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BE77 BE78 Calvert Cliffs Nuclear Power Plant Sub-Batch; BE77 Type

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Calvert Cliffs Nuclear Power Plant GUIDE TUBE TOP VIEW FUEL ROD SPACER GR l D FLOW HOLES - BOTTOM VIEW ORIGINALLY A RETENTION GRI NOW A GUARDIAN GRID (Westinghouse) or an Alloy 718 HMP grid in AREVA HTP Fuel \\ UPPER END \\ FIITING 15711 136.. 7'° Rlllllllllllll ACT IVE >,  ,,,, LENGTH LOWER END FITIING FUEL ASSEMBLY Figure 3.3-5 Revision 43

3.3-6 FUEL ASS EM BL y HOLD DOWN BAL. TiMORE GAS & ELECTRI:: CO. C:al vert Cliffs Nui:Iear Power Plant Fuel Assembly Hold Down Figure Rev.a

Calvert Cliffs Nuclear Power Plant Grid Perimeter Strip CEA Guide Tube Location. CANTILEVER TAB FUEL SPACER GRID Figure 3.3-7 Revision 32

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3.3-8 CONTROL ELEMENT ASSEMBLY (CEA) BALTIMORE GAS & ELECTRIC CO. Calven Cliffs Nuclear Power Plant 11* .1 II I. CONTROL ELEMENT ASSEMBLY (CEA) FIGURE 3.3-8 Rev. O 1/82 Rev.a

x ABBREVIATIONS FULL LENGTH FLCEA1 ISTANOAROJ FLCEA2 CRECONSTITUT ABLE CORNER F'INCERS> FLCEA8 CNON-RECONSTITUT ABLE> FLCEA7 INON-RECONSTITUT ABLE> NOTES: O" Ill I I -ZONE A ZONE 8 MATERIALS 12' 132" I I ZONE A ZONE B (1) ZONE "A" IS 8" f"OR f'LCEA1, f'LCEA2, AND f'LCEA7, AND 12" f'OR f'LCEA8. <2> 8*84 C Ag*Ag-111-Cd Al*Al203 S/S*Stoinless Steel Calvert Cliffs Nuclear Power Plant WESTINGHOUSE/ ABB-CE CONTROL ELEMENT ASSEMBLIES Figure 3.3-9A Revision 49

x ABBREVIATIONS FULL LENGTH FLCEA10 IAREVA full Strength> <Non-Reconstitutoblel FLCEA9 IAREVA Port Strength) INon-Reconstitutoblel NOTES: O" I I -ZONE A C1) ZONE "A" IS 12.5" FOR FLCEA10 AND FLCEA9 <2l 8*84 C Ag*Ag-In-Cd S/S*Stoinless Steel 111 ZONE A 133.!I" ZONE 8 MATERIALS 121 ZONE B131 C3l ZONE "B" STARTS 0.355" ABOVE ZONE "A" FOR ALL FLCEAlO RODS AND ONLY THE CENTER ROD FOR FLCEA9 I I Figure 3.3-98 Calvert Cliffs Nuclear Power Plant AREVA /FRAMATOME CONTROL ELEMENT ASSEMBLIES Revision 49

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3.3-14 UPPER GUIDE STRUCTURE ASSEMBLY FUEL ASSEMBLY ALIGNMENT PLATE L M Ii I EXAINSION CIJMP£HSATlllG A/NG GAS & ELECTRIC CO. Calvert Cliffs Nuclear Power Ph.mt UPPER GUIDE STRUCTURE ASSEMBLY Fgure 3.3-14 -ge.visi on 21 Rev. 21

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• Due to com redesign, Unit 1 Cycle 25 will not be qua.rtat 00!'$ $)plmetric.

UNIT 1 Cycle 25 Calvert Cliffs Quarter-Core Assembly Map Figure 3.4-4 Nuclear Power Plant Revision 52

45 885 54 BD1 c:r-Box Numbe Y-B*tCh 8 ac2 14 15 BB1 BE5 21 22 23 AB1 BE5 804 29 30 31 803 BE3 BE1 37 38 39 AE1 BE3 BD2 46 47 48 BE4 804 BE2 55 56 57 BE5 804 BD1 3 AC1 9 BE5 16 904 24 BE2 32 801 40 BE76 49 801 58 BE2 1 2 BB1 803 4 5 6 7 803 AE1 BE4 BE5 10 11 12 1 3 BE3 BE3 804 804 17 18 19 20 8E1 BD2 BE2 801 25 26 27 28 802 BE75 BD1 BE2 33 34 35 36 8E1 BD2 BE1 .803 41 42 43 44 802 BE1 BD2 8E1 50 51 52 53 8E1 802 BE2 803 59 60 61 52 BD3 BE1 803 805 Unit 2 Cycle 24 is oot qua.rter corn symme1ric The LT A is in location L-20 {not slmW'fl ). UNIT 2 Cycle 24 Calvert Cliffs Quarter-Core Assembly Map Figure 3.4-5 Nuclear Power Plant Revision 52

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• C>ue to core redesign, Unit 1 CycJe 25 w.ill not be quarter core S)fnmetric.

UNIT 1 Cycle 25 Calvert Cliffs Assembly Relative Power Density at BOC, HFP, ARO, Figure 3.4-7 Nuclear Power Plant Equilibrium Xenon Revision 52

[;:] X-Box Number 1 2: Y - Batch BB1 803 XXX - Assembly Relalive Power 0.248 0.443 Dens11v 3 4 5 6 7 AC1 BD3 AE1 BE4 BES 0.275 0.515 0.661 1.041 1.176 8 9 10 11 12 13 BC2 BES BE3 BE3 804 804 0.332 0.946 1.190 1.2B2 1.187 1.199 14 15 16 17 18 19 20 BB1 BES 604 BE1 802 BE2 801 0.334 0.968 1.129 1.294 1.131 1.. 265 1.105 21 22 23 24 25 26 27 28 AB1 BE5 804 BE2 802 BE75 801 I BE2 0.26S 0.944 1.128 1.257 1.110 1.236 1.097 1.247 29 30 31 32 33 34 35 36 803 BE3 BE1 BD1 BE1 BD2 8E1 803 0.515 1.189 1.294 1.115 1.268 1.102 1 -27{) 1.144 )( 37 38 39 40 41 42 43 44 AE1 BE3 BD2 BE76 BD2 BE1 802 BE1 45 0.663 1.280 1.130 1.241 1.116 1.258 1.10() 1.274 BB5 0.259

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X-BoxNl.Wllhor 1 2 Y-Batch AD4 884 xxx -Assembly Relative Power 0.224 U.318 Densilv 3 4 5 6 7 AD4 AE1 AF12 AF5 AF4 0.266 0.485 0.575 0.983 1.023 8 9 i 10 11 12 13 A04 AF5 AF4 AF4 AE4 AES 0.346 0.976 1.242 1.282 1.005 0.981 14 15 16 17 18 nr 20 A04 Af 5 AE5 AF1 AE2 AF1 AE3 0.346 0.982 1.046 1.394 1.068 1.330 1.062 21 22 23 24 25 26 27 28 AD4 AF5 AE5 AF3 AE3 AF1 AE1 AF1 0.268 0.974 1.048 1.356 1.121 1.402 1.073 1.385 29 JU 31 32 33 34 35 36 AE1 AF4 AF1 AE3 AF3 AE2 AF3 A.f2. 0.477 1.235 1.392 1.121 1.415 1.096 1.400 1.096 37 36 39 40 41 42 43 44 BB5 AF4 AE1 AF1 AE1 AF1 AE3 AF3 45 0.004 1.259 1.065 1.403 1.098 1.417 1.114 1.397 BA6 x 0.214 46 47 48 49 fJ() 51 52 53 AF5 AE4 AF1 AE1 f\\F3 AE3 AF2 AE1 54 0.967 1.004* 1.330 1.073 1.-Ml2 1.115 1.374 1.046 1\\81 0.311 55

56.

57 58 59 60 61 62 AF4 AE5 AE3 Af 1 AE2 AF3 AE1 Af 6 1.031 10.982 1.062 1.385 1.094 I 1.397 1.046 1.122 Long N1 Burrup (21... 715 GWd/MTU) Note: X = Maximum Fr Value = 1.514 UNIT 1 Cycle 25 Calvert Cliffs Assembly Relative Power Density at Figure 3.4-10 Nuclear Power Plant 10,000MWd/MTU, HFP, ARO, Equilibrium Xenon Revision 52

45 BB5 0.262 54 BD1 0 421 21 AB1 0.305 29 BD3 0.533 37 AE1 0.638 46 BE4 1.000 55 BE5 1.121 X - Box Number Y-Batch XXX - Assembly Relative Power Density B SC2 0.369 14 15 BB1 BE5 0.374 1.051 22 23 BES BD4 1.042 1.101 3 4 AC1 BD3 0.309 0.530 9 10 BE5 BE3 1.041 1.244 16 17 1304 BE1 1.100

• 1.367 24 25 8E:2 BD2 1.367 1.032 1

2 BB1 BD3 0.251 0.432 5 6 1 AE1 BE4 BE5 0.636 1.002 1.120 11 12 13 BE3 804 804 1.274 1.048 1.028 18 19 20 802 BE2 B01 1.081 1.. 318 1.018 26 27 28 BE75 BD1 Bf2 1.342 1.060 1.334 30 I 31 32 33 34 35 36 BE3 I BE1 801 BE1 BD2 BE1 BD3 l 1.24 I 1.3ea 1.086 1.32s 1.055 1.305 1.os1 I

• • • -*-... _=-_J.

__..x_ _________ ---****-***********---*-*****----

• 1.062 1.309 1.038 1 285 1.047 I I

56 157 58 59 60 61 62 804 801 BE2 BD3 BE1 803 BD5 1.028 1 018 1.334 1.081 1.290 1 047 0.810 I Long N-1 Burnup (22.0BO GWdfMTU} Note: X =Maximum Fr Value= 1.501 Calvert Cliffs Nuclear Power Plant UNIT 2 Cycle 24 Assembly Relative Power Density at 10,000MWd/MTU, HFP, ARO, Equilibrium Xenon* Figure 3.4-11 Revision 52

 0 § z c CJ) o osiom iii' !"I!! -u::i.ma:: !oo ... §I i!! :u "'O ur om  a 0 0 r-mm z.... ?o 00 ,,.:D om -< -0 oo r- =E !" m m.:n () 0 c: - (J) r- -f

0 OJ -

D OJ

-c c -t 3: - >< 0 mZ ZN 0 U1 z2 31::

E

-i 0

uc

& ti (A Of'.... I\\) USENRICHMENT TYPE BOX PEAKING FACTOR ENTHALPY RISE PIN PEAKING FA MAXIMA BOX PEAKING FACTOR ENTHALPY RISE FACTOR PIN PEAKING FACTOR 8 10 CL --- c 0.57 0.94 0.95 c o.73 1.02 I. 03 A JR c 0.65 1.02 1.03 c C* 0.65 I.OS 1.02 I. 24 1.03 I. 29 c C* a+ o.ss

1. 0 1 I.OB

0. 91

1. 21 I. 17 0.92 t.25 I. 21 c

8+ A

0. 76

1. 02

1. 03 I. 05

'* 14 1.09 1.06 I. 17

1. 11 Ct IA B+

. 0.97 1.01 I. 14 '* 22 1.00 '* 20

• • 26 I. 10 1.24 c+

8+ A

• • 14 I. 14 I. 07

1. 29

t. 20 I. 10 1.33 I. 24

1. 13 8+

A 8+ 1.os 1.06 I. 17

1. 17

l. 10 I. 21

1. 20

1. 13 I. 25 B

D c c o.ss 0.76

o. 91 1.05 0.92 1.06

c.

B+ 1.01 1.02

1. 2 1 I. 14 1-25 1-17 a+

A 1.08 1.03

1. 17 1.09

/ '* 21 I. 11 A 8+ 1.05 I. 15 1.09 I. 20

1. 12 1.24 8+

A I. 15 1.06

1. 20

1. 10 1.24

'* 12 IA I+ 1.06

1. 16 I. 10

1. 20

t. 12 I. 24 8+

A I. 16 1.06 I. 21 I. 10 I. 25

1. 12 A

8+ 1.07 I. 16 I. 10 '* 20

1. 13 1.24 E

F H K (: c o.s1 0.73 0.94 1.02 ft' Iii

1. 03 C+

c+ B+ 0.91

1. 14

1. 05 I. 22

'* 29 I. 17 I. 7.6 1.33 I. 20 A 8+ A 1.01 J. 14 1.06 1.08 I. 20 I. 10 I. 10 '* 24 I. 13 B+ A B+ I. 14 J.07 I. 17

1. 20

1. 10.

I. 21

1. 24

l. 13

'* 25 A 8+ A

t. 06

'* 16 t.07 '* 10 I. 21 I. JO

1. 12 I. 25

1. 13 B+

A B+ J. 16 1.06 I. 16

1. 20 I. 10 J. 20

1. 24 I. 12

1. 24 IA B+

IA 1.06 I. 15 1.05 I. 09 '* 20 I. 09

t. 12 I. 23 I. II D+

A B+ I. 15 1.04 I. 14

1. 20 I.OB I. 18

'* 23

1. 10 I. 22 IA B+

A 1.05 I. 14 I. 04 1.09 I. 18 1.07

1. It 1.22

'$*!

r.

I w f-N 2
3 4


0 0

  0 5 1 gj 2 6  z g 1 t:  c 9 i c x m z 11 %

• • -,--

[+/-;] X-Be< Number 1 2 Y-Batch AD4 BB4 XXX - Assembly Relative Power 0.332 0.456 Densitv 3 4 5 6 1 AD4 AE1 AF12 AF5 AF4 0.351 oüsaa 0.704 t127 1.169 8 9 10 11 12 13 AD4 AF5 AF4 AF4 AE4 AES OA35 1.044 1.228 1.273 1.056 1.049 14 . 15 16 17 18 19 20 AD4 Af 5 AE5 AF1 AE2 AF1 AE3 0.435 1.055 1-()51 1.313 1.038 1.288 1.054 )( 21 22 23 24 25 26 27 .28 A04 AF5 AE5 AF3 AE3 AF1 AE1 AF1 0.350 1.042 1.051 t294 1.000 1.293 1.023 1.290 29 30 31 32 33 34 35 .36 AE1 AF4 AF1 AE3 Af3 AE2 AF3 AE2 0.576 1_221 1.311 1.059 1.293 1.024 t285 1.027 37 38 39*** 40 41 42 43 44 B65 AF4 AE1 AF1 AE1 AF1 AE3 AF3 4:5 0.720 1.251 1.034 1.293 1.024 1.284 1-038 1.283 BA6 0.318 46 47 48 49 50 51 52 53 AF5 AE4 AF1 AE1 Af 3 AE3 N=2 Af1 54 1.108 Ul52 1.286 1J)23 1.285 1.038 1.276 0.998 AB1 0.447 55 56 57 58 59 60 61 62 AF4 AES AE3 Af 1 AE2 AF3 AE1 AF6 1.174 1Jl49 1.054 1.289 1.026 1.283 0.998 1.070 Longú 1 Bumup (21 -715 GWdlMTU} Noteû X = Maximum Fr Varue = 1.388 . Oue to core redesign. Ulit: 1 ()y(kl 2S Ml not be QUar1er core Sfnmetric. UNIT 1Cycle25 Calvert Cliffs Assembly Relative Power Density at EOC, HFP, Figure 3.4-13 Nuclear Power Plant Equilibrium Xenon Revision 52

X-Bo* Numbe< 1 2 Y-Batch 881 BD3 XXX -Assembly Relative Power 0.335 0.53a Density 3 4 5 s 7 AC1 BD3 AE1 BE4 BE5 0.365 0.599 0..114 1-102 1.100 8 9 10 11 12 13 BC2 BE5 BE3 BE3 804 BD4 OA11 1.024 1.216 1.247 1.042 1.027 14 15 16 n ta 19 20 881 BE5 BD4 BE1 802 BE2 BD1 0.418 1.018 1.037 'L301 1.036 1.277 0.996 21 22 23 24 25 26 27 28 AB1 BE5 B04 BE2 BD2 BE75 801 BE2 0.363 1.025 1.037 1.282 1.032 1.288 1.028 1.291 29 30 31 32 33 34 35 36 803 BE3 BE1 801 BE1 802 BE1 BD3 0.603 1.217 1.307 1.034 1.297 1.(}34 1.304 1.060 x 37 38 39 40 41 42 43 44 AE1 BE3 802 BE76 902 BE1 BOO BE1 45 0.711 1.248 1.036 1.289 1.041 L305 1.035 1306 BBS 0.349 46 47 48 49 50 51

52.

53-- 8E4 BD4 BE2 B01 BE1 802 BE.2 BD3 54 1.102 '1.040 1.276 1.028 1.304 1.035 1.287 1.046 B01 0.525 55 56 57 58 59 60 61 62 BES 804 B01 BE2 BD3 BE1 B03 BDS 1.160 1.027 0.996 1.291 1.000 1.306 1.047 0.857 Long N*1 Burnup (22.080 GWd/MTU) Note: X = Maximum Fr Value = 1.383 Unit 2 Cycle 24 is not quarter cae symmetric. UNIT 2 Cycle 24 Calvert Cliffs Assembly Relative Power Density at EOC, HFP, ARO, Figure 3.4-14 Nuclear Power Plant Equilibrium Xenon* Revision 52

o

!g I 0 G) z c: (/J Q.OQaDl (ti D> µ ip:! d1::imc

e oo

' !i:2:0 "'Diii 0m iii 0 a P 0 0

D m

- 0 G> :E _m z :D ao z Zm 0 (j) -t xOb m "" CJ z -n c: 0 - -t z :0 0 z

D

 0  o' -< 0 om r- > m G>

D 0

c: "'O OJ c.o :!! G>

tc OJ iR

,..--fNRICHMENf T x 0 00 BOX PEAKING F o: oo- *ENTHALPY RISE i...w.i.;..-;:_,1-P IN PEAK ING F MAXIMA BOX PEAKING FACTOR ENTHALPY RISE FACTOR PIN PEAKING FACl OR 8 10 G_-- 'PE ACTOR FACTOR f\\CTOH 1.30 1.39 1.42 c o.ss

o. 92

o. 94 c

0.79 I. 09 I I?

• 1 0.92 c

I. 19

o. 56

1. 20

0. 93 Cl

0. 95 I. 01 c

I. 12

o. 73

t. 15

0. 99 Bf I. 01 0.04 0.90 0.94 A

B c

0. 57

0. 89 n 01 c

C* 0.51 O.V3

0. 89 0.92 0.91 J.00 I C*

Bt \\ 0.94

a. 93 '.

I. 12

1. 1 1

1. 15

1. 12 Bl*

A 0. 95 I. 06 I. 10 '* 15 I I? I 19 A 61- ). 01

1. 13 I. 09 I. 24 I. 12 I. 26 IH A

0.95 1.07 1.09 I. 17 I. II I. 21 A B* 0,70 I. OJ 0.75 '* 20 0.76 I. 22 c 0 H K c c 0,56 0.73 1 0.93 0.99 0.95 1.01 O c c Cl C*I* IU 0,55 0,79 0.92 I. 01

0. 84

0. 92 1.09

l. 19

1. 12 0.90 0.94

... 12 I. 20 I. 15 0.94 2 t-.... en 8

o m

81-A B+ A 0, 94 0.95 J, OJ 0.95

o. 70

-0 3  I. 12 I. 10 1.09 I. 09

o. 75 I l.'i I 11 I 12 I. II 0 76 Bl A

81 A Bl 0.93 1.06 I. 13 I. 07 1.03 I. 11 I. 15 I. 24

1. 17 I. 20 J. 12 I. 19 I. 26 I. 21*

I. 22

o 0

` 4

o ffi z

A IH A Bl* A I 0 1.06 I. 10

1. 2 1 I. 23 I. 20 5

g;!

1. 16 I. 31 I.JO 1.34 I.JO 1.20 I. J3

1. 34

1. J7 I. 33 G')

o 0

c 8+ A Bl A IH I. 10 I. 24 I. JO I. 2lJ I. 30 I. 31 1.33

1. 39 I. 36

1. 37 1.:1'.t

1. az I J\\ I I. 41 I 41 A

81* A Bt A

1. 21

).30

l. 29 I. 30 I. 25

\\) 6 en CD ^ z z z 7 Ci) 0 I.JO 1.39

1. 37 I. Jn I. 34 1.34 I.")

I. 41 I. 41 I. JD UI* A DI A (I I

1. 23

1. 28

). 29 I. 17

1. OU 1.34 J. 36

).JO I. 27 I. 26 1.37 I. 41 I. 4 1 I.JI I. 28 A 81* A Bl A '"l1 '"l1

n 9

0 0 r _m 5 1.20 I.JO I. 25 I. OU 0.63 1,30 I. 37 l.34 I. 2b

o. 74 11 

0 1.33 I. 4 t 1.38 '* 26 0.78 z E F G J

[+/-]X-BoxNunber 1 2 Y-Batch AD4 BB4 XXX - Assen't>ly Relative Pclwer 0.227 0.320 Oensttv 3 4 5 6 7 AD4 AE1 AF72 AF5 AF4 0.265 0.493 0.568 1.049 1.037 8 9 10 11 12 13 A04 AF5 AF4 Af 4 AE4 AES 0.365* 1.006 1.208 1.294 1.111 1.023 14 15 16 17 18 19 20 AD4 Af 5 .Af 5 AF1 AE2 AF1 AE3 0.364 1.063 1.154 1.288 1.108 1233 1.116 21 12 23 24 25 26 27 28 AD4 AF5 AES Af 3 AE3 AF1 AE1 AF1 0.265 1.004 1.152 1.321 1.173 1.272 1.092 1.255 29 30 31 32 33 34 35 36 AE1 AF4 AF1 AE3 Af 3 AE2 AF3 AE2 0.483 1.200 1285 1.173 1.333 1.125 1.308 1.133 x 37 38 39 40 41 42 43 44 885 AF4 AE1 AF1 AE1 AF1 AE3 AF3 45 0.636 1.260 1.105 1273 1.128 1.294 1.165 1.332 BA6 0.214 46 47 48 49 50 51 52 53 AFS AE4 AF1 AE1 AF3 AE3 AF2 AE1 54 1.028 1.112 1.235 1.094 1.312 1.166 1.315 1.114 AB1 0.310 55 56 57 58 59 60 er* 62 AF4 AE5 AE3 AF1 AE2 AF3 AE1 AF6 1.049 1.029 1.119 1.257 1.134 1.332 1.114 1.079 Long N-1 Bt.mup (21.715 GW<L'MTU) Note: X = Maximwt FrVakte; 1.581

• Due to core ign, Uni 1 ey.cte 25 will rXlt be quarter core $}fnm"1t.

UNIT 1 Cycle 25 Calvert Cliffs Assembly Relative Power Density with Bank 5 Figure 3.4-16 Nuclear Power Plant Inserted to PDIL at BOC, HFP, Equilibrium Xenon Revision 52

2 Y-Ba*ch B81 8D3
X-Bo>Number XXX - Assembly Relative Power 0.237 0.418 Densilv 8 BC2 0.341 14 15 BB1 BE5 0343 0.995 21 22 23 AB1 BES 804 0.273 0.964 1.155 29 30 31 BD3 BE3 BE1 0.519 1202 1.316 x 37 38 39 AE1 8E3 802 45 0.649 1.269 1.133 BB5 D.248 46 47 4!3 BE4 BD4 BE2 54 0.985 1.120 1.235 BD1 0.407 55 56 57 BE5 804 801 1.092 1.036 1.059 Long' N-1 Bumup (22.080 GWdlMTU) Note: X"' MaXimum Fr Value"' 1.577 Unit 2 Cycle 24 Is not quarter core symmelric. 3 AC1 0.279 9 BE5 0.966 16 804 1.100 24 BE.2 1.. 288 32 801 1.140 40 BE.76 1.. 261 49 601 1.105 58 BE2 1249 I 4 5 6 7 803 AE1 BE4 BES 0.517 0.647 0.987 1J)91 rn 11 12 13 BE3 BE3 BD4 I BD4 1.202 1.270 1.127 1.035 l 17 18 19 20 8E1 802 BE2 BD1 1.316 1.133 1.238 "1.059 25 26 27 28 802 BE15 BD1 I BE.2 1.134 1.255 1.'103 1.249 33 34 35 1 36 BE1 602 BE1 I BOO 1.300 1.128 1.297 1.166 I 41 42 43 lE1 !802 BE1 BD2 1.142 1.301 1.129 I 1.306 I 50 51 52 53 8E1 80:2 BE:2 BD3 1.301 1.12:9 1.261 1.156 59 60 61 162 803 I BE1 803 I so5 1.165 1.306 1.156 i 0.853 I i ---*-------- -*--*--*..1..-- UNIT 2 Cycle 24 Calvert Cliffs Assembly Relative Power Density with Bank 5 Nuclear Power Plant Inserted to PDIL at BOC, HFP, Equilibrium Xenon* Figure 3.4-17 Revision 52

 (J1 z  c en !lo=m CD II> )> [g joQ' ... :n:n J!CI> om  s 0 0

n m

m "ti zo '? :E om "T1 :0 I 00 o en r- -i m6 .... m c m ::! oO cZ I -o mm 7> c G> 3:: :::0 0 c "ti (II 

n

 ti> (II 5 co ENRICHMENT TYPE xo. oo BOX PEAKING F. o.oo ENTHALPY RlSE o.oo PIN PEAKING F MAXIMA BOX PEAKING FACTOR ENTHALPY RISE FACTOR PIN PEAKING FACTOR 8 10 G_--- IUK FACTOR 'CTOR 1.27 1.33 1.37 c 0.57

o. 4112 0.93 c

0.71 0.97 0.98 A c 0.56 0,93 0.94 c 0.78 ?*%& c+ 0.97 1*(1 c+ 1.09 I. 22

1. 26 8+

0,96 1.03 l.M B c 0.56 0.93 0.94 c C* 0.58 1.00 0..91

1. 21

o. '12 I. 26 c

C* 8+ 0.58 0.77 1.05

o. 91

o. 98 1... 20 0.92 I. 10 I

1. 24 C*

8+ . 1\\ 1.00 1.05 1.08

1. 21 1.20

1. 17 1.26

1. 24 I. 19 8+

A B+ 1.05 1.08 I. 24 I. 19 I. 16

1. 31 L.,.,

1 IR I 3A. A 8+ A 1.03 I. 19 I. 15 I* Jg I*)* I*+, 8+ A B+ 1.05 J.05 1.23

1. 17

1. 14 1.30 I. 20 I. 16 1.34 A

B+ A 0.73 1.07 I. II 0.85 I. 20 n_e1 I. 24 D E H K c c 0.57

o. 71 0.92 0.97 0.93 0.98 c

C+ c+ B+ 0.70 0.97 1.09

o. 96.

1.08 I. 22 I. 22 1.03 I I c..> 2 I 0

0 I. 10 1.16 I. 26 1.06 m

"ti B+ A B+ A 1.05

1. 03 1.05 0.73

1. 19 I. 10 I. 17 0.85 I. 22

1. 12

1. 20 0.87 A

B+ A B+ I. 08

1. 19 1.05 1.07 I. 16

1. 27 I. 14*

t. 20 0

3 I# g U> -i

0 4 1§ 0

z

1. 18 1.31

1. 16 I. 24 8+

A . B+ A I. 24

1. 15 I. 23 I. II I. 31

1. 20 1.30-I. 17 1.36 1.23 1.34 I. 19

()  5 I !B 0 c "ti A 8+ A B+ I. 17 1.27 I. 14 I. 24 I. 21 1.33

1. 19 I. 29 I ?A 1 7 1.22 UI 6

, g B+ A 8+ A I. 27 I. 14 1.20 t.08 I*-. I*/ 1123 I* I0 A B+ A B+ I. 14

1. 20 1.00 0.99 I. 19 I. 29 I. 10 I. 14 I. 22 1.33 I. 13

'* 17 (') r-7 I$ m 0 c E CD 9

0 c

s: B+ A B+ A '* 24 I. 08 0.99 0.55 1.29 I. 15

1. 14 0.68 f 33 L 17

1. 17

o. 74 11 F

G .I

[+/-] X-lloJc N<rnbet 1 2 Y-Batch AD4 884 Assembly Relative Power 0,320 0.434 3 4 5 6 7 AD4 AE1 Af72 Af 5 Af 4 0.358 0.592 0.694 1.076 1.000 8 9 10 11 12 13 AD4 AF5 AF4 AF4 AE4 AE5 0.447 1.066 1.242 1.264 1.005 0.000 14 15 16 17 18 19 20 AD4 AF5 AE5 AF1 AE2 Af 1 AE3 0.447 1;083 1.075 1.334 1.042 1.264 1.014 )( 2*1 22 . 23 24 25 26 27 2B AD4 AFS AES Af3 AE3 AF1 AE1 AF1 0.357 t.064 1.075 1.324 1.082 1.312 1.000 1'.2fJ2 29 30 31 32 33 34 35 .X) AE1 AF4 Af 1 AE3 AF3 AE2 Af 3 AE2 0.580 1.234 1.331 1.081 1.323 1.046 1.309 1.044 37 38 39 40 41 42 43 44 BB5 Af 4 AE1 AF1 AE1 AF1 AE3 AF3 45 0.708 1.241 1.037 1.311 1.046 1.314 1.061 1.310 BA6 0.306 46 47 48 49 50 51 52 53 AF5 AE4 AF1 AE1 Af 3 AE3 Af 2 AE1 54 1.056 0.009 1.262 1.029 1.3()9 1.061 1:.200 1.012 AB1 0.425 55 56 57 58 59 60 61 62 AF4 AE5 AE3 AF1 AE2 AF3 AE1 AF6 1.093 0.900 1.013 1.291 1.044 1.309 1.011 1.034 Long N-1 Bumup(21.715 GWdJMTU) Note: X =Maximum Fr Value :::: 1.407

• Due to COO! redesign, um 1 C¥cle 25 will not be quarler t:ore s)fnmetnc.

UNIT 1 Cycle 25 Calvert Cliffs Assembly Relative Power Density with Bank 5 Figure 3.4-19 Nuclear Power Plant Inserted to POil at EOC, HFP, Equilibrium Xenon Revision 52

L£l x - "'" """"" 1 2 Y-Batch 881 BD3 X:XX - Assembly R.elatlve Pomr 0.3:23 0.512 Density 3 4 5 6 7 AC1 8D3 AE1 B:E4 BE5 0.372 0.903 0.702 1.()51 1.001 8 9 10 1t 12 13 BC2 BES 8E3 BE3 S.04 BD4 0.421 1.044 1.228 1.237 0.'991 0.880 14 15 16 17 18 19 20 BB1 BES BD4 8E1 BD2 B.E.2 BDt 0.428 1.043 1.059 1.3Z7 1.039 1.:253 0.958 21 22 23 24 25 26 27 28 AB1 BES 804 BE2 BD2 BEi'5 S.D1 BE2 0.370 1.046 1.060 1.311 t.053 1.307 1.()34 1.294 29 30 31 32 33 34 35 36 803 BE3 BE1 BD1 8E1 BD2 S.E1 BD3 0.607 1.229 1.327 1.055 1.:326 1.057 1..328 1.079 >i'

38.

jg 40 41 4= 43 M AE1 BE3 802 BE76 902 BE1 &D2 BE1 45 0.700 1.238 1.039 1.307 1.064 1.336 1.()59 1.334 BBS x 0.337 -.0-- 47-... 48 -;w-*** 50 ___,,_ 51 52

• 53---*

BE4 804 BE2 B01 BE1 602 BE2 603 54 1.052 0.990 1.253 1.035 t.329 1.059 1..314 1.085 BD1 0.500 55 56 57 58 59 60 61 62 BES 804 801 BE2 BD3 BE1 B.D3 805 1.081 0.880 0.957 1.294 1.079 1.334 1.()65 0.832 Long N-1 Bumup (22.080 GWdfMTU} Note: X

• Maximum Ft Value '" 1.407 Unit 2 Cycle 24 iil not quarter core symm@lnc..

UNIT 2 Cycle 24 Calvert Cliffs Assembly Relative Power Density with Bank 5 Figure 3.4-20 Nuclear Power Plant Inserted to PDIL at EOC, HFP, Equilibrium Xenon* Revision 52

o

!g 0 C') z c tll 89R"txl "'-m> .. < rr -v3 m:!  o£l=: A=::110 "V :i: - :D

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J 0

0
I iu-u a m I CJ m._ (Tl(/) E?;i

z...,.

z:z a-

z

><C"l-gJoo 0"'112

Z'TJ I

--o 01 -1_, n,- ri p;

c n

 t4* cl? Cl _r--ENRICHMENT TYPE x* ._BOX PEAKING FACTOR

o. 00........ ENTHALPY RISE FACTOR

o. oo--

n nn..-... PIN PEAKING FACTOR MAXIMA BOX PEAKING FACTOR 1.23 ENTHALPY RISE FACTOR 1.31 PIN PEAKING FACTOR 1.35 c 8

0. 63 1.04

1. 07 c

10

0. 83

1. 13 G_-*

I. 16 A I I c 0.74 I. 14

1. 17 c

C* 0.74

1. 14

1. 14

1. 30

1. 17

1. 33 c

c.

B+ 0.63

1. 09

1. 08 I. 03

1. 26

1. 19

1. 06

1. 29

1. 2 1 c

B+ A

0. 66

1. 03

1. 10

1. 18

1. 15

1. 17

1. 21

1. 1 7

1. 21 C+

A B+

1. 00

1. 06

1. 09

1. 29

1. 13

1. 18

1. 30

1. 16

1. 20 C+

B+ A

1. 14

1. 04 0.98

1. 23

1. 12 I. 06

1. 27

1. 15

1. 09 B+

A B+

0. 99

1. 01

0. 90

1. 09

1. 08

1. 04 I. 11

1. 1 1

1. 06 B

c D c c 0.63 0.86 I. 03 I. 18

1. 06

1. 21 C*

B+

1. 09 I. 03

1. 26 I. 15

1. 29

1. 17 B+

A

1. 08

1. 10

1. 19 I. 17

1. 21

1. 21 A

B+

1. 13 I. 15

1. 20

1. 23

1. 24 I. 25 B+

A

1. 15 I. 14

1. 23

1. 22

1. 25

1. 25 A

B+

1. 08 I. 14

1. 16

l. 22

1. 20

1. 25 B+

A

o. 93 I. 03

1. 10 I. 12 I. 11

1. 16 A

B+ 0.55

o. 96

0. 64

1. 13 0.69

1. 15 E

F H K c c 0.63 0.83 I. 04 I. 13 1-07 1-16 C+ C+ B+

1. 00 I. 14 0.99

1. 29

1. 23 I. 09 I. 30

1. 27 I. 1 1 A

B+ A

1. 06

1. 04

1. 0 1

1. 13

1. 12

1. 08

1. 16

1. 15

1. 11 B+

A B+

1. 09

o. 98

o. 90

1. 18

1. 06

1. 04

1. 20

1. 09

1. 06 A

B+ A

1. 08

o. 93

o. 55

1. 16

1. 10

0. 64

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