Quad Cities, Unit 1, Core Operating Limits Report for Cycle 24

ML15084A108
Person / Time
Site:	Quad Cities
Issue date:	03/06/2015
From:	Darin S Exelon Generation Co
To:	Document Control Desk, Office of Nuclear Reactor Regulation
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SVP-1516
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fExeloGeneratSVP-1516Mwahd 06, 20M6U. s. Nudw Reg.aosy Comm nATTN: Ooomrwe Control Doakwaslotgko, D.C. 20655Quad Nudew Powr Stalo, Unk IRenewed Faity Operatin Licens No. OPR20Subjet Cwor Operating mts Repas for Quad Citie UnkIt Cycle 24Quad CWes Nuclw Power Sation Unt 1 weo utdown for Reuol Outage 23(01 R23) onMarch 1,2015. In aoodo wihTechnical SpecifIcano iScton 5.6.Sd, enclosed is theCoe Opwa Limbt Repr (COLR) for Ouad Ctm Unit 1 Cyde 24.Should you have any ques ons onengt letW, ple contact Mr. Waly J. Seck at(309) 227-28o0.Site Vime ProoidenOuad OWesNuclerPowwrStadoEnclosue:Core qOpeat Limit Repor for Quad Citie Unit I Cycle 24cc: Regional AcMalismretr -NRC Region IIINRC Senior Residmen Inspector -Qued CiieM Nudear Power StationA C)c IuV-EnclosureCore Operating Limits ReportforQuad Cities Unit 1 Cycle 24 COLR Quad Cities 1 Rev. 10Quad Cities Unit 1 Cycle 24Core Operating Limits ReportRevision 0Page 1 of 61 COLR Quad Cities 1 Rev. 10Table of ContentsPage1. Terms and Definitions .............................................................................................................................. 52. General Information ................................................................................................................................. 63. Average Planar Linear Heat Generation Rate .................................................................................... 74. Operating Lim it Minim um Critical Power Ratio ................................................................................. 464.1. Manual Flow Control MCPR Operating Lim its .......................................................................... 464.1.1. Power -Dependent MCPR Operating Lim it ................. , ............................................................. 464.1.2. Flow -Dependent MCPR Operating Limit ...................... .................................. .464.2. Scram Tim e ...................................................................................................................................... 474.3. Recirculation Pum p ASD Settings ........................................................................................ ............ 475. Linear Heat Generation Rate ................................................................................................................. 536. Control Rod Block Setpoints ................................................................................................................. 577. Stability Protection Setpoints .................................................................................................... : ............ 578. Modes of Operation ................................................................................................................................. 589. Methodology ......................................................................................................................................... 6010. References ........................................................................................................................................... 61Page 2 of 61 COLR Quad Cities 1 Rev. 10List of TablesPageTable 3-1 MAPLHGR SLO m ultiplier ..................................................................................................... 7Table 3-2 MAPLHGR for Lattices 101 and 108 ..................................................................................... 7Table 3-3 MAPLHGR for Lattice 129 .................................................................................................... 8Table 3-4 MAPLHGR for Lattices 130 and 131 ........................................... ......................................... 8Table 3-5 MAPLHGR for Lattices 132 and 133 .................................................................................. 9Table 3-6 MAPLHGR for Lattice 134 ............................ ............................ ....................9Table 3-7 MAPLHGR for Lattice 135....................... ....................................... 10Table 3-8 MAPLHGR for Lattice 136 .............................................. 11Table 3-9 MAPLHGR for Lattice 137 ........................................................................................................... 12Table 3-10 MAPLHGR for Lattice 138 .... ............................................................................................... 13Table 3-11 MAPLHGR for Lattice 139 ................................................................................................... 14Table 3-12 MAPLHGR for Lattice 140 ................................................................................................... 15Table 3-13 MAPLHGR for Lattice 141 ................................................................................................... 16Table 3-14 MAPLHGR for Lattice 142 ................................................................................................... 17Table 3-15 MAPLHGR for Lattice 143 ................................................................................................... 18Table 3-16 MAPLHGR for Lattice 144 ................................................................................................... 19Table 3-17 MAPLHGR for Lattice 145 ....................................................................................................... 20Table 3-18 MAPLHGR for Lattice 146 ................................................................................................. 21Table 3-19 MAPLHGR for Lattice 147 ................................................................................................. 22Table 3-20 MAPLHGR for Lattice 148 ................................................................................................. 23Table 3-21 MAPLHGR for Lattice 149 ................................................................................................. 24Table 3-22 MAPLHGR for Lattice 150 ................................................................................................. 25Table 3-23 MAPLHGR for Lattice 151 ................................................................................................... 26Table 3-24 MAPLHGR for Lattice 152 ................................................................................................. 27Table 3-25 MAPLHGR for Lattice 153 ................................................................................................. 27Table 3-26 MAPLHGR for Lattice 154 ................................................................................................. 28Table 3-27 MAPLHGR for Lattice 155 ................................................................................................. 28Table 3-28 MAPLHGR for Lattice 156 ................................................................................................. 29Table 3-29 MAPLHGR for Lattice 157 ................................................................................................. 29Table 3-30 MAPLHGR for Lattice 158 ....................................................................................................... 30Table 3-31 MAPLHGR for Lattice 159 ................................................................................................. 30Table 3-32 MAPLHGR for Lattice 160 ................................................................................................. 31Table 3-33 MAPLHGR for Lattice 161 .................................................................................................. 31Table 3-34 MAPLHGR for Lattice 162 ................................................................................................. 32Table 3-35 MAPLHGR for Lattice 163 ................................................................................................... 32Table 3-36 MAPLHGR for Lattice 164 ................................................................................................. 33Table 3-37 MAPLHGR for Lattice 165 ................................................................................................... 33Table 3-38 MAPLHGR for Lattice 166 ................................................................................................... 34Table 3-39 MAPLHGR for Lattice 167 ................................................................................................. 34Table 3-40 MAPLHGR for Lattice 168 ................................................................................................. 35Table 3-41 MAPLHGR for Lattice 169 ................................................................................................. 35Table 3-42 MAPLHGR for Lattice 170 ................................................................................................. 36Table 3-43 MAPLHGR for Lattice 171 ................................................................................................... 36Table 3-44 MAPLHGR for Lattice 172 ................................................................................................. 37Table 3-45 MAPLHGR for Lattice 173 ................................................................................................. 37Table 3-46 MAPLHGR for Lattice 174 ................................................................................................. 38Table 3-47 MAPLHGR for Lattice 175 ................................................................................................. 38Table 3-48 MAPLHGR for Lattice 176 ................................................................................................. 39Table 3-49 MAPLHGR for Lattice 177 ................................................................................................. 39Table 3-50 MAPLHGR for Lattice 178 ....................................................................................................... 40Table 3-51 MAPLHGR for Lattice 179 ................................................................................................. 40Table 3-52 MAPLHGR for Lattice 180 ................................................................................................. 41Table 3-53 MAPLHGR for Lattice 181 ................................................................................................... 41Table 3-54 MAPLHGR for Lattice 182 ................................................................................................. 42Table 3-55 MAPLHGR for Lattice 183 ................................................................................................. 42Table 3-56 MAPLHGR for Lattice 184 ................................................................................................. 43Page 3 of 61 COLR Quad Cities 1 Rev. 10Table 3-57 M APLHG R for Lattice 185 ........................................................................................................ 43Table 3-58 M APLHG R for Lattice 186 ................................................................................................... 44Table 3-59 M APLHG R for Lattice 187 ................................................................................................ 44Table 3-60 M APLHG R for Lattice 188 ................................................................................................... 45Table 3-61 M APLHG R for Lattice 189 .................................................................................................. 45T able 4-1 S cram T im es ............................................................................................................................. 47Table 4-2 MCPR TSSS Based Operating Limits -Nominal FWT and FWNTR ..................................... 48Table 4-3 MCPR ISS Based Operating Limits -Nominal FWT and FWTR ........................................ 49Table 4-4 MCPR NSS Based Operating Limits -Nominal FWT and FWTR .................... 49Table 4-5 MCPR(P) -Nom inal FW T ................................................................................ .................. 50Table 4-6 M C P R (P) -FW T R ...................................................................................................................... 51Table 4-7 MCPR(F) -DLO and SLO Operation ................................................................................... 52Table 5-1 LHGR Limits for Lattices 101, 108, 129, 130, 131,132, 133, 134, 135, 136, 137, 138, 139,140,141,142,143,144,145,146,147,148,149,150, and 151 ........................... 53Table 5-2 LHGR Limits for Lattices 152, 153, 154, 155, 163, 164, and 165 ........................................ 53Table 5-3 LHGR Lim its for Lattices 156, 157 and 158 ........................................................................... 53Table 5-4 LHGR Limits for Lattice 159,160, 161, and 162 .................. ....... ..... 54Table 5-5 LHGR Limits for Lattices 166, 167, 168, 169, and 170 ........................................................ 54Table 5-6 LHGR Limits for Lattices 181, 185, 186, 187, and .189 ........................................................ 54Table 5-7 LHGR Limits for Lattices 171,172,173, 174, 178,179, 180, 183, and 188 ........................ 54Table 5-8 LHGR Limits for Lattices 176, 177, and 184 ...................,................................... 55Table 5-9 LHGR Limits for Lattices 175 and 182 ............................................................ 55Table 5-10 Power-Dependent LHGR Multipliers .................. ......................................... 56Table 5-11 Flow-Dependent LHGR M ultipliers ................. ................................................................. 56Table 6-1 RBM Allowable Values ......................................................................7Table 7-1 OPRM PBDA Trip Settings ...... m ........................................ 57Table 8-1 Allowed Modes of Operation and EOOS Conditions............................. 58Table 8-2 Core Thermal Power Restriction for OOS Conditions ............................ 59Page 4 of 61 COLR Quad Cities 1 Rev. 101. Terms and DefinitionsASD Adjustable Speed DriveDEHC Digital electro-hydraulic controlDLO Dual loop operationEFPD Effective full power dayEFPH Effective full power hourEOC End of cycleEOOS Equipment out of serviceEOFPL End of full power lifeFWTR Feedwater temperature reductionFWT Feedwater temperature*GWd/MTU Gigawatt days per metric ton UraniumICF Increased core flowISS Intermediate scram speedkW/ft Kilowatt per footLHGR Linear heat generation rateLPRM Local power range monitorMAPLHGR Maximum average planar linear heat generation rateMCFL Maximum Combined Flow LimiterMCPR Minimum critical power ratioMCPR(F) Flow dependent MCPRMCPR(P) Power dependent MCPRMELLLA Maximum extended load line limit analysisMIb/hr Million pounds per hourMSIV Main steam isolation valveMWd/MTU Megawatt daysper metric ton uraniumMWt Megawatt thermalNRC Nuclear Regulatory CommissionNSS Nominal Scram SpeedOLMCPR Operating limit minimum critical power ratioOOS Out of serviceOPRM Oscillation power range monitorPBDA Period based detection algorithmPLUOOS Power load unbalance out of servicePCOOS Pressure controller out of serviceRBM Rod block monitorRWE Rod withdrawal errorSLMCPR Safety limit minimum critical power ratioSLO Single loop operationTBVOOS Turbine bypass valve out of serviceTBV Turbine bypass valveTCV Turbine control valveTIP Traversing Incore ProbeTMOL Thermal mechanical operating limitTSSS Technical Specification scram speedTSV Turbine stop valvePage 5 of 61 COLR Quad Cities 1 Rev. 102. General InformationLicensed rated thermal power is 2957 MWt. Rated core flow is 98 Mlb/hr. Operation up to 108% ratedflow is licensed for this cycle. For allowed operating regions, see plant power/flow map.The licensing analysis supports full power operation to EOFPL+25 EFPD (16797 MWd/MTU) andcoastdown to a power level of 70%, given all burnup limits are satisfied. (Reference 3)Power and flow-dependent limits are listed for various power and flow levels. Linear interpolation is to beused to find intermediate values.The power-dependent OLMCPR and OLMCPR multiplier, K(P), are independent of scram speed. TheMCPR(F) values are independent of scram speed and feedwater temperature.The power-dependent and flow-dependent LHGR multipliers are independent of scram speed andfeedwater temperature.Only MCPR operating limits vary with scram speed. All other thermal limits are applicable with NSS, ISS,or TSSS.For thermal limit monitoring above 100% rated core flow, the 100% core flow values can be used unlessotherwise indicated in the applicable table.Page 6 of 61 COLR Quad Cities 1 Rev. 103. Average Planar Linear Heat Generation RateTechnical Specification Sections 3.2.1 and 3.4.1Lattice-specific MAPLHGR values for DLO and all EOOS conditions except SLO are provided in Tables3-2 through 3-61. During single loop operation, these limits are multiplied by the EOOS multiplier listed inTable 3-1.The MAPLHGR values for the fresh fuel operating in Quad Cities 1 Cycle 24 are analyzed up to anaverage planar exposure of 36.0 GWd/MTU and are provided in Tables 3-43 through 3-61. TheMAPLHGR values for the fresh fuel natural uranium lattices are detailed in Table 3-2 and also have beenanalyzed to an average planar exposure of 36.0 GWd/MTU.Table 3-1 MAPLHGR SLO multiplier(References 5, 6, 7, and 8)EOOSCondition MultiplierSLO 0.86Table 3-2 MAPLHGR for Lattices 101 and 108(References 5 and 6)All BundlesLattices101: Opt2-BO.71108: Opt2-T0.71Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 7.5036.0 or 75.0* 7.50* The natural uranium lattices (Lattices 101 and 108) for the fresh fuel operating in Quad Cities 1 Cycle24 have MAPLHGR values evaluated to an average planar exposure of 36.0 GWd/MTU. The fresh fuelincludes bundle types: Opt2-4.03-16GZ8.00/5.50-2GZ5.50 (QM24), Opt2-4.03-14GZ8.00/5.50-2GZ5.50(QN24), and Opt2-4.16-12G6.00-2GZ6.00 (Q024). Lattices 101 and 108 for fuel initially loaded in QuadCities 1 Cycles 21, 22, and 23 have been evaluated to an average planar exposure of 75.0 GWd/MTU.Page 7 of 61 COLR Quad Cities 1 Rev. 10Table 3-3 MAPLHGR for Lattice 129(References 8 and 12)BundleOpt2-4.01-14GZ6.00 (QF21)Lattice129: Opt2-B4.40-14G6.00Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.015.0 9.2610.0 9.3215.0 9.4420.0 9.6224.0 9.6730.0 9.4658.0 9.4670.0 8.09Table 3-4 MAPLHGR for Lattices 130 and 131(References 8 and 12).BundleOpt2-4.01-14GZ6.00 (QF21)Lattices130: Opt2-BE4.50-14G6.00131: Opt2-M4.50-14G6.00Avg. Planar Exposure .DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.065.0 9.3210.0 9.4215.0 9.5720.0 9.7524.0 9.8030.0 9.5958.0 9.5970.0 8.22Page 8 of 61 COLR Quad Cities 1 Rev. 10Table 3-5 MAPLHGR for Lattices 132 and 133.(References 8 and 12)BundleOpt2-4.01-14GZ6.00 (QF21)Lattices132: Opt2-M E4.46-14G6.00133: Opt2-T4.48-12G6.00Avg. Plana., Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.245.0 9.5110.0 9.4815.0 9.7520.0 9.9524.0 9.9830.0 9.7858.0 9.7870.0 8.51Table 3-6 MAPLHGR for Lattice 134(References 7 and 11)* BundleOpt2-4.07-19GZ7.50/5.50 (QG22)Lattice134: Opt2-B4.49-! 9G7.50Avg. Planar Exposure ... DLO(GWVdITU) MAPLHGR (kW/ft)0.0 9.632.5 9.625.0.. 9.517.5 9.3510.0 9.2312.0 9.2015.0 9.3717.0 9.5120.0 9.7122.0 9.6824.0 9.6430.0 9.5536.0 9.4642.0 9.4450.0 9.4260.0 9.4462.0 9.4664.0 9.6672.0 9.84Page 9 of 61 COLR Quad Cities. 1 Rev. 10Table 3-7 MAPLHGR forLattice 135(References 7 and 11)'BundleOpt2-4.07-19GZ7.50/5.50 (QG22)Lattice135: Opt2-BE4.57-19G7.50Avg. Planar Exposure .DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.722.5 9.695.0 9.567.5 9.3810.0 9.2312.0 9.2515.0 9.4717.0 9.6120.0 9.8222.0 9.7624.0 9.7230.0 9.6336.0 9.5442.0 9.5150.0 9.5060.0 9.4862.0 9.5064.0 9.7072.0 9.89Page 10 of 61 COLR Quad Cities 1 Rev. 10Table 3-8 MAPLHGR for Lattice 136(References 7 and 11)BundleOpt2-4.07-19GZ7.50/5.50 (QG22)Lattice136: Opt2-M4.57-19G7.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.732.5 9.695.0 9.557.5 9.3710.0 9.2112.0 9.2415.0 9.4817.0 9.6320.0 9.8222.0 9.7624.0 9.7130.0 9.6236.0 9.5342.0 9.5150.0 9.4860.0 9.4662,0 9.4864.0 9.6972.0 9.89Page 11 of 61 COLR Quad Cities 1 Rev. 10Table 3-9 MAPLHGR for Lattice 137(References 7 and 11)BundleOpt2-4.07-19GZ7.50/5.50 (0G22)Lattice137: Opt2-M E4.53-19G7.50Avg. Planar Exposure DLO(GWdIMTU) MAPLHGR (kW/ft)0.0 '9.852.5 9.845.0 9.717.5 9.5410.0 9.3912.0 9.4115.0 9.6717.0 9.8720.0 9.9922.0 9.9524.0 9.9330.0 9.8436.0 9.7542.0 9.7250.0 9.6460.0 9.6562.0 9.6864.0 9.9072.0 10.16Page 12 of 61 COLR Quad Cities 1 Rev. 10Table 3-10 MAPLHGR for Lattice 138(References 7 and 11).BundleOpt2,4.07-19GZ7.50/5.50 (QG22)Lattice138: Opt2-T4.53-19G7.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.872.5 9.875.0 9.757.5 9.5610.0 9.4012.0 9.3915.0 9.6217.0 9.8620.0 9.9622.0 9.9324.0 9.9130.0 9.8236.0 9.7342.0 9.7150.0 9.6160.0 .9.6362.0 9.6664.0 9.8972.0 10.16Page 13 of 61 COLR Quad Cities 1 Rev. 10Table 3-11 MAPLHGR for Lattice 139(References 7 and 11)BundleOpt2-4.07-19GZ7.50/5.50 (QG22)Lattice139: Opt2-T4.53-19G5.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.962.5 9.925.0 9.747.5 9.5310.0 9.4912.0 9.6215.0 10.0817.0 10.0520.0 10.0322.0 10.0024.0 9.9830.0 9.8736.0 9.7842.0 9.7650.0 9.6860.0 9.6962.0 9.7264.0 9.9472.0 10.21Page 14 of 61 COLR Quad Cities 1 Rev. 10Table 3-12 MAPLHGR for Lattice 140(References 7 and 11)BundleOpt2-4.07-17GZ7.50/5.50 (QH22)Lattice140: Opt2-B4.49-17G7.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.602.5 9.685.0 9.687.5 9.5210.0 9.3512.0 9.2715.0 9.4117.0 9.5220.0 9.6822.0 9.6824.0 9.6530.0 9.5836.0 9.5042.0 9.4750.0 9.4560.0 9.4362.0 9.4564.0 9.6572.0 9.84Page 15 of 61 COLR Quad Cities 1 Rev. 10Table 3-13 MAPLHGR for Lattice 141(References 7 and 11)BundleOpt2-4.07-17GZ7.50/5.50 (0H22)Lattice141: Opt2-BE4.57-17G7.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.622.5 9.705.0 9.727.5 9.5310.0 9.3512.0 9.3215.0 9.5017.0 9.6120.0 9.7922.0 9.7624.0 9.7330.0 -9.6636.0 9.5842.0 9.5550.0 9.4960.0 9.4762.0 9.4964.0 9.7072.0 9.89Page 16 of 61 COLR Quad Cities 1 Rev. 10Table 3-14 MAPLHGR for Lattice 142(References 7 and 11)BundleOpt2-4.07-17GZ7.5015.50 (QH22)Lattice142: Opt2-M4.57-17G7.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHIGR (kW/ft)0.0 9.582.5 9.665.0 9.687.5 9.5310.0 9.34.12.0 9.3115.0 9.5017.0 9.6220.0 9.8022.0 9.7624.0 9.7330.0 9.65.36.0 9.5742.0 9.5450.0 9.4760.0 9.4662.0 9.4864.0 9.6972.0 9.90Page 17 of 61 COLR Quad Cities 1 Rev. 10Table 3-15 MAPLHGR for Lattice 143(References 7 and 11)BundleOpt2-4.07-17GZ7.50/5.50 (QH22)Lattice143: Opt2-ME4.53-17G7.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.752.5 9.855.0 9.887.5 9.7210.0 9.5312.0 9.4815.0 9.7017.0 9.8620.0 9.9822.0 9.9624.0 9.9630.0 9.8836.0 9.7942.0 9.7650.0 9.6260.0 9.6462.0 9.6764.0 9.9072.0 10.17Page 18 of 61 COLR Quad Cities 1 Rev. 10Table 3-16 MAPLHGR for Lattice 144(References 7 and 11)BundleOpt2-4.07-17GZ7.50/5.50 (QH22)Lattice144: OpM2-T4.53-17G7.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.832.5 9.925.0 9.957.5 9.7510.0 9.5412.0 9.4915.0 9.6717.0 9.8420.0 9.9622.0 9.9524.0 9.9430.0 9.8636.0 9.7842.0 9.7250.0 9.5960.0

• 9.6262.0 9.6564.0 9.8872.0 10.17Page 19 of 61 COLR Quad Cities 1 Rev. 10Table 3-17 MAPLHGR for Lattice 145(References 7 and 11)BundleOpt2-4.07-17GZ7.50/5.50 (0H22)Lattice145: Opt2-T4.53-17G5.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.872.5 9.975.0 9.947.5 9.6810.0 9.5612.0 9.6315.0 10.0417.0 10.0420.0 10.0422.0 10.0224.0 9.9930.0 9.8936.0 9.8142.0 9.7850.0 9.6660.0 9.6862.0 9.7264.0 9.9472.0 10.22Page 20 of 61 COLR Quad Cities 1 Rev. 10Table 3-18 MAPLHGR for Lattice 146(References 7 and 11)BundleOpt2-4.12-12G5.50-2GZ5.50 (Q122)Lattice146: Opt2-B4.54-14G5.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.222.5 9.355.0 9.427.5 9.4710.0 9.5012.0 9.5215.0 9.7017.0 9.7520.0 9.7522.0 9.7324.0 9.7130.0 9.6136.0 9.5342.0 9.4950.0 9.4960.0 9.5162.0 9.5264.0 9.7272.0 9.89Page 21 of 61 COLR Quad Cities 1 Rev. 10Table 3-19 MAPLHGR for Lattice 147(References 7 and 11)BundleOpt2-4.12-12G5.50-2GZ5.50 (Q122)Lattice147: Opt2-BE4.62-14G5.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.332.5 9.435.0 9.507.5 9.5410.0 9.5812.0 9.6015.0 9.8017.0 9.8420.0 9.8322.0 9.8124.0 9.7930.0 9.7036.0 9.6142.0 9.5750.0 9.5760.0 9.5562.0 9.5664.0 9.7672.0 9.95Page 22 of 61 COLR Quad Cities 1 Rev. 10Table 3-20 MAPLHGR for Lattice 148(References 7 and 11)BundleOpt2-4.12-12G5.50-2GZ5.50 (Q122)Lattice148: Opt2-M4.62-14G5.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.322.5 9.425.0 9.497.5 9.5310.0 9.5712.0 9.6115.0 9.7817.0 9.83-20.0 9.8322.0 9.8124.0 9.7830.0 9.69..36.0 9.6042.0 9.5750.0 9.5660.0 9.5362.0 9.55..64.0 9.7672.0 9.95Page 23 of 61 COLR Quad Cities 1 Rev. 10Table 3-21 MAPLHGR for Lattice 149(References 7 and 11)BundleOpt2-4.12-12G5.50-2GZ5.50 (0122)Lattice149: Opt2-ME4.58-14G5.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.512.5 9.615.0 9.697.5 9.7410.0 9.7912.0 9.8115.0 10.0117.0 10.0520.0 10.0622.0 10.0424.0 10.0130.0 9.9136.0 9.8342.0 9.8050.0 9.7260.0 9.7362.0 9.7564.0 9.9772.0 10.23Page 24 of 61 COLR Quad Cities 1 Rev. 10Table 3-22 MAPLHGR for Lattice 150(References 7 and 11)BundleOpt2-4.12-12G5.50-2GZ5.50 (0122)Lattice150: Opt2-T4.58-14G5.50Avg. Planar Exposure DLO(GWd/MTU) jMAPLHGR (kW/ft)0.0 9.542.5 9.645.0 9.727.5 9.7410.0 9.7412.0 9.7815.0 9.9917.0 10.0320.0 10.0522.0 10.0324.0 10.0030.0 9.9036.0 9.8142.0 9.7950.0 9.6960.0 9.7062.0 9.7364.0 9.9572.0 10.23Page 25 of 61 COLR Quad Cities 1 Rev. 10Table 3-23 MAPLHGR for Lattice 151(References 7 and 11)BundleOpt2-4.12-1 2G5.50-2GZ5.50 (Q122)Lattice151: Opt2-T4.60-12G5.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.772.5 9.845.0 9.867.5 9.8710.0 9.8812.0 9.9315.0 9.9917.0 10.0420.0 10.0622.0 10.0424.0 10.0130.0 9.9236.0 9.8342.0 9.80* 50.0 9.7160.0 9.7262.0

• 9.7564.0 9.9772.0 10.25Page 26 of 61 COLR Quad Citiesý 1 Rev. 10Table 3-24 MAPLHGR for Lattice 152(References 6 and 10)BundleOpt2-4.03-18GZ8.0016.00 (QJ23)Lattice152: Opt2-B4.29-18G8.00Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 8.912.5 9.195.0 9.227.5 9.3710.0 9.6712.0 9.7815.0 10.0017.0 10.0420.0 9.9722.0 9.8724.0 9.8730.0 9.7636.0 9.6342.0 9.5250.0 9.4260.0 9.5772.0 9.7675.0 9.57Table 3-25 MAPLHGR for Lattice 153(References 6 and 10)BundleOpt2-4.03-18GZ8.00/6.00 (QJ23)Lattice153: Opt2-B4.47-18G8.00Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 8.822.5 9.105.0 9.067.5 9.0110.0 9.1212.0 9.1515.0 9.2617.0 9.3420.0 9.4922.0 9.6024.0 9.6530.0 9.5636.0 9.5242.0 9.4850.0 9.5260.0 9.6772.0 9.7775.0 9.67Page 27 of 61 COLR Quad Cities 1 Rev. 10Table 3-26 MAPLHGR for Lattice 154(References 6 and 10)BundleOpt2-4.03-18GZ8.00/6.00 (QJ23)Lattice'154: Oot2-BE4.57-18G8.00Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 8.952.5 9.285.0 9.237.5 9.0310.0 9.1712.0 9.2215.0 9.3617.0 9.4420.0 9.6122.0 9.7224.0 9.7330.0 9.6536.0 9.6242.0 9.5550.0 9.5960.0 9.6472.0 9.9175.0 9.64Table 3-27 MAPLHGR for Lattice 155(References 6 and 10)BundleOpt2-4.03-18GZ8.00/6.00 (QJ23)Lattice155: Opt2-M4.57,18G8.00Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 8.932.5 9.285.0 9.247.5 9.0610.0 9.1912.0 9.2315.0 9.3617.0 9.4620.0 9.6322.0 9.7424.0 9.7330.0 9.6436.0 9.6142.0 9.5650.0 9.5860.0 9.6072.0 9.8775.0 9.60Page 28 of 61 COLR Quad Cities 1 Rev. 10Table 3-28 MAPLHGR for Lattice 156(References 6 and 10)' *BundleOpt2-4.03-18GZ8.00/6.00 (QJ23)Lattice156: Opt2-ME4.54-18G8.00Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.062.5 9.395.0 9.347.5 9.1710.0 9.3212.0 9.3815.0 9.5317.0 9.6320.0 9.9222.0 9.9624.0 9.8930.0 9.8436.0 9.7742.0 9.7350.0 9.6860.0 9.6672.0 10.2475.0 9.66Table 3-29 MAPLHGR for Lattice 157(References 6 and 10)BundleOpt2-4.03-18GZ8.00/6.00 (QJ23)Lattice157: Opt2-T4.54-18G8.00Avg. Planar Exposure J :: DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.102.5 9.425.0 9.317.5 9.1410.0 9.3012.0 9.3415.0 9.4817.0 9.5820.0 9.9222.0 9.9624.0 9.9030.0 9.8436.0 9.7842.0 9.7050.0 9.6660.0 9.6672.0 10.1675.0 9.66Page 29 of 61 COLR Quad Cities 1 Rev. 10Table 3-30 MAPLHGR for Lattice 158(References 6 and 10)BundleOpt2-4.03-18GZ8.00/6.00 (QJ23)Lattice158: ODt2-T4.55-16G6.00Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.512.5 9.815.0 9.727.5 9.5810.0 9.6712.0 9.6215.0 9.7917.0 10.0120.0 10.0522.0 10.0424.0 9.9930.0 9.9336.0 9.8742.0 9.8150.0 9.7160.0 9.7172.0 10.2275.0 9.71Table 3-31 MAPLHGR for Lattice 159(References 6 and 10)BundleOpt2-4.08-18GZ8.00/6.00 (QK23)Lattice159: Opt2-B4.36-18G8.00Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.772.5 9.985.0 9.867.5 9.7710.0 9.9112.0 9.9315.0 9.9517.0 9.9220.0 10.0922.0 10.0124.0 10.0030.0 9.8436.0 9.6942.0 9.5750.0 9.4660.0 9.5972.0 9.8175.0 9.59Page 30 of 61 COLR Quad Cities 1 Rev. 10Table 3-32 MAPLHGR for Lattice 160(References 6 and 10)BundleOpt2-4.08-18GZ8.00/6.00 (QK23)Lattice1 60: Oot2-B4.54-1RGS.00..... It-B .54-18G. 00..Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.822.5 10.045.0 9.917.5 9.7510.0 9.8612.0 9.8015.0 9.6017.0 9.4820.0 9.4622.0 9.4524.0 9.5030.0 9.6636.0 9.6542.0 9.5950.0 9.6060.0 9.7072.0 9.8575.0 9.70Table 3-33 MAPLHGR for Lattice 161(References6 and 10)BundleOpt2-4.08-18GZ8.00/6;00 (QK23)Lattice.161: Opt2-BE4.63-18G8.00Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.882.5 10.235.0 10.087.5 9.7910.0 9.9312.0 9.9415.0 9.6417.0 9.5220.0 9.5322.0 9.5424.0 9.6230.0 9.7836.0 9.7242.0 9.6750.0 9.6560.0 9.6672.0 9.9975.0 9.66Page 31 of 61 COLR Quad Cities 1 Rev. 10Table 3-34 MAPLHGR for Lattice 162(References 6 and 10)BundleOpt2-4.08-18GZ8.00/6.00 (QK23)Lattice162: Oot2-M4.63-1 8G8.00.....r 2 ..... .. ...... ..Avg. Planar Exposure .DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.852.5 10.215.0 10.017.5 9.7510.0 9.9112.0 9.9415.0 9.6317.0 9.5220.0 9.5522.0 9.5524.0 9.6330.0 9.7836.0 9.7542.0 9.6650.0 9.6160.0 9.5872.0 9.9175.0 9.58Table 3-35 MAPLHGR for Lzttice 163(References 6 and 10)BundleOpt2-4.08-18GZ8.00/6.00 (QK23)Lattice163: Opt2-ME4.60-18G8.00Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 10.022.5 10.355.0 10.237.5 9.9510.0 1 0.0912.0 10.0615.0 9.8617.0 9.7320.0 9.8022.0 9.8324.0 9.9530.0 9.9936.0 9.9542.0 9.8950.0 9.7360.0 9.6972.0 10.2375.0 9.69Page 32 of 61 COLR Quad Cities 1 Rev. 10Table 3-36 MAPLHGR for Lattice 164(References 6 and 10)BundleOpt2-4.08-18GZ8.00/6.00 (QK23)Lattice164: ODt2-T4.60-18G8.00Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 10.092.5 10.405.0 10.337.5 10.0410.0 10.1612.0 10.0515.0 9.8317.0 9.7220.0 9.7322.0 9.9024.0 9.9830.0 10.0136.0 9.9542.0 9.8850.0 9.7060.0 9.5872.0 9.9375.0 9.58Table3-37 MAPLHGR for Lattice 165(References 6 and 10)BundleOpt2-4.08-18GZ8.00/6.00 (QK23)Lattice165: Opt2-T4.60-14G6.00Avg. Planar Exposure : DLO(GWd/MTU) IL;APLHGR (kW/ft)0.0 10.482.5 10.725.0 10.597.5 10.3710.0 10.4312.0 10.3015.0 10.0717.0 10.0120.0 10.0122.0 10.0224.0 10.0230.0 10.0236.0 9.9842.0 9.9250.0 9.8660.0 9.8272.0 10.2775.0 9.82Page 33 of 61 COLR Quad Cities 1 Rev. 10Table 3-38 MAPLHGR for Lattice 166(References 6 and 10)BundleOpt2-4.17-2GZ6.00-10G6.00 (QL23)Lattice1 66: Ont2-B4.59-1 2G6.00Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.322.5 9.495.0 9.397.5 9.3610.0 9.3612.0 9.3815.0 9.4117.0 9.4520.0 9.5222.0 9.5924.0 9.6030.0 9.6236.0 9.6242.0 9.6250.0 9.6260.0 9.6772.0 9.9175.0 9.67Table 3-39 MAPLHGR for Lattice 167(References 6 and 10)BundleOpt2-4.17-2GZ6.00-10G6 00 (01-23)Lattice167: Opt2-BE4.67-12G6.00Avg. Planar Exposuve DLO(GWd/rviTU) MAPLHGR (kW/ft)0.0 9.372.5 9.585.0 9.447.5 9.4710.0 9.5812.0 9.4615.0 9.5017.0 9.5620.0 9.6322.0 9.7024.0 9.7130.0 9.7636.0 9.7742.0 9.7050.0 9.6860.0 9.6572.0 9.9975.0 9.65Page 34 of 61 COLR Quad Cities 1 Rev. 10Table 3-40 MAPLHGR for Lattice 168(References 6 and 10)BundleOpt2-4.17-2GZ6.00-1 0G6.00 (QL23)Lattice168: Opt2-M4.67-12G6.00Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.362.5 9.605.0 9.427.5 9.5210.0 9.5912.0 9.4815.0 9.5117.0 9.5720.0 9.7022.0 9.7024.0 9.7230.0 9.7636.0 9.7942.0 9.6950.0 9.6660.0 9.6272.0 9.9975.0 9.62Table 3-41 MAPLHGR for Lattice 169(References 6 and 10).BundleOpt2-4.17-2GZ6.00-1 0G6.00 (QL23)* Lattice'169: Opt2-ME4.65-12G6.00Avg. Planar Exposure., DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.572.5 9.815.0 9.657.5 9.6710.0 9.7212.0 9.6615.0 9.7317.0 9.8220.0 9.9322.0 9.9824.0 9.9830.0 10.0036.0 10.0042.0 9.9450.0 9.8160.0 9.7772.0 10.2175.0 9.77Page 35 of 61 COLR Quad Cities 1 Rev. 10Table 3-42 MAPLHGR for Lattice 170(References 6 and 10)BundleOpt2-4.17-2GZ6.00-10G6.00 (QL23)Lattice*170: Ont2-T4.64-10G6.00170: r__ _ _.. ..... .....Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 10.012.5 10.195.0 9.987.5 10.0710.0 9.8412.0 9.8215.0 9.8217.0 9.8520.0 9.9422.0 9.9724.0 9.9730.0 9.9936.0 9.9942.0 9.93-50.0 9.8160.0 9.7772.0 10.2175.0 9.77Table 3-43 MAPLHGR for Lattice 171(References 5 and 9)Bundle.Opt2-4.03-16GZ8.00/5.50-2GZ5.50 (QM24)Lattice171: Opt2-B4.33-16G8.00-2G5.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 8.792.5 9.115.0 9.037.5 9.1910.0 9.3812.0 9.5115.0 9.7017.0 9.8020.0 9.9822.0 10.0024.0 10.0030.0 9.7836.0 9.64Page 36 of 61 COLR Quad Cities 1 Rev. 10Table 3-44 MAPLHGR for Lattice 172(References 5 and 9)BundleOpt2-4.03-16GZ8.00/5.50-2GZ5.50 (QM24)Lattice1M72. Opt2-B4.47-16G8.00-2G5.50,Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 8.732.5 9.055.0 8.967.5 8.9210.0 9.0612.0 9.1215.0 9.2417.0 9.3020.0 9.4222.0 9.5224.0 9.6430.0 9.6236.0 9.58* Table 3-45 MAPLHGR for Lattice 173(References 5 and 9)BundleOpt2-4.03-16GZ8.00!5.50-2GZ5.50 (0M24)Lattice173: Opt2-BE4.56-16G8.00-2G5.50Avg. Planar.Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 8.762.5 9.085.0 8.977.5 8.9610.0 9.1212.0 9.1915.0 9.3217.0 9.3920.0 9.5322.0 9.6324.0 9.7630.0 9.7236.0 9.68Page 37 of 61 COLR Quad Cities 1 Rev. 10Table 3-46 MAPLHGR for Lattice 174(References 5 and 9)BundleOpt2-4.03-16GZ8.00/5.50-2GZ5.50 (QM24)Lattice174: Opt2-M4.56-16G8.00-2G5.50Avg. Planar Exposure DLO ,(GWd/MTU) MAPLHGR (kW/ft)0.0 8.752.5 9.085.0 8.977.5 8.9510.0 9.1312.0 9.2015.0 9.3317.0 9.4020.0 9.5522.0 9.6524.0 9.7730.0 9.7136.0 9.68Table 3-47 MAPLHGR for Lattice 175(References 5 and 9)BundleOpt2-4.03-16GZ8.00/5.50-2GZ5.50 (QM24)Lattice175: Opt2-ME4.52w16G8.00-2G5.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 8.872.5 9.215.0 9.107.5 9.1010.0 9.2712.0 9.3615.0 9.5117.0 9.5920.0 9.8422.0 9.9924.0 9.9630.0 9.9136.0 9.85Page 38 of 61 COLR Quad Cities 1 Rev. 10Table 3-48 MAPLHGR for Lattice 176(References 5 and 9)BundleOpt2-4.03-16GZ8.0015.50-2GZ5.50 (QM24).Lattice176: Opt2-T4.52-16G8.00-2G5.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 8.912.5 9.245.0 9.127.5 9.0810.0 9.2412.0 9.3215.0 9.4517.0 9.5320.0 9.8322.0 10.0124.0 9.9630.0 9.9236.0 9.85Table 3-49-MAPLHGR for Lattice 177(References,5 and 9)BundleOpt2-4.03-16GZ8.00/5.50-2GZ5.50 (QM24)Lattice177: Opt2-T4.53-16G5.50Avg. Planar Exposure " DLO.(GWd/MTU) MAPLHGR (kW/ft)0.0 9.322.5 9.675.0 9.607.5 9.4010.0 9.5012.0 9.5815.0 9.8217.0 10.0220.0 10.0622.0 10.0424.0 10.0130.0 9.9536.0 9.88Page 39 of 61 COLR Quad Cities 1 Rev. 10Table 3-50 MAPLHGR for Lattice 178(References 5 and 9)BundleOpt2-4.03-14GZ8.00/5.50-2GZ5.50 (QN24)Lattice178: ODt2-B4.33-14G8.00-2G5.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.042.5 9.355.0 9.247.5 9.3110.0 9.4712.0 9.5715.0 9.7517.0 9.8320.0 9.9522.0 9.9724.0 9.9830.0 9.7636.0 9.62Table 3-51 MAPLHGR for Lattice 179(References 5 and 9)BundleOpt2-4.03-14GZ8.00/5.50-2GZ5.50 (QN24)Lattice179: Opt2-B4.46-14G8.00-2G5.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 8.992.5 9.275.0 9.177.5 9.0710.0 9.1212.0 9.2015.0 9.3017.0 9.3320.0 9.3922.0 9.4924.0 9.5930.0 9.6236.0 9.58Page 40 of 61 COLR Quad Cities 1 Rev. 10Table 3-52 MAPLHGR for Lattice 180(References 5 and 9)BundleOpt2-4.03-14GZ8.00/5.50-2GZ5.50 (QN24)Lattice180: Opt2-BE4.55-14G8.00-2G5.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.032.5 9.325.0 9.187.5 9.1210.0 9.2412.0 9.2715.0 9.3817.0 9.4320.0 9.4822.0 9.6124.0 9.7230.0 9.7136.0 9.68Table 3-53 MAPLHGR for Lattice 181(References 5 and 9)BundleOpt2-4.03-14GZ8.0015.50-2GZ5.50 (QN24)Lattice181.',: Opt2-M4.55-ý14G8,00-2G5.50Avg. Planar Exposure, DLO(GWd/MTU) .MAPLHGR (kW/ft)0.0 9.022.5 9.335.0 9.227.5 9.1610.0 9.2512.0 9.2915.0 9.3917.0 9.4320.0 9.4922.0 9.6224.0 9.7430.0 9.7036.0 9.67Page 41 of 61 COLR Quad Cities 1 Rev. 10Table 3-54 MAPLHGR for Lattice 182(References 5 and 9)BundleOpt2-4.03-14GZ8.00/5.50-2GZ5.50 (QN24)Lattice182: Opt2-ME4.51-14G8.00-2G5.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.172.5 9.485.0 9.367.5 9.3010.0 9.4112.0 9.4615.0 9.5717.0 9.6120.0 9.7722.0 9.9424.0 9.9530.0 9.9136.0 9.87Table 3-55 MAPLHGR for Lattice 183(References 5 and 9)BundleOpt2-4.03-14GZ8.00/5.50-2GZ5.50 (QN24)Lattice183: Opt2-T4.51-14G8.00-2G5.50Avg. Planar Exposure DLO(GWd/IMTU) MAPLHGR (kW/ft)0.0 9.212.5 9.515.0 9.377.5 9.2810.0 9.3812.0 9.4315.0 9.5417.0 9.5820.0 9.8022.0 9.9724.0 9.9430.0 9.9336.0 9.85Page 42 of 61 COLR Quad Cities 1 Rev. 10Table 3-56 MAPLHGR for Lattice 184(References 5 and 9)SBundleOpt2-4.03-14GZ8.00/5.50-2GZ5.50 (QN24)Lattice184: Opt2-T4.52-14G5.50Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.662.5 9.935.0 9.837.5 9.5810.0 9.5712.0 9.6715.0- 9.82,17.0 9.9820.0 10.0522.0-..- 10.0624.0 10.0230.0 9.9736.0 9.91Table 3-57 MAPLHGR for Lattice 185(References 5 and 9)BundleOpt2-4.i6-12G6.00-2GZ6.00 (Q024)Lattice185: Opt2-B4L58-14G6.00Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.022.5 9.215.0 9.157.5 9.1510.0 9.2212.0 9.2215.0 9.3117.0 9.3820.0 9.4922.0 9.5924.0 9.6030.0 9.6136.0 9.63Page 43 of 61 COLR Quad Cities 1 Rev. 10Table 3-58 MAPLHGR for Lattice 186(References 5 and 9)BundleOpt2-4.16-;12G6.00-2GZ6,OO (0024)Lattice186: Oot2-BE4.67-14G6.00Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.062.5 9.285.0 9.207.5 9.2310.0 9.3212.0 9.3015.0 9.3917.0 9.4820.0 9.6122.0 9.6924.0 9.7230.0 9.7636.0 9.73Table 3-59 MAPLHGR for Lattice 187(References 5 and 9)BundleOpt2-4.16-12G6.00-2GZ6.00(0024)Lattice187: Opt2-M4.67-14G6.00Avg. Planar Exposure ', DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.052.5 9.295.0 9.197.5 9.2710.0 9.3812.0 9.3215.0 9.4017.0 9.5020.0 9.6722.0 9.7024.0 9.7230.0 9.7736.0 9.72Page 44 of 61 COLR Quad Cities 1 Rev. 10Table 3-60 MAPLHGR for Lattice 188(References 5 and 9)BundleOpt2-4.16-12G6.00-2GZ6.00 (Q024)Lattice188: Ont2-ME4.64-1 4G6.00188: -- " .-M4...-.... ...Avg. Planar Exposure DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.232.5 9.475.0 9.387.5 9.4110.0 9.4712.0 9.4915.0 9.6217.0 9.7520.0 9.9322.0 9.9824.0 9.9930.0 10.0136.0 9.96Table 3-61 MAPLHGR for Lattice 189(References 5 and 9)BundleOpt2-4.16-12G6.00-2GZ6.00 (Q024)Lattice189: Opt2-T4.64-12G6.00Avg. Planar Exposure , DLO(GWd/MTU) MAPLHGR (kW/ft)0.0 9.612.5 9.845.0 9.677.5 9.7010.0 9.6612.0 9.6215.0 9.7017.0 9.7920.0 9.9322.0 9.9824.0 9.9830.0 9.9836.0 9.98Page 45 of 61 COLR Quad Cities 1 Rev. 104. Operating Limit Minimum Critical Power RatioTechnical Specification Sections 3.2.2, 3.4.1, and 3.7.7The OLMCPRs for Quad Cities 1 Cycle 24 were established to protect the SLMCPR during theanticipated operational occurrences.4.1. Manual Flow Control MCPR Operating LimitsThe OLMCPR is determined for a given power and flow condition by evaluating the power-dependent OLMCPR and the flow-dependent OLMCPR and selecting the'greater of the two.4.1.1. Power -Dependent MCPR Operating LimitFor operation at less than 38.5% of rated core thermal power, the OLMCPR as afunction of core thermal power is shown in Tables 4-5 and 4-6. For operation at greaterthan 38.5% of rated core thermal power, the OLMCPR as a function of core thermalpower is determined by multiplying the applicable rated condition OLMCPR limit shownin Tables 4-2 through 4-4 by the applicable OLMCPR multiplier K(P) given in Tables 4-5and 4-6. For operation at exactly 38.5% of rated core thermal power, the OLMCPR as afunction of core thermal power is the ma.ximum of either of the two aforementionedmethods evaluated at 38.5% of rated core thermal power.4.1.2. Flow -Dependent MCPR Operating LimitTable 4-7 gives the OLMCPR as a function of the flow based on the applicable plantcondition. The flow-dependent OLMCPR values are applicable to all base case andEOOS combinations.Page 46 of 61 COLR Quad Cities 1 Rev. 104.2. Scram TimeTSSS, ISS, and NSS refer to scram speeds. The scram time values associated with thesespeeds are shown in Table 4-1. The TSSS scram times shown in Table 4-1 are the same asthose specified in the Technical Specifications (Reference 13). Reference 3 indicates that theTSSS control rod insertion times that were actually used in the transient analysis areconservative with respect to the scram times specified in the Technical Specifications.To utilize the OLMCPR limits for Nominal Scram Speed in Table 4-4, the average control rodinsertion time at each control rod insertion fraction must be equal to or less than the NSS timeshown on Table 4-1 below.To utilize the OLMCPR limits for Intermediate Scram Speed in Table 4-3, the average controlrod insertion time at each control rod insertion fraction must be equal to or less than the ISS timeshown on Table 4-1 below.To utilize the OLMCPR limits for Technical Specifica tion Scram Speed in Table 4-2, the averagecontrol rod insertion time at each control rod insertion fraction must be equal to or less than theTSSS time shown on Table 4-1 below.The average control rod insertion time is defined as the sum of the control rod insertion times ofall operable control rods divided by the number of operable control rods. The time for inoperabledrives fully inserted (notch 00) can be conservatively included for calculation of core averagescram speed. (Reference 3)Table 4-1 Scram Times(References 3, 13 and 17)Control RodInsertion Fraction TSSS (seconds) ISS (seconds) NSS (seconds)(% from fully withdrawn)5 0.48 0.360 0.32420 0.89 0.720 0.69450 1.98 1.580 1.51090 3.44 2.800 2.6704.3. Recirculation Pump ASD SettingsTechnical Requirements Manual Section 2.1 .a.1Quad Cities 1 Cycle 24 was analyzed with a maximum core flow runout of 110%; therefore therecirculation pump ASD must be set to maintain core flow less than 110% (107.8 Mlb/hr) for allrunout events. (Reference 4) This value is consistent with the analyses of Reference 3.Page 47 of 61 COLR Quad Cities 1 Rev. 10Table 4-2 MCPR TSSS Based Operating Limits -Nominal FWT and FWTR(Reference 3)Nominal FWT FWTREOOS Combination Cycle Exposure (MWd/MTU) Cycle Exposure (MWd/MTU)1 15,000 > 15,000 < 15,000 > 15,000Base 1.71 1.76 1.71 1.76Base SLO 1.76 1.81 1.76 1.81PLUOOS 1.77 1.81 1.77 1.81PLUOOS SLO 1.82 1.86 1.82 1.86TBVOOS 1.88 1.91 1.89 1.91TBVOOS SLO 1.94 1.97 1.95 1.97TCV Slow Closure 1.81 1.86 1.81 1.86TCV Slow Closure SLO 1.86 1.92 1.86 1.92TCV Stuck Closed 1.71 1.76 1.71 1.76TCV Stuck Closed SLO1.761.81 1.76 J 1.81Page 48 of 61 Table 4-3 MCPRCOLR Quad Cities 1 Rev. 10ISS Based Operating Limits -Nominal FWT and FWTR(Reference 3)Nominal FWT FWVTREOOS Combination Cycle Exposure (MWd/MTU) Cycle Exposu (MWd/MTU)5 15,000 > 15,000 5 15,000 [ > 15,000Base 1.46 1.51 1.52 1.53Base SLO 1.50 1.56 1.57 1.58PLUOOS 1.54 1.59 1.54 1.59PLUOOS SLO 1.59 1.64 1.59 1.64TBVOOS 1.62 1.66 1.65 1.68TBVOOS SLO 1.67 1.71 1.70 1.73TCV Slow Closure 1.56 1.60 1.56 1.60TCV Slow Closure SLO 1.61 1.65 1.61 1.65TCV Stuck Closed 1.46 1.51 1.52 1.53TCV Stuck Closed SLO 1.50 1.56 1.57 1.58Table 4-4 MCPR NSS Based Operating Limits -Nominal FWT and FWTR(Reference 3)Nominal FWT FWTREOOS Combination Cycle Exposure (MWd/MTU) Cycle Exposure (MWd/MTU)<5 15,000 > 15,000 5 15,000 > 15,000Base 1.46 1.48 1.51 1.52Base SLO 1.50 1.52 1.56 1.57PLUOOS 1.51 1.55 1.51 1.55PLUOOS SLO 1.56 1.60 1.56 1.60TBVOOS 1.58 1.62 1.63 1.65TBVOOS SLO 1.63 1.67 1.68 1.70TCV Slow Closure 1.54 1.58 1.54 1.58TCV Slow Closure SLO 1.59 1.63 1.59 1.63TCV Stuck Closed 1.46 1.48 1.51 1.52TCV Stuck Closed SLO 1.50 1.52 1.56 1.57Page 49 of 61 COLR Quad Cities 1 Rev. 10Table 4-5 MCPR(P) -Nominal FWT(Reference 3)Core T Core Thermal Power (% of rated)Flow 1 _______________EOOS Combination low 0125 38.5 38.5 50 1 60 1 80 100(% of jRated) OLMCPR OLMCPR Multiplier, K(P)< 60 3.03 2.43 2.11Base> 60 3.13 2.68 2.441.31 1.18 1.12 1.05 1.00<_60 3.12 2.50 2.17Base SLO> 60 3.23 2.76 2.51< 60 3.03 2.43 2.11PLUOOS> 60 3.13 2.68 2.441.55 1.43 1.31 1.06 1.00<-60 3.12 2.50 2.17PLUOOS SLO> 60 3.23 2.76 2.51< 60 4.36 3.13 2.47TBVOOS> 60 4.36 3.34 2.861.31 1.18 1.12 1:05 1.00< 60 4.48 3.22 2.54TBVOOS SLO> 60 4.48 3.44 2.94<60 3.03 2.43 2.11TCV Slow Closure> 60 3.13 2.68 2.441.55 1.43 1.31 1.06 1.00<60 3.12 .2.50 2.17TCV Slow Closure SLO> 60 3.23 2.76 2.51< 60 3.03 2.43 2.11TCV Stuck Closed> 60 3.13 2.68 2.441.31 1.18 1.12 1.05 1.00<-60 3.12 2.50 2.17TCV Stuck Closed SLO> 60 3.23 2.76 2.51Page 50 of 61 COLR Quad Cities 1 Rev. 10Table 4-6 MCPR(P) -FWTR(Reference 3)Core Core Thermal Power (% of rated)EOOS Combination (%o 0 25 38.5 38.5 50 60 80 100Rated) OLMCPR OLMCPR Multiplier, K(P)<60 3.03 2.43. 2.11Base>60 3.13 -2.68 2.441.34 1.20 1.13 1.05 1.00<60 3.12 2.50 2.17Base SLO> 60 3.23 2.76 2.51<60 3.03 2.43 2.11PLUOOS> 60 3.13 2.68 2.44.. ... 1.55 1.43 1.31 1.06 1.00<60 3.12 2.50 2.17PLUOOS SLO> 60 3.23 2.76 2.51._< 60 4,73 3.30 2.53TBVOOS> 60 4.73 3.34 2.931.34 1.20 1.13 1.05 1.00_<60 4.86 3.39 2.60TBVOOS SLO> 60 4.86 3.44 3.01< 60 3.03 2.43 2.11TCV Slow Closure>60 3.13 2.68 2.441.55 1.43 1.31 1.06 1.00<60 3.12 2.50 2.17TCV Slow Closure SLO> 60 3.23 2.76 2.51< 60 3.03 2.43 2.11TCV Stuck Closed> 60 3.13 2.68 2.441.34 1.20 1.13 1.05 1.00<60 3.12 2.50 2.17TCV Stuck Closed SLO> 60 3.23 2.76 2.51Page 51 of 61 COLR Quad Cities 1 Rev. 10Table 4-7 MCPR(F) -DLO and SLO Operation(Reference 3)Core Flow DLO(% of rated) TLO SLO0 1.98 2.04100 1.38 1.42108 1.38 1.42Page 52 of 61 COLR Quad Cities 1 Rev. 105. Linear Heat Generation RateTechnical Specification Sections 3.2.3 and 3.4.1The TMOL at rated conditions for the Optima2 fuel is established in terms of the maximum LHGR as afunction of rod nodal exposure. The limits in Table 5-1 apply to bundle lattices that do not requireGadolinia set down penalties as well as any natural blanket segment in the core (lattice types 101 and108). The limits in Tables 5-2 through 5-9 apply to bundle lattices that require Gadolinia set downpenalties.The LHGR limit is the product of the exposure dependent LHGR limit from Table 5-1 through Table 5-9and the minimum of the power-dependent LHGR multiplier or the flow-dependent LHGR multiplier, asapplicable. The power-dependent LHGR multiplier is determined from Table 5-10. The flow-dependentLHGR multiplier is determined from Table 5-11, and is applicable for DLO and SLO and for all BaseCase and EOOS conditions.Table 5-1 LHGR Limits for Lattices 101,108, 129,130,131,132,133,134, 135, 136, 137, 138,139,140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, and 151(References 3, 11 and 12)Rod Nodal Exposure LHGR Limit(GWd/MTU) (kW/ft)0.000 13.7214.000 13.1123.000 12.2257.000 8.8762.000 8.3875.000 3.43Table 5-2 LHGR Limits for Lattices 152, 153, 154, 155, 163,164, and 165(Reference 18)Rod Nodal Exposure LHGR Limit(GWd/MTU) (kW/ft)0.000 13.7214.000 13.1114.999 13.0115.000 12.6235.000 10.7135.001 11.0462.000 8.3875.000 3.43Table 5-3 LHGR Limits for Lattices 156, 157 and 158(Reference 18)Rod Nodal Exposure LHGR Limit(GWd/MTU) (kW/ft)0.000 13.7214.000 13.1114.999 13.0115.000 12.5545.000 9.7045.001 10.0662.000 8.3875.000 3.43Page 53 of 61 COLR Quad Cities 1 Rev. 10Table 5-4 LHGR Limits for Lattice 159, 160, 161, and 162(Reference 18)Rod Nodal Exposure LHGR Limit(GWd/MTU) (kW/ft)0.000 13.7214.000 13.1117.999 12.7118.000 12.5232.000 11.1732.001 11.3462.000 8.3875.000 3.43Table 5-5 LHGR Limits for Lattices 166, 167, 168, 169, and 170(Reference 18)Rod Nodal Exposure LHGR Limit(GWd/MTU) (kW/ft)0.000 13.7214.000 13.1162.000 8.3875.000 3.43Table 5-6 LHGR Limits for Lattices 181,185,186, 187, and 189(Reference 3)Rod Nodal Exposure LHGR Limit(GWd/MTU) (kW/ft)0.000 13.7214.000 13.1123.000 12.2257.000 8.8762.000 8.3875.000 3.43Table 5-7 LHGR Limits for Lattices 171,172,173,174,178,179,180, 183, and 188(Reference 3)Rod Nodal Exposure LHGR Limit(GWd/MTU) (kW/ft)0.000 13.7214.000 13.1119.500 12.5619.501 12.4423.000 12.0934.000 11.0134.001 11.1357.000 8.8762.000 8.3875.000 3.43Page 54 of 61 COLR Quad Cities 1 Rev. 10Table 5-8 LHGR Limits for Lattices 176, 177, and 184(Reference 3)Rod Nodal Exposure LHGR Limit(GWd/MTU) (kW/ft)0.000 13.7214.000 13.1118.500 12.6618.501 12.4123.000 11.9741.000 10.2341.001 10.4457.000 8.8762.000 8.3875.000 3.43Table 5-9 LHGR Limits. for Lattices 175 and 182(Reference 3)Rod Nodal Exposure LHGR Limit(GWd/MTU). (kW/ft)0.000 13.7213.999 13.1114.000 12.71.23.000 11.8536.000 10.6036.001 10.9357.000 8.8762.000

• 8.3875.000 3.43Page 55 of 61 COLR Quad Cities 1 Rev. 10Table 5-10 Power-Dependent LHGR Multipliers(Reference 3)Core Thermal Power (% of rated)EOOS Combination 0 25 < 38.5 > 38.5 50 60 80 100LHGR MultiplierBase0.53 0.63 0.68 0.75 0.80 0.84 0.89 1.00Base SLOPLUOOS0.53 0.63 0.68 0.68 0.72 0.81 0.87 1.00PLUOOS SLOTBVOOS0.33 0.46 0.53 0.69 0.72 0.74 0.78 1.00TBVOOS SLOTCV Slow Closure0.53 0.63 0.68 0.68 0.72 0.80 0.87 1.00TCV Slow Closure SLOTCV Stuck Closed0.53 0.63 0.68 0.75 0.80 '0.84 0.89 1.00TCV Stuck Closed SLOTable 5-11 Flow-Dependent LHGR Multipliers(Reference 3)Flow LHGR(% of rated) Multiplier0 0.2720 0.4340 0.6060 0.8080 .1.00100 1.00108 1.00Page 56 of 61 COLR Quad Cities 1 Rev. 106. Control Rod Block SetpointsTechnical SpecificationSections 3.3.2.1 and 3.4.1The rod block monitor upscale instrumentation setpoints are determined from the relationships shown inTable 6-1:Table 6-1 RBM Allowable Values(Reference 20)ROD BLOCK MONITORUPSCALE TRIP FUNCTION ALLOWABLE VALUETwo Recirculation Loop 0.65 Wd + 56.1%Operation 0.65_W__+_56.1%Single Recirculation Loop 0.65 Wd + 51.4%Operation 0.6 WI+514The setpoint may be lower/higher and will still comply with the RWE analysis because RWE is analyzedunblocked (Reference 4).Wd -percent of recirculation loop drive flow required to produce a rated core flow of 98 Mlb/hr.7. Stability Protection SetpointsTechnical Specification Section 3.3.1.3The OPRM PBDA trip settings are given in Table 7-1.Table.7-1 OPRM PBDA Trip Settings(Reference 3)PBDA Trip Amplitude Setpoint (Sp) Corresponding MaximumConfirmation Count Setpoint (Np)1.14 16The PBDA settings are the only OPRM settings credited in the safety analysis as documented inthe licensing basis for the OPRM system. (Methodology Reference 10)The OPRM PBDA trip settings are based, in part, on the cycle specific OLMCPR and thepower/flow-dependent MCPR limits. Any change to the OLMCPR values and/or the power/flow-dependent MCPR limits should be evaluated for potential impact on the OPRM PBDA tripsettings.The OPRM PBDA trip settings are applicable when the OPRM system is declared operable, andthe associated Technical Specifications are implemented.Page 57 of 61 COLR Quad Cities 1 Rev. 108. Modes of OperationThe allowed modes of operation with combinations of equipment.out-of-service are described in Table8-1 below:Table 8-1 AllowedModes of Operation and EOOS Conditions(Reference 3) -EOOS Options Thermal Limit SetsBase Base (DLO or.SLO)PLUOOS PLUOOS (DLO or SLO)TBVOOS TBVOOS (DLO or SLO)TCV Slow Closure TCV Slow Closure (DLO or SLO)TCV Stuck Closed *Base (LO or SLO)See Table 8-2 for power restrictions.PCOOS PLUOOS (DLO or SLO)PCOOS and PLUOOS PLUOOS (DLO or SLO)PCOOS and TCV Slow Closure TCV Slow Closure (DLO or SLO)PLUOOS (DLO or SLO)PCOOS and one TCV Stuck CSee Table 8-2 for power restrictions.PLUOOS and one TCV Stuck Closed *PLUOS (DLQ or SLO)See Table 8-2 for power restrictions.* Also applicable to one TSV stuck closed or one TCV and TSV stuck closed in' the same line(Reference 3).** EOOS condition TCV Stuck Closed has identical thermal limits as the Base Case. Therefore, thiscondition will use the Base Case thermal limit set.Common Notes -Applicable to Base Case and all EOOS Combinations for DLO/SLO:1. All modes are allowed for operation at MELLLA, ICF (up to 108% rated core flow), andcoastdown subject to the power restrictions in Table 8-2 (Reference 3). Either EOC must bereached or coastdown must begin prior to exceeding 16797 MWd/MTU. The licensing analysisremains valid down to a coastdown power level of 70% given all burnup limits are satisfied perMethodology Reference 1. Each OOS Option may be combined with each of the followingconditions:* Up to 16 TIP channel traces and 2 common channel traces may be substituted using theSUBTIP methodology (Reference 15) provided the requirements for utilizing SUBTIPmethodology are met as clarified in Reference 14.* Up to 50% of the LPRMs OOS. (Reference 15)" An LPRM calibration frequency of up to 2500 EFPH (2000 EFPH + 25%). (Reference15)Page 58 of 61 COLR Quad Cities 1 Rev. 102. Nominal FWT results are valid for application within a +10°F/-30°F temperature band around thenominal FWT (nominal FWT curve is contained in Reference 4) and operating steam domepressure region bounded by the maximum value of 1020 psia and the minimum pressure curvein Reference 4. (Reference 3)3. For operation outside of Nominal FWT, FWTR results are valid for the minimum FWT curve (i.e.,the -120°F curve in Ref6rence 4)'and support a feedwater temperature reduction of up to 120°Ffor Base and all EOOS DLO/SLO conditions for cycle operation through EOC subject to therestriction in Reference 16 for feedwater temperature reductions of greater than 1 00°F. Therestriction requires that for a FWT reduction greater than 1 00°F, operation needs to be restrictedto less than the 100% rod line. For a feedwater temperature reduction of between 30°F and1200F, the FWTR limits should be applied.4. All analyses support the fastest TBV (assumed to be #1) OOS, with the remaining 8 TBVsmeeting the assumed opening profile in Reference 17. The analyses also assume a minimumturbine bypass flow of 3.467 Mlb/h" steam flow, equivalent to one TBV out of service (or partiallyclosed TBVs equivalent to one closed TBV), with the assumed opening profile for the remainingTBVs met. If the opening profile is NOT met, or if the TBV system CANNOT pass an equivalentof"3.467 MIb/hr steam flow, utilize the TBVOOS condition. (Reference 3)5. If any TBVs are OOS in the pressure control mode, the maximum steam flow removal capabilityfor pressure control needs, to be evaluated to ensure that at least the equivalent of two turbinebypass valves are available for pressure control (Reference 3). The DEHC system opensbypass valves sequentially for pressure control, and the total number allowed to open is limitedby the MCFL setting. See calculation QDC-5650-1-1598 (Reference 19) for the relationshipbetween MCFL "Limit Ref" setpoint and the number of bypass valves allowed to open inpressure control. Note that the MCFL is a limit on valve position demand, and not on actualvalve position. In other words, DEHC does. not receive feedback on valve position.when limitingdemand per the MCFL, therefore inoperable bypass valves requested to open prior to reachingthe MFCL will reduce total steam flow capability. If this condition CANNOT be met, enterTechnical Specification LCO 3.2.2 and 3.2.3.-6. A single MSIV may be taken OOS (shut) under any of the specified OOS options as long as corethermal power is maintained < 2218 MWt. (Reference 3)7. Between 25% and 50% of rated thermal power the PLUOOS thermal limits must be used if theprotective relaying is out of service, such that a load reject event will'not result. in a turbine trip.(Reference 3)Table 8-2 Core Thermal Power Restriction for OOS Conditions(Reference 3)EOOS Condition Core Thermal Power (MWt)One TCV Stuck Closed *PCOOS and one TCV Stuck Closed * <2366**PLUOOS and one TCV Stuck Closed ** Also applicable to one TSV stuck closed or one TCV and TSV stuck closed in the same line (Reference3).** The 2366 MWt power restriction is conservatively set. Operation above 2366 MWt is analyzed andallowed, but may require raising the MCFL setpoint and/or increasing TBV availability to increase theavailable total reactor vessel steam flow capability as described in Reference 3.Page 59 of 61 COLR Quad Cities 1 Rev. 109. MethodologyThe analytical methods used to determine the core operating limits shall be those previouslyreviewed and approved by the NRC, specifically those described in the following documents:1. Westinghouse Topical Report CENPD-300-P-A, "Reference Safety Report for Boiling WaterReactor Reload Fuel," July 1996.2. Westinghouse Topical Report CENPD-390-P-A, "The Advanced PHOENIX and POLCA Codesfor Nuclear Design of Boiling Water Reactors," December 2000.3. Westinghouse Report WCAP-1 6081-P-A, "1 0x1 0 SVEA Fuel Critical Power Experiments andCPR Correlation: SVEA-96 Optima2," March 2005. ,4. Westinghouse Report WCAP-1 6081-P-A Addendum 1 -A, "SVEA-96 Optima2 CPR Correlation(D4): High and Low Flow Applications," March 2009.5. Westinghouse Report WCAP-1 6081-P-A Addendum 2-A, "SVEA-96 0ptima2 CPR Correlation(D4): Modified R-factors for Part-Length Rods," February 2009.6. Westinghouse Report WCAP-1 5682-P-A, 'Westinghouse BWR ECCS Evaluation Model:Supplement 2 to Code Description, Qualification and Application," April 2003.7. Westinghouse Report WCAP-1 6078-P-A, "Westinghouse BWR ECCS Evaluation Model:Supplement 3 to Code Description, Qualification and Application to SVEA-96 Optima2 Fuel,"November 2004.8. Westinghouse Topical Report WCAP-1 5836-P-A, "Fuel Rod Design Methods for Boiling WaterReactors -Supplement 1," April 2006.9. Westinghouse Topical Report WCAP-1 5942-P-A, "Fuel Assembly Mechanical DesignMethodology for Boiling Water Reactors, Supplement 1 to CENPD-287-P," March 2006.10. GE Topical Report NEDO-32465-A, "Reactor Stability Detect and Suppress Solutions LicensingBasis Methodology for Reload Applications," August 1996.Page 60 of 61 COLR Quad Cities 1 Rev. 1010. References1. Exelon Generation Company, LLC and MidAmerican Energy Company Docket No. 50-254,Quad Cities Nuclear Power Station, Unit 1 Renewed Facility Operating License, License No.DPR-29.2. NRC Letter from D. M. Crutchfield to All Power Reactor Licensees and Applicants, GenericLetter 88-16; Concerning the Removal of Cycle-Specific Parameter Limits from Tech Specs,October 3, 1988.3. Westinghouse Document, NF-BEX-15-2, Revision. 0, "Quad Cities Nuclear Power Station Unit 1Cycle 24 Reload Licensing Report," January 2015.4. Westinghouse Document, NF-BEX-15-1, Revision 0, "Quad Cities Nuclear Power Station Unit 1Cycle 24 Reload Engineering Report," January 2015.5. Westinghouse Document, NF-BEX-15-6-NP, Revision 0, "Quad Cities Nuclear Power StationUnit 1 Cycle 24 MAPLHGR Report," February 2015.6. Westinghouse Document, NF-BEX-12-188-NP, Revision 0, "Quad Cities Nuclear Power StationUnit 1 Cycle 23 MAPLHGR Report," January 2013.7. Westinghouse Document, NF-BEX-11-9-NP, Revision 1, "Quad Cities Nuclear Power StationUnit 1 Cycle 22 MAPLHGR Report," October 2014.8. Westinghouse Document, NF-BEX-09-17-NP, Revision 1, "Quad Cities Nuclear Power StationUnit 1 Cycle 21 MAPLHGR Report," October 2014.9. Westinghouse Letter, NF-BEX--14-98, Revision 0, "Bundle Design Report for Quad Cities 1 Cycle24," August 5, 2014.10. Westinghouse Letter, NF-BEX-1 2-120, Revision 0, "Bundle Design Report for Quad Cities 1Cycle 23," September 4, 2012:11. Westinghouse Letter, NF-BEX-1 0-162, Revision 1, "Rev. 1 Bundle Design Report for Quad*Cities 1. Cycle 22," ,November 18, 2010.12. Westinghouse Letter, NF-BEX-08'-129, Revision 1, "Final Report for Quad Cities 1 Cycle 21Bundle Designs Revision 1," November 6, 2008.13. Technical Specifications for Quad Cities 1 and 2, Table 3.1.4-1, "Control Rod Scram Times".14. FANP Letter, NJC:04:031/FAB04-496, "Startup with TIP Equipment Out of Service," April 20,2004. (Exelon Engineering Evaluation EC 348897-000)15. Exelon Engineering Evaluation EC 357691-000, "EVALUATION OF APPROPRIATEUNCERTAINTIES FOR USE BY WESTINGHOUSE IN SAFETY LIMIT MCPR ANALYSES",November 28, 2005.16. Exelon Letter, NF-MW:02-0081, "Approval of GE Evaluation of Dresden and Quad CitiesExtended Final Feedwater Temperature Reduction," Carlos de la Hoz to Doug Wise and AlexMisak, August 27, 2002.17. Exelon TODI, QDC-14-022, Revision 0, "Operating Parameters List -Westinghouse (OPL-W) forQuad Cities Unit 1 Cycle 24 Transient Analysis," June 26, 2014.18. Westinghouse Document, NF-BEX-13-2, Revision 0, "Quad Cities Nuclear Power Station Unit 1Cycle 23 Reload Licensing Report," January 2013.19. Exelon Design Analysis, QDC-5650-1-1598, Revision 0, "Digital EHC Controller Settings forMaximum Combined Flow Limit (MCFL)," October 16, 2007.20. GE Document, GE DRF C51-00217-01, "Instrument Setpoint Calculation NuclearInstrumentation, Rod Block Monitor, Commonwealth Edison Company, Quad Cities 1 & 2,"December 14, 1999. (Attachment A to Exelon Design Analysis, QDC-0700-1-1419, Revision 0)Page 61 of 61