

Load Combination 310, Additional Increased External Pressure (290 psi),

Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-678 Table 2-330.

Load Combination 311, 4-ft. Drop onto Rod, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-680 Table 2-331.

Load Combination 312, 4-ft. Drop onto Rod at -40°F, Cold Environment, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-682 Table 2-332.

Load Combination 350, Fire at 30 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-684 Table 2-333.

Load Combination 351, Post Fire at 60 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-686

xxx Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 2-334.

Load Combination 352, Post Fire at 90 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-688 Table 2-335.

Load Combination 353, Post Fire at 120 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-690 Table 2-336.

Load Combination 354, Post Fire at 150 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-692 Table 2-337.

Load Combination 355, Post Fire at 180 Minutes, Hypothetical Accident Conditions of Transport - Model AOS-100B.................... 2-694 Table 2-338.

STIF1 Element Property Record............................................... 2-912 Table 2-339.

Generalized Stiffness Properties - All Models.................................... 2-919 Table 2-340.

Generalized Pallet and Cask Mass Properties - All Models.......................... 2-919 Table 2-341.

AGS Analysis - Model AOS-025............................................... 2-922 Table 2-342.

AGS Analysis - Model AOS-050............................................... 2-923 Table 2-343.

AGS Analysis - Model AOS-100............................................... 2-923 Table 2-344.

Increased Ground Impact Forces - All Models.................................... 2-923 Table 2-345.

Model AOS-100 Cable Loads................................................. 2-931 Table 2-346.

Maximum von Mises Stress in Shipping Cage Frame - Model AOS-050A............... 2-951 Table 2-347.

Maximum von Mises Stress in Lifting Bar - Model AOS-050A........................ 2-952 Table 2-348.

Bolt Stresses - Model AOS-050A.............................................. 2-952 Table 2-349.

Contact Forces - Model AOS-050A............................................ 2-952 Table 2-350.

Convergence of Elastic Stability Analysis, Mode 1 - Model AOS-050A................. 2-954 Table 2-351.

Maximum von Mises Stress in Shipping Cage Frame - Model AOS-100................ 2-959 Table 2-352.

Maximum von Mises Stress in Lifting Bar - Model AOS-100......................... 2-959 Table 2-353.

Displacements and Forces within Contact Elements - Model AOS-100................. 2-963 Table 2-354.

Displacements and Forces within Bolt Elements - Model AOS-100.................... 2-963 Table 2-355.

Convergence of Elastic Stability Analysis, Mode 1 - Model AOS-100.................. 2-964 Table 2-356.

Convergence of Elastic Stability Analysis, Mode 2 - Model AOS-100.................. 2-965 Table 2-357.

Additional Required Shoring Components -

Models AOS-050A, AOS-100A, and AOS-100A-S................................. 2-967 Table 2-358.

Stress Criteria - Models AOS-050A, AOS-100A, and AOS-100A-S.................... 2-970 Table 2-359.

Axial Shielding Plate ANSYS Model Loads - Model AOS-050A....................... 2-972 Table 2-360.

Axial Shielding Plate Stress Analysis Results during Hypothetical Accident Conditions of Transport - Model AOS-050A.................... 2-973 Table 2-361.

Axial Shielding Plate ANSYS Model Loads - Models AOS-100A and AOS-100A-S....... 2-978 Table 2-362.

Axial Shielding Plate Stress Analysis Results during Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-979 Table 2-363.

Cavity Spacer Plate ANSYS Model Loads - Models AOS-100A and AOS-100A-S........ 2-982 Table 2-364.

Cavity Spacer Plate Stress Analysis Results during Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100A-S..... 2-983

3. Thermal Evaluation Table 3-1.

Transport Package Thermal Environment Conditions - All Models...................... 3-2 Table 3-2.

Contents Decay Heat - All Models............................................... 3-2 Table 3-3.

Maximum Temperature Summary, Normal Conditions of Transport - All Models....................................... 3-3 Table 3-4.

Maximum Temperature Summary, Hypothetical Accident Conditions of Transport (Condition 3) - All Models................. 3-7 Table 3-5.

Type 304 Stainless Steel (SS304) Thermophysical Properties (Reference [3.16])......... 3-13 Table 3-6.

Tungsten Alloy Thermophysical Properties (Reference [3.3]) -

Models AOS-025A, AOS-050A, AOS-100A, and AOS-100A-S......................... 3-14 Table 3-7.

Carbon Steel Properties - Model AOS-100B (Reference [3.16])....................... 3-15 Table 3-8.

Air Thermophysical Properties (Reference [3.4])................................... 3-17 Table 3-9.

LAST-A-FOAM FR-3700 Series Foam Thermophysical Properties - All Models (Reference [3.19]),......................................................... 3-18 Table 3-10.

Heat Flux Values - All Models................................................. 3-24 Table 3-11.

Thermal Properties Used in Analysis as Function of Temperature, with Respect to the Air Gaps - All Models........................................ 3-29

Radioactive Material Transport Packaging System Safety Analysis Report xxxi for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 3-12.

Cask Assembly External Surface Orientation and Size, Normal Conditions of Transport - All Models...................................... 3-31 Table 3-13.

Cask Assembly External Surface Orientation and Size, Fire Condition - All Models.................................................... 3-33 Table 3-14.

Polynomial Coefficients Used in Equivalent Convective Property of Ambient Temperature and External Surface, Normal Conditions of Transport - All Models.......... 3-36 Table 3-15.

Polynomial Coefficients Used in Equivalent Convective Property of Ambient Temperature and External Surface, Steady-State Leading to the Fire and Cool-Down Conditions - All Models...................................... 3-39 Table 3-16.

Solar Heat Application to Cask Outside Surfaces - All Models......................... 3-42 Table 3-17.

Temperature Monitoring Points by Condition - Model AOS-025A...................... 3-54 Table 3-18.

Normal Conditions of Transport Thermal Evaluation Results - Model AOS-025A.......... 3-56 Table 3-19.

Load Case 101, 100°F Ambient, Maximum Decay Heat - Model AOS-025A.............. 3-58 Table 3-20.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation -

Model AOS-025A........................................................... 3-62 Table 3-21.

Load Case 103, -20°F Ambient, Zero Decay Heat, Zero Insolation - Model AOS-025A..... 3-66 Table 3-22.

Load Case 104, -40°F Ambient, Zero Decay Heat, Zero Insolation - Model AOS-025A..... 3-68 Table 3-23.

Load Case 105, -40°F Ambient, Maximum Decay Heat - Model AOS-025A.............. 3-70 Table 3-24.

Load Case 106, -20°F Ambient, Maximum Decay Heat - Model AOS-025A.............. 3-74 Table 3-25.

Fire Condition Thermal Evaluation Results - Model AOS-025A........................ 3-78 Table 3-26.

Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat -

Model AOS-025A........................................................... 3-83 Table 3-27.

Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Model AOS-025A.......................................... 3-87 Table 3-28.

Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Model AOS-025A.......................................... 3-91 Table 3-29.

Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Model AOS-025A.......................................... 3-95 Table 3-30.

Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Model AOS-025A.......................................... 3-99 Table 3-31.

Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Model AOS-025A......................................... 3-103 Table 3-32.

Temperature Monitoring Points, by Condition - Model AOS-050A..................... 3-107 Table 3-33.

Normal Conditions of Transport Thermal Evaluation Results - Model AOS-050A......... 3-109 Table 3-34.

Load Case 101, 100°F Ambient, Maximum Decay Heat - Model AOS-050A............. 3-111 Table 3-35.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation -

Model AOS-050A.......................................................... 3-115 Table 3-36.

Load Case 103, -20°F Ambient, Zero Decay Heat, Zero Insolation - Model AOS-050A.... 3-119 Table 3-37.

Load Case 104, -40°F Ambient, Zero Decay Heat, Zero Insolation - Model AOS-050A.... 3-121 Table 3-38.

Load Case 105, -40°F Ambient, Maximum Decay Heat - Model AOS-050A............. 3-123 Table 3-39.

Load Case 106, -20°F Ambient, Maximum Decay Heat - Model AOS-050A............. 3-127 Table 3-40.

Fire Condition Thermal Evaluation Results - Model AOS-050A....................... 3-131 Table 3-41.

Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat -

Model AOS-050A.......................................................... 3-136 Table 3-42.

Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Model AOS-050A......................................... 3-140 Table 3-43.

Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Model AOS-050A......................................... 3-144 Table 3-44.

Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Model AOS-050A......................................... 3-148 Table 3-45.

Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Model AOS-050A......................................... 3-152 Table 3-46.

Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Model AOS-050A......................................... 3-156 Table 3-47.

Temperature Monitoring Points, by Condition - Model AOS-100...................... 3-160 Table 3-48.

Normal Conditions of Transport Thermal Evaluation Results -

Models AOS-100A and AOS-100A-S........................................... 3-162 Table 3-49.

Load Case 101, 100°F Ambient, Maximum Decay Heat -

Models AOS-100A and AOS-100A-S........................................... 3-164

xxxii Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 3-50.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation -

Models AOS-100A and AOS-100A-S........................................... 3-168 Table 3-51.

Load Case 103, -20°F Ambient, Zero Decay Heat, Zero Insolation -

Models AOS-100A and AOS-100A-S........................................... 3-172 Table 3-52.

Load Case 104, -40°F Ambient, Zero Decay Heat, Zero Insolation -

Models AOS-100A and AOS-100A-S........................................... 3-174 Table 3-53.

Load Case 105, -40°F Ambient, Maximum Decay Heat -

Models AOS-100A and AOS-100A-S........................................... 3-176 Table 3-54.

Load Case 106, -20°F Ambient, Maximum Decay Heat -

Models AOS-100A and AOS-100A-S........................................... 3-180 Table 3-55.

Fire Condition Thermal Evaluation Results - Models AOS-100A and AOS-100A-S........ 3-184 Table 3-56.

Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat -

Models AOS-100A and AOS-100A-S........................................... 3-189 Table 3-57.

Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Models AOS-100A and AOS-100A-S......................... 3-193 Table 3-58.

Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Models AOS-100A and AOS-100A-S......................... 3-197 Table 3-59.

Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Models AOS-100A and AOS-100A-S......................... 3-201 Table 3-60.

Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Models AOS-100A and AOS-100A-S......................... 3-205 Table 3-61.

Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Models AOS-100A and AOS-100A-S......................... 3-209 Table 3-62.

Normal Conditions of Transport Thermal Evaluation Results - Model AOS-100B......... 3-213 Table 3-63.

Load Case 101, 100°F Ambient, Maximum Decay Heat - Model AOS-100B............. 3-214 Table 3-64.

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation -

Model AOS-100B.......................................................... 3-218 Table 3-65.

Load Case 103, -20°F Ambient, Zero Decay Heat, Zero Insolation - Model AOS-100B.... 3-222 Table 3-66.

Load Case 104, -40°F Ambient, Zero Decay Heat, Zero Insolation - Model AOS-100B.... 3-224 Table 3-67.

Load Case 105, -40°F Ambient, Maximum Decay Heat - Model AOS-100B............. 3-226 Table 3-68.

Load Case 106, -20°F Ambient, Maximum Decay Heat - Model AOS-100B............. 3-230 Table 3-69.

Fire Condition Thermal Evaluation Results - Model AOS-100B....................... 3-234 Table 3-70.

Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat -

Model AOS-100B.......................................................... 3-238 Table 3-71.

Load Case 112, Post Fire at 60 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Model AOS-100B......................................... 3-242 Table 3-72.

Load Case 112, Post Fire at 90 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Model AOS-100B......................................... 3-246 Table 3-73.

Load Case 112, Post Fire at 120 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Model AOS-100B......................................... 3-250 Table 3-74.

Load Case 112, Post Fire at 150 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Model AOS-100B......................................... 3-254 Table 3-75.

Load Case 112, Post Fire at 180 Minutes, 100°F, Maximum Decay Heat, Maximum Insolation - Model AOS-100B......................................... 3-258 Table 3-76.

Summary of Heat Transfer Exact Solution Properties and their Results................. 3-264 Table 3-77.

Comparison of Heat Test GE Model 2000 and LIBRA Results........................ 3-265 Table 3-78.

SS304 Stainless Steel Thermal Properties....................................... 3-269 Table 3-79.

Tungsten Alloy Thermal Properties............................................. 3-272 Table 3-80.

SA-105 Carbon Steel Thermal Properties,....................................... 3-274 Table 3-81.

Air Properties.............................................................. 3-277 Table 3-82.

Fire Condition Impact Limiter Crushed Geometry 30-Ft. Head-On Drop Analysis Results - All Models................................................. 3-284 Table 3-83.

30-Ft. Drop Deformations - Model AOS-100A.................................... 3-296 Table 3-84.

Impact Limiter Foam Properties - Model AOS-100A............................... 3-296 Table 3-85.

Compare Results Provided in Configuration 1 Versus Configuration 2, after 30 Minutes of Fire at 1,475°F - Model AOS-100A............................. 3-300 Table 3-86.

Compare Results Provided in Configuration 1 Versus Configuration 2, 7.5-Hour Cool-Down Transient - Model AOS-100A................................ 3-300

Radioactive Material Transport Packaging System Safety Analysis Report xxxiii for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 3-87.

Compare Results Provided in Configuration 1 Versus Configuration 3, after 30 Minutes of Fire at 1,475°F - Model AOS-100A............................. 3-301 Table 3-88.

Compare Results Provided in Configuration 1 Versus Configuration 3, 7.5-Hour Cool-Down Transient - Model AOS-100A................................ 3-301 Table 3-89.

Total Conductivity - Model AOS-025A.......................................... 3-309 Table 3-90.

Total Conductivity - Model AOS-050A.......................................... 3-311 Table 3-91.

Total Conductivity - Model AOS-100A.......................................... 3-313 Table 3-92.

Total Conductivity - Model AOS-100B.......................................... 3-317 Table 3-93.

Maximum Grashof Number - All Models......................................... 3-320 Table 3-94.

Grashof Number Evaluation at All Air Gaps - Model AOS-025A...................... 3-322 Table 3-95.

Grashof Number Evaluation at All Air Gaps - Model AOS-050A...................... 3-323 Table 3-96.

Grashof Number Evaluation at All Air Gaps - Model AOS-100A...................... 3-324 Table 3-97.

Surface Measurements and Descriptions, Normal Conditions of Transport - Model AOS-025................................. 3-325 Table 3-98.

External Convection Coefficients at 100°F Ambient Temperature, Normal Conditions of Transport - Model AOS-025................................. 3-327 Table 3-99.

External Convection Coefficients at -20°F Ambient Temperature, Normal Conditions of Transport - Model AOS-025................................. 3-329 Table 3-100.

External Convection Coefficients at -40°F Ambient Temperature, Normal Conditions of Transport - Model AOS-025................................. 3-331 Table 3-101.

Surface Measurements and Descriptions, Normal Conditions of Transport - Model AOS-050................................. 3-333 Table 3-102.

External Convection Coefficients at 100°F Ambient Temperature, Normal Conditions of Transport - Model AOS-050................................. 3-335 Table 3-103.

External Convection Coefficients at -20°F Ambient Temperature, Normal Conditions of Transport - Model AOS-050................................. 3-338 Table 3-104.

External Convection Coefficients at -40°F Ambient Temperature, Normal Conditions of Transport - Model AOS-050................................. 3-341 Table 3-105.

Surface Measurements and Descriptions, Normal Conditions of Transport - Models AOS-100A and AOS-100B.................. 3-344 Table 3-106.

External Convection Coefficients at 100°F Ambient Temperature, Normal Conditions of Transport - Models AOS-100A and AOS-100B.................. 3-346 Table 3-107.

External Convection Coefficients at -20°F Ambient Temperature, Normal Conditions of Transport - Models AOS-100A and AOS-100B.................. 3-348 Table 3-108.

External Convection Coefficients at -40°F Ambient Temperature, Normal Conditions of Transport - Models AOS-100A and AOS-100B.................. 3-350 Table 3-109.

Surface Measurements and Descriptions, Hypothetical Accident Conditions of Transport - Model AOS-025..................... 3-352 Table 3-110.

External Convection Coefficients at 100°F Ambient Temperature, Hypothetical Accident Conditions of Transport - Model AOS-025..................... 3-353 Table 3-111.

Surface Measurements and Descriptions, Hypothetical Accident Conditions of Transport - Model AOS-050..................... 3-355 Table 3-112.

External Convection Coefficients at 100°F Ambient Temperature, Hypothetical Accident Conditions of Transport - Model AOS-050..................... 3-357 Table 3-113.

Surface Measurements and Descriptions, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100B....... 3-359 Table 3-114.

External Convection Coefficients at 100°F Ambient Temperature, Hypothetical Accident Conditions of Transport - Models AOS-100A and AOS-100B....... 3-361 Table 3-115.

External Convection Coefficients at 1,475°F Environment, Fire Condition - All Models..... 3-363 Table 3-116.

Plate Temperature and Length Values.......................................... 3-365 Table 3-117.

Air Property Values at 172°F.................................................. 3-365 Table 3-118.

Curved Vertical Plates Used as Flat Vertical Plate Evaluation for Thermal Condition 1 at 100°F Ambient, Maximum Decay Heat, Maximum Insolation (Load Case 102) - All Models................................................. 3-369 Table 3-119.

Maximum Foam Temperature, 24-Hour Solar Heat Transient........................ 3-370 Table 3-120.

Configuration 1 and Configuration 2 Inside Plate and Cylindrical/

Conical Ring Thicknesses - All Models.......................................... 3-375

xxxiv Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 3-121.

Maximum Component Temperatures, Normal Conditions of Transport -

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Model AOS-025A.......................................................... 3-376 Table 3-122.

Maximum Component Temperatures, Hypothetical Accident Conditions of Transport - Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Model AOS-025A........................................ 3-377 Table 3-123.

Maximum Component Temperatures, Hypothetical Accident Conditions of Transport - Load Case 112, 7.5-Hour Cool-Down Transient, Model AOS-025A........ 3-377 Table 3-124.

Maximum Component Temperatures, Normal Conditions of Transport -

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Model AOS-050A.......................................................... 3-378 Table 3-125.

Maximum Component Temperatures, Hypothetical Accident Conditions of Transport - Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Model AOS-050A........................................ 3-379 Table 3-126.

Maximum Component Temperatures, Hypothetical Accident Conditions of Transport - Load Case 112, 7.5-Hour Cool-Down Transient, Model AOS-050A........ 3-379 Table 3-127.

Maximum Component Temperatures, Normal Conditions of Transport -

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Model AOS-100A.......................................................... 3-380 Table 3-128.

Maximum Component Temperatures, Hypothetical Accident Conditions of Transport - Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Model AOS-100A........................................ 3-381 Table 3-129.

Maximum Component Temperatures, Hypothetical Accident Conditions of Transport - Load Case 112, 7.5-Hour Cool-Down Transient, Model AOS-100A........ 3-381 Table 3-130.

Maximum Component Temperatures, Normal Conditions of Transport -

Load Case 102, 100°F Ambient, Maximum Decay Heat, Maximum Insolation, Model AOS-100B.......................................................... 3-382 Table 3-131.

Maximum Component Temperatures, Hypothetical Accident Conditions of Transport - Load Case 111, Fire at 30 Minutes, 1,475°F Ambient, Maximum Decay Heat, Model AOS-100B........................................ 3-383 Table 3-132.

Maximum Component Temperatures, Hypothetical Accident Conditions of Transport - Load Case 112, 7.5-Hour Cool-Down Transient, Model AOS-100B........ 3-383 Table 3-133.

Foam Density Properties - Nominal, 115% Nominal, and 85% Nominal, Model AOS-100A.......................................................... 3-384 Table 3-134.

Comparison of Maximum Component Temperatures with Varying Foam Densities -

Model AOS-100A.......................................................... 3-385 Table 3-135.

Nominal, 115% Nominal, and 80% Nominal Foam Specific Heat Properties -

Model AOS-100A.......................................................... 3-386 Table 3-136.

Comparison of Maximum Component Temperatures with Varying Specific Heat Values - Model AOS-100A................................................... 3-387 Table 3-137.

Case 1, Maximum Component Temperatures..................................... 3-412 Table 3-138.

Case 2, Maximum Component Temperatures..................................... 3-412 Table 3-139.

Case 3, Maximum Component Temperatures..................................... 3-412 Table 3-140.

Case 1, Stress (psi/MPa).................................................... 3-413 Table 3-141.

Case 2, Stress (psi/MPa).................................................... 3-415 Table 3-142.

Case 3, Stress (psi/MPa).................................................... 3-417

4. Containment Table 4-1.

Cask Lid Attachment Bolt Features and Properties Used for Fortran Program Input - All Models............................................. 4-12 Table 4-2.

Cask Lid Attachment Bolt Fortran Program Results Summary - All Models,.............. 4-17 Table 4-3.

Keensert Evaluation - Model AOS-025........................................... 4-20 Table 4-4.

Keensert Evaluation - Model AOS-050........................................... 4-23 Table 4-5.

Keensert Evaluation - Model AOS-100........................................... 4-26 Table 4-6.

Maximum Cask Cavity Pressure Due to Normal Conditions of Transport - All Models...... 4-30 Table 4-7.

Maximum Cask Cavity Pressure Due to Fire Condition - All Models.................... 4-30

Radioactive Material Transport Packaging System Safety Analysis Report xxxv for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

5. Shielding Evaluation Table 5-1.

Cask Component Dimensions, Outside Radius and Half-Height - All Models.............. 5-2 Table 5-2.

Cask Component Dimensions, Cavity Height and Axial Shield Thickness - All Models....... 5-3 Table 5-3.

Cask Component Materials Important to Shielding - All Models......................... 5-4 Table 5-4.

Maximum Radiation Level Summary for Normal Conditions of Transport - All Models....... 5-5 Table 5-5.

Maximum Radiation Level Summary for Hypothetical Accident Conditions of Transport - All Models......................... 5-5 Table 5-6.

Isotopes Analyzed for AOS Transport Packages - All Models.......................... 5-6 Table 5-7.

AOS Cask Components - All Models............................................ 5-11 Table 5-8.

Point Source Locations....................................................... 5-12 Table 5-9.

External Surface Deformation Used for Dose Calculation in Axial Direction - End Drop..... 5-15 Table 5-10.

External Surface Deformation Used for Dose Calculation in Radial Direction - Side Drop... 5-15 Table 5-11.

Distances from Center of Cask Used for Dose Calculations - Axial Location.............. 5-16 Table 5-12.

Distances from Center of Cask Used for Dose Calculations - Radial Location............ 5-16 Table 5-13.

Maximum Radiation Levels (All Isotopes Except Ir-192 and Ir-194) - Model AOS-025A..... 5-22 Table 5-14.

Maximum Radiation Levels (All Isotopes Except Ir-192 and Ir-194) - Model AOS-050A..... 5-23 Table 5-15.

Maximum Radiation Levels (All Isotopes Except Ir-192 and Ir-194) -

Models AOS-100A and AOS-100A-S............................................ 5-24 Table 5-16.

Maximum Radiation Levels (All Isotopes Except Ir-192 and Ir-194) - Model AOS-100B..... 5-25 Table 5-17.

Maximum Ir-192/Ir-194 Radiation Levels - Model AOS-025A.......................... 5-26 Table 5-18.

Maximum Ir-192/Ir-194 Radiation Levels - Model AOS-050A.......................... 5-27 Table 5-19.

Maximum Ir-192/Ir-194 Radiation Levels - Models AOS-100A and AOS-100A-S.......... 5-28 Table 5-20.

Maximum Ir-192/Ir-194 Radiation Levels - Model AOS-100B.......................... 5-28 Table 5-21.

AOS Cask Isotopic Heat Loads (Reference [5.2])................................... 5-30 Table 5-22.

AOS Cask Isotopic Heat Load Results........................................... 5-30 Table 5-23.

Isotope Photon per Decay - All Models.......................................... 5-31 Table 5-24.

Co-60 Gamma Spectra Used in Shielding Models - All Models........................ 5-31 Table 5-25.

Cs-137 Gamma Spectra Used in Shielding Models - All Models....................... 5-32 Table 5-26.

Hf-181 Gamma Spectra Used in Shielding Models - All Models....................... 5-32 Table 5-27.

Ir-192 Gamma Spectra Used in Shielding Models - All Models........................ 5-33 Table 5-28.

Ir-194 Gamma Spectra Used in Shielding Models - All Models........................ 5-35 Table 5-29.

Zr/Nb-95 Gamma Spectra Used in Shielding Models - All Models...................... 5-38 Table 5-30.

THIS TABLE INTENTIONALLY LEFT BLANK..................................... 5-38 Table 5-31.

Yb-169 Gamma Spectra Used in Shielding Models - All Models....................... 5-39 Table 5-32.

Volume Source Analysis - Source Geometry Dimensions............................ 5-43 Table 5-33.

Volume Source Analysis - Results.............................................. 5-43 Table 5-34.

10 CFR 71.47(a) Dose Rate Acceptance Criteria for Multiple Isotopes.................. 5-45 Table 5-35.

Multiple Isotope Calculation Reference Value Summary -

Models AOS-100A and AOS-100A-S............................................ 5-46 Table 5-35a.

Multiple Isotope Calculation Reference Value Summary - Model AOS-025A............. 5-47 Table 5-35b.

Multiple Isotope Calculation Reference Value Summary - Model AOS-050A............. 5-47 Table 5-35c.

Multiple Isotope Calculation Reference Value Summary - Model AOS-100B............. 5-48 Table 5-36.

Low-Energy Gamma External Dose Rates - Models AOS-100A and AOS-100A-S......... 5-49 Table 5-37.

Example Low-Energy Gamma and Beta Emitter Decay Heat Values.................... 5-51 Table 5-38.

Additional Exclusive Use Dose Rate Locations and Activity Limits -

Models AOS-100A and AOS-100A-S............................................ 5-52 Table 5-39.

Exclusive Use Activity Limit Maximum Dose Rates and Decay Heat -

Models AOS-100A and AOS-100A-S............................................ 5-54 Table 5-40.

Exclusive Use Maximum Activity Dose Rates and Decay Heat -

Models AOS-100A and AOS-100A-S............................................ 5-55 Table 5-40a.

10 CFR 71.47(b) Dose Rate Acceptance Criteria for Multiple Isotopes.................. 5-56 Table 5-41.

Multiple Isotope Exclusive Use Calculation Reference Values -

Models AOS-100A and AOS-100A-S............................................ 5-57 Table 5-42.

Approximate Change in Side Dose Rates - Models AOS-050 and AOS-100.............. 5-59 Table 5-43.

Side Dose Rates - Model AOS-050A............................................ 5-62 Table 5-44.

Side Dose Rates - Models AOS-100A and AOS-100A-S............................. 5-63 Table 5-45.

Side Dose Rates - Model AOS-100B............................................ 5-64 Table 5-46.

New Isotopic Dose Rates and Limits - Models AOS-050A, AOS-100A, and AOS-100A-S... 5-64

xxxvi Radioactive Material Transport Packaging System Safety Analysis Report for Model AOS-025, AOS-050, and AOS-100 Transport Packages, Rev. J, January 31, 2021 (Docket No. 71-9316)

Table 5-47.

Impact Limiter Offset Distance Differences - All Models.............................. 5-67 Table 5-48.

Projected Dose Rate Increase within Recessed Regions of Upper and Lower Impact Limiters - All Models................................... 5-68 Table 5-49.

Full Transport Package Surface Dose Rates/Ci - Model AOS-025A.................... 5-70 Table 5-50.

Maximum Transport Package Surface Dose Rate within Recessed Region of Upper and Lower Impact Limiters - Model AOS-025A.............. 5-70 Table 5-51.

Full Transport Package Surface Dose Rates/Ci - Model AOS-050A.................... 5-72 Table 5-52.

Maximum Transport Package Surface Dose Rate within Recessed Region of Upper and Lower Impact Limiters - Model AOS-050A.............. 5-73 Table 5-53.

Dose Rates within Recessed Region of Upper and Lower Impact Limiters - Model AOS-050A............................. 5-75 Table 5-54.

1-m TI Dose Rates/Ci - Models AOS-100A and AOS-100A-S......................... 5-77 Table 5-55.

Maximum 1-m TI Dose Rate within Recessed Region of Upper and Lower Impact Limiters - Models AOS-100A and AOS-100A-S.............. 5-78 Table 5-56.

Maximum Dose Rates within Recessed Region of Upper and Lower Impact Limiters - Models AOS-100A and AOS-100A-S.............. 5-78 Table 5-57.

1-m TI Dose Rate/Ci - Model AOS-100B......................................... 5-80 Table 5-58.

Maximum 1-m TI Dose Rate within Recessed Region of Upper and Lower Impact Limiters - Model AOS-100B............................. 5-81 Table 5-59.

Maximum Dose Rates within Recessed Region of Upper and Lower Impact Limiters - Model AOS-100B............................. 5-81

6. Criticality Evaluation There are no tables in Chapter 6.
7. Package Operations Table 7-1.

Additional Required Shielding -

Models AOS-025A, AOS-050A, AOS-100A, and AOS-100A-S.......................... 7-9 Table 7-2.

Cask Lid Attachment Bolt Size and Preload Torque - All Models....................... 7-11 Table 7-3.

Maximum Distance from Loaded Cask Surface to Take Transport Package Surface Dose Rate Measurements - All Models.................... 7-14

8. Acceptance Tests and Maintenance Program Table 8-1.

Acceptance Test Matrix........................................................ 8-2 Table 8-2.

Type 304 and 316 Material Requirements......................................... 8-5 Table 8-3.

Bolting/Screw Material Requirements............................................. 8-7 Table 8-4.

Casting Pipe/Casting Material Requirements (Type CPF-8, CF-8)....................... 8-8 Table 8-5.

LAST-A-FOAM FR-3700 Series Foams - Testing Program........................... 8-10 Table 8-6.

LAST-A-FOAM FR-3700 Series Foam Dynamic Crush Strength Limits, Parallel to Rise - All Models................................................... 8-12 Table 8-7.

LAST-A-FOAM FR-3700 Series Foam Dynamic Crush Strength Limits, Perpendicular to Rise - All Models.............................................. 8-13 Table 8-8.

Fabrication Examination Program Summary....................................... 8-14

9. Quality Assurance Program There are no tables in Chapter 9.
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