ML13232A217: Difference between revisions

From kanterella
Jump to navigation Jump to search
(Created page by program invented by StriderTol)
(Created page by program invented by StriderTol)
 
(3 intermediate revisions by the same user not shown)
Line 3: Line 3:
| issue date = 07/31/2013
| issue date = 07/31/2013
| title = Attachment 2 - Areva Document No. ANP-3102, Revision 3,Three-Mile Island Unit 1 Appendix G Pressure-Temperature Limits at 50.2 EFPY with Mur, Revision 3, Dated July 2013
| title = Attachment 2 - Areva Document No. ANP-3102, Revision 3,Three-Mile Island Unit 1 Appendix G Pressure-Temperature Limits at 50.2 EFPY with Mur, Revision 3, Dated July 2013
| author name = Mahmoud S H
| author name = Mahmoud S
| author affiliation = AREVA NP, Inc
| author affiliation = AREVA NP, Inc
| addressee name =  
| addressee name =  
Line 17: Line 17:


=Text=
=Text=
{{#Wiki_filter:ATTACHMENT 2 AREVA Document No. ANP-3102, Revision 3, "Three-Mile Island Unit 1 Appendix G Pressure-Temperature Limits at 50.2 EFPY with MUR," Revision 3, dated July 2013 ANP-3102, Rev. 3 July 2013 Three-Mile Island Unit I Appendix G Pressure-Temperature Limits at 50.2 EFPY with MUR ANP-3102, Rev. 3 July 2013 Three-Mile Island Unit 1 Appendix G Pressure-Temperature Limits at 50.2 EFPY with MUR Prepared by S. H. Mahmoud Reviewed by A.D. Nana AREVA Document No.77-3102-003 Prepared for Exelon Generation Co., LLC A AREVA ANP-3102, Rev. 3 Copyright
{{#Wiki_filter:ATTACHMENT 2 AREVA Document No. ANP-3102, Revision 3, "Three-Mile Island Unit 1 Appendix G Pressure-Temperature Limits at 50.2 EFPY with MUR," Revision 3, dated July 2013
© 2013 AREVA.All Rights Reserved A AREVA A AREVA ANP-3102, Rev. 3 Record of Revision Revision Pages/Sections/Paragraphs No. Changed Brief Description
/ Change Authorization 000 All Original Release 001 Page 2 Changed first sentence of first paragraph and deleted second and third paragraphs.
001 Page 49 Corrected graph format.002 Pages 3 and 4 Corrected the entry on the first column last row from "IS to LS Circ. Weld (63%)" to "LS Longit. Weld (OD 63%)" in both Tables 1 and 2 003 Page 2 Corrected misrepresentation of reference number to Regulatory Guide 1.99, Revision 2 in the reference list.Page 6 Corrected description of the input temperature-time histories (225 is changed to 255)Page 13 1. Changed "The location adjusted P-T limits calculated for normal step cooldown are shown in Table 10" to "The location adjusted P-T limits calculated for ISLH step cooldown are shown in Table 10" 2. Changed "The criticality limit temperature corresponding to a pressure of 2500 psig read from Figure 2, or it can be can be determined through interpolation of ISLH heatup data in Table 6." to "The criticality limit temperature corresponding to a pressure of 2500 psig can be determined through interpolation of ISLH heatup data in Table 6.3. Changed "The criticality limit curve is shown in Figure 1" to "The criticality limit curve is shown in Figure 3" Page 53 Inserted reference 10.++A AREVA A AREVA ANP-3102, Rev. 3 Table of Contents Page RECORD OF REVISION ........................................................................................................................
I LIST OF TABLES .................................................................................................................................
IV LIST OF FIGURES ................................................................................................................................
V


==1.0 INTRODUCTION==
ANP-3102, Rev. 3 July 2013 Three-Mile Island Unit I Appendix G Pressure-Temperature Limits at 50.2 EFPY with MUR


........................................................................................................................
ANP-3102, Rev. 3 July 2013 Three-Mile Island Unit 1 Appendix G Pressure-Temperature Limits at 50.2 EFPY with MUR Prepared by S. H. Mahmoud Reviewed by A.D. Nana AREVA Document No.
1
77-3102-003 Prepared for Exelon Generation Co., LLC


==2.0 BACKGROUND==
A                        ANP-3102, Rev. 3 AREVA Copyright © 2013 AREVA.
All Rights Reserved A
AREVA


..........................................................................................................................
A                                                                                    ANP-3102, Rev. 3 AREVA Record of Revision Revision    Pages/Sections/Paragraphs No.                Changed                  Brief Description / Change Authorization 000          All                          Original Release 001          Page 2                      Changed first sentence of first paragraph and deleted second and third paragraphs.
1 3.0 ADJUSTED NIL-DUCTILITY TRANSITION REFERENCE TEMPERATURES  
001          Page 49                      Corrected graph format.
........................
002          Pages 3 and 4                Corrected the entry on the first column last row from "IS to LS Circ. Weld (63%)" to "LS Longit. Weld (OD 63%)" in both Tables 1 and 2 003          Page 2                      Corrected misrepresentation of reference number to Regulatory Guide 1.99, Revision 2 in the reference list.
2 4.0 DESIGN BASIS FOR PRESSURE/TEMPERATURE LIMITS .................................................
Page 6                      Corrected description of the input temperature-time histories (225 is changed to 255)
5 4.1 Material Properties  
Page 13                      1. Changed "The location adjusted P-T limits calculated for normal step cooldown are shown in Table 10" to "The location adjusted P-T limits calculated for ISLH step cooldown are shown in Table 10"
............................................................................................................................
: 2. Changed "The criticality limit temperature corresponding to a pressure of 2500 psig read from Figure 2, or it can be can be determined through interpolation of ISLH heatup data in Table 6." to "The criticality limit temperature corresponding to a pressure of 2500 psig can be determined through interpolation of ISLH heatup data in Table 6.
5 4.2 Postulated Flaws ...............................................................................................................................
: 3. Changed "The criticality limit curve is shown in Figure 1" to "The criticality limit curve is shown in Figure 3" Page 53                      Inserted reference 10.
5 4.3 Upper Shelf Toughness  
          +
............................................................................................................
          +
5 4.4 Uncorrected Reactor Vessel Closure Head Limits ........................................................................
A AREVA
6 4.5 Convection Film Coefficient  
 
...............................................................................................................
A AREVA                                                                                                                                        ANP-3102, Rev. 3 Table of Contents Page RECORD OF REVISION ........................................................................................................................                        I LIST OF TABLES .................................................................................................................................                  IV LIST OF FIGURES ................................................................................................................................                  V
6 4.6 Reactor Coolant Temperature-Time Histories  
 
..............................................................................
==1.0  INTRODUCTION==
6 4.7 Adjusted Reference Temperatures  
........................................................................................................................                        1
...............................................................................................
 
6 5.0 TECHNICAL BASIS FOR PRESSURE/TEMPERATURE LIMITS ...........................................
==2.0  BACKGROUND==
8 5.1 Fracture Toughness  
..........................................................................................................................                       1 3.0   ADJUSTED NIL-DUCTILITY TRANSITION REFERENCE TEMPERATURES ........................ 2 4.0   DESIGN BASIS FOR PRESSURE/TEMPERATURE LIMITS .................................................                                                               5 4.1   Material Properties ............................................................................................................................       5 4.2   Postulated Flaws ...............................................................................................................................       5 4.3   Upper Shelf Toughness ............................................................................................................                     5 4.4   Uncorrected Reactor Vessel Closure Head Limits ........................................................................                               6 4.5   Convection Film Coefficient ...............................................................................................................           6 4.6   Reactor Coolant Temperature-Time Histories ..............................................................................                             6 4.7   Adjusted Reference Temperatures ...............................................................................................                       6 5.0   TECHNICAL BASIS FOR PRESSURE/TEMPERATURE LIMITS ...........................................                                                                 8 5.1   Fracture Toughness ..........................................................................................................................         9 5.2   Thermal Analysis and Thermal Stress Intensity Factor ...............................................................                                   9 5.3   Unit Pressure Stress Intensity Factor for Reactor Vessel Beltline Region ................................ 10 5.4   Unit Pressure Stress Intensity Factor for Reactor Vessel Nozzles ............................................                                         11 6.0   PRESSURE CORRECTIONS ................................................................................................                                     12 7.0  
..........................................................................................................................
9 5.2 Thermal Analysis and Thermal Stress Intensity Factor ...............................................................
9 5.3 Unit Pressure Stress Intensity Factor for Reactor Vessel Beltline Region ................................
10 5.4 Unit Pressure Stress Intensity Factor for Reactor Vessel Nozzles ............................................
11 6.0 PRESSURE CORRECTIONS  
................................................................................................
12 7.0  


==SUMMARY==
==SUMMARY==
O F RESULTS ........................................................................................................
O F RESULTS ........................................................................................................                               12 7.1   P-T Curves for ISLH Heatup / Cooldown ...................................................................................                             13 7.2   P-T Curves for Normal Heatup / Cooldown ...............................................................................                               32 8.0   SUM MARY ...............................................................................................................................                   48 9.0   CERTIFICATION ......................................................................................................................                       52 ii A
12 7.1 P-T Curves for ISLH Heatup / Cooldown ...................................................................................
AREVA
13 7.2 P-T Curves for Normal Heatup / Cooldown ...............................................................................
 
32 8.0 SUM MARY ...............................................................................................................................
A                                                                                                                             ANP-3102, Rev. 3 AREVA Table of Contents (continued)
48 9.0 CERTIFICATION  
Page
......................................................................................................................
52 ii A AREVA A AREVA ANP-3102, Rev. 3 Table of Contents (continued)
Page  


==10.0 REFERENCES==
==10.0 REFERENCES==
......................................................................................................................... 53 A
AREVA
A ARE'VA                                                                                                                        ANP-3102, Rev. 3 List of Tables Page Table 1: Adjusted Reference Temperature Evaluation for the TMI-1 Reactor Vessel Beltline Materials at the 1/1/2-Thickness Locations Applicable Through 50.2 EFPY with MUR ...................................                                  3 Table 2: Adjusted Reference Temperature Evaluation for the TMI -1 Reactor Vessel Beltline Materials at the 3/4-Thickness Locations Applicable Through 50.2 EFPY with MUR ...................................                                    4 Table 3: Material Properties ...........................................................................................................      5 Table 4: Lim iting RTNDT'S for TM I-1 Beltline Materials ........................................................................            7 Table 5: Limiting Location Corrections Factors for Pressure ...............................................................                  12 Table 6: TMI-1 Adjusted Location Specific P-T Limits for ISLH Heatup ..........................................                              14 Table 7: TMI-1 Criticality Limit Temperature Determination ............................................................                      16 Table 8: TMI-1 Tech. Spec. Basis P-T Limits for ISLH Heatup ........................................................                        17 Table 9: TMI-1 Adjusted Location Specific P-T Limits for ISLH Ramp Cooldown ............................ 20 Table 10: TMI-1 Adjusted Location Specific P-T Limits for ISLH Step Cooldown ............................ 23 Table 11: TMI-1 Tech Spec. Basis P-T Limits for ISLH Cooldown .................................................                              24 Table 12: TMI-1 Tech Spec. Basis P-T Limits for ISLH Composite Curve ......................................                                  27 Table 13: TMI-1 Adjusted Location Specific P-T Limits for Normal Heatup .....................................                                33 Table 14: TMI-1 Tech. Spec. Basis P-T Limits for Normal Heatup .................................................                            36 Table 15: TMI-1 Adjusted Location Specific P-T Limits for Normal Ramp Cooldown .......................                                      39 Table 16: TMI-1 Adjusted Location Specific P-T Limits for Normal Step Cooldown ........................                                      42 Table 17: Tech Spec. Basis P-T Limits for Normal Limiting Cooldown ............................................                              43 iv A
AREVA
A AREVA ANP-3102, Rev. 3 List of Figures Page Figure 1: TMI-1 Adjusted P-T Limits for ISLH Heatup and Cooldown .............................................                                                    30 Figure 2: TMI-1 Tech. Spec. Basis P-T Limits for ISLH (Composite Curve) ...................................                                                      31 Figure 3: TMI-1 Tech. Spec. Basis P-T Limits for Normal Heatup and Criticality Limit .....................                                                        46 Figure 4: TMI-1 Tech. Spec. Basis P-T Limits for Normal Cooldown ...............................................                                                  47 Figure 5: TMI-1 Summary Tech Spec. Basis P-T Limits at 50.2 EFPY with MUR for Normal Heatup and Critica lity Lim it ...............................................................................................................................          49 Figure 6: TMI-1 Summary Tech. Spec. Basis P-T Limits at 50.2 EFPY with MUR for Normal Cooldown
    ......................................................................................................................................................        50 Figure 7: TMI-1 Summary Tech. Spec. Basis P-T Limits at 50.2 EFPY with MUR for ISLH (Composite C u rv e ) ...........................................................................................................................................        51 A
AREVA
A                                                                                                ANP-3102, Rev. 3 AREVA
==1.0      INTRODUCTION==
This report presents operational pressure-temperature (P-T) limits for the reactor vessel at Three-Mile-Island Unit 1 (TMI-1). These limits are expressed in the form of a curve of allowable pressure versus temperature. In addition, the minimum temperature for core criticality is determined to satisfy the regulatory requirements of 10 CFR Part 50, Appendix G [1]. The uncorrected P-T limits for TMI-1 were determined for 50.2 effective full power years (EFPY) of operation with Measurement Uncertainty Re-capture (MUR). Pressure-temperature limits are calculated for the reactor vessel beltline, inlet and outlet nozzles, and closure head locations for normal heatup, normal cooldown, and inservice leak and hydrostatic (ISLH) test conditions. Pressure correction factors were determined between the RCS hot leg pressure taps and various other RCS locations.
==2.0      BACKGROUND==
The ability of the reactor pressure vessel to resist fracture is the primary factor in ensuring the safety of the primary system in light water-cooled reactors. The three areas of the reactor coolant pressure boundary addressed in the present report are the beltline shell region, the reactor coolant nozzles, and the closure head flange region.
A method for guarding against brittle fracture in reactor pressure vessels is described in Appendix G to the ASME Boiler and Pressure Vessel Code, Section XI, "Rules for Inservice Inspection of Nuclear Power Plant Components."[2]. This method utilizes fracture mechanics concepts and the reference temperature for nil-ductility transition, RTNDT, which is defined as the greater of the drop weight nil-ductility transition temperature (per ASTM E208 [3]) or the temperature that is 60 'F below that at which the material exhibits 50 ft-lbs and 35 mils lateral expansion. The RTNDT of a given material is used to index that material to a reference stress intensity factor curve (K1,). The Kl,, curve appears in Appendix G of ASME Code Section XI. When a given material is indexed to the K1 , curve, allowable stress intensity factors can be obtained for this material as a function of temperature.
Plant operating limits can then be determined using these allowable stress intensity factors.
The RTNDT of the reactor vessel materials, and in turn, the pressure/temperature limits of a reactor vessel, must be adjusted to account for the effects of irradiation. Neutron embrittlement and the resultant changes in mechanical properties of a given pressure vessel steel are monitored by a surveillance program consisting of periodic removal of surveillance capsules from an operating reactor and testing of reactor vessel material specimens obtained from the capsules. The increase in the Charpy V-notch 30 ft-lb temperature is added to the unirradiated RTNDT to adjust it for neutron embrittlement. This adjusted RTNDT is used to index the material to the K1, curve, which in turn, is used to set new operating limits for the nuclear power plant. These new limits take into account the effects of irradiation on the reactor vessel materials.
Pressure-temperature limits for the TMI-1 reactor vessel are developed in accordance with the requirements of 10 CFR Part 50, Appendix G [1], utilizing the analytical methods and flaw acceptance criteria of topical report BAW-10046A [4] and ASME Code Section XI, Appendix G[2].
As mentioned earlier, the three areas of the reactor coolant pressure boundary addressed in this report are the beltline shell region, the reactor coolant nozzles, and the closure head flange region. The beltline and nozzle regions are analyzed specifically for TMI-1 using the K1c reference fracture toughness. The effect of the change in the reference fracture toughness curve on the P-T limits for the closure head flange region is included by utilizing generic limits that have been derived for B&W-designed 177FA reactor vessels.
The TMI-1 reactor vessel contains both axially and circumferentially oriented welds. Therefore, the P-T limits for TMI-1 is based on the postulation of both axial and circumferential flaws in the most limiting axial and circumferential welds and the postulation of an axial flaw in the most limiting forging material of the reactor vessel.
Page 1 A
ARE VA
A                                                                                              ANP-3102, Rev. 3 AREVA One-hundred percent steady state condition Appendix G limits were considered for the development of low temperature overpressure protection (LTOP) P-T limits. To further support the development LTOP system limits, temperature differences between the reactor coolant in the downcomer region and the 1/4/4t wall location are determined for the maximum heatup rate transient. The V4 t wall location is defined as a point within the vessel wall that is located at a distance of one quarter of the vessel thickness from the cladding-base metal interface.
3.0      ADJUSTED NIL-DUCTILITY TRANSITION REFERENCE TEMPERATURES The '/4 t and / t ART values for the TMI-I reactor vessel beltline materials applicable to 50.2 EFPY with MUR are listed in Table 1 and Table 2. These values were calculated in accordance with Regulatory Guide 1.99, Revision 2 [10]. The calculation of the ART values for the weld metals also used BAW-2308 Revision IA and 2A [5]. The controlling beltline materials for the Three Mile Island Unit 1 reactor vessel are the lower nozzle belt to upper shell circumferential weld with ART values at 50.2 EFPY with MUR of 216.0 OF at the 1/4T wall location and 161.1 OF at the 3/4Twall location and the axial welds of the lower shell and upper shell, respectively with ART values at 50.2 EFPY with MUR of 183.9 °F at the 1/4 T wall location and 126.8 °F at the /4T wall location.
The ART values used for the development of the Three Mile Island Unit 1 reactor vessel P-T limits curves, calculated in 2006 for license renewal, were 234.5°F at the '/4T wall location and 178.5°F at the 3/4Twall location for the circumferential welds. The ART values used for the axial welds were 184.7 °F at the 1/4/T wall location and 126.8 °F at the 3/4 T wall location. Thus, in all instances the actual ART values or conservative ART values were used in the development of P-T limit curves performed in 2006.
Page 2 A
AREVA
A ARIEVA                                                                                                                                                              ANP-3102, Rev. 3 Table 1: Adjusted Reference Temperature Evaluation for the TMI-1 Reactor Vessel Beltline Materials at the 1/4-Thickness Locations Applicable Through 50.2 EFPY with MUR Estimated Fluence        Adiusted Reference Temperature Evaluation at 1/4T Location Reactor Vessel                        MatI.
ent Heat Numer A 50.2 EFPY, n/cm 2
Chema. Fluence  R Initial I RT.sT, a,  I 0
e I RTNr Shift, r,            1/4T Beltllne Region Location            Ident.      Number            Type            Cu      Ni        IS          1/4T  Factor    Factor        F                J F        Margin      ART Re*ulatory Guide 1.99, Revision 2, Position 1.1 Lower Nozzle Belt Forging (LNB)                              ARY 59      123S454    SA-508 CI2            0.08    0.72  1.32E+19    7.698E+18  51.0    0.927        3      31    17    47.3    70.7      121.0 Upper ShellPlate (US)              C2789-1      C2789-1    SA-302 Gr B Mod.      0.09    0.57  1.47E+19    8.575E+18  58.0    0.957        1      26.9    17    55.5    63.6      120.1 Upper Shell Plate (US)            C2789-2      C2789-2    SA-302 Gr B Mod.      0.09    0.57  1.47E+19    8.575E+18  58.0      0.957        1      26.9    17    55.5    63.6      120.1 Lower Shell Plate (LS)            C3307-1      C3307-1    SA-302 Gr B Mod.      0.12    0.55  1.47E+19    6.575E+18  82.0    0.957        1      26.9  17    78.5    63.6      143.1 Lower Shell Plate (LS)            C3251-1      C3251-1    SA-302 Gr B Mod.      0.11    0.5  1.47E+19    8.575E+18  73.0    0.957        1      26.9  17    69.9    63.6      134.5 LNB to US Circ. Weld (100%)        WF-70        72105      Linde 80 Flux          0.32    0.58  1.32E+19    7.698E+18  199.3    0.927      -31.1    13.7  28    184.8    62.3    [216.0]
US Longit. Weld (Both 100%)        WF-8        8T1762    Linde 80 Flux          0.19    0.57  1.31E+19    7.662E+18  167.0    0.925      -47.6    17.2  28    154.5    65.7      172.6 US to LS Circ. Weld (100%)        WF-25        299L44    Linde 80 Flux          0.34    0.68  1.43E+19    8.335E+18 220.6    0.949      -74.3    12.8  28    209.3    61.6      196.6 LS Longit. Weld (100%)            SA-1526      299L44    Linde 80 Flux          0.34    0.66  1.16E+19    6.778E÷18 220.6      0.891      -74.3    12.8  28    196.6    61.6    {183.9)
LS Longit. Weld (ID 37%)          SA-1526      299L44    Linde 80 Flux          0.34    0.68  1.15E+19    6.755E+18 220.6      0.890      -74.3    12.8  28    196.3    61.6      183.6 LS Longit. Weld (OD 63%)          SA-1494      8T1554    Linde 80 Flux          0.16    0.57  1.15E+19        N/A  167.0      N/A      -47.6    17.2  28    N/A      N/A        N/A
  -  Highest values of the adjusted reference temperature for circumferential welds.
    - Highest values of the adjusted reference temperature for base metal or longitudinal welds.
Page 3 A
ARIEVA
A                                                                                                                                                                ANP-3102, Rev. 3 AR EVA Table 2: Adjusted Reference Temperature Evaluation for the TMI -1 Reactor Vessel Beltline Materials at the                                                            %-
Thickness Locations Applicable Through 50.2 EFPY with MUR Estimated Fluence        Adusted Reference Temperature Evaluation at 3/4T Location Reactor Vessel                      Matt        Heat                                            C 50.2 EFPY, n/cm 2
Chem. (Fluence      Initial        Jo. RTNoT                3/4T Beltilne Region Location            Ident.      Number            Type            CU      Ni        IS        3/4T  Factor  Factor        F    '                F    Margin      ART Regulatory Guide 1.99, Revision 2, Position 1.1 Lower Nozzle Belt Forging (LNB)                              ARY 59      123S454    SA-508 C02            0.08    0.72  1.32E-19    2.80E+18  51.0    0.652      3        31  17      33.3    70.4      106.7 Upper Shell Plate (US)            C2789-1      C2789-1    SA-302 Gr B Mod.      0.09    0.57  1.47E+19    3.12E+18  58.0    0.680      1      26.9  17      39.4    63.6      104,0 Upper Shell Plate(US)            C2789-2      C2789-2    SA-302 Gr B Mod.      0.09    0.57  1.47E+19    3.12E+18  58.0    0.680      1      26.9  17      39.4    63.6      104.0 Lower Shell Plate(LS)            C3307-1      C3307-1    SA-302 Gr B Mod.      0.12    0.55  1.47E+19    3.12E+18  82.0    0.680      1      26.9  17      55.8    63.6      120.4 Lower Shell Plate (LS)            C3251-1      C3251-1    SA-302 Gr 8 Mod.        0.11  0.50  1.47E+19    3.12E+18  73.0    0.680        1      26.9  17      49.6    63.6      114.2 LNB to US Circ. Weld (100%)      WF-70        72105      Linde  80 Flux          0.32  0.58  1.32E+19    2.80E+18  199.3    0.652    -31.1    13.7  28    129.9    62.3    [161.1]
US Longit. Weld (Both 100%)      WF-8        8T1762    Linde  80 Flux        0.19    0.57  1.31E-19    2.78E+18  167.0    0.651    -47.6    17.2  28    108.7    65.7    {126.8J US to LS Circ. Weld (100%)        WF-25        299L44    Linde  80 Flux        0.34    0.68  1.43E+19    3.03E+18  220.6    0.673    -74.3    12.8  28    148.5    61.6      135.8 LS Longit. Weld (100%)            SA-1526      299L44    Linde  80 Flux        0.34    0.68  1.16E+19    2.46E+18  220.6    0.620    -74.3    12.8  28    136.8    61.6      124.1 LS Longit. Weld (ID 37%)          SA-1526      299144    Linde  80 Flux          0.34  0.68  1.15E+19        N/A  220.6      N/A      -74.3    12.8  28      N/A      N/A        N/A LS Longit. Weld (OD 63%)          SA-1494      8T1554    Linde  80 Flux          0.16  0.57  1.15E+19    2.45E+18  167.0    0.619    -47.6    17.2  28    103.4    65.7      121.5 3- Highest values of the adjusted reference  temperature for circumferential welds.
    - Highest values of the adjusted reference temperature for base metal or longitudinal welds.
Page 4 A
AREVA
A                                                                                                ANP-3102, Rev. 3 AREVA 4.0      DESIGN BASIS FOR PRESSURE/TEMPERATURE LIMITS Essential geometric data and analytical parameters used in the preparation of TMI-1 P-T limits are described below.
4.1          Material Properties Table 3 describes the material properties used in the development of the P-T limits for the TMI-1.
Table 3: Material Properties Temp.        Elastic          Thermal        Thermal          Specific        Density        Poisson's Modulus          Expansion    Conductivity          Heat                            Ratio Ref. [6]        Ref61          Ref.[6]          Ref.[6]                        (assumed)
(°F)        (106 psi)      (10- in/in/°F)  Btu/hr-ft-°F)      (Btu/lb-°F)      (lb/ft3 )
70          29.20            7.02            23.3            0.104            490.9            0.3 100          29.04            7.06            23.6            0.107            490.5            0.3 150          28.77            7.16            24.1            0.111          489.9            0.3 200          28.50            7.25            24.4            0.114          489.2            0.3 250          28.25            7.34            24.6            0.117            488.6            0.3 300          28.00            7.43            24.7            0.121            487.9            0.3 350          27.70            7.50            24.7            0.124            487.3            0.3 400          27.40            7.58            24.6            0.127          486.7            0.3 450          27.20            7.63            24.4            0.129          486.0            0.3 500          27.00            7.70            24.2            0.132          485.4            0.3 550          26.70            7.77            23.9            0.135            484.7            0.3 600          26.40            7.83            23.5            0.138            484.1            0.3 650          25.85            7.90            23.2            0.141          483.4            0.3 700          25.30            7.94            22.8            0.144          482.8            0.3 4.2      Postulated Flaws
: a.      Postulated Reactor Vessel Beltline Flaws Semi-elliptical surface flaws that are '/4t deep and 11/ 2 t long are postulated on the inside and outside surfaces of the reactor vessel beltline region. A longitudinal flaw is postulated in the base metal and the axial seam welds and a circumferential flaw is postulated in the circumferential welds.
: b.      Postulated Nozzle Comer Flaw A 3" (1/4 tNB) deep comer flaw is postulated on the inside surface of the reactor vessel inlet and outlet nozzles.
4.3      Upper Shelf Toughness A maximum value of 200 ksi'An is used for the upper shelf fracture toughness of the reactor vessel beltline. For the nozzle forging materials, a "no cut-off' limit is used.
Page 5 A
AREVA


.........................................................................................................................
A AREVA ANP-3102, Rev. 3 4.4    Uncorrected Reactor Vessel Closure Head Limits Pressure-temperature limits for the reactor vessel head-to-flange closure region for normal operation and ISLH operation were derived for TMI- I reactor vessel closure head region based on the K c fracture toughness curve.
53 A AREVA A ARE'VA ANP-3102, Rev. 3 List of Tables Page Table 1: Adjusted Reference Temperature Evaluation for the TMI-1 Reactor Vessel Beltline Materials at the 1/1/2-Thickness Locations Applicable Through 50.2 EFPY with MUR ...................................
4.5     Convection Film Coefficient A value of 1000 BTU/hr-ft2 -°F is used for an effective convective heat transfer film coefficient at the cladding-to-base metal interface for all times during heatup and cooldown when reactor coolant pumps (RCPs) are in use.
3 Table 2: Adjusted Reference Temperature Evaluation for the TMI -1 Reactor Vessel Beltline Materials at the 3/4-Thickness Locations Applicable Through 50.2 EFPY with MUR ...................................
When no reactor coolant pumps are running (i.e., before the first RCP is started during heatup and after the last RCP is shut off during cooldown), a value of 430 BTU/hr-ft 2-°F is used as an effective film coefficient at the cladding-to-base metal interface. This value was developed for flow conditions when no RCPs are running and 40
4 Table 3: M aterial Properties
°F water enters the vessel through the core flood nozzle as the decay heat removal system switches to an idle low pressure injection cooler. The outside surface is always modeled as a perfectly insulated boundary.
...........................................................................................................
4.6    Reactor Coolant Temperature-Time Histories Both ramped and stepped transient definitions are modeled for normal operation heatup and cooldown. The limiting normal heatup and cooldown transients (as determined by the controlling P-T limits) are also used to simulate the reactor coolant transients used for inservice leak and hydrostatic (ISLH) pressure testing.
5 Table 4: Lim iting RTNDT'S for TM I-1 Beltline Materials
The following input temperature-time histories are considered:
........................................................................
Normal Ramp Heatup, 50 *F/hr.
7 Table 5: Limiting Location Corrections Factors for Pressure ...............................................................
Normal Step Heatup, 15 OF/ 18 min. steps.
12 Table 6: TMI-1 Adjusted Location Specific P-T Limits for ISLH Heatup ..........................................
Normal Ramp Cooldown, 100 °F/hr to 255 'F then 30 0F/hr to 70 'F.
14 Table 7: TMI-1 Criticality Limit Temperature Determination
Normal Step Cooldown, 15'F/ 9 min. steps to 255 'F then 15 'F/ 30 min. steps to 70 'F.
............................................................
4.7    Adjusted Reference Temperatures As discussed in Section 3.0, limiting values of the adjusted reference temperature were evaluated. The limiting ART or RTNDT values that were used for determining the P-T curves are also listed in Table 4 for the l/4t and 3/ 4 t locations of the reactor vessel beltline wall at 50.2 EFPY with MUR. An RTNDT of 60 OF is used for the reactor vessel nozzles.
16 Table 8: TMI-1 Tech. Spec. Basis P-T Limits for ISLH Heatup ........................................................
Page 6 A
17 Table 9: TMI-1 Adjusted Location Specific P-T Limits for ISLH Ramp Cooldown ............................
ARE VA
20 Table 10: TMI-1 Adjusted Location Specific P-T Limits for ISLH Step Cooldown ............................
23 Table 11: TMI-1 Tech Spec. Basis P-T Limits for ISLH Cooldown .................................................
24 Table 12: TMI-1 Tech Spec. Basis P-T Limits for ISLH Composite Curve ......................................
27 Table 13: TMI-1 Adjusted Location Specific P-T Limits for Normal Heatup .....................................
33 Table 14: TMI-1 Tech. Spec. Basis P-T Limits for Normal Heatup .................................................
36 Table 15: TMI-1 Adjusted Location Specific P-T Limits for Normal Ramp Cooldown .......................
39 Table 16: TMI-1 Adjusted Location Specific P-T Limits for Normal Step Cooldown ........................
42 Table 17: Tech Spec. Basis P-T Limits for Normal Limiting Cooldown ............................................
43 iv A AREVA A AREVA ANP-3102, Rev. 3 List of Figures Page Figure 1: TMI-1 Adjusted P-T Limits for ISLH Heatup and Cooldown .............................................
30 Figure 2: TMI-1 Tech. Spec. Basis P-T Limits for ISLH (Composite Curve) ...................................
31 Figure 3: TMI-1 Tech. Spec. Basis P-T Limits for Normal Heatup and Criticality Limit .....................
46 Figure 4: TMI-1 Tech. Spec. Basis P-T Limits for Normal Cooldown ...............................................
47 Figure 5: TMI-1 Summary Tech Spec. Basis P-T Limits at 50.2 EFPY with MUR for Normal Heatup and C ritica lity L im it ...............................................................................................................................
4 9 Figure 6: TMI-1 Summary Tech. Spec. Basis P-T Limits at 50.2 EFPY with MUR for Normal Cooldown......................................................................................................................................................
5 0 Figure 7: TMI-1 Summary Tech. Spec. Basis P-T Limits at 50.2 EFPY with MUR for ISLH (Composite C u rv e ) ...........................................................................................................................................
5 1 A AREVA A AREVA ANP-3102, Rev. 3


==1.0 INTRODUCTION==
A                                                                    ANP-3102, Rev. 3 AREVA Table 4: Limiting RTNDT'S    for TMI-1 Beltline Materials Vessel              Wall          Limiting      RTNDT  (OF)
Component            Location        Material        at 50.2 EFPY Beltline              1/ t          SA-1526          184.7 4
Axial Weld                            WF-8            126.8 Beltline              1/4t          WF-70          234.5 Circ. Weld          _7/_4t
_            WF-70          178.5 Page 7 A
AREVA


This report presents operational pressure-temperature (P-T) limits for the reactor vessel at Three-Mile-Island Unit 1 (TMI-1). These limits are expressed in the form of a curve of allowable pressure versus temperature.
A                                                                                                ANP-3102, Rev. 3 AREVA 5.0      TECHNICAL BASIS FOR PRESSURE/TEMPERATURE LIMITS Pressure-temperature limits are developed using an analytical approach that is in accordance with the requirements of the ASME Boiler and Pressure Vessel Code, Section XI, Appendix G [2]. Additional requirements are contained in Table 1 of Appendix G to Title 10, Code of Federal Regulations, Part 50 [1]. The analytical techniques used to calculate P-T limits are based on approved linear elastic fracture mechanics methodology described in topical report BAW-10046A [4]. The fundamental equation used to calculate the allowable pressure is Pallow KIR - Krr SFx ki where, Pallow    =      allowable pressure KI      =      reference stress intensity factor ( K a or K 1c Srr  =      thermal stress intensity factor I,    =      unit pressure stress intensity factor (due to 1 psig)
In addition, the minimum temperature for core criticality is determined to satisfy the regulatory requirements of 10 CFR Part 50, Appendix G [1]. The uncorrected P-T limits for TMI-1 were determined for 50.2 effective full power years (EFPY) of operation with Measurement Uncertainty Re-capture (MUR). Pressure-temperature limits are calculated for the reactor vessel beltline, inlet and outlet nozzles, and closure head locations for normal heatup, normal cooldown, and inservice leak and hydrostatic (ISLH) test conditions.
SF      =      safety factor For each analyzed transient and steady state condition, the allowable pressure is determined as a function of reactor coolant temperature considering postulated flaws in the reactor vessel beltline, inlet nozzle, outlet nozzle, and closure head. In the beltline region, flaws are postulated to be present at the 1/4t and 3/ 4 t locations of the controlling material (shell forging, or circumferential weld), as defined by the fluence adjusted RTNDT. The reactor vessel nozzle flaws are located at the inside juncture (comer) with the nozzle shell, and the closure head flaw is located near the outside juncture with the head flange. P-T limits for the beltline and nozzle regions are calculated using a safety factor of 2 for normal operation and 1.5 for ISLH operation. The P-T limit curves presented consist of the allowable pressures for the controlling beltline flaw, inlet and outlet nozzles, and closure head, as a function of fluid temperature. These curves have been "smoothed", as necessary, to eliminate irregularities associated with the startup of the first reactor coolant pump during heatup and the initiation of decay heat removal during cooldown. After the initial determination of the P-T limit curves, location specific curves were adjusted for sensor location. No instrument error correction has been applied. The final results include the determination of a minimum/lower bound P-T curve.
Pressure correction factors were determined between the RCS hot leg pressure taps and various other RCS locations.
The criticality limit temperature is obtained by determining the maximum required ISLH test temperature at a pressure of 2500 psig (approximately 10% above the normal operating pressure). The ISLH analysis considers the most limiting heatup and cooldown transients. The approach satisfies the requirement of Item 2.d in Table 1 of 10 CFR 50, Appendix G [1]. It requires the minimum temperature to be the larger of minimum permissible temperature for inservice system hydrostatic pressure test or the RTNDT of the closure flange material + 160 OF.
Various aspects of the calculation procedures utilized in the development of P-T limits are discussed below.
Page 8                                                A AREVA


==2.0 BACKGROUND==
A                                                                                              ANP-3102, Rev. 3 AREVA 5.1      Fracture Toughness The fracture toughness of reactor vessel steels is expressed as a function of crack-tip temperature, T, indexed to the adjusted reference temperature of the material, RTNDT. Pressure-Temperature limits developed in accordance with ASME Code, Section XI, Appendix G, as permitted by RIS 2004-04 [7] , utilize the crack initiation fracture toughness, Kic = 33.2 + 2.806 exp [0.02 ( T -      RTNDT + 100 'F)]
The upper shelf fracture toughness is limited to an upper bound value of 200 ksi'lin for the reactor vessel welds and base metal and 250 ksi x/in for the inlet and outlet nozzles. The crack-tip temperature needed for these fracture toughness equations is obtained from the results of a transient thermal analysis, described below.
5.2     Thermal Analysis and Thermal Stress Intensity Factor Through-wall temperature distributions are determined by solving the one-dimensional transient axisymmetric heat conduction equation, O
PCP"  _ .c2T      1 aT.
P a        Or2    r Or subject to the following boundary conditions:
at the inside surface, where r = Ri,
                                                        - k      = h(Tw - Tb)
Or at the outside surface, where r = Ro, agr-0 where, p        density CP =    specific heat k =      thermal conductivity T =      temperature r=      radial coordinate t=       time h =     convection heat transfer coefficient Page 9 A
AREVA


The ability of the reactor pressure vessel to resist fracture is the primary factor in ensuring the safety of the primary system in light water-cooled reactors.
A                                                                                               ANP-3102, Rev. 3 AREVA Tw=       wall temperature Tb =     bulk coolant temperature R=       inside radius of vessel Ro =     outside radius of vessel The above equation is solved numerically using a finite difference technique to determine the temperature at 17 points through the wall as a function of time for prescribed changes in the bulk fluid temperature, such as multi-rate ramp and step changes for heatup and cooldown transients.
The three areas of the reactor coolant pressure boundary addressed in the present report are the beltline shell region, the reactor coolant nozzles, and the closure head flange region.A method for guarding against brittle fracture in reactor pressure vessels is described in Appendix G to the ASME Boiler and Pressure Vessel Code, Section XI, "Rules for Inservice Inspection of Nuclear Power Plant Components."[2].
This method utilizes fracture mechanics concepts and the reference temperature for nil-ductility transition, RTNDT, which is defined as the greater of the drop weight nil-ductility transition temperature (per ASTM E208 [3]) or the temperature that is 60 'F below that at which the material exhibits 50 ft-lbs and 35 mils lateral expansion.
The RTNDT of a given material is used to index that material to a reference stress intensity factor curve (K 1 ,). The Kl,, curve appears in Appendix G of ASME Code Section XI. When a given material is indexed to the K 1 , curve, allowable stress intensity factors can be obtained for this material as a function of temperature.
Plant operating limits can then be determined using these allowable stress intensity factors.The RTNDT of the reactor vessel materials, and in turn, the pressure/temperature limits of a reactor vessel, must be adjusted to account for the effects of irradiation.
Neutron embrittlement and the resultant changes in mechanical properties of a given pressure vessel steel are monitored by a surveillance program consisting of periodic removal of surveillance capsules from an operating reactor and testing of reactor vessel material specimens obtained from the capsules.
The increase in the Charpy V-notch 30 ft-lb temperature is added to the unirradiated RTNDT to adjust it for neutron embrittlement.
This adjusted RTNDT is used to index the material to the K 1 , curve, which in turn, is used to set new operating limits for the nuclear power plant. These new limits take into account the effects of irradiation on the reactor vessel materials.
Pressure-temperature limits for the TMI-1 reactor vessel are developed in accordance with the requirements of 10 CFR Part 50, Appendix G [1], utilizing the analytical methods and flaw acceptance criteria of topical report BAW-10046A
[4] and ASME Code Section XI, Appendix G[2].As mentioned earlier, the three areas of the reactor coolant pressure boundary addressed in this report are the beltline shell region, the reactor coolant nozzles, and the closure head flange region. The beltline and nozzle regions are analyzed specifically for TMI-1 using the K 1 c reference fracture toughness.
The effect of the change in the reference fracture toughness curve on the P-T limits for the closure head flange region is included by utilizing generic limits that have been derived for B&W-designed 177FA reactor vessels.The TMI-1 reactor vessel contains both axially and circumferentially oriented welds. Therefore, the P-T limits for TMI-1 is based on the postulation of both axial and circumferential flaws in the most limiting axial and circumferential welds and the postulation of an axial flaw in the most limiting forging material of the reactor vessel.Page 1 A ARE VA A AREVA ANP-3102, Rev. 3 One-hundred percent steady state condition Appendix G limits were considered for the development of low temperature overpressure protection (LTOP) P-T limits. To further support the development LTOP system limits, temperature differences between the reactor coolant in the downcomer region and the 1/4/4 t wall location are determined for the maximum heatup rate transient.
The V4 t wall location is defined as a point within the vessel wall that is located at a distance of one quarter of the vessel thickness from the cladding-base metal interface.
3.0 ADJUSTED NIL-DUCTILITY TRANSITION REFERENCE TEMPERATURES The '/4 t and / t ART values for the TMI-I reactor vessel beltline materials applicable to 50.2 EFPY with MUR are listed in Table 1 and Table 2. These values were calculated in accordance with Regulatory Guide 1.99, Revision 2 [10]. The calculation of the ART values for the weld metals also used BAW-2308 Revision IA and 2A [5]. The controlling beltline materials for the Three Mile Island Unit 1 reactor vessel are the lower nozzle belt to upper shell circumferential weld with ART values at 50.2 EFPY with MUR of 216.0 OF at the 1/4T wall location and 161.1 OF at the 3/4T wall location and the axial welds of the lower shell and upper shell, respectively with ART values at 50.2 EFPY with MUR of 183.9 °F at the 1/4 T wall location and 126.8 °F at the /4 T wall location.The ART values used for the development of the Three Mile Island Unit 1 reactor vessel P-T limits curves, calculated in 2006 for license renewal, were 234.5°F at the '/4 T wall location and 178.5°F at the 3/4T wall location for the circumferential welds. The ART values used for the axial welds were 184.7 °F at the 1/4/ T wall location and 126.8 °F at the 3/4 T wall location.
Thus, in all instances the actual ART values or conservative ART values were used in the development of P-T limit curves performed in 2006.Page 2 A AREVA A ARIEVA ANP-3102, Rev. 3 Table 1: Adjusted Reference Temperature Evaluation for the TMI-1 Reactor Vessel Beltline Materials at the 1/4-Thickness Locations Applicable Through 50.2 EFPY with MUR Estimated Fluence Adiusted Reference Temperature Evaluation at 1/4T Location Reactor Vessel MatI. Heat A 50.2 EFPY, n/cm 2  Chema. Fluence R Initial I a, I 0 e I RTNr r, 1/4T_____________________
ent Numer RT.sT, Shift, Beltllne Region Location Ident. Number Type Cu Ni IS 1/4T Factor Factor F J F Margin ART Guide 1.99, Revision 2, Position 1.1 Lower Nozzle Belt Forging (LNB) ARY 59 123S454 SA-508 CI2 0.08 0.72 1.32E+19 7.698E+18 51.0 0.927 3 31 17 47.3 70.7 121.0 Upper ShellPlate (US) C2789-1 C2789-1 SA-302 Gr B Mod. 0.09 0.57 1.47E+19 8.575E+18 58.0 0.957 1 26.9 17 55.5 63.6 120.1 Upper Shell Plate (US) C2789-2 C2789-2 SA-302 Gr B Mod. 0.09 0.57 1.47E+19 8.575E+18 58.0 0.957 1 26.9 17 55.5 63.6 120.1 Lower Shell Plate (LS) C3307-1 C3307-1 SA-302 Gr B Mod. 0.12 0.55 1.47E+19 6.575E+18 82.0 0.957 1 26.9 17 78.5 63.6 143.1 Lower Shell Plate (LS) C3251-1 C3251-1 SA-302 Gr B Mod. 0.11 0.5 1.47E+19 8.575E+18 73.0 0.957 1 26.9 17 69.9 63.6 134.5 LNB to US Circ. Weld (100%) WF-70 72105 Linde 80 Flux 0.32 0.58 1.32E+19 7.698E+18 199.3 0.927 -31.1 13.7 28 184.8 62.3 [216.0]US Longit. Weld (Both 100%) WF-8 8T1762 Linde 80 Flux 0.19 0.57 1.31E+19 7.662E+18 167.0 0.925 -47.6 17.2 28 154.5 65.7 172.6 US to LS Circ. Weld (100%) WF-25 299L44 Linde 80 Flux 0.34 0.68 1.43E+19 8.335E+18 220.6 0.949 -74.3 12.8 28 209.3 61.6 196.6 LS Longit. Weld (100%) SA-1526 299L44 Linde 80 Flux 0.34 0.66 1.16E+19 6.778E÷18 220.6 0.891 -74.3 12.8 28 196.6 61.6 {183.9)LS Longit. Weld (ID 37%) SA-1526 299L44 Linde 80 Flux 0.34 0.68 1.15E+19 6.755E+18 220.6 0.890 -74.3 12.8 28 196.3 61.6 183.6 LS Longit. Weld (OD 63%) SA-1494 8T1554 Linde 80 Flux 0.16 0.57 1.15E+19 N/A 167.0 N/A -47.6 17.2 28 N/A N/A N/A-Highest values of the adjusted reference temperature for circumferential welds.-Highest values of the adjusted reference temperature for base metal or longitudinal welds.Page 3 A ARIEVA A AR EVA ANP-3102, Rev. 3 Table 2: Adjusted Reference Temperature Evaluation for the TMI -1 Reactor Vessel Beltline Materials at the %-Thickness Locations Applicable Through 50.2 EFPY with MUR Estimated Fluence Adusted Reference Temperature Evaluation at 3/4T Location Reactor Vessel Matt Heat C 50.2 EFPY, n/cm 2  Chem. (Fluence Initial J o. RTNoT 3/4T Beltilne Region Location Ident. Number Type CU Ni IS 3/4T Factor Factor F ' F Margin ART Regulatory Guide 1.99, Revision 2, Position 1.1 Lower Nozzle Belt Forging (LNB) ARY 59 123S454 SA-508 C02 0.08 0.72 1.32E-19 2.80E+18 51.0 0.652 3 31 17 33.3 70.4 106.7 Upper Shell Plate (US) C2789-1 C2789-1 SA-302 Gr B Mod. 0.09 0.57 1.47E+19 3.12E+18 58.0 0.680 1 26.9 17 39.4 63.6 104,0 Upper Shell Plate(US)
C2789-2 C2789-2 SA-302 Gr B Mod. 0.09 0.57 1.47E+19 3.12E+18 58.0 0.680 1 26.9 17 39.4 63.6 104.0 Lower Shell Plate(LS)
C3307-1 C3307-1 SA-302 Gr B Mod. 0.12 0.55 1.47E+19 3.12E+18 82.0 0.680 1 26.9 17 55.8 63.6 120.4 Lower Shell Plate (LS) C3251-1 C3251-1 SA-302 Gr 8 Mod. 0.11 0.50 1.47E+19 3.12E+18 73.0 0.680 1 26.9 17 49.6 63.6 114.2 LNB to US Circ. Weld (100%) WF-70 72105 Linde 80 Flux 0.32 0.58 1.32E+19 2.80E+18 199.3 0.652 -31.1 13.7 28 129.9 62.3 [161.1]US Longit. Weld (Both 100%) WF-8 8T1762 Linde 80 Flux 0.19 0.57 1.31E-19 2.78E+18 167.0 0.651 -47.6 17.2 28 108.7 65.7 {126.8J US to LS Circ. Weld (100%) WF-25 299L44 Linde 80 Flux 0.34 0.68 1.43E+19 3.03E+18 220.6 0.673 -74.3 12.8 28 148.5 61.6 135.8 LS Longit. Weld (100%) SA-1526 299L44 Linde 80 Flux 0.34 0.68 1.16E+19 2.46E+18 220.6 0.620 -74.3 12.8 28 136.8 61.6 124.1 LS Longit. Weld (ID 37%) SA-1526 299144 Linde 80 Flux 0.34 0.68 1.15E+19 N/A 220.6 N/A -74.3 12.8 28 N/A N/A N/A LS Longit. Weld (OD 63%) SA-1494 8T1554 Linde 80 Flux 0.16 0.57 1.15E+19 2.45E+18 167.0 0.619 -47.6 17.2 28 103.4 65.7 121.5 3 -Highest values of the adjusted reference temperature for circumferential welds.-Highest values of the adjusted reference temperature for base metal or longitudinal welds.Page 4 A AREVA A AREVA ANP-3102, Rev. 3 4.0 DESIGN BASIS FOR PRESSURE/TEMPERATURE LIMITS Essential geometric data and analytical parameters used in the preparation of TMI-1 P-T limits are described below.4.1 Material Properties Table 3 describes the material properties used in the development of the P-T limits for the TMI-1.Table 3: Material Properties Temp. Elastic Thermal Thermal Specific Density Poisson's Modulus Expansion Conductivity Heat Ratio Ref. [6] Ref61 Ref.[6] Ref.[6] (assumed)(°F) (106 psi) (10- in/in/°F)
Btu/hr-ft-°F) (Btu/lb-°F) (lb/ft 3)70 29.20 7.02 23.3 0.104 490.9 0.3 100 29.04 7.06 23.6 0.107 490.5 0.3 150 28.77 7.16 24.1 0.111 489.9 0.3 200 28.50 7.25 24.4 0.114 489.2 0.3 250 28.25 7.34 24.6 0.117 488.6 0.3 300 28.00 7.43 24.7 0.121 487.9 0.3 350 27.70 7.50 24.7 0.124 487.3 0.3 400 27.40 7.58 24.6 0.127 486.7 0.3 450 27.20 7.63 24.4 0.129 486.0 0.3 500 27.00 7.70 24.2 0.132 485.4 0.3 550 26.70 7.77 23.9 0.135 484.7 0.3 600 26.40 7.83 23.5 0.138 484.1 0.3 650 25.85 7.90 23.2 0.141 483.4 0.3 700 25.30 7.94 22.8 0.144 482.8 0.3 4.2 Postulated Flaws a. Postulated Reactor Vessel Beltline Flaws Semi-elliptical surface flaws that are '/4 t deep and 1 1/2 t long are postulated on the inside and outside surfaces of the reactor vessel beltline region. A longitudinal flaw is postulated in the base metal and the axial seam welds and a circumferential flaw is postulated in the circumferential welds.b. Postulated Nozzle Comer Flaw A 3" (1/4 tNB) deep comer flaw is postulated on the inside surface of the reactor vessel inlet and outlet nozzles.4.3 Upper Shelf Toughness A maximum value of 200 ksi'An is used for the upper shelf fracture toughness of the reactor vessel beltline.
For the nozzle forging materials, a "no cut-off' limit is used.Page 5 A AREVA A AREVA ANP-3102, Rev. 3 4.4 Uncorrected Reactor Vessel Closure Head Limits Pressure-temperature limits for the reactor vessel head-to-flange closure region for normal operation and ISLH operation were derived for TMI- I reactor vessel closure head region based on the K c fracture toughness curve.4.5 Convection Film Coefficient A value of 1000 BTU/hr-ft 2-°F is used for an effective convective heat transfer film coefficient at the cladding-to-base metal interface for all times during heatup and cooldown when reactor coolant pumps (RCPs) are in use.When no reactor coolant pumps are running (i.e., before the first RCP is started during heatup and after the last RCP is shut off during cooldown), a value of 430 BTU/hr-ft 2-°F is used as an effective film coefficient at the cladding-to-base metal interface.
This value was developed for flow conditions when no RCPs are running and 40°F water enters the vessel through the core flood nozzle as the decay heat removal system switches to an idle low pressure injection cooler. The outside surface is always modeled as a perfectly insulated boundary.4.6 Reactor Coolant Temperature-Time Histories Both ramped and stepped transient definitions are modeled for normal operation heatup and cooldown.
The limiting normal heatup and cooldown transients (as determined by the controlling P-T limits) are also used to simulate the reactor coolant transients used for inservice leak and hydrostatic (ISLH) pressure testing.The following input temperature-time histories are considered:
Normal Ramp Heatup, 50 *F/hr.Normal Step Heatup, 15 OF/ 18 min. steps.Normal Ramp Cooldown, 100 °F/hr to 255 'F then 30 0 F/hr to 70 'F.Normal Step Cooldown, 15'F/ 9 min. steps to 255 'F then 15 'F/ 30 min. steps to 70 'F.4.7 Adjusted Reference Temperatures As discussed in Section 3.0, limiting values of the adjusted reference temperature were evaluated.
The limiting ART or RTNDT values that were used for determining the P-T curves are also listed in Table 4 for the l/4 t and 3/4 t locations of the reactor vessel beltline wall at 50.2 EFPY with MUR. An RTNDT of 60 OF is used for the reactor vessel nozzles.Page 6 A ARE VA A AREVA ANP-3102, Rev. 3 Table 4: Limiting RTNDT'S for TMI-1 Beltline Materials Vessel Wall Limiting RTNDT (OF)Component Location Material at 50.2 EFPY Beltline 1/4 t SA-1526 184.7 Axial Weld WF-8 126.8 Beltline 1/4t WF-70 234.5 Circ. Weld _7/_4t _ WF-70 178.5 Page 7 A AREVA A AREVA ANP-3102, Rev. 3 5.0 TECHNICAL BASIS FOR PRESSURE/TEMPERATURE LIMITS Pressure-temperature limits are developed using an analytical approach that is in accordance with the requirements of the ASME Boiler and Pressure Vessel Code, Section XI, Appendix G [2]. Additional requirements are contained in Table 1 of Appendix G to Title 10, Code of Federal Regulations, Part 50 [1]. The analytical techniques used to calculate P-T limits are based on approved linear elastic fracture mechanics methodology described in topical report BAW-10046A
[4]. The fundamental equation used to calculate the allowable pressure is Pallow KIR -Krr SFx ki where, Pallow = allowable pressure K I = reference stress intensity factor ( K a or K 1c Srr = thermal stress intensity factor I, = unit pressure stress intensity factor (due to 1 psig)SF = safety factor For each analyzed transient and steady state condition, the allowable pressure is determined as a function of reactor coolant temperature considering postulated flaws in the reactor vessel beltline, inlet nozzle, outlet nozzle, and closure head. In the beltline region, flaws are postulated to be present at the 1/4 t and 3/4 t locations of the controlling material (shell forging, or circumferential weld), as defined by the fluence adjusted RTNDT. The reactor vessel nozzle flaws are located at the inside juncture (comer) with the nozzle shell, and the closure head flaw is located near the outside juncture with the head flange. P-T limits for the beltline and nozzle regions are calculated using a safety factor of 2 for normal operation and 1.5 for ISLH operation.
The P-T limit curves presented consist of the allowable pressures for the controlling beltline flaw, inlet and outlet nozzles, and closure head, as a function of fluid temperature.
These curves have been "smoothed", as necessary, to eliminate irregularities associated with the startup of the first reactor coolant pump during heatup and the initiation of decay heat removal during cooldown.
After the initial determination of the P-T limit curves, location specific curves were adjusted for sensor location.
No instrument error correction has been applied. The final results include the determination of a minimum/lower bound P-T curve.The criticality limit temperature is obtained by determining the maximum required ISLH test temperature at a pressure of 2500 psig (approximately 10% above the normal operating pressure).
The ISLH analysis considers the most limiting heatup and cooldown transients.
The approach satisfies the requirement of Item 2.d in Table 1 of 10 CFR 50, Appendix G [1]. It requires the minimum temperature to be the larger of minimum permissible temperature for inservice system hydrostatic pressure test or the RTNDT of the closure flange material + 160 OF.Various aspects of the calculation procedures utilized in the development of P-T limits are discussed below.Page 8 A AREVA A AREVA ANP-3102, Rev. 3 5.1 Fracture Toughness The fracture toughness of reactor vessel steels is expressed as a function of crack-tip temperature, T, indexed to the adjusted reference temperature of the material, RTNDT. Pressure-Temperature limits developed in accordance with ASME Code, Section XI, Appendix G, as permitted by RIS 2004-04 [7] , utilize the crack initiation fracture toughness, Kic = 33.2 + 2.806 exp [0.02 ( T -RTNDT + 100 'F)]The upper shelf fracture toughness is limited to an upper bound value of 200 ksi'lin for the reactor vessel welds and base metal and 250 ksi x/in for the inlet and outlet nozzles. The crack-tip temperature needed for these fracture toughness equations is obtained from the results of a transient thermal analysis, described below.5.2 Thermal Analysis and Thermal Stress Intensity Factor Through-wall temperature distributions are determined by solving the one-dimensional transient axisymmetric heat conduction equation, PCP" O _ .c2T 1 aT.P a Or 2 r Or subject to the following boundary conditions:
at the inside surface, where r = Ri,-k = h(Tw -Tb)Or at the outside surface, where r = Ro,-0 agr where, p density CP = specific heat k = thermal conductivity T = temperature r = radial coordinate t= time h = convection heat transfer coefficient Page 9 A AREVA A AREVA ANP-3102, Rev. 3 Tw= wall temperature Tb = bulk coolant temperature R= inside radius of vessel Ro = outside radius of vessel The above equation is solved numerically using a finite difference technique to determine the temperature at 17 points through the wall as a function of time for prescribed changes in the bulk fluid temperature, such as multi-rate ramp and step changes for heatup and cooldown transients.
An equivalent linear thermal bending stresses (based on AT through the wall) is derived from the through-wall temperature distribution at each solution time point. Through-wall thermal stress distributions are determined by trapezoidal integration of the following expression:
An equivalent linear thermal bending stresses (based on AT through the wall) is derived from the through-wall temperature distribution at each solution time point. Through-wall thermal stress distributions are determined by trapezoidal integration of the following expression:
Thermal hoop stresses: o()=Ea I r 2 + Ri2f'Tr&dr+fr TrdrTr2~1- ý R' ,R[8, Eqn (255)]Expressing the thermal stress distributions by cr(x) = Co + C, (x/a) + C 2 (x/a)2 + C 3 (x/a)3 , where, x = is a dummy variable that represents the radial distance from the appropriate (i.e., inside or outside)surface, in.a = the flaw depth, in.The thermal stress intensity factors are defined by the following relationships:
Thermal hoop stresses:
For a 1/4 t inside surface flaw during cooldown, Kit = (1.0359 Co + 0.6322 C, + 0.4753 C 2 + 0.3855 C 3),r-a4 For a 1/4 t outside surface flaw during heatup, Kt= (1.043 Co + 0.630 CI + 0.481 C 2 + 0.401 C 3)O a 5.3 Unit Pressure Stress Intensity Factor for Reactor Vessel Beltline Region The membrane stress intensity factor in the reactor vessel shell due to a unit pressure load is Kjm = Mm x Ri/t where Ri = vessel inner radius, in.Page 10 A AREVA AREVA ANP-3102, Rev. 3 t= vessel wall thickness, in.For a longitudinal  
o()=Ea     I   r2 + Ri2f'Tr&dr+fr TrdrTr2~               [8, Eqn (255)]
'/4 -thickness x 3 -thickness semi-elliptical surface flaw: at the inside surface, Mm. 1.85 for 4t < 2 0.926 4t for 2 _< 4t _< 3.464 3.21 for 4t > 3.464 at the outside surface, Mm = 1.77 for 4t < 2= 0.893 4/t for 2 _< 4It _< 3.464= 3.09 for 4t > 3.464 5.4 Unit Pressure Stress Intensity Factor for Reactor Vessel Nozzles Considering a nozzle as a hole in a shell, WRC Bulletin 175 [9] presents the following method for estimating stress intensity factors for a nozzle comer flaw: Klm = o'r/-'i F(a/rn)where (= Ri/t R= nozzle belt shell inner radius, in.t = nozzle belt shell wall thickness, in.a = flaw depth, in.r,= apparent radius of nozzle, in.= ri + 0.29rc r= inner radius of nozzle, in.rc= nozzle comer radius, in.and F(a/r,) = 2.5 -6.108(a/rn)  
1-           &#xfd; R'       ,R Expressing the thermal stress distributions by cr(x) = Co + C, (x/a) + C2 (x/a) 2 + C3 (x/a) 3 ,
+ 12(a/r,)2 -9.1664(a/r,)
where, x=       is a dummy variable that represents the radial distance from the appropriate (i.e., inside or outside) surface, in.
3 Page 11 A AR EVA A AREVA ANP-3102, Rev. 3 6.0 PRESSURE CORRECTIONS The uncorrected P-T limits are calculated at the required locations or components in the RCS. However, the plant uses only two instruments locations for indicated pressure, the pressurizer low range tap and the hot leg wide range tap. Therefore, the uncorrected P-T limits may be corrected to one or both of these locations.
a=       the flaw depth, in.
These location corrections were calculated using a TMI-1 Cycle 19 RCS hydraulics model with 0% steam generator tube plugging, and analyzing it for various temperatures and pump combinations.
The thermal stress intensity factors are defined by the following relationships:
The location corrections are based on 0/0 pumps operating up to 100 OF (the conservative start temperature for the first two pumps) and then based on 2/0 pumps up to -200 OF, and 2/1 pumps up to -350 OF. The low range corrections (taken from the pressurizer) are conservatively estimated to be a constant 10 psi less than the wide range corrections (taken from the hot leg tap). Thus the limiting location corrections are from hot leg (wide range)tap and are applied to the P-T limits. The hot leg (wide range) tap pressure corrections are presented below in Table 5.Table 5: Limiting Location Corrections Factors for Pressure Temperature 70-100 101-199 200-349 350-499 500-5321 Range, &deg;F Component AP, psi RCP AP, psi RCP AP, psi RCP AP, psi RCP AP, psi RCP Beltline 22 (WR) 0/0 90 (WR) 2/0 104 (WR) 2/1 111 2/2 99 2/2 Outlet Nozzle 17 (WR) 0/0 74 (WR) 2/0 74 (WR) 2/0 67 2/0 51 2/1 RVCH 13 (WR) 0/0 70 (WR) N/A N/A N/A The correction factor was used for 601F as well, since the rounded correction factors are found to be bounding The correction factor is used for temperatures above 532&deg;F since the values are bounding for higher temperature 7.0  
For a 1/4 t inside surface flaw during cooldown, Kit =   (1.0359 Co + 0.6322 C, + 0.4753 C2 + 0.3855 C 3),r-a4 For a 1/4 t outside surface flaw during heatup, Kt=     (1.043 Co + 0.630 CI + 0.481 C2 + 0.401 C3)O a 5.3     Unit Pressure Stress Intensity Factor for Reactor Vessel Beltline Region The membrane stress intensity factor in the reactor vessel shell due to a unit pressure load is Kjm =   Mm x Ri/t where Ri =     vessel inner radius, in.
Page 10 A
AREVA
 
AREVA ANP-3102, Rev. 3 t=       vessel wall thickness, in.
For a longitudinal '/4 -thickness x 3 -thickness semi-elliptical surface flaw:
at the inside surface, Mm.       1.85             for 4t < 2 0.926 4t         for 2 _<4t _< 3.464 3.21             for 4t > 3.464 at the outside surface, Mm =     1.77             for 4t < 2
                      =   0.893 4/t       for 2 _<4It _<3.464
                        =   3.09             for 4t > 3.464 5.4     Unit Pressure Stress Intensity Factor for Reactor Vessel Nozzles Considering a nozzle as a hole in a shell, WRC Bulletin 175 [9] presents the following method for estimating stress intensity factors for a nozzle comer flaw:
Klm   = o'r/-'i F(a/rn) where
(=       Ri/t R=       nozzle belt shell inner radius, in.
t =       nozzle belt shell wall thickness, in.
a =     flaw depth, in.
r,=     apparent radius of nozzle, in.
                      =     ri + 0.29rc r=       inner radius of nozzle, in.
rc=     nozzle comer radius, in.
and F(a/r,) = 2.5 - 6.108(a/rn) + 12(a/r,) 2 - 9.1664(a/r,)3 Page 11 A
AR EVA
 
A                                                                                                                             ANP-3102, Rev. 3 AREVA 6.0         PRESSURE CORRECTIONS The uncorrected P-T limits are calculated at the required locations or components in the RCS. However, the plant uses only two instruments locations for indicated pressure, the pressurizer low range tap and the hot leg wide range tap. Therefore, the uncorrected P-T limits may be corrected to one or both of these locations. These location corrections were calculated using a TMI-1 Cycle 19 RCS hydraulics model with 0% steam generator tube plugging, and analyzing it for various temperatures and pump combinations.
The location corrections are based on 0/0 pumps operating up to 100 OF (the conservative start temperature for the first two pumps) and then based on 2/0 pumps up to - 200 OF, and 2/1 pumps up to - 350 OF. The low range corrections (taken from the pressurizer) are conservatively estimated to be a constant 10 psi less than the wide range corrections (taken from the hot leg tap). Thus the limiting location corrections are from hot leg (wide range) tap and are applied to the P-T limits. The hot leg (wide range) tap pressure corrections are presented below in Table 5.
Table 5: Limiting Location Corrections Factors for Pressure Temperature                     70-100                       101-199                       200-349               350-499         500-5321 Range, &deg;F Component                 AP, psi         RCP           AP, psi         RCP           AP, psi         RCP   AP, psi   RCP   AP, psi   RCP Beltline               22 (WR)           0/0         90 (WR)           2/0       104 (WR)           2/1   111       2/2     99     2/2 Outlet Nozzle               17 (WR)           0/0         74 (WR)           2/0         74 (WR)           2/0     67       2/0     51     2/1 RVCH                   13 (WR)           0/0         70 (WR)                           N/A                   N/A             N/A The correction factor was used for 601F as well, since the rounded correction factors are found to be bounding The correction factor is used for temperatures above 532&deg;F since the values are bounding for higher temperature 7.0        


==SUMMARY==
==SUMMARY==
OF RESULTS The following is a summary of results for the TMI-l P-T limits at 50.2 EFPY with MUR analysis corrected for location only. No correction due to instrument uncertainty is applied.Page 12 A AREVA AREVA ANP-3102, Rev. 3 7.1 P-T Curves for ISLH Heatup / Cooldown The Pressure-Temperature limits are developed for ISLH test operations.
OF RESULTS The following is a summary of results for the TMI-l P-T limits at 50.2 EFPY with MUR analysis corrected for location only. No correction due to instrument uncertainty is applied.
For ISLH heatup, adjusted location specific (i.e. on a per component basis) P-T limits are presented in Table 6. The Tech. Spec. basis P-T limits for ISLH heatup are shown in Table 8. The location adjusted P-T limits for ISLH ramp cooldown are presented in Table 9. The location adjusted P-T limits calculated for ISLH step cooldown are shown in Table 10. The Technical specification (Tech. Spec.) basis P-T limits for ISLH cooldown generated as the limiting allowable pressure at every calculated temperature is shown in Table 11. The adjusted P-T limits for ISLH heatup and cooldown are plotted in Figure 1. A limiting composite curve for Tech. Spec. Basis P-T limits for ISLH is developed, the pressure-temperature data is shown in Table 12 and the curve is plotted in Figure 2. The criticality I limit temperature corresponding to a pressure of 2500 psig can be determined through interpolation of ISLH heatup data in Table 6. As shown in Table 7, the criticality limit temperature is 262.7 'F. The criticality limit curve is shown in Figure 3 along with the normal heatup Tech. Spec. basis P-T limit curve.Page 13 A AREVA A AREVA ANP-3102, Rev. 3 Table 6: TMI-1 Adjusted Location Specific P-T Limits for ISLH Heatup Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi)60 65 70 75 80 85 90 95 100 105 110 115 120 125 130 135 140 145 150 155 160 165 170 175 180 185 190 195 200 205 210 215 220 225 230 235 240 245 250 255 260 832 833 835 838 841 841 850 857 863 802 810 819 828 839 851 864 879 895 913 932 954 978 1005 1035 1067 1103 1143 1187 1222 1275 1335 1400 1473 1553 1642 1740 1848 1967 2099 2244 2405 873 878 892 912 934 948 991 1029 1071 1059 1108 1162 1222 1289 1363 1444 1534 1634 1744 1866 2001 2149 2314 2495 2696 2918 3163 3433 3732 4050 4050 4050 4050 4050 4050 4050 4050 4050 4050 4050 4050 907 912 927 947 971 985 1030 1069 1113 1102 1153 1210 1272 1341 1418 1503 1596 1700 1814 1941 2080 2235 2405 2594 2802 3033 3287 3568 3878 4208 4208 4208 4208 4208 4208 4208 4208 4208 4208 4208 4208 671 811 953 1095 1237 1435 1633 1831 2029 2170 Page 14 A AREVA A AREVA ANP-3102, Rev. 3 Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi (psi)265 270 275 280 285 290 295 300 305 310 315 320 325 330 335 340 345 350 355 360 365 370 375 380 385 390 395 400 405 410 415 420 425 430 435 440 445 450 455 460 465 470 475 480 485 2582 2777 2993 3231 3494 3785 4106 4460 4788 4788 4788 4787 4787 4787 4786 4786 4786 4778 4778 4777 4777 4776 4776 4775 4775 4774 4774 4773 4773 4772 4772 4771 4771 4771 4770 4770 4770 4770 4769 4769 4768 4768 4766 4766 4766 4050 4050 4050 4050 4050 4050 4050 4050 4050 4050 4050 4050 4050 4050 4050.4050 4050 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4057 4208 4208 4208 4208 4208 4208 4208 4208 4208 4208 4208 4208 4208 4208 4208 4208 4208 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 4215 Page 15 A ARE VA A AREVA ANP-3102, Rev. 3 Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (4F) (psi) (psi) (psi) (psi)490 4765 4057 4215 495 4765 4057 4215 500 4776 4073 4231 505 4776 4073 4231 510 4775 4073 4231 515 4775 4073 4231 520 4774 4073 4231 525 4773 4073 4231 530 4773 4073 4231 535 4772 4073 4231 540 4772 4073 4231 545 4772 4073 4231 550 4771 4073 4231 555 4771 4073 4231 560 4770 4073 4231 565 4769 4073 4231 570 4769 4073 4231 Table 7: TMI-1 Criticality Limit Temperature Determination Criticality Limit Temp. at 500 psig Pressure Temp.(psig) (OF)2405 260 2582 265 Interpolating:
Page 12 A
2500 262.7 Page 16 A AREVA A AREVA ANP-3102, Rev. 3 Table 8: TMI-1 Tech. Spec. Basis P-T Limits for ISLH Heatup Fluid Temp.(OF)60 65 70 75 80 85 90 95 100 105 110 115 120 125 130 135 140 145 150 155 160 165 170 175 180 185 190 195 200 205 210 215 220 225 230 235 240 245 250 255 260 Governing Adjusted Pressure (psi)671 802 802 802 802 802 802 802 802 802 810 819 828 839 851 864 879 895 913 932 954 978 1005 1035 1067 1103 1143 1187 1222 1275 1335 1400 1473 1553 1642 1740 1848 1967 2099 2244 2405 Page 17 A AREVA A AREVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi)265 2582 270 2777 275 2993 280 3231 285 3494 290 3785 295 4050 300 4050 305 4050 310 4050 315 4050 320 4050 325 4050 330 4050 335 4050 340 4050 345 4050 350 4057 355 4057 360 4057 365 4057 370 4057 375 4057 380 4057 385 4057 390 4057 395 4057 400 4057 405 4057 410 4057 415 4057 420 4057 425 4057 430 4057 435 4057 440 4057 445 4057 450 4057 455 4057 460 4057 465 4057 470 4057 475 4057 480 4057 485 4057 Page 18 A AR EVA A AREVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi)490 4057 495 4057 500 4073 505 4073 510 4073 515 4073 520 4073 525 4073 530 4073 535 4073 540 4073 545 4073 550 4073 555 4073 560 4073 565 4073 570 4073 Page 19 A AREVA A AREVA ANP-3102, Rev. 3 Table 9: TMI-1 Adjusted Location Specific P-T Limits for ISLH Ramp Cooldown Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi)70 75 80 85 90 95 105 110 115 120 125 130 135 140 145 150 155 160 165 170 175 180 185 190 195 200 205 210 215 220 225 230 235 240 245 250 255 260 265 270 275 733 742 753 765 780 786 724 727 743 759 776 795 816 840 866 894 926 961 999 1042 1089 1141 1199 1263 1334 1397 1469 1549 1638 1735 1844 1963 2066 2193 2402 2580 2777 2995 3235 3501 3795 937 992 1041 1094 1154 1219 1295 1361 1501 1609 1728 1860 2006 2167 2346 2542 2760 3001 3266 3560 3772 3761 3748 3733 3716 3696 3674 3646 3616 3581 3540 3492 3395 3462 3405 3342 3293 3295 3296 3298 3300 974 1031 1081 1137 1199 1267 1347 1416 1562 1674 1798 1935 2086 2254 2439 2643 2869 3119 3395 3700 3919 3908 3895 3879 3862 3841 3818 3789 3757 3721 3679 3629 3528 3598 3538 3473 3423 3424 3426 3428 3430 953 1095 1237 1435 1633 1831 2170 Page 20 A AR EVA A AREVA ANP-3102, Rev. 3 Allowable Pressures Limiting Outlet Inlet Closure Fluid Beitline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi)280 285 290 295 300 305 310 315 320 325 330 335 340 345 350 355 360 365 370 375 380 385 390 395 400 405 410 415 420 425 430 435 440 445 450 455 460 465 470 475 480 485 490 495 500 4119 4308 4308 4307 4306 4306 4305 4305 4305 4304 4304 4304 4304 4304 4297 4298 4298 4298 4298 4299 4299 4300 4301 4302 4304 4304 4306 4308 4311 4314 4318 4322 4326 4331 4337 4343 4349 4356 4364 4373 4383 4393 4405 4418 4444 3302 3304 3307 3309 3312 3315 3318 3323 3326 3330 3334 3338 3342 3347 3358 3363 3369 3375 3378 3385 3392 3399 3407 3415 3424 3433 3442 3452 3463 3474 3485 3496 3509 3522 3536 3550 3565 3581 3597 3614 3632 3651 3670 3690 3727 3432 3434 3436 3439 3442 3445 3448 3454 3457 3461 3465 3469 3473 3478 3490 3495 3501 3507 3511 3518 3525 3533 3541 3549 3558 3568 3577 3588 3598 3610 3622 3633 3646 3660 3674 3689 3705 3721 3738 3756 3774 3793 3814 3834 3872 Page 21 A ARE VA A AREVA ANP-3102, Rev. 3 Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi)505 4459 3749 3895 510 4476 3769 3916 515 4494 3793 3941 520 4513 3818 3966 525 4533 3843 3993 530 4556 3870 4020 535 4582 3897 4049 540 4609 3925 4077 545 4638 3953 4107 550 4670 3982 4137 555 4703 4010 4166 560 4738 4037 4194 565 4772 4060 4218 570 4793 4072 4231 Page 22 A AR EVA A AREVA ANP-3102, Rev. 3 Table 10: TMI-1 Adjusted Location Specific P-T Limits for ISLH Step Cooldown Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (F) (psi) (psi) (psi) (psi)70 80 85 100 105 115 130 145 160 175 190 205 220 235 240 255 270 285 300 315 330 345 360 375 390 405 420 435 450 465 480 495 510 525 540 555 766 781 788 813 757 780 828 893 980 1098 1258 1464 1735 2050 2241 2777 3501 4347 4345 4343 4343 4342 4336 4336 4337 4341 4345 4353 4366 4382 4405 4436 4487 4539 4605 4690 910 1038 1094 1292 1324 1501 1860 2346 3001 3811 3772 3712 3619 3435 3501 3314 3318 3323 3330 3338 3351 3362 3383 3398 3418 3442 3470 3502 3538 3580 3628 3682 3759 3827 3905 3989 945 1078 1137 1342 1377 1562 1935 2439 3119 3960 3920 3858 3761 3570 3638 3444 3448 3454 3461 3470 3482 3495 3516 3531 3552 3577 3606 3639 3676 3720 3770 3826 3906 3976 4057 4144 953 1237 1435 2029 2170 Page 23 A AREVA A AREVA ANP-3102, Rev. 3 Table 11: TMI-1 Tech Spec. Basis P-T Limits for ISLH Cooldown Governing Fluid Adjusted Temp. Pressure (OF) (psi)70 724 75 724 80 724 85 724 90 724 95 724 105 724 110 727 115 743 120 759 125 776 130 795 135 816 140 840 145 866 150 894 155 926 160 961 165 999 170 1042 175 1089 180 1141 185 1199 190 1258 195 1334 200 1397 205 1464 210 1549 215 1638 220 1735 225 1844 230 1963 235 2050 240 2193 245 2402 250 2580 255 2777 260 2995 265 3235 270 3298 275 3300 280 3302 285 3304 Page 24 A AREVA AR ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi)290 3307 295 3309 300 3312 305 3315 310 3318 315 3323 320 3326 325 3330 330 3334 335 3338 340 3342 345 3347 350 3358 355 3363 360 3369 365 3375 370 3378 375 3385 380 3392 385 3399 390 3407 395 3415 400 3424 405 3433 410 3442 415 3452 420 3463 425 3474 430 3485 435 3496 440 3509 445 3522 450 3536 455 3550 460 3565 465 3580 470 3597 475 3614 480 3628 485 3651 490 3670 495 3682 500 3727 505 3749 510 3759 Page 25 A A R EVA A AREVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi)515 3793 520 3818 525 3827 530 3870 535 3897 540 3905 545 3953 550 3982 555 3989 560 4037 565 4060 570 4072 Page 26 A AR EVA A AREVA ANP-3102, Rev. 3 Table 12: TMI-1 Tech Spec. Basis P-T Limits for ISLH Composite Curve Fluid Temp.('F)60 65 70 75 80 85 90 95 100 105 110 115 120 125 130 135 140 145 150 155 160 165 170 175 180 185 190 195 200 205 210 215 220 225 230 235 240 245 250 255 260 265 Goveming Adjusted Pressure (psi)671 724 724 724 724 724 724 724 724 724 727 743 759 776 795 816 840 866 894 926 954 978 1005 1035 1067 1103 1143 1187 1222 1275 1335 1400 1473 1553 1642 1740 1848 1967 2099 2244 2405 2582 Page 27 A AREVA A AREVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi)270 2777 275 2993 280 3231 285 3304 290 3307 295 3309 300 3312 305 3315 310 3318 315 3323 320 3326 325 3330 330 3334 335 3338 340 3342 345 3347 350 3358 355 3363 360 3369 365 3375 370 3378 375 3385 380 3392 385 3399 390 3407 395 3415 400 3424 405 3433 410 3442 415 3452 420 3463 425 3474 430 3485 435 3496 440 3509 445 3522 450 3536 455 3550 460 3565 465 3580 470 3597 475 3614 480 3628 485 3651 490 3670 495 3682 Page 28 A A R EVA A AREVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi)500 3727 505 3749 510 3759 515 3793 520 3818 525 3827 530 3870 535 3897 540 3905 545 3953 550 3982 555 3989 560 4037 565 4060 570 4072 Page 29 A AR EVA A AREVA ANP-3102, Rev. 3 Figure 1: TMI-1 Adjusted P-T Limits for ISLH Heatup and Cooldown 2400 2200 2000.2- 1800 U'G1600 (A1400 U) 1200 I--1000 S800-0 6 100 4 000 4OO 200 0 0 50 100 150 200 250 300 350 Indicated RCS Inlet Temperature, OF 400 450 500 Page 30 A AREVA A AREVA ANP-3102, Rev. 3 Figure 2: TMI-1 Tech. Spec. Basis P-T Limits for ISLH (Composite Curve)2400 2200 2000.-1800 G 0.01600 01400 ID.a.U) 1200 1000 j 800 600 400 200 0 0 50 100 150 200 250 300 350 Indicated RCS InletTemperature, IF 400 450 500 Page 31 A AREVA A AREVA ANP-3102, Rev. 3 7.2 P-T Curves for Normal Heatup / Cooldown The Pressure-Temperature limits are developed for both normal heatup and cooldown operations.
AREVA
For heatup, location specific adjusted P-T limits are presented in Table 13. The Tech. Spec. basis P-T limits for normal heatup are shown in Table 14. The location specific adjusted P-T limits for ramp cooldown are presented in Table 15. The location adjusted P-T limits calculated for normal step cooldown are shown Table 16. The Technical specification (Tech. Spec.) basis P-T limits for cooldown generated as the limiting pressure at every calculated temperature is shown in Table 17. The Tech. Spec. basis P-T limits for heatup are plotted in Figure 3 and the Tech. Spec. basis cooldown P-T limits are plotted in Figure 4.Page 32 A AR EVA A AREVA ANP-3102, Rev. 3 Table 13: TMI-1 Adjusted Location Specific P-T Limits for Normal Heatup Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi)60 65 70 75 80 85 90 90 90 95 100 101 105 110 115 120 123 125 130 135 140 145 150 155 160 165 170 175 180 185 190 195 200 205 210 215 220 225 230 235 240 618 619 621 623 626 629 632 632 632 637 642 575 579 585 592 599 604 607 616 626 637 649 662 677 693 711 731 753 778 805 835 868 890 931 975 1024 1079 1139 1205 1279 1360 650 654 665 679 696 716 738 738 739 768 799 749 776 813 853 898 928 948 1004 1065 1132 1207 1290 1381 1482 1593 1717 1853 2003 2170 2353 2556 2780 3019 3019 3019 3019 3019 3019 3019 3019 676 680 691 706 724 744 767 767 768 798 830 780 808 847 889 936 967 988 1045 1108 1179 1256 1342 1437 1542 1658 1786 1927 2083 2256 2447 2657 2890 3138 3138 3138 3138 3138 3138 3138 3138 612 612 612 612 612 761 910 910 910 1058 1207 1180 1360 1585 1810 2035 2170 Page 33 A AREVA A AREVA ANP-3102, Rev. 3 Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi)245 250 255 260 265 270 275 280 285 290.295 300 305 310 315 320 325 330 335 340 345 350 355 360 365 370 375 380 385 390 395 400 405 410 415 420 425 430 435 440 445 450 455 460 465 1449 1548 1657 1777 1910 2057 2219 2398 2595 2813 3053 3319 3565 3565 3565 3564 3564 3564 3564 3563 3563 3556 3556 3555 3555 3555 3554 3554 3553 3553 3553 3552 3552 3551 3551 3551 3551 3550 3550 3550 3550 3549 3549 3549 3548 3019 3019 3019 3019 3019 3019 3019 3019 3019 3019 3019 3019 3019 3019 3019 3019 3019 3019 3019 3019 3019 3026 3026 3026 3026 3026 3026 3026 3026 3026 3026 3026 3026 3026 3026 3026 3026 3026 3026 3026 3026 3026 3026 3026 3026 3138 3138 3138 3138 3138 3138 3138 3138 3138 3138 3138 3138 3138 3138 3138 3138 3138 3138 3138 3138 3138 3145 3145 3145 3145 3145 3145 3145 3145 3145 3145 3145 3145 3145 3145 3145 3145 3145 3145 3145 3145 3145 3145 3145 3145 Page 34 A AREVA A AREVA ANP-3102, Rev. 3 Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi)470 3548 3026 3145 475 3547 3026 3145 480 3547 3026 3145 485 3546 3026 3145 490 3546 3026 3145 495 3546 3026 3145 500 3558 3042 3161 505 3557 3042 3161 510 3557 3042 3161 515 3556 3042 3161 520 3556 3042 3161 525 3555 3042 3161 530 3555 3042 3161 535 3555 3042 3161 540 3554 3042 3161 545 3554 3042 3161 550 3554 3042 3161 555 3553 3042 3161 560 3553 3042 3161 565 3552 3042 3161 570 3552 3042 3161 Page 35 A AREVA AREVA ANP-3102, Rev. 3 Table 14: TMI-1 Tech. Spec. Basis P-T Limits for Normal Heatup Governing Fluid Adjusted Temp. Pressure (OF) (psi)60 575 65 575 70 575 75 575 80 575 85 575 90 575 90 575 90 575 95 575 100 575 101 575 105 579 110 585 115 592 120 599 123 604 125 607 130 616 135 626 140 637 145 649 150 662 155 677 160 693 165 711 170 731 175 753 180 778 185 805 190 835 195 868 200 890 205 931 210 975 215 1024 220 1079 225 1139 230 1205 235 1279 240 1360 245 1449 250 1548 Page 36 A AR EVA A AREVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi)255 1657 260 1777 265 1910 270 2057 275 2219 280 2398 285 2595 290 2813 295 3019 300 3019 305 3019 310 3019 315 3019 320 3019 325 3019 330 3019 335 3019 340 3019 345 3019 350 3026 355 3026 360 3026 365 3026 370 3026 375 3026 380 3026 385 3026 390 3026 395 3026 400 3026 405 3026 410 3026 415 3026 420 3026 425 3026 430 3026 435 3026 440 3026 445 3026 450 3026 455 3026 460 3026 465 3026 470 3026 475 3026 Page 37 A AR EVA A AREVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi)480 3026 485 3026 490 3026 495 3026 500 3042 505 3042 510 3042 515 3042 520 3042 525 3042 530 3042 535 3042 540 3042 545 3042 550 3042 555 3042 560 3042 Page 38 A A R EVA A AREVA ANP-3102, Rev. 3 Table 15: TMI-1 Adjusted Location Specific P-T Limits for Normal Ramp Cooldown Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi)70 75 80 85 90 95 101 110 115 120 123 125 130 135 140 145 150 155 160 165 170 175 180 185 190 195 200 205 210 215 220 225 230 235 240 245 250 255 260 265 270 275 280 545 551 559 568 579 584 519 523 535 547 555 560 574 590 607 627 648 672 698 727 759 794 834 877 925 978 1022 1076 1136 1202 1276 1357 1446 1524 1619 1775 1909 2057 2220 2400 2600 2820 3063 699 740 776 817 861 910 913 1002 1107 1188 1242 1278 1377 1486 1607 1741 1888 2052 2232 2431 2652 2810 2802 2792 2781 2768 2754 2737 2716 2693 2667 2636 2600 2527 2578 2535 2488 2451 2453 2454 2455 2456 2458 726 769 807 849 895 946 951 1044 1153 1237 1293 1330 1433 1546 1672 1810 1964 2133 2321 2528 2756 2921 2912 2902 2891 2878 2862 2845 2823 2799 2772 2741 2703 2627 2680 2635 2586 2548 2550 2551 2552 2554 2555 612 612 612 761 910 1058 1180 1585 1810 2035 2170 Page 39 A AREVA A AREVA ANP-3102, Rev. 3 Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi)285 290 295 300 305 310 315 320 325 330 335 340 345 350 355 360 365 370 375 380 385 390 395 400 405 410 415 420 425 430 435 440 445 450 455 460 465 470 475 480 485 490 495 500 505 3205 3205 3204 3204 3203 3203 3203 3202 3202 3202 3202 3202 3202 3195 3196 3196 3196 3196 3196 3197 3197 3198 3199 3200 3200 3202 3203 3205 3208 3210 3214 3217 3221 3225 3229 3234 3239 3245 3252 3259 3267 3276 3286 3308 3320 2460 2461 2463 2465 2468 2470 2474 2476 2479 2482 2485 2488 2491 2502 2506 2510 2514 2517 2522 2527 2533 2539 2545 2551 2558 2565 2573 2580 2589 2597 2606 2615 2625 2635 2646 2657 2669 2681 2694 2707 2721 2736 2751 2783 2799 2557 2559 2561 2563 2565 2568 2572 2574 2577 2580 2583 2586 2590 2601 2605 2609 2613 2616 2621 2627 2633 2639 2645 2652 2659 2666 2674 2682 2691 2699 2708 2718 2728 2739 2750 2762 2774 2787 2800 2814 2828 2843 2859 2891 2908 Page 40 A AREVA A AREVA ANP-3102, Rev. 3 Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi)510 3332 2814 2924 515 3346 2832 2943 520 3360 2850 2962 525 3375 2870 2982 530 3392 2889 3002 535 3411 2910 3024 540 3432 2931 3045 545 3454 2952 3067 550 3478 2973 3090 555 3503 2995 3112 560 3529 3015 3133 565 3554 3032 3151 Page 41 A AREVA A AREVA ANP-3102, Rev. 3 Table 16: TMI-1 Adjusted Location Specific P-T Limits for Normal Step Cooldown Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (F) (psi) (psi) (psi) (psi)70 80 85 100 101 115 123 130 145 160 175 190 205 220 235 240 255 270 285 300 315 330 345 360 375 390 405 420 435 450 465 480 495 510 525 540 555 569 580 586 604 538 562 581 598 647 713 801 921 1072 1276 1511 1655 2057 2600 3234 3232 3231 3231 3231 3224 3224 3225 3228 3231 3237 3247 3259 3276 3299 3341 3380 3429 3493 678 774 817 965 921 1107 1251 1377 1741 2232 2839 2811 2766 2696 2558 2607 2467 2470 2474 2479 2485 2495 2503 2521 2531 2547 2565 2586 2609 2637 2668 2704 2745 2807 2858 2916 2979 705 804 849 1002 959 1153 1302 1433 1810 2321 2951 2921 2875 2802 2659 2710 2564 2568 2572 2577 2584 2593 2602 2620 2631 2647 2666 2687 2712 2740 2773 2810 2853 2917 2969 3030 3096 612 612 761 1207 1180 1810 2170 Page 42 A AR E VA A AREVA ANP-3102, Rev. 3 Table 17: Tech Spec. Basis P-T Limits for Normal Limiting Cooldown Fluid Temp.(OF)70 75 80 85 90 95 101 110 115 120 123 125 130 135 140 145 150 155 160 165 170 175 180 185 190 195 200 205 210 215 220 225 230 235 240 245 250 255 260 265 270 Governing Adjusted Pressure (psi)519 519 519 519 519 519 519 523 535 547 555 560 574 590 607 627 648 672 698 727 759 794 834 877 921 978 1022 1072 1136 1202 1276 1357 1446 1511 1619 1775 1909 2057 2220 2400 2455 Page 43 A AREVA AREVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure ('F) (psi)275 2456 280 2458 285 2460 290 2461 295 2463 300 2465 305 2468 310 2470 315 2474 320 2476 325 2479 330 2482 335 2485 340 2488 345 2491 350 2502 355 2506 360 2510 365 2514 370 2517 375 2522 380 2527 385 2533 390 2539 395 2545 400 2551 405 2558 410 2565 415 2573 420 2580 425 2589 430 2597 435 2606 440 2615 445 2625 450 2635 455 2646 460 2657 465 2668 470 2681 475 2694 480 2704 485 2721 490 2736 495 2745 Page 44 A"AR EVA A ARIEVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi)500 2783 505 2799 510 2807 515 2832 520 2850 525 2858 530 2889 535 2910 540 2916 545 2952 550 2973 555 2979 560 3015 565 3032 Page 45 A AR EVA A AREVA ANP-3102, Rev. 3 2400 2200 2000 1800 0.)1600 (A 1400 I.r/) 1200 U A14000 S800 o)"-600 400 200 0 Figure 3: TMI-1 Tech. Spec. Basis P-T Limits for Normal Heatup and Criticality Limit-P-T Limits for Normal Heatup-Criticality Limit P-T Limit Curve 0 50 100 150 200 250 300 350 Indicated RCS InletTemperature, OF 400 450 500 Page 46 A AREVA A AREVA ANP-3102, Rev. 3 Figure 4: TMI-1 Tech. Spec. Basis P-T Limits for Normal Cooldown 2400 2200 2000.01800 0.a1600 U) 1400 S1200.2 800-600 400 200 0 0 50 100 150 200 250 300 350 Indicated RCS Inlet Temperature, OF 400 450 500 Page 47 A AREVA A AREVA ANP-3102, Rev. 3 8.0  
 
AREVA ANP-3102, Rev. 3 7.1     P-T Curves for ISLH Heatup / Cooldown The Pressure-Temperature limits are developed for ISLH test operations. For ISLH heatup, adjusted location specific (i.e. on a per component basis) P-T limits are presented in Table 6. The Tech. Spec. basis P-T limits for ISLH heatup are shown in Table 8. The location adjusted P-T limits for ISLH ramp cooldown are presented in Table 9. The location adjusted P-T limits calculated for ISLH step cooldown are shown in Table 10. The Technical specification (Tech. Spec.) basis P-T limits for ISLH cooldown generated as the limiting allowable pressure at every calculated temperature is shown in Table 11. The adjusted P-T limits for ISLH heatup and cooldown are plotted in Figure 1. A limiting composite curve for Tech. Spec. Basis P-T limits for ISLH is developed, the pressure-temperature data is shown in Table 12 and the curve is plotted in Figure 2. The criticality I limit temperature corresponding to a pressure of 2500 psig can be determined through interpolation of ISLH heatup data in Table 6. As shown in Table 7, the criticality limit temperature is 262.7 'F. The criticality limit curve is shown in Figure 3 along with the normal heatup Tech. Spec. basis P-T limit curve.
Page 13                                             A AREVA
 
A                                                                   ANP-3102, Rev. 3 AREVA Table 6: TMI-1 Adjusted Location Specific P-T Limits for ISLH Heatup Allowable Pressures Limiting   Outlet   Inlet   Closure Fluid Beltline Nozzle   Nozzle   Head Temp. Weld (OF)     (psi)     (psi)   (psi)   (psi) 60       832      873      907    671 65       833      878      912      811 70     835      892      927      953 75     838      912      947    1095 80     841      934      971    1237 85     841      948      985    1435 90     850      991    1030    1633 95     857      1029    1069    1831 100     863      1071    1113    2029 105     802      1059    1102    2170 110     810      1108    1153 115     819      1162    1210 120     828      1222    1272 125     839      1289    1341 130     851      1363    1418 135     864      1444    1503 140     879      1534    1596 145     895      1634    1700 150     913      1744    1814 155     932      1866    1941 160     954      2001    2080 165     978      2149    2235 170     1005      2314    2405 175     1035      2495    2594 180     1067      2696    2802 185     1103      2918    3033 190     1143      3163    3287 195     1187      3433    3568 200     1222      3732    3878 205     1275      4050    4208 210     1335      4050    4208 215     1400      4050    4208 220     1473      4050    4208 225     1553    4050    4208 230     1642    4050    4208 235     1740    4050    4208 240     1848    4050    4208 245     1967    4050    4208 250     2099      4050      4208 255     2244      4050      4208 260     2405     4050      4208 Page 14 A
AREVA
 
A                                                ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting  Outlet    Inlet  Closure Fluid Beltline  Nozzle    Nozzle    Head Temp. Weld (OF)    (psi)    (psi)    (psi    (psi) 265    2582      4050     4208 270    2777      4050     4208 275    2993      4050     4208 280    3231      4050     4208 285    3494      4050     4208 290    3785      4050     4208 295    4106      4050     4208 300    4460      4050     4208 305    4788      4050     4208 310    4788      4050     4208 315    4788      4050     4208 320    4787      4050     4208 325    4787      4050    4208 330    4787      4050    4208 335    4786      4050    4208 340    4786      .4050    4208 345    4786      4050    4208 350  4778      4057    4215 355    4778      4057    4215 360  4777      4057    4215 365    4777      4057    4215 370    4776      4057    4215 375    4776      4057    4215 380    4775      4057    4215 385    4775      4057    4215 390    4774      4057    4215 395    4774      4057    4215 400   4773      4057    4215 405   4773      4057    4215 410   4772      4057    4215 415   4772      4057    4215 420   4771      4057    4215 425   4771      4057    4215 430   4771      4057    4215 435   4770      4057    4215 440   4770      4057    4215 445   4770      4057    4215 450   4770      4057    4215 455   4769      4057    4215 460   4769      4057    4215 465   4768      4057    4215 470   4768      4057    4215 475   4766      4057    4215 480    4766      4057    4215 485   4766      4057    4215 Page 15 A
ARE VA
 
A                                                                ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting      Outlet        Inlet Closure Fluid  Beltline      Nozzle      Nozzle  Head Temp. Weld (4F)    (psi)        (psi)        (psi)  (psi) 490      4765          4057        4215 495      4765          4057        4215 500      4776         4073        4231 505      4776         4073        4231 510      4775         4073        4231 515    4775         4073        4231 520      4774         4073        4231 525      4773         4073        4231 530      4773         4073        4231 535      4772         4073        4231 540    4772         4073        4231 545      4772        4073        4231 550      4771         4073        4231 555      4771         4073        4231 560      4770         4073        4231 565      4769         4073        4231 570      4769         4073        4231 Table 7: TMI-1 Criticality Limit Temperature Determination Criticality Limit Temp. at 500 psig Pressure        Temp.
(psig)          (OF) 2405          260 2582          265 Interpolating:
2500          262.7 Page 16 A
AREVA
 
A                                                               ANP-3102, Rev. 3 AREVA Table 8: TMI-1 Tech. Spec. Basis P-T Limits for ISLH Heatup Governing Fluid     Adjusted Temp.     Pressure (OF)
(psi) 60        671 65        802 70        802 75        802 80          802 85        802 90        802 95        802 100        802 105        802 110        810 115        819 120        828 125        839 130        851 135        864 140        879 145        895 150        913 155        932 160        954 165        978 170        1005 175        1035 180        1067 185        1103 190        1143 195        1187 200        1222 205        1275 210        1335 215        1400 220        1473 225        1553 230        1642 235        1740 240        1848 245        1967 250        2099 255        2244 260        2405 Page 17 A
AREVA
 
A AREVA ANP-3102, Rev. 3 Governing Fluid    Adjusted Temp.     Pressure (OF)       (psi) 265        2582 270        2777 275        2993 280        3231 285        3494 290        3785 295        4050 300        4050 305        4050 310        4050 315        4050 320        4050 325        4050 330        4050 335        4050 340        4050 345        4050 350        4057 355        4057 360        4057 365        4057 370        4057 375        4057 380        4057 385        4057 390        4057 395        4057 400        4057 405        4057 410        4057 415        4057 420        4057 425        4057 430        4057 435        4057 440        4057 445        4057 450        4057 455        4057 460        4057 465        4057 470        4057 475        4057 480        4057 485        4057 Page 18 A
AR EVA
 
A AREVA ANP-3102, Rev. 3 Governing Fluid    Adjusted Temp. Pressure (OF)      (psi) 490        4057 495        4057 500        4073 505        4073 510        4073 515        4073 520        4073 525        4073 530        4073 535        4073 540        4073 545        4073 550        4073 555        4073 560        4073 565        4073 570        4073 Page 19                A AREVA
 
A                                                                   ANP-3102, Rev. 3 AREVA Table 9: TMI-1 Adjusted Location Specific P-T Limits for ISLH Ramp Cooldown Allowable Pressures Limiting  Outlet    Inlet  Closure Fluid Beltline  Nozzle    Nozzle    Head Temp. Weld (OF)   (psi)     (psi)    (psi)    (psi) 70      733      937      974      953 75      742      992    1031    1095 80      753      1041    1081    1237 85      765      1094    1137    1435 90      780      1154    1199    1633 95      786      1219    1267    1831 105      724      1295    1347    2170 110      727      1361    1416 115      743      1501    1562 120      759      1609    1674 125      776      1728    1798 130      795      1860    1935 135      816      2006    2086 140      840      2167    2254 145      866      2346    2439 150      894      2542    2643 155      926      2760    2869 160      961      3001    3119 165      999      3266    3395 170    1042      3560    3700 175    1089      3772    3919 180    1141      3761    3908 185    1199      3748    3895 190    1263      3733    3879 195    1334      3716    3862 200    1397      3696    3841 205    1469      3674    3818 210    1549      3646    3789 215    1638      3616    3757 220    1735      3581    3721 225    1844      3540    3679 230    1963      3492    3629 235    2066      3395    3528 240    2193      3462    3598 245    2402      3405    3538 250    2580      3342    3473 255    2777      3293    3423 260    2995      3295    3424 265    3235      3296    3426 270    3501      3298    3428 275    3795      3300    3430 Page 20 A
AR EVA
 
A                                                ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting  Outlet    Inlet  Closure Fluid Beitline  Nozzle   Nozzle   Head Temp. Weld (OF)   (psi)     (psi)     (psi)   (psi) 280    4119      3302    3432 285    4308      3304    3434 290    4308      3307    3436 295    4307      3309    3439 300    4306      3312    3442 305    4306      3315    3445 310    4305      3318    3448 315    4305      3323    3454 320    4305      3326    3457 325    4304      3330    3461 330    4304      3334    3465 335    4304      3338    3469 340    4304      3342    3473 345    4304      3347    3478 350    4297      3358    3490 355    4298      3363    3495 360    4298      3369    3501 365    4298      3375    3507 370    4298      3378    3511 375    4299      3385    3518 380    4299      3392    3525 385    4300      3399    3533 390    4301      3407    3541 395    4302      3415    3549 400    4304      3424    3558 405    4304      3433    3568 410    4306      3442    3577 415    4308      3452    3588 420    4311      3463    3598 425    4314      3474    3610 430    4318      3485    3622 435    4322      3496    3633 440    4326      3509    3646 445    4331      3522    3660 450    4337      3536      3674 455    4343      3550      3689 460    4349      3565      3705 465    4356      3581      3721 470    4364      3597      3738 475    4373      3614      3756 480    4383      3632      3774 485    4393      3651      3793 490    4405      3670      3814 495    4418      3690      3834 500    4444      3727      3872 Page 21 A
ARE VA
 
A                                               ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting   Outlet     Inlet Closure Fluid Beltline  Nozzle   Nozzle   Head Temp. Weld (OF)   (psi)     (psi)   (psi)   (psi) 505  4459      3749    3895 510  4476      3769    3916 515  4494      3793    3941 520  4513      3818    3966 525  4533      3843    3993 530  4556      3870    4020 535  4582      3897    4049 540  4609      3925    4077 545  4638      3953    4107 550  4670      3982    4137 555  4703      4010    4166 560  4738      4037    4194 565  4772      4060    4218 570  4793      4072    4231 Page 22 A
AR EVA
 
A                                                                    ANP-3102, Rev. 3 AREVA Table 10: TMI-1 Adjusted Location Specific P-T Limits for ISLH Step Cooldown Allowable Pressures Limiting  Outlet    Inlet  Closure Fluid  Beltline  Nozzle    Nozzle    Head Temp. Weld (F)    (psi)    (psi)    (psi)  (psi) 70      766      910      945    953 80      781      1038    1078    1237 85      788      1094    1137    1435 100      813      1292    1342    2029 105      757      1324    1377    2170 115      780      1501    1562 130      828      1860    1935 145      893      2346    2439 160      980      3001    3119 175    1098      3811    3960 190    1258      3772    3920 205    1464      3712    3858 220    1735      3619    3761 235    2050      3435    3570 240    2241      3501    3638 255    2777      3314    3444 270    3501      3318    3448 285    4347      3323    3454 300    4345      3330    3461 315    4343      3338    3470 330    4343      3351    3482 345    4342      3362    3495 360    4336      3383    3516 375    4336      3398    3531 390    4337      3418      3552 405    4341      3442      3577 420    4345      3470      3606 435    4353      3502      3639 450    4366      3538      3676 465    4382      3580      3720 480    4405      3628      3770 495    4436      3682      3826 510     4487      3759      3906 525     4539      3827      3976 540     4605      3905      4057 555     4690      3989      4144 Page 23 A
AREVA
 
A AREVA ANP-3102, Rev. 3 Table 11: TMI-1 Tech Spec. Basis P-T Limits for ISLH Cooldown Governing Fluid     Adjusted Temp.     Pressure (OF)       (psi) 70         724 75          724 80         724 85         724 90          724 95          724 105         724 110        727 115         743 120        759 125        776 130         795 135        816 140        840 145         866 150        894 155        926 160         961 165        999 170        1042 175       1089 180        1141 185        1199 190       1258 195        1334 200        1397 205       1464 210        1549 215        1638 220       1735 225        1844 230        1963 235        2050 240        2193 245        2402 250        2580 255       2777 260        2995 265        3235 270       3298 275        3300 280        3302 285       3304 Page 24                                A AREVA
 
AR ANP-3102, Rev. 3 Governing Fluid    Adjusted Temp. Pressure (OF)      (psi) 290        3307 295        3309 300        3312 305        3315 310        3318 315        3323 320        3326 325        3330 330        3334 335        3338 340        3342 345        3347 350        3358 355        3363 360        3369 365        3375 370        3378 375        3385 380        3392 385        3399 390        3407 395        3415 400        3424 405        3433 410        3442 415        3452 420        3463 425        3474 430        3485 435        3496 440        3509 445        3522 450        3536 455        3550 460        3565 465        3580 470        3597 475        3614 480        3628 485        3651 490        3670 495        3682 500      3727 505      3749 510      3759 Page 25 A
A R EVA
 
A                       ANP-3102, Rev. 3 AREVA Governing Fluid    Adjusted Temp.     Pressure (OF)       (psi) 515        3793 520        3818 525        3827 530        3870 535        3897 540        3905 545        3953 550        3982 555        3989 560        4037 565        4060 570        4072 Page 26 A
AR EVA
 
A                                                                  ANP-3102, Rev. 3 AREVA Table 12: TMI-1 Tech Spec. Basis P-T Limits for ISLH Composite Curve Goveming Fluid    Adjusted Temp. Pressure
('F)       (psi) 60        671 65        724 70        724 75        724 80        724 85        724 90        724 95        724 100        724 105        724 110        727 115        743 120        759 125        776 130        795 135        816 140        840 145        866 150        894 155        926 160        954 165        978 170        1005 175        1035 180        1067 185        1103 190        1143 195        1187 200        1222 205        1275 210        1335 215        1400 220        1473 225        1553 230        1642 235        1740 240        1848 245        1967 250        2099 255        2244 260        2405 265        2582 Page 27 A
AREVA
 
A AREVA ANP-3102, Rev. 3 Governing Fluid     Adjusted Temp.     Pressure (OF)       (psi) 270        2777 275        2993 280        3231 285        3304 290        3307 295        3309 300        3312 305        3315 310        3318 315        3323 320        3326 325        3330 330        3334 335        3338 340        3342 345        3347 350        3358 355        3363 360        3369 365        3375 370        3378 375        3385 380        3392 385        3399 390        3407 395        3415 400        3424 405        3433 410        3442 415        3452 420        3463 425        3474 430        3485 435        3496 440        3509 445        3522 450        3536 455        3550 460        3565 465        3580 470        3597 475        3614 480        3628 485        3651 490        3670 495        3682 Page 28 A
A R EVA
 
A AREVA ANP-3102, Rev. 3 Governing Fluid    Adjusted Temp.      Pressure (OF)        (psi) 500        3727 505        3749 510        3759 515        3793 520        3818 525        3827 530        3870 535        3897 540        3905 545        3953 550        3982 555        3989 560        4037 565        4060 570        4072 Page 29 A
AR EVA
 
A                                                                                           ANP-3102, Rev. 3 AREVA Figure 1: TMI-1 Adjusted P-T Limits for ISLH Heatup and Cooldown 2400 2200 2000
      .2- 1800 U'
G1600 (A1400 U)
I- 1200 1000 S800 4OO 46000 100 200 0
0 50        100      150      200      250      300      350     400 450 500 Indicated RCS Inlet Temperature, OF Page 30 A
AREVA
 
A                                                                                           ANP-3102, Rev. 3 AREVA Figure 2: TMI-1 Tech. Spec. Basis P-T Limits for ISLH (Composite Curve) 2400 2200 2000
.- 1800 G
0.
01600 01400 ID.
a.
U) 1200 1000 j  800 600 400 200 0
0 50 100       150       200     250       300       350     400    450      500 Indicated RCS InletTemperature, IF Page 31 A
AREVA
 
A                                                                                         ANP-3102, Rev. 3 AREVA 7.2     P-T Curves for Normal Heatup / Cooldown The Pressure-Temperature limits are developed for both normal heatup and cooldown operations. For heatup, location specific adjusted P-T limits are presented in Table 13. The Tech. Spec. basis P-T limits for normal heatup are shown in Table 14. The location specific adjusted P-T limits for ramp cooldown are presented in Table 15. The location adjusted P-T limits calculated for normal step cooldown are shown Table 16. The Technical specification (Tech. Spec.) basis P-T limits for cooldown generated as the limiting pressure at every calculated temperature is shown in Table 17. The Tech. Spec. basis P-T limits for heatup are plotted in Figure 3 and the Tech. Spec. basis cooldown P-T limits are plotted in Figure 4.
Page 32 A
AR EVA
 
A                                                                      ANP-3102, Rev. 3 AREVA Table 13: TMI-1 Adjusted Location Specific P-T Limits for Normal Heatup Allowable Pressures Limiting  Outlet    Inlet  Closure Fluid  Beltline  Nozzle    Nozzle    Head Temp. Weld (OF)    (psi)    (psi)    (psi)    (psi) 60      618      650      676      612 65      619      654      680      612 70      621      665      691      612 75      623      679      706      612 80      626      696      724      612 85      629      716      744      761 90      632      738      767      910 90      632      738      767      910 90      632      739      768      910 95      637      768      798    1058 100      642      799      830    1207 101      575      749      780    1180 105      579      776      808    1360 110     585      813      847    1585 115     592      853      889    1810 120     599      898      936    2035 123      604      928      967    2170 125     607      948      988 130     616      1004    1045 135     626      1065    1108 140     637      1132    1179 145     649      1207    1256 150     662      1290    1342 155     677      1381    1437 160     693      1482    1542 165     711      1593    1658 170     731      1717    1786 175     753      1853      1927 180     778      2003    2083 185     805      2170    2256 190     835      2353    2447 195     868      2556    2657 200     890      2780    2890 205     931      3019    3138 210     975      3019    3138 215     1024      3019    3138 220     1079      3019    3138 225     1139      3019    3138 230     1205      3019    3138 235     1279      3019      3138 240     1360      3019      3138 Page 33 A
AREVA
 
A                                              ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting  Outlet    Inlet  Closure Fluid Beltline  Nozzle    Nozzle    Head Temp. Weld (OF)  (psi)    (psi)    (psi)  (psi) 245  1449      3019    3138 250  1548      3019     3138 255  1657      3019     3138 260  1777      3019     3138 265  1910      3019     3138 270  2057      3019     3138 275  2219      3019     3138 280  2398      3019     3138 285  2595      3019     3138 290. 2813      3019      3138 295  3053      3019      3138 300  3319      3019      3138 305  3565      3019      3138 310  3565      3019      3138 315  3565      3019      3138 320  3564      3019      3138 325  3564      3019      3138 330  3564      3019      3138 335    3564      3019      3138 340    3563      3019      3138 345    3563      3019      3138 350    3556      3026      3145 355    3556      3026      3145 360    3555      3026      3145 365    3555      3026      3145 370    3555      3026      3145 375    3554      3026      3145 380    3554      3026      3145 385    3553      3026      3145 390    3553      3026      3145 395    3553      3026      3145 400    3552      3026      3145 405    3552      3026      3145 410    3551      3026      3145 415   3551      3026      3145 420   3551      3026      3145 425   3551      3026      3145 430   3550      3026      3145 435   3550      3026      3145 440    3550      3026      3145 445   3550      3026      3145 450   3549      3026      3145 455   3549      3026      3145 460   3549      3026      3145 465   3548      3026      3145 Page 34                              A AREVA
 
A                                              ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting  Outlet    Inlet  Closure Fluid Beltline  Nozzle    Nozzle    Head Temp. Weld (OF)  (psi)    (psi)    (psi)    (psi) 470  3548       3026     3145 475  3547      3026     3145 480  3547      3026     3145 485  3546      3026     3145 490  3546      3026     3145 495  3546      3026     3145 500  3558      3042    3161 505  3557      3042    3161 510  3557      3042    3161 515  3556      3042    3161 520  3556      3042    3161 525  3555      3042    3161 530  3555      3042    3161 535  3555      3042    3161 540  3554      3042    3161 545  3554      3042    3161 550  3554      3042    3161 555  3553      3042    3161 560  3553      3042    3161 565  3552      3042    3161 570    3552      3042    3161 Page 35 A
AREVA
 
AREVA ANP-3102, Rev. 3 Table 14: TMI-1 Tech. Spec. Basis P-T Limits for Normal Heatup Governing Fluid     Adjusted Temp.     Pressure (OF)       (psi) 60          575 65          575 70        575 75        575 80        575 85        575 90        575 90        575 90        575 95        575 100        575 101        575 105        579 110        585 115        592 120        599 123        604 125        607 130        616 135        626 140        637 145        649 150        662 155        677 160        693 165        711 170        731 175        753 180        778 185        805 190        835 195        868 200        890 205        931 210        975 215        1024 220        1079 225        1139 230        1205 235        1279 240        1360 245        1449 250        1548 Page 36                                    A AR EVA
 
A AREVA ANP-3102, Rev. 3 Governing Fluid    Adjusted Temp.     Pressure (OF)       (psi) 255        1657 260        1777 265        1910 270        2057 275        2219 280        2398 285        2595 290        2813 295        3019 300        3019 305        3019 310        3019 315        3019 320        3019 325        3019 330        3019 335        3019 340        3019 345        3019 350        3026 355        3026 360        3026 365        3026 370        3026 375        3026 380        3026 385        3026 390        3026 395        3026 400        3026 405        3026 410        3026 415        3026 420        3026 425        3026 430        3026 435        3026 440        3026 445        3026 450        3026 455        3026 460        3026 465        3026 470        3026 475        3026 Page 37 A
AR EVA
 
A AREVA ANP-3102, Rev. 3 Governing Fluid     Adjusted Temp. Pressure (OF)       (psi) 480        3026 485        3026 490        3026 495        3026 500        3042 505        3042 510        3042 515        3042 520        3042 525        3042 530        3042 535        3042 540        3042 545        3042 550        3042 555        3042 560        3042 Page 38 A
A R EVA
 
A                                                                        ANP-3102, Rev. 3 AREVA Table 15: TMI-1 Adjusted Location Specific P-T Limits for Normal Ramp Cooldown Allowable Pressures Limiting  Outlet    Inlet  Closure Fluid  Beltline  Nozzle    Nozzle    Head Temp. Weld (OF)    (psi)    (psi)    (psi)   (psi) 70      545      699      726      612 75      551      740      769      612 80      559      776      807      612 85      568      817      849      761 90      579      861      895      910 95      584      910      946    1058 101      519      913      951    1180 110      523      1002    1044    1585 115      535      1107    1153    1810 120      547      1188    1237    2035 123      555      1242    1293    2170 125      560      1278    1330 130      574      1377    1433 135      590      1486    1546 140      607      1607    1672 145      627      1741    1810 150     648      1888    1964 155     672      2052    2133 160     698      2232    2321 165     727      2431    2528 170     759      2652    2756 175     794      2810    2921 180     834      2802    2912 185     877      2792    2902 190     925      2781    2891 195     978      2768    2878 200     1022      2754    2862 205     1076      2737    2845 210     1136      2716    2823 215     1202      2693    2799 220     1276      2667    2772 225     1357      2636    2741 230     1446      2600    2703 235     1524      2527    2627 240     1619      2578    2680 245     1775      2535    2635 250     1909      2488    2586 255     2057      2451    2548 260     2220      2453    2550 265     2400      2454    2551 270     2600      2455      2552 275     2820      2456      2554 280     3063      2458      2555 Page 39 A
AREVA
 
A                                                ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting  Outlet    Inlet  Closure Fluid Beltline  Nozzle  Nozzle    Head Temp. Weld (OF)    (psi)    (psi)    (psi)  (psi) 285    3205      2460    2557 290    3205      2461    2559 295    3204      2463    2561 300    3204      2465    2563 305    3203      2468    2565 310    3203      2470    2568 315    3203      2474    2572 320    3202      2476    2574 325    3202      2479    2577 330    3202      2482    2580 335    3202      2485    2583 340    3202      2488    2586 345    3202      2491    2590 350    3195      2502    2601 355    3196      2506    2605 360    3196      2510    2609 365    3196      2514    2613 370    3196      2517    2616 375    3196      2522    2621 380    3197      2527    2627 385    3197      2533    2633 390    3198      2539    2639 395    3199      2545    2645 400    3200      2551     2652 405    3200      2558    2659 410    3202      2565    2666 415    3203      2573    2674 420    3205      2580    2682 425    3208      2589    2691 430    3210      2597    2699 435    3214      2606    2708 440    3217      2615    2718 445    3221      2625    2728 450    3225      2635    2739 455    3229      2646    2750 460    3234      2657    2762 465    3239      2669    2774 470    3245      2681    2787 475    3252      2694    2800 480    3259      2707    2814 485   3267      2721    2828 490   3276      2736    2843 495   3286      2751    2859 500   3308      2783    2891 505   3320      2799    2908 Page 40 A
AREVA
 
A                                                ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting  Outlet    Inlet  Closure Fluid Beltline  Nozzle    Nozzle    Head Temp. Weld (OF)    (psi)    (psi)    (psi)    (psi) 510    3332      2814    2924 515    3346      2832    2943 520    3360      2850    2962 525    3375      2870    2982 530    3392      2889    3002 535    3411      2910    3024 540    3432      2931    3045 545    3454      2952    3067 550    3478      2973    3090 555    3503      2995    3112 560    3529      3015    3133 565    3554      3032    3151 Page 41 A
AREVA
 
A                                                                           ANP-3102, Rev. 3 AREVA Table 16: TMI-1 Adjusted Location Specific P-T Limits for Normal Step Cooldown Allowable Pressures Limiting   Outlet     Inlet Closure Fluid   Beltline   Nozzle   Nozzle   Head Temp. Weld (F)     (psi)     (psi)     (psi)   (psi) 70      569        678      705    612 80      580        774      804    612 85      586        817      849    761 100      604        965    1002    1207 101      538        921      959    1180 115        562    1107      1153    1810 123        581    1251      1302    2170 130        598    1377      1433 145      647      1741      1810 160        713    2232      2321 175        801    2839      2951 190        921    2811      2921 205      1072      2766      2875 220      1276      2696      2802 235      1511      2558      2659 240      1655      2607      2710 255      2057      2467      2564 270      2600      2470      2568 285      3234      2474      2572 300      3232      2479      2577 315      3231      2485      2584 330      3231      2495      2593 345      3231      2503      2602 360      3224      2521      2620 375     3224      2531      2631 390     3225      2547      2647 405     3228      2565      2666 420     3231      2586      2687 435     3237      2609      2712 450     3247      2637      2740 465      3259      2668      2773 480     3276      2704      2810 495     3299      2745      2853 510     3341      2807      2917 525     3380      2858      2969 540     3429      2916      3030 555     3493      2979      3096 Page 42 A
AR E VA
 
A                                                                    ANP-3102, Rev. 3 AREVA Table 17: Tech Spec. Basis P-T Limits for Normal Limiting Cooldown Governing Fluid    Adjusted Temp.      Pressure (OF)      (psi) 70        519 75        519 80        519 85        519 90        519 95        519 101        519 110        523 115        535 120        547 123        555 125        560 130        574 135        590 140        607 145        627 150        648 155        672 160        698 165        727 170        759 175        794 180        834 185        877 190        921 195        978 200        1022 205        1072 210        1136 215        1202 220        1276 225        1357 230        1446 235        1511 240        1619 245        1775 250        1909 255        2057 260        2220 265        2400 270        2455 Page 43 A
AREVA
 
AREVA ANP-3102, Rev. 3 Governing Fluid     Adjusted Temp.     Pressure
('F)      (psi) 275        2456 280        2458 285        2460 290        2461 295        2463 300        2465 305        2468 310        2470 315        2474 320        2476 325        2479 330        2482 335        2485 340        2488 345        2491 350        2502 355        2506 360        2510 365        2514 370        2517 375        2522 380        2527 385        2533 390        2539 395        2545 400        2551 405        2558 410        2565 415        2573 420        2580 425        2589 430        2597 435        2606 440        2615 445        2625 450        2635 455        2646 460        2657 465        2668 470        2681 475        2694 480        2704 485        2721 490        2736 495        2745 Page 44 A
                                "AR EVA
 
A                       ANP-3102, Rev. 3 ARIEVA Governing Fluid     Adjusted Temp. Pressure (OF)       (psi) 500        2783 505        2799 510        2807 515        2832 520        2850 525        2858 530        2889 535        2910 540        2916 545        2952 550        2973 555        2979 560        3015 565        3032 Page 45 A
AR EVA
 
A                                                                                                      ANP-3102, Rev. 3 AREVA Figure 3: TMI-1 Tech. Spec. Basis P-T Limits for Normal Heatup and Criticality Limit 2400 2200 2000          -P-T    Limits for Normal Heatup 1800          -Criticality  Limit P-T Limit Curve 0.
      )1600 (A 1400 I.
r/)A14000 1200 U
o)
S800 600 400 200 0
0      50        100        150      200        250  300      350      400        450      500 Indicated RCS InletTemperature, OF Page 46 A
AREVA
 
A AREVA                                                                                     ANP-3102, Rev. 3 Figure 4: TMI-1 Tech. Spec. Basis P-T Limits for Normal Cooldown 2400 2200 2000
      .01800 0.
a1600 U) 1400 S1200
      .2  800
      -   600 400 200 0
0 50        100      150      200       250       300     350     400 450      500 Indicated RCS Inlet Temperature, OF Page 47 A
AREVA
 
A AREVA                                                                                         ANP-3102, Rev. 3 8.0    


==SUMMARY==
==SUMMARY==
The Tech. Spec. basis P-T limits for normal operating heatup and cooldown and ISLH operation were reported in the previous section for TMI-1 at 50.2 EFPY with MUR. This section provides summary P-T curves for heatup, cooldown, and ISLH with some key points (P-T limits) indicated on the plot.Figure 5 shows a summary of the TMI-1 Tech. Spec. basis P-T Limits for normal heatup and criticality limit with some key points noted on the plot. Figure 6 shows a summary of the TMI-1 Tech. Spec. basis P-T Limits for normal cooldown with some key points noted on the plot. Figure 7 shows a summary of TMI-1 Tech. Spec. Basis P-T Limits for ISLH (Composite Curve).Page 48 A AREVA A AREVA ANP-3102, Rev. 3 Figure 5: TMI-1 Summary Tech Spec. Basis P-T Limits at 50.2 EFPY with MUR for Normal Heatup and Criticality Limit 2400 2200 2000 1800 0.01600 W 1400 2!0.(/1200 U-o 1000 u 800 600 400 200 0 0 50 100 150 200 250 300 350 Indicated RCS InletTemperature,OF 400 450 500 Page 49 A AREVA A AREVA ANP-3102, Rev. 3 Figure 6: TMI-1 Summary Tech. Spec. Basis P-T Limits at 50.2 EFPY with MUR for Normal Cooldown 2400 2200 2000 1800 1600 U3 1400 CL i-a-W 1200 1000 u 800 600 400 200 0 T265, 2400... -In 250, 1909 240, 1619- -____220, 1276/1 90, 921________ ________16069 70, 519 13 3 &#xfd; 130 '574 101. 519 ____ ____ ____0 50 100 150 200 250 300 350 Indicated RCS Inlet Temperature, OF 400 450 500 Page 50 A AREVA A AREVA ANP-3102, Rev. 3 Figure 7: TMI-1 Summary Tech. Spec. Basis P-T Limits at 50.2 EFPY with MUR for ISLH (Composite Curve)2400 2200 2000 1800 eL* 1600 Wfl 1400 (L h.1200 1000 a)o 800 600 400 200 0 0 50 100 150 200 250 300 350 Indicated RCS Inlet Temperature, OF 400 450 500 Page 51 A AREVA A AREVA ANP-3102, Rev. 3 9.0 CERTIFICA71ON Pressure/temperature limits for the TMI-1 reactor vessel have been calculated to satisfy the requirements of 10 CFR Part 50, Appendix 0 using analytical methods and acceptance criteria of the ASME Boiler and Pressure Vessel Code, Section XI, Appendix G,1995 Edition.Samer -L. Malmioud, Principal Engineer Component Analysis and Fracture Mechanics Date 'This report has been reviewed for technical content and accuracy.Ashok D. Nana, Supervisor Component Analysis and Fracture Mechanics Date Verification of independent review.lk&#xfd;tw c6rPl-'Wirr ,I--, Date Tim M. W'iger, Manager I Component Analysis and Fracture Mechanics This report is approved for release David Skulna, Project Manager Date Page 52 A AREVA A AREVA ANP-3102, Rev. 3  
 
The Tech. Spec. basis P-T limits for normal operating heatup and cooldown and ISLH operation were reported in the previous section for TMI-1 at 50.2 EFPY with MUR. This section provides summary P-T curves for heatup, cooldown, and ISLH with some key points (P-T limits) indicated on the plot.
Figure 5 shows a summary of the TMI-1 Tech. Spec. basis P-T Limits for normal heatup and criticality limit with some key points noted on the plot. Figure 6 shows a summary of the TMI-1 Tech. Spec. basis P-T Limits for normal cooldown with some key points noted on the plot. Figure 7 shows a summary of TMI-1 Tech. Spec. Basis P-T Limits for ISLH (Composite Curve).
Page 48 A
AREVA
 
A                                                                                                               ANP-3102, Rev. 3 AREVA Figure 5: TMI-1 Summary Tech Spec. Basis P-T Limits at 50.2 EFPY with MUR for Normal Heatup and Criticality Limit 2400 2200 2000 1800 0.
01600 W 1400 2!
0.
(/1200 U
              -o 1000 u   800 600 400 200 0
0   50     100     150     200       250     300     350     400      450      500 Indicated RCS InletTemperature,OF Page 49 A
AREVA
 
A AREVA                                                                                                         ANP-3102, Rev. 3 Figure 6: TMI-1 Summary Tech. Spec. Basis P-T Limits at 50.2 EFPY with MUR for Normal Cooldown 2400 T265, 2400
                                                                                ... - In 2200 2000 250, 1909 1800 1600                                                            240, 1619-   -____
U31400 CL i-a-                                                            220, 1276 W 1200 1000
                                                        /1 90, 921 u  800
________16069 600 70, 519 13         3   &#xfd;   130 '574 400                          101. 519     ____        ____       ____
200 0
0        50           100       150     200           250         300     350 400 450 500 Indicated RCS Inlet Temperature, OF Page 50 A
AREVA
 
A AREVA ANP-3102, Rev. 3 Figure 7: TMI-1 Summary Tech. Spec. Basis P-T Limits at 50.2 EFPY with MUR for ISLH (Composite Curve) 2400 2200 2000 1800 eL
* 1600 Wfl 1400 h.
(L W* 1200 a) 1000 o   800 600 400 200 0
0     50     100     150       200       250     300     350     400    450    500 Indicated RCS Inlet Temperature, OF Page 51 A
AREVA
 
A AREVA                                                                                         ANP-3102, Rev. 3 9.0     CERTIFICA71ON Pressure/temperature limits for the TMI-1 reactor vessel have been calculated to satisfy the requirements of 10 CFR Part 50, Appendix 0 using analytical methods and acceptance criteria of the ASME Boiler and Pressure Vessel Code, Section XI, Appendix G,1995 Edition.
Samer -L.Malmioud, Principal Engineer                         Date '
Component Analysis and Fracture Mechanics This report has been reviewed for technical content and accuracy.
Ashok D. Nana, Supervisor                                     Date Component Analysis and Fracture Mechanics Verification of independent review.
c6rPl-'Wirr lk&#xfd;tw ,I--,
Tim M. W'iger, Manager I                                     Date Component Analysis and Fracture Mechanics This report is approved for release David Skulna, Project Manager                                 Date Page 52 A
AREVA
 
A AREVA ANP-3102, Rev. 3


==10.0 REFERENCES==
==10.0 REFERENCES==
: 1. Code of Federal Regulations, Title 10, Part 50 -Domestic Licensing of Production and Utilization Facilities, Appendix G -Fracture Toughness Requirements, Federal Register Vol. 60. No. 243, December 19, 1995.2. American Society of Mechanical Engineers (ASME) Boiler and Pressure Vessel Code, Section XI, "Rules for Inservice Inspection of Nuclear Power Plant Components," Appendix G, Fracture Toughness Criteria for Protection Against Failure, 1995 Edition with Addenda through 1996.3. ASTM Standard E 208-81, "Standard Method for Conducting Drop-Weight Test to Determine Nil-Ductility Transition Temperature of Ferritic Steels," American Society for Testing and Materials, Philadelphia, Pennsylvania.
: 1. Code of Federal Regulations, Title 10, Part 50 - Domestic Licensing of Production and Utilization Facilities, Appendix G - Fracture Toughness Requirements, Federal Register Vol. 60. No. 243, December 19, 1995.
: 4. AREVA NP Document BAW-10046A, Rev. 2, "Methods of Compliance with Fracture Toughness and Operational Requirements of 1OCFR50, Appendix G," by H. W. Behnke et al., June 1986.5. AREVA NP Document BAW-2308, Rev. IA and Rev. 2A, "Initial RTNDT of LINDE 80 Weld Materials," by K. K. Yoon., August 2005 and March 2008.6. ASME Boiler and Pressure Vessel Code, Section III, Rules for Construction of Nuclear Power Plant Components, Division 1 -Appendices, 1995 Edition with Addenda through the 1996 Edition.7. NRC Regulatory Issue Summary 2004-04: Use of Code Cases N-588, N-640, and N-641 in developing Pressure-Temperature Operating Limits, Dated April 5, 2004.8. Timoshenko, S.P., and Goodier, J.N., Theory of Elasticity, Third Edition, McGraw-Hill Book Company, 1970.9. PVRC Ad Hoc Group on Toughness Requirements, "PVRC Recommendations on Toughness Requirements for Ferritic Materials," Bulletin No. 175, Welding Research Council, August 1972.10. U. S. Nuclear Regulatory Commission, "Radiation Embrittlement of Reactor Vessel Materials," Regulatory Guide 1.99, Revision 2, May 1988.Page 53 A AR EVA}}
: 2. American Society of Mechanical Engineers (ASME) Boiler and Pressure Vessel Code, Section XI, "Rules for Inservice Inspection of Nuclear Power Plant Components," Appendix G, Fracture Toughness Criteria for Protection Against Failure, 1995 Edition with Addenda through 1996.
: 3. ASTM Standard E 208-81, "Standard Method for Conducting Drop-Weight Test to Determine Nil-Ductility Transition Temperature of Ferritic Steels," American Society for Testing and Materials, Philadelphia, Pennsylvania.
: 4. AREVA NP Document BAW-10046A, Rev. 2, "Methods of Compliance with Fracture Toughness and Operational Requirements of 10CFR50, Appendix G," by H. W. Behnke et al., June 1986.
: 5. AREVA NP Document BAW-2308, Rev. IA and Rev. 2A, "Initial         RTNDT   of LINDE 80 Weld Materials,"
by K. K. Yoon., August 2005 and March 2008.
: 6. ASME Boiler and Pressure Vessel Code, Section III, Rules for Construction of Nuclear Power Plant Components, Division 1 - Appendices, 1995 Edition with Addenda through the 1996 Edition.
: 7. NRC Regulatory Issue Summary 2004-04: Use of Code Cases N-588, N-640, and N-641 in developing Pressure-Temperature Operating Limits, Dated April 5, 2004.
: 8. Timoshenko, S.P., and Goodier, J.N., Theory of Elasticity, Third Edition, McGraw-Hill Book Company, 1970.
: 9. PVRC Ad Hoc Group on Toughness Requirements, "PVRC Recommendations on Toughness Requirements for Ferritic Materials," Bulletin No. 175, Welding Research Council, August 1972.
: 10. U. S. Nuclear Regulatory Commission, "RadiationEmbrittlement of Reactor Vessel Materials,"
Regulatory Guide 1.99, Revision 2, May 1988.
Page 53 A
AR EVA}}

Latest revision as of 02:21, 6 February 2020

Attachment 2 - Areva Document No. ANP-3102, Revision 3,Three-Mile Island Unit 1 Appendix G Pressure-Temperature Limits at 50.2 EFPY with Mur, Revision 3, Dated July 2013
ML13232A217
Person / Time
Site: Three Mile Island Constellation icon.png
Issue date: 07/31/2013
From: Mahmoud S
AREVA NP
To:
Office of Nuclear Reactor Regulation
References
TMI-13-107 77-3102-003, ANP-3102, Rev. 3
Download: ML13232A217 (62)


Text

ATTACHMENT 2 AREVA Document No. ANP-3102, Revision 3, "Three-Mile Island Unit 1 Appendix G Pressure-Temperature Limits at 50.2 EFPY with MUR," Revision 3, dated July 2013

ANP-3102, Rev. 3 July 2013 Three-Mile Island Unit I Appendix G Pressure-Temperature Limits at 50.2 EFPY with MUR

ANP-3102, Rev. 3 July 2013 Three-Mile Island Unit 1 Appendix G Pressure-Temperature Limits at 50.2 EFPY with MUR Prepared by S. H. Mahmoud Reviewed by A.D. Nana AREVA Document No.

77-3102-003 Prepared for Exelon Generation Co., LLC

A ANP-3102, Rev. 3 AREVA Copyright © 2013 AREVA.

All Rights Reserved A

AREVA

A ANP-3102, Rev. 3 AREVA Record of Revision Revision Pages/Sections/Paragraphs No. Changed Brief Description / Change Authorization 000 All Original Release 001 Page 2 Changed first sentence of first paragraph and deleted second and third paragraphs.

001 Page 49 Corrected graph format.

002 Pages 3 and 4 Corrected the entry on the first column last row from "IS to LS Circ. Weld (63%)" to "LS Longit. Weld (OD 63%)" in both Tables 1 and 2 003 Page 2 Corrected misrepresentation of reference number to Regulatory Guide 1.99, Revision 2 in the reference list.

Page 6 Corrected description of the input temperature-time histories (225 is changed to 255)

Page 13 1. Changed "The location adjusted P-T limits calculated for normal step cooldown are shown in Table 10" to "The location adjusted P-T limits calculated for ISLH step cooldown are shown in Table 10"

2. Changed "The criticality limit temperature corresponding to a pressure of 2500 psig read from Figure 2, or it can be can be determined through interpolation of ISLH heatup data in Table 6." to "The criticality limit temperature corresponding to a pressure of 2500 psig can be determined through interpolation of ISLH heatup data in Table 6.
3. Changed "The criticality limit curve is shown in Figure 1" to "The criticality limit curve is shown in Figure 3" Page 53 Inserted reference 10.

+

+

A AREVA

A AREVA ANP-3102, Rev. 3 Table of Contents Page RECORD OF REVISION ........................................................................................................................ I LIST OF TABLES ................................................................................................................................. IV LIST OF FIGURES ................................................................................................................................ V

1.0 INTRODUCTION

........................................................................................................................ 1

2.0 BACKGROUND

.......................................................................................................................... 1 3.0 ADJUSTED NIL-DUCTILITY TRANSITION REFERENCE TEMPERATURES ........................ 2 4.0 DESIGN BASIS FOR PRESSURE/TEMPERATURE LIMITS ................................................. 5 4.1 Material Properties ............................................................................................................................ 5 4.2 Postulated Flaws ............................................................................................................................... 5 4.3 Upper Shelf Toughness ............................................................................................................ 5 4.4 Uncorrected Reactor Vessel Closure Head Limits ........................................................................ 6 4.5 Convection Film Coefficient ............................................................................................................... 6 4.6 Reactor Coolant Temperature-Time Histories .............................................................................. 6 4.7 Adjusted Reference Temperatures ............................................................................................... 6 5.0 TECHNICAL BASIS FOR PRESSURE/TEMPERATURE LIMITS ........................................... 8 5.1 Fracture Toughness .......................................................................................................................... 9 5.2 Thermal Analysis and Thermal Stress Intensity Factor ............................................................... 9 5.3 Unit Pressure Stress Intensity Factor for Reactor Vessel Beltline Region ................................ 10 5.4 Unit Pressure Stress Intensity Factor for Reactor Vessel Nozzles ............................................ 11 6.0 PRESSURE CORRECTIONS ................................................................................................ 12 7.0

SUMMARY

O F RESULTS ........................................................................................................ 12 7.1 P-T Curves for ISLH Heatup / Cooldown ................................................................................... 13 7.2 P-T Curves for Normal Heatup / Cooldown ............................................................................... 32 8.0 SUM MARY ............................................................................................................................... 48 9.0 CERTIFICATION ...................................................................................................................... 52 ii A

AREVA

A ANP-3102, Rev. 3 AREVA Table of Contents (continued)

Page

10.0 REFERENCES

......................................................................................................................... 53 A

AREVA

A ARE'VA ANP-3102, Rev. 3 List of Tables Page Table 1: Adjusted Reference Temperature Evaluation for the TMI-1 Reactor Vessel Beltline Materials at the 1/1/2-Thickness Locations Applicable Through 50.2 EFPY with MUR ................................... 3 Table 2: Adjusted Reference Temperature Evaluation for the TMI -1 Reactor Vessel Beltline Materials at the 3/4-Thickness Locations Applicable Through 50.2 EFPY with MUR ................................... 4 Table 3: Material Properties ........................................................................................................... 5 Table 4: Lim iting RTNDT'S for TM I-1 Beltline Materials ........................................................................ 7 Table 5: Limiting Location Corrections Factors for Pressure ............................................................... 12 Table 6: TMI-1 Adjusted Location Specific P-T Limits for ISLH Heatup .......................................... 14 Table 7: TMI-1 Criticality Limit Temperature Determination ............................................................ 16 Table 8: TMI-1 Tech. Spec. Basis P-T Limits for ISLH Heatup ........................................................ 17 Table 9: TMI-1 Adjusted Location Specific P-T Limits for ISLH Ramp Cooldown ............................ 20 Table 10: TMI-1 Adjusted Location Specific P-T Limits for ISLH Step Cooldown ............................ 23 Table 11: TMI-1 Tech Spec. Basis P-T Limits for ISLH Cooldown ................................................. 24 Table 12: TMI-1 Tech Spec. Basis P-T Limits for ISLH Composite Curve ...................................... 27 Table 13: TMI-1 Adjusted Location Specific P-T Limits for Normal Heatup ..................................... 33 Table 14: TMI-1 Tech. Spec. Basis P-T Limits for Normal Heatup ................................................. 36 Table 15: TMI-1 Adjusted Location Specific P-T Limits for Normal Ramp Cooldown ....................... 39 Table 16: TMI-1 Adjusted Location Specific P-T Limits for Normal Step Cooldown ........................ 42 Table 17: Tech Spec. Basis P-T Limits for Normal Limiting Cooldown ............................................ 43 iv A

AREVA

A AREVA ANP-3102, Rev. 3 List of Figures Page Figure 1: TMI-1 Adjusted P-T Limits for ISLH Heatup and Cooldown ............................................. 30 Figure 2: TMI-1 Tech. Spec. Basis P-T Limits for ISLH (Composite Curve) ................................... 31 Figure 3: TMI-1 Tech. Spec. Basis P-T Limits for Normal Heatup and Criticality Limit ..................... 46 Figure 4: TMI-1 Tech. Spec. Basis P-T Limits for Normal Cooldown ............................................... 47 Figure 5: TMI-1 Summary Tech Spec. Basis P-T Limits at 50.2 EFPY with MUR for Normal Heatup and Critica lity Lim it ............................................................................................................................... 49 Figure 6: TMI-1 Summary Tech. Spec. Basis P-T Limits at 50.2 EFPY with MUR for Normal Cooldown

...................................................................................................................................................... 50 Figure 7: TMI-1 Summary Tech. Spec. Basis P-T Limits at 50.2 EFPY with MUR for ISLH (Composite C u rv e ) ........................................................................................................................................... 51 A

AREVA

A ANP-3102, Rev. 3 AREVA

1.0 INTRODUCTION

This report presents operational pressure-temperature (P-T) limits for the reactor vessel at Three-Mile-Island Unit 1 (TMI-1). These limits are expressed in the form of a curve of allowable pressure versus temperature. In addition, the minimum temperature for core criticality is determined to satisfy the regulatory requirements of 10 CFR Part 50, Appendix G [1]. The uncorrected P-T limits for TMI-1 were determined for 50.2 effective full power years (EFPY) of operation with Measurement Uncertainty Re-capture (MUR). Pressure-temperature limits are calculated for the reactor vessel beltline, inlet and outlet nozzles, and closure head locations for normal heatup, normal cooldown, and inservice leak and hydrostatic (ISLH) test conditions. Pressure correction factors were determined between the RCS hot leg pressure taps and various other RCS locations.

2.0 BACKGROUND

The ability of the reactor pressure vessel to resist fracture is the primary factor in ensuring the safety of the primary system in light water-cooled reactors. The three areas of the reactor coolant pressure boundary addressed in the present report are the beltline shell region, the reactor coolant nozzles, and the closure head flange region.

A method for guarding against brittle fracture in reactor pressure vessels is described in Appendix G to the ASME Boiler and Pressure Vessel Code,Section XI, "Rules for Inservice Inspection of Nuclear Power Plant Components."[2]. This method utilizes fracture mechanics concepts and the reference temperature for nil-ductility transition, RTNDT, which is defined as the greater of the drop weight nil-ductility transition temperature (per ASTM E208 [3]) or the temperature that is 60 'F below that at which the material exhibits 50 ft-lbs and 35 mils lateral expansion. The RTNDT of a given material is used to index that material to a reference stress intensity factor curve (K1,). The Kl,, curve appears in Appendix G of ASME Code Section XI. When a given material is indexed to the K1 , curve, allowable stress intensity factors can be obtained for this material as a function of temperature.

Plant operating limits can then be determined using these allowable stress intensity factors.

The RTNDT of the reactor vessel materials, and in turn, the pressure/temperature limits of a reactor vessel, must be adjusted to account for the effects of irradiation. Neutron embrittlement and the resultant changes in mechanical properties of a given pressure vessel steel are monitored by a surveillance program consisting of periodic removal of surveillance capsules from an operating reactor and testing of reactor vessel material specimens obtained from the capsules. The increase in the Charpy V-notch 30 ft-lb temperature is added to the unirradiated RTNDT to adjust it for neutron embrittlement. This adjusted RTNDT is used to index the material to the K1, curve, which in turn, is used to set new operating limits for the nuclear power plant. These new limits take into account the effects of irradiation on the reactor vessel materials.

Pressure-temperature limits for the TMI-1 reactor vessel are developed in accordance with the requirements of 10 CFR Part 50, Appendix G [1], utilizing the analytical methods and flaw acceptance criteria of topical report BAW-10046A [4] and ASME Code Section XI, Appendix G[2].

As mentioned earlier, the three areas of the reactor coolant pressure boundary addressed in this report are the beltline shell region, the reactor coolant nozzles, and the closure head flange region. The beltline and nozzle regions are analyzed specifically for TMI-1 using the K1c reference fracture toughness. The effect of the change in the reference fracture toughness curve on the P-T limits for the closure head flange region is included by utilizing generic limits that have been derived for B&W-designed 177FA reactor vessels.

The TMI-1 reactor vessel contains both axially and circumferentially oriented welds. Therefore, the P-T limits for TMI-1 is based on the postulation of both axial and circumferential flaws in the most limiting axial and circumferential welds and the postulation of an axial flaw in the most limiting forging material of the reactor vessel.

Page 1 A

ARE VA

A ANP-3102, Rev. 3 AREVA One-hundred percent steady state condition Appendix G limits were considered for the development of low temperature overpressure protection (LTOP) P-T limits. To further support the development LTOP system limits, temperature differences between the reactor coolant in the downcomer region and the 1/4/4t wall location are determined for the maximum heatup rate transient. The V4 t wall location is defined as a point within the vessel wall that is located at a distance of one quarter of the vessel thickness from the cladding-base metal interface.

3.0 ADJUSTED NIL-DUCTILITY TRANSITION REFERENCE TEMPERATURES The '/4 t and / t ART values for the TMI-I reactor vessel beltline materials applicable to 50.2 EFPY with MUR are listed in Table 1 and Table 2. These values were calculated in accordance with Regulatory Guide 1.99, Revision 2 [10]. The calculation of the ART values for the weld metals also used BAW-2308 Revision IA and 2A [5]. The controlling beltline materials for the Three Mile Island Unit 1 reactor vessel are the lower nozzle belt to upper shell circumferential weld with ART values at 50.2 EFPY with MUR of 216.0 OF at the 1/4T wall location and 161.1 OF at the 3/4Twall location and the axial welds of the lower shell and upper shell, respectively with ART values at 50.2 EFPY with MUR of 183.9 °F at the 1/4 T wall location and 126.8 °F at the /4T wall location.

The ART values used for the development of the Three Mile Island Unit 1 reactor vessel P-T limits curves, calculated in 2006 for license renewal, were 234.5°F at the '/4T wall location and 178.5°F at the 3/4Twall location for the circumferential welds. The ART values used for the axial welds were 184.7 °F at the 1/4/T wall location and 126.8 °F at the 3/4 T wall location. Thus, in all instances the actual ART values or conservative ART values were used in the development of P-T limit curves performed in 2006.

Page 2 A

AREVA

A ARIEVA ANP-3102, Rev. 3 Table 1: Adjusted Reference Temperature Evaluation for the TMI-1 Reactor Vessel Beltline Materials at the 1/4-Thickness Locations Applicable Through 50.2 EFPY with MUR Estimated Fluence Adiusted Reference Temperature Evaluation at 1/4T Location Reactor Vessel MatI.

ent Heat Numer A 50.2 EFPY, n/cm 2

Chema. Fluence R Initial I RT.sT, a, I 0

e I RTNr Shift, r, 1/4T Beltllne Region Location Ident. Number Type Cu Ni IS 1/4T Factor Factor F J F Margin ART Re*ulatory Guide 1.99, Revision 2, Position 1.1 Lower Nozzle Belt Forging (LNB) ARY 59 123S454 SA-508 CI2 0.08 0.72 1.32E+19 7.698E+18 51.0 0.927 3 31 17 47.3 70.7 121.0 Upper ShellPlate (US) C2789-1 C2789-1 SA-302 Gr B Mod. 0.09 0.57 1.47E+19 8.575E+18 58.0 0.957 1 26.9 17 55.5 63.6 120.1 Upper Shell Plate (US) C2789-2 C2789-2 SA-302 Gr B Mod. 0.09 0.57 1.47E+19 8.575E+18 58.0 0.957 1 26.9 17 55.5 63.6 120.1 Lower Shell Plate (LS) C3307-1 C3307-1 SA-302 Gr B Mod. 0.12 0.55 1.47E+19 6.575E+18 82.0 0.957 1 26.9 17 78.5 63.6 143.1 Lower Shell Plate (LS) C3251-1 C3251-1 SA-302 Gr B Mod. 0.11 0.5 1.47E+19 8.575E+18 73.0 0.957 1 26.9 17 69.9 63.6 134.5 LNB to US Circ. Weld (100%) WF-70 72105 Linde 80 Flux 0.32 0.58 1.32E+19 7.698E+18 199.3 0.927 -31.1 13.7 28 184.8 62.3 [216.0]

US Longit. Weld (Both 100%) WF-8 8T1762 Linde 80 Flux 0.19 0.57 1.31E+19 7.662E+18 167.0 0.925 -47.6 17.2 28 154.5 65.7 172.6 US to LS Circ. Weld (100%) WF-25 299L44 Linde 80 Flux 0.34 0.68 1.43E+19 8.335E+18 220.6 0.949 -74.3 12.8 28 209.3 61.6 196.6 LS Longit. Weld (100%) SA-1526 299L44 Linde 80 Flux 0.34 0.66 1.16E+19 6.778E÷18 220.6 0.891 -74.3 12.8 28 196.6 61.6 {183.9)

LS Longit. Weld (ID 37%) SA-1526 299L44 Linde 80 Flux 0.34 0.68 1.15E+19 6.755E+18 220.6 0.890 -74.3 12.8 28 196.3 61.6 183.6 LS Longit. Weld (OD 63%) SA-1494 8T1554 Linde 80 Flux 0.16 0.57 1.15E+19 N/A 167.0 N/A -47.6 17.2 28 N/A N/A N/A

- Highest values of the adjusted reference temperature for circumferential welds.

- Highest values of the adjusted reference temperature for base metal or longitudinal welds.

Page 3 A

ARIEVA

A ANP-3102, Rev. 3 AR EVA Table 2: Adjusted Reference Temperature Evaluation for the TMI -1 Reactor Vessel Beltline Materials at the  %-

Thickness Locations Applicable Through 50.2 EFPY with MUR Estimated Fluence Adusted Reference Temperature Evaluation at 3/4T Location Reactor Vessel Matt Heat C 50.2 EFPY, n/cm 2

Chem. (Fluence Initial Jo. RTNoT 3/4T Beltilne Region Location Ident. Number Type CU Ni IS 3/4T Factor Factor F ' F Margin ART Regulatory Guide 1.99, Revision 2, Position 1.1 Lower Nozzle Belt Forging (LNB) ARY 59 123S454 SA-508 C02 0.08 0.72 1.32E-19 2.80E+18 51.0 0.652 3 31 17 33.3 70.4 106.7 Upper Shell Plate (US) C2789-1 C2789-1 SA-302 Gr B Mod. 0.09 0.57 1.47E+19 3.12E+18 58.0 0.680 1 26.9 17 39.4 63.6 104,0 Upper Shell Plate(US) C2789-2 C2789-2 SA-302 Gr B Mod. 0.09 0.57 1.47E+19 3.12E+18 58.0 0.680 1 26.9 17 39.4 63.6 104.0 Lower Shell Plate(LS) C3307-1 C3307-1 SA-302 Gr B Mod. 0.12 0.55 1.47E+19 3.12E+18 82.0 0.680 1 26.9 17 55.8 63.6 120.4 Lower Shell Plate (LS) C3251-1 C3251-1 SA-302 Gr 8 Mod. 0.11 0.50 1.47E+19 3.12E+18 73.0 0.680 1 26.9 17 49.6 63.6 114.2 LNB to US Circ. Weld (100%) WF-70 72105 Linde 80 Flux 0.32 0.58 1.32E+19 2.80E+18 199.3 0.652 -31.1 13.7 28 129.9 62.3 [161.1]

US Longit. Weld (Both 100%) WF-8 8T1762 Linde 80 Flux 0.19 0.57 1.31E-19 2.78E+18 167.0 0.651 -47.6 17.2 28 108.7 65.7 {126.8J US to LS Circ. Weld (100%) WF-25 299L44 Linde 80 Flux 0.34 0.68 1.43E+19 3.03E+18 220.6 0.673 -74.3 12.8 28 148.5 61.6 135.8 LS Longit. Weld (100%) SA-1526 299L44 Linde 80 Flux 0.34 0.68 1.16E+19 2.46E+18 220.6 0.620 -74.3 12.8 28 136.8 61.6 124.1 LS Longit. Weld (ID 37%) SA-1526 299144 Linde 80 Flux 0.34 0.68 1.15E+19 N/A 220.6 N/A -74.3 12.8 28 N/A N/A N/A LS Longit. Weld (OD 63%) SA-1494 8T1554 Linde 80 Flux 0.16 0.57 1.15E+19 2.45E+18 167.0 0.619 -47.6 17.2 28 103.4 65.7 121.5 3- Highest values of the adjusted reference temperature for circumferential welds.

- Highest values of the adjusted reference temperature for base metal or longitudinal welds.

Page 4 A

AREVA

A ANP-3102, Rev. 3 AREVA 4.0 DESIGN BASIS FOR PRESSURE/TEMPERATURE LIMITS Essential geometric data and analytical parameters used in the preparation of TMI-1 P-T limits are described below.

4.1 Material Properties Table 3 describes the material properties used in the development of the P-T limits for the TMI-1.

Table 3: Material Properties Temp. Elastic Thermal Thermal Specific Density Poisson's Modulus Expansion Conductivity Heat Ratio Ref. [6] Ref61 Ref.[6] Ref.[6] (assumed)

(°F) (106 psi) (10- in/in/°F) Btu/hr-ft-°F) (Btu/lb-°F) (lb/ft3 )

70 29.20 7.02 23.3 0.104 490.9 0.3 100 29.04 7.06 23.6 0.107 490.5 0.3 150 28.77 7.16 24.1 0.111 489.9 0.3 200 28.50 7.25 24.4 0.114 489.2 0.3 250 28.25 7.34 24.6 0.117 488.6 0.3 300 28.00 7.43 24.7 0.121 487.9 0.3 350 27.70 7.50 24.7 0.124 487.3 0.3 400 27.40 7.58 24.6 0.127 486.7 0.3 450 27.20 7.63 24.4 0.129 486.0 0.3 500 27.00 7.70 24.2 0.132 485.4 0.3 550 26.70 7.77 23.9 0.135 484.7 0.3 600 26.40 7.83 23.5 0.138 484.1 0.3 650 25.85 7.90 23.2 0.141 483.4 0.3 700 25.30 7.94 22.8 0.144 482.8 0.3 4.2 Postulated Flaws

a. Postulated Reactor Vessel Beltline Flaws Semi-elliptical surface flaws that are '/4t deep and 11/ 2 t long are postulated on the inside and outside surfaces of the reactor vessel beltline region. A longitudinal flaw is postulated in the base metal and the axial seam welds and a circumferential flaw is postulated in the circumferential welds.
b. Postulated Nozzle Comer Flaw A 3" (1/4 tNB) deep comer flaw is postulated on the inside surface of the reactor vessel inlet and outlet nozzles.

4.3 Upper Shelf Toughness A maximum value of 200 ksi'An is used for the upper shelf fracture toughness of the reactor vessel beltline. For the nozzle forging materials, a "no cut-off' limit is used.

Page 5 A

AREVA

A AREVA ANP-3102, Rev. 3 4.4 Uncorrected Reactor Vessel Closure Head Limits Pressure-temperature limits for the reactor vessel head-to-flange closure region for normal operation and ISLH operation were derived for TMI- I reactor vessel closure head region based on the K c fracture toughness curve.

4.5 Convection Film Coefficient A value of 1000 BTU/hr-ft2 -°F is used for an effective convective heat transfer film coefficient at the cladding-to-base metal interface for all times during heatup and cooldown when reactor coolant pumps (RCPs) are in use.

When no reactor coolant pumps are running (i.e., before the first RCP is started during heatup and after the last RCP is shut off during cooldown), a value of 430 BTU/hr-ft 2-°F is used as an effective film coefficient at the cladding-to-base metal interface. This value was developed for flow conditions when no RCPs are running and 40

°F water enters the vessel through the core flood nozzle as the decay heat removal system switches to an idle low pressure injection cooler. The outside surface is always modeled as a perfectly insulated boundary.

4.6 Reactor Coolant Temperature-Time Histories Both ramped and stepped transient definitions are modeled for normal operation heatup and cooldown. The limiting normal heatup and cooldown transients (as determined by the controlling P-T limits) are also used to simulate the reactor coolant transients used for inservice leak and hydrostatic (ISLH) pressure testing.

The following input temperature-time histories are considered:

Normal Ramp Heatup, 50 *F/hr.

Normal Step Heatup, 15 OF/ 18 min. steps.

Normal Ramp Cooldown, 100 °F/hr to 255 'F then 30 0F/hr to 70 'F.

Normal Step Cooldown, 15'F/ 9 min. steps to 255 'F then 15 'F/ 30 min. steps to 70 'F.

4.7 Adjusted Reference Temperatures As discussed in Section 3.0, limiting values of the adjusted reference temperature were evaluated. The limiting ART or RTNDT values that were used for determining the P-T curves are also listed in Table 4 for the l/4t and 3/ 4 t locations of the reactor vessel beltline wall at 50.2 EFPY with MUR. An RTNDT of 60 OF is used for the reactor vessel nozzles.

Page 6 A

ARE VA

A ANP-3102, Rev. 3 AREVA Table 4: Limiting RTNDT'S for TMI-1 Beltline Materials Vessel Wall Limiting RTNDT (OF)

Component Location Material at 50.2 EFPY Beltline 1/ t SA-1526 184.7 4

Axial Weld WF-8 126.8 Beltline 1/4t WF-70 234.5 Circ. Weld _7/_4t

_ WF-70 178.5 Page 7 A

AREVA

A ANP-3102, Rev. 3 AREVA 5.0 TECHNICAL BASIS FOR PRESSURE/TEMPERATURE LIMITS Pressure-temperature limits are developed using an analytical approach that is in accordance with the requirements of the ASME Boiler and Pressure Vessel Code,Section XI, Appendix G [2]. Additional requirements are contained in Table 1 of Appendix G to Title 10, Code of Federal Regulations, Part 50 [1]. The analytical techniques used to calculate P-T limits are based on approved linear elastic fracture mechanics methodology described in topical report BAW-10046A [4]. The fundamental equation used to calculate the allowable pressure is Pallow KIR - Krr SFx ki where, Pallow = allowable pressure KI = reference stress intensity factor ( K a or K 1c Srr = thermal stress intensity factor I, = unit pressure stress intensity factor (due to 1 psig)

SF = safety factor For each analyzed transient and steady state condition, the allowable pressure is determined as a function of reactor coolant temperature considering postulated flaws in the reactor vessel beltline, inlet nozzle, outlet nozzle, and closure head. In the beltline region, flaws are postulated to be present at the 1/4t and 3/ 4 t locations of the controlling material (shell forging, or circumferential weld), as defined by the fluence adjusted RTNDT. The reactor vessel nozzle flaws are located at the inside juncture (comer) with the nozzle shell, and the closure head flaw is located near the outside juncture with the head flange. P-T limits for the beltline and nozzle regions are calculated using a safety factor of 2 for normal operation and 1.5 for ISLH operation. The P-T limit curves presented consist of the allowable pressures for the controlling beltline flaw, inlet and outlet nozzles, and closure head, as a function of fluid temperature. These curves have been "smoothed", as necessary, to eliminate irregularities associated with the startup of the first reactor coolant pump during heatup and the initiation of decay heat removal during cooldown. After the initial determination of the P-T limit curves, location specific curves were adjusted for sensor location. No instrument error correction has been applied. The final results include the determination of a minimum/lower bound P-T curve.

The criticality limit temperature is obtained by determining the maximum required ISLH test temperature at a pressure of 2500 psig (approximately 10% above the normal operating pressure). The ISLH analysis considers the most limiting heatup and cooldown transients. The approach satisfies the requirement of Item 2.d in Table 1 of 10 CFR 50, Appendix G [1]. It requires the minimum temperature to be the larger of minimum permissible temperature for inservice system hydrostatic pressure test or the RTNDT of the closure flange material + 160 OF.

Various aspects of the calculation procedures utilized in the development of P-T limits are discussed below.

Page 8 A AREVA

A ANP-3102, Rev. 3 AREVA 5.1 Fracture Toughness The fracture toughness of reactor vessel steels is expressed as a function of crack-tip temperature, T, indexed to the adjusted reference temperature of the material, RTNDT. Pressure-Temperature limits developed in accordance with ASME Code,Section XI, Appendix G, as permitted by RIS 2004-04 [7] , utilize the crack initiation fracture toughness, Kic = 33.2 + 2.806 exp [0.02 ( T - RTNDT + 100 'F)]

The upper shelf fracture toughness is limited to an upper bound value of 200 ksi'lin for the reactor vessel welds and base metal and 250 ksi x/in for the inlet and outlet nozzles. The crack-tip temperature needed for these fracture toughness equations is obtained from the results of a transient thermal analysis, described below.

5.2 Thermal Analysis and Thermal Stress Intensity Factor Through-wall temperature distributions are determined by solving the one-dimensional transient axisymmetric heat conduction equation, O

PCP" _ .c2T 1 aT.

P a Or2 r Or subject to the following boundary conditions:

at the inside surface, where r = Ri,

- k = h(Tw - Tb)

Or at the outside surface, where r = Ro, agr-0 where, p density CP = specific heat k = thermal conductivity T = temperature r= radial coordinate t= time h = convection heat transfer coefficient Page 9 A

AREVA

A ANP-3102, Rev. 3 AREVA Tw= wall temperature Tb = bulk coolant temperature R= inside radius of vessel Ro = outside radius of vessel The above equation is solved numerically using a finite difference technique to determine the temperature at 17 points through the wall as a function of time for prescribed changes in the bulk fluid temperature, such as multi-rate ramp and step changes for heatup and cooldown transients.

An equivalent linear thermal bending stresses (based on AT through the wall) is derived from the through-wall temperature distribution at each solution time point. Through-wall thermal stress distributions are determined by trapezoidal integration of the following expression:

Thermal hoop stresses:

o()=Ea I r2 + Ri2f'Tr&dr+fr TrdrTr2~ [8, Eqn (255)]

1- ý R' ,R Expressing the thermal stress distributions by cr(x) = Co + C, (x/a) + C2 (x/a) 2 + C3 (x/a) 3 ,

where, x= is a dummy variable that represents the radial distance from the appropriate (i.e., inside or outside) surface, in.

a= the flaw depth, in.

The thermal stress intensity factors are defined by the following relationships:

For a 1/4 t inside surface flaw during cooldown, Kit = (1.0359 Co + 0.6322 C, + 0.4753 C2 + 0.3855 C 3),r-a4 For a 1/4 t outside surface flaw during heatup, Kt= (1.043 Co + 0.630 CI + 0.481 C2 + 0.401 C3)O a 5.3 Unit Pressure Stress Intensity Factor for Reactor Vessel Beltline Region The membrane stress intensity factor in the reactor vessel shell due to a unit pressure load is Kjm = Mm x Ri/t where Ri = vessel inner radius, in.

Page 10 A

AREVA

AREVA ANP-3102, Rev. 3 t= vessel wall thickness, in.

For a longitudinal '/4 -thickness x 3 -thickness semi-elliptical surface flaw:

at the inside surface, Mm. 1.85 for 4t < 2 0.926 4t for 2 _<4t _< 3.464 3.21 for 4t > 3.464 at the outside surface, Mm = 1.77 for 4t < 2

= 0.893 4/t for 2 _<4It _<3.464

= 3.09 for 4t > 3.464 5.4 Unit Pressure Stress Intensity Factor for Reactor Vessel Nozzles Considering a nozzle as a hole in a shell, WRC Bulletin 175 [9] presents the following method for estimating stress intensity factors for a nozzle comer flaw:

Klm = o'r/-'i F(a/rn) where

(= Ri/t R= nozzle belt shell inner radius, in.

t = nozzle belt shell wall thickness, in.

a = flaw depth, in.

r,= apparent radius of nozzle, in.

= ri + 0.29rc r= inner radius of nozzle, in.

rc= nozzle comer radius, in.

and F(a/r,) = 2.5 - 6.108(a/rn) + 12(a/r,) 2 - 9.1664(a/r,)3 Page 11 A

AR EVA

A ANP-3102, Rev. 3 AREVA 6.0 PRESSURE CORRECTIONS The uncorrected P-T limits are calculated at the required locations or components in the RCS. However, the plant uses only two instruments locations for indicated pressure, the pressurizer low range tap and the hot leg wide range tap. Therefore, the uncorrected P-T limits may be corrected to one or both of these locations. These location corrections were calculated using a TMI-1 Cycle 19 RCS hydraulics model with 0% steam generator tube plugging, and analyzing it for various temperatures and pump combinations.

The location corrections are based on 0/0 pumps operating up to 100 OF (the conservative start temperature for the first two pumps) and then based on 2/0 pumps up to - 200 OF, and 2/1 pumps up to - 350 OF. The low range corrections (taken from the pressurizer) are conservatively estimated to be a constant 10 psi less than the wide range corrections (taken from the hot leg tap). Thus the limiting location corrections are from hot leg (wide range) tap and are applied to the P-T limits. The hot leg (wide range) tap pressure corrections are presented below in Table 5.

Table 5: Limiting Location Corrections Factors for Pressure Temperature 70-100 101-199 200-349 350-499 500-5321 Range, °F Component AP, psi RCP AP, psi RCP AP, psi RCP AP, psi RCP AP, psi RCP Beltline 22 (WR) 0/0 90 (WR) 2/0 104 (WR) 2/1 111 2/2 99 2/2 Outlet Nozzle 17 (WR) 0/0 74 (WR) 2/0 74 (WR) 2/0 67 2/0 51 2/1 RVCH 13 (WR) 0/0 70 (WR) N/A N/A N/A The correction factor was used for 601F as well, since the rounded correction factors are found to be bounding The correction factor is used for temperatures above 532°F since the values are bounding for higher temperature 7.0

SUMMARY

OF RESULTS The following is a summary of results for the TMI-l P-T limits at 50.2 EFPY with MUR analysis corrected for location only. No correction due to instrument uncertainty is applied.

Page 12 A

AREVA

AREVA ANP-3102, Rev. 3 7.1 P-T Curves for ISLH Heatup / Cooldown The Pressure-Temperature limits are developed for ISLH test operations. For ISLH heatup, adjusted location specific (i.e. on a per component basis) P-T limits are presented in Table 6. The Tech. Spec. basis P-T limits for ISLH heatup are shown in Table 8. The location adjusted P-T limits for ISLH ramp cooldown are presented in Table 9. The location adjusted P-T limits calculated for ISLH step cooldown are shown in Table 10. The Technical specification (Tech. Spec.) basis P-T limits for ISLH cooldown generated as the limiting allowable pressure at every calculated temperature is shown in Table 11. The adjusted P-T limits for ISLH heatup and cooldown are plotted in Figure 1. A limiting composite curve for Tech. Spec. Basis P-T limits for ISLH is developed, the pressure-temperature data is shown in Table 12 and the curve is plotted in Figure 2. The criticality I limit temperature corresponding to a pressure of 2500 psig can be determined through interpolation of ISLH heatup data in Table 6. As shown in Table 7, the criticality limit temperature is 262.7 'F. The criticality limit curve is shown in Figure 3 along with the normal heatup Tech. Spec. basis P-T limit curve.

Page 13 A AREVA

A ANP-3102, Rev. 3 AREVA Table 6: TMI-1 Adjusted Location Specific P-T Limits for ISLH Heatup Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi) 60 832 873 907 671 65 833 878 912 811 70 835 892 927 953 75 838 912 947 1095 80 841 934 971 1237 85 841 948 985 1435 90 850 991 1030 1633 95 857 1029 1069 1831 100 863 1071 1113 2029 105 802 1059 1102 2170 110 810 1108 1153 115 819 1162 1210 120 828 1222 1272 125 839 1289 1341 130 851 1363 1418 135 864 1444 1503 140 879 1534 1596 145 895 1634 1700 150 913 1744 1814 155 932 1866 1941 160 954 2001 2080 165 978 2149 2235 170 1005 2314 2405 175 1035 2495 2594 180 1067 2696 2802 185 1103 2918 3033 190 1143 3163 3287 195 1187 3433 3568 200 1222 3732 3878 205 1275 4050 4208 210 1335 4050 4208 215 1400 4050 4208 220 1473 4050 4208 225 1553 4050 4208 230 1642 4050 4208 235 1740 4050 4208 240 1848 4050 4208 245 1967 4050 4208 250 2099 4050 4208 255 2244 4050 4208 260 2405 4050 4208 Page 14 A

AREVA

A ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi (psi) 265 2582 4050 4208 270 2777 4050 4208 275 2993 4050 4208 280 3231 4050 4208 285 3494 4050 4208 290 3785 4050 4208 295 4106 4050 4208 300 4460 4050 4208 305 4788 4050 4208 310 4788 4050 4208 315 4788 4050 4208 320 4787 4050 4208 325 4787 4050 4208 330 4787 4050 4208 335 4786 4050 4208 340 4786 .4050 4208 345 4786 4050 4208 350 4778 4057 4215 355 4778 4057 4215 360 4777 4057 4215 365 4777 4057 4215 370 4776 4057 4215 375 4776 4057 4215 380 4775 4057 4215 385 4775 4057 4215 390 4774 4057 4215 395 4774 4057 4215 400 4773 4057 4215 405 4773 4057 4215 410 4772 4057 4215 415 4772 4057 4215 420 4771 4057 4215 425 4771 4057 4215 430 4771 4057 4215 435 4770 4057 4215 440 4770 4057 4215 445 4770 4057 4215 450 4770 4057 4215 455 4769 4057 4215 460 4769 4057 4215 465 4768 4057 4215 470 4768 4057 4215 475 4766 4057 4215 480 4766 4057 4215 485 4766 4057 4215 Page 15 A

ARE VA

A ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (4F) (psi) (psi) (psi) (psi) 490 4765 4057 4215 495 4765 4057 4215 500 4776 4073 4231 505 4776 4073 4231 510 4775 4073 4231 515 4775 4073 4231 520 4774 4073 4231 525 4773 4073 4231 530 4773 4073 4231 535 4772 4073 4231 540 4772 4073 4231 545 4772 4073 4231 550 4771 4073 4231 555 4771 4073 4231 560 4770 4073 4231 565 4769 4073 4231 570 4769 4073 4231 Table 7: TMI-1 Criticality Limit Temperature Determination Criticality Limit Temp. at 500 psig Pressure Temp.

(psig) (OF) 2405 260 2582 265 Interpolating:

2500 262.7 Page 16 A

AREVA

A ANP-3102, Rev. 3 AREVA Table 8: TMI-1 Tech. Spec. Basis P-T Limits for ISLH Heatup Governing Fluid Adjusted Temp. Pressure (OF)

(psi) 60 671 65 802 70 802 75 802 80 802 85 802 90 802 95 802 100 802 105 802 110 810 115 819 120 828 125 839 130 851 135 864 140 879 145 895 150 913 155 932 160 954 165 978 170 1005 175 1035 180 1067 185 1103 190 1143 195 1187 200 1222 205 1275 210 1335 215 1400 220 1473 225 1553 230 1642 235 1740 240 1848 245 1967 250 2099 255 2244 260 2405 Page 17 A

AREVA

A AREVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi) 265 2582 270 2777 275 2993 280 3231 285 3494 290 3785 295 4050 300 4050 305 4050 310 4050 315 4050 320 4050 325 4050 330 4050 335 4050 340 4050 345 4050 350 4057 355 4057 360 4057 365 4057 370 4057 375 4057 380 4057 385 4057 390 4057 395 4057 400 4057 405 4057 410 4057 415 4057 420 4057 425 4057 430 4057 435 4057 440 4057 445 4057 450 4057 455 4057 460 4057 465 4057 470 4057 475 4057 480 4057 485 4057 Page 18 A

AR EVA

A AREVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi) 490 4057 495 4057 500 4073 505 4073 510 4073 515 4073 520 4073 525 4073 530 4073 535 4073 540 4073 545 4073 550 4073 555 4073 560 4073 565 4073 570 4073 Page 19 A AREVA

A ANP-3102, Rev. 3 AREVA Table 9: TMI-1 Adjusted Location Specific P-T Limits for ISLH Ramp Cooldown Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi) 70 733 937 974 953 75 742 992 1031 1095 80 753 1041 1081 1237 85 765 1094 1137 1435 90 780 1154 1199 1633 95 786 1219 1267 1831 105 724 1295 1347 2170 110 727 1361 1416 115 743 1501 1562 120 759 1609 1674 125 776 1728 1798 130 795 1860 1935 135 816 2006 2086 140 840 2167 2254 145 866 2346 2439 150 894 2542 2643 155 926 2760 2869 160 961 3001 3119 165 999 3266 3395 170 1042 3560 3700 175 1089 3772 3919 180 1141 3761 3908 185 1199 3748 3895 190 1263 3733 3879 195 1334 3716 3862 200 1397 3696 3841 205 1469 3674 3818 210 1549 3646 3789 215 1638 3616 3757 220 1735 3581 3721 225 1844 3540 3679 230 1963 3492 3629 235 2066 3395 3528 240 2193 3462 3598 245 2402 3405 3538 250 2580 3342 3473 255 2777 3293 3423 260 2995 3295 3424 265 3235 3296 3426 270 3501 3298 3428 275 3795 3300 3430 Page 20 A

AR EVA

A ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting Outlet Inlet Closure Fluid Beitline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi) 280 4119 3302 3432 285 4308 3304 3434 290 4308 3307 3436 295 4307 3309 3439 300 4306 3312 3442 305 4306 3315 3445 310 4305 3318 3448 315 4305 3323 3454 320 4305 3326 3457 325 4304 3330 3461 330 4304 3334 3465 335 4304 3338 3469 340 4304 3342 3473 345 4304 3347 3478 350 4297 3358 3490 355 4298 3363 3495 360 4298 3369 3501 365 4298 3375 3507 370 4298 3378 3511 375 4299 3385 3518 380 4299 3392 3525 385 4300 3399 3533 390 4301 3407 3541 395 4302 3415 3549 400 4304 3424 3558 405 4304 3433 3568 410 4306 3442 3577 415 4308 3452 3588 420 4311 3463 3598 425 4314 3474 3610 430 4318 3485 3622 435 4322 3496 3633 440 4326 3509 3646 445 4331 3522 3660 450 4337 3536 3674 455 4343 3550 3689 460 4349 3565 3705 465 4356 3581 3721 470 4364 3597 3738 475 4373 3614 3756 480 4383 3632 3774 485 4393 3651 3793 490 4405 3670 3814 495 4418 3690 3834 500 4444 3727 3872 Page 21 A

ARE VA

A ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi) 505 4459 3749 3895 510 4476 3769 3916 515 4494 3793 3941 520 4513 3818 3966 525 4533 3843 3993 530 4556 3870 4020 535 4582 3897 4049 540 4609 3925 4077 545 4638 3953 4107 550 4670 3982 4137 555 4703 4010 4166 560 4738 4037 4194 565 4772 4060 4218 570 4793 4072 4231 Page 22 A

AR EVA

A ANP-3102, Rev. 3 AREVA Table 10: TMI-1 Adjusted Location Specific P-T Limits for ISLH Step Cooldown Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (F) (psi) (psi) (psi) (psi) 70 766 910 945 953 80 781 1038 1078 1237 85 788 1094 1137 1435 100 813 1292 1342 2029 105 757 1324 1377 2170 115 780 1501 1562 130 828 1860 1935 145 893 2346 2439 160 980 3001 3119 175 1098 3811 3960 190 1258 3772 3920 205 1464 3712 3858 220 1735 3619 3761 235 2050 3435 3570 240 2241 3501 3638 255 2777 3314 3444 270 3501 3318 3448 285 4347 3323 3454 300 4345 3330 3461 315 4343 3338 3470 330 4343 3351 3482 345 4342 3362 3495 360 4336 3383 3516 375 4336 3398 3531 390 4337 3418 3552 405 4341 3442 3577 420 4345 3470 3606 435 4353 3502 3639 450 4366 3538 3676 465 4382 3580 3720 480 4405 3628 3770 495 4436 3682 3826 510 4487 3759 3906 525 4539 3827 3976 540 4605 3905 4057 555 4690 3989 4144 Page 23 A

AREVA

A AREVA ANP-3102, Rev. 3 Table 11: TMI-1 Tech Spec. Basis P-T Limits for ISLH Cooldown Governing Fluid Adjusted Temp. Pressure (OF) (psi) 70 724 75 724 80 724 85 724 90 724 95 724 105 724 110 727 115 743 120 759 125 776 130 795 135 816 140 840 145 866 150 894 155 926 160 961 165 999 170 1042 175 1089 180 1141 185 1199 190 1258 195 1334 200 1397 205 1464 210 1549 215 1638 220 1735 225 1844 230 1963 235 2050 240 2193 245 2402 250 2580 255 2777 260 2995 265 3235 270 3298 275 3300 280 3302 285 3304 Page 24 A AREVA

AR ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi) 290 3307 295 3309 300 3312 305 3315 310 3318 315 3323 320 3326 325 3330 330 3334 335 3338 340 3342 345 3347 350 3358 355 3363 360 3369 365 3375 370 3378 375 3385 380 3392 385 3399 390 3407 395 3415 400 3424 405 3433 410 3442 415 3452 420 3463 425 3474 430 3485 435 3496 440 3509 445 3522 450 3536 455 3550 460 3565 465 3580 470 3597 475 3614 480 3628 485 3651 490 3670 495 3682 500 3727 505 3749 510 3759 Page 25 A

A R EVA

A ANP-3102, Rev. 3 AREVA Governing Fluid Adjusted Temp. Pressure (OF) (psi) 515 3793 520 3818 525 3827 530 3870 535 3897 540 3905 545 3953 550 3982 555 3989 560 4037 565 4060 570 4072 Page 26 A

AR EVA

A ANP-3102, Rev. 3 AREVA Table 12: TMI-1 Tech Spec. Basis P-T Limits for ISLH Composite Curve Goveming Fluid Adjusted Temp. Pressure

('F) (psi) 60 671 65 724 70 724 75 724 80 724 85 724 90 724 95 724 100 724 105 724 110 727 115 743 120 759 125 776 130 795 135 816 140 840 145 866 150 894 155 926 160 954 165 978 170 1005 175 1035 180 1067 185 1103 190 1143 195 1187 200 1222 205 1275 210 1335 215 1400 220 1473 225 1553 230 1642 235 1740 240 1848 245 1967 250 2099 255 2244 260 2405 265 2582 Page 27 A

AREVA

A AREVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi) 270 2777 275 2993 280 3231 285 3304 290 3307 295 3309 300 3312 305 3315 310 3318 315 3323 320 3326 325 3330 330 3334 335 3338 340 3342 345 3347 350 3358 355 3363 360 3369 365 3375 370 3378 375 3385 380 3392 385 3399 390 3407 395 3415 400 3424 405 3433 410 3442 415 3452 420 3463 425 3474 430 3485 435 3496 440 3509 445 3522 450 3536 455 3550 460 3565 465 3580 470 3597 475 3614 480 3628 485 3651 490 3670 495 3682 Page 28 A

A R EVA

A AREVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi) 500 3727 505 3749 510 3759 515 3793 520 3818 525 3827 530 3870 535 3897 540 3905 545 3953 550 3982 555 3989 560 4037 565 4060 570 4072 Page 29 A

AR EVA

A ANP-3102, Rev. 3 AREVA Figure 1: TMI-1 Adjusted P-T Limits for ISLH Heatup and Cooldown 2400 2200 2000

.2- 1800 U'

G1600 (A1400 U)

I- 1200 1000 S800 4OO 46000 100 200 0

0 50 100 150 200 250 300 350 400 450 500 Indicated RCS Inlet Temperature, OF Page 30 A

AREVA

A ANP-3102, Rev. 3 AREVA Figure 2: TMI-1 Tech. Spec. Basis P-T Limits for ISLH (Composite Curve) 2400 2200 2000

.- 1800 G

0.

01600 01400 ID.

a.

U) 1200 1000 j 800 600 400 200 0

0 50 100 150 200 250 300 350 400 450 500 Indicated RCS InletTemperature, IF Page 31 A

AREVA

A ANP-3102, Rev. 3 AREVA 7.2 P-T Curves for Normal Heatup / Cooldown The Pressure-Temperature limits are developed for both normal heatup and cooldown operations. For heatup, location specific adjusted P-T limits are presented in Table 13. The Tech. Spec. basis P-T limits for normal heatup are shown in Table 14. The location specific adjusted P-T limits for ramp cooldown are presented in Table 15. The location adjusted P-T limits calculated for normal step cooldown are shown Table 16. The Technical specification (Tech. Spec.) basis P-T limits for cooldown generated as the limiting pressure at every calculated temperature is shown in Table 17. The Tech. Spec. basis P-T limits for heatup are plotted in Figure 3 and the Tech. Spec. basis cooldown P-T limits are plotted in Figure 4.

Page 32 A

AR EVA

A ANP-3102, Rev. 3 AREVA Table 13: TMI-1 Adjusted Location Specific P-T Limits for Normal Heatup Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi) 60 618 650 676 612 65 619 654 680 612 70 621 665 691 612 75 623 679 706 612 80 626 696 724 612 85 629 716 744 761 90 632 738 767 910 90 632 738 767 910 90 632 739 768 910 95 637 768 798 1058 100 642 799 830 1207 101 575 749 780 1180 105 579 776 808 1360 110 585 813 847 1585 115 592 853 889 1810 120 599 898 936 2035 123 604 928 967 2170 125 607 948 988 130 616 1004 1045 135 626 1065 1108 140 637 1132 1179 145 649 1207 1256 150 662 1290 1342 155 677 1381 1437 160 693 1482 1542 165 711 1593 1658 170 731 1717 1786 175 753 1853 1927 180 778 2003 2083 185 805 2170 2256 190 835 2353 2447 195 868 2556 2657 200 890 2780 2890 205 931 3019 3138 210 975 3019 3138 215 1024 3019 3138 220 1079 3019 3138 225 1139 3019 3138 230 1205 3019 3138 235 1279 3019 3138 240 1360 3019 3138 Page 33 A

AREVA

A ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi) 245 1449 3019 3138 250 1548 3019 3138 255 1657 3019 3138 260 1777 3019 3138 265 1910 3019 3138 270 2057 3019 3138 275 2219 3019 3138 280 2398 3019 3138 285 2595 3019 3138 290. 2813 3019 3138 295 3053 3019 3138 300 3319 3019 3138 305 3565 3019 3138 310 3565 3019 3138 315 3565 3019 3138 320 3564 3019 3138 325 3564 3019 3138 330 3564 3019 3138 335 3564 3019 3138 340 3563 3019 3138 345 3563 3019 3138 350 3556 3026 3145 355 3556 3026 3145 360 3555 3026 3145 365 3555 3026 3145 370 3555 3026 3145 375 3554 3026 3145 380 3554 3026 3145 385 3553 3026 3145 390 3553 3026 3145 395 3553 3026 3145 400 3552 3026 3145 405 3552 3026 3145 410 3551 3026 3145 415 3551 3026 3145 420 3551 3026 3145 425 3551 3026 3145 430 3550 3026 3145 435 3550 3026 3145 440 3550 3026 3145 445 3550 3026 3145 450 3549 3026 3145 455 3549 3026 3145 460 3549 3026 3145 465 3548 3026 3145 Page 34 A AREVA

A ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi) 470 3548 3026 3145 475 3547 3026 3145 480 3547 3026 3145 485 3546 3026 3145 490 3546 3026 3145 495 3546 3026 3145 500 3558 3042 3161 505 3557 3042 3161 510 3557 3042 3161 515 3556 3042 3161 520 3556 3042 3161 525 3555 3042 3161 530 3555 3042 3161 535 3555 3042 3161 540 3554 3042 3161 545 3554 3042 3161 550 3554 3042 3161 555 3553 3042 3161 560 3553 3042 3161 565 3552 3042 3161 570 3552 3042 3161 Page 35 A

AREVA

AREVA ANP-3102, Rev. 3 Table 14: TMI-1 Tech. Spec. Basis P-T Limits for Normal Heatup Governing Fluid Adjusted Temp. Pressure (OF) (psi) 60 575 65 575 70 575 75 575 80 575 85 575 90 575 90 575 90 575 95 575 100 575 101 575 105 579 110 585 115 592 120 599 123 604 125 607 130 616 135 626 140 637 145 649 150 662 155 677 160 693 165 711 170 731 175 753 180 778 185 805 190 835 195 868 200 890 205 931 210 975 215 1024 220 1079 225 1139 230 1205 235 1279 240 1360 245 1449 250 1548 Page 36 A AR EVA

A AREVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi) 255 1657 260 1777 265 1910 270 2057 275 2219 280 2398 285 2595 290 2813 295 3019 300 3019 305 3019 310 3019 315 3019 320 3019 325 3019 330 3019 335 3019 340 3019 345 3019 350 3026 355 3026 360 3026 365 3026 370 3026 375 3026 380 3026 385 3026 390 3026 395 3026 400 3026 405 3026 410 3026 415 3026 420 3026 425 3026 430 3026 435 3026 440 3026 445 3026 450 3026 455 3026 460 3026 465 3026 470 3026 475 3026 Page 37 A

AR EVA

A AREVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure (OF) (psi) 480 3026 485 3026 490 3026 495 3026 500 3042 505 3042 510 3042 515 3042 520 3042 525 3042 530 3042 535 3042 540 3042 545 3042 550 3042 555 3042 560 3042 Page 38 A

A R EVA

A ANP-3102, Rev. 3 AREVA Table 15: TMI-1 Adjusted Location Specific P-T Limits for Normal Ramp Cooldown Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi) 70 545 699 726 612 75 551 740 769 612 80 559 776 807 612 85 568 817 849 761 90 579 861 895 910 95 584 910 946 1058 101 519 913 951 1180 110 523 1002 1044 1585 115 535 1107 1153 1810 120 547 1188 1237 2035 123 555 1242 1293 2170 125 560 1278 1330 130 574 1377 1433 135 590 1486 1546 140 607 1607 1672 145 627 1741 1810 150 648 1888 1964 155 672 2052 2133 160 698 2232 2321 165 727 2431 2528 170 759 2652 2756 175 794 2810 2921 180 834 2802 2912 185 877 2792 2902 190 925 2781 2891 195 978 2768 2878 200 1022 2754 2862 205 1076 2737 2845 210 1136 2716 2823 215 1202 2693 2799 220 1276 2667 2772 225 1357 2636 2741 230 1446 2600 2703 235 1524 2527 2627 240 1619 2578 2680 245 1775 2535 2635 250 1909 2488 2586 255 2057 2451 2548 260 2220 2453 2550 265 2400 2454 2551 270 2600 2455 2552 275 2820 2456 2554 280 3063 2458 2555 Page 39 A

AREVA

A ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi) 285 3205 2460 2557 290 3205 2461 2559 295 3204 2463 2561 300 3204 2465 2563 305 3203 2468 2565 310 3203 2470 2568 315 3203 2474 2572 320 3202 2476 2574 325 3202 2479 2577 330 3202 2482 2580 335 3202 2485 2583 340 3202 2488 2586 345 3202 2491 2590 350 3195 2502 2601 355 3196 2506 2605 360 3196 2510 2609 365 3196 2514 2613 370 3196 2517 2616 375 3196 2522 2621 380 3197 2527 2627 385 3197 2533 2633 390 3198 2539 2639 395 3199 2545 2645 400 3200 2551 2652 405 3200 2558 2659 410 3202 2565 2666 415 3203 2573 2674 420 3205 2580 2682 425 3208 2589 2691 430 3210 2597 2699 435 3214 2606 2708 440 3217 2615 2718 445 3221 2625 2728 450 3225 2635 2739 455 3229 2646 2750 460 3234 2657 2762 465 3239 2669 2774 470 3245 2681 2787 475 3252 2694 2800 480 3259 2707 2814 485 3267 2721 2828 490 3276 2736 2843 495 3286 2751 2859 500 3308 2783 2891 505 3320 2799 2908 Page 40 A

AREVA

A ANP-3102, Rev. 3 AREVA Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (OF) (psi) (psi) (psi) (psi) 510 3332 2814 2924 515 3346 2832 2943 520 3360 2850 2962 525 3375 2870 2982 530 3392 2889 3002 535 3411 2910 3024 540 3432 2931 3045 545 3454 2952 3067 550 3478 2973 3090 555 3503 2995 3112 560 3529 3015 3133 565 3554 3032 3151 Page 41 A

AREVA

A ANP-3102, Rev. 3 AREVA Table 16: TMI-1 Adjusted Location Specific P-T Limits for Normal Step Cooldown Allowable Pressures Limiting Outlet Inlet Closure Fluid Beltline Nozzle Nozzle Head Temp. Weld (F) (psi) (psi) (psi) (psi) 70 569 678 705 612 80 580 774 804 612 85 586 817 849 761 100 604 965 1002 1207 101 538 921 959 1180 115 562 1107 1153 1810 123 581 1251 1302 2170 130 598 1377 1433 145 647 1741 1810 160 713 2232 2321 175 801 2839 2951 190 921 2811 2921 205 1072 2766 2875 220 1276 2696 2802 235 1511 2558 2659 240 1655 2607 2710 255 2057 2467 2564 270 2600 2470 2568 285 3234 2474 2572 300 3232 2479 2577 315 3231 2485 2584 330 3231 2495 2593 345 3231 2503 2602 360 3224 2521 2620 375 3224 2531 2631 390 3225 2547 2647 405 3228 2565 2666 420 3231 2586 2687 435 3237 2609 2712 450 3247 2637 2740 465 3259 2668 2773 480 3276 2704 2810 495 3299 2745 2853 510 3341 2807 2917 525 3380 2858 2969 540 3429 2916 3030 555 3493 2979 3096 Page 42 A

AR E VA

A ANP-3102, Rev. 3 AREVA Table 17: Tech Spec. Basis P-T Limits for Normal Limiting Cooldown Governing Fluid Adjusted Temp. Pressure (OF) (psi) 70 519 75 519 80 519 85 519 90 519 95 519 101 519 110 523 115 535 120 547 123 555 125 560 130 574 135 590 140 607 145 627 150 648 155 672 160 698 165 727 170 759 175 794 180 834 185 877 190 921 195 978 200 1022 205 1072 210 1136 215 1202 220 1276 225 1357 230 1446 235 1511 240 1619 245 1775 250 1909 255 2057 260 2220 265 2400 270 2455 Page 43 A

AREVA

AREVA ANP-3102, Rev. 3 Governing Fluid Adjusted Temp. Pressure

('F) (psi) 275 2456 280 2458 285 2460 290 2461 295 2463 300 2465 305 2468 310 2470 315 2474 320 2476 325 2479 330 2482 335 2485 340 2488 345 2491 350 2502 355 2506 360 2510 365 2514 370 2517 375 2522 380 2527 385 2533 390 2539 395 2545 400 2551 405 2558 410 2565 415 2573 420 2580 425 2589 430 2597 435 2606 440 2615 445 2625 450 2635 455 2646 460 2657 465 2668 470 2681 475 2694 480 2704 485 2721 490 2736 495 2745 Page 44 A

"AR EVA

A ANP-3102, Rev. 3 ARIEVA Governing Fluid Adjusted Temp. Pressure (OF) (psi) 500 2783 505 2799 510 2807 515 2832 520 2850 525 2858 530 2889 535 2910 540 2916 545 2952 550 2973 555 2979 560 3015 565 3032 Page 45 A

AR EVA

A ANP-3102, Rev. 3 AREVA Figure 3: TMI-1 Tech. Spec. Basis P-T Limits for Normal Heatup and Criticality Limit 2400 2200 2000 -P-T Limits for Normal Heatup 1800 -Criticality Limit P-T Limit Curve 0.

)1600 (A 1400 I.

r/)A14000 1200 U

o)

S800 600 400 200 0

0 50 100 150 200 250 300 350 400 450 500 Indicated RCS InletTemperature, OF Page 46 A

AREVA

A AREVA ANP-3102, Rev. 3 Figure 4: TMI-1 Tech. Spec. Basis P-T Limits for Normal Cooldown 2400 2200 2000

.01800 0.

a1600 U) 1400 S1200

.2 800

- 600 400 200 0

0 50 100 150 200 250 300 350 400 450 500 Indicated RCS Inlet Temperature, OF Page 47 A

AREVA

A AREVA ANP-3102, Rev. 3 8.0

SUMMARY

The Tech. Spec. basis P-T limits for normal operating heatup and cooldown and ISLH operation were reported in the previous section for TMI-1 at 50.2 EFPY with MUR. This section provides summary P-T curves for heatup, cooldown, and ISLH with some key points (P-T limits) indicated on the plot.

Figure 5 shows a summary of the TMI-1 Tech. Spec. basis P-T Limits for normal heatup and criticality limit with some key points noted on the plot. Figure 6 shows a summary of the TMI-1 Tech. Spec. basis P-T Limits for normal cooldown with some key points noted on the plot. Figure 7 shows a summary of TMI-1 Tech. Spec. Basis P-T Limits for ISLH (Composite Curve).

Page 48 A

AREVA

A ANP-3102, Rev. 3 AREVA Figure 5: TMI-1 Summary Tech Spec. Basis P-T Limits at 50.2 EFPY with MUR for Normal Heatup and Criticality Limit 2400 2200 2000 1800 0.

01600 W 1400 2!

0.

(/1200 U

-o 1000 u 800 600 400 200 0

0 50 100 150 200 250 300 350 400 450 500 Indicated RCS InletTemperature,OF Page 49 A

AREVA

A AREVA ANP-3102, Rev. 3 Figure 6: TMI-1 Summary Tech. Spec. Basis P-T Limits at 50.2 EFPY with MUR for Normal Cooldown 2400 T265, 2400

... - In 2200 2000 250, 1909 1800 1600 240, 1619- -____

U31400 CL i-a- 220, 1276 W 1200 1000

/1 90, 921 u 800

________16069 600 70, 519 13 3 ý 130 '574 400 101. 519 ____ ____ ____

200 0

0 50 100 150 200 250 300 350 400 450 500 Indicated RCS Inlet Temperature, OF Page 50 A

AREVA

A AREVA ANP-3102, Rev. 3 Figure 7: TMI-1 Summary Tech. Spec. Basis P-T Limits at 50.2 EFPY with MUR for ISLH (Composite Curve) 2400 2200 2000 1800 eL

  • 1600 Wfl 1400 h.

(L W* 1200 a) 1000 o 800 600 400 200 0

0 50 100 150 200 250 300 350 400 450 500 Indicated RCS Inlet Temperature, OF Page 51 A

AREVA

A AREVA ANP-3102, Rev. 3 9.0 CERTIFICA71ON Pressure/temperature limits for the TMI-1 reactor vessel have been calculated to satisfy the requirements of 10 CFR Part 50, Appendix 0 using analytical methods and acceptance criteria of the ASME Boiler and Pressure Vessel Code,Section XI, Appendix G,1995 Edition.

Samer -L.Malmioud, Principal Engineer Date '

Component Analysis and Fracture Mechanics This report has been reviewed for technical content and accuracy.

Ashok D. Nana, Supervisor Date Component Analysis and Fracture Mechanics Verification of independent review.

c6rPl-'Wirr lkýtw ,I--,

Tim M. W'iger, Manager I Date Component Analysis and Fracture Mechanics This report is approved for release David Skulna, Project Manager Date Page 52 A

AREVA

A AREVA ANP-3102, Rev. 3

10.0 REFERENCES

1. Code of Federal Regulations, Title 10, Part 50 - Domestic Licensing of Production and Utilization Facilities, Appendix G - Fracture Toughness Requirements, Federal Register Vol. 60. No. 243, December 19, 1995.
2. American Society of Mechanical Engineers (ASME) Boiler and Pressure Vessel Code,Section XI, "Rules for Inservice Inspection of Nuclear Power Plant Components," Appendix G, Fracture Toughness Criteria for Protection Against Failure, 1995 Edition with Addenda through 1996.
3. ASTM Standard E 208-81, "Standard Method for Conducting Drop-Weight Test to Determine Nil-Ductility Transition Temperature of Ferritic Steels," American Society for Testing and Materials, Philadelphia, Pennsylvania.
4. AREVA NP Document BAW-10046A, Rev. 2, "Methods of Compliance with Fracture Toughness and Operational Requirements of 10CFR50, Appendix G," by H. W. Behnke et al., June 1986.
5. AREVA NP Document BAW-2308, Rev. IA and Rev. 2A, "Initial RTNDT of LINDE 80 Weld Materials,"

by K. K. Yoon., August 2005 and March 2008.

6. ASME Boiler and Pressure Vessel Code,Section III, Rules for Construction of Nuclear Power Plant Components, Division 1 - Appendices, 1995 Edition with Addenda through the 1996 Edition.
7. NRC Regulatory Issue Summary 2004-04: Use of Code Cases N-588, N-640, and N-641 in developing Pressure-Temperature Operating Limits, Dated April 5, 2004.
8. Timoshenko, S.P., and Goodier, J.N., Theory of Elasticity, Third Edition, McGraw-Hill Book Company, 1970.
9. PVRC Ad Hoc Group on Toughness Requirements, "PVRC Recommendations on Toughness Requirements for Ferritic Materials," Bulletin No. 175, Welding Research Council, August 1972.
10. U. S. Nuclear Regulatory Commission, "RadiationEmbrittlement of Reactor Vessel Materials,"

Regulatory Guide 1.99, Revision 2, May 1988.

Page 53 A

AR EVA