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| number = ML20247H360 | | number = ML20247H360 | ||
| issue date = 03/30/1989 | | issue date = 03/30/1989 | ||
| title = App 11A, Core Residence Times, to | | title = App 11A, Core Residence Times, to CESSAR Sys 80+ Std Design | ||
| author name = | | author name = | ||
| author affiliation = ABB COMBUSTION ENGINEERING NUCLEAR FUEL (FORMERLY | | author affiliation = ABB COMBUSTION ENGINEERING NUCLEAR FUEL (FORMERLY | ||
| Line 17: | Line 17: | ||
=Text= | =Text= | ||
{{#Wiki_filter: | {{#Wiki_filter:. | ||
CESSAR !!!nney,. | CESSAR !!!nney,. | ||
APPENDIX 11A CORE RESIDENCE TIMES I | APPENDIX 11A CORE RESIDENCE TIMES I | ||
i | i | ||
) | |||
8904040445 890330 PDR | 8904040445 890330 PDR ADOCK 05000470-K PDR | ||
CESSAR 8!nincano,. | CESSAR 8!nincano,. | ||
Text Pace | (Sheet 1 of 1) o EFFECTIVE PAGE LISTING APPENDIX 11A Table of Contents P_ age Amendment i | ||
Text Pace Amendment 11A-1 11A-2 11A-3 O | |||
O Amendment E December 30, 1988 | O Amendment E December 30, 1988 | ||
CESSAR !!nifico = | CESSAR !!nifico = | ||
TABLE OF CONTENTS | TABLE OF CONTENTS | ||
-APPENDIX 11A Section Subiect Pace No. | |||
1.0 | 1.0 DERIVATION OF CORE RESIDENCE 11A-1 TIMES j | ||
i | |||
[~ | [~ | ||
CESSAR !! Sinc m., | CESSAR !! Sinc m., | ||
O 1.0 | O 1.0 DERIVATION OF CORE RESIDENCE TIMES The derivation of the core residence times for circulating crud as shown in Section 11.1.2 is as follows: | ||
A. Circulating Crud: | A. | ||
The number of radioactive atoms ( | Circulating Crud: | ||
dN g | The number of radioactive atoms (N ) in the crud film on f | ||
Solving for N | in-core surfaces at any time is: | ||
dN g *Ed-1"f (11A-1) i dt Solving for N yields the following: | |||
g | |||
^I #*8) atoms /g (11A-2) | |||
N (1 - e | |||
= | |||
The number of radioactive atoms (N | g i | ||
[DN=N | Where: | ||
("+0+A i) N | I 4 | ||
is the activation rate for each isotope i f | |||
o" | (d/g-sec), | ||
A | is th decay constant for each isotope A | ||
(secs p), | |||
a llA-1 | f and t | ||
is the desired core residence time (seconds). | |||
res The number of radioactive atoms (N ) released to the reactor c | |||
coolant at any time is: | |||
[DN=N | |||
[ER] A | |||
("+0+A i) N atoms /sec | |||
~ | |||
f c | |||
c Solving for N yields the following: | |||
c N (ER) A "I" + 0 + A 1) t f | |||
c N | |||
(1 - e | |||
) | |||
(11A-3) o" (a + B + A.) | |||
1 2 | |||
Where: | |||
ER is the erosion rate (g/cm -sec), | |||
A is the core surface area (cm ), | |||
c is the plateout rate (secs-1), | |||
o a | |||
llA-1 | |||
1 CESSAR E!i#icari:u I | 1 CESSAR E!i#icari:u I | ||
(secs-1), | Oi p | ||
is the purification cleanup rate (secs-1), | |||
and A | |||
Total amount of crud (M ) released to the reactor coolant | is the decay constant (secs-1), | ||
any time is: | y Total amount of crud (M ) released to the reactor coolant any time is: | ||
dM | dM | ||
[ER) A | |||
[ER) A | - ( | ||
Solving for M | + | ||
l | )M (11A~4) | ||
= | |||
Where: | T c | ||
1 | dt where M in ludes both radioactive and nonradioactive material. | ||
c Solving for M yields: | |||
c l | |||
)t) grams (11A-5) | |||
- (a + | |||
l M | |||
(1 ~ | |||
* c" | |||
) | |||
Where: | |||
ER is the erosion rate (g/cm -sec), | |||
1 A | |||
is the total system area (cm ), | |||
T | T | ||
~ | |||
is the plateout rate (secs ~ ), | |||
The activity | and a | ||
p is the purification cleanup rate (secs ~1). | |||
The activity (A ) | |||
A | of the crud released to the reactor g | ||
coolant is: | |||
This activity (A. | A N fC dps per gram of crud in reactor (11A-6) | ||
Solving equation (11A-7) for t | A1=M c | ||
coolant substituting the values of N | |||
and M | |||
into the above expression and assuming 1. | |||
is shall when compared to a and l | |||
p, the activity of the crud is as follows: | |||
A | |||
~ i res) | |||
(0.06) dpm/mb-crud c | |||
(1 -e Ag=If lu-7) where 0.06 is a constant changing dps/g-crud to dpm/mg-crud. | |||
This activity (A. | |||
is also assumed to be the activity of the crud which plated) out on out-of-core surfaces. | |||
Solving equation (11A-7) for t yields quation (1) | |||
(See es Section 11.1.2). | |||
11A-2 | 11A-2 | ||
CESSAR ninneuio B. Denosited Crud The activity (A ) of the deposited crud is 3 | CESSAR ninneuio B. | ||
Denosited Crud The activity (A ) of the deposited crud is 3 | |||
Solving equation (11A-8) for't | g g = Z d (1:- e res).0.06 (11A-8) | ||
N A | |||
=A y | |||
Solving equation (11A-8) for't yields. equation (2). (See res Section 11.1.2) 1 i | |||
11A-3}} | 11A-3}} | ||
Latest revision as of 20:27, 1 December 2024
| ML20247H360 | |
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| Site: | 05200002, 05000470 |
| Issue date: | 03/30/1989 |
| From: | ABB COMBUSTION ENGINEERING NUCLEAR FUEL (FORMERLY |
| To: | |
| Shared Package | |
| ML20247G537 | List:
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| References | |
| NUDOCS 8904040445 | |
| Download: ML20247H360 (6) | |
Text
.
CESSAR !!!nney,.
APPENDIX 11A CORE RESIDENCE TIMES I
i
)
8904040445 890330 PDR ADOCK 05000470-K PDR
CESSAR 8!nincano,.
(Sheet 1 of 1) o EFFECTIVE PAGE LISTING APPENDIX 11A Table of Contents P_ age Amendment i
Text Pace Amendment 11A-1 11A-2 11A-3 O
O Amendment E December 30, 1988
CESSAR !!nifico =
TABLE OF CONTENTS
-APPENDIX 11A Section Subiect Pace No.
1.0 DERIVATION OF CORE RESIDENCE 11A-1 TIMES j
i
[~
CESSAR !! Sinc m.,
O 1.0 DERIVATION OF CORE RESIDENCE TIMES The derivation of the core residence times for circulating crud as shown in Section 11.1.2 is as follows:
A.
Circulating Crud:
The number of radioactive atoms (N ) in the crud film on f
in-core surfaces at any time is:
dN g *Ed-1"f (11A-1) i dt Solving for N yields the following:
g
^I #*8) atoms /g (11A-2)
N (1 - e
=
g i
Where:
I 4
is the activation rate for each isotope i f
(d/g-sec),
is th decay constant for each isotope A
(secs p),
f and t
is the desired core residence time (seconds).
res The number of radioactive atoms (N ) released to the reactor c
coolant at any time is:
[DN=N
[ER] A
("+0+A i) N atoms /sec
~
f c
c Solving for N yields the following:
c N (ER) A "I" + 0 + A 1) t f
c N
(1 - e
)
(11A-3) o" (a + B + A.)
1 2
Where:
ER is the erosion rate (g/cm -sec),
A is the core surface area (cm ),
c is the plateout rate (secs-1),
o a
llA-1
1 CESSAR E!i#icari:u I
Oi p
is the purification cleanup rate (secs-1),
and A
is the decay constant (secs-1),
y Total amount of crud (M ) released to the reactor coolant any time is:
dM
[ER) A
- (
+
)M (11A~4)
=
T c
dt where M in ludes both radioactive and nonradioactive material.
c Solving for M yields:
c l
)t) grams (11A-5)
- (a +
l M
(1 ~
- c"
)
Where:
ER is the erosion rate (g/cm -sec),
1 A
is the total system area (cm ),
T
~
is the plateout rate (secs ~ ),
and a
p is the purification cleanup rate (secs ~1).
The activity (A )
of the crud released to the reactor g
coolant is:
A N fC dps per gram of crud in reactor (11A-6)
A1=M c
coolant substituting the values of N
and M
into the above expression and assuming 1.
is shall when compared to a and l
p, the activity of the crud is as follows:
A
~ i res)
(0.06) dpm/mb-crud c
(1 -e Ag=If lu-7) where 0.06 is a constant changing dps/g-crud to dpm/mg-crud.
This activity (A.
is also assumed to be the activity of the crud which plated) out on out-of-core surfaces.
Solving equation (11A-7) for t yields quation (1)
(See es Section 11.1.2).
CESSAR ninneuio B.
Denosited Crud The activity (A ) of the deposited crud is 3
g g = Z d (1:- e res).0.06 (11A-8)
N A
=A y
Solving equation (11A-8) for't yields. equation (2). (See res Section 11.1.2) 1 i