Slide Presentation Entitled Reactor Vessel Asymmetric Pressure Loads

ML20010A635
Person / Time
Site:	05000470
Issue date:	06/24/1981
From:	Natan T ABB COMBUSTION ENGINEERING NUCLEAR FUEL (FORMERLY
To:
Shared Package
ML20010A625	List: LD-81-040, Forwards Summary of 810622-25 SER Meeting in Windsor,Ct W/Mechanical Engineering Branch & Aps/Bechtel Re CESSAR-F, Chapter 3 ML20010A635 ML20010A642
References
NUDOCS 8108110623
Download: ML20010A635 (16)
v • d • e

Text

. _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _

=

> T CD O c--

30 CD Dw O-00 0ESCRIBE O

PLANT P R E S S U FI E LOADS GEOMETRY OO ON 1r T A CJ CALCULATE ON" MASS AND CALCULATE EVALUATE 20 t'

S UC-

-b FOUNDATIONS ENERGY RELEASES COMPARTMENT AND WALLS

]

PRESSURES t

VALUATE

+

SUPPORT

-p LOADS SUPPO RTS Q

.. ~

DFFINE START DESCRIBE O

PIPE ECCS PIPING g

g BREAKS GEOMETRY 1 r 1r 1r 1 r l DEFINE PLASTIC

~

OBTAIN ECCS PIPING ECCS PIPING PREPARE DEFINE i

REHAVIOR Op STR UCTUR AL

[g F O UND ATION

--> RCS COMPONENT-#

ANALYSIS 00LD LEG

-9

-b i

4 l SUPPORTS OF RCS.

P;PE MOTION ANALYSIS EVALUATION REPORTS PROPErtTIES g

J L 2 6 J k Jk ab h

g.,...w,

Dg OBTAIN E' VEL'UAT'l0$

]

+

VESSEL

-b 1

f. 0'F'CE'0'MS't

=*l MOTION 7

+y 4

y 1MP

=.)

CALCULATE

,..... [0 E'V'ALUATION-0D BLOWDOWN AN,D[F%f..

+ 'o F IN'T'ERN ALS O

'lNTEnNhts' LOADS l

f 9P h.e gy a a.u. sn.

t v..m>~fd4 3o

, v g-STRUCTURAb STRUCTU*

'[AWASY$8%,, 4

'EVALUATIOM

l E'R b,ANYSM_

4 OPFUEL-l.Ahi4FUE OpNTER,Mk.S

, g_ds((UE4 e

-s i

f i

. P{ = VERTICAL HYDilAULIC FORCES ON PT = PlPE UllEAK THRUST i

. INTERNALS Ph = HORIZONTAL CAVITY PRESSU'RE FO HORIZONTAL HYDRAULIC FORCES ON P

pCV= VESTICAL CAVITY PRESSURE FORCES g = VESSEL Ph = HORIZONTAL HYDRAULIC FORCES ON PV = VERTICAL HYDRAULIC FORCES I

INTERNALS 9

ON VESSEL l

l i

o.1 --l j.w * :,

f-

, }

Qs'-L.*?.'s~S' e

' o

.e,g:.0 u

., G y

1

\\

.t

• a f

• 4:.

• d;

~

s...

.B.lOLOGICAL SHIELD WALL

.s' r.-

.% e o.s s ~,*.

=

e.

, * '. ':' '4 4. w -Iyf.-

6-l

[

sy If

'.,i INLET OUTLET

/(h c

} {

o.-

POSTULATED /

-t [

PIPE BREAK r

i t

ATION f " / <' :s # *

. s L. *. ' Y :,.

s

.4 y

'.P 2

.. *4

. c.'s h'

.t s.

\\

. y' t:~

S..-

s

• e s.t 4.

t e

1

.a; ;

f.:

z.-

r.

' 8,' }

M

• 4 e

I Ih \\

>; s. -

g,,.:s sg g...

• 2 3...

.a*.%

4*'

. it.#3;

/4 Js

'*f 9::

c.,*

w :,.

n.

• so.

t...

• y.3 D

h.,

,b,..

.r.

i-

-,,---w

....-w.rw-

.r-7,-

, -.-. ---_-_,,--,,- m

-,--y.

..--,.__,__,mme_..y.,

,..y.-

-yv.3-,-,.,---,,c.

P{ = VERTICAL HYDRAULIC FORCES ON PT = PIPE BREAK THRUST H

INTERNALS FC = HORIZONTAL CAVITY PRESSU'RE FORC HORIZONTAL HYDRAULIC FORCES ON pV = VERTICAL CAVITY PRESSURE FORCES P

R = VESSEL H = HORIZONTAL HYDRAULIC FORCES ON C

l P

P"i t VERTICAL HYDRAULIC FORCES I

=

INTERNALS v

ON VESSEL i.

~

=

_s*. s'- t. *.~*.

• s

• v l

g.1.~;s.w a.,

{

. r.

1 s-o

.o5 0.

5 * *.

f

(

,p 4

j t

• ef

• 4:.

s r.>-

'B.lOLOGICAL SHIELD WALL r.~

• :.6 a,

'sf

. _ L.. ' <., 3.e : o...

's e

~$

l")

4

,d.

Py T1

.',i +

INLET

/

r-.

OUTLET POSTULATED /

%t

}\\

1 g /

H" BR E AK i

i LOTION

.:. C..: s-. yr g.,..-

,,,... 3.

.e e

i

3.. ;:.

g) s

.4,.

9..

og

.a...

s d. <.

t.

1 s,. s.

o.

.h 9 y,S g.

g

' a,q :

/

n 1

I I

\\

r c... w,.

... n.% *(;

e4 i...,'...<,.

1 s,..

'. s, st'.'.:f."

l4

. g...

y o.

c'..

h..:*,.

.;..o a:

w

.si:,7

=

a

.on-e..e.~ %'.~.:a c =

• t

• . o c

e. s.~,..

4 *.

.G*.

~. p.6>a

~

s

. ~

6 * ;v. -* Q,.

t,.. :

e.

. y '.,.- 4 --

.p

._.._-w_,

.my_,

_,,,.-,,..,,,,,,,__.-_-,.,,,,-.,,,_o.,,_,,_Qw.

..n.

PT = VERTICAL HYDRAULIC FORCES ON a PIPE DREAK THRUST PT N

N PC = HORIZONTAL CAVITY PRESSU'RE FORC PN = VESSEL pCV= VERTICAL CAVITY PRESSURE FORCES HORIZONTAL HYDRAULIC FORCES ON PH = HORIZONTAL HYDRAULIC FORCES ON y Ph = ON VESSEL VER~i1 CAL HYDRAULIC FORCES INTERNALS e.

?

o.1,'~l g ts', * :.,

f f

?~s'L,',',;.NW

• ~

c

.; c> s',.0 3,,.-

)

i g

,f a *

-o g. g

-@d

• d:.

mW I

'B.lOLCGICAL SHIELD WALL

, #^ '

N 1.

pF 6

.:.g.

s.!

<. s,.6,o, 4:

a;. -

)

sc

., 3.

'h;

/

.c e-p

\\

!f T

'.,i -->-

.IN' ET r -- -

4-

}{ OUTLET POSTULATEDj#

g 1

[

' ' BR E AK i

i

. s g*. :.w. yrg., '.

LwATION

?,'8.,"-C

/ * 's

. *g =

' f H

.J

• . u a

4+;

• 5:'-

• s'?.:'

.Q E.

f;

,r V.

Pp- +

vff g.:

. g?..

r.

c M

.j e

I II\\

> c *,. w.

.; :r. ;.>

s....

..g (

• 3.

7...

r.s.f.:.4;.T

N.

3

.; y.."?'

L,4 e

.e* \\ *.

-n..

.c.s

~

v 49 8

$..-1.g'

..-*.7

• • a

• , o - c e. g.* *.

A.,***,-

e',**'..

e,-};',,...,.,

, A.,,...e,,,

0

4.. o** :

v d..

• %,., J.

.g g,.

e

l PT = VERTICAL HYDRAULIC FORCES ON PT = PIPE UltEAK THRUST

. INTERNA LS P = HORIZONTAL CAVITY PRESSliRE FORCES PN = VESSEL HORIZONTAL HYDRAULIC FORCES ON pCV= VERTICAL CAVITY PRESSURE FORCES Py = HORIZONTAL HYDRAULIC FORCES ON P = VERTICAL HYDRAULIC FORCES INTERNALS v

ON VESSEL 6

s.

Py g

I l

e.?,,' j.t> ;'.*0,.,

f

}

Q s.k. '.'* s ~ '

o c 6. :

7

., b 3

i s

.t oo g g

=+-P aq; H

I

~B.lOLOGICAL SHIELD WALL p

y R

s..

..6 C-

.:g y.n.'. :.9.kV. 2 s~-

e.

o.s.

a N

.r.

-t rT

e.. p

-}

y

."t +

INLET v

(( OUTLET

/ rw Pt e.-,

POSTULATEDj#

-t P"'

BR EAK

[

Lb ATlON I

8 9

j

." < g. * :.%. %, *".

"e s

.

s l,., -

. *g! *

. i..

• ~~P"

\\

.i l

. s::.

.H

2..-

.,t.

Pg_ #

l w.,

1 a.

g.

1 a.a. :

a.

f l

>\\

l lh \\

3; r +

.; :g,. +.sg,,*

s...

r.s..",t : #s.

. 2...

s

~

s.

/4

s :,. ; g.:.e -

ts g-..

v

.,. 9 c:

l g.

... o. a. a....,..

.a e..<.

'b t i '. u e.

o ~.

. 3 :..... ' q.. : -.

s.

~.s)v..sQ*

e~

g.:.

.y

..s -

--,.-.-an.

-,,.--,,,.-.,-,,--,...--.Q

,w

PT = VERTICAL HYDRAULIC FORCES ON PT = PIPE DREAK TilRUST

. lNTERN ALS plI = HORIZONTAL CAVITY PRESSilRE FORCES C

PN = VESSEL HORIZONTAL HYDRAULIC FORCES ON pV= VERTICAL CAVITY PRESSURE FORCES C

H = HORIZONTAL HYDRAU!.lC FORCES ON P

= VERTICAL HYDRAULIC FORCES I

INTERNALS ON VESSEL k

t V

Pg

?... L..,,

o.1;~;; w '.*0,.,

(m N l_.

.' s *

..sr c

o. c> 6

(

.t

-p 3

1 pc4

.e.

a

-P w

' d.3 N

8 I

'BlOLOGICAL SHIELD WALL p

e C.

~

6 t.-

.1

-(*,

',;}ho..4,'.' _@..

4-

.~

',h; 4

d.

p

~\\

ff T

.',i +

INLET y

OUTLET

/cm P1

'POSTULATEDj#

h

\\\\

-t i

i

/

PIPE BREAK LOG 4rTION

";*..p,; g.. *j.

g.

9 1

s

-8 3-

. i..

d 4 3-

.a--P

?

'+;

A 1

.A..

\\

8

s..-

.c C.

,3, b.

R s

n

• a,1; ;

+\\

N s

v <-

.f :s,.g.

• s....

^ 3...

.'.9 M.

,3,f.,..g'

/J.

s,:,. g.: g -

p,7 g-.-

y

,.y og...

e'f,:

,a

u.. "

o. a a.,,..,..

... ~%. % ; *.....

., :.. s.. t.,:

e.

.o 5 r...s

.e...

~.

v

.~

f *.. ;.

.s.-

e

• . e,

PI = VERTICAL HYDRAULIC FORCES ON PT = PIPE DREAK TilRUST ERNALS Ph = HORIZONTAL CAVITY PRESSU'RE FORC PN = VESSEL HORIZONTAL HYDRAULIC FORCES ON pV= VERTICAL CAVITY PRESSURE FORCES C

PH = HOP'.ZONTAL HYDRAULIC FORCES ON

= VERTICAL HYORAULIC FORCES I

INTERNALS ON VESSEL pv R

,.;. ; ;.u...,

[;

f, t. *.:'. J.' r*

.o g:.4 y 2..

• k.<

.O.

y

.e.

a

-- p w

~ *o' N

8 I

' BIOLOGICAL SHIELD WALL P.

m P R

~

'~

c 6

. %.+

o.s

' ~.,:.

e..?..y=.-

. g.-

,t s.'; 4..,

.z

.,a 4

gj 1

r T

\\

p

.) -->-

INLET y

OUTLET

/m P1

\\\\

o:

@OSTULATED/

h

~

-t PnPE BREAK i

i LOLNSTION j

" L'.tp,;;g$ p..,*#

\\

V h l. p

.' " 'e

.,. i.

H n.-.-p i :

A I

4,..

\\

.H

. g:s C.

S..-

.: t R

.s

@g.

4.. :

..a.', ;

>\\

x mi w

~

I I

\\

>;r <,. s:.

.; :s.g, s

g,s, Q.i..

/J.

^ 7...

~ $?

45-a s,:,...e: - -

a p, y g-y s.7, Y

C "g.'.'.

?, :

.1 t...'.,i' a...,

. a :.. r.

.,.. ?

o. a......,..

e-o~

. ~, z. t,..

.s)v..s.; *

(,.. :

~.

o.

'...s -

.g

a 3500 3

li 11 i

i i

si si 3g 2500 r 1

EM g.

6 t[ IPA'_

a:

1500 1

o-A-

_~

u.

l 1000- :.

.n.,

l i

t 500 L

,\\

r i

0 li l'

1 l'

l' I!

1:

I L- -

02 0.050i 0 1001 0.150' O.2001 0.2508 0.3001 0.3501 0.4003 0'401 0 TIMii, SECONDSi

'...~

~

m::

2:, ;1{. < -.t_ ',(fy.W(G[)ll..c: 1d.

r....

' _..C -;,2;:blk.hMli,;.y....;;n;-q ::;-b$$$Nk$$^h$lkh&&f}h 5

+

. 1 x :-

+

l

[

h[gh}hjN$

ft

• R +. f' '"

'3 '. ' i '1 i-?N.? -

b

 :.';p..jh;M.f;. * $AAl (ONOFRE.SUDDEMLY APP.LTED THRusy FoncE l

WITH JET IMPINGEMENT FAcroR 1

i i

23 is i

.i i

?.

i 1

1 i

2

'~

l

~

.s t

,o,

..x in t

4 M#

O i

W-o 4

i

?

t i

cn <

~ r3-2C E S!.

g i

il I

l Ey o

O.i 0.1 c3 0.4 O

Gg TIME, SEC cn 4

-O i

O (n l

g _0..

4 55.

a. <n

• 6' 5' 3 x

Ch l'

(n 3

~

A n..

p

~__

i

O

- ~O - - -- -- -

~ ~ ~ - ~ ~ ~ ~

~~~~ ~~

O~~~

I CD CORE SUPPORT B ARREL HORIZONTAL FORCING FUNCTION [Typ

.o l -l 1

i i

i i

i i

i i

3 4

i l

i l

2 f

~

i N:

m

$ I

~

f r!

a:g p

10 I

bl n

Amm

~

n o

~

~

x gvv~v-v l

t

-1 p

' r.a 123 d

n>

H r

- i I

1 I

f I

l l

~2 l

l 0

80 160 240 320 400 TIME, MSEC

)

~

0 02 O

x 6,

S N

L O

A I

T 0

T N

5 1

C OZ N

L I

A U

R C

F O

I H

T G

R E

N V /

I C

R C

O E

F S

l 0 m 0

E 1

R E

U M

I S

T O

S E

R P

Y T

I V

I A

0 C

5 f

3 2

1 0

x ga ile.

uE O

O O

o

)

ALLOW ABLE VESSEL SUPPORT LO ADS (Of f

'N

• SA 503 CLASS 2 ALLOWABLE STRESSES:

I I

\\

f.1EMBR ANE (Pt,1)

• 50.8 KS1 MEMBR ANE + BENDING IPt,1+PL+PB) d 76.2 KSI g R ADI AL l y' Allowable Column [ ensile Load (Totall (Boltingi

, DIRECTION 14 N/

I F

/ Allowable Compressive Column load (Totall (Buckling) 12

~

,2 H

Allowable Vessel g,rt Pad Load 10 REACTOR VESSEL fr 8

0

~

VERTICAL k

H 8 V2 9

COLD LEG GUILLOTINE

p 6

Allowable Vessel Support.

Pad load (Pipe Rupture)

=

N g

g 4

H 4.4 i

I V 2.7 HOT LEG,

GUILLOTINE N Allowable Column Load 2

(Pipe Rupturel (Tension and Compression) j I

O 2

4 6

8 10 12 14 16 18 20 3

g VERTICAL LOAD (V) x 10 KIPS P

N l

pV 4

. ae 0

=

0 O

O' RV HORIZONTAL SUPPORT LO AD VS TIME 350 IN 2 C O L D LE G G U I L LO TI N E [$4+> c0MF#b INT DEPRESSURIZATION + EXT CAV PRESSURR + THRUST i %

m 6000 li

!\\

e l

\\

o-

/

i i

E2 i

/

's PRESSURE EXT CAV s

~

i

/,,,',

/

4000 l

'. '+ THRUST 4

/

i

/

o s'

\\

i l

.g

/

i

\\

l i

i W

/

\\

/

~

's i

l' i

\\

I i

g a

~

2 2000

,l

/

l

's,j,

\\,% /,/

l

,/

/

a.

e

' 's, l

\\

l

\\/

\\,

l

'c I

\\, il 0

n-o z

+.

o

.N.

x l

E -2000 i

-4000 I

I l

100 200 300 400 TIME, MSEC i

O i

o.

p.49

.r..

S,@i REACTOR VESSEL LOCA SUPPORTS k

C[*

y gg g.f;p yre.. w.

• .u p

SUPPORTI

'i M 9f :-

, STRUCTURE ~

h_

s

!Q% -- -

i.?

M fis.

/

1 f

C.'

o HOT LEG fT r t

r Il' COLUMN.

l t

I

,. - BA S'E j,,.'.s' PLATE (TYf i

t..t. y L

LOADT

/

N

^,

MATERIAh; LIMITING REACTOR' N. IN GAR' "'-

VESSEL

' ~

~

=-

li

'l 8

/

r, g

\\ ~'. : :.s

- u, g-9 d

a I

p.. %

,. s J'1 s

N; 'i t

f s

i.

i GAP e.

A t

A'-

'?

I.

~-

SECTION A-A

• L" O /

i i

i COLD LEG N0ZZLE

'm SUPPORT

',l

[

.m STRUCTURE i

Q'..

)

t \\

.>e

'\\

. -l?*w' v

k.

~

' xk,k

.._ i

..y.

p.

{Bh SECTIO C

I S

i

-_ b *i -__,._ _ _ - - -

~

O o

O 350 SQU ARE INCH COLD LEG GUILLOTINE RUPTURE I

HO R I Z O NT A L S U P P O R T LO A D S (Spoueree')

1 l

i I

8 i

s 8

I i.

l 1

i e

s l

l 1

H H

2 3

,H4 s

s 4000 g

g o_

7 i

i H

i i

1

!o

<s i

's i

I s

/\\

I i

e

l. s=, l

\\

4

r i

i

\\

s'

\\,-

i.-

S 2000

/

PIPE I

\\

s i

.i I

'[s i

'i kBREAK e

i e

~

w i

s,,

j[

'g,,,'

~'

,f s

'N

,/ "s, 4

i

/\\

/\\

DIRECTION OF REACTION ON l'

i N

FIGURE INDICATES

m

-i g

PREDOMINANT SIGN ON PLOT.

/

/

s N

- -s' i

y -2000 s

l N.f j

\\

g g

t, I

y A

~

is -4000 j

i H

i 2

I 1

H 3

-6000 i

i i

I i

i I

1 100 200 300 400 TIME, MSEC O

t 9

O O

O 4

I TOT AL HORIZONT AL FOR CE ON RE ACTOR C AVITY W ALLS [TYP) j 1

I I

I I

I l

1 2

--- 100 IN GUILLOTINE AT VESSEL OUTET N0ZZLE

~

2

~

350 IN GUILLOTINE AT VESSEL INLET N0ZZLE 12 i

1 l

l 10 n

n P

D 5

r\\

p\\

l 'I l

l\\

I \\

i 2

l

[l\\

f i

1 1

I l

I i

l o

8 j

i j

g g

I

4 u_

\\

g l

t i

I 1

I I

i

~

l I

i

~

j i

I i

S I

l

\\

\\

I

\\

I d

6 1

I

\\

I l

l E

l

\\

I

\\

\\

l t

I I

\\

I

\\

s I

~

l 6

j g

~

\\

l

$A l

I

\\

l

\\

~

I

~

t l

\\

l l

I

\\

l

\\

\\

f~

l I

\\

l I

l

\\.

\\

\\

l

\\

l

\\

\\

g 2

l

\\

~

i l

f

\\

I

\\

I I

\\

g I

Il I

l I

0 I

J 0.05 0.10

0. 15 0.20 0.25 0.30 0.35 0.40 TIME, SEC i

u