Calculation EC-059-1041, Suppression Pool Ph Post Loca.

ML060120421
Person / Time
Site:	Susquehanna
Issue date:	09/20/2005
From:	Richard Anderson, Capiotis M, Waselus M M Susquehanna
To:	Office of Nuclear Reactor Regulation
References
PLA-5963 EC-059-1041
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NUCLEAR ENGINEERING CALCULATION COVER SHEET NEPM-QA-0221-1

1. Page 1 of 77 Total Pages 77>2. TYPE: CALC >3. NUMBER: EC-0591041

>4. REVISION:

1*>5. UNIT 3 )>6. QUALITY CLASS: Q>7. DESCRIPTION:

Suppression Pool pH post LOCA 8. SUPERSEDED BY: 9. Alternate Number: 10. Cycle: 11. Computer Code/Model used: 12. Discipline:

M>13. Are any results of this calculation described in the Licensing Documents?

s Yes, Refer to NDAP-QA-0730 and NDAP-QA-0731 0 No>14. Is this calculation changing any method of evaluation described In the FSAR and using the results to support or change the FSAR? (Refer to PPL Resource Manual for Definition of FSAR)3 Yes, 50.59 screen or evaluation required.

E No>16. Is this calculation Prepared by an External Organization?

ED Yes El No EG771 Qualifications may not be required for individuals from external organizations (see Section 7.4.3).>16. Prepared by: Michael Waselus ) .6/J/0S Print Name(EG771 Qualification Required) ignature Date> 17. Reviewed by: Ronald Anderson Print Name(EG771 Quallfication Required)

Signature MDale>18. Verified by: Ronald Anderson Print Name(EG771 Qualification Required)

Signature bate>19. Approved by: Milt Capiotis efl6E al 165/b Print Name(Qualifed per NEPM-QA-0241 and Siglature Date comply with Section 7.8 of NEPM-QA-0221)

>20. Accepted by: Romka V VOWa~t.Sn 91201te Print Name(EG 771 7 lf~o Required) and't ;S comply Wth Section 7.9of NEPM-0A-0221 Dc.l4rt ADD A NEW COVER PAGE FOR EACH REVISION IReCCARRf Vrifed Fields FORM NEPM-OA-0221-1, Revision 8, Page 1 of 1. ELECTRONIC FORM _ p..IRU RED FIELDS I. l.r I I ADD A NEW COVER PAGE FOR EACH REVISION II'4Uk.;Lt:AH RFr. !z1felveriftedfields 1

Page 2 CALCULATION REVISION DESCRIPTION SHEET NEPM-QA-022

1.2 REVISION

NO: I CALCULATION EC-059-1041 NUMBER:l FULL REVISION E SUPERSEDED l PAGE FOR PAGE U VOIDED A R R Revised d R o Description Pages d Revision on the Listed Pages All U 0 n Complete calculation revision of all pages due to page renumbering.

U U O Specific revision I changes are itemized as follows to aid in the review of Revision 1.2 ED O U Add Calculation Revision Description Sheet.3 0 U O Add Technical Change Summary Page.5 U 0 Add Revision I purpose.6 El 0 Add Revision I results & EPU assumption.

Clarified ESF leakage__ assumption.

Added EPU note to design input 5.7 U 0 U Clarified SLC tank volume (design input 7) is available volume above pump suction shutoff level.10 U 0D U Add EPU changes for hydriodic acid.12 U E D Add EPU changes for nitric acid.15, 16 El 0 O Correct gamma equation; Add EPU changes for drywell doses.16 U 0 Add EPU changes for hydrochloric acid (HCI) for beta radiation.

1 8 U 0., U Change Rev. 0 & Add Rev. I EPU HCi for gamma radiation.

19, 20 U 0 UO Correct CsOH equation and Rev. 0 results &, add EPU changes.20, 21 U 0 U] Update Rev. 0 & add EPU changes for summary of acids & bases.22 U 0 El Update Rev. 0 unbuffered pool pH values.23 U 0 U Add EPU changes for unbuffered pool pH.25, 26 U 0 O Update Rev. 0 & add EPU changes for final pool pH values.27 U 0 U Update Rev. 0 & add EPU results. i 28 U 0 fl Added References 17, 18 and 19 and Technical Specification Bases B3.1.7 to Reference 12.FORM NEPM-OA-0221-2.

Revision S. Page I of I ELECTRONIC FORM_ _ s _ _ _ z X _ _I 146 IU 1 Li U AadealKeterencesiI,1ixand 1Y and lechmcal Specitication I I IRskc,-c'R' 1 XtnRF-ferert-I?II Page 3 TECHNICAL CHANGE SUMIARY PAGE NEPM-QA-0221-5 Calculation:

Number: EC-059-1 041 Revision No. 1 This form shall be used to (1) record the Technical Scope of the revision and (2) record the scope of verification if the calculation was verified.

It should not be more than one page. Its purpose is to provide summary information to the reviewer, verifier, approver, and acceptor about the technical purpose of the change. For non-technical revisions, state the purpose or reason for the revision.Scope of Revision:

The scope of this revision is to update the calculation to include the effects of extended power uprate (EPU) conditions on the post LOCA suppression pool pH. The main effect of EPU is an increase in the radiological doses used for radiolysis in the suppression pool and the electrical cables and changes in the total core inventory of iodine and cesium due to the increase in the core thermal power from the Revision 0 analyzed power of 3616 MWt to the proposed EPU power of 4032 MWt.Scope of Verification (If verification applies):

This verification is a review of the technical changes of Revision I and the format of the entire document due to the renumbering.

FORM NEPM-QA-0221-5, Revision 0, Page i of 1, ELECTRONIC FORM FORM NEPM-QA-0221-5, Revision 0. Page 1 of t, ELECTRONIC FORM PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6106/2n5 Suppression Pool pH post LOCA Calc. No. EC-059-1041L Designed By M. Wasclus Sh. No. 4 Checked By R. Anderson TABLE OF CONTENTS 1.0 OBJECTIVE

.............................................

5

2.0 CONCLUSION

S AND RECOMMENDATIONS

........................................

5 3.0 ASSUMPTIONS I INPUT .........................................

6 4.0 METHOD .........................................

7 4.1 Hlydriodic Acid ...........................................

8 4.2 Nitric Acid .........................................

10 4.3 Hydrochloric Acid ........................................

.12 4.4 Cesium Hydroxide

........................................

.18 4.5 Summary of Acid and Base Production

................

.. ......................

20 4.6 Sodium Pentaborate

-Suppression Pool Buffered pH ..........

i .......................

24 5.0 RESULTS ........................................

27

6.0 REFERENCES

..........

28 Attachment I Cable Data ...29 Attachment 2 Cable Drawings ...32 Attachment 3 Email from R. Vazquies to M. Waselus SPp7Cond.xs

...75 PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA Caic. No. EC-059-1041 Designed By M. Waselus Sh. No. 5 Checked By R. Anderson 1.0 OBJECTIVE The purpose of this calculation is to evaluate the post LOCA suppression pool pH crediting the injection of a fixed quantity of sodium pentaborate into the pool via the Standby Liquid Control (SLC) system to assure the pool pH is maintained above a value of 7 within 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> (Reference 19). Maintaining the suppression pool pH greater than 7.0 post-LOCA precludes the need to consider iodine reevolution from the pool during the LOCA in calculating the potential offsite and control room radiological consequences.

This calculation is based on the methodology provided in NUREG/CR-5950 (Reference 1), NUREG-1081 (Reference

2) and NUREG/CR-5732 (Reference 3).Per NUREG/CR-5950 there are a variety of acids and bases produced in containment during a LOCA. These include the following:

• Boric Acid which is not applicable to a BWR and not considered any further herein.* Hydnodic Acid (HI) is a strong acid Introduced into containment with the release of iodine.* Carbon Dioxide (CO 2) which depresses the pH of water by being absorbed in water from air to form carbonic acid. Carbonic acid is a weak acid the effects of which are insignificant relative to the other acids produced during the LOCA. However, the initial suppression pool pH may be depressed below 7.0 during normal operation by the absorption of CO 2.Section 2.2.3 of Reference 1 states that pure water will attain a pH that approaches 5.65 due to the absorption of CO 2.A conservatively low pH is assumed as the initial condition for this evaluation and as such the effects of CO 2 are not considered further herein.* Nitric acid (HNO 3) is a strong acid produced by the irradiation of water and air.a Hydrochloric acid (HCI) is a strong acid produced by the radiolysis or pyrolysis of chlorine bearing materials during the accident.

Per section 2.2.5.3 of NUREG/CR-5950, pyrolysis occurs at temperatures around 752 OF which is well above the post LOCA temperatures (maximum drywell temperature

< 330 OF). Therefore, only radiolysis is considered in this analysis.* Cesium Hydroxide (CsOH) is a strong base introduced into containment with the release of cesium during the accident.* Core-Concrete Aerosols are basic materials released from the interaction of the molten core materials with concrete.

Consistent with the course of the postulated accident, core damage is assumed to be terminated after the in-vessel release phase and these chemicals are not considered any further herein.The purpose of Revision 1 of the calculation is to update the analysis for the effects of extended power uprate (EPU).

2.0 CONCLUSION

S AND RECOMMENDATIONS The results of the analysis demonstrate that with the injection of the Technical Specification minimum quantity of sodium pentaborate (13.6 weight percent), the 30 day suppression pool pH is greater than 7.0 which precludes the need to include reevolution of iodine from the suppression noni nnot I OrA ThA pfl0dlv sl mnnr.A.inn nnnl nH rpnrArntR the wnrRt rasp nH SI;Ih.rn1IPnt tn The results of the analysis demonstrate that with the in ection of the Technical Specification r--*~ ~ ~ ~ ~ ~ ~ ~~~neto of- the Tech-- -*r br---a ~ ~ -* ~~n

• PP&L CALCULATION SHEET Dept. 0341 Rad &Eff Tech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA Calc. No. EC-059-1041 Designed By M. Waselus Sh. No. 6 Checked By R. Anderson the injection of the sodium pentaborate early in the accident scenario, the pH in the pool will be greater than the 30 day value since the generation of the post LOCA acids reaches its peak values at 30 days.The conservative 30 day suppression pool pH calculated herein is 8.61 with credit for post LOCA CsOH production in the pool and 8.58 without credit for post LOCA CsOH production in the pool for a reactor power of 3616 MWt.The conservative 30 day suppression pool pH calculated herein considering the effects of EPU with a reactor power of 4032 MWt is 8.60 with credit for post LOCA CsOH production in the pool and 8.57 without credit for post LOCA CsOH production in the pool.3.0 ASSUMPTIONS I INPUT The following assumptions are used in this analysis: The impact of ESF leakage is small compared to the suppression pool volume and will be ignored since there will be continuous makeup to the pool to maintain water level.* The beta dose to cables is reduced by a factor of 2 due to localized shielding effects.* The gaseous HCI produced by cable radiolysis will be conservatively assumed to be instantly dissolved in the suppression pool.* Sodium pentaborate will be injected via the SLC system for pH control.* The suppression pool will be assumed to be well mixed by action of the ECCS systems such that a single pH value can be applied to the entire pool.The effect of EPU on this analysis is conservatively modeled as an increase of 25% in the radiation values used herein (See Reference 18, Item 10). The integrated radiation doses used in the radiolysis portions of this calculation are proportional to the core thermal power.The actual increase for EPU is estimated to be 11.5% [4032 MWtI3616 MWtJ which is bounded by the 25% assumption.

The following design input data is used in this analysis: 1. Minimum suppression pool pH during normal plant operation (Starting point for post LOCA pool pH transient).

2. Minimum suppression pool volume used in design basis LOCA.3. Quantity and timing of sodium pentaborate input to the suppression pool.4. Weight percent of chlorine for the various cable insulations.

5. Post LOCA Gamma and Beta dose rate profiles and energy flux in drywell, wetwell and suppression pool including values from isotopic deposition on surfaces.

In accordance with USNRC RG 1.183, section 1.3.5 and SECY-98-154, the TID-14844 Equipment Qualification dose rates previously calculated in the drywell air and suppression pool (beta and gamma)bound those generated by AST. The doses are increased to account for the higher EPU power.dose rates previously calculated in the drywell air and suppression pool (beta and gamma)

PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA Caic. No. EC-059-1041 Designed By M. Waseus Sh. No. 7 Checked By R. Anderson 6. Conservative values for the core inventory of cesium and core inventory of iodine in gram moles. These Inventories include the stable Cs-1 33 and 1-127 species.7. Standby Liquid Control Storage (SLCS) tank minimum available capacity : 4587 gallons (Reference 12). This volume is available volume above pump suction shutoff level.8. The SLCS tank is maintained between a temperature of 76 and 110 "F. (Reference 4, page 68).9. The concentration of sodium pentaborate in the SLCS tank 2 13.6 weight percent (Reference 12).10. The SLC system pump flow rate is ! 41.2 gpm @ a 1224 psig. (Reference 4, page 29).4.0 METHOD Through basic chemistry equations, the pH of a solution is directly related to the concentration of H4 ions by the formulas: pH = -log[H]pOH = -log[OH-1 pH+pOH=14-log[H] -log[OH= 14 or[HI [OH-I = 10'where:[H+i = concentration of H* ions (moles/liter)

[HO] = concentration of OH- ions (moles/liter)

The initial suppression pool pH assumed at the start of the accident is 6. This is a conservative value based on the actual pH history at SSES as seen on the following figure (Reference 16).

PP&L CALCULATION SHEET Dept. 0341 Rad & EffTech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA Caic. No. EC-059-1041 Designed By M. Waselus Sh. No. 8 Checked By R. Anderson Suppression Pool pH Combined SSES-1 and SSES-2 January 199D to October 2004____ I.i I .t A .j TS I__ j71 i{___6.T 02 6.3 64 6.6 6.0 6.7 6.0 .9 7 71t 7.2 73 7.4 7.1 7.1 2D2 15B This corresponds to a value of H' = I E-6 moles/liter

4.1 Hydniodic

Acid Per section 2.2.2 of Reference 1, hydnodic Acid (Hi) is a strong acid introduced into containment with the release of iodine, but small amounts are likely in containment.

Table I of USNRC Regulatory Guide 1.183 (Reference

5) indicates that 5% of the halogen inventory is released during the gap release phase and an additional 25% Is released during the early in-vessel phase. In accordance with Section 3.5 of Reference 5, 95%6 of the Iodine released should be assumed to be cesium iodide (Csl) 4.85% elemental and 0.15% organic iodine. The basis for this release was NUREG-1465, section 3.5 (Reference

6) Wherein it states iodine entering containment is at least 95% CsI with the remaining 5% as I plus HI, with not less than 1%of each as I and HI. This analysis will conservatively assume that all 5% of the release is in the form of HI in order to maximize the acid generation.

This release process is assumed to occur at a constant rate over the release period identified in Table 4 of Reference 5.LOCA Release Phases BWRs Reference 5 Phase Onset Duration Gap Release 2 min 0.5 hr Early In-Vessel Release 0.5 hr 1.5 hr LOCA Release Phases BWRs Reference 5

PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA Calc. No. EC-059-1041 Designed By M. Waselus Sh. No. 9 Checked By R. Anderson The core iodine inventory used in this evaluation includes stable 1127 to maximize the amount of acid produced.

Per Reference 7, the total core inventory of iodine is 107 gram atoms at the beginning of cycle and 228.7 gram atoms at the end of cycle. The value of 228.7 gram atoms is conservatively used in this analysis.

Note: For a monotonic element gram mole equals gram atom. The following equations are used to describe this release.During the Gap Release Phase: d/dt[HI] = [0.05

• 0.05mi] / [Vsp

• 0.5 hr]During the Early In-Vessel Release Phase: d/dt[HI] = [0.05 0.25miJ / [Vsp

• 1.5 hr]where: mi = gram mole iodine = 228.7 Vsp Suppression pool volume (liters) = 3.738+06 liters [132000 ft3]The volume of water in the suppression pool following a LOCA is conservatively assumed to consist of the suppression pool water volume at low water level plus the normal volume of water in the reactor coolant system. From Reference 8, the suppression pool low water volume is 122,410. ft 3 and is based on a low water level in the pool of 22 ft. The mass of water in the reactor coolant system is 610,000. Ibm. This mass is obtained from Reference 9, Table A28.1.The coolant water volume is conservatively based on a temperature of 70 OF.Coolant water volume = 610,000. Ibm / 62.4 Ib/t 3 = 9776. ft Pool Volume Post-LOCA

= 122,410 ft 3+ 9776 ft 3 = 132186 ft 3 (Use 132000 ft 3)Integrating the above yields: During the Gap Release Phase:[H11(t) = [miu I [200Vsp] * [t -tgrp]where tgrp = onset of the gap release phase = 0.0333 hr [2 minutes]During the Early In-Vessel Release Phase:[H11(t) = [miu / [120 Vsp] * [t -(0.5 + tgrp)] + [mi] / [400 Vsp]The final Hi concentration at t 2.033 hr [1.5 hr+0.5hr+2 min], the end of the iodine release from the core is given as: Thg~ fmnoI WI ,n'nrtinof 9 Ml'% hr ri A Fr.a&f Rhr49-' mini fh& aneI Mf #Km ininf redianen frmm PP&L CALCULATION SHEET Dept. 0341 Rad&EffTech.

PROJECT Date 6/06/2005 Suppression Pool pH post LOCA Caic. No. EC-059-1041 Designed By M. Waselus Sh.No. 10 Checked By R. Andezson[Hl](2.033 hr) = [(228.7) / (120*3.738E+06)]

• [2.033 -(0.5 + 0.0333)] + [228.71 /[400*3.738E+06]

1H11(2.033 hr) = [5.0985E-071

• [1.5] + 1.5296E-07

= 9.1773E-07 molesiliter or a total of 3.4 moles [9.1773E-07 moles/liter

• 3.7378E6 liters).where 3.7378E6 liters is the suppression pool volume.The core iodine and cesium Inventory for the EPU core is provided in Reference

17. Reference 17 provides the Inventory as grams. The value is converted to gram atoms by dividing each isotope by ts atomic number. The values are given as follows.Isotope grams gm atoms Isotope grams gm atoms Reference 17 Reference 17 1-127 6.349E+03 4.999E+01 1-129 2.842E+04 2.203E+02 Cs-133 1.857E+05 1.396E+03 1-130 1.352E+00 1.040E-02 Cs-134 1.780E+04 1.328E+02 1-131 8.633E+02 6.590E+00 Cs-1 35 7.869E+04 5.829E+02 1-132 1.513E+01 1.146E-01 Cs-1 36 1.008E+02 7.415E-01 1-133 1.963E+02 1.476E+00 Cs-137 1.994E+05 1.456E+03 1-134 9.244E+00 6.899E-02 Cs-138 4.882E+00 3.538E-02 1-135 5.990Ei01 4.437E-01 Cs-1 39 1.322E+00 9.509E-03 Total 3.591 E+04 2.790E+02 Total 4.817E+05 3.568E.03 The final Hi concentration for EPU conditions at t = 2.033 hr [1.5 hr+0.5hr+2 min], the end of the iodine release from the core is given as:[Hl](2.033 hr) = [(279)1 (120*3.738E+06)]

• [2.033 -(0.5 + 0.0333)] + [2791 1 [400*3.738E+06]

[1-](2.033 hr) = [6.2199E-07]

• [1.5] + 1.8660E-07

= 1.1196E-06 moles/liter or a total of 4.2 moles [1.1 196E-06 motes/liter t 3.7378E6 liters].where 3.7378E6 liters is the suppression pool volume 4.2 Nitric Acid Radiolytic production of nitric acid is discussed in section 2.2.4 of Reference I and section 3.3.1.1 of Reference

3. The nitric acid (HNO 3) is produced by the irradiation of water and air. Both references provide the following constant for nitric acid production based on experimental data.g(HNO 3) = 0.007 molecules/1 00ev where the relationship is based on radiation absorption in the aqueous phase. This value is based on a water temperature of 86 0 F, which is conservative for use following a LOCA since the solubility of nitrogen reduces with increasing temperatures.

Per PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/06(2005 Suppression Pool pH post LOCA Calc. No. EC-059-1041 Designed By M. Waselus Sh. No. I I Checked By R. Andemon Reference 1 section 2.2.4, the equates to a radiation G value of 7.3-E-06 moles HNO03 L Megarad which means H' and NO 3 increase by 7.3-E-06 moles for each Megarad of dose delivered to the suppression pool water. This is expressed as: d/dt[HNO 3] = 7.3E-06 moles HNO 3/ L Megarad

• DR(t)where: DR(t) = dose rate as a function of time in the suppression pool (Megarads/hr).

The suppression pool dose values are based on the integrated energy absorption in the suppression pool from References 14.Reference 14, Page 29 provides the integrated energy absorption in the sump (suppression pool)for a power of 3458 MWt (Reference 14, page 8). The values for 3E+6 seconds (34.7 days) are conservatively used for the 30 day dose required.

The values are: G+B Sump Iodine Sump 1 .575E30 ev 1.691 E30 ev Converting these energy depositions to Mrad yields the following:

11.575E30 ev + 1.691E30 evl 1 Mev/10 8 ev

• 1 erc/6.25E5 Mev

• IRad:gm/1 00 eras

• I Mrad/10 6 Rad *1 cc/am 3.7378E9 cc or 13.98 Mrad for 3458 MWt. The current power level being evaluated is 3616 MWt. The activity entering the suppression pool is taken as proportional to the power. Therefore, for the purposes of determining the quantity of nitric acid formed, a 30 day suppression pool integrated dose of 14.62 Mrad is applied [13.98

• 3616/3458].

These dose rates were determined using TID-14844 source terms. In accordance with USNRC RG 1.183, section 1.3.5 and SECY-98-154, the TID-14844 Equipment Qualification dose rates previously calculated in the drywell air and suppression pool (beta and gamma) bound those generated by AST. Therefore, It can be concluded that the dose rates calculated with TID-14844 are conservative and acceptable for use in determining the HNO 3 production herein.[HNO 3](t) = 7.3E-06 P DR(t) dt where t = time into accident (hrs)or the nitric acid produced at any point in time is given as[HNO 3 I(t) = 7.3E-06

• Integrated Dose at Time t.[HNO 3](30 days-suppression pool dose) = 7.3E-06

• 14.62 = 1.0673E-04 moles/liter.

or a total of 398.9 moles [1.0673E-04 moles/liter

• 3.7378E6 liters].where 3.7378E6 liters is the suppression pool volume.or a total of 398.9 moles 11.0673E-04 moles/liter

• 3.7378E6 litersl.

PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/0612005 Suppression Pool pH post LOCA Calc. No. EC-059-1041 Designed By M. Waselus Sh. No. 12 Checked By R. Anderson For EPU conditions this value is conservatively increased by 25% with the resulting 30 day suppression pool integrated dose equal to 18.28 Mrad 114.62 Mrad

• 1.251 and[HNO 3](30 days-suppression pool dose) = 7.3E-06

• 18.28 = i.3344E-04 moles/liter.

or a total of 498.8 moles [1.3344E-04 moles/liter

• 3.7378E6 liters].4.3 Hydrochloric Acid The radiolysis of chloride-bearing cable jacketing will result in the production of HCI vapor as documented in Section 2.2.5.2 of NUREG/CR-5950 (Reference 1). It should be noted that a significant portion of the HCI vapor produced from cable radiolysis would react with the metal components within the primary containment (e.g., cable trays, gratings, etc.) and never enter the suppression pool. However, for this analysis it is conservatively assumed that all of the gaseous HCI produced is immediately dissolved in the suppression pool water. A model for the production of HCI from cable jacketing is developed below based on the approach given in Appendix B of NUREG/CR-5950.

The absorption of a radiation flux at a radius, r, can be described from basic principles as: q (r) = v (Ro)e ,(Rr)p = Linear Absorption Coefficient (cm 1) from Table below.Ro = Outside cable radius (cm)Cable and Air Material Properties Reference 2 Density LinearAbs rption Coefficient Material (gm/cm-) Beta Radiation Gamma Radiation Hypalon 1.55 52.08 0.099 EPR 1.27 42.67 0.081 Air 1 0.0198 0.0000374 Similar to the approach in Reference 1, Appendix B, the production of HCI from radiolysis is given by: R = G (SA)(pA where: R = HCI production rate (gm moles/sec)

PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA CaIc. No. EC-059-1041 Designed By M. Waselus Sh. No. 13 Checked By R. Anderson G = Radiation G value for Hyalon (molecules HCI/100 ev)SA = Cable surface area (cm )p= Incident radiation energy flux (Mev/cm 2-sec)A = Absorption fraction of energy flux in Hypalon jacket.Radiation G value for Hypalon Note: The radiation G value for Hypalon adopted in Reference 1, Section 2.2.5.2 Is 2.115 molecules HCI per 100 eV. This G value is based on the energy absorbed by the polymer consistent with the footnote to Table 3 of NUREG-1081 (Reference 2). As described in Reference 2, this value represents a balance between the increased HCI production at elevated temperatures expected during accidents and the neutralization potential of fillers in the cable. The resulting value is 3.512E-20 moleslMev (Reference 1, page B.3). This term can also be expressed in terms of moles/Mrad (absorbed dose)-gm (exposed material).

3.512E-20 moleslMev

• 6.25E+5 Mevlerg

• 100 ergs/gm-Rad

• 1 E+6 Rad/Mrad = 2.195E-6 moles/Mrad-gm or 9.97E-4 moles/Mrad-lb.

This value is conservative compared to the value of 4.6E-4 moles of HCI per lb of insulation per Megarad listed in Section 2.2.5.2 of Reference I since it produces about 2.2 times more HCI per lb of exposed material.Absorption fraction of energy flux in Hypalon jacket The absorption fraction is the fraction of incident radiation energy flux absorbed by the Hypalon.As provided in Section 4.2 of NUREG-1081 (Reference 2), the factor is calculated with the following equation (Reference 2, Equation 4-5 -gamma and Equation 4-9 -beta): Ay,H = 1 -exp[-PyH

• tH]where: A H Absorption of incident gamma radiation guy -Linear adsorption coefficient

-gamma Hypalon (0.099/cm) tH = Hypalon thickness (cm)A I-H exp[-pr

• tHJ where: Apb H Absorption of incident beta radiation=,B Linear adsorption coefficient

-beta Hypalon (52.08/cm) tH = Hypalon thickness (cm)Using the above equations and values the following figure plots the radiation fluxes through Hypalon jacketing.

As seen essentially all of the beta energy is completely absorbed even by relatively thin Hypalon cable jacketing while very little of the gamma energy is absorbed.

In the subsequent analysis all of the beta energy will be assumed completely absorbed in the jacket.I Ubilly Lilt auuve equauurib emu viuens Ltle IUIIUWIlrg ,iureM putts Ue rauiatiun nuxes inrougil Hvn:41nn inri'atinn Al QPon ac~antinitl saIl nf tha hots onarnv ic rnmnlataki ahenrhoi auvon hit PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6106/2005 Suppression Pool pH post LOCA Calc. No. EC-059-1041 Designed By M. Waselus Sh. No. 14 Checked By R. Anderson 1.200 K IC C 0 C 4-U 00000 0 0.02 0.04 0.08 0.08 I.1 Cable Thickness (inches)0.12 HCI Generation The HCI generation can be calculated with the above equations as (See Reference 2, Equations 5-7 and 5-8 for gamma and Equations 5-10 and 5-11 for beta).Gamma: R = G (SA) vp A = G ' SA* Ey/V * [(1-exp(-pyair*r))/

pyeil * [11- exp (_pyH*tH)]

Beta: R G (SA) q A G SA

• EV '1/pp3air where: R HCI production rate (gram moles/hr)EyN Energy release rate / unit volume (Mev/hr-cc) gamma EON Energy release rate/ unit volume (Mevlhr-cc) beta PYH Linear adsorption coefficient

-gamma Hypalon air pyalr Linear adsorption coefficient

-gamma air r Distance of air to cable (cm) (252 cm).Un8fai Linear adsorption coefficient

-beta air SA Cable surface area (cm 2)tH Hypalon thickness (cm)G 3.512E-20 gram moles/Mev (Reference 1, Appendix B)tH Hypalon thickness (cm)I I ,

PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6106/2005 Suppression Pool pH post LOCA Caic. No. EC-059-1041 Designed By M. Waselus Sh. No. 15 Checked By R. Anderson Using the form for G in terms of absorbed dose [9.97E-4 moles/Mrad-lb (exposed material)], the total HCI generation from an integrated energy release is given as follows: Gamma: MHCI Beta: MHO where: MHO W t[1- exp(_py'H*tH)1 Jo DR dt G G

• W * [1- exp(-pye*tHW)Iot DR dt G

• W* JoDR dt HCI production (gram moles)Weight of cable jacket material (Ibs)Time (hrs)Fraction of gamma energy absorbed Integrated dose (Mrad)moles/Mrad-lb Using G in terms of absorbed dose (Mrad) replaces G (Ey/N) [(1-exp( -pyair'r)I pyai 2 I where the values were in terms of an incident flux and absorbed energy.The 30 day drywell doses are taken from Reference 10, Tables 2 and 3.Drywell Doses @ T = 30 days Dose (Rad) Dose (Mrad)Airborne gamma 8.19E+06 8.19 Plateout gamma 1.88E+06 1.88 Airborne beta 2.32E+08 232 Plateout beta 2.67E+08 267 Adjusting these values for EPU conditions using the conservative factor of 1.25 yields the following:

Drywell Doses @ T = 30 days ' Dose (Mrad) Dose (Mrad)

• 1.25 Airborne gamma 8.19 10.24 Plateout gamma 1.88 2.35 Airborne beta 232 290 Plateout beta 267 334 Due to the different attenuation properties of beta and gamma radiation they are addressed separately.

Beta: Beta:

PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA CaIc. No. EC-059-1041 Designed By M. Waselus Sh. No. 16 Checked By R. Anderson From Attachment 1, the total weight of cable jacket (assumed to be Hypalon properties) is 4855.42 lbs. Also as seen the jacket thickness in almost all cases is equal to or greater than the thickness required for the entire beta energy to be absorbed.The HCI concentration in the suppression pool is MHCI / Pool Volume (132000 ft 3 or 3.738E+6 liters) or[HCI] = G

• W* Integrated Beta Dose[HCI = 9.97E-4 moleslMrad-lb

• 4855.42 lbs 1/2[232 Mrad + 267 Mradl I 3.738E+6 liters[HCIQ = 3.2313E-04 molesll due to beta or a total of 1207.8 moles [3.2313E-04 moles/liter

• 3.7378E6 liters].where 3.7378E6 liters is the suppression pool volume and a factor of 2 reduction is taken for the beta dose due to self shielding effects.The HCI concentration in the suppression pool considering the adjustment for EPU conditions is MHC1 I Pool Volume (132000 ft 3 or 3.738E+6 liters) or[HCIJ = G

• W* Integrated Beta Dose[HCI = 9.97E-4 moleslMrad-lb

• 4855.42 lbs

• Y2[290 Mrad + 334 Mrad] / 3.738E+6 liters[HCI] = 4.0405E-04 moles/l due to beta or a total of 1510.3 moles [4.0405E-04 molesiliter

• 3.7378E6 litersl.Gamma: Unlike beta radiation, the gamma radiation can penetrate the cable interior and HCI may be generated by interior jackets on individual conductors in multi conductor cables.Based on a review of the various cable types listed in Attachment 1, a bounding cable type is developed to conservatively determine the potential HCI production.

A review of Attachment I indicates that type Q1 1 cable comprises about 45% of the total cable length and 57.9% of the total outside jacket mass. Based on the information in Attachment 2 for type Q0 1 cable the mass of internal Hypalon and EPDM insulation is determined where the properties for Hypalon are conservatively applied to the EPDM material.

The resulting Q11 insulation-jacket mass/ft is conservatively applied to the total length for all cable types from Attachment

1.

PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA Caic. No. EC-059-1041 Designed By M. Waselus Sh.No. 17 Checked By R. Anderson Approximate Representation of Type Q1 I Cable 0.06 in Hypalon jacket I0.0 in Hypalon/conductor 0.02 in EPDM Per Attachment 2, there are thirteen 20 gage conductors with 20 mils EPDM and 10 mils Hypalon each.Per Marks (Reference 15), diameter of 20 AWG conductor equals 0.032 inches. Therefore, the area of insulation-jacket/conductor is: rr[R 2 2 -R 1 2] = Tr[(0.046in/i2in/ft) 2 -(0.01 6in/1 2in/ft)2] = 0.0000406 19/conductor The total mass of insulation-jacket is conservatively estimated as: 13 conductors

• 0,0000406 ft2/conductor

• 96.7 lb/ft 3

• 79478 ft -4070 lbs.Where: 96.7 lb/ft 3 = density of Hypalon 79478 ft = total length of all cable from Attachment

1. By inspection of Attachments 1 and 2, type Q1 1 cable bounds most types of cable used at SSES and provides a conservative estimate of the material used to generate HC1.HCI concentration in the suppression pool is MHcI / Pool Volume[HCII = G

• W* [1- exp(-Iy'*tH)]

Integrated Gamma Dose I * ------_-*-t. '- LA _ Xv .

PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6106/2005 Suppression Pool pH post LOCA CaIc. No. EC-059-1041 Designed By M. Waselus Sh. No. 18 Checked By R. Anderson[HCIJ = 9.97E-4 moles/Mrad-lb

• [4855.42 + 40701lbs * [(I -exp- (.099

• 0.681)] * [8.19 Mrad +1.88 Mradl 1 3.738E+6 liters[HCI] = 9.97E-4

• 8925.42 lbs

• 0.0652

• 10.07 /3.7378E+6

[HCI] = 1.5631E-6 moles/liter due to gamma or a total of 5.8 moles [1.5631 E-6 moleslliter

• 3.7378E6 liters].where 3.7378E6 liters is the suppression pool volume.Therefore, for 3616 MWt the total gamma + beta HCI equals 5.8 moles + 1207.8 moles 1213.8 moles.Using the adjusted EPU values for gamma radiation of 10.24 Mrad airborne and 2.35 Mrad Plateout yields the following:

HCI concentration in the suppression pool is MHCi I Pool Volume[HCI] = G

• W* [1- exp(-Py H*tH)]

• Integrated Gamma Dose[HCI] = 9.97E-4 moleslMrad-lb

• [4855.42 + 4070]1lbs

• [(1 -exp- (.099 0.681)1 [10.24 Mrad +2.35 Mrad] I 3.738E+6 liters[HCI] = 9.97E-4

• 8925.42 lbs

• 0.0652

• 12.59 /3.7378E+6

[HCI] = 1.9543E-6 molesiliter due to gamma or a total of 7.3 moles [1.9543E-6 moles/liter

• 3.7378E6 liters].Therefore, for EPU conditions at 4032 MWt, the total gamma + beta HCI equals 7.3 moles +1510.3 moles = 1517.6 moles.4.4 Cesium Hydroxide Per section 2.3.1 of Reference 1, cesium may be introduced into containment in various forms following an accident.

The cesium will form cesium hydroxide and cesium borates which are basic materials Table 1 of USNRC Regulatory Guide 1.183 (Reference

5) indicates that 5% of the alkali metal inventory (including cesium) is released during the gap release phase and an additional 20% is released during the early in-vessel phase. Table 1 Reference 5 also indicates that 5% of the halogen inventory is released during the gap release phase and an additional 25% is released during the early in-vessel phase. In accordance with Section 3.5 of Reference 5, 95% of the iodine released should be assumed to be cesium iodide (Csl). This release process is assumed to occur at a constant rate over the release period identified in Table 4 of Reference 5.during the early in-vessel phase. In accordance with Section 3.5 of Reterence 5, 95% of the-4;-1__^^v k- ---..-- @"rl+_A Ace L d '.-.1J X_/#_E k_____ __ : _..

.-@ .-PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA Caic. No. EC-059-1041 Designed By M. Waselus Sh. No. 19 Checked By R. Anderson LOCA Release Phases BWRs Reference 1 Phase Onset Duration Gap Release 2 min 0.5 hr Early In-Vessel Release 0.5 hr 1.5 hr The core cesium and iodine inventories used in this evaluation include stable Cs-133 and stable I-127. Per Reference 7, the total core inventory of iodine is 107 gram atoms at the beginning of cycle (BOC) and 228.7 gram atoms at the end of cycle (EOC) and the total core inventory of cesium is 1490.9 gram atoms at BOC and 2969.5 gram atoms at EOC. The EOC values are used in this analysis.

Although the BOC value for cesium is lower than the EOC value which would result in less CsOH, the EOC values are used consistent with the basis for the radiological calculations and other data input to the analysis which are conservatively based on EOC values.These include the core source terms, pool iodine concentration (HCI), EQ dose rates, etc.Note: For a monotonic element gram mole equals gram atom. The following equations are used to describe this release.During the Gap Release Phase: d/dt[CsOH]

= [0.05mcs -(0.95

• 0.05mi)J / [Vsp

• 0.5 hr]During the Early In-Vessel Release Phase: d/dt[CsOH]

= [0.2mcs -(0.95 0 0.25mi)] / pVsp

• 1.5 hr]where mi = gram mole iodine = 228.7 mcs = gram mole cesium = 2969.5 Vsp = Suppression pool volume (liters) = 3.738E+06 liters [132000 ft3M Integrating the above yields: During the Gap Release Phase:[CsOH](t)

= [0.1 mcs -0.095mi] 1 ['sp] * [t -tgrpj where tgrp = onset of the gap release phase = 0.0333 hr [2 minutes}During the Early In-Vessel Release Phase:[CsOHJ(t)

= [0.4mcs -0.475mi] / [3 Vsp] * [t -(0.5 + tgrp)] + [0.05mcs -0.0475mi]

I [Vsp]The final CsOH concentration at t = 2.033 hr 11.5 hr+0.5hr42 mini is given as: During the Early In-Vessel Release Phase:

PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA Calc. No. EC-059-1041 Designed By M. Waseius Sh. No. 20 Checked By R. Anderson[CsOH](2.033 hr) = [0.4 2969.5 -0.475

• 228.7/ [3 3 3.738E+061

• [2.033 -(0.5 + 0.033)] +[0.05

• 2969.5 -0.0475 '228.71/ [3.738E+06J

[CsOH](2.033 hr) = [[1187.8-108.6/[1.1214E+07]]

• [1.51 + [148.475 -10.861/[3.738E+06]

[CsOHJ(2.033 hr) = [1.444E-041

+ [3.682E-05]

moles/liter

[CsOH](2.033 hr) 1.8122E-04 moles/liter or a total of 677A moles [1.8122E-04 moles/liter

• 3.7378E6 liters].where 3.7378E6 liters is the suppression pool volume.From section 4.1, for EPU conditions the values for core iodine and cesium are: ml = gram mole iodine = 279 mcs = gram mole cesium = 3570 The final CsOH concentration for EPU at t = 2.033 hr [1.5 hr+0.5hr+2 min] is given as:[CsOHJ(2.033 hr) = [0.4

• 3570 -0.475

• 279] / [3 ' 3.738E+06]

• [2.033 -(0.5 + 0.033)] + [0.05 *3570 -0.0475

• 279] / [3.738E+06]

[CsOH](2.033 hr) = [1.733E-04]

+ [4.421 E-051 moles/liter

[CsOH](2.033 hr) = 2.1751E-04 molesiliter or a total of 813 moles [2.1751E-04 moles/liter

• 3.7378E6 liters].4.5 Summary of Acid and Base Production The following provides a summary of the production of acids and bases in the suppression pool for 3616 MWt.Material Concentration Concentration in Concentration in Reference in Suppression Suppression Suppression Section Pool generated Pool generated Pool by Beta by gamma radiation radiation moles/liter moles/liter moles/liter Hydriodic Acid NA NA 9.18E-7 4.1 Nitric Acid NC NC 1.07E-4 4.2 Hydrochloric Acid 3.23E-4 1.56E-6 3.25E-4 4.3 Cesium Hydroxide NA NA 1.81E-4 4.4 NA: Not Applicable NC: Not Calculated I Hydrochloric Acid 1 3.23E-4 1 1.56E-6 3.25E-4 4.3 I , -- .s .i AI ~ A u iI 11 I -. --! ..--I a- .-6 ----! -j -I 1, I I 1IA I s n r- v 1 .4 A

--PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA Calc. No. EC-059-1041 Designed By M. Waselus Sh. No. 21 Checked By R. Anderson materia ISuppression Reference Section Pool gm-moles Hydriodic Acid -3.4 4.1 Nitric Acid 399 4.2 Hydrochloric Acid 1214 4.3 Total acid 1616.4 Cesium Hydroxide 677.4 4.4 The following provides a summary of the production of acids and bases in the suppression pool for EPU conditions at 4032 MWt.Material Concentration Concentration Concentration in Reference in Suppression in Suppression Suppression Pool Section Pool generated Pool generated by Beta by gamma radiation radiation moles/liter moles/liter moles/liter Hydriodic Acid NA NA 1 .1 2E-6 4.1 Nitric Acid NC NC 1.33E-4 4.2 Hydrochloric Acid 4.04E-4 1.95E-6 4.06E-4 4.3 Cesium Hydroxide NA NA 2.18E-4 4.4 NA: Not Applicable NC: Not Calculated Material Suppression Reference Section Pool gm-moles Hydriodic Acid 4.2 4.1 Nitric Acid 499 4.2 Hydrochloric Acid 1518 4.3 Total acid 2021.2 Cesium Hydroxide 813 4.4 PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA Calc. No. EC-059-1041 Designed By M. Waselus Sh. No. 22 Checked By R. Anderson Based on the above, the unbuffered pH of the suppression pool at 3616 MWt is 3.6 including credit for CsOH production I Suppression Pool gm-moles/liter H' for pH 6 1 .OOE-06 Hydriodic Acid 9.18E-07 Nitric Acid i.07E-04 Hydrochloric Acid 3.25E-04 Total Acid 4.34E-04 H- for pH = 6 1 .OOE-08 esium Hydroxide 1.81 E-04 otal Base 1.81 E-04 Total Acid -Total Base 2.53E-04 pH unbuffered

= -log[2.53E-04]

= 3.6 Equivalents strong acid = 2.53E-04 gm-molesIliter*

3.7378E+06 liters = 946 gm-moles strong acid The following provides the unbuffered pH of the suppression pool without credit for CsOH production.

Suppression Pool gm-moles/liter for pH=6 1.00E-06 Hydriodic Acid 9.18E-07 Nitric Acid. 1.07E-04 Hydrochlorc Acid 3.25E-04 Total Acid 4.34E-04 OH for pH 6 1.00E-08 Cesium Hydroxide 0 Total Base I.0OE-08 Total Acid -Total Base 4.34E-04 I pH unbuffered

= -log[4.34E-04]

= 3.36 Equivalents strong acid = 4.34E-04 gm-moles/liter*

3.7378E+06 liters = 1622 gm-moles%O; --e-kw4 , %.-s w -ev_& .T --e_ .._ ._ I i O rmiu,' %,tIS*.alIL_

PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6106/2005 Suppression Pool pH post LOCA Caic. No. EC-059-1041 Designed By M. Waselus Sh. No. 23 Checked By R. Andemon The following provides the results for EPU conditions at 4032 MWt.The unbuffered pH of the suppression pool is 3.49 including credit for CsOH production.

Suppression Pool gm-molestliter Ho for pH=6 1.0OE-06 Hydriodic Acid 1.12E-06 Nitric Acid 1 .33E-04 Hydrochloric Acid 4.06E-04 Total Acid 5.41E-04 OH for pH = 6 1.OOE-08 Cesium Hydroxide 2.18E-04 Total Base 2.18E-04 Total Acid -Total Base 3.23E-04 i pH unbuffered

= -log[3.23E-04]

= 3.49 Equivalents strong acid = 3.23E-04 gm-molesiliter*

3.7378E+06 liters strong acid= 1207 gm-moles The unbuffered pH of the suppression pool for EPU without credit for CsOH production is 3.27.Suppression Pool gm-moles/liter H+ for pH -6 1.00E-06 Hydriodic Acid 1.12E-06 Nitric Acid 1.33E-04 Hydrochloric Acid 4.06E-04 Total Acid 5.41E-04 OH- for pH = 6 1.00E-08 Cesium Hydroxide O.00E+00 Total Base 1.00E-08 Total Acid -Total Base 5.41 E-04 pH unbuffered

= -1og[5.41 E-04] = 3.27 Equivalents strong acid = 5.41E-04 gm-moles/liter*

3.7378E+06 , .-. e -'F 41 -fl12 W600FT-4o

= -Innfli 41 F-041 = :3-27 liters = 2022 gm-moles PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 610612005 Suppression Pool pH post LOCA Caic. No. EC-059-1X41 Designed By M. Waselus Sh. No. 24 Checked By R. Anderson 4.6 Sodium Pentaborate

-Suppression Pool Buffered pH In order to maintain the post LOCA suppression pool pH greater than 7 a buffering agent is required to offset the various acid production post LOCA. The chosen method at SSES is to introduce sodium pentaborate (SPB) to the reactor vessel and ultimately the suppression pool via the standby liquid control system (SLCS). The SLCS solution is an aqueous solution of sodium pentaborate (Na 2 B30O 1 6*10H 2 O) which is a mixture of borax and boric acid dissolved in water.The molecular weight Is: Component No. of Atoms Atomic Weight Molecular Weight Na 2 22.9898 45.9796 B 10 10.811 108.11 0 16 15.99994 255.999 Total I __ 410.09 gm/mole Using the maximum temperature of 110 OF (Dl 8) for the SLCS solution and the minimum SLCS tank volume of 4587 gallons (Dl 7) with the minimum concentration of sodium pentaborate of 13.6 weight % (Dl 9) the mass of sodium pentaborate is determined as follows: Solution mass, m = 4587 gallons * [1 ft 3 1 7.4805 gal] * [1 Ibm 10.01 6165 ft 3 1 = 37933.5 Ibm Mass of sodium pentaborate (SPB), mp = 0.136

• 37933.5 Ibm = 5158.95 Ibm Converting the mass of sodium pentaborate to gm-moles results in the equivalent of: 5158.95 Ibm SPB* 453.59 gm/Ibm SPB /1 mole SPBI 410.09 gm = 5706.2 gm-moles.The required quantity for pool pH control is injected early during the postulated LOCA. Per DI 10, the minimum SLC pump capacity is 41.2 gpm. Therefore, the time to inject the contents of the SLC tank is: Time to Inject = 4587 gallons/41.2 gal/min 111 minutes for one pump or 56 minutes for two pumps.This weak acid and its conjugate base will buffer the pool water at a pH corresponding to the following:

pH = pKa + log [anion]l[acidl where: pK a = negative of the log of the acid dissociation constant = -log[K.1 Ka = 5.8E-10 for borate buffer (Reference 1, section 2.3.3)[anion] = borate concentration

.,J,,Ir4 = mir- enno-antrnfinn

a otRheL of the acid dissociation constant = -lo[Ka1 PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA Calc. No. EC-059-1041 Designed By M. Waselus Sb. No. 25 Checked By R. Anderson Sodium pentaborate dissolves in water producing boric acid and sodium borate: Na 2 B 1 oO,6 + 16 H 2 0 o.2 Na- +2 B(OHY 4+8 1 3 B0 3 Therefore, the injection of 5158.95 Ibm SPB or 5706.2 gm-moles SPB results in 11412.4 gm-mole equivalent of borate [2* 5706.21 and 45649.6 gm-mole equivalent boric acid [8

• 5706.2] added to the pool.Summarizing the above equivalents yields the following with credit taken for CsOH production in the suppression pool.Material in Pool Sodium Equivalent Column 2- Volume pool Final pool Pentaborate strong acid Column 3 concentrations gm-moles gm-moles added to Section 4.5 liters gm-moles/I I pool gm/moles .-Equivalents 11412.4 946 10466.4 3737800.0 2.8001E-03 borate I I Equivalents boric 45649.6 946 44703.6 3737800.0 1.1960E-02 Therefore, the suppression pool pH after addition of the sodium pentaborate equals 8.61: where: pH = pKa + log [anion]/[acid]

pH = -log[5.8E-10]

+ log [2.8023E-03/1.1962E-02]

= 9.24 +(-0.63) = 8.61.For the conservative case with no credit for CsOH production in the suppression pool the results are provided as follows.Material in Pool Sodium Equivalent Column 2 -Volume pool Final pool Pentaborate strong acid Column 3 concentrations gm-moles gm-moles added to Section 4.5 liters gm-moles/I pool gm/moles Equivalents 11412.4 1622 9790.5 3737800.0 2.6193E-03 borate Equivalents boic 45649.6 1622 44027.7 3737800.0 1.1779E-02 acid I Therefore, the suppression pool pH at 3616 MWt after addition of the sodium pentaborate equals 8.58: where:

PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6106/2005 Suppression Pool pH post LOCA Calc. No. EC-059-1041 Designed By M. Waselus Sh. No. 26 Checked By R. Anderson pH = pKa + log [anionyl[acid]

pH = -log[5.8E-10]

+ log [2.6213E-03/1.1781+E-021

= 9.237 +(-0.653)

= 8.58.Similar to the above the following provides the final suppression pool pH for EPU conditions.

Material in Pool Sodium Equivalent Column 2- Volume pool Final pool Pentaborate strong acid Column 3 concentrations gm-moles gm-moles added to Section 4.5 liters gm-moles/l pool gm/moles Equivalents 11412.4 1207 10205.4 3737800.0 2.7303E-03 borate Equivalents boric 45649.6 1207 44442.6 3737800.0 1.1890E-02 acid Therefore, the suppression pool pH after addition of the sodium pentaborate for EPU power equals 8.60: where: pH = pK. + log [anionylacid]

pH = -log[5.8E-101

+ log [2.7321E-03/1.1892E-02]

= 9.24 +(-0.64) = 8.60.For the conservative case with no credit for CsOH production in the suppression pool the results are provided as follows.Material in Pool Sodium Equivalent Column 2- Volume pool Final pool Pentaborate strong acid Column 3 concentrations gm-moles gm-moles added to Section 4.5 liters gm-moles/I polmes Equivalents 11412.4 2022 9390.4 3737800.0 2.5123E-03 borate Equivalents boric 45649.6 2022 43627.6 3737800.0 1 .1672E-02 acid I III Therefore, the suppression pool pH after addition of the sodium pentaborate equals 8.57: where: pH = pKa + log lanion]/[acid]

pH = -log[5.8E-10J

+ log [2.5141E-03/1.1674+E-02]

= 9.24 +(-0.67) = 8.57.r-L -_- -9 PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA Cale. No. EC-059-1041 Designed By M. Waselus Sh. No. 27 Checked By R. Anderson 5.0 RESULTS The results of the analysis demonstrate that with the injection of the Technical Specification minimum quantity of sodium pentaborate, the 30 day suppression pool pH is greater than 7.0 which precludes the need to include reevolution of iodine from the suppression pool post LOCA.The 30 day suppression pool pH represents the worst case pH. Subsequent to the injection of the sodium pentaborate early in the accident scenario, the pH in the pool will be greater than the 30 day value since the generation of the post LOCA acids reaches its peak values at 30 days.The conservative 30 day suppression pool pH calculated herein is 8.61 with credit for post LOCA CsOH production in the pool and 8.58 without credit for post LOCA CsOH production in the pool.For the case of EPU conditions, the conservative 30 day suppression pool pH calculated herein is 8.60 with credit for post LOCA CsOH production in the pool and 8.57 without credit for post LOCA CsOH production in the pool.These results are summarized in the following table.Case pH @ 3616 MWt pH @ 4032 MWt pH with credit for post LOCA CsOH 8.61 I 8.60 pH without credit for post LOCA 8.58 8.57 CsOH PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA Catc. No. EC-059-1041 Designed By M. WascIUS Sh. No. 28 Checked By R. Anderson

6.0 REFERENCES

1. NUREG/CR-5950, Iodine Evolution and pH Control, Revision 3 (12/92).2. NUREG-1081, Post-Accident Gas Generation from Radiolysis of Organic Materials, September, 1984.3. NUREG/CR-5732, Iodine Chemical Forrns in LWR Severe Accidents, April, 1992.4. Design Basis Document for Standby Liquid Control System DBD 042, Revision 2.5. USNRC Regulatory Guide 1.183, Alternative Radiological Source Terms For Evaluating Design Basis Accidents At Nuclear Power Reactors, July 2000.6. NUREG-1465, Accident Source Terms for Light-Water Nuclear Power Plants- Final Report, February, 1995.7. PPL Calculation EC-FUEL-1602, Core Average Source Term for End of Equilibrium 24-month Cycle.8. PPL Calculation EC-012-0442, Containment Volume & Weights, Revision 0.9. PPL Calculation EC-PUPC-1001, NEDC-32161P, General Electric Power Uprate Engineering Report For Susquehanna Steam Electrc Station, Revision 6, 5124/04.10. PPL Calculation EC-RADN-1004, Post Power Uprate Post-LOCA Radiation Levels for Equipment Qualification, Revision 7, 11/21/03.11. PPL Drawing C206130, Sheet 1, Primary Containment Zones, Revision 4 12.PPL Technical Specification 3.1.7, Amendment 178 and Bases, B3.1.7, Revision 0, Standby Liquid Control System,.13. PPL Calculation EC-RADN-1005, Post Accident Equipment Qualification Doses for Power Uprate, Revision 1.14. PPL Calculation EC-073-0006, Hydrogen/Oxygen Generation in an Inerted Containment, Revision 0.15. Marks Standard Handbook for Mechanical Engineers, 7kt Edition.16. Email from R. Vazquies to M. Waselus, SPjH Cond.xIs, 12/09/04 included as Attachment 3.17. EC-FUEL-1615, "AREVA Alternate Source Term (AST) Fission Product Inventory For Atrium-10 Fuel", Revision 0, 4/25/05.18. PLE-23866, Inputs for Alternate Source Term Analysis, May 3, 2005.19. Safety Evaluation by the Office of Nuclear Reactor Regulation Related to Amendment No. 145 to Facility Operating License No. NPF-29 Entergy Operations, Inc., et. al., Grand Gulf Nuclear Station, Unit 1, Docket No. 50-416, March, 2001.

......PP&L CALCULATION SHEET Dept. 0341 Rad & Eff Tech. PROJECT Date 6/06/2005 Suppression Pool pH post LOCA Catc. No. EC-059-1041 Designed By M. Waselus Sh. No. 29 Checked By R. Anderson Attachment I Cable Data Received from PPL (R. Vazquies) 12/7/04 Attachmcnit I Si) rlC-059-1041 page 30 FIREZONE Cable_ Soni. Of 2!!!EqIueete*~k MMC COCIOIZE WPFT 6. Jtdackal Jmc* kalnhicuw OR Ikch OR-OJT dewf sbV crff ag .c*.lb I -4F ~ J11 7 .31*1 00 .1001_0155055 8700 54.7245 8234.366 0.47 0.01 1- 21 0 _____*1 .0.0 0.045 0.2535 0.2085 96.7 0.0439 123.3128 2811.501 6.28 0.13 I 4F 1i3 252 0.63 _ 3__ AM010 0.2 0. 0.0 0.315 0.296 96.7 0.0722 15.27 2123.72 1.1 0.37 I .Ffu00 ____ *100.3 0.0 0.6 0.3425 0.2825 96.7 0.0101 106.6058 2105.930 4.3 0.06-4F ____ 1 ____ 0.9 ______ 6 0.44 0.0 0.0 0.45 0.27 96.7 0.1384 218.8981 1581.697 1.38 0.03 1 4F 383 ____ 0.821 3A____ *8 0.4 0. 0.06 0.4125 -0.3525 .6.7 0.066 200.656 2072.173 1.04 10.04-97 :814 162 0.44. ____ __ 0.12 ____ 0___ ____ .2225 0.2325 9671 0.0000 108.2330 0.00 0.00 I 1.4F 0 177 0.43 _____ *14 0.' 0 0.045 0.217 0.172 96.7 0,0369 105.5578 299.220 68.85 1.25 1 4F .03 181 0. ______

• 14 0.14 0.04 0.041 0.2525 0.2075 96.7 0.0437 122.828 2812.585 6.09 0.14 1 4F .05 2_____ 0.2len ____* 14 0.24 0.0 0.0 0.3123 0.2525 96.7 0.0715 152.0126 2125.519 18.31 0.25 1 I4F 07 110.875 _____ 014 0.. 0.0 0.0 0.3375 0.2775 96.7 0.0778 164.1736 2108,930 9.03 0.19 1 .47 0 771 0.874 1 Is 1 0 ___2 _ 0.0 0.0 0.337 0.277 96.7 0.077 162.9304 2109.235 59.82 1.23 1 4F 1 17422 0.681 1 *20 0.19 0.0 0.0 0.3405 1 0.2805 .98.7 0.0786 1036229 2107.118 11369.46 28.21 1 4F ___ 21d 0. 2O0x 03 0. 0.6 0.4296 0.3695 96.7 0.1011, 206.926 2565.760 21.44 0.44 1 IE4 .134A 0.371__3_A__

G la 1 0.07 0.045 0.04. 0.158 0.143 96.7 0.0314 91.4508 2910.29 42.20 0.67 1-I.E old8 0.24. la___ *1 0.0 0.04d 0.045 0.1715 0.1265 96.7 0.0282 83.4246 2848.832 25.74 .0.53 1-I4F _____711 0.0 _____ 016 0.2 0.o 0.0 0.3425 0.2825 96.7 0.0781 186.6058 2105.930 5.62 0.12 1-4 3.2____ _____ 0.8 21 is18 0.0.Oo 0. 0.444 0.384 98.7 .0.1046 210.979 2060.706 40.04 0.82 1 14F 896~ 0. _____ 16 0. 0.04d 0.04. 0.1985 0.1535 96.7 0O.0334 96.6564- 298.462 300.18 6.18 14IEF____

124 0.79 1 *016 --0.27 0.O 0.0 0.3765 0.3103 96.7 0.0677 183.1448 2067.83 10.8 0.22 I 1-4F 3 165 0.487 la___ 01 0.111 0.04 0.045 0.241 0.196 96,7 0.0415 1172321 2825.776 68.78 1.42 1 147 ___ 34 0. _____ 1 *0400.3 0.064 0.069 CSPE 0.3675 0.3025 98.7 0.0919 178.7688 1945.736 3.12 0.96 I 14F MO__ ____ 0.3821 _ __ *16 0.0 0.044 0.04. 0.181 0.136 98.7 0.0301 88.0407 2925.644 18.98 0.I1-I4F 71 1.13A 3 AWO _ *18 0. O .0d 0. 0.566 0.486 967 0.1775 275.3252 1550.691 12.61 .0.25 I.E 08 19 0.324 3AW___ 020 0. 0.04d 0.04 0.162 0.117 .96.7 0.0265 78.6032 2975.178 5.09 0.10 I.17_4____

0.5 7____

AM* 14 0.1 0.04d 0.049 CSPE 0.275 0.23 9070.0479 133.7711 2790.252 1.20 0.02 1-41'___ 2C__ 0. CAM_ *6 0.6 OA__ -0,060OCSPE 0.390 0.335 96.7 0.0024 182.1439 2079.396 2.66 0.06§-4I. 2561 0.47 2___ AM 14 0.1 0.044 0.045 CSE 0.2375 .0.19235 96.7 0.0406 115.5296 12830.071 104.83 2.15 14E'0 417 0.50 _____ AW 14 0.1 .-0.04 0.045 CSE 2525 0.30715 96. 0.0437 172.8262 2812.585 18.21 0.38 14E 1007 0. 5____ AM 14 0.21 0.06 0.060OCSPE 0.3125 0.2525, 96.7 0.0716 152.0128 2125.519 7.69 0.16 1.4F 7 _ 94__ 0.67 7____ AM0 14 0.27 0.o 0.O6O CSPE 0.3375 -0.277 96.7 0.0770 j54,173 2108.930 36.46 0.79 1 I4F 12 AM01 *14 0.46 0. 0.O6O CSPE 0.43' ~ O315.-. 96.7 0.131 209.1683 1588.907 3.55 0.07 1.4F 132____ 0. .*0 10 0.23 0. 0,O6O CSPE 0.315 0.2~59 96.7 0,0732 153.2287 .2123.729 20.78 0.43 1.E 10 .0.345 1 *0 6 0.13 0 ___- 0.030OCSPE 0.128 0.1425 96.7 0.0198 83.8110 .4206.03 2.05 0.04.IE____0.6____

• 06 .050.0.00 CSE 0.4775 305... 96.7 0.1477 232.2753 1572.960 11.27 0.23 IE____ 134C 0.825 3AW a0 8 0. 0Q .060 0.4125 0.3525 96.7 0.0966 250.6566 2072.173 1129.76 2.67`~l.E81 20 0. 2_____ 010 0.19 0.0 0.3 0.256 98.7 0.0527 145.8321 276.685 11.01 0.23 2-47 .2 X 0.50O 2____ AM10 0.1700 00 0.3935 *0.2065 96.7 0.0430 123.3120 ?011.501 1.97 0.03 ZE 13 2____ 0.6 AM___ *10 02 0. 0.O 0.318 0.255 98.7 0.073 183.2287 2123.725 18.60 0.25 1.4F 14 5d0.66 _____ AM 10 0.32 0. 0.f 0.3425. .0.2825 96.7 0.0791 186.656 2105.930 4.43 0.00 2.41 0.. 2____ *0G6 0.44 0.0 0.01 0.45 0.37 96.7 0.1384 218.8961 1581.087 4.15 00 2.F id 0.825 3____ *G 6 0.450 0. 0.4125 '0.3525 96.7 0.0089 300.6566 2072.173 1.64 00 I-f 11911 0.434 2____ AWG 14 0.1 0.04 0.04 0.217 0.172 96.7 0.0369 105.5575 .2865.330 43.98 09 24IF 03114 0S 3_____ A 14 0.14 .4 0.04 .0.2525 0.207 96.7 0.0437 123.626 2812.585 5.20 011 Z-4F __ 22 0.825 ______ *14 0.24 0. 0.E 0.325 .0.2525 96.7 0.0715 152.0126 2125.519 1605 0.3 2-47 1 0.87 W014 0.3 0. 0. 0.3375 0.277"6. 0..0778 16176 20.3 7.9 .6 2.1 ____ 8 .7 0602 .0. 0.337 0.27 96.7 0.0777 163.9304 2109.235 51.06 1 05 2.E 11 _____ ,8 200 0.19 0.0. 0.3405' 0.260 96.7 0.76 15.39 20718 1416 36 2 0 *20 ___0.31 0. 0. 0.4295 -'.95 96.7 '0.1611 , 20626. '.2670 12 09-

-.-Attachment I to EC-059-1041 page 31_F I ..n-.no_ gnnd Sen I -ho net TU 1uL ono4 0.047-ILI I ORO 1 0 JT.4 0.1#1 0.143 ___ft I I~t ~ 2~~160 b 0.034 L91.508 291.26 77.93 4. 1.01 X o@..f.l I AwN ".I oX 0.0AN D061~ 0.3105 0.2505 96.7 0.0710 I 15i.0397 1 2126.974_ _ __F _ _ l 7 ;- 0 0l -I o 0.5.0 035 96.7 0.1048 1 215.97 I 2060.706 37.52 _ ____PAP 3728 a-WA 4 fawv la 0m 0a4cI 0.19a5 f.135 0WM34 666584 I 2R89 4X2'169.17 4-10 M.F I__ _ 4 .1 ~ s 0. .__ _ _ .O 0.3765 0.3165 867 0.0877 183.1448 2087.83 30.26 0.82 1-4F 00 _ Is 0.11 004. 0.04 0.241 0.196 96.7 0.0417 117.2321 2825.778 56.75 1.1 L14F _07503 8 m -mm O.F_ _ _ _ _ 0 G400 .06Oe6Cd 03 7 0.3025 96.7 0.0919 178.7668 10 67 6 3.31 0.07 M_69 0.3 ,6 _ 0.0 .0.04 0. 0.181 0.136 -.7 0.0301 88.0457 20.98 0.43 71LI .____, __ .0. 5._66 ._ 0.486 96.7 0.1775 275.3252 165.691 13.85 0.29; 54F _ __ 203 0.324 20 0.WG 0.04l -0.04 0.162 .0.117 967 0.0265 176.833 2975.178 55.8 0.11:-4F , ____ 2941 0.47 2A WG 14 0.12 0.04d 0.045 CSPi 0.2375 _ .1925 96-7 0.0408 115.5296 2830.071 120.06 Z47: 4F .3 _ 46 o.s50 .: WG 14 0.1 0.04 _ 0.045 CSP 0.2525 02075 96.7 0.0437 122.6262 2912.585 20.09 0.41: 54F i!OS 6t _ 0.62 __ Wa14 0.21 o. 0.060 CSP 0.3125 02525 96.7 0.0715 152.0126 2125.519 6.29 0.13 54F wT .< l : 1 0. -_ AW0 14 _0.2 0. o. o socs n o.375 0.2775 .0.0778 164.1736 710.930 3Z1S 0.e6:!4F Z12 21 0. 1 W01 4 0. 0. 4 _OO .0CSPE 0.43 0.35 967 0.1316 200.1693 1588.907 2.78 0.06;.4F Z13 2 0.R 3 AM 10 0.2z W- .0. 000CS 0.315 _9.25 s6.7 -9 0.0722. 153.227 2123.729 20.20 0.42: 4F _ Z6t 54 0.34. 1 WG 8 0.13 0e 0._030CSPt 0.1725 0.1425 967 0.0191 83.9110 4208.933 1.06 0.02 M.F 60 3 0.95 3A__ _ W a 6 0..4 0.0 O08O CsP 0.475 0.3975 6 0.1477 232.2763 1572.860 10.78 02 4-4F 3 0. _ ______ W a 8 0.3 00 0.080 CSPE 0.4125 0.3525 96.7 0.086 209.6566 2072.173.

111.94 23 79744 48MA.2 1oo P ChCSPE ..-owAfonWtd h dhe10._yethwfl Jaket _ .._ ., ....___ ..._ __ --- _F,---_ -: _ _-- I I I _ I I I I [ I I II IE: NOTE: The portion of the Table highlighted in gray has been modified by the calculatlon originator to provide additional values for the analysis.

Attachment 2 to EC-059-1041 page 32 Attachment 2 Cable Drawings Attachment 2 to EC-059-1041 page 33 PPL Susquhanna, LLC AMwwD PA 15101-1179 TL60,so774.7723 Raz610f7742 vWqukyPtWecis Decenber 8. 2004 Mr. Michael Waselus Parsons Energy & Chemical 2675 Morgantown Road Reading, PA 19607 SUSQUEHANNA STEAM ELECTRIC STATION SUPPRESSION POOL pH ANALYSIS PLE-23745

Dear Mr. Abrarns:

The following drawings are attached for your use in determining cable dimensions for the Suppression Pool pH analysis: 1. ForType B12 Cables 2. ForType D1I Cables 3. For Type D12 Cables 4. For Type D13 Cables S. For Type 014 Cables 6. For Type D62 Cables 7. For Type D83 Cables 8. For Type L02 Cables 9. For Type L03 Cables 10. For Type L05 Cables 1I. For Type L07 Cables 12. For Type N09 Cables 13. For Type 011 Cables 14. For Type 020 Cables 15. For Type 024 Cables 16. For Typo 024A Cables 17. For Type 025 Cables 18. For Type 026 Cables 19. For Type 027 Cables 20. For Type 028 Cables 21. For Type 029 Cables 22. For Type 030 Cables 23.. For Type R04 Cables 24. For Type TOS Cables 25. For Type T06 Cables 26. For Type T08 Cables 27. For Type U07 Cables FF103301 Sheet 8901 FF103301 Sheet 5201 FF103301 Sheet5301 FF103301 Sheet 5401 FF10301 SheetfSC1 FF103300 Sheet 5801 FF103301 Sheet 5701 FF103301 Sheet4701 FF103301 Sheet 4801 FF103301 Sheet 4901 FF103301 Sheet 5001 FF103310 Sheet 0301 FF103310 Sheet 2501 FF103310 Sheet 0701 FF103310 Sheet 1401 FF61954 Sheet 44 FF103310 Sheet 1501 FF10330 Sheet 1601 FF103310 Sheet 1701 FF103310 Sheet 1801 FF103310 Sheet 1901 FF103310 Sheet 2001 FF103500 Sheet 0201 FF103310 Sheet 2601 FF103310 Sheet 4101 FF103310 Sheet 4301 FF61882 Sheet 5 Attachment 2 to EC-059-1041 page 34 1 1 9 i i j II II Decernbe 8,2c04 PLE-23745 Page 2d12 28. For Type U63 Cables 29. For Type Z02 Cables 30. For Type Z03 Cables 31. For Type Z05 Cables 32. For Type ZO7 Cables 33. ForTypeZ12 Cables 34. ForTypeZ13 Cables 35. For Type Z61 Cables 36. For Type Z63 Cables 37. For Type Z83 Cables FF61882 Sheet 8 FF103950 Sheet 1201 FF103950 Sheet 1301 FF1 03950 Sheet 0201 FF103950 Sheet 1101 FF103950 Sheet 1001 FF103950 Sheet 0901 FF103950 Sheet 0601 FF103950 Sheet 0701 FF103950 Sheet 0801 Please contact me at 610-774-7723 H you need additional Infornation.

My erail address Is ravazquiesOpplweb.con.

Sincerely, Ronald Vazquies Senior Engineer -Mechanical Design Engineering RAVVIr cc: wlo att T.F. Mackay R.L Doty D.G. Kostelnik Nuclear Records GENPL5 GENPL5 GENPLS GENPL4 aia JZ PF 1.O330i 'h. 89ci I1*OC~2719S

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• lP INlV POWER IN ULIT PAWTUCKET.

RHODE ISLAND i n{ ONTL 886E ISO___..W. MFG. SPEC. E OQ I_ ..

LO-P)- IV5 -DL):I_ -Jh.___A .* .*. 'I*9-= 4 -i P I t INSULATD a JACKET CONICTOR ANlNEALED TIN £0 OOPPER 7SDIt ROZ4 t I:0__ i I .030" WALL J MLAflO DIV WALL I4YPtWN JAMKE I* MYLAR TAPE U£. IS OPTIONAL.F USED, IT MAY BE APPLIED UNDER, OVER, OR BOTH YNOER AND OVER ESM TAPE.0 9 a Vt a0 ITEM: I DIMENSIONAL ORAME i 14 AWG, 2 CONDUCTOR PARALLEL 900 -00 WV POWER a CONTROL CABE SPRINSULATION WITH HYPALON JACKET HYPALON JACKET OVeRALL I f.NmL- OM FI WM FLAME IMStONT PLLS.WMPD P N{eGS AR-' fl!s ..~. r* i, l. .~. ,4h U-OMHANNA -STE MM'TM!,.AMERICAN INSULATED WRE l g IANIA' Iso A ia.GT CORPORATION

.W UGHT PAWTVCKET, RMODE ISCA/N Oj88Zt-3._0 I J L-Oc I- t- Laju ih. 4AV.8 _ I ftt2, m -15 > A -Zd^ -_ '* a **INSULgFED a JACIMT CMOMT ARNmeo Tm cOew coImul 7 smR .0242m , 30L WALL EPR ION.Q5"NWALL HMLON JACKET:., f i , ..4735P MYLAR YAPfE USE 15 OPTIONAL.IF USED, IT MAY GE APPIED UND , OVER, OR OMTH UNDER AND CVER OSE TAPE.-I-10 II. TCK, LASS REWINORCED FLAME BARRIER TAPQ.gA=5Y.% QOVeRLAP 9 g 9 ml 9 0 ITEM: 2- OIMENINAt DRAWINSG 14 AW%, 3 CONDTOR ROUND 90C-800 VOLT POWER 5 CORM CABLE EPR INLA=N WITtf WML6N JACKET*HYFALON %JACKET OVALL NOTE;YmQ2 FltI= YI AmE R mA El=SUPPUL: Aw ELECTRIC CORR UN". N.J. PO. m e270 M .ECHTEL POWER CORP...1. .. .i SU4bANNA STEAM EEC TRIC AMERICAN INSULATED WIRE PLANT.CORPORATION

_U _- .- A POW, ER 'a LI PAWTUCKET, RHODE ISLAND TL 6E130 SC ES1 I I.. I OQ CD L05 FF 1.0350a h. 1ZVJ-eera .e a>^.fo INSULATEO

& JACKET CONDUCTOR ANNE I I1+ O t3O WALL CPR INSULATION eWtALL WPALtON JACKeT I .^ I!* , .0. 4 1..'I.I:ALED TIN COAM ODPPCR S7'S5 a.0242e J1* CLEAR WLAR TAPE WRAP .* CAR MYLAR TAPE WRAP 4 .INW.ATED JACKETED CXRS.* PC r.O6iOF HEAVY DUTY HYPALCN JACKET 10 MIL tW.CK, MsASS RINMCED

• w FLAME BARR'EN TAPE.- , IF.25% OVER.AP , I 01 i 'II I.I I WILAR TAPE USE IS OPTICYAL.USEDP IT MAY 't APPLIED UNVER, IVE, OR BOTH UNDER AN'D OR ESC TNAPv.B.Z o 9-a a7 I0 a.'0 i NCE: =_ P1LLM WI.FLAWE R____TAN3_

FRB.SUPPL'!R:

CAME ELECTRIC CORP *JNION. N.J. RC. PER 8275 ITEM: 3 DIMENSIONAL DRAWIN.14 AWO, S COND;CTOR ROUNO 90-C-600 VT .POWER CONT CASU EPR IMULATION WITH HYPALHN JACKET.HYPMAON JACKET OVERALL i* IP : &HTEL :PO ER CORP AEER T IN- *LATl i t SUSOU E .NNA f STA M AM LEC T'C PLANn AVRICAX INSULATED WIRE PMMVM 00IM 0 ILKLA f CCRPORATION

_ A *OWER S U 4 zAW'TVJC'ET, RHQO!'lISLAN2 A _0 us ,Atmi I.,ATE -A A.s'. W... SPE. Er I"S75 5...hO.A L0l FF O03Oi0 5h. 5001.';; *d-' '= _ o_ !A _ fM-v --I r1 -.5 ..ta r I INSULATED a JACKET CONDUCTO ANNEALED TM COAIED CPER 7 STRS x .0242" t.Ow WALL EP NmsUAT!ip JOI HfPALON JACKET: ,V;I 4 p lt CLEAR MYLAR TAPE WRAP 4' INSULATED JACKETED CCR*_ Q j t* MYLAR TAPE USE S OQTONAL.IF USED, IT MAY SE APPLIED UNDER, OVER, OR BOTH UNDER AND OVER ESE TAPE.I.a 0 m o 0 R 10 MIL THICK, OLASS REINFORCED FLAME BARRIER TAPE,TYPE tiE.25% OVERLAP ITEM: 4 DIMENSIONAL DRAWING 14 AWO, 7 CONDUCTOR ROUND 90C 000 VOLT POWR a CONTROL CABLE CPM INSULAT1ON WITH HYPALON JAC?HYPALON JACKET OVERALLlNOTE Y= P I F AME 89ISIAL4Z ML.....

• t.. DAlftl nt geVsftft AftD omtfl, 1 A .fA n SWU Ro7-<, rF. eECHTL PowER CORP. I C/o SOUSEHANNA STAM ELEC.AMMRICAN INSULATED WIRE PLANT CORPORATION -PENNS. YMIA POWER B LtT PAWTUCKET, RHODE MSLANO STEL 8056-t-S3..

j .A.MMG,5-____ ___ ___ ___ ___ ____ ___ ___ ___ ___ ____ ___ ___ ___ ___ 5!.-_ -_ ..... I. '.-.-.---.---...-.---.-..

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--Attachment 2 to EC-059-1041 page 46 r4 -8tPCTI e C..*p j .FFio33 O0 Sh. 301 lechtel Tag Number N09 i Item 5.SAMaEL MOORE PART EER 293560933-001 , ine. (9) conductors of sixteen (16) gauge. seven (7) strand tinned c copper with tvwety (20) ails Z'Tm primary Insulation and tan (10)midls aypalon intermediate jacket; color coded per IPCEA. Kethod 14, all conductors colored white and numbered; a sixteen- (16) gauge.seven (2) straiid cinaed copper drain vire with two (2.0) mile Alu-uinum/klylar tape shield and five (5.0) 311 silieone-rubber fiber-glass fire barrier and sixty (60) ails black Hypalon outer jacket.Maximum O.D. .674 inches let Weight per Mn 217 lbs.Kwimm Length 6,700 feet laximmu Pulling Tension .l6 lbs. RECE V Jacket Legend: Dekoron Dekorad Control Cable 1935 Samwel Moore -Aurora, 0 1976/)Lt Sumber FINAL DRAWING MWST SU6: CER1IFIED CoRRECT FOR: 1935-60933-00

.. _ \BECMEL P.O. a856-131-A

_C\ SUSQUERAMA STEAM ELECTRIC STATTION v C UITS I and 2?E. SYLVANIA POWER AND LIT COMPANY C .c LC~l .... signed-'Date. 6116177..SAMUEL MOORE AND CO. l PRODUCT SPECIFICATIO.

lSEEr I CFl AP .I =T PAR no._Auror4, Ohlo, l ' ifX7 1935-60933-001 Attachment 2 to EC-059-1041 For i Vatica Only*, .,_, t T page 47 I i.i_.7 r_ I C2; CE REI S1 F F -O 5 S .Z 0 --Bechrel Tag Nsmber Q-ll Item 38 -...4.NV'. N.I -I SAMUEL MWORE PART NUMBER 1990-90036 7 Thirteen (13) conductors; one pair of twenty (20) gauge. type K! (chroinel slumel) solid conductors with twenty (20) mils WEDM primary insulation and ten (10) ails typalon intenrediateejacket, color coded per ANSI standards; eleven (U1) conductors of twenty (20) gauge, seven (7) strand tinned copper with twenty (20) ils EPDMH primary insulation and ten (10) uils Hypalon Intermediate jacket, color coded per tPCE&, Hithod £4, all conductors colored white and numbered; one and five tenths (1.5). ilts clear Mylar overwrap with one and seven -tenths. (1.7) mils copier/Mylar tape shield with a twenty (20) gauge, seven (77 strand bare copper drain wire and five (5.0) slls silicone rubber f$berglass fire blarrier ovcrsll and sixty (60) eils black Hypalon outer jacket.Maxium G.D.Net Weight per FT-Maximum Length Maximum lulling Tension.- .68i inches 187.3 lbs.6,650 feet 116 lbs.RECEIVED I [.U I I97 Jacket Legend: Dekoron Dekorad 1990 Samuel Moore Aurora, 0*1976/Lot Number FISAL DRAStl:C MOST SBOIJ: CEtRlTIED CORR£CT WOR: 1990-90036 EEC0TFL P. 0. 8856-131-A rS US MAZ STEAH ELECTRIC STATION1 P UTS I and 2 40 a, SAMUBL4M4ORE AND CO. -FROMU UUMIClN I SIH Aurora, Ohio APPO. DATL IPAM PD.1 7/1/7 14 con..4a90016 tECT 1 OF I-a Attachment 2 to EC-059-1041 page 48 For AtkVmation OnlY., cOANOEs *EVS I: O FFQ J Lossiot Sh." OL to fg.'t Bechtel Tag Number Q-20 item 9 SAJUMIIE )_M PART MMM 193502733-CO0 Twenty-seven (27) conductors of twenty (20) gauge. sevia (7) strand tirned copper vlth twenty (20) mile KPMK primary insuletion and ten (10) mils Hypalon intermdiate jacket; color coded per IPC, Method #4 -all coa-ductors colored white and numbered; a twenty (20) gauge, severe (7)atrand tinned copper drain wire vith tw (2.0) mdle Alumiuinigylar tape shleld and five (5.0) ails silicone rubber fiberglass fiee barrier and sixty (60) ails black Hypalon outer jacket.I milmuz O. D.Net Weight per MnE Yaximu Length Paxizm Pulling Tension.339 Inche 308.3 lbs., 3,750 fact.217 lbs.I A#CEIVE1 l. Aue 1 1977 Jacket Legendt. Dekoro tekorad Control Cable 1935 Samuel Moore -Aurora, 0 1976/Lot Number VIAL.DR CERTIFIE 1935-0 AUISG MUST SHOW: D CORR=ECT FOR: 2733-001 4C, (4.0~61 a6 4CAUG 9 1977mECETL P.O. 885f-131-A

.SUSQUEXAM STEAM ELECTSIC STATIWON MUNIS 1 and 2 PENNSYLVANIA PMER AND UCHT CO.Signed oae_ 7 C, bate: 6/16/77 SiMUEL MOORE AND (0. -PROMUCT DEScRrPTrIq O I WEET I OF I o, ./6/7 3 I73 I Aurora; Ohio 6116177 1935-02733-001 a S -*

Attachment 2 to EC-059-1041 page 49 For Information Only'CHNAMEs' IMSION 1-p rFF1035310 Sh. 2.'0i I Bechtel Tag Number Q-24* titem 18*SAMTEL 19R P5T NUtlBER 1952-68340-002 One (1) pair of sixteen (16) gauge, seven (7) strand tinned copper con-OG ductors with twenty (20) mils EDK prinary insulation and tea (10) xils Eypalon lutemediate jacket; color coded black and white vith a rsteen (16) gauge, seven (7) strand tinned copper drain wire; two (2.0) ails Alominutz/ylar tape shield and forty-flve

-(45) ils black Hypalan outer jacket.* an -.D. .3j6 incles.-et Veigt per IT .67. lbs. RECEIVE .D .NixAZa Length. 10,000 feet AUG 1i 9 .lazxm Pulling Tension 59 lb .Jacket Legend: Dekorcn Dekorad estrment wire 1952 Samuel Moore-A uro r a , O hio R N N O T S 0 f 1976/Lot Number FINL DRAWING MST SHOW: CERTIFIED CORECT FOR: 1952-45340-002 BEClTEL P.0. 8856-131-A SU. .E-ISAQ STEAM ELECTRIC STATION N -RE .lITS 1 and 2.C EItVED i MELVMN POWER AMD LICMT CO.AlG 1977 Signed t&. 1 -Date: 6116177 SAMUILAMORE AND CO. ^ ns I SKE ST1CFL Autoro, Ohio 6l16177 1952-68340-002

---

Attachment 2 to EC-059-1041 page 50 For Inforlation 1Y *- -a i ..S.2H.N .R A G h 25 AMT IPAULACN.

LL, A j aU. .OLT* JACIMT LECGENM DM WOVD EASTOSP Ot4OTRCAE OF WG)Y CURO* PREPD9M I YPALOM NWpL OVAi~A.040(RO P)PIO*LTS) (SEQ MAX M CD. .NC .MI. MUM N RADIUS.(IN E) :.MAXIUM PWNG ENSIN (1SS) 6.424*CALCULATEP MAXiMUM LENGTH OM~l; 10.000 FURCW DEKORONpl

_ FF16I ..5...,~ qj JUNE.21 ISSO I!

Attachment 2 to EC-059-1041 page 51 f-Ww 9MMS9UlyfEmislQM 2-- .'- Q -! --F- ..h ~Q-*~ ~ fC2Z5 .Ffi0o3X0 st. 15-* I I ..Bechtel Tar,..Ito Number Q-25: 19 4.tnn'S I L MOCRE 1 jAT lUER 1974-50233-Oll Two (2) pair of sixteen (16) gauge, nineteen (19) strand tinned copper conductors vith twenty (20) sile ZPDH primary insulation

• nd tan (10)idls 8ypalon intermediate jacket; color coded black. white and numbered on the white leg vith a sIxteen (16) gauge, seven (7) strand tinned copper drain wfrei two (2.0) mile alumimum/Kylar tape shield and one and five tenths (1.5) a1* tylar separator tape over each pair; five (S.) tile silicone rubber fiberglass fire barrier overall and sixty (60) all. black lypalon outer jacket.* 1(ax m 0.D.Set Weight per MFT maximum Length MaWimum Falling Tension.62. inches 172 i lb.7.000 feet 98 bs.Jacket Legend. Dekoron Dekord Instrument wirc sIt V* Samul Moore j AUC 7* Aurora, 0 I J!J.3976hLot Number rAL DIRAVINGC MLMS? &Wz: CERTIFIED COR.RECT FOR: 1974-50233-001.-

r~i; bECHEL P. 0. $BIL-13!-A Rec Iy 0*UG , E. StISQhiWNA STEAK ELECTRIC STATION I~ i VNIT121 I and 2 lEPKSYLVANIA MM:R AND LICHT CO.te 7/ ? _tRODUCS DESCRIPTION ISHEET--]

-I -3974-5023S-001

.... .

Attachment 2 to EC-059-1041 page 52 or In " a 0 Y REVISION 2...?-(* FF l13-53D Sh, 1.6i01 i 1.i I Jecht;l Tag Nuber Q-26 Itce 20.(V.to I-'.t SAMUEL FDORE PART NUMNER 1974-S0333-001 Three (3) p31r of sixteen. (16) gauge, nineteen (19) strand tined copper"enductore with twenty (20) wils EPZU primary Insulation and ten (10) mils Eypalon intermediate jacket; color coded black, white and numbered on the vwhte leg with a sixteen (16) gauge, 7 strand tinned copper drain vire; two (2.0) idle aluminuin/Mylar tape shield and one and five tenths (1.5) mlug bylar separator tape over eacb pair; five (5.0) *ils cilicone rubber fiber-glass fire barrier overall and slxty (60) ails blek Hypalon outer Jacket.)Iaximum O.D.Net Weight per OFT .u11M ing th ensc Maxtmum Polling Tension.685 Inches 222.5 lbs.* 5,500 feet 137 lbs.Jacket Legend: Dekoron Detarad Instrument Wire 1974 Samuel Moore Aurora. 0 1976/Lot Number..alAU6118 7 7..I U 2" PRW.INAL DRAYMIN MUST SlO': CERTIFIED CORRECT FOR: 1974-.50333-0O1 BtzaTEL P. 0. 8856-131-A

._ IQSUSEIAQUER A UTEAS ELECTRIC STATION i R C l~lSSI gad 2 II TLVALIA POWER AND LICUT CO.l WD 1&Z3 ned O .- =p o ,;, I ? Se:CT~gte 7/1/7_I, M on.t-a 91 I.eI SAMUEL MOORE AND C0. PRODUCT DESCRIPTICS EET I OF I Arro. DATE PART 7 10.Auroma Ohio IAP. 7/l/77 1974-50333-001

._ _C Attachment 2 to EC-059-1041 page 53 Fgr, 144amation .Cnly-*~.-4;-a i 31V1STV 2* .-D!AIW55 Pi IF1riTK o 5K ir11Li.-..MI.-4 Is.Pd*0-4I I.g&1 Bechtel Tag Number Q-27-Iltem'21 SAMXEL MOORE lPART NUMER 1974-50733-001 Seven (7) pa#r of sixteen (16) gauge, naineteen (19) etrand tinned copper comductors with twenty (20) ulls EPim primary iu*ulation and ten (10)mils lNypalon Intermediate jacket; color coded blck. white and numbered oan the white leg with a sixteen (16) gauge, 'seveC (7) strand tinned copper drain wire; tcw (2.0) ais aluminumtylar tape shield- and one ind five tentlas (1.5) ilis Bylar separator tape over each pair; five (5.0) milt sllicone rubber fiberglass fire barrier overall snd sixty (60) oils black Bypalon outer jacket. .KIn=im 0.D. .888 inches Net Veight per SPT '451.7 lbs.Xax4n I-ength 3.000 feet 8axim PhllIng Tension 294 lbs.Jacket Legend: Dekorom Dekorad nstrumnenr Wire 197,4 AUS I ¶977 Samuel Moore -Aurora, 0 ' JfiINA PgL, 1976/Lot Number',yAL DRAWNGc 1m SoUst CrrFIED CDECr RFM.1974-N0733-:001 R ECCE ED? lbearEL P. 0. 5856-331-A.

7 -. US=QUw SA STEW1i ELECTRIC STATIOV A0uG 9 1977 uNlTS 1 and 2 P.IWSYLVANIA POWEr AX" LTGXT C0.,1s ,T:Oi}Signed Q P:_Catet i1l,/77 SANIUE MOORE AND CID P=Wcr KffteraN IHlw1 O.u a Ohi _".IPR 0 Au~aa Oh l D7/1/77 1974-50733-00 Attachment 2 to EC-059-1041 page 54 ror Inf6rmation Only --. ---.flfl. VC~tWT 1 , I_t..34 ,_ QZ FF.I3 .O 5h. iSO1 _Bechtel Tag 2hmber Q-28 ,tei 22 SAM= M PART FUMNR 1962-6834G-002 Three (3) conductors of sixteen (16) gauge, seven (7) strand tinned cop-per conductors with twenty (20) Mile 1DM primary Insulation end ten (10) Milo lypalon intermediate jacket; color coded per lPCU, Kethoq 01, all conductors colored white and numbered with a sixteen (16) gauge, seven (7) strand tinned copper drain wire, two (2.0) mils Aluminum/Ky-lar tape shield and forty-five (45) mile black Eypalop outer jackat.laximu O.D. .397 inches get Veight petr MT 82.2 lbs. i I.aximm Length 9,300 feet AU6I197 7 axI- Pulling Tension 78 lbs.Jacket Legend: Dekoron Dekorad Instrument Vire 1962 Samuel Hoore Aurora, 0 1976/11ot Number TIM DBAMC MM CER1IFIID CORRECT FOR.1962-68340-002 BECHEM. P.O. 8856-131-A SUSQUMMAM STEAM EtECtIC STATIOu MIUTS 1 and 2 R EC E i V D XFJ1SrLVANIA ONER AND LICMT CO.I AUG& g 1977, lte C Bate: 6116177 , :' rTx,.I I'm 0 I&b in 104 SAMwEMOORE AND CO. FROWCr CESCuxnPbl

• l SNEET 1 OL.F__1L_Ammra, Ohio 'APP. I W,77 IT l962-68340.oo2

-C Attachment 2 to EC-059-1041 page 55'or Infoi*. -inat.ion only-..-- wIrou I_ _ _._Ii ,q 2.ft I .l-echtel Ta Nuraber Q-29 Item 23 Ia).t I 114.1.-Z Z,&AM= fOORE PART OMUNRER 1984-50333-001 Trree:(3) trvids.of sixteen (16) gauge. aimeteean (i9)-strand tined copper conductors uith twenty. (20) wis RS primay ieitation and ten (10) wilt llypaloa Izteiediete Jacket; color coded per. XPCUE. etbod /4. all con-doceors white and iumsbered witb a sixteen (16) auge. seven (7)- strand tinned copper drain wire; tw (2.0) mis slunismiylar tape shield and one and five teeths (1.5) mil Ilar separator tipe over macb triad; five.(5.0) ails silicone rtubier fiberglassj fire barrier overall and sixty (60)mils blac Nypalan outer jacket..,KasIMu O.D.* 'Net Weight per )0FT Maximtw Length I&W-Efrm Pullting T.'ngion..753 Inches fl4.4 lbs.4,500 feet 196 lbst.jacket Legend, DakaoTnf Velkorad Inetrtrent Wire 1984 'AUG I 977 Samuel Ifoore .I ~ 4 aurora, 0 P lgl6lLot Ilumber F .VnRAL DAvIrG M=S SHfO., AUG 9 7718-33-0 r .

-* SEUUTE P. 0. 8856-131L-k SUSQUEU.'OA STEAK ELECTRIC STATION UNITS 1 axd 2 o PENNSYLVANIA PCEI MD LICHT CO.Signed 430--t- -P.C....-w4 Date, 711177 .0 Ia 5 r VC.V a SAMUE. MooRE AND Co. PROl= =EsciPmon

] I o I Aufro, Ohio -. AS". 77 lA*T *a. 3 711177i 1984-50333-001

-II i I I II II I Attachment 2 to EC-059-1041 page 56 PWrmiatiou Only .'Wn ~-r CWV4?T~ S.., .__ .%fampra -o la-Q30 FF1.0iZ. 5h. ZOOL.r. ..Bechtel Tag Iunber Q-30 item 24., i:o.',8.4 I I*0 SAUL MORZ PART OMER 1935-50433-001 Four (4) conductors of sixteen (16) gauge. olneteen (19) strand tinned copper with twenty (20) ilUs EM primary insulation and ten (10) gals tlypalon intermediate jaeket; coloi' coded per IPCE:A, Method 14, all con-duetors colored white and numbered with a sixteen (16) gauge, seven (7)strand timed copper drain wire; two (2.0) dils oluminumHylar-tape shield-and five (5.0) miS silicone rubber fiberglass fire barrier and forty-five (45) mil black Eypalon outer jacket Maximu O.D. -Net Weight per MFT.Maxiui Length .1Maximum Pulling Tension.482 inches 110.4 lbs.*10,000 feet 98 1ba.Jacket Legend: Dekoron Dekorad Samuel Moore Aurora, 0.1976/Lat Number Control Cable 1935 1.C0.RECEIVED I.AUG 9 1977 Nt .*. `ST:?;t JIJAL DRASIZIG MUST SHOW: CERTIFIED CORRECr FORI BECRTEL P. 0. 8856-131-A SUSQUEAIUIA STEAH ELECTRIC STATICN INTS I and 2*ESRSYLVAIIA POtER AND LICHT CO.Signed o j, CL 04 9 5.4 in S r a-.Date: 7/L/77 SAMUEL.MOORE AND CO. l R=C DESCRIPION l SHEET .IOFLP Aurora, Ohh i l,1, lT pt 5-5 0 0 1-S Attachment 2 to EC-059-1041 page 57=r10fcatioC Only--FF LOS3-W 5h. ZO1 ROLl'Produd Data tioSectn 3: Sheet 6* Okonite Okolon Type RHH, RHW, USE SWOV Power Cable OwAIunwm Oaxduicw/W RaiMgt'NS CA B-.C.-btiaron 0kI12ab*koeakdeb0&.w, brit kW OSU wtdaaedy tuggd e omO The h"si Ofmess b wts es b5 tcWGlh t2 A"g h 45 dS@ IIA A g U u 4J0 A 6 0 11S 2SO MC taugh NoO M6CD a es avdbr7SO WM e wI~OOOUDAII

• JakeMswM"I="wshes VW Okton l&et upiedvAh ffBs lthe bsa vuanwzed orla*onsred-pid eM based sOOWd W vdos&*UWmfetxt=

bIech-scidS dkaW&Apacalbln5 OkcnftOc 50G VWl PgwC~fs we ee nded bI uNe bI la bw vfte cdzts We dwwSityd UT-vie Fse pfedt =WdatiL TIe* c n be histlte hi w r. .it su detgv o smd dt Spooid ,adtwSyW dtet biW (Sizes 18 bh, 0d be Rated brx5CueandCC*y.

wduswPweclrtatic vandptor WASrM o 2a1.B M e e S o e x a c t a t q f r meats of Wtoem Standard 61 to PCEA 648-66NEMA

%C lMarch1971)tfo ASTM D2802.?0..hd ~el: Exces lr i mne ds O1 WSCEA64B41. (BEdt nSection 4.13M0, HeaW ~D*. duicr-ProdtwA Fntues O.id~mekW eslsance 9=Sovenous wtbu' iCCghw1eadat aEuwepboodgecodsin e0daomial-M ahtghbWelIwe..

sLowSICndpOwebetor Mec htaf lynogged eRestwn low w. Os e ORS, 0$d u dvaD~es AdditiO"al Informalton Sb*e. WegW W WA daIsecon Wwiecnhleergeoluisci Price kdwo atmis Fesenled anaopate*whfthinVt~baikcdvi~sOn For acIfiwa iafraIonconad vw tCed Otarepaeere-eice A tfmaded Akosem Ccr shm ftw-Okows-59 At4 AWO45 fW 61 PAVO-141 A-R-SS Msw 250 1ACM400 MCM-55 mtRs " a M cli gO G A8Set--Ok~~

---Attachment 2 to EC-059-1041 page 58 orfta)ft-kot~ln Type RHH, RHW, USE GMC Po* Cable.Om~ fmum Cartduewo/9O Peairm FF i03500 R01q.. * .Product Data : Section 3: Sheat 6 -0 Owotoi,~~abo.

0 Ag ¶tot 2Awng,45mfls01 Avvvfthroh f4/0A.gM 65 irh a50 MGM1____ 05MCK vnt;W WTWi~h10 MCIA.00l~* CWe- -Nof bc16t £Aoz.bsNeO*

lkdL 4aoo. Sip feC"m .eItICal. 5lni"& vocors &. Om "WW WtuI40J AN11 S,70 07j W.? a" 020425S 4 I so 20. .44I6 i 13-14 S Si 45 I. .541187 178 'W I 22* 13"1-1051 toI to 45 1.14 .58? 14.78 208 ~ .. 139 1"2.14"i am0 to 45 1.14 im2 15*0 245 -35150 Ab-1131 ./ So. 45 1.14 £Str 17?Ad '29 491 #--"-swn~ 4/0 19 45' 1.14 .13 18.5? u4s rs?35 0212214431 no 0 S., In 1.5 *4 21.49 446 we 24o*--pW3241.y71.350 8? 4$ iks .50 24.6 74. 191 =.VS32,11-01

%W 37 65 1.65 IASI1 27.46 M5 a71 Ilat.mU2t0G .?150 el -5 JA5 1.32 3383 1072 .5344 488 5FI41.3551 4;o- f i T5 SAW~ 4787.:74 455i32 Ii.79 A8 11C Amec~ft 64, cky tI =. vii evo so 65 so SIX 120'5$15$1no 20*50 210 W8 44$55 70 125 M4 as5 16I$'Is i6o*20 405 450:51fts 38 Awo *smugft 02 Awo W O 6"We d#r "ga *-*uOk 1000mCu ft1000W i f t g m c W Om a l on&3"0u '.84 .S AgOWN o We S S*mS n *~(* W soduC.wx In* #W*0Ca*&" or *pced godiaf CWftF WrIfylo expacWes bowd onl OOC sk wSiUal 9s IPC!&A WttW*L Om SOC opbloat md50 1 v viskms bVI.10: f6O 41W I1.(y by AQI es 6sockeednbedi Boo no9 6We two Sw.. CS) "nevgloft to tmc wy wiGbleq wdec &Wfts.SOC "OI I T4E KONITE COMPANY FProey NsCew -46 I 0, II Attachment 2 to EC-059-1041 page 59 I n ro l 1kr %.OflY.3 U'Vft; I* I.I'4 , .-Q FF' iO35O Sh. Z40i1 Bechtel Tag Nu=bet TQ-S Item 39 I .t SIEL MWDORZ ?LRWnSB 1902-6S340-001 ane C1) pair of sixteen (16) tauge, type TX (copper coitaonten) solid eonductors with twenty (20) mils eP F.primry Insulation and ten (10)1ils flypelon Intermediatee Jacket; eoler coded per AiqSl standead.

with a sixteen (16) gauge. solid tinned'copper drain wire, to (2.0) alis.alOainum/Ilylar tape shield and forty-five (4S) aile blue Eypalen outer jacket.-* OaruC.t..

i362.inchec Vet Weight per XFT 68.3lbs.: Naxizmm Length 30,000 feet , taximum P slling Tension 59 lb*..Jacket Legend: Bekoron Devorad Tbertecouple mtension Vire 1902 Samuel Hore Aurora. 0 19761Lat Number RECEIVEQ AUV6 1977 nlmAL DRnI.1C UST PsIIJ: 'ClQTIplgD 00tC 1FO.t , 190245340-001 RECUTEL P. 0. 8856-131-A SUSQUENhwA STEAM LCtIlC STATION L~ AIA and I M LCU CD.lAUG 9 ' ^S J0L~ t i~t: lJ~tL7 SAMURaMOORE AND CO. PRODKC DESCRIPION SHEET.4..OQF

.4.Aurora, Ohio i 7')w l 1902-65340-0.

Attachment 2 to EC-059-1041 page 60)r: Infogation -Only -.~ ;* s .1nrwMTOW 9..I* .TQCAC. FrF 163351 5h. 41pi U .Bechtel Tag Number TQ-6 Item 40 t4.W.t It I1 SAMEML MOORE PART FWUER 1924-612A3-001 Twelve (12) pair of sixteen (16) gauge, type TX (copper constantan) solid conductors with twenty (20) mile DHM. prImary insulation and tean (10) ils Hypslon internediate jacket; color coded per ANSI standards; each pair shielded with a sixteen (16) gauge, solid tinned copper drain wire and two (2.0) ail aluoinum/Hylar tape shield and one and five tenths (1.5)uIl Mylar separator; five (3.0) ails -slicone rubber fiberglass fire barrier overall and eighty (S0) mils blue Nypalon outer jacket.Maximnum O. D Net Veight per FrT Haxi&uM Length Maximm Pulling Tension-1.132 inches 646 lbs.2,400 feet 490 lbs.-lAU6 ¶ 7 T.RSXE ElRIV0 I I*Jacket Legend: Dekoron Dekoratd Thermocouple Extension Wire 1924 Samuel Moore A-srora. 0 1976ILat Rumber FIKAL DRAVDC MUST SUo:u CEZ1IFIED CORRXCT FOR: 1924-612A3-O01 BECUTEL P.0. 8856-131-A SUSQUEILUIXA STEAK ELECTRIC STATION UNlTS 1 AND 2?ERSYLVANXA POWER AND LIGHT CO.Signed O -T. ; Ca.-.-t Datet M/M7 DUCT DESCRtPION l SHEI T- 71 OF I I. -AY& ART 10.7/1177 1924-61ZA3-O1

....I.I I I I Attachment 2 to EC-059-1041 page 61;I.Vor dnfcrmation Only.---I., " ._CF1A G.F_ Fm-EVSION 2 t- .,, W. -',.......Tfuirn_ ----V -FF 'A An 5%h -T N.I.4.t Becktel Ta BUImber TQ-itae 47 '.SAMUELi NDORZ PART PUKBR 1902-03340-001 One (1) pair of twenty (20) gauge solid type IX (chromef alumel) conductors with twenty (20) vils EPI#I prinary Insulation and ten- (10) ails Vyalon inter ediatc jacket; color coded per ANSI standards; eighteen gauge, solid tinned copper drain vire; two (2.0) ell alUminum/Kylar tape shield and forty-five (45) a1is yellow Vypaloo outer jacket.Maxiug O.D.met Weight per )GT NaxNIM Length. -Maxivuim Pulling Tension.324 inchee.45.5 lbs.0,000 feet 23 2ba.fECEIVDF[Al AUG 1 ¶77 1'SUSaUEItAJ.

Jacket Legend: Dekoron Dekorad Therecouple Extension Wire 1902 Samuel Moore Aurora. 0 1976/Lot Number TIM DRAvING MUST SNHOs CERTIFIED CORRECT FORt-1902-03340-M1 BEcTrEL P.O. 8856-131-A SUSqUEHANNA STEAM ELECTRXC STATION.UNITS 1 and 2 PENNSYLVANIA POWER MD LIGHT'C0.Signed

• p.llate: 711277 II f i I ,- I 4*T C4 0~SAMUEL MOORE AND CD.Aurra 1 Ohio PRODUCT DESCRiPTION l SHEEt 1 COF. I ko No. -I O I T NO.7117 1902-03340-001 j-a i

-07 FF 0198Z 51h. 5 PRODUCT COOl: Cs5Oeo70 CMMTICTf DTAILSOZSCRJtrlon:

7'C 14 AN VIUIVALL1AI nOW'"TRIP" ff13016 RADIIS (OURIM K IfIALLATT?")

MRIlUN G161DIRS RADIUS PEPOARfrt TRAINING)RAXItMX PULLIRO .TtSOR (STRAIIT A.)i MAXIMUM SIDEVALL PRESSUgs lot PRODUCT CONT1I 010070 I *I. ..*.CD nTR DETAILS?P~I CASLO Ce I U07 -_.I 1.1

• IKI ts.15 , IRcKts t22 LIo 60 LS/FT Of sSlD RADIUS ,. AUCK.I.I I TC .030 'ITRYLEPF 9: rm 0.Vlp 0-,.R 0%..Ll 111 I I 1-Descittkloq 7TC. 14 AWSc PlloW. III S0OW CIRCUIT tDOifIIFSCAITI@i 1ltA NUhS I 1 R PRINT LESECI TO ItOLUDE: 'IC 14 An COPPER ROCIESTOSI UKA ARIIPACTURGO, TRACIA911.1 DIAMtCtR~a IR IAL .S10 No"I6RAL Ufl, , 139 LbS/f@C 960C FIVIVALL*

III XLPI CSP I MO. A IflUCITIAL OOTASE NAxINUYI .550-I 4 11 I.15E _Tr-' lTT, carn I e r~ I TM:=om ,_. .M M 'NAM ow i 7_ 1 0..-.

• .1 :: LA ' ...T .._ _PROPOT cool, 952-41170 UCT1~no 'D-rILS.*uc*IPt~s

~ .?I 14 Afl IISPVALL, iii *,0?SINUIl 1102IN EMIUS tS0113R4.tITALLAII@W32

.MIfIM" *It1fl RASWIS (na"A16M rlAZiflo)l

,,Amwma OgU11439.TIfON (9TRANIIT 15)1 * *MAHNwq SIfFVAU FRSURE't ., Im-* W LuIssi o I VICABLEC KID KNA IS .0s ,. ..illt ng 111TA.1A , sci",'ti, I i~,aw~m

• t$94 i:;. *j *... I....I ri, ' rs -.1.Z..;!1-1!A-, ,, re .* a -----0 (*2 0 O 6.0 ,P_ __I,..,..-. .14 PROnCT CoDed P!2-0904 WTeron I FF61-98: 5.DETAILS STUTIONDET)

IL$PROUC 'qt -'.. :-,-0 .', CM * '. ..1,'0 VITr 3.12 Awl QXOfIgW12S

.010' SLCK CHLOtS9YtFORATt¶ PO St"YLt~I ILANEt t 1sTARDT 4ACXEI n~~l~~t l.tS INCHStS^tt~B^

i .ts II OIFLYPROPILENEGOC"R 1000 LBS/FVT F BERD RADIUS._Cc

• A1 i?.0612 TC .045'FLAPI lnTXRI CROsS-LIUeS POLtETRYU9lE RIRDER, TAPE

: C FF4 6-8 ..... I ....*41$CIPTION 211 I A" FIAWAIL Ill M it 2.1$ awnn gWe qpvIRS MININum stIlk RA0IUS (MnIN IESTALtTIO@I)

' rso ne rtus.09 ItC KwV P~et~tvws tsz~te W KC 1Xl.ia R * , ,. : .iT co.n....U63 alotprVx er etn U4l1tS colmolotett slmantvl PAXIUDU PVLLIPS TIAlt JSntONT tuns,1 M1XIRR SIMPALL #RISISVRe 1.22 Z t1s IA, LOS fit mmt 71.0ses to lasupo.tP9 tocoLIS/fT or tnDo UtmS Asz NI~cSsAt)

\ /PtN 1?AII I' l 1-PIW3 oITAtPIT 311M0 TAPE ISCIPTIOsil t/C S AN PIIIVALL Sit Sol'Ci 2Cuff INWTIF*CATeg1011 )VU110S 4.PUN? LISIN sO INCLenws RI5PU4CT921A.

TRACiAIILITY

• Z*ITPI8'.

dOINALS .?40*Iq HIIL lM. MS owili Sf1 &,VS 1n7.Tt0 T1 .*4S S. CtSe~lTo 7T W WfIn 3.11t n 531 i00w '.I 3 I-r-)a 0 P1 on)3 oep R J......^-ew~2 p~____ I

-N 0 rIn I-I 0 LA 0 0 14 BIW PAR 4 13231-H-002 PE*SYLVANIA POWER & UGHT CO BECHTEL SPEC 8856-E-401 P?0.8856-E-401-A, ITEM I(COZ)..Ia* Ii 0 A, 2t 8 "-4 yt~ b3 i (A^ 14A e.1 /.O 4" TDW/ W CD~Q5 W fLNP+ C C o9 a 1<o'09 0 w-&-t -mm.W'C:, s O- Tp P (LE- JACKET, b4V 5KC:,J ! 4P &WC-,

• W C CSU,&AII F, PALR I #,o'"" ' , a4'p;'~j wilt.e 0-4 0 CO.m rio 0 6 o0 %0:%Ch.I .C-PART NO.Dci I 1fAXI e 0. N (o, V .1 n 2/t M1 AA .ARIv Part I13?3n2C 4Gw2 Peiviay.... .Pm r A Li vtft C*. .*AWt NO____________

CBIW) T P.O. F564-fOl-AC, item 1 (C02)_~s _*iA CO I .I

• -...B.* ..*. .. .*. .-.-s -l -0 0 TA-D Lr 0 LA.7 0 Ii. ..- ... .It -"- ;.19. '"_-* *;- 4 _S,_ Z ; .' ..........................

• --.blW .13232-H-003

• .PENNS'it A-' POWER. B UGHT C.. .: ECHTEL SPtC' 885G-E-401 ,j .4 i A .oov';^; l;gg &.z-(-v4(A-1AW&

W-7i.24* =U*4rf* AAAPSt~ !Ifr OI.' : ..." ' ^Wa N~v-t~mp-r cot,: FS wt EAT^ ^W ,<Ap.q I.I..113 I;', --.0 ff.*,o..R........... ...... .., I ....1.: j -: O-su pw. FINl4 -M * ..* ANGE .; : ATE i* * .l i:I- ,l ..: Ds_40 4 O I 1 Ct R A T E1 O) 1 I i i t A R T N O.I CIW P Q i B Part 013232-H-0 3 ' .-*. .l = ; ;sytvshnl Pgo56r I Ltigt .°; ;o *. * "O.*AsWm c .t .** -^* ... .A D ..e____ ___ __ .,,;. .' . ...In__a I. .... -.-.-. -.-..S..)

N 01 71 (A 0 (A~I.. -..'g46I4Z 1-'K.............

.;: W1 PAST 3 H-OQ05~Iw 1 .4 ..J _PeNNSY(LVANIA P#ER 9 LIGHT Q.BECHTEL. SPEC 8856o.E-401

.* PQ fi 885iE-4Q-AC, .TEM 3 (Oj .-:W%~~ ...L.. * , .. ;,, A;..; BEW§Z0^b '121.o z'N N lp9t p IE.~O' 'LL. ,.41S" M~Qm!Ep " Cb,'-.OLT\e.

'ELNTA.I ' .:'P>, FLA NMZO .&L AG4 T.' .¢' i ,;.ALA-"l; as; ,MS IX q) C+ *;b f'* ' VCT IL................

.';. i..0 w0.I ro E`4..t... 'b S..I.. ...... I S..t..-I* .* , .* S..* ......U.- .0 co V a rm IC)00\0 Q53 sct KW 11 -.00 140 IIS~c~f woo An riqwr ". loP5w u"1l55 w .., a st~ic IncAII b FINtIH I * .4 .N,: Fl ..CANA , .......:

• REVISIONS.---l.- .....---.--IMM.*NNVW IUflSAILII

.. ...., DUCIF1J7=

'a~lwo-unis$ l rtwt FOACT" DWW.40W , * .1 DRIN ..DATE 5..Cw4 3 DATE ;s6 IkI Pt{/ .DA OIr h&f.R *.,,__o Mfy__, r _s .I'--.*-W.!CM4 W(NS4OM ) * ; ,* , ' '.__6 wSe CA^. CC.hiLE S/C 014 AM ' .p' -AlM Part I 13234; I..O5.PennsylvanlaPewer a Lnht Co.-I Pechtel Spec 8856-E-401 P.O. 18356-E-401-C, Item n3 (LU5..I..I: I., ..@ : ..

._. .. I .4- ...: N 0-0L (A Z'0-LA 0-1'~~~. -A t w'-.PE fr.D""" ' .' .'IA 4' E5 .v... , .,,,,,,. :\-88 .-; ... { ... ...,* , ... :..,....,,.;-PAR, `35-H-OOT7

~EN~ytANIA

-' PbNR 8L~TC 8tMurEL SPEC 88b-E4O ef o~ ITEM4, (LOT)JAOCP-TP~zli=

• • .... A .'f4 .54 A~0 t%-)0 C)0'0.*, t o Mt0 WANu ain. FINISH ~ .' .OA.G.DATE

• OliN D~ATE.m leg l*( c CHICDAcE i A .', .'.PAST NO.____________________

Light -co .WS~ ~~3SH-O 1W ~ ~ ~ .~~ f8838~4 t!C tv O T0 1SC85--401.

o -DAION OQ 0 0%'0.._._-

N 1n-0 0 0f I El 0 w 0 MF no To uA lp*1 I 0 N T1 In*L-(A 0 LA-o-0 P: it1 Is..i,,11 01 ,If II jii 81W PAR 414007-H -00 3 I PENNSYLVANIA POMWER R LIGHT M.BECHTEL SPE 8856-E-401 PIQe8856-E-401-AC, 1TEM 8 (D03*1'C t I I I I I I WAV- 0, W C, CUFOVE w* , ~ OY~L .C CA5LE COL'E e 13* j ii II!.i I I* +/-AI a O151'r .:t 0:°tA It.t eA 'Wo .',.to Oe flit A .fill I.., %t I M ,,2 -_"IJ t ,r_*_rm.0 , 401 __ "-%w~F -- --.--- -'--f-f, SC I0 10m W^1..&At vw&00A

• iuKs M-15s M. I cONGt I DAT I_ e.__ n7 nL a& W. .a .I AL -I-,,,. -v-- ..%wat U_ " _"..__4 W _m A 016"W siM'.inia_BO -STON_T~t ,"11 3/C no men D1I htrt / 4M-0003 Ptnmsylvena Po w A Ubt Co.tchtel Spec 8856-401 P.o, q1M56-r.4a1.Ac, Ites S (013)___________________

I I____ w Ja 12 t' P N U'6n 0 (A 0* o1*}ti Strg 1 S p B1W PART A'14009-H-GOr PENNSYLVANIA POWERS LIGHT COa BECHTE SPEC 8856-E-401 c0e854E-'40 -Ac, ITEM 2 (DGI)I.fr.o.A6 I n4A, 1.Q "~W~.~ Co1*045WA%-L..

0:,W~ J44^E C2X: -151s CAME SYN'S w4,(sQ%) 1/C 4L*AWt, CDO VOLI. ,A 6 go 0 o 9 0 6C I r T-MtoP bt __ __ .._._-om 1 I~ --I I rs.D I "x'lOO L>f"tn" ""e'VKN unt % .em:K C D^ ATE !A" a. f I, 4 1 MMNAI SVwf0E" A 8Y 13019 eov n1"t Ie ff AMII 518 Part M14o9w-O6 Pewmsylva'iT Pe A Elht eo.I echtel SeC 1R56-tT1 IP.D. f M.S56-Iml1W, item 12 (!I1)PART NO.OCAW: NO.-a~-4 N J Lo Ihill ,. 1I.1... .. P"Y -1.a ..., 1W PART .4 OJ6 -H -O3:.PENSYLVNIA, POWEPR S LIGH: 4Z.: BECNTELPC 8856-E-40 P.Q 6.85-E-4QI-AC ITEM 13 (DG3).A 4 ,. .', 0~ : ' *(6W 4'wrfl CORSj '. A tnS b fm414 N&DP( A4e &17,.M~'S4SC(1.,.,4 x 14 0 F S.9 0 6s tA np I.',;' ,,, #,-.... .* .. ..,* f '- -'TOE NOT *- Nol .CH ANGE D AT! l Y a DIMP4*HS Nt INCS t', ..NVISI -MM oS DAT *itc8 .. 1n 6. , , * .* .V l4 *O._NU C Hi' iwui 4ecFf CWK. bAT .a FtA0ut10 ODI E

• A DAT .* BiW Part ' 14016-M-O

..: ..a>S ; * ;2 iBOBSTN

• Cbn¶vc 8p85~-E-4O3

.2 ltli i , .,..,-.WPA A- '. .9- -. -. 4 -.6 I-~A-t -h_ -,x ,", ' ;I : ' ,1- I, ~. .-. .I'; I, 1 ;' '- ...........

,' ., ..', *:,I ,__ ' ,: f: .: -.. : '. ' ;.-.: , ' I,' I t15_W

...d9w H I N-n CA 0 BIW ART 14013-H-003 iI 0 PENNSVAN1A POWER A LIGHT BECHTEL SPEC 8856-E-401 RiO*+86-E-4O-AC, ITEM I1 Ca (D83),A 5 ez Si 5v,1fOA%0 r.~Ic (qmw- C tyi Jc<t z F= ?CRTPt. 0Td`.C C O CC¢ 0 9 O h C.Loo?.lat~e!'

PQI S .JA>* Eft~s* eSvertN'i1 F ave^.4 0 n., 0 0.R_= -C-HANGE 3 By~ lO MAlt'W-l ICAWA c il .I 50P O ISrnw tCW ____ __ _ _____.__,__

__ _ o 3R'N"Xt T 3 C #8 A19"Ac?'.t VW S no *Ar~ V~W 0 A " ~ ~~ ,BWPv R1-- O P-ollylymia Pow & Lioht Co.o _ wOAT.N 8eehtel Spe" M64-! 1 NO.7 A W B LATM P.o. 1 W56..-Jfn- , Item 11 (M)la* v Attachment 3 to EC-059-1041 page 75 Attachment 3 Email from R. Vazqules to M. Waselus SPpFJCond.xis

i;A.? ., , A...

Attachment 3 to EC-059-1041 page 76 TOscwu"43Mictiasid K nWaselizr.imaSLbW SabI&Cptt n4: Tor Rh*insdividual I=4 Svpweeuuln MIR;. anld for tha CacbLao Uas&. Rb.*fnn-3 S~qrs Vovo to Is 3. ThieresI me oftsurmn r25a 4.2. CMa rsst Are 13 Or hj;h~- DpOCJDQ 2h Cng&IteINt ps in. I bell.:. that wi *"Id .*pport

• w *aunvLue of .. tI lilojy RI=t ELI off Cho f"antsreaujan wt.1 he 9: rhghr fItsio GrjtiC&2 and IC CoiLive Writh It, then A OW02IISMin aW ol Rate Chat the Ahipprih*La.

p*1l water in at rekatii*1.y Mtprt.This SMans tAet Lt ba* littis bufhtng GOenCity sliad theV wl e sWwitli*to gelmtlvely amall widitlono of &*jd or banse..Aan dn't k~W how the *619Okatleas work, hut m0elt Not to .th Wb 0*o s w tbat.*sy osuet. trlsoiULM pifoeptmec n1. aalat to l LO pain tbo*lian of & CMA. or inject Waanf to tile same oncoct. If ws 1n3.et Sir. W Senti Uednesday.

Dwo-enb..

GS. 3004 10.30 M9 tos vatquiea.

Reoold Allen xLebjwootuI HtaiR*0?cflt 90and the awgds Vat. but I thinA t sor~t Too Chia Plet.I supreavslo Pool pH Combined 8811!1 byd S O January 90O to October 20$4 T I A a I.1 I A.0 n 0 VI M1 .2 C.S .4 ea as qr Cl as 7 7.1 7.2 7.3 A 7,5 7A PW 111--1-- -*I-4-4