ML18038A200
| ML18038A200 | |
| Person / Time | |
|---|---|
| Site: | Nine Mile Point  |
| Issue date: | 08/22/1986 |
| From: | Mangan C NIAGARA MOHAWK POWER CORP. |
| To: | Adensam E Office of Nuclear Reactor Regulation |
| References | |
| (NMP2L-851), 1989G, NMP2L-0851, NMP2L-851, NUDOCS 8608260141 | |
| Download: ML18038A200 (556) | |
Text
REQUL ORY INFORMATION DISTR IBUTL lu SYSTEN {R IDS) lP CCESS ION NBR: 8608260141 DOC. DATE: 86/08/22 NOTARIZED: NO DOCKET
, ACIL: 50-410 Nine Nile Point Nuclear Station> Unit 2> Niagara Noha 05000410 AUTH. NANE AUTHOR AFFlLIATION NANQAN> C. V. Niagara Nohaell Power Corp.
REC IP. NANE RECIPIENT AFFILIATION ADENSWi, E. Q. BWR Prospect Directorate 3
SUBJECT:
Fortoards marked-up FSAR pages to shoto necessary changes> in addition to 860819 submittal. Summary of changes h explanation of each change to aid review of matl included.
W/affidavit dc 26 ove1 size encls.
DISTRIBUTION CODE: B001D COPIES RECEIVED: LTR ENCL SI ZE:
TITLE Licensing Submittal: PSAR/FS*R Amdts Zc Related orrespondence NOTES REC lP lENT COPIES RECIP I ENT COP IES ID CODE/NANE LTTR ENCL ID CODE/NAPPE LTTR ENCL BWR EB BMR EICSB BWR FOB BMR PD3 LA BWR PD3 PD HAUQHEY> N 01 2 2+
BWR PSB BMR RSB 1 p INTERNAL: ACRS 41 ADN/LFNB ELD/HDS3 IE FILE IE/DEPER/EPB 36 IE/DGAVT/GAB 21 NRR BMR ADTS NRR PMR-B ADTS L NRR/DHFT/NTB REQ F 04 RQN1 DAl'1I/NIB EXTERNAL: BNL{Af'1DTS ONLY) 1 g DNB/DSS {ANDTS) 4 03 02 LPDR NSIC 05 1f NRC PDR PNL QRUEL> R 1 SM.
TOTAL NUi'ABER OF COPIES REQUIRED: LTTR 36 ENCL 31
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NIAGARA MOHAWK POWER CORPORATION/300 ERIE 8OULEVARD WEST, SYRACUSE, N.Y. 13202/TELEPHONE (315) 474-1511 August 22, 1986 NMP2L 0851 Ms. Elinor G. Adensam, Director BNR Project Directorate No. 3 U.S. Nuclear Regulatory Commission 7920 Norfolk Avenue washington, DC 20555
Dear Ms. Adensam:
Re: Nine Mile Point Unit 2 Docket No. 50-410
'As a result of Niagara Mohawk's verification of the Final Safety Analysis Report for Nine Mile Point Unit 2, we are submitting Final Safety Analysis Report pages marked to show the necessary changes. These changes are in addition to those in our August 19,. 1986 submittal.
Generally, these changes are minor and do not affect the Safety Evaluation Report. However, where a change affects the Safety Evaluation Report, this is indicated. He have provided a summary of the changes and an explanation of each change to aid review of this material. Niagara Mohawk would appreciate your expeditious review of these items.
Typed versions of these changed pages will be provided as soon as possible. These changes will be included in a subsequent Final Safety Analysis Report update.
Although the majority of the changes submitted in this letter have been verified by our Compliance and Verification Department, the verification of some items have not been completed because of problems encountered in retrieving some of the supporting documents., The verification of these items will be completed as expeditiously as possible,,and we will notify you if this results in any change to this submittal.
'ery truly yours, Senior Vice President WHB/ar 1989G xc: N. A. Cook, NRC Resident Inspector Project File (2) 8608260141 860822 PDR ADOCK 05000410 A PDR
I C
UNITED STATES OF AMERICA NUCLEAR REGULATORY COMMISSION In the Matter of Niagara Mohawk Power Corporation ) Docket No. 50-410 (Nine Mile Point Unit 2) )
AFFIDAVIT C. V. Man an , being duly sworn, states that he is Senior Vice President of Niagara Mohawk Power Corporation; that he is authorized on the part of said Corporation to sign and file with the Nuclear Regulatory Commission the documents attached hereto; and that all such documents are true and correct to the best of his knowledge, information and belief.
Subscribed and sworn to before me, a Notary Pyblic in and for the State of New York and County of , this ~~ day of 1986.
Notar Public in and for a County, New York My Commission expires:
CHRISTINE AtISTIN Notary Public in the State of New York ualif>ed in Onondaga Co. No. 478768
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SUMMARY
OF HANGES
~Chan e SER Tech. Spec.
~Pa e Chan e Descri tion Justification Code ~Im act Im act Table 1.3-3 Change the design environmental This change is made to be No No Page 2 of 3 temperature of the suppression consistent with design chamber from 275'F to 270 F, document.
Page 1.10-64i and Incorporate radiation values Final as-bui 1 t calculations E No No Table II.B.3-1, to replace "later's" in text. are now included.
pages 1 and 2 Table 2.2-8 and Change toxic chemical analysis Thi s change ref ects the 1 No No III.D.3.4-1 values to make tables correct values for the consistent. results of the toxic chemical analysis.
The allowable operator times either remained the same or increased.
Therefore, the results are essentially unchanged.
Table 2.2-9 Change the ambient temperature These are typographical No No from "33 C" to "32 C" and the corrections to the table.
vapor density from 1.55 x 10~ g/cm3 to 1.55 x 10-3 g/cm>.
Page 2.5-17la Changed "all the collected water" Clarification of actual No to "the collected water" system performance.
Figure 2.5-150 Remove Vs from the figure. As a matter of clari- No No fication, remove Vs.
As shown, the information was unclear.
Page 3.1-24 Change "two" to "one" control This change is based upon No No rod notch. compliance review to NEDE 2149B.
(1964G) gg( c 6/ I
SUMMARY
OF CHANGES C~han e SER Tech. Spec.
~Pa e Chan e Descri tion Justification Code ~Im act t Table 3.2-1 Page 1 of 26 Change the classification of reactor vessel stabilizer and reactor vessel insulation from "I" to "NA" for electrical
'hese changes are correction of errors in the table.
E No No classification and from "NA" to for Seismic Category.
Page 3.6A-15 Change "S" to "Sh" Thi s i s typographi cal No No correction.
pageos Table 3.8-4 Insert revised table. This change was erroneously E No No Page 2 of 4 changed to the wrong version of the It is now up to date.
Table 3.9A-12, Remove valves from table. The These valves are no longer E No No Pages 1 and 9 valves include 2CCP*MOV22A,B; used as active valves in the of 21 2CCP*MOV93A,B; 2CCP*RV82A,B,C,D; design. These valves normally 2CCP*RV83A,B;2CCP*RV84A,B'CCP*RV85A,B;2LMS*SOV156 closed or used for pressure boundary only.
Table 3.9B-2q Change the loads on the These changes are made E No No discharge nozzle of the to be consistent with design Standby Liquid Control Tank. document.
Table 5.2-1 Insert Code Case N-377 on the This change was erroneously E No No Page 8c of 8 Table. removed from the FSAR but we still intend to use this code case.
Table 5.4-2 Change the capacity required/ These changes are made to No No actual for valves. be consistent with design documents.
(1964G)
SUMMARY
OF CHANGES C~han e SER Tech. Spec.
~Pa e Chan e Descri tion Justification Code ~tm act Page 5.4-34a, Various descriptive changes These changes clarify the No 5.4-34b, 5.4-34c to total developed head cal- capability of the Alternate culation and flow rate of the Shutdown Cooling System.
Alternate Shutdown Cooling.
System.
Table 6.1-1 Delete the flow diverter doors The flow diverter doors No No Page 2 of 2 from the table. are not pressure retaining and therefore do not belong in Table.
Page 6.2-55b Change the equation for bypass This change is made to be No No leakage rate. consistent with design document.
Table 6.2-3 Change the design environmental This change is made to be No No Page 1 of 2 temperature of the suppression consistent with design chamber from 275'F to 270 F. document.
Table 6.2-33 Change the data on subcompart- These changes are made to No No and Table 6.2-34 ment vent path description and be consistent with design blowdown data under recircu- documents.
lation suction line break.
Table 6.2-54 Change the reactor building These changes are made to No design and performance data. be consistent with design document.
Table 6.2-56 Change feedwater valve MOV21B The change to the feed- No No Page 2 of 24 from Division II to Division I water valve corrects a and add penetrations Z-5c and typographical error.
Z-61 including their contents The two penetrations and to the table. their contents are in-advertently omitted from Amendment 27 of the FSAR.
(1964G)
SUMMARY
OF CHANGES
~Chan e SER Tech. Spec.
~Pa e Chan e Descri tion Justification Code ~Im act Im act Table 6.2-56 Change TIP N2 purge line to NRC requested that the No No Page 7 of 24 a solenoid valve. outside N2 purge line be changed from a check valve to a solenoid valve to meet 10CFR50 Appendix A.
Table 6.2-64 Change the estimated quantity This change is made to No No of insulation used in drywell revise estimated values to actual quantity. to as-built values.
Figure 6.2-42 Replace the "deleted" figure This figure is added to No No with the attached figure for show the capability of approximate spray coverage the containment spray in suppression chamber.
Figures 6.2-70 Delete the figures. These figures are deleted No No Sheet 21 of 43 because the text in Section and 6.2-86. 6.2 that referenced to those figures are deleted. These figures are shown in the figures of Section 9.3 of the FSAR.
Page 6.5-9 Delete the sentence that The rated flows for drywell E No No mentioned the drywell and and suppression chamber as suppression chamber sprays mentioned in FSAR page rated flows. 6.2-46a.
Figures 6A.4-40 Replace the figures with The new figures reflect No No and 6A.4-41 attached new figures. actual design.
Page 7.1-7 Change FSAR to committ to set- Our letter 40604 dated No No point methodology in FSAR. 2/7/86 committed to inclulde this in the FSAR.
(1964G)
SUMMARY
OF HANGES
~Chan e SER Tech. Spec.
~Pa e Chan e Descri tion Justification Code ~Im act t Table 7.5-1 Change control room/outside Actual design use 2 No No Page 7 of 14 differential pressure and recorders for special overall differential pressure fi ter train flow.
1 to special filter train flow. Differential pressure is available on another recorder.
Page 8.2-24c Change some of the degraded These changes are made No No voltage relay set points. to be consistent with Technical Specifications.
Table 8.2-1 Expand discussion of footnote 9 This change clarifies the No No Page 4 of 4 on 2025KVA running load. basis for 2025KVA running load:
Table 8.3-1 Change various values These are vendor supplied No No Pages 1 to 13 diesel generators loads. values which reflect as-Table 8.3-2 bui 1 t condi tion.
Pages 1 to 11 Table 8.3-5 Table 8.3-6 Table 8.3-4 Add values that have been This table is changed ,No No Pages 1 to 60 designated "later" and update to update the Class 1E existing information to the load per as-built conditions.
Class lE loads.
Page 9.1-10 Change "negative" to "positive'-'he a'ctual effect of the No No addition of the channels based upon the reactivity analysis is positive. This corrects this page.
(1964G)
SUMHARY OF CHANGES
~Chan e SER Tech. Spec.
~Pa e Chan e Descri tion Justification Code ~Im act Page 9.1-29 Revise description of lifting Sling assembly is proof E No No slings and strong backs. tested at 150 percent rated load. The slings are designed with safety factor of 3 times the rated load but not all slings are rated at 125 tons.
Sling assemblies will be used to move other equipment.
Spreader beams are used in lieu of a lifting cruciform.
Figures 9.1-19 and Revision to figures. Revision to these figures No No 9.1-20 to match design drawings.
Page 9.2-9 Remove service water discharge Continuous monitoring of No No pH and conductivity indications. pH and conductivity is not required.
Tables 9.2-1 Replace Tables 9.2-1 and These changes are made to No No and 9.2-2 9.2-2 with the attached support the Technical Tables 9.2-1A, 9.2-1B, and Specifications.
9.2-2 with new formats to show required service water flows for Division I, Division II, and normal operation.
Table 9.2-3 Delete ADS air compressor The ADS air compressor No No Page 1 of 2 from components being is not used because the ADS supplied with RBCLCHS uses the instrument air.
(1964G)
SUMMARY
OF CHANGES C~han e SER Tech. Spec.
~Pa e Chan e Descri tion Justification Code ~Im act Page 9.3-11 Change "172 psig" to approxi- This change is made to be No No mately "175 psig" for nitrogen consistent with other FSAR gas to the ADS. sections and logic diagrams.
Page 9.3-35 Remove "locally". Insert The actual location of the E No "utilizing switches in the switches are in the control main control room." room.
Page 9.4-14 Remove "smoke is detected in This change reflects actual E No No computer room." design in the logic diagram.
Pages 9.4-44 and Change the description of the This change reflects the No No 9.4-45 post accident monitoring indi- logic shown in Figure 9.4-13 cators to reflect Figure 9.4-13. previously provided in Amendment 23.
Pages 9.5-38, Change the description of the These changes reflect as- No 9.5-38a, and diesel generator compressed built condition.
9.5-45 air starting system.
Figure 9A.3-3 Change the fire area designation The change reflects actual No No in the figure. configuration of the fire designation.
(1964G)
SUMMARY
OF CHANGES
~Chan e SER Tech. Spec.
~Pa e Chan e Descri tion Justification Code ~Im act Im act Figure 9A.3-14 Replace reference to page 1 of Page 2 of the figures=are No No Pages 1 and 2, the figureswith door identi- deleted. The information Figure 9A.3-15 fications. Delete page 2 in page 2 of the figures Pages 1 and 2, of the figures. are already provided in Figures 9A.3-16 Table 9A.3-17.
Pages 1 and 2, Figures 9A.3-17 Pages 1 and 2.
Table 9A.3-16 Modify existing information These changes reflect as- No No Pages 1 and 2 in the area of fire loading. bui lt condition.
Table 9A.3-17 Delete reference to radiation This change reflects as- No No Pages 1 to 3 shield and pressure tight bui lt condition.
for special purpose doors.
Expand table to incorporate additional comparision of non-labeled doors.
Page 9A.3-42 Change the description of the This change reflects the No door opening. as-built condition.
Page 9A.3-44 Remove the statement on floor Floor and equipment drains N No No and equipment drains in areas are not provided in these protected by total flooding areas to preclude the loss gaseous suppression systems. of gaseous suppression agents.
(1964G)
SUMMARY
OF CHANGES .
~Chan e SER Tech. Spec.
~Pa e Chan e Descri tion Justification Code ~Im act . ~Im act Tables 9B.6-1, Update various pages of the These changes are made to No No 9B.6-3, 9B.8-1 and tables in the area of fire be consistent with 9B.8-2 area/subarea and fire zone Section 9A of the FSAR.
identification. There is no safe shutdown effect.
Page 10.2-3a Delete the statement of 0.10 This 0.10 second closing No No second closing time for power time has not been verified.
assisted nonreturned valves in the extraction lines.
Page 11.2-17 Change "13,400" gpm to "30,428", These changes are made No No and "2.67 x 1013 cc/yr" to to be consistent with "6.05 x 1013 cc/yr" and Table 11.2-5 previously change the average liquid submitted. The changed radwaste influent and effluent values are consistent flow. with FSAR Table 11.2-5 No No and supported by design document.
Page 11.3-5 Change "vacuum pump shutdown" These changes reflect the No No to "vacuum pump" and delete as built design.
"auto switchover to a standby train" for the offgas control panel.
Table 11.4-4 Change the flow capaci ty of These changes are made No Page 1 various solid radwaste to be consistent with equipment. design documents.
Table 14.2-63 Add a reference, NFPA 12-1985, This change clarifies the No No Pages 1 and 2 to the test procedure 3 for requirement of the test co'ncentration tests. procedure.
(1964G)
SUMMARY
OF F ANGES
~Chan e SER Tech. Spec.
~Pa e Chan e Descri tion Justification Code ~Im act Im act Table 14.2-77 Change acceptance criteria ¹4 The design capacity of the E 6-21 6-4 to match FSAR changes described standby gas treatment is 6-40 on page 6.2.57d. required to meet Section 6.2 6-14(SSER 3)
Table 14.2-129 Change the overspeed setpoint The words in the FSAR have E No No to match the Technical been modified to match the Specifications. Technical Specifications.
Table 14.2-225 Insert page 3 of 3 of Table This page was previously No No 14.2-225. deleted.
Questions and Change instrument numbers for These changes reflect May affect No Responses compliance with Reg. Guide 1.97. recent as-built review supplement 4 Table 421.36-1 of compliance with Regulatory Guide 1.97.
Questions and Change the response section This change clarifies the No No Responses from ". . . "T" off an existing function of the high-F421.39(7.6) reactor vessel pressure pressure top connection transmitter . . ." to ". of this transmitter.
directly senses reactor vessel pressure .
Table 430.50-1 Change "1.5" to "1.25" to meet This change is made to No No ASME Section III. respond to NRC i tern re-quested to meet ASME Section III Class II.
ASME Section III requires piping be tested to 1.25 design pressure.
(1964G)
Nine Nile Point Unit 2 PSRR ThBLE 1.3-3 (Cont)
HNP QPPSS Ziaaer La Salle Uni~g Uit2 Q Unit 1 Units 1 2 Suhaergence.of vent pipe helov 9.5 ain 11.67 ain 10 12 suppression pool surface, ft 11.0 aax 12.00 aax Design environaental teaperature 340 340 340 of dryvell, OF Design environaental teaperature. 275 275 275 of pressure suppression chaaher, oP Dovncoaer vent pipe 1.37< +> 1 9 2 ~ 17 1 9 pressure loss factor Break area/total vent area 0.0108 0 0105 0 008 0 0105 Calculated aaxiaua pressure 39. 7 34 7 40.4 34 after blovdovn to dryvell, psig Calculated aaxiaua pressure 34. 0 28 0 35.6 28 in suppression chaaher, psig Calculated aaxiaua initial 50 35 50 pressure suppression pool teaperature rise, 4P Leakage rate, ~ free voluae/day 1 1 B 200oF 0 5 B 200oF 0. 635 0 at 45 psig and 340oP
@Rcpt guggjBg gSegtioRs 3.8.4~ 6.2)
Type Controlled Controlled Controlled Controlled leakage, leakage, leakage, leakage, elevated elevated elevated elevated release~ >> release release release Construction Lover levels Reinforced Reinforced Reintorced Rein forced concrete concrete concrete concrete Upper levels Steel super- Steel super- Steel super- Steel super-structure and structure and structure and structure and siding siding siding siding Roof Steel decking Steel decking Steel decking Steel decking haendaeat 17 2 of 3. January 198'
0 Nine Mile Point Unit 2 FSAR 10 Ci/gm to well below the maximum level that can be tolerated at the normal reactor sample station.
The counting room used for post-accident sampling analysis is located in Unit l. It is surrounded by concrete walls approximately 3 ft thick. The emergency ventilation system inlet duct for this room is 1500 ft from the Unit 2 stack.
It has particulate filters. Assuming containment isolation, background radiation levels are predicted to be ~ater Illraajhr.
M,3 To demonstrate the effect of background radiation, a Cs-137 source was counted with a 5 mR/hr background level from a Eu-152 source. The Cs-137 was counted with an accuracy of 10 percent, which is well within the factor of 2 requirement.
Criterion 10 Accuracy, range, and sensitivity shall be adequate to provide pertinent data to the operator in order to describe radiological and chemical status of the reactor coolant systems.
Clarification 10 The recommended ranges for the required accident sample analyses are given in Regulatory Guide 1.97, Rev. 2. The necessary accuracy within the recommended ranges are as follows:
Gross activity, gamma spectrum: Measured to estimate core damage these analyses should be accurate within a factor of 2 across the entire range.
- 2. Boron: Measured'o verify shutdown margin.
In general, this analysis should be accurate within
+5% of the measured value (i.e., at 6,000 ppm B the tolerance is +300 ppm while at 1,000 ppm B the tolerance is +50 ppm.) For concentr'ations below 1,000 ppm, the tolerance band should remain at
+50 ppm.
- 3. Chloride: Measured to determine coolant corrosion potential.
Amendment 10 1.10-64i April 1984
Nine Nile Point Unit 2 FSAR TABLE II B 3-1 TINE AND DOSE PROJECTIONS FOB PASS SAHPLING~ TRAHSPORT0 1ND AHALISIS XRsg ~tart )~to p~so~C>> ~Ho e ~od Extreaities Not es Decision to take saaple 0 NA ~Ltd H(p Assuaes TSC and OSC activat4
+Ltd gg and saaple rooa.habitated Bead containaent ataosphere
+teal 880 ~Lt r /+
Ha levels in control rooa Operate control panel for dilute reactor coolant 20 ~ttr 't < Qttr 9.5 6" lead shielding Transport dilute reactor coolant ~0 tr .~~1 ~z.S.~
~Lt F00 SCCA 3" lead M'8<Ed; ~(PlhX) shielding(g~)
to laboratory Prepare coolant for isotopic qQ~ ~1'k.s
~60 1 ~r 'tr < >+~ 4 08
'~*"
Col<as lead for Q 8 (,R Wx)
I e< Sh'c(4',ng g~ gg)
Perfora isotopic analysis of coolant
~ttr 88 IL.-+tr 2 0.
CQg <~en' ~" le~
Analyxe coolant for Boron rt@0 (118) 1 ~2.>- ~tr %.( t t 4" lead for H.B.
'IE "le,g >S;dd,',~
Prepare saaple panel for containaent 20 40 ~ttr O ~tr D ataosphere Ice g gh el':g g Operate control panel for (550 2 Ltr 'V~0 ~tr 9ÃrO 2" lead shielding contain aent a taosphexe Transfer containaent ataosphere 35(y V Ltr 2.9e Z Z" leuc( >4'bbing to saall cask S:Sr Z.
Transport containaent ataosphere to laboratory
~55 Ltt'r ~ttr i. 8 3" lead shielding Ci less Prepare containaent for isotopic ataosphere Sgt
~r)S.Z. iZ 4" lead for H.B.QVlpag Perfora isotopic analysis of C>Q
(.9-'t Ltr
'8. 8-'5
~ Z.o re Ir leis >4;,Lb;~ (e~) .
eP
125 1 containaent ataosphere Operate control panel for total N<~ ~Ltr Z.Sr l
~Ltr 0 5 r$ 6 " lead shielding dissolved gas Operate control panel for 10-al reactor coolant t.Q
~180 195 e.f 2 +l ro
~ttr Q Q rCI 6" lead shielding Aaendaent 14 1 of 2 October 1%4
a Bine Bile point Unit 2 PSLB TLBLE IZ.B.3-1 (Cont) ~
fags) mznosure< <> laRl Start S~t Persons<a 1>~Mo e B~od Extreaities ~3 Notes Transport 10-nl reactor coolant. 95 55 3 ~tv ~Ltt (55/lead shielding+ax to laboratory ZJJ )eJag ~'clcVJAQ(g J1
~tl '4" lcAIL Lnalyxe 10-al reactor coolant 7 g.> 3 Llama>.
utt lead for Q B.(tl,gg) for chloride J3l +r.at 6.'cal Sb;LId q(m'n)
<<>Nuaber of persons perforaiag particular task.
<>>Doses are based on the assuaption that the decision to take a saaple is aade 1 hr after reactor scraa.
L send aen t 1JJ 2 of 2 October 1%a
Nine Mile Point Unit 2 FSAR TABLE III D 3 4- 1 RESULTS OF TOXIC CHEMICAL ANALYSIS FOR THE CONTROL ROOM HABITABILITYSTUDY Allowable Maximum Control Time Chemical Room Concentration Toxic Limit Period Location Chemical pm~in J.A. FitzPatrick Ng ~65- 'X5 274 15 Plant HgSCg 0.. 002 2 COg 54. 8 15 Propane 0-.+5 a9 43. 1 15 Alcan Cl, WG++ OoL 0.045 2 Propane 9-.78- 5,5 43 1 15 0 9+& 274 Ng CO~
M5~~~
0 Oln o-a~ ~~o o5 15
~t5 Route 104 HCB.~ ~%8 a.o9 0. 050 2 N~ 9- e$ 274 15 COg 0. 06~ 54. 8 2 Nine Mile Point Ng WFH- lS.o 274 15 Unit 1 COg lb.x. 54. 8 15 HgSOi t,S x.t p- < 0.002 2 Nine Mile Point HgSOg 0.002 2 Unit 2 C02 54. 8 15 Halon 1301 432 15 27/ v5 cc pps'awew ~+(~gfPYC $ 0xto 0 l5 Sir4srau ~ gypped
Nine Mile Point Unit 2 FSAR TABLE 2.2-8 PREDICTED VAPOR CONCENTRATIONS IN THE UNIT 2 CONTROL ROOM
'5 Maximum Allowable Control Room Toxic T3.me Chemical Concentration Limit Period Location Chemical Q<~m~3 min James A. N2 7.5 274 FitzPatrick H2SOq 6.6 x 10 0.002 2 plant CO@ 4.3 54. 8 15 Propane 0.9 43. 1 15 Alcan Clp 0. 017 O. OZ 0.045 2 Propane 3.5 43.1 15 N2 0.9 2 15 HCL 0.02 0. 002
~ O.~ o5 15 CO@ 0.06 54. 8 2 Route 104 HC1 0.04 2 Np 0.4 274 15 23 COp 0. 06 54. 8 2 Nine Mile N2 15.0 274 15 Point Unit 1 CO2 10.2 54.8 15 Nine Mile HqSOq H2 SOq ao-'.050 1.3 x 10
- 0. 002 D. oO/7 0.002 0.002 2
2 Point Unit 2 Coz 32.8. 54.8 15 Halon 4.0 432 15 1301 Ng 20 5
~ 274 15 Copperweld Isopropyl 4.0 x 1.2 as Bimetallics Alcohol Group Amendment 23 1 of 1 December 1985
Nine Mile Point Unit 2 FSAR TABIE 2.2-9 INPUT DATA FOR VAPOR RUN
- 32. 6 Ambient temperature ~~55' Wind speed 1 m/sec Iiquid density of propane Boiling point 0.S8S g/cm>
-42.2 C
~-- I~
3 Vapor density 1.55~0* g/cm~
Heat of vaporization 81. 7 cal/g Specific heat 0.576 cal/g C Amendment, 3 1 of 1 June 1983
Nine Mile Point Unit 2 FSAR one of the pumps, the pump in the second sump will be able to pump (aall Ehe collected water. Each sump and each ver-tical access shaft connecting the sumps to the surface con-sists of concrete pipes.
2.S.4.6.4 Permeability Determinations Permeabilities of the foundation materials are estimated on the basis of recent studies performed at the Unit 2 site, vious studies conducted at the adjacent Nine Mile an d previous Point Unit 1 and James A. FitzPatrick sites (82) . The per-meability studies for Unit 2 consisted of the following:
Amendment 23 2.5-17la December 1985
GROUND SURFACE P SAT = 140 PCF Vs = 800 FT/SEC AMAX = 0.15 G SEISMIC INPUT ROCK (HALF-SPACE)
Vs 7.70 FT/SEC OO NOTES'O SIMPLIFY THE ANALYSIS,'DUCTLINES 907, 922, AND MANHLE NO. 1 ARE CONSERVATIVELYTREATED AS LAYERS OF SOIL THAT HAS SAME PROPERTIES AS STRUCTURAL FILL THE SOIL SYSTEM IS ASSUMED TO HAVE INFINITE AREAL EXTENT ANO IS DIVIDED INTO 13 LAYERS.
INPUT DATA FOR THIS COMPUTER ANALYSIS INCLUDE THE FOLLOWING:
- 1. EARTHQUAKE ACCELEN3GRAPHS
- 2. UNIT WEIGHT ANO SHEAR WAVE VELOCITY OF SOILS
- 3. RELATIONS BETWEEN SOIL DYNAMICPROPERTIES ANO SHEAR STRAIN.
FIGURE 2.5-150 THE INPUT SOIL SYSTEM NIAGARA MOHAWK POWER CORPORATION NINE MILE POINT-UNIT 2 FINAL SAFETY ANALYSIS REPORT AMENDMENT 13 AUGUST 1984
Nine Mile Point Unit 2 FSAR trip systems have tripped. This logic scheme is called a one-out-of-two taken twice arrangement. The RPS can be tested during reactor operation. Manual scram testing is performed by operating one of the four manual scram controls. Two manual scram controls are associated with each trip"system, one in each trip channel. Operating one manual scram control tests one trip channel and one trip system. The total test verifies the ability to deenergize the scram pilot valve solenoids. Indicating lights verify that the actuator contacts have opened. This capability for a thorough testing program significantly increases reliability.
Control rod drive (CRD) operability can be tested du '
normal reactor operation. Drive position indicators in-core neutron detectors are used to verify c rol rod movement. Each control rod can be withdrawn note e and then reinserted to the original position without significantly perturbing the nuclear system at most power levels. One control rod is tested at a time. Control rod drive mechanism overtravel testing demonstrates rod-to-drive coupling integrity. Hydraulic supply subsystem pressures can be observed on main control room instrumentation. More importantly, the hydraulic control unit scram accumulators pressure and the scram discharge volume water level are monitored. The scram discharge volume is sensed by level switches which automatically scram the reactor when the volume is high enough to verify that the volume is filling up, yet low enough to ensure that the remaining capacity can accommodate a scram.
Main steam isolation valves can be tested during reactor operation. For test, the valves move shut a very small distance from the fully open position, then automatically open fully without affecting reactor operation. If reactor power is sufficiently reduced, the isolation valves ca.. be fully closed. During the refueling operation, valve leakage rates can be determined.
Residual heat removal (RHR) system testing can be performed during normal operation. Main system pumps can be evaluated by taking suction from the suppression pool and discharging through test lines back to the suppression pool. System design and operating procedures also permit testing discharge valves to the reactor recirculation loops. The low pressure coolant injection (LPCI) mode can be tested after reactor shutdown.
Each active component of the emergency core cooling system (ECCS) reguired to operate in a DBA is designed to be 3.1-24
Hine Nile Point Unit 2 FSAP TABLE 3-2-1 EQUIPNEHT A HD STFOCTOe E CLASSI PICA TIOH Quality Electrical Group Duality ( 3) ~ )z ~
Scope of Classifi- Seisaic Classifi- Assurance ~ ), Tornado Reply Location cation Category cation Leguirenent ~~) Protection Notes gg~~SX~tRR Reactor vessel GE PC Nh Reactor vessel support skirt GE PC NA Reactor vessel appurtenances pressure retaining portioas GE PC NA A CFD housing supports GE PC Hh HA Reactor iaternal structures, engineering safety features PC Nh HA Reactor internal structures, other GE PC Nh HA Hh NA CZ Ji)
Control rods GE PC Nh I Hh v Control rod drives GE PC Hh I NA I Core support structure GE PC NA HA I Encl asseablies GE PC HA I HA I
)0)
Reactor vessel stabilizer GE PC I (
C)4)
~
Reactor vessel insulation l~~o'er Systea Znstruaentation condensing P PC HA 36)
I chaabers GE PC Nh C SRV air accuaulators P PC Nh Piping, SRV discharge P PC HA Piping, aain steaa vithin outeraost isolation valve PC Pipe supports, aaia steaa vithin outeraost isolation valve PC Pipe vhip restraints, aain steaa, and feedvater PC,RB NA Piping, feedvater vithin outeraost isolation ralve PC Hh Piping, other RCPB piping vithin outeraost isolation valre PC Piping, instruaentation beyond outeraost isolation ralve P RB ~ TB Hh I or HA B or D I or HA Safety/relief ralves GE PC 1E I A I h aendaent 25 1 of 26 Harsh 1986
Nine Mile Point Unit 2 FSAR
- b. The following design stress limits are not exceeded for Safety Class 2 piping: .
( 1) The maximum stress ranges do not exceed
- 0. 8 ( 1. 2 S h+S a) ~ as calculated by Equations (9) and (10) in Para-graph HC-3652, ASNE Code Section III, considering normal and upset plant conditions (i.e., sustained loads, occasional loads, and thermal expansion) and an OBE ev'ent.
5h (2) The maximum stresses do not exceed
- 1. 8 S, as calculated by Equation (9) in
'aragraph NC-3652 under the loadings resulting from a postulated piping failure of fluid system piping beyond these portions of piping.
C. Welded attachments for pipe supports or other purposes, to these portions ,of piping are avoided, except where detailed stress analysis demonstrates compliance with the limits discussed in Items 2a and 2b.
- d. The humber of. circumferential and longitudinal piping wel~ and branch connections is minimized.
- e. The length of these portions of piping is reduced to tahe minimum length practicable.
The design of pipe anchors or restraints (e.g., connections to containment penetrations and pipe @hip restraints) does not require welding dirmtly to the outer surface of the piping (e.g-, flued integrally forged pipe fittings are used), except where such welds are capab3.e of 100-percent volumetric inservice iaaspection. This .criterion is also applicable =o the portion of piping between the containment and the inside containment isolation va:ves-g, For these po~ions of high-energy fluid system pi ping, preswrvice and subsequent inservice examinations are performed. in accordance with Amendment 12 '
. 6A-15 June 1984
Nine Nile Point Unit 2 PShR TABLE 3.8-4 (Cont)
PAFT II Mhere. S ucture Is Not Integral and Continuous (Closure Joint Fegion Only)
Design C~a~eo I Load Coabination Stress Coaoarison hSNE Paraaranh Design I D+ PD+OBE Fm <1.0 Sa Bl TD PE-3131 (C)
Pl <1. 5 Sa Pl + Fb <1. Sa ib TD D+ PD JOBE+ J Pa< l gerof 12SaorSy N ~-313 1-2 (
ze 8 T or TD<
< larger of 1.8 Sa or 1.5 Sy 8 TD or TD~
Pl + Fb < larger of 1.8 Sa or 1.5 Sy 8 TD or TD~
m < Sa
< 1 8 TD 5 Sm 8 TD NF-3131 (C)
Pl Fb < 1.5 Sa 8 TD D+ FD + SSE+ J Fa< la rof 12Saor Sy NE-313 1-2 ze 9 TD or T Pl larger of .8 c Sy 8 TD or Sn or 1
Pl + Pb < larger o 1. 8 Sa or 1 5 Sy 8 TD or TD~
Design III D+ >E Pa <1.0 S~ 8 TE NE-3131 (C)
>I <1.5 Sa 8 TE Pl + Pb <1.5 Sa 8 TE ASNE III instability criteria YE-3133 8
-3131 (C)
Design IV Deleted Design V D+Pf +OBE Pa + 1.5 Sm 8 TL Feg. Gui 1 57 OPerating I D + Po + To + OBE nl + Fb + 0 <3 Sa NE-3222 Pl + Pb + Q + F (fatigue evaluation) haendaent 26 2 of 4 Nay 1986
Efae Nile Point Oait 2 PSALM TAbLE 3,8- ~ (Cont)
PAIT II Shore Stractare ya Sot Integral aa5 Continuous (Cloaare Joint nngion only)
Desiga Caigsgtr jQlkSQIhlhhfckth gtgeae gosphgfsona ALEE parsdrahh Deaiqn I b + PD + Obh e SET e LOCA Pa S1 0 Sa I TD NE-3131- (C)
Pl S1 ~ 5 Sa a TD Pl s Pb S1 ~ 55aatD be PD+Obhe SET eLOCA+ J Pa S larger of 1.2 5a or Sy h) R-818)-Z, i TD or TD<
D e PD< + ODE e 5NT e LOCA J Pl S larger of 1.8 sa or 1.5 Sy 0 TD or TD~
Pl e Pb S larger of 1.8 Ss or 1 ' Sy 0 TD or TDI Deaiqa II D e PD e 555 + SET e LOCA Pa 5 5a 0 TD P1$ 1 55 ~ ~ TD lt-3131 (C)
Pl e Ph S 1 ~ 5 Sa ~ TD D e PD e 555 e SET + LOCA e J Pa S larger of 1.2 5a or Sy ME-3'LSL 4 0 TD or TDi I
D e PD< e $ 5E e SIT e 14CA e J %5 S larger of 1 ~ 8 Sa or 1~ 5 Sy a TD or TD~
Pl e Pb S larqer of 1.8 Ss or 1 ~ 5 5y 0 TD or TD<
Deaiqn III D e PE e ODE Pa S1.O Sa t Ta NE 3131 (C)
Pl ASqE
+ Pb S1 5 5a III instability i TE criteria HE-3133 6 HE-3131 (C) operatlaq I D e Po e To + OILe SENT e LOCA Pl e Pb40$ 35a aE Pl + Ph evaluation) i O e t (fatigue Operatinq II D e Po e To + 55L 4 SAT e LOCA Pl + Pb i 0 S3 Sa NE-1222 Test D+ PT Pa SO ~ 85 Sy a Ty nE-6322 i
Pl ph Sl 25 SF a >T 2 of 1
Nine Mile Point Unit 2 FSAR TABLE 3.9A-12 ACTIVE VALVES (BOP)
SYSTEM VALVE PRESSURE ASME VALVE OPERATOR ACTIVE NAME SIZE TYPE R~ATING
- CLASS MFG. MODEL (HFG) FUNCTION SPEC.
Reactor plant 2CCP>>HOV14A>B 12 Gate 150 3 1 SHB-0-25(1) 63* P304R component cooling 2CCPaHOV15A > B 4 Gate 150 2 1 SHB-000-5(1) 9 P304R (CCP) 2CCPs'HOV16A>B 4 Gate 150 2 1 SHB-000-5(1) 9 P304R 2CCPeHOV17A>B 4 Gate 150 2 1 SHB-000-5(1) 9 P304R 2CCP>>MOV18A,B 12 Gate 150 3 1 SHB-0-25(1) 63'- P304R H a e SHB-00-1 2CCWHOV93A>B 6 Gate 150 3 1 SHB-00-10(1) 65m P30 2 a e SHB-00-1 1 P304R 2CCP+HOV124 8 Gate 150 SHB-00-15(1) P304R 2CCP>>MOV265 8 Gate 150 SHB-00-15(1) P304R ZCCWHOV273 8 Gate 150 SHB-00-15(1) P304R ZCCP RV60A > B > C 3/4x 1 SRV 150/150 None C051A 2CCWRV64A>B 2x3 SRV 150/150 None C051A 2CCPaRV 170 3/4 x '1 SRV 150/150 None C051A 2CCP>>RV171 34x 1 SRV 300/150 None C051A 2CCWR 2- 3 x 1 1 3 8 None CO IA ZCCWRV83A>B 3/4 x 1 SRV 150/150 3 8 None 4 C051A ZCCPaRV84A>B 3/4 x 1 SRV 150/150 3 8 None 4 C051A 2CCP>>RV85A B 3/4 x 1 SRV 150/150 3 8 No C051 2CC MOV A,B a e SHB-000-5(1) 9 P304R ZCCWAOV37A 1 1/2' Plug 150 NCB520-SR80(2) 64>> P304K ZCCP>>AOV37B Plug 150 NCB725-SR80(2) 64* P304K 2CCF4'AOV38A 1 1/2 Plug 150 NCB520-SR80(2) 64* P304K 2CCP+AOV38B 2 Plug 150 NCB725-SR80(2) 64m P304K
+Active functions 63-65 are not listed at end of this table.
Amendment 26 1 of 21 Hay 1986
Nine Hile Point Unit 2 FSAR TABLE 3.9A-12 (Cont)
SYSTEM MARK VALVE PRESSURE ASHE VALVE OPERATOR ACTIVE NAME NUMBER SIZE TYPE R~ATING (* CLASS HODEL (HFG) FUNCTION SPEC.
2ISC4'EFV17 3/4 Check 1250 2 13 None 60 C151C 2 IS CaEFV 18 3/4 Check 1250 2 13 None 60 C151C 2ISCaEFV19 3/4 Check 1250 2 13 None 60 C151C 2 IS &EFV20 3/4 Check 1250 2 13 None 60 C151C 2ISQKFV21 3/4 Check 1250 2 13 None 60 C151C 2ISC4'EFV22 3/4 Check 1250 2 13 None 60 C151C 2ISC4'EFV23 3/4 Check 1250 2 13 None 60 C151C 2ISCaEFV24 3/4 Check 1250 2 13 None 60 C151C 2ISCaEFV25 3/4 Check 1250 2 13 None 60 C151C 2I SC4'EFV26 3/4 Check 1250 2 13 None 60 C151C 2I SWEFV27 3/4 Check 1250 2 13 Hone 60 C151C 2ISCaEFV28 3/4 Check 1250 2 13 None 60 C151C 2ISCeEFV29 3/4 Check '250 2 13 None 60 C151C
.2ISCaEFV30 3/4 Check 1250 2 13 None 60 C151C 2ISCeEFV31 3/4 Check 1250 2 13 None 60 C151C 2ISC4'EFV32 3/4 Check 1250 2 13 None 60 C151C 2ISCeEFV33 3/4 Check 1250 2 13 None 60 C151C 2ISCaEFV34 3/4 Check 1250 2 13 None 60 C151C 2 IS WEFV35 3/4 Check 1250 2 13 None 60 C151C 2ISCeEFV36 3/4 Check 1250 2 13 None 60 C151C 2ISCaEFV37 3/4 Check 1250 2 13 None 60 C151C 2 IS WEFV38 3/4 Check 1250 2 13 None 60 C151C 2 ISWEFV39 3/4 Check 1250 2 13 None 60 C151C 2ISCaEFV40 3/4 Check 1250 2 13 None 60 C151C 2ISCaEFV41 3/4 Check 1250 2 13 None 60 C151C 2 IS C4'EFV42 3/4 Check 1250 2 13 None 60 C151C Containment 2LMS*SOV152 3/4 Globe 1500 76P-001(7) 16 P304X leakage 2 S*SOV153 3 4 Glob 1500 76P-001(7) 16 4X monitoring (LHS) S*SOV156 Globe P304X 2LHS V157 3/4 0 e 1500 76P-001(7) 16 Amendment 26 9 of 21 Hay 1986
Niae Bile toiat lait 2 tSAR TABLE 3~9b-2g STANDBY LIQUID CONTROL TASK Allowable stress or Actnal Stree Hiniaaa Thickness or Thickness Rsktezia Iet~~~ IIagy Reauire8 or Load ar Load Shell thickness loads) Norsal aad browaell 8 Yonaq apset desiqa prassare <process E9oipeent Design> 0.010 ia O. 25 in aa4 teaperatare Stress licit ASIE 5ectioa III 30~000 psi 1,203 psi 2 Noxxle loa4s Loa4s: Nor sal aa4. Ae aaxieas soaests 4ae to.
epact 4esiqa pressers pipe reac'tioa aa4 aaxiaaa ant teaperatwre forces sLall aot exceed the allowable liaits.
Owertlow aoxsle to ~ a50 lb 98 lb No ~ 310 ft-lb 195 ft lh zlzz x)a 1 woxr) ~ 2 Discharge aoxxle to ~ LSQ lb 287 boa iF 3$ 'o a, ib -lb Bo ~ 310 ft-lb gag 211 ft-lb (g( 9 ft Loads: taalte4 the eaxiaas accents lae to 4ea4 wei9ht~ tLeraal pipe reaction a'a4 aaxiean expaasioa, an4 SSk forces sLall eot excee4 the allowable linits Ower flor noxale to ~ 510 lb 109 lb Bo ~ 372 f t-lb 209 f t-1b 1 Wcax) e 2 DiscLarqe noxxle to ~ 5%0 )b Qg4 5 lb 4%i 1b No ~ 372 ft-1b 3( 1 ft 1h Z~ 0 ft-)h Aachor bolts ASBE Section IXI 10,000 psi 8 boa psi
~
~. Dyaasic loals Egniwalent static 1 75 g Lorixontal 1-0%6 9 Lorixoatal a SSE 75 9 vertical 0.71 g vartical
- h. Say all
- c. LOCA Aaendaeat 12 1oC 1 Juae 19da
Nine Mile Point Unit 2 FSAR
/ ) TABI,E 5.2-], (Cont)
Code Case Number/ i App L cab 1 e Titla System location Identification In System Attachment Method No. Line No. Su ort No. Weld T e 1 Service waxer 2 SWP-006-104-3 2 st 491A3 ps?t Fillet - Two sides 2 Service Water 2SWP-003"901-3 2-SWP-PSR 1101A3 Fillet - Two sides N-339 CRD penetra- Examination of Ends of Fillet tfon sleeve guides, con-Welds, Section Classes 1, 2, III, and Division 1, MC duit supports attached to suppression chamber liner N"369 Class 2 and 3, Resistance Welding of Bellows, and MC con- Section III, Division 1 struction of bellows N-392 Class 2 and 3 Procedure for Evaluation of the pipe supports Design of Hollow Circular Cross Section Welded Attachments on Classes 2 and 3 Piping, Sec-tion III, Division 1 N-413 Pipe supports Minimum Sine of. Fillet Welds For linear Type Supports, Section Division 1, Subsection NF III, In accordance wf th Code Case 'N 413 allowable weld stress of p
21 ksi for base metals with a tensile strength range of 58 ksi to 70 ksi will be used.
' 'For NSSS-supplied equipment only, code cases applicable to reactor coolant pressure boundary components (but not their supports) are identified.
Amendment 26 8cof8 May 1986
5SNK III Effective Throat Thickness of Ccmponen< Partial Penetration Groove Weld@
Supports Section III, Division 1, Claeaeo 1, 2p and 3
Nine Mile Point Unit 2 FSAR Further operational description of the alternate shutdown cooling method is discussed in Section 15.2.9. The adequacy of the SRVs for liquid flow in this mode of operation is discussed in Section 1.12.
The RHR pumps have sufficient head to satisfy the requirement of the alternate shutdown cooling mode of operation. The following calculation demonstrates the adequacy of the pump flow/head requirement.
The following design features/criteria were applied to the calculation.
- 1. Suppression pool level is assumed at minimum drawdown level of l97 ft-8 in.
- 2. Frictional flow losses are based on a 40 F suppres-sion pool water temperature.
The total developed head (TDH) required to provide adequate cooling water flow rate in this mode of operation is given by the following formula:
2 a TDH=Za-Zg+PaP)+~V-~V+ h 2g 2g L where:
Zz = Elevation of the RPV outlet nozzle (el 322 ft-0 in);
o credit xs ta en or the ower e e RV discharge return to the suppression pool.
Zz = .Elevation of the suppression pool water level (el 197 ft-& in) corresponding to the minimum pool Pa-P, =
drawdown level.
~~ ~~< ~~++wgdd,'~</
Difference in pressure between the nlet and our. e of the flow pat, a ro since the pump suction source and SRV discharge destination are the arne, i.e., the suppression pool.
2 aWr /ar/rg ~hrU +g wv> <~me'Pk +
~U
= Velocit ead at the e o t e SRV piping dxs-2g charge o e ession pool.
nAs+x deil V~ = Velocit head in the suppressi'on poo at t 2g R um suc xons conser e ssumed to be Amendment 8 S.4-34a January 1984
Nine Mile Point Unit 2 FSAR h = Frictional head loss fxom all components in the flow path, including the RHS suction strainers (50 percent clogged); RHS heat exchangers, RPV, mazn steam sa e y-re xe va ves xsc ar e n a interconnec xng pxping, valves, etc Npc'e~ <g < y %%dele+ '7oaeO MQ The head loss across the SRVs is based on data provided in the Analysis of Generic BWR Safety/Relief Valve Operability Test Results, CE-NEG NEDE-24988-P, dated October 1981. For this calculation, re SRVs are assumed open in the ADS mode of operation. The flow coefficient Cv for each valve was taken as 415 in accordance with NEDE-24988-P, Table 5:2-1.+f Based on the piping/equipment axrangements of flow resistances described previously, and on the RHR pump characteristics shown in Figure 6.3-SB, the RHR pump will provide a flow rate of 7,060 gpm in the alternate shutdow cooling mode.
Evaluation of the terms in the foregoing equation at this flow xate is shown as follows:
Zx-Z> = 322 ft - 197 ft-8 in = 124.3 ft Pg-Pg @ ~~y]y- OPsrD P
~V 2g
= 1.4 ft (at the SRV discharge outlet) h .='.9 ft (suction strainer, RHR pump suction and valves) piping
+ 157.8 ft.(RHR heat exchanger, RHR pump discharge
- piping and valves)
+ 35 ' ft (RPV)
+ 83.6 ft (main steamand piping, SRV, SRV discharge piping, T-quenchexs) a Total h L
= 81. t Amendment 8 5. 4-34b Januaxy 1984
Nine Mile Point Unit 2 FSAR Calculating TDH required using preceding values:
8N.8 f++ i'p7.d g+ fez.7 TDH = 124e3 ft + + 14 ft + . f = 6. ft The developed TDH for the RHR pump at 7,060 gpm is 407 t, ich satis'fies the preceding TDH requirement.
Low Pressure Coolant In'ection Mode The functional design basis for the LPCI mode is to pump a total of 7,450 gpm of water per loop using the separate pump loops from the suppression pool into the core region of the vessel, when the vessel pressure is 20 psid over drywell pressure. Injection flow commences at 225 psid vessel pres-sure above drywell pressure.
~~z~~p g4 <<cAr'Sly ~Nv ~U Fjv~
co~'// ~</'~~ ~ p Am ~W
~~/8;/ p>~~/~ wC 4/d 2'TA ~
~/i " glz ~~h id A~/
~~ j+ Mrmcr+e~w+r g/~i~g ~~/ccJAPPA+'
(Pz fS)~ <z et'Z
~~
P
~~~~@~ beAdc ~ ~z ~w~~~d p/ //C5~ 'Q C4~k'/ p gP~zocr g Q
~
~ c~~'t BC'~/tvP~Ugm.
ry +h.~ ~i~~ rn~g~<5+g Ap</A/Hi+
\
V~8 V'+ ~ W> b~X~e.
Amendment 8 + 5.4-34e January 1984
( Ctur'W Pd W )
4,>g,~ g ZnJcrl 4r g. +'f 90 )
I c Wi'i'etc~/ACE,dlk,S~a~
iM W.c ..p W~.HA>..roc/ural ~+ r Ac
~a'Me..W gcrr~e4r..=- .S. @
/Ager/ ~ /~~~ l,'(j.S'45A-aug)
S Jere Xv~/u~g~y HQe Warts, Hc~,~&4>> gcS W~r,~~a Ae~/ ~egvre~e~g~~.~&~2 r$ eregr~
/'c'. Ar~. s y cz'> H~
~p4~..e..~ 8 hs
. +Ac.
ee
~
.c~rsh
~
4 e~~re y'J~
~p4 r, Ae../eR'rV rk. PAe Svjprrss . )
, ...p'aol @AM ~i p@mu ercR~iYpkA,.NQ sy~eemre
.~0~. ~A,W ~p~acrsg~/W',~~~~M3/
~ ~ ~ ~
Nine Mile Point Unit 2 FSAR TABIE 5.4-2 RHR REI IEF AND SAFETY VAIVE DATA Capacity Set Pressure Required/Actual (psig)
Valve Function m Maximum F025 Thermal NA/10 470 (2RHS+RV20 relief A,B,C)
FOSSA, B Thermal NA/1 200
( 2RHS*RV61 relief A,B)
FOSSC Thermal NA/1 105
( 2RHS*RV61C ) relief F055 Safety 97,000 19,972 500 (2RHS+SV34 (lb/hr)
A,B) 2RHS*SV62A, B Safety 194, 000/293, 688 500 (lb/hr)
F036 (2RHS*RV108)
F005 (2RHS*RV110)
F030 (2RHS*RV139)
Safety Thermal relief Thermal relief aEo/q g5 NA/1 NA/1
~ 125 220 S4~
z~
( F231) Thermal NA/10 1240 I 2RHS*RV152 relief 2RHS~RV56A, B Thermal NA/20 500 relief 2RHS*RV42A,B Thermal NA/20 500 relief (F236) Thermal m~e 180 '
2RHS*RV117 relief '3.4 Amendment 23 1 of 1 December 1985
Nine Hile Point Unit 2 FSAR TABLE 6. 1-1 (Cont)
Specification
~ooe onen Form ~ala erla l ASME ASTM Va ives Forg ing Carbon steel SA-105 Flow diverter doors Plate Carbon stee I A 36 (24-in recirculation suction lines)
ECCS Piping Pipe Carbon steel SA-106 Gr. 8 Pipe Stainless steel SA-358 Type 304 Cl.l or Type 316 Pipe Stainless steel SA-376 Type 304 or SA-312 Type 304 Fittings Forg ing Carbon steel SA-105 Carbon stee I SA-234 WPB Stainless steel SA-182 F304 Stainless steel SA-403 WP304 or WP304W Va Ives Forging Carbon steel SA-105 Cast ings Carbon steel SA-216 Gr. WCB Plates Carbon steel SA-515 Gr. 70 Forg ings Stainless steel SA-182 F316 or F304 Castings Stainless steel SA-351 Gr. CF8 Standby liquid control system Injection line Pipe Stainless steel SA-312 Type 316L Valves: ASHE Safety Class I Forg ings Stainless steel SA182-F316L ASHE Safety Class II Forg ings Sta Inless Steel SA182-F316 Amendment 3 2of2 June 1983
Nxne Male Point Unit 2 FSAR losses and leakage. Post-accident makeup Nq will be provided by two bottled nitrogen connections located outside the reactor building (see Section 1. 10, Item II.K.3.28).
6.2.3.2.4 Bypass Leakage Rates Bypass leakage rates as a function of time after tne postulated LOCA are predicted :or each path by two meth ds, assuming isothermal flow and zsentropic flow. Table 6."-55a lxsts the bypass paths considered and their contribu" ons to the total oyoass leakage, assuming isothermal : low determined with tne following equation:
= K (P u - P')/RT (6.2-1")
D u/
Where p. (~
P = Upstream absolute pressure (post-LOCA pressure/
temperature profile per Section 6.2.1)
= Downstream absolute pressure T = Upstream absolute temperature R = Gas constant K = ons gp mane
~~Ktechnical xrom the 1ClCA~
specifi-cation of allowable leak rate tee-m = Mass flow rate Coueaion ~~~~
To quantify the sensitivity of the bypass. leakage analysxs to the flow model assumption, the bypass calculation was repeated considering the leakage flow to be characteri"ed as isentropic flow through an orifice. Table 6.2-55b summarizes the isentropic flow results determined with th' following equation:
p m~A u
PD p
u Y 1 P
pu Y
Y (6.:-13 )
Where:
Amendment 2 1 6.2-55b September 'g85
Nine Mile Point Unit 2 FSAR TABLE 6.2-3 CONTAINMENT DESIGN PARAMETERS Desi n Parameters
~Dr well
- 1. Internal design pressure, psig 45
- 2. External design pressure, psig 4.7
- 3. Drywell floor design differential pressure, psid
- a. Downward 25
- b. Upward 10 Design environmental temperature, ~F 340
- 5. Design structural temperature, F 293
- 6. Design leak rate, % of free volume/day at 45 psig and 293'F
- 7. Drywell net free volume (including downcomers), ft3 3.11 x 10~**
Su ression Chamber
- l. Internal design pressure, psig 45
- 2. External design pressure, psig 4.7
- 3. Drywell floor design differential pressure, psid
- a. Downward 25
- b. Upward 10
- 4. Design environmental temperature, F ~27 s g'70
- 5. Design structural temperature, F 212
- 6. Design leak rate, % of free volume/day at 45 psig and 293'F
- 7. Suppression chamber free volume, ft3
- a. Minimum at HWL 192,028
- b. Maximum at LWL 201,322 Su ression Pool Suppression pool volume, ft3
- a. Minimum at LWL 145,495
- b. Maximum at HWL 154,794
- 2. Suppression pool surface area, ft~ 5, 813
'Amendment 27 1 of 2 July 1986
Nine Hilo Point Unit 7 fSAR TABI I: 6>.7.-33 SURCOHPARTHENI Vf NI PATII DESCRI PT ION 2<<-Inch Recirculation Suction Linc Brcak Oryucll llcad Subcompartmcnt V mt, f rom lo I)oscription Vcnl.
I'a th Volume Vo l))mc Path flow Arr.a llr.ad loss Coeff'icir.n ol'rnt A
No, Nodr. No. Nodr. No, [ fhokrd/llnrl)okra Lf~ 1 f ft~ft f rictior) 1()rni))(I I.>I)ansion Contraction Tota I I 2 llnr.hokr.d 7. <<0' 0 0017 I . 731 0.9?77 0. <<97<< 2.65 2 2 Unchokcd 0.5G .0 6'.
(
3 2 III)cl)))kcd 7. 58) 0. I68 0.0060 I.ORG 0. 9775 0. <<918 2.51
<< 7 Unrhokcd I( ) . I ( I I G 5 ? Unrhokrd 2 <<0 0.<<73 0.0017 l.231 0.9277 0.-<<92<< 2. 5 6 Unrl)okrd 1. 00 ).
0 ~534 00 Amendment 11 1 of 1 June 1984
0 Nine Mile Point Unit 2 FSAR TABLE 6.2-34 BLOWDOWN DATA 24-Inch Recirculation Suction Line Break Drywell Head Subcompartment Blowdown Blowdown Mass Blowdown Energy Time Flow Rate Enthalpy Release Rate
~sec Btu ibm Btu sec 0.00 26,310 550.7 1.449 x 107 0.25 26,410 551,6 1.457 x 107 0.50 26,500 552.4 1.464 x 107 0.75 26,580 553.2 1.470 x 107 1.00 26,650 554.0 1.476 x 107 1.25 26,720 554.7 1.482 x 107 1.50 26,800 555.4 1.488 x 107 1.75 26,860 556. 1 1. 494 x, 107 2.00 26,920 556.7 1.499 x 107 2.25 26,970 557.3 1.503 x 3,07 2.50 27,020 557.9 1.507 x 107
- 0. oo 33( oo I'&so x to 2,SO 8 34do ~S1. 0 l BSOX lO 7 Amendment 11 1 of 1 June 1984
Vti o TABa 6.2-54 Bi i:D ~iG D:-SiCN AND P:"RFOR .ANC:" 'DA A v VIP>>
vQ ( Cv ~
g lg >600 vo'u -,e 4 547, 304 ~tz - the en" ire -eac=o" bu'd -..g ( incIud'ng auxiliary bays) is co ls de as one vol T ans env Ana ys .
s Steel Liner Conc P
ete
."..arv Corta'..ent Wall Thickness 0.375" 6S.0" Thermal Conduc=ivity Btu Neglected 1.0
- ft- F !The"mal Capac'ance Neglected 28.8 P~='mary contairwent atmosphe e to steel line heat trans "er coefficient, hoI i 2.0 Btu/h -ftz- F Prima v containmen- concrete to reactor building avmosphe e, ho:
5.0 Btu/hr-ftz-OF Combined ove all coefficient of heat transfe apIga l u = 1/(1/hi oF+ 63.0/(12!c) + 1/ho) = 0.17 Btu/
h>>
I ftz
- 2. Reactor Bu'd'g Wall
- =eat trans er is considered ac oss the reactor b .'¹ng hea" ga'.
walls as this results in a net pose d 5g(4dO~Q a+clyiz c.owa'~denrad <<~~>~~y 1 of 1 M oQQ&1VI M Cnnb $ xWe Vo>u~e. O-I'- y,S+7 3c+
i~I z.< k ~<q~ g- EiSZ C. Fe. 'T4~ <~a~%~<<
Mama<'A 5, %a ~w g'id <>i ~P a> e yacc.e.m0 I I I
~= ~
Hina Hilp Poipt Onit 2 FSAR Location T 1 BL E 6 2 56 leant) nf va iv<) Length of inc 'idc/ Pipe - Car.- Valve<>>
FSAn Outs!do ta!anent to Potcntial Isola-Pene- CDC or Arru<igo ~ Fr!cary .Outside Typo Dypilsii Pns! t Inn . tion Clos uro Povar tration Systau Bcg ESP sita cunt Conta in- Isolation Tcs t Loa lluuhnr, Oper xr tun tnr. Hniln Horuai Signal Ti. ac Source I No ~HUB 5'Iistcc JL01, PISH<5~ 'l) run t v.i 1vo ka'Ji')
liu<h Si<JMC r.E Tyne nlnr. C 4) Shutiln'un xcclilnnt Fai!acne < 4) C4) <s 4l Cv)
I Fccdvatcr Mater 24 6.2-70 nuts< do I li <)4) 2YMS+AOY23A 022- F0321 Suing procass Spring Open Close<1 Closed H/A Reverse Tha tine H/1 11,32 41 line A to BPV 55 Ho Sb. 3 2~ C Yo Chock AOV (Last' only) flou it takes Inside 2YMS>V)21 0'>2- YO )oil i 5 v il iJ Process 0/1 OPen Closed Closod 0/A Bcvarse for anc Chock flou vulva volune tu puss through tho valve
~ ~
Ou<S! i!C 15 ~ -4<i 2YM54HOV2 Ih 022-F0651 Cata Ho<) Elec. Open . C les Closed PAI RH Div I uter 8 6 '2 70 2MCS>HOY200 033-F040 Ci abc Ho I Bloc. tfanuai open Open Closed PAI Div I Sh. 3 Z-40 Pcedvutcr 55 Bo 'Mater 24 6 2 70 C Yos 2 Y 0 S < V I 2 'lI 022 Y0100 I Suing H/1 Procuon . 0/1 Open Closed Closed Reverso The tine H/1 11,32 linc 0 to BPY Sb. 3 Ct ock flou il. takes Bcvarsc fnr ona Oulsl<>, i 2YMS>X<<V'>30 022- F0120 5ulng 0 <u<)k AOY I'rnccss Spring (Lust only)
Opun Closcil Ciosad H/K flou 'alva
~ voiuaa to pass through thc valve oletsida 15<-hu 2 Y"S 4 I i 0 V 2 I!I P22-F0550 Cata HOV Elec. Hanual Open Closed Closed PAI H/1 Di v Qzj Mater 0 6.2-70 2<J<)545<)Y200 <<040
')33 Cio!io Hnv Blue. Hanual Opnn Oncn Closed PAI H/1 D iv Sh. 3
'z-51 BHS Punp 1 C HO<<4) 2BHS<:I<)Y)1 E12- Pooh.'I Tricen- HOV Elec. Hanual Open Closed Open PAI RH IIS Div I 13>35 suction fran 5b 4 l.ric suppression but<.cr-pool fly Z-SD BHS Punp 0 56 'Ics Mater 2 < 6.2-7". Outsido 20<-'J" C Ho< )4) 20HS>..OY)0 512- Yoohn ! .r<can- IIOV Elec. Hanual Close'pen -FAI 'H 45 Div II 13435 y suction froc Sb 4 LL ic i suppra sion buttcr-pool f ii 1
Mater 24 6.2-70 Outside 9'-9" ~
2RHS*HOV1C E12-F004C Tricen- Elec.
i!<
Z-5C RHS Pump C suction from 56 Yes Sh. 4 C Hot !
tric
)NV Hanual Open Closed Open FAI RN 45 Oiv II 13 i
suppression pool butterfly Z-61 RHS test line 56 Yes Mater 18 6.2-70 Outside 19'-3" C Ho 2RHS*HOV308 E12-F2018 "
,Tricen- HOV Elec. Hanual .: Open Closed Loop 8 to sup- Sh. 6 tric .
. Open FAI RH $5 pression pool butterfly r
Amendment 27 2 of 24 July 1986
'p
~ w APED':8.60826 0.141-::,g(, ..
Also Avdhhle OII Apertare Card
S C'
l"
a Hine Ni'le Point Unit '2 FSLB Location of valve Length of Insido/ Pipe - Con- TABLE 662 56 (Cont)
FSAR Outside tainaont to P otontial Pene- GDC or Arrange Priaary Outside Type Bypass Vh YS} (v )
tration Systea Page ESP Size aunt Contain- Isolation Test Leakage Huaher Pos Isola-
)BED S. c}Bhht}OI} Culd6. Svstea Fluid gin} l'16}I}re(} ) NI}nt V,}1 YII (}) neth sure II Pover tion Closure Pover Oper- Actuator HEI}e Horual Post- Pailure Signal Tice Source Z 28 RDS lines Yes HOC zv ) ator prcuhe Sncnhh XX C}) Ca a) Cv) Motes to RPV 125'-0N
}
Outside 39 Insert 39 Qith-Qatar 1 3/4 Outaidc 125 '0" See Mote 17 draval Check 8/1 Process N/1 Closed Closed Close4 Reverse
- 6. 2-70 Inside No(>> ) 2SLSav}0 1-F007 Stop 8/A 8/1 2-29 SLCS to 55 Yes Boron 1 1/2 Out"ide C C4 chock I
flov BPV solu- Sh 43 2 ~ }ON C 2SLS ~ NOV5L CII1-F0061 NOV Elec. J! anual Closed Closed Cfosed Closed Reverse N/1 8/1 tion globo flov Stop Outsido 3 10 2SLS ~ HOVSB C4 1-F006D check NOV Elec. Manual Closed Closed C)oned Closo4 globo Reverse 8/1 8/1 flou 2 30L Spare Ho 2-308 Spare Ho I-311 TIP drive 57 Mo Mote 1 1/2 6.2-70 Outside 2 ~ 4N NoC al ) 8/A 28}CS+SOvlA Ball SOV Elec. Closed Closed Closed Closed 'Bs F ~ R}}sZ 8/1 120 VAC 18,1 gui4e tube 19 S'h. 19 Outs}.de 8/A 28HSivEXlh Shear 8/A Open Open Open Open RN N/A 125 VDC 28, to RPV 8/1'OV 2 31B TIP drive 57 Ho Note 1 1/2 6 ~ 2-.70 Outside 5 ~ 4N Ho(it) 8/A 2MHSiSOV}B Ball Elec. N/1 Closed c:losed Closed Close4 F6886Z 8/A Outside Bs 120 VAC 18 ~ 19 guide tube 19 Sh. 19 8/A 28}(saVEX}D S}Sear 8/1 8/A 8/h Open Open Open Open RN '8/1 125 VDC 28 ~ 34 to RPV I 2 31C TIP drive 57 No Mote 1 1/2 6.2-70 Outside 2 I 4N Mo(a}) 8/A 286}S ~ SOY lC Ball SOV Elec ~ 8/1 Closed Close4 Closed" Close4 Bs FIBNY 8 }l/1 120 VLC 18, 19 guide tube 19 Sh. 19 Outside 8/h 28}}S+VEX}C Shear 8/1 N/A N/A Open Open Open Open RN 8/h 125 VDC 28,34 to RPV 2-31D TIP drive 57 Ho Note 1 1/2 6.2-70 Outsi4e 2 ~ 4N HOCS>> ) 8/1 2HNS~SOV}D Ball SOV Elec. '8/1 Closed Closed Closed Close4 86F(RNSZ 8/1 120 VAC 18 ~ 19 guide tube 19 S}I. 19 Outside 8/1 2}}HS~VEX}D Shear 8/A 8/A H/1 Open Open 0~en Open RN N/1 125 VDC 28i34 )t to RPV 2 31E TIP drive 57 Mo Hote 1 1/2 6. 2-70 Outside 2 ~ 7N C No(k>>) 8/1 2N 8 SiSOV lE Ball SOV Elec. 8/A Closed Closed Closed Close4 Bs F688 8/h 120 VLC 18 ~ 19/ guide tube 19 Sh. 19 0utside }l/h 2885+VEX}E Shear N/A 8/1 8/1 Open Open 0~en Open RN N/A 125 VDC 28,34 to RPV
'BOI/ 6k&c}c. QobCCl 2-32 Ha purge to 56 Ho Ha 1 1/2 6 2 70 Outside 7 ~ .-6N Yes Sssll 661166 - GIS}ks(sckk Process 8/A Open Close4 Closed 8/1 BIF6RN6Z 5 120 VAC TIP indez Sli. 42 aechanisn Check 8/A Process 8/1 Open Closed Closed Reverse N/A N/A flov Xnsi4e 2GSH av170 Z-331 CCP to supply RCS 56 Ho Hater 4 6.2-70 Sh. 20 Inside Outside 7 '0N C Ho(a})
2CCP~MOV94L 2CCP I'MOV17A Cato Cate BOV HOV Elecs Elec. Manual Manual Open Open Open Open C]osed Closed FAX PLI B~ FNRN,Z 20 BIFIRNIZ 20 Div Div II I 6 Puap 1 Aaendnent 27 7 of 24 July '}986 Tj; APER~, 860S P S p l4 I Qg CARD
'lso.Av~l@ eely .
~
APettIIX'6 GliP'
- I I 6
i ~ ( L,
Nine Nile Point Unit, 2 FSAR TABLE 6.2-64 TYPE AND QUANTITY OF INSULATION USED IN DRYWELL Materi al. Vol~ume fte ~25 ~etcaln 2 to Temp-Mat 87 Min-K (gg>.s 366 V 5'8 Amendment 15 oE 1 November'984
R'l- ALP C.~ ~ i+~ I MSGR+ THIS FIGURE HAS BEEN DELETED FIGURE 6.2-42 NIAGARA MOHAWK POWER CORPORATION NlNE MILE POINT-UNIT 2 FINAL SAFETY ANALYSIS REPORT AMENDMENT27 JULY 1986
0 SECTION AS RKPRESKNTS 4 AREA OF SUPPRESSION POOL WITH SPRAY COVERAGE SHOWN AT ELEVATION 100.$
'UPPRESSION POOL OUTER WALL KLEVATIOK199,5 SPRAY RING ELEVATION 231'ECTION CC SPRAY ItlNG 20'UTER WALL PEDESTAL NOZZLE ORIENTATION
'PEDESTAL WALL KLKVATION100,$
FIGURE '6.2-42 gpPRox i H4q a SI RAY COVERAGE IN SUPPRESSION CHAMBER NIAGARA MOHAWK POWER CORPORATION NINE MlLE POINT-UNIT 2 FINAL SAFETY ANALYSIS REPORT
IPC OPC V n 2CCPK MOVI6A 2CCP % MOV I5A 2CCP % MOVI68 2CCP 5 MOV I58 M M 2CCP K RVI71 (Z348 ONLY) Z34A, 8 o B g (Z34 ONLY) 0 0 (Z34A ONLY) (Z34A ONLY) Z-3aA, 8 CCP RETURN FROM REClRC PUMP A & B (g FIGURE 6.2-70 OLATION VALVE ARRANGEMEN FOR PENETRATION Z-34A. B SHEET 21 OF 43 NIAGARA MOHAWK POWER CORPORATION NINE MILE POINT-UNIT 2 FINAL SAFETY ANALYSIS REPORT AMENDMENT 15 NOVEMBER 1984
FROM NITROGEN GAS STORAGE TANKS IFIRST VALVE LISTED IS APPLICABLE TO PATH THROUGH 2IAS ~ TKi. SECOND VALVE LISTED IS APPLICABLE TO PATH THROUGH 2IAS'TKS) INSIDE REACTOR BLDG 2GSN. V113. 2IAS 2IAS
'SOVX 'SOVV V77 181 181
'SOVX 'SOVY 2GSN 2GSN 186 146 V 118, '73A, B V78 2 2GSN I 2GSN 1 /2" 53A 2GSN B
'72A, B I'70A, 8 '71A, B EL 265'-0" 2IAS
'TKi 2 I AS
'TKS 'OY I 64, 2IAS 2IAS 'SOV165 iV13$ 'V372 S
'V138 V371 EI 302'-4" EL 291'-0 3/4 2IAS 2IAS FC EL. 296
EL 303'-4" ADS 'V137 0 V174 VALVE ov138 0 V175 ACCUMULATOR 2IAS C I AIR RECEIVING CLCgy,
'V889 @pe, go2.
TANKS AT 38$ PSIG I
~IRC J~- r O~RC giq~c QSk ]z -I<
FIGURE 6.2-86 NITROGEN SYSTEM LINES TO INSTRUME AIR ADS VALVE ACCUMULATOR AI ECEIVING TANKS NIAGARA MOHAWK POWER CORPORATION NINE MILE POINT-UNIT 2 FINAL SAFETY ANALYSIS REPORT AMENDMENT 18 MARCH 1985
0 Nine Mile Point Unit 2 FSAR decomposition of construction materials of the charcoal filters, is not postulated to occur simultaneously with any other plant accident requiring the operation of the SGTS for radioiodine removal credit. 6.5.2 Containment Spray System 6.5.2.1 Design Bases The containment spray system is capable of guickly reducing containment pressure during the post-accident period of a LOCA through condensation of steam in the drywe'll and through cooling of the noncondensable gases in the free volume above the suppression pool. The design of the containment spray system is to Category I and Safety Class 2 requirements. 6.5.2.2 System Design The containment spray. system consists of two subsystems: the drywell spray and the suppression chamber spray. The drywell spray consists of two independent loops and spray headers. The suppression chamber spray consists of one spray header supplied from two otherwise independent loops. Since the water source for all containment sprays is-'the suppression pool, the system is a closed loop. The spray water is cooled by the RHR heat exchangers. e ows e rywe a nc ers m loo and 450 gpm/lao , re v 'ontainment spray xs an operatxona mo e o the RHR system (Section 5.4.7). The containment spray isolation valves are electrically interlocked to allow actuation of the drywell, spray, only when there is a high drywell pressure signal present. After a high drywel1 pressure signal is present, a second electrical inter lock prevents actuation o f either the drywel1 or suppression chamber spray lines until the corresponding LPCI injection valve is shut.'he containment spray system is safety related and, in case of loss 'of offsite power, supplied with a redundant onsite standby power source. The system is'esigned to operate under the conditions indicated in Table 6.2-6. A procedural restriction prohibits the operators, during the first 10 min following a LOCA, from closing
'nterrupting an LPCI injection valve and core cooling 6.5-9
800 50
. 400 gcd~sc9 I'<~
350 ),qzp c.HN~ t 300 ~ ~50 200 150 100
$0 0.88 0.78 0.88 0.88
$ 58 1 08 TIME (SEC)
FIGuRE 6A.4-40 y/ATER JET TIME HISTORY ONE QUENCHER ARM SEGMENT IN X-Y PLANE {HORIZONTAL) NIAGARA MOHAWK POVYER CORPORATION NINE MILE POINT-UNIT 2 FINAL SAFETY ANAL.YSIS REPORT
0'. I 'I
~ .I ~
~ ~
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~ ~
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~ ~
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0 250 225 200 175 PcJ(g c ig PEA pqvwcif ~ 150 ~+7'25 A ~ g 0 100
~ 25 0 54 044 Oeld 0,dl o.ae 1.04 TIME (sac)
FIGURE 6A.4-41 WATER JET TIME HISTORY ONE QUENCHER ARM SEGMENT IN Z PLANE (VERTICAL) NIAGARA MOHAWK POWER CORPORATION NINE MILE POINT-UNIT 2 FINAL SAFETY ANALYSIS REPORT
~ ~ ~ ~
~ ~ ~
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Nine Mile Point Unit 2 FSAR
- 2. Physical separation between divisions of essential systems and between essential systems and essential circuits is maintained for all essential nuclear steam supply systems (NSSS) except the NMS, the RPS, the PRM system, and the control rod drive (CRD) hydraulic system.
- 3. Design criteria for fire protection is discussed in Section 9.5.1.
Re ulator Guide 1.89 Refer to Sections 3.10 and 3.11. Re lator Guide 1.97 Refer to Section 1.10. Re ulator Guide 1.100 Refer to Section 3.10. Re lator Guide 1.105 The trip set point (instrument set point) and allowable value (technical specification limit) are contained in Chapter 16. These parameters are all appropriately separated from each other and their selection is based on instrument accuracy, calibration capability, and design drift (estimated) allowance data. The set points are within the instrument accuracy range. The established set points provide margin to satisfy both safety requirements and plant availability objectives. ~mused. Re
~>4 ~a<
lator Guide 1.118 4= This guide endorses/modifies IEEE-338-1975. Discussion of IEEE-338 is presented on a system-by-system basis in the analysis portions of Sections 7.2, 7.3, 7.4, and 7.6 with the following clarification of the regulatory guide requirements. Position C.6b Trip of an associated protective channel or actuation of an associated Class 1E load group is required on removal of fuses or opening of a breaker only for the purpose of deactivating instrumentation and control circuits.
- 7. 1. 2. 4 Instrument Errors The determination of set points requires that during the design of safety-related systems, instrument drift, setability, and repeatability be considered when selecting instruments. and controls.
Adequate margin between safety limits and instrument set points is provided to allow for instrument error. The appropriate trip setpoints and allow-able values are listed in Chapter 16. The amount of instrument error is determined by test and exper-ience. The set point is selected based on these Amendment 26 7 ~ 1 7 May 1986
NHPC will provide to the NRC, prior to the startup fo11owing the first refueling outage, a detailed technical assessment of the methods used to establish protection system setpoints and allowable values supplied by General Electric. The assessment will be based on the generic findings of the Instrument Setpoint Hethodology Program currently in process and being reviewed by the u ear e u o omm ss o . The technical assessment will include the following:
- 1) The values assigned to each component of the combined channel error allowance (e.g., modeling uncertainties, analytical uncertainties, transient overshoot, response times, trip unit setting accuracy, sensor accuracy, test equipment accuracy, sensor drift, nominal and harsh environmental allowances, trip unit drift), the basis for these values, and the methods used to sum the individual errors. Nhere zero is assumed for an error, a )ustification that the error is negligible shall be provided;
- 2) Confirmation that the setpoints selected for the initiation of protective actions ensure that the reactor core and reactor coolant
~
system are prevented from exceeding the licensing safety limits for the transients and accidents analyzed.
f 0
Nine Mile Point Unit 2 FSAR TABLE 7.5-'1 (Cont) Nutnber of ~estee Parameter edge Bea<loat el>ennets ~Ran e Control building Control building Indicating 12 N/A HVAC . HVAC fan status lights control building Indicating HVAC dampers position lights Control switch OPEN-CLOSE position for: Outside air isola- Indicating 2 tion valve position lights Air inlet isolation Indicati'ng damper position lights Inoperability Status lights N/h Heater inlet air Indicator 60o. - 1204F temperature Heater outlet air Indicator 60o' 150 F temperature Filter train outlet Indicator 60oi' 250oF temperature control room A/c return Indicator 32oF>> 120oF air temperature ontrol room/outs fferential pressure dicator gc.oc'4r Qi~ +3 in M.G. c overall differential Recorder -6. ta in M G ~O ressure stick
.Aec Special filter train Status lit.l:l.s N/A Tr~A out-of-service status F' tlu0 Control room A/C Status lit;;:lo N/A out-of-service status Relay room A!C return 1 lid \ ciltor 60v; i2uteP air temperature
0 Nine Nile Point, Unit 2 FSAR The minimum voltages at the various buses and their connected loads under different loading conditions summarized in Table 8.2-1.
.,Two levels of undervoltage protection are provided at, the 4.16-kV emergency buses: one to detect loss of offsite power, and one to detect. degraded voltage conditions. The loss of offsite power relay is set to trip the offsite power supply breaker, alarm the control room, and initiate emergency diesel generator starting when the 4.16-kV bus voltage drops to 3212.86 V, which corresponds to 475.5 V at the 600-V buses. The time setting is+3.0 sec.
c pp~o)riwaQ$ y In order to maintain 90 percent voltage at thc 600-V motor terminals, it. is calculated that the degraded voltage relay would have to be sct at 3,847 V. This assumes that all of the 600-V connectable load is bein supplied simultaneously from the load center NC' conccrne a setting e xg cou result in an unnecessary transfer of power supply during motor starting conditions. Additional field test and analysis will be performed to dctcrmine the lowest level this relay can be set and still ensure minimum voltage at the 600-V motor terminals. The NRC vill be consulted rior to lowe rin this relay set oint below 3,847 V. ett n the degra ed voltage re ay at 3,84 V corres onds to 29. V at the 600-V buses. With the maximum of 12-V permissible drop between the 600-V load center bus and an 600-V load during normal running, this corres onds <> > to 17. V at the 600-V load terminals, vhich is gl R7 of the rated load voltage of 575 V. PThe de raded percent volta e relay is provided with tvo time delays. e rst time delay is t 8 sec. Folloving this time delay, the degraded vo tage c ndi ion is alarmed in the control room under normal plant operating conditions. Under accident conditions, the offsite pover supply breaker vill trip, and the emergency diesel generator vill start following this time delay.. The second time delay is set 30 sec. Following this time delay, the degraded voltage ondition vill be breaker alarmed in. the control room, the offsite power vill start undervill supply trip, and the emergency diesel generator normal plant operating conditions. When the emergency buses are energized from the diesel generators, the undervoltage protection scheme preventi any load shedding during sequencing of emergency loads on the bus under an accident condition. When the emergency buses arc energized from thc offsite source (preferred source) thc undcrvoltage protection scheme is functionally operational. Amendment 17 8.2-24c January 1985
~~ V~
soo y 95.x7 ari,u I A
Sine Sile poiat Unit 2 PS1S TRSLS 8 2 1 (Cont) Light load indicates very- lightly loaded I 16-kT bus (2-6 STl or less) and very lightlv loaded 13.8-kv bus (1 HTA). the load tap changer for the reserve statioa service transforaer ad)usta accor4ing to the Xoad on the 13.8-kv bus. ror the auxiliary boiler trusforaer, the tap changer is set at the center tap (115 kv) ~ ~~ Saxisua load iadicates 'axiaua load on the I 16 kT as well as the 13.8-kT bases (for reserve station service transforaer, 57 8 STh oa 13 ~ 8-kT bus and 8.7 llTi on 1.16-kT bus~ for auxiliary boiler transforaer, 12 SV1 on 13.8-kv busi an4 5 5 ST1 on 8 16 'kT bus) Partial load indicates 'ery heavily loaded ~ .16-kT bus and very lightly loade4 13 '-kv bus (for reserve station service traasforaer, 8.7 STl on 1.16-kT bus an4 1 Svl on 13 8-kT bus; for auxiliary boiler transforaer, 5.5 STA on u 16 ky and 1 svl on 13,8 kT) since the load tap chaager oa the reserve station service transforaer ad)usta accor4ing to the load oa the 13 8-kT bus+ the li16-kT buses experieace worst voltage under this condition ~ ~ > Light load for the 600-T load centers indicates lightly loaded load ceater bus (100 kTi running load): the voltage on the a.16-kT bus is assuaed to be the lowest (3,832 T at load center transforaer pri,sary side). ci) Saxiaua load for the 600-T loa4 ceater in4icates aaxiaua load on the load ceater bus (2,025 kTA runniag load ; the voltage on the u 16-kT bus is assuaed to be the lowest (3~832 T at load center transforaer.priaary side) ca ~ ) Noraal load for the 600-T load centers indicates that only the loads which are energized during aoraal plant operation are on the 600-T load center bus (estiaated 1 ~ 600 kTl) the load center transforaer is rated for 1 ~ 500/2 ~ 025 kN, an4 the actual loa4 is approxiaately 1~200 kvl) 1 the voltage on the a~16-kT bus is assuaed to be the lowest. ci a1 Light load~ aaxiaua loa4 and aoraal
~
load oa SCCs iadicate light loading, aaxiaua loa4ing, and noraal loading conditions, respectively< of the SCC busi all these coaditions assuae the lowest voltage on the 600-T load caster froa which it is fe4 laendaent 16 tofu Deceaber 1984
P f: E)L/f, .~t t(INE nlLE pOINI UMII 2 f SAR TABLE 8.3-1 DIVISION I STANDBY DIESEL GENERATOR 2EGS EGI LOAD TAOULATIOM DESIGN BASIS ACCIDENT DIESEL GENERATOR LOAOtNG POSSIBILITIES NONACCIOENT LOADING Slt(ULTANEOUS LOOP a LOCA ( LOOP MITH DELAYED LOCA LOCA MITH DELAYED LOOP M)TH UNIT TRIP POMER SOURCE/ S'f ART I t(G 51AR) INC STARTING STARTING EOUIPnEN'I Ol VI- KVA RUt(NING STARTING ,KVA RUNNING S'f ART)NG KVA RUNNING STARTING KVA, RUNNI HG STARTING IOEMTtfY NO. DESCRIPIIOM S ION RATING VOLTS PHASE (KYAR) KVA T I tlE
~
te(VAR) Kya T IHE IKVAR) KVA T I f(E (KYAR) KVA i! IIE 2EMsrsMGIOI Oe9 0.9 ~ o.9 2RHS PIA RHR PUflP A 1.000 HP 4.000 5.68( 790 1 SEC .5.681 790 T SEC 5 !681 ')90 Tg) SEC 5 681
~ naNUAL PF=0.115 PF=O. I IS PF=O. I IS PF=0.115 AF TER 1 =3. 25 HR
/
'7 5,4 5,p 2CSL>P) Lpcs punp l!500 HP 4.000 8>425 l!160 Tgb SEC 8 !425 I 160
~ T@> SEC 8.425 I ~ 160 I 'EC NOT REOUIRED e'LOOP P(=0.)6 PF -0. 16 2SMPePIA SM punp a 600 HP 4.000 PF =0.16 3!097 PFo(L247 500 I PunP(a)t)USTA T o'f=32++39 OR 46 '
F 097 pf'=0.247 I PutlP o1=32. ). SEC 4 o A 37 t)OSTARI OR
-~MS 42 r
3.097 Pf =0.247 500 3.097 PF=0.247 '90 500
~
I PUHP A OSTART et o1=32 .. o OR 4L SEC 4, oT>Qj SEC. SEC 4 o:(~:> S( C
>> tti>D
'7 Pl(fit'tatlUAL I punp naMG)(L I PunP naituac 7c) I pU(lp naMU STARTED 37 37 42 42 'b7 2SMP~PIC sM I'unf c 600 l(P 4 F 000 3 '97 500 I punp(aglosf AR)) 3 097 PF=0.24')
500 3!097 PF =0. 24'1 500 I PuflP oT=32. A t)OSTART 3!097 PF =0.24'7 500 ) t'unp amdsfa 1 oTo32 .Qg OR AS PF=0.247 ofo32.(t!P /Agni OR 4 SEC 4 o)+>! ~S>'I-C SEC 4 o =(ii 6,, pUnp nanuai SEC 4 ol~~~'>> I PutlP nANUALLY. L Pu)IP tl (UAL~ 70 I STAR)ED 37 42 37 et.2 37 42 '37 2SMP<<PIE SM PuflP E 600 HP 4.000 3 '9) 500 I PunPCA(ttosIA(()3 3 097 ~ 500 I PUflP 3!097 500 I PUMP(Alt)OSTAR)T oT<32+ 3>097 PF=0.247 500 I punp AIIHSTART 4& OR ~7-PF =0.247 o T =32/X/ (Lf( (cr>> PF = 0.247 9R 4 PF=0.247 P-,. R Q) oT=32 a()TOST'T=32.4 S('C 4 o I
.~QS(:
Plltu'a> U T 7Q SEC 4 o .~i'. I PUflf'AiibXL 70 SEC SEC ~ I PunP nANUAL Slr. SEC c o)>(5$ I PunP nAWUALLY
~~O STARTED 2SFC<<PIA SFC MATER C I RCU(. A110N G 450 HP '.000 3 2 !279 Pl'=0.201 360 tlAt(UA( ANItR I=2 )(R P
. !779
-0.20) 360 flANUAL AF)ER T=2 HR 2 !279 PF=0.281 360 MANUAL AFTER
't-2 t(R 2 279
~
PF=0.281 360 HANUAL.AF1ER To2 HR PunP A 2EJS<USI 2EJSRXIA 2EJS<<XIB 2HVRAUC4)3A LOAD CENTER
'fRANSf'ORMER LOAI) CFNIER TRAMsf ORMER Rt AC ION Buttolnu 2
l!500/ 2.025 KVA 1.500/
'25 KVA 150 t(P 4.160/
600 V 4el60/ 600 V 575 3 3 3 18.000 (1 So. I SFC) 18!000 I'I 50.1 StC) BGO 19 19 lbo 1=1.5 T=o T=o SEC I Io.ooo 1150.1 StC) IB >000 IT 50.1 SEC) 860 19 19 150 T=o 1=0 T=1.5 SFC 18.000 IT 50.1 SEC) 18.000 11 SO. I SEC) 860 19, 19 150
'0 T=I.S T=o SEC 1
(8.000 (1= 0.1 SEC) 18!000 (1= 0.1 SEC I 860 19 19 150 T=O T=o T=30 SEC tlANUAL UMI I COO( fR A 2HVK~CHLI A( I ) COMIROL G 180 HP 575 3 722 180 T=30 sEc naMuaL 'l22 180 T=30 SEC naNUAL ')22 180 T=30 SE6 naNUAL 722 180 T=30-SEC tlANUAL~ BU I LO I ((G CHILLER IA 2HCSKP)(L22A l(YOROGEN G 120 KM 575 3 )20 120 1=2.5 HR .)20 120 T=2.5 HR 120 120 T=2.5 HR 120 120 T"2.5 HR RtCOMBIMER POMER CABLE A TOTAL LOAD ON 36.000 Ts 0.1 SEC 35 F 000 1 50.1 SEC 36,000 T~o.) SEC 36.000 ISO.) SEC 2EJS~US1 135.166) (35 166)F (35 166)
~ (35.166) 30 O.ls T <).5 SEC 38 0.1>> T <1.5 SEC 38 0.1>>T <1.5 SEC 38 O.I ST <1.5 SEC 860(8061 38 (.5 5) < 4SEC 860(006) 38 1.5 51 < 4SEC 860(806) 38 1.5 51 < 4 SEC 8601806) 38 1.5 5T < 4SEC e luu 4>> T <30 SEC IUO 451 <30 SEC 188 4>>T<30 SFC )88 45T<30 SEC 722(6771 )Oft 305 1<36 S>f;C 7!>g(677) 188 3051<36 SFC 722( 677 ) 188 30 5T < 36 SEC 722(677 ) 188 30 <<1 < 36 SEC 368 36 51<2.5 t(R 3f>u 36 5 T < 2. 5 t(R 3GB 36 <<T < 2.5 HR 368 3651< 2.5 HR 488 Ta2.5 1(R 400 T>>2.5 HR 488 I> 2.5 HR 488 Tt2.5 HR i
~ ~
AHENOnENf 23 I OF 13 DECEM()LR I o'85 APERTURE ?>> ' C re
~
i!
.86 0 S,S::8;.0 1 4 j"~P$ ",:','.'::';::;:.";:
e, r ' e i ee ~
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'1 I
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1 NINE tl[LE PO[Ht UN[I 2 FS'AR TABLE 8 3-1 (CONTI GESIGN BASIS ACCIGEH[ IESEL CENERATOR LOAO[NG POSS[BIL[T[E'S HONACC[GEHT LOAQ[NG S[nULIANEOUS LOOP a LOCA LOOP MIIH OELATEG LOCA LOCA HITH GELAYEG LOOP MI'fH UNIT TR[P [CENTI)V LOOP POMER SOURCE/ STAR['ING staRf[NG START INC EOUIPnENf 0 IV I- KVA RUNHINC S TART IHG KV" RUNN INC STARTING KVA RUNNING STARTING START[NO NO. DESCR IP f ION S I 0)l RAT ING VOLTS PHASE (KVAR) KVA T lt(E (KVAR) KVA T I tlE (KYAR) KVA RUNNING STARTING KVA T[nE iiiVAlli KVA T illE 2EHS ~ nCC101 2Hvz>>uc2A SM PunP Ptt 40 HP 575 240 40 I=60 SEC tlANUAL 24 40 T=60 SEC UNIT COOLER 240 40 T=60 SEC tlANUAL 240 40 T=60 SEC nANUAL nANUAL'=60 2HVT~UC2C sM punp UNIT COOLER Itr 40 HP 575 240 40 T=oo SEC NANUAL 240 40 SEC nANUAL 240 40 T=60 SEC tlANUAL 240 40 T=60 SEC naNUAL 2snpinovla SM BACKMASH 0 0.13 HP 5 /5 1.3 0. 26 '[=0 ).3~ 0.26 I'=0 1.3 0.26 t=o LtNE 1.3 0. 26 I'=0 2SMP>>t)OVIC SM BACKMASH L [NE 0 0.13 HP 575 1.3 o.26 t >> 10 nlN nanuaL 1.3 0.26 I > 10 t([N naHUAL 1.3 o.26 t> 10 ntN nanuaL 1.3 0.26 t> 10 tllH t)ANUAI. . ~ 2SMP t(OVIE SM STRA I HER BACKMASH 0 0.13 HP 575 1.3 0.26 t > 10 ntN naNUAL I 3~ 0 26 T > 10 tl[N t(ANUAL 1.3 0.26 I> 10 n[N nANUAL 1.3 0.26 T > 10 n[H OANUAL 4.0 gS.o 2SMP&nov3A SM Io fURO(NE PL At(i g 575 I"0 (g T=o t=o @40 '8,0 2SMP ~ tlOV30A t)OIOR-OPENAfEO I t(p 575 lo 2 T" 0 I 0,' ( T=O Qo T=O 10 t=o GATE 9.9
~99 @<9.8 ~(99 (9.8 ~9r) 2 2SMP>>novsoa SM PUnps G[SC)(ARCE HEAGER Q4. 575 T=O I (Q2 '[=0 ([.OCA I g 99 ~
r=o [Loop) (9. 8 T=O t)ANUAL . 2sMp at(ov74a sM punp 0 26 HP 575 26 5.6 I-"0 26 S.2 26 5.2 GISCHARGE T=O 26 5.2 T=O BLOCK VALVE 2SHP ~ ((OV74C sM punp 0 26 Hp 575 5.6 T=O T=O 5.2 T=O T=O 0[SCHARGE BLOCK VALVE 2SMP ~ ((OV74E SM PU()P 2.6 Hp I> 0[SCHARGE 575 3 26 5.6 10 tllH t)ANUAL 26, 5.2 T > 10 KIH nAHUAL 26 5.2 I> 10 nlN t(AHUAL 26 5.2 I> 10 ntH t)AHUAI. 2SMPinOV77A BLOCK VALVE t(ofuR-OPERATEG I.O )."I 7.0 ze [A '7. I~ C 575 3 ~tLU ~(.32 t=0 OANUAL T=O naNUAL ~(i. ~(.32 .6 CatE T=O OANUAL
~3 r=o naNUAL 2SMP>>SSRIA BAR RACK 2.8 575 KB 28 KM .,2. 8 HEAI'ER ([16.8 f0f ) ( )gB I[ID.~ T=O
.BT r r [T6:8:;r(fr~
2.8 T=O io Mi'a~us-.~zan 2.8 '[=0 QI9.8 2,8 le:~~IT~ 2.8 T=O " 2SMP>>SSR2A BAR RACK HEAIER 2.8 28 KM 575
~16.0 2.8 ro'f).
2.8 (T6.0 To~I) T=O 2.8 M6.3 t t I.[ CB.B:IOT D 2.8 T=o C5 2.8 [) 70m [76.8 2.8 T~ T=O ~.8 2,8
<[-(6.0-tOX~(-I . 8-GKCP T=O 2SMP>>SSR3A 2SMP>>SSR4A .
BAR RACK HEA[ER BAR RACK 0 2.8 KM KM ~ 575 575 t 2.,8 2.8 t6.8'ror) fr[6.o lo~rl D.B 2.8 Q6:0 2.8 2.8 IT[;[6.8 TOT[> T=o t=o (KlL.~~ll
.2 8 28 2.8 Q~ T=o nx6:
2.8 2.8 T=O 2SMP>>SSRSA HEAfER BAR RACK 2.8 KM 575 CL6.0 f[)g[ [.16iB TOT~1 2.0 2.8 T=O
~
2.8 2.8 L I 6.8. Io I. Q I o.tf TOT[7 ~B tli~~r6;8-IOTP
.2 8 T=o i 2.8
(( 2~8 T=O T=O ....2.8 .2,8 T-"0 2. 8 .2..8 2SMPisSR6A HEAICR iQfi,n IUQ ([6,() I()('Jj r JJ.B.(j I "j;n~r0 Caw:.0:UNIT:LL(),8 TG23 T=O 2.8 dZ53CXJD2~. 2.8 g Tg~, T=O 28 20 t~ BAR RACK 0 2.8 KM 575 . 'I-"0 I'=0 '"
.2. 8 2.8 2.8 .2 8 I=O 2,8 2,8 I 6 6:Elf HEAIER ~)6.8 IQ.U (16.'8 T=O TO~A .ELBE ~ LT6j}+olI 7[6:8 to CEE8 QKE~>Q 2SMP~SIR4A STRAINER SM 3 HP 575 3 18 3 T=O IB 3 T=o 18 3 T=o 18 3 t=o 2SMPisfR4C SIRAINER SM 3 HP 575 r lo nlN 3 18 3 naNUAL t>10 n[N nANuaL 18 T>lo tllH tlANUAL 18 3 T>>10 n[N ..~..
t)A)(UAI. 2SMPis[R4E STRAINER SM 0 3HP 575 3 18 3 r )o ntN f>lo t(IN 18 r>10 nIN 18 t>10 tl[N, ".= tlANUAL tlANUAL tlANUAL tlANUAL At)ENOnENI 23 2 OF 13 W [fiOEnBER 1985 APERTURE C
~ kvaQable. 0~
l c I r Jw~ S'~ J E f
h' NINEInILE POINT UNIT 2 FSAR TABLE 8.3-1 (CONTI
~< C" = uO SrC)
GCSICN OASIS ACC IUCWll~o)l.l)LL OLNCRATOR LOAOING POSSI IL I T IES NONACCIOENT LOAOING slnuLrawEous Loop 4 Loca ,I LOOP M(TH GELAYEO LOCA LOCA WITH OELAYEO LOOP LOOP WITH UHIT TRIP POWER SOURCES START IHG START ING START ING START ING KVA EOUIPnENT 0) VI- KVA RUNNING STARTING KVA RUHHING STARTING KVA RUNNING STARTING
) IIIE IIIVAR)
RUNNIHO STARTING IOFNT(TY NO. OESCRIPT I ON SION RAT IHG VOLTS PHASE (KYAR) KVA T lnE IKVAR ) IIV A T ltlE )KYAR) KVA KVA T I WE TOTAL LOAO OH 2W(~c3) zr 4 CVIK) 2'hc4( 2C3) 2EHS nCCIOI 4:. Oc Tc6 SEC 73( )50 Os T<6 SEC EUD 0<T<6 SEC Os Ts6 SEC 6st<60 IK3~ 6<T<60 SEC m-d3 6ct(60 SEC 6<T<60 SEC 480(450) >3< 60=t SEC 66 SEC 4/0( 45(U c'-3<0 60<1<<66 SEC ~ 480(450) 60sT zzr~st<
<)66 SE(; 480(450) S9~
/99~ 60sTs6
~(,(,4)
VI 1<<~E'>b
<<7~1
/20 IO T
10 nlw -t <10 n')N 6 n).
~ ) 0 tl)N 6 SEC SEC ~S'.
a4(a4)
)St)i Ill<79 c'2(r~s'f < ) 0 A@A ~9 1210 n(N 6 SEC tl)N 10 tllw st <<10 fllN 6 SEC ~SI St)
Der(34) <<P~ fo nlw
,) 0 nlw sT <<10 tllN 6 Tt: )0 tllw 6 SEC SEC H~ 66sT<
T> n)N 1?osrc- . 2EJSxPNLIOIA SMI'fCHGEAR G 400 A 575 3 300 50 T=O 300 50 T=O 300 50 T=O 300 50 T=O ROOn a EnERCEt(CY 600-V PANEL 2EJSxPNLI03A AB-N EnERCEwCY G 400 A 575 3 150 25 T=O 150 25 T=O 150 25 T=O 150 25 T=O 600-V PANEL 2EJSxPNLI04A AB-tl EtlERGENCY 0 400 A 575 300 50 T=O 300 50 T=O 300 50 T=O 300 50 T=O 600-V PANEL 2FMSxnoV21A FEEOMATER TO G 26.6 HP 575 610 )22 T=l 0 tllw 610 122 T=)0 tl)N 610 )22 T=)0 n)N 610 122 T=)0 tllw REACtOR nawuaL t)AWUAL tlAHUAL MANUAL 2FMSxnov218 FEEAMATER To G 26.6 HP 575 610 122 t=)0 nlw 610 122 T=)O nlw 610 122 T=)0 tllw 610 122 T=I0 tl)N REAC)OR nat(UAL nAHUAI. tlANUAL llANUAL 2CTSxFN)A SofS FILfER C 40 HP 575 3 240 40 T=o 240 40 T-O 240 40 T=O 240 40 T=o TRA)tr OISCHARGE FAW (2 '75 2GTSxt(OVI A HVR tl)X PLEWutl 0.34 llP 3 3.4 0.68 T=O T=O 3.4 0. 68 T=O 3.4 0.68 T=O 10 SG(S q20 g4 PRO 2GTSxnov2a SGIS FILTER 575 3 T=O T=O T=O T=o G Q) HP r-4 TRAIN A It(LET
@20 @4 T=O S T=O 620 g4 T=O 20'fsxnov3A SCIS F ILIER QHP 575 3 T=O
'IRA(t( A OISCHARGE 2CTSxtloV4A OECAY )IEAT 0 I HP 575 3 10 1.7 T=O )D 1.7 T=O 10 ~
).7 T"0 10 ~ 1.7 T=o COOLER TO )RAIN A 3.3 ( O. (KE(x ~okk @33 O kk 3.5 ~O. (o('cs
@ES f(0) 2HCS.nov)A ME)MELL HYUKOGEtt G 0.33 HP 575 3 IS nawuaL AS REOUIREO nANUAL AS REOUIREO
~ nAHUAL AS REOUIREO nANUAL AS REOUIREO
REconolwER
)SOLAT IOW VALVE o.( 4 P O. (P('k ~O.(AE(x 2HCSxtloV2A ME)ML(.L 0 0.33 HP 575 3 nawuaL 3.3 tlANUAL 3.3 nANUAL tlANUAL l(YDrr()UCrt AS RCOUIREO AS REOU)REO AS RCOUIREO AS REOUIREO RECOru) I WER ISO).AT ION VALVE O.(c)rc O.(c)rx ~O.CcxcE c
2HCSxtloV3A ME)MELL 0 0.33 HP 5)5 3 3.3 ~3. nawuaL 3.3 nawuaL 3.3 nANUAL tlAHUAL ~ ~ HYOKUGEN AS RLUUIREO AS REOUIREO AS REOUIREO AS REOUIREO RECOnolwER ISO(.ATION VALVE 4 r anENonENT 23 3 OF 13 OECEnBER )985 A
~0Av~
>pertme Cm;IIt
~ ~
86;08 2 8:0 1.4: 1i.'05-'=-.':.,',.'.:-": '-:,':"',:.;::;,":."";-. '
l,
'II r o)
E 4 C4 Cd. tg+ C 7 J 1 ~ J I gA I C l
l i H[HE [LE POINT UwtT 2 FSAR IABLE 8.3-1 (CONT 1 OESIGN BAS(S ACCIOENI [ESEL GENERATOR LOAO(NG POSS[BIL[l'IES NONACCIOENT LOAOINO SlflULI'ANEOUS LOOP 4 LOCA LOOP M[TH OELAYEO LOCA LOCA M[TH OELAYEO LOOP LOOP MITH UNIT TRIP POMER SOURCE/ START ING STAR[ NG START ING STARTING EOUIPnENT OIVI- KVA RUNtl (NG Sl'AR I ING Kva'HVAR RUNNING START ING KVA RUNNING STARTING KVA RUNNING STARTING [OENTltY No. OESCRI('flow 5 ION RAI ING VOL I' PHASE (KYAR) KVA T lt)E I KVA T ltlE (KYAR) KVA T ltlE (KYAR I KVA T lflE 2HCS>nov4a METMELL 0.33 HP 575 g0 ~r tlANUAL 3.) o.c(, nawuaL ~ tlANUAL I 3 3 ~30.0i& tlANUAL HYOROGEN AS Rt.ou(REO AS REOUIREO as REGUIREO AS REOUIREO REConott)ER ISOLATlott VALVE 2HCS ~ floVSA Mf (MELL G 0.33 HP 575 3 3.3 ~3. o.os nA))uaL As REOUIREO g.gg nawuAL AS REOUIREO 3.3 47.Cp& tlAHUAL AS REOU IREO 3.3 ~0.&b tlANUAL AS REOUIREO HYUROGFtl RE Col)8 [NE)t ISOLA) lON VA(.VE 2wcs.novsa ME IMELL G 0.33 HP 575 . 3 3.3 ~0.33 O.f / nANuaL 33 (CD3 .0 60 llANUAL 3.3 O.0 b nawuaL t(ANUAL HYOKOGEN AS REOUIREO AS REOUIREO AS REOUIREO AS REOU[REO RECOr)8 INER ISOLATION VALVE 2SMP>novl7A SM 10 RUCLCM 1.6 HP 575 16 T>10 t)IN T>10 tllw 16 T>10 nIN 16 T>10 ntw tlAt(UAL tlANUAL tlAt)UAL tlAHUAL 2SMP~tlov1BA Rt)CI CM Io SM 1.6 HP 575 16 T>10 ntW T>10 fl[N 16 T>10 tllN 16 T>10 tllw nawuaL t)ANUAL nat)UAL t)AtluAL 2SMP'~novl9A SM lo ROCLCM 575 10 T=o T=o 10 T=O 10 2 T=O t)E I EXC))ANGER 2SMP~nov21A RBCLCM To SFC 0.33 HP 575 3.3 0. 45 T=10 tllw 0. 45 T=10 fllw 3.3 0. 45 T=10 nlw 3.3 0.45 T=lo ntw COOL POOL nawuaL tlANUAL t)ANUAL flANUAL 2SMP~nov33A RIIR HEAt 0.86 HP 575 8.6 I. 72 T~10 f)[N 1.72 T 10 n[H 8.6 l. 72 T~ I0 tllw NOT EXCHANGER A [0 nANUAL tlANUAL (LOCA) t)At(UAL REOUIREO 0[set)ARGE 2SMP nov38A SM IO HUCLCM 0.6 HP 575 6 1.2 T= I 0 flit) 1.2 T=1 0 f)IN 1.2 T=lo n[N 1.2 T=10 f)IN nAt)UAL flANUAL nawual. f)ANUAL 2SMP f)OV39A RBCLCM fo SM 0.6 HP 575 6 . 1.2 T=10 nlw 1.2 T=to ntw 1.2 T=10 A[N 1.2 T=l 0 nlw t)At)UAL nANUAL HANUAL 'lA,NUAL 2SMP~nov90A SM 10 RHR 0.88 HP 575 8.6 1. /2 " 1-IO ntW l. 72 T~)0 tl(N 8.6 1.72 T~ IO tllw NOT HEA[ EXCHANGER nawuaL nAwuaL tlANUAL REGUIREO 20ER~nov)20 CONfAlwf)ENf 0.64 HP 575 6. 4 0.71 T=O 0. 71 T=O 0.71 T=O 6.4 0.71 T=O ISOLA[ION VALVE 575 3.2 0.36 T=o 3.2 0. 36 T=O 3.2 0.36 3.2 0.36 T-"0 20ERxnov)3) OER [At)K I 0.33 HP VENI )3 20FR flov120 ORYMELL FLOOR Qtr 57S i .t 8)O T=O -)B.O 0./ T=O -/B.O ~2.4 T=o ~/S.O (O) 2.C T=O ORA[tt OISCHARGE
~/2 i
20FR'novl39
)SOLAT ION VALVE ORYME(.L FLOOR OHA[tt VENT
@O./r 575 ir.O ~/>2 T=O (D)-/.0 /.2 T=o Q co T-"0 C.o ~/.2 T=o ISOLATION VALVE TURBINE stEan 80 24 T=3 SEC 24 T=3 SEC 80 T=3 SEC 80 24 T=3 SEC 2tcs.nov121 G 8HP 575 3 8%)
SUPPLY 150 o.33 25Ls novla OUIBOARO s'fAt)GBY Llou[o Cottf ROL 575 3.3 - O.&0i t=98 SEC 3.3 ~ 0 k& T=98 SEC(LOCA) 9,'8 ~0.4 C T=98 SEC NOT REOUIREO 575 240 40 T=98 SEC 40 T=98 SEC(LOCA) 240 40 T=98 SEC NOT REOU[REO 2SLSAP(a SIANOBY LIOUIO 40 HP put)P A 5'? 3. ...r 2nss.novi)2 T=O 8.1 T=o B. I T=o 32 8.1 T=0 nA(N stEan to 1.6 HP 575 8.1 Cot)OENSER TK At)ENotlENf 23 4 OF 13 OECEnBER 1985 APERTURE CARD
E 4g 1 1&%1 ( tQ
/
V< <<~~l
HIHE f)ILE Potwl'N(T 2 FSAR TABLE 8.3-1 (CONT I OESIGN BASIS ACC10EHI 01'ESEL GENERATOR LOAO(NG POSSIBILITIES NONACCIOENT LOAOING 5 I tlUL IA NEGUS LOOP 4 LOCA LOOP N(IH OELAYEO LOCA LOCh W(TH 0(LAYEO LOOP ,LOOP WITH UN(I TRIP PONER SOURCE/ START ING STARTING START ING START IHG EoulpnEHI OIVI- KVA RUNNING STARTING KVA RUNHIHG STARI IHG KVA RUNNING START ING KVA RUNNING START IHG (GENT III No. OESCR(P(lou S tot( RATING VOLTS PHASE (KYAR) KVA T I HE (KYAR) KVA TINE (KYAR) Kyh TINE (KYAR) Kyh j !IIE 2cns ~zs Hz)02 1.0 HP 575 6 I T> I HR OANUAL 6 I T> I HR f)AHUAL 6 I T> IHR nANUAL 6 I I > I HR HANUAL ANALY2ER PUNP 0.70 ZSLS>>novsh SIAWOBT LIOU(0
~).6') 5)5 ~470 ~at.q I >to ntw nAHUAL 70 ~7/.p T >10 GIN HANUAL 7;0 ~76~ T >10 ntw nhwUAL ?.'0 (K7p-1.4( T <<lo f(lw nhNUAL STOP CHFCK VALVE 2HSS>>r)OV)19 VEttf VALVE 0.33 HP 575 0.36 tlANUAL 3.2 0.36 r)ANUAL 3.2 0.36 f)ANUAL 3.2 0.36 t)ANUAL 2nss-nov208 natu SIEhn 0.33 HP 575 - 3 3.2 0.36 I=o 32 036 I=o 3.2 0. 36 T=O 3.2 0.36 T=o VALVE 2CSL>>FVI (4 LPCS IESf 0.34 HP $ 75 HOI REOUIREO HOI REOUIREO HOT REOUIREO NOT REOUIREO ZCSL.nav(04 Llcs lunp Io 8.0 ))P 575 80 16 T=17 SEC 80 16 T=(7 SEC Bo 16 I=17 SEC 80 NOT REOUIREO NOT REOUIREO REACfUR Z.O 2CSL>>tlOV107 (.pcs ntwtnun 2 HP 575 20 5.5 T=o 20 5.5 T=O 5.5 T=o 20 5.5 T=o FLO)t (0 Kt)R 2csL>>novi)2 SUPPRESSION 0.68 HP 575 6.8 1.46 l=o nhHUAL 6.8 I. 46 T=o HANUAL 6.8 1.46 T=o tlAHUAL 6.8. 1.46 T=o HANUAL POOL 10 LPCS POOL 2CSL>>P2 LPCS SISfEn I 0 HP 575 60 10 T=o 60 10 T=O 60 10 T=o 60 10 I='0 PRESSURE PUnP 2ICS>>P2 RCIC SYSIEn 0 (0 HP 575 60 10 T=O 60 10 T=O 60 10 T=O 60 10 T=.o PR'ESSURE PUnP A t 2NCS>>noVllz RNCU OUTBOARO 5.2 HP 575 48 8.48 T=O -48 8.48 T=o 48 8. 48 T=o 48 8. 48 I=o ISOLAI ION SIEAtl VALVE I,phd fit))Q Lonql i/A0 Lon Vth)C.
zwcs>>novzo(O NAfER CLEhtlUP Io 1.6 HP Sls 16 3.) nhNUAL 16 3.1 ~ht(UA ) 16 3.1 tlANUA 3,( Loiter< ftMB tAANUAL FEEUNA IER
$ 10 I0cj c I( tzOBEc
/330(/ as) l >>2C/z~s) /33Z (~2<a) / /Bg&(/3o(t)
TOIAL LOAO ON 2E)ls nccl02 (t?93l I?.1~( OO('lZ) 222~ 253 ~4;I, 0<I <3 3< I <6 SEC 6 <T <17 SFC SEC 00( lz ) 22g~D 5)~ os 3s T 6 sT <I
<3 SEC I <6 SEC I SEC
&yz~i 80( lz) 25m~
OsIc3 3s 6 sT T SEC c6 SEC cl7 SFC tt'5~57:
~~)274
~D) 2/f ~ 10 os T se i ft~ia m rllHs I <
SEC nt l tzoS2C p t'2o see BO(72) 242(237) 253~
?cga 2cg~
17s T <23 SEC 23 985
< T T
<98
<104 SEC SEC 80(72) 242(237) 2cg 2cg~
~ I 23 js T <23 SEC I <98 98 sf <104 SEC SEC ool 72) 242( 237 )
2' 2cg~ 17 < T 23sI 98s T
<23 SEC
<98 SEC
<(04 SEC
/zo~ sf <<O n(u 223~ /20~ <(Io I< 10 tl(N n~s
/zoos I <10 nlw ffgggp 223~ lo ntws T<<0 ntw 6 ser sfg0~9 lo nlws T SSE) tcI?)A 223-cd lo rltws T.<
8KKfEF~iXE" t ~t.v M / <<R - L~O~P~Qg~~~ 223~ I WR 6(S I 223~i- . I HRs T< I I)R 6 SEC 6(51 223~). I HR< T < I HR 6 SEC 6(51 1 HRs T < I HR 6 SEC
?2~4 I>'1 HR 6 SEC 2gig.~i) I> 1 HR 6 SEC ?g4 ~j I> I HR 6 SEC AnENonEwf 23 5 0F 13 GEcEHBER 1985 Ep (I:ARD
~.
0 ',<i C. I h E
<g l I'
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IC BCVl NINE nlLE polwt Uwll 2 FSAR TABLE L3- I ( CONT ) OFS)GN OASIS ACCIOEN( 0)ESEL GENFRATOR LOADING POSS(OIL It)ES NONACC I BENI'OAOING slnULlANEGUS Loop 4 LocA LOOP Nl tu OE(.AYEO LOCA LOCA WITH OELAYEO LOOP )Loop M)TH uw)T TRlp 5 PONER SOURCE/ STARTING START ING STARTING START ING
,rr E oui pnEw1 OIVI- KVA RUNNING START)NG KVA RUNNING STARTING KVA RUNH IN G STARTIHG KVA RUNNING STARTING IOENTI)Y No. OESCRIP)low Slow RATING VOLTS PHASE (KYAR) KVA tlnE (KYAR I KVA T(nE (KYAR) KVA T(nE fKVAR) KVA 5) ll) 2E((S.nCC103 (0 lC (O 2CCP>>nov)2< ORYWFLL COOLFR I 575 3 16 T=O MANUAL ~(..) 7=0 nawuat ~)6 T=o ~)h ~3.S TO RBCLCH HP Qf(i
~AHULL T=O((~ANUA~L outooARo I 2CCPxnoV)4A RBCLCN TO G 1.6 HP 575 16 t=o nawuaL 16 3.5 T=o nawuaL 16 3.5 T=o nawuaL 16 3.5 T=O t)ANUAL SFC )(EAT EXCHANGER A I'=O 2CCP>>flov)BA St C HEAl G I 6 HP 575 3.5 T=O f(ANUAL 16 T=O flANUAL 16 3.5 T=o nawuAL 16 3.5 tlANUAL -*
EXC()ANGER A C
)
.To ROC(.CN 2CCPxnOV22A RCS PU(lP A I HP 575 10 1.8 T=O 10 1.8 T=O 10 1.8 T=O . 10 1.8 T=o To RBCLCH 2CCP>>tfov265 Cot(TAINt(ENT 0 I HP 575 10 2.2 T=O 10 T=o 10 2.2 T=O 10 2.2 T=o ISOLATION VALVE )
2CCP.nOv)SA RBCLCN 10 RCS 0.33 HP 575 3.3 0.55 3.3 0.55 3.3 0.55 T=O 0. 55 T=o C ~ PunP A OUTBOARO ' ISOLATION 2CCPxr(OV158 RBCLCN 10 RCS G 0.33 HP 575 3.3 0.55 3.3 0. 55 T=O 3.3 0.55 T=O 0.55 T"0 PUt)P 8 OU'fOOARO
)SOLAllotf 2CCP>>tloV)7A TO HBCICN RCS 0.33 HP 575 3.3 0.55 3.3 0. 55 T=O 3.3 0. 55 T"0 3.3 ~
0.55 T=O PU(lP A OUIHOARO ISOLATION I ' 2CCPxtlov178 to Ruc( cM Hcs 0.33 HP 575 3.3 0.55 t=o 3.3 0. 55 T"0 3.3 0. 55 T"0 3.3 0. 55 T=o ,*5 PuflP 8 OUIUOARO 5 ISOLATIOW ) 2CCP>>ftov93A RHC(.CN 10 G (LS7 HP 575 3 6.7 1.5 T=o 6.7 1.5 T=o 6.7 T=O 1.5 T=o 2l<CS-P(A ~ ~ Cool ENS 2EGA-tt(A 0() ) AIR G )5 f(P 575 90 T-0 90 15 T=O 90 IS T=O 90 15'5 T-P .
).
Coftl'f(LSSOR )A 2EGA-n2A OG I A)R G 15 HP 5(S 15 T=o 90 15 '1 =0 90 15 T=O 90 T=o ' conpwtssOR 2A c 2EGF>>PIA OG I (.Ul l. OIL 3 6 7"0 T=O T=O 0 I C
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THAt(SI LR 5 punp a ~ 'f T=o ') 2EGF>>PIC 00 I FUF( OIL G I l(P 575 3 6 7 Rat(SF(:R pun( C 2EGoxPIA (.U(3E OIL 0 15 HP 5 f5 3 Not REOUIREO lfot REOUIREO HOT REOUIREO NOT REOUIRFO C I RCU(. A t I Ow punp ri- ~6YAS~ ~>Sf't~~ 2EGSxP)a JACKE1 WA1FR G 5 HP 575 3 WOT REOUIREO Hot REOUIREO HOT REOUIREO Not REOUIREO C I RCU( A I ) ON vunp 2EGt>>CH2 Llfl(C OIL G 12 tfw 575 3 WQT ((SOU IRFO Not REOUIREO NOT REOUIREO Not REOU)REO I(EA IfR Tr APERTURE anENOnEwt 23 6 OF (3 OECEnBER 1985 Also Avai4510 0)gt APeX tTXre algid
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~
5)f)ULI'AWFOUS LOOP 4 LOCA LooP MITH OELaYEo LocA LOCA MITH OELAYEO LOOP LOOP HI TH UNIT TRIP POMER SOURCE/ SIARI ING Sl'ART ING EOUIPnEw) OI VI- KVA START ING STARTIHG IOENTIIY NO. OESCR I PI ION SION RAIIWG VOLTS PHASE RUNHING STARTIHG KVA RUNNING STARTING KVA RUNNING START ING Kva R IKYAR) KVA IlnE )KYAR) KVA T It)E IKvaR) Kva i iflf RUNNING STARTING r IKVAR) KVA It)E ZEG I R Ct Q> JACKFI MAIER )8 KM 575 T
))EATER NOI REOUIRFO NOI REOUIREO NOI REOUIREO HOI REOUIREO 2HVCRACU)A COW)ltaL Root) G 40 t)P 575 g
A/C UWII IA 240 40 T=O 240 40 T=O 240 40 1=0 240 40 T=O 2HVC*ACU2A REL~Y Roan G 40 HP 575 A/C UNIT 2A 240 1=0 240 40 T=O 240 40 T=O 240 40 T=O ZHVCRACU3A REno IF. G 2 HP 575 Sttu)UOMN ftoaf) T=O T=O 12 1=0 12 A/C UNIT T=o rr r ZHVCRFNIIA flaKEUP AIR G 7.5 )IP 575 - 3 SMI ICI)GEAR 45 7.5 T=30 45 7.5 1=30 45 0.5 T=30 45 7.5 FLOUR T=30 SEC ZHvcxFWZA Cot/fROL Root) )0 l HP 575 10 60 10 r A/C Of)as)FR T=O 60 10 T=o 60 10 FAN A T=O ZHVCRiFN4A BAIIERY Roan a 3 HP 575 3 18 EXt)AUST I'AN 18 T=O )8 3 T=O 18 T=O R
~ E Zwvc*novla cowfttaL Root) 0.25 tlP 575 0.5 r A/C SPECIAL T=o 2.5 0.5 2.5 0.75 r
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T=O 2.5 0.5 T=O Ff),ILR BYPASS ZHVKRCHLIAI3) AUX I t. I ART 0 I L 0.75 tlP 575 4.5 0. 75 4.5 0.75 punp T=O 4.5 0.75 T=O 4.5 0.75 T=o ZHVKRPIA CawfkaL )5 IIP 575 BI) I I U it)a 90 15 T=O 90 IS T=O 90 15 T=O 90 Ctt I I I LO MAI ER 15 I-"0 ~" C I RCUL A I I aw punp a 44~7')~)r4 Pl/'SMP (its l7A SM To CMS curt) 5 0.7 HP 575 3 T >10 tllW tlANUAL -/ < T >10 nlw flANUAL 4C7)-/ 4 <<10 lllw nAHUAL i'0 T /+ T> I 0 IIIH tlANUAL 2SMPRflav66A SM 10 SIAt/OBY I HP 575 3 10 2 T=o 10 2 T=O COOIERS EA 10 2 T=O 10 2 T-O i 2SMPRf)OV67A SM 10 Catt I wot.
+HP 575 3 LIP 6" Q-/ZrS T> 10 tllN f)ANUAL Qt)-64 (P-/Z.S T >10 flIN f)ANUAL to)-d4 (9-/2 8 <<10 tllN tlANUAL
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2SMPRP2A REACIOR 10 HP 575 3 Btt) I.GING 60 10 T=O 60 10 T=O 60 10 Wtrr T=O 60 10 T=O r" V CHII I ER SM . Punr a ZHVPRFW)a OG I FXHAUSI 30 HP FAN )A 575 180 30 1-0 180 30 T-0 180 30 T=O 180 30 1=0 c'S)4PX jV54A wF," tif:ACaq 0 70)IP 7.0 T=O 7.0 14 T'= o Fl < APEHTITRR-r%
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0 NINE tl(LE POINI'NIT 2 FSAR TABLE 8.3-1 GFSICN BASIS ACCIOEt)T OtESEL GEt)ERA[OR LOAOING POSSIBILITIES HONACCIOENT LOAOING SIGULtANLOUS LOOP 4 LOCA LOOP HITH OELATEO LOCA LOCA )tl'fH OELAYEO LOOP LOOP H [ I'H UN [ t f R IP PO)IER SOURCE/ S[AR[ING SI'AR[IHG STAR((NO STARTING EOU[PtiENT Olvl- KVA RUN)lliVG START ING KVA RUNil [NG START(NC RUNHINC StART INC KVA RUNNING S I'AR 1 I NG [GENT I IT NO. OESCRIPT ION S ION RA[INC VOLTS PHASE I KVAVI Kva 1' nE (KYAR) KVA t lnE IKVAR) KVA T(IIE (KYAR) KVA T I f1E 2t)VPaFNIC OG I EXHAUSf 30 HP 5')5 ton 30 T=o IOO 30 T=O 180 30 T=o IBO 30 T=O FAN IC 2RtlS ~ FY38A TES[ I.INE A [0 G 0.34 HP 5IS T=o 3 4 0. 34 T=o 3.4 0.34 T=o 3.4 0. 34 NOT SUPPK'S I ON REOUIREO 2R)IS~nov)A PUUL St)t'I'HLSS I ON Q'DI2 T=o 16 T=O 16 T=o IS CQ3'-5. 2 T4~ 575 IS IIANUAL AS POOl. TO REOUIREO R)IR I'Utih A 2Rhsanov104 T=o on HEAl) St't(AT IO IL7 HP 5/5 T=o 1.4 T=o 1.4 1.4 i ANUAL A OUIIOARU REOUIREO ISOLA f ION 2RH S. tl0 v(13 St)u[OONN C 20 HP 575 200 21.7 r=o 200 21. 7 T=o 200 2(.7 T"0 200 21.7 naiVUAL A COOLING St)PPLT EQUIREO OUfBUARI) ISOLA[(OW 2RHS.nOV)2a HEAf EXCtlANGER I )IP 575 10 26 T=lo tllN 10 2.6 T=lo n[N 2.6 T" 10 tl[N 10 2.6 ~T=O [T)a u2 A TU REAC[OH 0.38 Lo Time 2RHS~ilov142 HEAI EXCHANGER 575 3.3 0. 42 I'=0 3.3 0. 42 T=o 3.3 o. 40 T=o 0.42 ~ [.. tlANUAL A,S 8 to LMS Ot) IREn 2RHS nov I Sa Cot)['htltil'f 2.6 HP 575 26 T=1 0 tllN 26 8.1 T= I 0 nlN 26 8.1 T=lo flIN 26 B. I NO[ St'NAT a REOUIREO 2RHS nOv24 RI.AC(UN 10 0.86 t)P 575 2.2 T=O 8.6 2.2 T=o 8.6 2.2 T=o 2.2 wctu vaP nANUAL A RNR PUt)P A RFO)IIREO 2RHSi nov224 SfEatl 22 4.4 IS 4.4 T=o 16 4.4 T=o CON0ENSING 0 I.S tlP 575 T=O 16 QQog~otJ TO EXCHA)(GER.A T iii+'giiaga) 2RHS~nov23A SfEatl C 1.6 HP 575 22 1'=0 IS 4. 4 T=O 16 4. 4 T=O 16 4.4 At)UAI. AS COnti! NS INC 'nu[REO
'[0 EXC)tal)GEH A 2R)IS~NOV24A LPCI INLEt A ~ S.S HP 575 SS. I &. 4 T=o I 'P. 4 T=O 66 12. 4 T=o 66 12. 4 NOI REOU IREO 2R)IS inov25a CON[athtlENI 2.6 HP 575 40.5 B. I T"-0 26 8.1 T=O 26 8.1 T=o 26 8.1 NOf St'RAT A REOU IREO 28)ISatlOV26A HEAf FXCHANGER 0.13 )IP, 575 1.3 0. 13 (1ANUAL AS 1.3 O. 13 tlANUAL AS 1.3, 0.13 tlANUAL AS 1.3 0:13 t)ANUAL AS A VEttf 10 REOIIIREO REOUIREO REOUIREO REOUIREO SUI'PRESSION POOI, 2'.25 2Rhs.nov27A HEaT ExchaNGER 0.13 HP 575 1.3 0. 13 tlAtlUAL AS 1.3 0. 13 IIANUAL AS 1.3 0. 13 tlANUAL AS 1.3 0. 13 tlANUAL AS A YEN) 10 REOUI RE 0 REOU IREO REOUIREO REOU IREO SUPPRESSION POOL / ~ i 2RHS tlov30A RtlR REfURN TO SUP)'RESSIOtt POOL (21 (2) t +Q-.B.Z tlANUAI. AS REUU Ik[.0 tlANUAL AS REOUIREO
- I& C)&9.2 tlANUAL AS REOUIREO (D )Ca ~9i2 tlANUAL AS REOU IREO
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'00 Eno(CLNC Y 600-V PANEL 2HVC*CHIIA CorrtkoL i ( G 60 KW 575 60 60 T=o 60 T-"0 60 60 T=o 6o 60 T=O ei)ttnlwn C <<'o tttfr< ~ 'Oi) rt ur> rrLA(tn 2HVC~CH12A C()N(NUL G 40 KM 575 3 40 40 T=O 40 40 T=O 40 40 T"0 ~
40 40 T=o Hit(I nitro geLr>-q ~annul Vir trg No(In ~>rrt) HI.A IF N 2SC Y.XO I 0 I A Q I S(rr luu t I ON G 25 KVA 575 I 300 f=o 300 T=O 300 T=O f t(ANSI iiiiin.ii ( 0. I 5'L C I t Li SEC) , (0.1 SEC I 10.1 SEC I 60i)V- 120/240V 2VBA UPSPA (ACI I Dl'I IA G 25 K'IA 5/5 3 300 T=O 3OO 45 T=O 300 45 T=a 300 45 t=o CON I i(ui lii'i> (0.1 SEC) 10.) SLCI ( 0. I 5 f. C I (0.( SEC) AnENQ:ithi 23 9 OF 13 OtCEn8ER 1985 APERTURE
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NINE (I(LE POINf UNIT 2 FSAR TAQI.I: 0.3 ~ I (CAN( ) Ol'!.i(ctt OASIS ACC IUt ttl 0 [F..'i( t. GFNLIIA[OH LOAOtNG POSS [8 tL I f IES NONACC IGEHT LOADING S[ttULTANEOUS LOOP 4 LOCA LOOt'l TH OF.LAYEO LOCA LOCA Hl[H OELAYEG LOOP LOOP HITH UNIT TR[P PONER SOURCE/ START(HG STARf(HG STARf[HG OIVI- STARI'tNG EOUIPttEhtf OESCRIP((OH RATING VOL'IS KVA RUNH IHG STAR I [NG KVA 'UNNING SfARf [NG KVA RUNNING SfART(NG KVA STAR f [NG IOLHflTY iVO. 5 I OH Pt(ASE (KYAR) KVA T Itic (KVAH )., KVA T ltlE (KYAR) T )tlE RUNN [7(G KVA (KYAR) KVA T I tlE 2)44 S~ uRr, I (3) RKMi48 Fht.~.T 6 4HP 575 3 rhro/ w"~r/rr'""D //or REQUrrZa o'ol tE JIBED PV, Qrlnr.L AIR+ j /Vol /PZ.? Uiwd4>> TOIAL LOAO OH 2EJS>>PHLIOOA 1850( 1653 I 0<f ~0.[ SFC 1850( [653[ 0 <T<0.1 SEC 185011653) - 0 ST SO. I SEC 1850( 1653 O~TsO.I 590(393 1 IO O.l:f--6 SF,C 590(393 I 70 O-l'-0.6 SEC 590(393) 70 O.l -T-6 SEC 590(393 I SEC 315 f>6 SEC 315 T>6 SEC 315 'T BSEC
) 70 3[5 0 1 ST~6 T>> 6 SEC SEC 2LAC>>Pt)L I OOA 2QYS CHCR2AI 125-'I O' IERY G- 300 A 575 3 70 70 T=O 70 70 T=O 70 70 T=O CHARCER OIV I 70 IO T=O 2LAC>>XLEOI LIGHT[HO 0 30 KVA 5 IS 3 360 T=O 360 30 T=O 360 30 T=O TRAHSFOrlt[ER (0.1 SEC I 0.1 SEC I 360 30 T=O 600-208T/120V
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2SCt[>>XQ I 0 I A OI IOtt 0 25 KVA 575 I 300 T=o 300 25 T=O 300 25 T=O 300 25 T=O TRAHSr Otttti:rt (0.1 SEC) (0.1 SEC I (O.I SEC 600'20/240V I [0.1 SEC I 25Ct)>>XQI02A OISIN I BUT [OH 0 25 KVA 575 I 300 T=O 300 25 T=O 300 25 TRAHSFORIIER (0.1 SEC T=O 300 25 T=O 600- 120/240V I [0.1 SEC I [0.[ SEC I (0.1 SEC) 2SCtl>>X0103A QIStR[buf[OH 0 25 KVA 575 I 300 T=O 300 25 T=O 300 25 T=O THAttSFU[ttlE[t (0.1 SEC (0.1 300 25 T=O 600-120/240v I SEC I [0.1 SEC I (0.1 SEC I 25CII>>XO[04A } 0 I S IH I Qt) I (ON 0 25 KVA 5 IS 300 T=O 300 T=O 300 h5 T=O 1[tAt(St Ulttlt'll 300 .T=O 600-1?0/240V 2SCII X0105A 0(SIR(OUI [OH 0 25 KVA 575 I 300 '[=0 300 T=O .300 THAI[Sr )UHttEH T=O 300 T=O ~ .. ~ .' 600-120/240V 2VBA>>UPS2A GIV IA COWIROL 0 25 KVA 5/5 I (AC2) UPS TOIAL LOAO ON 2LAC>>PI(LIOOA 2650(2558 I T >0. I SEC 2650( 2558 I T ~0.1 SEC 2650l 2558 I - T 50.[ SEC 2Q)0(25581 ~0.[ SEC 125 T>>0.[ SEC 125 T>> 0.1 SEC T ~0.1 SEC [25 T %0.[ SEC 2NNS-SNC014 2CCP-3C RQCLCN PUIIP 3C H 150 HP 4.000 3 900 150 AS REOU(REG ~
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2CCP-PIC RQCLCN PUtlP IC H 150 HP F 000 3 900 150 , AS REOU(REO 2ROS-PIA COHIKOL ROO N 300 HP F 000 3 CHIVE Put(P a 1.800 300 AS REOU[REO h i ~~ a LOAO [NCLUOEII Itt 2L JS PNLIOOA h
. ~ hh hh A(1EHOIIENI ?3 10 OF (7 OECEIIBF R 1985
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NIHC n[LE POINT UNt t 2 FSAR TABLF 8.3-1 (CON(') LOAOINC POSSIBILITIES NDNAcc[DENT LCADINC DESIGN BASIS ACCIOENt OIESEI GENERA[OR LOCA N[l'H OELATEO LOOP LOOP NITH UN(T TRIP Stnul Tat!rOus LOOP C. LOCa I.OOP H((H OELATEO LOCA START INC STARTINC 5 I'AR 1 INC RUNNING STARTING KVA RUNNING STARTIHG 5TARI ING START ING KVA PONER SOURCE/ KVA RU(lN INC S t ART INC KVA RUN)(ING T tnE [KYAR ) KVA T lnE (KYAR) KVA TINE EOU I POEN I OIVI- RAIING 'VOLTS P)IASE (KYAR ) KVra T tnE I KYAR I KVA IOENf[IT No. DESCR(Pt(ON 5 I ot( 2I)JS-US5 450 75 AS REOUIREO l5 t(P 5 IS 2AAS-Cl BREATHING AIR 115 115 conpNEsso(f 575 28TS-CHGRIAI 125 ' BA[TERT 500 A ' 900 150 AS REOUIREO et(au EH 1RAIN [HSIRui)ENI AIR N 150 HP 5 IS 21AS-CIA NONCO(NC[- 110 T=O (IAHUAI. COnPRLSSO< a OENT 0 IS IR I OUI luf) 5 lb 2t(JS-PNL500 ' I 344 112 T=O nANuaL PANEL 600 IT=0.1
~
SEC I 2VBB-XO500 ~ Iso[ A [ ION 112 KVA TRANSFOKnER li344 1(2 T=O naNUAL UPS (T=0.1 SEC) N 112 KVA 5'l5 3 2VBB-XD501 ISO( AT ION
'f RaiiSf ORnER 150 T=O f)ANUAL 900 r UPS RMCU PvnP A 150 HP 2NCS-P I A 60 (0 T=O naNUA(.
2N)ls-nccu08 N )0 HP 575 3 20tR-Psa REAC(OH Bill) 0 INC
~ EOU(PntNI T=O nAHUAL DRAIN PunP A N 10 HP 5'IS 3 2DER-PSC RCAC[ON But[ 0(NCi EUU(PnhNT 25 T=O f(AI(UAL ORA(N Pufu' (50 A/C FOAtl H 25 HP SIS 3 2FPF-P)A CONCf ufHA I ION 18 3 T=O flANUAL Put lP 2FPF-P2A A/C Fuan NosE N 3 HP SIS 3 20 T"-10 SEC nANUAI.
120 s)at[un PunP 20 HP 575 3 2cno-pl nA(N SEAL OIL N 12 2 T= I 0 SEC f(ANUAI.. Pu)IP OIL N 2 )IP 575 3 20flo-P3 SEAL 7.5 T"-10 SEC nANUAL vlcuun punp N 7.5 t(P 575 3 2Gno-P4 RECIRCULA((OH 0.8 0 13 T 0 naNUAt. 5EAL OtL punp 'I 3 'i OR[YE MATER N 0.13 HP 575 2ROS-PV101 PRESSURE (50 25 T 0 nanuat. CON(KOL N 25 HP SIS 3 2RPn-nCIA RE AC(OR PRO ILC I (ON 30 T=l HR f)C SE I A tuRBINF S HP 575 3 2tf)L-P6A BFA(t in(i 30 5 T=I HR LIF I Pull(' SIS 3 2 f f)L-P68 Iu)f0 I ut BE 'f [NC N 5 HP At(EHof)ENT 23 ll OF 13 OE'f;Ef(BER 1985 L IF I PunP 8 0- gPPR~
- CILRD,, 88 OB 9-6 01,4,i,,=,.-l;...,..';;::;;.",;...,:
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h d NINF. fllLE POINT UNI f 2 FSAR TABLE 8.3-1 (CONI) OEStGN BASIS ACCIOF'Nf OtES'C(. GENERAfOR LOADING POSSIBILII'IES NONACCIOENT LOAOING Sltiul IAHEOUS I.OOP 4, LOCA LOOP MiT)l OELAYEO LOCA LOCA HITH OELAYEO LOOP LOOP M)TH UNIT TRIP POMER SOURCE/ srARriNG STARrfNG SfARTING SfARr IHG EQUIPnENT ~ OIVI- KVA RUNNING I'AR I !NG KVA RUNHING SfARI'ING KVA RUNNING START ING KVA RUNNING SI'ART ING IUENII IZ NO. OESCN IP I ION S ION RAf ING VOL)5 PNASF (HVAR ) KVA r lnC (KYAR) KVA r lnC (KYAR) KVA T If)C (KYAR) KVA TlhlE
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2fnL-P6C TURB(tiE N 575 3 ( I I' (I) 30 T" I HR 8 . AR ING I.IF I Put i' 2IOL-P60 1 URti I NF 5 itr 575 30 T=l HR BL Alt I tio L! t I ruiir 0 2)nL-P6E )UHt) IN( N SUP 575 3 T=l HR Bf. AR I NG Llf I Putii' \~ 4
~
ZrnL-PSF TURB(NE H SUP 575 3 30 T=l HR BEARING LIFI PUIIP F ~ C ~ 2T(lL-P6G f URl) I NE H 5HP 575 3 30 ,5 T=l HR . ~ BFAR ltiG LII I I'Ut)r 0 2fnL-PGH lit!<I)I)if N 5 Iit' 30 T=l HR Ui At< Inn Lll I Puili' ' 2MCS-OIXIOOA RMC it f'RL I:OA T I HP 5/5 T=D tlANUAL AC( IAIOK A 2MCS-nl X I 0 I A RMcii RCS Iii I HP 575 T=O IIANUAL FEEO AGIIATOR A 2MCS-nov)06 RMCU TO LMS N 2.6 HP 575 26 7.1 T=O tlANUAL 2Mcs-novl07 RMcu To nAtN N 2.6 HP 575 26 7.1 T=O f)ANUAt. CQMOF NSER 'I
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2Mcs-novl08 RMCU SYsfCn N 0.67 IIP 575 6.7 T=O tlANUAt. GRAIN h ~ 2MCS-tlov)09 REGFiiFRAtir 1.6 IIP 575 16 4.9 T=O IIANUAL h HEA( FXC)IAHGER h ~ h To l(LAC)utt 2MCS-nov<<0 CLEANiiP SZS (Eti N 1,6 i(P 16 T=o nANUAL BYPASS Ht'(5 hh 2MCS-tioV)ll iiEA I EXCIIAiiGLR I.G 16 4.9 T=o tiANUAL UZI'AS:I fu RLAC'rOH 2MCS-PI2A RMoi PRECOAr 10 HP 575 85 8.5 T=O nANUAL Put)P A 2MCS-P6A RMCU F ILTFR 3 HP 575 T=O nANUAL OEn(NERAL IVER 20.77 HOLOUP Put)P A 2MCS-P6C Ri(CU F I L f ER 3 HP 575 20.77 3.7 T=o llANUAL OEtilNERAL12ER t J h ~
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20CR-P3A REAC fOH Bit(LO(NG 10 IIP .575 3 10 T=O nANUAL Eou)PncNr GRAIN PUNP A 2)niS-ncc011 2CCI'-nov)A RBci CM lu N 0.)3 HP 575 1.3 0. 39 T = 0 tlAHUAL~ =~ .,: s OR(M(t I CU[)I.F.I( Ot)IUOAI> ~ q'h h ' Also AwuJah19 On
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NINE fl(LE POINT UNI I 2 FSAR 1ADLE (L3-I ICOt(T) DESIGN OASIS ACCIUENI 0)l SFL GCNERA10R LOADING POSSIBILITIES NOMACCIOENT LOADING SlfIULTAN(.GUS LOOP 4 LOCA LOOP Hl (H DELAYED LOCA LOCA Hll'H DELAYED LOOP. LOOP HI TH UNIT TRIP POWER SOURCE/ S1AR I ING STARTING START)NG STARTING EoulpnEMT OI VI- KVA RutINING STAR I ) NG KVA RUtft(I NG STARTING KVA RUNNING STARTING KVA RUNNING START I NO IDEM) TY NO. DESCRIPTION SION RATING VOLTS PHASE (KYAR I KVA TlnE I KYAR I KVA T I IIE (KYAR) KVA T If)E (KYAR) IIVA TIIIK 2CCP-tIOVIC RBCLCH TO 0.13 HP 575 ).3 0.39 T=o (IANUAL ORYWLI.L COOLER OUTBOARD IsoLATIOM 2CCP-nov2A RBCLCH fO N 0.13 HP . 575 3 1.3 O. 39 T=o flANUAL DR'IWL'Ll CUOIER OIITBOANO
)SOI A I ION 2ccp-nov2c RIICLCW 10 N 0.13 HP 575 . 3 1.3 0.39 T=O naNUAL OR'YWI I I COOI ER OUIBOARO ISOI.AT)OH 2ccp-nov3a RBCICH 'fo N 013 HP 575 3 1.3 O. 39 " T-"0 tIANUAL DRYIIEII COOLER OIIlQOARU ISOLA))ON 20RS-UC)A ORYWLLL CIHII.ER 20 IIP )20 20 T=Bo f)IN IA f)AIIUAL 20RS-UCIC ORYHEIL COOLER N 20 IIP 575 120 20 T=30 nIM IC IIAMUAI.
20RS-UC2A ORYHF(L COOLFR N )0 HP 575 60 10 T=3O nIN 2A natruaL 20RS-UC2C ORYHFLL COOI.ER )0 HP 575 60 10 T=3O n)N 2C tlAMUAL 20RS-UC3A DR'f WELL COOLER N 15 HP 5')5 90 T=30 nIM 3A tlat(UAL 21AS-C2 aos vat.vE N 7.5 HP 575 45 1 5 NO'1 REQUIRED conf'RCssoR 2ns5<<H'fv7A nslv OulooaRD 3 HP 575 18 T=0 flAt(UAL 2tlS5 HYV18 nslv Ou)BOARD 3 IIP 18 T=o tlat(UAI. 18 " 3 T=o fIANUAL 2nSS-H'YV7C nSIV OU)BOARD N . 3HP 2nsS.HYv70 nS)v OUTBOARD 3 HP 18 T=o flANUAI. ~ r r 2RCS~HOVIOA RECIRCULA)ION 4 HP 575 40 11 ~ 2 T=O naNuaL PURP A SUCIIOM vaLYE 2RCS~nOYIBA RECIRCUI.A IIOtt 4 HP 575 40 11.2 T=o fIANUAI. PUOP A SUC)lurr VALYE 0.7 2HCS novlol RCS lo RWCU N hali HP 515 Qs 2.1 T=o natIUAL
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2HCS tlOV103 RCS jo RWCU 1.6 HP 575 16 5.1 T=O nAIIUAL'-"0
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2WCS~HOY)04 RCS )u kwCU 0.6 HP 575 2.1 tlANUAL
'=o 2HCS tIOY105 kCS TO RWCU 0.6 HP 575 2.1 naNuft.
,K' I I ) OISCUIINLC)f U l)UR) tIG I.OCA AHCNOIIENT 23 13 OF 13 OECEHBER )585 80 AvagaMe jg~ .I APei fare.GT ~P r
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p<v NINE MILE POINT UNIT 2 FSAR TABLE 8.3.2 OIVIS)ON ) I STANOBY OIESEL GENERATOR 2EGsxEG3 LOAO ]ABULATION OFSIGN BASIS ALC lot:NI OIESEL GENERATOR LOADING POSSIBILITIES NONACCIOENT LOAOING Slt(ULfaNEAUS LOOP 4 LOCA LOOP W)TH OELAYEO LOCA Loca MITH GELAYEG Loop LOOP WITH UNIT IRIP POWER SOURCE/ STARIING S)ART lttG STARTING STARTING EOUIPnENT 0 I VI- KVA RUNNING STARTING KVA RUNNING STARTING KVA RUNNING STARTING KVA RUNNING STARTtNG IOENIIIY N(L OESCRIPIION SION RAI ) NG VO(.ts PHASE IKVAR) KVA TlnE IKVAR) KVA T I OE (KYAR) KVA I lflE (KYAR) (KVA) T I tlE 2ENS ~ SMG)03 2R(tssP I 8 RHR PunP 8 Y 1.000 HP F 000 5.681 790
/ 0.9 I>Q SEC 5.681 790 I+~
o.9 SFC 5 o 681 790 T(SEC o.9 5.681 790 nANUAL AFTER PF =0.)15 PF =0.115 PF=O.]15 PF =0. 115 T=I HR IF REOU1REO 5.$ 5,4. 2RttsiP I C Rt(R PunP C Y ).000 HP 4.000 5.681 790 IQ(i SEC 5.681 790 I+SEC oto32.89OR 5 681
~ 790 I+SEC 5.681 790 tlANUAL AF'IER PF =0.115 PF =0.1) 5 op?
PF =0. 115 A~ PF =0.115 T=l HR 2SMP*P)8 SM punp 8 Y 600 t(P F 000 3 3.097 500 I PunP hlYIOSTA~R ~2 3.097 500 I PuflP Atttf0stjgt 3.097 500 I PUrlP AZOSTAIPf 3e097 500 > eunw ~@/os/aR~w I unp 8 PF =0.247 olo32.(]c)NON (4p SEC PF<0.247 4 o t;~r'i St.c 4 o To+A.SFC~t(t
$ 6 SEC PF =0.247 oT 3213()t OR Cj SEC C o TEST.$ CC )7(t PF =0.247 oto32.&oOR a o TPW'SEC.
(fj SEC I PU(tl'lANUALLT I PU(lP'flANUALLY I PuflP flANUALL'Y )7P Stat(l EO STAR IEO Sl'ARTEO SlaRIEO
<p1 /37 7 2SMPaPIO SM PunP O Y 600 HP 4.000 3 '97 500 I PUt)P AlH'GS)atà ot-32 At) OR @t SEC 3 ~ 097 500 I pUflp autosIAR+~
ol =32 '3(tt.OR 3.097 PF=0.247 S00' Pun. MOST>dt oto32.89;OR +4 SEC 3.097 PF= 0.247 500 I PunP >MOSIARI f~ oto32.6S~,OR QP SEC PF=0.247 ~ PF=0 247 SEC 4 o TH~9 Sl:C 4 o T<65LSEC ~O 4 o T~.S[c )70 4 o TgQLQEC ~ I Put(P HAtluiLLT I punpwaNUAM7 I PU(lP flANUALLY ) lunP nadOECiir SIAR)EO 51ARIEO SI AR IEO A~
'laRTEO
'2@7
%7 2SMPaP)F SM PUllP F 600 HP 4.000 3.097 500 ) PunP t]uf(ts)ARK 3.097 500 ) Puf(P AEOSTA94 3.097 500 ) PUflP +U]OSTJ(84 3e097 500 I PuflP 4 OSTAR~~2 PF =0.247 oto32.,99.0R gl SEC 4 o I -..i9 St. C PF=0.24) oto32./39.0R $6'EC 4 o I~a~'9FQ 7(t PF=0.247 oto32.l39 4 o TQj9SEC
~ OR $8'EC PF= 0.247 ol=32 4 0 T > '
9 ~ OR SEC po ~ I punt naNuALLY I Puilf'lAt(UALLY I PUnP nANUAIMT/'TAR I PU()P naNUALLY Sl A((IEO Sl ARIEO IEO SIARIEO 2SFCRP)8 SFC MATER Y 450 HP 2.279 360 nAN()AL AFIER 2 e279 360 nANUAL AFTER 2.279 360 nattuAL AFTER 2 279
~ 360 flAttUAL AFTER CIRCULATION I'F =0.281 1=2 ((R PF o0.281 T"2 HR PF=0,281 1=2 HR PF=0.28] 1=2 HR
'9 PUGP 8 2EJSsUS3.
2EJsaX3A LOAO CEN]ER ) 500/ 4.)60/ 3 18 ~ 000 19 T=O 18 ~ 000 T=O ]8 .000 )9 T=O 18e000 19 I"0 IRANSFORnER
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2.025 KVA 600 ( I < O. I SEC) (15 0. I SEC) I T50.1 SEC I ( I 5 0. I SEC I 2EJsaX38 Loao CEN)ER I 500/ 4.160/ 3 10 F 000 )9 T=0 )8.000 )9 T=O 18 ~ 000 19 I=O 18. 000 )9 T=O
'IKartst URnER 2 F
'25 KVA 600 ( I < O. I SEC I (150.1 SEC I (1<0.1 SEC) ( I S 0.1 SEC I l=).5 I=I.s
'60 2HVR*UC4138 REAC]OR BUILO- 'Y 150 HP 575 3 Of)0 150 I= 1.5 SEC 860 150 SEC 150 SEC 860 150 1=30 tl)N f(ANUAL ING UNII COOLER 8 2HVK ~ CHLIB() I CONTROL BUILO- Y 180 l(P 575 3 722 )80 T"30 SEC 722 )80 T=30 SEC 722 T=30 SEC 722 180 T=30 SEC tlANUAL-ING CHILLER ]8 2HCS ~ PNL228 HYOROGEN RE-COflUINER POWER Y )20 KM 75 3 )20 120 T "2.5 HR 120 )20 I=2.5 HR 120 120 T=2.5 HR ]20 120 T=2.5 HR CABLE 8 TOTAL LOAO ON 36 ~ 000 T50.1 SEC 36.000 TSO.] SEC 36o000 T< 0.1 SEC 36 000 T<0.1 SEC 2EJS<US3 (35.)66) (35 '66) 0.)5T<].s l35 AD ]66) 38 0.1ST <].5 (35 F 166) 38 0.15T <1.5 SEC 38 0.15t <1.5 SEC y 38 SEC 1.5SI'4 SEC SEC 860( 806) 3tl ).5<t<4 SEC 860( 806) 38 1.551 <4 SEC 860(806) 38 860(806) 38 1.551 <4 SEC
)88 4 <f <30 SEC 188 4 5'f <30 SEC 188 4 <I <30 SEC )88 4 ST<30 SEC
,72/( G 17 I IUO 30 < 1< 36 SF.C 722I677 I )OB 30 5 '1<36'EC ?22(677) )88 30 5 T<36 SEC 722(677) 188 30 5 1<36 SEC 3GB 36 SEC < 1<2.5 HR 368 36 SEC 5 T<2.5 HR 368 36 SEC < I<2.5 HR 368 36 SEC 5 T< 2.5 HR 488 I >2.5 HR 488 T>2.5 HR 408 T >2.5 HR 488 1 <2.5 ttk Af(ENonENT 23 I OF ll OECEnBER 1985 SBOBB() 0141:;.)4; .,:.:;:,:...:
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NINE n(LE POINI'N[T 2 FSAR tABLE 8.3-2 (CONf.,l 0Es(GN BAs[s AccloENT OIESEL GENERAI'OR LOAO[NG PosslBtLIT(ES NONACC[OEHT LOAOING r S(OULTANEOUS LOOP 4 LOCA LOOP M[TH OELAYEO LOCA LOCA M[TH OELAYEO LOOP LOOP WITH UN[T TRIP POWER SOURCE/ START ING 6 I'AR T I NG START ING EoulpnENr STARTING OIV[- KVA RUNNtNG STARTING KVA RUNNING STaRt(NG KVA Kva [OEN[IIY No. OESCR(PIION SION RAt ING VOLTS PHASE (HVAR) Kva tlflE (KYAR) KVA TIIIE (KYAR ) RUNH[NG KVA
'START INE ING (KYAR)
RUNNING STARTIHG 1 KVA TlfIE 2EHsinCC301 2HVY>UC28 sw punp ptt Y 40 HP 5') 5 240 40 T=60 SEC rlANUAL 240 40 T=60 SEC ANUA 240 40 T=60 SEC UNIT COOLER 240 40 flANUAL T=60 SEC 2HVYIUC20 sM punp ptl Y 40 HP 575 3 240 40 T=BO SEC([)ANVIL 240 40 T=60 SEC ~ANNAL 240 40 T=60 SEC 240 40 nANUAL I'=60 SEC uNIT COOLER f 2swpinov[8 SM BACKWASH Y 0.13 HP 575 1.3 0.76 T=o 1.3 0.26 T=o 0.26 2SMP~novlo L INL 0.13 HP
) I~ 3 T= 0 1.3 0. 26 T=o SW BACKMASH 575 1.3 0. 26 T(5l0 f)IN IIANUAL 1.3 0.26 IIIH IIANUAL Qio L I(IE Y Tidal 0 I~ 3 o.26 n[H naHUAL 1.3 0.26 +[0 nIH nakuaL 26Mpinov[F SM STRAINER 0.13 HP 575 3 1.3 0. 26 1+0 tllH flANUAL 1.3 0. 26 Tg)0 (l[N (IANUAI. 1.3 o.26 -Io n(N naHUAL 1.3 BACKWASH 0.26 7= 0 fllN nANUAL 4
23Mpinov38 SM To fURBINE ButLOING Y HP 575 3 (Q-4C) Q-c) T=O T=o 5 T=o 8 T=O 2swp>nov308 noIOR-OPERA IEO Y I HP 575 lo t=o 10 2 T=o 10 2 T=o 10 GA IE 2 T=o 99 2SMP ~ f)OV508 SW I'UOPS OIS-CHAkGE HEAOER Y ~Q) HP 575 3 ~i99 rVB T=o (Ft)-99 ~)98 T=o (LOCA I ~99 I'AS T=o (LOOP) (9,8 T=o nANUAL 2Swp nOv748 sw pun( ots- 2.6 HP 575 3 26 ~i@ T= 0 T=O 26 T=o T=o CHARGE BLOCK 5.2 5.2 vaLvE 2swp~nov74D SM Puf)P 0[S- Y 2.6 HP 575 3 26 T=o 26 26 T=o 26 T=o CHARGE BLOCK VALVE 2SWP*flov74F SM PU(IP OISCHARGE Y 2.6 HP 575 t>[o n[N nakuaL T> lo tllk nAHUAL 26 T> I o ntk nANUAL BLOCK VALVE 0.7 2 5 2 26 5 2 T> I o n[H nAHUAL 2skp*nov778 flo fOR GAfE
~ OPERA I ED Y .6b HP 575 3 ~70 T-0 fIAHUAL 7.O
(.4 T=o naHuaL 7.O [.4 T=o f)AHuaL T=o IIANUAL I.4 2SMPissR I 8 BAR RACK Y 2.8 KM 575 I 2.8 2.8 T=O 2.8 2.8 T=o 2.8 2.8 T=o HEAIEr[ 2.8 2.8 T= 0 2SWPissR28 'BAR RACK Y 2.8 KM 5)b I 2.8 2.8 T=o 2.8 T=o 2.8 2.8 T=o HEA IER 2.8 2.8 T=o 2SWPRSSR38 BAR RACK Y 2.8 KW 575 2.8 T-"0 2.8 2.8 T=o 2.8 2.8 T=o HEAIER
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2.8 2.8 T=o 2SMP>SSR48 uak RACK Y 2.8 KM 575 I 2.8 2 8 . T=O 2.8 2.8 T=o 2.8 2.8 T=O 2.8 HEAIER 2.8 T=o 2SMP4SSRSB OAR RACK 575 I 2.8 T "-0 2.8 T=o 2.8 2 8 HEA(ER T=O 2.8 2.8 T=o 2SMPissk68 BAR RACK Y 2.8 KM 575 I 2.8 2.8 T=o 2.8 2.8 T= 0 HEAI'ER 2.8 2.8 T=o 2SMPasTR48 SIRA[NER SM Y 3HP 575 3 18 T"0 T=o (8 T=o
/ 18'8 3 T=o 2SWP ~ StR40 SlkAI)rEk SM Y 3HP 575 18 T> lo n[N nANUAL T> 10 fllN IIANUAL T>[0 ntk 18 18 nAHUAL 3 T> lo fltk nAHUAL 2SMPiSTR4F SlkAINER SW Y 3HP 575 3 18 T> 10 fllN GANUAL 18 f> [0 fl[H f)ANUAL 18 3 I'> I 0 n(N
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GANUAI. 18 3 T> lo n[H nANUAL AnENOOENf 23 2 OF 11 OE ..".BER 1985 I 't>> Rt~
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NINE nlLE POINT UNIT 2 FSAR TABLE 8.3-2 (CONf I DESIGN OASIS ACCIOEwf 0(ESEL CENERATOR LOAD(NG POSSIBILITIES NONACCIOENT LOADINO SlflULfANFOUS LOOP 4 LOCA LOQP HITH DELAYED LOCA LOCA MI TH DELAYED I.OOP LOOP MITH UNI'I TRIP PowER SOURCE/ StAR(ING sraR I INC START(NG STARTINC EQULPf)Cwr DIVI- Kva RUNNING STARIING Nva RUNN(NC STARTINC t(VA RUNNING SI'ART INC NVA RUNNING STARTINC (OCNIITY WO. DESCRIPTION SION RA'flNG VOLTS PHASE (KYAR) NVA T( fIC (KYAR) NVA TrnE t KYAR) KVA T ltLE LKVAR) NVA Tlf(E 0<1'<6 2ii{r/) 0<T<6 i i /r/' oar<6 s EC g~D" TOTAL LOAD OH 2EHS>nCC30) JI )5(r)i 42-uS 6<r<60 SEC SEC 62fiL5ED 480( 450 / 2-~ c,ZW BET<60 SEC SEC ~a~)~IL co2~ 6S T<60 SEC g() ~ 05T<6 SEC 6<T<60 SEC
/IP i~O< 7 X I0//If/I 480(450)
$ 5Kip
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) <<c, 60 < T <66 SEC 66 SEC<I<(Qj IO nlwkr<LO.L nlw j(P w "-
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6051'<66 SEC 66 SEC 5T<((7~II 10 nlW< r<LO.L nlw 4801450) c,2~4;
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<</,~>> IO.I n(N< T 2EHs~nCC302 3S'30 a5 2E JsiPtIL3028 AB-S EnERGENCY 400A 575 3 180 30 T=o 180 T=o 180 Q3 i=i 180 0 T=O 600-V PANEL 2EJS>>Pi(L3038 AB-S ENERGENCY 600-V PANEL Y 400A 575 3 L50 25 T=O 150 25'=0 150 25 T=o 150 25 T=o 2EJS.PWL3048 Ao-S EtlERGEt(CY 40oa 5)5 3 360 so t=o 360 50 7"-0 360 50 r=o 360 '50 T=o 600-V PANEL 2GTS ~ FNIB SGI'S FILTER Y >>O )TP 575 3 240 40 T=o 240 40 T=O 240 40 T=O 240 40 T=o IR*lw 8 LN(.Ef DISCHARGE FAW 2ors-nOvlo 1(vR nlx PLENun Y 0.34 HP 575 3 34 068 t 0 3,4 0.68 T-"0 3.4 0.68 r=o 3.4 0.68 T=o ro SG(s 2crs.nov28 Sofs FILTER 5/5 3 ~i- ZO ~~+ T=o (g- Zo -< t=o T=O 20 4 T=o TRAIN 8 INLET 2
2CTS.nov38 SCfS FILTER TRA(w 8 DISCHARGE Y Qi HP 575 3 (m)--0 Q7 4 T=o (17))-2o -o r=o Qy' (P3-$ T=0 (DO ZO
~4 T-0 gciT kl/c//ooc >> 6'aO L '/IiLVC 2HP 5U 7r 0 20 7= 0 20 7>>0 gO Tscp 2ors~nov>>8 DECAY HEAT Y I HP 575 Io 1. 7 T=0 lo 1.'7 T=o 10 I. I T=o 10 I.'7 T=o COOLER IO TRAIN 8 2HCS ~ tlov I 8 ME fwCI,L HYDRO- Y 0.33 HP 575 3 3.3 .3 fLANUAL AS 3.3 .3 tlANUAL AS 3.3 nawuaL As 3.3 ~ t)ANUAL AS GEN RCCQIIB I ivER C G,(i/~ REQUIREQ REQUIRED 4 p,/ci/ REQUIRED RE'QUIRED ISOLAI ION VALVE p >>
33
'3 2HCS ~ nov28 ME(MELL HYORO- Y 0.33 HP 575 3 tlANUAI. AS nawuaL as 3.3 nawuaL as 3.3 tIANUAL AS GEN (SU(A RCCOflo I t)ER ~
g.(,g RCQULREA i REQUIRED p~Y, REQUIRED ISOLAI IQW VALVE p c,r 0 ~@ REQU(REI) 2HCs~nov38 WETMELL HYORO- Y 0.33 HP 575 3 33 ~3 nawuaL as 3.3 t(ANUAL AS 3.3 tlAHUAL AS 3.3 nawuaL As GEw RECOnolwER <().qo REQUIRED REQUIRED (ig,f/Ci, REQUIRED ISOLATION VALVE o kh 0 4,4,REQUIRED 2HCS ~ tloV48 ORYMELL HYOf(0- Y 0.33 HP 575 3 3.3 o. Zl) tlANUAL As 3.3 nAwuaL AS 3.3 t)ANUAL AS 3.3 nawuaL as GEW RECOflo ltIER ~g.gc REQUIRED p 4,Q REQUIRED 0 &g REQU I RED g p r g REQUIRED ISOLATION VALVE 2wcs>>nov58 DRYMCLL HYDRO-GEN RECOIIOLNER LSOLAI LOW VALVE Y 033 HP 575 3 33 gg g
'lANUAL AS RCQIILREI) 3,3 j i(C3J/ nawuaL REQUIRED AS 3.3
- q. nawuaL As p,c,(, REQu (RED 3.3 nawuaL As 0 &g REQUIRED 2HCS nOv68 ORYMELL HYORO- Y 033 HP S IS 3 3.3 nawuAL AS 3.3 .33) 'tlANUAL AS 3.3 t)ANUAL AS 3.3 t)ANUAL AS Cliw RCCQIIQIHER (IOW VALVE p u, REQULRCn p C p REQUIRED g,c,/~ REOU I RED p ( g REQUIRED 2SWP.ffov I 'IB sw ro HUI:Lcw 1.6 HP 575 3 16 3 f 10 t) IN tlANUAL 16 3 T > lo tllw t)ANUAL 16 3 r > lo tllN tIANUAL 16 3 r>> lo tllw tlANUAL 2swp.nov)oo RUCICM 10 SM 1.6 HP 575 3 (6 3 t >> 10 tltff tIANUAL 3 t > 10 nlN nANUAL 16 f > lo tl(W IIAWUAL 16 3 r>> 10 tflw t(ANUAL 2SMP-novl98 ow lo ROCLCM f HP 5 I5 3 lo 2 r=o 10 2 1=0 10 2 I=o 10 2 f=o HEar ExoiiawGFR An('NIN(tf( 23 3 OF ll OLC(flol'R Iof)S APERTIME..
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OI VI- Kva RUNNINC STARTING KVA 'UNNING 5 I'ART INC Kva RUNNING START ING 'VA RUNN(NC STARTING 2S'MPH OESCRIPflPN SION Rat ING Vol.fS PHASE (KYAR) KVA rtnE IKvhR)',: Kva TlnE (KYAR) Kva T I rlE IKVAR) KVA T I flE 2SMP ~ nov218 RBCLCM fo SFC 0.33 HP 575 3.3 0.45 T=IO rllN nANUAL 3.3 0.45 T=lo rllN nANUAL 3.3 4.5 T=(0 tllN HANUAL 3.3 COOL POOL O.45 T= I 0 nlN naNUAL (0. == l OO /<<i& / ~4i
'lov338 RHR HEat Ex- Y ~el HP 575 T=lo ntN nat(uaL T=1 0 tilt( t)ANUAL 8.3 T-"'le tlIN HANUAL Nor REOUIRED cliaNGER 8 fo I (LOCA ) LocA PiiL~S DISCHARGE TUNNEL 2Cns.~ ~M)Q- j~ Y I HP 5 IS 3 6 T> I HR tlANUAL T> I HR nANuaL I T>1 HP. rlANUAL I T> I HR tlANUAI.
2SLS.nOvsa ANALTLEit PunP SIANDOT LIOI)IO STOP CHECK VALVE 0,7 5/5 3 ~6. -70 S.T) I.'> I HR nAHUAL 7.01 ~i 4 T > I HR )1ANUAL 7.0 ~/.4 T> I HR t)ANUAL 7i0 dCZP-/.4<< T> I HR tlANUAL 0.7 2SMPinov388 SH TO RBCLCH +HP 575 3 <<6)-70 ~!.4 T=l 0 tllN tlANUAL (6)-7.0 T:-I 0 tlIN tlANUAL CE 7o ~/.4 T:-lo tltN IIANUAL ~/4 T=lo ntN naNuaL 2SMP.rlOv398 RBCLCM to SH Y
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- 7.o M-/4 T=to nIN rlANUAL 2SMP ~ i"iov908 RIIR MEAT EX- Y 0.86 HP 5 IS 3 86 1.72 T= I 0 tilt) rlANUAL 0.6 1.72 TRIO tllN tlANUAL e.e 1.72 T10 tl(N tlANUAL I'S.o NOT REOUIREO CHANGER INLF. I I LOCA I 2OER novll9 coNralnnFNI 0.64 HP 575 3 6.4 0. 71 T=O 6.4 0. 71 T=O 6.4 0.71 T=o 6.4 0.71 T=O ISOLA)ION VALVE 20ER ~ loV130 OER TANK VENT Y 0.33 HP 5'IS 3 32 0. 36 3.2 0. 36 T=o 3.2 0.36 'f=0 3.2 0.36 20FR nov121 ORYMEIL FLOOR GRAIN OISCHARGE ISOLATION VALVE I5 3 <<ti 0-l .O ~>.g o.c 6 T=O /Ro 1
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)DEH)llY NL DFSCRII'f)PH RUNMINC STARTING KVA RUNNINC SION RA)]NC VOLTS pnasE IKvaR ) ttva f )nE IKVARI KVA T lflE IKVAR) Kva T I tlE )KYAR ) KVA STARTINC 1 I flE 2HVC~ACU38 REnolE snut- Y '2 HP 575 3 12 2 1=0 12 2 T=O 12 T=O DDMH HOOn 12 2 T=o A/C UNII 2HVC ~ FNI]8 n/,KEUP A)R Y 7.5 IIP 575 3 40 'I.S =0 T 40 7.5 T=o 40 ').5 1=0 40 SMI I CIIGE AR 7.5 1=0 FLOOR 2HVC ~ FN28 CON)ROL RDOfl 10 HP 5 IS A/C Dt)us1CR Y 3 60 10 T=o 60 )0 . 1"0 60 10 1=0 60 10 T=O F At) 8 2HVC ~ Ftfc8 8/.1 ltRY Roon 8 Y 3 HP 575 3 18 3 1=0
. EXCHANGE FAN 18 3 T=o 18 3 T=o 18 3 T=O 2HVC.novl8 CONTROL R0011 Y 0.25 HP 575 3 25 0.25 T=o lo A/C SPECIAL 0.25 1=0 10 0.25 T=o )0 0 25 T=O FIL)ER BYPASS 2HVKiP)8 CONT ROL BUILD)NG 'Y 15 HP 575 3 90 IS T=O 90 CHILLED MATER 15 T=o 90 15 T=o 90 15 1=0 CIRCULAIIDH
/=V475 PunP 8
/0.7 2SMP-;ovc7<< SM punt 5 IO CMS IIP 575 3 QJW 7.0 ~4. I 4 )>10 tl]N ~i po '~ 1.)O n)M 7.o C3-/4 1>>O n]N (Q-/.4 t>10 n]M naHUAL tlANUAL IlANUAI. naHuaL 2SMP.nOv668 SM 10 S]ANDBY Y I IIP 5 /5 3 lo 2 T=O 10 2 T=O 10 2 T=O 10 00 COO) Lll 0 tl]N /2.8 T> I 0 tl]H (ll0-'Co4 Q /p,g T>]0 tl]M Q-/2 8 T>10 tlIH flaNUAL naNUAL naNual.
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10 ]0 2 T>)0 tl]N naNuaL naNuaL f)ANUAI. 2SMP~P28 REACIOR GUILD II'unpC)t)LL-NG Y 10 HP 575 3 60 10 1>>o n)H 60 10 T>)0 tl]H 60 10 1>>o nlN 60 1>>o nlN tlAN)IAL naHUAI. tlANUAL ER sM 8 IIANUAL 2HVP FHIB
~ Dc 2 Lxnaust Y 30 HP SIS 3 I
180 30 T=O 180 30 T=o 100 30 I AN lu T=O 180 30 1=0 II AWED 2HVPiFHID DG 2 EXHAUST 30 HP 575 3 100 30 FAH )D T=O )80 30 T=o ]80 30 T=o )80 30 T=o 0..3 c. 33 2RHS~FV388 1651 LINE 8 10 SUPf'NESS I OM T 4~ HP 575 I98 W TO ~o'f c/8 . Q$ 0.33 T=O 0.33 1=0 O. 33 HOT REOUIRED POOL 2RHS ~ FV38C HIIR runp c 0.34 HP 575 3 2.04 0.34 tu stn'l>>> Put lP 8 NI SS)DM
'lo HHH T 1.6 IIP 5'IS 3 16 3.9 T =0 )6 '.2 T=o 16 32 T=O 16 LOHO t)nE OANUAL
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P-EVI~<O NINF. tl[LE Polnf UNI fj2 FSAR TABLE-8.3-2 (CONT) Hl'6 OFSIGM OASIS ACC IOEt[f OIESEL GENERATOR LOAOING POSSIB(LI TIES NONACC[OENT LOAO[NG S[nuLTAN[:Ous LOOP 4 LOCA LOOP M(TH OELAYEO LOCA LOCA MlfH OFLAYEO LOOP LOOP M(TH UNIT TRfP POWER SOURCE/ Sl'AR T I iVG Eou[PnEM( OI VI-START ING Sf ART ING STARTING KVA RUiVtl(NG STAR f [NG KVA 'UNtl)NG START ING KVA RUNNING STARTING loEufl)T N(L OESCR[P(IOM SiOM RA( ItIG VOL TS PilASE (KVA(t1 KVA T (tiF. (KYAR) KVA T (HE tKVAR) KVA TlnE KVA RUNNING STARTING (KYAR) KVA T[tlE 2RtiS ~ tlovIC SUPPRLSSION Y 1.6 5 IS 3 16 3.9 7=0 i& 3.2 T=O POOL to RLLR 16 3.2 T=o 16 3.2 NOT REOU IREO Pun? 2RtlS tloVI 12 C So COOLING @ i7? 575 gyi92 4
~/92 I I
~(-. T=O r>6 4L SUPPLT [MBOARO LONG T[nE ISOLA()OM . naNUAL
'2RHS ~ tlovl)5 SM INJFC(ION 1.6 tlP 575 22 4.4 Tu RLAC(OH Y 3 NOI REOU IREO 4. 4 Nol'EOUIREO 22 4.4 NOT REOUIREO 22 4.4 Not'EOUIREO I 2RHS tloV116 SM INJF(:I IOM Y 1.6 i[P 5'IS 3 25 5.0 NOI REOUIREO 5.0 NOT REOUIREO 25 To Rf.ACtuR 5.0 No,f REOUIREO 25 5.0 NOT REOUIREO 2RnS nOv)28 HEAT EXCHANGER Y 575 3 )0 2.6 T=[0 n)N 2.6 T=(0 n[H 8 to REAC(OR 10 2.6 T=(0 n[N 10 2.6 T=O 2Rns.novl49 HEAt EXC((A((GER Y 0.33 HP 575 3 33 0.53 T=O 3.3 0.53 T=O 3.3 0.53 T=0 8 fo LMS 3.3 0 53 ANUAL EOU[RED as,nL(5 2&ns~nov)58 coM( A [nnEMI 2.6 HP 575 40.5 T" 10 tl[N
/$ )snug SPRAT 8 3 8.1 40.5 8.1 T=i0 n(N 40.5 8.1 r=io n(N 40.5 B.l Nof REOUIREO 2RHS nOV28 REAC)OH TO Y 0.86 ii? 5/S 3 86 2.2 NO i REOUIREO 8.6 2.2 NOT REOUIREO 8.6 2.2 NOT REOU IREO 8.6 2 2 ANUAL AS RLLR Puti? 8 Eou IREG 2Rns.nov228 SIEAtl COMOLNS ING Y 1.6 HP 575 3 16 4.4 T=O 16 4.4 T=O LL) iinua) 16 4,4 T=O 16 4. 4 T=0 TO EXCLLA:IGER 8 2RnS.nOv238 StEA(l CONOFNS ING Y 1.6 HP 575 3 16 T=O .4. 4 T=O 16 4,4 To EXCHANGER 8 T=o 16 4.4 ANUAL AS ~T 2RHS tiov248 LPCt [)ILET 8 Y 6.6 HP 575 3 66 )2. 4 66 '24 T-"0
~OU(REO 66, T=O 66 [2. 4 T=O 66 12.4 NOI'EOUIREO 2RHS tlov24C LPCt INLET C Y 66HP 575 3 66 [2. 4 T=O [2. 4 T=O 66 12. 4 T=O 66 12.4 NOT REOUIREO 2RH5%nov258 COMTAIMtiEMT Y 2.6 HP 575 3 40.5 8.1 T=io nrN 40.5 8.[ T=I 0 HIN 40.5 8.1 SPRAY 8 T=(0 40.5 8. I T"-0 tlIH'.3 2Rns nov268 nEar ExcnaNGER Y 0.13 HP 5 IS 3 1.3 0.13 tiANUAL ).3 0.13 naNUAL 0. )3 8 VEiVt to j tlANUAL 1.3 0. 13 T= 0 AS REOUIREO AS REOU[REO REOU[REO
'S SUP('RESS[ON POOL 2Rtts nov278 nEaf EXCHANGER 0.13 HP 575 3 1.3 0. 13 '(AttuAL
).3 0. 13 nanuaL [.3 0. 13 8 VEMf TO t(ANUAL 1.3 0. [3 T=O AS REOUIREO i AS REOUIREO AS REOUIREO SUPPRESSION POOL 2Rns~nov308 RHRB Rfn to ~pl 575 Q2-3 @/6 +32 naNUAL
@//ii j 3.2'lANUAL naNUAL ~/Q 82 2RM5/$ t/~'IB>>
SUPP(LESS(OM POOL 6'"6 VALv6 V 0 (3HP 575 '.3 0 2/$ AS REOUIREO T=o 0.2'c AS REOUIREO
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AS REOUIREO T$ 0 [.3 0.2/$ NOT REOUIREO 7$ 0 2Rns.nov328 HEA( EXC((ANG-ER 8 (0 Rcic 0.7 575 ~7 T=O -7 )i4 T=O T=O 7 )i4 T=30 SEC 2RHS tlov338 SUPPRESSION Y 0.33 HP 575 0.92 T=O 3.3 0.92 T-"0 3.3 0.92 T=O POOL SPRA'T 0.92 NOT REOUIREO 2Rns-tlov378 HEAOER 8 RLLR L(ME 8 I'0 SUPPRESSION POOL Y 0.33 HP 5 IS 3 33 0.5 T=0 3.3 '.5 T=O 3.3 05 T-0 3.3 0 5 T=o 2Rnsinov4& Rtift n(M[nutt Y 1.9 LLP 575 19 T=9 SEC [9 T=9 SEC FLOM to SUP 19 f=9 SEC 19 LONG TERn PR('.SS[otl POOL nov4C RtiR n(NI tlun 19 HP 5/5 3 T=)4 FLOM tu SLIP-Y 19 3,8 SEC'Rt(5$ 3.8 T=i4 SEC 19 T=14 SEC 19 3.8 NOT REOUIREO '; PHtbs(OM POOL AHEMOHEHT 23 7 OF ll OECFH&E($ 'Ig&5
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HIM(; rl]Lf. POINT UM11 2 FSAR TaOLE 8.3-2 tCOHT I OESIGN BASIS ACCIUFNI OIESEL GENERATOR LOAOING POSSIBILITIES NONACCIOENl'OAOING Slf(UL)'ANFOUS LOOP 4 LOCA tiOOP HITH OELAYEO LOCA LOCA NITH OELAYEO LOOP LOOP H]TH UNIT TRIP POHER SOURCE/ STARTING STARTIHG Sl'ART ING STARTING EOUIPnEMT 01 VI- KVA RUNNING SfARTING KVA 'UNNING STARTING KVA RUNNING START ING Kva RUHH]NG STARTING
]OEM T I T Y H(1 OESCR I PT ION SION RA] It(G VOLTS Pt(ASF IKYAR) KVA I lnE tKVAR)t KVa T I t(E (KYAR) KVA T I tlE (KYAR) KVA T I(IE 2RHS ~ t(OV408 SHUTOOH(t COOL- Y 10.6 F(P 5'Is 3 )06 15 9 T=o 106 )59 T 0 106 ~ 15.9 T" 0 106 15.9 L0NG TERn ING RL'IU((N U 2Rtls nov678 R(IR SIIUI ()UFIM UYI'ASS Y 0.33 t(P 575 3 3.3 0.33 HO( R(.OUI((ED 3.3; 0.33 NO'f REOUIREO 3.3 0.33 NOI'EOUIREO 3.3- 0.33 LONG TERn 2R(tsinov88 (ILAT EXC((ANG- 575 3 )6 1.6 1=0 16 1.6 T= 0 16 )~ 6 T=o 16 ]~ 6 LONG TERn ER U OYI'ASS 2RHS~nov98 RHR PUf(P 8 HEAI EXCIIAMGER fO $ 75 3 CD I& ~-3.2 T=l 0 f(IN CD-/Cp ~
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]0 HP 575 3 60 10 '-o 60 lo T=o 60 10 T=O 60 )0 T=o 2HVKiCHLI tlg) AUX IL I ARY OIL Y 0.75 HP 575 4.5 0.75 T=o 4.5 0.75 T-"0 4.5 0.75 T=O 4.s 0.')5 T=o
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~,'53 19( 181 ';
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]Rat(SFORKER (0.1 SEC) (0.1 SEC) (0.1 SEC) (0.1 SEC) 600V-208Y/)20V 2EJA~XO3018 OISIRIBUTION Y 25 KVA 575 300 5 T=o 300 300 5 T=o 300 5 T=o TRAMSFORnER (0.1 SEC) (0.1 SEC') (0.1 SEC) (0.] SEC) 600V-120/240 2EJSrPML3018 Swt)CHGEaR 575 3 420 70 T=o 420 Io 420 70 T=o 420 70 T=o
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RE(.aY RGOn 306 HEAIER PMLCL()2 B 2HVC CON(ko( 8( OG Y 40 KH 575 3 40 40 T=O 40 40 T=o 40 T=o 40 40 T=O RE I.AY t(ootl l 288 I(CA)L(t 2SCV4X030)B OI5 I ((I(5UI ION Y 25 KVA 5/5 I 300 5 T=o 300 5 T=O 300 5 T=o 300 5 T=o 1RAt(st OKnLR (0.1 SEC) Io.l SEC) (0.1 SEC) (0.1 SEC) 600V-120/240V l 2VBaiUPS28 Olv Ila COH- 25 KVA 5 Is 300 4S T=O 300 45 T=o 300 . 45 T-o 300 4S T=O (ACI) 1ROL UPS (O. I SEC) (O.l SEC) (0.1 SEC) (0.1 SEC) TOTAL LOAO ON '850 I-) 653 I 051<0.) 1850( 1653 o<r<o.l sEc 1850( 1653) 0<T50 I ]850( 1653) 051 50.1 2E JS~('N( 3008 590( 393) 60 300 0.)< I <6 I >6 SEC SEC SEC 590( 393)
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N!NE tltLE POINT UNIT2 FSAR IADLE (L 3-2 ( CONT ) ~ POSS(8(LITIES NOMACCIDEMT LOADING DESIGN OASIS ACCIDENT DIESEL GENERATOR LOAD(MG LOOP )ttfH DELAYED LOCA LOCA )(ITH DEL AYED LOOP LOOP WITH UNIT TRIP StilUL tANEOUS LOOP 4 LOCA Sf ART IHG START ING STARTING PO)(ER SOURCE/ StARf(NCi 'UNNING START ING Kva RUNNING S'f ART ING Kva RUNNING STARTIMG SfARI ING KVA EQV t P>"iENI' OI VI- KVA RUt(NING rtnE (KYAR)I, KVA r lnE IKVAR) Kva I' tIE (KYAR) KVA T It)E DEMI I I 'Y NO OESCR IP f ION SION RAflNG yot.rs PII'SE I KV>LR ) ttva ZLAC>PNL3008 70 70 T=O 70 70 T=o 70 70 T=o 28YS 125-V BAIIFRY Y 300 A 3 70> 70 I=o CHARGER s)ANO ICHOR?8'LACsXLEOZ BY OIV Ll T=o 360 T=o 360 30
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5 T=o L IG)tl (NG Y 30 KVA 575 3 (0. I SEC) (0.1 SEC) f Rat) st ORHL(c (0.1 SEC) (O. I SEC I 600-'"s)HY/L20V T=o 360 15 T=o 360 30 T=o LID)tt ING 30 KVA 575 3 360 IS. T=o 360 (0.1 SEC) 2LACsXLE05 Y (0.1 SEC) (0.1, SEC) TRAt)St Vk>>ER (0.1 SEC) 600-208Y/120V 360 30 T=o 20 T=O 360 20 T=o 360 20 T=O 2LACsXLE07 L I Gtt I I HG Y 30 KVA 575 3 360 (0.1 SEC) (O.L SEC) IRANSFORt)ER (0.1 SEC) (0.1 SEC) 600-20BY/120V T=O 300 25 T=o T=o 300 5 T=O 300 5 2SCn XD3018 0 I S I R I BV'f LON Y 25 KVA 575 300 5 (0.1 SEC) (0.1 SEC) IRANSFORniER (0. I SEC) (0. I SEC) 600-120/240V T-"0 300 25 T=o 5 T=O 300 T=o 300 2SCn XO3028 OIS(RIBVf ION Y 25 KVA 575 I 300 (Q.l SECI (O.L SEC I TR')SFORi)ER (0.1 SEC) (0.1 SEC) 600-120/240V T"-0 300 25 T"-0 t=o 300 T=o 300 2SC(lsXD3038 0 I 5 I K I BU f ION 25 KVA 300 5 (0.1 SEC) (0 I SEC) TRaNSFORGER ( 0. I SEC ) (0.1 SEC) ZVBAiUPSZB 600- 120/?40V OIV IIA 25 KVA 575 T=O T=O Q-tI( T-" 0 Q-g T=O~ (AC2) CDNrRGL vps T=o 300 T=O 300 5 T=o 575 300 5 T=O 300 5 (0. I SEC) ZSCtlsXD3058 0 ISfR IBVT tON y 25 KVA (0.1 SEC) (0.1 SEC I TRAt)SFORt)ER (0.1 SEC) 600-120/?40V 5 . T=o 300 5 T=O T=O 300 5 T=O 300 2SCttsXD3048 (K LOU( ION 25 Kva 575 300 5 (0.1 SEC) (0.1 SEC) 0 1 5 TRANSFORtlEft (O.L SEC) (0. I SEC) 600-120/240V TofAL LOAD ON 2LACiPNL3008 - T~o.l 2650(2558 ) TS0. I SEC 2650(2558) - T S 0. I SEC 2650(2558 ) T~ 0.1 SEC
,26SO(2558) SEC 135 T+0.1 SEC 135 TO 0.1 SEC 135 T&0.( SEC 135 T~o.t SEC ZNNS-SNGOIS 1>800 .300 AS REOUIRED 2ROS-P IB CRD PunP 8 M 300 HP 4.000 - 3 900 150 AS REQUIRED ZCCP-P)8 RBCLCH PU()P IB N 150 HP 4>000 3
'.000 3 (I) ~ 150 AS REOUIRED 2CCP-P38 RBCLC)t PUL)P 38 150 HP IISS-N SIIJS 900 Iso naNUAL 21AS-C LB INSIRVnENI AIR N 150 HP 575 cont'ttcssnR 8 115 115 ZOYS-Clio>R Lo I I?!I "V Hat tt.t(Y N 500 A 5)5 Ct(AHNL'Il 115 115 Zl)YS-CHO>K IC I I?5- V Hh t LEHY tt 500 A Ct)AR(tt tt i LOAD It)CLVOE() IN ZEJS~I>NL 30l((IQ anENQncwt 23 9 OF II DECEHBER 1985
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H 2NLG-ncc009 20ER-P38 ORTMELL FOUIP- N )0HP 5'I S 60 10 T=O nANUA(. tlENI Ol(AIM PunP 8 20ER-PSB f(EAC)OR BUILO- M )0 HP 575 60 10 T=O naNUAL
)NG FGUIPOENT OHAIN PUtlP 8 20ER-PSO REACIOR BUILO- N )0 HP 5')S 60 10 T=o naMUAL ING EOUIPtlENf GRAIN PunP 0 2FPF-PIB A/C FOAtt Cott- N 25 HP 575 ISO 25 T=o naMuaL CENTRAllott PutlP 2FPF-P28 a/C Foan HOSE 3 HP 575 18 T=o naNuaL SlAIIOM PunP 2RPtl-tlG(8 REACIOR PRO- N 25 HP 575 150 25 T=O tlANUAL IEC'fIOM tlG SET 8 2TnL-P4 ll)Rtllt(C GEAR N 50 HP 575 II
( I ) 500 50 T=o naNuaL 0)L punp t 21(CS-tl)X)008 HMCU fRECOAT N I HP 575 (I) T=O t)ANUAL AGITAIOR 8 2MCS-tl)X1018 RMCU RESIN 575 T=O tlANUAL N I HP FEEO AGI)a)OR 8 85 T=O tlANUAL 2MCS-P128 RMCU PRECOAT N )0 HP 575 PunP 8 3HP 3.') T=o naMuaL 2MCS-P68 RMCU F ILIER N 575 Utn) t(LRAI.)2ER HOLOUP f'UflP 8 2MCS-P60 RMCU FIL1ER 575 37 3.7 T=O f(ANUAL N 3 HP 4 Ul tlltttttal.12ER M HUI UUIutu' Pl+i HC I: 012 2ccp-novlo ttltC( Clt IU N 0.)3 HP 575 1.3 0.39 T=O tlANUAL URYU( I t Ltltn ER 2CCP-tloVID OUI HUARU ISOLA) I 0>> GRYMFI( ('Jl)left 0.13 ttftS 1.3 0.39 T =0 tlANUAL 0(t)BCARO IsulA(IJM AHEMonEMT 23 10 OF:: OECEt:BER 1985
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Nine Hile Point Unit 2 FSAR TABLE 8 3-4 LIST OF CLASS 1E SAFETY-RELATED LOADS BY POWER SOURCE Amps Amps Equipment Identit Descri tion<<~ Full Locked power Source No. nfsisionc ~ > ~Retie Volts Phas e Load Rotor zdenti~t no.
2CCP +SOV87A 2CCP'~SOV87B 2CCP+SOV87C 2CHS'~ RU 1 OA Radiation monitor unit 2CHS'i RU 10B Radiation monitor unit 2CHS~SOV37A Isolation valve 1.5 A 120 1 1.5 2CHS~SOV37B Isolation valve 1 5 A 120 1 5 2CHS~SOV38A Isolation valve 1 5 A 120 1.5 2CHS+SOV38B Isolation valve 1.5 A 120 1.5 2CSH+SOV108 I cooler Unit 2GTS+UC1A 1A 10 hp 575 2GTS~UCle Unit cooler 1B 10 hp 575 2HVC~UC108A Unit cooler 10 hp 575 2EJS~PNL102A battery room 275 2HVC+UC1088 Unit cooler 10 hp 575 2EJS~PNL301B battery room 275 2HVR~SOV204 Reactor discharge . G dumper 2RHS~SOV126 2RHSd'E48 SMP 8.0 A 120 8 0 2SCM0PNL103A Cross-tie drain 2RHS~SOV35A Isolation valve 0.5 A 120 0.5 2SCMd'P NL30 3 B 2RHSiSOV358 Isolation valve 0-5 A 120 0.5 e'SCMsPNL3038
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Nine llile Point Unit 2 PSAN TASLE S<<3-8 {Cont) haps . Alps nt Pal 1 Locked NfCahzLea'hh@s %alta ~e 2V88 PNL810 5 NSZV diatribe 0 200 A 120 200<<0 CP 2VS S+t NL810 1 tion panel 2VSSe PNQl104 NSIV distribu- mr 200 h 120 200<<0 2V88ePNL8101 tion panel {y/N) 5'500KVA4lL 2EOS+EO1 DO Die<< I 0 ~SO0 W ) ~~WOy 3 763<<3. ~e Diesel general r 2EOSEO2 DO Die<< III <<szso wkS 3 6I %1&6 Diesel generator 2EOSeM3 ~ DO Div<< II k ~eg/~i~O<<<< 3 763<<3 Diesel generator 28ISeaaoo&,m 125-V dc seitcb- 0 2e000 h 125 0 809 cP 2RSebhT2h gear 28ybeH%002844 125-V dc switch T 2y000 h 125 28YSebhT28 C<3g ~
2878ebAT2A 125-V 18 2.500 hi 125 28ybeC1RQt2ht standby battery Die<< I ODO.
nn<<kSeaau(i) iki-<<ak aakk<<- 330 28%PCMlOA1 gear 'Zoo 28t8~402A~ 125 V do seitch- 800 125 330
(~P, gear 28ISebhT28 125 'V 18 2g500 hl 125 standby battery DiY<< II ~Ob'125 28I84N0028 125 V gear dc seitch
'~800 h 2ceo 330 28TSeCSQW281 2878&60028~125-V dc swf tch- 800 A 125 330
(~ljkkk 6~
28YS+EAT2C 125-V 1E 100 125 28YSCBOW2C1 standby battery Die<< III 3 oi 60
~ o I ~ sgo 2'to ~ 2 f~s~ ~ ~ n ~ ~ nas~oo sIoepoo I' ~ ~ 4+ f4W1 ~ s~ 'o Nine ICIe Point Unit 2 PSALM TAELE de3 8 (Cont)
Aape PulI Poorer Source Eqaipwent
%MAIS Eahins ~e ~ae 5'
so to K 2STS+PNL201h 125-V dc di>> 225 A 125 O ~2O 2STSPNL20ah tribution panel 2STSPNL20ab 125 V dc die 225 A 125 o ~oo <2+gV 2STS+PNL201b tribution panel 2ST SPNL20 ah 12$
ACESIPNLa (1] 00 control panel 2¹lsPNL20 ah 2CESaIPNLSOT(2) tm control panel C~P 125 2STS+PNL20ah controI panel 125 2CEselma01(3) D0 D0 control 1 12$
2CESIPNLI01(8)
I 0 0 125 0 Xaergency gen-2EOE4 EXC1 erator <<xcita ( /7d Ci: ':~c<'~o .
0 c~125 .'~'so 70 1 ~ 800 CfbYSPNL20SAO
- 2EOPeP1 2CESIPNLI12(1) 2CESIPNLS 12 00 (2) 00 control panel oontrol panel M ccetro1 paneI CV as as o
o
~t6 CP 2ETsHIL20ab 2STS+PNL20a b 2SYS+PNL20a b 2CES+IPNLS12 (3)
M control panel Q7 as o M.. CKv"-- DSTSPNL20ab
~~125 -
2CESIPELS12(8) 0 2ST 8PlIL20I Raat'gency gen-2EOEEXC2
~ rator excitati ,. -,-)$ 5 (-IL~.'.1.04 )+g q; lb.~
2EayeP2 Q1hp +125~ ~07 ~7~$ 1 ~ 800 (2STS+PNL20 e- F 00 A 25 200 2STSPNL20(h 125-V c tribution panel 0 600 2bTS+8%! 002h 12$ -V 600 A 125 ~
2DNS~1 ~ dc NCC reactor building el 2aO ~
125 2bTdeSN0002h 2EJS081 (3) 600-V eeer-gency eeitch-gear dc control po22er
~ o! 40
biae bile toiat bait 2 t5lp flbLb bo3 4 [Coat)
=
lapa laps tall tqaf paeat
~~Qybl ta ~~~ctl 5aat L884 ~r Locked
( Raa
!oeer 5oarce IhaDhtua bT5+550002L 2 e5%010 {2) i160-T eaergancy 0 125
~ eitchgeai asia 2bTS+550002L t52L (DC) /Did IL 0 2b TStbL 201b con 12S-T dc dis ~ 00 L 12$
+o 2bTs5504028 tribatioa panel 2D85ahCCb1 115 T dc 8CC reactor beildia9 640 l 12$ 600 2bTS+540402b el 2aO ~
2bTS+5%0002b 28J 53 {3) 600-T 05 eaer- T 0eacf se t ch-gear dc atrol poser 2855 5%0103{2) (160 T ~ r0eacy ol I 125 ST5 5%00028 aaitchbea dc coa poaer 2TbieQt52b (DC) Die IIl, trol Otb ILTL 125 28TSe5%00028 a,2 20. 8 190 2D85ebCCll 21CSeft108 bCIC paap to 0 36 hp 12$
coadeasate storaie 2,g 2085ebccl1 aaAP 2ICS+809116 T,abe oil coolia9 0+36 hp 125 ~ oO 1 10 I eater sapply 12S 19 2055ehCCL1 2ICSe NOT 120 aCIC stean
~ apply 12$ . 1ao50 82 0 2DhSehCCLT 2ICSahor122 tCIC tarbiae 1 erhaast SCIC pnap to 12$ 190 2055ehCCL1 2ICS+hOT 12a condensate storage Laendnant 21 Sof 60 Septeeber
Eiae bile toiat bait 2 tbll SlbLE be 3 ~ {Coat) lips lips Eqaipaeat tall Locked toner 5oarce IOEIfiD&a~ ueauiaiiua 1 15Xtaiaa'" alta khan JmC Rui9r 2ICSehOT 126 ECIC paap to reactor 1250 ~~
ZAN 148 194 2D85ehCC A1
~or 2ICSe807129 Coadeasate 125 190 2D85eECCA1 atoraye to ECIC paip 2ICSehOT136 Sappreiaioa pool into ECIC paip
~pp 125 P pp 190 2D85ehCCA'I 2ICSOEOT 183 tCIC paap aiai- hp 125 ~ iO 21~70 ~ 2D85+8CCA ) 1
~ aa floe to aappreaaion pool 4~o ~rp7+w 2ICSehOT 150 ECIC trip 03 hp 2D85+hCCA1 throttle valve gi/4 ~rod r~.9 2ICShOT 16a Taenia breaker valve oathoard 125 ~eQ 2D85+ECCA1
~C4AC /o~e9 2ICShOT 18 8 Tacaaa breaker 125 2D85+ECCbl 28TMJC2l valve inboard btCS air coa preener(gpgO A.
Service eater y'036 80 hp 125 575 8~<
g p'EOS 2885ECC101 WEL paap preaaare iadicator traaa bitter aait ZH~4/AC 25rtehOT1A cooleJ'ervice eater
~gr 0.13 hp st 575 3 z4. S
~ 36 B2+
2p 52
@ga p iblcc AP/
2885ebCC 101 hackeash liae 2$ rp+hoT1c Service enter Op13 hp S75 - 3 ~ 36 2 S2 g./i'24.%
2885+hCC'l01 backeaeh liae 25rt+hov 18 Service enter 4 Op13 hp 575 ~ 36 2 52 28b5ebCC101 ittainer backeaeh
,so 25re+hOT3l "Service enter 4 ap 575 2885+8CCTO\
to tnrbine plant g7CS<nfoV /5'9 SCrC a~~m ilgff< Zsrfz+/fad8/
leeidneit 21 n ~zH~RV rN'f 60 5epteiber 1985
~ + 4 tw of 4 ~ r
Ãfne Nile Point Onft 2 PSALM TABLE Sr3 a (Cant) hays Nays Equipaent Full Iecked Power Source de tt acr C41 e ~gtaa Eshins ~d ~t~o RSVPINV30A Notomperated 1 hp 515 228 128 1r 800 RESSNCC101 gate valve
/4.4,0 /O+.OO, RSIIPeNHFSOA Service water 575 dKiI RES 8+NCC101 puaLy diecharge header valve RSQPeIEIV7ah Service vater 2.8 hy 575 ~ i7 2%r 2 RESSeNCC101 puny diacharge block valve Service vater 2+8 hy 515 ~ ~7 Rgr 2 RESSNCC101 puaLp diecharge block valve Service water 2.5 hp 515 ~ 1 2g+ 2 RESS+NCC10 1 puny discharge block valve RSVPN&77A Noto operated 05 hy ! $ 15 3 1r Sa 'lr 800 2EH SNCC101 gate valve Q~o RSWP88% 1 A Sar rack heater ~WI5'BI5 $ 15 RESSNCC101 RSMPSSRRA Sar rack heater 57$ RESSeNCC101 Rl%PNN3A, bar rack heater ~IS 515 RESSNCC101 Dr/5' 2DOeSSEIA Sar rack heater IN 515 2ES8NCC10'1 RSVPSSRSh Sar rack heater ILw 51$ RESSeNCC141
~r /5' RSIO+88%4A Sar <<ack heater REHS+SCC10 1 RSNP+STRI A Strainer eervice hp 575 3 3 88 21 ~ 7 1r 730 RESS+IICC101 vater 28MPSTRaC strainer eervice $ 1$ 3rdd 21 ~ 7 1r 730 REHS+NCC141 .
water RsNP+sTRIE Strainer aervice 3 hp 3edd 21r 7 'Ir 730 REH 8+NCC101 water 7 oT d0
Pf 7 ~ NQ I ~' ~ ~ 4 ~ A$ 0 ~ ~ ~ 4~
3 ltine IIile haunt Unit 2 NN TAELE 803 a (Cont) 2$ JSSNL101A .
laelall '"
seitchgear roon h energency COO-V
~ve ~Ca%
4 0 ~07 ~+
~aa 3
~Tl 150 Locked
+t~~
3 twofer Sonrce 2ESS+IICC102h panel 2EJSePHL103A AS ll energency 600-V panel
~ 40 A 76OO s 150 2E88IICC102A 2MSIIIL10a A AB II energency 600-V panel IOO. A ~lgdg 3 2888llCC102A 2kMSalNV21h teedvater to 2606 hp 575. 3 2101 236 3r 600 2888lICC102h z~~A m]8 ~gsoVa 2c-~ ar5 Zri(d zmce DADA'AccioEA 24TSyS Ih 84TS filter train ~4 hp 515 3 2888lICCID2h diecharge fan 9yZ 2R Reactor boilding 0030 hp 1092 1096 2888+llCC I 02A ventilation Six pleo'M to gratee 232 2QTS+lOV2A 84TS filter train hp 515
~OP 2EESiIICC142A A inlet 0 ~HAD 84TS filter train p 515 3 2888+OICC102A h diecharge 24TStlNVah Decay beat cool .1 0 hp 515 22 128 10800 2EESHCC102A to train A 28CSIIV 1A Ileteell hydrogen 4033 hp S15 0015 5025 2888IKC102h recoebiner ieol-ation valve
. 28CSNN2lL ~11 hydrogen recoaLbiner ieo-0 33 hp 515 0015 50 25 2l!hSi%CC'f 02A lation valve 28CSaNIV3A Meteell hydrogen 0033 hp S1S 0015 5 25 2EESeIK C 102A recoebiner ieo-lation valve 2cM5%8d-Q A H< ~~<<YBsR. syS 9 /+70 2ggggyfCC/Ofl
~
Pub/eC 4 c~g %79 9 2 50 p+g + pfgQ-/MA 2QT$ 4hbVZPP gL4C'5 g gyp 8 of 60 C- VXV
0 8 ~ ~ i ~ ~ 'P'i' ~ J t~ g ~ ',
Nine Nile Point Onit 2 PSAR NABLE 8 3 ~ (cd)
A+pe Aape Pull Locked IL LI ga~g V~ ~isa 2BCSeNOV lh IIetwll hydrogen 6 0+33 hp 515 3 4 15 5~25 2ESSeNCC102A recoabiner ieo-lation valve Netwll hydrogen 0.33 hp 515 0 75 . 5 25 2EBSftCC102A recoebi nor ieo-lation valve 2SCSeINV6h Netwll hydrogen Oi33 hp 51S 0~75 5 25 2EBSiNCC102h recoaLbiner ieo-lation valve 2NSSeINV 112 Nein eteaa to 1~6 hp 515 3 3i2 20 ~ 1i 800 2EBSNCC102A ghfsis%~/l9 condenser vs&'7 vga ~
~~os 5/P <<(aO 4 20 g~z+~ccfozh 2NSS+IClV208 eteaa valve 515 3 2ES8NCC102A
$ P~o VH'Iain 28IIPeINV11A Service <<ater 1 6 575 3 2-5 20 2 1 ~ 800 2EBS+lICC102h to RSCLCII hp'+6 RSCLCII to hp 515 2i5 -20+2 1~ 800 2EBSeNCC102A eervice <<ater service eater 1~0 hp 515 2o2a 12+8 2EBSaNCC102A to RSCZCII beat a@changer 2QIPeNOV21h RSCLCII to SPC Oi33 hp 515 0+%2 3+6 1,700 2$ 88IKC102A .
cooling pool 28IIPICIV33A RSR heat ex- 0 $6 hp 515 3+8 10+3 2ESSNCC102A changer A to die charge tcnnel 28IIPINV38h ~ Service <<ater 0 6hp 575 1 68 gi52 1 ~ 800 2ESSeNCC102A to RSCLCII 28IIP+ICN3'SA RSCKCII
~ erotica to vater Oi6 hp 515 1~68 8+52 1~ 800 288~1 02A 2QIP+IQVSOA Service <<ater 0 86 hp 515 3 e 10 3 28$ 8ilKC102A to RES beat
~ xchangek 8 of 60
~ ~ ~ OOV 4'5 tt g4 ~
' ~ ~ Q fI~ \) fP~ I Nine Nfle Point Onft 2 tSAR ASM bo3 S (Cont) heal)s Rape
'Locked Squf Peent aI-'1'l ~t ~ass ~d tutor Rwer Source 2CSLPV11 ~ LPCS teat 0 575 3 0 66 1 ~ 800 2888 102C oI~o(Z 2CSL+N)V'lOS LPCS pnsp to 0 575 3 3y 600 28884KC102C reactor 2CSLNIV 107 LPCS wininua 200 }Ip 515 3 Lb 20~ 8 3~600 2888eNCC102C floe to RBR I
2CSL+NN 112 Suppression pool 515 1.8 2 EBSKCC102C to LPCS pusp 2CSLeP2 LPCS syatea 10 hp 515 10 3 51 ~ 0 3 s$ 5 2EESNcc102c
~ pressure puep 2DERiN)V120 Containeent iso- 0 6S hp 515. 3. 0~66 3e b 1e8 00 2888NCC102C lation valve 2DER+lNV131 Reactor building 0
~o.s ~7~+ ~4.20 2888+lOCC1D2C
~ quf peent drains tlt1. vent 2DPRN) V120 Reactor building ' 1~3 hp 57$ 3. 1e 800 2888+NCC}02C f'loor drain dis-charge isolation valve 2DPR4CIV 13% Reactor plant Dbhp 515 0~$ 6 S 2 1e 800 2888%CC102C floor drain vent isolaticxl valve 2ICSlKIV 121 Turbfne stean 515 Sq5 75i ~ 3,600 2888NCC102C supply isolation outboard
~/f45+ ~EI, 00 2ICS+P2 RCIC systea 10 hp. 57% ~ <5 2EESiHCC102C pressure puep h 0+5 2SLSoNOV1h 8tandby liquid 0 01 hp 51$ 3 ~7Z 40+0 2888NCC102C control ~H/'
ZsgSAHodgA SLCS adrs zbaLATA "h<VE
~ 97% a} /ega /di W gus g pgCAZA 2SLSaP1h Standby lfqufd 0 }1p 515 3 ~1 0 2e6 1~ 75$ 28}}8HCC102C Puep A
//z. AeaZyq~~ ].po PNEL g A"oE 65 gMcgozc
~ I Nine Nile Point Unit 2 PSAR
%ABLS Se 3-8 (Cont) hnps tquiynent rrr Pu lda Locked Power Source e IWUII ' B~
go~to 2MCS+IClV112 NJ epstea board etean out- 515 .3 2EES+NCC'l02C RkVCU ter
~A2$
ieolation valwe c
(eel VAUlf B gg 515 3. 2EESSCC102C to feedwater 2CCPeN)V$ 2a Doeeetic water 515 2~1 8 8 1i100 2EHS+lICC103h cooler to RBCLCM outboard I azo ao.ac 2cc prov 1ah RBCLCM to SPC 18bp 515 1gd00 2EES+NCC103h heat exchanger A goi o 2CCPNBI 1 dh SPC heat ex 18hp 515 1~800 2ES SNCC103h changer A to RBCICN 2CCP+MV22A RBCLCM trna 1~0 by 515 2~2. 12~8 Ted00 2t ES+NCC103A RCS yuay h 2CCPeNOV285 Saolatfm valve 515 2~1 8~b 1i740 2EEfPNCC103A containnant 2CCP>IQIQP RBCICM to RCS 0~$ 3 hp 515 CTRL ~ 2 1 ~ 800 2ESSSCC103A yuap h outboard I
~B RBCLCM outboard tO I
RCS hp 515 de 2 1 ~ 80 2EEIWNCC103A To RBCICM yunp h outboard I RCS Oa33 hp 515 .3. gp 1~800
~
2~NCCf 03A
~
2CCPl B TO RBCLCN RCS 0+33 hy 1i d00 18~NCC103L yuxIP A outboard I 515'15 576'+33 2CCP+IC)V%3A RBCLCN to 2 RCS
~F0 3
~jr gB 1e700 2EHS~103L P1h coolere tEgrQfM/A L5 /A/R CoAP IA Ao~ cesar f75 .
/0'O gade~C C/oM 11 oC 80 2EQAWA24 c q/'gW Cc&P 2A /5.8o g~g~ ~~Cd/OQA en7bC
. r I ~vflfwlr.letO(/fl . ~
'w9fe ' VP 'f'4'lt ~ ~ gyywsw~+' + ~l ~ ~ ft tcine Nile Point Onit 2 PEAR TAELE So 3 ~ (Cont)
Pover Source c c1 p~ylLc ~ I Ic~t ~e NFu
~a 1
/i74e Locked 7'icpe ~~t~~.
28OPePth M 1 fuel oil 515 3 2EHPWOCCt 03A tranefer puap h /s Do fueL oil ~/5 515 2EHSIKC103A 2ECNePtC 1 transfer puap C 2EQOePth Lube oil circu- 15 hp 515 83,5 tr800 2EHS'eNCC103A latica puap cenera1 apace* $ ~1 kQ $ 15 5 1 2EHSHCCt 03h heater 2ECSiP1h Jacket eater cir- 0 515 3 5 6 3I~2 trS00 2EESiflCC103h culation puap 2881 aCH2 faha oil heater 575 3. 12 2EHSiNCC103h 2EOT+CHI Jacket vater 515 2EHS+NCC103A heater 2HVCeAC01A Control axe A/C lO hy 515 ~ t, 2I6 2EHSaNCC 103A unit 1h 2HVC+ICQ2A Relay ram h/C iO by 515 ~1 2I6 2EH~ICC103h unit 2A 2.5 4.3o Reaote ehutdovn 2 hp 515 2EHlVIKCt03h on rooa h/C cxcit 2HVCPHYLAtA 2HVCerit Nakeup air 7i5 hy 515 goO Se 2EHEiNCC103A
~ vitcbgear floor 2HVCetll2A Control roc'/C 10 hp 51$ . 3. 10+5 6S ~ ti160 2ERtiNCC103h booeter fan A Hattery rooa h 51$ 2+6 2t 2 2EHSI'le 103A exchange fan C4 4Z 2HVC+lCN1h Control rooa h/C hp $ 15 3 2EES+NCC103h special filter bypass 12 of 60
-~ ~
yICr~ y ~ slrt' 'so'r ' iI. rrr33.o ~vr ff 3 ~ ~ ~ ~ 3 ~ w~ ~ ~ 3'r ~I33'~rrZC3t. r rr rr ~ F Sine Nile Point Onit 2 tSAH TAHLH Sr3 8 {Cont) lmlpa AIcpe RLdhla "'
Syaipawnt Full Locked Power Source de IJ Ratgg Phaae ~d e S MrV~
Rotor 2HVÃCHL1 haafliary of 1 Op75 hp 575 3. 2SH~103A Eu+p 2HVHaP1A Control building 1S hp 575 1ar8 80. 1r 750 2HHSNCC103h chilled water circulatf ny puap h 29.2 Service water 575 0 2HHSiNCC103A to CNS gaape 2SlQeNWS CA Service <<ater to 4 $ 75 2r1 Sr8 1g700 2HHSNCC143A standby DO coolere 53A 2SHPMV47A Service water. to 575 ,3. 2EH8NCC103A control DO relay rcxm coil Service water to 1 6 hp 575 3r2 20 2 2HHSNCC103A dfecharge tunnel 28M'fCN%3A ieolation Service water to
/
Or hp 57S g Zo /950 2%HI+NCC103L diecharge tunnel ieolatfon Service water to 1 hp 575 2r1 Sr8 tr 700 2HHSeNCC103h 2I1oePRA Standby Do coolere Control building Q3 33 575 Aloes ~ 4@7 1i 15$ 2HHSeNCC103h chiller Service water puip h 2HVPPII1A DO 1 eahauat 30 hp 575 32 0 185 2EHSifKC103C fan 1h 2HV~1C DO 1 exhauet 30 hp 575 32r0 185 2HHSWCC103C fan 1C 2RHS+tV38L Teat iihe h to
~ uppreeeion pool
'r3i hp 575 065 ao 2EH 8+NCC 103C
~z/oA ~~+ W ~ SC >.S'0 ZAW~cC/MC 13 of 50
~ f~% iO1'I ~ ~ +q~~gee b
~ 'e p ~~ ', r < ~ g~'%f4 hf fffFfoWp +V ~
~
~ ~ ~ ~
Bine Nile Point %sit 2 fSAR OILS So3 b {Cont)
Eguipaent de 2RHSeINVIA Reahlle "
Suppression paol
'ldJ i+6 hy 515 3 Aa a tuel 3&2 '0 Aaya locked
~toe 2 2888ifKCI03C to.RHR puny A 2RHSNIV10a bead spray in 0,7 hp 575 I.ea -9.6 ~ 740 2888+NCCID3C outboard isola tion 2RHSeNIV113 Cooling supply 20 hp 575 3. 20%6 156 3r 600 2888NCC103C outboard isola tion p~s /~co 2RHOlE)VI2A Seat exchanger h IiO hp 515 2888COCCI 03C to reactor 2RHSeilV162 Seat exchanger b 0 33 hp 515 Oi$ 6 1~2 irb00 2888eNCCI03C to liquid rad
~ laate system 2RHIWElVI$A Containaent 2q6 hp 575 1e72 29 2 Iib00 288 SiNCCI03C spray h 2RHSeliV2h Reactor to RHR 0 .86 hy 51$ 3oal 10 31 2888+NCCI 03C puap h 2RHSlNV22h Stean candenaing 1+6 hy 515 3i1 16 Ir740 2EHWNCCI 03C to heat ex-changer h Stean condensing 1~6 hp 515 3i1 16 Ie 700 to heat ex 2RBSelClV2ah 2RHSelElV2$ A
~
changer h inlet Containaent h bob hp 2i6 hp
'515 575
~ ~0 Ee72 67 5 29 2 Irb00 2$ 80iNCCI 03C 2EHSlICCI 03C spray h -85 r.Z 2%88ifOV26h Seat exchanger h l413 hy 575 3, 2888iNCCI03C vent to suppres-sion pool Ia oi 60
~ s',P 'f 1Pf tl 't~Pt ++%%I ~o' ) $ %t%rr%% +vgl +'I f' ' 'rr } er - ~.t'ai>>%e%rrr'ch% '%" 't
~
~
~ Q+ i Nine Nile Point Onit 2 ySAR TABLE 8%3 ~ {Cont)
Aape Agape Eqaipaent de t c~ l 24ZWe~c" ~>>kaa ~t ~ae ta11
~
tucked 7>> g Rater Boerce Heat exchanger h 0 13hp 57S 3 288$ +NCCt03C tent to eappree~
cion pool C
Z~ddO 2HHSaINV30A RHH retarn to 288$ NCC103C eappreeeion pool 2RHSINV32A Beat exchanger A 0%C hp 575 1%CS 0 52 1 ~ SDD 2888flCCt 03C to RCXC 2RHlPIB&33A Sappreeeion pool 0%33 hp 5'75 0%5C B% 2 1rb00 2888aNCC103C epray header A 2RHSINV37A RHB line A to eappreeeion pool 0%33 hp 575 0%5C B>> 2 10%00 2888~ 103C 2/a dd 28RYICIVBA RBR aicdnaa floe 1%0 hp 575 2>>S 1r SDD 288$ rNCCt S3C to eappreeeice pool 2RHSeINVIOA Shatdcwn cooling '10 C hp 575 12%2 .te7 3r lDO 288$ +NCC103C retarn h
~ 53 4~5'0 2RHSaIHIW7A RHR ehatdovn hp 575 2IHSeNCC105C hypaee Heat* erchanger 1%'F hp 575 3 3%2 20% 2 288$ +NCCt 03C A bypaee RHR paep h to 1%C hp 575 3%.2 20% 2 288$ eNCC103C heat exchanger h 2898CHQR2CS 125-V battery ~gnDC 2888ilRC241 charger etandby 2BTB~QQ2C2 DLV%
125-V Ztl battery
~0!7C 288$ +NCC241 charger
/r g /C7 2CSBIB)V I0 I Condensate etor- .. 0.7 hp 575 288$ aNCC241 age to BPCS paap t5 of 60
'1+ I ~ 0 v 0tVf v ~ VO~ -iW'+:I1VV <<reggae) IS<.'tllN 0 1 ~ ~ ~ $
hfae bile Pofat bait 2 PSih TLELE bo 3vl (Coat) lays aaps Egaf pseat tall Locked Rhhti~lua 5oarce ltkriaha" Ra&a Lhhl lhihj ) as ICaaDtEMha 575 2%v 0 2885+8CC2C1 2CShcbOP'l05 tloe btpass to v p sappressioa pool
/9<8 2885e 8CC2C I 2CShc807107 8PCS yaap to 575 reactor /9iI 575 28858CC2C1 2CShchOP 110 Test btpass to coadeasa'te shor age 575 11v6 68 2885chCC2C1 2CShe807111 Test bypass to 2CSha 807 112
~ appressfoa pool Test bZpass to 575
~/Bag ~i/ 2885ehCC2C1 coadeasate stor-
~4iZ ~gg 0 2C5880P118 age 5apyressioa pool to EPC5 575 ~e/5'dorer
~/de 2885ebCC2C1 2CSEP2 Staadbt eater 10 hp 575 3 3t aS 2885+8CC2C1 le4 paap 822 COOS 288$ +acc2cl 254lle 3 DO 2 air 7e5 hy 575 coapressor 3
~/8Z ~8. 2885+8CC201 284tP2l M 2 teel oil Q7P1 575 2EOP+P28 traaster paap DO 2 E
feei ofl 575
/ 8Z Cps O4 2885ehCC201
~ ~
treasurer
'p'aap b
~Z>04' 2hllS+8CC201 2EOOcp1 8PCS M 2 cir- 1 hp 575. 3 calatia4 ofl paap.
1S.O 2885abCC201 2EOT+C81 8PC5 M 2 faaer- P 15 kh 575 sfon heater g,g+
8PC5 DO 2 space 575 2885ehCC201 2EOT +81 heater lacadacat 21 16 of 60 Septeaber 1%5
~
$ .<pohcy <~ <s<o o<<o ~, ' ~ <<+ es f ~ ~
~%eood< ~ g<g<ov ~ e ~ ~
o o
Riae Rile Point Dnit 2 PSAR Thhih 8%3-8 {Coat) lapa Egoipaeat p:Pi Locked Porer 5oarce khatQIQaaa JtaaaLaGan<> EaQIS XuLta Tiaai LRa{L hhRL 28TCOC102 RPCS eritchyear 5 hp 575 3. 5.48 32$ 9 28858CC201 coos anit coolet
'2o0 28Tpef 42l DD 2 exhaaat 30 hp 575 186 2E85e RCC201 taa 2l 28TPeP424 00 2 eahaaat 30 hp 575 32 0 186 2885ehCC201 faa 2b I
I 28TPiOC2 DD 2 aait cooler 5 hp 2885ehCC201 hPC5 DQ roon o
o I 28TR+oca031 Reactor beildiae 2 aotors 575 3
~84 <o ~<<a%
2885RCC20'1 RPC5 eeparatot cooler el 196 ~
ega 28TR e Uca 034 loeactot baildiay 2 aotore 575 3 6 2885+OCC20'I aepatator cooler e) 196'raaaf
~'~~r~
2llceILE03 orner oo ooo ~$ $ --gy$ $ $ oo.o cP 2E85ehCC201 800 208T/120 T 25CheXRC200P tag alatiay 15 hTL 575 15 e e 2885ehcc2C1 traaacotaet
~i%0 25CTeID200P Diattibatioa traaaforaet 2$ koo (fffl+Qgo 2885' RCC2C1 600 120 T
~ C4 &So 258P+80T 15l 5errice rater 0.33 hp 575 3 1i 700 2885ehCC20'1 to RPCS aait cooler ~ ~
25QPihOT 154 Serrice rater to hPCS aait D33hp 575 3 2ERSehCC201 cooler 25'aPrbOTSal bernice rater 3 hub 1 ~ 700 Eh5RCC201 to etandb7 D/a coolere 838 laendaent 21 17 ot 60 Septeeber 1985
f ~dd~t tr of ~ ~ R+I f ~ ~A
~ ~At o ~ w ~ s.~q ~ Rtto r~v 8ine Kile Point Onit 2 PShl ThEM do 3 ~ (Cont) hape hap s Equi peent Pull incked Po<<er Source de tt ILLI Y~ ~ae rdlod Rotor Ree~ab Service vater to etandby N cool P 1 hp 57S, 3 Ro1 d~d 1 ~ 744
~ re 838 ZC 824 o RSVYaQCRS Service <<ater IO hp 575 3 RESSitKC301 puep PIT unit cooler e~a8o ~ar4.oo Service <<ater IO hp 57S REESalKC301 punp PIT unit cooler RSMPiNN18 service 0 13 hp 57S Og36 2 52 2ERSaHCC301
<<ater'ack<<aah line RSQPiNN1D Service vater 0 13 hp 57$ 0 36 2 S2 REHSNCC301 backeaah line RSMPelQV1P Service <<ater 0 13 hp 575 Oo36 2.52 2EESalICC301 etrainer back<<aeh 4 aid 4lr8 RSitP~V38 Service eater to 2 hp 575 REES+NCC301 turbine plant RtNP%%308 Notor>>operated 1 hp 575 RoRI 12 d REES&CC301 gate valve s,9 RS8P+KN 508 Service <<ater hp 57$ 3. 2888alICC301 diecharqe
@~ S42 Z4 RSEPaNOT7I8 Service water p 575 3 2888+IICC301 diecharge block valve
~Psed00 ~ ~ t~
RSNP~7ID Service <<ater 2o6 hp 575 ' 3- 288Sa8CC30 1 punp diecharqe block valve RSNP+lSV7IP Service eater
~~r7 hp 57S REHS+lKC30 'I puap discharge block valve 1d oP 64
~ v p! ~ <<+p~ y r ~ v ~ <<!r ' ~ .r~y.y!rvr <<r rr ~ !. ~~ ~ ~ ~ ~ ~ ~ ~ ~ <<
f'e'ine Nile Point Unit 2 FShb ThbLE Sr 3 ~ (Cont) hape hsepe Eqei peent R~ee e" ~ae Fall
~d Locked Rotc}r Poeer Soorce Xdebtttg 2$ INoICN77b Motor-operated 575 3 1+So 1 ~ $ 00 II'ES~301 gate calve 28IIP SSR1b bar rack heater CCPkll (F77'3 Qo! ~A 2$ 8$ Ncc301
~8/5 28IIPeSSR2B bar rack heater ~7~00 1 5
2EH8+llcc301
~re 28IIPeSSR3b bar rack heater Q~S)-POd 1 2ESSNCC30-w /9 /Or 6 2SMPSSRIB bar raok heater ($77-300 ! /or 4~
12ESWNCC3 2$ NPe8$ %58 bar raok heater ~57~$ 09 1 C~ 2ESS+IICC301 B~r! yore 2%IF88% 6b bar rack heater +gg-3bP1 2ES WIICC301 2SMPSTRlb Strainer eervice 3 hp 575 .3 3r6$ 2tr7 1r 730 2$ $ 8NIcc301 eater
'8QPSTRIO Strainer oar%ice 575 3r68 21r7 1r730 2ESS+SCC301 eater 28WPeSTRIP Strainer eereice 575 3. 3r6$ 21r 7 1r730 2ESStKC301 eater 2EJSPNI302b hb-8 emergency a00 h ~So gg~ 3 150. 2ESS+HCC302b 600-V panel 2EJSePIII303b hb-S eaergency 600-V panel
~ 00 h, B'-6~O 3 CS 2EES1ICC302b 2LTSeÃIX30lb hb-S eaergency $ 00 h, ~!5 CKr 600-V panel yg 3 2EESWCC302b I
2PIISINV21b toadeater to 266hp $ 7$ 3 27 1 236 ~ 3,600 kBSellCC302b reactor B
OTS filterfan train eo hp $ 75 1~ 775 2$ $ 8+lOCC302$
diocharge 2OTSNOVlb I5% cia ylenm Or3a hP $ 71 3 1i92 ~ 96 8'~tRC302b to OTS 2c&aVMCCSS gg, fPHRLy')PEA'lew /.70 B of 19 60
~0 ~ >> + ~
~ f ~ tf ' ~ >>ff >>f>>>>f t>>qP ~ >>ff>> ~ ~ f ~ ~
Nine Nile Point Dnft 2 PSM TJLKS S>>3 ~ {Cont) hafpe toll Egnipaent d ~ LJJ'" Ul ~aa ~a Locked
)p~ot r Pover Soaree 2OTSIKIV2b OTS tilter train S.inlet
~n>> 51$ 2ERS+IOCC30'Ilb
~20 OO.
3STSICIV3b ITS tilter Y $ 7S 2EESelKC302b train b diecharge 2OTSeN)Vab Decay heat cooler Y 1>>0 hp 515 2>>2 12 S 1 ~ 800 2EES+IICC302b to train b 28CSelQV1b Net<<e11 hyrdogen Y Og33 hp 51.5 0>>75 5>>2$ 2ERSaIICC302b reeoabiner isolation valve
~ 4 Qetveii hydrogen Y 0 33 hp 515 ~ 5>>~ 25 2EbbiNCC302b recoebiner ieolation valve 28CS+IEIV3B Netve11 hydrogen 0 33 hp 575 0>>15 $ >>2$ 288$ NCC302b recoaLbiner isolation valve 28csllovab Dry<<ell hyrdogen Y 0>>33 hp 575 0>>15 $ >>2$ ESS+IRC302b racoabiner iaolation valve 28CSaICIV 5b Dry<<ell hydrogen Y 0 33 hp 51S 0>>15 5>>2$ 2EESillCC302b recoabiner ieolaticn valve 28CSalCIV6b Dry<<ell hydrogen Y hp 515 2EltbaIICC302b recoebiner iaolation valve 2SWP+IEIV17b Service vater '1 6hp 515 &~2 ~20.50 ~
~
2AS~IKC302b to RBCLC<<
~2 2>> ao 28NPeNlV18b RBCGCN to QP>> 515 3 2SllPeMV1gb aervice <<ater Service '<<ater RBCLCQ heat
&dV'>>33 to 1~ 0 hp 575 2>>26 12>>S 2ESSeNCC302b 2ERSaNCC302b exchanger 251.s RfHc vsH sees z~s~
XS oI.A7 IW VAI.If'<
~ rod /,9g j&4&o g&&gbfCCI2IO28 20 ot 60 gpam~V2BB ass-g4rap 2oogt'/5 g. 50 g%~~90g9
Nine Nile Point Onit 2 tel tJLSLE Sr 3 S {Cont) hops haps Equitant toll Locked Rwer Source da tt IILLI p~gg ~ase ~d S 28MPaICIV21b RNXCM to StC 0 33 hp 575 3 0 92 3.6 1r100 ~IKC302b oooling pool
~3+5 2SMP+N)V33b RSR heat es 57$ 10 3 2EHSaNCC302b changer b to discharge tennel 28MP+NIV3db Service vater hp 515 1 68 ~ 1r~ 500 2ESS+NCC302b to RSCLCM 9000 28MPlKW39b RSCLCM to hp 57$ 1 ~ 58 2ESSaNCC302b .
service vater 28MPaNIVSOb RBR heat ex- Orb5 hp 515 3rd 10 3 2ESSNCC3025 changer inlet 2DERaNIV119 Contaknsent Orde hP 575 Or65 3 8 1r 800 2ES SIKC302D isolation valve
~C w~rr 2DER+NIV130 Der TK1 vent 57$ RESSNCC302D 2DPRaNIV121 Dryve11 floor 1r3 hp 57$ 3 2~2 gr 0 1r 804 2ESSalKC302D drain discharge isolation valve O~SS a +
2DAlaNIV154 Drywall floor 1 ~ 800 2ER¹NCC302D drain discharge isolation valve 2ICS+NIV125 NOV stean snpplP 575 9r12 1$ a 3r 500 2ESSNCC302D line 21CSaIEIV170 SVPass of NOV128 ~on@ 57$ QNSiNOC302D INIVlb NSIV seal out- 0 33 hp $ 7$ 0 56 ~ 2 1rd00 2%SI¹NCC302D board isolaticA 2NSI N) V2b NSIV seal 0 33hp 575 ~r 2 1~ dao 2ESWNCC302n inboard isolation 2NSS+lC)V111 Naia stean condensate to inboard isolation 15hp 97'%56
$ 7$ 3~2 20r i 1, d00 2ESSaNCC302D 21 of 60 Z~~ge&uvl)B ya~ elva ~ 60 4r2 gEgS~Ncc3o2A
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Nine Nile Point Unit 2 tSIR TASLE 833 a {Cunt) hape tuaps bquipaent Pull locked Power Source dent t AJJ +Qng V~ ~ae Load R~tgr A ohio 2SLS+NOV1b Standby liquid ~35 575 3 2SHSaNCC302O control 2SLSP1b Standby liquid ~0 hp 575 a1ro . 2e6 1 ~ 755 2EHSaNCC302n 8~4'8iO 2NCSeINV102 RNCQ inboard ieolaticxl Valve gg 575 2EHSeNCC302D 2HVEeCHLI~ huxiliary oil 037S hp 575 2CCCICCC30$ bf puip Z 24 J'~ PO 2CCPaINV 122 Drywall cooler to 575 1r 700 2EHS+NCC303b RbCLCN inboard I 2CCP+INV1ab RSCLCN to 136 hp 575 33 2AM SPC 1 ~ 800 2EHSaNCC303b heat exchanger b Z 2o 2L"na 2CCPaNIV18b SPC heat exchang- 1 6hp 575 1,800 2EHSNCC303b er to RSCLCN
/CA CCCt+~1 RBCLCN from RCS 0333 hp 575 1 ~ 800 2EHSaNCC303b ituap h RSCLCN troa RCS Or33 hp 575 ~gp lr 800 2ESS+NCC303b RSCLCN puap b jr'CS 1~0 hp 575 23 2 12+8 1 ~ 800 2EHSaNCC3038 2CCPeI87V273 RbctCM to dryeel1 575
~2+ ~/2o+
2EHSaNCC303b cooler inboard 2cc paled)v%38 ieolation RbCLCN to 575 3
/rPO i9 9 ~ 1r 700 2EHSeNCC303b 2RCS P1b coolere 2CCPN)V91h Cooling eater to P1a
~t33 575 ~4 ~vs 2EHS+NCC303b
~ 95 2CCPINV9lb Cooling eater e 575 2EHS+ NCC303b to Plb 22 oC 60
- 'I ~ > ~ <<<<<< ~ ~ ~ ~ IL ye
'l~,/rI p
~ 4 ~ 4~<<g <<<<p ~ ~Qe<< ~feffttw<<)v (W
'\ Pho iline Nile point Qnit 2 FShS ThBLE So3~8 (Cant) hsIps Fall paver Soarce Bquiyscent de mdal "' Qe~~Ie) Rat ~t ~e ~d Rotc~ tt 2EOFeF1b DO 3 fuel oil Y
/e 515 3 QP ps. ~
2EBS+NCC303b transf oraer pusp b 2EOFet1D DO 3 fuel oil 515 ~~<< ) 2EBSaNCC303b tranef orner paep D Ieo5 83 5 1 ~ 800 2EBSNCC303b 2EOO+F1b Labe oil circu- 1S hp 515 lation paaIp 515 5 7 2EBSNCC303b 2EGSe83 Generator space S.1 irN heater 515 Sod 3a 2 2EBSa NCC303B 2EGSeFIB Jacket vater circulation paap 2EHSNCC303b 2ECT+C83 Lube oil heater 12 kN 515 3 12 515 18 2EBSNCC303b 2ECTeCHS Jacket vater .
heater 515 216 2EHSNCC303b 2BVCICQ1b Control men h/C Y e0 hp anit 1b 515 ~1 2e6 2EHS+NCC303b 28VCeACQ2b Relay rooa ~0 hp h/C unit 2b Zi /'~ g 51$ 2EHSNCC303B 28VCehCQ3b Raaote shutdovn Y 2 hp on rooa h/C unit 2888+NCC303b 28VCeF%1IS Nakeup air 7+5 hp 515 goO
~ vitchgear floor ~0 10 hp 51$ 10 5 1i 760 'EBS+NCC303b 28VCeFÃ2b Control rooa h/C Y booster fan b 51$ 2 6 29<<2 2EHSaNCC303D 28VCeFBIB Bittery roon b 3 hp exchange fan
~MS 2EHSaHCC303B 28VCalNV1B Control ro~ h/C 515 3 special filter i5S ~~++ gWcgHo+
2+PQ4hfl 8 bypass
~3AIR'CouP /H is/p of do
~Talc, 23
~~~~~cC SdEQ Zgyg4 +12 ><<g/a Cd&PZa HpP ~73 3
1Vp wt rr r 'e wH "9 >r ~ rr r ~
~ ftlgi rr rr ~ ~
gr~~~ l '
Nine Nile Point Unit 2 PSM TN5LE be 3-8 (Cont) haps Alps tall bqaiyaent den Ilrr /~ting ~ass ~d Locked Hector Paver Source 28'PIb Control building 1$ hp 515 3 Ie 8 90 Ii150 2888+HCC303b chilled vater ~
circulating Vm b 29,2 28ll 1b Service vater to hp 515 2EBSNCC303b CMS paape Serv'ice vater to T 515 brb 1i 100 2EESiNX303b standby DO coolers E3b 2SMWNIV61b Service water to hp 515 2885+NCC303b cont ground relay roon coil 28vemV928 Service vater to 1~6 hp - 515 2EHSWCC303b discharge tunnel isolati 2SQP+MV 93b Service vater to
/ hp S15 2EHSeNCC303b discharge tunnel isolation 2SQPNOV95b Service water to 515 2e '1 bob It70 288beNCC303b standby M coolers 2SQPPlb Catch basin chiller service Q3hp 515 Ii11$ 2Eh8NCC303b water panp b 28VPPNIb DO 3 exhaust 30 hp S'15 32~0 186 288SIIICC303D fan lb 2BVPPNI0 DO fan 3 exhaust 1D 30 hp $ 15 3 32 0 186 288~303 D Test line b to
~
93'p a.8 2RBS+tV38B $ 15 066 a 2EHSiNCC303D suppression pool RHHS+PV38C RHR paap C to Oe38 hp $ 1$ Or 66 ~ ro 2EHS+2tCC303D suppression pool Ra oE 60
I
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)
~,
r Nine Nile Point Unit 2 tSRR
%MRNA 8%3-e (Cant)
Rape Rape Eqoipaent RL<< '" m<< ~aa Pall
~d Locked
~R~r Power Soarce 2RH&NOV1b sapproaaion pool Y 1~6 hp 57S 3 3%2 20% 2 2EH8NCC303D to RBR paep 8 2RHS%)VIC Sappreaaion pool Y ~3hp 575 3 3 2 20.2 2888+IICC343D to RHR paimp C
/~SL2 2RBS+NOV112 Sbatdown cooliny Y 575 3r500 288$ NCC303D eapply inboard iaolation 2RBSIRIVI IS Service <<ater 1 Chp 575 2%9 20 2 1 ~ 800 2EHS~NCC303D hypaae to reactor 2RB8INV116 Service water 1 6 hp 575 3 2%9 20% 2 1 ~ 500 2888+lRC303D hypaaa to.reactor
/re /4'O 2RESINV 128 Heat exchanger 8 Y ~9 p 575 . 3 2888NCC303D to reactor 2RHSIOV169 beat exchanger b Y 0 33 hp 575 0%5C ~ %2 1rb00 2888+NCC303D to liquid radwaate
~ yaton QCLNO 2RBSINV Ifb containaont 2 6 hp 5)5 9%2 1r 800 2888rNCC303D epray ~
2RBSINV28 Reactor to RSR 0%06 hy 575 3 ae 10 31 2EESKtCC303D 2RBSINV22b, Steam cond eneing 1%6 hy $ 75 3%1 16 1r 700 2888aNCC303D to heat er ctIanger b 2RBdaINV23b Stean condeneing 1%6 hy 315 3%1 15 1r 700 28$ 8iNCC303D to boat or~
cban9ar B 2RHS+IC)V2ab LPCZ inlet b 6%6 hp 575 3 8 0 67%5 2E58NCC303D 2Ras~elv2ac LPCI inlet C 66hp 575 3 80 575 EHSifKC303D 2RaarleV258 Contain sent 2 6hp 575 3 e 72 29.2 1r 500 2888+NCC303D BgvsswMY&B apray B gcoae VIXVX o.ggr/P 2$
6'N of 60
~ ~ 2r5O Za+Z emceMSD
~ f f I ~ss ~ ~f~s I /~I,I ~ ~ ~ \ Pt S f'lfl+SI I 1Is'I ~ . ' ~ ~ ~ (ytpf Y'11 '+~"" s I" I
~s Nine Nile point Dnit 2 tSRR
'ThEN 8>> 3 ~ (Cont)
~Pl Eqaiycoent t ILIS ~Rat ~ ~t ~as ~d
~e Locked Rotor I/i O 2RBHolV26b Heat exchanger b ~ 0+13 hp 515 3 2EHSolKC303D vent to suppres-s icn pool.
2RHSoNA27b Heat exchanger b vent to suppres-0 13hp 515 3 HP gP 2EH8~303D eicn pool
~/I6O B~Pr 8'o t td.dd 2RBSlR)V30b RBR return to 1 2888vNCC303D-2RBSsMV32b suppression pool Boat exchanger
+s7 515 i 8o6859.o 1 ~ 800 2EHS+SCC303D b to RCIC 2RBSsNOV33b Suppression pool Oo33 hp $15 0~56 e 2 1g800 2EHSNCC303D spray header b 2RHSolEIV31b RHR line b to Oi33 hp 0+54 es 2 1 ~ 800 2EH8~303D suppression pool 2RHS+lCIVob RHR ainima 1.% hp $ 15 28 208 1y800 2EHSKKC303D flac to suppression pool RHR siniacua 1 ~ '9 hp 515 2~8 20mb 1i 800 2EHSiNCC303D floe to suppres-sion yool 2RBSsleVSOb Shatdoen cooling )OA hp $15 12 2 3m 100 2EHSoNCC303D retarn b 2RBSolNV61b RHR shuttkwn 515
<~5 1'+2 2RHSolICC303D bypass boat exchanger 515
~D. 0 QRESoCOCC303D b bypass RBR yusy b to 1+6 hp 515 3+2 ~80
. 3 2EHSMCC903D heat exchanger B 2RHSop2 RHR eystea 10 hp 515 10 3 51 3io55 2EH8~303D pressure pusp 26 of 60
I
~ 'Lf ~ 10010>>0' ~ ' l~ 1 rhl'>> V' ~ 0>>0 hhV 0>> 0 0' ~ +y ' ~ 0 > ~
~ >>>> ~ - 0 IV f<f ~~ 1 le S ~ 'O >>l ~
t hw Nine Nile Point pnit 2 PSAR TABLE 8>>3 8 {Cont)
A+pe Alpa Pull Locked Po<<er source Equipaent de t >>>>>>S'=" ll'l'l VcCe ~aa Rotor O~
~OC2C service <<ater 0 ~0 hp 575 3 2EHS+QCtbt puap PIT unit cooler V 2csL~Btg LPCS puap beater 0 SIN 120 7.8 2EJIPPNLt Obh V2HVR B813A Reactor building 100 2EJh+PNLtbbh
~ 13A heater unit cooler h hir coepreaaion 30 M 120 2EJAPNL140h
~ etor beater 2RBsiBIA RHR motor heater Ois ktt 120 5+22 2EJAPNL100h pump A 28PCBth ~ SPC lation
<<ater circu-puap isa'.o ~
2EJhe PNL100h A heater 2$ LBBtA Standby liquid ao tt 120 ~ 2E Jh+PNLt OOA h heater 2EJAPNLt 0 t h Q 2BZS lsra8402A s<<itchg ear heater 105 ktt 210 1 6.25 2EGB+QVR1 0enerator 2EJA+PNLtbth governor 2EQBPH1 Panel heater e 120 - 1 2EJhe PNL101A 2EJB~B1 Load center 3i5 kN 2ao 2EJAPNL10tA beater 'l
. 2ENBiatOBto 1 S<<itchg ear ~ +25 kM 120 3508 ALlh+00L101h heater
~/0l,46 2HV R+CHL1h(2) Control building 0 2 4kvh 120 1 2EJAPNL10th chiller th
!'8QP+Ht h service <<ater 120 1 2EJA+PNLtbth puap A OiO
~ 0otor heater 27 ot 44
~ Ts>>esi '>>w ~ >>>> 'f ~ ~ ~ >>,I ~~ >> ss >>~$ ~>>>>sleet lf sl ~ ~ s ,y... ~ I~ ~ >> ~ >>sss>>>> ~ ' A~ >>>>
I leone Nile Point Unit 2 PSAR TABLE S>>3 ~ (Cont) 2SWP81C Service water poap C
~ etor heater
>>UL "'20 1 Rape Fail Agape Locked
~~o 2EJAIPlIL10 I A Service water 120 2EJhaPIIL101h 2$ IP818 puep E aotor heater 28V$ 48i138 'eactor building 2>>0 kII 120 2EJAPIIL300 8 e138 heater unit cooler A NN aotor heater 0>>6 kN 120 5>>22 2EJA+PIIL300b 2R88+81b yuap b 2888~ 81C RER puap C 0 6 kN 120 1 s.ss 2EJAeFHL300b aotor heater 2$ PCe81b SPC water circu- 120 2EJhePllL300b lation yuatp b heater 120 t>>0 2EJhe PIIL300b 2SLSa81b Standby liquid ~0 kN pLQlp b heater 2BYS+SQQ80028 Switchg ear 1>>5 kM s.ss 2EJAPIIL301b 7i i heater oene rator 2EJ Ae PllL301b governor 2EOSapbe Panel heater .120 1 2EJAePIIL301b 2EJS+QS83 Load center 3 6 kII '2e0 1 15 CiP QPhPÃL301b
~/eg heater ~ .
288S+HN8103 Switchg ear ~ >>25 he 120 ~ 1 35>> e 2EJhePEL301b heater
~/4 @ 2EJA+PllL301b 28VEKRL1B f2) Control building Y 2>>0 ITVA 120 chiller 18 2e oi 60
000 Lv a t.hv %
~ ~ ~ h00 VVo~ hLhVI03 ~ ~. ~ ~ ~ ~ ~0 ~ ~ i ~ r~oi ~ ~ teyraieti ~ "e ~ %
P 4~
3 p
bine Nile Point Dnit 2 PSAR TAKE dh3 i (Cont) h03lpe aa0pe ta11 Locked Po00er Source Equipa0ent de tt ec BALLL ~aee ad Rot~
120 2EJAPS er puap B 000 motor heater 120 2EJhe PllL301b 2SWPeb1D Sereioe Mater p pD P.D notor heater q 2EJAPRL301b Sereice eater 120 pump P 2EJAPRL100A 2EJhePllLI01h a0otor heater Reactor building 120-V heater panel Contxol building
'150 A 150 A 260 1
~, 15 8$ o 2EJheXD100A EJAXD101h I
120/260 v heater panel I op 0 2EJAe PNL300b Reactor building 120-V heater panel 150 A 208 3
~o 88.a 033 2EJA+XD300b I Control building 150 A 260 2EJAaXD301b 2E JhePNL301b 120/2a0-V heater panel
.o 2BTSeCE0%2A2 125-V battery 300 h PC 51$ 3 00 2EJSPSL100h charger p,0 2EJheXD100A Dietribution tranef orner 30 003 ~$ 75'3 300 CP 2EJbePIIL100h 6OOV-20SX/120 V 00$ ~ ~
2EJAeXD101h . Dietribution 25 kVA 2EJS+PlIL100h tranef orner 60ov 120/2ao v 2EJWPSL102A S00itchgear F 00 A 300 10'0& 2EJS+PlIL100A rooa0 A Coo~ 470 0 emergency 600-V panel 29 of 60
2 qt~yt ~ ~
P9 g P~0 ~ ~ .0 ~ ~ 0 q ~0 ~ l0P ~@~ ~ Pdttqws yg~ 0, ~ RP ~ ~ .~ 0P ~00020 Nine Nile Point Unit 2 tSAR ThHLH 803 8 (Cont) hap s hapi
"' "' R tall hgaiyaent PRRRIIP PLRP ~t ~as KPPRd Locked R~ata Power Soarce 2HVCCI11h Control baildiny 60 kN 515 ~ PNL100A eqaipaent roon 306 beater Control baildiny 10 IN $ 1$
equi pnent nxm 288 28CVeXD101h Distribation 2% RVR .~dRS 2EJStÃL100A transf orner 600-V-120/280-V 2VHheUPH2h(hC1) Die lh 2S kVA 515 2HJS+tÃL1 OOA control UPS
'75 2HVRDC801h Reactor baildiny 51S 205 1600 2HJStNL101A space cooler el 17$ d 2HVReIC801D Reactor baildiny 2 5 1600 2EJStHL101A space cooler el 115I ///Qo'Fi40 2HVRDCI 02A Reactor baildiny 595 90 2HJSatNL101A
~ yace cooler ei 17$ i 2HVRaIC8025 Reactor baildiny 515 2EJHetNL10'lh space cooler el 11$ I 2HVReDC808A Reactor baildiny 515
~Bd,oo 2EJS+PNL101h space cooler el 1$ 6i 2HVRIK808H . Reactor baildiny 3 hp 575 3060 25 2SJSetNL10 th space cooler el 196I gazoo /MA 28vRQcs1 ah Reactor baildiny hp . $ 1$ 2HJH Olh space cooler el 17$
30 of 60
l
~
@fan g )4' ') ~ ~ L t ) ~
8 i+pl ~ ' a fe lline Nile Point Qnit 2 PSAR tAILE be 3 ~ (Cont) 2EJb tt Egest R
nt Reactor buildin ZQP LUI Q
p~n I hp
~
S7$
~s 3
Aa)ps Foll 5 ~
heps Locked Ruhr
- 31. 2 Power Source 2EJS+PHL101h personnel airlock 2A g~gVA 7 Spec filter train 6 $ 7S 3 2EJS+PllL102A electric heater 2HVCslE.'141h Standby ewitch- 7oS hp 515 bib 2EJSsPÃL102A gear roon h mit cooler 2HVCsQC103A Chloride roon $ 7$ 1 23 10+5 2EJS+PHL102A unit cooler 28VC~QC 101 Control building cable tunnel I 1$ hp 575 1$ i2 ba 2EJSWHL102h unit cooler 2HVCQC 106 Cable area base 1$ hp 57$ 1$ i2 be 2EJS+PNL102A unit cooler
~~g20 2EJS+PllL'1 02A 28VP+QC1A QQ '1 unit cooler 575 standby QQ roew 2HVRi@105 Reactor building Q 3 hp $ 7$ 36 231 2EJS+PllL103h space cooler el 198I 2HVRQCI07A Reactor building 1 5hp 575 1 8512 2EJSPllL103A space cooler el 2HVRsQCI07b 215'eactor building I 1 S hp S1.S 1~ 8$ 1L8 25384PIIL103A space cooler el 215~
g//VR
~ac)mc Reactor building space cooler 0 15hp 57$ . 3 1 85 12 6 2EJSPHL103h el 215'I Z.2y /d.tO 2HVR+QCI1$h SQT el space cooler ~hp $ 75 2EJ 8+PHL103h CA//8A '//F'C4 261 ~
c~rj~oy~~ 5 . 3 /iB Idw 50 ggJggML,/os g~ygK~ HA'DH 31 of 60
&k'c ~ cAs/SC Co@'7/&AYpools /.Qi s75 / '8 /~W ZrJS+ ~Lro2A
). Incr 9dllQ
~ + I ~ fWIlf D Nine Nile Point 0nit 2 PSN ThSLR so 3 ~ (Cont)
Equi paent it tilter train t I1 A
g+v~eogt 4 I It~at 20 kit g ~
575
~ace 3
Load 20 0 hsape Locked Rotor Power source d
28JSiPHL10ih beater Ieactor building 575 54 3bi7>
28VS+KIOeh 5 hp 2EJSPSLlOeh
~ pace cooler el 2a4<
28VRaOCIOIb Reactor building 4 575 s'a+I ~ma 2EJ8+ WL14a A apace cooler ei 2iOD 28VRQCI10h Reactor buildtng 0 1~5 hp 575 28JSePNL10IA apace cooler el 240'eactor 28VN+QCe 'l1h building 0 3+3C 2S 28JSePNL10%h apace cooler el 261 2'IA
~
/eA 28V8eQCI12h Reactor building 6 3D3C 25 apace cooler el 261 ~
2R&CSN2b2 125-V battery 300 Ag + 515 D . DD
( gP 2$ JS+PitL300b charger 2EJhXD3 408 Oietrlbution tranaforaer 30 kVA 57%
4oo D 3D C>~ 28JS+PNL3448 COO-V-244Y/120 V 28JheXD341$ Dietributim 2S kVA 28JSPNL3005 tranaf orner COO-V 'l24/2IO-V theo ~~
28JSa PÃL3018 evitchgear ~ 00 h ~1 3 1DD 2EJSiPIIL300b roon b eeergency 644-V panel 28VCC8118 control building 60 kN 2
Y 515 8'PitL300h
~ quipeent moa 306 heater z~~ eABr4A Fko+g /A~ ], pre /7' 9 g//yA'4CAH32A ~'MAD Ie. SPD~ .fXG
/ure 32 of 5'r+
CO
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~+4a 2EJSePHL300b 1 Control building IO kW ui nt rooa
+OCl 2SCVsHD3018 Distribution 25 kV7L 2EJS+PSL300b transf oraer 640-V-120/210-V i'+
2VbhsQPS28(hC1 f Dir. IlhQPS .-
control WAR l v-4gdv ~.
-train-25 lb%
0 515 515 2EJSpllL304b 2EJSePlCL301b 28VCsl8:101b Standby aeitch- 1.5 hp 515 2EJS+PRL301b gear rooa b unit cooler 2HVCsQC103b Chloride sooa 515 1i23 10 5 28JSPllL301b unit cooler 28VCsQC105 Control building 515 5 II 35 2EJSePlIL301b cable tunnel 2HVCsQC107
" C$ H"~$~<<"
2HVHQC1I 28VRQC401b
" 'itreit cooler Cable area base
'NPsnts'~
standby DG cooler Reactor building space cooler rooa T
~ ~
5 hp 2 hp
$$ $ 1$
- =..5e.
515 515
..=
3 1$
~.W g @z 2 5 (%4 C~~
2N SeNIL301b
$ ar~m$ @z 2EJSs 28J8P1CL302b g~
~ l 175$
2HVRsQCI01C ~ Reactor building 2 hp 515 ~ 3 2+5 '16 2EJS+PHL3028 space cooler el 115$
2HVR+QC 1 01 8 Reactor building 2 hp $ 7$ ( ($ 37 2~5 16 2EJS+PNL342b space cooler eL 175$
Z~Jse&l>Id "->
Vcr CAB/HB cern/RWi.+g 4 Q7S
/ PIDO+cf WAD% 33 of 64 Mech can//L7 ~~+Fig fPeo~ j.5/e ~a- ~use &LB<<<
v op ~ <<yips w qqgi <<r ~e ~ ~ ~ ~ ~ ~ ~ '<tO "~> W~. gyes ~~ ~ t.. ~ ~ '
~&~cRflof. ~' 4+tI. QP t Sine @le Point tInit 2 Ybaa TILSLE Sr 3 ~ (Cent)
Equi paent; ca ~ '~s xu&! Rban to
~ad l
e ILape Locked Qi~to d P l.BOOB
'i~a 2%FROCI01t Reactor boilding Y 2 hp 515 3 25 14 2EJ apace oooler el 115I Reactor building $ 15 2EJS+PRL302b I apace cooler I C
4 2NIRaQCOOCD Reactor bniIding apace cooler 3 hp 515 ~3 2$ 2EJS%%3025 el 196'r A 28IRQC11lb boilding $ 75
~85 apace cooler el 11$ i Reactor boilding 575 2re 15 7 2EJS+HIL303b apace cooler el 190'eactor boilding 1r5 hp 575 1 85 12,6 2EJSPIIL303b apace cooler el 21$
2EVROCl01E Reactor beilding apace cooler Y - 1~ 5bp 515 1 05126 1EJSOPIIL303b el 21St Z.Z4 m.80 2EIIR+IKO15S SOT apace cooler 515 2EJS+PRL303b eZ 261 ~
g]8 :-. j) tilter train beater b ~
'r 14 kII $ 15 3, 20,0, GP e NL30ib Reactor building
~a+,Z 2EIIROCC0%L .Y $ 75 2EJS+PRL30ab apace cooler el 2aO ~
28IIRaQCI09b Reactor bailding 57$ SC 3I2 2EJSPIIL30lb apace cooler el
~%-gp~ 2aD'~~
)(/WR jgPNC/A 5 zeeA bpQ -. 4a.4o z~+W~>E 3a oY CO ghlPsk r4Pd03 ~+QIHCy Z5iKVA r. "-~~>> / 4w. go Za/s~MLso2.8i )
XFWR >.. &ou
Nine Nile point Qnit 2 tSAR TJQKR 8 3 ~ {Cont)
AIfps d tt Eqoi paent No III Ii E&4a V~e M%1
~i Rocked Pover Soarce d
2BVE+QC810$ Reactor building apace cooler 1+5 hy 5153 1~8$
/Zr 40 2EJSPlIL30 lb
~ 1 250I 2BVRaQCI 10C Reactor building ti5 hp 515 1~8$
~zM 2EJSPÃK30ab apace cooler el 240'eactor SHEQC81lb haildiny 3m 36 2EJS+AIT 30 ab apace cooler el 26'lz 25%R+Qca11c Reactor bai1ding 575 3. 35 25 2EJS~34 lb apace cooler 2BVRQC8 128
~ 1 251 ~
Reactor haildiny 515 '3 3~36 . 25 2EJS
~H Oab
~ pace cooler el 261 ~
l"C O 2EBS~C101(1) 600-V NCC ecreen- 6 600 A 600 2EJSaQS1 veil el oo 440-V NCC 261'EBSaRC101{2) acreen- 0 400 A 600 2EJSQS1 veil el 241 ~
2EBS+NCC102 (1) 400-V NCC 400 A 500 2EJSKJ81 reactor building el 240 600-V NCC
'EBS~ICC102{2) 600 A 600 reactor baildiny f.: nP 2EBS+lRC103 (4) 600-V NCC 400 A 3 , 540 2EJS+QS1 central baildiny el 2aOi 2EB8~103 {2) 600-V NCC 400 A 600 2EJS081 control bail ding el 2aO ~
35 at 54
Nine Nile Point Unit 2 PSAI YASLE do3 I (Cont) hnpe haps Pall Locked Sqaipaent de tt No ecr one a~ gv~eQg4 ea )~ted% ~t ~ae ~d ot Suit~ear rom 400 1 400 2EJS+Q$ 1 2EJd+PIIL100A 1 eaeryency 600-V panel 28CdePIIL22he Hydrogen 120 RN 515 120 recoebiner 2ITEKBKTA(Q pcwer cable 1 cocctroL chiller building 11 11 HP s 515 cl 125 2%JSeUS1 2EVheIC6131 Reactor building 150 hp 575 3 130~ ~ 2EJSeU$ 1 unit cooler 1
~~A 2EJSKl$ 1 2LACePIIL1001 Control rom 1
~ nergencf lighting paneL ~ ~ ~
4u) F 00 2EEdalRC301(1j 600-V NCC ecreen- Y 400 1 4Mb 600 well el 261 ~
2$ $ $ NCC301(2j 400-V NCC ecreen- 400 A vell el 241 ~
~ 288$ IKC302 (1) 400"V NCC Y 400 1 reactor building (l)
~ l 400-V2aO'EHdeNCC302 reactor building NCC 600 1 CS'00 600 2EJdeU$ 3
~ OI "c,'O 2EddiNCC303 (1) 400 V IICC 600 1 400 2EJf@7$ 3 ccatroL building 2ESditKC303 (2) 400-V NCC Y 600 1 3 600 2EJSKld3 control building el 261 ~
boO 2EJS~WL300b deitchgear rom b Y 600 1 CITS 600 2EJdU$ 3 emergency 600-V panel 36 oC 60
P
~ Ass rlrt I
Nine Nile Point Unit 2 PSA1 TASLE Sr 3 ~ (Cont) hape Eqaipnent iI ~v~e~caI ~i~n ~te ~ae hnpe Pull
~ad RotoL'ower Locked Source lurch ecr onC 28CS+PIIL22b Hydrcxgen Y 120 kll $ 7$ 3 120 recoabinar power cable b AP~
2SVXKXL18 (1) Control building 180/+ 57$
chiller 2EVEQCI138 18 Naactor building 150 hp 575
/~98.80
~; 2EJSQS3 unit cooler b 2EJ8+083 2LAC+PHL3001 Control roon b eaergency lighting
~ s 2EJSIX2 '
2ERSNCC201(1) 600 V
~ witchuaar r~
NCC EPCS 2EJS+X2 MESSNCC201{2) 600 V IICC EPCS ewitcbgear roon OO 1 500 ir000 780 2CSLP1 QCI g62 2EN8SII0101 600-V QS eaar- 1,600 A gency ewitchgear 4,oa ssssoossgW saa-s as ~a- 1 600 A g62 2E)IS+8%0101 gency ewitchgear roon h 1r000 bP ar000 3 126 820 1 77$ 2ENSiSQ0101.
2EBSP1A NR pcuiy A a 1r 77% 2E!CS+8%5'l0 1 28PCP1A SPC water circ- ~ 50 hp 3 55 32%
ulating puap A ~
2SMP+P lb Service water 500 hp 1r000. 3 77 2- aa7 tr 200 2ENS+SMO101 pcaap h 28llPP1C Service water 600 hp ir000 3 77 2 II7 1s 200 2EWPSQ0101 puap C 28IIPPIE Service water 500 hp lr000 3 ')1 2 aa7 1~ 200 2EÃ8880101 pwrp PIE 37 of 60
~'
~,
r-.
~ <~ <<'
!Cine Itile Point ttnit 2 PSAN ABLE So3-4 (Cont) ape Equiyaent ~Pi Locked Power source dett CCS II&imr FuRa )thor 2CSSP1 SPCS ycap 3r050 hp br000 3 318 1r 784 2EICS+SIC6102 4160/600"V .
1EJdeX2 225 RVh 3 31~0 2EIISeSIRI102 tra naforner HPCS C os 2EJlW$ 3 600-V eeergency 1r 540 h CAP 3 952 2EbdeSIN103
~ witchgear
(%V 2EJSQS3 (Q COO-V energency 1rCOO h 470 3 962 2Esdisr0103 eritcbg ear 2RbdeP1b RSR pony b 1r040 bp er040 126 424 2ESS+8%010$
2RES+P1C RER yeay C lr000 hp ~ r400 125 820 1r 715 2EICSrlnCO103 2SPCP1b SPC rater circo- 450 hp 3 55 329 r 719 2ESSSN0103 lating yanp b 2$ INeP1b service rater 640 hp br 000 3 77+2 447 ~ 200 2EICSeCRRI 103 yunp B 2$ loeP1D Service rateL 600 hp br 000 3 77~2 447 1 ~ 200 2ESSeSIIO103 yaep D heal 2SIIP+P1P Service rater 640 bp br 000 3 17& 2 ~ 47 1 ~ 20 2ESSeSWI103 poop P1t
/Si V /2,uc fP 2EPS+II0042 Energency eritch- 1 ~ 200 h 2EPIIeSQQ401 gear <<2<<<<<<
gfIQAV 2EPS'i%t0404 Energency ewitch- 1r200 h 2 3 2EPbeJWQ003 Qear 2BYSKRQR1h1: 12S-V battery 340 S7.5 3 80 2LAC+P ICL104h I .
~
~
charger Div 2LhC+XLXOl Lighting 30 kvh 3 34~0 2LhC+PNL100h traneforaer 500 108Y/120~V 3b of 54
Nne mile Point unit 2 PS'NLI 803 ~ pont) hape hepe Poll Locked Pover Source Eqeipeent tt ~tg V~oe ~ae ~ad Rotor aa So ac Lighting tranef orner g~ee leyte~
30 INh ~4 3 30~0 2LhCePWL100h Ql 640 208Y/120M C~ 30 2LAC+PÃL100h
'ACIL!06 Lighting 30 kVh tranef orner 640-148Y/110 V 28CN+ID101h Dietribotion 25 kVA 2LRCPlIL100h tranef orner 640 120/2IO-v 28CNIID102h Dietribction 2$ RVh 2LhCPSL100h traneforner 600-120/2IO V 2SCS+ID103h Dietribntion 25 kVh 2LhC+PlIL100h tranef orner 600 124/210 v 2VBhQP82h(hC2) Die Ih 25 RVh 2LACiWL100h control OPS 2BTSeC80I281 12$ -V battery 300 h OC +V$ 80 2LhcnL3008 charger etandby Die II 2LhCIL! 02 Lighting 30 lych 3 300 CP 2LhCaPllL300b traneforner 600 208Y/120 V 2LAC+XLEO5 I ighting 30 RVh 3 300 Q7 2LhC~a3008 trane forner 2LhCa XMOT ~
600~208Y/120 V Lighting tranef orner 600-208Y/120 V 30 lych ~~e 6ee.
~ .3 30
~4BW
'a 2LhC+P1IL300b 2~ID3018 25 OWL l 1 2LAC+PllL3048 transforner ADA'ietribution 604 V-120/250-V '
2scPt4xDlo4A naS60ba+a g ggglA a~~
~nCArwm 39 of 64 2Sckf g ZsevW, y8.40' ZLAc@ ~ZluoA
~ v" ~ (p( ~ ((
((g'N>>(a ~ (~ ~ ( eryqVe ~~
f( "~
I I s Nine Nile Point Onit 2 PSAN
'fhbLE So) S (Cont) e Inye Squi~nt tu 1 Locked Pover Source de t Rkrk%iQn~a'<~knm ~te ae ~d
< ai~40 po~r 2SCNeID)02b 120-V dietri-hution panel 25 INL 4Q 2LACPNL300b
~NB
+0 2SCNeXD)0)b 120 V diatri 25 kVA 2LAC+PNL)00b hution yanel
~SF< ~C8 0((
2VbheOPS2b PC?) Die IIA cmtrol OPS 25 kVA 2LACetllL300b 2LACePNLE01 I ighting panel a 3 2LICXLE01 2LACePNLE02 Lighting panel v g)Q 150 A 208 . 3 2LACeXLE02 2LACePNLEQS Lightinq panel 150 A 2QS 3 %50 A 2LAC+)KIOj 2LACePNLEQ5 Lightin0 panel 150 208 3 3'08
~
(
150 A 2LliCeXL$05 2LACePNLEQS Lightinq panel 208 2LACeXLE06 Lighting panel 208 3 150 A 2KACeXLE07 Lighting panel 150 A 208 3 150' 2LACeXL200t 2NSSeNOV10A (((((( N((& T(((O Oo )hp 575 oie2 2 1 1>>7QO 2NN~COQ)A 2NSSeNOV10C Nain eteaa valve 0>>13 hp 575 . Qee2 2% 1 1>>7QO 2NN~CCO03C 2lmlbelClV158 Nein ates valre N Oe13 hp 575 Oi36 1>>800, 2NN~KCOO)C 2NVIePN15A Electrical 0 75hp 575 1 ~ 8 ~ 1 ~ 200 2l~ICC006 A bay eahauat fan 2SVIPN15b Electrical 575 1>>200 2tg~ICC006b hay eahauat fan 2NSSebIV7h ~ . NSIV outboard N 3 hy 2Nl~CCO 1 1.
2NSSeHTV78 3 hp 575 2NNS~11 2NS8elRVlC N8IV outboard 3 hy 575 2NNS-NCC011 2NSSe SIV7D NSIV outboard N ) h 575 2NH5-NCCO1 1 ZSt AAPD8048 ~~y uisnABuv~ J ggKVA bdD ggAG4 ~sC '%WAN
~~7%4h'JssoP&48k ~ Oof 60 zz~~ e XD3oSB ggyy g7lsTRI5uTi 4 ASKS aou wy.4d Ae ~ ~LyooS
~ ~+>><<Af<<ft>>fbi>>>>rf <<i" +>> wtei >><<s <<>><<o~ Pggo<<" ~ ~ ~ ~
l >>>> ~ ~ -<<>><<<<y~~~ft) ~,rii.<>3 ~ (Cont) lhgaipaent de 2RC!F INV10h Ru<<<<>> "'>>la "'ecircalation
~Qg
~ bp V~ot 575
~aa hape tul1
~d
-Sa4 hope Locked Rotor 1 800 poorer Soarce
~bmICC$ 91 panp h
~ action valve Recircalation $ -bp- S>>$ 87e 8 1 ~ 800 paap h 575"'57$
diachar9e valve 2NCS+NOV101 1CS to eater gdPhy ~~ T' 1 ~ 800 ." " 2NH~CC01~
oleanap 2NCSIC7V 103 1CS to eater cia anap 6hp'; 575'" 3 1;i <<16-a << 1i700 s>>2IINIMICC11% I I
2lCSINV 108 1CS to <<ater cleanap 06hp'7S 1>>68" f>>52 I~ 800 2lf!~CCOf1 -I l
2NCSaNOV105 RCS to <<ater 0>>6 h 575 '1>>6b " 9>> 52 1 ~ 800 2IIS&tICC01~
cleanap o 5~
2DtweWN128 RPV drain POL~ "N" ..57$ ~~ 2Na~CC012 2D~INV12% RPV drain lSoL i+QIC N~ 575
~Co ar@f-'N~
2NSSaHZV6h NSIV inboard ~ tA"57 cP 2NSaeCCOS5 2NSS+BZV6b NSIV inboard kibp - -57S 2NSS NCCtft 2NSSEEV6C NSIV inboard 3 ibp . 57S CiP 21%~$ 12 2NSS+SZV6D NSIV inboard 57S (~W RSRPINV108 Vent. valve QK-~ i75.- ,3..<<>>,
2NS~VI 'Ib Vent valve 0 66hp 57S 3 2l~C012 2NSS+NOV119 Vent valve e O. >> 2llS $ <<NCC01 2 2NS$ ~189 Nain eteaa valve ~~>>vs - s- 2llltHICCOQ>>
2NSS+NDV 207 Nain stean valve 2N$ ~4lb 11 oi 60
Nine Nile Point Onit 2 PShR ThBLE bd3-8 (Cont)
~ hnp s Equigeeat den t htl ' IILUI t~t ~t Po 1 fjgad Locked Rata A'-8 t Power Soorce 2RCSlilV108 Recircolation 515 3 Sd6 1 ~ 800 288~012 P~P B section ralre 2RCSK0OV18b Recircolation 8 hp 57$ 5~6 e7 8 1rbOO 2RB~CC012 ponp 8 discharge ralre Reactor building 204 hp $7$ 102 1~ 152 polar crane
~ otor el 387i td~ ~
2ERSaSNQI02 8160-v Bpcs 1 ~ 200 h 3. 1r 200 2NNS SQQ16/11 ssitchgear 142 4(Lo V 2ERSaeeiol (1) = 8160-V emergency cwitchgear 10'1 1 ~ 200 h M8m 1r 200 2NNS-SN016/18 2ERSSt0103 (1) ~ 160-V eaergency 1r240 h
~wea 1 ~ 200 2NN~l%17/1b
<<ritcbgear 102
- 2EPSSNQ001 Eaergency 1 ~ 200.h 1r 240 2NPS SMQ001
<<eitcbgesr 2EPSalWQ003 Eaergency 1r200 h 1k'0'%% 1r 200 2NPS-SN6403 avitchgear 2CESRhX008 (1) SRN/IRN CRD rack N 0%2 kll 120 28Ch PNL200 2CESaRhXOOb (2) Si IRN rack N 3 1 kN 2SCh PNL200 2NS I 90h(3) Relay ogic cabi- N 120 28CL PNL200 net 2N88aBVY6h) 2NSSa PltL908(3) lay logic cabi- 120 Ch PÃL200
~
net (2NSSiBVI68) 2NSSaIPÃL (3) Relay logic cabi- N 120 28Ch PNL240 net (2N88iBVY6C) 2N88+IPHL90D(3) Relay logic 120 28Ch-8IL200 cabinet 12 of 60
Nine Mile Point Unit 2 FSAR TABLE B.3-4 (Cont)
Amps Amps Equi pment Pull Locked Power Source Volts Phase Load Rotor Rom Identity No.
K002 RWCU instrument 120 2S A-PNL20 rack A 2HSS~IPNL91A(3) Relay logic cabi- 120 2SCA-PNL201 net (2MSS~HVY7A) 2HSS+IPNL91B(3) R logic cabi- 120 2SCA;PNL201 net SS~HVY7B) 2HSS~IPNL91C(3) Belay logic abi- 120 2SCA;PNL201 net (2HSS~HVY 2MSS~IPNL91D(3) Relay logic cabi- 2SCA-PNL20 1 net (2HSS+HVY7D) 2GTS+SOV101 Primary contain- 0.5 A 120 0 5 2SCI-PNLA10 1 ment purge isolation valve 2GTS~SOV102 Primary contain- 0 5A 12 0.5 2SCI-PNLA101 ment purge isolation valve 2MSS'iSOV93A HSIV drain valve 120 2S CI-P NLA1 0 1 2HSSN27 2HSSi'SOV93B , HSIV drain valve 120 2SCI-PNLA101 2HSSN27 2MSS~SOV93C HSIV drain valve 120 2SCI-PNLA101 2HSSN27 2HSS~SOV93D HSIV drai alve 120 2SCI-PNLA10 1 2IASiSOV171 Is~ tion 0.5 A 120 0.5 2SCI-PNLB101 Waive 2IASN01 2SFC+SOV114 Cleaning valves 05A 120 0.5 2SCI-PNLC104 2SFCN11 2SFC4'SOV115 Cleaning valves 0.5 A 120 0.5 2SCI-PNLC104 2SFCN11 43 of 60
Nine Mile Point Unit 2 FSAR TABLE 8.3-4 (Cont)
Amps Amps Equipment Full Locked Po~er Source Volts Phase Load Rotor ~R ~Zdentit No, HVP+MOD6A Exhaust fan 1A 0-25 hp 120 1 5 8 4 2SCM+PNL101A 2HVPA04 2HVPi'MOD6C Exhaust fan 1C 0 25 hp 120 5 8 2SCMi PNL101A 2HV A04 2HVP+SOV4A DG 1 vent VPA04 120 2SCM~PNL101A 2HVP~SOV4C DG 1 vent 2HVPA 120 2SCMi PNL101A 2HVR~MOD6A P859 inlet 0.5 hp 120 9 8 58. 8 2S M+PNL101A damper 2HVRA88 2HVR~MOD7A Fan A P859 05hp 120 9 8 58 8 2SCM'~PNL101A
.discharge 2HVRA88 2HVR~SOV1A Reactor building 0 SA 0 5 2SCM+PNL101A vent valve P859 2HVRA89 2HVR+SOV10A Reactor building 0 A, 120 0.5 2SCM~PNL101A vent valve P859 2HVRA89 2HVR+SOV34A 2SCM+PNL101A 2HVR'+SOV9A Reactor building 05A 120 0.5 2SCM+PNL101A vent valve P859 2HVRA89 2SFC~SOV35A SFC valve P 0 5 A 120 0.5 2SCM~PNL101A 2SFCA06 2SFC+SOVSA SFP valves P859 0SA 120 0.5 2SCMIPNL101A 2SFCA06 2SFCiSOV6A SFP valves P859 0 5 A 120 0.5 2SCM+PNL101A 2SFCA06 2SMP~SOVVA Pump seal P601 0.5 A 120 0.5 2SCM~PNL101A 2S'MPA3 2 45 of 60
~ >> ~
graf~ tt +fP ~ +III 0 2.>> ~ I' I+M+' ~ l2 IP~ V2~ P" Q>> 1 I Q w~VfaOfTP+fl I~ ~ If+ I'I I ~
Nine Nile Point Unit 2 PSAS ThSLSSo3 e (Cont)
Aepe AIcpe Full Locked bqaiyaent de t 1$ EW' " IIUJ at n ~d 2~toe 2SCRIPlIL101h 2SNPallVSA Peep eeal P801 h 120 2SNPA32 Ch 18CS~PRL102A bearing cooler h 120 0 2CCP+$ 70124 P859 2CCPA13 nB ~o.S 28'NC 102A bearing cooler ~ A 120 2CCP+80V9h PSS'9 2CCPA13 120 4 5 28 CN+PNL102A V 2CNS80V1SA Ieolatice valve ooS A P859 2CNSA03 28CÃPNL102A V 2CNS~S0V1ai Ieolation valve 05A 120 0 5 P589 2CNSA03
~5k'QASA122 ~A 2bCRitNL102h Iaolatice valve . 1 P58' 2CNSA03
~CO Ieolatice valve g O~F A120 2SCIf+PHL102h P8$ 9 2CNSA03 120 28CIPPNL102A 2CNS80V23E Ieolation valve CI~S PSS9 2CNSA03
~cs8 28ClfPlIL102h
'CNS80V2QL IP859 eolation valve O.SA12O 2CNSA03 2CNS80V2IC Iaolation valve PSS9 2CNSA03
~e -RA. 12O
~4'i b'oI 2SCllNIL102A "L 0~8 6120 , 28CNPNL102A i.-2CNS80V25A Ieolaticac valve P859 2CNSA03 v,8 ~ ~
Ieolation valve ~s o.SA 12o
~
e 28dll+KcL102h PSS9 2CNSA03 Or8 I. 2CNSSOV2dh Iaolatim valve (0 S AO P'+120 ~PNL102A P859 2CNSA03 c.8 2CNS+SOV26C Ieolation valve cf S.h ooSA 120 2SCIC+P NL102h P859 2CNSA03
~ Sof 80
'I
~ F02 y ~ ~ ~ 'i+02 ~ ' ~ 0 ~ V0 0
- 02se~ 20~~wg 0o' ~ ~~ ~ 'I 2~ ~ ~
Nine Nile Point tacit 2 PSALM VASLS 8+3 a (Cont)
ASaPd Locked toenr soerce Pbaee ~tor d t Ido a on valve 005 A 120 005 28CÃPNL102A P859 2CNSA03 Ieolaticn valve 005 h 120 005 2$ 0tePNL'l02A PS59 2CNSA03 "2CNSeSOV3ah Iaolaticm valve 005 h 120 005 2$ CRPNL102h PS59 2CNSA03
'CNSeSOV35A Idolation valve 0 5A 120 005 28'PNL102h PS59 2CNSA03 o.22
<'2CNSeSOVCOA Ialatice valve 63 CV 28CNPNL102A
~
2CNSeSOV61h Ieolation valve o~A 2$ CNPNL102h o~8
'CNSeSOVC2A
~ 2CNSeSOV63A Ieolation Ieolatice valve valve
~oaf o~
d-8~
2$ CNiPNL102h 2$ CNetllL102h
< lcas80vCah Isolatica valve 28CNePNL102A 1'CNSeSOV65A Ieolation valve 220 a~a 28CNtllL102A 28VCeR)D 88th filter 2A 00125 hP 120 28CII+PNL10 A 28VCA12 2SVCelOD51A sekeey air 120 28CN+PNL102A 28VCA12 2SVCelDC1A Control buildiny 0 25 hp 120 2$ CINPNL102h idolatim deeper 28VCA12
'i lSVCeSOV1gA eg Nels rooe 0025 hP 120 OSCARtÃL102A A/C 2A 28VCA12 228VCeSOV170 Diecharge daayar 0 005 h 120 28CNePHL102h P659 a1 of 60
~, ) ~ )~~ i~( ~y ~ ~ ~ ' >+fP% Ph'fFQtff >> (Qt'81 0' ' ~
~ wysgyey ~ > 1~
Nine Nile Point Qnit 2 PSAR TASLE 8 3-8 (Ccrlt)
Eqniyaent de t 2HVC+SOV183 biecharge daeper
>>J> ~lat n 0&5 h
~
120
~as Aa e Foll Load haps Locked ft~ot I
twer Source 28CIPPIIL 42A P859 2HVCII33
= 2HVCSOV6h Control r~
h/C 1h 2HVCA12
~ 025by '120 '. ~v.s 2SCNPllL102h r 2HVÃSOV3EA Computer AIC Oe5 A 120 o.s 67 28ClCtÃL102A P859 2HVKAOI
~o.e
~2IAS+SNC181 Ieolation valve A 120 2SCS PIIL102I, 2IASA17
~OS
< 2IR880VT181 Ieolatice valve ~o>di'88'd 28CNetIIL102A 2IASA17 v 2lhs+80v16e
>2lhbeSOV166
< 2IASH)V167 Ieolatiaa valvee P859 2IhSA11 Ieolation valvee P859 2IASA11 Ieolation valvee
~dsgd oi8d ogd'$
~ 2SCNWIIL'l02A 2bCSPNL102A 28CIltIIL102A P859 2IASA11
~o>
~'IAS+SOV168 Ieolatim valvee di'i8 2SCllPIIL102h P861 2IA8$11
~dEo BIAS~169 Ieolatim valvee 2SCNPHL102h P85'9 2IASA11 W2IAS'~AN'I10 Ieolatice Valvee
~085 ~O 2$ UfPIIL102A P861 2IA8811
/o.NN/
~ ZSMP80V15IA SMT cooler valve 2SMPh29 120 cgP 28QfPRL102A ZSMP+84V572 SMT cooler valve 0~5 A 120 o.s Cg 2SCIO+PIIL102A 2SMPA29 g~.~w' 26MPIOV573 SMT cooler valve 28MPh29 124 c8V 4 2SClf+PRL142A i8 of 64
~ \ ~ P glV l 00 lo ~ ~ % ~ ~ 0ll 0 l '0 ~ ltlWPfll+0l ~ ) ~ ~ $ 44 ~ ~ ~ l ~ 0 l4 ><a lV i+ > ~tl Wll Nine Nile Point Unit 2 PSAI TASL8 $ 03 ~ (Cont) hape hap s Equipaent Full Locked.. Pwer. Source RLl'l ~a aolor de t 2$ 8pasov513 ee cooler 28WR2%"
valve . o.. A - " "120" 28~ 1IL102K OPIPNLa01(5} DQ control panel 120 2$ CR+PlIL103A 2CSSvIPNLI01 {7) Da control panel 120 2$ CNPIIL103A
'FPNaSOV218 Primary contain- h 120 28CIOPIL103h
%ant iaolatilRl 'os/
valve v 2FPQ+SOV220 Priaary contain- 2SCIIPNL103A ment iaolation valve
" 28VCSOV Contml building 005 A 120 005 2SCNPNL103h 1ST eaoke daaper r~al 28VC4SOV120 Solenoid valve 05A 120 005 2$ CNvPNL103A 28VCSOV1I2 Solenoid valve 005 h 120 0 5 2$ CN+t NL103h 28VCSOV1$ 5 Solenoid valve 005 A 120 005 2$ ClC+PHL103h
- 28VCRlV1IS Solenoid valve 05A 120 005 28Cll~PSL103A J 28VCSOV16% Control building 005 A 120 0 5 2$CNPNL103A h/C 28VC+MV171 Contml bailding 005 h 120 005 2SCIOPHL'l03A A/C
'8VCSOV1$ 2 Control building 005 A 120 005 2$ CHPlIL103h h/C 2HVC832
'8VCaSOV212 Solenoid valve 005 h 120 1 005 2SCNPSL103A J
; 28VCSOV213 Solenoid valve 005 h 120 1 005 2$ CR+PIIL103h 28VK+TV21h Control bailding 0 25 hp 120 QP 2706 28Clf+PSL103A h/C 28VFh02
~9 of 60
I, l5 I0 0<< I It I0 ~ <<II~ ~l ~ rl ~ <<W ~
I
"<<<<0'0 ~
leone Nile Point Dnit 2 tsM TABLE So 3 ~ {Cont)
Anpe Anpe tall Equiyaent .
de tt llo <<<< ~e ~Ph as Load Locked toeer Source 2BVR+TV22A Control building 0 0025 ~ 120 2706 2LNSiSOV'l53 AlC 28VlQL02 Isolation valves 2U58h01 0 gp 120 28CN+tlIL103A ZLNSebov157 Isolation valves 2LIISAO 'l a BP 120 2SCN+PNL103A
~
28tcaSOV17h Cooling valves 005 h 120 0.5 Qt 2SCNatbL103h P859 28fCA05
. 28PCeSOV18h Cooling valves 05h 120 0 5 2SCNitÃL103A P859 28PCA05 28PCelNV1'9h Cooling valves 005 h 120 0 5 2SCN+t BL103A P859 28PCA05 2SPC+SOV33A Oooling valves 005 A 120 0 5 2SCINtlC 103h P859 28PCA05
'8PCa80V37h BPP valves 005 h 120 0,5 2SCNaPBL103A 28PCA05
'" 2CPSeSOV106 'solation valve 005 A 120 2SCNPNL301b P861 2CP8801 Isolation valve 005 A 120 0 5 28CII+t NL301b 2CPSSOV1078CSeSOV14b P861 2CPSB01 Bydrogen reconhiner A 120 (RP gy 2SCNPNL301b P861 2BC8807 o.8 ~o.8 ~~
'BCSeSOV11b bydrogen A 120 RSCl0itNL301b recoabiner P861 2BCSB07 2BVPeN)D1b M rooa 3 exhaust Y 0025 hP 120 5 8 276. 28CKPNL301b fan 2BVPBOi 28V PN) D1D M rooa 3 exhaust Y 00)S hp 120 58 276 28CllPNL3018 fan 2HVPBOe 50 of 60
~ +if+I ~5 gP'fig<<<<0$ +<<<<<<
I QV0 ~ <<sssl~~sa<<aPflp<< ~~ ' ss ~ g 0'pH 0 '00 0+~~sass %<<<<<<s pj Nine Nile Point Unit 2 tsAR TNLE L3 a (Cont)
Hahanat fan 1b CE) g t ~j p~yg 0025 hP
~
120
~ace 1
toll jdlhd 5ib Locked (ag..
Soerce 2SCNiPRL301b 28VPBOI 2HVPalNDSD Hxhauat fan 1D. 0025 hp 120 5 8
~ 27'5 2SCNetNL301b 28VPBOI
- g. eA i 18VPaSOVab DO 3 vent P861 120 ~can 2SCNtÃL301b
~ g7~
28VPBOI
~adit
-'28VPeMVlb Do 3 vent 550000 ~
P861
~
120
~ ~ ~ ~ <<
2SCNPIL301b
/Sasa<<00005 000> sac<> 2HVRBSS v 2HVRe80fAS Reactor building Y 005 A 120 05 CF 2SCNetRL301b vent P861 2HVRB89 Jsssa<<seas sa<<csos sasxa5ss 5 005 A 120 1 0.S 57 2SCNiPRL301b vent PS61
~CH~2HVRbbt
+ 28VRlRlV3lb vF~ A>~ a~5> w~g Jaasa<<00AS Y 5 00000 50550505 vent P861 Y
Y 0 5'20 1 28CNitNL301b 2SCNetIL301b
~28MP~b 2HVRBSt Paap eea1 P601
/'4 A 120 RkNitRL301b 2$ MPlRNSB 2SMPB32 Puap eeal P601
/ 120 2SCNPNL301h 28NPB32
/.
p 2CCP5580V12b hearing cooler Y 0 h 120 28CNitRL302h PS61 2CCPB13 51 of 60
Nine Nile Point Onit 2 PSAN TABLb be3-8 (Cont) hsps Locked Poeer Soccrce Iqaiyaent dent one I~ grfgggc e) %~a ~t ~ae Rtttog d 2CCPeSOVtb bearinq cooler h 28Clfi P861 2CCPB13 82C 8 SOVISS isolation ralree ~ Y Oe5 h 120 Oi5 2$ CIlePNL302b P861 2CNSb03 VXNSiSOV16i isolation ra iree 05A '120 0 5 28CINPNL302b P861 2CNSb03 2CNS$ $ 23b Ieolation ralree 120 2$ CIOetNL302b P851 2CNSB03
- 2CNSeSOV23D Ieolation ralree 120 28CIIePNL302b P851 2CNSb03 2CNbebOV23P Ieolatim ralree 120 28CÃet NL302b t861 2CNSb03 2CNSeSOV2ab Ieolation ralree 120 P861 2CNSb03 2CNSeSOV2a D isolation ralree 120 28Cf&tNL302b P861 2CNSB03 2CNSeSOV2Sb Ieolation ralree 120 28CÃ+PNL302b P861 2CNSB03 2CNSSOV25D Ieolatice ralree 120 28CKetllL302b P851 2CNSB03 Ieoiation ralree 120 28CICetNL302 8 P861 2CNSB03 Ieolation ralree 120 28CNPNL3028 P861 2CNSb03 2CNS+SOV32b Ieolatice ralree 0~5 A 120 OoS 2$ CNitNL3028 P861 2CNSB03 CNS+SOV33B Isolation ralree 0~5 A 120 0 5 P861 2CNSB03 52 of 50
0 Iqr>>>> yi>>>>>>err ty>> wP++>> '>>gfv>>>>>> tt~lfE'fg>>>>1 Qt ~ >> ~ ~ ~ ~ >>>>>> 1 ~in'etPy% hl>> ~ ~ ~ (H>>
r ~
Nine Nile Point Dnit 2 PSAB TABLb do3-a (Cont)
Alps Alps Equigaent Pull Locked Poorer Soaree dent s o CPS e Cs) or Or 2cNsedov3ab Isolation valves 120 2SCNiPIIL302b PS61 2CNSB03
~o.e 2CNSeSOV35b. Isolation valves 120 28CIIePNL302b P$ 61 2CNSB03 2CNSeSOV60b Isolation valves 120 28CN+PNL302b 2CNSSOV 618 Isolation valves 120 2$ CIIPHL302b adP 2CNSeSOV628 Isolation valves 120 2$ CINPÃL302b 2CNS+SOV63b Isolatice relace 120 2$ CNePHL302b 2CNSeSOV6lb Ieolatim sa lees 120 2SCICiPNL302b ab'o5
" 2CNS+SOV65b Isolation valves 120 2SCÃ+FHL3028 i 2CPSeSOV10t Isolation valses Oo5 h 120 2$ CI0+PIIL3018 P$ 6'I 2CPS802 2CPSiSOV105 Isolation valves Oe5 h 120 0 5 2$ CIIPNL302b P861 2CPSB02
" Isolation valves +/.
2CPSSOV121 120 28CNPNL302b P$ 61 2CPSB02 2CPSeSOV'122 Isolation Valves /le 120 28CNsPIL302b PS61 2CPSB02 28VC+NOD3b HEPA filter 2b . 120 2$ CNPNL302b 28VC812 28vcNoD5ab Nalcesp air 120 . 1 28CNPICL302b 28VCB12 28VC+IKID61b Control building 0 25hp '120 1 2$ CNPNL302b isolatica dasper 28VCB12 28VCR) V12B Relay roon 0.25 hpl 120 28CSi PNL302b A/C 18 2HVCB12 53 of 60
Nine Nile Point Unit 2 PSAB TABLE Se 3- ~ {Cont)
Eqef psent "T
Fo l Aapa Locked Pwer Source de t No V~ts ~ass ~d gen~t~tNc~
~ '8VCRN114 Discharge dasper ~ 5 h 120 1 Oe5 2SCIC+PNL302b pd61 28vcN3a 28VCaSOV193 ~
Discharge d atsper Oe5 h 120 Oe5 2$ CN+PNL302b P861 28VCN34 28VCSOVCb control mon Oe25 hy 120 21 6 28CK+P NL302b h/C 1b 1HVCB12
- 28MalOV36b Coaputer h/C Oe5 h 120 0 5 2SCINPNL301b P861 28VKBOa O~~h 2IASSOVX185 Isolation valve 120 2SCÃ9NL302b
" 2lhbaSOVX186 1IABb11 Isolation valve n/ h 120 28CNWNL3028 1IASB11
~ 21hbaSOV165 Isolation valves A. 120 ~d 2SCNaPNL3028 Pd61 2ZASb11
~44
~ 2IASa$ %140 Isolation valves 2SCN+PNL302b P861 2IASb11 c
I/2lhbaSOV182 Isolation valves h 120 2SCNaPNL302B P859 2IASB11
&2IAS+SOVI83 Isolation valves 05h '120 0.5 2SCN~NL302b P859 2IASb11
~C4F 2IASaMV144 Isolation valves 120 1 (K5 G5 2SCNPNL302b P859 2IASA11 Ag ~o.S 2IhbaSOV185 Isolation valve ~ h ..120 28CNatlIL302b 2IASB1'1
- 281CaSOV35b SPP valves Oe5 h 120 O.5 2SCÃPNL302b P851 2SPCBOC 28PCaSOVSB SPP valves P 861 28Clt+PNL302 2SPCS06
Nne 1Iile Point thit 2 PSN fQILR L3 8 (Cont) bqeipaent d nt 2$ PCeSOVCb laeddls'"
SPP valvee POCI 2SPCBOC a~ "'ll 0~5 L alta 120
@BE 1
Iape Pall h
0+5 1sspe Locked motor Pover Scarce 28NP8ovl5a8 lated cooler valve 120 28ClfPllL302b cF cs PSC1 2SMP52%
ju.5W 28IPRN $71 . ett cooler valve 120 2SCINPHL302b PSC1 2SNP52%
2SNPeSOV$ 1 4 lb'ooler valve 120
~A@ 28CINP8L3025 P4C1 2 b/%
NSZPSLII 2($ ) DO control panel 120 28CNPllL3035
(
2CRt+2PSRAI 2 P) DO control panel 120 28CN+PHL303b
'FHNSOV2H Prbsar3 contain- 120 28Cll+PSL3035 aent ieolaticn valve A
2PPltSOV221 Primary contain- A 120 ment iaolatiExl valve
~
28VCeSOV177 Control building 0+5 1 120 0 5 2SCHPNL3035 I/c 28vcb32 2SVCe M%1% Control building 0~5 k 120 0+5 28CIIiPlIL303b i/C 28VCl02 25VCBOVID 2 Control building Oo5 A 120 0~5 28CIIPIIL303b h/C 2HVCS32 2lvc8ov2II. Solenoid valve 005 A 120 0 5 28C%+PlK303b 2NVC+SOV215 Solenoid valve 0~5 X 120 .. 1 Oi5 2~8L3035 control building 0 2$ hp 120 1 21% C 2SClP PÃL3038 h/C 28VKB02 control building
~sf 28V)IM228 0+25 hp 120 27 d 2eaPPNL3038 ll/C 28VRB02 55 of CO
r .ti~W~ ~ ~ oo C ~ R~ ."0 <<" ' r 00~0g,o~'W'~"' R'
~~
Nina Nile Point Unit 2 tshI TASLS 803-8 (Cont) tNul toccer Source Ilooo "'
Locked Squipaant da t ooooooo ~d Rotor 2LN+SOV152.~ Iaolation valves ~ h 28CIItlC303 2LNS 801
~e, 28CHtlCL303b i 2LN5SOV158 Ieolation Valves 2LÃ8801 120 Cooling valves 005 A 124 0 5 2SCÃ+PSL303b 28tCeSOV1lb PS61 2stCBOS 2SPC+MV18b Cooling valvaa 05A 124 0 5 28CKPSL303b P861 2SPCBO5 Cooling valves 005 A 120 005 2SCNPHL303b 28tCaSOV1%b P86$ 2SPCBOS
~ 2dtCSOV33b .
Cooling valvaa 05h 120 005 28CKACL303b P861 2SPCBOS 28lC$ %31b Stt valves 005 A 120 005 2SCR+tbL303b 2SPCBOS 28'PSL001h 120-V diatribe- 225 A 120 1. 150 28C8XD101h tion panel /0+
28CNePNL102h - 120-V diatribe- 225 h 120 150 28CWXD102h tion panel 28CNePNL103h 120-V distribu- 225 h 120 1 150 ~XD103A tion panel 2SCNPNL30)b, 120-V diatribu- 225 h 120 1$ 0 28CNeXD301b tion panel fog 28'ML302b 120-V d iatribe- 225 h 120 1 150 28Cl0+XD302b tion panel /oV 28CNi PNL303B 120 V diatribe- 225 h 120 150 28CH+XD303b tion panel 120-V diatribu- 225 h i~~ 2SCIC+Xl&200P rdcnotSL20dt 120 tion panel 56 ol 60
~ <<<<<< l <<~ r cygtrven<<'<<'% I~~~~y~~rpe wi.~ri .m ~ ~s <<I ~, ~ gs ~ t'r t ~ oe TI~
~ i Sine I61e Point, Onit 2 PSAR TABLB 8<<3 I {Cont)
Aape Agape Pull Locked CE) I~a V~ot ~a ~ ~d Ro PV5h SOTS filter pv inlet
~ 16 hp F1 28CV+P lIL101h train h 2XJB+DRA1 (I) ac or building 120 28CV+PHL101A para onnel airlock~trol 2KJheDRA1 [2) Reactor building 120 28'PNL101h perammel airlock-lightin
'8MPe SOV%7h Reactor boilding 0 0%5 h 110 0<<5 vent 2SMPAIO 2CSBebl BPCS pmap heater t<<38 .kN 120 28CVtlfL200 t 28VPetOD1A DO rooa 2 erhaaat P 0<<25 hp 120 5<<S 27<<6 28CV+PRL200t fan 2A diacharge 28VPlND2b DQ rcxm 2 erhaast 0 25 hp 120 $ <<8 27+6 2SCVetllL200t fan 1b diecharge 28VP+lNX)7A trhacat fan 2h 0<<25. hp 120 2SCVeaa200t discharge 28VPCOI 2HVP+N) D78 Exhaeet fan 2b 0<<25 hp 120 P~RC 2$ CIPML240t diacharge 28VPCOI cc~SH DI 2 vent +~5'+ 2SCVetÃL200t inlet 28VPCOI
@~5'A
~ iSVPeSOV5b DO 2 vent 2a! Ve'tllL200t inlet 28VPCOI 28MPSOV$ 81 Service water
~c7o Z 28CV+tHL200t valve P871 28MPlla5 W<<:.-
201'8'PUB ITS filter pv 0 16 hp (.120 i 1 28CV+PWL301b p ~
57 of 60
~ ~ ~.r~- pe~yi~e ~ ~ ' lo >~ i Rl,tT%
~ ~ ~ ~'i~'l~ Ift gW ~ I a ~~~nl~H'M~
~ ~
Nine Nile Point Onit 2 PShR TAILS So3 ~ (Cont)
"T Equipnent en t al u '" Bu SSL I-. tu 1 Agape Locked Pcwer Source BDRA2 (1) Reactor building 25'PNL301b pereonnel airlock-control 2XJBDRA2 (2) Reactor building 124 28CVePNL301b pere onnel airlock-lighting 28llPeSOV%7b Reactor building Oo5 h 120 Oe5 28'PNL301b vent 28MPBIO 28CVePNL101h OTS Ilieco 0 ~
2SCVX9101h 120/2aO-V panel 2SCVeHIL2005 SPCS aeitchgaar 225.h 280 2SCVeIO200P roon 120-V niece panel 2$ CVePNL301b 4YS aiec.
120/2a0 ~ v panel 150 A 6B
'KQP
,C+ cP 2$ CV+XD3018 2VBSPRL101h 120-V OPS die- 200 A 120 2VSAKJP82h tribution panel 2VBSePSL301f 120-V UPS die- 200 A 120 2VSAIOP82S tribution panel 2NSSeIPRLgth(1) Relay logic cabi- 0 120 10 2VSS+PNLA105 net RVY7h 2NSSiIPNLglb(1) Relay logic cabi- 0 120 10 2Vb SePNIA105 net !5%78 t
~ ~
2NSSIPRLg 1C (1} Relay logic cabi- 0 120 10 2lfSSepNLA105 net BVYTC 2NSS+IPNL%10(1) Relay logic cabi- 4/N 120 10 2VBSePNLA1 05 net BVY7D 2NSSOIPNL90h(1 j Relay logic cabi- Y 120 15 2VSfPPNLA105 net (2NSS~BVY6A) 58 of 60
~ q 0'1 vs gal egg>lrt
~ ~ <tlel ~ ~ o~eifat. ~~~w%Ts~ ~
Nine Nile Point Onit 2 Pshb YhbLH So3 8 [Cont) haph ape nt Poll tucked Power Scarce att bqni eel ta1 a n ~ae ~ad Rtr 2KSSIPNL90B Relay logic cabi- Y 120 1 ~ 2VBSPNLA105 net {2NssiHVT6B) 2KSSZPNL90C(1) Relay logic cabi- Y 120 RESPNLb10C net (2NssiHVTCC) 2INISIPNL90D(1) Relay logic cabi- Y 120 2VBSPNLS105 net {2NSS+HVT6D) 2KSSeIPNL91A{2) Relay logic cabi 4 120 2VbbePNI 85105 net {2NSSHVT1h) 2KSSIPNL91b{2) Relay logic cabi- 120 2VBS~ILb105 net {2NNHVT1B) 2KSSIPNL91C{2) Relay logic cabi- 4 120 2VBSPNLb105 net i2KSsiHVT7C) 2KSSeIPNL9ID(2) Relay logic cabi- 4 120 2IFh8+PNLb105 net {2NssaHVT7D) 2NSSeIPNL90A(2) Relay logic cabi- 120 2VBSPNLb10C net HVT6h 2KSS +IPNL908 {2) Relay logic cabi- 120 2VSSPNLS10C net NVT6b 2KSSIPNL90C(2) Relay logic cabi- 120 2VSSPNLb106 net VT6C 2KSSaIPNL90D(2) Relay logic cabi- 120 2VBSPNL$ 10C net HVT6D QCSSIPNLIOT {a) DO contmi panel 120 1 2VSSPNL101h 2KSSIPNLA07 (6) DO contml panel 120 1 2VBSPNL101h 2CBSeIPNLa12(a) DO contml panel 120 1 2VbbePNL301b 2KSSIPNLC12(6) DO control panel 120 2VbbePNL301b 2CESa1PNLC13 DO cIaItml panel 59 oE 60
~ f& ' ' ~ ~
~ J Niae Nile koint Oaft 2 MM tham!.3-a facet}
tuel Locked Eqai~nt e t aI.UI S~tgg ~t ~e ~ad ~to~
.. g4rs+xDce) A~41 SF'q zygiA'W g <g.+0 ~sw~gro~+
WEAR
,Zh/~<fgedZ Mzr~~iij ELVA S7$ ~
zc/H+8VL/cW KFjlR 2se~cpalA a~~.B .~A
&~~ '75
/ /PJ'S g<~e~d/oZA Mhb7$ ZZ JS W+Lro9A
<2~k rSZEA /rpwza S5 ILQ]A$
ou~ur
%.'~~R
/,5'pS / Q,o
/gmswcM le co~~i~~~ +~~~ i>(P ggJ~~R4l/d~
c~zmm RA'R $ggpgg
+ADA'Z~P~A829A gffN + /.BP!P D~ 8 /I8 /Ao ~ ..g~~~~L/@<A 8 &DWyartbm ><g~g~30BP
~~)KNEAD 'H~c P 5'r~ g ( g, /0.0
~z&lsfc/BAPB
~WAAt+NPAPHl
+~< gP~ g ), 4p /dr 0 ZE4++ pp/l 3o98
/z4VR+cA6/VB AA'cP4 y ] g]/P PrK~EL I AALPl pWeA AS gg/g 8lL$098 i 2dVA'4 cAB328 Rg BcPO rP~ y /'g/p'.
F4064 JP8D sauo~
g'o g~~ pg4g03B
/~fr+ pnfLBp,~'u/ocf/'/Iran '
~~~a '"gg~gA,ASS gp~ g )4 /o.o ~J~g FVLso9g
'ZSeFX caBZg g """~ pe A.<rg~
ygguic.C WATER,
] gy]g
~)~~a- "X"
~ ~
)
Nine Nile Point that 2 PshR TRBLB So3 S {Cont) ha pe hI!ps Rqoipaent Pull Locked Power Source dent t $ 0~IC ~tLoQl ~ 1 I <<¹$ $ l~ltl /I~It II Vo as e ~d Rotor 2CBsa1PNA1l Do ct S pt cubicle 0 e e 0 0 ided in an asenWcet to the FshR~
tvoJti s a >RIt TD OESCRIPTIOB!
R/C ~ hir conditioning CQS ~ Circulating <<ster eystea N ~ Diesel generator GTS s Gas treats!ent systen BPCS ~ High-pressure core spray BVR ~ Reactor building ventilation LPCS ~ ~ressure i Notor control core spray NCC center NSIV ~ Nain stem isolatica raise PIT ~ Pressure indicator transaittcr RbctcN ~ Reactor building closed loop cooling water RcIc a Reactor core isolation cooling RBR ~ Residual heat reaoeai RPS ~ Reactor protection systea RNCQ ~ Reactor <<ster cleanup SPC < Spent fuel cooling and cleanup SPP ~ Spent fuel pool SGTS ~ standby gas treataent eystea sNT ~ serwice eater trareling screens, wash and disposal TBCLCN ~ Turbine building closed loop cooling vater DPS ~ minterroptible power supply
-<<await TO OZVXSZONc O e Creen (Division I) ~ !l tP ~
~ 'tallow (Division II)
Purple {Division III)
~ !
N ~ Non-diVision o 1 r sonof R b ~ blue {Division of RPs)
N ~ Nhite (Division of RPS) d0 oi dO
Nine Nile Point Unit 2 FSAR The basic cell geometry is shown on Figure 9'.1-4. The reactivity of the basicB'4cell is a function of B loading in the Boraflex. The loading used for the criticality analysis is the minimum to be incorporated into the design and corresponds to 0.028 grams of B per square centimeter of cross sectional area. The nominal Boraflex thickness is 0.106 in. The thickness tolerance of +0.010 is addressed as one of the perturbations to the multiplication fact'or of the basic cell.
The fuel assembly is represented by an explicit fuel pin distribution of selected U-235 enrichments typical of the General Electric Company's intra-assembly fuel pin arrangement (which produces a bundle slightly enriched section enrichment of 3.60 weight percent U-235). No credit was taken for burnable poison in the fuel. If this fuel with uniform 3.6 weight percent U-235 were to be analyzed for infinite lattice reactivity (K~), as was done for the new fuel racks, the resultant K~ would be 1.40.
The reactivity perturbation effect of the Zircaley fuel channel around the bundle when located in the spent fuel rack is ne ative. As an added conservatism, the assumption is made that all fuel assemblies are stored without channels.
All reactivity perturbation effects are included in the criticality analysis. The final result shows that the worst case multiplication factor, K~ 5 0.8961.
The racks, on their pedestals, provide adequate 'space underneath for relatively unrestricted coolant water flow.
The holes in the cell bottom plates allow sufficient flow through and around each fuel assembly.
The spent fuel pool is cooled by the spent fuel pool cooling and cleanup system (Section 9.1.3). Decay heat loads are computed for a filled pool for the following cases:
Case 1: A normal refueling discharge containing 260 fuel assemblies cooled 12 days after reactor shutdown (12 DARS). The remainder of the pool is filled with normal refueling discharges cooled for multiples of 18 months. The total heat load is 14.4 x 10~ Btu/hr.
Case 2: A full core of 764 fuel. assemblies cooled 12 DARS, discharged 180 days after the last refueling. The remainder of the pool is filled with normal refueling discharges (260 fuel assemblies each) cooled 180 days Amendment 14 9.1-10 October 1984
Nine Mile Point Unit 2 FSAR Liftin Stron back The lifting strongback (Figure 9.1-19) is used for lifting the pressure vessel head, the drywell head, and all other critical loads during refueling. The strongback conforms to the lifting configuration required for each lift. This strongback has dual load attaching points providing a redundant lifting design.
The strongback is designed to support three times the rated load (static and dynamic) in accordance with NUREG-0554.
All welding is in accordance with the ASME Boiler and Pressure Vessel Code Section IX and AWS Dl.1. The completed assembly is proof tested at 25 percent rated load. After the load test, all structura welds are magnetic particle inspected. g5O Liftin Slin s and Stron backs Lifting slings (Figure 9.1-19) will be used in conjunction with the main strongback to loads during refueling.
lift The and transport all critical ings an trongbacks are designed incorporating a safety factor o 3 times the rated load of 125 tons. e slings and strongbacks form a redundant lifting system phd gQnp, en-4esiqgQ >nce(.@to)i9Q
- a. ~Peg (oM ~ 3 4i~~ Me ~M lc~-
A complete set of four slings will be used when lifting and transporting the shield plugs, drywell head, reactor vessel insulation, reactor pressure vessel head fuel transfer shielding bridge~ d service p a orm. The slings are 0 ars that will set using strain gauges. This will ensure equal loading at each point and will also ensure level lift.
A separate sling set and liftin cruciform lifting the dryer and separator augur ill be used when 9.1-20). These b
slings and the lifting cruciform are designed for underwater service. The cruciform structure is des'igned in accordance with the AISC Manual of Steel Construction.
f6C3 Each completed sling assembly is proof tested at percent of the rated load. All welds after load testing are magnetic particle inspected.
Service Platform The service platform (Figure 9.1-21) is provided to facilitate maintenance work on reactor'nternals. It provides a working platform for people and hand-guided tools, and it also can support a jib crane. The service 9.1-29
SFC and WCS f 1 l ter removal plugs, storage pool gate, service platform, and other cr1t1cal loads. The sling lift1ng assemblies are solid bass with turnbuckles that independently attach to both strongbacks to fac111tate d1stribut1on of load to all slings.
I ~
KASS
~ sasse ~ Isaasvs K aaaal (i
III444vs
~ al 4 Lal
~ I4 aa s
,)i,l
~ llsa SS K I~ VKSSISS
~s I sa ~ KVI slvasss I
I
~ Vasss Illsa AKI~
44 Illla Kslsllss ala4 44
~
I II
~Ia sall ~ ~ I I I4
~ 4\la ss ~ II~
~ IKls10 IVIVI I FIGUfll-.9 I 20
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Nine Mile Point Unit 2 CESAR
- 9. Each service water pump discharge header pressure.
- 10. Each RHR heat exchanger service water return radiation level.
- 11. Each service water discharge loop radiation level. I
~'"
- 12. Service water return temperature from each component (IOCAI.).
22
- 13. Service water discharge pH and conductivity (EOCAL).
Recorders are provided for:
Each RHR heat exchanger service water return radiation level (Section 11.5.1.1.1, Item 5).
- 2. Each service water discharge loop radiation level (Section 11.5.1.1.1, Item 6).
Alarms are provided for:
- 1. Service water system inoperable.
- 2. Service water pumps suction pressure low.
- 3. Service water pumps autostart.
- 4. Service water pumps motor/pump bearing temperature high.
- 5. Service water pumps auto trip/fail to start.
- 6. Service water pumps discharge flow low.
- 7. Service water pump discharge headers pressure low.
- 8. Spent fuel pool makeup valve not closed.
- 9. Service water to TBCJ.CW heat exchangers pressure low.
- 10. Service water to RBCICW heat exchangers pressure low.
22
~
Amendment 22 9.2 -9 November 1985
Nine Mile Point Unit 2 FSAR TABLE 9.2-1A DIVISION I COMPONENTS REQUIRED SERVICE WATER FLOWS (GPM)
ASSUMING COMPLETE FAILURE OF DIVISION II I
Equipment Identification LOCA IIt Number Division LOCA<1) LOOP Shutdown<1) LOOP NOTES Reactor Bui ldin 2HVR*UC401A 29 29 <4),<7) 2HVR*UC4018 (4),(7) 2HVR*UC401C 0 0 <4),(7) 2HVR*UC401D (4),(7) 2HVR'UC401E <4),<7) 2HVR*UC401F (4),(7) 2HVRAUC402A 54 54 54 (5) 2HVR*UC402B (5) 2HVR*UC403A 77 77 77 77 (5) 2HVR*UC4038 (5) 2HVR*UC404A 21 21 21 21 2HVR*UC4048 21 21 21 21 2HVR*UC404C 2HVR*UC404D 2HVR*UC405 ~
13 13 13 13 2HVR*UC406 2HVR*UC407A 16 16 16 16 1934G Page 1 of 6
Nine Mile Point Unit 2 FSAR TABLE 9.2-1A (Cont'd)
DIVISION I COMPONENTS REQUIRED SERVICE HATER FLOSS (GPM)
ASSUMING COMPLETE FAILURE OF DIVISION II Equipment Identification LOCA E(
Number Division LOCA(1) LOOP Shutdown(1) LOOP iXOTES Reactor Bui ldin (Cont'd) 2HVRAUC407B 16 16 16 16 2HVR*UC407C 16 16 16 16 2HVR*UC407D 2HVR~UC407E 2HVR*UC408A 29 29 29 29 (5) 2HVR*UC4088 (5) 2HVR*UC409A 0 2HVR*UC409B 2HVR*UC410A 16 16 16 16 2HVR*UC410B 2HVR*UC410C 2HVR*UC411A 21 21 21 21 2HVR*UC411B 0 2HVR*UC411C 2HVR*UC412A 21 21 21 21 2HVR*UC412B 2HVR*UC413A 350 350 0 (5) 1934G Page 2 of 6
Nine Mile Point Unit 2 FSAR TABLE 9.2-1A (Cont'd)
DIVISION I COMPONENTS REQUIRED SERVICE WATER FLOWS (GPM)
ASSUMING COMPLETE FAILURE OF DIVISION II Equipment Identification LOCA 5 Number Division LOCA(l) LOOP Shutdown(1) NOTES Reactor Buildin (Cont'd) 2HVR*UC413B 0 0 0 (5) 2HVR*UC414A I 26 26 26 26 (5) 2HVR UC414B II 0 0 0 (5) 2HVR*UC415A I 20 20 20 20 (5) 2HVR*UC415B II 0 0 0 0 (5) 2RHS*ElA I 7 400 7 400 7 400 4pp(2) 2RHS*E18 0 0 0 2RHS*PlA 20(3) 20(3) 20(3) 2p(3) 2RHS*P1B II 0 0 0 2RHS~PlC II 0 0 0 0 2SFC*E1A I 2,410 2,410 2,410 41 0( 3) (5) 2SFC*E18 (5) 2HCS*RBNR1A 10 10 2HCS*RBNRlB 1934G Page 3 of 6
Nine Mile Point Unit 2 FSAR TABLE 9.2-1A (Cont'd)
DIVISION I COMPONENTS REQUIRED SERVICE HATER FLOHS <GPM)
ASSUMING COMPLETE FAILURE OF DIVISION II Equipment Identification LOCA 5 Number Division LOCA<1) LOOP Shutdown<1) LOOP NOTES Control Buildin 2HVK*CHL1A 340 340 340 340 (5) 2HVK*CHLlB (5) 2HVC~UC101A 29 29 29 29 2HVC*UC101B 2HVC*UC102 2HVC*UC103A 2HVC*UC103B 2HVC4104 29 29 29 29 2HVC*105 2HVC~106 52 52 52 52 2HVC*107 2HVC*108A 50 50 50 50 2HVC+108B Di e s e 1 Generator Bui di n 1
2EGS*EG1 800 800 '0 800 ZEGS*EG2 600 600 600 1934G Page 4 of 6
Nine Mile Point Unit 2 FSAR TABLE 9.2-1A (Cont'd)
DIVISION I COMPONENTS REQUIRED SERVICE WATER FLOWS (GPM)
ASSUMING COMPLETE FAILURE OF DIVISION II Equi pmen t Identi f i cation LOCA 5 Number Division LOCA(1) LOOP Shutdown(1) LOOP NOTES Diesel Generator Buildin (Cont'd) 2EGS*EG3 2HVP*UC1A 2HVP*UC18 2HVP*UC2 Screenwell Buildin 2HVY UC2A 85 85 85 85 (6) 2HVY*UC2B (6) 2HVY*UC2C (6) 2HVY*UC20 (6)
TOTAL FLOW (GPM) 1934G Page 5 of 6
Nine Mile Point Unit 2 FSAR TABLE 9.2-1A (Cont'd)
DIVISION I COMPONENTS REQUIRED SERVICE WATER FLOWS (GPM)
ASSUMING COMPLETE FAILURE OF DIVISION II NOTES:
Manual isolation of divisions and non-safety related equipment is assumed.
(2) Flow required after manual initiation.
(3) Flow required after manual initiation when cooling water from RBCLCW is unavailable; no sooner than seven hours into event.
(4) Only three of six components in operation.
(5) Only one of two components in operation.
(6) Only two of four components in operation.
(7) Backup loop *normally valved out.. No automatic initiation of backup divisional components.
KEY:
HVR Reactor building unit coolers RHS Residual heat removal heat exchangers and pumps SFC - Spent fuel pool cooling heat exchangers HCS DBA hydrogen recombiners HVK - Control building chilled water chillers HVC Control building unit coolers EGS Diesel generator coolers HVP Diesel generator control room unit coolers HVY Service water pump room unit coolers 1934G Page 6 of 6
0' Nine Mile Point Unit 2 FSAR Table 9.2-18 DIVISION II COMPONENTS REQUIRED SERVICE WATER FLOWS (GPM)
ASSUMING COMPLETE FAILURE OF DIVISION I Equipment Identification LOCA 5 Number Division LOCA<i) LOOP Shutdown(i) LOOP NOTES Reactor Buildin 2HVR*UC401A (4),(7) 2HVR*UC4018 29 29 29 29 (4),(7) 2HVR*UC401C 29 29 29 (4),<7) 2HVR*UC401D (4), <7) 2HVR*UC401E 0 (4),(7) 2HVR*UC401F (4),(7) 2HVR*UC402A (5) 2HVR*UC4028 (5) 2HVR*UC403A (5) 2HVR*UC4038 77 77 77 77 (5) 2HVR*UC404A 2HVR*UC4048 2HVR*UC404C 21 21 2HVR*UC404D 21 21 21 21 2HVR*UC405 .
2HVR*UC406 13 13 13 13 2HVR*UC407A 0 2HVR*UC4078 0 1934G Page 1 of 5
Nine Mile Point Unit 2 FSAR Table 9.2-18 (Cont'd)
DIVISION II COMPONENTS REQUIRED SERVICE HATER FLOHS (GPM)
ASSUMING COMPLETE FAILURE OF DIVISION I Equipment Identification LOCA &
Number Division LOCA(1) LOOP Shutdown(1) LOOP NOTES Reactor Buildin (Cont'd) 2HVR*UC407C 0 0 2HVR*UC407D 16 16 16 16 2HVR*UC407E 16 16 16 16 2HVR*UC408A 0 0 (5) 2HVR*UC4088 0 0 0 0 ~ (5) 2HVR*UC409A 29 29 29 29 2HVR*UC4098 0 0 2HVR*UC410A 0 0 2HVR*UC4108 16 16 16 16 2HVR*UC410C 16 16 16 16 2HVR*UC411A 0 0 2HVR*UC4118 21 21 21 21 2HVR'UC411C 21 . 21 21 21 2HVR*UC412A 0 0 2HVR*UC4128 21 21 21 21 2HVR'UC413A 0 0 (5) 2HVR*UC4138 350 350 (5) 2HVR*UC414A 0 0 (5) 1934G Page 2 of 5
Nine Mile Point Unit 2 FSAR Table 9.2-18 (Cont'd)
DIVISION II COMPONENTS REQUIRED SERVICE WATER FLOWS (GPM)
ASSUMING COMPLETE FAILURE OF DIVISION I Equipment Identification LOCA E(
Number Division LOCA(1) LOOP Shutdown(i) LOOP NOTES Reactor Bui ldin (Cont'd) 2HVR*UC4148 26 26 26 26 (5) 2HVR*UC415A I 0 0 (5) 2HVR*UC4158 II 20 20 20 20 (5)
ZRHS*E1A I 0 0 0 0 2RHS*E18 II 7 400(2) 7 40()(2) 7 ~
40()(2) 7 400( )
2RHS*PlA 0 0 0 0 2RHS*P18 20(3) 20(3) 20(3) 20(3) 2RHS*plC 20(3) 20(3) 20(3) 20(3) 2SFC*E1A I 0 0 0 0 (5) 2SFC*E18 II 2,410 2,410 2,410 2,410 (5) 2HCS*RBNR1A 2HCS*RBNR18 10 10 Control Bui din 1
2HVK'CHL1A (5) 2HVK+CHL18 340 340 340 340 (5) 2HVC*UC101A 1934G Page 3 of 5
Nine Mile Point Unit 2 FSAR Table 9.2-1B <Cont'd)
DIVISION -II COMPONENTS REQUIRED SERVICE HATER FLOWS <GPM)
ASSUMING COMPLETE FAILURE OF DIVISION I Equipment Identification LOCA 5 Number Division LOCA<i) LOOP Shutdown<i) LOOP NOTES Control Buildin <Cont'd) 2HVC"UC101B 29 29 29 29 2HVC*UC102 19 19 19 2HVC*UCI03A 2HVC*UC103B 2HVC*104 2HVC*105 13 13 13 13 2HVC*106 I 2HVC*107 II 52 52 52 52 2HVC~108A 2HVC*108B 50 50 50 50 Diesel Generator Bui din 1
2EGS*EG1 2EGS*EG2 600 600 600 2EGS*EG3 800 800 800 2HVP*UC1A 2HVP*UC1B 2HVP*UC2 1934G Page 4 of 5
1 Nine Mile Point Unit 2 FSAR Table 9.2-1B (Cont'd)
DIVISION II COMPONENTS REQUIRED SERVICE WATER FLOWS (GPM)
ASSUMING COMPLETE FAILURE OF DIVISION I Equipment Identification LOCA E(
Number Division LOCA<1) LOOP Shutdown<1) LOOP NOTES Screenwell Buildin 2HVY*UC2A (6) 2HVY*UC28 85 85 85 85 (6) 2HVY'UC2C (6) 2HVY*UC2D (6)
TOTAL FLOW (GPM)
NOTES:
Manual isolation of divisions and non-safety related equipment is assumed.
(2) Flow required after manual initiation.
(3) Flow required after manual initiation when cooling water from RBCLCW is unavailable; no sooner than seven hours into event.
(4) Only three of six components in operation.
(5) Only one of two components in operation.
(6) Only two of four components in operation.
(7) Backup loop normally valved out. No automatic initiation of Backup Div isional Components.
KEY:
I HVR - Reactor building unit coolers RHS Residual heat removal heat exchangers and pumps SFC - Spent fuel pool cooling heat exchangers =
HCS DBA hydrogen recombiners HVK - Control building chilled water chillers HVC Control building unit coolers EGS Diesel generator coolers HVP Diesel generator control room unit coolers HVY Service water pump room unit coolers 1934G Page 5 of 5
Nine Mile Point Unit 2 FSAR TABLE 9.2-2 NONESSENTIAL COMPONENTS COOLED BY THE SERVICE WATER (SWP) SYSTEM Identi cation Flow/Uni t Total Flo Numbe m m Reactor Bui in NotesCCP-EIA-C 5, 834 11, 688 2HVR-CLC2 400 400 Turbine Buildin 2CCS-EIA-C 8, 760 17,520 2ARC-EIA,B 300 300 23 2ARC-E2A,B 1,900 1,900 2CNA-DCL1 0 190 2HVT-UC201A,B 5 116 2HVT-UC202A,B 58 116, 2HVT-UC203A,B 58 116 2HVT-UC204 32 32 2HVT-UC205 32 32 2HVT-UC206A-F 64 384 2HVT-UC207A,B 5 116 2HVT-UC208A,B 5 106 2HVT-UC209A,B 9 98 2HVT-UC210A, B 49 98 2HVT-UC211 32 32 2HVT-UC212A,B 53 106 2HVT-UC213A,B 53 106 2HVT-UC214A, B 53 06 2HVT-UC215A,B 53 1 6 2HVT-UC216A-E 65 32 2HVT-UC217A,B 43 86 2HVT-UC218A-E 65 325 2HVT-UC219 32 32 2HVT-UC220 25 25 2HVT-UC221A,B 53 106 2HVT-UC222A-F 49 294 2HVT-UC223A, 53 106 Amendment 23 1 of 2 December 1985
Nine Mile Point Unit 2 FSAR Table 9.2-2 SERVICE HATER FLOH REQUIREMENTS FOR NORMAL POHER GENERATION Equipment Identification Number Division Flow (GPM)
Essential Com onent Flows Reactor Buildin 2HVR*UC401A 29 2HVR*UC401B 29 2HVR*UC401C 29 2HVR*UC401D 2HVR*UC401E 2HVR*UC401F 2HVR*UC402A 54 2HVR*UC402B 2HVR*UC403A 77 2HVR*UC403B 77 2HVR*UC404A 21 ZHVR*UC404B 21 2HVR*UC404C 21 2HVR*UC404D 21 2HVR UC405 13 2HVR*UC406 13 2HVR*UC407A 16 2HVR*UC4078 16 2HVR*UC407C 16 1934G Page 1 of 9
Nine Mile Point Unit 2 FSAR Table 9.2-2 SERVICE WATER FLOW REQUIREMENTS FOR NORMAL POWER GENERATION Equipment Identification Number Oivision Flow (GPM)
Reactor Buildin (Cont'd) 2HVR*UC4070 16 2HVR*UC407E 16 2HVR*UC408A 29 2HVR*UC4088 2HVR*UC409A 29 2HVR*UC4098 2HVR*UC410A 16 2HVR*UC4108 16 2HVR*UC410C 16 2HVR*UC411A 21 2HVR'UC4118 21 2HVR*UC411C 21 2HVR*UC412A 21 2HVR*UC4128 21 2HVR*UC413A 2HVR*UC4138 2HVR*UC414A 26 2HVR*UC4148 1934G Page 2 of 9
Nine Mile Point Unit 2 FSAR
'able 9.2-2 SERVICE HATER FLON REQUIREMENTS FOR NORMAL PONER GENERATION Equipment Identification Number Oivision Flow (GPM)
Reactor Buildin (Cont'd) 2HVR*UC415A 20 2HVR*UC4158 2RHS*E1A 2RHS'E18 2RHS*plA 2RHS*P18 2RHS*plc 2SFC*E1A 2SFC*E18 2HCS*RBNR1A 2HCS*RBNR18 Control Buildin 2HVK*CHL1A 340, 2HVK*CHL18 2HVC*UC101A 29 2HVC*UC1018 29 2HVC'UC102 19 1934G Page 3 of 9
Nine Mile Point Unit 2 FSAR Table 9.2-2 SERVICE WATER FLOW REQUIREMENTS FOR NORMAL POWER GENERATION Equipment Identification Number Division (Cont'd) Flow (GPM)
Control Bui din 1
2HVC*UC103A 2HVC*UC103B 2HVC*104 29 2HVC*105 13 2HVC*106 52 2HVC4107 52 2HVC*108A 50 2HVC*108B 50 Diesel Generator Buildin 2EGS EG1 2EGS*EG2 2EGS*EG3 2HVP*UC1A 2HVP*UClB 2HVPAUC2 0 1934G Page 4 of 9
Nine Mile Point Unit 2 FSAR Table 9.2-2 SERVICE WATER FLOW REQUIREMENTS FOR NORMAL POWER GENERATION Equipment Identification Number Division Flow (GPM)
Screenwell Buildin 2HVY'UC2A 85 2HVYAUC28 85 2HVY'UC2C 2HVY*UC20 Total Essential Flow 1,597 Non-Essential Com onent Flows Reactor Bui ldin 2CCP-E1A (1) 5,834 2CCP-E18 <1) 5,834 2CCP-Elc (1) 0 2HVR-CLC2 400 Turbine Buildin 2CCS-E1A (1) 8,760 2CCS-E18 (1) 8,760 2CCS-Elc (1) 0 2ARC-E1A (2) 300 2ARC-E18 <2) 0 1934G Page 5 of 9
Nine Mile Point Unit 2 FSAR Table 9.2-2 SERVICE WATER FLOW REQUIREMENTS FOR NORMAL POWER GENERATION Equipment Identification Number Division Flow (GPM)
Turbine Buildin (Cont'd) 2ARC-E2A (2) 1,900 2ARC-E2B (2) 2HVT-UC201A 58 2HVT-UC2018 58 2HVT-UC202A 58 2HVT-UC202B 58 2HVT-UC203A 58 2HVT-UC203B 58 2HVT-UC204 32 2HVT-UC205 32 2HVT-UC206A 64 2HVT-UC206B 64 2HVT-UC206C 64 2HVT-UC206D 64 2HVT-UC206E 64 2HVT-UC206F 64
=2HVT-UC207A 58 2HVT-UC207B 58 2HVT-UC208A ,53 2HVT-UC208B 53 1934G Page 6 of 9
Nine Mile Point Unit 2 FSAR Table 9.2-2 SERVICE WATER FLOW REQUIREMENTS FOR NORMAL POWER GENERATION Equipment Identification Number 01 v i sion Flow (GPM)
Turbine Bui ldin (Cont'd) 2HVT-UC209A 49 2HVT-UC2098 49 2HVT-UC210A 49 2HVT-UC2108 49 2HVT-UC211 32 2HVT-UC212A 53 2HVT-UC2128 53 2HVT-UC213A 53 2HVT-UC2138 53 2HVT-UC214A 53 2HVT-UC2148 53 2HVT-UC215A 53 2HVT-UC2158 53 2HVT-UC216A 2HVT-UC2168 65 2HVT-UC216C 65 2HVT-UC2160 65 2HVT-UC216E 65 2HVT-UC217A 43 1934G Page 7 of 9
Nine Mile Point Unit 2 FSAR Table 9.2-2 SERVICE WATER FLOW REQUIREMENTS FOR NORMAL POWER GENERATION Eguipment Identification Number Division Flow (GPM)
Turbine Buildin (Cont'd) 2HVT-UC217B 43 2HVT-UC218A 65 2HVT-UC2188 65 2HVT-UC218C 65 2HVT-UC218D 65 2HVT-UC218E 65 ZHVT-UC219 .32 2HVT-UC220 25 2HVT-UC221A 53 2HVT-UC221B 53 2HVT-UC222A 47 2HVT-UC222B 47 2HVT-UC222C 47 2HVT-UC222D 49 2HVT-UC222E 49 2HVT-UC222F 49 2HVT-UC223A 53 2HVT-UC223B 53 2HVT-UC224 42 1934G Page 8 of 9
Nine Mile Point Unit 2 FSAR Table 9.2-2 SERVICE WATER FLOW REQUIREMENTS FOR NORMAL POWER GENERATION Equipment Identification Number Division Flow (GPM)
Turbine Buildin (Cont'd) 2HVT-UC225 42 2HVT-UC226 53 TOTAL NON ESSENTIAL FLOW 34,888 ESSENTIAL 5 NON ESSENTIAL TOTAL 36,485 NOTES'nly two of three components in operation.
Only one of two components 1n operation.
KEY:
HVR - Reactor building un1t coolers RHS Residual heat removal heat exchangers and pumps SFC Spent fuel pool cooling heat exchangers HCS - DBA hydrogen recombiners HVK Control building chilled water chillers HVC Control building unit coolers EGS Diesel generator coolers HVP Diesel generator control room unit coolers HVY Service water pump room unit coolers CCP Reactor bu1lding component cooling water heat exchangers CCS Turbine building component cooling water heat exchangers ARC Vacuum pump seal water coolers and steam jet air ejector precoolers HVT - Turbine building unit coolers 1934G Page 9 of 9
Nine Nile Point Unit 2 FSAR TABLE 9.2-3 DESIGN DATA OF CONPONENTS SUPPLIED WITH REACTOR BUIIDING CLOSED LOOP COOLING WATER Total Heat Flow Transferred at Require- 95 F SWS Inlet Quan- Node of ments Temperature )z3
~ti t ~~m Spent fuel pool dent,~'otal Normal/ 2, 410 15.0 heat exchangers acci-RWCU nonregen- Normal 1, 410 38 56
~
erative heat exchagner RWCU pump bear- 2 Normal 110 0.82 ings, coolers, pedestals, and seal jackets Reactor building 2 Normal 210 1. 08 equipment drain coolers Drywell equipment 1 Normal 105 drain cooler Drywell unit space 9 Normal 1,295 6.3 coolers Reactor recircula- 2 Normal/ 4.73 tion motor winding coolers, motor dent'~'50 acci-bearing coolers, and pump seal coolers Instrument air 3 Normal 90 1.3 compressor' ntercoolers, aftercoolers, and jackets pe%e ADS air compressor 1 Shutdown 10 0.01 Amendment 23 1 of 2 December 1985.
Nine Mile Point Unit 2 FSAR The automatic depressurization system is safety-related, and all pressure-retaining components of the system are designed, constructed, and inspected in accordance with the applicable requirements of ASME Section III, Division 1, Subsection ND for Class 3 components, and Subsection NC for Class 2 components. Not included in this safety-related classification are the nitrogen gas storage tanks, equipment, and components located in the yard outside the reactor building.
Piping segments that penetrate the primary containment and serve as a containment boundary are designed to Safety Class 2, Category I requirements.
The loss of nitrogen gas for instrumentation and controls causes gas-operated valves to fail to appropriate safe positions. In the event that the nitrogen gas supply from the nitrogen gas storage tanks is lost, a 5-day supply is available to the accumulators from ADS nitrogen receiver tanks 2IAS*TK4(Z-) and 2IAS*TKS(Z-). In addition, there are provisions for recharging the ADS nitrogen receiver tanks through its individual supply lines located in a missile-protected area outside the standby gas treatment building from special emergency tube trailer supply connections.
These special, emergency rech'arging lines are part of the
~ GSN system and are classified Seismic Category I, Safety Class 3.
Power Generation Bases
+~pros The automatic depressurizatio system requires clean, dry, oilfree nitrogen gas at. 72 psxg to be supplied to the selected group of seven main steam safety relief valves and their respective accumulators located inside the reactor primary containment. This designated group of ADS safety relief valves and accumulators is divided into two subgroups with three or four valves and accumulators in each subgroup.
Each subgroup is supplied with nitrogen gas from one of two separate ADS receiver tanks. Each ADS receiver tank is supplied with nitrogen gas at 365 psig from a bank of six horizontal, high-pressure nitrogen gas storage tanks located outside the reactor building. Nitrogen gas supplied for instrumentation and controls meets or exceeds the equivalent air quality requirements established for safety-related control air systems (SRCAS) by ANSI MC11.1-1975 (approved January 15, 1976) (ISA-S7.3), Quality Standard for Instrument Air.
All piping, valves, and fittings associated with the automatic depressurization system are of stainless steel materials. Also, the system wi'll be given a complete Amendment 23 ~ 9.3.-11 December 1985
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per formanc e. The svs=em unct J,OL as 1 0 a r W<
event exce pt tha" the pro" Dsc luid 's demineralized wa"er cvO~ t'4e ystem test tank.
Operational testing of =he SLC sys em ' pe ormed 'n at.
'east two parts to avo c .".ad;e"ten"ly 'njec" ng b "".". 'n=o tne rea"tor. With tne valves to the reactor and - ro' the s"o acre tank closed and he valves to and f om the s" tank opened, deminerali ed wa=er in the test tank car. be recirculated by ocall sta" ing either pump~ Th's t s= can be accomplisned with tne reacto operating without af:ecting the operability of the other pump. During a refueling or maintenance outage, the injection portion of the system can be func"ionally tested by valving the suction line to the t;est tank and actuating tne system from the main control room. System operation is indicated in the main c "rol room. vigil J zing 1(e,yICJ.IJ. ~ c~ tc.be fl e, JvlaJn ccnrrc I r ocrA ~
After functional tests, the injection valve shear plugs and explosive charges are replaced and al'he valves returned to their normal positions as indicated in Figure 9.3-17.
After closing a local locked-open valve to the reactor, le.rkage through outboard isolation valves or the injec" ion valves can be detected by opening valves at a test connection in the line between the containment isolation valves. Position indicator lights in the main control room indicate that the local valve is closed for tests or open and ready for operation. Leakage from the reactor through the inboard isolation valve can be detected by opening the same test connection in the line between the isolation valves when the reactor is pressurized.
The test tank contains demineralized water for approximately 3 min of single pump operation. Demineralized water from the make-up water system is available for refilling or flushing the system.
Shou'ld the boron solution ever be injected into the reactor, either intentionall'y or inadvertently, the operator verifies that the normal reactivity controls are adequate to keep the reactor subcritical, and then removes the boron from the reactor coolant system by initially flushing for gross dilution followed by operating the reactor water cleanup system. There is practically no effect on reactor operations when the boron concentration has been reduced Amendment, 18 9.3-35 March 1985
Nine Mile Point Unit 2 FSAR energizing, or automatically trips, a heater when the associated supply air flow is low.
The relay room smoke removal damper is controlled manually.
Interlocks prevent opening, or automatically trip closed, the damper when either relay room 'air conditioning unit fan is running.
The computer room supply air fans are controlled manuall and locally. Interlocks prevent starting or automaticall trip) a fan when moke is detected zn e com uter room he Halon system discharge is znxtiate , or both computer room air conditioning units are stopped. The computer room air conditioning units stop automatically when the Halon system discharge is initiated.
The computer room smoke removal dampers are controlled manually. Interlocks prevent opening, or automatically trip closed, the dampers when the Halon system discharge is initiated.
The remote shutdown room air conditioning units are controlled locally. Each unit is controlled automatically by the associated remote shutdown room space temperature.
Interlocks prevent'tarting, or automatically trip, a unit when the associated control building chilled water circulation pump is not running. The units can also be controlled manually.
Monitorin Indicators are provided for each relay room air conditioning return air temperature.
Alarms are provided for:
Relay room ventilation system trouble.
- 2. Relay room ventilation system inoperable.
- 3. Relay room air c"."." "ioning units auto s"art and auto trip/fail to start.
Computer room ventilation system trouble.
Remote shutdown room ventilation system inoperable.
Amendment 24 9.4-14 February 1986
Nine Mile Point Unit 2 FSAR fans can also be controlled manually. The associated inlet and outlet dampers open or close automatically when the as-sociated fan is running or not running, respectively. The dampers can also be controlled manually.
9.4.4.5i3 Monitoring Q.RT'e arate normal and post-accident indicators are provided for:
Main stack gaseous radiation, ow range.
- 2. Main stack gaseous radiation, high range.
Main stack particulate radiation, low range.
>S Main stack exhaust flow rate, ow range.
Main stack exhaust flow rate, high range.
eparate normal and post-accident records are provided for:
Main stack gaseous radiation, low range.
- 2. Main stack gaseous radiation, high range.
- 3. Main stack particulate radiation, low range.
Main stack exhaust flows, low range.
- 5. Main stack exhaust flow, high range.
Main stack exhaust flow rate.
Alarms are provided for:
- l. Turbine building ventilation system trouble.
- 2. Turbine building ventilation elevator machine rooms smoke detected.
- 3. Turbine building ventilation supply air smoke detected.
- 4. Turbine building area radiation monitor activated.
- 5. Process airborne radiation monitor activated, 6 Effluent gaseous radiation monitor activated
, In+.nab ck. Ack~ak~g 9.4-44
Nine Mile Point Unit 2 FSAR
- 7. Effluent articulate radiation monitor activated.
.9.4.5 Service Building Heating and Ventilating System The service building heating and ventilating system, shown schematically in Figure 9.4-2, serves the following areas:
- 1. Service room, foam room, and entrance corridor.
- 2. Access passageway.
- 3. Service water valve pit.
Design data of principal equipment utilized in the system are listed in Table 9.4-6.
9.4.5.1 Design Bases The design bases for the system are:
To provide an environment that ensures habitability of the areas served, consistent with personnel comfort and optimum performance of equipthent, within the temperature limits shown in Table 9.4-1.
- 2. The system is "designed to nonnuclear safety standards and is not required for safe shutdown of the plant.
r per~+.seWg,. QU< Q Qelqhblimi 4 kionS kr n~4Aakion oC 'tr'e ev; 0 bo.r or~, M~ 4 c" c~m Sc; d~C: e6 ~s, UL raW4 Q. sern'laLes UL ra4eck .Q(o.s> 3+ega<~ QdcWo,peg ~ y '3Qg bine bile Poiat bait 1 PSap 'TabLt 9a 3-17 cohpaRIsos btyvtts OL-Labtl.to cLass a Doobs abD obIT 2 bostabtLto sptcIaL pobposb books RfiKtot 5i@, OL-Labeled 3-hr Door ROF Roe 83658 Special Pur ose ~ t tight) Spec al >>urpose Doors pecial Purpose Door gb l&abaJJhll()" ((aUlL D() 85 h%%8%2L 1 or coaposite construct(os - 1 3/8>> thick 1/a" soli4 steel plate Cosposi't ~ construction Coaposite coastructioa-nstruct ion 16 gauge cover sheets with 1 5/8>> thick 1 7/8>> thick 2-3/16" cover 6 1/a" thick, 11 gauge cover ~ iaeral wool insulation aa4 20 SLeets oC a36 with 1 1/2" sheets with 6>> thick fiberglass qauqe Reiatorciag SFES (6" O.C.) tLick fiber9lass insulatioa insulatioa aa4 C6 x 8.2 a36 steel aad 1 1/2 x 9/16 x 3/16" channels ia the skeleton and bar chaaaefs all around the a roun4 the periphery of 'the periphery ot the 4oors door>> .Ick bolts hortised lock or latch sets vith Six 1 1/a>> square CP1018 steel Tvo 1>> lock bolts, asth a1219 Tvo 1 1/2>> 4(sauter lockiag oae single point spriag-actuated bolts with a 2 1/2" tbrovl two at OSSO1215 steel - ~ in. tea(bio Pion aISI CP1018 steel with bolt, (5/8" x 1>>) ~ aotched Cor nyloa ~ acL jaab aad oae each at head aa4 76 ksi< 1>> tbrov Latch Cour 1/2" dlaaeter aSTO aa90 inserts (5/8>> or 3/a" throv) sill bolt hoasiags oC strike sade ot super ollite hex bolts oa aoaating brackets, 3>>xa 3/a"x1" a36 steel stock at operating teaperature oC one each at bead and sill up to 2004P bushings on the lock are broaxe ia ~ xcess ot 50 'ksi '. (nues 1 1/2 or 2 pairs of a 1/2"xa 1/2"x0.180" 2 Liaqes with 1" diaaeter Two heavy duty hinge aneablies, Six hinges with 2" diaaeter steel bell beariag butt biaqes - with 1/a>> pia and thrust bearing, vel4ed welde4 to the door Crane pia and thrust bearing welded to or 5/16" piss with bolts to structural steel angle tress ~ ad secured to the 4oors the structural steel aaqle Crane. )rane la gauqe pressed steel Crane with a36 steel aa9les tor sill, Lead, 636 steel channels three sides with bar stops veld a36 welde4 steel angles aad plates Cor jaabs to tbe esbedde4 plates in t'Le 44 adjustable anchors aad jaabs welded together aad stiffened with gasset plates, to tbe channels to preveat u require4. Claae propagation I le id Pressed steel Crane anchored to vali a-36 steel angle Crass Chanael traae iateraitteat a36 steel franc iateraitteat fillet i natallat ion with 1 ~ gauge a4jwstable jasb anchors continuously Cillet welded to welded to the existiaq wel444 to existinq esbedded franc at 2~ ia O.C exis'ting aabedded traae. ~ sbedde4 Crane nendaeat 26 hay 1986 0 0 @ere eic.r= /'an i OWd 2 F5a< C I P(84m 9'8, 3 -(0 l1 O I A co< AR(ge4'c'wEE'A'g - llsN eo cL8as 8 oops IHO uu(r 4 >wlrf8EAeo ~((Eo.(az Age'~ o os II I% l O sPmgz, AA%>z Anal 5P~5l fn((( anoR5 W 5P~Rl I'uRPosE DooA5 R l% A O (R R RIR'Tsuf ER/EDDAS) (4'VERS IZEO EavItmun) CAE5SoRE 7/SVT) Oooo. CcofsrR.MTlaV ~ Sava sTFEL P&9f6 Con(Posts c.ouzytvcriou 3 i( TSI<K 4f(TH /8 ~icy, Co VEE. sHEEr eVEC 3" ~ l& X /I4 cANNHEl- s 3 7AicK AhluEbol hJool /pJ S M4 )AT(oA/ I P oc,g BQLT5 lif gidhET~R Cf !pig w~>~g saute cata@ A 4A SWAN(- i(.ocK(a(6 84s i'll gh~ PiA(p sr'<chug a7A4e . A~c.c 8opr a'cellars nX O op e(V xh $ -3csf'cckhd5+ H A 'W A I 7'(P(Gent 4f(ik I 4L 0(hhzfCX ~li/o ~(R(<F5 Q/(Tr( l l4 r A O P(g wuo T((E(RSr sceeu+ O>(in ET'. Cg ((4E('r<a~ O WELPEP TO S7ZVCfuC8L SROL P<<vs lid'coEO To 5'(i<<~E- IO rO Becca I-ban~ Sneg. @em ~laillE lg AAIGZE g X(I'g 0 I-OI- S(~g HERO rfuo Za~((S 8ogreo ANo RHGlt. S'AB Sh Coi ((ENEMY Srir~ hlsznap ro ~~(-'O . ((HO J(liEBS Q(iH C P 'P.l gk/i ra /Agan(,S cd@SEg Doog sidP> O R O f(EID (usia((bio(( STeSL &fCrlK F(.'d((l(= II +g$ 'fg 7 a Ejm8Eoosg 5Rxg Bu6l6 FRRI((E IteAoxcjp O C RPl@lE 4hlg sACQ kfQ.0Ed ro Cc(ucZETE: H(W'~ " Rl 4 ~% V'0 EmaCOOEO AHGlG Oiil((lz rE L F P P8u S(ERR/ O a O +<&oR s t A llttttw +ILES Por~r upstr Z C E l VA,S-J Q M C waPBPISorrI 8E ~EEIrI tJl -AheECED CLAM 8 Gooses RN o AT 4 AOAllASELST<ac-DIChL lt'ari E iZrsgaeL STIFC&VEC5 AII1rp r E' KATEA/hL C'STIFFavEA5 I'l" ItuCC a'eer eu~+EZ ~a~~ I HE Pool. P<AwcrER., L g "Tctea Ft BE'Rt-Lllss ws cl1I TIDE lg M a~rS /a OemErH ao<< C LItTCII Pl.E'CTRIC,AQ.'1 o1r ~h TF;D M 4, 4 O eoLrs L~IZD W aoTP 4ll&f lst I'nIIIeltL 2 oc;g ? ll II SIDE'5 OF 7II6 Dook nX CI rr nX n 0a I.l tales< g Telo IIW6l5 XIIVI gj9LV8HI2ED HINGE 5 COHNEc< M I tt': n OidmerZL HutGE. PnI. Hlsr6a ed~ VERricau V g g. IDiar- ~I O I m Z t5 4/ELOPED To TH6 ooDR oooR sac.r ID% O C) z R R fll 5'rS ~T O O X S "8 3 'X ~le BIIGLE X 1'NGC.e Bo<TSO ? KELOID r o F-W8ELZtD re E geEOTDE'P Pl87E DAO ltthlGLa. Q+gCC, gfgDED 70 $ 7X<cs L 51'. Qolrlhtll aCI Ft ELD WS?Itllhrtoa 8-3t: SteeI. HIISLF I9ut" Ze SWTZO ro M COu7?II (I oII5LV RElOE'D pg pe 8KO O R CI M THE EMggOgED FANE CpfghfAlEg I RcsllER TAAcC, n R ~ f 8 cd.TED IO 1IIlGLF-M Cl O M 4 nO o O nI M ha h OIO I hhtIO h OOO h OIO ! I I hh OO O ON I ~ I ~IOe ~ hh h ON 'I h ~ h tli h ON IN'hh V O OON hh OO1 h Id ggg hh N4 ~ h tl 4 hh lh hit hh h IO 4 h <<(4 h Ih t ~ h ~ am~ Qg) Ih hit ~ h ON hhoN hlh a )aAf ~ h h hh<<hl ~ ~ C4 alh a e44 a nAf FIGURE QA3-3 FIRE PROTECTION ARRANGEMENT UNIT NO.2 STATION BUILOINGS PLAN EL 2I4'-0" 4 2I5'.0 NIAGARA MOHAWK POWER CORPORATION NINE MILE POINT-UNIT 2 FOAL SAFETY ANALYSIS REPORT gggf ~gL,Y C ggl CALCULATI OF THE EXPAN 0 WATERTIGHT DOORS D TO-IRE EXPOS D R NUMBERS: SA 175.3i SA 175-4; NA 175-2; R 175-4; R 5-5; R 175-7 AND C 239-1 OVE LL DOOR DIME IONS TOTAL DOOR/FRA GAP 31-5/8" 5" HORIZONTAL VERTICAL 0,875 1.250 438" X 87-7/ 0.875 1.250 THE FOLLOWING LCULATIONS VERIFY ATTHERE WOULD BE NO INTERFERENCE (C TACT FORCE) BET EN THE DOOR AND FRAME DURING A FIRE WHE A TEMPERATU RISE OF 1930'F (2000'F 70'F = 1930'F) IS EXPERIEN D BY THE D R. THE METHOD OF CALCUL TING E ANSION IS BASED ON THE LARGEST SIZE OF THE DOOR TIMES ET PERATURE RISE TIMES THE COEFFICIENT OF STEEL EXP ION (0.0000065) WIDTH OF DOOR = 38" T AL EARANCE = 0.875" LEARA E ON ONE SIDE OF DOOR) EXPANSION IN WIDTH 8 X 1930 X 0.0 0065 -"0.48 TE: 0.48" IS LESS AN 0.875" HEIGHT OF DOOR 7.875" TOTAL CLEAR CE = 1.250" (CLEARANCE 0 TOP AND BOTTOM OF DOOR) EXPANSION HEIGHT = 87.875 X 1930 X 0.0000065 = .1" NOTE: 1.1" IS LESS THAN 1.250"
CONC WALL EILBEO ANGLE HINGE NEOPRENE ma+ OOOR SEAL OR FRAllE STEEL OR l2 HANowlLEEL 4 s C STEEL COVER PAN ~ STEEl. OR OR FRAME LATCH BOLT FL DETAIL-A ELIBEO PI.ATE FL FL OETAll.- A E L E V AT 10N NEOPRENE SECTIONS d DETAILS HANOWHEEL OQOR SEAL HINGE OR FRAllE STEEL OR EiiBEO ANGLE e'n5-5~ $ ~ ggI75j-3 Rt7+~P to A gI7g-7,CZ ~g } FLORAL OR FRANE 3-l4 0 LATCH BOLT I- STEEL COV EA PAN CONC WALL WATS A HT OQPRS ASSEMBLY 2-2 NIAGARA MOHAWK POWER CORPORATE LPH NINE MILE POINT UNIT 2 SAP t: I Y ANAL Y 'LS AEPQll l CALCULATION THE EXP ION OF RADIATION IELDING DOORS DUE TO FIRE EXPOSU DOOR NUMBERS: 72 -20, 7277 217-277,-22 THE ABOVE LISTED RAD TION SHIELDINQOOORS ARE ARRANGED SUCH THAT THE DOOR PANELS VERLAP THEPOOR OPENINGS IN ALL DIRECTIONS. THIS ARRANG ENT ALLOWS DOORS TO EXPAND FREELY IN ALL DIRECTIONS WHEN SUB CTED TO HEAT ON ONE SIDE. THEREFORE, NO SIGNIFICANT, OEFORMATI OR WARPING OF DOORS CAN BE EXPECTED. FIGURE 9A.3-15 RADIATION SHIELD D ORS PAGE 2 OF 2 NIAGARA MOHAWK POWER CORP RATION NINE MILE POINT-UNIT 2 FINAL SAFETY ANALYSIS REPORT AMENDMENT21 SEPTEMBER 1985 CALCULATIONOF THE EXPANSION OF 3 PSI TORNADO DOORS DUE TO FIRE EXPOSURE DOOR NUMBERS: ET214-2, ET237-1, SW261 ~ 14, DG272-4 C288-1, C306-1, C261-1, R240-7, AB 261-3, NA240.1, R240-2. R240-3, SA240-1. SW280-1OTE: DOOR NO. R240-7 IS A PRESSURE TIGHT DOOR WHICH HAS FXPANSION CHARACTERISTICS SIMILAR TO THAT OF THE TORNADO DOORS DESCRIBED HEREIN) DOOR OVERALL DOOR DESCRIPTIOH DIMEHSIOHS TOTAL DOOR/ AME GAP HORI ~ R. 7OHTALyklCAL OIAQ. TO AOO 5 PRESSURE. 55 5/i"X$5-1/i" .50 1.12 TIGH SIHQLE I.EAF UTILITY. 55 2/2"XS9.1/IS" .50 1.15 1.2i SIHQLE L TORHADO, TI ~ I /2"X22-1/i" 1.12 1.2i DOUSLE LEAF THE FOLLOWING C LCULATIONS VERIF'PTHAT THERE WOULD BE NO APPRECIABLE INTE RENCE (CONST FORCE) BETWEEN THE DOOR AND FRAME DURING IRE WHERE 4 TEMPERATURE RISE OF 19304F (2000 'F 70'F = 19304 IS EXPEMNCED BY THE DOOR. THE METHOD OF CALCUI.A 6 gXPANSIONIS BASED ON THE SIZE OF 7 DOOR TIMES THE TEMPERAT E RISE TIMES THE COEFFICIENT OF ST L EXPANSION (0.0000065) HORIZONTALEXPANSION ORNA 0/PRESSURETIGHT, SINGLE LEAF AN UTILITY,SINGLE LEAF) X 1930' $ 8.50 X 10. ~ 'F. A4-IN. .p'5.75.IN. HORIZONTAL EXPAllSION (TORNADO,DO BLE LEAF) 71.5-IN. X 1930'.i X 6.50 X 10 ~ 'F' .87-VERTICAL EXP NSION (TORNADO,DOUBLE LE ) 83.25.IN. X 930' X d.so X 10 ~ 'F' 1.02-IN. VERTICA XPANSION (UTILITY.SINGLE LEAF) 59.44- . X 1930' X 6.50 X 10 ~ 'F' .73-IN. DIA NAL EXPANSION (TORNADO/PRESSURETIGHT, Sl GLE 4 DOUBLE LE, UTILITY,SINGI.E LEAF) 'F' 0.8 IN. X '1930' X d.50 X 10 ~ ~ 1.11 ~ IN. ~ DOOR NO. SW280.1 HAS HORIZONTALAND VERTICAL DOOR RAME GAP OF .32 AND.63 WHICH IS SUFFICIENT TO PERMIT EXPAN N FOR FIRE INVOLVINGTHE PRESENT FIRE LOAD. FIGURE 9A.3-16 TORNADO AND PRESSURE GHT DOORS PAGE 2 OF 2 NIAGARA MOHAWK POWER CORP RATION NINE MILE POINT-UNIT 2 FINAL SAFETY ANALYSIS REPORT AMENDMENT26 MAY 1986 ~ ~ -'4 s s Il I s EMBEO AHGLE 'ss DR FRAIIE II1I ss >'I ~ s sI s s sS .sI!. OR FRAIlE II sl Il II I II s II OOOR STOP /I OR FRAIlE II HINGE IIUSIHG Is ASSELIBLY STEEL OR sl II ~s l2 3-3 II I~ STEEL IVER PAH 4 000R EVBEO AII'LE F.s I II ~ II COVER OR FRAHE ~ ~ s s I PAH ' ss STEEL OB h ~ Is 3$ II rs II I ~ sI LOCKIHG BOLT OR FRAME ~ Os sI ASSEMBLY II I HIHGE ~ .. ".. ~ ~ COHC CllRB I OCK BOLTKEEPER FL L L. STEEL OR COVER PAH LOCKIHG bOLT E LEVATION L.'AOIA FIGURE BAN-15 ORS LEVER HAHOLE AGE I OF TYPICALSf CTIO ~p) Z0ygq+P) A/77 gg NINE MILE POINT-UNIT 2 FINAL SAFE IY ANALYSIS,HFPORI COHC-WALL. EI4 BED AHGLE OR FRAIIE OA FRAME HOLLOW STKELOR HEOPREHK SKAL LEVER HAlOLE H) LIOW STEELOR ALUM SAOOLK lOLIOW STEELOR: FL H INC E ~l ~ETAIL. A IHC BOLt 0 E TA I L.A FL I EL E VATIOH fhill-3,5QZSO-I y g >7-l,'SQz4l-HOLLOW LOCKIHC ALT be21ZH. -I czar i-I czs8-).cm STEEL OR LEVER HIHGE STEEL EMBEO AHGLE HAHOLE PLATE ' ~s C tN~O tie STEEL tHERMAL FIBERGLASS IHSUL PLAT K FIGURE 9A3-16 ~ oa STEEL CHAHHEL OOOA FRAME ~ ~~ J CONC ~ ~ , ~ WALL TORNA ~ ~
- DOOR -239-1 ONLY FIGURE 9A.3-14 WATERTIGHT DOORS PAGE 2 OF 2 NIAGARA MOHAWK POWER CORPORATI NINE MILE POINT-UNIT 2 FINAL SAFETY ANALYSIS REPORT AMENDMENT26 MAY 1986
~ I NINE MILE POINT-UNIT 2 FINAL SAFETY ANALYSIS REPORT AMENDMENT Pl CLClTI-~ ~ IICC1 ~ sa" L DOOR EMBEDDED FRAME ODOR FRAME 5lbJ /~ E 279-0 ~ ~ I I I I ISAAC TIVE ACTIVE HINGE HOUSING PANEL ASSEMBLY DQQR PANE L ~ e C I I 4,g DOOR PANEI. ~ ~ EL 26I-O t ~ ~ '4 ~ ~ ' 0 a ~ A! ~ c ~ % ~ ~ I ~ .C I CL LOCKING BOLT I AND KEEPER EMBEDDED EL EVATION DOOR PANEL FRAME DOOR (RR 26I-2) DOOR FRAME DOOR PANEL TYP) DETAIL A ~ ~ ~ ~ ~ DETAIL-A ~ 0 FIGURE 9A.3-1i 3(T YP) R BIGOI-'LD4 RAI ACCESS OOQR 2-2 RRK4 I-2 NIAGARA MOHAWK POWER CORPORATION NINE MILE POINT-UNIT 2 FOAL SAFETY ANALYSIS REPOR'I CALCULATIO OF THE EXPANSION OF RAIL AD ACCESS DOOR RR 281-2 DUE TO FIRE E OSURE. THE ABOVE MENTI ED RAILROAD A ESS DOOR IS ARRANGED SUCH THAT THE DOOR PA LS OVERLAP E DOOR OPENING. THIS ARRANGE-MENT ALLOWS DOOR EXPAND ALL DIRECTIONS WHEN SUBJECTED TO HEAT ON ONE SIDE, WEVE HE FREE MOVEMENTWILLBE LOCALLY RESTRAINED AT HINGE A CH LOCATIONS, BUT CAUSING NO .. SIGNIFICANT DEFORMATIO R WARPING OF DOOR WHICH COULD ALLOW FIRE PROPAGATIO FIGURE 9A.3-17 RAILROAD ACCESS OOO PAGE 2 OF 2 NIAGARA MOHAWK POWER CORPORA N NINE MILE POINT-UNIT 2 . FINAL SAFETY ANALYSIS REPORT AMENDMENT26 MAY 1986 Nine Mile Point Unit 2 FSAR TABLE 9B.6-1 FIRE AREA/FIRE SUBAREA/FIRE ZONE IDENTIFICATION Fire Fire Area Fi re Subarea Zone North Aux Bldg/FA1 201SW LFCS Room, North Auxiliary Bay, El 175 Ft 202SW RHS Pump Room A, North Auxiliary Bay, El 175 Ft 203SW RHS Heat Exchanger Room A, zii SaJ North Auxiliary Bay, Wo: 22.l Sw El 175 Ft P~~ Ph~qE.~ asia @DD EpA'-p OCSCplMahl) Reactor Bldg/FA2 Reactor Building, RCIC Pump Room, El 175 Ft South Aux Bldg/FA3 207SW RHS Pump Room B, South Auxiliary Bay, El 175 Ft-208SW RHS Pump Room C, South Auxiliary Bay, El 175 Ft 206SW RHS Heat Exchanger Room B, Reactor Bldg/FA4 Woo: l 3~04 NP South Auxiliary Bay, E 175 Ft . u SAcA'Peru Wo 4) Re ctor Building, HPCS ~ I PAq6> Room, El 175 Ft FAQ: 302NW Electrical Tunnel, 354 FAS 301NW Electrical Tunnel, 1404 0 6 l 1 Or4 S'tr Control Bldg/FA21 327NW Control Building, HPCS Cable Routing Area, El 244 Ft 342XL Control Bui lding, HPCS Svitchgear Room, El 261 Ft Diesel Gen'ldg/FA28 402SW Division I, Diesel Generator Room Division I, Diesel Generator Control Room Amendment ll 1 of 6 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.6-1 (Cont) Fire Fire Area Fire Subarea Zone FA29 403 SW Division II, Diesel Generator Room Division II, Diesel Generator Control Room FA30 404SW Division III, HPCS Diesel Generator Room Division III, HPCS Diesel Generator Control Room Control Bldg/FA75 339NZ Control Building, Division III, Battery Room, El. 261 Ft orth Auxiliary Bay/FAS 211SW North Auxiliary Bay, go<i= Tcr El 198 Ft I ADA Al 231SW North Auxiliary Bay unJO&L FA) Electrical Room, El 240 Ft FA37 221SW Auxiliary Bay, North Access Area B, El 215 Ft outh Auxiliary Bay/FA6 214SW South Auxiliary Bay, Ilhol/6 Po El 198 Ft I'A)S 1, Aoa FA12 239SW South Auxiliary Bay, Electrical Room, OAsen El 240 Ft 224SW Auxiliary Bay, South Access Area B, El 215 Ft Control Bui lding/FA16 306NW Control Building General Area, El 214 Ft 312~ Control Building General Area, East, El 214 Ft 23 321NW Control Building Cable Chase, West, El 237 Ft Amendment 23 2 of 6 December 1985 ~ ' Nine Mile Point Unit 2 FSAR TABLE 9B.6-1 (Cont) Fire Fire Area Fire Subarea Zone 332NW Control Building Cable Chase,'est, El 261 Ft 3 52NW Control Building Cable Chase, Hest, El 288 Ft 37 1NW Control Building Cable Chase, West, El 306 Ft FA17 305NW Control Building Cable Chase, Hest, El 214 Ft 322NW Control Building, Division I Cable PÃ7 Routing Area, 'D d R 333XL Control Buxlding, g Pg.+ Division I Standby Switchgear Room, El 261 Ft 331NW Control Building Corridor, El 261 Ft 334NZ Control Building, Division I Battery Room, El 261 Ft FA 309NW E~Tl44AL QgQ gl > Control Building 2~ 0 Cable Chase, East, El 214 Ft 324NW Control Building Cable Chase, East, El 237 Ft 337NW Control Building Cable Chase, East, El 261 Ft 359NW Control Bui lding Cable Chase, East, El 288 Ft 377NW Control Building Cable Chase, East, El 306 Ft FA19 323NW Control Building, Division II Cable Routing Area, El 237 Ft leo: Amendment 23 3 o'f 6" 'December'985 0 Nine Mile Point Unit 2 FSAR TABLE 9B.6-1 (Cont) Fire Fire Area Fire Subarea Zone 336XL Control Bui'ding, Division II, Standby Switchgear Room, El 261 Ft 335NZ Control Building, Division II Battery Room, El 261 Ft FA43 338NZ Control Building Remote Shutdown Room, East FA44 343NZ Control Building Remote Shutdown p~i~ Room, West co(=a fg,o FA2 325NW Control Building, lib Division I, Chble Routing Area, El 244 Ft t 4+~ 340Nz Control Bum ng, Division I, HVAC Room, El 261 Ft Control Building, hhoVE ~ 326NW Division II, Cable VM Phil Routing Area, 1 244 341NZ Control Building, Division II, HVAC Room, El 261 Ft FA24 356NZ Control Building, PGCC Relay Room, El 288 Ft FA25 360NZ Control Building, Division I, HVAC Room, El 288 Ft FA26 373NZ Control Plant Control Building,'ain Amendment 11 4 of June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.6-1 (Cont) Fire Fire Area Fire Subarea Zone Room, El 306 Ft 378NZ Control Building, Division I I, HVAC Room, El 306 Ft 'A27 FA76 380NZ Control Building Corridor/Instrument Shop, El 306 Ft Tunnels/F~ 5~ 256NZ Main Steam Tunnel FA48 236NZ Electrical Tunnel Vent 23 Room, El 237 Ft, Div. I FA55;. 361NZ, Pipe Tunnel 363NZ 237NZ 23 362NZ Radvaste Tunnel Service Water Pump Area/ FA60 807NZ Service Water Pump Room B FA61 806NZ Service Water Pump Room A Intake Area/FA71 802NZ, ntake Area 803NZ w~ 64lo iw g Reactor Bui lding/FSA34 212SW Reactor Building General Area, North, El 175 Ft. 222SW Reactor Building General Area, North, El 215 Ft 232SW Reactor Building General Area, North, El 240 Ft 243SW Reactor Building General Area, North, El 261 Ft Amendment 23 5 of 6 December 1985 Nine Mile Point Unit 2 FSAR TABLE 9B.6-1 (Cont) Fire Fire Area Fire Subarea Zone 252SW Reactor Building General Area, North, El 288 Ft zs~zguJ Reactor General Building Area, North, El 306 Ft 271SW Reactor Building General Area, Northwest, El 328 Ft 273SW Reactor Building General Area, Northeast, El 328 Ft 281NZ Reactor Building General Area FSA35 213SW Reactor Building General Area, South, El 175 Ft 223SW Reactor Building General Area, South, El 215 Ft 238SW Reactor Building General Area, South, El 240 Ft 245SW Reactor Building General Area, South, El 261 Ft 255SW Reactor Building General Area, South, El 288 Ft ~s~Q Reactor Building General Area, South, El 306 Ft 274SW Reactor Building General Area, Southeast, El 328 Ft FA87 287SW Reactor Building, Division I, SFC Pump Room, El 288 Ft Amendment 23 6 of 6 December 1985 C Nine Mile Point Unit 2 FSAR TABI.E 9B.6-3 (Cont) Building/ Fire Zone Drawin No. Elevation I.D. Numbers Remarks Control Bldg 359NW Cable Chase East El 288'-6" Control Bldg 360NZ Div 1 HVAC Rm El 288'-6" Turbine Bldg 731SW Cols 8-12 El 277'-6" Screenwell 803NZ Bldg El 261'-0" Figure 9A.3-7 Reactor Bldg 2e+. General Area El 306'-6" Reactor Bldg General Area El 306'-6" .6~ Q Control Bldg 371NW Cable Chase West El 306'-0" Control Bldg 373NZ Main Plant Control Room El 306'-0" Control Bldg 377NW Cable Chase East El 306'-0" Control Bldg 378NZ Div 2 HVAC Rm El 306'-0" Control Bldg 380NZ Instrument Shop El 306'-05 Amendment ll 8 of 9 June 1984 Nine Mile 'Point Unit 2 FSAR TABIE 9B.8-1 CIST OF SAFE SHUTDOWN EQUIPMENT BY FIRE AREA/FIRE ZONE Fire Fire Required Area Zone E i ment Train Remarks FA1 201SW 2CSI +FE107 3 Aux. Bay 2CSL*P1 3 North 2CSI +P2 El 175 2HVR*TIS22A 1,3 2HVR*TI S22B 1,3 ~/5 f xylo 2HVR*UC402A 1,3 2HVR+UC402B 1,3 202SW 2CCP*AOV37A 1,3 2CCP*AOV38A 1,3 2CCP*SOV37A 1,3 2CCP*SOV38A 1,3 2HVR~TIS23A 1,3 2HVR~TI S23D 1,3 2HVR~UC401A 1,3 2HVR*UC401D 1.3 2RHS>FE14A 1,3 2RHS*MOV2A 1,3 2RHS~P1A 1,3 2RHS+Vl 2RHS*V39 2RHS*V9 2SWP*AOV20A 1,3 2SWP*AOV22A 1,3 2SWP*SOV20A 1,3 2SWP*SOV22A 1,3 203SW 2*JB0921 1,3 2HVR*TIS116 1,3 2RHS*CE11A 1,3 2RHS~MOV12A 1.3 2RHS~MOV32A 1,3 2RHS~MOV37A 1,3 2RHS~MOV8A 1,3 2RHS+ SOV17A 1,3 2RHS*TE13A 1,3 A~QFe ev.am pg ~o) +A' '2L[$vi boo A<<Q~ A ~ P~. +~3 hso ~i~e) ~+ pg.z.i) Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Fire Requi red Area Zone Train Remarks FA3 206SW 2*JB0356 2,4 Aux. Bay 2*JB0922 2,4 South 2HVR*TIS115 2,4 El 175 (99 2RHS*CE 1 lB 2,4 <i5 vs+ 2RHS*LT28B 2,4 2RHS*MOV12B 2,4 2RHS*MOV32B 2I4 2RHS*MOV37B 2,4 2RHS*SOV17B 2,4 2RHS*V14 2,4 2RHS*V25 2,4 2RHS*V26 2,4 2RHS*V272 2,4 2RHS*V273 2,4 2RHS*V31 2,4 2RHS*V32 2,4 2RHS*V33 2,4 2RHS*V34 2,4 2SWP*MOV33B 2,4 2SWP*MOV90B 2,4 2SWP*RE23B 2,4 2SWP~TE12B 2,4 207SW 2+JB0184 2,4 2*JB0209 2,4 2*JB0210 2,4 2CCP*AOV37B 2,4 2CCP+AOV38B 2,4 2CCP*SOV37B 2,4 2CCP*SOV38B 2,4 2HVR*TIS23C 2,4 2HVR*TIS23F '2,4 2HVR*UC401C 2,4 2HVR*UC401F 2,4 2RHS*MOV149 2,4 2RHS~MOV4B 2,4 2RHS*MOV8B 2,4 2RHS*P 1B 2,4 2RHS*TE13B 2,4 2RHS*Vll 2,4 2RHS*V2 2,4 2RHS*V42 2,4 2RHS*VS 2,4 2RHS*V8 2,4 'RHS*V89 2,4 2RHS-V91 2,4 Amendment ll 4 of 75 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Fire Required Area Zone E i ment Train Remarks 2SWP*AOV20B 2,4 2SWP*AOV22B 2,4 2SWP*SOV20B 2,4 2SWP*SOV22B 2,4 208SW 2HVR~TI S23B 2,4 2HVR*TIS23E 2,4 2HVR*UC401B 2,4 2HVR*UC401E 2,4 2RHS*MOV4C 2,4 2RHS*P1C 2RHS*V3 2,4 2RHS*V6 2,4 CABLES 2,4 2RHS+FE14B 2,4 2RHS~FE14C 2,4 Aoo: Z)P$ A (A,oc ~Li ice mN @.25) C'tdDZi EZg&<. (mO >~i is~ e < y.Zg) Rw ggg $ IAJ Ape AiL IHF'a Wnh F'g. 2$) Amendment 22 5 of 75 November 1985 Nine Nile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Fire Required Area ~FA7 Elec a FAN> Z0I18 302Nw CASE ES rain Ramarka Tunnel 35o +Pa3 P,gL ~ TH IS +iD Pg. & OF ~lS ~ASKS'g nzm wA,B Amendment 23 7 o{75 December 198S Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Area FA8 Fire Zone 301NW E~ Required 2CMS*AITSA Train 1,3 Remarks Elec. 2CMS~AIT71A 1,3 Tunnel 2CMS iAIYSA 1,3 1<a'g W 2CMS <<AI Y71A 1,3 2CMS*AT6A 1 3 2CMS+AT71A 1,3 2CMS~PNL73A 1.3 CABLES 1,3 soQA ~Hs~g AMn Sthent 11 8 of 75 June 1984 Nine Mile Point Unit 2 FSAR 9B.8-1 (Cont) ire Required Area Zone E i ment Train Remarks 230'ire ~v+g Elec. Tunnel l5 304NW 2CMS*AIT6B 2CMS*AIT71B 2CMS*AIY6B 2,4 2,4 2,4 2CMS*AIY71B 2,4 2CMS*AT6B 2,4 2CMS*AT71B 2,4 2CMS*PNj73B 2q4 CABI ES 2,4 gF /Bled ~ U~pm- t=AI~ nF L i-IiS Amendment ll 9 of 75 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) " Fire Required Area Zone Train Remark 198'ire Pp Aux. Bay North 1 211SW 2HVR*UC405 2RHS*MOV26A 2RHS*MOV27A 1,3 1~3 1,3 El 2RHS*MOV9A 1,3 2RHS*SV34A 1.3 - 2RHS*SV62A 1,3 2RHS*TE10A 1r3 2RHS*V183 1,3 2RHS*V196 1,3 2SWP*PT140A 1,3 2SWP+RE23A 1,3 CABI ES 1,3 A<~ oF TAis +o pg. I OW ~1~ TW-~ Ueoc~ t=A I Amendment ll 20 of 75 June 1984 Nine Mile Point Unit 2'SAR TABLE 9B.8-1 (Cont) Fire Required Area Zone E i ment Train Remarks 240'ire North Bay FA'ux. 231SW 2CMS*AE6A 2CMS+AE71A 2CMS*AIZ6A 1,3 1,3 1,3 El 2CMS*AIZ71A 1,3 2CMS*E/I6A 1,3 2CMS*E/I71A 1,3 2CMS*PNL66A 1,3 2CMS*SOV64A 1,3 2CMS*SOV65A 1,3 2DMS*MCCA1 1,3 2EHS*MCC102 1,3 2EJA*PNL100A 1,3 2EJA+XD100A , 1,3 2EJS*PNL101A 1,3 2EJS*PNL103A 1,3 2EJS*PNL104A 1,3 2HVR+TIS19A 1,3 2HVR*TIS19B 1,3 2HVR*UC408A 1,3 2HVR*UC408B 1,3 2ICSAMOV129 1 2SCV*PNL101A 1,3 2SCV*XD101A 1,3 CABLES 1,3 c, p ~i ~+ +~,~ T~ Pg, l W cwYtum')go&L I Amendment ll 21 of 75 June 1984 0 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) are Required Area Zone E i ment Train Remarks d~A3 215'ire I=A~ Aux. Bay North 221SW 2*JB0020 2*JB0022 2*JB0024 1,3 1,3 1,3 El 2*JB0060 1,3 2*JB0085 1,3 2*JB0355 1,3 2SWP*MOV19A 1,3 CABLES 1,3 p cD p~~ oF ~)~~ 7> pf i oF T l)op~ FAI Amendment ll 22 of 75 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Required Area Zone E i ment Train Remarks A 198'ire South FA3 214SW 2*JB0021 2*JB0023 2HVR+UC406 2,4 2,4 2,4 El 2RHS*MOV26B 2,4 2RHS*MOV27B 2,4 2RHS*MOV9B 2,4 2RHS*SV34B 2,4 2RHS*SV62B 2,4 2RHS*TE10B 2,4 2RHS*V189 2,4 CABLES 2,4 AL C op +~s ~ 'Pg, &OF ~kkt~Y~W UhJoc~ FA 8 Amendment 11 23 of 75 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Required Area Zone aen Train Remarks 240'ixe FA12 FAS ux. Bay South 239SW 2CMS+AE6B 2CMS*AE71B 2CMS*AIZ6B 2,4 2,4 2,4 El 2CMS*AIZ71B 2,4 2CMS*E/I6B 2,4 2CMS*E/I71B 2,4 2CMS*PNL66B 2,4 2CMS*SOV64B 2,4 2CMS*SOV65B 2,4 2DMS*MCCB1 2,4 2EHS*MCC302 2,4 2EJA+PNL300B 2,4 2EJA~XD300B 2,4 2EJS+PNL302B 2,4 2EJS*PNL303B 2,4 2EJS*PNL304B 2,4 2HVR*TIS16A 2,4 2HVR+TIS16B 2,4 2HVR*UC409A 2,4 2HVR*UC409B 2,4 2SCV*PNL301B 2,4 2SCV+XD301B 2,4 CABLES 2,4 Amendment 11 24 of 75 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Required Area Zone abLK Train Remarks 21S'ire rAeX P> Aux. Bay South 224SW 2+JB0013 CABLES 2,4 2,4 El nF Pit s T P$ UWDi~ P'AS Amendment 11 25 of 75 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Required Zone Train Remarks FA16 306NW CABLES 1,3 Control Bldg. / 32 1NW 2+JB5016 2~JB5081 1,3 1,3 Cable Chase 2+JB5147 1,3 West 2+JB8014 1,3 2*JB8015 1,3 332NW 2+JB0207 1,3 2*JB0208 1,3 2*JB5118 1,3 2HVC*AOD169 1,3 2HVC*SOV169 1,3 352NW 2+JB5047 1,3 2BYS*PNL201A 1,3 2BYS+PNL202A 1,3 2SCM*PNL101A 1,3 2 SCM*PNL102A 1,3 2SCM*PNL103A 1,3 Pox 2SCM*PNL104A 1,3 1,3 ~ 2SCM*PNL105A CA 2SCM*XD101A 1,3 2SCM*XD102A 1,3 2SCM*XD103A 1,3 ,2SCM*XD104A 1,3 2SCM*XD105A 1,3 2VBS*PNL101A 1,3 371NW 2VBS*PNLA103 1,3 Amendment 23 26 of 75 Deceinber 1985 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Fire Required Area Zone BBLR" Train Remarks FA17 305NW CABLES 1,3 Control 322NW 2*JB5004 1,3 Bldg. 2*JB5014 1,3 2*JB5018 1.3 2*JB5039 1,3 2*JB5043 1,3 2+JB5092 1,3 2~JB5093 1,3 2+JB5119 1,3 2*JB5128 1,3 2*JB5150 1,3 2*JB5160 1.3 2*JB8028 1,3 2*JB8080 1,3 2+JB8082 1,3 2*JB8084 1,3 2*JB8091 1,3 2HVC*AOD170 1,3 2HVC*AOD213 1,3 'HVC*FS172 1,3 2HVC~ SOV170 1,3 2HVC*SOV2 13 1,3 2HVC*TE174 1,3 2HVC*UC106 1,3 2SWP+AOV573 1,3 ~ 2SWP*SOVS 3 1 3 SCM*PNL2 OP 1,2 2SCV*PNL200P 1,2 333XL 2BYS~CHGR2A1 1,3 2BYS~CHGR2A2 1,3 2BYS*SWG002A 1,3 2EHS*MCC103 1,3 2E JA~ PNL101A 1,3 2EJA*XD101A 1,3 2E JS*PNL100A 1,3 2EJS*US1 1,3 2E JS*XlA 1,3 2E JS*xlB 1,3 2ENS*SWG101 1,3 2HVC~TE38A 1,3 2LAC*PNL100A 1,3 2LAC*XLE01 1,3 2LAC+XLE04 1,3 2LAC+XLE06 1,3 2VBA*UPS2A 1,3 '7 Amendment 23 of 75 December 1985 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Required Area Zone nra " Train Remarks FA18 53'ire Control Bldg. ~ NONE r r 2+JB5148 2*JB5149 >i 9. 2,4 2,4 C~c 337NW 2*JB5123 2,4 QgHE.w 2HVC*AOD177 2,4 2HVC*SOV177 2,4 3 59NW 2BYS*PNL201B 2,4 2BYS*PNL202B 2,4 2SCM+PNL301B 2,4 2SCM*PNL302B 2,4 2SCM*PNL303B 2,4 2SCM*PNL304B 2.4 2SCM*PNL305B 2,4 2SCM*XD301B 2,4 2SCM*XD302B 2,4 2SCM*XD303B 2,4 2SCM*XD304B 2,4 2SCM*XD305B 2,4 2VBS*PNL301B 2,4 377NW 2VBS~PNLBX03 2,4 CABLES 2,4 AD~ him ihip~ ra~& P4. g ~4 cM l)Hccm FAi5 Amendment 23 29 of 75 December 1985 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Fire Required Area Zone E i ment Train Remarks FA19 323NW 2*JB5015 2,4 Control 2+JB5019 2k 4 Bldg. 2*JB5026 244 2*JB5040 2,4 2*JB5044 2,4 2*JB5050 2,4 2*JB5082 2,4 2*JB5094 2,4 2*JB5105 2,4 2*JB5124 2,4 2*JB5138 2,4 2*JB5163 2,4 2*JB8075 2,4 2+JB8077 2,4 2*JB8079 2,4 2*JB8081 2,4 2*JB8083 2,4 2*JB8085 2,4 2+JB8092 2,4 2HVC~AOD178 2,4 2HVC+AOD179 2,4 2HVC+AOD214 2,4 2HVC~ AOD215 2,4 2HVC~FS196 2,4 2HVC+SOVI78 2,4 2HVC+ SOV179 2,4 2HVC+ SOV214 2,4 2HVC+SOV215 2,4 2HVC*TE198 2,4 2HVC+UC107 2,4 2,4 2SNPeSOV 74 2 4 ADo aLi iH~~ JB502 335N2 2e JB5155 2BYS*BAT2B 2,4 2,4 ~w Pdj.55 2HVS*UCIOIB 2,4 2HVC~UC108B 2,4 2SWP*AOV154B 2,4 2SWP*AOV78B 2,4 2SWP*SOV154B 2,4 2SWP*SOV78B 2,4 336XZ 2BYS~CHGR2BI 2,4 2BYS~CHGR2B2 2,4 2BYS~SWG002B 2,4 2EHS*MCC303 2,4 Amendment. Il 30 of 75 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Fire Required Area Zone E i ment Train Remarks FA22 325NW 2* 049 1,3 Control 40NZ 2*JB5069 Bldg. 2+JB5116 1,3 2+JB5117 2,4 NOTE 3 2EJS*PNL102A 1,3 2HVC~AOD54A 1,3 2HVC*AOD54B 2,4 NOTE 3 2HVC*FS56A 1,3 2HVC+FS56B 2,4 NOTE 3 2HVC*FS56C 2,4 NOTE 3 2HVC+FS56D 1,3 2HVC*SOV54A 1,3 2HVC*SOV54B 2,4 NOTE 3 2HVC*TI S29A 1,3 2HVC*UC103A 1,3 2HVK+CHL1A 1,3 2HVK*FE15A 1,3 2HVK*FT15A 1,3 2HVK*LS16A 1,3 2HVK*LS41A 1,3 2HVK*PlA 1,3 2HVK*RV14A 1,3 2HVK*TC18A 1,3 2SWP*FT29A 1,3 2SWP+MOV67A 1,3 2SWP*PT79A 1,3 2SWP*P2A 1,3 2SWP*TE35A 1,3 2SWP+TE91A 1,3 2SWP*TV35A 1,3 CABLES 1,3 CABLES '2,4 NOTE 3 Amendment 23 34 of 75 December 1985 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Fire Required Area Zone E i ment Train Remarks FA23 326NW 2*JB5017 2,4 MoUE Tg Control 2*JB8016 2,4 Bldg. 1 2*JB8017 2,4 2,4 Q, 50 (QL 341NZ 2*JB5 QtJ P CP-2EJS*PNL301B 2,4 2HVC*TI S29B 2HVC*UC103B 2,4 2,4 FAi 5 2HVK*CHL1B 2,4 2HVK+FE15B 2,4 2HVK+FT15B 2,4 2HVK*LS16B 2,4 2HVK*P1B 2,4 2HVK*TC18B 2,4 2SWP*FT29B 2,4 2SWP*MOV67B 2,4 2SWP*PT79B 2,4 2SWP*P2B 2,4 2SWP*TE35B 2,4 2SWP*TE91B 2,4 2SWP*TV35B 2,4 CABLES 2,4 Amendment 11 35 of 75 June 1984 Nine Mi 1 ~ Point Unit 2 TSAR TABLE 98.8-1 (Cont) Jive FiYe Required Area Zone E i mant Train Remarks rAW4~ 256NZ 2MSS~RYV7A 1,2,3,4 NOTE 14 Ma'n 2MSS~HYV7B 1,2,3,4 NOTE 14 Steam 2MSSAHYV7C 1,2,3,4 NOTE 14 Tunnel 2MSS~HYV7D 1,2,3,4 NOTE 14 Amendment 11 52 of 75 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Required Area Zone E i ment Train Remarks 237'ire FA48 Elec. Tunnel Vent Room, Div I El FASS 2*JB0359 2,4 237'37NZ Elec Tunnel Vent Room, Div II 2*JB0578 2*JB5125 2HVC*AOD192 2,4 2,4 2,4 El 2HVC*AOD193 2,4 2HVC*FS161 2,4 2HVC*SOV192 2,4 2HVC+SOV193 2,4 2HVC*TE165 2,4 2HVC+UC105 2,4 2SWP*AOV571 2,4 2SWP*SOV571 2,4 361NZ 2*JB8148 1,3 NOTE 10 2*JB8149 2,4 2SWP*FT523 2,4 2SWP*FT533 2,4 2SWP*MOV47B 2,4 2SWP*MOV92B 2,4 2SWP*MOV93B 2,4 2SWP*PT142B 2,4 2SWP*PT54B 2,4 2SWP*PV54B 2,4 2SWP+RE146B 2,4 2SWP*RUW146B 2,4 362NZ 2CSH*I T3A 1,2 2CSH~LT3B 1,2 CABLES 2,4 l)5 p~ [C. Amendment 23 53 of 75 December 1985 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Fire Required Area Zone Tna1n Remarks 2ISC*LT9A 1,3 2ISC+LT9C 1,3 2ISC+PT15D 1,3 2ISC*PT17A 1,3 2ISC*PT17C 1,3 2ISC*PT2A 1.3 2ISC~PT2B 1,3 2ISC*PT4C 1,3 2ISC*PT4D 1,3 2ISC*PTSA 1,3 2 SC*PT5D 1,3 C *PT6A 1,3 RHS*PDT24A 1,3 2RSS+LT114 1,3 2RSS+PT102 1,3 252SW 2+JB0064 1,3 2*JB0067 1,3 2*JB0121 1,3 2*JB0122 1,3 2+JB0123 1,3 2~JB0340 1,3 2+JB0346 1,3 2~JB0814 1,3 2CSL*MOV104 3 2HVR*AOD1A 1,3 2HVR*AOD204 1,3 2HVR*AOD34A 1,3 2HVR*AOD6A 1,3 2HVR*AOD9A 1,3 2HVR*SOVlA 1,3 2HVR*SOV204 1,3 2HVR~SOV34A 1,3 2HVR*SOV6A 1,3 2HVR~SOV9A 1,3 2HVR*TIS31A 1,3 2HVR*UC413A 1,3 2ICS*AOV156 1 2ICS-IT221 1 2RHS*MOV24A 1,3 2RHS~V143 2,4 NOTE 6 2RHS*V70 1,3 2SWP*AOV97A 1,3 )hi 2SWP*SOV97A 1,3 261@~ 2HVR*UC413B 2+JBO600 pl. NOTE 15 I ~~ 2SFC*V227A 1,3 Amendment '27 66 of 75 July 1986 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Fire Required Area Zone Train Remarks 2SFC+V227B 2,4 NOTE 6 271SW 2*JB0019 1,3 2*JB0027 1,3 2*JB0448 1,3 2*JB0450 1,3 2SFC*AOV19A 1,3 2SFC*AOV33A 1.3 2SFC+HV35A 1,3 2SFC~HVS4A 1,3 2SFC+LS33A 1,3 2SFC*LS33C 1.3 2SFC*LS34A 1,3 2SFC+LT32A 1,3 23 2SFC*SOV19A 1,3 2SFC*SOV33A 1.3 2SFC*SOV35A 1,3 2SFC+SOV54A 1,3 2SFC+TE31A 1,3 2SFC+V100B 1,3 2SFC+V101B 1,3 2SFC*V102B 1.3 2SFC~V260A 1.3 2SFC"LT2A 1I 3 273SW 2SFC+LT32B'SFC~V100A 2,4 NOTE 1 1,3 2SFC+V101A 1,3 2SFC*V102A 2,4 NOTE 6 2SFC*V104B 1,3 2SFC~V105B 1,3 2SFC~VX07 2,4 NOTE 6 2SFC*V148A 1,3 2SFC+V260B 2,4 NOTE 6 2SFC~V9 1,3 I 23 281NZ 2HVR~AOD10A 1,3 2HVR*SOVlOA 1,3 CABLES 1,3 FA87 287SW 2SFC~PlA 1.3 23 SFC Pump Room A Fflo87 pv,$ 1)$ l,3 lq> Amendment 23 67 of 75 December 1985 +~is ~pe somber ie veek Kw ph,cMt~k p~~~ ~<(y Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) Fire Fire Required Area Zone E i ment Train Remarks 2SFC-PI60B 2,4 26 2SFC*V7 2,4 274 2SFC*V229 2,4 CABLES 2,4 Amendment ll 73 of 75 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-1 (Cont) LEGEND OF NOTES (Cont) NOTE 9 This equipment is failsafe design; therefore, safe shutdown capability exists. NOTE 10 The junction box feeds failsafe design equipment; therefore, safe shutdown capability exists. NOTE 11 The equipment is not required for safe shutdown in case of a fire in this fire area. It is required only during operation from the remote shutdown room. Therefore, safe shutdown capability exists. NOTE 12 In case of a fire in this fire subarea, this equipment will be operated manually through proper administrative procedure. NOTE'3 In case of' fire in this area, pool cooling will be initiated through proper administrative procedure. NOTE 14 In case of loss of these outboard isolation valves, inboard isolation valves are available I to close the main steam lines. 'NOTE 15 The unmitigated fire load in fire zone 252 SW is less than 1 minute. A concrete barrier is provided between 2HVR*UC413A and 2HVR*UC413B. The wall is 2-ft thick, extends 1.25 ft above the top, 8 ft beyond the end of each unit cooler which contains the fan motor,. and 1 ft beyond the opposite end. The unit coolers are noncombustible except for motor insulation which i s contained within the steel fan casing. The only credible fire (involving motor insulation) would be contained within the casing and would not involve both unit coolers. Amendment 27 75 of 75 July 1986 Nine Mile Point Unit 2 FSAR TABLE 9B.8-2 RESUITS OF FIRE PROTECTION ANALYSIS FOR SAFE SHUTDOWN CAPABILITY IN ACCORDANCE WITH 10CFRSO APPENDIX R BALANCE OF PLANT AREAS Fire Area FA1, Auxiliary Bay North, El 175 ~)98 ) ) Fire Zones in This Fire Area 201SW LPCS zoom 202SW RHS room 0 203SW RHS heat exchanger room Pro osed Modifications The following equipment/cables're being modified in accordance with methods outlined in Section 9Be 6 to bring this fire area into compliance with Section III.G.2 of Appendix R: NONE \ Conclusions In case of a fi re in thi s fi re area, saf e shutdown capability exists through safe shutdown trains 2 and 4. 2,ll fA Qssik g<<l~ ~s Al<<ihasry ~ CL I98 hrta Ft Q IJss<a A<<ass ~ Q 7.<5 Pc esi $ < P<<gg Q<<<LaseI Sg QCCtr<~ FL 'L0o PC Amendment 23 1 of 38 December 1985 Nine Mile Point Unit 2 FSAR TABIE 9B.8-2 (Cont) Fire Area FAS, Auxiliary Say South, El Fire Zones in This Fire Area 175 ~1/8 ) QCS ) ~ pf' 206SW RHS heat exchanger room 207SW RHS pump room B 20SSN RHS pump .room 0 p ~O ro osed Modifications The following equipment/cables are being modified in accordance with methods outlined in Section 9B.6 to bring this fire area into compliance with Section III.G.2 of Appendix R: NONE Conclusions cfog In case of a fire in this fire area, safe shutdown capability exists through safe shutdown trains 1 and 3. XI/~ 5oatL 4SAil eaaa d Lu6..[ I)8 P4 W<4$eI Ih<<ih~ +,5~2.AS~ 4FSm- 1, St WSFe %/$ 41 goeg. 4SS4~ + i 8lc4cat ~ ) El ~g Amendment 11 3 of 38 June 1984 Nine Mil~ Point Unit 2 FSAR TABIE 9B.8-2 (Cont) F:AB Fire Area FA7, Electrical Tunnel P Fire Zones in This Fire Area 302NW Electrical tunnel, Pro osed Modi ica.ions 35'he fo 1 1owinq equipment/c able s are being modi fi ed in accordance with methods ou lined in Section 9B. 6 to bring this fire area into compliance with Section ? II.Q.2 of Appendix R: NONE i Conc lu s ons In case o f a fire in thi s fire area, saf e shutdown capability exists through safe shutdown trains 2 and 4. Amendment 11 5 of 3S June 1984 Nine Nile Point Unit 2 FSAR TABLE 9B.8-2 (Cont) Fire Area FA8, Electrical Tunnel Fire Zones in This Fire Area 30'NH Electrical tunnel, 1404 BQ~M e gi'I~w~, vt4t4eL pro osed Modifications The fol lowiny methods equipment/cables outlined in are being modified in Section 98. 6 to bring accordance with this fire area into compliance with Section III.G.2 of Appendix R: NONE Conc lusi ona In case of a fire in this fire area, safe shutdown capability exists through safe shutdown trains 2 and 4. Amendment 11 6 ot 38 June 19B4 Nine Mile Point Unit 2 FSAR TABLE 9B.8-2 (Cont) pAiS' s ~ ,I Fire Area A9; Electrical Tunnel / l / Fire Zones in This Fire Area I 304NW Electrical tunnel, 230'ro osed Modifications The following equipment/cables are being modified in accordance with methods outlined in Section 9B.6 to bring this fire area into compliance with Section III.G.2 of Appendix R: NONE Conclusions In case of a fire in this fire area, safe shutdown capability exists through safe shutdown trains 1 and 3. ~>MlblAE'iS pp Amendment 11 7 of 38 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-2 (Cont) Fire Area FAS, Auxiliary Bay North, El 198 Ft Fire Zones in This Fire Area 211SW Access area Pro osed Modifications The following equipment/cables are cbeing modified in accordance with methods outlined in Section 9B. 6 to bring: this fire area into compliance with 'ection III.G.2 of Appendix R: NONE 'I Conclusions In case of a fire in this fire area, safe shutdown capability exists through safe shutdown trains 2 and 4. Amendment 11 13 of 38 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-2 (Cont) Fire Area FA11, Auxiliary Bay North, El 215 Ft Fire Zones in This Fire Area 231SW Electrical room Pro osed Modifications The fol lowing equipment/cables are being modified in accordance with methods outlined in Section 9B. 6 to bri.ng this fire area into compliance with Section III.G.2 of Appendix R: NONE Conclusions In case of a fire in this fire area, safe shutdown capability exists through safe shutdown trains 2 and 4. Amendment 11 14 of 38 June 1984 0 Nine Mile Point Unit 2 FSAR TABLE 9B.8-2 (Cont) Fire Area FA37, Auxiliary Bay North, El 215 Ft Fire Zones in This Fire Area 221SH Access area Pro osed Modifications The following equipment/cables are being modified in accordance with methods outlined in Section 9B.6 to bring this fire area into compliance with Section III.G.2 of Appendix R: NONE Conclusions In case of a fire in this fire area, safe shutdown capability exists through safe shutdown trains 2 and 4. Amendment 11 15 of 38 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-2 (Cont) Fire Area FA6, Auxiliary Bay South, El 198 Ft Fire Zones in This Fire Area 214SW General area, el 198 ft Pro osed Modifications The following equipment/cables are being modified in accordance with methods outlined in Section 9B. 6 to bring this fire area, into compliance with 'Section III.G.2 of Appendix R: NONE Conclusions In case of a fire in this fire area, safe shutdown capability exists through safe shutdown trains 1 and 3. Amendment ll 16 of 38 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-2 (Cont) Fire Area FA12, Auxiliary Bay South, El 240 Ft. Eire Zones in This Fire Area 239SW Electrical room Pro osed Modifications The following equipment/cables are being modified in accordance with methods outlined in Section 9B. 6 to bring this fire area into compliance with Section III.G.2 of Appendix R: NONE Conclusions In case of a fire in this fire area, safe shutdown capability exists through safe shutdown trains 1 and 3. Amendment. 11 17 of 38 June 1984 Nine Mile Point Unit 2 FSAR TABI,E 9B.8-2 (Cont) Fire Area FA41, Auxiliary Bay South, El 21S Ft Fire Zones in This Fire Area 224SW Access area Pro osed Modifications The following equipment/cables are being modified in accordance with methods outlined in Section 9B.6 to bring this fire area into compliance with Section III.G.2 of Appendix R: I NONE I I Conclusions l In case of a fire in this fire area, safe shutdown ! capability exists through safe shutdown trains 1 and 3. Amendment 11 18 Qf 38 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-2 (Cont) Fire Area FA16, Control Building Fire Zones in This Fire Area 306NZ Cable chase west, el 214 ft ft 3 12N~ Control building vault, el 214 ft 321NW Cable chase west, el 237 332NW Cable chase west, el 261 ft ft 352NW Cable chase west, el 288 371NW Cable chase west, el 306 ft Pro osed Modifications The following equipment/cables are being modified in accordance with methods outlined in Section 9B. 6 to bring this fire area into compliance with Section III.G.2 of Appendix R: NONE Conclusions I In case of a fire in this fire area, safe shutdown capability exists through safe shutdown trains 2 and 4. Amendment 23 19 of 38 December 1985 Nine Mile Point Unit 2 FSAR TABLE 9B,8-2 (Cont) Fire Area FA17, Control Building Fire Zones in This Fire Area 305NW General area, el 214 ft 23 322NW Division I cable routing area, el 237 ft 331NW Corridor, el 261 ft 333XL Division I switchgear room, el 261 ft 334NZ Division I battery room, el 261 ft 30-gg4l plA/io4T osed Modifications ~~Q~~$ h~~eLJ ~Fj'ro The following cables are being modified in accordance with methods outlined in Section 9B.6 to bring'his fire area into compliance with Section III.G.2 of Appendix R: NONE Conclusion In case of a .fire in this fire area, safe shutdown capability exists through safe shutdown train 4. 23 Amendment 23 20 of 38 December 1985 Nine Mile Point Unit 2 FSAR TABLE 9B.8-2 (Cont) Fire Area FA18, Control Building Fire Zones in This Fire Area 09NW 3 24NW 337NW Cable Cable T chase chase east, east, pep<<, el el 237 ft 261 ft 3 59NW Cable chase east, el 288 ft 3 77NW Cable chase east, el 306 ft Pro osed Modifications The following equipment/cables are being modified in accordance with methods outlined in Section 9B.6 to bring this fire area into compliance with Section III.G.2 of Appendix R: ~ NONE Conclusions In case of a fire in this fire area, safe shutdown capability exists through safe shutdown trains 1 and 3... Amendment. 23 21 of 38 December 1985 Nine Mile Point Unit 2 FSAR TABLE 9B.8-2 (Cont) Fire Area FA19, Control Building Fire Zones in This Fire Area 323NW Division II cable routing area, el 237 ft 335NZ Division II battery, room,,el 261 ft F PO 336XL 'ivision II switchgear room, el 261 ft )Ih/ Dl IISio 4 '1T ~~c p ~~ ~ g ~~ all ~~ Fr The following equipment/cables are being modified in accordance with methods outlined in Section 9B.6 to bring this fire area into compliance with Section III.G.2 of Appendix R: NONE Conclusions In case of a fire in this fire area, safe shutdown capability exists through safe shutdown train 3. Amendment 11 22 of 38 June 1984 0 Nine Mile Point Unit 2 FSAR TABLE 9B.8-2 (Cont) Fire Area FA22, Control Building Fire Zones in This Fire Area 325NW Division I cable routing area, el 244 ft zvxsxon AC room, Pro osed Modifications The fol lowing equipment/cables are being modif ied in accordance with methods outlined in Section 9B. 6 to bring this fire area into compliance with Section III.G.2 of Appendix R: NONE Conclusions In case of a fire in this fire area, safe shutdown capability exists through safe shutdown trains 2 and 4. Amendment ll 25 of 38 'June 1984 0 Nine Mile Point Unit 2 FSAR TABLE 9B.8-2 (Cont) Fire Area FA23, Control Building ~ Fire Zones in This Fire Area ft H 3 26NW Division rou xng area, el 244 tI HVAC room, Pro osed Modifications The following equipment/cables are being modified in accordance with methods outlined in Section 9B. 6 to bring this fire area into compliance with Section III.G.2 of Appendix R: NONE Conclusion In case of a fire in this fire area, safe shutdown capability exists through safe shutdown trains 1 and 3. Amendment 11 26 of 38 June 1984 Nine Mile Point Unit 2 FSAR TABI.E 9B.8-2 (Cont) Fire Area FA24, Control Building El 288 Ft 'pgcc p.C~ See Section 9B.8.2 p.~ Amendment 23 27 of 38 December 1985 Nine Mile Point Unit 2'SAR TABLE 9B.8-2 (Cont) Fire a "ea Fa34 Main Steam Funnel Fire Zones 'n This Fire Area 2S6NZ Main steam tunnel Pro osed Modifications The following equipment/cables ate being modi fi ed in accordance with methods outlined in Section 9B. 6 to bring this fire area into compLianco with Section I II.G.2 of Appendix Ri NONE In case of a fire in this firo area, safe shutdown capabiLity exists through safe shutdown trains 1, 2, 3, and 4. Amendment 11 32 of 38 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-2 (Cont) Fire Subarea FSA34, Reactor Building, North Half Fire Zones in This Fire Subarea 212SW General area, el 175 ft 222SW General area, el 215 ft 232SW General area, el 240 243SW General area, el 261 ft 252SW General area, el 288 26 General area, el 306 ft 271SW General area, el 328 273SW General area, el 328 281NZ General area, el 328 ft Pro osed Modifications The following equipment/cables are being modified in accordance with methods outlined in Section 9B.6 to bring this fire subarea into compliance with Section III.G.2 oS-Appendix R: NONE Conclusions In case of a fire in this fire area, safe shutdown capability exists through safe shutdown trains 2 and 4. Amendment 11 37 of 38 June 1984 Nine Mile Point Unit 2 FSAR TABLE 9B.8-2 (Cont) Fire Subarea FSA35, Reactor Building, South Half Fire Zones in This Fire Subarea 213SW General area, el 175 223SW General area, el 215 238SW General area, el 240 General area, el 261 ft 255S General area, el 288 General area, el 306 ft ft ~ 274SW General area, el 328 Pro osed Modifications The following equipment/cables are being modified in accordance with methods outlined in Section 9B. 6 to bring this fire subarea into compliance with Section III.G.2 of Appendix R: NONE 23 Conclusions In case of a fire in this fire area, safe shutdown capability exists through safe shutdown train 3 after modifications have been completed. Amendment 23 38 of 38 December 1985 Nine Mile Point: Unit 2 FSAR heaters and in the feeds to the auxiliary steam system. These counter 'ed valves are swing check valves with lever arms and air cylinders nd have closing time of . sec. The air cylinders use air pressure ternal o mazn tain ai a spring in compression. Upon release of the air pressure the spring provides enough force aat the start of the stroke to overcome sticking and to place the swing disc in the flow stream. The spring will not close the valve against flow, but will provide sufficient motion to confirm operability. The air cylinder/spring does not prevent the disc from closing on reverse flow. Additionally, the extraction steam system is designed so that the total unrestrained energy in the piping and equipment volume is less than the turbine manufacturer's maximum value limit. Nonreturn valves are not supplied in the extraction lines to the fifth point feedwater heaters since the steam is prevented from'expanding through any turbine stages by the cc~bined intermediate valves. Nonreturn valves are not needed on the extraction lines to the second and first point heaters, since they contain insufficient stored energy to produce an unacceptable overspeed event. Th e main stop valves, contxol valves, and combined intermediate valves are tested in accordance wi Technical Specifications. The extraction valves are tested for movement weekly, Internal inspection and maintenance will be performed in accordance with the five refueling cycle turbine and valve maintenance and inspection program. One of each type main steam valve will be disassembled and inspected at approximately 3 1/3-yr intervals. The generator is a direct coupled, three-phase, 60-Hz, 25-kV, 1,800-rpm synchronous generator with a hydrogen-cooled rotor and a water-cooled stator. The generator is raet d a t 1 348 400 kVa, 0.90 power factor (p.f.), with a short circuit ratio of 0.58 and a maximum hydrogen p ressure of 75 psig. The exciter system is the Alterrex type. The alternator-exciter is a three-phase, 1,800-rpm, 60-Hz, air-cooled machine rated at 3,385 kW, 555 V with a response ratio of The turbine utilizes conventional governing devices 'n EHC (two system consisting of itial , devices), initia p ressure regulators, speed governor, startup control emergency devices for turbine and. plan p (overspeed governor, backup. overspeed, master trip, low vacuum trips, motori'ng protection, thrust bearing wear Amendment 27 10.2-3a July 1986 Nine Mile Point Unit 2 FSAR
- 2. 2 NIAGARA MOHAWK POWER CORPORATION
Overall system tests for the waste collector subsystem, the floor dra'.n collector subsystem, and the regenerant waste subsystem establish the overall decontamination factor for the entire subsystem. ~ ~
- c. Distillate conductivity.
11.2.3 Radioactive Release and Doses Table 11.2-5 is a tabulation of the expected annual liquid releases and conforms with the method and parameters given-in NUREG-0016, Revision 1. The design base release from the liquid effluent stream in Ci/yr per nuclide is given in Table 11.2-6 and corresponds to operation with design failed fuel conditions as di'scussed in Section 11.1. The release is based on effluent discharge to the environs only through the waste collector subsystem, as liquid from all other subsystems eventually recycles to the waste collector tanks. Tritium release from liquid pathways is anticipated at 52 Ci/yr. 11.2.3.1 Release Points All process liquid releases from Unit 2 are fed into the service water system discharge bay that is directed to Lake Ontario. Figure 11.5-8 (Sheet 2) shows all systems that feed the discharge bay. Figure 11.2-1 shows the release point of each system to the discharge line. Figure 9.2-11 shows the physical location of the discharge into the lake. 11.2.3;2 Dilution Factors The only dilution factor used in evaluating the release of radioactive liquid effluents is that provided by the cooling tower blowdown. Treated radioactive effluents are dilute n the discharge bay with a blowdown flow of 3,400 gpm ( .6 x 10'~ cc/yr). Amendment 23 11. 2-17 December 1985
- 11. 2. 2. 9 Summary Over 225,000 gal of bulk stora e apacity is available to collect and store the avera e liquid radwast t volumes of a oroximatel 41, 100 d. with rocess inventory of a roximately 5, 0 ga . Storage facilitzes e so avaxla e o ed liquid. The treated liquid bulk storage capacity is 100,000 gal which allows sufficient time for sampling and disposa approximately 2,04 gpd to the environs and recycling< 9,060 gpd to the con ensate storage tank.
Nine Mile Point Unit 2 FSAR contxol switches, and a system mimic display mounted on the face of the control panel. The panel will alarm and control all necessary components so the operator will have complete knowledge of system status. The system has been designed to operate completely unattended during normal operation. The control panel has alarm provisions for the following system parameters: 1 ~ System inlet temperature.
- 50) 9 3-<
S. Catalytic recombiner outlet tempexature.
- 2. System inlet pressure.
- 3. Preheater outlet temperature (low) .
- 4. Preheater outlet temperature (high) .
16. 17. vacuum pump utdow . Auto switchover to standby ~~ train. ~pf'loo.h f7 g: System outlet flow. I< ~ Pretreatment high radiation. The off-gas control panel is located in the off-gas area in the turbine building. The control room has a trouble alarm which alarms on all the items noted in Section 11.3. In Amendment 5 11.3-5 October 1983 Nine Mile Point Unit 2 FSAR TABLE 11.4"4 SOLID WASTE MANAGEMENT SYSTEM MAJOR EQUIPMENT LIST Parameter Waste sludge tank 2WSS-TK8 25 Number 1 Capacity, gal 25 1, 355 I Material of construction Type 316L stainless steel Asphalt storage tank 2WSS-TK2 25 Number 1 Capacity, gal 10,800 Material of construction Carbon steel Extruder/evaporator 2WSS-EV25 25 Number Capacity, gpm Varies ( = 1.0) 25 Material of construction Mfg standard Asphalt metering pump 2WSS-PSAEB 2 5 Number 2 Capacity, gpm 0 ~ 1-0.6 Material of .construction Cast iron I 25 Asphalt recirc pump 2WSS-P3AGB 25 Number 2 2 5 Capacity, gpm 20 Material of construction ' Cast iron Waste sludge transfer pump 2WSS-Pll 25 Number 1 Capacity, gpm 50 Material of construction Type 316 stainless steel Waste sludge metering pump 2WSS-P12AEB ". 5 Number 2 Cap ac i ty, gpm Material of construction
- 6. Condenser outlet temperature.
- 7. Condenser outlet hydrogen concentxation.
- 8. Condenser high level.
- 9. Condenser low level.
- 10. Freezeout dryer inlet hydrogen concentration.
- 11. Freezeout dryer outlet temperature.
- 12. Charcoal adsorber tanks - inlet moisture.
- 13. HEPA filter differential pressure.
- 14. Vacuum pump suction pressure.
- 15. Vacuum pump auto start.
gpm Material of construction Type 316 stainless steel Amendment 25 1 of 2 March 1986 Nine Mile Point Unit 2 FSAR TABLE 14.2-63 FIRE PROTECTION COg System 45 Test Ob'ectives
- 0. 2-0. 9 Type 316 stainless steel Decant pump 2WSS-P10 2 5 Number Capacity, '
system and components.
- 1. To demonstrate the operation of the fire protection CO+
Safet Precaution Follow NMPC safety rules and proper procedures during testing. Prere i si tes
- 2. To ensure the system is properly designed and constructed.
4 ~ The fire computer, fi re detection, and ventilation systems are available to support testing. Test Procedure 1, The CO< storage tanks are filled.
- 1. All applicable preliminary tests are completed and the system turned over to NMPC.
- 2. All applicable power sources to supply electric power to motors, control circuits, and instrumentation.
- 3. Valve lineups are completed.
Concentration tests are performed on total flooding systems ao, 'ned, (Onl>sc~tsc noh'),'in a~c4on t.S.~. K t cue, 'in ~<<~~<<i + ~F5 6 la-1'NS'. earbonCiz'ikey systems.
- 2. The CO< hose reels are, verified for proper operation.
- 3. The CO< hazard valves are puff tested, with the CO< zone piping isolated and its bypass open, from the local fire panel, main fire panel, and associated detection zones in both manual and automatic modes of operation.
Amendment 24 1 of 2 February 1986 Nine Mile Point Unit 2 FSAR TABLE 14.2-63 (Cont)
- 4. The generator hydrogen and CO< subsystems are tested for CO< flow.
Acceptance Criteria
- 5. Alarms and annunciators are verified for proper response 22 in conjunction with the various tests performed.
or, L<~,(un'.m o44r
- 1. Total flooding systems automatically actuate on a signal from associated detectors, as described in 22 Section 9 '.1.2.9.
- 2. Ventilation dampers associated with total flooding systems close on initiation of gas flow, as described in Section 9A.3.5.6.7.
22 4. Ventilation equipment associated with total flooding systems shut down on a fire signal, as described in Section 9A.3.5.6.7. Amendment 22 2 of 2 November 1985 Nine Mile Point Unit 2 FSAR TABLE 14.2-77 (Cont) Acceptance Criteria
- 3. CO@ concentrations for to a ooding systems are in accordance wi th NFPA Codes Volume 1, Code 12: Carbon Dioxide Systems.
22 wg, as described in Section 6.2.3.1.
- 1. The SGTS starts automatically on any of the three 22 signals described in Section 6.5.1.2.1.
- 2. The standby train of the SGTS starts automatically, as described in Section 6.5.1.5.
- 3. Each standby gas treatment system train can maintain reactor building pressure equal to or below -0.25 in.
Amendment 22 2 of 2 November 1985 0 Nine Mile Point Unit 2 FSAR TABLE 14.2-129 (Cont) Acce tance Criteria
- 4. The secondar containment drawdown time to -0.25 in. wg is less see a a maximum of , c m (see Technica Specification Section 3/4.6.
bg~ew ~e, now'irgsh oPedk ~ah WAP > )Q jo g A poynihoA > u)htchevee <s LeSZ~ Abc Amendment 26 2a of 2 May 1986 Nine Mile Point Unit 2 FSAR TABLE 14.2-225 (Cont)
- 1. Systems required to operate during LOCA and/or loss of offsite power conditions operate within time and load requirements of their design, in accordance with Section 8.3.
- 2. In the event one diesel generator becomes unavailable, the remaining two diesels will be capable of feeding the loads necessary for safe plant shutdown in accordance with Section 8.3.
- 3. The failure of any one electrical division does not affect the operation of the others or their IOCA/containment isolation functions.
- 4. The diesel generators can'tart and assume their LOCA/containment isolation and/or loss of power loads in the specified times and sequence while maintaining voltage and frequency within specified limits, from both cold (normal standby) and hot (operating) temperatures, sped <n'ce~
- 5. On a loss of the largest single load the diesel generator does not exceed 75 percent of the e ttin w zc s e I 26
- 6. The design emergency loads can start and run properly under minimum and maximum ac voltage conditions.
- 7. The temperatures on the larger power transformers does not exceed the transformer's maximum rated temperature while carrying maximum available load.
- 8. Voltage drops from load centers to MCCs and MCCs to motor loads shall be within design requirements.
- 9. The ECCS loads can be started, accelerated, and run while being supplied from normal offsite or standby ac power systems. WNcov~~
The maximum flow, F, the pressure, P, and the slope of the flow variation with pressure, A, can be obtained f om the plant parameters specified in Section 15.1.2.3.2. Level 2: r The maximum valve position must be greater than the calculated position reguired to supply: With rated complement of pumps - 115.5 percent NBR at 1,071 psia.
- 1. F .percent NBR at P psia.
- 2. [F percent + A(P-P rated)) percent NBR at P rated psia.
Amendment 18 3 of 3 March 1985 Nine Nile Point Unit 2 FS1R ThBLE 421 36-1 CONPORN1NCE TO REGULhTORY GUIDE 1 97 Reg. Guide 1.97, Rev. 3 SNEC/ P4raeeteL P~g~~e Sensor j}uallfication Qh Power Display G~I~D~a Dmcg/BtgoB TBrgRbgR C+~+gc~gRB gogBggoR gns~t~I)a~ segsaic Enrironaental Class Su~le Lacation Hots s B 13-D193 Power Png Pluz Lerel 81a. Core 0.5-125% pwr Yes Yes II Non-1E P603 hverage Pwr 81b. Plax Lvl N/h 0-125% pvr No No II Hon-1E P603 Rng C51- N0021-H In ter- B lc Core 4.0x10-a - Yes Yes II Non-1E P603 ~ ediate 12.6% Pwr Rng Plux Level No HO C51-N00'I 1-0 Source Rng Flux Level Bld. Core 0. 1-1z10 ~ {QP II Non-IE P603 Control Rod B2 Core Nfthdrawn Yes Yes II Non-1E P603 Position or Scraa Rz Coolant B3 Uait 1 50-2,000 N/1 N/1 II Hon-1E-Boron Conc H.P~ Lab. ppa 2ISCaLT131/ Reactor Tsl Baa Rx Bldg 230 64- Yes Yes I Dir. 1 P601 5,41 822-N0441 Lerel - 1 (Sec 430 69< (Fuel Zona) Contat) 2ISCOLT138/ Reactor Tsl B4b. Rx Bldg 230.69- Yes Yes I Div 2 F601 5,41 822-N044B Level - 8 (Sec 430 69" (Fuel tone) Contat) 2ISC+LT9+ Reactor Tsl B4a Bldg 375 70- Yes Yes I Di.v 1 P601 5,41 B22-N09~ Level - 1 (Sec 585 70 (Ride Range) Coatat) 8 2ISC+LT Reactor Tsl B4b Rz Bldg 375.70- ~ Yes Yes I Dir. 2 P601 5~ 41 B22-N09 Level - B (Sec 585 70 I5 (Ride Range) Contat) N/1 Core B5 N/1 Teaperature haendaent 26 1of 18 Nay 1986 Nine Nile Point Nnit 2 FSAP TABLE 421.36-1 (Cont) Reg. Guide 1.97 Rev. 3 S QEC/ Pa rane ter ~ PdKRBc)~tr Sensor ~ualif icatinn 0A Rover Display GE-NED I D 0 Descrintion Variable Classification Location Instr. Panqe Seisaic Environaental Class s~uplI Location Nots s 2CNSvPT21 Dryvell 87a 1 Rz Bldg 0-150 Yes Yes I Div 1 P601 Pressure-1 (Sec psig Contat) Bldg 0-150 Tes Tes -I Di v 2 P898 I?C 2CNSaPT2B Dryvell B7b. 1 Rx Pressure-B {Sec psig Contnt) 2CNSvPT71 Suppression B7c. 1 Rx Bldg 0-150 Yes Tes I Div- 1 P601 Chaaber (Sec psig Pressure-1 (Contat) 2CNSaPT78 Suppression B7d. 1 Rx Bldg 0-150 Yes Yes I Div 2 P898 ) 2C Cha aber (Sec psig Pressure-8 Contat) See Note 7 Dryvell BB Suap Level 2CNSaPT1A Priaary B9a 1 Rx Bldg -5 to +5 Yes Yes I Div.. 1 P601 Containaent (Sec psig Pressure-1 Contat) 2CNS+PT1B Prinary B9b. 1 Fx Bldg -5 to +5 Tes Yes I Div 2 o601/ 8 Containaent (Sec psig P898 Pressure-B Contat) 2A AS V 134 g Priaary B10al 1 N/1 N/A Yes Tes I Div 1 >851 135 Containaent Vlv Isolation-AAS 2AAS~V136 ~ Prinary 810al 1 N/A Tes Yes I Div. 1 P851 137 Containnent Vlv Isolation-ASS 2CCP+NOV17A Priaary 810bl 1 ~ N/A N/1 Yes Yes I Div. 1 P602/ 37 B;124 '65, ~ Containaent Vlv Isolation P873 lg~ 8 CCP 2 of 18 Nay 1986 Avendaent 26 Nine Nile Point Unit 2 FSAR TABLE 421.36-1 (Cont) Reg. Unide 1 97, Rev. 3 SNEC/ Paeaaeaee 2S~SSSee equal,ificagion QA Pover Display @~ED Isgag 222222222eS ~<l!12 uaSSksicaaiae 2maaaee 2eaaK EeiSe Seisnlc Environaental Class Suonlr Location Notes 2CCn+NOT16hi Priaary 810h2 N/1 N/1 Yes Tes I Dir 2 P602/ 37 Be 94hz Bp Containaent P873 122'73 Vlr Isolation-CCP 2CNSaSOV24A, Prinary 810c1 Yes Tes I Div 1 P873 C:26A,C;321; Containaent 331;341 351; Isolation-60A ~ B ~ APBg CHS 2cssescpgllC psiaaep slsc2 N/1 N/1 Yes Yes I Dir. 2 P875 D126B,D;328; Containnent 338;348; 358; Isolation-611i B;63hi 8 CBS 2CPS+AOT Prisary 810d1 N/1 Yes Tes I Div 1 F873 IOi 111 104'05'I Containnent +SOV119P 120 Isolation-CPS AOV 2CPS 06, Prinary 810d2 N/1 Tes Tes I Div 2 P875 107 ~ 108, 109 Containnent aSOV121 ~ 122l Isolation- +SCWIB2)(33 CPS 2CSBehOV 108 Pr inary 810e N/1 Yes Tes I Div. 3 P60 1 +BOV105s 107 Containaent 1~ 118 Isolation ee F005 CSB 12r F004 ~ F023 ~ FOI 5 2CSLNAOT101 Prinary $ 10f N/1 N/1 Yes Tes I Dir 1 P601 iNOV104 ~ 112 Cont ainaent t21-FO Isolation -F005 CSL F074 2DERallOV120, Prinary BIOgI N/A Yes Yes I Dir 1 PR73 131 Containaent Isolation-DER haendaent 14 3 of 18 Octohet'984 Qiae Rile Point Onit 2 FSlR TBBLE 421 36-1 (Cont) SWEC/ Paraaeter Reg. Guile 1.97 ~~ae RX 'er. 3 Ses~s~ ~vali ttaatioa Dl saves Display CE-NED g~~l 9 Racy,&ion tarinhXQ, ~QQi,fian&onha ~ocatgon ggsfg~ flRSe SQf s~c Enrjrgnaegtag Cgass ~Su 81L Location Notes 2DEB+HOT119D Priaary B10g2e 1 Q/1 H/1 Tes Tes I Dir 2 P873 130 Containaent Isolation-DER 20FR+HOT120i Priaary 810h1 1 Q/1 Q/1 Tes I Dir. 1 P873 139 Containaent Isolation-DFR 2DFBahOT121 ~ Priaar y B10h1 1 Q/1 Q/1 Tes Tes I Dir. 2 F873 140 Coataiaaeat Isolation-DFR 2FPQ+SOT218 Prisary Containaeat $ 10)1 1 Q/1 Q/1 Tes Tes I Dir. 1 P849 36 220 Isolatioa ve FPQ 2FPQ+SOT219i Priaary $ 10)2 Q/1 Q/1 Tes Tes 1 Dir 2 P849 36 221 Coatainaent Isolatioa-FPQ 2FQSeHOT211, Priaary 810k1 Q/1 Tes Tes I Dir 1 F603 Contaiaaent 2"F0651,$ Isolation-B FQS w 21esalOT231> Priaary $ 10k2 1 Q/1 Tes Qo II Qon-1E P603 8 Coataiaseat 22-F0321,$ Isolation ee 8 FQS HgSVXSOVI&6 pa~ggV a~rso4.-~ ~ ~/w y~ YEs DiV l Pbo3 2HCSaHOT11, Priaary 810L1 1 Q/1 ~ Tee Tes I Dir. 1 'P873 21D31p41 ~ Containaent 51,61 Isolatioa va RCS 2HCSaHOT1BD Pri nary B10L2 1 Q/1 . Q/1 Yes Tes I Dir. 2 P875 28 ~ 38,48 ~ Containal nt 58'$ Isolatioa-HCS laendaent 14 4 of 18 October 1984 Nine Bile Point Unit 2 TSAR TABLE ¹21.36-1 (Cont) SNEC/ GDDPB 2 g Parasatar ~p Reg. Onide 1.97 ~ Rev. 3 BBBnttp I ppacrgpttkr pa~b+e c+BBitjgcatioa Location instr Oualification iianga Seisaic Qh Environaental Class Pover ~Su Display ply Location Notes 2IASvSOV 16¹, Priaary B10s1 1 Yes Yes I Div 1 F601/ 38 166,167, 168 Containaent P851 Isolation-IAS 2IASvSOT165, Priaary 810s2 1 N/1 Tes Tes I Div. 2 P601/ 38 180, 184, 185 Containaent P851 Isolation-IAS 5 EOT121, 126, 136 Priaary Containaent B10n1 1 N/1 Yes Yes I Div. 1 P601 g 1¹3,16¹ Isolation- +AOV 156 ~ 157 ICS E51-F064 g P068P F013, F031B F019 ~ F080 ~ E5 1"'P065, F066 2YCSvhOV128, Prinary B10n2 1 N/1 Tes Tes I Div. 2 P601 1¹8,170 Containaent E51-P063, Isolation-F086BF076 ICS 2LNSvSOV153, Priaary B10pl 1 Ies Yes I Div 1 F873 157 Cont a in ae nt Isolation-LHS I 2LBSeSOT152, Priaary B10p2 1 Yes Tes 1 Div 2 P875 156 Containaent Isolation-LNS 2 SvhOV112, Priaary 810q1 1 Tes Yes I Div 1 P602 Zr)B Containaent a22 a/i Zsoiatioa-tFOI9 llS FO68 2hSS~HIV7A ~ r nary 8102j2 1 N/1 N/h Tes Tes RPS P602 B,C,D Containaent Div. 1 822-F0281,8, Isolation-CP D NSS laendaent 14 5 of 18 October 198¹ Sine Sile Point Unit 2 FSLR 421.36-1 (Cont) TABLE Guide 1.97, Rev. Reg 3 Se sor ua ification Oh Povor Dis la Location Instr n ~ nanae,a, seisaic pnrironaentall class sunplr nRr Location NotQS 2HSSaHOV 111 Priaary 810q3 1 N/A 8/A Yes Tes I Div. 2 P602 822-F016 Containaent Tsolation-HSS 2NSSaSYV61, Priaary 810q4 Yes Tes I RPS F602 Bf Cf D Containaent Dir 2 822-F0221,8, Isolation Cf D HSS C51-8004hf 8, Priaary 810r 1 R/h II Won-1E P607 10 C,D,E Containaent Isolation-RHS 2RCSaSOV651, Priaary 810s1 1 Tes Yes I Div 1 P602 8;661 ~ 8; 67A, Containaent B;fttR.BB Zsotattot 2RCSaSOV RCS 835-tO20 l05 2RCSvSOV79hf Priaary 810s2 1 Tes Yes I Div 2 P602 8;801,8;811, Containaent 8;82A ~ 8 Isolation-2RCSiSO RCS 835- PO19 IOQ 2RHSa V11, Priaary 810t1 W/h Tes ~ Tes I Div 1 P601 151, 251,2 301 331 1,,241, Containaent Isolation-RHS 401 '71f 104, 113;&tfotIIbRf 394 812- P004 a, t0161, t04 P0421, P017hf t0741 f gQ7gg F1051,P0271f POSOAf P A P0991, F023,F008 of October 1984 haeudaen t 14 6 18 Nine Nile Point Unit 2 YSAR TABLE 421. 36-1 {Con t) heg Guide 1.97, Rev. 3 SMHC/ I Paraneter PgrRgetllg Descrintion Variable Classification gocgtion Sensor ualification h Pover Dis l GE-NED D 4 Instr,PR~e Seissic Environnental Class SuRplI Location Notes 24ItS C 2RHS+NOV18 Prinary 810t2 1 N/A Yes Yes I Div 2 P601 1C. 158;/gpss Co ntainaent 258; Isolation 268;278;3081 RH 67+ 338; E12- FK048 408;112t W~ICg,g 'AJIOV 3'PB C; FO 68; 1 F04;F0428,C F0178;P0748; P07 8;F1058,,POSOB; F0998; F009 FOZ7 g FOr~ tt 2SAS~V160, Prinary 810ul lt/h N/A Yes Yes I Div 1 P851 161 Containaent Isolation-SAS 2SAS V162, Priaary 810u2 1 N/A N/A ~ Yes Yes I Div 1 P851 163 Containaent Isolation-SAS 2SLSi'NOVSA Prinary 810v 1 tt/A N/A Yes Yes I Div. 1 P601 C41-F006A Containnent Isolation-SLS 2SLS+NOV58 Priaary 810v2 1 N/A N/A Yes Yes I Div 2 P601 C41-FOG+ Containnent Isolation-SLS 2MCS~NOV112, Priaary 810vl' N/h Yes Yes I Div 1 P602 200QLC Containaent G33-F004, Isolation-P040 MCS 2 MCS ~ NOV 102 Priaary 810v2 1 N/A N/A Yes Yes I Div 2 F602 G33-F001 Containnent Isolation-MCS hnendnent 24 7 of 18 February 1986 Nine hile Point Unit 2 FSAR TABLE a21 36-1 (coat) S 1FC/ Paraaeter Reg. Guide 1.97 I'a eter 'ev 3 smsyg ~y~2222222L ql !oeae rlsrlay Cg-IIEg IiD. A DescIgptgon Varlabge CgassificattjoR Eaci~~an Xnaar~aam 2ri222S 2n22Xaairn2u Slam 2mrlZ ~w2laa 2RBS-CAB 170 Containaent C13 Naia Stack Tsotopi No Tes IT Non>>lE P882 39 Effluent Enclosare 1 10'} Radioactivity aci/cc 2PRS-CAB180 Ef fluent Radioactivity Cla turb Bldg Isotopic Turb oper No Tes II Non-1E P882 (UPS) vI 2~-FTtA,B hain Feedvater C33-N001A,B Flov -A,B Floor aci/cc Turb Bldg Turb Bldg 0-8.5 No 'o II Non-1E P603 lbs/hr (each) 2CNS LT8A ~ 8 Condensate D2 Cond Stor 0-500 No IT Noa-1E F851 Storage Tk TKtA,TKtB K gal Level - AD 8 . (each) 2RRS+FT6 ~ A Suppression D3a Rx Bldg 0-850 gps Yes Tes I Dir 1 P601 E'IZ-N09IH Chaaber (Sec Spray Contat) Header Flov - A '2RRSeFT6aB Suppression D3b Rx Bldg 0-a50 gpa Yes Tes I Dir 2 F601 &z-~09Ia Chaaber (Sec Spray Contat) header Flov - 8 See Note 18 Dryvell Da t8rs1 Pressure See Note 19 Suppression D5 Water Level (Weir Well) 2CBSATE67A ~ Sappression D6a Suppression 50- Tes Tes I Div- 1 F601 20 ~ a1 68Ar69Ar70A Pool water Pool 250aF Teap-A 2CRS +TE678 ~ Suppression D6b Sappressipn 50- Yes Tes I Dir. 2 F601/ F598 20rat ) 2l 68B ~ 698,708 Pool Water Pool 250aF Teap-8 Aaendaeit 26 10 of 18 hay 1986 Nine Bile Point Unit 2 FSLR TLBLE 421 ~ 36-1 (Cont) Guide 1.97, Rev. SQEC/ QC~ro Zap ~ Sarasatsr Reg QtioCj~Cot Va~@% ~srt~~s~ Cr~~ss r kaat,on 3 Joe~at on Sensor ~ualification Oh Pover Display Instr~PaRge Seisaic Environaental Class S~uRly Location Notes 2chSWE101 Dryvell D7a 2 Dryvell 0-400oF Tes Tes I Div. 1 F873 20, 41 J zc tbru Ltaos 8 inc 109 Teap - L 2CBSaTE116 Dryvell D7b Dryvell 0-400oF Tes Yes I Div 2 P875 20, 41 tbru Ltnos 8 inc 124 Tenp B 2RHSaFT63L Dryvell D8a Rx Bldg 0-7,950 Yes Yes I Div. 1 p601 EIZ-nlo9~ Spray (Sec gpa Header Contat) Flov L 2RHSaFT63B Dr yvell D8b Rx Bldg 0-7,950 Tes Tes I Div 2 F601 QZ-/VO9gS Spray (Sec gpa Header Contat) Flov - B 19 See Note 19 hain Steaa D9 Line Isolation Valve See Note 19 Leakage Control Systea Press 2SV V ZT220 Priaary D10a 2 Lcoustic Yes Yes I Div 1 +SV-VP 140 237 Safety Sensor on Belie'f Tail Pipe Valse (18 total) Position 2ILSaPT181 Priaary D10b 2 Rx Bldg 0-250 Tes Yes I Div 1 >601 Saiety (Sec psig Relief Contat) Valve LDS Header Pressure-L 2ILS+PT230, Priaary D10c 2 Rx Bldg 0-200 psig Yes Tes I Div. 1 P601 231 ~ 232 Safety (Sec Relief Contat) Valve-LDS Tank Pressure 11 of 18 hay 1986 haendaent 26 Nine Bile Point Unit 2 FSAR TABLE 421- 36-1 (Cont) Peg. Guide 1.97, Pev. 3 SQEC/ Paeaaetet mesc};$ 8fioB Zagda~e 06 Sensor ~Hali fication Qh Pover Dxsplay Seisaic Envigonaental Class S~uRly 1.ocation Notes VB~bgg C~Bss~liczLtiioq LacBfioB e 2SLSiPT113 SACS Flov D17 2 Rx Bldg 0-86 gpa Tes Tes I Div. 1 F601 6'~7-6007 (Sec (Contat) 2SLSaLT103 SLCS D18 Px Bldg 0-100 000 Tes Yes I Div- 1 F601 C41-N001 Storage (Sec Gal Tank Contat) Level See Note 22 RHR Systea D19 22 See Note 22 tlov 2RHSaTE13A RHR Heat D20a Rx Bldg 0-6000F CS CS eoa-16 P601 E12-Q0271 Exchanger (Sec Outlet Contat) Teap - 1 HO AIO 28RSaTE138 RHR Heat D20b Ba Bldg 0 600eP gQ ggl J! C77 ~a Boa-10 P601 E12-N0278 Exchanger (Sec Outlet Contat) Teap - 8 2SMPaTE311 Cooling D21a Screen- 35-1304P Tes Yes I Div 1 P601 20 Qatar Teap veil Bldg to ESt Systea Coaponents - 1 2SQPaTE318 cooling D21h Screen- 35-130oP Tes Tes I Div 2 P601 20 Mater Teap veil .Bldg to ESP Systea Coaponents - 8 2SQPatT131 Cooling D22a Rx Bldg 0-10 F 000 Tes Yes I Div 1 P601 23 E12-10071 Mater Flov (Sec gpa to ESP Systea Contat) Coaponents - 1 Bq 2SQP+FT1@ Cooling D22b Px Bldg 0-10,000 Te's Yes I Di v 2 F601 23 E 12- N 0 07I)I) Mater tlov (Sec gpa to ESP Systea Con tat) 8 Coaponents - 8 Aaendaent 26 13 of 18 Nay 1986 Nine Rile Point Unit 2 PSAR TABLE 421.36-1 (COnt) Beg. Guide 1.97, Rev. 3 ualific tion A Pover Display Seisaic environRental Class SuDD Locdtion Votes 2SVn+PT76A Cooling D22c Diesel 0-860 gpa . Tes Tes I Dir 1 P852 Mater Plow Gen. Bldg to ESP Systea Coaponents-Dir~ 1 Qp f)gg F7748 2SVP Cooling D22d Diesel 0-860 gpa Yes Tes Dir 2 P852 Mater Plov Gen. Bldg to ESP Systea Coaponents-Dir 2 DSL 2SVP+PT535 Cooling D22e Diesel 0-650 gpa Tes Tes I Div 2 P852 Mater Flov . Gen. Bldg to ESP Systea Coaponents-Dir. 3 DS1 2LVS-2A, B,C; High Radio- D23 Bad vaste 0-100% Ro II Ron-1E LVCS 26A,B;276'=tirity Bldg Coaputer 280 Liquid Graphics 'tank Level 2H VF ~ AOD 1A ~ Eaerqency D24a Rx Bldg M/A Tea Yes I Div- 1 P 870 6A ~ 9Ag 10A Ventilation (Sec Daaper Contat) Position 2HVR+AOD'1B~ Eaergency D24b Rz Bldg B/A Tes Tes I Dir. 2 P871 68.9B,10INI Ventilation {Sec ~e Daaper Contat) Position Status of D25a 2BTSe 0-150 vdc Yes Yes I Div 1 P852 Stdby Pwr SQG002A Sources-Battery Voltage-2BYSiE/E1A Status of D25b 2BTS~ -2000 to Yes Yes I Dir 1 P852 Stdy Pwr SMGO 3000 aaps Sources- z Battery Current Anendaent 14 14 of 10 October 1984 Nine Nile Point Unit 2 PSAR TABLE 421.36-1 (Cont) Reg Guide 1.97, Rev. 3 Qaa1 if ication QA Pover Display Seisvic Enrironveatal Class SunBlv Location Notes Status of D25c 2BYS~ 0-150 rdc Yes Yes I Dir. 2 P852 Stdby Pvr SNGO Sources- 2. Battery Voltage - 2 2BYS+E/E1f S Status of D25d 2BYS4'2000 to Tes Tes. I Dir. 2 P852 Stdby Pvr SVG0028 +2000 Sources- a%ps Battery Current - 2 ZCES+ZPHL Vl'I Status of D25e 0-150 vdc Yes Yes I Dir. 3 9852 Stdby Pvr Sources-Battery Voltage - 3 ZCES&ZAVLOl'I 2BTSoE/E 101 Status of D25f -100 to Yes Tes I Div 3 P 852 Stdby Pvr +100 aaps Sources-Battery Current - 3 8sta Status of D25g 0 to 120 Tes Tes I Div 1 PP52 Stdby Pvr OPS21 vac Sources-UPS Voltage - 1 Pfk N/R Status of 025I1 0 to 250 Tes Tes I Dir. 1 N/1 Stdby Pvr UPS2A asps Sources-OPS Current - 1 ~VS+< N/R Status of 025$ 0 to 120 %ps Yes I Di.r. 2 o852 Stdby Pvr OPS28 vac Sources-UPS Voltage - 8 ~V&St 8/R Status of D25t 0 to 250 Yes I Div. 2 N/1 Stdby Pvr UP~ aaps Anendnent 15 of 18 October 1984 Nine Nile Point Unit 2 FSAR TABLE 421 36-1 (Cont) Reg Guide 1.97 ~ Rev 3 SNEC/ Paraaeter paraSeanS sensor QaalLfgcatlon QA Pover Display CE=NED lahk Descrintion VRAQRbgR ggyggigicRggon f,ocRtion gnsgg~pRRRe Seigoic EnvjgonaRntal Cgass S~uRlI Location Notes Sources-UPS Current - B pe N/R Status of D251 2 2EJS1 0 to 750 Tes Yes I Div 1 2EJS+051 25 stdby Pvr vac Sources-600V Svgr Voltage K/R Status of D25a 2 2EJSa 0 to 3,000 Tes Tes I Dir. 1 N/A 26 Stdby Pvr XlkiB aaps Sources-6QQV Svgr Current Status of D250 2 ~ 2EJS+ 0 to 750 Tes I Div 2 2EJS+US3 25 Stdby Pvr US3 vac Sources-600V Svgr Yoitage Status of D25p 2 2EJsr 0 to 3,000 Tes Tes I Div 2 N/A 26 Stdby Pvr X3A,B as ps Sources-60QY Svgr Current Status of D259 2 ~$ 145 lOI 0 to 4 16 Tes Yes I Dir 1 9852 25 Stdby Pvr kr Sources >> 4 kY Svgr Voltage N/R Status of D25r 2 g~ lb f 0-1000 YBS Tes I Div. 1 9852 27 Stdby Pvr aap Sources - 4 kV Diesel Svqr Current feed or 1,500 aap noraal and alt feeds Aaendaeat 14 16 of 18 October 1984 Nine Nile Point Unit 2 FSAR Th BLE 421. 36-1 t Con t) Reg. Guide 1.97, Rev. 3 SMEC/ Paraaeter Pagasgter Senso Qualif icatioa ~ Qh Pouer Disnlay G E-QPP I,g,i, Qescgiption Vgriyblg Cjewsgficatiog location instr. Range Seisaic Pnvironsental Class Shpply Locati Notes H/R Status of 025s 2 0 to ¹.16 Yes Yes I Div. 2 'nA52 Stdby Pvr ZEAS+ Swatch kv Sources - 4 kV Svgr Voltage H/R Status of D25t 2 0-1,000 asp Yes Yes I Div. 2 P852 27 Stdby Pvr 2 '/S+S WQ l09 Diesel Feed Sources- 0-1,500 asp 4 kV Svgr noraal 6 alt Current feeds H/R Status of D25u 2 CQb 0 to 4.16 Yes Yes I D iv. 3 P852 25~40 I >~ Stdby Pvr ZErVS AsoV4/~ kv Sources - ¹ kV Svgr Voltage N/R Status of= D25v 2 ~ @/I 0-600 aap Yes Yes I Div. 3 985'2, 27,40 I ~i Stdby Pvr Diesel Feed Sources - 4kV 0-1,500 anp Svgr Current norsal 8 alt feeds See Note 28 Status of D25v 2 28 Stdby Pvr Sources-Air for ADS 2$ NS+RElhiC Prisary E1a Dry veil 1-10v Yes Yes I Div 1 9889 Containsent R/hr Area Radia-tion High Rng 2RNSi RE18 ~ D Prisary Elb Dryvell 1-10v Yes Yes I Div 2 F880 Containaent R/hr Area Fadiation High Rng See Hote 29 Secondary E2 2 29 Containaent brea Radia-tion See Note 30 Vital brea E3 See See HO II Hon-1E Badn Computer Radiation Note 30 Hote 30 30'1'nendaent 24 17 of 18 February 1986 0 Hine Hile Point Unit 2 PShR TABLE 421.36-1 (Cont)
- 2. One feedwater pump tripped condition 68 percent NBR at 1,021 psia.
Rev 2) . 7 Dryvell suaps are aonitored via suppression pool level instruaents (paraaeters C7a and b) after an accident
- 6. Paraneter not aeasured or aonitored in accordance vith BUR Ovners Group's position that BUR core theraocouples are ineffective in a BUR core because of thernodynaaic considerations (position based upon Regulatory Guide 1.97 ~
>o. 11. Tr >ears>a> ~qcore~r~o>e ( >sse~slies> Paraaet r saae as paraaeters 86a and b. ~l ~Q.a~~geggg ( g-~~ Q h ))P Gd4.'J~W QHKS+~Egg4, Q(
- 8. Upper range of instruaent covered by variable 8.7.b.
- 9. Testable check valve, outboard of containaent.
17 Paraaeter saae as paraaeters 87a~ b, and 89a, b. Overlapping of ranges is required to neet the regulatory guide.
- 12. Paraaeter saae as paraaeters E1a and b.
- 13. Unit 2 has a Hark II containaent. During a LOCk the suppression pool serves as a suap because the outside (of containaent) holding tanks are isolated.
- 14. Bottoa of ECCS suction line is 192 ~ . Suppression pool H.Q.L. is 200>.
- 15. Paraneter sane as paraaeters 87a and b.
- 16. Paraaeter sane as paraaeters 86a and b.
haendaent 17 18a of 18 Janus ry 198"> TP,ScE +g ) >( -l & u< j ~4~ ~++4 ~ ~~ ccw74Pv ~M M p~y~~~~ SEWER, CM58D gpgyg A~sl wzoV97~,4~, ~ WHf'f8~ DWi& ~HE g, pd~~~~yrusgg VWVZ5 ~Crt VA.vga r8A Mm vM @04M /~Wr. Wwn" o~Wyvog EXCEPT Du&'rVCr SrrPC7aP MD 4ffCC7Ceefn/ M. gu4/h/Q )OEZigg5'P OPSC+rZO& e) W ~CCr>TED Wkw'~ w/V~ ZH'RI~() ~wrac~ ypavz (znss+id7V SA, B,C, oe 0) C~as'~ wdinl sr'~ Dukw Ltrv'E'A.vE5'wS+SevflR,',C, 4) Mg p/d 7 r 4w+R y'4MPPiNwgiv 7 XS'o<+770rv'dc, vga'. Nine Mile Point Unit 2 FSAR QUESTION F421.39 (7.6) Section 7.6.1.2 of the FSAR discusses the interlocks on t)i~ LPCI and LPCS that are provided to prevent overpressurization of these low pressure systems that interface with the reactor coolant system. The FSAR states that the LPCI and LPCS discharge valves are prevented from opening until differential pressure across the valves is low enough to prevent system overpressurizations. I t is t)>e staff's concern that for a small break event the LPCI/LFCS pumps will quickly develop a discharge head sufficient to satisfy the permissive even though the reactor vessel pressure can still be at normal operating pressure. A single failure of the downstream check valve could then conceivably result in a LOCA outside containment. It is the NRC staff's position that redundant protection against overpressurization of the low pressure ECCS systems be provided in accordance with the provisions of Bran h Technical Position ICSB 3. This may be satisfied at Nine Mile Point - Unit 2 by modifying the current design such that the 'motor operated valves that interface between the low pressure ECC systems and the reactor coolant system are interlocked to prevent opening unless the reactor ve."..".~l. pressure is lower than the design pressure of the sy"tems involved.
- 18. Paraneter sane as paraneters B9a and b.
- 19. Paraaeter not applicable to Unit 2.
- 20. Instruaent range aeets intent of the regulatory guide 21 Unit 2 utilizes HPCS in lieu of HPCI
- 22. Paraaeter sane as paraaeters D16a and b.
- 23. Services RHR heat exchangers.
- 24. Services eaergency diesel generator sets Rote that flov is aeasured froa diesel vs to diesel.
- 25. Bus voltage is aeasured.
- 26. Paraaeter consists of tvo signals: noraal and alternate feeder current (individual inputs) .
- 27. paraaeter consists of three signalss noraal, alternate, and diesel feeder current (individual inputs) .
RESPONSE
The existing differential pressure transmitter will )ie utilized. T e ressure top c tion of this
s transmittex: ill,be change vessel ressure transm'er wx specifxe <o' an (88 psid for IPCS and 130 psid for LPCI).T off an existin rea ssive setpoint zn the Technical Specifications This change is shown on revised Figures 5.4-13 (LPCI) and 6.3-7 (LPCS), an~) is described in revised Sections 7.3.1.1.1.3 and 7 3.1.1.1.4.
~ This will ensure that t)ie injectirn val.r~would not receive a permissive signal to open w)e'en t)i~ reactor pressure is above design pressure of the low pressure ECCS piping.
Nine Mile Point Unit 2 FSAR TABLE 430.50-1 (Cont) A discussion of each segment follows. Diesel En ine and DSA Skid The engine-mounted piping and components of the fuel oil, engine cooling water (except heat exchangers which are designed to ASME Section III, Class 3), starting ai r, and lubricating oil systems are seismically qualified to Category I requirements as part of the diesel engine skid. These systems, furnished with the engine, are the standard systems developed by the engine manufacturer in accordance with DEMA standards and have a long history of service and reliability. These systems, piping, and components are designed, fabricated, inspected, installed, and tested in accordance with the requirements of ANSI B31.1. To meet the intent of ASME Section III requirements for the engine and DSA skids, the pressure test will be performed using ASME Section III, Class 3, hydrostatic parameters. The skids are qualified to seismic Category requirements. Piping over 4 in, (6-in lines between the cooling water heat exchanger, expansion tank, and engine block) will be liquid penetrant examined prior to preoperational testing. Furthermore, the expansion tank will be hydrostatically tested at 1.5 times its design pressure.~~ Diesel Oil Stora e and Da Tanks Su lied b the Fabricator These components are ASME Section III, Class 3. Pi in and Com onents Connectin Skids The fuel oil piping up to the diesel engine skid and the cooling water system piping and components up to the diesel engine heat exchanger are designed, fabricated, inspected, installed, and tested in accordance-.with ASME Section III, Class 3 requirements. The piping connecting the diesel fuel oil storage and day tanks is designed to ASME Section III, Class 3. The piping connecting the DSA skid to the engine skid is designed to ANSI B31.1 and is gnated seismic Category I. H drostatic testin of 1.5 times design pressure will be accomplished during onsi e testing of the auxiliary systems. Essential components of the air starting system are designed to ASME Section III. The system is classified Safety Amendment 13 2 of 3 August 1984
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