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seeURIW=R!LA1'1!e INP'OltMM'ION - Ylii:1'1111eu, UNBER 18 erR :!.398 NLS2016049 ENCLOSURE 1 Cooper Nuclear Station Flood Hazard Reevaluation Report, Revision 1

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SEeURIT't'-ftELATEt, INFORMATION - Wll't II IOLE) UNDEft 16 CFR 2.S96 H

Nebraska Public Power District Alwnys there when )'011 necJ t,s Cooper Nuclear Station FLOOD HAZARD REEVALUATION REPORT SL-012450 Revision 1 Project No.: 11784-017 September 2016

~ Safety-Related D Non-Safety-Related 55 East Monroe Street* Chicago, IL 60603 USA* 312-269-2000 www.sargentlundy.com SECURIT¥-REb\TEf) INFORMATION - WITltttete UNf>ER 10 Cfifit 2.~90

SECURIT¥=RELATEB 1Nf-ORM>%TION - Y't'ITHHOLB UNBER 18 Cf-R 2.398 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 LEGAL NOTICE This report was prepared by Sargent & Lundy, L.L.C. ("S&L"), expressly for the sole use of Nebraska Public Power District

("Client") in accordance with the agreement between S&L and Client. This Deliverable was prepared using the degree of skill and care ordinarily exercised by engineers practicing under similar circumstances. Client acknowledges: (1) S&L prepared this Deliverable subject to the particular scope limitations, budgetary and time constraints, and business objectives of the Client; (2) information and data provided by others may not have been independently verified by S&L; and (3) the information and data contained in this Deliverable are time-sensitive and changes in the data, applicable codes, standards, and acceptable engineering practices may invalidate the findings of this Deliverable. Any use or reliance upon this Deliverable by third parties shall be at their sole risk.

Legal Notice ii SECURIT'f-RELATEB INf-ORMt<TION - 1t'VITHHOLB UNBER 18 Cf-R 2.398

SECURITY-RELATEB INl'-Oft.MATION - WITHHOLB UNBEft. 10 Cf-ft. 2.390 Nebras ka Public Power Dis trict SL-012450 Cooper Nuclear Station Revision 1 F LOOD H AZARD R EEVALUATION R EPORT Project No,: 1178-017 SIGNATURES Preparer :

Section I f.;~4fM~ Date Reviewer:

Section I

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M. Kaiseruddin Date 21 \ 4- I ' 6

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Preparer: , 1 ~

Sections 2 and '3 M. Salehi Date (except Section 2.3)

Reviewer: .9/ 1 4 /l 6 Sections 2 and 3 N. M. Patel Date (except Section 2.3)

Prepar er:

Section 2.3 N. M. Patel Date

'Reviewer:

Section 2.3 Date Preparer: qbttlL/2 Sections 4 and 5 M. Nienaber Date Approver:

B. E. Jelke Date Signatures Hf ,,.. ,,

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SECUfUTY-RELATEB INl'-Oft.MATION - WITI-IHOLB UNBER 10 CFft. 2.390

SECURIT*RELATEB INFORMATION - WlfHHOLB UNBEff 16 Cfff 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION Rl!PORT Project No.: 11784*017 TABLE OF CONTENTS LEGAL NOTICE ....................................................................................................................................... 11 SIGNATURES ................................................:........................................................................................ 111 TABLE OF CONTENTS ......................................................................................................................... IV LIST OF TABLES ................................................................................................................................... IX LIST OF FIGURES ................................................................................................................................. XI LIST OF ACRONYMS AND ABBREVIATIONS.................................................................................... xv INTRODUCTION/ PURPOSE ............................~................................................................................. XIX

1. SITE INFORMATION RELATED TO THE FLOOD HAZARD .......................................................1-1 1.1 Detalled Site Information ......................................................................................................1-1 1.1.1 Sitelayout ..................................................................................................................... 1-1 1.1.2 Spatial Data Sets............................................................................................................1-2 1.1.3 Elevation of Structures, Systems, and Components (SSCs) .........................................1-2 1.1.4 Topography ....................................................................................................................1-2 1.1.5 Missouri River and Tributaries ........................................................................................1-2 1.2 Current Design Basis Flood Elevatlons ..............................................................................1-4 1.2.1 Summary of CNS External Flood Design and Licensing Basis ......................................1-4 1.2.2 CLB Local Intense Precipitation (LIP) ............................................................................1-6 1.2.3 CLB Flooding in Streams and Rivers .............................................................................1-6 1.2.4 CLB Dam Breaches and Failures ...................................................................................1-7 1.2.5 CLB Storm Surge ........................................................................................................... 1-7 1.2.6 CLBSeiche ....................................................................................................................1-7 1.2.7 CLB Tsunami. .................................................................................................................1-7 1.2.8 CLB Ice-Induced Flooding ..............................................................................................1-7 1.2.9 CLB Channel Migration or Diversion ..............................................................................1-7 Table of Contents

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SECURlf'f-RELAfEB INf-ORMAflON - WlfHHOLB UNE>ER 16 CFR 2.396

SECURIT'f-RELA'fED INI-ORMA'ffON - 1t'VITI II IOLB UNDER 16 CFR 2.398 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 1.2.10 CLB Combined Effects ...................................................................................................1-8 1.2.11 CLB Associated Effects ..................................................................................................1-8 1.3 Flood-Related Changes and Flood Protection Changes .................................................1-10 1.4 Changes to the Watershed or to the Local Area .............................................................. 1-11 1.5 Current Design Basis Flood Protection and Mitigation Fe;atures ...................................1-12 1.6 Additional Site Detail...........................................................................................................1-16 1.7 References ...........................................................................................................................1-17 1.8 Tables ...................................................................................................................................1-19 1.9 Fig ures..................................................................................................................................1-22

2. FLOOD HAZARD REEVALUATION .............................................................................................2-1 2.1 Local Intense Precipitation (LIP) ..........................................................................................2-1 2.1.1 Probable Maximum Precipitation Depths .......................................................................2- 1 2.1.2 Drainage Areas and Local Drainage Parameters ...........................................................2-2 2.1.3 Peak Discharges ..,.........................................................................................................2-3 2.1.4 Hydraulic Model Setup ...................................................................................................2-3 2.1.5 Effect of LIP .................................................................................................................... 2-6 2.1.6 References ............................,........................................................................................2-6 2.1.7 Tables.............................................................................................................................2-8 2.1.8 Figures .........................................................................................................................2-15 2.2 Flooding in Streams and Rivers (PMF)..............................................................................2-32 2.2.1 Probable Maximum Precipitation (PMP) ......................................................................2-33 2.2.2 PMP Runoff Hydrographs ............................................................................................2-35 2.2.3 Water Level Determinations .........................................................................................2-37 2.2.4 Combined Effects .........................................................................................................2-44 2.2.5 Associated Flooding Impacts .......................................................................................2-46 2.2.6 References ...................................................................................................................2-48 Table of Contents _ ( ..

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9ECURIT¥-RELATEB INFORM>\TION - Wl'fHHOLD UN BER 16 e1-R 2.998

SECURITY-RELATED INFORMATION - WITtlllOLD UNDER 16 CFR 2.396 Nebraska Public Power District SL--01 2450 Cooper Nuclear Station Revision 1 FLOOD HAZARD Rl!l!VALUATION REPORT Project No.: 11784-017 2.2.7 Tables ...........................................................................................................................2-52 2.2.8 Figures ......................................................,.................................................................. 2-63 2.3 Dam Breaches and Fallures ...............................................................................................2-92 2.3.1 Flood Protection Level at the CNS Site ........................................................................2-94 2.3.2 Hydrologic Evaluation ...................................................................................................2-94 2.3.3 Hydraulic Evaluation .....................................................................................................2-98 2.3.4 Combined Effects .......................................................................................................2-104 2.3.5 Associated Flooding Impacts .....................................................................................2-105 2.3.6 References .................................................................................................................2-109 2.3.7 Tables.........................................................................................................................2-111 2.3.8 Figures .......................................................................................................................2-133 2.4 Storm Surge .......................................................................................................................2-168 2.4.1 References .................................................................................................................2-168 2.5 Seiche .................................................................................................................................2-169 2.5.1 References .................................................................................................................2-169 2.6 Tsunaml ..............................................................................................................................2-170 2.6 .1 References .................................................................................................................2-170 2.7 Ice-Induced Flooding ........................................................................................................2-171 2.7.1 Methodology ...............................................................................................................2-171 2.7.2 Most Severe Historical Ice Jam Event.. ......................................................................2-171 2.7.3 Upstream Breach ofan Ice Dam ................................................................................2-172 2.7.4 Downstream Ice Jam and Resulting Backwater .........................................................2-172 2.7.5 Effect of Ice-Induced Flooding ....................................................................................2-172 2.7 .6 References .................................................................................................................2-173 2.7.7 Figure .........................................................................................................................2-174 2.8 Channel Migration or Diversion .......................................................................................2-176 2.8.1 Historical Channel Migration or Diversion ..................................................................2-176 2.8.2 Regional Topographic Evidence ................................................................................2-177 2.8.3 Ice Causes .................................................................................................................2-179 Table of Contents vi Sa.1r9ant: &, Lundy

• SECUfflTY-M'ELATEE> INFOffMATION - V't~ITHHOLE> UNflEff 16 CFff ! .~96

SECUR:IT¥-RELATEB INFOR:MATl6N - VtlTI ltl6LE> UN BER 16 CFR 2.396 Nebraska Public Power District SL.012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZARD REEVALUATION REPORT 2.8.4 Flooding of Site Due to Channel Migration or Diversion .............................................2-179 I

2.8.5 Human-Induced Changes of Channel Diversion ........................................................2-180 2.8.6 Conclusions ................................................................................................................2-180 2.8.7 References .................................................................................................................2-181 2.8.8 Figures .......................................................................................................................2-184 2.9 Combined Effects ..............................................................................................................2-199 2.9.1 References .................................................................................................................2-199

3. COMPARISON OF CURRENT AND REEVALUATED FLOOD-CAUSING MECHANISMS ........3-1 3.1 Local Intense Precipitation ...................................................................................................3-1 3.2 Flooding in Streams and Rivers...........................................................................................3-1 3.3 Dam Breaches and Failures ........................................................................................... '......3*2 3.4 Storm Surge ...........................................................................................................................3-3 3.5 Seiche .....................................................................................................................................3-3 3.6 Tsunami ..................................................................................................................................3-3 3.7 Ice-Induced Flooding ............................................................................................................3-3 3.8 Channel Migration or Diversion ...........................................................................................3-4 3.9 Combined Effects ..................................................................................................................3-4 3.10 Associated Effects ................................................................................................................3-4 3.10.1 Hydrostatic and Hydrodynamic Loads............................................................................3-4 3.10.2 Debris Loads ..................................................................................................................3-5 3.10.3 Erosion and Sedimentation ............................................................................................3-5 3.11 Other Pertinent Factors ................................................................................,........................3-5 3.11.1 Flood Duration ................................................................................................................3-5 3.11.2 Overtopping ....................................................................................................................3-5 3.1 1.3 Inundation .......................................................................................................................3-6 3.12 Conclusions .......................................................................... "................................................3-6 Table of Contents /*!"

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SECURIT'f-RELATEE> INFORrMTl6N - WITHH6LE> UNE>ER 16 CFft 2.396

8ECURIT¥-RELATED INFORMATION - WITHHOLD UNDER 16 CFR 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZARD REEVALUATION REPORT 3.13 References .............................................................................................................................3-6 3.14 Tables .....................................................................................................................................3-7

4. INTERIM EVALUATION AND ACTIONS TAKEN OR PLANNED ................................................4-1 4, 1 Regulatory Background ................ .,,........ ,.. ,......................,............ ,............................... ,,., ..4-1 4.2 Evaluation of the Impact of the Reevaluated Flood Levels on Structures, Systems, and Components (SSCs) ........................................................ ,....................................................4-1 4.3 Interim Evaluatlon and Actions Taken or Planned for CNS ..............................................4-2 4.3.1 Dam Failure_.................................................................................................................. .4~2 4.3.2 Channel Migration or Diversion ..................................................................................... .4-3 4.4 Reference ........................................................................................................................... ,...4-3

5. ADDITIONAL ACTJONS ... ,................. ,................................ ,......................................................... 5-1 Table of Contents .,,,..,--*

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SECURIT¥=~ELATED INFORMATION - VtlTHHOLD UNE>ER 16 CFR ! .S90

SECURIT-RELAfEB INFORMATION - WITHHOLB UND!R 16 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 LIST OF TABLES Table 1.8-1: Missouri River Dams ...........................................................................................................................................1-20 Table 1.8-2: Design Evaluation Summary ...............................................................................................................................1-20 Table 1.8-3: Missouri River Drainage Area .............................................................................................................................1-21 Table 2.1-1: PMP Values and Intensities at the CNS Site .........................................................................................................2-9 Table 2.1-2: Peak Discharge .....................................................................................................................................................2-9 Table 2.1-3: Drainage Area and Peak Flow at each Cross Section-Zone A .........................................................................2-1 0 Table 2.1-4: Drainage Area and Peak Flow at each Cross Section - Zone B .........................................................................2-11 Table 2.1-5: Drainage Area and Peak Flow at each Cross Section- Zone C .........................................................................2-12 Table 2.1-6: Drainage Area and Peak Flow at each Cross Section -Zone D .........................................................................2-13 Table 2.1-7: PMP Water Levels ..............................................................................................................................................2-14 Table 2.2-1: Point 3 (shown in Figure 2.2-4) AdjuS1ed Precipitation Depths Based on HMR 52 .............................................2-53 Table 2.2-2: Model Input Parameter Definitions and References ............................................................................................ 2-54 Table 2.2-3: Summary of Unsteady Computational Parameters .............................................................................................2-56 Table 2.2-4: Location of Inflow Hydrographs........................................................................................................................... 2-56 Table 2.2-5: Comparison of Manning's Roughness Coefficients used in the Model to Standard Values ................................ 2-57 Table 2.2-6: NSE Coefficient S1Jmmary and Peak Discharge Comparison for 2011 Validation Simulation ............................. 2-57 Table 2.2-7: Inflow Hydrograph Location Summary for PMF Simulations ...............................................................................2-58 Table 2.2-8: PMF Simulations Peak Magnitude and Time at RM 556.16 ................................................................................2-60 Table 2.2-9: Monitoring Point Summary ..................................................................................................................................2-60 Table 2.2-10: Calculation of Wind-Driven Waves and Wind Setup Approaching CNS ............................................................2-61 Table 2.2-11: Submerged Embankment Results.....................................................................................................................2-61 Table 2.2-12: Wave Runup Approaching CNS Main BuHding Complex ..................................................................................2-61 Table 2.2-13: Forces on Intake Structure ................................................................................................................................ 2-62 Table 2.2-14: Debris Impact Loads ......................................................................................................................................... 2-62 Table 2.3-1: Salient Features of Missouri River Mainstem Dams..........................................................................................2-112 Table 2.3-2: Dam Break Parameters for Hypothetical Dams.................................................................................................2-113 Table 2.3-3: HEC-HMS Model Input Parameters and Definitions.......................................................................................... 2-116 List of Tables ix SECURITY-RELATED INFORMATION - WITHHOLB UNBER 16 CFR 2.396

SECURIT'f-RELATEf> INFORMATION - WITHHOLf) UNf>ER 16 CFR ! .396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Table 2.3-4: Hypothetical Dam Outflow Summary from HEC-HMS Model ............................................................................ 2-1 18 Table 2.3-5: 500-Year Flow on Missouri River at Drainage Locations .................................................................................. 2-121 Table 2.3-6: Peak Flow at HEl>RAS Inflow Locations ..........................................................................................................2-122 Table 2.3-7: Land Use Types and Manning's Roughness Coefficients ................................................................................. 2-124 Table 2.3-8: Non-System Dam Failure Peak Stage at CNS and Plant Flood Protection Level ............................................. 2-124 Table 2.3-9: Peak Stage/Flow at CNS for Combined System and Non-System Dam Failure ............................................... 2-125 Table 2.3-10: Model Boundaries for TUFLOW ...................................................................................................................... 2-126 Table 2.3-11 : Maximum Channel and Right Overbank Discharge end WSEL at CNS for Upstream Boundary Sensitivity Analysis ............................................................:.....................................................................................................2-126 Table 2.3-12: Monitoring Point Summary for Fort Peck Hydrologic Dem Failure .........................................:........................ 2-127 Table 2.3-13: Monitoring Point Summary for Oahe Sunny-Day Dam Failure ........................................................................ 2-127 T"ble 2.3-14: Calculation of Wind-Driven Waves and Wind Setup Approaching CNS ..........................................................2-128 Table 2.3-15: Summary of Wind Setup, Wave Runup, and Total Water Levels at SSCs ......................................................2-128 Table 2.3-16: Summary of Water Depth above Roof at Important Plant Structures .............................................................. 2-129 Table 2.3-17: Summary of Water Depth above Bridge Deck at Important Bridges ...............................................................2-130 Table 2.3-18: Resultant Forces and Elevations on Main Building Complex Structures ......................................................... 2-131 Table 2.3-19: Resultant Forces and Elevations on Intake Structure .....................................................................................2-131 Table 2.3-20: Debris Impact Loads ....................................................................................................................................... 2-132 Table 3.14-1: Current Licensing Flood Elevations and Reevaluated Flood-Causing Mechanisms ...........................................3-8 Table 3.14-2: Debris Impact Loads Summary ..............................................................................................., ........................... 3-9 List of Tables X

SECURIT11'=RELATEf> INFORMATION - 't'VITI IHOLf> UNf>ER 16 CFR 2.996

s~eURITY-RELATEB INFORMATION - WITtftlOLB UNDER 18 eFR 2.398 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784*017 LIST OF FIGURES Figure 1.9*1 : Site Location ......................................................................................................................................................1-23 Figure 1.9-2: Missouri River Tributaries .................................................................................................................................. 1-24 Figure 1.9-3: Overhead View of CNS 1 ................................................................................................................................... 1-25 Figure 1.9-4: Overhead View of CNS 2 ................................................................................................................................... 1-26 ,

Figure 1.9-5: Missouri River Reservoir System .......................................................................................................................1-27 Figure 1.9-6: Missouri River Path in 1879 at the Site of CNS.................................................................................................. 1-28 Figure 1.9-7: Aerial Photograph of the Plant Site in 1971 ....................................................................................................... 1-29 Figure 1.9-8: Aerial Photograph of CNS Showing Flooding .................................................................................................... 1.30 Figure 2.1-1: Locatlon of Security Barriers ..............................................................................................................................2-16 Figure 2.1-2: Drainage Areas for LIP Evaluation .....................................................................................................................2-17 Figure 2.1-3: Offsite Drainage Area behind USACE levee ..................................................................................................... 2- 18 Figure 2.1-4: Cross Sections for LIP Evaluation - Zone A ....................................................................................................... 2-19 Figure 2.1-5: _C ross Sections for LIP Evaluation - Zone B .......................................................................................................2-20 Figure 2.1-6: Cross Sections for LIP Evaluation - Zone C ....................................................................................................... 2-21 Figure 2.1-7: Cross Sections for LIP Evaluation - Zone D ....................................................................................................... 2-22 Figure 2.1-8: HEC-RAS Cross Sections for Zone A ................................................................................................................2-23 Figure 2.1*9: HEC-RAS Cross Sections for Zone B (sheet 1 of 2) ..................................................................................._.......2-24 Figure 2.1-10: H EC-RAS Cross Sections for Zone C (sheet 1 of 2) ........................................................................................2-26 Figure 2.1-11: HEC-RAS Cross Sections for Zone D (sheet 1 of 4) ........................................................................................ 2-28 Figure 2.2- 1: location Map .....................................................................................................................................................2-64 Figure 2.2-2: PMP Position 1 - Sheet a (see subsequent Sheets b, c, and d for PMP Positions 2 to 4) .................................2-65 Figure 2.2-3: Geographic Distribution of Basins o f Influence for Missouri River Drainage above CNS ................................... 2-69 Figure 2.2-4: PMP Spatial Distribution over Platte River Basin (P3 Centroid; 41 .35N, 96.20W) ............................................. 2-70 Figure 2.2-5: Antecedent Final Model PMF Hydrographs for P1, P2, P3, and P4 ................................................................... 2-71 Figure 2.2-6: Subsequent Storm Final Model PMF Hydrographs for P1 , P2, P3, and P4 ....................................................... 2-72 Figure 2.2-7: Missouri River Junctions ....................................................................................................................................2-73 Figure 2.2-8: Full Floodplain PMF Hydrographs for Gavins Point Release of 160,000 cfs ...................................................... 2-74 List of Figures xi SECURIT¥-RELATEB INFORMATION 'VITttHOLD UNBER 16 CFR 2.996

SEOURIT¥*REU<f!B INl-6RMJ!ltfl6N - WITHHOLB UNB!ff 16 CI-R 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Figure 2.2-9: PMF Hydrographs for 2-0 Model Upstream Boundary RM 556.16 .................................................................... 2-75 Figure 2.2-10: PMF Downstream Boundary Condition Rating Curve RM 510.03....................................................................2-76 Figure 2.2-11: Study Area Overview for the 2-0 Model........................................................................................................... 2-77 Figure 2.2-12: Spatial Distribution of Land Use Classes to Determine Manning's Roughness Coefficients ............................ 2-78 Figure 2.2-13: Computational Mesh Overview ..................................................................................*..................................... 2-79 Figure 2.2-14: Computational Mesh Near CNS....................................................................................................................... 2-80 Figure 2.2-15: 2-0 Model Inflow Hydrographs......................................................................................................................... 2-81 Figure 2.2-16: Comparison of Discharge Hydrographs through the Study Reach...................................................................2-82 Figure 2.2-17: Contours of Maximum Water Surface Elevation for PMF Event - Large Scale................................................ 2-83 Figure 2.2-18: Contours of Maximum Water Surface Elevation for PMF Event- Small Scale ................................................ 2-84 Figure ~*2:.19: Contours of Maximum Depth for PMF Event- Overview.......................:***********...............................................2-85 Figure Z:2-20: Contours of Maximum Depth for PMF Event- Small Scale.............................................................................2-86 Figure 2.2-21: Contours of Maximum Velocity for PMF Event- Small Scale ..........................................................................2-87 Figure 2.2-22: Fetches from Embankment Points of Interest .................................................................................................. 2-88 Figure 2.2-23: Labeled Points of Interest ................................................................................................................................2-89 (bJ(3) 1 U '> C. § 8240 Figure 2.2-24: -1(d) (b)(4) (b)(7)(F) and Locations of Interior Runup Calculations ...*.........................................................2-90 Figure 2.2-25: Expected Maximum Extent of Wave Runup at Representative Locations........................................................ 2-91 Figure 2.3-1 : Non-System Dams Downstream of Gavins Point Dam ............................*....................................*.................. 2-134 Figure 2.3-2: Remaining Non-System Dams Downstream of Gavins Point after Screening Inconsequential Dams ............. 2-135 t~~E~/fJ;(~} Figure2:3-3:HEt>HMS*Plan*for*MissourrRiverbet~ to Omaha, l',IE....................................................2-136 Figure 2.3-4: HEC-HMS Plan for Missouri River from Omaha, NE to CNS ...........................................................................2-137 (b)(3) 16 Figure 2.3-5: Dam Failure Hydrographs at u s c § Dam due to System Hydrologic Dam Failure ................................ 2-138 824o-1(d)

Figure 2.3-6: Dam Failure Hydrographs at (b)t4) (b,i7J Dam due to System Sunny-Day Dam Failure ...............................2-139

~b~(il~~ (~}~{~)*~.ig~r1:1 ?}:?: §t:!!~cted pam Fail1Lr.eJ:iY-dtographs am due to System Dam Failure ...................................2-140 (4) (b)(7)(F) Figure 2.3-8: Land Use Classes Used for Manning's Roughness Coefficient ....................................................................... 2-141 Figure 2.3-9: Estimated Peak Stage at CNS due to Non-System Dam Failure ..................................................................... 2-142 Figure 2.3-10: Estimated Peak Stage at CNS due to System and Non-System Dam Failure ..*............................................2-143 Figure 2.3-11 : Estimated Peak Discharge at CNS due to System and Non-System Dam Failure ........................................2-144 Figure 2.3-12: Study Area Overview .....................................................................................................................................2-145 Figure 2.3-13: Computational Mesh Overview ......................................................................................................................2-146 List of Figures , .../

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seeURIT¥-REU<TEB INF6RM1'Tl6N - Vrlfl l~IOLD UNBER 18 CFR 2.998

S!CUfflT'(-ftl!LATl!O INfiOftMATION - WITHHOLE> UNE>Eff 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD Rl!l!VALUATION REPORT Project No.: 11784*017 Figure 2.3-14: Computational Mesh Near CNS ..................................................................................................................... 2-147 Figure 2.3-15: Building Roof Elevations Included in Model (ft NAVD88) ............................................................................... 2-148 Figure 2.3-16: Model Boundary Condition Location and Type ..............................................................................................2-149 Figure 2.3-17: Discharge Hydrographs for Upstream Boundary and Stage Hydrograph for Downstream Boundary J * *1-~~~~l~~~(~)~(~)

Hydrologic Failure ..................... ..............................................................................................................................2-150(4) (b)(7)(F)

Figure 2.3*18: Discharge Hydrographs for Upstream Boundary and Stage Hydrograph for Downstream Boundary J . . . . j ~b~~~~~~)s(~)

Sunny-Day Failure ..................................................................................................................................................2-151 (4) (b)(7)(F)

Figure 2.3-19: Site Monitoring Points forWSEL Depth and Velocity During Dam Failure Events .........................................2-152 31 6

Figure 2.3-20:l\~)~ ~ I Hyd. Failure - Overview of Velocity Magnitude at 1/10/3000 20:30 (time of maximum velocity with WSEL above plant flood protection elevation at Point 11) ......................................................................................2-153 (b)(3)16USC

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• I I Hyd. Failure- Mid-Level View of Velocity Magnitude at 1/10/3000 20:30 (time of maximum velocity (4), (b)(7)(F) with WSEL above plant flood protection elevation at Point 11) ...............................................................................2-154

~b~~l~~{~)~(;} Figure.2.,a.22{ *** * ...  ! Hyd. Failure - Site-Level View of Velocity Magnitude at 1/10/3000 20:30 (time of maximum velocity (4) (b)(l)(F) with WSEL above plant flood protection elevation at Point 11) ................................................:..............................2-155 Figure 2.3-23 CT)~3b1; Hyd. Failure - WSEL Overview at 1/11/3000 20:20 (time of max. WSEL at Site) ..........................2-156 l24o-1 (d)

Flgure 2.3*24.J(b)(

4) (b) Hyd. Failure - WSEL Mid*Level View at 1/11/3000 20:20 (time of max. WSEL at Site) .................2-157 Figure 2.3-25: (l)(F) Hyd. Failure - WSEL Site-Level View at 1/11/3000 20:20 (time of max. WSEL at Site).................2-158 Figure 2.3-26: WSEL with Fetch Overlay ..............................................................................................................................2-159 Figure 2.3-27: Fetch Directions for Waves Approaching Plant East and Plant West ............................................................2-160 Figure 2.3-28: Fetch Directions for Waves Approaching Plant North and Plant South .......................................................... 2-161 Figure 2.3-29: Plan View of Pressure Calculation Surfaces for j~l( (ii,4) (b)(l)(F) 40* 1 ....................................................2-162 Figure 2.3-30: Groundi::over in Vicini of CNS......................................................................................................................2-163 (b)(3) 1 Figure 2.3*31 : Inundation Map for u Sc § Hydrologic Dam Failure Scenario (Large-Scale Map) ..................................... 2-164 82401 Figure 2.3-32: Inundation Map for (d) (b) Hydrologic Dam Failure Scenario (Medium-Scale Map) .................................2-165 (4) (b)(7)

Figure 2.3*33: Inundation Map for (F) Hydrologic Dam Failure Scenario (Small-Scale Map) ..................................... 2-166 Figure 2.3-34: Bridge Location Map ...................................................................................................................................... 2-167 Figure 2. 7-1 : Hydrologic Unit Code (HUC) for Different Watersheds Upstream and Downstream of the Site ....................... 2-175 Figure 2.8-1: 1879 Land Cover .............................................................................................................................................2-185 Figure 2.8*2: 1940 Aerial Photography.................................................................................................................................. 2-186 Figure 2.8-3: 1965 Aerial Photography..................................................................................................................................2-187 Figure 2.8-4: 1993 Aerial Photography..................................................................................................................................2-188 Figure 2.8-5: 1999 Aerial Photography.................................................................................................................................. 2-189 List of Figures ,.,,/,'

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9ECUR:IT¥-R:ELATED INFORMATION - WITtt~tOLD UNDER: 18 CFR: 2.398 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784*017 FLOOD HAZAR.D REEVALUATION REPORT Figure 2.8-6: 2003 Aerial Photography..................................................................................................................................2-190 Figure 2.8-7: 2005 Aerial Photography..................................................................................................................................2-191 Figure 2.8*8: 2010 Aerial Photography..................................................................................................................................2-192 Figure 2.8-9: Hydric Soils ......................................................................................................................................................2-193 Figure 2.8-10: Geomorphic Soil Description ..........................................................................................................................2-194 Figure 2.8-11: Soil Textures ..................................................................................................................................................2-195 Figure 2.8-12: 2011 Landsat Thematic Mapper Surface Reflectance On-demand ...............................................................2-196 Figure 2.8-13: 2012 Aerial Photography................................................................................................................................ 2-197 Figure 2.8-14: 2011 Flood Breach Locations ........................................................................................................................2-198 List of Figures xiv .. \

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SECURIT'f-R:ELATED INFORMATION - 'NITliHOLD UNDER 18 CFR: 2.998

SECURIT'1'*RELATEO INfiORMATION - WITHHOLD UNDER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION Rl!PORT Project No.: 11784-017 LIST OF ACRONYMS AND ABBREVIATIONS Acronym or Abbreviation Explanation 1-, 2-, 3-D one-dimensional, two-dimensional, three-dimensional ac acre ac-ft acre-feet ACES Automated Coastal Engineering System AEC U.S. Atomic Energy Commission AEP annual exceedance probability ANS American Nuclear Society ANSI American National Standards Institute ASCIE American Society of Civil Engineers BSNP bank stabilization and navigation project BWR boiling water reactor CFR Code of Federal Regulations CEDAS Coastal Engineering Design & Analysis System CEM Coastal Engineering Manual cfs cubic feet per second CLB Current Licensing Basis CNS Cooper Nuclear Station COL combined operating license CRREL Cold Regions Research and Engineering Laboratory DEM digital elevation model ERP Elevated Release Point ESP early site permit ESPA early site permit application ESRI Environmental Systems Research Institute FEMA Federal Emergency Management Agency FHR flood hazard reevaluation List of Acronyms and Abbreviations ,,,.:-;'

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SECURIT¥-RELATED INFORMATION - WITHHOLD UNDER 16 CI-R 2.996

SECURIT¥*RELATEC, INFORMATION - 'NITHHOLB UNBER 16 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Acronym or Abbreviation Explanation FIS flood insurance study ft feet fps feet per second FSAR Final Safety Analysis Report GI Generic Issue GIS geographical information system HEC-HMS Hydrologlc Engineering Center Hydrologic Modeling System HEC-RAS Hydrolog!c Engineering Center River Analysis System HHA Hierarchical Hazard Assessment spectral significant wave height HMR Hydrometeorological Report hr hour HTab Hydraulic Table HU hydrologic unit HWM high-water mark in Inch in/hr inch per hour IPEEE Individual Plant Examination for External Events ISFSI Independent Spent Fuel Storage Installation ISG Interim Staff Guidance kips 1,000-pound force lb pound LiDAR Light Detection and Ranging LIP Local Intense Precipitation LOB Left Overbank m meter mi mile min minute List of Acronyms and Abbreviations I \

xvi S.argor\~ ~ j Lundy I l c SECURIT¥-RELATED INFORMATION - WITHHOLB UNBER 16 CFR 2.996

SECURIT¥-REUcfED INl'OptMATION - WITI II IOLB UNBER 18 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Acronym or Abbreviation Explanation mph mile per hour MPF Multi-Purpose Facility MSL mean sea level MWe megawatt electric MWt megawatt thermal NAVD88 North American Vertical Datum of 1988 NCDC National Climatic Data Center NCHRP National Cooperative Highway Research Program NDNR Nebraska Department of Natural Resources N°EmbE north embankment east NGVD29 National Geodetic Vertical Datum of 1929 NID National Inventory of Dams NLSWE Non-linear Shallow Water Equation NOAA National Oceanic and Atmospheric Administration NPPD Nebraska Public Power District NRC U.S. Nuclear Regulatory Commission NRCS Natural Resources Conservation Service NSE Nash-Sutcliffe efficiency coefficient NTTF Near-Term Task Force NWS National Weather Service PA Protected Area PBL planetary boundary layer PMF Probable Maximum Flood PMP Probable Maximum Precipitation PMT Probable Maximum Tsunami psf pound per square foot RCIC Reactor Core Isolation Cooling RHR Residual Heat Removal List of Acronyms and Abbreviations xvii ' .

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J, SECURIT¥-RELATEB INFORMATION - \VITI II IOLB UNBER 18 CFR 2.998

SE6URIT¥-REt:Al'eo INfiORM>\l'ION - rtfll'HHOLE> UNE>ER 16 eFR 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZARD REEVALUATION REPORT Acronym or Abbreviation Explanation RG Regulatory Guide RM River Mile ROB Right Overbank scs Soil Conservation Services SER Safety Evaluation Report SGTS Standby Gas Treatment System SSC structure, system, and component Tp peak wave period tpd tons per day UMRSFFS Upper Mississippi River System Flow Frequency Study USAGE U.S. Army Corps of Engineers USAGE-OD USACE Omaha District USAR Updated Safety Analysis Report USBR United States Bureau of Reclamation USCG United States Coast Guard USDA United States Department of Agriculture USGS United States Geological Survey VBS vehicle barrier system WEmbN west embankment north WEmbS west embankment south WEmbW west embankment west WRF width reduction factor WSEL water surface elevation List of Acronyms and Abbreviations xviii Sorg0_;t,& Lundy 11 Q

', I SE6UfUT'f -RELATED INFORM1'TION - WITI II IOLD UNDER 18 CFR 2.998

8ECURl'fY-REUlc'fEB INfiORMA'flON - Wl'fHHOLB UNBER 16 CfiR 2.996 Nebraska Plllblic Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 INTRODUCTION / PURPOSE Following the accident at the Fukushima Dai-ichi nuclear power plant resulting from the March 11 ,

2011 , Great Tohoku Earthquake and subsequent tsunami, the U.S. Nuclear Regulatory Commission (NRC) established the Near-Term Task Force (NTTF). The NTTF Charter tasked the NTTF with conducting a systematic and methodical review of NRC processes and regulations to determine if the agency should make additional improvements to its regulatory system. Ultimately, a comprehensive set of recommendations was developed.

In response to the NTTF recommendations and pursuant to Sections 161.c, 103.b, and 182.a of the Atomic Energy Act of 1954, as amended, and Title 10 of the Code of Federal Regulations (10 CFR),

Section 50.54(f), the NRC has requested information from all operating power plant licensees. The purpose of the request is to gather information to:

• Reevaluate seismic and flooding hazards at U.S. operating reactor sites.

• Eacilitate the U.S. Nuclear Regulatory Commission's (NRC) determination if there is a need to update the design basis and structures, systems, and components (SSCs) important to safety to protect against the updated hazards at operating reactor sites.

• Address Generic Issue (GI) 204 regarding flooding of nuclear power plant sites following upstream dam failures.

The information request relating to flooding hazards requires licensees to reevaluate their sites applying present-day regulatory guidance and methodologies being used for early site permit (ESP) and combined operating license (COL) reviews, including current techniques, software, and methods used in present-day standard engineering practice to perform the flood hazard studies. The results are compared against the site's current licensing basis (CLB) for protectiotn and mitigation from external flood events.

This report describes the flooding reevaluation performed for Cooper Nuclear Station (CNS). This report satisfies the information requested by Enclosure 2 (Recommendation 2.1: Flooding) of U.S. NRC letter, Request For Information Pursuant To Title 10 Of The Code Of Federal Regulations 50.54(()

Regarding Recommendations 2.1, 2.3, And 9.3, Of The Near-Term Task Force Review Oflnsights From The Fukushima Dai-Ichi Accident, dated March 12, 2012 (Reference 1.7-1 ).

Introduction I Purpose __,,.

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8EOURIT¥*RELATED INFORMATION - Wl'fHHOLB UNDER 16 CfiR 2.996

9ECURIT¥-RELATEE> INFORMATION - WITHHOLE> UNE>ER 16 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZA'RD REl!VALUATION REPoRT

1. SITE INFORMATION RELATED TO THE FLOOD HAZARD 1.1 DETAILED SITE INFORMATION Cooper Nuclear Station (CNS) is located on the Nebraska portion of a 1,090-acre (ac) site (Reference 1.7-2, Section 1.1) in Nemaha County, Nebraska and Atchison County, Missouri.

The plant, located approximately 55 miles (mi) south-southeast of Omaha, Nebraska and 100 mi north-northwest of Kansas City, Kansas, is on the west bank of the Missouri River at River Mile (RM) 532.5 located midway between the villages of Brownville and Nemaha, Nebraska. ArcMap was used to show the location of the plant (see Figure 1.9-1 ). This portion of the Missouri River is referred to as the Lower Brownville Bend. The U.S. Army Corps of Engineers (USACE) has stabilized the channel near the plant using pile dikes and bank protection. This control prevents meandering of the river within the alluvial flood plain (Reference 1.7-3, Section 4.1).

The Missouri River flows past the site in a southeaster1y direction under open-river conditions, there being no downstream dams to control the stage of the river. In the vicinity of CNS, levees with crest elevations of approximately 902 feet (ft) mean sea level (MSL) control the river section during flood stages. River flow is controlled by a series of flood control dams on the upper Missouri River, which are operated by the USACE for a number of authorized purposes, including flood control, navigation, irrigation, power, water supply, water quality control, recreation, and fish and wildlife. The Platte River (see Figure 1.9-2) is a major source of flow and joins the Missouri River south of Omaha, Nebraska.

Maximum water surface elevation (WSEL) at the CNS site, as reported by the USACE, was 899 ft MSL in 1952 prior to the installation of the upstream control dams. Peak flood flow In 1952 was 414,000 cubic feet per second (cfs), which would have been reduced to approximately 100,000 cfs if today's controls had been in place at that time.

The site coordinates are approximately 40° 21' north latitude and 95° 38' west longitude (Reference 1.7-4, Chapter II, Section 2.1). See Figure 1.9-1, Figure 1.9-3, and Figure 1.9-4 for various views of the plant.

1.1.1 Site Layout CNS consists of a single boiling water reactor (BWR) with a capacity of 835.5 megawatt electric (MWe) / 2,419 megawatt thermal (M\/Vt) and first went into service on July 1, 1974 (Reference 1.7-4, Chapter I, Section 1.0).

The principal! structures of the station consist of the Reactor Building, Turbine Building (including service area appendages), Control Building, Radwaste Building, Augmented Radwaste Building, Intake Structure, Diesel Generator Building, Drywall and Suppression Chamber, Miscellaneous Circulating Water System Structures (e.g., circulating water conduits, seal well, etc.). (See Reference 1.7-4,Section XII.) Aside from the Intake Structure, the nearest building to the river channel edge is approximateliy 200 ft away (Reference 1.7-5, Section 2.1).

Site lnformatio*n Related to the Flood Hazard 1-1 9ECURIT¥-RELATEE> INFORMATION - WITHHOLE> UNf>ER 16 CFR 2.996

SECUR:IT¥-R:ELATEI:> INFOR:MATION - W1ITHHOLD UNDER: 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-01 7 1.1.2 Spatial Data Sets Elevations in Section 1 are referenced to MSL for consistency with the CNS Updated Safety Analysis Report (USAR}. In this context, MSL is equated to Plant Datum and Is distinct from other geodetic vertical datums. Reference 1.7-3 notes that Plant Datum is the same datum used in the USAR.

1.1.3 Elevation of Structures, Systems, and Components (SSCs)

The station site grade level of 903 ft MSL has been raised 13 ft above the natural grade level of 890 ft MSL, In order to bring final grade 1 ft above the existing 902 ft MSL levee constructed by the USACE (Reference 1.7-4, Chapter II, Section 4.2.2.2).

The levee is situated at a nominal elevation of 902 ft MSL. The finished floor elevation is given as 903.5 ft MSL for all Class I structures (Reactor Building, Turbine Building, Diesel Generator Building, Control Building, Radwaste Building, Intake Structure and Controlled Corridor). The Z-Sump is at 890 ft MSL, and the Elevated Release Point (ERP) tower foundations are at 891 ft MSL (Reference 1.7-3, Section 4.0).

1.1.4 Topography Prior to the construction of CNS, the site was nearly flat with only one or two feet of relief over the majority of the area. General grade elevation was approximately 890 ft MSL. A bluff, approximately 150 ft above the floodplain, running north-south, is located about one mile west of the river near the plant area. An earthen levee parallels the west (right) river bank at a distance of approximately 500 ft.

Surface drainage of the site was poor because of the lack of natural relief. The levee also inhibits surface runoff from the area behind the levee to the river (Reference 1.7-6, Section 2.2).

Federal Levee R548 is adjacent to the CNS main plant area. The top elevation of the levee near the site is approximately 902 ft MSL, 1 ft below the nominal plant grade of 903 ft MSL. The levee extends north of the plant, where it terminates at the higher ground near the bluffs. South of CNS, the levee follows the right bank of the Missouri River, curving around to the west and running parallel to the left bank of the Nemaha River, which is a tributary to the Missouri River, and turning north where it meets the higher ground near the town of Nemaha. The top elevation of the levee varies from approximately 902 ft MSL near CNS to approximately 897 ft MSL on the southern end, with top elevations of the levee as low as 894 ft MSL locally, The area enclosed by the levee and the higher bluffs to the west Is 4000 ac (Reference 1.7-7, Section 5.1.8).

1.1 .5 Missouri River and Tributaries The Missouri River Basin drains 529,000 square miles (mi2), including about 9,700 mi2 located in Canada. The Basin spans 10 states, including all of Nebraska, most of Montana, Wyoming, North Dakota, and South Dakota; about half of Kansas and Missouri; and smaller parts of Iowa, Colorado, and Minnesota. The Missouri River is fed from several major tributaries, including the Yellowstone, Platte, Kansas, Grand, and Osage Rivers. The Missouri River extends 2,619 mi from its uppermost source at Browers Spring on Hell Roaring Creek and 2,321 mi from Three Forks, Montana, where the Site Information Related to the Flood Hazard 1-2 SECUR:ITY:-RELATED INFORM1'TION - WITI-IHOLD UNl:>ER 16 CF~ 2.996

SECURITY-RELATEB INI-ORMATION - 'filTI UIOLB UN BER 18 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Jefferson, Madison , and Gallatin Rivers converge. The Missouri River is the longest river in the United States, draining one-sixth of the country. The Missouri River Mainstem System (System) consists of six dams and reservoirs on the Missouri River located in Montana, North Dakota, South Dakota, and Nebraska. The six System dams are Fort Peck Dam in Montana; Garrison Dam in North Dakota; Oahe Dam, Big Bend Dam, and Fort Randall Dam in South Dakota; and Gavins Point Dam in South Dakota and Nebraska. The System has a capacity to store 73.1 million acre-feet (ac-ft) of water, which makes it the largest reservoir system in North America. Runoff from upstream of the System is stored in the six reservoirs. Water is released from the System as needed for downstream flow support. Released water from the most downstream dam in the System, G1;1vins Point Dam, flows down the Missouri River, which includes the Bank Stabilization and Navigation Project (BSNP) from Sioux City, Iowa to the mouth near St. Louis, Missouri (Reference 1.7-8 and Figure 1.9-5).

The location of six System dams is noted in Table 1.8-1. There are no dams or similar structures on the Missouri River downstream of the plant site. (See Figure 1.9-2 and Figure 1.9-5 and Reference 1.7-4, Chapter II, Section 4.2.2.1.)

Site Information Related to the Flood Hazard ,.,,

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SECURIT'a'*RELATED INFORMJfcTION - 1t'VITHHOLE> UNDER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZARD REEVALUATION REPORT 1.2 CURRENT DESIGN BASIS FLOOD ELEVATIONS This section summarizes key flood and plant information found in the CNS USAR.

1.2.1 Summary of CNS External Flood Design and Licensing Basis The flooding Design Basis of CNS consists of the Final Safety Analysis Report (FSAR) and FSAR questions, which used USACE studies. The CNS flooding Licensing Basis consists of the Safety Evaluation of the Cooper f-:Juclear Station (SER).

1.2.1.1 Flood Levels (FSAR/USAR)

Information on riverine flooding in the CNS USAR is based on independent studies performed by the USACE and by the U.S. Atomic Energy Commission (AEC). Information from the USAGE study is summ13rized in the USAR and its predecessor, the FSAR. The AEC study is summarized in the CNS SER. These studies are discussed in subsequent sections of this report.

The projected upper limit of elevation for a.1,000-year flood discharge is 900 ft MSL and for a 10,000-year flood discharge is 902 ft MSL. The Probable Maximum Flood (PMF) is established at 903 ft MSL with a projected return frequency estimated to be in excess of 1,000,000 years. The PMF is derived by centering a probable maximum rainstorm critically over the drainage a,rea above Brownville. The USACE has estimated that the peak discharge for the PMF is 600,000 cfs (Reference 1.7-4, Chapter II, Section 4.2.2.1). This estimate is based on a qualitative judgment that the peak of a PMF event should be between two to three times the peak of a standard project flood. Preliminary estimates of standard project conditions on the Missouri and Platte Rivers were used in estimating the PMF peak of 600,000 cfs at CNS (Reference 1.7-4, Chapter II, Section 4.2.2.1 and Reference 1.7-9). Table 1.8-3 summarizes the approximate drainage area (mi2) for locations of interest along the Missouri River.

The effects of a sustained wind in conjunction with a PMF were evaluated by USACE using the procedures described in the U.S. Army Coastal Engineering Research Technical Report 4. Assuming a 45-mile per hour (mph) overwater wind speed and a 903 ft MSL PMF WSEL, the significant shallow-water wave height was computed to be 4.0 ft. The 1% wave height was computed to be 6.7 ft. The runup was computed to be 6. 7 ft on a smooth vertical wail located in shallow water and 4.8 ft on a one-on-three riprapped slope. The fetches are of sufficient length that the above waves could be generated with winds from the north through east through south. It should be noted, however, that these wave height values are based on relationships derived from studies made 011 lakes and oceans, and it is believed that the same parameters would not produce waves as high as those computed above in highly turbulent, fast-flowing river flood waters (Reference 1.7-4, Chapter 11, Section 4.2.2.1 and Reference 1.7-18).

The wave action, as mentioned above, will not affect the plant proper since the nearest building is located about 200 ft from the river edge and is surrounded by grade to elevation 903 ft MSL. Wave energy would be dissipated before reaching any of the main buildings. Wave action at the Intake Structure will not affect the safe shutdown of the plant since the service water pumps and controls are Site Information Related to the Flood Hazard ,*/

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9ECURIT¥-RELATEB INFORMATION

• WITI II IOLB UN BER 18 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION R90RT Project No.: 11784-017 protected by massive reinforced concrete walls and slab up to elevation 919 ft MSL (Reference 1.7-4, Chapter II, Section 4.2.2.2 and Reference 1.7-18).

Flooding caused by ice blockage is considered credible only at river levels significantly lower than the PMF. Flooding caused by ice blockage would cause water surface elevations below those of the PMF.

(Reference 1.7-4, Chapter II, Section 4.2.2.1.)

The failure of a large upstream dam is not considered probable. These dams are massive earthen structures with impervious core walls, large freeboard for wave action, and adequate spillways. The dams are located in a zone of low seismic activity. The Gavins Point Dam, closest dam to the site, is over 275 mi upstream (Reference 1.7-4, Chapter 11, Section 4.2.2.1).

These dams are under constant inspection by local USACE personnel and are inspected once a year by a team of professionals. If seismic failure occurred in spite of these circumstances, the failure would most probably be caused by other than instantaneous failure of a major portion of the dam. Under these circumstances, overtopping of Gavins Point Dam, although conceivable, is not likely to occur (Reference 1.7-4, Chapter 11, Section 4.2.2.1).

1.2.1.2 USACE Study The USACE estimated a PMF elevation between 902 ft MSL and 903 ft MSL at CNS. This is based on a Probable Maximum Precipitation (PMP) event occurring upstream of Brownville, Nebraska and a resulting flow rate in the Missouri River of 600,000 cfs. The rainfall event producing this flow rate is described in FSAR Question 2.1 as originating over the Platte River Basin (Reference 1.7-9).

1.2.1.3 AEC Study Safety Evaluation Report The AEC performed an independent PMF study for CNS, which is summarized in the CNS SER. Based on detailed PMF estimates in the general region of the site, AEC staff conservatively estimated the peak PMF discharge to be about 1,000,000 cfs. This estimate was conservatively considered to reflect the total runoff potential represented by the large drainage area downstream of the USACE dams, plus the relatively minor component that could be contributed by releases from these dams. AEC staff concluded that the dams should remain intact during a PMF. Additionally, AEC staff constructed an analytical water surface profile model of the Missouri River from below CNS to the Brownville Bridge a few miles upstream and estimated the PMF still WSEL at the site would be 901 .2 ft MSL. The model was verified by reproducing historical flood high-water marks using estimates of floodplain geometry and flood runoff rates. Coincident wave action induced by an assumed 45-mph wind was estimated to produce a maximum WSEL of 909.2 ft MSL at the Intake Structure and 905 ft MSL on the other exposed safety-related structures. AEC staff did not consider seismically induced dam failure coincident with PMF credible but considered the effects of a seismically induced.failure of one of the largest upstream dams concurrent with flood levels of one half of the PMF and concluded that the water level that could result at CNS is less than the AEC staffs estimated PMF (Reference 1.7-2, Section 2.4.3).

This information has been incorporated into the USAR. (See Section 1.2.1.1 of this report)

Site Information Related to the Flood Hazard 1-5 SECURIT't'-RELATEB INFORMATION - WITI II IOLB UNBER 16 CFR 2.998

SECURITY-RELATED INFORMATION - WITtlHOLD UNDER 16 CFR 2.998 Nebrask.a Public Power District SL-012450 Cooper Nuclear Station

• Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 1.2.1 .4 Conclusions The immediate station area grade is at elevation 903 ft Mean Sea Level (MSL). This is 1 ft above the existing levee, and equal to the highest projected level of the maximum probable natural flood.

Therefore, because 903 ft MSL was used in the design of the plant with wave energy dissipating before reaching any of the main buildings, the design basis still WSEL due to Missouri River Flooding is 903 ft MSL (Reference 1.7-4, Chapter 11, Section 4.2.2.1). Wave action at the Intake Structure is possible, but no value is given, as waves will not affect the safe shutdown of the plant since the Service Water pumps and controls are protected by concrete walls up to 919 ft MSL (Reference 1.7-4, Chapter II, Section 4.2.2.2).

In the 1973 SER for CNS, the Atomic Energy Commission (AEC) found that dam failure was less than the calculated value for PMF. The United States Army Corps of Engineers later stated that though failure of an upstream dam is considered improbable, the resulting stage of the river at CNS (assuming the most critical combinations of timing) would be approximately elevation 905-906 ft MSL (Reference 1.7-4, Chapter II, Section 4.2.2.2). This value was determined after the $ite had been designed, and after the SER had confirmed that the dams remain intact after a PMF, and that a seismic event does not exceed the staff estimated PMF. Therefore, 906 ft MSL is the Current Licensing Basis (CLB) for dam break.

1.2.2 CLB Local Intense Precipitation (LIP)

From Hydrometeorologlcal Report No. 33 (HMR-33) dated April, 1956 by the U.S. Department of Commerce-Weather Bureau and the USACE (Reference 1.7-10), it was determined that the PMP for the CNS site area is 23.5 inches (in) total rainfall for a 24-hour period. This bounding PMP value was obtained from HMR-33 Figure 17 (August). (See Reference 1.7-4, Chapter 11, Section 3.1.3). An independent evaluation by the AEC determined that the PMP 1-hour rainfall rate was 9.7 in per hour (Reference 1.7-2, Section 3.4).

Class I and Class II buildings are protected from the effects of precipitation through the use of roof drains and overflow scuppers. The Reactor Building, Diesel Generator Building, and Control Building use 4-in roof drains and 6-in scuppers. The remaining local site drainage is designed such that any excess rainfall not immediately absorbed into the ground will flow away from the buildings to be discharged into drywells or low lying areas adjacent to the plant site. Therefore, this configuration can safely remove the accumulated water from the PMP rate described in the USAR, Chapter II, Section 3.1.3, and can also accommodate the 9.7 in per hour (Reference 1.7-11 and Reference 1.7-4, Chapter 11, Section 3.2.3) rate estimated by the AEC without adverse effects on the safety-related systems necessary for safe shutdown (Reference 1.7-4, Chapter II, Section 3.2.3).

1.2.3 CLB Flooding In Streams and Rivers Refer to Section 1.2.1.

Site Information Related to the Flood Hazard ,,

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SECURITY-RELATED INFORMATION - WITHHOLD UNDER 16 CFR 2.396

SECURITY-RELATED INFORMATION - WITHHOLD UNDER 16 CFR 2.S96 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZARD REEVALUATION REPORT 1.2.4 CLB Dam Breaches and Failures The USAR (Reference 1.7-4, Chapter II-, Section 4.2.2.1) notes that a dam failure was not considered a credible event. The maximum expected still water level at the site associated with a postulated dam failure was 906 ft MSL, with a minimum warning time of three days (Reference 1.7-4, Chapter II, Section 4.2.2.2). No associated effects (wind-wave, debris, etc.) were considered in the dam failure scenario.

1.2.5 CLB Storm Surge The CLB is silent on flooding effects from storm surge. However, due to its location, the storm surge flooding mechanism can be scree,ned out for CNS.

1.2.6 CLB Seiche The CLB is silent on flooding effects from seiche. However, due to its location, the seiche flooding mechanism can be screened out for CNS.

1.2.7 CLB Tsunami The CLB is silent on flooding effects from tsunami. However, due to its location, the tsunami flooding mechanism can be screened out for CNS.

1.2.8 CLB Ice-Induced Flooding Flooding caused by ice blockage is considered credible only at river levels significantly lower than the PMF. Flooding caused by ice blockage would produce WSELs below those of the PMF (Reference 1.7-4, Chapter II, Section 4.2.2.1). Thus, the CLB does not include quantitative parameters for ice-induced flooding, but the ice-induced flooding effects are bounded by the PMF.

1.2.9 CLB Channel Migration or Diversion The CLB discusses this mechanism only with respect to channel migration away from the site due to levee failure on the opposite river bank and the potential loss of the heat sink. Channel migration toward the site was not considered credible.

Changes in river alignment have occurred in the past as a result of meteorological events. The river channel at present is stabilized as a result of permanent revetments constructed under the supervision of the USAGE over a number of years; thereby, making It extremely unlikely that the river would be diverted at Brownville Bend. If, however, in spite of these controls, the river should be diverted, it would most likely occur as a result of the failure of a major upstream dam - either Oahe Dam or Fort Randall Dam, although dam failure is not considered credible in the CLB. The closer of the two dams, Fort Randall Dam, is almost 350 mi upstream from the plant site and there would be a three-day warning before the river reached a peak flood stage at CNS. While the river is at peak flood stage at the site, the postulated diversion of the Missouri River might occur upstream. During peak flood stage, reactor shutdown procedures could begin and continue as the flood water slowly receded. With the river Site Information Related to the Flood Hazard ,...,,,*

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SECUR:l'TY-R:El:Al'ED INFOR:MA:l'ION - 1'Vll'~IHOLD UNDER: 16 CPR: 2.398 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No,: 11784*017 diverted and the flood waters fully receded, what might remain in front of the Intake Structure would be a large body of still water cut off from the upstream flow and possibly cut off at a point downstream.

After the river diversion occurs, the resulting isolated body of water in the vicinity of the site, fed by groundwater inflow, would retain essentially the same stage characteristics that apply to the current open river as long as the main channel were retained in the existing valley. It was concluded that there would be an adequate supply of water to affect a safe shutdown of the plant (Reference 1.7-4, Chapter II, Sections 4.2.3.1 and 4.2.3.2). The AEC concurred with these findings in the CNS SER, which states that it was considered unlikely that major channel diversions would occur (Reference 1.7-2, Section 2.4.5).

1.2.10 CLB Combined Effects Combined effects of different flood-causing mechanisms are discussed in Section 1.2.1 through 1.2.8, where applicable.

1.2.11 CLB Associat_ e d Effects Section 9 of Reference 1.7-12 defines "Flood height and associated effects" as:

The maximum still WSEL plus the following factors:

• Wind waves and runup effects.

• Hydrodynamic loading, including debris.

• Effects caused by sediment deposition and erosion.

• Concurrent site conditions, including adverse weather conditions.

• Groundwater ingress.

• Other pertinent factors.

1.2.11.1 Wind Waves and Runup Effects The CLB values for wind waves and runup is 909.2 ft MSL at the Intake Structure and 905 ft MSL for other exposed safety-related structures (Reference 1.7-4, Chapter II, Section 4.2.2.2).

1.2.11.2 Hydrostatic and Hydrodynamic Loads The principal structures are designed to withstand hydrostatic loads up to the flood protection level of 906 ft MSL with margin (Reference 1.7-4, Chapter II. Section 4.2.2.2).

The CLB is silent on hydrodynamic loads.

1.2.11.3 Debris Loads The CLB is silent on flooding debris loads (Reference 1.7-4); however, the CLB does discuss a runaway barge (Reference 1.7-4, Chapter II, Section 4.3).

Site Information Related to the Flood Hazard 1-8 SECURIT¥-RELATED INFORM>\TION - WITHHOLB UNEJER: 16 CFft 2.996

SECURIT¥*RELATEB INFORMA'flON - WITltHOLB UNBER 18 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 In summary, the Intake Structure and Class I equipment located inside are qualified to withstand a barge impact. Additionally, a barge that impacts the Intake Structure guide wall will, therefore, have little if any effect on plant operations.

1.2.11.4 Erosion and Sedimentation Effects of erosion and sedimentation during extreme flooding events are not analyzed in the CLB.

1.2.11.5 Concurrent Site Conditions The CNS CLB (Reference 1.7-4) does not specifically discuss evaluation of concurrent site conditions.

1.2.11.6 Groundwater Ingress The CNS CLB does not specifically address or quantify groundwater in-leakage from the site subsurface water table. Groundwater level Is monitored/logged once per shift based on level indicators located wi'.hin site well(s) providing plant water supply. According to CNS personnel, site groundwater level normally fluctuates between 875 ft MSL to 885 ft MSL with the highest recorded level of 900.8 ft MSL during the May 2011 Missouri River flood event (Reference 1.7-5, Section 3.7).

1.2.11.7 Other Pertinent Factors The Maintenance Procedure directs the CNS maintenance personnel in the installation of temporary flood control barriers and features. The procedure provides a system of primary barriers at the openings of the outside walls of the Main Building Complex to seal the buildings up to elevation 906 ft MSL. Secondary barriers are provided strategically inside the buildings to control any minor leakage past the primary barriers and to segregate the building complex into small areas that can be more easily protected (Reference 1.7-5, Section 3.5.)

Site Information Related to the Flood Hazard

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SECUR:ITY-RELATEB INFORM:1'%l'ION - 'lt1ll'ttl IOLB UNBER: 16 CPR 2.396

SECURIT¥-RELATEE> INFORMATION - 1VITHHOLE> UNE>ER 16 Cf-ff 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 1.3 FLOOD-RELATED CHANGES AND FLOOD PROTECTION CHANGES The plant design features and their functional requirements that provide protection against the design basis external flood mechanisms are provided in the USAR (Reference 1.7-4). The credited flood protection related attributes of the overall plant configuration that support the design for mitigation against external flooding have not changed from the time of initial lieensing. Enhancements to procedural guidance supporting tlhe implementation of protective actions against external flooding have been made over time. The temporary barriers deployed in Procedure 7.0.11 (Reference 1.7-13) now consist of engineered flood barriers. The use of these barriers, instead of the original sandbag barriers, has resulted in a significant reduction of the barrier deployment time and effort.

Changes to the hydrosphere around the CNS site and physical changes to the CNS site (e.g., security changes, buildings, etc.) are discussed in Section 1.4 of this report.

Site Information Related to the Flood Hazard ,*<'

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SECURIT¥-RELATEE> l~Nf-ORMATION - 'NITHHOLE> UNE>ER 16 CPR 2.396

SECURIT'f-RELATEE> INFORMATION - VIITHHOLD UNDER 16 CFR 2.396 Nebraska Publlc Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project Na.: 11784-017 1.4 CHANGES TO THE WATERSHED OR TO THE LOCAL AREA As shown in Figure 1.9-6, the river was much wider and further to the east than it is today, as also illustrated in Figure 1.9-7 and Figure 1.9-8. (Reference 1.7-14).

The CNS site is located in the floodplain of the Missouri River at approximate Missouri River Mile 532.5.

As a result of the location, the site is subjected to hydrometeorological events relevant to inland sites.

The Missouri River Basin upstream of CNS and downstream of Gavins Point Dam combined with Platte River Basin, as discussed in Section 2.2 of this report, encompasses approximately 132,657 mi2.

Changes in watershed properties particularly affect the estimation of the PMF and upstream dam failure flooding. It Is expected that watershed characteristics do change through the years, with the expansion of urban areas and change in land use and land cover. However, all of the changes that may have occurred in the past were captured in the current flooding hazard reevaluation. The reevaluation took into account the existing watershed conditions, which were incorporated through the hydrologic and hydraulic model calibration efforts. It should be noted that since the construction and operation of CNS, there has been no major upstream dam or impoundment on the Missouri River or tributaries constructed or proposed.

Any changes in local area that may have occurred in the past, including the vehicle barrier installed for a security measure, were Incorporated in the LIP analysis of the current flooding hazard reevaluation.

(See Section 2.1 of this report.)

Site Information Related to the Flood Hazard 1-11 SECURIT¥-RELATED INFORMATION - WITHHOLD UNl:lER 16 CFR 2.396

SECURIT¥*RELATED INFORM1'TION - 'NlfHHOLB UNBER 16 CFR 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784-01 7 FLOOD HAZARD REEVALUATION REPORT 1.5 CURRENT DESIGN BASIS FLOOD PROTECTION AND MITIGATION FEATURES The general ground elevation surrounding CNS Class I structures, which corresponds to the PMF event elevation, is elevated 13 ft above the natural floodplain to 903 ft MSL (Reference 1.7-4, Chapter 11, Section 4.2.2.2). The finished floor elevation of all Class I structures is placed at elevation 903.5 ft MSL, or 0.5 ft above the PMF event. These structures were designed for a hydraulic load equivalent to a groundwater elevation of 903 ft MSL and reviewed for integrity for a river elevation up to 906 ft MSL.

Grade level openings on exterior walls of the buildings (except for the Intake Structure) are protected from wave effects and WSELs up to 906 ft MSL with flood barriers erected per CNS Procedures 7.0.11 (Reference 1.7-13) and 5.1, Flood (Reference 1.7-15), as previously discussed in Section 1.2.11 .7 of this report.

The CNS Flood Protection Feature Inspections, in accordance with the request from the U.S. Nuclear Regulatory Commission (NRC) as defined in the Recommendation 2.3, Flooding, Enclosure 4 of the 50.54(f} letter dated March 12, 2012 (Reference 1.7-5) found that the CNS flood protection active and passive feahires, e.g., walls, floors, roofs, penetration seals, doors, check valves, etc., were confirmed to be installed per design, functional, in good material condition, and appropriately controlled procedurally to ensure continued functionality.

The following CNS safety-related plant structures and procedures have been identified as protected from flooding as noted:

Intake Structure The maximum water level on the outside of the Intake Structure of 909.2 ft MSL (PMF plus wave effects) will not affect safe operation of the Service Water pump motors. The Intake Structure is built with a floor elevation of 903.5 ft MSL. The Service Water pump motors are positioned approximately 4.5 ft above the floor and are protected by 24-inch-thick concrete walls to an elevation of 919 ft MSL. Therefore, direct wave action will be dissipated and the water level in the room would be below the elevation of the Service Water pump motors (Reference 1.7-4, Chapter 11, Section 4.2.2.2).

Reactor Building The Reactor Building is protected from wave effects and flood water by grade level building walls and by temporary flood barriers to elevation 906 ft MSL.

Emergency Diesel Generator Building The Emergency Diesel Generator Building is protected from wave effects and flood water by grade level building walls and by temporary flood barriers to elevation 906 ft MSL.

Radwaste Building The Radwaste Building is protected from wave effects and flood water by grade level building walls and by temporary flood barriers to elevation 906 ft MSL.

Site Information Related to the Flood Hazard .. ,,

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SECURIT¥-RELATEE> INFORMATION - WITHHOLf) UNDER 16 CFR 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZARD Rl!l!VALUATION REPORT Control Building The Control Building is protected from wave effects and flood water by grade level building walls and by temporary flood barriers to elevation 906 ft MSL.

Controlled Corridor The Controlled Corridor is protected from flood water by grade level Reactor and Turbine Building walls to elevation 906 ft MSL.

Turbine Building The Turbine Building is protected from wave effects and flood water by grade level building walls and by temporary flood barriers to elevation 906 ft MSL.

Z-Sump {Below ERP Tower)

As noted in the USAR (Reference 1.7-4, Chapter II, Section 4.2.2.2), the top of floor drain Z-Sump, at the base of the ERP tower, is located at elevation 891 ft MSL and, therefore, is within postulated flood levels. The Z-Sump contains equipment essential to the operation of the Standby Gas Treatment System (SGTS) and, therefore, the sump must remain functional whenever Secondary Containment is required. Although the ground elevation at the sump is only 890 ft MSL, the Z-Sump will not be affected by flooding since the sump penetrations are sealed and the proper functioning of the sump is monitored when flood levels reach 890 ft MSL.

Diesel Fuel Storage Tanks As noted in the USAR (Reference 1.7-4, Chapter II, Section 4.2.2.2); there is sufficient fuel in the Diesel Oil Storage Tanks to ensure seven days of operation of a single diesel generator powering a single critical division of safe shutdown loads. This time duration is sufficient to obtain more fuel, if needed. The two storage tanks are buried and their appendages are protected by a substantial cover. The manholes providing access to the Diesel Oil Transfer Pumps, the capped fill connections, and the tank vents are all located above 906 ft MSL. The design and installation of the tanks ensure flotation does not occur when empty during the PMF.

The following CNS plant structures have been identified as important to the protection of the various safety-related structures and equipment and are also protected from flooding as noted:

Augmented Radwaste Building The Augmented Radwaste Building is protected from wave effects and flood water by grade level building walls and by temporary flood barriers to elevation 906 ft MSL.

Boner Room The Boiler Room is protected from wave effects and flood water by grade level building foundation walls and by temporary flood barriers to elevation 906 ft MSL.

Site Information Related to the Flood Hazard ,,

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SECURIT¥-RELATED INFORMATION - WITHHOLD UNDER 16 CfiR 2.396

SECURITY-RELATEf) INFORMATION - VilTI IHOLD UNDER 16 CFR 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD Rl!l!VALUATION REPORT Project No.: 11784-017 Fan Room The Fan Room is protected from wave effects and flood water by grade level building foundation walls and by temporary flood barriers to elevation 906 ft MSL.

Water Treatment Plant The Water Treatment Plant is protected from wave effects and flood water by grade level building foundation walls and by temporary flood barriers to elevation 906 ft MSL.

Tool Crib The Tool Crib is protected from wave effects and flood water by grade level building foundation walls and by temporary flood barriers to elevation 906 ft MSL.

Machine Shop The machine shop is protected from wave effects and flood water by grade level building foundation walls and by temporary flood barriers to the elevation of 906 ft MSL.

Multi-Purpose Facility (MPF) Building The MPF Building is protected from wave effects and flood water by grade level building foundation walls and by temporary flood barriers to the elevation of 906 ft MSL.

Other Site Structures Various site out-buildings and structures classified as not important to safe operation and shutdown of the plant are located at base elevations lower than the PMF elevation of 903 ft MSL. Per CNS Procedure 5.1 , Flood (Reference 1.7-15), evaluation of the protection of these assets is determined by NPPD plant management by implementing actions based oo various parameters, including plant safety, asset value, importance to overall long-term power generation, etc.

Procedures Upon reaching an actual river level of 895 ft MSL or receiving a river level forecast of 902 ft MSL within the next 36 hours4.166667e-4 days <br />0.01 hours <br />5.952381e-5 weeks <br />1.3698e-5 months <br />, the site flooding procedure is implemented. Apart from implementing temporary protection up to 906 ft MSL as previously discussed, the procedure directs the discharge of liquid radwaste as required to provide room for handling flood leakage. The floor and equipment drains and portable gasoline pumps are used to control leakage past the primary and secondary barriers.

Site Information Related to the Flood Hazard 1-14 SECURITY-RELATED INFORrMTION

• WITIIHOLD UNDER 18 CFR 2.996

SECURITY-RELATED INFORMATION =VIITI II IOLD UNDER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 A plant shutdown is initiated under any of the following conditions:

• Floodwaters either reach 902 ft MSL, or are forecast to reach 902 ft MSL within the next 36 hours4.166667e-4 days <br />0.01 hours <br />5.952381e-5 weeks <br />1.3698e-5 months <br /> (as from the 10,000 year flood or an upstream dam failure).

• Floodwater accumulates in either Diesel Generator Room, any of the four Reactor Building Quads, or the Control Building basement.

• Plant conditions warrant reactor to be shut down.

(Reference 1.7-4, Chapter 11, Section 4.2.2.2.)

Site Information Related to the Flood Hazard 1-15 SECURIT'f-RELATED INFORMATION

• WITI ltiOLD UNDER 16 CFR 2.996

SECURITY-FtELATED INFOFtMATION - WITHHOLB UNDEFt 16 CFFt :2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZARD REEVALUATION REPORT 1.6 ADDITIONAL SITE DETAIL All available s ite details have been noted.

Site Information Related to the Flood Hazard 1-16

• SECURITY-RELATED INFORMATION - WITHHOLD UNDEFt 18 CFR 2.998

SECUFtlT'f -FtELATED INfiOFtMA:l'ION - Wl'fHHOLD UNDER 16 CFR 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 1178~-017

1. 7 REFERENCES 1.7-1. U.S. Nuclear Regulatory Commission, Request for Information Pursuant to Title 10 of the Code of Federal Regulations 50.54(f) Regarding Recommendations 2.1, 2.3, and 9 .3, of the Near-Term Task Force Review of Insights from the Fukushima Dai-ichi Accident, March 12, 2012.

1.7-2. Safety Evaluation of the Cooper Nudlear Station. Docket 50-298. 02-14-73.

1.7-3. NPPD Engineering Evaluation Number 12-035, Revision 0, "Review of 2012 Topographic Survey of CNS," March 2013.

1.7-4. Cooper Nuclear Station USAR, Revision xxvi1.

1.7-5. Nebraska Public Power District, Flooding Walkdown Submittal Report for Resolution of Fukushima Near-Term Task Force 10 CFR 50-54 (f) Section 2.3 Flooding Response.

1.7-6. Nebraska Public Power District, Columbus, Nebraska, Engineering Criteria Document for Cooper Nuclear Station. June, 3, 1970.

1.7-7. Calculation 2012-12283, Revision 0, Evaluation of Local Probable Maximum Precipitation (PMP).

1.7-8. United States Coast Guard, Mississippi River and Tributaries Waterways Action Plan Missouri River Annex 2011 .

1.7-9. Cooper Nuclear Station, FSAR Question Number 2.1, Amendment Number 9.

1.7-10. Hydrometeorological Report No. 33, Dated April 1956.

1.7-11. Cooper Nuclear Station, FSAR Ques1ion Number 2.3.6, Amendment 17.

1.7-12. U.S. Nuclear Regulatory Commission, "Interim Staff Guidance far Performing the Integrated Assessment for External Flooding," JLD-ISG-2012-05, November 30, 2012.

1.7-13. CNS Operations Manual, Maintenance Procedure 7.0.11 , Flood Control Barriers, Revision 29, Dated 02-19-14.

1.7-14. Calculation 2014-00225, Revision 0, Task 810-Missouri River Channel Geomorphic Evaluation at CNS.

1.7-15. CNS Emergency Procedure 5.1 Flood, Revision 13.

1.7-16. Hydrodynamic Computer Modeling to Predict Missouri River Probable Maximum Flood Elevations and Flow Velocities at Cooper Nuclear Station, NEDC 11-076, Revision 1, Dated August 08, 2011 .

Site Information Related to the Flood Hazard , ....;*

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SECURIT¥-RELATEB INFORMATION - WITI It IOLB UNBER 16 CfiR 2.996

secURITY-RELATED INFORMATION - '1/ITHHOLB UNDeR: 18 CFR 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION RfiltORT Project No.: 11784-017 1.7-17.ArcMap Version 9.3.1 (Build 3000). ESRI, Redlands, CA 1.7-1 B. Cooper Nuclear Station, FSAR Question Number 2.2, Amendment Number 9.

1.7-19. Cooper Nuclear Station, FSAR Question Number 2.4, Amendment Number 11.

Site Information Related to the Flood Hazard 1-18 SECURIT'f-RELATEE> INFORMATION -WITHHOLD UNDER 10 CFR 2.390

SEeURIT¥-RELATEE> INFORMATION

• WITI II IOLE> UNE>ER 18 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 1.8 TABLES The tables associated with Section 1 are presented on the following pages.

Site Information Related to the Flood Hazard .*,

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SEeURIT't'-RELATEE> INFORMATION - WITHHOLE> UNE>ER 16 eFR ! .396

SEeURl'f¥-RELA'fEO INI-ORMA'flON - \\'Ill ll'iOLI) UNOER 16 eFR 2.396 Nebraska Public Power District Sl-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Table 1.8-1 : Missouri River Dams Name Location Near River Mile Gavins Point Yankton, South Dakota 811 Fort Randall Lake Andes, South Dakota 880 Big Bend Chamberlain, South Dakota 987 Oahe Pierre, South Dakota 1072 Garrison Bismarck, North Dakota 1389 Fort Peck Glasgow, Montana 1771 Note:

1. Plant location: River Mile 532.5 Table 1.8-2: Design Evaluation Summa1ry CNS Condition Comment Evaluation PMF Peak Flow Rate 11> 600,000cfs PMP Event centered above Brownville, NE.

Plant site elevated +/-903 ft MSL. First floor of all Class I PMF Still Water Surface E_levation 903 ft MSL C2l buildings at 903.5 ft MSL.

Flood barriers not needed at intake since critical PMF + Wave Runup at Intake Structure equipment is elevated above 906 ft MSL and protected 909.2 ft MSL from wave impacts.

Class I buildings' grade level openings at 903.5 ft MSL PMF + Wave Action Main Plant Complex No impact protected by flood barriers from standing water up to 906 ft MSL.

Notes:

1. The USACE estimated a higher river stage during the PMF than the AEC, despite the fact it used a lower now rate (600,000 cfs versus 1,000,000 cfs). Details of the methodology utHized by the AEC to develop its stage flow relationship were not described, except for a statement in the SER text that the AEC constructed an *Analytical Model." The analysis conducted by CNS in 2011 is consistent with the USACE stage discharge estimates (Reference 1.7*16).

2. This elevation Is based on a steady flow rate of 600,000 els. See Reference 1 .7, Chapter II, Section 4.2.2.1.

3. See Reference 1.7-5, Section 2.7, Site Information Related to the Flood Hazard 1-20 SECURIT¥~RELATED INFORMATION - WITHHOLB UNOER: 16 CFft 2.S96

SECURIT¥*RELATEf> INFORMATION - WITHHOLE> UNE>ER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION Rl!PORT Project No.: 11784-017 Table 1.8-3: Missouri River Drainage Area Drainage Area Location (Approximate (Missouri River)

(Square Miles)

Above Fort Peck Dam 57,500 Above Garrison Dam 181,400 Above Oahe Dam 243,490 Above Fort Randall Dam 263,480 Above Gavins Point Dam 279,480 Above Mouth of Platte River 323,530 Platte River at Mouth 90,200 At Cooper Nuclear Station 4 14,600 Reference 1.7-4, Chapter II, Section 4.2.2.1 Site Information Related to the Flood Hazard 1-21

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SECURIT¥-RELATEB INFORMATION - WITHHOLE> UNE>Eft 16 CfR 2.996

SECURITY-ftELATEE> IN~OftlVIATION - WITIIIIOLD UNDER 18 CPR 2.396 Nebraska Public Power District SL,01245O Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 1.9 FIGURES The figures associated with Section 1 are presented on the following pages.

Site Information Related to the Flood Hazard 1-22 SECUftlTY-RELATEf> INFORMATION - WITttttOLD UNElER 16 CFft 2.390

SEOURIT'i'*RELATEB INFORM>\TION - WITI II IOLB UNBER 18 OFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVAt.UATION REPORT Project No.: 11784-017 Figure 1.9-1 : Site Location Reference 1.7-17 Site Information Related to the Flood Hazard 1-23 Snrgnnt: & Lundy SEOURIT¥*RELATEB INFORMATION - WITttttOLB UNBER 18 CFR 2.998

SECURIT¥*RELATED INFORMATION - Vt11TI II IOLD UNDER 18 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Figure 1.9-2: Missouri River Tributaries Reference 1.7-4. Figure 11-4-1 Site Information Related to the Flood Hazard 1-24 S...-gant: & Lundy SECURITY-RELATED INFORMATION

• WITI II IOLD UNDER 18 CFR 2.998

SECURITY-RELATED INFORMATION - WITtttfOLD UNDER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Figure 1.9-.3: Overhead View of CNS 1 Site Information Related to the Flood Hazard 1-25 S.,rgono: & Lundy SECURIT¥-RELATED INFORMATION - WITHHOLD UNDER 16 CFR 2.996

9ECURIT¥*RELATEB INFORMATION - WITHHOLD UNDER 18 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revi sion 1 Project No.: 1178-4--017 FLOOD HAZARD REEVALUATION REPORT Figure 1.9-4: Overhead View of CNS 2 Site Information Related to the Flood Hazard 1-26 SECURITY-RELATED INFORMATION - WITl-l~tOLB UNDER 18 CFR 2.998

SECURIT¥*RELATEB INFORMATION - Wl'fHHOLB UNBER 16 CFR 2.S96 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Figure 1.9-5: Missouri River Reservoir System tissouri River ~lainstem Reservoir System

• Site Information Related to the Flood Hazard 1-27 S..rgc,no:. & Lundy SECURIT¥-RELA'fEB INFORMATION - V/l'fHHOLB UNBER 16 CFR 2 .S96

SECURITY*RELATED INFORMATION - WITIHIOLD UNDER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Figure 1.9-6: Missouni River Path in 1879 at the Site of CNS 0

Reference 1.7- 14 (Note: Current river path Is overlaid and is in faded blue.)

Site fnformation Related to the Flood Hazard 1-28 SECURITY-RELATED INFORMATION - WITI II IOLD UNDER 16 CFR 2.996

SECURITY*RELATED INFORMATION - WITHHOLB UNBER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11764-017 Figure 1.9-7: Aerial Photograph of the Plant Site in 1971 0 zooo f .. ..

Reference 1.7-14 (This photograph was taken after construction of CNS began In 1968, but prior to CNS officially opening In 1974. The river channel and banks looked much like they do today.)

Site Information Related to the Flood Hazard 1-29 Snrgnnc & Lundy SECURIT¥ -RELATED INFORMATION - WITI II IOLD UN BER 16 CFR 2.996

SECURIT¥-RELATES INFORMATION - WITHI-IOLS UNSER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Pro1ect No.: 1178-4-017 Figure 1.9-8: Aerial Photograph of CNS Showing Flooding t

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• Reference 1.7-14 (This Figure shows a uten,te Image of the Missouri River taken on July 9, 2011 ancl the effect of the maximum releases from Gavlns Point Dam cluring the 2011 ftoocl. Flood waters hacl Inundated the ftoodplain In many of the areas where the Missouri River hacl once meandered within the bounclaries of the levees. There was visible ftoocling east of the eastem levee due to the upstream levee breaches. There was also visible stancling water on the west side of the river, west of the levee, likely due to Interior drainage. There Is no evidence that a new channel was beginning to form. The resolution of the image Is such that it Is not possible to discern the status of the bank stablliiaUon structures.)

Site Information Related to the Flood Hazard 1-30 SECURIT'f-RELATES INFORMATION - WITHHOLS UNSER 16 CFR 2.996

SECURITY-RELATEB INFORMATION

• WITHHOLf> UNBER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZARD REEVALUATION REPORT

2. FLOOD HAZARD REEVALUATION 2.1 LOCAL INTENSE PRECIPITATION (LIP)

Probable Maximum Precipitation (PMP), also known as local Intense Precipitation (LIP), is the measure of the extreme precipitation (high intensity/short duration) at a given location. Evaluation of the flooding hazards to the safety-related Systems, Structures, and Components (SSCs) at Cooper Nuclear Station (CNS) due to LIP is presented in this section of the report. U.S. Nuclear Regulatory Commission (NRC) guidelines NUREG/CR-7046 (Reference 2.1-1), NRC Regulatory Guide 1.59 (Reference 2.1-2), and ANSI/ANS-2.8-1992 (Reference 2.1-3) fom, the basis for the approach and methodology used in this evaluation. The analysis was performed with the conservative assumption that the local storm drainage system (culverts, ditches, storm sewers, dry wells, etc.) would not be functional during the LIP event.

The LIP flood effects on CNS were detem,ined by performing site-specific hydrologic and hydraulic analyses. The rational method (Reference 2.1-4) with conservative runoff coefficients (i.e.,1.0) was used for computation of peak PMP runoff from different drainage areas of the plant site. The U.S. Army Corps of Engineers (USACE) Hydrologic Engineering Center River Analysis System (HEC-RAS) computer program (Reference 2.1-5) was used to determine the maximum water surface elevation and flow velocity. Due to the relatively short duration of the flooding event and the shallow depth of inundation, the effects of wind-waves were not considered. Reference 2.1-6 defines Plant Datum the same as Datum used in the USAR (which is MSL).

The vertical datum used for this section (i.e., Section 2.1) was the CNS Plant Datum. The National Geodetic Vertical Datum of 1929 elevation (NGVD29) is equal to Plant Datum elevation plus 0.11 feet [ft] (Reference 2.1-6). The North American Vertical Datum of 1988 elevation (NAVD88) is equal to NGVD29 elevation plus 0.26 ft (Reference 2.1-6). The NAVD88 elevation is equal to Plant Datum elevation plus 0.37 ft. All directions are with respect to the Plant North direction, which is oriented to the west of the true north direction.

The effect of LIP on CNS was not evaluated previously in the Updated Safety Analysis Report (USAR, Reference 2.1-7). As presented in Section 4.2.2.2 of the USAR, the finished floor elevation of Principle Class 1 Structures (SSCs) is at 903.5 ft Plant Datum (903.87 ft NAVD88) and the general site grade elevation is at 903.0 ft Plant Datum (903.37 ft NAVD88).

2.1.1 Probable Maximum Precipitation Depths As prescribed in NUREG/CR-7046 (Reference 2.1-1 ), the LIP used in the analysis is the 1-hour, 1-square mile PMP at the CNS site. Parameters to estimate the LIP were obtained from the U.S.

National Weather Service (NWS) Hydrometeorological Reports HMR 51 and HMR 52 (see References 2.1-8 and 2.1-9).The estimated depths from HMR 51 are for precipitation durations 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> and longer and drainage areas from 10 to 20,000 square miles. These estimates were used with procedures outlined in HMR 52 to determine PMP depths of various durations less than 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> and Local Intense Precipitation (LIP) 2-1 SECURIT¥-ftELATEB INFORMATION - WITHHOLB UNBER 16 CFR 2.996

SECURIT¥*RELATEE> INFORMJ!<TION - WITHHOLB UNE>ER 16 CFR 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 drainage are*as up to 1 square mile for the site. Table 2.1-1 presents the PMP depths and intensities for various durations at the CNS site.

2.1.2 Drainage Areas and local Drainage Parameters The CNS site is located on the west (right) bank of the Missouri River near Brownville, Nebraska, at approximate River Mile (RM) 532.5. The latest available topographic survey (Reference 2.1-6) for the plant site area was used for delineation of drainage areas (zones). The main plant area is relatively flat without well-defined flow paths, and is delineated into drainage areas considering drainage away from the Central Building Complex in all directions. The majority of the plant area perimeter is bounded by 9 to 10 rows of jersey barriers (Figure 2.1-1) with variable longitudinal spacing (1 inch to 36 inches). A portion of the security barrier south of the plant is formed by Kontek concrete block barriers. The jersey barriers are 12.5 ft long and 32 inches (in) high and the Kontek blocks are 10 ft long and 3 ft high. Due to the variability in opening size, potential for barrier relocation, and potential for staggered openings between barrier rows; conservatively, openings between barriers were not considered flow paths for thi~ analysis.

Figure 2.1-2 shows the four drainage areas considered in the main plant area, identified as Zones A, B, c,.and D. All safety-related facilities at CNS are located within these four zones. Peripheral portions of the main plant area that are not directly connected to, or that do not affect the safety-related facilities, were not included in the PMP zones. These small areas located along the periphery of the main plant area would generate a relatively small amount of runoff that would drain away from these areas without affecting the runoff draining away from the safety-related facilities.

Zone A is located on the east side of the plant, near the Missouri River. The Intake Structure is located along the downstream (eastern) boundary of Zone A. The grade elevation in this zone varies from 902 ft (902.37 ft NAVD88) to 903.5 ft (903.87 ft NAVD88). Although runoff could flow to the south where the grade slopes down toward the area of the discharge canal and sludge pond, all runoff from Zone A is considered to flow over the eastern boundary to the river on the south side of the Intake Structure, resulting in conservative estimates for the maximum water level in Zone A.

Zone B is located on the north side of the main plant area. Security bar riers are located along the northern edg1e of the zone at the downstream boundary, with relatively high elevations on the west side and lower elevations on the east side toward the river. The grade elevations at the downstream boundary of Zone B range from 902.5 ft (902.87 ft NAVD88) on the west side, to 897 ft (897.37 ft NAVD88) and below on the east side. Due to multiple obstructions on the western side of Zone B (i.e.,

tanks, buildirngs, etc.), the flow paths on the west side of some cross sections were considered blocked and not used for conveyance. Additionally, due to the relatively high grade elevation and security

• barriers downstream of the tanks, the areas between the tanks were designated as ineffective flow areas within the HEC-RAS model. All runoff from Zone B was considered to drain away from the main plant through the area between the Condensate Storage Tank and the Fabrication Shop, and discharge over the top of the security barriers on the east side of the northern boundary. Overtopping of the barriers was considered at the downstream boundary of Zone B.

Local Intense Precipitation (LIP) /

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SECURIT¥ -RELATEE> INFORMJ!<TION - WITHHOLB UNE>ER 16 CFR 2.396

SECURITY-RELATED INl-0RMATl0N - WITHHOLD UNDER 16 CI-R 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAzARD REEVALUATION REPORT Project No.: 11784*017 Zone C is located on the south side of the main plant area. Runoff from this zone drains over the southern periphery of the main plant area to the low elevation area near the discharge canal, where it can flow unobstructed to the Missouri River. The grade elevations at the downstream boundary of Zone C range from 904 ft (904.37 ft NAVD88) to 902 ft (902.37 ft NAVD88), and all runoff from Zone C was considered to exit the zone on the west side of the storage tanks and buildings located near the downstream (southern) boundary.

Zone D is located on the west side of the main plant area. The security barriers (32 inches high) are located at the western edge of this zone and act as an obstruction. As runoff accumulates behind the barriers and causes ponding in Zone D, runoff will flow to the south. Overtopping of the barriers along the western boundary of Zone D was not considered in this analysis due to the relatively high elevations of the top of barriers. Although the flow path along the west side of the East Warehouse between the security barriers and the building has the capacity to convey the entire peak flow from Zone D, it is expected that some runoff will flow into Zones B and C. Flow-balancing calculations were performed to determine the quantities of runoff flowing to these zones.

The offsite drainage area was delineated (Figure 2.1-3) considering Federal Levee R548 that is adjacent to CNS with a top elevation of approximately 902 ft (902.37 ft NAVD88). The levee extends north of the plant, where it terminates at the higher ground near the bluffs. South of CNS, the levee follows the right bank of the Missouri River, curving around to the west, running parallel to the left bank of the Nemaha River, and turning north where it meets the higher ground near the town of Nemaha.

The area enclosed by the levee and the higher bluffs to the west measures 4000 acres (ac). The effect of runoff from the offsite drainage area on PMP water levels near CNS is discussed in Section 2.1.4.

2.1.3 Peak Discharges To compute the peak runoff, time of concentration for each zone was estimated using the Kerby Equation (Reference 2.1-10). For each zone, flow length, average slope, and roughness coefficient were estimated and used as input for the Kerby Equation. The surfacing in the main plant area is mostly gravel and concrete or asphalt-paved, and the roughness coefficient was considered to be 0.02 (Reference 2.1-4).The estimated times of concentration are presented in Table 2.1-2. Using the PMP values corresponding to the time of concentration, the applicable PMP intensity for each zone was estimated. Employing the rational method (Reference 2.1-4), peak runoff for each of the zones was estimated. A conservative runoff factor value of 1.0 (indicating 100% runoff without any infiltration or other losses) was used in the rational method.

2.1 .4 Hydraulic Model Setup For computations of water levels, the HEC-RAS Version 4.1 computer program (Reference 2.1-5) was used. Separate HEC-RAS runs for each zone were performed. The site features and flow obstructions in each drainage area are characterized by cross sections (Figure 2.1-4 through Figure 2.1-7) and used in the hydraulic analysis.

Local Intense Precipitation (LIP) 2-3 SECURIT't'*RELATED INFORl\~TION - WITHHOLD UNDER 16 CFR 2.998

SECURITY-RELATEE> INFORMATION - WITHHOLE> UNE>ER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 The surfacfng in the main plant area is primarily gravel and concrete or asphalt-paved. Reference 2.1-4 recommends Manning's roughness coefficients ranging from 0.011 to 0.025 for such surfaces.

Conservatively, a Manning's roughness coefficient of 0.030 was used to account for minor obstructions.

The flow at each cross section was computed by prorating the peak discharge of the entire zone based on the drainage area upstream of that cross section. Table 2.1-3 through Table 2.1-6 present the peak flow at each cross section for Zones A through D, respectively.

For Zones A, C, and D, the critical depth was considered as the downstream boundary condition to account for the flow transition from the relatively flat main plant area, over the peripheral boundary and down a steep slope. Critical depth was considered for the downstream boundary condition in Zone B to account for the flow over the security barriers, which were considered to act as a weir. The present-day regulatory guidance (References 2.1-1 and 2.1-11) does not provide combined-events criteria governing the coincident water level in an adjacent river during the LIP event. The normal river water level at CNS is well below elevation 890 ft (880.37 ft NAVD88), and the CNS USAR defines the normal summer water level as 880 ft (890.37 ft NAVD88 [Reference 2.1-7]).The 25-year water level in the Missouri River at CNS is 898.04 ft (898.41 ft NAVD88 [Reference 2.1-12]).The 25-year water level is well below the lowest elevation of any cross section considered in the evaluation and will not affect drainage from the site during an LIP event. Therefore, there is no backwater effect from the Missouri River at the downstream boundary for Zones A, B, and C. Zone D discharges to the floodplain behind the USACE levee, and is not affected by water levels in the Missouri River or the offsite area.

Runoff from the offsite drainage area will pond on the floodplain behind the USACE levee. Comparing the total PMP runoff volume with t he storage volume available behind the levee showed that the maximum surface elevation of the ponded water level will be less than 892 ft (892.37 ft NAVD88).Therefore, water levels at the boundary of the main plant area, during an LIP event, will not be affected by runoff from the offsite drainage area.

Several temporary trailers are installed in the main plant area at CNS. The trailers are accounted for in the analysis as complete obstructions. Sensitivity runs with and without the trailers performed using HEC-RAS indicated that these trailers have a negligible effect on the PMP water levels estimated for this analysis. '

Initially, the maximum water levels for each zone were computed without considering the cross flow between the adjacent zones. Subsequently, a trial-and-error flow-balancing exercise was performed to determine the cross flows that result in matching water levels at the interface between zones.

2.1.4.1 LIP Runoff Water Levels without Cross Flow between Zones The resulting maximum water level in each zone during an LIP event, without consideration of cross flow between zones, is summarized below:

Local Intense Precipitation (LIP) .,,,

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SECURIT¥*RELATEE> INFORMATION - WITI IHOLD UNDER 16 CFR 2.996

SE6URIT¥-RELATEB INFORMATION - WITHHOLB UNBER 16 6FR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017

• Zone A maximum water level= 903.05 ft (903.42 ft NAVD88)

• Zone B maximum water level= 903.35 ft (903.72 ft NAVD88)

• Zone C maximum water level= 903.59 fl (903.96 ft NAVD88)

• Zone D maximum water level = 903.80 ft (904.17 ft NAVD88) 2.1.4.2 Water Levels with Cross Flow between Zones Preliminary water level estimates without consideration of cross flow showed the water levels in Zones Band D differ by nearly 6 inches. Through a process of trial-and-error, a cross flow of 63 cubic feet per second (cfs) is considered to flow from Zone D to Zone B (Figure 2.1-5). A cross flow of 63 cfs was chosen because It represents all of the peak flow at the upstream-most cross section of Zone D and provides closely matching (less than a 1-lnch difference) final water surface elevations between Zones B and D.

Cross flow can occur from Zone D to Zone C upstream of the East Warehouse, and from Zone C to Zone D downstream of the East Warehouse (Figure 2.1-6). Cross flow from Zone D into Zone B was deducted from Zone D before the cross flow balancing between Zones C and D was performed. Cross flow from Zone C into Zone A (Figure 2.1-7) was estimated following the cross flow balancing between Zones C and D.

The maximum water level in Zone B is approximately 5 inches higher than the maximum water level In Zone A. The broad-crested weir equation (Reference 2.1-13) was used to estimate the cross flow from Zone B to Zone A The potential for submerged weir flow was checked using Figure 5-15 of Reference 2.1-14. A total cross flow of 108 cfs enters Zone A at the upstream boundary and was applied to every cross section In the zone. Conservatively, the flows at cross sections in Zone Band Zone C were not reduced to account for this flow out of the zone. Figure 2.1-8 through Figure 2.1-11 present the results of the hydraulic analysis for all HEC-RAS cross sections considering cross flow between two adjacent zones. The resulting maximum water level in each zone during an LIP event, considering cross flow between zones, is summarized below.

• Zone A maximum water level= 903.19 ft (903.56 ft NAVD88)

• Zone B maximum water level= 903.47 ft (903.84 ft NAVD88)

• Zone C maximum water level= 903.50 ft (903.87 ft NAVD88)

• Zone D maximum water level= 903.50 ft (903.87 ft NAVD88) 2.1.4.3 Velocity The maximum velocity obtained from the HEC-RAS output for each zone is summarized below.

• Zone A maximum velocity = 3.64 feet per second (fps)

• Zone B maximum velocity= 4.49 fps

• Zone C maximum velocity = 2.87 fps

• Zone D maximum velocity = 5.02 fps Local Intense Precipitation (LIP) 2-5 SECURIT't'-RELATEB INfiORMATION - WITHHOLB UNBEfit 16 Cfiift: 2.996

SECURIT¥*RELATED INFORMATION - \VITHHOLI:> UNDEfit: 16 CFfit: 2.396 Nebraska Public Power District SL-01245O Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 The HEC-RAS simulations were performed under subcritical flow conditions; however, the results indicated that there could be supercritical flow conditions in Zones B and D. Additional HEC-RAS test runs using a mixed-flow regime resulted in no change to the maximum water levels estimated for these zones. Since the subcritical flow dominates in the upstream areas, upstream water levels are controlled by water levels downstream, not the upstream boundary condition. However, the velocities at some cross sections are affected when a mixed-flow regime is employed.

In Zone D, supercritical flow occurs in the area located between the Warehouse and the security barriers at Cross Section D500, with a maximum velocity of 5.12 fps. T he model indicated that a hydraulic jump occurs between Cross Sections 0500 and D400. The Froude number is close to 1.0, indicating that the hydraulic jump is weak; howe'l(er, the potential for erosion exists due to turbulence at the location of the jump. In Zone B, supercritical flow occurs on the steep slope at the periphery of the main plant area at Cross Section B200. The velocity at this location is 9.34 fps; hence, there is a potential for erosion of the sloped surface. Both of the locations that have potential for site erosion are located around the periphery of the plant, away from safety-related SSCs, and would not affect any CNS safety-related facilities.

2.1.5 Effect of LIP Table 2.1-7 presents a summary of the Maximum Water Levels in all zones at different cross sections.

These water levels consider cross flow between zones for steady-state, subcritical flow conditions. The maximum estimated water level due to LIP at CNS is 903.50 ft (903.87 ft NAVD88), which is equal to the finished floor elevations for Principal Class 1 Structures. While significant inundation above the

. finished floor elevations is not expected, the potential for minor flooding at the entrances of these structures may exist during the peak of the event.

Reference 2.1-14 recomme,nds a maximum permissible flow velocity of 6.0 fps to prevent erosion of channels with fine-gravel surfacing. The potential for erosion in the main plant area is low, as the velocities do not exceed 6 fps and are generally less than 3 fps. Velocities on the steep slope at the periphery of the main plant area may cause local erosion of the sloped surface, but there would be no effect on safety-related facilities.

Due to the relatively short duration of the flooding event and the shallow depth of inundation, the effects of wind-waves were not considered. Additionally, debris loading and transportation were not considered in the analysis due to the relatively low velocity and shallow depth of LIP flood waters near CNS safety-related facilities, and due to the lack of debris sources in the CNS main plant area.

2.1.6 References 2.1-1. Design-Basis Flood Estimation for Site Characterization at Nuclear Power Plants in the United States of America, NUREG/CR-7046, Office of Nuclear Regulatory Research, U.S. Nuclear Regulatory Commission, November 2011.

2.1-2. Regulatory Guide 1.59, Design Basis Floods for Nuclear Power Plants, Revision 2, Office of Standards and Development, U.S. Nuclear Regulatory Commission, August 1977.

Local Intense Precipitation (LIP) ,,*'{

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SECURIT¥ -RELATEB INFORMATION - WIT HHOLD UNf>ER 16 CFft: 2.S96

SECURIT¥ -RELATEB INFORMATION -WITHHOLD UNDER 10 CFR 2.390 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 1178-017 2.1-3. American Nuclear Society, ANSI/ANS-2.8-1992, Determining Design Basis Flooding at Power Reactor Sites, July 1992.

2.1-4. Handbook of Applied Hydrology, VenTe Chow, McGraw- Hill Inc., 1964.

2.1-5. Hydrologic Engineering Center's River Analysis System {HEC-RAS) Version 4.1 for Windows.

U.S. Army Corps of Engineers, 2010.

2.1-6. NPPD Engineering Evaluation Number 12-035, Revision 0, "Review of 2012 Topographic Survey of CNS," March 2013.

2.1-7. Updated Safety Analysis Report (USAR - 2.7), Cooper Nuclear Station, Site and Environs, Hydrology, Site Flooding Protection, Dated 01 /16/01.

2.1-8. Hydrometeorological Report No. 51 (HMR 51), Probable Maximum Precipitation estimates, United States East of the 105th Meridian, National Weather Service, National Oceanic and Atmospheric Administration (NOAA), June 1978.

2.1-9. Hydrometeorological Report No. 52 {HMR 52), Application of Probable Maximum Precipitation Estimates - United States East of the 105th Meridian, National Weather Service, National Oceanic and Atmospheric Administration {NOAA), August 1982.

2.1-10. Hydrology and Hydraulic Systems, Ram S. Gupta, Second Edition, Waveland Press, Inc.,

2001.

2.1-11 . Standard Review Plan, Revision 4, NUREG-0800, Section 2.4.2 Floods, United States Nuclear Regulatory Commission (USNRC), March 2007.

• 2.1-1 2. Upper Mississippi River System Flow Frequency Study, Hydrology and Hydraulics, Appendix F, Missouri River, U.S. Army Corps of Engineers, Omaha District, November 2003.

2.1-13. Handbook of Hydraulics, Ernest F. Brater, Horace W. King, Sixth Edition, McGraw-Hill, Inc.,

1976.

2.1-14. Engineering Manual EM 1110-2-1601 , "Engineering and Design - Hydraulic Design of Flood Control Channels," Table 2-5, p 2-16, U.S. Army Corps of Engineers, 1991 .

Local Intense Precipitation (LIP) ~,..

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SECURIT¥ -RELATEB INFORMATION =WITI II IOLB UNBER 18 CFR 2.998

SECURIT¥-RELATED 1Nf-ORM)8[TION - \VITIIIIOLE> UNDER 16 Cf-R %.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 2.1.7 Tables Tables associated with Section 2.1 are presented on the following pages.

Local Intense Precipitation (LIP) 2-8 (\

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SECURIT'f -RELATEB INf-ORMATION - WITI ti IOLB UN BER 16 Cf-R %.396

SECURIT¥-RELATI!" INP'OfitMATION - WITHHOLB UNBER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Table 2.1-1: PMP Values and Intensities at the CNS Site 1 hr, Point PMP PMP Depth PMP Duration and Area Location Source Intensity (in)

Ratio (In/hr) 24 hr, 10 mi 2

- HMR 51 - Figure 20 33.3 -

1 hr, point location - HMR 52 - Figure 24 18.2 18.2 30 min, point 0.765 HMR 52 - Figure 38 13.9 27.8 15 min, point 0.534 HMR 52 - Figure 37 9.7 38.8 5 min, point 0.338 HMR 52 - Figure 36 6.2 74.4 Table 2.1-2: Peak Discharge Drainage Time of Rainfall Peak Flow Slope Zone Area Concentration Intensity Discharge Length (ft) (ft/ft)

(acres) (min) (in/hr) (cfs)

A 2.61 130 0.0077 4.0 74.4 194 B 5.30 280 0.0036 6.9 59.7 316 C 4.00 285 0.0035 7.0 59.1 236 D 6.29 650 0.0031 10.6 46.2 291 Note:

1. A 5-minute time of concentration is appl led to any drainage area In which the estimated time of concentration Is less than 5 minutes.

Local Intense Precipitation (LIP) 2-9

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SECURIT'f-RELATEB INFORM>\TION - WITHHOLB UNBER 16 CFR 2.996

SEOURIT¥-RELATED INFORM>9cTION - "ft'ITHHOLD UNDER 16 Cl-ff 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Table 2.1-3: Drainage Area and Peak Flow at each Cross Section - Zone A Col umn: (1) (2) (3) (4)

Peak Flow (cfs) Peak Flow (cfs)

Cross Section Upstream Ratio Upstream Flow Profile: Flow Profile:

Area (ac) Area to Total Area Initial (Without Final (With Cross Flow) Cross Flow)

A800 1.04 0.398 77 185 A700 1.22 0.467 91 199 A600 1.47 0.563 109 217 ASO0 1.73 0.663 129 237 A400 1.98 0.759 147 255 A300 2.23 0.854 166 274 A200 2.46 0.943 183 291 A100 2.61 1.000 194 302 Notes:

1. Column (2) = Column (1) /Total Area; Total Area= 2.61 ac

2. Column (3) = Column (2) x Peak Flow; Peak Flow" 194 cfs

3. Column (4) = Column (3) + 108 cfs from Zone B and Zone C (Cross Flow)

Local Intense Precipitation (LIP) 2-10 Sargc.-'.ti~ &1Lundy' '~

SEOURIT¥-RELATED INFORMATION - WITHHOLD UNDER 18 CFff 2.996

SEetJRIT'l'-RELATEB INPORMATION - WITHHOLB tJNBER 16 ei-R 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION Rl!PORT Project No.: 11784-017 Table 2.1-4: Drainage Area and Peak Flow at each Cross Section - Zona B Column: (1) (2) (3) (4)

Peak Flow (cfs) Peak Flow (cfs)

Upstream Ratio Upstream Flow Profile: Flow Profile:

Cross Section Area (ac) Area to Total Area lnltlal (Without Final (With Cross Flow) Cross Flow)

B1200 0.75 0.142 45 108 B11 00 1.16 0.219 69 132 B1000 1.49 0.281 89 152 B900 2.13 0.402 127 190 B800 2.38 0.449 142 205 B700 2.81 0.530 168 231 B600 3.41 0.643 203 266 B500 3.65 0.689 218 281 8400 4.10 0.774 244 307 B300 4 .65 0.877 277 340 B200 4.95 0.934 295 358 B100 5.30 1.000 316 379 Notes:

1. Column (2) = Column (1) I Total Area; Total Area= 5.30 ac

2. Column (3) = Column (2) x Peak Flow; Peak Flow

• 316 cfs

3. Column (4) = Column (3) + 63 cfs from Zone D (Cross Flow)

Local Intense Precipitation (LIP) 2-11 SEetJRIT','*RELATEB INFORMATION - WITHHOLB tJNBER 16 CFR 2.998

SECURFf"f-RELATEe INFORMATION - Vt'ITlftlOLD UNDER 16 eFR 2.398 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: ! 1784-017 Table 2.1-5: Drainage Area and Peak Flow at each Cross Section - Zone C Column: (1) I (2) (3) (4)

Peak Flow (cfs) Peak Flow (cfs)

Upstream Ratio Upstream Flow Profile: Flow Profile:

Cross Section Area (ac) Area to Total Area Initial (Without Final {With I Cross Flow) Cross Flow)

C1200 1.08 0.270 64 65 C11 00 1.19 0.298 70 72 I

C1000 1.37 0.343 81 84 csoo 1.74 0.435 103 109 C800 2.1 1 0.528 124 130 C700 2.50 0.625 148 154 C600 2.69 0.673 159 165 C500 2.95 0.738 174 180 C400 3.26 0.815 192 170 C3D0 3 .48 0.870 205 154

\

C200 3.82 0.955 225 145 156 C1D0 4.00 I 1.000 236 Notes:

1. Column (2) = Column (1) / Total Area; T otal Area = 4.00 ac

2. Column (3)

• Column (2) x Peak Flow; Peak Flow" 236 cfs

3. Column (4) = final profile resulting from cross flow balancing with Zone D Local Intense Precipitation (LIP) -~*;J*

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SECURIT¥-RELATED INFORMATION - 'NITHHOLD UNBER 16 CFR 2.396

SECURIT¥-RELATED INFORMATION - WITHHOLE> UNDER 16 CFR ! .S96 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No,: 11784-017 Table 2.1-6: Drainage Area and Peak Flow at each Cross Section - Zone D Column: (1) (2) (3) (4)

Peak Flow (cfs) Peak Flow (cfs)

Upstream Ratio Upstream Flow Profile: Flow Profile:

Cross Section Area (ac) Area to Total Area Initial (Wrthout Final (With Cross Flow) Cross flow)

D2000 1.36 0.216 63 0 D1900 1.66 0.264 77 14 D1800 1.81 0.288 84 21 D1700 2.18 0.347 101 38 D1600 2.38 0.378 110 47 D1500 2.82 0.448 130 67 D1450 2.99 0.475 138 75 D1400 3.42 0.544 158 95 D1300 3.96 0.630 183 120 D1200 4 .12 0.655 191 126 D1100 4.23 0.672 196 131 D1000 4.40 0.700 204 137 D900 4.78 0.760 221 152 D800 4.94 0.785 229 160 D700 5.19 0.825 240 171 D600 5.30 0.843 245 176 D500 5.46 0.868 253 184 D400 5.66 0.900 262 222 D300 5.82 0.925 269 258 D200 6.08 0.967 281 298 D100 6.29 1.000 291 308 Notes:

1. Column (2)

• Column (1) /Total Area; Total Area* 6.29 ac

2. Column (3) = Column (2) x Peak Flow; Peak Flow= 291 els

3. Column (4) - Final profile resulting from cross flow balancing with Zone C Local fntense Precipitation (LIP) 2-13 Sargent S..,L.uridy 1

• 0:

' I SECURIT¥-RELATeD INFORMATION - WITHHOLD UNf>ER 1e Cf'R 2.396

SECURIT¥*RELATED INFORM3'TION - WITHHOLB UNDER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD Rl!l!VALUATION Rl!PORT Project No.: 11784-017 Table 2.1-7: PMP Water Levels Zone A ZoneB ZoneC ZoneD Water Water Water Water Cross Cross Cross Cross Level (ft) Level (ft) Level (ft) Level (ft)

Section Section Section Section A800 903.19 81200 903.47 C1200 903.50 D2000 903.50 A700 903.17 6 1100 903.46 C1100 903.48 D1900 903.50 A600 903.16 81000 903.45 C1000 903.49 D1800 903.50 A500 903.14 8900 903.40 C900 903.47 D1700 903.50 A400 903.07 8800 903.39 C800 903.45 D1600 903.50 A300 903.02 8700 903.35 C700 903.44 D1500 903.50 A200 902.84 6600 903.33 C600 903.43 D1450 903.5 A1001 902.55 6500 903.32 csoo 903.4:f D1400 903.50

- - 6400 903.17 C400 903.42 01300 903.49

- - 8300 902.54 C300 903.38 D1200 903.49

- - 8200 900.51 C200 903.15 01100 903.49

. - 8100 899.79 C100 902.30 01000 903.47

- - - - - - 0900 903.15

. - . . - - 0800 903.06

- - - - - - 0700 902.85

- . - . - - 0600 902.51

- - - - - - D500 902.16

- - - - - - 0400 902.02

. - . - . - D300 902.01

. . - - . - 0200 901.76

- - . - . - 0100 901 .51 Note:

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SECURIT¥*RELATED INFORMA1'16N - 'NITHHOLE> UNE>E" 16 CPR ! .S96 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION Rl!PORT Project No.: 11784-017 2.2 FLOODING IN STREAMS AND RIVERS (PMF)

The Cooper Nuclear station (CNS) is located on the west (right) bank of the Missouri River in Nemaha County near Brownville, Nebraska at approximate Missouri River Mile (RM) 532.5 (see Figure 2.2-1 ).

In this section of the report, the Probable Maximum Flood (PMF} in the Missouri River was evaluated to assess the flooding hazard on the safety-related facilities at CNS. The PMF is the hypothetical flood (peak discharge, volume, and hydrograph shape) that is considered to be the most severe reasonably possible, based on comprehensive hydrometeorological application of the Probable Maximum Precipitation (PMP} and other hydrologic factors favorable for maximum flood runoff, such as sequential storms and snowmelt (Reference 2.2-1 ).

The hydrologic conditions in the Missouri River at CNS are complex due to size of the contributing Missouri River watershed (414,900 square mlles above Rulo, Nebraska near CNS, United States Geological Survey [USGS] gage number 06813500 [Reference 2.2-21) and the six System dams (Fort Peck, Garrison, Oahe, Big Bend, Fort Randall, and Gavins Point) located on the mainstem of the Missouri River upstream of CNS (Figure 2.2-2 sheet a). The Missouri River is the longest river in the United States, draining one-sixth of the country (Reference 2. 2-3). The U.S. Army Corps of Engineers (USACE) regulates all of the System dams. They are regulated as a hydraulically and electrically integrated system. Runoff from upstream of the System dams is stored in the six reservoirs. USAGE controls the water release from the System dams. Released water from the most downstream dam in the System, Gavins Point Dam, flows down the Missouri River toward CNS. In addition, there are also a large number of other dams (referred to as "Non-System" dams) in the drainage basins contributing to the Missouri River downstream of the "System" dams and upstream of CNS (see Figure 2.3-1 ).

The U.S. Nuclear Regulatory Commission (NRC), in Section 5.3 of NUREG/CR-7046 (Reference 2.2-1), suggests use of flood simulation models developed by federal agencies, such as USAGE. Following such recommendations, the Hydrologic Engineering Center Hydrologic Modeling System (HEC-HMS, Reference 2.2-4} and the Hydrologic Engineering Center River Analysis System (HEC-RAS, Reference 2.2-6) were used to perform the hydrologic (Section 2.2.2) and hydraulic (Section 2.2.3) analyses, respectively.

The PMF value for CNS was developed using the following steps:

• Determine probable maximum precipitation (PMP) over the basins that drain into the Missouri River below Gavins Point Dam and upstream of CNS.

• Develop the PMF hydrographs by applying the PMP over the basin.

• Route the PMP runoff using one-dimensional (1-D) unsteady basin-scale hydraulic model and generate boundary conditions for a reach-scale two-dimensional (2-D) hydraulic model.

• Determine depth and velocity of the fiow at CNS during PMF using a reach-scale 2-D hydraulic model.

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• Calculate wind setup, wind-wave runup, and hydrostatic and hydrodynamic forces on systems, structures, and components (SSCs) and other buildings at CNS due to the PMF.

• Calculate debris impact forces and evaluate the erosion and sedimentation at the site.

Details of each step of the analysis are provided in the following sections.

2.2.1 Probable Maximum Precipitation (PMP)

In this section of the report, estimation of a realistic, yet conservative, PMP over the Platte River Basin and the adjoining reaches of the Missouri River identified as the Lower Basin (Fort Calhoun) and the Lower Basin (Cooper) is discussed (see Figure 2.2-3). This PMP was used to determine the maximum water level at CNS at Missouri RM 532.5 resulting from the PMF in the Missouri River.

2.2.1.1 Basin Delineation The applicable basin was delineated using the United States Department of Agriculture (USDA)

Watershed Boundary Dataset (Reference 2.2-7). Watershed boundaries define the aerial extent of surface water draining to a particular point, which is CNS. The watershed boundaries were defined through the use of hydrologic units (HUs) to establish a baseline rain gage boundary framework, accounting for all land and surface areas. Geographical Information System (GIS) software, specifically Environmental Systems Research Institute (ESRI) ArcGIS (Reference 2.2-8), was used to delineate the basin. The delineated basin outline is shown in Figure 2.2-3.

2.2.1.2 PMP Alternatives Section 9.2.1.1 of ANSI/ANS-2.8-1992 (Reference 2.2-9) and Appendix Hof NUREG/CR-7046 (Reference 2.2-1) specify three different alternatives for a flood reevaluation analysis. The alternatives comprise a combination of:

• Alternative 1 - mean monthly (base) flow, median soil moisture, antecedent or subsequent rain (the lesser of rainfall equal to 40% of the PMP and a 500-year rainfall),

PMP, and waves induced by the 2-year wind speed applied along the critical direction.

• Alternative 2- mean monthly (base) flow, probable maximum snowpack, a 100-year, snow-season rainfall, and waves induced by the 2-year wind speed applied along the critical direction.

• Alternative 3- mean monthly (base) flow, a 100-year snowpack, snow-season PMP, and waves induced by the 2-year wind speed applied along the critical direction.

An evaluation of these alternatives showed that Alternatives 2 and 3 do not create an extreme peak in a short time period as Alternative 1 does. Therefore, Alternative 1 was used in this analysis as it was the most conservative approach.

The 500-year, 72-hour rainfall value for a point at the centroid of the PMP analyses for the basin was obtained from National Oceanic and Atmospheric Administration (NOAA) Atlas 14 (Reference 2.2-10).

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SECURIT¥*RELATEB INFORMATION - Vt,ITHHOLB UNBER 16 CP.R 2.996

SEOURIT¥*RELA1'Ef} INFORMATION - VilTHHOLf> UNE>ER 16 OFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Analysis showed that applying a 40% PMP over the basin results in approximately one half the rainfall volume that a 72-hour 500-year storm event would create. Therefore, the 40% PMP was considered as the antecedent rain. The 40% PMP storm event will precede the PMP storm event by 3 days (3 to 5 days allowable in ANSI/ANS-2.8-1992, Reference 2.2-9) as this period of transition is meteorologically reasonable for this region of the United States.

2.2.1.3 PMP Development PMP storm depth, spatial distribution, centering, and orientation pattern for a 72-hour storm period adopted for the drainage basins upstream of CNS and downstream of Gavins Point Dam were derived following the procedures described in the National Weather Service (NWS) Hydrometeorological Reports 51 and 52 (HMRs 51 and 52, References 2.2- 11 and 2.2-12, respectively). The PMP estimates obtained from these HMR procedures are location-specific and have accounted for orographic and seasonal effects.

The Jo~er portion of the Basin (38,672 square miles), including the Platte River watershed below Lake Mcconaughy and the portion of the Missouri River watershed between Gavins Point Dam and CNS, was chosen as the watershed area of interest for this PMP analysis. Centering the PMP event over the lower portion of the Basin produces the most hydrologically conservative result. ANSI/ANS-2.8-1992 (Reference 2.2-9) recommends that enough storm center positions be considered to ensure that the most critical condition has been determined. In this study, four storm centers (centroids) and orientations (Figure 2.2-4) were used so that the hydrologic sensitivity and resultant flows from the analyses of the PMP could identify through hydrologic modeling (Section 2.2.2) which location would produce the highest water elevation at CNS. The following steps were performed in establishing the PMP resulting in the highest water elevation at CNS:

• Obtain the all-season precipitation values from HMR 51 at all four storm centers for basins ranging from 10 to 20,000 square miles for the 6-, 12-, 24-, 48-, and 72-hour durations.

• Because the maximum basin size available from HMR 51 data is 20,000 square miles, only four basin sizes less than the 20,000 square miles were analyzed, in order to develop an envelope that generates the maximum precipitation volume. Basin sizes of 20,000-, 15,000-, 10,000-, and 6,500-square miles were chosen to develop the envelopment curves.

• The incremental differences between Oto 6-hour, 6 to 12-hour, and 12 to 18-hour precipitation values were then calculated and the digitized isohyet pattern was centered on the basin centers and oriented along the long axis of each basin (Figure 2.2-4) using GIS software.

• Determine the cumulative rainfall volume for each of the four enveloping basin sizes to determine which size has the highest volume and, therefore, the highest PMP value.

The 20,000 square miles of watershed yielded the highest precipitation volume with the exception of the fourth center (P4 in Figure 2.2-4) analysis in which the 15,000-square mile watershed yielded the highest precipitation volume.

Flooding in Streams and Rivers (PMF) 2-34 SEOURIT¥-RELATED INFORMATION - WITHHOLE> UNE>ER 16 OFR 2.996

SECURIT'f-REl:Al'EEJ INPO"MAl'ION - WITI lliOLEJ UNEJER 16 CFR 2.996 Nebraska Public Power District SL-01245O Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017

• Distribute the storm-area-averaged PMP over the drainage basin and develop precipitation depths for each storm area and 6-hour temporal distribution period (see Table 2.2-1 ). The 40% PMP storm event was then determined by multiplying the data in Table 2.2-1 by 0.4.

2.2.2 PMP Runoff Hydrographs A hydrologic model of the Missouri River extending from downstream of Gavins Point Dam to Kansas City, Missouri was originally developed by USAGE Omaha District (USAGE-OD, Reference 2.2-13) using HEC-HMS Version 3.5. This existing model was obtained and modified for this study to generate hydrographs from the basins upstream of CNS and downstream of Gavins Point Dam that contribute to the Missouri River PMF at CNS. The process used to develop the PMF hydrographs for the watersheds upstream of CNS includes the following:

• Review basin model configurations and parameterizations.

• Validate the reasonableness of the model at key locations for each basin.

• Determine the highest-computed PMF hydrograph at CNS based on hydrologic modeling.

2.2.2.1 Hydrologic Model Development The eight HEC-HMS models (one for each river basin depicted in Figure 2.2-2) received from USACE-OD used the following methods: Deficit and Constant loss, ModClark transform, Recession baseflow, and Muskingum-Cunge channel routing. A summary of model input parameter definitions and references are provided in Table 2.2-2. The analysis incorporated the Hierarchical Hazard Assessment (HHA) approach outlined in Section 2 of NUREG/CR-7046 (Reference 2.2-1 ). Consistent with the HHA approach, any adjustments to model input parameters were made globally conservative to the extent possible without increasing the level of detail of the model.

The USACE-OD basin model inputs were reviewed and verified by comparing the values with the corresponding range of values available in standard literature. The spatial distribution of the initial deficit, constant loss rate, and maximum deficit values were evaluated by creating a map of the basin and examining the variation in values across the basin model as compared to hydrologic soil group. In addition, the loss and transform parameters were verified for a typical subbasin within each basin or major tributary using values and equations found in the standard literature.

The United States Geological Survey (USGS) indicates that a small portion of each drainage area is non-contributing area; however, conservatively all areas were considered as contributing in the model.

The PMF is such an extreme event that normal drainage patterns may be altered; therefore, inclusion of the non-contributing drainage area would produce a conseNative estimate of the PMF hydrograph for CNS.

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8ECUftlT¥-RELATEEJ INFORMATION - WITH HOLE> UNf>ER 1e CFR 2.996

SECURIT'f-R:ELATED INI-OR:MATION - WITI II IOLB UNBER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD RHVALUATION Rl!PORT Project No.: 11784-01 7 2.2.2.2 Hydrologic Model Validation Daily stream flow data were used for upstream boundary conditions to validate model performance at key locations within the basin. Such data were obtained from the USGS and Nebraska Department of Natural Resources (NDNR} Websites (References 2.2-2 and 2.2-13, respectively).

To examine the reasonableness of the magnitude and timing of the peak flow and the volume of the hydrographs, the models were executed for the largest historic storm for which data were available and computed hydrographs were compared to stream gage values at the key locations within the basin. The selected storm was a 1984 storm for all basins except the Platte River basin, which used a 2010 storm.

The model hydrographs were compared to measured hydrographs by computing the Nash-Sutcliffe model efficiency coefficient (NSE). The NSE generally is used to assess the predictive power of a model's ability to reproduce observed data. NSE ranges between negative infinity and 1.0 (1 inclusive),

with NSE = 1 being the optimal value. Essentially, the closer the model efficiency is to 1, the more accurate the model. In addition to NSE, the Pearson correlation coefficient (r) was determined. The coefficient provides a measure of the linear relationship between two variables, in this case, measured and computed discharge. The models were considered validated when the modeled versus measured hydrograph NSE was greater than 0 and/or r was greater than 0.7, unless otherwise justified.

If required, model parameters were adjusted to obtain an acceptable fit to USGS hydrographs. Analysis showed that the basin response was most sensitive to the constant loss rate. Therefore, the constant loss rate was reduced in all models and other parameters were adjusted until a reasonable match to gage records was realized. An attempt was made to globally reduce all constant loss rates in the basin; however, it was found that reducing the constant loss rate variably within the basin provided the best fit for each gage location. Some of the reduced constant loss rates were lower than the recommended range listed in Table 11 of HEC-HMS Technical Reference Manual (Reference 2.2-4), but the modified rates are considered acceptable and produced more conservative model results. To match the baseflow and recession limb of the hydrograph, the recession constant and initial discharges were further adjusted. The computed hydrographs provided a relatively good fit to the measured values in terms of peak discharge, volume, and timing, especially for the magnitude of the historic storm used and the size and relative coarseness of the model.

2.2.2.3 PMF Hydrograph Determination The PMF hydrograph is a result of applying a PMP over a specific area and routing the resulting hydrographs to a point of interest, which is CNS. PMP positions (as discussed in Section 2.2.1, Figure 2.2-4) were executed using the validated model for the watersheds upstream of CNS and downstream of Gavins Point Dam. As discussed in Section 2.2.1.2, the 40% PMP value was considered as the antecedent or subsequent storm. According to ANSI/ANS-2.8-1992 (Reference 2.2-9}, a preceding storm usually is the more critical, but an alternative subsequent timing should also be investigated.

Therefore, in addition to the antecedent storm with the PMP, another simulation was performed with the PMP and the subsequent storm. This was done only for the position that resulted in the highest PMF at CNS to compare whether the antecedent or subsequent condition resulted in a higher peak. The sequential timing (3-day lag) was the same as the antecedent condition.

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SECURIT't'-RELATEE> INFORMATION * 'NITHHOLE> UNE>ER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION Rl!PORT Project No.: 11784-017 NUREG/CR-7046 (Reference 2.2-1), recommends increasing the unit hydrograph peak discharge by 5% to 20% and reducing the unit hydrograph Jag time by 33% to account for non-linearity effects during an extreme event such as the PMF. The HEC-HMS modeling framework in this analysis used the ModClark transform, which does not produce a unit hydrograph. Therefore, instead of increasing the peak discharge or reducing the lag time of a unit hydrograph, the time of concentration in all subbasins was reduced by 33% as a surrogate for reducing unit hydrograph lag time and the constant loss rate was reduced so that the peak discharge was increased from 5% to 20%.

ANSI/ANS-2.8-1992 (Reference 2.2-9) recommends mean monthly flow during the month of occurrence of the PMF to be used as the baseflow at the beginning of an antecedent storm. Where USGS gage data were available, the initial baseflow values of the subbasins draining to the gage locations were adjusted to match the maximum mean monthly flow during the months when the PMP will most likely occur. The initial baseflow values in subbasins for which no USGS gage data were available were not changed. The four PMP positions in this Midwestern part of the country will likely occur in the warmer months of the year. Typically, the highest mean monthly flows at the USGS gages used for this study occur in May, June, and July.

PMF hydrographs at Brownville, Nebraska for all four PMP positions with 40% antecedent storm are presented in Figure 2.2-5. Similarly, hydrographs with 40% subsequent PMP are shown in Figure 2.2-6.

Analysis results (Figure 2.2-5 and Figure 2.2-6) showed that the 40% PMP Position 3 (Figure 2.2-2, sheet c) followed by 3 days of no precipitation, followed by the PMP Position 3 (Figure 2.2-2, sheet c) resulted in the highest peak flow at CNS, which was considered as the controlling PMF hydrograph and was routed through the Missouri River using dynamic hydraulic modeling (as discussed in Section 2.2.3).

Position 1, centered over the Platte Basin and Loup River Basin (Figure 2.2-2, sheet a), resulted in the lowest peak PMF at CNS. This is due to the presence of sandy soils in the Loup Basin and the associated relative high constant loss rates compared to adjacent basins. Position 4 (Figure 2.2-2, sheet d), centered near CNS, resulted in the second lowest peak PMF at CNS. This is due to the storm being centered over the lower portion of the contributing basin at CNS, and thus not having the runoff volume necessary to produce a relatively large PMF. Position 2 (Figure 2.2-2, sheet b) generated the second highest peak PMF at CNS. The Platte River and Elkhorn River contributed most of the peak discharge.

Figure 2.2-5 shows that the PMP Position 3 hydrographs have a peak discharge of approximately 832,250 cubic feet per second (cf:S) at CNS. Figure 2.2-7 shows the location and RM of each junction that their outflow hydrographs from the hydrologic model were used as an input to the hydraulic simulation described in Section 2.2.3.

• 2.2.3 Water Level Determinations The hydraulic conditions in the Missouri River between Gavins Point Dam (approximate RM 810) and CNS during flood flows are complex due to the presence of revetment, river training structures, levees, roadway embankments, river meanders, and bridges. To evaluate this complexity, a multi-leveled modeling approach was adopted in this flood hazard reevaluation study. A 310-mile basin-scale one-Flooding in Streams and Rivers (PMF) 2-37 SECURIT'f-RELATEE> INFORMATION - WITHHOLE> UNE>ER 16 CFR 2.996

SECURITY-RELATEB INFORMATION - WITHHOLE> UNBER 16 CFR 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION Rl!PORT Project No.: 11784-017 dimensional (1-D) HEC-RAS unsteady model was used to predict the PMP hydrograph (as discussed in detail in Section 2.2.2) translation and attenuation in the Missouri River from Gavins Point Dam to CNS.

The results from the 1-D basin-scale routing model were then used as upstream boundary conditions for a reach-scale two-dimensional (2-D) hydraulic model. This reach-scale model, approximately 46 miles in length, was further used to predict the complicated interaction between the river channel and overbank areas that provides an estimate of flow distributions near CNS. The results from this 2-D reach-scale model were used to predict water surface elevations and velocities at CNS for the PMF.

2.2.3.1 One-Dimensional Steady-State Hydraulic Model In 2003, an unsteady model was developed and calibrated by the USACE-0O for the Upper Mississippi River System Flow Frequency Study {UMRSFFS), Reference 2.2-14. The Federal Emergency Management Agency (FEMA) regulatory model was developed in HEC-RAS by converting the UMRSFFS unsteady model to a steady-state model and then calibrated to the unsteady model 100-year flood event results (Reference 2.2-15). This model was obtained from FEMA and used for evaluatiqn of PMF at CNS. The model had undergone rigorous review prior to acceptance by FEMA.

The regulatory FEMA HEC-RAS steady-state model of the Missouri River was used to develop a 1-D HEC-RAS steady-state hydraulic model of the Missouri River for CNS PMF analysis that became the basis for the 1-D HEC-RAS unsteady model of the Missouri River (as discussed in Section 2.2.3.2).

The process used to develop the 1-0 steady-state hydraulic model from the regulatory FEMA model included:

• The hydraulic model cross sections were modified and updated with post 2011 flood bathymetric and Light Detection and Ranging (UDAR) survey data.

• Manning's roughness coefficients varied both horizontally and from cross section to cross section, but remained within the range of published values. In certain instances, Manning's roughness coefficients outside of the published ranges for overbank land uses were used to describe flow resistance from buildings or other overbank structures.

• The sensitivity of steady-state hydraulic results at the Missouri River near CNS (RM 532.35) was assessed with a discharge of 290,000 cfs by increasing and decreasing the Manning's roughness coefficients in the model domain by 10% and 20%. Analysis demonstrated that the model results were sensitive to Manning's roughness coefficients, which is consistent with guidance in NUREG/CR-7046, Section 5.4 (Reference 2.2-1 ). However, the majority of stage-discharge comparisons from this sensitivity analysis are within the 95% prediction interval.

• The sensitivity of steady-state hydraulic results for the Missouri River near CNS (RM 532.35) was assessed with a discharge of 290,000 cfs by increasing and decreasing the normal depth slope of the downstream boundary from 0.0001 to 0.0002 and 0.00005. The mean channel velocity and water surface elevation WSEL were identical between the three runs at this location. This indicates that the downstream boundary condition is located at an adequate distance downstream of CNS.

• The model was calibrated for 100-, 200-, 500-year, and 2011 flood events (Reference 2.2-14) to better replicate published stage-discharge relationships. The NRC, in NUREG/CR-7046, Section 5.5 (Reference 2.1 -1), prescribes validation of the Flooding in Streams and Rivers (PMF) , f'

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SECURIT¥-RELATED INFORMATION - Vt1ITlltt0LB UNDER 16 CFR 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Pmjecl No.: 11784-017 simulation models using the largest historical flood near the site. The 2011 flood event on the Missouri River resulted in the highest peaks within the modeled reach since 1952 (i.e., prior to construction of the five lower mainstem dams). Therefore, the measured data at USGS stream gages were considered the best available information because the data were collected during the 2011 flood event. The computed WSELs compared favorably to measured gage data and published flood insurance study (FIS) values for the 100-, 200-, and 500-year discharges within the modeled reach. In addition, the computed WSELs compared reasonably to measured values within the reach for the 2011 flood flows. Therefore, the model was considered cali brated for flows between the 100- and 500-year events (including the 2011 flood event) and, in accordance with NUREG/CR-7046, Section 5.5 (Reference 2.1-1 ). provides some assurance that the estimated design-basis floods will not be underestimated. In the calibrated HEC-RAS steady-state model, the channel Manning's roughness coefficients varied from 0.025 to 0.029 in the channel and generally from 0.020 to 0.120 in overbank areas.

2.2.3.2 , One-Dimensional Unsteady Hydraulic Model The 1-D steady-state hydraulic model of the Missouri River, as discussed in the previous section, was the primary data source for the HEC-RAS unsteady model. With the exception of modifications to the Manning's roughness coefficients, levee locations, and ineffective flow areas, the geometry from the steady-state model was used in the unsteady flow analysis. Figure 2.2-1 shows the extent of the modeled reach. The model was used to generate boundary conditions, including an upstream inflow hydrograph, upstream flow distributions, and a downstream stage hydrograph for a reach-scale unsteady 2-0 model of the Missouri River valley in the proximity of CNS. Specifically, this model predicted translation and attenuation of hydrographs that contribute to the PMF at CNS, considering inflows at Gavins Point Dam and tributaries throughout the modeled reach. The process used to develop the unsteady model included:

• Validate the HEC-RAS unsteady model with input and gage data from the 2011 flood event, making the necessary changes to replicate observed discharges, stages, and timing.

• Analyze PMF flaw scenarios using the HEC-RAS unsteady model.

• Establish inflow discharge hydrographs at RM 556.16 and outflow rating curve(s) at RM 510.03 to be used as boundary conditions for the unsteady 2-D model.

2.2.3.2.1 HEC-RAS Unsteady Model Development There are approximately 133.5 total miles of federal levees along the M issouri River. To address the uncertainty associated with predicting event routing through the modeled reach, some simplifying assumptions were made in order to develop a conservative estimate of flood translation and attenuation. Only federal levees were included in the model, which is consistent with the approach used by USAGE in the UMRSFFS (Reference 2.2-14). It is d ifficult to predict when, where, and how levee overtopping or breaching wiU occur over approximately 133.5 miles of levee using a 1-D unsteady model. Overtopping of the levee can be modeled considering levees as lateral weirs, but the assumption was made that the inclusion of lateral weirs was unnecessary to calculate a conservative Flooding in Streams and Rivers (PMF) 2-39 SECUR.I T¥-RELATED INFORMATION - WITHHOLD UNBER 18 efiR ! .996

SEOURIT¥-RELATED INFORM:ATION - 't'ilTHHOLD UNDER 16 CI-R 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-01 7 estimate of the hydrograph translation and attenuation throughout the system. Detailed hydraulic analysis in the vicinity of the site was performed using the reach-scale 2-D model. Therefore, two levee scenarios were evaluated for the unsteady analysis to "bookend" the boundary condition: complete levee failure (full floodplain) and the levees remain in place (levee-constrained).

Sensitivity of both upstream and downstream boundary locations of the 2-D model was tested by changing the Manning's roughness coefficient within a range of 20%. Analysis showed that PMF timing and magnitude at RM 556.16 (2-D model upstream boundary location) were not significantly sensitive to changes in Manning's roughness coefficient. The results demonstrated that the downstream boundary (at RM 510.03) of the 2-D model was sensitive to changes in Manning's roughness coefficient. This highlighted the importance of using Manning's roughness coefficients that had been validated.

In an unsteady simulation, non-conveyed volume would be temporarily stored in the overbank until the bank elevation is exceeded. Therefore, levee features were assigned to prevent water from being stored in the overbank until the channel bank elevation was exceeded. Aerial photography (Reference 2.2-16) was used to determine locations where flow was cut off by natural or man-made blockages.

A summary of the HEC-RAS unsteady computational model parameters are presented in Table 2.2-3.

2.2.3.2.2 HEC-RAS Unsteady Model Validation Several USGS stream gages are located within the modeled reach (Figure 2.2-1 ). Stage and discharge measurements recorded by USGS at these gage sites during the 2011 flood event were used to generate the inflow boundary conditions of 14 tributaries between RM 810 and RM 498. USAGE-reported daily discharges (Reference 2.2-17) at Gavins Point Dam were used to generate the inflow hydrograph at Gavins Point Dam for the validation event and to identify a discharge to be considered as a coincident flow with the PMF. The location of all inflow hydrographs pertaining to this evaluation are presented in Table 2.2-4.

The NSE was evaluated for the predicted stage and discharge hydrographs within the modeled reach (Reference 2.2-18). The HEC-RAS unsteady model was considered validated provided that:

• NSE for each flow hydrograph was greater than 0.90 of the value reported at the gage locations.

• Computed 2011 peak water surface elevations were within +/-1 foot of observed WSELs at gage locations.

• Any locations and/or instances that do not meet the above two criteria were justified based on levee breach location and chronology (Reference 2.2-19).

The model was executed using the same roughness coefficients used for the steady-state hydraulic model (Section 2.2.3.2). The flow hydrograph matched reasonably well; however, the stage hydrographs were systemically 1 to 2 ft low. Therefore, in an effort to produce a model that achieves better validation criteria, a simulation with a 10% global increase of Manning's roughness coefficient for Flooding in Streams and Rivers (PMF)

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SECURIT'l'-RELATEB INFORMATION - WITHHOLB UNBER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEV~LUATION REPORT Project No.: 11784-017 both the channel and overbank was executed. Table 2.2-5 shows the minimum and maximum roughness coefficients.

Graphical comparisons of observed and computed discharge hydrographs and stage measurements at

• the gage locations were evaluated. The timing and magnitude of predicted flow hydrographs for the 2011 event compared well with the recorded flow hydrograph. The summary of the NSE coefficient along with peak discharge and stage comparisons are shown in Table 2.2-6.

2.2.3.2.3 PMF Hydraulic Simulations The resultant tributary discharges from the final model using PMP Position 3, preceded by the 40%

PMP antecedent condition simulation (as discussed in Section 2.2.2) were used in the HEC-RAS unsteady model as lateral inflow discharges at tributary locations throughout the model. For smaller tributaries, contributing flows were aggregated and incorporated at a RM corresponding to the approximate inflow location, and were referred to as Missouri Basin Inflow. Table 2.2-7 summarizes the location of inflow hydrographs used in the model. Additionally, the downstream boundary condition of a normal-depth boundary with a slope of 0.0001 *was specified in the model based on sensitivity to validation results.

Two different releases from Gavins Point Dam were considered: the mean monthly average flow of 35,000 cfs and the release of the record flow (from the 2011 flood event, Reference 2.2-17) of 160,000 cfs. Additionally, as discussed in Section 2.2 .3.2.1, for each flow condition, two simplifying assumptions were made to provide conservative approximations of PMF translation and attenuation through leveed reaches: full floodplain and levee constrained.

The HEC-RAS unsteady model cross section at RM 556.16 was chosen as the upstream boundary condition of the 2-D model because it is located at a sufficient distance upstream of the point of interest (i.e., CNS) and a tie-back levee, as well as a major confluence (the Nishnabotna River).The downstream boundary condition of the reach-scale 2-D model was located at RM 510.03. This location is approximately 5 miles downstream of federal levee alignments and is in a relatively straight river reach 20 miles downstream of CNS. Analysis of results showed that the full-floodplain condition with 160,000 cfs at Gavins Point Dam results in the highest peak discharge and includes the most conservative Gavins Point Dam release. Therefore, this condition was used for the upstream inflow hydrograph for the 2-D model. The hydrographs, as they translate and attenuate throughout the modeled reach, are shown in Figure 2.2-8. The hydrographs at RM 556.16 are shown in Figure 2.2-9, and the peak magnitude and date are summarized in Table 2.2-8. The rating curves created from the HEC-RAS unsteady model results from both levee conditions were nearly identical, as shown in Figure 2 .2-10.

2.2.3.3 Two-Dimensional Reach-Scale Hydraulic Model The purpose of conducting a detailed 2-D hydraulic model of the Missouri River near CNS was to determine spatially and temporally varying information about water surface elevations, depths, and velocities at CNS during the PMF. Evaluation of site-specific erosion, sedimentation, and debris effects was also performed based on information available from the 2-D model. The modeled (i.e., 2-D) reach Flooding in Streams and Rivers (PMF) /

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SECURlf>f=RELATED INFORMATION - WITHHOLD UNDER 16 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11764-017 FLOOD HAZARD REEVALUATION Rl!PORT of the Missouri River extended from north of Hamburg, Iowa (approximate RM 556), to north of Craig, Missouri (approximate RM 510). An overview of the modeled reach is shown in Figure 2.2-11 . The process used to develop the 2-D model included:

• Developing the digital elevation model (DEM) surface roughness characteristics, appropriate computational mesh and description of levee crests, and boundary conditions from the 1-0 unsteady model, as discussed in Section 2 .2.3.2.1 .

• Validating the 2-D unsteady model with gage data and high-water marks (HWMs) from the 2011 flood event and making any changes necessary to replicate observed stages, as discussed in Section 2.2.3.2.2.

• Analyzing PMF flow scenarios using the 2-D numerical model TUFLOW FV, as discussed in Section 2.2.3.2.3.

2.2.3.3.1 2-0 Model Development TUFLOW FV, version 2013.02.056_dev (Reference 2.2-20), was used in this analysis to perform the 2-D hydraulic simulation. The model solves the Non-linear Shallow Water Equations (NLSWE) on a flexible mesh using a finite-volume numerical scheme. The model was not extended away from the Missouri River valley. Specifically, it did not include the Nishnabotna River valley in the model geometry. This eliminates potential storage for floodwaters during _ t he PMF, but the effect on peak WSELs at CNS is insignificant because the capacity of the Missouri River valley is large in comparison with the area extending north along the Nishnabotna River. Near the confluence of the Little Nemaha River and the Missouri River, the study area was extended west of the Missouri River valley approximately four miles. By extending the computational domain, the model was able to better calculate the flow distribution across the levees near the Little Nemaha, which is important for inundation at CNS. Major model inputs included digital elevation data, land cover/land use data, a computational mesh, levee crests, and boundary conditions, as described in the following paragraphs:

• Elevation Data: The elevation source for the model was based on the combination of the DEM used for the 1 D HEC-RAS steady-state model {Section 2.2.3.1), USGS LiDAR data, USAGE bathymetry data, USGS 10-m DEMs (Reference 2.2-21), and a site-specific survey.

• Surface Roughness: A combination of land cover/land use data {Figure 2.2-12) from three states, Iowa (Reference 2.2-22), Missouri (Reference 2.2-21 ), and Nebraska (Reference 2.2-23), were used to assign the appropriate Manning's roughness coefficient representing the surface roughness in the 2-D model.

• Computational Mesh: The study area was represented by a computational mesh (Figure 2.2-13 and Figure 2.2-14) containing 410,314 unstructured elements. The mesh was coarser in areas that were farther away from CNS and finer in areas where more detail is required. Buildings at the CNS site were represented by a void space in the computational mesh. The mesh sensitivity analysis demonstrated that changes in mesh size do not cause a large enough change in WSELs to warrant changes from the original mesh size chosen. Most variations were within 0.1 foot at CNS.

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• Levee Crests: Levee crests and roadway embankment elevations from the DEM were incorporated into the model. It was assumed that no levees, railroad embankments, or roadway embankments would be compromised during the PMF. The autoweir function of TU FLOW FV was used, which automatically applies the standard weir equation to embankments and other high points in the model topography. The weir coefficient was estimated to be on the order of 2.5 using Hager's equation (Reference 2.2-24). A sensitivity analysis was performed and as a result, a weir coefficient of 1.6 was used globally. This represents a conservative WSEL at CNS.

• Boundary Conditions: The location and type of the boundary conditions are shown in Figure 2.2-11. The 1-D unsteady HEC-RAS model (as described in Section 2.2.3.2.3) was used to establish the Missouri River boundary condition. The PMF hydrograph (Figure 2.2-9) was divided between within levee (referred to as main channel) and outside of levee discharges east of the main channel (referred to as left overbank).

La1eral inflows to the HEC-RAS model at RM 542.10 (Nishnabotna River), RM 535.30 (Honey Creek), and RM 527.8 (Little Nemaha River) were also included. The lateral inflows at RM 535.30 were included with the Missouri River overbank discharge because they represent a basin east of the Missouri River. The inflow hydrographs for each of the four boundaries are shown in Figure 2.2-1 5.

A normal-dep1h condition with a friction slope of 0.00022 was used at the downstream end of the model domain based on the geometry in the HEC-RAS unsteady model, which allowed for different main channel and overbank water surface elevations.

Sensitivity analyses were performed for both upstream and downstream boundary conditions. Results showed that WSEls at CNS were not sensitive to the upstream and downstream boundary condition.

2.2.3.3.2 2..() Model Validation The model was validated for the 2011 Missouri River flood event using the available <lischarge and water level data recorded at USGS gage sites as well as HWMs reported by USAGE after action report (Reference 2.2-19). Since several levee breaches were reported during the 2011 flood event, two different steady-state discharge and levee condition combinations were considered in the validation.

The first geometry considered levee breaches fully developed for L575 (RM 551 and RM 544) and L550 (RM 539 and RM 523), while the second geometry included only levee breaches fully developed for L575 and not L550. The simulation was conducted using steady-state discharge of 257,000 cfs and 207,000 cfs on the Missouri River for the first and second geometric conditions, respectively. The first case provided the highest discharge on the protected or land side of the levee, while the second case generated the highest discharge on the river side of the levee between RM 544 and RM 523.

Simulated WSELs in the channel and interior were on average 0.1 foot and 0.8 foot lower, respectively, than measured HWMs. Within the context of this validation, the model calculated 36,000 cfs Jess discharge in the left overbank than was measured on one day during the 2011 flood event, and discharge in the channel is overestimated. Overall, the model simulated flow distribution across the river valley reasonably well for a reach scale model.

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SECURIT¥-RELATEB INFORMATION - 't'YITHHOLB UNBER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 2.2.3.3.3 2-D Model Hydraulic Simulations The inflow hydrograph used for the Missouri River was the full floodplain routing of the PMF event with a coincident discharge of 160,000 cfs from Gavins Point Dam, as discussed in detail in Sections 2.2.3.2.3 and 2.2.3.3.1. Figure 2.2-16 shows hydrographs at four locations within the modeled reach. From the upstream end of the model to Hamburg, peak discharges increased due to lateral inflows from the Nishnabotna River. Between the Nishnabotna River and CNS, the peak discharge was attenuated due to storage in the left overbank. Downstream of CNS, peak discharges increased again due to lateral inflows from the Little Nemaha River. The peak PMF discharge at CNS was 797,600 cfs.

Most of the CNS main plant areas were not inundated during the PMF event. Figure 2.2-17 and Figure 2.2-18 present contour plots of the maximum WSEL. Model results showed that the peak WSEL In the main channel near the intake structure was 902.8 ft NAVD88. The peak WSEL at CNS, which occurs at the upstream side of the plant on the main channel side of the levee (see Point Bon Figure 2.2-18),

was 903.3 ft NAVD88. When WSELs in the right overbank peak, the model indicated shallow flooding with depths of 0.5 foot or less near the Security Building (see Point 3 in Figure 2.2-18).

Maximum water depths are shown in Figure 2.2-19 and Figure 2.2-20 and contours of maximum velocity magnitude are shown in Figure 2.2-21. Peak velocities were less than 0.5 fps across much of the site, with the highest velocities seen where the federal levees north of the site are overtopped.

Model results indicated that velocities in that area peak between 5 and 6 fps.

Water depths and velocities are further investigated at three critical locations, including the Intake Structure, Switchyard, and the Elevated Release Point (ERP). A summary of grade elevation, maximum WSEL, maximum velocity, and maximum depth are provided in Table 2.2-9.

2.2.4 Combined Effects Determination of the total water level at the CNS site with the consideration of wind and wave effects based on the predicted maximum still water level from the PMF (Section 2.2.3.3.3) at the Missouri River is described in the following sections.

2.2.4.1 Water Level at CNS with Wind Setup In accordance with the guidelines in ANSI/ANS-2.8-1992 (Reference 2.2-9), the maximum PMF level at the plant site needs to consider the wind setup and wave runup effect from the coincidental occurrence of a 2-year design wind event. The 2-year fastest annual mile wind speed at the site is 55 miles per hour (mph) at 30 ft above the ground based on Reference 2.2-9. The methodology outlined In Coastal Engineering Manual (Reference 2.2-25) was followed to convert the annual extreme-mile wind speed to a 1-hour duration wind speed and then to 10-, 15-, and 20-minute wind speed durations.

Wind-driven waves were calculated using the "Windspeed Adjustment and Wave Growth" module of the Automated Coastal Engineering System (ACES) in the Coastal Engineering Design & Analysis System (CEDAS) Version 4.03 (Reference 2.2-26). The ACES uses the wind fetch option, elevation of observed wind, observed wind speed, duration of observed wind, duration of final wind, latitude of Flooding In Streams and RiVers (PMF)

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SECURIT't'*RELA'fEB INp;QRMJ!!c'flON - Wl'fHHOLB UNBER 16 ep;R 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 observation, restricted fetch geometry, and average fetch depth as input The shallow restricted option was chosen because the waves are not expected to propagate under a deep-water condition for a significant duration and the fetch is not unlimited for wave formation. The fetch geometry was determined by extending lines at directional (radial angle) increments of 22.5 degrees from a representative point at the CNS site to the extent of the river cross sections in all directions as shown in Figure 2.2-22. The ACES analysis was completed for each fetch. ACES outputs were spectral significant wave height (Hmo) and peak wave period (Tp). Wave characteristics were calculated using equations provided in Reference 2.2-27. Wind approaching along the longest and deepest fetch for each point of interest (Figure 2.2-23) was modeled in ACES to determine the controlling (maximum) significant wave height at each point In the case that the longest fetch was not the deepest, both the longest fetch and the deepest fetch were checked. The fetch with the larger wave height was then considered to be the controlling fetch.

Wind setup was calculated along the controlling fetch for each point of interest using Equation 4 of U.S.

Bureau of Reclamation ACER Technical Memorandum No. 2 (Reference 2.2-28). The calculated value was added to the PMF WSEL (described in Section 2.2.3.3.3) and the new WSEL was used for .

subsequent wave runup and associated effects calculations. Wind setup was not added to the PMF WSEL on the interior of the perimeter embankments because setup is not significant at these locations.

Equation 2-2 of EM 1110-2-1614 (Reference 2.2-29) was used to convert the spectral significant wave height (Hmo) to 1% wave height (H1%, the average of the highest 1% of waves). In accordance with ANSI/ANS-2 .8-1992 (Reference 2.2-9), H1-. was used as a design wave height for subsequent analyses.

A summary of ACES input and outputs along with wind setup and 1% wave height at six points of Interest are presented in Table 2.2-10. The largest wave height was calculated at point of interest West Embankment North (WEmbN, see Figure 2.2-23), with an H, 04 of 4.56 ft. Wave heights tended to be largest on the southern and western edges of the site due to the relatively longer and deeper fetches for waves to propagate to those points, whereas waves from the east are blocked by the federal levee.

2.2.4.2 Wave Runup lrbt3)~tilJSC §824o-1(d) ~

Locations of runup calculations for waves approaching the ,*,1141 1h1rl1t[) rom different directions are shown in Figure 2.2-24. Combinations of Coastal Engineering Manual (CEM) Chapter 6 (Reference 2.2-25) and FEMA guidelines (Reference 2.2-30) were used for wave run up calculations.

For conservatism, all reduction factors as well as the factor for influence of angle of incidence were set to 1, meaning no reduction. Design wave height (H,%) was used as wave input. For embankments located north and south of the Intake Structure, runup calculations showed that these embankments are overtopped. Therefore, Reference 2.2-30 was used to estimate the horizontal extent of runup. The extent of inundation is shown in Figure 2.2-25.

For WEmbN and North Embankment East (NEmbE) embankments (see Figure 2.2-23), the transmitted wave height was calculated using Equation Vl-5-54 of CEM (Reference 2.2-25). This was done because the wave is passing over other embankments to reach these two points of interest. Inputs included transmission coefficient (0.75), design wave height (H1%), median rock size, freeboard Flooding In Streams and Rivers (PMF) /

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SE6URIT'f-RELATEB INFORMATION - 1't1ITllltOLB UNDER 16 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 (negative for submerged embankment), and width of embankment crest. The minimum of transmitted wave height and breaker wave height (equal to 0.78 times design wave height [Hl'/41) was used for runup calculations of these two points. The results are summarized in Table 2.2-11.

Wave runup results are presented in Table 2.2-12. The wave runup from the west was calculated to be 1.4 ft, contributing to a maximum water level of 902.9 ft NAVD88. The runup produced from the plant west is not expected to reach the main critical building complex, as shown in the Figure 2.2-25. Runup from the plant north was calculated to be 0.5 foot, resulting in a maximum water level of 904.1 ft NAVD88. Topography indicates that CNS grounds in this area are below 904.1 ft NAVD88, further indicating that the buildings in this area would be exposed to runup from interior waves. Any interior protection provided to prevent exposure to wave runup from the north should extend to an elevation of at least 904.1 ft NAVD88 to provide protection to the Main Building Complex. While the farthest extent of the run up is expected to reach the Main Building Complex, it is expected to be minimal (on the order of inches). Reference 2.2-31 indicates that plant flood barriers extend to an elevation of 906 ft Plant Datum (906.37 ft NAVD88), which is high enough to provide adequate protection from the run up.

The vertical extent of runup on the Intake Structure was calculated to be 908.4 ft NAVD88, which is equivalent to a PMF WSEL of 903.0 ft NAVD88 plus 5.4 ft runup.

2.2.5 Associated Flooding Impacts 2.2.5.1 Overtopping Equation 11-4-28 of GEM (Reference 2.2-25) was used to estimate a theoretical wave runup at an unsubmerged embankment, identified as point of interest West Embankment South (WEmbS) in Figure 2.2-23. Inputs included design wave height (H 1%) at the embankment toe, peak wave period, embankment slope, embankment freeboard, and surface roughness reduction factor. Analysis showed that the theoretical runup is higher than the embankment height, confirming that the embankment is overtopped. Equation Vl-5-22 of CEM (Reference 2.2-25) was used to calculate the overtopping discharge at point of interest WEmbS. An overtopping discharge of 45 gallons per minute per linear foot was calculated at this location.

2.2.5.2 Erosion and Sedimentation The potential for erosion of the embankments due to wave action was assessed using erosion threshold guidance from the USAGE EROC/CHL TR-10-7 (Reference 2.2- 32). Inputs included a safety coefficient, grass quality factor, design wave height (H1-.), embankment slope, and duration of waves.

The potential maximum erosion depth was calculated to be 0.26 foot. This erosion depth was based on the wave exposure at WEmbN, which is the largest (most conservative) wave height as shown in Table 2.2-10.

2.2.5.3 Hydrodynamic Forces Hydrostatic and wave-induced hydrodynamic pressures and forces were calculated on the Intake Structure in accordance with the Goda pressure formula as described in GEM Table Vl-5-53 Flooding in Streams and Rivers (PMF) 2-46 SE6URITY-RELATEB INFORMATION - WITHHOLB UNt>Eft 16 efift 2.396

SECURITY-RELATED INfiOft:MAflON - 't'tlTHHOLD UNDEft: 16 CfiR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD Rlll!V.ALUATION REPORT Project No.: 11784-017 (Reference 2.2-25). Inputs included design wave height, wave length , water depth, and structure geometry. The largest wave heights are expected to impact the east face of the Intake Structure. For conservatism, pressure and force calculations were computed on the east face and treated as applicable on the north and south faces.

The Morison equation (Reference 2.2-27) was used to calculate the forces on the north wall of the Intake Structure due to a river current. Inputs included a drag coefficient, still water elevation, bottom elevation, water density, and current velocity. Outputs included the force per unit width of the north face wall of the Intake Structure.

Values for hydrostatic, wave-induced hydrodynamic, and current-induced hydrodynamic forces are listed in Table 2.2-13.

2.2.5.4 Debris and Impact Loads Review of possible flood debris items was undertaken to develop a spectra of flood debris sources. The following items were considered to represent a range of debris sources available upstream of CNS.

Two debris sources and masses were based on ASCE 7-10 {Reference 2.2-33) recommendations and the barge mass was based on typical barge sizes on the Missouri River. Additional vehicle and marine vessel masses were based on manufacturer data available on the Internet.

• ASCE 7-10 miscellaneous debris - 1 kip

• Large natural debris (ice, trees) - 4 kips

• Large vehicles and boats (tug boat, bus, mobile home) - 40 kips

• Tank-type debris (train cars, chemical tanks, semi trailers) - 100 kips

• Barge - 5,100 kips Flood debris impact loads were calculated for the first two debris objects using the methodology presented in Chapter CS of ASCE 7-10 (Reference 2.2-33), with the following considerations:

• Duration of impact load of 0.03 seconds was recommended based on Reference 2.2-33, Section C5.4.4, with the pulse shape taken as a half sine wave.

• Velocity of the debris was considered to be equal to the water velocity, which may differ for each debris type, depending on the expected debris path.

• Importance factor value of 1.3 for Risk Category IV was used (Reference 2.2-34, Section 4.2.8).

• Depth coefficient was selected from Table CS-2 of Reference 2.2-33.

• Orientation coefficient value of 0.80 was used, as recommended in Equation C-5 of Reference 2.2-33.

Flooding in Streams and Rivers (PMF) 2-47 SECURITV-"ELATED INFORM>\TION - WITIHIOLD UNDER 16 CFR 2.996

SECURITY-RELATEB INfiORMATION

• WITI IHOLB UNBER 18 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017

• Blockage coefficient from Table C5-3 of Reference 2.2-33, considering sheltering within 100 ft upstream was used.

• Dynamic load factor depends on the fundamental vibration period of the impacted structure, and the maximum value from Table C5-4 of Reference 2.2-33 was conservatively used.

Flood debris impact loads were calculated for the other larger size debris objects using the methodology presented in Section 3.14.8 of AASHTO (Reference 2.2-35). Equation 3.14.8-1 of Reference 2.2-35 is calibrated for impacts of large vessels, so its results for the Large Vehicles and Boats, Tank-Type Debris, and Barge sources are considered more applicable than the ASCE 7-10 (Reference 2.2-33) method.

Estimated debris impact loads due to PMF for different debris were determined using the methodologies identified above and based on channel and overbank velocities. A summary of impact load values is presented in Table 2.2-14. As shown in the table, a barge with the maximum channel velocityi(8.5 fps) will result in a maximum impact load of 3,332 kips.

2.2.6 References 2.2-1. Design-Basis Flood Estimation for Site Characterization at Nuclear Power Plants in the United States of America, NUREG/CR-7046, Office of Nuclear Regulatory Research, U.S. Nuclear Regulatory Commission, November 2011 .

2.2-2. United States Geological Survey (USGS), 2013, USGS National Water Information System (NWIS), Washington, D.C., accessed June 1, 2013, http://waterdata.usgs.gov/nwis/.

2.2-3. Missouri River Annex, 2011 , Mississippi River and Tributaries Waterways Action Plan.

2.2-4. U.S. Army Corps of Engineers (USACE). March 2000. Hydrologic Modeling System HEC-HMS Technical Reference Manual. U.S. Army Corps of Engineers, Hydrologic Engineering Center:

Davis, California.

2.2-5. U.S. Army Corps of Engineers (USACE). August 2010. Hydrologic Modeling System HEC-HMS Version 3.5. U.S. Army Corps of Engineers, Hydrologic Engineering Center: Davis, California.

2.2-6. U.S. Army Corps of Engineers (USACE). January 2010. River Analysis System HEC-RAS Version 4.1. USACE, Hydrologic Engineering Center, Davis, California.

2.2-7. United States Department of Agriculture, 2012. Geospatial Data Gateway. Website:

http://datagateway.nrcs.usda.gov/, accessed 12/14/2012. Washington, D.C.

2.2-8. ArcMap Version 10.2 (2013). ESRI, Redlands, CA.

2.2-9. American Nuclear Society, 1992, ANSI/ANS-2.8-1992: Determining Design Basis Flooding at Power Reactor Sites, American Nuclear Society Publishing, La Grange Park, IL.

Flooding in Streams and Rivers (PMF) ./

2-48 ( \.

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SECURITY-RELATEB INfiORMATION - WITI II IOLB UNBER 18 erR 2.996

SECURITY-ftELATEE> INFORMATION - 'tVITHHOLf> UNDER 16 CFR 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZARI> REEVALUATION REPORT 2.2-1 0. National Oceanic and Atmospheric Administration (NOAA). Atlas 14 Volume 8 Version 2, Precipitation-Frequency Atlas of the United States, Midwestern States, NOAA, National Weather Service, Silver Spring, MD.

2.2-11. NOAA, 1978. Hydrometeorological Report No. 51, Probable Maximum Precipitation Estimates, United States East of the 105th Meridian, U.S. Department of Commerce, NOAA, USACE, Washington, D.C.

2.2-12. NOAA, 1982, Hydrometeorological Report No. 52, Probable Maximum Precipitation Estimates, United States East of the 105th Meridian, U.S. Department of Commerce, NOAA, USAGE, Washington, D.C.

2.2-13. Nebraska Department of Natural Resources (NDNR), 2013, Department of Natural Resources Stream Gaging, accessed June 1, 2013. http://dnr.ne,gov/docs/hydrologic201 3.htmL 2.2-14. U.S. Army Corps of Engineers (USACE), November 2003, Upper Mississippi River System Flow Frequency Study: Hydraulics and Hydrology Appendix F, Missouri River, USAGE, Omaha District, Omaha, NE.

2.2-15. Federal Emergency Management Agency (FEMA). May 3, 2010. Flood Insurance Study; Douglas County, Nebraska and Incorporated Areas. Flood Insurance Study Number 31055CVOOOC. U.S. Department of Homeland Security, Washington, DC.

2.2-16. United States Geological Survey (USGS), 2013, USGS LandsatLook Viewer, Washington, o.c., accessed October 1, 2013. http://landsatlook,usgs.goyt.

2.2-17. U.S. Army Corps of Engineers (USACE), 2013, USAGE Northwestern Division MRR Daily River Bulletin, accessed September 1, 2013. http://www.nwd-mr.usace.armv.mil/rcc/.

2.2-18. Moriasi, D.N., J.G. Arnold, M.W. Van Liew, R.L. Bingner, R.D. Harmel, and T.L. Veith, 2007, "Model Evaluation Guidelines for Systematic Quantification of Accuracy in Watershed Simulations," Transactions of the ASABE 50(3): 885- 900, http:/fddr.nal.usda.gov/dspace/bitstream/10113/9298/1 /I ND44003774. pdf.

2.2-19. U.S. Army Corps of Engineers (USAGE), undated, After Action Report: Missouri River and Tributaries Flood of 2011, Received from John Remus, USACE, via e-mail on October 1, 2013.

2.2-20. BMT WBM, 2013, TUFLOW FV User Manual. Flexible Mesh Modeling, Version 2013.02.056_dev.

2.2-21 . University of Missouri, Columbia, 2013, Missouri Spatial Data Information Service, accessed October 10, 2013. ftp://www.cares.mlssouri.edu/pub/dem/.

2.2-22. Iowa Department of Natural Resources, 2013, Natural Resources Geographic Information Systems Library, accessed November 4, 2013. http://www.igsb.uiowa.edu/nrgislib:x/.

2.2-23. Multi-Resolution Land Characteristics Consortium, 2013, National Land Cover Database, accessed May 17, 2013. http://www.mrlc.gov/index.php.

Flooding in Streams and Rivers (PMF) .,~*,

2-49 Sar-g o ~ ~ Lundy 1 ,t-1

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SECURIT¥-RELATEf> INFORMATION - WITtil IOLD UNDER 16 CFR 2.996

SECURITY-RELATED INFORMATION - Vt'ITHHOLD UNDER 18 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD Rl!EVALUATION REPORT Protect No.: 11784-017 2.2-24. Hager, W.H., 1987. "Lateral Outflow Over Side Weirs." Journal of Hydraulic Engineering, ASCE, Vol. 113, No. 4, PP 491 -504.

2.2-25. U.S. Army Corps of Engineers (USAGE), 2008, Coastal Engineering Manual, EM 1110-2-1100, Washington, D.C. (in 6 volumes).

2.2-26. CEDAS-ACES Version 4.03 (2014), Veri-Tech, Vicksburg, MS.

2.2-27. Dean, R. and R. Dalrymple, 1991 , Water Wave Mechanics for Engineers and Scientists. World Scientific, Hackensack, NJ.

2.2-28. United States Bureau of Reclamation, 1981, Freeboard Criteria and Guidelines for Computing Freeboard Allowances for Storage Dams, ACER Technical Memorandum No. 2.

2.2-29. U.S. Army Corps of Engineers (USACE), 1995, Engineer Manual 1110-2-1614, Design of Coastal Revetments, Seawalls, and Bulkheads.

2.2-30. Federal Emergency Management Agency, 2007, Guidelines and Specifications for Flood Hazard Mapping Partners, Atlantic Ocean and Gulf of Mexico Coastal Guidelines Update, 360 p.

2.2-31. Nebraska Public Power District CNS Operations Manual, Maintenance Procedure 7.0.11, Rev. 29, "Flood Control Barriers."

2.2-32. U.S. Army Corps of Engineers (USACE), 2010, ERDC/CHL TR-10-7, Flood-Side Wave Erosion of Earthen Levees: Present State of Knowledge and Assessment of Armoring Necessity.

2.2-33. ASCE 7-10, "Minimum Design Loads for Buildings and Other Structures."

2.2-34. United States Nuclear Regulatory Commission (NRC), July 29, 2013, Guidance for Assessment of Flooding Hazards Due to Dam Failure, Japan Lessons-Learned Project Directorate JLD-ISG-2013-01.

2.2-35. AASHTO, "LRFD Bridge Design Specifications, "7th Edition.

2.2-36. U.S. Army Corps of Engineers (USACE), August 1994, EM 1110-2-1417 Flood Runoff Analysis, U.S. Army Corps of Engineers: Washington, D.C.

2.2-37. Natural Resources Conservation Service (NRCS) and United States Department of Agriculture (USDA), 2013, Soil Survey Geographic (SSURGO) Databases for Iowa, Kansas, Minnesota, Missouri, Nebraska, North Dakota, and South Dakota, accessed April 30, 2013.

http://soildatamart.nrcs.usda.gov.

Flooding in Streams and Rivers (PMF) 2-50 SECURITY-RELATED l,NFORMATION - Vt'ITI II tOLD UNDER 18 erR 2.998

SECURIT¥-RELATED INFORMATION - WITHHOLD UNDER 16 CFR 2.~S6 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No,: 11784-017 2.2-38. U.S. Department of Agriculture (USDA), June 1986, Technical Release 55.Urban Hydrology for Small Watersheds.

2.2-39. Natural Resources Conservation Service (NRCS), May 2010, National Engineering Handbook, Part 630 Hydrology.

2.2-40. Chow, V.T ., 1959, Open Channel Hydraulics, McGraw Hill.

~ ote: Reference 2,2-36 through Reference 2.2-40 are cited lo the tables that follow, Flooding in Streams and Rivers (PMF) 2-51 S~rgont &, Lundy~

SECURli"t'-RELATED INFORMATION - WITHHOLD UNDER 16 CF" 2.396

SECURITY-RELATEE> INFORMATION - WITltttOLE> UNE>ER 16 CFR 2.S96 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 2.2.7 Tables Tables associated with Section 2.2 are presented on the following pages.

Flooding in Streams and Rivers (PMFJ 2-52 SECURITY-ftELATEE> INFORMATION - WITltttOLD UNDER 18 CPR 2.S96

SECUR:IT'f-"ELATEE> INFORMATION - V'-tlTHHOLfl UNE>ER 16 CF~ 2.996 Nebraska Public Power District SL,01245O Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Table 2.2-1: Point 3 (shown in Figure 2.2-4) Adjusted Precipitation Depths Based on HMR 52 6-ht Increment 12 11 10 9 7 6 5 3 1 2 4 a Number 6-ht Time I 72 66 60 54 42 36 30 18 6 12 24 48 Period Time Period 0--6hr 6-12ht 12-18hr 18-24hr 24-30hr 30..J6hr 36--42hr 42-4Bhr 48-54hr 54-60hr 60-66hr 66*72hr lsohyet. (in)

A(10) 0.30 0.30 0.30 0.30 0.64 0.64 0.64 0.69 12.52 2.18 0.65 0.64 B (25) 0.30 0.30 0.30 0.30 0.64 0.64 0.64 0.69 11 .67 2.13 0.65 0,64 C (50) 0.30 0.30 0.30 0.30 0.64 0.64 0.64 0.68 10.87 2.08 0.65 0.64 D (100) 0.30 0.30 0.30 0.30 0.64 0.64 0.64 0.66 9.95 2.05 0.65 0.64 E (175) 0.30 0.30 0.30 0.30 0.64 0.64 0.64 0.67 ; 9.19 2.01 0.65 0.64 F (300) 0.30 0.30 0.30 0.30 0.64 0.64 0.64 0.67 8.43 1.88 0.65 0.64 G (450) 0.30 0.30 0.30 0.30 0.64 0.64 0.64 0.66 7.90 1.94 0.65 0.64 H (700) 0.30 0.30 0.30 0.30 0.64 0.64 0.64 0.66 7.26 1.91 0.65 0.64 I (1000) 0.30 0.30 0.30 0.30 0.64 0.64 0.64 0.66 6.74 1.88 0.65 0.64 J (1500) 0.30 0.30 0.30 0.30 0.64 0.64 0.64 0.66 6.18 1.86 0.65 0.64 K (2150) 0.30 0.30 0.30 0.30 0.64 0.64 0.64 0.65 5.70 1.82 0.65 0.64 L (3000) 0.30 0.30 0.30 0.30 0.64 0.64 0.64 0.65 5.26 1.80 0.65 0.64 M (4500) 0.30 0.30 0.30 0.30 0.64 0.64 0.64 0.65 4.69 1.77 0.65 0.64 N (6500) !l.30 0.30 0.3 0 0.30 D.64 0.64 0.64 0.64 4.17 1.73 0.65 0.64 0 (10000) 0.30 0.30 0.30 0.30 0.64 0.64 0.64 0.64 3.57 1.70 0.65 0.64 P (15000) 0.30 0.30 0.30 0.30 0.64 O.M 0.64 0.63 2.97 1.68 0.65 0.64 a (2soooJ 0.20 0.20 0.20 0.20 0.42 0.42 0.42 0.43 1.44 0.95 I 0.43 0.42 R (40000) 0.04 0.04 0.04 0.04 0.08 0.08 0.08 0.08 0.32 0.12 0.06 0.08 Flooding in Streams and Rivers (PMF) 2-53 SECU~IT,' -RELATEE> INFORMATION - V'flTHHOLB UNl:>E~ 16 CFP( 2.996

SECURIT¥*RELATEB INFORMATION - WITHHOLB UNBER 16 CFR 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 F LOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Table 2.2-2: Model Input Parameter Definitions and References Hydrologlc Parameter Definition Reference Drainage area Area that contributes to runoff. USGS gages and GIS tools Deficit and Constant Loss Parameters Initial deficit The amount of precipitation lost due to Table 6-1 of EM 1110-2-1417 interception and depression storage. (Reference 2.2-36), as referenced in HEC-HMS Technical Reference Manual (Reference 2.2-4)

Constant loss rate The* loss rate Is based on the maximum Table 11 of HEC-HMS Technical infiltration capacity of the soil. Reference Manual (Reference 2.2-4)

Maximum deficit The maximum amount of water that can be SSURGO GIS soil data available stored in the soil profile. water holding capacity (Reference 2.2-37)

Impervious surface The*percentage of the basin from which all Aerial photographs precipitation runs off.

ModClark Transform Parameters Time of concentration The time it takes flow to travel from the TR-55 method (Reference 2.2-38).

hydraulically most distant point to the watershed Slope was calculated using elevation outlet. and flowpath length values *taken from USGS topographic map; velocity for shallow concentrated flow was estimated using NEH-4 (Reference 2.2-39).

Storage coefficient An index of the temporary storage of runoff In HEC-HMS Technical Reference the watershed as it drains to the outlet point. Manual (Reference 2.2-4). lit is This parameter typically is based on gage data assumed that this value was adjusted and is adjusted during the calibration process. through calibration by USAGE.

Flooding in Streams and Rivers (PMF) , ,*

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SECURIT¥-RELATEB INFORMATION - WITHHOLB UNBER 16 CFR 2.396

SECUff:ITY-ff:ELATEB INFOff:MATION - 'l'ilTHHOLB UNBEff: 16 CPff: 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD R.EEVALUATION REPORT Project No.: 11784-017 Table 2.2-2: Model Input Parameter Definitions and References, continued Hydrologic Parameter Definition Reference Recession Baseflow Parameters Initial discharge Discharge at the start of the simulation. These USGS and NDNR gages values may be adjusted based on antecedent (Reference 2.2-2 and conditions. If gage data warrant. this is adjusted Reference 2.2-13,)

for historic storms. ANSI/ANS-2.8-1992 suggests use of mean monthly baseflow at the beginning of an antecedent storm, during the month of occurrence, for the PMF hydrograph analysis.

Baseflow recession Represents the decay of the baseflow. This Table 16 of HEC-HMS Technical constant parameter may be adjusted during the Reference Manual (Reference 2.2-4) calibration process.

Threshold type (ratio to User~efined threshold flow that defines the time HEC-HMS Technical Reference peak or threshold at which the recession model of HEC-HMS Manual (Reference 2.2-4) discharge) defines the total flow, expressed as either a flow rate or ratio to the computed peak. It was assumed that this value was adjusted through calibration by USACE.

Reservoir Parameters Stage-Discharge Function Stage-discharge relationship for the reservoir Provided by USACE outlet works.

Elevation-Storage Function Elevation-storage relationship of the reservoir. Provided by USACE Initial Elevation Initial elevation in the reservoir at the start of the Provided by USACE simulation.

Flooding in Streams and Rivers (PMF)

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SECUff:ITY-ff:ELATED INFORMATION - WITtllfOLB UNDER 18 CPR 2.998

SECURITY-RELATEB INf-ORMATION - WITI II IOLD UN BER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Table 2.2-3: Summary of Unsteady Computational Parameters Parameter Value nme step (minutes) 5 Theta (implicit weighting factor) 1.0 Water surface calculation tolerance (ft) 0.02 Maximum number of iterations 20 DSS messaging level 4 Maximum error in water surface solution (abort tolerance, ft) 100 Table 2.2-4: Location of Inflow Hydrographs Inflow Hydrograph (USGS Gage) lniflow River Mile <11 Gavins Point Dam 810.87 James River near Scotland, SD (06478500) 797.73 Vermillion River near Vermillion, SD (0647901 0) TT1 .90 Big Sioux River at Akron, IA (06485500) 734.00 Floyd River at James, IA (06600500) 730.95 Omaha Creek at Homer, NE (06601000) 719.62 Little Sioux River near Turin, IA (06607500) 669.23 Soldier River at Pisgah, IA (06608500) 664.00 Boyer River at Logan, IA (06609500) 635.22 Platte River at Louisville, NE (06805500) 594.82 Weeping Water Creek at Union, NE (06806500) 568.67 East Nishnabotna River at Riverton, IA (06809900) and 542.10 West Nishnabotna River near Riverton, IA (06808820)

Little Nemaha River at Auburn, NE (0681 1500) 527.80 Tarkio River at Fairfax, MO (06813000) 507.50 Note:

1. River Mile corresponding to location in HEC-RAS model.

Flooding In Streams and Rivers (PMF) 2-56 SECURIT¥-RELATEB INFORMATION - WITI II IOLD UNBER 18 CFR 2.998

SEeURPl"t' -R:ELATED INFORM>9cTION

• WITHHOLB UNBER 16 e1-R 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Table 2.2-5: Comparison of Manning's Roughness Coefficients used in the Model to Standard Values Channel Overbank Parameter Minimum Maximum Minimum Muimum Values from steady-state model 0.025 O.D29 0.020 0.120 Global 10% roughness increase 0.028 0.032 0.022 0.132 Values from Reference 2.2-40 0.016 0.060 0.011 I 0.160 Table 2.2-6: NSE Coefficient Summary and Peak Discharge Comparison for 2011 Validation Simulation Nash* Observed Predicted Observed Predicted Sutcliffe 2011 Peak Peak 2011 Peak Peak Stage Location Efficiency Discharge Discharge Stage (ft NAVD88)

Coofflclent (cfs) (cf11) (ft NAVD88)

USGS gage 06486000, Missouri River 1092.01 0.993 192,000 185,484 1092.74 at Sioux City, IA (RM 732.2)

USGS gage 06601200, Missouri River 0.993 191,000 186,390 1050.40 1049.78 at Decatur, NE (RM 691.0)

USGS gage 06610000, Missouri River 0.987 217,000 199,408 984.53 984.29 al Omaha, NE (RM 615.9)

USGS gage 06807000, Missouri Ri11er 933.14 0.981 229,000 227,608 933.B6 at Nebraska City, NE (RM 562.6)

USGS gage 06810070, Missouri Ri11er 272,000 904.82 903.51 0.941 233,089 at Brownville, NE (RM 535.3)

USGS gage 06813500, Missouri Ri11er 863.94 0943 328,000 234,043 863.87 at Ruic, NE (RM 498.0)

Flooding in Streams and Rivers (PMF) 2-57 sceUR:IT't'=RELATED INFORMATION - Yt'FfHHOLE> UNE>ER 16 eFfit 2.996

8ECURIT1f-RELATED INI-ORMATION - WITHHOLD UNDER 16 Cl-fit ! .396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Table 2.2-7: Inflow Hydrograph Location Summary for PMF Simulations Inflow Name Lateral Flow River Mile 11 >

Missouri Basin Tributary (21 808.26 Missouri Basin Tributary (21 807.02 James River 797.73 2

Missouri Ba~in Tributary ( J 796 30 Bow Creek <2l 787.75 Missouri Basin Tributary (2J 775.27 Vem,illion River 771.90 2

Missouri Basin Tributary < > 751.61 Aowa Creek C2> 745.19 2

Elk Creek < > 737.40 Big SiouX' River 734.00 Perry Creek 731 .76 Floyd River 730.95 Omaha Creek 719.62 12 Blackbird Creek > 697.41 Missouri Basin Tributary <2> 808.26 Missouri Basin Tributary 12> 807.02 James River 797.73 21 Missouri Basin Tributary ( 796.30 2

Bow Creek ( ) 787.75 Missouri Basin Tributary (21 775.27 Vermillion River 771 .90 Missouri Basin Tributary 12> 751 .61 Aowa Creek 121 745.19 Flooding in Streams and Rivers (PMF) 2-58 SECURITY-RELATED INFORMATION - WITIIIIOLD UNDER 18 CFR 2.998

SECURITY-RELATED INFORMATION - VtlTHHOLD UNDER 16 CFR 2.396 Nebraska Public Power District SL-01245O Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Table 2.2-7: Inflow Hydrograph Location Summary for PMF Simulations, continued Inflow Name Lateral Flow River Mile 111 Elk Creek IZl 737.40 Big Sioux River 734.00 Perry Creek 731.76 Floyd River 730.95 Omaha Creek 719.62 Blackbird Creek <2l 697.41 Missouri Basin Tributary l2) 691 .35 Little Sioux River 669.23 Tekamah Ditch <2> 664.16 Lower Soldier River 664.00 2

Missouri Basin Tributary < > 648.78 Boyer River 635.22 Pigeon Creek 12> 622.16 Missouri Basin Tributary 12> 616.48 Mosquito Creek 121 605.87 Platte River 594.82 Pony Creek and Keg Creek <2l 587.06 Plum Creek and Ervine Creek 12l 572.05 Missouri Basin Tributary 121 561.93 South Branch Weeping Water Creek 568.67 Nishnabotna River 542.10 Honey Creek <21 535.30 Little Nemaha River 527.S0 Tarkio River 507.50 Notes:

1. River Mile corresponding to location in HEC-RAS model.

2. These tributaries are not ~sled in Table 2.2-4 because they are subbasins within the Missouri River basin HMS model that do not have USGS stream gages.

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)/

SECURIT't'-RELATEB INFORMATION - Wll'tltlOLD UNE>ER 16 CFR 2.396

SECURITY-RELATED INFORMATION

• WITI II IOLD UNDER 18 eFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION R .l !PORT Project No.: 11784-017 Table 2.2-8: PMF Simulations Peak Magnitude and Time at RM 556.16 Peak Time-Peak Simulation Event Begins on 1/1 00:00 Discharge (cfs)

(date, hours : minutes)

PMF + 35,000 cfs at Gavins Point, full floodplain 522,400 1/1 0 22:00 PMF + 35,000 cfs at Gavins Point, levee constrained 546,700 1/10 15:00 PMF + 160,000 cfs at Gavins Point, full floodplain 731 ,200 1/1015:00 PMF + 160,000 cfs at Gavins Point, levee constrained 712,700 1/1011:00 Table 2.2-9: Monitoring Point Summary Maximum Maximum Grade Maximum Maximum Overland Channel Monitoring Point Elevation WSEL Depth Velocity Velocity (ft NAVD88) (ft NAVD88) (ft)

(fps) (fps)

1. Intake structure (north) 894.0 902.8 0.4 8.5 8.8

2. Intake structure (east) 880.0 902.8 2.0 8.5 22.8

3. Switchyard 896.6 901.5 0.5 N/A 4.9

4. ERP 892.6 902.8 0.2 N/A 10.2 Flooding In Streams and Rivers (PMF) 2-60 (\

y Surgc,nt & Lundy , , c SEeURITY-RELATEB INFORMATION - WITl-11 IOLB UNBER 18 eFR 2.396

SECURITY-RELATED INFORMATION - WITIIHOLB UNDER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Table 2.2-10: Calculat ion of Wi nd-Driven Waves and Wind Setup Approaching CNS Controlling Average Design Wind Point of Fetch Depth Fetch Length W ind Speed H,.o r. Wavelength Wind Setup H,,.

Interest Angle Along Speed Duration (ft) (s) (ft) (ft)

(ft)

(mph) (ft)

(deg) Fetch (ft) (min)

Intake 0 15.09 10466 46.8 10 2.16 2.68 36.4 0.21 3.61 structure NEmbE 0 14.33 12665 46.1 15 2.23 2.74 37.8 0.25 3.72 NEmbW 337.5 12.55 6220 -46.8 10 1.66 2.32 27.-4 0.15 2.77 SEmb 180 16.09 19525 45.6 20 2.72 3.07 -47.0 0.34 4 .5" WEmbN 180 16.23 19948 45.6 20 2.73 3.08 47.3 0.35 4.56 WEmbS 180 16.50 19311 45.6 20 2.71 3.06 46.8 0.33 4.53 Table 2.2-11 : Submerged Embankment Results Point of Freeboard, Including Transmission Transmitted Wave Maximum Interest Setup (ft) Coefficient Height (ft) Depth-Limited Wave (ft) 5.77 WEmbN -7.4 0.75 3.42 transmitted wave height acceptable 1.48 NEmbE -2.2 0.08 0.30 transmitted wave height acceptable Table 2.2-12: Wave Runup Approaching CNS Main Building Complex Point of Wave PMFWSEL Runup Vertlcal Runup Horizontal 1

Interest Runup (ft) (ft NAVD88) Extent (ft NAVD88) Extent (ft)

WEmbN 1.4 901.5 902.9 N/A NEmbE 0.5 903.6 904.1 N/A N of IS 4.9 903.0 N/A 103 S of IS 6.0 902.7 NIA 128 Note:

1. Wind setup is included in the PMF values listed for N of IS and S of IS. Wind setup was not Included In the PMF values listed for WEmbN and NEmbE due to the wave calculations being applied to a location that ls within the perimeter embankments where wind setup would be negligible.

Flooding In Streams and Rivers (PMF) 2-61 Sorga n ,: &,Lundy *'"

.~~*.

SECURIT11'*RELATED INFORMATION - W't11TI !HOLD UNDER 18 CFR 2.998

SECURIT¥=RELATED INFORMATION - WITI II IOLD UNDER 16 CFR 2.996 Nebras ka Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Table 2.2-13: Forces on Intake Structure Resultant Force Elevation Force Type (ft NAVD88) (lb per linear foot of wall)

Hydrostatic 869.6 78,312 Wave-induced 888.1 3,752 Current-induced 878.0 25 Table 2 .2-14: Debris Impact Loads Maximum Velocity Debris Source PMF (kip) 1000 lb miscellaneous debris 15.54 4000 lb large natural debris 62.15 Channel (8.5 fps) Large vehicles and boats 295.08 Tank-type debris 466.56 Barge 3332 1000 lb miscellaneous debris 3.66 4000 lb large natural debris 14.62 Overland (2.0 fps) Large vehicles and boats 69.43 Tank-type debris 109.78 Barge 784 Flooding in Streams and Rivers (PMF) 2-62 SECURIT't'-RELATED INFORMATION - WITI II IOLD UNDER 16 CFR 2.996

SECURIT¥-RELATEB INFORMA'flON - 'tVITI II IOLD UNBER 16 CFR 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11764-017 2.2.8 Figures Figures associated with Section 2.2 are presented on the following pages.

Flooding in Streams and Rivers (PMF) 2-63 SECUR:IT'f-RELATEB INFORMATION - WITI II IOLD UNDER 16 CFR 2.396

SECURIT¥*RELATEB INF6RMAT16N - WITHH6LB UNBER 16 CFft 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZARD REEVALUATION REPORT Figure 2.2*1 : Location Map e Rt.1800

+

+'° OlieOU)OO OmaNC,Nt<

AlllolNfNE RM700

+

OGGOl200 MeeounRNtt AIOec&MNE oa,oo,oo

~ R , ,..

Al LOOI" IA 06805500 Plane A,.,..

AHOUllv... NE 4'RM57' 0Geoe500

\"'-'OWlltWC,...,

AIU.-NE 0 USGS Gage 08807000 06810070 IMl,oon R,,,r A1 IMIIO<JIIRY111

+ Missouri River Mlle (1960) Ntbl-C<t,NE Al-~*~* NE Model Extent 06011500 L,m.-.R,vt1 Al ....llurn NE 06813000 FIS Counties T""'°Ri,tr N.Faoi!.. MO 0 25

• °:'~, 1,. ,.,.,

C1td*h bo urce, E.r1 0.'1.,.'11 111 1 N -l J f..,

f '" ..,o RM500 1'1'f' lij ui,t** *"t P c.1,, U[ICO uaoa , ~o N PI " "CA N G ** *

• u 1(1~ "I OIU H,l o,an1nc, ita, Wt '(

[1 11 J ec,111 M[TI E 1 t1 C t!I"* Hont Ko.-9 1 , _.1nt OpO l l"ld '"' 0 . . Wt'tr COfflf'"'" W' Flooding In Streams and Rivers (PMF) 2-64 SECURIT¥*RELATEO INF6RMil<TION - 1t'IITHH6LB UNBER 16 CFft 2.996

SECURITY-RELATEE> INFORMATION - WITI II IOLB UNBER 18 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 1178--4-017 Figure 2.2-2: PMP Position 1

• Sheet a (see subsequent Sheets b, c, and d for PMP Positions 2 to 4)

MINN!SO A G R E P L A Vermillion

.., River Basin

-- Missouri River Basin from Gav1ns Point to Sioux City I I\

Missouri River Basin from Omaha to Nebraska City

~ PMPStorm E l) M1ssour1 River Basin

~ Extent from Nebraska Ctty ,. **

to Kansas Cny T, f

• 1

• 0

---==:: :J*----

65 130

~,,,* :.

1 ti.:,. *

~------~

'l i*~ .~~~* C.t ar.90' o,,e,nic.* ~ ...... I , , .. , ...

C*"'ll!!llfl , ,

sc.: "r'-8"'~-,;;*

.. . c,un.,_:t:!'~*

Ul 11 ; *Ut l1-f :1,

!*: '!\c*;**:~,::

• • • nt -""°"* ...,. ....... IS ttr .. l u .,

Flooding in Streams and Rivers (PMF) 2-65 S..rgant: & Lundy

• SECURITY-RELATEE> INFORMATION - 't'IITI II IOLB UN BER 18 CFR 2.998

SECU"ITY-fitELATEO IN~OfitMATION - WITI II IOLD UNDER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784--017 Figure 2.2-2: PMP Position 2 (sheet b)

G p l R

A E

-* ,.w*r-~ 1

.., River Basin Missouri Basin from Point to s*

I ii\

A Missouri River Basin from Omaha to Nebraska C ity

,-,-,, PMP Storm [: D Missouri River Basin

~ Extent from Nebraska City to Kansas City 0 65 130 1

s.,!... '?'., ** c, d. '\**, .... ( * ""' ,. ... vu'b , ** , ... '"'*"****

Mies ltC*****t P . , , ca 0 US.t.'S f&O ilr,jp, '-IICAlll c. ........ tC. N .... 11 .. , . , Jf l o,.,. ... ,. 'SM v, ,~,, J*p,*tt *1111, l I '""II* H*f\11" flQI .,.. tr .. Cl'§. Uull Ce1111r1u ,1; Flooding In Str:eams and Rivers (PMF) 2-66 Sargnnt; &. Lundy SECURIT¥ -RELATED INFORM~TION - WITI II IOLD UNDER 16 CFR 2.996

SEeURITY*RELATEB INFORMATION - WITHHOLB UNBER 16 eFR 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 1178-4.017 Figure 2.2-2: PMP Position 3 (sheet c)

G R E P L A

• -- Missouri River Basin from Gavins

. ~

Point to Sioux City Missouri River Basin from Sioux City to Omaha A

Platte River Basin Missouri River Basin rrom Omaha to Nebraska City

~ PMPStorm E n Missouri River Basin from Nebraska City ., .,

L.....11 Extent to Kansas City 0 65 130 s.,!: ... 't., *. Ct*if,I s... ,

• t,, ~J~ .. ' A.l\tf(O ,,,.., * .., In.,...,.

MIies * , *

• 11 P .,,.

O,ll,. ft * ~**v ,

Ct acu U\C9 t AO l~o **,** M[,1 l ul lltiPS JIIQ~** c *

• e .. - IC"'t .,; .... ~ .., 'fl l!*n* t*fooc l.1Jn11 ,utd '"* C.I~ U**r c ** m ... ,,,

Flooding in Streams and Rivers (PMF) 2-67 Snro*ne& Luncfv SEeURITY-RELATEB INFORMATION - WITllltOLB UNBER 16 eFR 2.396

SEC! IRITY RELli\TliQ INPORMATION - WITI II IOLD UNDER 16 CFR 2.396 Nebraska Public Power District SL-01 2450 Cooper Nuclear Station Revision 1 FLOOD HAZARD R£EVALUATION REPORT Project No.: 117~-017 fi gure 2.2-2: PMP Position 4 (sheet d)

G R E P L A Vermillion River Basin

,\ti Missouri River J

• Basin from Gavms Point to Sioux City M1ssoun River Basin from Sioux City to Omaha I I\

A I Platte River Basin I Mi Basi 10

,.,..,, PMP Storm [ 1) Missouri River Basin

~ Extent from Nebraska City to Kansas City 0 65 130 "

Lt , tttt it!

~,,,,t,11, tJ1ty.,, ~t*41*1* ~owr t t ~ll('h l f""1* NAVlfG f .tt11110M l1t1*rl'l'lar,,

,., "", ,., P ro,11 n ra ca u-._c.c; rAn HP NR CA ~, r., a.,,_ 1r. N ti; ..... ,,., Nt Otdf\U'I. '""~" l " ' ' ' ' " " Ml 1 l. I I r.,-, .... IH0nQ K* ,.QI met nu* (,I\ Uu11 Cenmunltl' .,.

Flooding in Streams and Rivers (PMF) 2-68 Sargon,: & Lundy

• S!CU"IT't'-ftELATED INFORMATION - WITI ltfOLD UNDER 16 CFR 2.996

SECURIT¥-RELATEB INF6RMAT16N - WITHH6LB UNBER 16 CFR 2.S96 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZARD REEVALUATION REPORT Figure 2.2-3: Geographic Distribution of Basins of Influence for Missouri River Drainage above CNS M1nouri Rlwr above Fon Ped<

t>,1631q ml Y1llo-loM 70,0211q ml.

Mldclle Buln (Miuounl ~

'"**1*,q.m, l Lower 8a1ln (Fon Calhoun)- - ---1

~0.148-<<i, ml Gn,na Po,nl ~

Lo_, Buln (Cooper) 1,117 lq ml.

Flooding in Streams and Rivers (PMF) 2-69 SECURIT¥-RELATEB INF6RMATl6N - WITHH6LB UNBER 16 CFR 2.S96

SECURITY-RELATED INFORMATION - rt'rlTtfttOLD UNDER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Figure 2.2-4: PMP Spatial Distribution over Platte River Basin (P3 Centroid; 41 .35N, 96.20W)

w ott.

s 0

H L

p Q

~

R H IA

,.!!e-clt, Jl ,q $S u Flooding in Streams and Rivers (PMF) 2-70 SECURITY-RELATED INFORMATION

• WITI II IOLD UNDER 16 CFR 2.998

SECURITY-RELATEB INFORMATION - WITHHOLB UNBER 18 CFR ! .998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11764-017 Figure 2.2-5: Antecedent Final Model PMF Hydrographs for P1 , P2, P3, and P4 800000 I 02 700,000 ~

04 600,000 S00,000 ---------ti 300,000 1-----------H 200,000 I2 100,000 0

1/1/3000 o,oo I /6/3000 0 00 1/11/3000 OcOO I/16/3000 0;()0 1/21/3000 000 1/26/3000 0.00 1/31/3000 0 00 Date

- ruwl M ~ POitllQn 1 - r1N1Moc:t.ffto\1ll<Wll hn,11 Model POl,lt,on J - F""'I Model Po,,i,on 4

- PMI' "°"°" I t**I - P,_.P Pos,i,on 21.,) PMP Po,,1- l ton) -PMP Po\,l,on

• t**I M15soun River at Brownv1llt, N E Flooding In Strums

• nd Rivers (PMF}

2-71 SECURITY-RELATEB INFORMATION - 't't'ITI II IOLB UNBER 18 CFR 2.398

9ECURIT¥-RELATEB INFORMATION - WITHHOLB UN BER 18 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 1178-4--017 Figure 2.2-6 : Subsequent Storm Final Model PMF Hydrographs for P1, P2, PJ, and P4 0 .2 700.000 t---ttt--+--....-----tt---------------------------....--i 04 600.000 06 500.000 t - - -f f

' ?i i

~ 400.000

_______________________! ! 0.8 3"

.,: n

~ 300.000 I -------________,-t * ~

200.000 12 100,000 14 0

1/1/3000 0:00 1/6/3000 0 00 1/ 11/3000 0-00 1/16/3000 0'.00 1/21/3000 0-00 1/26/3000 0:00 1/31/3000 0;00 Date Missoun River at Brownville. NE Flooding In Streams and Rivers (PMF) 2-72 S..rga ne,.&Lundy

• SECURITV-RELATEB INFORMATION - 'NITI II IOLB UNBER 18 CFR 2.398

SECUftlTY-ftELATEB INFOftMATION * 't't,ITI It IOLB UNBEft 16 CFft 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 1178-4-017 Figure 2.2-7: Missouri River Junctions Flooding In Streams and Rivers (PMF) 2-73 SEOURIT,' -RELATED INFORM1'cTION - WITl-11-IOLD UNDER 16 CFft 2.996

SEOURITY-RELATEB INFORMATION - **'YITtttlOLB UNBER 18 OFR 2.398 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11764~17 Figure 2.2-8: Full Floodplain PMF Hydrographs for Gavins Point Release of 160,000 cfs 900000 160,000 ds at Gavins Point Full Floodplain

- ~xC,ty 100000 - Deutur

- ~*~

-Pt.;1l brnouth

- Nl>br**lt.tClty

- llrownvlll~

- RulO 200000 100000 L,,~...-----------------

l /l;/00000 l/ll/00 01)0 1/16/00 0-00 1/21/00 0.00 1/ 16/00 0 .00 I /31/00 0-00 2/5/00000 Flooding in Streams and Rivers (PMF) 2-74 Sarge"" & Lundy

• SECURITY-RELATEB INFORMATION - *t'YITtlllOLB UNBER 18 OFR 2.398

SECURIT¥-RELATED INFORMiltTION - WITt II IOLD UNDER 18 OFR 2.398 Nebraska Public Power District SL--012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZARD REEVALUATION REPORT Figure 2.2-9: PMF Hydrographs for 2-0 Model Upstream Boundary RM 556.16 800000 000 er, full Floodpl~., ~

000 ch l ~f> (Of\jltJlnN:i 700000 000 fSf ull floodpl~I~

- OOOcf~ lf'Vff Con\lrJ!Md 600000 sooooo i..

t" 400000 2

j

.300000 100000 l(X)()O()

0 1/1/lOOO 1/&/3000 1/ ll/3000 1/16/'JOOO 1/21/3000 1/16/1000 1/31/3000 Flooding In Streams and Rivers (PMF) 2-75 S..rguno: & Lundy SECURIT¥-RELATED INFORMiltTION - WITI II IOLD UNDER 18 CFR 2.998

SECURITY-RELATED INFORM]!(TION - WITI II IOLD UNDER 18 OFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No .: 1178--017 Figure 2.2-10: PMF Downstream Boundary Condition Rating Curve RM 510.03 River Missouri Reach 1 RS* 51003 seo--------------

RC

• CH~= 100 inlt 1 RC

• CHS_PMF. l&OFFP RC

• CNS PMF 3'ioL 87$

I RC

• CNS PMf 35___.

FFP J J 1$$1--~----------.------------.-------1 0 200000 AOOOOO eooooo 800000 1000000 Flooding In Streams and Rivers (PMF) 2-76 Snro*nt: & Lt..tndy "

SECURIT¥-RELATED INFORM1'TION - WITHHOLD UNDER 18 CFR 2.998

SECURIT¥*RELATEB INFORMATION - WITI II IOLB UNBER 16 CFR ! .996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT P101ect No.: 11784-017 Figure 2.2*11 : Study Area Overview for the 2*0 Model Flooding in Streams and Rivers (PMF}

2-77 Sargeant: & Lundy

• SECURIT't'-RELAl'Ef) INFORMATION - 'ft11TI II IOLB UNBER 16 CFR ! .996

SECURIT¥-RELATES INFORMATION - 't'IITHttOLS UNSER 16 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZAA.D R EEVALUATION R EPORT Project No.: 1178-4-017 Figure 2.2-12: Spatial Distribution of Land Use Classes to Determine Manning's Roughness Coeffic ients

- Open Water

- Wetland

- Forest

- Grassland

- RowCrops

- Urban

- Roads Flooding in Streams and Rivers (PMF) 2-78 Sarg11nt & Lundy SECURITY-RELATES INFORMATION - WITHHOLS UNSER 18 CFR 2.998

SECURITY-RELATED INFORMATION - WITI II IOLD UNDER 18 CFR 2.398 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-01 7 Figure 2.2-13: Computational Mesh Overview Floodin g In Streams and Rivers (PMF) 2-79 Snrg*MC & Lundy SECURITY-RELATED INFORMATION - WITI II IOLD UNDER 18 CFR 2.998

SECURIT¥=RELATEB INFORMATION - 'NITltltOLB UNBER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Pro1ect No.: 11784-017 Figure 2.2-14: Computational Mesh Near CNS Flooding In Streams and Rivers (PMF) 2-80 Sorg..nr: & Lundy SECURIT¥-RELATEB INFORMATION - WITHHOLB UNBER 16 CFR 2.996

SECURlfY-RELATEE> INFORMATION - WITI II IOLE> UNE>ER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVAI.UATION REPORT Project No.: 11784-017 Figure 2.2-15: 2-D Model Inflow Hydrographs 500.000 450,000 400,000 350,000 300,000 r 2so.000 -

M 1\>0\III lelt Ovtlb~1k M,s,ourl ~ ,n Ch.llllN'I i

0 -l1Ule N~m.il1' 200.000 - ~nabotna 150,000 100,000 50,000 0

0 so 100 150 200 250 300 Time (hour)

Flooding In Streams and Rivers (PMF) 2-81 Sorg-&Lundy SECURIT¥-RELATEE> INFORMATION - WITI II IOLD UNDER 16 CFR 2.996

SECURITY-RELATED INFORMATION - 't't~ITHHOLD UNDER 16 C~R 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD H AZARD R EEVALUATION R EPORT Project No.: 11784-017 Figure 2.2-16: Comparison of Disc harge Hydrographs through the Study Reac h 900,000 800,000 700,000 600,000

[ 500,000

..l' - U/S Modtl Boond.l1y (RM 556) 1i - HillllburB,IA(RM So!S) 2i 400,000 - CNS (RM 533)

- O/S ~ I Boundary (RM SI 0) 300,000 200,000 100,000 0

0 50 100 1SO 200 250 300 Time (hours)

Flooding in Streams and Rivers (PMF) 2-82 Sorganl: & Lundy

• SECURITY-RELATED INFORMATION - 'NITI II IOLD UNDER 18 CFR 2.998

SECURIT¥*RELATED INFORMATION - WITI II IOLD UNDER 18 CFR 2.398 Neb raska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD R .EEVALUATION REPORT Project No.: 1178'1-017 Figure 2.2-17 : Contours of Maximum Water Surface Elevation for PMF Event - Large Scale Flooding in Streams and Rivers (PMF) 2-83 G*rgeno:: & Lun dy SECURIT¥ -RELATED INFORMATION - WITI II IOLD UNDER 18 CFR 2.998

SECURIT¥*RELATED INFORMATION - WITHHOLB UNBER 16 CFR 2.996 Nebraska Public Power District SL-01 2450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 1178-1...()17 Figure 2.2-18: Contours of Maximum Water Surface Elevation for PMF Event - Small Sc ale Flooding in Streams and Rivers (PMF) 2-84 Sorgon t & Lundy SECURIT¥-RELATEO INFORMATION - WITI II IOLB UN BER 16 CFR 2.996

SECURIT¥-RELATED INFORMATION - WITHHOLE> UNE>ER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 1178'1-017 Figure 2.2-19: Contours of Maximum Depth for PMF Event* Overview Flooding in Streams and Rivers (PMF}

2-85 S.nrgor& & Lundy SECURITY-RELATEE> INFORM1'TION - \'VITI II IOLD UNDER 16 CFR 2.996

SECURIT¥-RELATEB INFORMATION - WITHHOLB UNBER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 1 178-017 Figure 2.2-20: Contours of Maximum Depth for PMF Event - Small Scale Flooding in Streams and Rivers (PMF) 2-86 B orgnnt) & Lundy SECURITV-RELAl'EB INFORMATION - WITI II IOLB UN BER 18 CFR 2.998

SECURIT¥*RELATED INFORMi!tTION - WITHHOtt, UNDER 16 CFR 2.396 Nebraska Pu blic Power District SL-01 2450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 1178-4-017 Figure 2.2-21 : Contours of Maximum Velocity for PMF Event - Small Scale Velocity (ft/s) 0 85 8

75 7

65 Flooding In Streams and Rivers {PMF) 2-87 Sorganc, Q Lundy SECURIT¥-RELATED INFORMATION - WITHHOLD UNDER 16 CFR 2.396

SECURITY-RELATEE> INFORMATION - WITHHOLE> UNE>ER 16 CFR 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 Figure 2.2-22: Fetches from Embankment Points of Interest Legend Fetches 0 Points or Interest

- 1 Ft Depth Contour

- Federal Levees Water Depth High : 63.3 ft NAVD88 Low : 0 ft NAVD88 Flooding in Streams and River s (PMF) 2-88 SECURIT't'-RELATEE> INFORM1'TION - WITI II IOLE> UNE>ER 16 CFR 2.996

SECURITY-RELATEB INFORMATION - WITI II IOLD UNDER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 1178-4-0 17 Figure 2.2-23: Labeled Points of Interest

= Perimeter Erroankmeot 0 Pocnts Of Interest Flooding in Streams and Rivers (PMF) 2-89 SECURITY-RELATED INFORMATION * 't'IITI II IOLD UNDER 16 CFR 2.996

SECURIT¥-RELATED INFORMATION - WITtttlOLB UNDER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 1178-4-017 (b)(3) 16USC §824o-1(d)

Figure 2.2-24: (b)(4) (b)(7)<F) 0w 00375

- 0075 0225 Flooding in Streams and Rivers (PMF) 2-90 Sur-gone & Luridy S,ECURIT¥-RELATEB INFORMATION - \\llTI II IOLD UNDER 16 CFR 2.996

SECURITY-RELATED INFORMATION - WITHHOLD UNDER 16 CFR 2.996 Nebraska Public Power District SL-01 2450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 117~ -017 Figure 2.2-25: Expected Maximum Extent of Wave Runup at Representative Locations (b)(3) 16 USC § u24o 1(d) (b1(4) b1(7 (f)

Flooding In Streams and Rivers (PMF}

2-91 S.rgant: Q Lundy 9ECURIT¥=RELATED INFORMATION - WITt It IOLD UNDER 18 CFR 2.998

9ECUfUfY-ftELATED INPOffMATION - WITHHOLD UNBEft 18 eFft 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZARD REEVALUATION REPORT 2.3 DAM BREACHES AND FAILURES The flooding reevaluation for Cooper Nuclear Station (CNS) adopted the approach and methodology for estimating the flood wave generated by upstream dam failure scenarios using the most current data available and the numerical modeling software Hydrologic Engineering Center-River Analysis System (HEC-RAS), Reference 2.3-1; Hydrologic Engineering Center-Hydrologic Modeling System (HEC-HMS), Reference 2.3-2, from the U.S. Army Corps of Engineers (USAGE); and TUFLOW FV Flexible Mesh Modeling, Reference 2.3-3, from BMT WBM. In particular, the CNS analysis fo!llows the guidance of ANSI/ANS 2.8-1992 (Reference 2.3-4) for the assessment of the potential dam failure modes and the specification of the antecedent and combined event conditions, consistent with the recommendations of NUREG/CR-7046 (Reference 2.3-5). The U.S. Nuclear Regulatory Commission (NRC) guidance on acceptable dam failure analysis methodologies is published as the Dam Failure lnteriim Staff Guidance (ISG) titled "Guidance for Assessment of Flooding Hazards Due to Dam Failure" (Reference 2.3-6), and was followed iri this assessment. The methodology prescribed in the Dam Failure ISG document was the basis of the reevaluation for flooding effects at CNS due to upstream dam failures.

The complexity of the Missouri River hydrologic condition along with System and Non-System dams is discussed in Section 2.2 of this report. The locations of all System dams and all Non-System dams in

~~~1~-~-~)~f~)-- - -tFh,~ ~!~~~~~i River watershed downstream of (4) (b)(?)(F) 2 1gure .3- .

I I

Dam and upstream of CNS are shown in As discussed in Section 2.8.5 of this report, the Bank Stabilization and Navigation Program (BSNP) was authorized under various Congressional acts since 1912. Fort Peck Dam was authorized under the Rivers and Harbors Act of 1935. The lower five dams (Garrison, Oahe, Big Bend, Fort Randall, and Gavins Point) were authorized under the Flood Control Act of 1944. Additional bank stabilization projects were authorized by various Flood Control Acts. Further stream bank erosion controls were authorized under the various Water Resourc.es Development Acts. The navigational channel project was declared officially finished in 1981 , with the terminus of the project at RM 734.8 at Sioux City, Iowa.

the USACE actively maintains the channel. It is unknown whether the USACE plans to* revise channel maintenance procedures or the System dams.

Following the guidance of ANSI/ANS-2.8-1992 (Reference 2.3-4), the combined effects of wind setup anq wave runup for a two-year design wind speed occurring coincidently with the maximum still water level as a result of the postulated upstream dam breach scenario were analyzed specifically for CNS Main Building facilities and Intake Structure.

As specified in the Dam Failure ISG , a large number of the dams in the watershed may have no impact on flooding at a site due to a combination of small dam size or large distance from the site. The Dam Failure ISG defines "inconsequential dams" as those dams that can be removed from consideration without analysis because they meet the criteria of having minimal or no adverse failure consequences beyond the dam owner's property. The Dam Failure ISG further suggests a second screening analysis for all dams that remain after removing the inconsequential dams, using several simplified modeling approaches for identifying dams whose failure would likely have negligible impacts on flooding at a nuclear power plant. Such dams are termed "noncritical dams." After the second screening, all Dam Breaches and Failures 2-92 ((

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SEeURITY-ftELATEB INFORMATION - WITHHOLB UN BER 18 eFft 2.998

9ECURIT¥*RELATEB INp;QRMATION - WITI IHOLB UN BER 16 ep;R 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 remaining dams are considered "potentially critical dams," and detailed analyses are required to assess these potentially critical dams to show which are truly critical to the flood hazard estimates at the CNS site. The potentially critical dams that are not shown to be critical through detailed analyses are assigned to the "noncritical dams* category. The Dam Failure ISG specifies that the cumulative effect of all noncritical dams should be carried forward and added to refined estimates for the critical dams. A screening-level analysis was performed to identify dams whose failure will have no impact to the CNS site.

The six System dams that are upstream of the CNS site on the mainstem of the Missouri River are critical dams. The salient features of these dams are presented in Table 2.3-1 from the Master Manual of Missouri River Mainstem Reservoirs (Reference 2.3-7). In addition to the information shown, more critical data related to each dam and its operations are required to erform the detailed u stream dam failures anal sis for these S stem dams l> (J) 16 USC § 8240 l(dl (b)(4) (l>)(7XF) ese resu ts were used to determine an overall dam failure flood hazard water surface elevation (WSEL) at the CNS site. The main steps followed for the upstream dam failures (combined System and Non-System dams) related to the CNS site are as follows:

• (0)(J)1oUSL; §8>4o1(<l) (l>)\4 1D)(/),,f)

Dam Breaches and Failures 2-93 SECURIT¥-RELATEB INf-ORMATION - WITHHOLB UN BER 16 Cf-R 2.996

SECURIT¥-RELATED INFORM311cTION - WITI II IOLD UNDER 18 OFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZA.RD R.ll'!VALUATION REPORT Project No.: 11784-017 (b)(3) 16 USC § 8240 l(d) !b)(4) (b) 7)\FJ Data used for the evaluation in this section include all dams located within the Missouri River Basin, downstream of Gavins Point Dam and upstream of the CNS site, as maintained in either federal or state inventories. The USACE National Inventory of Dams (NID) database (Reference 2.3-8) was queried for those states encompassed within the Missouri River Basin downstream of Gavins Point Dam and upstream of the CNS site. The states within the study area are Colorado, Iowa, Minnesota, Nebraska, North Dakota, South Dakota, and \Nyoming. The NID database does not publish dam hazard classification; dam inventories maintained by each state's respective dam safety agency or state*

engineer's office contain these hazard classifications. Therefore, additional dam inventory data were obtained directly from relevant state agencies.

The 3,327 remaining dams after screening the inconsequential dams from the total Non-System dam list within the Missouri River Basin downstream of Gavins Point Dam and upstream of the CNS site are shown in Figure 2.3-2. In accordance with NUREG/CR-7046 (Reference 2.3-5) and Dam Failure ISG (Reference 2.3-6), the effort for evaluating the flood levels occurring due to dam failure was reduced by grouping dams together and representing them as hypothetical dams. Altogether, 49 hypothetical dams on different tributaries entering the Missouri River or the Platte River were considered. Dam break parameters of each hypothetical dam are presented jn Table 2.3-2.

2.3.1 Flood Protection Level at the CNS Site Maintenance Procedure 7 .0.11 of CNS Operations Manual (Reference 2.3-9) reports that flood barriers are designed for a river flood water elevation of 906.00 ft CNS Plant Datum (906.37 ft NAVD88).The conversion from CNS plant datum to NAVD88 datum is provided in Reference 2.3-10.

2.3.2 Hydrologic Evaluation 2.3.2.1 HEC-HMS Model Dam Breaches and Failures

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2-94 B arga~ & , Lundy *~ *

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9ECURIT¥-RELATEf> INFORMATION - WITHI IOLD UNDER 16 CFR 2.996

SECURIT¥-RELATED INFORMATION - WITI II IOLB UNBER 18 CFR 2.998 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZARD REEVALUATION REPORT (bJ(3}.16 USC § B24o-1(d}, (b)(4) (b}(7}(F}

2.3.2.2 Flow Hydrographs for Non-System Dams (b)(3) 16 USC § 824o-1(d). (b}(4) (b)(7}(F}

Dam Breaches and Failures 2-95 SECURIT¥=RELATEB INFORMATION - WITHHOLB UNBER 18 CFR 2.998

SECURIT¥-RELATED INFORMATION - WITHHOLB UNBER. 16 CFR. 2.396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 (b)(3) 16 U SC § 8240-1 (d) (b)(4) (b)(7)(F) 2.3.2.3 Base Flow Data (b)(3) 16 USC§ 8240 1(d), (b)(4) (b)(/)(r-)

Dam Breaches and Failures ,,,.

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SECUR.IT'l'-RELATEB INFOR.MATION ='IIITtit IOLD UNDER 18 CFR 2.996

8ECURIT't'-RELA'fEB INFORMATION

• V-tlTHHOLB UNBER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 Project No.: 11784-017 FLOOD HAZARD REEVALUATION Rl!PORT (b)(3) 16 U SC § tl24o 1(d) (b)(4) (b)(7)(F) 2.3.2.4 USACE Dam Failure Hydrographs The NRC transmitted the USAGE analyses results for all six System dams for hydrologic and sunny-day dam failure. The USAGE did not provide hydrographs resulting from seismic failure of the System dams because it concluded that the dams are seismically robust and not subject to failure during a seismic event. The USACE did not provide a descr,iption of its approach or assumptions used: however, the NRC confirmed that the detailed analyses performed by the USACE were in compliance with the Dam Failure ISG requirements. The USACE analysis of System dams included failure of Non-System dams upstream of Gavins Point Dam. The USACE provided hydrographs resulting from failures of the six System dams at a location immediately downstream of Gavins Point Dam. The USACE discharge hydrographs directly downstream of Gavins Point Dam were used for the combined System and Non-System dam failure analyses. Seven dam failure scenarios were selected for the combined System and Non-System dam failure analysis. These selections were based on bounding values of peak flow and timing to eak flow at the CNS plant site. The seven selected scenarios are listed below.

(b)(3) 16 USC

• 1.* ,,. . drolo ic Fail r : (bl( ) 1 U 5 § 8 o I ( ) ( ( ), ( )(7 ( )

§ 8240 1(d) (tlJ (4) (b)(7)(F) ( ( 1 s L 8240 1( (b) ( )( (r This scenario was se ec e ecause o I s 1g magn u e o pea ow.

~b~~l~~<~)~(~r*. . .2, .. [:J Sunny-Day Failure: This scenario was selected because of its high magnitude of peak flow. --- (b)(3) 16 USC § 8240 1 (4) (b)({)(r)

(~)(~) IO \Jr.le I b14o 1ltt}i (IJf : :... ***-~;- +*

• l l::lydrologic. pa.ffl:1red * .. *

• Us th d b 4 b 7 F The hydrologic failure

14) (b)(r)W) scenar ~ cted because of Its high magmtu e of pea flow. UE  : j results indicated

' that th (b)(3 1 sunny-day dam failure does not result in failure of *

• Dam downstream (b)( 3l 16 u 5 c

• • ' §8*24o*l(d) (b) so the sunny-day dam failure scenario is bounded by other events and was not (4) (b)(7)(FJ selected for detailed analysis.

. ***4;** f * ** * ** !Hydrotogic F.lauuce* I hi'L')cenario was selected because I .. JDamisthe (b)(3J 16 us c

................ closest upstream dam to * **** * * * * ****** JDam and would result in the snortest time to peak ai (~~~~~*))W\ (bl

( (lI c Dam of the upstream hydrologic failure scenarios.

§824o 1(d},(b) ,---- 3 16 S 5* ..........................

• _ .,...unny-Day Failure** This scenario was selected because '-*- - - ~ -loam is the I .. . . . . . . .... . *

(bl( ) u c

§8240°1(d) (b)

. . . . . . . .. ..~

• *. .. . . . e.a m damtol-** .. ***** IDam and _would resul~ in the shortest time to peak at (4) (b)(7)(r)

. . . . ..... . . **** ***

• Dam of the upstream sunny-d .

6;  :* *. . Hydro/ogicFailure+ I 4 is the rb)\J) 16 u 8 c § 824o- 1(dJ. (bl( l* (b)(T) The hydrologic failure scenario w~ d because of its high magnitude of peak flow. US~ suits

. . . . ....indicatedthatthe l=:__Jsunny-day dam failure does not result in failure of L=JJam . . . . . . . . t~~l;!~,S(~)

(4) (b)(?)(F)

Dam Breaches and Failures 2-97 S a rgorl~ &: Luncty'~ "

SECURIT'f -R:ELATEB INFORMATION - WITHHOLD UNDER: 18 Cfi" 2.396

SECURITY-RELATED INFORMATION - WITHHOLB UNDER 16 CPR ! .396 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 1

I downstream, so thet %=~1 ~ a sunny-day dam failure scenario is bounded by other events and was not selected for detailed analysis.

(b){3) 16 USC

§ 824o-1(dr(b)

• 7, 10X3) 16 us c § a2.io.11d !bx4I ,~ F H drolo ic Failure: While (b)(3) 16 USC § 824o-1(d). (b)(4). (b)(7)(F}

this scenano was see e o s ow a comparison e een (4), (b}(7)(F) pea ow an 1me o pea WI o her scenarios at the CNS site.

(b)(3l 16 u 5 c NoneoUbenam failure-hydrographs fo~ - - !Dam were consider,ed. The failure results for this

§ 824o-1(d},(b}

(4) (b)(7)(F) dam are not bounding in terms of flow magnitude or time to peak at the CNS site.

The seven dam failure scenarjos li~ ed above were selected for detailed hydraulic analysis. The dam (b)(3l 16 u 5 c Jailuiehydrog.raphs-at-1------* !Dam due to both hydrologic and sunny-day failures of the System

§ 824o-1{d} {b)

(4) (b)(7)(F) dams are presented in Figure 2.3-5 and Fi ure 2.3-6, respectively. The seven selected System dam failure hydrographs downstream of t h ) Dam used for the combined System dam and Non-System dam failure analysis are presen e m 1gure 2.3-7 .

.2.3.3 Hydraulic Evaluation A one-dimen~ D) HEC-RAS model of the Missouri River between I

• l oam * - .. .. ~b~~l~!(~ls(~l

~b~~l~~.(~)~(;} (approximateL=......J and Rulo, Nebraska (approximate RM 498) was developed for the PMF for the (4) (b)(7)(F)

(4). (b)(7)(F) CNS site, and it was modified and used to route the dam breach hydrographs and compute the peak WSEL at the CNS site due to upstream dam failures. The results from the 1-D basin-scale routing model were then used as upstream and downstream boundary conditions for a reach-scale two-dimensional (2-D) hydraulic model. In addition, the results of 1-D basin-scale hydraulic model were used to determine the travel time and Hooding duration. This reach-scale model, approximately 46 miles long, was further used to predict the complicated interaction between the river channel and overbank areas that provides an estimate of flow distributions near CNS. The results from this 2-D reach-scale model were used to predict water surface elevations (WSELs), depths, and velocities at CNS for the dam failure scenarios.

2.3.3.1 Route Dam Failure Hydrographs for Non-System Dams t,o CNS Site Using One-Dimensional HEC-RAS Model The HEC-RAS model with the full floodplain geometry was used for upstream dam failure evaluation.

Similar assumptions made for the model geometry for PMF were used. A summary of unsteady HEC-RAS model computational parameters is presented in Table 2.2-3 and Table 2.2-5. Initially, the Non-System dam failure analysis (peak flow estimated as 1.3 million cfs) was performed with no changes in the HEC-RAS model geometry. However consideriJ significant increases in the peak flow and volume (b)(3} 16Y SC _of the Syst.emd.amJallure._hydrographs (i ffs} compared to PMF runs, minor modifications 0

§ 8240- 1(dl {b) to the floodplain geometry were made to otam mod stability without compromising model

"' ,cu-,,,r, conservatism for the Non-System dam failure analysis.

Hydraulic Table Parameter (HTab) increments were increased by 10% and the number of points set to 100 at all cross sections to prevent the maximum discharge from exceeding the range of cross section HTabs. These HTab vertical increments ranged from 1.0 ft to 1.25 ft in the PMF HEC-RAS model, and ranged from 1.1 ft to 1.375 ft for dam break flood evaluation. All bridge features and cross sections Dam Breaches and Failures ,,,,./.-

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2-98 , '

Sargll?li.f ~.Lundy\~-:

SECURIT'i'*REL>\TED INFORMATION - WITHHOLB UNf>Eft f6 CFft 2.396

SECURITY-RELATEE> INFORMATION =WITI II IOLD UNDER 16 CPR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD REEVALUATION REPORT Project No.: 11784-017 upstream and downstream of the bridges were removed, which prevented water from being stored behind embankments, thus resulting In Jess attenuation and faster translation of hydrographs.

Evaluating the upper end of peak dam failure flows showed that removing bridges and cross sections

{when compared to simulations with bridges and sections included) did not have an effect on the peak WSEL or time to peak; however, this did improve model stability at bridge structure locations.

Sensitivity analyses were performed for the Non-System dam failure HEC-RAS model with both sets of geometries (with and without the changes described in paragraphs above) and found that the resulting WSELs differed only by a few tenths of a foot. For consistency, the same geometry with the above-described changes was used for Non-System dam failure analysis and combined System dam and Non-System dam failure analysis.

Figure 2.3-8 shows that the land use types are classified into nine broad categories over the model domain. Research provided by Chow (Reference 2.3-14) and Fread (Reference 2.3-15) indicates that when the channel banks are exceeded and shallow flow exists in the floodplain, the total resistance has a tendency to remain the same or increase, since the overbank roughness is generally higher than the channel roughness. However, as flow stages increase in the overbank, as occur especially in larger systems in the United States, the resistance effect can remain the same or slightly decrease. Based on graphical data provided by Chow and Fread showing Manning's roughness coefficient (also known as Manning's n) versus discharge on the Mississippi River, the Manning's roughness coefficient can remain the same or decrease up to 20% for stages above bankfull. On the Nishnabotna River, Chow provides tabular data that indicate Manning's roughness coefficient for a corn field would not decrease for depths greater than 4 feet (ft), while for a pasture, Manning's roughness coefficient could decrease approximately 20%. These data suggest that the reduction of Manning's roughness coefficient up to 20% may be appropriate for some land use coverage to account for depth of flow.

Because the expected depth of flow on the floodplain near the facility could exceed 30 ft, for purposes of dam failure modeling, the Manning's roughness coefficients were reduced 20% for the grassland, wetlands, and row crops land use areas within the modeled domain. Despite Chow's data, for conservatism, it was assumed that corn and other row crops would be flattened and/or uprooted at the depths expected during a dam failure flood event. Therefore, the roughness value for row crops was also decreased by 20%. Row crops occupy over 75% of the floodplain land use within the modeled domain (Figure 2.3-8). Roughness coefficients were not decreased for the open-water land use areas (channel and other water bodies) because the roughness would not change due to depth. It is also assumed that the forest or urban land obstructions would remain in place during a dam failure event, which would occupy the majority of the water column. Therefore, Manning's roughness coefficients for forested and urban areas were not decreased. However, Manning's roughness coefficients on the site were reduced since the buildings were explicitly represented. Based on values provided in Reference 2.3-14, and accounting for the presence of various concrete barriers and appurtenances, a value of 0.025 was selected for paved. In addition, the switchyard areas were assigned a value of 0.08 since there are numerous concrete foundations and metal structures consistent with treed areas.

Table 2.3-7 lists the Manning's roughness coefficient associated with each land use type used in the PMF, Non-system dam failure analysis and Combined System and Non-system Dam failure analysis.

Dam Breaches and Failures 2-99 SECURl'f'f-"l=LATEO INFORMA'flON - 't"ill'I fl fOLD UN BER 16 CFR 2.996

9ECURIT¥*RELATED INFORMATION - 'i'IITttHOLD UNDER 16 CFR 2.996 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 FLOOD HAZARD Rl!l!VALUATION REPORT Project No.: 11784-017 According to guidance from the Dam Failure ISG (Reference 2 .3-6), levees that provide flood protection for the plant site should be considered to fail when overtopped. Although there is no levee that protects the CNS site, there are levees on the left and right banks of the Missouri River in the vicinity of the site.

Consistent with this guidance for levees that protect the site, levees adjacent to the site would be considered to fail once overtopped. A full floodplain flow for the Non-System dam failure condition was considered as the WSEL would be near top of levee at the start of the simulation, which is the 500-year discharge in the Missouri River. Additional flows from the Non-System dam failure would provide enough discharge to overtop the levees early in the simulation. This consideration would have impact only on the rising limb of the dam breach hydrograph until the time that the levees overtop, and therefore, this condition was not expected to impact peak stage or discharge.

The 500-year flow from the USACE UMRSFFS report (Reference 2.3-12) was considered as the dam release from Gavins Point Dam for the Non-System dam failure analysis. The locations and peak inflows of the combined Non-System dam failure and 500-year flow hydrographs used in the model are summarized in Table 2.3-6. The peak computed WSEL at the CNS site was checked against the plant flood protection level to identify ~ny potentially,eritical dams that require evaluation with detailed , 1 methods.

Based on the Dam Failure ISG, as discussed in Section 2.3 of this report, the peak WSEL was calculated. In accordance with the Dam Failure ISG, the cumulative effects of the noncritical dams were carried forward and added to refined estimates for the critical dams. The stage and discharge hydrographs at the CNS site and the comparison between the peak of the stage hydrograph and the design flood protection level at the CNS site are presented in Figure 2 .3-9. The comparison of peak stage from hydrograph with CNS design flood protection level is presented in Table 2.3-8. The combined hypothetical dam failure hydrographs produce a peak stage of 903.09 ft NAVD88 at the CNS site, which is less than the existing plant flood protection level of 906.37 ft NAVD88; therefore, all Non-System dams below Gavins Point Dam and above the CNS site were classified as noncritical.

All HEC-RAS model simulations were executed and finished with stable and converged results.

2.3.3.2 Route Combined System and Non-System Dam Failure Hydrographs to the CNS Site Using One-Dimensional HEC-RAS Model (b)(3) 16 U.s C § tl24o-1(d) (b)(4) (b)(7)(F)

Dam Breaches and Failures .*,

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9ECURIT¥=RELATED INFORMATION

• WITI II IOLD UNDER 16 CFR 2.996

SECURIT'f-RELATEB INFORMATION - WITHHOLO UNOE" 16 CI-R 2.S96 Nebraska Public Power District SL-012450 Cooper Nuclear Station Revision 1 fLDOD HAZARD REEVALUATION REPORT Project No.: 11784-017 .

2.3.3.3 Water Level Magnitude and Timing Using One-Dimensional HEC-RAS Model (b)(3)16USL f I

§ 8240 1(dJ(b) Asdlscussecnn- s-ectRm- 2:3*:3-:-n ,r this report, alll..._ __,__,.,:,-,~ ams were found to be noncritical and

'~' " " "c, 1 7 the cumulative effect of these noncritical dams were carried forward and added to refined estimates for the critical dams.

The stage and discharge h~drographs at the CNS site from the seven! !dam failure scenarios ~b~~l-~~(~ls(~l (bX3l 16 u 8 c . .~ combined with I ] dam failure hydrographs are presented in Figure 2.3-1 O and Figure 2.3-11 , (4) (bJ(7)(F)

~::;(~t* 4 (b)t ! respectively, with the results tabulated in Table 2.3-9. As discussed in Section 2.3.1 of this report, CNS flood barriers provide protection for floo~ n elevation of 906.37 ft NAVD88. As shown Jn Table

~;~:.~:(~. 2.~..- .. . hydrologic failure scenario of D would result in the highest estimated peak stage r&~8 4¥a~"0 .*:ofl....._Jft NAVD88 at the CNS site. The Dam hydrologic failure scenario would result in (4), (b}(7)(Fi f l the ~J~~ aq;\~ ~f69f&Y'N1alt 1tfiBoTNS site, with an estimated peak stage of (7tt NAVD88 arriving .. __ (b)(3)_16 USC afte~ ~~ (

1 Jrom the start of the dam breach. The! -** IDam failure ~~l~it~

s~enario est~mat~d peak s~age was less th~n the ~lant Hood_protection level. The dam failure s~narjo ielci~¥~lCT !;(~

. S site having an estimated peak flood stage that.

• I ~8740 .1(d) (b)

( ( l 11:1 t § ,, 0 l(dl (bX l \b) drolo ic failure scenario, for which the estimated peak stage (4) (b)(7)(F)

~b~1l~~i~t(;l is fl NAVD88, arriving abou ( -'> 1b ~c 11c (t>) 1 *b l fter the dam breach. By default, (4) (b)(7)(F) HE - AS computes the flow distribution across t e cross section, divided Into left overbank, main channel, and right overbank (Reference 2.3-16).

2.3.3.4 Two-Dlmenslonal Hydraulic Model A detailed 2-D hydraulic model of the Missouri River near CNS was developed using TU FLOW FV software to evaluate the PMF at CNS. That model is described In detail in Sections 2.2.3.3.1 and 2.2.3.3.2. The modeled (i.e., 2-D) reach of the Missouri River extended from north of Hamburg, Iowa (approximate RM 556), to north of Craig, Missouri (approximate RM 510)- see Figure 2.3-12. The existing 2-D model was further revised to better address hydraulics of the study area during the dam failure event and used to determine spatially and temporally varying information about WSELs, depths, and velocities at CNS for the dam failure scenarios. Modifications to the original 2-0 PMF model are described in Sections 2.3.3.4.1 through 2.3.3.4.5 below. AU other parameters were kept unchanged.

The modified PMF TUFLOW model is referred to as the Dam Failure TUFLOW Model.

2.3.3.4.1 Study Area At the upstream boundary of the model (RM 556.16), the PMF model extended to levee R573 on the right overbank rather than the bluff. This approach simplified model setup and the upstream boundary condition sensitivity analysis, performed using the PMF model, and showed that flow distribution at the upstream boundary of the model did not affect the model results in the area of interest near CNS. For the dam failure model, the model was extended west at the upstream boundary to the Missouri River Dam Breaches and Failures 2-101 SECURIT'f-R!Ll<'fEfJ INflORMATION - WITHHOLB UNBER 16 Cf" 2.998

SECUFtlT'f ~FtELATEB INFOFtMATION

135,273.58 43.6 85 7.04 5.16 133.71 0.71 11.76 Table 2.3-15: Summary of Wind Setup, Wave Runup, and.Total Water Levels at SSCs Maximum Water Still Water Wind Wave Wind Level, including SSC Level Setup Runup Direction Setup and Runup (ft NAVD88) (ft) (ft)