| author name = RILEY H W

{{#Wiki_filter:Arizona Nuclear Power Project TITLE/DESCRIPTION OOCUHENT NVHSER/3-HC-H 3-pc+~5 tc~~I Cwt pc v"wf mwc5 4 Jij Pov I l PS 3 PUL~P 881123002S 881109*PEtR ADOCK 05000528 P PDC (SSuc P r US'C.BG'CT-iT&L SECH TZ CHECKER I~~/8S REYI SION OESCRI I TloN VC I-V.L 1veV dj V U6 DR1G1NATCR DATE DATE DATE iVEH/P""il DATE DATE i k INTERNAL CONTROL NO.ltd.al-IS3'CALC-ma CALCULATION COVER SHEET CHEET e PROJECT SUBJECT JOB NO 18601-183 CALC.NO.13-MC-HA-A02 TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM FILE NO.PROJECT QUAUTY CLASS MECH DISCIPUNE D 0 0 C O 0 U I cn O gD<cn c CS~C c C 0 0 D 0<C Cl Ol Cn CC)CO Q.0 0 U l 0 cn O cn c cc)No COMPUTER PROGRAM SCP YES NO PROGRAM NO.(S)ME 204 RECORD OF ISSUES 0 E S CAIPTloN TOTAL No.OF SHEETS LEAST SHEET No.7Z p~+ORIGwAL.z uc VERSION/RELEASE NO.Al GS DATE APPR pj LQ O I O R g c~e 0 C~cn 0 C 0 Oa<<cn cn cS cn C)Cl U P O 0cn cn 0 c 0 C C cn U Cl 0 cn e gc 0 O cn 0 CC Cl cn O U C O 0 Cl O I cn cn'D 0 Cll FLM INFORMATION ENTERED IN THIS SPACE: O SHOW PROFESSCONAL ENGCNEEA STAMP.F AEOOCRED.~ENTKA REFERENCE To WCLVSlON OF CHECKER'S AI TERNATE GAL.GCAATlONS, 6 USED.~PAOVOE ANV NOTES TO ASSCST CHECKr4G Aha APPROVAC<<O Cg N D cn~

1.Computer Runs For: A.HPSI Pump Room with no HVAC 52 53 54 18 19 20 21 22 23 24 25 26 27 28 29 30 31 B.C.HPSI Pump Room with no HVAC and Door Open HPSI Pump Room with no HVAC and Door Open (Alternate Run for verification of average room temperature for Case B)61 67 3$36 LAO 9999.l 7/SS if f CALCULATION SHEET CPLC NO 13-MC-HA-A02 PROJECT JOB NO 18601-183 SUEJECT TRANSIENT TE2PERATURE STUDY FOR HPSI PUMP ROOM SHEET NO.REV ORIGINATOR DATE i->W'E CHECKER DATE REV ORIGINATOR DATE 5'Fo~w CHECKER DATE.tQ VDI-bJ L 0 PURPOSE 10 12 13 14 The design basis for cooling the HPSI pump eauipment rooms, when the pumps are in service, uses unit coolers and the Essential Chilled Water System for cooling.In the event that either the unit coolers or the Essential Chilled Water system fails when the HPSI pump runs, the room temperature will rise rapidly.The purpose of this study is to determine the transient air temperature for 24 hours in the HPSI pump room for the following two cases: 17 18 19 A)s)Fluid temperature in the pipes of 225 F with no HVAC Fluid temperature in the pipes of 225 F with no HVAC and the room door open.20 21 22 23 24 2$During post-Loca condition, the limiting containment sump temperature is 225 F as shown in reference 19, figure 6.2.1-24.Standard room heat-up (RNHTUP)computer program, ME204, Rev.A is used to study the room ambient air heat-up by the equipment and other heat loads in the HPSI pump room.26 27 28 29 30 31 The heat generated in the room is transferred to the room ambient air, stored in the room enclosure concrete (heat sink)and transferred to the air outside the room.The transient temperature for the HPSI room ambient air is studied for a time period of 24 hours without any HVAC.In addition, the transient temperature is studied when there is no HVAC and the pump room door is open.35 36 LAO 3991il 7/99

PROJECT CALCULATION SHEET JO8 gp 18601-183 TRANSIENT TE2PERATURE STUDY FOR HPSI PAP ROOM CALC.Np'3-MC-HA-A02 SHEET NO.REV ORIGINATOR j'-//'ATE 3->F-SZ CHECKER DATE 6'.Q.gn Sc&#xc3;gy REV ORIGINATOR DATE CHECKER DATE.iO)D W cC 0: 0 3 II.DESIGN CRITERIA: 10 12 13 14 This is a study of the effect of certain equipment failures which are, strictly speaking, beyond the specific design basis for the affected systems.The results will be used as input to a probabalistic risk assessment evaluation done by others.The systems involved in this study are the Safety Injection (HPSI subsystem), Auxiliary Building HVAC (Normal and Essential), and Essential Chilled Water.Their design criteria are references 21, 22 and 23.17 18 20 21 22 23 24 2$27 28 29 30 31 36 I AO 9995,1 9/SS

CALCULATION SHEET PROJECT JQB NQ 18601-183 CALC.NO.13 MC-HA-A02 REV ORIGINATOR ii&/4'ATE 0-28'-k CHECKER d 4.P DATE 5-~HE REV 0 R I GIN A TO R SUBJECT T~SIENT TEMPERATURE STUDY@OR PEPSI PRP ROOM DATE SHEET NQ.6 CHECKER DATE.tO)I31-bl E<L'I 2 III.STUDY ASSUMPTIONS1 1.Fluid temperature for the HPSI system in the HPSI pump room is 225 F.During post-Loca condition, the maximum containment sump temperature is 225 F as shown in reference 19, figure 6.2.1-24.10 12 13 2.The initial temperature inside the HPSI room is 75 F.This is based on the assumption that normal HVAC is available before the time period of this study.Temperature of 75 F is the typical normal temperature in the auxiliary building and is based on the operating experience.

17 18 19 20 21 22 23 24 2S 26 27 28 29 30 31 3.The initial temperature outside the HPSI room is 75 F.This is based on the assumption that normal HVAC is available before the time period of this study.The initial temperature of 75 F is the typical normal temperature in the auxiliary building and is based on the operating experience.

4.Essential or normal HVAC is not available during time period of this study.This is the principle assumed failure at the onset of this study as discussed in section 5.Initially, steady state temperature conditions exist in the HPSI pump room and outside the pump room.3S 36 LAO 5998.1 7/55

PRO JECT (CALCULATION SHEET Jpe Np 18601-183 TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM C>t C Np 13-MC-HA-A02 SHEET NP.REV ORIGINATOR

/'~~%j DATE CHECKER?-28'-88'~

@p DATE REV ORIGINATOR DATE CHECKER DATE L iO OI-wzc 12 0 10 12 13 4 6.The room is simplified as an enclosed space bounded by the same thickness of walls, ceiling and floor.All of the room walls actually are 2'-9" each.In case of floor, no credit is taken for the thickness being more than the wall thickness of 2'-9".Due to the low heat load generated in 24 hours compared to the thermal capacity of the existing walls to absorb the heat, the additional.

floor thickness will not make any difference to the room ambient air temperature.

7.The walls, ceiling and floor are used as a heat sink.For details, refer to Section VI.C of this study.16 17 18'I 9 20 21 22 23 25 26 27 28 29 30 31 8.The heat generated within the room is considered as being constant.This is due to the fact that more than 90$of the heat load, as shown in figure 1, is from the electric motors.For details refer to Sections VI.D and VII.A.1.e of this study.9.Temperature at the inner surface of the insulation is equal to the temperature of the fluid in the pipe.This assumes that the temperature of the outside pipe surface is the same as the fluid temperature.

It also assumes that the temperature drop across the very small air gap between the pipe and the inside surface of the insulation is zero.This provides a conservative estimate of the piping heat load for this study.35 36 10.For calculation of heat dissipated by the pump, the pump modeled as a flat surface.This provides a conservative estimate compared to a cylindrical surface.LAO 1%48 s TIAW

PROJECT CALCULATION SHEET JO8 NO 18601-183 CANC NO 13-MC-HA-A02 SUBJECT TRANSIENT TEMPERATURE STUDY FOR HPSI PEP ROON SHEET NO.REV ORIGINATOR p~~p DATE->8'-S8'HECKER DATE REV ORIGINATOR DATE 5'-O'Se CHECKER DATE 11.When a wall is shared by two rooms, which may be heated at the same time, half of the wall surface area will be considered as a heat transmission pathway for each room.This will provide half of the wall as a heat sink for each room.Each HPSI pump room shares a common wall with the other HPSI pump room and with a CS pump room.50 52 53 54 Operation of only one HPSI pump is required, but two are assumed.The operating HPSI and CS pumps could be from different trains so that these pump rooms may not be adjacent to each other.This study uses a worst case scenario and assumes two common walls.57 58 59 20 25 22 23 24 23 26 27 28 29 30 35 12.The dimensions of HPSI pump rooms A and B for all three units are essentially identical.

In addition, the electric motors and pumps, equipment, lighting and piping sizes and lengths are virtually the same for all of these room.This study is performed for HPSI pump room A for Unit 1 and is applicable to HPSI room A and B for all three units.13.The shield wall in the pump room is considered a heat sink.The shield wall is converted to an equivalent wall having same thickness as the room walls.In doing this, the equivalent surface area on one side of this wall is modelled as a heat transmission pathway to the adjacent spaces.The shield wall surface area and volume are approximately 4S and 2.5%respectively of the pump room surface area and volume.35 36 I AO 9999 I 7/95

@g g-yg~.lO)nI-hl E<D 10 As can be seen from the results in Appendicies A and B, very little heat is transmitted through the walls;most is stored in it.This approach reasonably accounts for the shield wall mass, but slightly under estimates the rate at which heat is transferred into the shield wall because only one surface is assumed ava3.lable for heat transfer.Because the surface area and volume of the shield are a small percentage of the total, this w3.11 provide reasonably acceptable results.12 13 16 17'I 8 19 20 21 22 23 24 26 27 28 29 30 31 14.For the case when the room door is open, half of the room opening is assumed for air flow into the room and the other half is assumed for the a3.r flow out of the room.ASHRAE Ref.1, Chapter 19, Page 334, indicated that if there is only one opening, or if one opening is extremely large relative to the others, the neutral zone (where there is no pressure difference between inside an outside)will be at or near the center of the opening.This reference supports the above assumption

.In addition , 50$effectiveness of the opening (normal value 50%to 60%)'for air flow is used.For details, refer to section VII.B.1 15.Per assumpt3.on 4 above, the essential HVAC is not avaz.lable during t3me period of th3.s study.For a conservative approach, ACU fan will be assumed running, without chilled water through the essential co3.ls.The heat load due to this motor is minor as compared to the heat load from the HPSI pump motor.82%efficiency for the ACU fan motor is assumed for calculation of room heat load.This is a typical motor efficiency for 5 hp motors as shown in reference 1, Chapter 22, table 30, page 417.35 36 I AO)44'7/AS 0 ii PROJECT CALCULATION SHEET Jp8 Np 18601-183 CALC Np 13-".1C-HA-A02 U8gECT TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM SHEET NP.REV ORICINATOR t'5 all~D A T 6'Zf-Il'd'HECKER DATE REV ORICINATOR DATE CHECKER DATE 0 0 DI-4IE<C V 6'I 16.Moving air is assumed in the room due to ACU fan rather than normal still air.A conservative value of the surface resistance of 0.25, based on the assumed value of air velocity of 7 1/2 mph, is used.(See Reference 1, Chapter 20, table 1, page 357)10 12 13 16 17 18 19 20 2!22 24 25 17.The lighting load in the HPSI pump room is assumed to be 2 Watts/FT.This is a typical lighting load for industrial buildings as shown in the national electrical code 1987 handbook, reference 7.18.This study is performed for a time period of 24 hours.The computer model can provide details for a maximum of 720 steps (Refer Section VI.D).Therefore, each step or time increment is 2 minutes.19.The room walls are required to be divided into a number of layers for computation of temperature distribution in the concrete walls by the computer model.The required input for the thickness of the first layer and the multiplication factor for thickness of other layers are selected as 0.01 f t (approx.1/8")and 1.41 respectively.

PROJECT CALC U LATION SH EET JP8 NO 18601-183 TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM CgLC Np 13-MC-HA-A02 SHEET NO.REV ORIGINATOR j~</t DATE CHECKER g4~N DATE REV-A'g ORIGINATOR DATE CHECKER DATE IZ iO)I3 I-WE<IZ 0 20.For calculation of air flow due to temperature difference for the case of open door, the room average temperature is assumed to be 140 F.For support of this average 0 temperature, see Section VII.C, verification of average room temperature.

10 12!3 16 17 18 I9 20 21 22 23 24 26 27 28 29 30 31 21.For calculation of air flow due to temperature difference for the case of open room door, the average temperature outside the room is assumed to be 90 F.It assumes that doors in the corridor will be opened for enough air mixing to have the average temperature of 90 F.This approximates an average temperature after the pump room door has been open for a while.Note: the initial temperature was 75 F.(Assumptions 2 6 3).22.Concrete has the following properties:

A.Density 144 lbs/f t (Ref 6)B.Thermal conductivity 0.54 (Ref 6)C.Specific heat 0.2 btu/lb-F (Ref 6)23.The net pump room volume is required as input to the computer model.For calculation of net room volume, the volume of the HVAC equipment in the HPSI pump room is insignificant and is neglected.

36 LAO)998.1 9I99

ORIGINATOR CHECKER REV/~5~~i/~C ALCULATION SHEET PROJECT JO8 Np 18601-183 SU 8 JECT TRANS IENT TEMPERATURE STUDY FOR HPS I PUMP ROO REV DATE DATE ORIGINATOR 6 0'/a DATE SHEET Np.CHECKER DATE~iO 0 Ol-wzc II Np 13 MC HA A02 2 IV.

3 10 12 13 14 18 19 20 2'I 23 24 1.ASHRAE Handbook of Fundamentals, 1972.2.Technical specif3.cation for thermal insulation materials and the application to piping and equipment, specification number 13-MM-301, Rev.2.3.Line designation list, 13-P-ZZG-014, Rev.29.4.Auxiliary building essential cooling System heat load calculation, calculation number 13-MC-HA-051, Rev.1.5.P&I diagram, safety injection and shutdown cooling system, drawing number 13-M-SIP-001, Rev.19.6.Pr3.nc3ples of heat transfer, th3.rd edition, Frank Kreith, Intext Educational Publishers.

table A-2, Physical Properties of Some Nonmetals, page 635.7.The National Electrical Code 1987 Handbook, fourth ed'.tion, General Lighting Loads by Occupancies, table 220-3 (b), page 100.8.NAVCO Piping"Datalog", National Valve and Manufacturing Company, Pittsburg, PA.Ed3.tion No.10.9.Auxiliary building isometric, draws.ng number 13-P-SIF-201, Rev.21.10.Auxiliary builds.ng isometric, drawing number 13-P-SIF-203 Rev 23.26 2 I 28 29 30 11.Auxiliary building plan at elevation number 13-C-ZAS-110, Rev 16.12.Auxiliary building plan at elevation number 13-C-ZAS-112 Rev 4.40'-0", drawing 40'-0", drawing 31 33 13.Aux'.liary building plan at elevate.on 51'-6", drawing number 13-C-ZAS-116 Rev 17.14.Ingersoll-Rand pump drawing for HPSI pump, log N001-11.01-15-6 LAO 3998.I 1ISS

.1 f' CALCULATION SHEET PROJECT JQQ NO 18601-183 TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM NO 13-MC-HA-A02 SHEET NO.REV ORIGINATOR DATE CHECKER DATE REV ORIGINATOR DATE CHECKER DATE , I O>D I-bl z<L 0 10 12 13 14 17 18 19 20 21 22 23 24 15.ingersoll-Rand Pump Manual, log N001-11.05-1, HPSI pump data sheet and pump curve.16.Pump motor data sheets, log N001-11.05-7-2 17.Reliance Electric Co.drawing, log M721A-112-2 18.User's and Theoretical Manuals Verification Report, program RMHTUP-Room Heat Up, program number ME204 Rev.A1, Bechtel Power Corporation, San Francisco Power Division.19.Final, Safety Analysis Report, Palo Verde Nuclear Generating Station, Ammendment 17.20.Auxiliary Building Base Mat, Sections and Details, Drawing Number 13-C-ZAS-124, Rev.13.21.Detailed Design Criteria, Part III, System HA, HVAC-Auxiliary building, Rev 8.22.Detailed Design Criteria, Part III, System SI, Safety Injection and Shutdown Cooling System, Rev 5.23.Detailed Design Criteria, Part III, System EC, Essential Chilled Water System, Rev 3.26 27 28 29 30 31 35 36 I AO 9999.I 7/OS I t CALCULATION SHEET pRpJEcr ANPP Jps gp 18601-183 SU8JECT TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM Cp,l C gp 13-MC-HA-A02 SWEET NP./REV ORIGINATOR DATE CHECKER DATE REV ORIGINATOR DATE CHECKER DATE/Skg'-4-SE'>O)OI-"Z'1 II V.

OF RESULTS: 10 12 The transient temperature summary for the HPSI pump room air for the cases is shown below.For Case A, the temperature values can be used directly.For cases B and C, having the door open results in air flow in and out of the room.As explained on page 51 the average of the results is felt to best estimate the transient temperature profile when the room door is open.14 No HVAC and Door Closed No HVAC and Room Door Open 17 IS 20 21 22 23 24 26 26 27 28 29 30 31 Time Period 0 min 2 min 4 min 12 min 36 min 1 hr 2 hr 4 hr 6 hr 8 hr 12 hr 24 hr CASE A: Tem., F 75.93.34 104.10 117.79 124.76 128.66 135.64 145.37 152.80 159.07 169.57 193.35 CASE B: Tem., F 0 75 84.93 90.97 99.26 103.37 105.53 109.36 114.69 118.75 122;16 127.88 140.79 CASE C: Tem., F 0 75 87.77 95.42 105.64 110.74 113.50 118.40 125.22 130.43 134.80 142.14 158.72 Avg B 8 C Tem., F 86.35 93.20 102.45 107.06 109.52 113.88 119.96 124.59 128.48 135.01 149.76 35 36 I AO 3999,l 7/85 I(

CALCULATION SH EET.PROJECT JO8 NO 18601-183 CP,LC NO 13-MC-HA-A02 SUBJECT TRANSIENT TEMPERATURE STUDY FOR HPS I PUMP ROOM SHEET NO.REV ORIGINATOR PS&/lu.DATE s-aS-$$CHECKER DATE REV g-<Pi ORIGINATOR DATE CHECKER DATE.iO)13l WE+8.'V VI.ROOM HEAT-UP COMPUTER MODEL A.Model

(Ref 18)The room heat-up computer program, RMHTUP, program number ME204, version A1, can be used to study the room ambient air heat-up by the equipment heat or any other heat sources in the room.10!2 13 14 The temperature of room ambient air increases with time, due to the heat released from the equipment and other sources.'he heat generated within the room is transferred to the ambient room air, stored in the room enclosure (walls, ceiling, and floor)and transferred to the air outside the room.17 18 19 20 21 22 23 24 2S 26 27 28 29 30 31 The room walls are divided into a number of layers with incremental thicknesses for numerical computation by the computer program.ln this study, the value of imaginary thickness of first layer of concrete wall is selected as 0.01 ft and the multiplication factor of imaginary thickness of other layers is taken as 1.41.In other words,.the first concrete layer thickness is 0.01 ft (approx.1/8"), the second layer thickness is 0.0141 ft (approx.3/16"), third layer 0.01 X (1.41)ft, etc.The transient room temperature is determined from the heat balance equation, which balances the heat generated within the room and the heat transferred to the ambient room air, stored in the room enclosure and transferred to the outside air, as shown below: 3S 36 L AO 4994.I 7/45 1/

PROJECT CALCULATION SHEET JO8 Np 18601-183 TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM C/$lLC NP 13-MC-HA A02 SHEET NO.REV ORIGINATOR ysz//DATE 34'.Sg CHECKER 5.4.P'ATE REV ORIGINATOR DATE CHECKER DATE.IQ)OI-ILI z<L O QA/ALL QdgutP Q,//Isla AtR@0M.7BI3)G Clif, 10 12 13 14 EQUIP=AMB AIR+WALL+OUTSIDE AIR 18 19 20 21 22 23 24 WHERE EQUIP AMB AIR WALL Heat generated from equipment or any other source in the room, BTU/HR Heat transferred to the ambient room air, BTU/HR Heat stored in the room walls, ceiling and floor, BTU/HR 2 OUTSIDE AIR Heat transferred to the outside air, BTU/HR The room amb3.ent temperature and the wall temperature distribution are calculated at fixed time intervals.

In addition, total heat stored in the ambient a3.r and in the concrete walls and heat transferred to the outs3.de air are prov3.ded for each time interval.33 l AO$$9$il 1/$5 I

CALCULATION SHEET PROJECT Jp8 gp 18601-183 SU8JECT TRANSIENT TEMPERATURE STUDY FOR HPSI PEP ROON gp 13 MC-HA-A02 SHEET WP.REV ORIG IN A TOR/~M~~/g DATE-)g-djj CHECKER DATE REV ORIGINATOR DATE CHECKER DATE.lQ>131-Ill E<L 0 B.Input Required for Computer Model: The following information is required as input for transient temperature study in the HPSI pump room: 10 12!3 14 I 2.3.5.6.7.8.Initial room ambient temperature, degrees F Initial outside ambient temperature, degrees F Equipment and other heat generated in the room, BTU/HR Net room surface area, ft Net room volumeft Thickness of room enclosure, ft Density of room enclosure material, lbs/ft Thermal conductivity of room enclosure material, BTU/HR-ft-F 17 18 19 20 21 22 23 24 25 9.Specif ic heat of room enclosure material, BTU/lb-F 10.One period of time increment for calculation, min 11.Imaginary thickness of f irst layer of room enclosure, ft 12.Multiplication factor of imaginary thickness of other layers 26 27 28 29 30 38 36 I AO 9999.1 7/99  

CALCULATION SHEET PROJECT JpB Np 18601-183 TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOif CALC.Np 13 MC-HA-AO2 SHEET NP.Rav ORIGINATOR PZe4'ATE 3->II-2 CHECKER DATE REV S'-&Pi ORIGINATOR DATE CHECKER DATE>13I-I4 E cC IL LI C.Assumptions for the Computer Model 2.The room is simplified as an enclosed space bounded by the same thickness of walls, ceiling, and floors.The gross room volume is corrected for the volume 10 12 13 14 occupied by piping and equ3.pment.

3.The gross room surface area of the room enclosure 3.s corrected for the area occupied by equipment.

4.The enclosure walls, ceiling and floor are taken as a heat sink.D.Computer Model Limitations 17 18 19 20 21 22 23 24 25 26 27 28 29 30 1.The room enclosure walls, ceo,ling and floor must be cons3dered as having the same thickness and of the homogenous material.2.The a3.r temperatures outside the room must be considered as being the same and rema'.ning constant.3.The heat generated within the room must be considered as be3ng constant.No heat generated outside the room can be cons@dered.

E.Computer Model Output The following information 3.s provided 3.n the computer model output: 31 34 35 36 LAO 399$.1 7/$5 TAF QAT QST QOT Final room air temperature at each period, F 0 Heat stored 3.n the ambient az.r, BTU Total heat stored in the concrete, BTU Heat transferred to the outside air, BTU

CALCULATION SHEET ORIGINATOR DATE ORIGINATOR 3-05-8 5-6'a 8 PROJECT JOB NO 18601-183 SUBJECT TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM REV DATE CHECKER REV S54 DATE SHEET NO.CHECKER DATE NO 1 3 MC-HA-AO2 3 4 VII.STUDY: This s tudy is per f ormed f or the f ol lowing two cases: 10 12 13 A.B.Fluid temperature in the HPSI pipes of 225 F with no HVAC and room door closed.Fluid temperature in the HPSI pipes of 225 F with no HVAC and room door open.CASE A 16 17 18 19 20 21 22 23 24 FLUID TEMPERATURE IN THE HPSI PIPES OF 225 F WITH NO HVAC AND ROOM DOOR CLOSED: 1.Heat Loads: a.Electric Motors Heat Load: This heat load consists of the heat generated by the HPSI pump motor and ACU fan motor.1.HPSI Pump Electrical Motor Heat Load: 26 27 28 29 30 31 HPSI Pump design flow=850 gpm (REF 15)Pump design flow BHP=885 hp (REF 15)Motor efficiency, P=94.8" (REF 16)36 4 A43 3996,I 1/65

-~~~Se/4.'ATE r gv2c CHECKER 6 AJ.P/DATE$.~PS REV ORIGINATOR DATE CHECKER DATE.IO)Dl-W 0: U The pump and the motor are inside the HPSI pump room.The fluid is pumped to outside of the room.Motor lleat load=BHP X 2545 X~(1-)(REF 1, note C, table 30, chap 22, page 417)10 12 13 14 I 885 X 2545 X (1-0.948)BTUlHR 0.948 123,'545 BTU/HR ii.ACU Fan Motor Heat Load: 18 19 The essential ACU fan may be running without essential chilled water thru the essential cooling coils (See Assumption 15)21 22 23 24 26 26 ACU fan nameplate hp=5 (REF 17)Motor efficiency

CALCULATION SHEET PROJECT JOB NO 18601-183 TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM NO 1 3 MC HA-A02 SHEET NO.ORIGINATOR

/~z~/~i DATE-2e-'g CHECKER DATE REV ORIGINATOR DATE 9-~BI CHECKER DATE L'tp>Dl-bJ z 4 IL 0 From ref 1, chap 22, table 30, page 417, eff 5 X 2545 0.82 10 15,518 BTU/HR 12 13 14 Total motor heat load=123,545+15,518 139,063 BTU/HR 17 18 19 20 21 22 23 24 26 27 28 29 30 31 b.Lighting Heat Loads: The heat load is due to the lighting in the HPSI pump room.HPSI pump room area=(20'-6")X (17'-3")(Ref 11).2 20.5 X 17.25 FT 353.63 FT Typical lighting load for industrial buildings=2 watts/FT (REF 7)2 Room lighting load=(Room area, ft)X (2 watts/ft)X 3.41 BTU/HR-watt 353.63 X 2 X 3.41 BTU/HR 2412 BTU/HR 36 36 LAO 1999.1 1/99 ij CALCULATION SHEET JQ8 Np 18601-183 PROJECT TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM C<l C Np 13-MC-HA-A02 SHEET NP.l ORIGINATOR DATE-'>d'-~"d'HECKER DATE 5-zing'EV ORIGINATOR DATE CHECKER DATE I2.IQ OI-big 4 C 0 IO I2 I3 4/I7 IS 20 2I 22 23 24 25 c.Piping Heat Load: When the HPSI pump is operating; design basis cooling is provided by an essential Air Cooling Unit (ACU).Essential chilled water is recirculated through the ACU chilled water cooling coils.In the event that either the essential ACU or the Essential Chilled Water System fails, the pump room temperature will rise rapidly.The HPSI pump initially supplies cooling water from the refueling water tank.When that source is used, the HPSI pump recirculates water from the containment sump to remove decay heat in the core during the time period under study.It is assumed that the HPSI system is operating in both safety injection and long term recirculation modes during this time period.The HPSI piping in this room is used for one of these two operating modes.Therefore, all the HPSI piping in the room is used to calculate heat loads.26 27 28 29 30 3I 35 36 LAO 9998.I 7/SS  

PROJECT CALCULATION SHEET JOB NO 18601-183 TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM CALC NO 13-MC-HA-AO2 SHEET NO.e ORIGINATOR DATE CHECKER DATE REV ORIGINATOR DATE CHECKER DATE 0 I)DI-LI E g L 0 This heat load is due to the HPSI pump suction and discharge piping in the HPSI pump room.All of the process piping in this room is insulated.

The following equation can be used to calculate the heat flow thru insulated piping: 10 12 13 14 17 18 19 20 21 22 23 24 29 qs=to-ta rs log rs+Rs ro K (Ref 1, chap 20, eq 11, page 353)26 27 28 29 30 31 Nhere qs=Rate of heat transfer per square foot of outer surface of insulation, BTU per (hour)(square foot).Temperature of inner surface of insulation, degrees F 33 36 LAO 5994,1 7/55 J

CALCULATION SHEET PROJECT JOB NO 18601-183 TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM CALC NO 13-MC-HA-A02 SHEET NO.ORIGINATOR DATE CHECKER DATE REV ORIGINATOR DATE CHECKER DATE C iO)nI-LZ0 4l cC 10 12 13 ro k Rs Temperature of ambient air, degrees F Outer radius of insulation, inches Inner radius of insulation, inches Thermal conductivity of insulation at mean temperature, BTU per (hour)(square foot)(of per inch thickness)

Surface resistance, (hour)(square foot)(degrees F)per BTU.4 For suction and discharge piping: Fluid temperature or o=225 F (See Assumption 1)l7 18 19 20 21 22 23 24 Ambient air temperature or a=75 F (See Assumption 2)Surface resistance, Rs=0.25 (See Assumption 15)Jacket emissivity of the calcium silicate insulation

=0.85 e 100 Degrees F (Ref 2)26 Mean insulation temp=225+75=150 F 28 29 30 31 Thermal conductivity of calcium silicate insulation at 0 150 F mean temperature, K=0.40 BTU per (hour)(square foot)(F temp difference per inch thickness)(REF 1, 0 table 3B, chapter 20, page 364).33 36 I AO 9999.1 9I95

CALCULATION SHEET JO8 NO 18601-183 ,...PROJECT TRANSI NT TM'ERATURI'TUDY FOR HPSI PU.ROO.f l ORIGINATOR OATC CHCCKCR RCV OATC ORIGINATOR OATC CAL'C NO 13-.fC-HA-A02 n-SHEET NO CHCCK CR 0ATC cz 4'..4 S.~S-&y P JIM<HEAP Loh Gs (couT.)'I 0 I.PuM/'uc rioter PiPr~c v'H~P>w/', sue,rioh prp]~g/4'HE Woe q coHsrsys o p,re Foll obrrlr 4'Ps>r L/mE;l2 LWE'Jo.I PSZALOO 8;L REI=3J Love sizz=to"~H<o ir X)VSSE(.LQ

'PO III 7'CA'CESS, a 2 0 V'y Pe Oi'ilISu.LATrOrr=CALCiu~St Li C8 TE I6 PIPE 0 0,~/0.7~/REF 8J I9 20 21 2 2 2)24 25 26 29)0 Pf07'E: XNSLllgygg N 0 Da.ld ,'$+Pz.g2)/Q I 7~WF EX<7 IN('rVStlLA 7/04 7H/c<r~M F 4 Pit INq]buD F quI PWE+7 a+4 4EzEcTEc PER RE~g Z.xHI8Ir D SEc,7r0A 7ABca.D-~55 56

~8'I P FlP JECT DD CALCULATlON SHEET Jp8 Np 18601 183 CJI LC Np 13-MC PA-A02 8JEC, RA."SI:.NT TRACER'STREE S UDY FOR HDSI DI'MD ROOM SHE"T NQ.CV i ORIGINATOR OATC b->S-cQ CHCCKCR OATC RCV i ORIGINATOR OATC CHC KCR OA~C.CI uH sM.c71 nl PlPJNC Fo<io'PIPE 75/v 7b 2/o 7J 2-ti 7 375'.37x F<oR EQM/I T/OW ZgO~~oN PA QE IO 0 IIg 7 37<S 37S STAN/gq.g-pi~17 Id tO OQ7'St+E S~gPg~ggjCg Q 5 ZNSCCLA 7ION F 7/gluEAR F 7/2.3 86 F7~/tWeaR F7>, gg@7~/LiuEAR+<$5./g)57K//fg.LluE>R I 7]0 IAO)~'~,I)I~S

CALCULATION SHEET P.'L DD)q~AJcCT I CHCClC CR TRANS I=NT T&#x17d;F~'xiR S I L.DY~~/;vo/4 ORIGINATOR OATC I Jpg gp 18601 183 FOR HDSZ DI~ROOM OATC RCV I ORIGINATOR OATC CAt C.Np.13 MC v~AO SHEE NP.OAYC CHCCKCR u~tP 5OC71On1 S(DE 10/INK nfO.pIPE Sl z 6///4 8 H&j 7 Lu/D/~P/PF-LZN<V'//"LW~aR F7 F7~<~HR.plus H~7 LoAD B7A.IHR 51 s P szAZOo8///2-0 q5~I)5S 50 19 XO 7 H E PIPE/-EN4'u rNwog~ig V rOA i~~RO+j 4E/'/Z/I 7/ok//j L///o/Ig/T/g s//am~o~P'2.6 aS%9)0 SS S4 LAO)~9~,I 1i~s

~1 P ROJECT CALCULATION SHEET JQQ NQ 18601-183 TRANSIENT TEMPERATURE STUDY FOR HPSI PPiiP ROON CALC NP 13-MC-HA-A02 SHEET NO.REV ORIGINATOR o f.'g OATE CHECKER OATE REV OR I GIN A TO R OATE CHECKER OATE ,IO>aI-Ll ZO ERci 3g Z..PLLM/'iS Caa<CE'IPE~

K 7-/lP PPIL/P QiE Cliz<P E PiP/AI<I'IV'ea H PSZ POLYP BOO codsiJ7s oF 7'H-E F'scLOAii&g L(u'F>;]f.Lln E NO./P>ZA LOG'9 kAiD l PSrR L,/uO-L IVE sizf z Q SCfg ri<LCLA7/od 7H]~nggss lPO 1//.S IO 7'yP~OF ZNSu/g7/ag c Crt/C,,/Very Sl/./M7E I2 I3 Ii P/Pe g..p fRFF 8 Q I7 IS l9 20 2I<IV>ILLA'/Oht O.J)Q~Z-+(Z>g p I)p.LIuR uo.I p><A I-/0~II/wE'izE=2.<cH/go II LA 7/OAI THICKNESS/'5 PRew 22 27 2S 29 30 7yP~OF~~/~4(L17!0a c Cg<C,ggg ggL/CA7Z f/P<o.s=z-s7s<<>ML87I'ON O.g.=g 37'.(g>I,~)I S.S7S" 36 LAO 999~,I)II9

PROJECT CALCULATION SHEET JP8 NP 18601-183 TRA ISIENT T~ERATURE STUDY FOR HPSI PUMP ROON CALc No 13-NC-HA-A02 SHEET NO.PMe/7 g~2g-CKER OATE O'-SH REV ORICrlNATOR OATE CHECKER I2.IQ 0OI~z~L V 10 12 LIZZIE nI0 I PszAL,/gg I LIAISE SiZ P=P SC.II/$0~/><<<LA 7)on/THIu(IIIpza

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pRQJECT~P CALCULATION SHEET Jp8 Np 18601-183 CALC Np 13-MC-HA-A02 DATE REV OR I GlN A TO R TRA.'iSIE.tT T~ERATURE STUDY FOR HPSI PlPiiP ROON DATE SHEET NP.CHECKER DATE , IO>a+LI 0: U PiPe 10 y 5>7K S 2-<.CZ,7r 12 13+o A.375 2-I>I IS7r 16 17!8 19 20 2.6Z 7X g(k 6 l 7z I~j 8's-0 Qo~o 4$22 R6~I f 6'7a/q~rz~25 SuRs'Acz r)~~A OP'use.c.g Tio~27 28 29 30 3l k6'x I'Yl 6TA/h'll.glIJKA g f7'6.6'6 6tyu/g g.LgrzErlR LAO 399~I 1/IS

PRPJECT CALCULATION SHEET Jpg Np 18601-183 SUQJECT TRANSUDE tT TEMPERATURE STUDY FOR HPS I PUMP ROOM CALC gp 13-MC-HA-A02 SHEET NP.CHECKER DATE REV ORIGINATOR DATE CHECKER DATE P9Se,ji~~z-N c~e'4 caw.I Q>DI-W cC I2 0 FoR, 3 P]P E.lo<~~$3~S 2 I'E 10 s as..~)boas'90 16 17 18 19 20 2!22 23./D a 3 8 7W/le-i 7 ga7SZSE>cCR FR C E'RE A 0 F Se scCZA 7iON Ei x lO'FI l=7/l ISEAR/Z.7$F v/lxuSA<F7 25 27 28 29 30 3I)o'43~2 7W 8TQ i/g.LzazAq pr aS l3 07</PR.lzaSAiI S'7\

4 PROJECT (CALCULATION SHEET JOg NO 18601-183 Ug JECT TRAilS EENT T~ERATURE STUDY FOR HPS I PUMP ROON Cgl C NO 13-MC-HA-A02 SHEET NO.REV ORIOINATOR f~~/f"'ATE gg CHECKER OATE REV ORICINATOR OATE CHECKER OATE pox p Sis cuazc z~i>p L iA75 h/0 PiPE 51ZE/hl Pi/E L&kg 7H F7 HEA'T LoA D/L (NEAR F7 STM HR, LID F7'EA7 Lo/3 87'cC HR 10 12 IPsrALo't$

Ii g-o 5$e$5 JCg~$+5/t'szA L/oo 36-o gg 3S-~lO/17'I 8 19 20 21 22 16<Psrd L(os-psI'AL (g g 3" 5/-0" I/z-o ,...2 8'3 36 8'<~SI=/, FFo 2$"/371/2=33/'oisces//Rgg 25 27 28 29 50 PATE~4 L PI pill/Arp4~P/PK/&I17Hs sEg g~FEFE~c'E

PROJECT CALCULATION SHEET JO8 Np 18601-183 cALc Np 13-MC-HA-A02 SUSJECT TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM SHEET Np.REV ORIGINATOR j~f)~'ATE 3-2$'~"5 CHECKER DATE REV g-CPS'RIGINATOR DATE CHECKER DATE.tp Lli O I I2 0 d.Heat Dissipated by the HPSl Pump: 10 I/vsQLQ TIOH 12 13 The pump walls are assumed to be flat surfaces (See Assumption 10).16 17 18 The heat dissipated by the pump can be calculated from the following equation for flat surface: 19 20 21 22 23 24 qs=to-ta L+Rs (REF 1,chap 20, page 353, equation 10)25 26 27 28 29 30 31 Where L=insulation thickness, inch Per reference 2, the insulation used on the HPSX pump is mineral wool and is 2" thick.Therefore, L=2" At mean 150 F, the mean temp K=0.285 (REF 2, exhibit F, section 2C, para F.2.1E)Rs=0.25 (For details, see Assumption 16)35 36 an nnna~7<ay

PRpJECT CA LC U LATI ON S H EET Jp8 gp 18601-183 CALC Np 13-~C-HA-A02 SU8JECT TRANSIENT TEMPERATURE STUDY FOR HPSI PU".P ROON SHEET VP.REV O R I G IN A TO R DATE CHECKER C>.h/+I DATE-cg-N REV ORIGINATOR DATE CHECKER DATE ,4Q 4l CEu qs=225-75 2+0 25 0.285 20.64 BTU/HR-FT 10 From ref 14, Surface area of HPSZ pump=tt X 34 X 42.5=33.53 Ft 12 12 12 13 Heat dissipated by HPSZ pump 20.64 X 31.53 BTU/HR 651 BTU/HR 16 18 19 20 21 22 23 24 23 26 e.Total Heat Loads: The following is.the sum of the heat loads in the HPSI pump room: HPSI pump and ACU f an Electric motors heat load=139,063 BTU/HR Lighting heat load 2,412 BTU/HR Piping heat load 5,986 BTU/HR Heat dissipated by pump=651 BTU/HR 27 28 29 Total Heat Load 148,112 BTU/HR"I AO)994.1 3/9$

PROJECT C CALCULATION SHEET Jp8 Np 18601-183 Np 13-MC HA A02 U B J ECT TRANS I ENT TEMPERATURE STUDY FOR HPS I PUMP ROOM SHEET Np.REV ORIGINATOR DATE-2f-Q CHECKER DATE 4''se-g REV ORIGINATOR DATE CHECKER DATE.iO)D-IWI2 U I2 I6 20 2I 22 2S 27 26 29 A.HPSX PUPfP/Oops SCCgFAC,Z ggZA 9 VOL,O~E Q..@Ps~PUMP Roo/)avgFgce+gag.PPgg f Vh1/gd OW D I~E/I, Sg u/I/S/t/I/LxAfx g 2.o-6 x 17-3 X Z7-3 CAFE'l 4 Ra)HP>>Pu~P gom g a~o A coenee tuwzz (~!6"x>7-~3 4JI7H p/sx Pu&P/too+13 AND~oowA'o~~<~I.(zn-4>~J~l 7g G5 PuhfP+004 (gee n)7fgg SCrgggCE 4g&f gf'//I'Z S'HARel)aASL/'S couoiDEgop

/RE~=i7-3 Zs V.F<~Sgg,pAgE//I~EA=/7-g 5 Zo-g%078.L.SggFgcE ggEA~~@~3~zzo7 f'2-774FgE (S A<h/FLS cow 4!7+g-0 2-0 QEF//)Q~gNs/o~s LX~S 8=I 0////g 2.-0 p~uwE.oC as9 a7-'@uZVAZZ/vV

P ROJECT t'.CALCULATION SHEET Jpg Np 18601-183 CpLC Np 13-MC-HA-A02 U EJECT TRAi~SI ENT T~ERATURE STUDY FOR HPS I Pl&iP ROOi 1 SHEET Np.REV ORIGINATOR DATE CHECKER DATE REV O R I G I N A TO R DATE CHECKER DATE Co.Q.4-y@.tQ OI-4l g cC L'7o~AL NccA',CAca AAF A=~4'7~~~z>q~Fr<10 12 13@gal/pu AP F Look kgEA occ~p/E>8 V D M&I</0~4 AeD b1o 7oR 4E 7 (ldll-~o~)

ga s.+/2 l~16'I 7 IS 19 20 ZI 22 23 nfa 7.sgggg cz dR~~~R BFA7 vx.gnla Hwato&25 26 27 28 29 30 3l

P ROJECT CALCULATION SHEET JpB Np 18601-183 CALO Np 13-MC HA-A02 SUBJECT TRANSIEVT T~ERATURE STUDY FOR HPSI PUNP ROON SHEET Np.REV ORIGINATOR 0 ATE'~s-Q CHECK ER.Pf Pl OATE-Z&gg REV ORIGINATOR DATE CHECKER L.iO)gl-ILI V h.HP4I F'uP Roomy V0Zuz/ROD REC'/'3I'UPIP U<LVIVE-pT y/3V g g2 S p y y-,)'7t/2-zs sr Fr~IO~APL(u<Vycv~g-Ti x I-o.qs-+7 9 l2 l3+As'LA TE veLclNE (do>9'so s r~37,b I6 I7 I8 I9 Ho7og VaCuAE'$g~gI 40'3 x l2-2I 22 23 25 76 27 26 25 30 31 (9S~oy F7~ZaigP,r~C Pu~I W P-~os(><<g p.gg~o'V~~~'~35 36 li PROJECT CALCULATION SHEET JOQ NO 18601-183 CALC NO 13-MC-HA-A02 UBJECT TRAilSIEVT TEMPERATURE STUDY FOR HPSI PUMP ROO.f SHEET NO.0 REV ORIGINATOR f>Se.//DATE-~I-JS CHECKER 6 4.N OATE REV ORIGINATOR DATE CHECKER OATE.iO>OI-bJ L'p<pz~g pol.uw E zan 77/E/oL(oui~<r<<<<<q~~(Z<s~a.s-,~y,za,~y

~~~sag THE HP~/Oat.Q(A(g No f(PE SI ZE gQ5gQ7/08 p(pp O.g),~~4'l8 I Psx A Loop ll lo jgi7J/2--0 10 (Psl'A Lo)p II g-0 12 13 16 17 19 20 21 22 25 26 II g(-o I p~g g l (00 I/MAL (us.S I-0 I I I (2-0 (0 5 IP>zA L(o<-fl~ugLuHE oF (Psz A Lou I'-=~x()fP~/Q7Z g I>V r~~~, 2.V z.~6 sr~/gqLuME oF IPs<A Lo99-~~x(7'~)(2-27 26 29 voLue~os(7 J-)3<-o (>//op/7 30 3l 2 I rf I(oLugE OF ('P~~"~(u+--~(/w 8 oV F>~e VO(U(I((t<~(PS'~3 L(0$-P>//g$1 y (>-o=7 Z2/+

PROJECT CALCULATION SHEET JQQ PO 18601-183 gO 13 MC-HA A02 SUSJECT TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM SHEET NO.REV ORIGINATOR 1 8m~//I DATE CHECKER DATE REV OR I GIN ATO R DATE CHECKER DATE.iO)Ol-IiI Z 4 L 0 3.Input Data: Case A 10 The 2.3.'.following input data for the computer model is used: Initial room ambient temp.=75 F fAssumption 2]0 Initial outside ambient temp.=75 F[Assumption 3]Equipment and other heat generated in the room=148,112 BTU/HR[See Section VII.A.1.e]

Net room surface area=2232 FT[See Section VII.A.2]2 Net room volume=9152 FT[See Section VII.A.2]2 12 13 14 6.Thickness of room enclosure=2.75 FT[Ref 11]7.Density of room inclosure material=144 LBS/FT 3[Ref 6]17 18 8.9.Thermal conductivity of room enclosure material 0.54 BTU/HR-FT-F[Ref 6]Specific heat of room enclosure material=0.2 BTU/LB-F[Ref 6]19 20 21 22 23 24 25 10;One period of increment for calculation

=2 min fAssumption 18]11 Imaginary thickness of f irst layer of concrete enclosure 0.01 FT[Assumption 19]'2.Multiplication factor of imaginary thickness of other layers=1.41[Assumption 19]26 27 28 29 30 3'I 34 36 I AO 3998,1 7/85

PROJECT CALCULATION SHEET JO8 NO 18601-183 OP,I C NO 13-MC-HA-A02 SU8JECT TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM SHEET NO.REV ORIGINATOR f'.m~/4 DATE CHECKER DATE REV ORIGINATOR DATE CHECKER DATE IL.)Q>nI-bl z<0: 0 4.Results: Case A 10 The transient temperature for the HPSI pump room ambient air obtained from the computer output, is shown in Figure 2.The transient temperature output, Appendix A, shows that without any HVAC and the door closed, the calculated temperature in the HPSI pump room will be as follows: 12 13 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 0 min 2 min 4 min 12 min 36 min 1 hr 2 hr 6 hr 8 hr 12 hr 24 hr 75 93.34 104.10 117.79 124.76 128.66 135.64 145.37 152.80 159.07 169.57 193.35 LAO 5998<1 1/85 l

PRpJECT~P CALCULATION SHEET JpB Np 18601-183 SUBJECT TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM CALC Np 13-MC-HA-A02 SHEET NP.REV ORIGINATOR j's~e.4.'ATE CHECKER DATE REY ORIGINATOR DATE CHECKER DATE L IQ)OI-14 z<I2 0 VII.B CASE B FLUID TEMPERATURE IN THE HPSI PIPES OF 225 F WITH NO HVAC AND ROOM DOOR OPEN: 1.Air Flow Due to Temperature Difference:

10 When the temperature in a building or a room is different fro that outside, a pressure difference between the inside and th outside occurs as a result of the difference in air density, i.e.due to the chimney effect.12 13 14 The air flow dueto the temperature difference is calculated follows: 17 pc=0.52ph (1 1)[Ref 1, ASHRAE Chapter 19, Page 334 To Ti equation 2]20 21 22 24 Where pc p h To pressure difference across room enclosure due to chimney effect, inches of water absolute pressure, psi.distance from neutral zone, feet absolute outside temperature, F absolute room temperature, F 0 ,26 27 LAO-5999.l 9/55

PROJECT CALCULATION SHEET JOB Np 18601-183 CpLC Np 13-MC HA AO2 SUSJECy TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM SHEET NP.REV ORIGINATOR DATE CHECKER DATE REV ORIGINATOR DATE CHECKER DATE.lD)DI-bJ L'The door opening is 6'-6" X 3'-3"[Ref 13].Therefore, h=3'-3" (1/2 the height, assumption 14)10 Assuming room temperature of 140 F and outside tempera.ture of 90 F,[Assumptions 20 and 21], the pressure difference, pc 0 0.52 X 14.7 X 3.25[1-1]x 460+90 460+140 12 13 14 0.52 X 14 7 X 3.25[1-1]550 600 0.0037641 inches of water 17 I8 I9 20 21 22 23 24 25 The flow velocity can be expressed equivalent to a head as: pv=0.000482V[Ref 1, chap 19, page 333, eq 1]2 Where pv=velocity head, inches water gauge V=air velocity, miles per hour Thus, 0.0037641=0.000482V or V=2.80 miles/hr.velocity 26 27 28 29 30 31 34 35 36 Quantity of air Q Where Q LAO$998il 7/SS flow through door opening: EAV (Ref 1, chap 19, page 344,equation 6)air flow, cfm f ree area of the opening, f t (1/2 height x 2 width, assumption 14)air velocity, feet per minute=miles per hour X 88 effectiveness of opening (0.50 to 0.60 for perpendicular flow) l PROJECT CALCULATION SHEET JO8 NO 18601-183 CA LC.NO 13-MC-HA-A02 SUBJECT TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM SHEET NO.REV ORIGINATOR SWlh DATE"-2f g'HECKER DATE REV-Zd'-gP ORIGINATOR DATE CHECKER DATE~0>os-M z cf L V Half of the door opening is assumed for flow into the room and the other half for flow out of the room[See Assumption 14]In addition, E=0.50 is used 8 Therefore, Q=0.5 x (3.25 x 3.25)x (2.80 x 88)1301 CFM 10 11 2.Heat Loads with Door Open-Case B!2 f3 14 17 18 19 20 21 22 23 24 25 The heat load generated within the room is the same as in Case A.Nith the door open there is energy transport from the room as a result of the air flow.This energy transport from the room is modelled as a constant over the 24 hour period of interest and is calculated as follows: Air flow due to open door=1301 CFM Heat removed=1.08 X CFM X (Temp Difference)

BTU/HR 77,858 BTU/HR 36 1 AO$999.1 7199

CALCULATION SHEET P ROJECT JOQ Np 18601-183 SU8JECT TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM REV DATE DATE REV CHECKER O R I G IN A TO R ORIGINATOR DATE SHEET Np.CHECKER DATE CALC Np 13-MC-HA-A02 f~~(1/.2d'-BP BIO)O I-hip<L'3.Input Data: Case B All input data for Case B is the same as for Case A on=page 42 except for item j)3, Room heat load, which is 77,858 BTU/HR.4.RESULTS: Case B 12 13 The transient temperature for the HPSI pump room ambient air, obtained from the computer output, is shown in Figure 3.The transient temperature output, Appendix B, shows that, without any HVAC and the pump room door open, the calculated temperature in the pump room will be as follows: 16 18 19 20 21 22 23 24 25 26 2l 28 29 30 Time Period 0 min 2 min 4 min 12 min 36 min 1 hr 2 hr 4 hr 6 hr 8 hr 12 hr 24 hr Tem era ture F 0 75 84.93 90.97 99.26 103.37 105.53 109.36 114.69 118.75 122.16 127.88 140.79 35 36 I AO S99d.1 7/85 I

CALCULATION SHEET PROJECT JOB NP 18601-183 REV ORIGINATOR DATE CHECKER DATE 5-Zd'-Pi REV ORIGINATOR SUBJECT T~SZENT TEMPERATURE STUDY pOR NpSZ p&p ROOM DATE CALC.NQ.13 MC-HA-A02 SHEET NQ.CHECKER DATE.IQ 0DI bl E cC L 0 I VII.C CASE C: Verification of Average HPSI Room Temperature:

10 The average room ambient temperature was assumed to be 140 F for case B.The computer output for the case B (Appendix B)shows that the room temperature is 128 F after 12 hours.It is apparent that the average heat removed by the chimney effect is slightly over estimated and that the final temperature may be slightly underestimated.

To establish an upper limit, the chimney effect was recalculated for 128 F.13 17 I8 19 20 21 22 23 24 2S 1.Air Flow due to Temperature Difference:

Case C.Using the methodology used in case B, the pressure difference, air flow and corresponding heat load are recalculated, due to temperature difference, with room temperature 128 F and outside temp 90 F (same as before): 0 pc=0.52 x 14.7 x 3.25[1-1 1 x[460+90 460+128]0.52 x 14.7 x 3..25[1-1][550 588]0.0029191 26 27 28 29 30 31 Calculating an equivalent air velocity and flow as before: 0.0029191=0.000482V[Ref 13, chap 19, page 333, eq 1]2 Air velocity, V=2.46 miles/hour Air flow, 9=0.5 x(3.25 x 3.25)x (2.46 x 80)CFM 1143 CFM 36 36 LAO 5991,l 1/55

REV ORIGINATOR DATE CHECKER~4'ATE REV ORIGINATOR CALCULATION SHEET PROJECT JpB Np 18601-183 SUBJECT TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM DATE SHEET Np.CHECKER DATE~iO)DI-4l z 4 LL 0 CAI C Np 13-MC-HA-A02 2.Heat Load with the Door Open: CASE C Heat removed through the open door=1.08 x 1143 (128-90}1.08 X 1143 X 38 46,909 BTU/HR Net heat load with door open 148,112-46,909 101,203 BTU/HR 10 12 13 14 3.input Data: Case C All input data for Case is the same as for Case A on page 42 except for item I 3, Room heat load, which is 101,203 BTU/HR.4.RESULTS Case C'18 19 20 21 22 23 24 26 27 28 29 30 31 Using this heat load, computer model is again run.The result of this computer run, Appendix C, is plotted on Figure 3.It indicates that the temperature after 12 hours is 142 F and.th 24 hour temperature is 158.72 F.The transient temperature for the HPSI pump room ambient air, obtained from the computer output, is shown in Figure 3.The transient temperature output, Appendix C, shows that, without any HVAC and the pump room door open, the calculated temperature in the pump room will be as follows: 35 36 (I 1 l CALCULATION SHEET ORIGINATOR CHECKER ORIGINATOR 9 O'-R'ROJECT JPg NP 18601 183 TRANSIENT TEMPERATURE STUDY FOR HPSI PUMP ROOM REV DATE DATE REV sent'v-sf-gg p DATE CHECKER DATE.IQ>pk 14 Z g 0: 0 CA(C NP 13-MC-HA-A02 SHEET NO SO 4.RESULTS CASE C (Continued) 10 12 13 14!'17 18 19 Time Period 0 min 2 min 4 min 12 min 36 min 1 hr 2 hr 4 hr 6 hr 8 hr 12 hr 24 hr Tem erature F 0 75 87.77 95.42 105.64 110.74 113.50 118.40 125.22 130.43 134.80 142.14 158.72 21 22 23 24 2$26 27 28 29 30 31 34 35 36 I AO)998.1 7(SS