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LIST OF FIGURES NUMBER PAGE | |||
LIST OF FIGURES | |||
NUMBER PAGE | |||
: 1. Pilgrim BOC-4 12 | : 1. Pilgrim BOC-4 12 | ||
: 2. Pilgrim BOC-5 18 | : 2. Pilgrim BOC-5 18 | ||
: 3. Reactivity Loss Per Cell Removed Versus 22 | : 3. Reactivity Loss Per Cell Removed Versus 22 Distance from the Core Center v e A | ||
Distance from the Core Center | |||
v e A | |||
A v | A v | ||
) | ) | ||
1542 119 2 | 1542 119 2 | ||
2 (iv) | 2 (iv) | ||
LIST OF TABLES NUMBER PAGE | LIST OF TABLES NUMBER PAGE | ||
: 1. CASMO Criticality Calculations for Uniform Water Moderated Lattices 6 2 2. Critical State 1 7 | : 1. CASMO Criticality Calculations for Uniform Water Moderated Lattices 6 2 2. Critical State 1 7 | ||
Line 70: | Line 52: | ||
: 5. Crftical State 4 10 | : 5. Crftical State 4 10 | ||
: 6. Critical State 5 11 | : 6. Critical State 5 11 | ||
: 7. Cross Section Sets Generated by CASMO for 13 | : 7. Cross Section Sets Generated by CASMO for 13 Critical State 1 | ||
Critical State 1 | |||
_' 8. Results of the Benchmark Calculations 16 | _' 8. Results of the Benchmark Calculations 16 | ||
: 9. Cross Section Sets for Multiple Controlled Cell 20 | : 9. Cross Section Sets for Multiple Controlled Cell 20 Removal Analysis | ||
Removal Analysis | |||
: 10. Multiple Controlled Cell Removal BOC-5 Results 21 | : 10. Multiple Controlled Cell Removal BOC-5 Results 21 | ||
: 11. Multiple Controlled Cell Removal B0C-5 Fresh 24 Assemblies Without Gd | : 11. Multiple Controlled Cell Removal B0C-5 Fresh 24 Assemblies Without Gd | ||
: 12. Multiple Controlled Cell Removal Ficticious Cycle 26 With Presh P8DR3282 Fuel No Gd j 13. Multiple Controlled Cell Removal Fresh Core of P8DRB282 27 | : 12. Multiple Controlled Cell Removal Ficticious Cycle 26 With Presh P8DR3282 Fuel No Gd j 13. Multiple Controlled Cell Removal Fresh Core of P8DRB282 27 With One Highly Burned 8DB219L | ||
: 14. Water Cross Section Parametric Study 30 1542 120 (v) l | |||
With One Highly Burned 8DB219L | |||
: 14. Water Cross Section Parametric Study 30 1542 120 (v) | |||
l | |||
PILGRIM 1 MULTIPLE CONTROLLED CELL REMOVAL 1.0 Introduction s The Technical Specifications for Pilgrim Nuclear Power Station - Unit #1 prohibit withdrawal of more than one control rod when the mode switch is in the " refuel" position. The reason for this restriction in, to preclude in-advertent criticality. Certain refueling maintenance activities such as replacement of control rods or control rod drive mechanisms can be done in less time and potentially with lower personnel radiation exposure, if more than one control rod can be withdrawn at a time. This study was undertaken - | |||
j by Boston Edison to demonstrate that multiple control rods can be removed from the core without violating the shutdown margin requirements as long as the adjacent fuel in the cell is removed prior to the control rod removal. | |||
PILGRIM 1 MULTIPLE CONTROLLED CELL REMOVAL 1.0 Introduction s The Technical Specifications for Pilgrim Nuclear Power Station - Unit #1 prohibit withdrawal of more than one control rod when the mode switch is in | |||
the " refuel" position. The reason for this restriction in, to preclude in-advertent criticality. Certain refueling maintenance activities such as replacement of control rods or control rod drive mechanisms can be done in less time and potentially with lower personnel radiation exposure, if more than one control rod can be withdrawn at a time. This study was undertaken - | |||
j by Boston Edison to demonstrate that multiple control rods can be removed from the core without violating the shutdown margin requirements as long | |||
as the adjacent fuel in the cell is removed prior to the control rod removal. | |||
The purpose of this report is to present the method and results 2 | The purpose of this report is to present the method and results 2 | ||
pertinent to multiple controlled cell removal for Pilgrim 1. From the reactor physics standpoint the removal of a controlled cell (four fuel assemblies plus control rod) affects the reactor state because of the following: | pertinent to multiple controlled cell removal for Pilgrim 1. From the reactor physics standpoint the removal of a controlled cell (four fuel assemblies plus control rod) affects the reactor state because of the following: | ||
: a. The removal of fuel t | : a. The removal of fuel t | ||
: b. The removal of the control blade | : b. The removal of the control blade | ||
- c. The creation of a water filled gap which acts as a flux trap. | - c. The creation of a water filled gap which acts as a flux trap. | ||
Although the final reactor state following the removal of a controlled cell will be determined by the reactivity contributions made by each of the effects listed above, the individual reactivity contributions will not be determined, only the total reactivity contribution will. The present aralysis will show | Although the final reactor state following the removal of a controlled cell will be determined by the reactivity contributions made by each of the effects listed above, the individual reactivity contributions will not be determined, only the total reactivity contribution will. The present aralysis will show that at any cycle of Pilgrim 1 all reactivity contributions from multiple 1542 121 | ||
that at any cycle of Pilgrim 1 all reactivity contributions from multiple | |||
1542 121 | |||
_T | _T | ||
controlled cell removal lead to a more suberitical state, and consequently increase the shutdown margin of the core. | controlled cell removal lead to a more suberitical state, and consequently increase the shutdown margin of the core. | ||
This analysis consists of two sections, the benchmark section and the multiple controlled cell removal section. The benchmark section is intended to show that the method and the computer programs used reproduce accurately critical states of Pilgrim 1. This provides the necessary confidence in the method and computer programs so that the multiple controlled cell re-moval analysis can be performed. The multiple controlled cell removal analysis uses the same method and computer programs, in order to show that | This analysis consists of two sections, the benchmark section and the multiple controlled cell removal section. The benchmark section is intended to show that the method and the computer programs used reproduce accurately critical states of Pilgrim 1. This provides the necessary confidence in the method and computer programs so that the multiple controlled cell re-moval analysis can be performed. The multiple controlled cell removal analysis uses the same method and computer programs, in order to show that multiple controlled cell removal always results in a more suberitical state. _ | ||
multiple controlled cell removal always results in a more suberitical state. _ | |||
n h | n h | ||
i l | i l | ||
; 1542 122 i | ; 1542 122 i | ||
l | l | ||
[ l I | [ l I | ||
.._.-_7--....-..... . . . . | .._.-_7--....-..... . . . . | ||
2.0 Method The method used in this study has been based on Pilgrim 1 nuclear design parameters and cycle data such as assembly types, assembly layout, and assem-blywise average exposure distribution. In addition, it utilizes the computer programs GAPCON-Thermal 2 1 ,CASM0 2 , ppq3 . Among the computer programs, GAPCON-Thermal 2 is a fuel performance code and has been used to calculate the fuel temperature which is an input parameter to CASMO. CASMO is a lattice code capable of performing physics calculations for boiling and pressurized water reactors, in pin cell or assembly geometry. This code has the capability of performing controlled and uncontrolled fuel depletions at any void and can _ | |||
2.0 Method | |||
The method used in this study has been based on Pilgrim 1 nuclear design | |||
parameters and cycle data such as assembly types, assembly layout, and assem-blywise average exposure distribution. In addition, it utilizes the computer programs GAPCON-Thermal 2 1 ,CASM0 2 , ppq3 . Among the computer programs, GAPCON-Thermal 2 is a fuel performance code and has been used to calculate the fuel temperature which is an input parameter to CASMO. CASMO is a lattice code capable of performing physics calculations for boiling and pressurized water reactors, in pin cell or assembly geometry. This code has the capability of performing controlled and uncontrolled fuel depletions at any void and can _ | |||
handle fuel rods with gadolinia. CASMO has been used to calculate macroscopic | handle fuel rods with gadolinia. CASMO has been used to calculate macroscopic | ||
/ | / | ||
cross sections which are input to PDQ. PDQ is a fine mesh nuclear simulator | cross sections which are input to PDQ. PDQ is a fine mesh nuclear simulator capable of performing diffusion theory calculations. | ||
capable of performing diffusion theory calculations. | |||
Based on the Pilgrim 1 nuclear design parameters and cycle data the method proceeds as follows: | Based on the Pilgrim 1 nuclear design parameters and cycle data the method proceeds as follows: | ||
: a. CAPCON-Thermal 2 is set up to calculate the fuel temperature at full power conditions. This fuel temperature is a necessary input to CASMO when full power calculations need to be performed. | : a. CAPCON-Thermal 2 is set up to calculate the fuel temperature at full power conditions. This fuel temperature is a necessary input to CASMO when full power calculations need to be performed. | ||
: b. For each assembly type a CASMO is set up in assembly geometry. For | : b. For each assembly type a CASMO is set up in assembly geometry. For assemblies with zero exposure a beginning of cycle CASMO calculation is performed at the proper conditions. For assemblies with different than zero exposure,CASMO is set up and depleted uncontrolled at full h power and average void conditions. The restart file is saved at the required exposure points and then a CASMO restart calculation is per-formed by attaching the required restart file and performing the necessary restart calculations at the proper conditions such as, zero power, cold (680F), controlled, no equilibrium xenon, etc. From each | ||
assemblies with zero exposure a beginning of cycle CASMO calculation is performed at the proper conditions. For assemblies with different than zero exposure,CASMO is set up and depleted uncontrolled at full h power and average void conditions. The restart file is saved at the required exposure points and then a CASMO restart calculation is per-formed by attaching the required restart file and performing the necessary restart calculations at the proper conditions such as, zero power, cold (680F), controlled, no equilibrium xenon, etc. From each | |||
CASMO calculation two group average macroscopic cross sections are calculated. The two group macroscopic cross sections are calculated in CASMO by flux and volume weighting the macroscopic cross sections of all fuel, fuel with gadolinia, water rod, channel, wide and narrow water gaps and the control blade (if present). For a given cycle the j assemblies of the same type are gathered into groups of approximately equal exposure. For each group the average exposure is calculated and controlled or uncontrolled cross sections sets are calculated with CASMO at the average exposure. These sets of cross sections are input to PDQ and are assigned respectively to controlled or uncontrolled assemblies - | |||
CASMO calculation two group average macroscopic cross sections are | |||
calculated. The two group macroscopic cross sections are calculated in CASMO by flux and volume weighting the macroscopic cross sections of all fuel, fuel with gadolinia, water rod, channel, wide and narrow water gaps and the control blade (if present). For a given cycle the j assemblies of the same type are gathered into groups of approximately equal exposure. For each group the average exposure is calculated and controlled or uncontrolled cross sections sets are calculated with CASMO at the average exposure. These sets of cross sections are input to PDQ and are assigned respectively to controlled or uncontrolled assemblies - | |||
in the group. | in the group. | ||
: c. For each cycle a quarter core or, if necessary, a full core PDQ is set | : c. For each cycle a quarter core or, if necessary, a full core PDQ is set up in two energy groups. Each assembly with its wide and narrow water gaps is homogenized in PDQ and is represented with an 8 x 8 plannar region. The quarter core geometry consists of 120 x 120 mesh grid and a | ||
up in two energy groups. Each assembly with its wide and narrow water gaps is homogenized in PDQ and is represented with an 8 x 8 plannar region. The quarter core geometry consists of 120 x 120 mesh grid and a | |||
the full core geometry consists of 240 x 240 grid with 1.905 cm mesh size. A controlled cell in PDQ consists of four plannar regions which are assigned controlled cross sections. The removal of a controlled cell is simulated by assigning water cross sections to its four plannar | the full core geometry consists of 240 x 240 grid with 1.905 cm mesh size. A controlled cell in PDQ consists of four plannar regions which are assigned controlled cross sections. The removal of a controlled cell is simulated by assigning water cross sections to its four plannar | ||
/ | / | ||
Line 164: | Line 96: | ||
1542 124 | 1542 124 | ||
^ | ^ | ||
3.0 Benchmark Calculations The intent of this section is to provide confidence in the programs and the method used in the analysis. The first part of the benchmark cal-culations consist of pin cell CASMO criticality calculations and the second consists of CASMO-PDQ calculations at the beginning of Pilgrim 1 cycle 4. | |||
3.0 Benchmark Calculations The intent of this section is to provide confidence in the programs | 3.1 CASMO Criticality Calculations A number of CASMO criticality calculations for unif rm moderated | ||
and the method used in the analysis. The first part of the benchmark cal-culations consist of pin cell CASMO criticality calculations and the second consists of CASMO-PDQ calculations at the beginning of Pilgrim 1 cycle 4. | |||
3.1 CASMO Criticality Calculations | |||
A number of CASMO criticality calculations for unif rm moderated | |||
- lattices have been performed on pin cell geometry using the 25 energy group J | - lattices have been performed on pin cell geometry using the 25 energy group J | ||
library and the experimental criticality data of Reference 4. Table 1 lists the re-sults of this analysis. Considering all the cases analyzed, the calculations result | library and the experimental criticality data of Reference 4. Table 1 lists the re-sults of this analysis. Considering all the cases analyzed, the calculations result in a Keff mean value of 1.00076 with a standard deviation of a sample about the mean of 2.00617 which is in very good agreement with the criticality data. | ||
T 3.2 Pilgrim 1 BOC-4 Critical Calculations Five cold critical states from the beginning of cycle 4 of Pilgrim 1 were used to test the accuracy of the method. Quarter core PDQ calculations, using CASMO generated cross sections, were performed in order to calculate the effect-ive multiplication factor. The calculations used the control rod positions and coolant temperatures of the BOC-4 critical states. The date from the cold critical. states are shown on Tables 2 through 6. Figure 1 shows the cycle 4 assembly layout from Reference 5, and the beginning of cycle 4 assemblywise exposure distributions from the plant process computer. The fuel assembly 1 | |||
in a Keff mean value of 1.00076 with a standard deviation of a sample about the mean of 2.00617 which is in very good agreement with the criticality data. | |||
T 3.2 Pilgrim 1 BOC-4 Critical Calculations | |||
Five cold critical states from the beginning of cycle 4 of Pilgrim 1 were used to test the accuracy of the method. Quarter core PDQ calculations, using CASMO generated cross sections, were performed in order to calculate the effect- | |||
ive multiplication factor. The calculations used the control rod positions and coolant temperatures of the BOC-4 critical states. The date from the cold critical. states are shown on Tables 2 through 6. Figure 1 shows the cycle 4 assembly layout from Reference 5, and the beginning of cycle 4 assemblywise exposure distributions from the plant process computer. The fuel assembly 1 | |||
design parameters were obtained from References 6,7, and 8. | design parameters were obtained from References 6,7, and 8. | ||
For the first critical state two group average macroscopic cross sections were generated for the fuel types and conditions shown on Table 7. Similar cross section sets were generated for the remaining critical states using their respective coolant temperatures. The water cross sections were calculated in CASMO, by flux and volume weighting the wide and narrow water gap cross sections of 8DB219 assembly at the critical state coolant temperature. | For the first critical state two group average macroscopic cross sections were generated for the fuel types and conditions shown on Table 7. Similar cross section sets were generated for the remaining critical states using their respective coolant temperatures. The water cross sections were calculated in CASMO, by flux and volume weighting the wide and narrow water gap cross sections of 8DB219 assembly at the critical state coolant temperature. | ||
1542 125 | 1542 125 | ||
TABLE 1 CASMO Criticality Calculations for Uniform Water - Moderated Lattices CASE CASMO Keff 9 1.00290 10 1.00323 11 1.00096 12 1.00801 13 1.01141 14 1.00909 - | |||
15 1.00071 16 .99561 17 1.00590 18 1.00401 19 1.00246 20 .99380 21 .99473 22 .99384 23 .99337 24 .99213 1542 126 | |||
TABLE 1 CASMO Criticality Calculations for Uniform Water - Moderated Lattices | |||
CASE CASMO Keff 9 1.00290 10 1.00323 11 1.00096 | |||
12 1.00801 13 1.01141 14 1.00909 - | |||
15 1.00071 16 .99561 17 1.00590 | |||
18 1.00401 19 1.00246 20 .99380 21 .99473 | |||
22 .99384 | |||
23 .99337 24 .99213 | |||
1542 126 | |||
TABLE 2 CRITICAL STATE 1 BOC-4 Pilgrim 1 Date 11-14-77 Coolant Temperature 157 F 3 | |||
TABLE 2 CRITICAL STATE 1 | Control Rod Notch Position Withdrawn 51 48 0 48 0 48 0 48 47 4 0 0 0 4 0 0 0 4 43 48 0 48 0 48 0 48 0 48 0 48 0 0 0 8 0 0 0 4 0 0 0 4 39 4 35 0 48 0 48 0 48 0 48 0 48 0 48 0 31 0 0 4 0 0 0 8 0 0 0 8 0 0 | ||
. 27 0 48 0 48 0 48 0 48 0 48 0 48 0 23 0 0 8 0 0 0 4 0 0 0 4 0 0 19 0 48 0 48 0 48 0 48 0 48 0 48 0 15 4 0 0 0 4 0 0 0 8 0 0 0 4 11 48 0 48 0 48 0 48 0 48 0 48 07 4 0 0 0 4 0 0 0 4 03 48 0 48 0 48 0 48 02 05 10 14 18 22 26 30 34 38 42 46 50 1542 127 m | |||
BOC-4 Pilgrim 1 Date 11-14-77 Coolant Temperature 157 F 3 | |||
Control Rod Notch Position Withdrawn 51 48 0 48 0 48 0 48 47 4 0 0 0 4 0 0 0 4 43 48 0 48 0 48 0 48 0 48 0 48 0 0 0 8 0 0 0 4 0 0 0 4 39 4 35 0 48 0 48 0 48 0 48 0 48 0 48 0 | |||
31 0 0 4 0 0 0 8 0 0 0 8 0 0 | |||
. 27 0 48 0 48 0 48 0 48 0 48 0 48 0 | |||
23 0 0 8 0 0 0 4 0 0 0 4 0 0 19 0 48 0 48 0 48 0 48 0 48 0 48 0 15 4 0 0 0 4 0 0 0 8 0 0 0 4 11 48 0 48 0 48 0 48 0 48 0 48 | |||
07 4 0 0 0 4 0 0 0 4 03 48 0 48 0 48 0 48 02 05 10 14 18 22 26 30 34 38 42 46 50 | |||
1542 127 | |||
m | |||
^ | ^ | ||
TABLE 3 CRITICAL STATE 2 BOC-4 Pilgrim 1 Date 11-15-77 Coolant Temperature 2890F Control Rod' Notch Position Withdrawn 51 48 0 48 0 48 0 48 47 12 0 0 0 12 0 0 0 12 43 48 0 48 0 48 0 48 0 48 0 48 39 12 0 0 0 12 0 0 0 12 0 0 0 12 35 0 48 0 48 0 48 0 48 0 48 0 48 0 31 0 0 12 0 0 0 20 0 0 0 12 0 0 27 0 48 0 48 0 48 0 48 0 48 0 48 0 23 0 0 12 0 0 0 12 0 0 0 12 0 0 19 0 48 0 48 0 48 0 48 0 48 0 48 0 15 12 0 0 0 12 0 0 0 12 0 0 0 12 11 48 0 48 0 48 0 48 0 48 0 48 07 12 0 0 0 12 0 0 0 12 03 48 0 48 0 48 0 48 02 06 10 14 18 22 26 30 34 38 42 46 50 1542 128 | |||
TABLE 3 CRITICAL STATE 2 | |||
BOC-4 Pilgrim 1 Date 11-15-77 Coolant Temperature 2890F | |||
Control Rod' Notch Position Withdrawn | |||
51 48 0 48 0 48 0 48 47 12 0 0 0 12 0 0 0 12 43 48 0 48 0 48 0 48 0 48 0 48 | |||
39 12 0 0 0 12 0 0 0 12 0 0 0 12 35 0 48 0 48 0 48 0 48 0 48 0 48 0 31 0 0 12 0 0 0 20 0 0 0 12 0 0 27 0 48 0 48 0 48 0 48 0 48 0 48 0 23 0 0 12 0 0 0 12 0 0 0 12 0 0 19 0 48 0 48 0 48 0 48 0 48 0 48 0 15 12 0 0 0 12 0 0 0 12 0 0 0 12 11 48 0 48 0 48 0 48 0 48 0 48 07 12 0 0 0 12 0 0 0 12 03 48 0 48 0 48 0 48 02 06 10 14 18 22 26 30 34 38 42 46 50 1542 128 | |||
TABLE 4 CRITICAL STATE 3 BOC-4 Pilgrim 1 Date 11-16-7 7 Coolant Temperature 180 F Control Rod Notch Positions Withdrawn 51 48 0 48 0 48 0 48 47 8 0 0 0 8 0 0 0 8 43 48 0 48 0 48 0 48 0 48 0 48 - | TABLE 4 CRITICAL STATE 3 BOC-4 Pilgrim 1 Date 11-16-7 7 Coolant Temperature 180 F Control Rod Notch Positions Withdrawn 51 48 0 48 0 48 0 48 47 8 0 0 0 8 0 0 0 8 43 48 0 48 0 48 0 48 0 48 0 48 - | ||
39 8 0 0 0 8 0 0 0 8 0 0 0 8 35 0 48 0 48 0 48 0 48 0 48 0 48 0 31 0 0 8 0 0 0 10 0 0 0 8 0 0 27 0 48 0 48 0 48 0 48 0 48 0 48 0 23 0 0 8 0 0 0 8 0 0 0 8 0 0 19 0 48 0 48 0 48 0 48 0 48 0 48 0 15 8 0 0 0 8 0 0 0 8 0 0 0 8 11 48 0 48 0 48 0 48 0 48 0 48 07 8 0 0 0 8 0 0 0 8 03 48 0 48 0 48 0 48 02 06 10 14 18 22 26 30 34 38 42 46 50 | 39 8 0 0 0 8 0 0 0 8 0 0 0 8 35 0 48 0 48 0 48 0 48 0 48 0 48 0 31 0 0 8 0 0 0 10 0 0 0 8 0 0 27 0 48 0 48 0 48 0 48 0 48 0 48 0 23 0 0 8 0 0 0 8 0 0 0 8 0 0 19 0 48 0 48 0 48 0 48 0 48 0 48 0 15 8 0 0 0 8 0 0 0 8 0 0 0 8 11 48 0 48 0 48 0 48 0 48 0 48 07 8 0 0 0 8 0 0 0 8 03 48 0 48 0 48 0 48 02 06 10 14 18 22 26 30 34 38 42 46 50 1542 129 | ||
1542 129 | |||
_9_ | _9_ | ||
TABLE 5 CRITICAL STATE 4 BOC-4 Pilgrim 1 Date 11-19-77 Coolant Temperature llioF Control Rod Notch Positions Withdrawn 51 48 0 48 0 48 0 48 47 0 0 0 0 0 0 0 0 0 - | TABLE 5 CRITICAL STATE 4 BOC-4 Pilgrim 1 Date 11-19-77 Coolant Temperature llioF Control Rod Notch Positions Withdrawn 51 48 0 48 0 48 0 48 47 0 0 0 0 0 0 0 0 0 - | ||
43 48 0 48 0 48 0 48 0 48 0 48 39 0- 0 0 0 4 0 0 0 4 0 0 0 0 35 0 48 0 48 0 48 0 48 0 48 0 48 0 31 0 0 4 0 0 0 4 0 0 0 4 0 0 27 0 48 0 48 0 48 0 48 0 48 0 48 0 23 0 0 4 0 0 0 4 0 0 0 0 0 0 19 0 48 0 48 0 48 0 48 0 48 0 48 0 15 0 0 0 0 0 0 0 0 4 0 0 0 0 11 48 0 48 0 48 0 48 0 48 0 48 | 43 48 0 48 0 48 0 48 0 48 0 48 39 0- 0 0 0 4 0 0 0 4 0 0 0 0 35 0 48 0 48 0 48 0 48 0 48 0 48 0 31 0 0 4 0 0 0 4 0 0 0 4 0 0 27 0 48 0 48 0 48 0 48 0 48 0 48 0 23 0 0 4 0 0 0 4 0 0 0 0 0 0 19 0 48 0 48 0 48 0 48 0 48 0 48 0 15 0 0 0 0 0 0 0 0 4 0 0 0 0 11 48 0 48 0 48 0 48 0 48 0 48 07 0 0 0 0 0 0 0 0 0 03 48 0 48 0 48 0 48 02 06 10 14 18 22 26 30 34 38 42 46 50 1542 130 | ||
07 0 0 0 0 0 0 0 0 0 03 48 0 48 0 48 0 48 02 06 10 14 18 22 26 30 34 38 42 46 50 1542 130 | |||
TABLE 6 CRITICAL STATE 5 BOC-4 Pilgrim 1 Date 11-25-77 Coolant Temperature 1370F Control Rod Notch Positions Withdrawn 51 48 0 48 0 48 0 48 47 4 0 0 0 4 0 0 0 4 43 48 0 48 0 48 0 48 0 48 0 48 39 4 0 0 0 4 0 0 0 4 0 0 0 4 35 0 48 0 48 0 48 0 48 0 48 0 48 0 31 0 0 4 0 0 0 8 0 0 0 4 0 0 27 0 48 0 48 0 48 0 48 0 48 0 48 0 23 0 0 4 0 0 0 4 0 0 0 4 0 0 19 0 48 0 48 0 48 0 48 0 48 0 48 0 15 4 0 0 0 4 0 0 0 4 0 0 0 4 11 48 0 48 0 48 0 48 0 48 0 48 07 4 0 0 0 4 0 0 0 4 03 48 0 48 0 48 0 48 02 06 10 14 18 22 26 30 34 38 42 46 50 | |||
TABLE 6 CRITICAL STATE 5 BOC-4 Pilgrim 1 Date 11-25-77 Coolant Temperature 1370F Control Rod Notch Positions Withdrawn | |||
51 48 0 48 0 48 0 48 47 4 0 0 0 4 0 0 0 4 | |||
43 48 0 48 0 48 0 48 0 48 0 48 | |||
39 4 0 0 0 4 0 0 0 4 0 0 0 4 | |||
35 0 48 0 48 0 48 0 48 0 48 0 48 0 31 0 0 4 0 0 0 8 0 0 0 4 0 0 27 0 48 0 48 0 48 0 48 0 48 0 48 0 23 0 0 4 0 0 0 4 0 0 0 4 0 0 19 0 48 0 48 0 48 0 48 0 48 0 48 0 15 4 0 0 0 4 0 0 0 4 0 0 0 4 11 48 0 48 0 48 0 48 0 48 0 48 07 4 0 0 0 4 0 0 0 4 03 48 0 48 0 48 0 48 02 06 10 14 18 22 26 30 34 38 42 46 50 | |||
!542 131 | !542 131 | ||
FIGURE 1 , | FIGURE 1 , | ||
PILGRIM BOC-4 26 1 2 3 4 b5 6 7 8b9 to b1 19 | PILGRIM BOC-4 26 1 2 3 4 b5 6 7 8b9 to b1 19 | ||
/L L k/ L L () L L /L L (./ L L\/H 2 \/L 1 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 6.3 0.0 L 1 H 1 H 1 H 2 H 2 H 2 L 2 | /L L k/ L L () L L /L L (./ L L\/H 2 \/L 1 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 6.3 0.0 L 1 H 1 H 1 H 2 H 2 H 2 L 2 | ||
C/ L | C/ L | ||
' "'\#' ' ' ' ' '^' ''^ ''"* ''''' | ' "'\#' ' ' ' ' '^' ''^ ''"* ''''' | ||
Line 297: | Line 138: | ||
7 0.0 0.0 0.0 0.0 0 .0 0.0 0.0 0.D 0.0 0.0 5.6 0.0 0.0 H 2 H 2 H 2 L 8 | 7 0.0 0.0 0.0 0.0 0 .0 0.0 0.0 0.D 0.0 0.0 5.6 0.0 0.0 H 2 H 2 H 2 L 8 | ||
g 0. C 7.1r .0 7. P g0. 0< 6.3g g0 .0 6. ), g 0. 0 5.h0.0 | g 0. C 7.1r .0 7. P g0. 0< 6.3g g0 .0 6. ), g 0. 0 5.h0.0 | ||
/L H\/ L H(./ L H (./ L H() L L() L 9 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 L 2 H 2 H 2 H 2 L Assembly Type 10 y.0 67'%0.0 6.f TO.05. 7 /" %0. 0 6./r5 0.C Average Exposure GWD/T C/ H Hk/L Hk./L H() 2 L\. 4 11 0.0 0. 0 0.0 " 0. 0 5.5 0.0 0.0 0.0 0.0 2 2 2 2 2 2 L 12 4.(y'9 1 3.p y.9 5 7 g0.0 50 (%5.8 L L \/ L Lk/ L L \/ L 13 0.0 0.0 0.0 0. 0 0.0 0. 0 0.0 NUMBER IN CORE 1- 8DB262 20 2- 8DB262 132 L- 8DB219L 244 H- 8DB219H 184 TOTAL 580 | |||
/L H\/ L H(./ L H (./ L H() L L() L 9 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 L 2 H 2 H 2 H 2 L Assembly Type 10 y.0 67'%0.0 6.f TO.05. 7 /" %0. 0 6./r5 0.C Average Exposure GWD/T C/ H Hk/L Hk./L H() 2 L\. 4 11 0.0 0. 0 0.0 " 0. 0 5.5 0.0 0.0 0.0 0.0 2 2 2 2 2 2 L 12 4.(y'9 1 3.p y.9 5 7 g0.0 50 (%5.8 L L \/ L Lk/ L L \/ L 13 0.0 0.0 0.0 0. 0 0.0 0. 0 0.0 NUMBER IN CORE | |||
1- 8DB262 20 2- 8DB262 132 L- 8DB219L 244 H- 8DB219H 184 TOTAL 580 | |||
}Q | }Q | ||
TABLE 7 s | TABLE 7 s | ||
Cross Section Sets Generated by CASMO for Critical State 1 Fuel Type Exposure Void Mod T. Fuel T EQ.Xe Control (GWD/MT) (OF) (OF) 8DB219L 0 0 157 157 No No 8DB219L 0 0 157 157 No Yes 8DB219H 0 0 157 157 No No 8DB219H 0 0 157 157 No Yes - | Cross Section Sets Generated by CASMO for Critical State 1 Fuel Type Exposure Void Mod T. Fuel T EQ.Xe Control (GWD/MT) (OF) (OF) 8DB219L 0 0 157 157 No No 8DB219L 0 0 157 157 No Yes 8DB219H 0 0 157 157 No No 8DB219H 0 0 157 157 No Yes - | ||
8DB262 4 0 157 157 No No 8DB262 4 0 157 157 No Yes 8DB262 7 0 157 157 No No 8DB262 7 0 157 157 No Yes 8DB262 11 0 157 157 No No 8DB262 11 0 157 157 No Yes | 8DB262 4 0 157 157 No No 8DB262 4 0 157 157 No Yes 8DB262 7 0 157 157 No No 8DB262 7 0 157 157 No Yes 8DB262 11 0 157 157 No No 8DB262 11 0 157 157 No Yes 1542 133 I | ||
1542 133 | |||
I | |||
The calculation of the effective multiplication factor for each critical state should be estimated by performing three dimensional calculations so that the partially withdrawn control rods will be accurately represented. Since three dimensional calculations are prohibitively expensive the' effective mult-iplication factor was estimated by performing two dimensional PDQ calculations. | The calculation of the effective multiplication factor for each critical state should be estimated by performing three dimensional calculations so that the partially withdrawn control rods will be accurately represented. Since three dimensional calculations are prohibitively expensive the' effective mult-iplication factor was estimated by performing two dimensional PDQ calculations. | ||
First, a quarter core PDQ calculation was performed having fully inserted all the fully inserted and all the partially withdrawn control rods for the criti-cal state. Second, another quarter core PDQ calculation for the same critical state was performed having fully inserted all the fully inserted control rods, while all the partially withdrawn rods were fully withdrawn. The above PDQ calculations provide effective multiplication factors Keffl and Keff2 which ~ | First, a quarter core PDQ calculation was performed having fully inserted all the fully inserted and all the partially withdrawn control rods for the criti-cal state. Second, another quarter core PDQ calculation for the same critical state was performed having fully inserted all the fully inserted control rods, while all the partially withdrawn rods were fully withdrawn. The above PDQ calculations provide effective multiplication factors Keffl and Keff2 which ~ | ||
Line 323: | Line 151: | ||
The worth of these control rods when fully inserted is -2.07897%4f. In critical state 1 these control rods are withdrawn a total of 100 notches out of the 960, therefore, the reactivity adjustment to Keffl is: | The worth of these control rods when fully inserted is -2.07897%4f. In critical state 1 these control rods are withdrawn a total of 100 notches out of the 960, therefore, the reactivity adjustment to Keffl is: | ||
1 2.07897 x = .216559%or 1542 134 | 1 2.07897 x = .216559%or 1542 134 | ||
Consequently, the estimated Keff (critical state 1) = 1.000411. Table 8 shows the results of all the benchmark calculations. The value of the est-imated Keff depends on the coolant temperature. To understand the sensi-tivity to the coolant temperature, the calculation of critical state 1 was repeated at 137 F. The estimated Keff's for the two critical state 1 cal-culations are: | Consequently, the estimated Keff (critical state 1) = 1.000411. Table 8 shows the results of all the benchmark calculations. The value of the est-imated Keff depends on the coolant temperature. To understand the sensi-tivity to the coolant temperature, the calculation of critical state 1 was repeated at 137 F. The estimated Keff's for the two critical state 1 cal-culations are: | ||
Keff (157) = 1.000411 Keff (137) = 1.003871 From these Keff's it is seen that for a -20 F change in the coolant temper-ature the estimated Keff changes only by +.35%. In addition, this brief | Keff (157) = 1.000411 Keff (137) = 1.003871 From these Keff's it is seen that for a -20 F change in the coolant temper-ature the estimated Keff changes only by +.35%. In addition, this brief calculation shows that the moderator temperature coefficient at BOC-4 conditions is negative. The negative moderator temperature coefficient | ||
calculation shows that the moderator temperature coefficient at BOC-4 conditions is negative. The negative moderator temperature coefficient | |||
, suggests that the multiple controlled cell removal analysis be performed at 680F coolant temperature. From Table 8 and the results of the above calcul-ation it is concluded that the method used in the benchmark calculation is acceptably accurate. | , suggests that the multiple controlled cell removal analysis be performed at 680F coolant temperature. From Table 8 and the results of the above calcul-ation it is concluded that the method used in the benchmark calculation is acceptably accurate. | ||
1542 135 | 1542 135 | ||
_g- y y y y y TABLE 8 Results of The Benchmark Calculations Partially Withdrawn Rods Reactivity 1 Keff 2 Reactivity Notches Notches Adjustment Estimated Mod Keff Temp Worth (Af %) When With- to Keff I Critical Fully In Fully In drawn ( Af %) State Keff 0F | _g- y y y y y TABLE 8 Results of The Benchmark Calculations Partially Withdrawn Rods Reactivity 1 Keff 2 Reactivity Notches Notches Adjustment Estimated Mod Keff Temp Worth (Af %) When With- to Keff I Critical Fully In Fully In drawn ( Af %) State Keff 0F | ||
-2.078970 960 100 .216559 1.000411 Critical State 1 157 .998248 1.019404 | -2.078970 960 100 .216559 1.000411 Critical State 1 157 .998248 1.019404 | ||
Line 343: | Line 162: | ||
-2.111127 960 162 .356253 .999894 180 .996345 1.017753 i Critical State 3 | -2.111127 960 162 .356253 .999894 180 .996345 1.017753 i Critical State 3 | ||
-1.744523 384 32 .145377 1.002122 Critical State 4 111 1.000665 1.017068 | -1.744523 384 32 .145377 1.002122 Critical State 4 111 1.000665 1.017068 | ||
-2.110436 960 84 .184663 1.003517 Critical State 5 137 1.001661 1.023293 | -2.110436 960 84 .184663 1.003517 Critical State 5 137 1.001661 1.023293 4 | ||
N Ch I | |||
Ch I | |||
4.0 Multiple Controlled Cell Removal Analysis The results of the benchmark calculations have shown that the method used is acceptably accurate and for this reason it can be applied to the multiple controlled cell removal analysis. | 4.0 Multiple Controlled Cell Removal Analysis The results of the benchmark calculations have shown that the method used is acceptably accurate and for this reason it can be applied to the multiple controlled cell removal analysis. | ||
The objective of this analysis is to show that at any cycle of Pilgrim 1 removal of one or more controlled cells at a time always leads to a more sub-critical state. This objective will be achieved in three steps. First, the effect of multiple control cell removal is evaluated at cold (680F), Xenon-free conditions at the beginning-of-cycle 5 core loading configuration, which is a typical and representative reload configuration for Pilgrim 1. A sufficient _ | The objective of this analysis is to show that at any cycle of Pilgrim 1 removal of one or more controlled cells at a time always leads to a more sub-critical state. This objective will be achieved in three steps. First, the effect of multiple control cell removal is evaluated at cold (680F), Xenon-free conditions at the beginning-of-cycle 5 core loading configuration, which is a typical and representative reload configuration for Pilgrim 1. A sufficient _ | ||
Line 356: | Line 170: | ||
Figure 2 shows the BOC-5 core loading configuration for Pilgrim 1. This loading pattern is typical of reload cores which are loaded in a quarter-core sy= metric, scatter pattern of high and low reactivity bundles. As such, the reactivity worth of individual four bundle cells varies from cell to cell. | Figure 2 shows the BOC-5 core loading configuration for Pilgrim 1. This loading pattern is typical of reload cores which are loaded in a quarter-core sy= metric, scatter pattern of high and low reactivity bundles. As such, the reactivity worth of individual four bundle cells varies from cell to cell. | ||
Removal of a controlled cell affects the reactivity of not only the cell which is removed, but also the adjacent cells as well. Before reaching any general conclusion on the effects of controlled cell removal, a sufficient number of cases must be examined to span the range of combinations repre-sentative of the core configuration, e.g. high reactivity cell adjacent i542 137 | Removal of a controlled cell affects the reactivity of not only the cell which is removed, but also the adjacent cells as well. Before reaching any general conclusion on the effects of controlled cell removal, a sufficient number of cases must be examined to span the range of combinations repre-sentative of the core configuration, e.g. high reactivity cell adjacent i542 137 | ||
FIGURE 2 PILGRIM 1 BOC-5 26 1 2 3 4 b5 6( 7 8b9 10 b1 19 | FIGURE 2 PILGRIM 1 BOC-5 26 1 2 3 4 b5 6( 7 8b9 10 b1 19 | ||
/3 2H k / FH 3()3 2H \./ FH 3()3 2H\ / FL 2H\/2L 1 i L4. 0 9.4 0.0 13.4 15.6 9.6 0.0 14.1 15.2 10.9- 0.0 11.2 11.2 2H FH 2L FH 2L FH 2L FL 2L FL 2L FL 2L 2 9.7 0.0 0.0 6.3 0.0 | /3 2H k / FH 3()3 2H \./ FH 3()3 2H\ / FL 2H\/2L 1 i L4. 0 9.4 0.0 13.4 15.6 9.6 0.0 14.1 15.2 10.9- 0.0 11.2 11.2 2H FH 2L FH 2L FH 2L FL 2L FL 2L FL 2L 2 9.7 0.0 0.0 6.3 0.0 | ||
Line 372: | Line 182: | ||
/3 2L( / FL 2L (./ 3 2L (./ FL 2H(.)2L 2L(./ 2L 9 15.2 6.1 0. 0 10.9 14.7 5.7 0.0 11.2 10.1 11.5 11.4 2H FL 2L FL 2H FL FL 2L 2L 10 Assembly Type 0.8 0.p(1.6 0. % 0.3 0.0g 0 | /3 2L( / FL 2L (./ 3 2L (./ FL 2H(.)2L 2L(./ 2L 9 15.2 6.1 0. 0 10.9 14.7 5.7 0.0 11.2 10.1 11.5 11.4 2H FL 2L FL 2H FL FL 2L 2L 10 Assembly Type 0.8 0.p(1.6 0. % 0.3 0.0g 0 | ||
.0 3.H1.5 Average Exposure GWD/T | .0 3.H1.5 Average Exposure GWD/T | ||
/FL 2L(/ FL 2L ( / FL 2L(./2H 2L\../2L 11 0.0 6.2 0. 0 4.9 0.0 6.0 10.211.5 11.5 2H FL FL 2L 2L 2H 2L 12 fl. 2 0. H .0 5. M 1.0 11.h11.C J2L 2L() 2H 2L(/ 2H 2L (,/2L 13 11.111.5 11.1 11.5 11.0 11.3 11.3 Number in Core FH P8DRB282 64 | /FL 2L(/ FL 2L ( / FL 2L(./2H 2L\../2L 11 0.0 6.2 0. 0 4.9 0.0 6.0 10.211.5 11.5 2H FL FL 2L 2L 2H 2L 12 fl. 2 0. H .0 5. M 1.0 11.h11.C J2L 2L() 2H 2L(/ 2H 2L (,/2L 13 11.111.5 11.1 11.5 11.0 11.3 11.3 Number in Core FH P8DRB282 64 FL P8DRB265L 120 2H - 8DB219H 124 2L - 8DB219L 212 3 - 8DB262 60 TOTAL 1542 138 380 | ||
FL P8DRB265L 120 2H - 8DB219H 124 2L - 8DB219L 212 3 - 8DB262 60 TOTAL 1542 138 380 | |||
to high reactivity cell, high reactivity cell adjacent to low reactivity cell, edge cell, interior cell, multiple cells,etc. | to high reactivity cell, high reactivity cell adjacent to low reactivity cell, edge cell, interior cell, multiple cells,etc. | ||
The cases which were evaluated and the resultant core K-effectives are | The cases which were evaluated and the resultant core K-effectives are shown in Table 10. The effect of removing one, two or three cells was examined by performing full core PDQ calculations. The remaining multiple cell removal cases, where 4 or 8 or 16 symmetric cells were removed at a time, were evalu-ated by performing quarter core PDQ calculations. The assembly design para-meters were obtained from References 7, 8 and 9. Table 9 shows the fuel types and conditions for which average macroscopic cross sections were generated for the analysis. The water cross sections were generated in CASMO by flux and vol _ | ||
ume weighting the wide and narrow water gap cross sections of an 8DB219L assembly. To verify that the water cross sections have been properly determined a parametric study was performed and it is shown in Appendix A. The first case shown in Table 10 is the all-rods-in case with no cell (s) removed. The remaining cases are for various combinations of controlled cells removed. All cases in Table 10 were analyzed in quarter core geometry, except cases 14, 15 and 16 which were analyzed in full core geometry. From Table 10 it can be seen that for all cases considered the reactor reaches a more suberitical state after controlled cell removal as compared to the all-rods-in case with no cell (s) removed. The reactivity loss per cell removed for the various cases in Table 10 is plotted as a function of distance from the core center in Figure 3. From Figure 3 it can be seen that the reactivity loss is always positive and it is higher for cells removed closer to the core center. There are no anomalous points to suggest a need to consider additional cases. Since the removal covers unifo rmly the distance from the center to the core periphery, there is reasonable assurance that any other cells that have not been analyzed will follow the trend seen in Figure 3. It is therefore concluded that all representative combinations of controlled cell removals at BOC-5 lead to a more suberitical state. | |||
shown in Table 10. The effect of removing one, two or three cells was examined by performing full core PDQ calculations. The remaining multiple cell removal cases, where 4 or 8 or 16 symmetric cells were removed at a time, were evalu-ated by performing quarter core PDQ calculations. The assembly design para-meters were obtained from References 7, 8 and 9. Table 9 shows the fuel types and conditions for which average macroscopic cross sections were generated for the analysis. The water cross sections were generated in CASMO by flux and vol _ | |||
ume weighting the wide and narrow water gap cross sections of an 8DB219L assembly. To verify that the water cross sections have been properly determined a parametric study was performed and it is shown in Appendix A. The first case shown in Table 10 is the all-rods-in case with no cell (s) removed. The remaining | |||
cases are for various combinations of controlled cells removed. All cases in Table 10 were analyzed in quarter core geometry, except cases 14, 15 and 16 which were analyzed in full core geometry. From Table 10 it can be seen that for all cases considered the reactor reaches a more suberitical state after controlled cell removal as compared to the all-rods-in case with no cell (s) removed. The reactivity loss per cell removed for the various cases in Table 10 is plotted as a function of distance from the core center in Figure 3. From Figure 3 it can be seen that the reactivity loss is always positive and it is higher for cells removed closer to the core center. There are no anomalous points to suggest a need to consider additional cases. Since the removal covers unifo rmly the distance from the center to the core periphery, there is reasonable assurance | |||
that any other cells that have not been analyzed will follow the trend seen in Figure 3. It is therefore concluded that all representative combinations of controlled cell removals at BOC-5 lead to a more suberitical state. | |||
1542 139 | 1542 139 | ||
TABLE 9 Cross Section Sets for Multiple Controlled Cell Removal Analysis Assembly Type Cross Section - | TABLE 9 Cross Section Sets for Multiple Controlled Cell Removal Analysis Assembly Type Cross Section - | ||
First Sten 8DB262 2G, Controlled, 680F, 13.5 and 15 GWD/MT 8DB219L 2G, Controlled, 680F, 4,6 and 11 GWD/MT 8DB219H 2G, Controlled, 680F, 9.9 and 10.9 GWD/M P8DRB265L 2G, Controlled, 680F, O GWD/MT 78DRB282 2G, cont.olled, 68 F,0 O GWD/MT Second Step P8DRB265L 2G, Controlled, 68 F,0 O GWD/MT , No Gd P8DRB282 2G, Controlled, 680F, O GWD/MT , No Gd Third Step P8DRB282 2G, Controlled, 680F, O GWD/MT , No Gd 8DB219L 2G, Controlled, 680F, 30 GWD/MT 1542 140 | |||
First Sten 8DB262 2G, Controlled, 680F, 13.5 and 15 GWD/MT 8DB219L 2G, Controlled, 680F, 4,6 and 11 GWD/MT 8DB219H 2G, Controlled, 680F, 9.9 and 10.9 GWD/M P8DRB265L 2G, Controlled, 680F, O GWD/MT 78DRB282 2G, cont.olled, 68 F,0 O GWD/MT Second Step | |||
P8DRB265L 2G, Controlled, 68 F,0 O GWD/MT , No Gd P8DRB282 2G, Controlled, 680F, O GWD/MT , No Gd Third Step P8DRB282 2G, Controlled, 680F, O GWD/MT , No Gd 8DB219L 2G, Controlled, 680F, 30 GWD/MT 1542 140 | |||
TABLE 10 Multiple Controlled Cell Removal BOC-5 Results Cells Removed Keff | TABLE 10 Multiple Controlled Cell Removal BOC-5 Results Cells Removed Keff | ||
: 1. None .945166 | : 1. None .945166 | ||
Line 420: | Line 211: | ||
: 16. 31-30 UL & UR & Ll Full Core .940502 | : 16. 31-30 UL & UR & Ll Full Core .940502 | ||
* UL - upper left, UR - upper right, LL - lower left 1542 141 | * UL - upper left, UR - upper right, LL - lower left 1542 141 | ||
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Line 1,285: | Line 499: | ||
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The beginning-of-cycle is not the most reactive state of the core in cycle 5. The most reactive state is reached when the reload bundles reach their peak reactivity as the gadolinia burn out. To examine whether the con-clusion just reached is valid throughout cycle 5, it would require rerunning all cases, previously examined, but with new cross section sets updated for various cycle 5 exposure increments. An alternate approach and the one which is used herein is to make a conservative bounding calculation. The matter at issue is quite simply-is there a reactivity loss or is there a reactivity gain for controlled cell removal at the time the core is at its most reactive state in the cycle? If there is a reactivity gain, then one is concerned with the absolute value of Keff, since there is danger of inability to maintain shutdown margin. However, if there is a reactivity loss, then the absolute value of Keff is inconsequential since the results are in the conservative direction. The method used in this analysis to maximize the reacitivity state of the core for cycle 5 is to examine the case in which previously exposed bundles are assumed to remain at the BOC-5 exposure and the new reload bundles are assumed to have no gadolinia at zero exposure. This results in a reactivity of the reload bundles which is much greater than would ever be achieved in a normal cycle, and conseq-uently a core reactivity state which is more reactive than any time in cycle 5. | |||
The beginning-of-cycle is not the most reactive state of the core in cycle 5. The most reactive state is reached when the reload bundles reach their peak reactivity as the gadolinia burn out. To examine whether the con-clusion just reached is valid throughout cycle 5, it would require rerunning all cases, previously examined, but with new cross section sets updated for various cycle 5 exposure increments. An alternate approach and the one which is used herein is to make a conservative bounding calculation. The matter at issue is quite simply-is there a reactivity loss or is there a reactivity gain for controlled cell removal at the time the core is at its most reactive state in the cycle? If there is a reactivity gain, then one is concerned with the | |||
absolute value of Keff, since there is danger of inability to maintain shutdown margin. However, if there is a reactivity loss, then the absolute value of Keff is inconsequential since the results are in the conservative direction. The method used in this analysis to maximize the reacitivity state of the core for cycle 5 is to examine the case in which previously exposed bundles are assumed to remain at the BOC-5 exposure and the new reload bundles are assumed to have no gadolinia at zero exposure. This results in a reactivity of the reload bundles which is much greater than would ever be achieved in a normal cycle, and conseq-uently a core reactivity state which is more reactive than any time in cycle 5. | |||
Using the method just described, the first three cases from Table 10 were reanalyzed and the results are shown on Table 11. The cells which are assumed to be removed were selected because they are near the center of the core which is a high reactivity worth area. As can be seen, the core loses reactivity as control cells are removed. This demonstrates that the conclusion previously reached for beginning of cycle 5 is valid throughout the cycle. | Using the method just described, the first three cases from Table 10 were reanalyzed and the results are shown on Table 11. The cells which are assumed to be removed were selected because they are near the center of the core which is a high reactivity worth area. As can be seen, the core loses reactivity as control cells are removed. This demonstrates that the conclusion previously reached for beginning of cycle 5 is valid throughout the cycle. | ||
The last issue to be addressed is whether this conclusion is valid for all cycles. This is verified by bounding the range of bundle enrichments which might be loaded in subsequent reloads and by evaluating the controlled cell removal 1542 143 | The last issue to be addressed is whether this conclusion is valid for all cycles. This is verified by bounding the range of bundle enrichments which might be loaded in subsequent reloads and by evaluating the controlled cell removal 1542 143 | ||
TABLE 11 Multiple Controlled Cell Removal BOC-5 Fresh Assemblies Without Gd Cells Removed Keff | |||
TABLE 11 Multiple Controlled Cell Removal | |||
BOC-5 Fresh Assemblies Without Gd | |||
Cells Removed Keff | |||
: 1. None 1.022974 | : 1. None 1.022974 | ||
: 2. 31-30 1.012614 | : 2. 31-30 1.012614 | ||
- 3. 35-26, 27-34 1.011246 1542 144 | |||
- 3. 35-26, 27-34 1.011246 | |||
1542 144 | |||
effect. The maxinum enrichment available for Pilgrim is that of the P8DRB282 bundle. In this analysis the maximum enrichment is bounded by assuming that the bundle contains no gadolinia. The first bounding case evaluates the removal effect assuming a full core of fresh P8DRB282 bundles without gadolinia. The results of this analysis are shown on Table 12 and the reactivity loss as a R | |||
effect. The maxinum enrichment available for Pilgrim is that of the P8DRB282 | |||
bundle. In this analysis the maximum enrichment is bounded by assuming that the bundle contains no gadolinia. The first bounding case evaluates the removal effect assuming a full core of fresh P8DRB282 bundles without gadolinia. The results of this analysis are shown on Table 12 and the reactivity loss as a R | |||
function of distance from the core center has been plotted on Figure 3. From Figure 3 it can be seen that the results of this fictitious cycle follow the trend established by the B0C-5 results. The second bounding case (the most conservative one) evaluates the effect of removing a single highly burned cell (consisting of four 8DB219L bundles at 30 GWD/MT in position 35-34) from a quarter-core of fresh P8DRB282 bundles without gadolinia. The results of this ~~ | function of distance from the core center has been plotted on Figure 3. From Figure 3 it can be seen that the results of this fictitious cycle follow the trend established by the B0C-5 results. The second bounding case (the most conservative one) evaluates the effect of removing a single highly burned cell (consisting of four 8DB219L bundles at 30 GWD/MT in position 35-34) from a quarter-core of fresh P8DRB282 bundles without gadolinia. The results of this ~~ | ||
analysis are shown on Table 13. From Tables 12 and 13, it can be seen that the core reaches a less reactive state after the removal. Since the results of Tables 12 and 13 conservatively bound all future Pilgrim 1 cycles it is concluded that the removal of one or more controlled cells from any cycle of Pilgrim 1 will not violate shutdown margin requirements because it leads to a more sub-critical state. | analysis are shown on Table 13. From Tables 12 and 13, it can be seen that the core reaches a less reactive state after the removal. Since the results of Tables 12 and 13 conservatively bound all future Pilgrim 1 cycles it is concluded that the removal of one or more controlled cells from any cycle of Pilgrim 1 will not violate shutdown margin requirements because it leads to a more sub-critical state. | ||
1542 145 | 1542 145 | ||
=@ e . p.m , | =@ e . p.m , | ||
-i---. -- -- um | -i---. -- -- um | ||
TABLE 12 Multiple Controlled Cell Removal Fictitious Cfele With Fresh P8DRB282 Fuel No Cd Cell Removed gegf | |||
TABLE 12 | |||
Multiple Controlled Cell Removal | |||
: 1. None 1.140383 | : 1. None 1.140383 | ||
: 2. 43&47-30, 31-42646 1.133016 | : 2. 43&47-30, 31-42646 1.133016 | ||
Line 1,339: | Line 525: | ||
: 6. 43-30, 31-42 1.133149 | : 6. 43-30, 31-42 1.133149 | ||
: 7. 35-34 1.130278 1542 146 | : 7. 35-34 1.130278 1542 146 | ||
--e- | --e- | ||
I TABLE 13 I | I TABLE 13 I | ||
Multiple Controlled Cell Removal - | Multiple Controlled Cell Removal - | ||
I Fresh Core of P8DRB282 With One Highly Burned 8DB219L I | I Fresh Core of P8DRB282 With One Highly Burned 8DB219L I | ||
Cell Removed Keff I 1. None 1.131706 I 2. 35-34 1.130278 | Cell Removed Keff I 1. None 1.131706 I 2. 35-34 1.130278 I | ||
I I | I I | ||
1542 147 g | I 1542 147 g | ||
I I | I I | ||
I I | I I | ||
Line 1,360: | Line 539: | ||
I .- - . . _ ___ ._. | I .- - . . _ ___ ._. | ||
I I 5.0 conclusion | I I 5.0 conclusion The analysis presented in this report shows that the method used is acceptably accurate and that removal of more than one controlled cell at a time, from any cycle of Pilgrim 1 at shutdown conditions, does not violate the shutdown margin requirements because it leaves the reactor in a more sub-I critical state. | ||
The analysis presented in this report shows that the method used is acceptably accurate and that removal of more than one controlled cell at a time, from any cycle of Pilgrim 1 at shutdown conditions, does not violate the shutdown margin requirements because it leaves the reactor in a more sub-I critical state. | |||
I I - | I I - | ||
I I | I I | ||
Line 1,371: | Line 548: | ||
I 2e. | I 2e. | ||
APPENDIX A | APPENDIX A I After the removal of a controlled cell the volume is filled with water. | ||
I After the removal of a controlled cell the volume is filled with water. | |||
The water cross section for PDQ are calculated in CASMO by flux and volume weighting the wide and narrow water gap cross sections. Keeping in mind that these gaps are small compared to the controlled cell volume, one might question whether these cross sections are appropriate. To answer this question two sets of water cross sections were generated for BOC conditions at 680F one using the standard narrow and wide gap dimensions and the other using 10 cm and 12 cm thickness for the narrow and wide water gaps respectively. The results of this study is shown on Table 14. From Table 14 it can be concluded that for _ | The water cross section for PDQ are calculated in CASMO by flux and volume weighting the wide and narrow water gap cross sections. Keeping in mind that these gaps are small compared to the controlled cell volume, one might question whether these cross sections are appropriate. To answer this question two sets of water cross sections were generated for BOC conditions at 680F one using the standard narrow and wide gap dimensions and the other using 10 cm and 12 cm thickness for the narrow and wide water gaps respectively. The results of this study is shown on Table 14. From Table 14 it can be concluded that for _ | ||
this analysis the water cross sections are not very sensitive to the water gap dimensions. | this analysis the water cross sections are not very sensitive to the water gap dimensions. | ||
Line 1,385: | Line 560: | ||
I . .- | I . .- | ||
TABLE 14 Water Cross Section Parametric Study Keff Standard Size 12 cm Wide Gap Cells Removed Gaps 10 cm Narrow Cap | TABLE 14 Water Cross Section Parametric Study Keff Standard Size 12 cm Wide Gap Cells Removed Gaps 10 cm Narrow Cap | ||
: 1. None .945091 .945026 | : 1. None .945091 .945026 | ||
Line 1,396: | Line 569: | ||
I I | I I | ||
I . .. .. - - .. . . | I . .. .. - - .. . . | ||
References | References |
Revision as of 00:28, 2 February 2020
ML19253C909 | |
Person / Time | |
---|---|
Site: | Pilgrim |
Issue date: | 11/30/1979 |
From: | Antonopoulos P BOSTON EDISON CO. |
To: | |
Shared Package | |
ML19253C906 | List: |
References | |
NUDOCS 7912120337 | |
Download: ML19253C909 (50) | |
Text
B e
I I PILGRIM-1 MULTIPLE CONTROLLED CELL REMOVAL by Petros T. Antonopoulos I Nuclear Fuel Division November, 1979 I
I I
I Prepared by M fr7</#* //' 38' 77
/ Date I
Reviewed by // m t /. b d /) -
[1k hh Ddte '
p '
Approved by $cfr ==_ N. [ra f2 2-79
[ Date I
I 1542 117 I Boston Edison Company 800 Boylston Street Boston, Massachusetts 02199 I 7 9121. 2033y7
I TABLE OF CONTENTS PAGE List of Figures (iv)
List of Tables (v) 1.0 Introduction 1 2.0 Method 3 3.0 Benchmark Calculations 5 3.1 CASMO Criticality Calculations 5 3.2 Pilgrim 1 BOC-4 Critical Calculations 5 4.0 Multiple Controlled Cell Removal Analysis 17 5.0 Conclusion 28 Appendix A 29 References 31 I
1 5
l 1542 118 I
E I
(iii)
I
LIST OF FIGURES NUMBER PAGE
- 1. Pilgrim BOC-4 12
- 2. Pilgrim BOC-5 18
- 3. Reactivity Loss Per Cell Removed Versus 22 Distance from the Core Center v e A
A v
)
1542 119 2
2 (iv)
LIST OF TABLES NUMBER PAGE
- 1. CASMO Criticality Calculations for Uniform Water Moderated Lattices 6 2 2. Critical State 1 7
- 3. Critical State 2 8
- 4. Critical State 3 9
- 5. Crftical State 4 10
- 6. Critical State 5 11
- 7. Cross Section Sets Generated by CASMO for 13 Critical State 1
_' 8. Results of the Benchmark Calculations 16
- 9. Cross Section Sets for Multiple Controlled Cell 20 Removal Analysis
- 10. Multiple Controlled Cell Removal BOC-5 Results 21
- 11. Multiple Controlled Cell Removal B0C-5 Fresh 24 Assemblies Without Gd
- 12. Multiple Controlled Cell Removal Ficticious Cycle 26 With Presh P8DR3282 Fuel No Gd j 13. Multiple Controlled Cell Removal Fresh Core of P8DRB282 27 With One Highly Burned 8DB219L
- 14. Water Cross Section Parametric Study 30 1542 120 (v) l
PILGRIM 1 MULTIPLE CONTROLLED CELL REMOVAL 1.0 Introduction s The Technical Specifications for Pilgrim Nuclear Power Station - Unit #1 prohibit withdrawal of more than one control rod when the mode switch is in the " refuel" position. The reason for this restriction in, to preclude in-advertent criticality. Certain refueling maintenance activities such as replacement of control rods or control rod drive mechanisms can be done in less time and potentially with lower personnel radiation exposure, if more than one control rod can be withdrawn at a time. This study was undertaken -
j by Boston Edison to demonstrate that multiple control rods can be removed from the core without violating the shutdown margin requirements as long as the adjacent fuel in the cell is removed prior to the control rod removal.
The purpose of this report is to present the method and results 2
pertinent to multiple controlled cell removal for Pilgrim 1. From the reactor physics standpoint the removal of a controlled cell (four fuel assemblies plus control rod) affects the reactor state because of the following:
- a. The removal of fuel t
- b. The removal of the control blade
- c. The creation of a water filled gap which acts as a flux trap.
Although the final reactor state following the removal of a controlled cell will be determined by the reactivity contributions made by each of the effects listed above, the individual reactivity contributions will not be determined, only the total reactivity contribution will. The present aralysis will show that at any cycle of Pilgrim 1 all reactivity contributions from multiple 1542 121
_T
controlled cell removal lead to a more suberitical state, and consequently increase the shutdown margin of the core.
This analysis consists of two sections, the benchmark section and the multiple controlled cell removal section. The benchmark section is intended to show that the method and the computer programs used reproduce accurately critical states of Pilgrim 1. This provides the necessary confidence in the method and computer programs so that the multiple controlled cell re-moval analysis can be performed. The multiple controlled cell removal analysis uses the same method and computer programs, in order to show that multiple controlled cell removal always results in a more suberitical state. _
n h
i l
- 1542 122 i
l
[ l I
.._.-_7--....-..... . . . .
2.0 Method The method used in this study has been based on Pilgrim 1 nuclear design parameters and cycle data such as assembly types, assembly layout, and assem-blywise average exposure distribution. In addition, it utilizes the computer programs GAPCON-Thermal 2 1 ,CASM0 2 , ppq3 . Among the computer programs, GAPCON-Thermal 2 is a fuel performance code and has been used to calculate the fuel temperature which is an input parameter to CASMO. CASMO is a lattice code capable of performing physics calculations for boiling and pressurized water reactors, in pin cell or assembly geometry. This code has the capability of performing controlled and uncontrolled fuel depletions at any void and can _
handle fuel rods with gadolinia. CASMO has been used to calculate macroscopic
/
cross sections which are input to PDQ. PDQ is a fine mesh nuclear simulator capable of performing diffusion theory calculations.
Based on the Pilgrim 1 nuclear design parameters and cycle data the method proceeds as follows:
- a. CAPCON-Thermal 2 is set up to calculate the fuel temperature at full power conditions. This fuel temperature is a necessary input to CASMO when full power calculations need to be performed.
- b. For each assembly type a CASMO is set up in assembly geometry. For assemblies with zero exposure a beginning of cycle CASMO calculation is performed at the proper conditions. For assemblies with different than zero exposure,CASMO is set up and depleted uncontrolled at full h power and average void conditions. The restart file is saved at the required exposure points and then a CASMO restart calculation is per-formed by attaching the required restart file and performing the necessary restart calculations at the proper conditions such as, zero power, cold (680F), controlled, no equilibrium xenon, etc. From each
CASMO calculation two group average macroscopic cross sections are calculated. The two group macroscopic cross sections are calculated in CASMO by flux and volume weighting the macroscopic cross sections of all fuel, fuel with gadolinia, water rod, channel, wide and narrow water gaps and the control blade (if present). For a given cycle the j assemblies of the same type are gathered into groups of approximately equal exposure. For each group the average exposure is calculated and controlled or uncontrolled cross sections sets are calculated with CASMO at the average exposure. These sets of cross sections are input to PDQ and are assigned respectively to controlled or uncontrolled assemblies -
in the group.
- c. For each cycle a quarter core or, if necessary, a full core PDQ is set up in two energy groups. Each assembly with its wide and narrow water gaps is homogenized in PDQ and is represented with an 8 x 8 plannar region. The quarter core geometry consists of 120 x 120 mesh grid and a
the full core geometry consists of 240 x 240 grid with 1.905 cm mesh size. A controlled cell in PDQ consists of four plannar regions which are assigned controlled cross sections. The removal of a controlled cell is simulated by assigning water cross sections to its four plannar
/
regions. To determine whether the removal of a controlled cell leads to a more or less subcritical state two PDQ calculations are performed.
The first calculation has all controlled cells in the core and the second has the cell or cells of interest removed. If the calculated Keff of the second case is less than the Keff calculated from the first case, it is concluded that the removal leads to a more subcritical state.
1542 124
^
3.0 Benchmark Calculations The intent of this section is to provide confidence in the programs and the method used in the analysis. The first part of the benchmark cal-culations consist of pin cell CASMO criticality calculations and the second consists of CASMO-PDQ calculations at the beginning of Pilgrim 1 cycle 4.
3.1 CASMO Criticality Calculations A number of CASMO criticality calculations for unif rm moderated
- lattices have been performed on pin cell geometry using the 25 energy group J
library and the experimental criticality data of Reference 4. Table 1 lists the re-sults of this analysis. Considering all the cases analyzed, the calculations result in a Keff mean value of 1.00076 with a standard deviation of a sample about the mean of 2.00617 which is in very good agreement with the criticality data.
T 3.2 Pilgrim 1 BOC-4 Critical Calculations Five cold critical states from the beginning of cycle 4 of Pilgrim 1 were used to test the accuracy of the method. Quarter core PDQ calculations, using CASMO generated cross sections, were performed in order to calculate the effect-ive multiplication factor. The calculations used the control rod positions and coolant temperatures of the BOC-4 critical states. The date from the cold critical. states are shown on Tables 2 through 6. Figure 1 shows the cycle 4 assembly layout from Reference 5, and the beginning of cycle 4 assemblywise exposure distributions from the plant process computer. The fuel assembly 1
design parameters were obtained from References 6,7, and 8.
For the first critical state two group average macroscopic cross sections were generated for the fuel types and conditions shown on Table 7. Similar cross section sets were generated for the remaining critical states using their respective coolant temperatures. The water cross sections were calculated in CASMO, by flux and volume weighting the wide and narrow water gap cross sections of 8DB219 assembly at the critical state coolant temperature.
1542 125
TABLE 1 CASMO Criticality Calculations for Uniform Water - Moderated Lattices CASE CASMO Keff 9 1.00290 10 1.00323 11 1.00096 12 1.00801 13 1.01141 14 1.00909 -
15 1.00071 16 .99561 17 1.00590 18 1.00401 19 1.00246 20 .99380 21 .99473 22 .99384 23 .99337 24 .99213 1542 126
TABLE 2 CRITICAL STATE 1 BOC-4 Pilgrim 1 Date 11-14-77 Coolant Temperature 157 F 3
Control Rod Notch Position Withdrawn 51 48 0 48 0 48 0 48 47 4 0 0 0 4 0 0 0 4 43 48 0 48 0 48 0 48 0 48 0 48 0 0 0 8 0 0 0 4 0 0 0 4 39 4 35 0 48 0 48 0 48 0 48 0 48 0 48 0 31 0 0 4 0 0 0 8 0 0 0 8 0 0
. 27 0 48 0 48 0 48 0 48 0 48 0 48 0 23 0 0 8 0 0 0 4 0 0 0 4 0 0 19 0 48 0 48 0 48 0 48 0 48 0 48 0 15 4 0 0 0 4 0 0 0 8 0 0 0 4 11 48 0 48 0 48 0 48 0 48 0 48 07 4 0 0 0 4 0 0 0 4 03 48 0 48 0 48 0 48 02 05 10 14 18 22 26 30 34 38 42 46 50 1542 127 m
^
TABLE 3 CRITICAL STATE 2 BOC-4 Pilgrim 1 Date 11-15-77 Coolant Temperature 2890F Control Rod' Notch Position Withdrawn 51 48 0 48 0 48 0 48 47 12 0 0 0 12 0 0 0 12 43 48 0 48 0 48 0 48 0 48 0 48 39 12 0 0 0 12 0 0 0 12 0 0 0 12 35 0 48 0 48 0 48 0 48 0 48 0 48 0 31 0 0 12 0 0 0 20 0 0 0 12 0 0 27 0 48 0 48 0 48 0 48 0 48 0 48 0 23 0 0 12 0 0 0 12 0 0 0 12 0 0 19 0 48 0 48 0 48 0 48 0 48 0 48 0 15 12 0 0 0 12 0 0 0 12 0 0 0 12 11 48 0 48 0 48 0 48 0 48 0 48 07 12 0 0 0 12 0 0 0 12 03 48 0 48 0 48 0 48 02 06 10 14 18 22 26 30 34 38 42 46 50 1542 128
TABLE 4 CRITICAL STATE 3 BOC-4 Pilgrim 1 Date 11-16-7 7 Coolant Temperature 180 F Control Rod Notch Positions Withdrawn 51 48 0 48 0 48 0 48 47 8 0 0 0 8 0 0 0 8 43 48 0 48 0 48 0 48 0 48 0 48 -
39 8 0 0 0 8 0 0 0 8 0 0 0 8 35 0 48 0 48 0 48 0 48 0 48 0 48 0 31 0 0 8 0 0 0 10 0 0 0 8 0 0 27 0 48 0 48 0 48 0 48 0 48 0 48 0 23 0 0 8 0 0 0 8 0 0 0 8 0 0 19 0 48 0 48 0 48 0 48 0 48 0 48 0 15 8 0 0 0 8 0 0 0 8 0 0 0 8 11 48 0 48 0 48 0 48 0 48 0 48 07 8 0 0 0 8 0 0 0 8 03 48 0 48 0 48 0 48 02 06 10 14 18 22 26 30 34 38 42 46 50 1542 129
_9_
TABLE 5 CRITICAL STATE 4 BOC-4 Pilgrim 1 Date 11-19-77 Coolant Temperature llioF Control Rod Notch Positions Withdrawn 51 48 0 48 0 48 0 48 47 0 0 0 0 0 0 0 0 0 -
43 48 0 48 0 48 0 48 0 48 0 48 39 0- 0 0 0 4 0 0 0 4 0 0 0 0 35 0 48 0 48 0 48 0 48 0 48 0 48 0 31 0 0 4 0 0 0 4 0 0 0 4 0 0 27 0 48 0 48 0 48 0 48 0 48 0 48 0 23 0 0 4 0 0 0 4 0 0 0 0 0 0 19 0 48 0 48 0 48 0 48 0 48 0 48 0 15 0 0 0 0 0 0 0 0 4 0 0 0 0 11 48 0 48 0 48 0 48 0 48 0 48 07 0 0 0 0 0 0 0 0 0 03 48 0 48 0 48 0 48 02 06 10 14 18 22 26 30 34 38 42 46 50 1542 130
TABLE 6 CRITICAL STATE 5 BOC-4 Pilgrim 1 Date 11-25-77 Coolant Temperature 1370F Control Rod Notch Positions Withdrawn 51 48 0 48 0 48 0 48 47 4 0 0 0 4 0 0 0 4 43 48 0 48 0 48 0 48 0 48 0 48 39 4 0 0 0 4 0 0 0 4 0 0 0 4 35 0 48 0 48 0 48 0 48 0 48 0 48 0 31 0 0 4 0 0 0 8 0 0 0 4 0 0 27 0 48 0 48 0 48 0 48 0 48 0 48 0 23 0 0 4 0 0 0 4 0 0 0 4 0 0 19 0 48 0 48 0 48 0 48 0 48 0 48 0 15 4 0 0 0 4 0 0 0 4 0 0 0 4 11 48 0 48 0 48 0 48 0 48 0 48 07 4 0 0 0 4 0 0 0 4 03 48 0 48 0 48 0 48 02 06 10 14 18 22 26 30 34 38 42 46 50
!542 131
FIGURE 1 ,
PILGRIM BOC-4 26 1 2 3 4 b5 6 7 8b9 to b1 19
/L L k/ L L () L L /L L (./ L L\/H 2 \/L 1 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 6.3 0.0 L 1 H 1 H 1 H 2 H 2 H 2 L 2
C/ L
' "'\#' ' ' ' ' '^' ^ "*
H L H L H \ L H L Hk L 2 \/ L -
3 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 5.3 0.0 4 L 1 H 2 H 2 H 2 H 2 H 2 L g 0.C10.p g 0. 0 7.1n .0 7.3g(. 0 7.2g.0 6.{0.0 3.6 0.0 0
%)L H() L H () L H () L H() L H() L 2(
5 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 6 .2 0.0 6 L 1 H 2 H 2 H 2 H 2 H 2 L g0. C 9.7gg0.0 6.7g.0 6.9gg0.0 7.4 0.0 6. 0.0 5.8 0.0
/L N/L H\/ L HVL H(/ L H() 2 L(
7 0.0 0.0 0.0 0.0 0 .0 0.0 0.0 0.D 0.0 0.0 5.6 0.0 0.0 H 2 H 2 H 2 L 8
g 0. C 7.1r .0 7. P g0. 0< 6.3g g0 .0 6. ), g 0. 0 5.h0.0
/L H\/ L H(./ L H (./ L H() L L() L 9 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 L 2 H 2 H 2 H 2 L Assembly Type 10 y.0 67'%0.0 6.f TO.05. 7 /" %0. 0 6./r5 0.C Average Exposure GWD/T C/ H Hk/L Hk./L H() 2 L\. 4 11 0.0 0. 0 0.0 " 0. 0 5.5 0.0 0.0 0.0 0.0 2 2 2 2 2 2 L 12 4.(y'9 1 3.p y.9 5 7 g0.0 50 (%5.8 L L \/ L Lk/ L L \/ L 13 0.0 0.0 0.0 0. 0 0.0 0. 0 0.0 NUMBER IN CORE 1- 8DB262 20 2- 8DB262 132 L- 8DB219L 244 H- 8DB219H 184 TOTAL 580
}Q
TABLE 7 s
Cross Section Sets Generated by CASMO for Critical State 1 Fuel Type Exposure Void Mod T. Fuel T EQ.Xe Control (GWD/MT) (OF) (OF) 8DB219L 0 0 157 157 No No 8DB219L 0 0 157 157 No Yes 8DB219H 0 0 157 157 No No 8DB219H 0 0 157 157 No Yes -
8DB262 4 0 157 157 No No 8DB262 4 0 157 157 No Yes 8DB262 7 0 157 157 No No 8DB262 7 0 157 157 No Yes 8DB262 11 0 157 157 No No 8DB262 11 0 157 157 No Yes 1542 133 I
The calculation of the effective multiplication factor for each critical state should be estimated by performing three dimensional calculations so that the partially withdrawn control rods will be accurately represented. Since three dimensional calculations are prohibitively expensive the' effective mult-iplication factor was estimated by performing two dimensional PDQ calculations.
First, a quarter core PDQ calculation was performed having fully inserted all the fully inserted and all the partially withdrawn control rods for the criti-cal state. Second, another quarter core PDQ calculation for the same critical state was performed having fully inserted all the fully inserted control rods, while all the partially withdrawn rods were fully withdrawn. The above PDQ calculations provide effective multiplication factors Keffl and Keff2 which ~
satisfy the following relation:
Keffl 4 Keff (critical state)( Keff 2 Since two dimensional PDQ calculations can not account for the reactivity contributions of the withdrawn notches an estimate of Keff (critical state) is obtained by adjusting Keffl . The adjustment to Keffl is estimated assuming that the reactivity worth of the partially inserted control rods is proportional to the number of notches they are inserted. For example, consider critical state 1 Keffl = .998248 Keff2 =1.019404 from Table 2 it can be seen that there are 20 partially withdrawn control rods.
The worth of these control rods when fully inserted is -2.07897%4f. In critical state 1 these control rods are withdrawn a total of 100 notches out of the 960, therefore, the reactivity adjustment to Keffl is:
1 2.07897 x = .216559%or 1542 134
Consequently, the estimated Keff (critical state 1) = 1.000411. Table 8 shows the results of all the benchmark calculations. The value of the est-imated Keff depends on the coolant temperature. To understand the sensi-tivity to the coolant temperature, the calculation of critical state 1 was repeated at 137 F. The estimated Keff's for the two critical state 1 cal-culations are:
Keff (157) = 1.000411 Keff (137) = 1.003871 From these Keff's it is seen that for a -20 F change in the coolant temper-ature the estimated Keff changes only by +.35%. In addition, this brief calculation shows that the moderator temperature coefficient at BOC-4 conditions is negative. The negative moderator temperature coefficient
, suggests that the multiple controlled cell removal analysis be performed at 680F coolant temperature. From Table 8 and the results of the above calcul-ation it is concluded that the method used in the benchmark calculation is acceptably accurate.
1542 135
_g- y y y y y TABLE 8 Results of The Benchmark Calculations Partially Withdrawn Rods Reactivity 1 Keff 2 Reactivity Notches Notches Adjustment Estimated Mod Keff Temp Worth (Af %) When With- to Keff I Critical Fully In Fully In drawn ( Af %) State Keff 0F
-2.078970 960 100 .216559 1.000411 Critical State 1 157 .998248 1.019404
-2.294662 960 254 .607519 .991992 Cr Rical State 2 289 .986049 1.008876
-2.111127 960 162 .356253 .999894 180 .996345 1.017753 i Critical State 3
-1.744523 384 32 .145377 1.002122 Critical State 4 111 1.000665 1.017068
-2.110436 960 84 .184663 1.003517 Critical State 5 137 1.001661 1.023293 4
N Ch I
4.0 Multiple Controlled Cell Removal Analysis The results of the benchmark calculations have shown that the method used is acceptably accurate and for this reason it can be applied to the multiple controlled cell removal analysis.
The objective of this analysis is to show that at any cycle of Pilgrim 1 removal of one or more controlled cells at a time always leads to a more sub-critical state. This objective will be achieved in three steps. First, the effect of multiple control cell removal is evaluated at cold (680F), Xenon-free conditions at the beginning-of-cycle 5 core loading configuration, which is a typical and representative reload configuration for Pilgrim 1. A sufficient _
number of cases are evaluated to verify that all representative conditions of removal of one or more controlled cells have been examined. It will be con-cluded that all representative combinations of controlled cell removals at BOC-5 lead to a more subcritical state. Since beginning-of-cycle is not the most reactive state in cycle 5, because of the gadolinia depletion effect, the second step of the analysis is to demonstrate that the conclusion reached in the first step is valid throughout cycle 5. Finally, the third step of the analysis is to demonstrate that the conclusion reached for cycle 5 is a general conclusion which applies to all cycles.
Figure 2 shows the BOC-5 core loading configuration for Pilgrim 1. This loading pattern is typical of reload cores which are loaded in a quarter-core sy= metric, scatter pattern of high and low reactivity bundles. As such, the reactivity worth of individual four bundle cells varies from cell to cell.
Removal of a controlled cell affects the reactivity of not only the cell which is removed, but also the adjacent cells as well. Before reaching any general conclusion on the effects of controlled cell removal, a sufficient number of cases must be examined to span the range of combinations repre-sentative of the core configuration, e.g. high reactivity cell adjacent i542 137
FIGURE 2 PILGRIM 1 BOC-5 26 1 2 3 4 b5 6( 7 8b9 10 b1 19
/3 2H k / FH 3()3 2H \./ FH 3()3 2H\ / FL 2H\/2L 1 i L4. 0 9.4 0.0 13.4 15.6 9.6 0.0 14.1 15.2 10.9- 0.0 11.2 11.2 2H FH 2L FH 2L FH 2L FL 2L FL 2L FL 2L 2 9.7 0.0 0.0 6.3 0.0
.0 .9 ). 0 5.9 0. 5.6 0.0 .5 _
/FH 26 / FH 2L( / FH 2H ( /FH 2Hb M 2L \ /FL FL\./2H 3 0.0 9.3 0.0 10.1 0.0 10.7 0.0 9.9 0.0 11.6 0.0 0.0 11.0 4 3 FH 2L 3 2L FH 2L 3 2L FL 2L 2L 2L (3.6 0. H 0.3 13 g l.6 0.0 g y.9 L3.p g11 .( 0. 0g. 0 6.2g 1.5 A. ) 3 2L ( /FH 2H() 3 2H(,)FL 2L ( / 3 2H(,/FL 2L(, H S
15.6 6.2 ). O 11.0 15.4 10.2 0.0 10.5 14.2 10.6 0.0 10.f 11.( i 6 2H FH 2H FH 2H FL 2L FL 2L FL 2L 2H 2L
.5 0. M O.70.0r 0.1 0. '.0 3.O n 6.0 0. 0g. 6 38 All 2L\.2H 2L(,hL 2L(,/ FL 2 A / FL FL ( J2H 11/ 1.3 7 0.0 4.1 0.0 6.2 0.0 8.3 0.0 10.6 0.0 0.0 10.6 2L(
11.] 11.1 3 FL 2H $ zL FL 2H 2H 2H 2L 2L 8
4.CO.0 g .2 13.y0.2 0.0g0.3 11. g l.3
- 3. H 1.4
/3 2L( / FL 2L (./ 3 2L (./ FL 2H(.)2L 2L(./ 2L 9 15.2 6.1 0. 0 10.9 14.7 5.7 0.0 11.2 10.1 11.5 11.4 2H FL 2L FL 2H FL FL 2L 2L 10 Assembly Type 0.8 0.p(1.6 0. % 0.3 0.0g 0
.0 3.H1.5 Average Exposure GWD/T
/FL 2L(/ FL 2L ( / FL 2L(./2H 2L\../2L 11 0.0 6.2 0. 0 4.9 0.0 6.0 10.211.5 11.5 2H FL FL 2L 2L 2H 2L 12 fl. 2 0. H .0 5. M 1.0 11.h11.C J2L 2L() 2H 2L(/ 2H 2L (,/2L 13 11.111.5 11.1 11.5 11.0 11.3 11.3 Number in Core FH P8DRB282 64 FL P8DRB265L 120 2H - 8DB219H 124 2L - 8DB219L 212 3 - 8DB262 60 TOTAL 1542 138 380
to high reactivity cell, high reactivity cell adjacent to low reactivity cell, edge cell, interior cell, multiple cells,etc.
The cases which were evaluated and the resultant core K-effectives are shown in Table 10. The effect of removing one, two or three cells was examined by performing full core PDQ calculations. The remaining multiple cell removal cases, where 4 or 8 or 16 symmetric cells were removed at a time, were evalu-ated by performing quarter core PDQ calculations. The assembly design para-meters were obtained from References 7, 8 and 9. Table 9 shows the fuel types and conditions for which average macroscopic cross sections were generated for the analysis. The water cross sections were generated in CASMO by flux and vol _
ume weighting the wide and narrow water gap cross sections of an 8DB219L assembly. To verify that the water cross sections have been properly determined a parametric study was performed and it is shown in Appendix A. The first case shown in Table 10 is the all-rods-in case with no cell (s) removed. The remaining cases are for various combinations of controlled cells removed. All cases in Table 10 were analyzed in quarter core geometry, except cases 14, 15 and 16 which were analyzed in full core geometry. From Table 10 it can be seen that for all cases considered the reactor reaches a more suberitical state after controlled cell removal as compared to the all-rods-in case with no cell (s) removed. The reactivity loss per cell removed for the various cases in Table 10 is plotted as a function of distance from the core center in Figure 3. From Figure 3 it can be seen that the reactivity loss is always positive and it is higher for cells removed closer to the core center. There are no anomalous points to suggest a need to consider additional cases. Since the removal covers unifo rmly the distance from the center to the core periphery, there is reasonable assurance that any other cells that have not been analyzed will follow the trend seen in Figure 3. It is therefore concluded that all representative combinations of controlled cell removals at BOC-5 lead to a more suberitical state.
1542 139
TABLE 9 Cross Section Sets for Multiple Controlled Cell Removal Analysis Assembly Type Cross Section -
First Sten 8DB262 2G, Controlled, 680F, 13.5 and 15 GWD/MT 8DB219L 2G, Controlled, 680F, 4,6 and 11 GWD/MT 8DB219H 2G, Controlled, 680F, 9.9 and 10.9 GWD/M P8DRB265L 2G, Controlled, 680F, O GWD/MT 78DRB282 2G, cont.olled, 68 F,0 O GWD/MT Second Step P8DRB265L 2G, Controlled, 68 F,0 O GWD/MT , No Gd P8DRB282 2G, Controlled, 680F, O GWD/MT , No Gd Third Step P8DRB282 2G, Controlled, 680F, O GWD/MT , No Gd 8DB219L 2G, Controlled, 680F, 30 GWD/MT 1542 140
TABLE 10 Multiple Controlled Cell Removal BOC-5 Results Cells Removed Keff
- 1. None .945166
- 2. 35-26, 27-34 .937744
- 3. 31-3U .939369
- 4. 47-42, 43-46 .944748
- 5. 39-30, 31-38 .931509
~
- 6. 51-30, 31-50 .944373
- 7. 35-30, 31-34 .934888
- 8. 35-34 .937729
- 9. 31-26, 27-30 .940316
- 10. 43-34, 35-42 .940103
- 11. 43&47-30, 31-42646 .938685
- 12. 43-30, 31-42 .938803
- 13. 27-26 .942571
- 14. 31-30 UL* Full Core .943292
- 15. 31-30 UL & UR* Full Core .942032
- 16. 31-30 UL & UR & Ll Full Core .940502
- UL - upper left, UR - upper right, LL - lower left 1542 141
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The beginning-of-cycle is not the most reactive state of the core in cycle 5. The most reactive state is reached when the reload bundles reach their peak reactivity as the gadolinia burn out. To examine whether the con-clusion just reached is valid throughout cycle 5, it would require rerunning all cases, previously examined, but with new cross section sets updated for various cycle 5 exposure increments. An alternate approach and the one which is used herein is to make a conservative bounding calculation. The matter at issue is quite simply-is there a reactivity loss or is there a reactivity gain for controlled cell removal at the time the core is at its most reactive state in the cycle? If there is a reactivity gain, then one is concerned with the absolute value of Keff, since there is danger of inability to maintain shutdown margin. However, if there is a reactivity loss, then the absolute value of Keff is inconsequential since the results are in the conservative direction. The method used in this analysis to maximize the reacitivity state of the core for cycle 5 is to examine the case in which previously exposed bundles are assumed to remain at the BOC-5 exposure and the new reload bundles are assumed to have no gadolinia at zero exposure. This results in a reactivity of the reload bundles which is much greater than would ever be achieved in a normal cycle, and conseq-uently a core reactivity state which is more reactive than any time in cycle 5.
Using the method just described, the first three cases from Table 10 were reanalyzed and the results are shown on Table 11. The cells which are assumed to be removed were selected because they are near the center of the core which is a high reactivity worth area. As can be seen, the core loses reactivity as control cells are removed. This demonstrates that the conclusion previously reached for beginning of cycle 5 is valid throughout the cycle.
The last issue to be addressed is whether this conclusion is valid for all cycles. This is verified by bounding the range of bundle enrichments which might be loaded in subsequent reloads and by evaluating the controlled cell removal 1542 143
TABLE 11 Multiple Controlled Cell Removal BOC-5 Fresh Assemblies Without Gd Cells Removed Keff
- 1. None 1.022974
- 2. 31-30 1.012614
- 3. 35-26, 27-34 1.011246 1542 144
effect. The maxinum enrichment available for Pilgrim is that of the P8DRB282 bundle. In this analysis the maximum enrichment is bounded by assuming that the bundle contains no gadolinia. The first bounding case evaluates the removal effect assuming a full core of fresh P8DRB282 bundles without gadolinia. The results of this analysis are shown on Table 12 and the reactivity loss as a R
function of distance from the core center has been plotted on Figure 3. From Figure 3 it can be seen that the results of this fictitious cycle follow the trend established by the B0C-5 results. The second bounding case (the most conservative one) evaluates the effect of removing a single highly burned cell (consisting of four 8DB219L bundles at 30 GWD/MT in position 35-34) from a quarter-core of fresh P8DRB282 bundles without gadolinia. The results of this ~~
analysis are shown on Table 13. From Tables 12 and 13, it can be seen that the core reaches a less reactive state after the removal. Since the results of Tables 12 and 13 conservatively bound all future Pilgrim 1 cycles it is concluded that the removal of one or more controlled cells from any cycle of Pilgrim 1 will not violate shutdown margin requirements because it leads to a more sub-critical state.
1542 145
=@ e . p.m ,
-i---. -- -- um
TABLE 12 Multiple Controlled Cell Removal Fictitious Cfele With Fresh P8DRB282 Fuel No Cd Cell Removed gegf
- 1. None 1.140383
- 2. 43&47-30, 31-42646 1.133016
- 3. 31-30 1.132806
~
- 4. 35-30, 31-34 1.126882
- 5. 31-26&30, 27-30 1.132351
- 6. 43-30, 31-42 1.133149
- 7. 35-34 1.130278 1542 146
--e-
I TABLE 13 I
Multiple Controlled Cell Removal -
I Fresh Core of P8DRB282 With One Highly Burned 8DB219L I
Cell Removed Keff I 1. None 1.131706 I 2. 35-34 1.130278 I
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I 1542 147 g
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I .- - . . _ ___ ._.
I I 5.0 conclusion The analysis presented in this report shows that the method used is acceptably accurate and that removal of more than one controlled cell at a time, from any cycle of Pilgrim 1 at shutdown conditions, does not violate the shutdown margin requirements because it leaves the reactor in a more sub-I critical state.
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I 2e.
APPENDIX A I After the removal of a controlled cell the volume is filled with water.
The water cross section for PDQ are calculated in CASMO by flux and volume weighting the wide and narrow water gap cross sections. Keeping in mind that these gaps are small compared to the controlled cell volume, one might question whether these cross sections are appropriate. To answer this question two sets of water cross sections were generated for BOC conditions at 680F one using the standard narrow and wide gap dimensions and the other using 10 cm and 12 cm thickness for the narrow and wide water gaps respectively. The results of this study is shown on Table 14. From Table 14 it can be concluded that for _
this analysis the water cross sections are not very sensitive to the water gap dimensions.
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TABLE 14 Water Cross Section Parametric Study Keff Standard Size 12 cm Wide Gap Cells Removed Gaps 10 cm Narrow Cap
- 1. None .945091 .945026
- 2. 31-30 .939373 .939002 1 _
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References
- 1. C.E. Beyer, C.R. Hann, D.D. Lanning, F.E. Panisko and L.J. Parchen,
" User's Guide for GAPCON-Thermal 2: A computer Program for Cal-culating the Thermal Behavior of an Oxide Fuel Rod", BNWL-ll897, November, 1975.
- 2. A. Ahlin, M. Edenius, H. Haggblom, "CASMO A Fuel Assembly Burnup Program", Studvic Report AE-RF-76-4158 (Rev. Ed), June, 1978.
- 3. W.R. Cadwell, "PDQ-7 Reference Manual", WAPD-TM-678 (1967).
- 4. L.E. Strawbridge and R.F. Barry; " Criticality Calculations for Uniform Water - Moderated Lattices", NSE, 23,58-73 (1965)
I 5. Reload No. 3 Licensing Submittal for Pilgrim Nuclear Power Station Unit #1, May 1977, NEDO-21462-01.
I 6. Pilgrim Reload No. 3 Revision 1, Nuclear Design Report, August 1977, NEDE-21512. -
- 7. Pilgrim Reload No. 1, Nuclear Design Report, March 1974, NEDE-20354.
- 8. BWR/4 and BWR/5 Fuel Design, October 1976, NEDE-20944-P.
- 9. Generic Reload Fuel Application, Licensing Topical Report NEDE-2_40ll-P.
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