1. The lower limit for lithium concentration vas increased from

.2 ppm to 1.0 ppa. This was done because lithium has an inhibiting ef fect on crack initiation and propagation when its concentration is maintained at about ten times greater than the sulfur concentration in the Reactor Coolant System (RCS). The upper limit for sulfur (as sulfate) is .1 ppm, '

thus the lower limit for lithium is 1.0 ppm.

Lithium concentration is based on boron concentration, with a maximum allowable concentration of 2.0 ppm. The lithium concentratiens range has thus been changed to 1.0-2.0 ppm.

2. Chloride was changed to meet revised B&W Water Chemistry Guidelines.

_ 3o _

- - r , - ~ - ,, , , . , n .y,-- ,-

1 l

l TABLE IV-1 THREE MILE ISLAND UNIT I PRIMARY WATER CHEMISTRY ADMINISTRATIVE LIMIT CHANGES OLD NEW SAMPLING SA.T LING ,

FREOUENCY FREQUENCY OLD LIMIT NEW LIMIT PAR /O'ETER Daily 0.2 - 2.0 (ppm) 1.0 - 2.0 (ppm)

Lithium NONE Varies wich boren a ec.:s.~.c: ::.: .

Chlorides ~ SX/wk SX/wk 10.15(ppm) {0.1 (ppm)

Sulfate, (S0 4=) NONE Daily . NONE f,100 (ppb)

Sodium.. NONE 2X/wk NONE (1.0 ppm 4.8-8.5 4.6-8,5 pH 5X/wk $X/wk Conductivity SX/vk SX/wk NONE ,

-- Check for Con-sistency With Boric Acid and LiOH Concentration p

9.

} -

1 s

4 6

y , , .-. , . , . , y r - , - , . - -

. , = . - - - .

3. Sulfur '(reported as sulfate) was added to the Administrative Limits because of its deleterious effects en crack initia-i tien and growth in Alloy 600.

4. Because sedium becomes easily activated and is an important contributor to total activity in the RCS, it will be moni-

• tored. l D. Cleanus of Sulfur from RCS '

To preclude corrosion by sulfur contaminan'ts already in the RCS, GPUNC plans to conduct a chemical cleaning program to remove or oxidi:e residual sulfur. Testing has shown that near the outer

-urf::e of the er.ide film, sulfur is tredominantly eresent as suliste. Furtner into :ne sur: ace riis, metal suliices pre-dominate.

• The cleaning process was select'ed to chemically convert the metal sulfides on the steam generator' tubing into soluble sul-i -fates. In general, the process to be used in the plant is as  :

.follows: . ,

The RCS, Makeup and Purification. System, and the Decay Heat ,

a Removal Systems will be in use. .  ;

t The pressurizer will be-used to increase system pressure to approximately 320 psig.

a r

• Main coolant pumps will alternately operate and cooling water flow through the Decay Heat . Removal heat exchangers  ;

will be adjusted so that the entire system operates at j approximately 130*F.  !

• The coolant at this point will contain a boric acid concen-

~

tration between 1800 and 2300 ppm as 3 and lithium con-- ,

centration of.2.0 - 2.2 ppn.  ;

• Af ter- temperature and pressure have been established, con-

'- centrated ammonia hydroxide ( 30 wt %) will be added via the ' ;

caustic mix tank and Decay Heat Pump- suction.to increase the - i reactor coolant pH to 8.0 -- 8.2  ?

• 30 wt % Hydrogen Peroxide will be similarly ' charged into the - !

reactor RCS to establish a final concentration of 15 - 20 l ppm. Since the peroxide will decompose, further_ additions will be made as .needed throughout the test to keep the .

peroxide in specification. +

7 -

32 -

i L

e'* w  :., $ b + ,.-,,-.r4 -,r1 ,,,..wI - - .Ev e- .y ,n- r--y, , ,,--r.,

• The cleaning solution will be continuously circulated.

Cleaning is expected to take approximately 2-3 weeks. ,

Termination of the cleaning process will be based on the determination that no further sulfur is being solubilized and results from the process development tests.

Both.the dissolved sulfate and the a=monia added will be ,

removed from solution by ion exchange resin in the normal purificatien systems to levels consistent with nor=41 RCS chemistry values. ,

A comprehensive test program was performed to determine the  ;

ef fectiveness of the cleaning process , and to verify that the conditions of cleaning would not introduce a corrosive environ-cen:. ~he prcgram and reau.;a are -ticassec tr. a Jap-rs a s_afety evaluation. Hydregen peroxide appears to be effective in recoving sulfur from both tubing surfaces and from inside

- ~

.. crevices. Based on testing, 350-400 hours of exposure to the ,

I hydrogen peroxide solution is expected to be adequate to remove 50-80% of the sulfur present.

I. ' conclusions  !

GPUNC has i=plemented corrective acEions in four areas in order to prevent recurrence of OTSG corrosion. The sodium thiosulfate tank has been removed fro = service to prevent additional in-advertent introductions of sulfur, and chemical cleaning is planned to remove existing sulfur. Stricter administrative controls have been placed on introduction of other potential che=ical contaminants. Stricter controls have also been placed i on RCS chemistry to maintain a non-corrosive environment. These -

actions are expected to prevent contamination and corrosion-by ,

sulfur and by other chemicals.

i l l

. l

[ .

I

. - - - - - ---s a e s - - - - -

.f.......

. . , . . , . r.3.

.. n..-c....

.a..... ,;e.:.;.................e.,,,,.:. . . . . . .

T A. Le scrirtien cf irr:es s and Ge:tetry

.. . . . . C ce L.. .. .. .: ., ..

e . . .

. . *.. ... 6.d - * 'J I t e Xar.ina:ier.s ha*.e revi a.e.j a .arje

• .L.*er ;;

.. . . k. ,. g y:.. .Je.t,. . .g n. :...1.. . . . .

.. t . 7 7..

.. .. .. o. '.. t s .b . t g .. .

a

r. f ,. :. t .. . .. .

s

> defined as anv eddv curren: indi:adion interrre:ed as

'.. v.a.l. *A.: . .2 . s c .' e d. . ' ". c u . .-e. . .

g ..

., s.. ..e.. ...s..g. I.C'. .h.e cete:: art,. :y are ce,"inec .. . .

.. . . in ,e:: en .

..y. ..4ne repair approach is to es:ablish a new pri=ary syste: pressure A kine:ic expansien of :he bound ar.v belov'these defec:s.

ube within :).e :ubeshee: vill be :he apprea:h used :c e'- e

..- . . . n : s . .,. :

..... . . . . a11 .. w.es y..:c

. . . 3., n .. .-.

g

. . .e.

3.y f. s s. . .

. . . . .i.a..

viii be .:. e ne:::al.y expanded irrespe :ive c. v.ne:y..er er ne:

3 they have a defe::, and .irrespe::ive :f whether they vill be .

,a

.,...,: :. . . ,. n . . . L.. ..u . e . ... s . e.,:. y:. ,. . e. . .. : a.. e a $c

r. 33 . . .

. . . .:.6 . . . E4***E830..:*.3,y -. , E '. .A..: .. *-**- i*...s...**'-**CI.

.s.. * * * - **e*- .

s._.g.:.e .g.g:... .. ....

. s 1'0,..s

~. , ' : 0 } 1 c y:. . . .s,. g.s..

Detal,.s can be .Ount. in 6 t.e.geren0e e . .' . 100. .eferer. e

... . . 7

.e .s. . .. . .

s

. p . .

t. a.7.

s t

d

.. Eine* c euy.e -XDansion s.. ,

4 i p., y:--*.yE 4 : . . -**-**

. . ' . .g. J* ..: u ..: *

• • • y .g.g:- y g ,*,,-

.ne ....,,s s .-r- - - - * - r -

r.....

. c u. ;: s..... . : y ,- C .t y..w.. . . . . . : e ..g .: . .a. .. . . .. . 7...'.,"s...,...a.<...

... . . . ..; u s. '. 3.. .

... O .... c ,.z...s

.:...- 1- ( E.. .'. r . . s .-.V e l' ex y a.s:... C.e e. s.. a.

.u.. ....u .

.r.. .c.. . ..6** **** .

. ..: . u..e

b. :..u.... .

t L.b,. s ..e u e .'5 ..

u.s ce.t. :..,,.2 .. u. . s. .. a $.u :c. eX.4.s:. .

.. e . :. : . a.).

.es.;.

. . . . . 7 .. ..

Delov :Ge .Cres: CtleC: v ,1.

. . , 3

...6.'s .

. 3 prC\*:c e :.ne Oesire:

. .3.Ca; car *y-ing' r.argins . 4:e expans.o . servin; as :. en new pre ssure beundary-is :he be::c:. six-inches Of a 1" in:h ex;znsien ... s: .. . . . . . .

., 1 ex...,w: .....e..3 .. g....s . , 3. . .. h ,. c .a ,.. t .; s.. ..

..r.6- -- rr--

, . , ~.

= . ..u. . . . u 2 ,. s. ,. . :

s ta ...o,s . .

.. t. u., ,. s . .c.. . . . . . .

s .w  :

s.. s 1u c.. a.. y cy e s.a . e . ,...e.7 . 0y.: .a. , a. .. ...: . a . . .

u .a . 7. . : . . ..

jcin:. Tubes vi:h defects lever than 11" vi'.'. '!c cc .sidered ind ivi du a11v. Th:se vi:h the-1:ses: defa:: between 11" and

.n se vi:.n

., . o .

36n vit.

.3 .ce expa.ded using a: .a. expa.sien. -

n  : .

. . ,.. .... ......wg5 .....

.s..a. ,a. u.,......,

a. .u, .. .,.y d e .ee .. .s .o.... ... . . . . . . .

vill be taken cu: cf servi:e'.

- 2

.9

• w ~ .v - .- , , v- --r.--g

The ~h*.-1 CT5G repair p;c:ess is as f:'.'.:vs.

.c.... .

ves .:..:C.-

A .~us..

A u .he . s....;t...

s:.., .. ..... e .-- ....,. rr..

ubeshee: Crevi:e.

u. .,. .. .e......

.  : . e ....a.:.., ..... ..

.. ... ... .:s....e (vaporize wa:erl.,

.e i

4 Kinetically e y. rand tubes a 5 Clean debris free. kine:iC er. pans ion

-- ._ u

• 6 .u.ill tube ends l t

e

.,Ush t* C.5v, .

5 Flug necessary :ubes

=

c Clean OTSG vi:h fel: p'.ugs.

,. s :... s ..a .: t , ,. ., .: ..

...,. so...

ts.......

~s

. . -- .: 6 * ..-- .- ,' C- --

...e . e. ... . ;w...

~.

.: . . . C ...:..ses a k:.c..:. . . . ... e h.r-- . , . S .-*-

s" "g s ". *. .' n . ' a

...gg g .w ...: ... s. .. ,. s. : .. s ) u s *. D e l."V

• h. .". u'~r ~re ". *. ".'- *.. s '. . *. *. . . .

Ane ,R:ne ::

in :ne area C: the origina. shCp re,.1 expans. en.

3 t%.a.s:w,... . ...

. . 1 O t- .. .nt ,.t g. s s .. e D . .. , s. s. .,

. . . . . .y z.; . . e.. . ....u..a., .. . .a .. . . a s. u.. .

y .. .

.w,

. . . . ..u. D ,. s . . , .s....

... C

- . . . . . . .he .u.s,..C . .

...g .:. ... g *. (~. .w c

• f g S :*6 .U y g 3 : ,- -;3 S*- *..*-- .,e- --

.t' 'E : , ,* *. . . ,

• 4.y C .: .ae s :. g.... uwa . s :. .s . ...

. . .u. . a.

. . c.  : C '. '. .....e

. ...:.. . s& S.. ., "

kine:ical'.y expanded jDint. ,

3. . .ne repaired tube sha.3 & sustain :.en sax =ur.Ces;gn Dasis

• - : r.. e* :

. J ax . ?. .e.s.Ae . ..

• e -

A wa.d C. .1*. .1 %. . ....

5 a. .. .s..,.

. . . . . . . C As/ .

ge... .v. w .-

T. ., a c ,

).. .. 2. . .. ..e a a..:a......s... a. s. '.). s :.S:one.e s .

• o ..n:s is e. u. ..s.. .. '.. s

.%: ..  : . , C .e.

... ...C..e._e..

....e s s! s .* .*r. .

6 6. ..e.

s e. . :. . s :. , . . 6. ***3 C.l.f.

.* -- A . . .

u .. .u,

.u, ....*-e*,,.

..~,% u,...,t. -- *- - - .ht t y . *. rC 2 , ~2 g --. a *. l f

~ ' - --- ~ ~-- *- - * ~

r=k-' **** .. . . . .:.... r' .

'..h..,,e.

as :,.a'. e. 4.... CC.res., .

r v.2... w;.g .. .v .w:. . . . s '. C s.. . .us..

3 ,.

4. .r.t :C a t e r re ssure CVC.A es eX-ane .int:ial Cesign 11.,e 00'e::1Ve IC: O,n e tube ,K1:e*1C i

par.s'.en is 5 years.

c..

.... . 1'.1,...

... C ,g.

. . i..t. . gee.,1'n. . 6 . -

8.s/O. 3 *'3 *...a.: s ..:. 11

. a.e7 .._.: ... . ,/.

u. .; ....t.

C....e

.. . : , . .. s..e qu. .a.: 1:. : C

. o. . 10 .......a... .C

. s ,. .

..  : s .2  ; . w  :

. . . . s .

r--6..e

A design life of 35 years has been established as a goal. ,

I The qualification program will include test specimens for cyclic testing for a 35 year life separate from those used to initially qualify the repair for a 5 year life. These specimens will be tested using the same key parameters but with greater numbers of cycles in order to satisfy the 35 year life goal.

3. Tube Preload ,

The design objective stated in the original steam generater equipment specification for TM1-1 OTSGs was that the tubes .

ret be in e:mpressien when cold. ,

The repaire"d tube tensile preload shall not be changed by

_~

= ore than 3C lbf at ambient temperature. This design ,

• - objective is intended t'o assure that tube preload tension is maintained so that the vibrational characteristics of the tube will be unchanged for a preload change of this magnitude.

4. Resicual Stresses .

One design objective is to minimize tensile stress in the transition region between the expanded and unexpanded  ;

portions of the tube. Analysis shows that an abrupt transi-tion results in higher residual stresses and larger stress  ;

concentraticns. A transition length between 1/8" and 1/4"

• has been established as a goal.

An objective of maintaining additional residual tensile stresses (both circumferential and axial) resulting from kinetic expansion in the transition less than 45% of the .2%

of f set yield stress at room temperature has been established.

d

-- - 5. heat Transfer Recuirements .

No credit is taken for heat transfer within the tubesheet.

6. Pressure Boundary Leakage The original design basis for steam generator tube leakage

.was to provide generators with no detectable leaks at ship-l ment and to control leakage to an acceptable operating level by monitoring and repair over the 40 year life of the plant.

The kinetically expanded' joints used for repair of the TMI-l l

steam generators are designed to be essentially leak tight.

l The expansion is designed to provide a seal b'elow potential l

t e

- -. s - - . - ;e- - , - + - --

, ,- - - - - , , .v-- y---

I 1

'. ear. pa:hs in a'.1 tubes :: be repaired.  !;':e s vi:5 una:cep:ab'.s leakage as indi:a:ed by the ; e::itical d-ip and ni::csen bubble tests (see Appendix A =ay be roll expanded abeve the icver 6" :o a::e:p: :c seal the leakage.

If :his is unsuccessful the :ube vill be ;'.ugged and/or , ,

s:abilized if necessary. l f

,4

... r.

... sr.. .:.., r.._

..:_,.....e., . . e.2. 3..;. ,..,_.. . ....,.g...

leaka.re lini

s vill centinue to be se:,tv :he e:hnical .

i Specification li=it of 1 sp=. however, in c der :o cen::e!

.ne a=eun: o,. vaste that requ :es processing, a cesign g:a.

J of 1 lb/h 7:0jected total leakage fro: D0th genera 0:s has

. been se fer the qualification p cgra . '

Eubble testing can

! distinguish a leak tha: is of the =a;nitude of C.1 gallens

_m. .yer. day. An eng'inee:ing evaluatien cf bubble tes: results

! as they rela:e to expe::ed leakage vi'.1 be condu::ed in

• • c: der :o de:er=ine wha: tubes require plugging. 5:a:isti:a. .

analysis vill be applied :e 5he verification tes: results.

C. Oualificatien Pretrac A series of =e:hanical tests and che=i:a'.. and cer:qsien tests

!' vere perfer=ed :e qualify :he kine:i: ex;ansion, and :Se kine:i: ..

i expansion' process :c =ee: the design gea..s c:. produe.:.; a ;cin: ,

capable .of carrying required 1 cads , providing a leak :ish: s,,.:,a e a '. ,

s, a.a ..v.. ..e .a> .....,s. .

.es:.s.a1 .. ...e

.u ... ..

c. .. . 3 e. ......

cf preli=inary tes:s was cendue:ed :e es:ablish :he cpti:n=

> para.e:ers fe: a kine:i: expansien p ccess tha: vill yie'.d 4, a::eP:arte scin:s vi:.n lov residual stresses. A_, ., : t :n a . :es:s. .

vere cendu::ed en a full si:e s:ca: generate: at b5V's M: .

• 'ernen W::ks .

. A core detailed des: ip;ict cf :he tes:s and '

re s e'. : s can be fo nd in Referen:e 23.

a

1. Me:hanical Tests

a. preli=inary Leak and Axial Lead Tes ts

, T.inetic expansions were tested :: deter =ine the asii ::

axial load which eculd cause :he expansic: :o slip.

Af:er'a se: cf expansien parare:ers were p:s:u'.a:ed, leak rate and axial lead tes:s we re ;erferred te de:a:- ~

! =ine whe ther :he exp ansien v:uld s:i'.1 appe a: adequa:e

! for a cc :cded tubesheet, cf:e: :her a*. ::.d pressure i .

cycling, and af:e: adjacent tubes have been er.panded.

f The following c.ccep:an:e sea.ls vere a;;1ied. .

l l

(1) Wa e leak at a p:essere differen:ial ef 1175 psi;

(? izary . :e Se:endary ) 3.3 x 10-5 lb/h: pe :ubt.

[ +

L

• 1 b

. 37 _.

i .

l -

e6 --. ,w-' i--.,,..e - ~ ,--+ e--- -,.,e,,- - -.,,.--p r-.m e-- . , - - 4

• e -mm w , w g -

\

1 e l l

(..,,....z...

) .. -

.3 .

. c.s:s......

.. . .....; 3 9. ..., . .v. . ... . r... . . . .

(3) Margin in ;;' iou: icads and leak rate te acccu .: fe:

p:,..e c sr=s a' ' 3e cv:,.:ngd *. . *. anc

. a - :. .- .. . ' g; : .. .s:a..vs

. .....-.:. . '-e-

s:::a.

s. tea..v

<.. w: : :., e>..a ,:..

.. . . . .... .e...

i

($) u.; . . . :_:.e . c. g.:.us.:.

.. s..s:

.2

. . . . u... s .a  :. .. .. .n e . ... n. . ...

.. u. . ,. e ,x. .. .. s :. n ...ess.

I (6) Mini =i:e in plane defer =a:icn cf :he expanded :ute

! ' clock hele and adjacen:. hole s.

J f

• t,

. .,, e .z e.c. . .. s c .s - .. u.. ,. . a ~. a ....a

... p.e.ss..., . .. ....:.. ..

~,. ,.1 c. . .. '. c as . v =. . e - .' .. :. a '. .

1

b. i.eak and Axial 1. cad Oualifi

stien Tests

,a

. . .,. .e. g .e. s. r- s .. ,;; *--,.* ;

- - ,.- ,- , gr.

--s .: -...,,,

- s.a- .

.y.,.

. gxi , 8. .. , a. . . .y : . .,.......

. .g.,..:1:..v..

. .. .. . a. . .. .. .. .. ,. e. . e ,. ., . -

s :. ... .- e u... :. .,. .,e,

. g s n ...

. ., a. ....g.. e :. :. e . . ..,.. .: n.... : . e x.7.., . s :. .

y :. ,. ,. n ,v ,. c.. n.s:g.e..

a . ... . s.,,,:.. .c... .gn...<. .; ... .;e.,. . . . . .:.a.2 ..e . . .

e::e:: c, re-expan:ing prev us.y expance: :u:es.

- . - . s a

+

4 4

i 4 f g - * . . . . - ++ +-N-r -+ *'-'s- y +7 *.+t V3 -? y v'  ? Y -- T. *v' y - d ---

p~.. , e..f . a,. ,. ....

..:.e.:a.. . .e...:. 3...

.u.. ..a s.a.:s.:.a.. . . . e . . s. . . a .

len :: '--

-asults snew c y . :cn:::ence . eve,. :.na: --

c' ..'. .<.-.s ex,.-...v..'...-..- .- , . ' . . . - . . '. c .- '. - .. s. .' . e .

than 3140.lbs. A cean leaka6e ra:e, c. : a'. : # 1ess :han -

3.2 x 10-3 lbs/h /:ube was desired.

Results indicate tha: ther=41 cycling : ends :o de:: case pullce: Icad, however th :=al'y cycled blocks pulled a:

70'? gave a 99 - confiden:e level :ha: 990 cf the tube expanded vill have pullout leads in ex:ess of 4170 lb.

- -' One block which was pull tes:ed a: 330*F save 99/99

~

sta:is:i:a1 ccnfidence tha: pelleu: lead veuld be in c,.r.e.,..

excess c.a e .z e, 0 l.es. .

ane ges.. cen.z :en:e :.r.a e. ....

cf the tubes have pulleu: above 2110 *.b is easily =e:.

In addi:icn, an expansien pull :es: perfer=ed en a fu'.1 s.- a.e ge . e.a.c. . . . . a.. v.... .. . . .. . . s....; .

. . .. . a . ... a. ;. .. ... ..... .: ..

capabili:y of a: less: 3600 ppends.

Le .r,.. a . e . e s .'. s a .# . e . .'..e . a '. c v. .- '. 3. - .- . .- . .v .'.-- .... x i

1 ':

e-

. a.- - : .e . . e- a . .- x . s

. - 6 s. u. . .ru...

. . . . /. . ,. . .-.

a... .. ,... .. ..3,.

g..e; .e -e e.-. ...e... --:....e ...a. .,r.

v. e .s. . . ,

..,. ,...s .. .-.. .. .. . ..

-..c... x. ..,~ . ..t ....e.-.n: s,.. .e . a . x. . . : . s :.a.:...e

. . , . . . ... ... e.... . .... .

fiden:e :ha: 99% cf the nor= ally expanded,:ubes vill have leakage ra:es ne greater ther.132.4 x.. '.S~; ib=/h /:ube. - . . .

...le ant th. s ra:e exceeds :.ne ces t.en c:.e:::ve c: 3.2 x 1C c Ib=/hr/:ube, 1: is s::11 a very ice .eak rz:e.

F.esults cf 1eak ra:es af:e: axial loading are f:und in Referen:e 23.

ll u.,. .:. .. u, c ..-..C . m~ s~ e. 1 e .- >. . a. .' .- . . v. . '. s _ .- 7. 3 - - . a . >. .~.. e A. e.......

. . - .,.i . ..: v ,. ,. e .,... . ... ...v . , . . s> . : ..., . u. e ,. e s . ....

.. . . . . .. ,. .u.

. . . 2. .. ,. .a . .. .. .

.. .:.. , Sp,.. z1..a.:c .. .. s

. . . .. a r.

c .c .. h ,. .e . .-..

m

.. 8. : _.: ...:

. .. ..v ar- - - .

rate of the ene block showed an intresse ietkee- 10'? and 400*F (61 ef the :otal range of leak rates) lea'ing :e .he I conclusien tha: the leak ra:e fer.a.:cie  :...

a cperating ten-y u. . a. ~ s. e p......u .. . , s

v. t.. g c : a.e .z, . c .. ... .... s . :. .u

3. .. . .. .. - . ..u....  :

a.. . .o- .e

. ,,,..a.u....

. . .. e

c. .i.e sic.;a,, ::ress -testine

(,. ,3..: ..

.e  :.. . .v . . . , : . : e.

. . . . . . . . . . . . .. e> .,

: ..4....

........:n.,

. .is ..e s. . de.e._:new;

.u..,.

ea r ..,:.. . . . . . . .. e......... ...,..... s . ....

. u. .

u..ulg

. .ead t .o. a . . ..... :. .. r. .. .. ...a . ., ... ......g ..: ..:.e...

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. 3c. -

9 e

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f.

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g: . ..CVLgeg

.. y. a. . . . . . . . . . . . . .

(2) ?.e sidual Stre ss Me asure ent s

+ .ne a::ual residual s::ess was ceasure: n spe: a.

te st . .. clocks using X-ray. di.,::a:: ion an,. strain gage

et. .:9ues te ce:er=ine Pest .,ane::: exransion tu:e stresses in t.ne :: ansi :.:n area a: :ne bc::o= c:. :ne expansien anc at a se:ene pc :: nea: :ne c1,.d.te. c:.

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gg..nfe.

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yield s::eng:.n ca:ertaas.

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y s. .. s:.C. .. e. 1. .; .C..

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=.

d. ,. . . .a .... . a .c.. :.. AeS.S

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. . .e ~. b.

. . =. =. '. .' e - . s c ' . '. . =..

eXpans 0:. cn :.ne :ube-00-:Obeshee: VeAcs, at: One tcDe

,e...n,

... .o

. ce.e . . . :n,. .,.. s. .. a.:...

s...,a : . . . , , . . . .

.3 pznsion. A design scal of chtni;ing :he 7:e'. cad by less

...,.e,.

. . . . . -. s ,t.s

. c,,,. .c

. e.s . ..a.:..

..s .... ...

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c i

l'

\

y e. 2 :. c _ , .. . D 4. .= ~. e .

_. 4. . n a.~

rne ef fects cf explosive expa .sien e- :he tubeshee:

. g g ,. ... . . y.., a

-e.e.-.nec.

>:-=..,:....... ..

-- .:- . . 3.:. .,..

.no,.es in :he :u.oesnee were reasured - bef ere and a,:e: .

he expansion and cc: pared.

9

' e s

T

~

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• refer.ted belCV O f b C th *ht eXp5T.fici. ler.ith in-

• .*2 5 spe C*iC . p;Ojr&O and the p;Cg!2O 00 Ve-iiy *hnt e 3 *h

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1 l

l

1. Results of the Expansion length Inspection procram Dat-of-generator expansions indicated that the process expansion inserts and detonating materials performed as those used in the qualification program. Profilometry and dia=eter and depth gauge checks showed that the in-generator expansions were within the range of variation of the quali-fication progra= expansions. In addition, eddy current examination using the absolute (8x1) probe was conducted for the first lot of kinetically expanded , tubes in both steam generators. The 8x1 absolute probe has been chosen for this in-process monitoring in the newly expanded area because the coining process of the expansion creates so much background ci e tht: the .566" ?ttnderd diff.srentici eribe it not useful fol'.owing kinetic expansion. The 5xl absolute probe

~

-_ - _ provides 360* coverage. A judgement concerning defect are length can be made depending on how many coils of the 8xl

• • probe detect an indication. Laboratory testing has shown

~

l that a 1 coil indication can have an are length of 5' to  :

40* , a 2 coil indication has an are length up to 85* , and a 3 coil indication has an are length up to 130*. Although

, the 8xl absolute probe can be used to quantify the circum- j ferential extent of a particular indication, it cannot be used to accurately determine the percent thru-wall of the l indication. The scope of the examination included 151 tubes in OTSG S and 284 tubes in OTSG A. The eddy current data ,

was analyzed from the top of the 6" qualification length for -

kinetic expansion down through the bottom of the upper tube- l As a result of this data evaluation, 9 tubes in OTSG i sheet.

B and 6 tubes in OTSG A were reported as having indications which had not previously been detected by the .540" OD ,

high-gain standard dif ferential probe. I These new Sxl ECT indications were evaluated to determine their significance. The evaluation included 1) Fiberscope i examination of selected tube areas where ihdications were detected, 2) Comparison of the size of any visual indica-tions to the ECT sensitivity curves, and 3) Laboratory '

metallographic and ECT examination of known cracks which had been expanded. The following was concluded from this evaluation:

1. The only visual evidence seen which correlates with the ECT indications is small pits and a mechanical scratch.

2. Laboratory expansion of known cracks confirms no growth (no ductile tearing) and indicates no change in 8x1 ECT  !

signal from known cracks. l l

l l

l -

- 44 _

O

.~.

.. s .- ,. .: ..s..es,.

.. . . :.nc:..a.:..s . . . . . . 1.e . .s.--..s.....s..s

-s. .. .w which vere previ:usly belev the 5 0 E T s ensitivi::.

v :. .. u. . . .. . . y. er u. p. .e . . .u. e u s ..e e . (.. . .< , .. u. ,... : . 6. e .-

,. . ..y :s s -

s:all : hat the reliability cf :he new j:in: is no:

L .: :t . .t .a .

u u s.. ..

. . .., - ... r..s.a..e .easc.

. . . .:. . .u..a.:...

.u

. g.. . u. ... . .cx.- ._.u.,. :.s-.,...s:.:..,.. .. .... ..... .....

..a...,-. . .e . r. .,..u.,.

vi:hin the UTS. The Sx1 p::be a;;<ars :: he s: sensi-

...: y e e .....s .. . .u.. .o .es.y...> .6 .0 .:.8 r-. V:.--

• E.- 8 8, 8 1,* ,4 .u,J are c.2 no consequance.

Section IX documents extensive vor.k done to evalua:e the a x: .._ ., : e c .a. ... r. u.u_ .a u ca. y.e ,.e.

1- s e.s.:

s

.c.. - .yie ...,. .::

_ _.c.f :he plan: and'ne: cause tube failure under ner:21 or a::iden: tube loadings. A:cep:sile circu ferential ex:en:

. vs. throughvall dep:h curves fer various leading and 3

.g . . .

ana.ys s c end :.:1ons in :.ne .ree span are snevn n sigure

.ue:.  :  : -

s .:o.. . . . .:. ...- -,. a.e .e

.\,

. . . . . r-- *n>. Ct .1c.. - . .. . . n e .; ., :. n . .

a . e s a '. l e . *.*. . a .. ~'n e .- . .- .'.. s ..- e '. e .- '. . . 3 ~ . ~ *. a -

. '4 u". *. '.. s .- -; '

ce:yani:a. means in :.ne .eree s pan.

These curves are con-serva::ve :c: in.,::::: ens in :.ne j:: : since ,. pads i= pose.,

en :he tubes are trans i: ed to the :ubeshee: in the area of

, g,..c, .,

ex a .:.,. toa>.s c.. . .tu.:...:..

.v..e ..3 . . . v. . . . a .. e c .s ..

viz. ee equal :e c .ess

.c . . . . . . .

t

. nan :.n o s e an a .v. :e ., ., e: :.ne :ree- .

span. .- ec a. age in:ce;h an.

s:2. . ce:e::s wht:. are ....c. .. . ..

th:: ghwall is also expe::ed :: be less than c: e:u s '. to .

si ilar cracks in the freespan. Una: ep stle leakaze vill be identified during precritical :es:ing and :he :ute vill

y. e e :. .:ner p,.cgge, or repairec.

-sc: :u..ese ressens, it is c c . . '. u ' e '. '.'.~. s ~. s ~ a '. '. e .i ~. s c . u . .' =. ~. e .- .. s. ' .- . .- . 'c s . . ~. '. =. "3 " t '. .: -

,a. g.ea . a n , a .:. :. e . . y.. e. . e ,.. :. a . .:u ,. :. .; . . c .: .y, . . . .e.. . ...;......

.. :. sy.r,.

.. .. .eg .u..n.

. . . g ..a .: . c,.. ,. :. n.3 :. s ...s  : .. ..s , :..., , u. e .: .3 . . ,. . .:

: e .a c...a

.. . . : n s. . , y e y s. s ,. ,. :... e c.x,. e .a a.y .

....s..

. .. . . . exo. -- :..a.:...a... .e. . ..u.. e ,

expanded regien to be condue:ed foll:ving :he kinetic expan-- _j sien. .nese indica: ons vil,a be eva*.ua:e,. to ccn:::: t.es: ,

a

hey are a::eptable, and vill be lef: in service and re-ex :ined during ' he 90 day ECT p:cg:t .

. Ide-:i fica tion a-d Expansion of Mis fires E  :

I d

{

)

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s ..

e,

...u.,. .....'. **

a-t

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E.. cte:*****"f * .** *}* .* ..*

'

• J .y, ...%s * * * * * * *3

%.,.... . . . * . s * .. ** ..**

• • ..J f* A 1** d"p . . . .

• • • ..6 .e .**

. *- ' . * * * * . n=C. 1. C. * . . . * * = . *** .

• t....,* =.e, a~. e .= .= . ~ s~ *. . s. ..* ...

l .s. , .

. . C=.=..*.*E=..*. 6.. ..

A.. : .

.z a

p1a . . C. u  ; ... . .J a.. . t . :. ..a.. . %. . e 11' 'e'. a '. : %. . . . m. S.: ....

rr*65 ***-**6 C s7 o. . . : . , s.w

. . . . . . . ... : .he . pC.e. o . .1El .

CC See..un

.. g. ..,5 ..: . %.. . e

.....,. ..g.,

. .. Pgg66g s,....*-.1.

- - - g. 1,,

- -- - . . . g g . .g.-- .,

• A A

~

=.A c.r.... ag, .,s ., .s.. .s .

.... .'D ,. S 15 s .. '. *. . L*

2..,. .e...

... w

. %. 4,. .

p.. t :. . . ..c., . . g.

C, " E l l '..' C c* *. *. *. *.. p *. C3* . 4 #.*".* 2 d *. .#5..

. . * * ' .*.*. e* e ' . 8. .. *3 . ". C .# C.n.

.. n ;. s l e . .u.. , ..* , a ..

.. s. . e i s e x,... ., . e . ' ... %. ,. - ...... s .. : :: . .: e.. . w. m. L. e .

1.. C P, *.. *.e# *.. .".#"..'.. '.*... 3. p* *. *. * *.1

. *w ** C E L . **a**."*~g'.

• . . .C.*... 1 a* *. .' ,V , 1 6c*. W.. *tS.

.AL - *. I. *. S '. . .* *. *. t *. C '. . *. . #. #. #. *.. * *. #..* G e 'L 8. 7. F * '. . . ~. 7.

g.  : ' * - b ,e $ *.,.*.. .e s* *. *.s....

..e... *.. ..*.. .% . . . e- c c.A .. . . . L. a. *. p g *.

aJ..w*J:.lO ..

}US L.,c. ... . ..,

..g .

. . . .. t.%.

=

.. .. . '.a

.; - b.: .} %. p ..v. v... . . : ; , & e k %. s.. .s .... w. .3 '1.

. e$ . .:...

. . . . . ' . .. s . . ,y . '. q c'*. 86*

s

e. <e.

s 4

.-__-----------w---s.--- __-x - - --2,-- ., - - - - - - - - - -.m a.--,

t t

.  : . .. v. -

. ea s. .- .. .. .: . . .. ....-

'.eak length and a ucrs: case C.0C1" radia*. annulus, the '.eak

. 3. C b e .- *. s . . "w . .*. ef --. -. . -...

. . .e .as p . . .,. ex. f. :C...y.., L. *

.: *:_: ~.%. . :. S .. .. ... .. .. ..., I g ...,.

..... .c .o n e Ae u... : a . ...1 .c m, . :g.....e . .. ... .. .. ..

s #. . e .s *. .-...c .0e.*.'. ~. C k. '. C . . . s e . ". *s *. *. '. *. '.*..*.*'.S*. . . .'; s . . . " . . " .

I

. g 'r.. ...y y.... 7 . .c . . L. t . - t sv-s=*s---=

r-

=

-= ss ~~ E -~I- s's ---

.y.. . . v.. s u es os s .....C e

. ..x S

. r *- c. l . s..:.. '. ^5 *..e.A r... ...s.,. ......

a L. ,. 1. .

. .a . t .; ...;

..y...:C.

1 e .s .. o.nf yCL.*d . D,. .*.33,.5 y.... .J.

• • . , a. a. e . . .

4

. stao:1.:ec. .

i Of the app cxi=stely 7000 tubes

• eniv. about 101 were to be ele sr.ed.

.e..: r p e. c.' .- p1ue~.6 ... *.ube ceL'.' .. o . '- . '.'=...-: . . .....' ... ' . * . . . -

• - - -  :-g y 3... -...s

. . . . . :.s .ne

.. ...y,.

.. .... ,,,:cr.. a . > 1 c .-y.,. .a... :. cou,.g u..~

c: be dync=ica11v, uns:able in cross fiev areas and cause 4 _

ves: da= age to adjacent tubes. i.ppr:xi=stely ha'.f cf the

1:. ,.a, .. .u.

.. a .....y ,. s y : t .- .u.e s..u. .. ... .. : . u. s .. -..;. . ..e.,... v . . . . ..

...33 r . .

da=sge. ~he re=ainder are in areas Of =ini=ci :::sS fic ,

sw.. .,. c .. .,.. .w.

. : . s . .b :.11.y

. s d yn ... . . . .. . . .. ...t....

7.. ...

- s

., a . e ,. . ..: v ,. . .;

n... ... . u. e .e u. ,. ,. .. ..... ....,~

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s . . . . . .

.. . . . , . ,n..

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i t

r T

-. t. $.. ;. ~, .. .,. : . . ,. .e ...  : ns.

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4 expansiens leak :es:.

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e r. .e!.

.. =..,

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no : 0.a,.w testing vil3. inc.uce transien:s :.a: v :1 p.a:e

.- = . g .

. . .- 3.,:

cpera:ing Icads'en :.ne new join:.  :. ..ese ::ansien:s e incluCe F

'7- .

_O ,

{

t g y9 -p-%... ,- , *. g.-,- - - -g,e . . , _ . , r-v.. , , , - . -

l l

a. normal cooldown

b. accelerated cooldown l

c. 1400 psid operational leak test.

I Leakage will be monitored before and after the transients.

l i

A = ore detailed explanation of the testing programs can be found in Appendix A.

l In the event unacceptable leakage is identified for par-ticular tubes, they will be repaired, if ~ possible , or removed from service. The backup repair method which has been selected is to place a hard mechanical roll expansion above the kinetic expansion joint 6" qualification length. ,

~

The roll expansion will ce cen:ere'c some discance acove ene

___ top of the 6" q'dalification length of the kinetic expan-sion. This distance has been preliminary selected as 1". i

- '

• Although the roll expansion' will extrude some metal, it is considered intuitively obvious that it will not affect the  !

I ability of the qualification length to carry normal and accident loads. In fact, the roll may actually increase  !

j pullout load capability.

The leak sealing ability of the roll expansion'will not be {

tested. Roll expansion will be used only in tubes needing additional sealing as determined by visible N2 bubbles.

There will be subsequent leak testing prior to HFT, which 8 vill demonstrate the effectiveness of the expansion as a l

seal. Additionally, early expansion t'esting using hard roll i expansions demonstrated that such expansions sealed leaking tubes.  !

If any expanded, then rolled, tube continues to leak exces- ,

sively af ter given the chance to "self seal", plugging vill j be necessary. l l

~' - F. Conclusions Based on a qualification program, the kinetic joint meets or exceeds the design bases of the original joint, including the following factors:

G e

~

I

- l

a. 1,oad-carrying capability.

b. Tube preload,

c. Minimization of residual stresse s.

Leakage is projected to be less than one-one hundredth of the technical specification li=it of 1 gpm.- Kinetic expansion in the upper tubesheet is a safe and reliable method of repair for -

all tube s that will remain in service in the D'.I-1 steam genera-tors. The tube joints vill remain structurally sound and essen-tially leak-tight during all design conditions over at least a five year period.

Ow se 9 4 e

f

• m

+

e e

49 -

I

-. q# + e p g y g

l i

l l

VI. EFFECTS OF EXPANSION REPAIR ,

The possible effects of the kinetic expansion process with respect to introduction of chemical i= purities, the effect on the OISG structure, the effect on tubesheet corrosion characteristics and the effect on existing plugs have been evaluated.

A. possible Introduction of Che=ical I= urities The specification for OISG tube repair addresses the issue of impurities in the system. It specifies that the inside of the steam generator will not be exposed to materials containing more than 250 pp= sulfur and 250 ppm total chlorides and f1'uorides ,

L :72:ifi2d 12:2:::512 ::::n:: c f 1:" :si tin;  :#-: 22::1:.

Required deviations,will be addressed on a case basis. A

- - - material control program with quality controls was required for confir=ation that material is not introduced inside the steam generator without assurance th.at its constituents are known and

~ l acceptable was implemented. l l ' The large majority of the debris was demonstrated (testing in mockups and a full-scale OTSG) to be particulate matter. The large particulate debris was removed by manually picking up

pieces by hand, and by vacuuming in both the ' lower and upper heads. Particulate debris in the tubes was removed by forcing l felt plugs through each tube.

In addition to the easily removed particulate debris, laboratory tests showed a thin layer of material was deposited on the ec- l posed OTSG surfaces. This film consists primarily of carbon, ,

identified as polypropylene. The amounts of contaminants , sul- .

far and other elements, in this layer are low (traces only). In order to minimize the potential for the film interfering with a subsequent sulfur treatment, steps were taken to minimize film i thickness. The CTSG surfaces were coated prior to expansion with a substance which, when flushed with water,. reduced the film thickness significantly.

This residual film is not uniform over the length of the tubes,  !

being thickest nearest the expansion. The results of tests show a remaining layer, after flushing, which averages 50 Angstroms '

thick over the length of the tube. A similar condition should ,

exist at the top of the tubesheet surfaces and the inner sur-  !

faces in the dome of the upper head. -

. As a worst case, it may be assumed that the 50 A film on the [

31,000 tubes melts as the reactor coolant approaches operating  ;

temperature. The polypropylene is not: soluble in hot water,- but .

ir i b '

e -

p-r , -

y e- --m- ,--n - ,r.-  % 2 a,-.m +

mr -- +-r- 'ee--*+--- - - --w++-we+ -,~vm+ w-+

the high velocity coolant through the tubes could entrain par- l ticles as they sof ten and lose fil= tension on the tube sur- f face. The turbulant reactor coolant flow would carry these minute dreplets of =olten plastic throughout the reactor coolant.

system as a very dilute e=ulsion of about 0.44 ppm polypro-pylene. The de=ineralicers and filters in the letdown syste=

would gradually recove this slight impurity from the reactor coolant. Industry experience shows that there =ay be a tendency for the molten droplets to collect in relatively stagnant areas of the reactor coolant system. The reactor head would be the ,

cost likely area of concentration, and during cooldown the poly ,

propylene =ay solidify as a film on the under side of the dome. j In the unlikely event that the total volume of plastic were to sapsrs a : : in :aa cac; cr;;, :n- - L.. 2a : :.: r-u icu.. ...-

lect a negligible amount of residue.

i Should there be a reactor cool'down, any molten droplets re-  ;

maining in the coolant would tend to solidify as a film on the l coolest surface available. Both the letdown and decay heat I syste=s will be cooling portions of the reactor coolant and the l polypropylene would redeposit as a thin film on the letdown andl decay heat cooler tubes. The hot surfaces in the core are the j least likely places for the plastic' to solidify. 'There is no i reasonable assu=ption which would indicate the half cup vol,u=e ;

of plastic film could cause a problem before it is re=oved from!

the syste=. ,

B. Possible Ef fects on OTSC Structure .

It has been postulated that the kinetic expansion may, because of the large nucber of tubes involved, have significant effects on the stea: generator as a structure as well as on the indi-vidual tubes.

For individual expansion, evaluation of the tubesheet ligaments has shown no significant ef fects of expansion. .It was pcstu-lated that with cultiple kinetic expansions there could be a shock wave reinforcement such that the sequence of explosions or the length of the prima cord should be controlled to insure that the tubesheet is not overstressed. The concern was that the shock wave may travel at about the speed of sound through the caterial, and if adjacent tubes exploded in a manner such that their shock wave reinforces shock waves from other tubes, there could be a condition where the tubesheet is overstressed.

Testing was performed in the steam generator at Mt. Vernon using strain gages and an accelerometer to demonstrate that the coin-cident explosions of the maximum number of tubes to be expanded

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I

Eased on the test results, tubesheet inspection and trevice flushing, extensive corrosion of the tubesheet by resi-cual sulfur deposits or reactor coolant is considered highly unlikely .

D. Ef fects cf Ex:ansiens on Existing plugs The TM1-1 OTSG tubes have been taken out of service by four different procedures: '

1. Explosively welded plugs - Plugs inserted into the tube and explosively welded in position within the tubesheet.

_. ne: cec plugs .:luga .e..=- c. - :. 4 tu.e ancs .: : _; -;.a u; a:

the top of the upper tubesheet.

3. Hydraulically expanded tubes sealed with a welded plug -

tubes that have been ic=obilized by expansion af ter a short section of the. tube within the tubesheet was removed. The tubes were then taken out of service by installing welded plugs in the tubesheet openings.

d 4. Mechanically rolled plugs.  :

B&W has evaluated the effect the forces of the kinetic expan-sions may have on the integrity of the first three of these plugs and expansions and has concluded the kinetic expansions will not affect their mechanical integrity or leak tightness.

Tests of the kinetic expansion process in steam generator model test blocks with conditions simulating those in the TMI-1 steam generators show that the kinetic expansion does not produce any permanent tubesheet ligament defornation. This leads to the conclusion that plugged tubes adjacent to kinetic expansions will not be altered by changes in the tubesheet ligament, since

~. no percanent change is noted. .

During additional tests on an actual GTSG, B&W examined, by dye penetrant tests, the tube-to-tubesheet welds and tubesheet ligaments of the kinetically expanded tubes and the tube-to-tubesheet welds adjacent to expanded tubes and have not seen any de gradation.

Thirdly, the extensive laboratory and field experience of B&W with explosive plugging tubes in operating steam generators

- indicates that damage to plugged tubes due to detonation of explosives in adjacent tubes does not occur.

b O

_- g , . , . . . - ,

Tests were performed on qualification blocks with rolled plugs in place and explosive expansions of all adjacent tube loca-tions. Leak rate and axial load tests were done to verify that the rolled plugs continued to meet the acceptance criteria to which they were originally qualified for use.

Lastly, a pre-operational post-kinetic expansion pressure test of each generator will be made to verify the integrity of the primary to secondary pressure boundary, thus providing added assurance that the plugged tubes have not degraded.

E. Conclusions

.:.;.;, .'. a:. .u : i : =7 = . - -

3aseo on ne euc.e ava. ae:.;r. a.

process will hr.ve no adverse ef fect on the OTSG In structure, addition,tube-a sheet corrosion, or plugs previously installed.

• cleaning process has been developed which will remove the resi-due from the expansion process. In conclusion, overall there are no adverse effects from the kinetic expansion process.

4

TlII. PLUGGING REPAIR DESCRIPTION SIEMARY A. Introduction 4

Those tubes which have defects below the 16" from the primary surface of the upper tubesheet (US) and cannot be recovered and returned to service by the above described Kinetic Expansion repair shall be removed from service by plugging. A defect is defined as any eddy current indication interpreted as greater than or equal to 40% through wall. For conservatism, any less than 40% I.D. indication with a large enough circumferential extent to be detected on three or more of the eight coils of the absolute probe will be treated as a defect for plugging pur-The limits of edd" current detectabilit r are defined in 1

rests.

i Section IX. There are a total of 259 tubes in A anc do tuces in a OTSG that have been plugged with either Westinghouse rolled plugs or E&W welded and explosive plugs. It' is projected that  !

an additional 627 tubes in A and 185 tubes in B OTSG will be removed from service by plugging after kinetic expansion. 19 tubes in A and 10 tubes in B steam generator which have been cut and removed for metallurgical examination were plugged with a B&W welded tapered cap on the top and an explosive plug at the 3 bottom tubesheet. Defective tubes in some locations will be stabilized as indicated in Table VII-1. 475 tubes will be s tabilized. The purpose of tube stabilization is to minimize the risk due to propagation of tube defects located in regions

- with high potential for flow induced vibration resulting in circumferential tube severence and causing damage to adjacent tubes or creating loose parts. The lower tube end will be plugged with an explosive plug. The following sections give an evaluation of the methods selected for tube plugging and stabilization, and a description of the types of plugs to be used.

A B. TVpes of Plugs

1. B&W Welded Tapered Plug, Welded Cap,' Stabilizer and B&W 2 j

Explosive Plug i

B&W Welded Tapered Plug is used to plug the bare upper tube-sheet hole for tubes where the tube end has been removed.

B&W's welded cap is used to seal the upper tube end for those tubes which will be plugged and stabilized. Prior to-installing the weld cap, the existing tube end will be machined off leaving a portion of the tube end and the existing weld protruding above the tubesheet surface. The weld of the nail cap will fuse with the existing seal weld,

~

providing the desired pressure, bou,ndary.

i

)

l t

t VII-1 0071.1NE OF DASIC TUSC PLUGGING /STABILIIING PLAM Dt able Pluggable Defect Pluggable Indication

>,401 TW 4 40 Percent Tw and 8 x 1 >2 Coils,ID

[ a E

m a a = n

.: r--

15th SP to LS - 4 15th SP to LS-4 US + f to ny Tube Spar 15th SP to LS-4 15th SP 15th SP to LS-4 in Lane / Wedge to in Lanc/ttc. Ige 8xl i 2 colls 48 and to =24

.:ot Isolated

.y Dottos 6*

US + 4 San > 2 colls Illstorical Defect Area (Note 4) LS -4 Nistorical (Notes 2 and 4) - ..! kinetic Defect Area (Note II spansion i 1 1 1 I . I Flug and Stabtlize to Plug Only . lug Only Fly and Stabittee PlugA Stabilise Plug and Stabilize to Bottom of 14 $P to Sottom of

• at least in Spari notto:n of leth SP (Kote 3) (Note 3) 14th SP of Defect

. 1. includes tube secttons f rom l>ottom of 15th support plate to 4-inches up into Lot tom of upgcr tutiesheet.

2. Include: tube section from bottom of 15th support plate to f inches down fron ene

• op of tiie lower tubesheet.

3. . See rigure Vil 2- for tubes in I.ane/ Wedge area.

4. Sal is ECT probe with 8 absolute coils e

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B&W Explosive Plug is used to plug LTS tube ends where B&W plugs are used in UTS. Both B&W plug types MK-1 and MK-3 have been qualified for OTSG tube plugging and used in the operating E&W units.

35W standard design stabilizer rods will be threaded onto the welded cap to form a stabilizer assembly of the desired length. . The stabilizer is a multi-piece assembly of solid red made of Inconel SB-166. Joint tightness. is maintained by crimping the pieces together beyond the threaded sec-tions. The segment length is dependent upon the tube bundle location.

' . ' ' :111:d : 7:r2d pl :;: . nliad :: . r:pl::3.ce < :, tri stablizer rods have been previously qualified see References

- -30 through 35.

2. Festinghouse Rolled Plugs ,

Westinghouse plugs were designed for a primary pressure of 2500 psi and 650*F and a secondary pressure of 1050 psi and 600'F. Cracks in the roll transition or the area of the seal weld do not exclude the use of Westinghouse rolled plug.

The Westinghouse rolled plug is machined from bar stock that has received a thermal heat treatment which has been demon-strated by laboratory testing to have improved resistance to intergranular attack in caustic and polytheonic acid envi-renments, compared to treatments at different temperatures and times.

The Westinghouse Roll Plug Qualification Program for TMI-l has been completed for a 5 year life, and results are docu-nented in Westinghouse Report WCAP-10084.

C. Plugging and Stabilization Criteria Final tube plugging and stabilization criteria were selected to minimize the possibility of cracks propagating to a size which could part under stress conditions, either plugged or unplugged tubes. Analyses presented in Section IX show that the vibra-tional effects of cross flow are not expected to contribute to crack growth in an unplugged tube. However , as a precautionary measure, plugged tubes with defects in the area of highest cross flow between the 15th support plate and US+4, are stabilized.

In addition, stabilizers have been used where eddy current in-dicates a crack of significant size in historical defect areas, and below the 15th support plate where.I.D. $x1 indications are greater than 2 coils. Measures to monitor for crack propagation due to flow-induced vibration or other means, including leakage I

i +

l l

l __ _~ _ _ _ _._ . _

monitoring (Section X) and eddy current inspection for wear

( Appendix A) are discussed separately.

I The steam generator has been divided into six areas for purposes TVo of dispositioning tubes for plugging and stabilization.' ,

areas are within the upper tube sheet: between US+8 and US+4, and between US+4 and US+0, where US+0 is the lower face of the i upper tubesheet. Tubes where the lowest defect is above US+8 l' are repaired by kinetic expansion. Tubing between the tube-sheets has been divided into three areas: tubes between the 15th support plate and US+4, tubes between the 15th support  !

plate and LS-4 in the lane / wedge area, and tubes between 'the 15th support plate and LS-4 outside the lane / wedge area. The

.; . .a : ai hin . .; 1 2r ::: :: c.2 2 : .

la;; r2;ien :::s ::::u Plugging and stabilization criteria are discussed in detail in Reference 25 and sum =arized below: ,

I

1. Tubes with Defects Between. US+4 and US+8" i t

Tubes with a defect between US+5 and US+8 may not be effec-tively repaired by the 22" Kinetic Expansion. A qualified i length of 6" expansion is required to insure a leak-tight, load-carrying joint to assure the OTSG integrity is retained ,

under the most adverse conditions during ' operation. There-  ;

fore, those tubes with defects between US+4" and +8" will be  !

i both kinetically expanded to 22" and plugged. Even if the existing crack would propagate in the future and sever at  ;

US+5", testing (Ref. 23) indicates that the expansion joint ',

below the severance would provide enough engagement to main- l tain the preload in the tube and carry the loads associated with the most severe transient during normal operation.

Thus tubes with defects in this area are not expected to wear adjacent tubes due to dynamic instability in high l crossflow. Therefore, it was concluded that these tubes j need not be stabilized (unless stabilization is required by  :

I defects of greater than 3 coils between US'+4" and US+5").

2. Tubes with Defects Between US+4 and US+0 i Even with a 22" expansion, these tubes would not have the 3" kinetic expansion joint below the defect to maintain preload i and assure that the tube will not slip under the most severe ,'

transient during normal operation (i.e . , 100*F/hr. cool-down). If the tube ratcheted down to the point where it was j

in compression during operation, the potential exists for i the tube becoming dynamically unstable or buckle. There- i fore , af ter receiving a 22" expansion, a tube with a defect in this area will be plugged and stabilized through the 14th {'

tube support plate.

9 O

I.

3. Tubes with Defects Between 15th Support Place to US+0  !

indication in this area, For conservatism, any eddy current or circumferen-regardless of type, through-wall measurementTubes with defects in tial extent, was treated as a defect.

this area received a 17" expansion snd were stabilized to the 14th tube support plate, unless a lower defect was located in an area requiring a longer stabilizer.

This criterion covers the high cross ' flow tube span in the Even if a tube were postulated top of the steam generator.

to become severed at this elevation, it could not get free and damage adjacent tubes.

4 Tubes with Defects from 15th Support Plate to LS-4 in Lane

~ ~

Wedge Area B&W plants have a history,of corresion and vibration prob-lems in the areas of the untubed inspection lane. As a precautionary measure, an area of potential problems has been defined one row on either side of the lane, widening to a wedge shape as the lane nears the periphery. For tubes indication,.regardless of in this area, any I.D. eddy current or circumferential extent, type, through-wall measurement,These tubes will receive a 17" will be treated as a defect.

expansion, then be plugged and stabilized through the 14th support plate unless other criteria require stabilization through the defect in the lower spans.

5. Tubes with Defects Between the 15th Support Place and LS-4 In the tube span between the 15th support plate and LS-4 outside the lane / wedge area defects were divided into two groups: 1) ECT indications greater than or equal to 40%

through wall with 8xl indication greater than 2 coils, and

2) ECT indications greater than or equal ~to 40% through wall with 8xl indicttion less than or equal to 2 coils.

After a 17" expansion, tubes with defects greater than or equal to 40 through wall and 8xl greater than 2 coils were stabilized through the span with the lowest defect for that tube. Tubes with greater than 40% through wall defects and Ex1 indications on 2 coils or fewer were expanded to 17" or 22" as appropriate and plugged with the Westinghouse rolled l

plug.

f

, - - _ -- _. ... __ . . - ~ . .- - -

This criterion provides a means for determining the tube are length extent of a defect in order to decide if the' tube should be stabilized. The tube would be stabilized at least within the tube span containing the ECT indication if there i is any substantial size or are length involved in the ECT indication. If an ECT indication is seen on less than three coils on the 8x1 ECT probe it means that the arc length of ,

the degraded area of the tube of a maximum of about 0.41 inch long at the inside diameter of the tube. Because of 1 the " thumbnail" shape of the inside diameter cracks found at ,

TMI-l this means that the average are length of the largest !

l i two-coil ECT crack would be about 0.26 inch. This size  !

crack is accentable without stabilizint and is not excected to propagate to failure 'y omecnanical means during opera-tion (Ref. 25).

. This criteria for stabilizing, based on arc length as .

measured by the 8xl probe is not invoked for ECT indications i less than 40 percent through wall because such an indication is too small to fail the tube. Even if a tube had a 360* i indication, the tube would not fail with less than 40 percent penetration (Ref. 25). _

6. Tubes with Defects in the Lower Tubesheet Below LS-4 l Tubes with pluggable defects in the lower 20" of the LTS were removed from service using a Westinghouse rolled plug or an explosive plug. A welded plug was used in lieu of l mechanical rolled plugs if the defect was in the rolled area.~

1 D. Post Repair Testing The following post repair tests will be performed to verify plug 'l integrity.

1. 150 psig bubble test

2. 150 psig drip test

3. 1400 psid operational leak test l Details on post repair testing can be found in Appendix A.

i i

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E. Conclusions The OTSG Tube Plugging Pia, will restore the pressure boundary  ;

integrity of the steam ghirrators by removing defective tubes l from service for those tribes which have defects below the region available for expansion repair.

The plugs used have been previously qualified for use. Tubes i have been stabilized which have large defects in areas of high crossflow or areas of historic problems with vibration or cor-rosion at B&W plants. Thus plugged tubes with the highest potential for tube serverence in the future are prevented from j wearing adjacent tubes.

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Vill. COMP ARISON OF TUBE PLUGGING WITH DESIGN BASIS A. Introduction This section describes the results of analyses performed to determine if che steam generators could be safely operated with up to 1500 tubes plugged. The first part of this section re-views the operational consideration of operating with tubes removed from service for: reduction in total flow and margin to

• departure from nucleate boiling effects of asymetric flow dis-tribution, ef fects on flow coastdown rate, ef fects on steam generator mass inventory and capability of natural circulation.

The se.cond part reviews the ef fects of removing tubes from ser-vice on smatl anc serge aresa masa 02 cec 4:: a;;_cer..a a 41. ,

.as all other ac'cidents and transients analyzed in the FSAR. The third part considers the effects of plugging on moisture carry-

• over. These analyses have concluded that the margins of safety as defined in the Technical Specification will not be reduced by operating the TMI-l steam generators with up to 1500 tubes re-moved from service.

B. Operational Performance _

1. RC Flow Rate and Margin to Minimum DNBR i

The calculated RC flow rate for all four RC pumps operating as a function of an equal number of tubes plugged in each steam generator is shown in Figure VIII-1. Generally, a reduction in tubes available for RC flow will cause the tube bundle pressure drop to increase. Since the remaining sys-tem pressure losses- are about four times greater than the tube bundle pressure losses, only a slight reduction in total RC flow rate will result. The total RC core flow for 1500 plugged tubes will be the same as the symmetric case,-

i.e. 750 in each steam generator. From the figure, the reduction in total RC flow will be from .109% of design to 108. 2% , a change o f 0. 8% . (Reference 42)

In order to determine the impact on the existing steady state Departure from Nucleate Boiling Ratio (DNBR) resulting from the RCS flow reduction at steady state, a study was performed to determine the minimum RCS flow rate required to maintain the existing DNB ratio for the THI-1 licensed power level of 2535 HWt. The existing DNB steady state ratio of j' 2.0123 was determined at a conservative power level of 2568

~ MWt and an RCS flow rate of 106.5% of design flow.

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The methodology for the analysis was to calculate the hot' bundle flow by using a CHATA (Reference 36) core model which took heat balance input from the CIPP code (Reference' 37).

By using the hot bundle flow in the computer code TEMP (Reference 38), the Minimum DNBR (MDNBR) was calculated for the hot' sub cl.annel from the BAW-2 correlation (a cor-relation.

The results indicate that DNBR value of 2.0123 can be main-tained with an RCS flow rate of 104% of design and a power of 2535 MWt as compared with the original 106.5% flow and 2568 MWT. The minimum calculated RCS flow rate at TMI-1 has been 109.5% of design flow. Tne maximum error#' on this value T' i : r,:ul:2 .'- #a - - # **?"

. ; 1. ? *: . . : .i r:m :

of design. Th,is will be reduced to 107.2% after the tubes

- - - are plugged. This is substantially greater than the design basis flow rate of 106 5% which would be required to main-

• tain the design basis steady state DNBR value of 2.0123 at 2568 MWt. For the TMI-l power level of 2535 MWT, the 104%

design flow requirement to maintain the same DNBR provides for an even greater margin. It can thus be very conser-vatively cencluded that the plant design basis flow rate considerations will be preserved with 1500 tubes plugged.

2. Asymmetric RC Loon Flow Distribution The final plugging pattern will be about 6% of the tubes in the A Steam Generator and about 2% of the tubes in the B Steam Generator. In order to investigate the asymmetric ef fect of the RC loop flowrates, an evaluation of an exag-gerated plugging pattern of 1500 tubes in one of the TMI-l steam generators has been performed. The Loop A flowrate will be approximately 2-1/2% smaller than Loop B.

Field data at TMI-l during the last cycle has shown that the A loop has typically about 3% more flow than the B loop.

The result of more plugging in the A Steam Generator will thus be a somewhat more balanced loop flow distribution.

The new flow difference is expected to be approximately 0.5%.

3. RC Flow Coastdown Rate With a significant number of tubes being plugged, the resis-tance factor for the RC flow passing through the OTSG will ,

be increased. This increased resistance may change the flow distribution if one RC pump is tripped while the other pump in the coolant loop is maintained in operation. The com-bined core flow during the coastdown may also be different.

- 63.-

O 4

(

l Further, the minimum margin to DNBR during a less of flow eve nt is known to be dependent on pump coastdown rates. To address these issues the following analysis was done.

A cocputer analysis has been conducted using the B&W code "PUMF" (Reference 39) for the TMI-l type reactor coolant.

system's flow coastdown curves with zero and 1500 tubes plugged in the A Steam Generator. . The FSAR analyses served as the base case for the four pump -coastdown transient.

Results of the analyses with 1500 cubes plugged in one steam generator show that the FSAR coastdown rate is still bounding.

Figure VIII-2 su== arises the data obtained fron the four pump coastd'own transient performed with the TMI-l version of PUMP code and compares.this data with the FSAR analyzed flow coastdown. This comparison shows that the flow even with 1500 plugged tubes starts at a higher level than the flow assumed in the FSAR analysis and coasts down at approxi-

=ately the same rate since the flow is at all times greater than that assumed in the FSAR the minimum margin to DNB will not be changed. .

4. Steam Generator Water Inventory and Operating Level- 4 Indication The water inventory in the steam generator, will increase by a small amount due to the decrease in average quality in the plugged section. REIRAN-02 (Reference 43) and TRANSG (Reference 44), which are both one dimensional transient ther=al hydraulic computer programs with slip option, have been used. The inventory increase was calculated to be 5%

or less, which is less than 2000 pounds with 1500 cubes plugged.

- Total secondary side flow will increase only slightly with decreased steam outlet temperature. This would tend to cause a slight increase in pre ssure drop. This increase will be of fset by the reduction in average quality (increase in density). The net ef fect should be little or no increase in the startup level.

5. capability of Natural Circulation The impact of steam generator tube plugging on the capability of stable transition to natural circulation was examined by using the B&W compu,ter program AUX (Reference 49). Symmetric plugging of 1500 tubes in each side-was

x e

assumed to be the bounding case. Figures VIII-3 and VIII-4 ccmpare the analysis results of 1500 cubes plugged to no tubes plugged. At about 500 seconds af ter the/ reactor coolant pumps trip, the stable natural circulation flow with 1500 tubes plugged is about 8% less than that.with no tubes plugged. At no time is natural circula' tion lost,and the reactor coolant system remains subcooled. Ihe subcooling ~

margin for 1500 cubes plugged is only about,2*F'Iess than the case without plugging (about 90'F). Therefore these analyses have shown that natural circulation is still an ef fective method for decay heat removal. - 1 l

i C. A : idea.t sed Transient Serformance

_l . LOCA Analys&s

• The potential ef fects of SG tube plugging on ' generic Large Break LOCA (LBLOCA) and Small Break /LOCA (SBLOCA) analyses (Reference 40) with 1500 cubes plug'ged has been'eKamined.

With about 6% of the tubes in the A St.eam Generator-and about 2% tubes in the B Steam Generator _being plugged, the generic (2772 MWt) LOCA analyses for -B&W 177FA Lowcred Loop Plants remain valid for IMI-1, with continded operation at core power levels up to the licensed 2535 MWt at the existing LDCA limits. An overview of 'this examination is provided below.

a. SBLOCA Concerns The evaluation models used in the existing S510CA analyse's (Reference 40) assume equilibrium c'onditions within the control volumes used to model the SG secon-dary side. For this reason, the localized cooling .ef-fects of EFW spray on particular tubes,- and the ef fects on this cooling if particular tubes are deactivated, cannot be accurately predicted with enese models.

In the application of the revised SELOCA evaluation model (Reference 41), it was a'sseded that:

1. The percentage reduction in the number of peripheral

! tubes removed from service will degrade the EfW spray cooling heat removal capability in a 1:1' relationship.

l

2. The degradation in heat removal capability,from EFW spray cooling translates directly to a reduction in-

' depressurization ra'te by a l~:1 r'elationship.

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In reality, these relationships are expected to be con-servative. Since if EFW spray impacts a deactivated tube, it will not be heated and/or flashed immediately but will either:

1. Be redirected onto adjacent active tubes, or;

2. Flow inward into the tube bundle, providing cooling

' to active interior tubes, or;

3. Fall into the saturated steam or saturated water region, resulting in increased cooling within these regions and/or an increase in the fill rate to the appropriate level setpoint.

A more detailed discussion of EFW spray effectiveness and the THI-l response to SBLOCA with plugged tubes is

• given in Ref. 59.

Therefore the water is available in the steam generator and will result in greater EFW spray cooling and higher )

depressurization rate than predicted by the analyses.

In this evaluation (Reference 42), two break cases were considered. The first is the worst case with respect to peak clad temperature for a small break LOCA, identified as approximately a 0.07 ft2 cold leg break. The second, belongs to the category of breaks in which SG heat removal is needed to help depressurize the .RCS.

The 0 01 ft2 break was analysed because this was the largest break size which would result in RCS repres-surization.

Plugging 1500 SG tubes was used as a upper bound which represents a deactivation of approximately 5% of TMI-l's total tubes. Also, because substantial tube plugging will be done in the peripheral SG tubes regions, it is estimated that about 18% of TMI-l's total peripheral ,

tubes will be deactivated. i Worst Case 0.07 ft Cold leg Break with One HPI Train For this break size, the primary system pressure decreases below 1000 psi (approximately.the secondary Af ter this time ,

side pressure) at about 300 seconds.

SG heat removal is no longer possible, and the secondary side becomes'a heat source for the primary system. Core uncovery begins at about 1350 seconds -and ends at about The maximum time that SC (and EFW spray) 1750 seconds.

cooling can be of benefit during the accident is the first 300 seconds. This is very short when. compared with the time to begin core uncovery.

4

I t

The plugging of 1500 SG tubes will result in a reduction of the initial RCS liquid inventory by about 200 ft3

' This results in the core being uncovered about 3 seconds e

earlier and in approximately a 10F increase in peak cladding temperature (to about 1100*F). This will have minimal Lapr.ct on the outcome of this accident. It should also be noted that the generic analyses show

• that, for a 0.07 ft2 break with 2 HPI trains, the core

' does not uncover and temperature remains below 700*F.

0.01 ft2 Cold Leg Break Ta : . :'. f:2 ::'i 12; ir2 2; :221 n: sa a 'c: 2; t d u c #. q the revised SBLOCA mocel. All of the original analysis

' assumptions were preserved, including a 20 minute operator delay in initiating emergency feedwater. Two cases were analyzed considering the effects of tube plugging on the decrease in RCS depressurization rate which could increase the time to initiate ESFAS and the rate of heat transfer in the boiler condenser mode. It was found that:

With a 1600 psig low RCS pressure' ESFAS setpoint, the 0.01 ft2 case will result in ESFAS actuation regard-less of the reduced peripheral and internal SG heat removal caused by the plugging of 1500 SG tubes. Before ESFAS actuation, the RCS was subcooled and either forced or natural circulation existed. Consequently, SG heat removal was found to take place throughout the entire SG tube region, not predominantly in the peripheral regions. Therefore, the SG heat removal rate is not reduced by more than 5% during the period prior to ESFAS, and this will delay only slightly the activation of ESFAS.

^

The 0.01 ft2 break case will cause the RCS to enter the boiler-condenser (B-C) mode. In this mode, EFW spray cooling of the peripheral tubes is an important factor in the RCS depressurization. Thus, peripheral SG tube plugging could have a more significant effect on this cooling mode. The evaluation showed that, with 18%

of all peripheral tubes plugged, suf ficient steam

=

generator EFW spray heat removal capability remains so that the rate of RCS depressurization is reduced by only about 12%. Even with this reduction, calculations with all other original analysis assumptions unchanged show a minimum of five feet of coolant remains above the core throughout the event. Since the 0.01 ft2 break is

approximately the largest break which would result in RCS repressurization, the plugging of 1500 SG tubes is expected to have only minimal ef fect on SBLOCA e transients.

In summary, these small break size LOCA analysis show that for the previously limiting case of 0.07 ft 2 cold leg break with only one EPI train available, peak clad temperature increased by only 10*F to about 1100*F. For the 0.01 ft2 cold leg break, the slight delay in ESFAS actuation and the reduced area for EFW cooling have an insignificant' ef fect on the outcome of the transient

2 mini um :f Ji a f:-:: :f :::':-: r:::in: ::: n the core for both the plugged tube and unplugged tube

-- - - cases. Therefore the generic LOCA analyses remain valid for TMI-l even with a small reduction in SG heat removal caused by tube plugging.

b. LBLOCA The important parameters for the LBLOCA which are effected by plugging of tubes are the initial flow and flow coastdown. The ef fects of the reduction in coolant volume associated with 1500 plugged tubes (200 f t3 )

are negligible for this event. The plugging of 1500 SG tubes at IMI-1 will reduce total system flow. However, the reduced flow will still be greater than the flowrate used in the generic LBLOCA analyses. This, coupled with IMI-l's lower core power (2535 MWt vs the generic 2772 MWt) provides margin in initial conditions for TMI-1, relative to the generic analysis. During the early portion of a LBLOCA transient when the reactor coolant pumps are coasting down, the analyzed system flow rate (see VIII.B.I.3) with additional resistance due to plugging will be greater than assumed designed flow rate

~~

with the case of no plugging.

The reduction of 200 ft3 of primary coolant volume will have little impact to the consequence of LBLOCA.

Since the OTSG's are unevenly plugged with more tubes plugged in A than B. If a cold leg break occurs in the A side, the reduction of RC fluid is part of that blown out of the break, and there will be no impact to the result at all. However, a break in the B side will result in slightly less total fluid passing through the l

core during the blowdown period. For about 11,000 f t3 total fluid loss within.approximately 24 seconds, the reduction of 200 ft 3 will correspond to 0.4 second O

n, n

shorter blowdown time and thus a slightly earlier fuel heatup between blowdown and refill. This dif ference is minimal and therefore, the resulting peak cladding te=-

perature that occurs during this developed reflood stage should not be changed. Also, vent flow is conserva-tively neglected during the refill /reflooding phases .of LELOCA analyses for the 177FA Lowered Loop plants. Tube plugging will therefore have no impact on core flooding rates.

2. FSAR Analyses of Other Transients

' An assessment of the icoact of the plugged steam generator cuces on cae ao: A;;y of che .545 ca sa:aly respcac co E5Al transient ebnditions has been performed. The plant is ex-pected to be operated with up to a total of 1500 SG tubes

. plugged for both steam generators at the licensed rated power level. Each event in the TMI-l FSAR will be addressed in light of the expected impact of steam generator tube plugging on assumptions used to produce the current FSAR analysis.

a. Unco =censated Operating Reactivity Changes This event is core burnup related and is normally com- ,

pensated for by Integrated Control System action over the life of the fuel cycle. Steam generator plugging will not affect the core kinetics and thus have no

~

impact on the event.

b. Startup Accident /CRA Withdrawal at Power The CRA Withdrawal from Startup conditions and at power results in primary system overpressurization. The FSAR prediction of RC pressure and peak thermal power is based on the conservative assumption that all heat pro-duced in the core remains in the primary system, i.e.,

no steam generator heat transfer. The tube plugging will result in a 200 ft3 volume reduction of the primary coolant ( 2%). At peak thermal power the reactor coolant pressure increase was 118 psi in the FSAR. With the small volume reduction and consequently slightly higher heatup rate the peak pressure may in-crease slightly but will remain well below the 2750 psig limit. Therefore, the FSAR analyses remain bounding

. with respect to the acceptance criteria on thermal power and system pressure. .

9 R

c. Moderator Dilution Accident The moderator dilution event is a relatively slow over-l pressurization transient due to increased reactivity by boron dilution. Change in steam generator plugging will not affect the basic assumptions of this analysis and

( therefore the FSAR remains bounding.

d. Cold Water Accident (Pump Startup)

The pump startup event is a small ovtricoling transient due to an increase in flow from an idle loop. The analysis nerformed for See, tion 8.B.3 demonstrated that tae pu=p cnaracteriscic curves ca.ierance s are negii-gible fbr the unplugged and the 1500 plugged tube cases. The reactivity change will cause a power and RCS pressure increase. The transient will be terminated by either the high reactor pressure trip or the power / flow trip. The FSAR remains bounding.

e. Loss of Coolant Flow See Section VIII C.1.

f. Stuck / Dropped Rod Event The FSAR analysis is bounding since SG heat transfer and RCS flow do not ef fect this event. .

g. Loss of Electric Power The unit will trip on loss of electric power. With the loss of the reactor coolant pumps, natural circulation in the primary loop and heat removal by the emergency feedwater system are required. The impact of tube plugging on the ability of natural circulation is demon-strated in Section B.S.

h. Steam Line Failure The licensing basis for TMI-l is the double-ended rup-ture. This FSAR analysis is based on a very conserva-tive prediction of SG secondary inventory. Operation with plugged tubes results in a secondary inventory greater than operation without plugged tubes but it is l

not as great as that considered for the FSAR analysis.

Secondary inventory is one of the parameters that deter-mine the safety considerati'ons of return to criticality, 1

70 -

.+,,-,,.,,p-, -

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and reactor building pressure. The calculated water increase with 1500 plugged tubes is less than 5%, which will result in a maximum steam generator inventory of 42,000 lb. per steam generator in contrast to the FSAR analysis assumption using a steam generator inventory of 55,000 lb per steam generator. .It is therefore con-cluded that the FSAR case remains bounding.

i. Steam Generator Tube Failure ',

The steam generator tube rupture accident is analyzed assuming a 435 gpm leak from a completely severed OTSG tabe. The RCS is decressupi ed and iselsted at 34

=inutes, at vnich time leakage from the RCS is assumeo to stop. The reduced RC flow as a result of the plugged tubes is greater than the RCS flow assumed for this a

cooldown rate (even the 100% design flow is not required to cool the RCS) . Similarly, more than enough OTSG heat transfer area is available to cool the RCS.

Of fsite dose from the Tube Rupture Event will not be affected by plugging 1500 tubes because neither the time required to isolate the OTSG nor the leak rate from the

~ broken tube is af fected by the tu'be plugging.

j. Fuel Handling Accident This accident is assumed to occur during outage a l refueling outage while the reactor is shut down. Change in steam generator plugging pattern has no impact to the assumptions.

k. Rod Ejection Accident Fast reactivity excursions are not influenced by SG heat removal. The event is an adiabatic heatup. The FSAR analysis remains bounding.

1. Maximum Hypothetical Accident The analysis assumed that a given amount of radio-activity has been released following core exposure and I studied the ef fectiveness of the building spray system and Engineering Safeguard systems leakage on to the enviro nment. The steam generators are not related to the scenario and thus have no impact on the conclusion.

O e

b - - - -

_ _ _ _____ m ___ --m -----_ - _ . - -

m. Waste Gas Tank Ruoture The Waste Gas Tank is located in the Auxiliary B6ilding i

and the analysis of its rupture is not related to the steam generator's function. The event is thus un- ,

affected.

n. Loss of Main Feedwater/Feedwater Line Break i i

A loss of feedwater accident is an event resulting in primary systec heatup, increased pressurizer level and * ,

pressure, and reactor trip either by anticipatory fune-tion (loss of tain feedwater pumps) or high RCS pres-

3. .--- t - --.':- ,731: 3 , .-.-7.-e- f.34-

- r.

water heat ren: val through the steam generators. With

-- - - - the plugging of 1500 tubes in the steam generators, the intitial heatup rate will be slightly faster. However,

• the anticipatory trip on high pressure will shut the reactor down and reduce the heat input to its decay heat level regardless of the minor dif ference in heatup rate. Emergency feedwater has.the flow capability of ~

removing decay heat up to about 7 percent power. This is greater than the decay heat at any time after shut-down. In the SBLOCA analysis using the revised LOCA model it was demonstrated that heat transfer rate is not significantly changed with the amount of plugged tubes.

Therefore the FSAR analysis of the loss of feedwater accident remains valid,

o. Steam Generater Overfill Steam generater overfill was analyzed as a part of the TMI-1 Restart Report, (Reference 50). This analysis identified that it takes at least 10 to 17 minutes for auxiliary feedwater to overfill to the top of the steam generator's shroud. Operators are instructed to isolate

"'

• the feedwater flow path as soon as the'OTSG water level reaches 82.5% on the operating range (high level alarm) and to trip or throttle feedwater pumps if the level reaches 90%.

The impact of up to 1500 plugged tubes in one steam generator will be about 5% inventory increase at about the same level indication. This has been shown in Section B.4. This implies a reduction of the over-l l

filling time by about 60 to 100 seconds. The time for the operator to respond to the high level alarm will be shortened. Moreover since there is still sufficient 1

1

,-,. -3 - -

time and uncmbiguous symptoms available for the opera-tors, their prompt response is expected and thus the overfill would be corrected. In addition, a stress analysis has been performed on the consequences of flooding the TMI Unit 1 Main Steam line. The results of 1 deadweight internal pressure and thermal expansion l l

analysis show that the main steam piping can withstand these affects. Therefore operatin,g the steam generators with 1500 plugged tubes will not present a safety con-cern with respect to steam generator overfill. j D. Moisture Carrv-over Considerations i E~ilustions vere nerformed to determine whetSer the clueging pattern would allow moisture to be carriec up with the steam, l

_ causing potential'for erosion of components or steam lines. i

' Calculations of steam conditions at the entrance to the turbine

• show approximately 33*F of superheat, indicating no moisture problems in the bulk steam. Evaluations were also done, to determine the potential for local ef fects in areas of high plugging before mixing equalizes temperature. Calculations j include multidimensional thermal hydraulic simulation of the OTSG with plugged tubes using the THEDA II Code. ,Results indi-cate that moisture carryover from the clustered plugging of tubes should not be a problem. The effects of the aspirator bleed ports and the geometric design of the 15th tube support plate (outermost holes are not broached) work together to sub- j stantially reduce moisture carryover. An ISI program will be implemented to further assure the integrity of peripheral tubes and downstream components and piping. Peripheral tubes in areas of high plugging are included in the post repair eddy current ,

program. A supplemental ISI program of steam system fittings will be implemented. Both programs are described in Appendix A.

E. Conclusions a

.- Evaluation has shown that up to 1500 plugged tubes per steam

generator have no adverse ef fects on performance of the steam generators. The reductions in flow and heat transfer are not large enough to affect the licensing basis analyses for transients or accidents. In addition, moisture carryover is not expected to cause erosion problems, but monitoring of the steam system fittings will identify erosion should it occur.

1 T

f l -

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IX. UNREPAIRED PORTION OF TUBES Reference 2 and Sections IV through VI of this report discusses tubes in the area of the kinetic expansion, plugged tubes and how they meet the design basis. This section discusses how tubes in the remainder of the steam generator meet the design basis. The rationale for resuming operation with the existing steam generator

! tubing is based on these facts:

1. Corrosion tests indicate that the crac. king mechanism has been arrested and will not reactivate in low sulfur primary 4

j coolant water chemistry. If the cracking does. reactivate due to an unknown mechanism at operating temperatures or I, durinq heatuo and cooldown cycles, it is anticipated that i

une precr cical cescing sequence iculc allow autiiciene cime ,

for defects to propagate through wall to a size that would

_ allow leakage to be detected. l

2. Analyses have demonstrated that cracks below a minimum range of length and through wall thickness will not propagate to i failure by combinations of flow induced vibration, thermal cycles, and mechanical loading. Analyses have also cal-

culated a minimum size below which a crack will not become unstable due to plastic tearing or ligament necking during a MSLB. The range of crack sizes above this was detectable by 4

the ECT inspection program that was used to inspect the '

l

- steam generators, and were removed or plugged.

3. Any through wall defects that are large enough to propagate unstably and are not picked up during the 100% ECT inspec-tion because of equipment or analyst error will be detected by leakage monitoring programs during the test program.

A. New Damare Not Occurring

! The following paragraphs address the subject of new damage not occurring in the steam generators. _ Short term corrosion testing t program has provided evidence that the crack mechanism is ar-

rested and the long term corrosion tests will act as an antici-patory program for crack initiation. An eddy ' current flaw growth program has shown that cracks are not initiating or pro-pa gating. Defect indications which are less than 40% through wall and less than 90* in circumferential extent will .be left in service and monitored for crack propagation. ' The precritical i testing program will detect reinitiation of corrosion through

-leakage monitoring.

b w , , - - . . - . . . . . , ,, . , . _ , , , , , , , . - . _,-,-..w i.-_,_,,,...y r .,,. , , , - -. , . . , .,-,m

The corrosion testing program results are described in Section III. Tests on actual and archive Steam Generator tubing to date have established:

(a) Cracking will not occur unless an active reduced species of ,

sulfur is present and cracks in SG gubing will not propagate I in the present chemical environment ;

(b) Sulfur induced cracking requires an oxidizing potential which does not exist under normal hot operating conditions ;

(c) Lithium hydroxide is an ef fective inhibitor of the' cracking nah:ni:r.

-- - -Tubing which has undergone the repair and chemical cleaning process has also been tested. Accelerated tests performed on this tubing under severe chemical environments has not produced any cracking. To provide assurance that the mechanism has no long term time dependency, a long term corrosion test program has been initiated to provide an anticipatory assessment of tube performance under actual steam generator operating conditions.

This program will lead plant operation and will run for approxi-mately one year.

Since identification of the steam generator problem, cracks in the generators have been monitored for growth. Eddy current testing of about 100 tubes in each steam generator was conducted on a repetitive basis to attempt to ascertain if the inter-granular attack mechanism was continuing to damage the OTSG tubing during continued dry primary side lay up conditions. The sample selected for this monitoring assumed half tube sheet symmetry and included tubes with no defects, tubes with a variety of defect indications and tubes in periphery and in-tarior areas of the bundle previously identified as high and low defect rate areas, respectively. The method used involved a

~

relative comparison of the low gain .510 sta'ndard dif ferential probe eddy current responses from seven repetitive examinations of the sace tube population over a period of time extending from December 1981 through July 1982. The eddy current data was evaluated and compared with previous data for each tube to determine if reported variances from test to test were related to variability in the physical repeatability of analysis of threshold-level defects or to the appearance of fresh defects grown in the interim period between tests. In July 1982, a "new baseline" condition was established with both the .510" std.

-gain technique and the .540 high gain technique performed con-secutively (within 3 days of each other).

6 O

d The consistent pattern of the test comparisons indicated that significant growth of new intergranular cracks was not detected.

Sece variability in repeatability of recorded results was ob-served, hcwever careful review and comparison with previous data established these as expected variances due to such things as

" probe =otion" noise levels, and previous indications inad-vertently not recorded.

The comparison of the July 1982 .540" 'high gain technique data to the July 1982 510" standard gain technique data run 3 days apart showed a 94% (188 of 201 tubes) agreement with a "no-growth" result. Where 6% (13 of 201 tubes) of the tubes had

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nique, these are established as a product of the higher sensi-

~

~ 'tivity of the .540 technique. This result is consistent with other cecparisons of these two techniques. As further confir-mation, in August 1982 about 29 tubes were selected from OTSG-1B at-large, where reinspection with .540 high gain techniques had revealed defect indications in addition to those previously identified by the .510" standard gain technique. These 29 tubes were rerun with the .510 standard gain technique and in all cases, a comparison of the two .510 data sets revealed that the tube's condition was unchanged.

It is also noted that these findings are not altered by the results cf the 100% inspection of both OTSG's by the .540" high gain technique (when compared to .510" data from about 6 months earlier). No significant patterns of crack growth were apparent in this bulk comparison of data.

Within the limits of eddy current test sensitivity and repeat-ability, no new cracks were formed or developing in the OTSG tubing during the period from December 1981 to August 1982.

Tubes with ECT indications below US+8" of I.D. 20-40% through wall and verified by the 8xl probe to be actual defects are considered degraded tubes. Depending on their circumferential i extent, the tubes will be lef t in service and monitored on an l extended ISI program. The extended ISI program will include 100% reinspection of the 40% and less through wall indications as a separate subset for three continuous refueling outages. If these eddy current examinations show no substantial growth in the cracks, they will be lef t in service. Tubes showing signs of crack propagation will be taken out of service based on normal and accepted criteria. Lack of defect propagation will give additional assurance that the mechanism is arrested in the long term.

l l

l l 1 l 1 l

.- - . - - - - -_ - = . .- - . . -.- - - - - - .- . _ - .

l More rapid propagation if it occurs, will be evident during the precritical and power ascension test program described in  !

I Appendix A. This program will subject the tubes to normal heat-up and cooldown stresses and to one accelerated cooldown stress test. Between each of these tests the plant will be maintained l

in hot, pressurized condition to allow time.to determine if l

cracks have propagated to a through wall extent and to allow

sufficient time to detect any changes in leakage. The test program will be completed by a cooldown from hot conditions to l

cold shutdown temperatures as a final test of tube integrity.

Leakage monitoring will be continuous during and af ter this test.

i leakage monitoring programs are adequate to detect 100* through

. .1 ::1:12 ini ;ul i: U. iurin; L :::nsiant :: v::idt,:

l condition. Adequase time for propagation will be allowed during l

- the test program. Since previous experience indicated that the mechanism propagates rapidly, a lack of any significant leakage would provide added assurance that cracks are not propagating.

Corrosion testing indicated that the mechanism will not be active in high temperature environments such as those that will exist during the test period. Eddy current examination is not planned to be conducted at this phase of the test program since leakage detection has higher integral sensitivity.and reli-ability. In addition, opening the steam generator for inspec-tion would expose the tubing to an unnecessary oxidizing environment. Good engineering practice dictates that exposure l

to air should be minimized.

1 Both long and short term corrosion tests provide evidence that the crack mechanism is arrested. The flaw growth program has shown that cracks are not propagating or initiating within the steam generators. The precritical and power escalation test program will give assurance in the short term, and in the long term, steam generator leakage monitoring and the long term cor-rosion test program will give tube integrity data and assurance that cracks are not initiating or propagating 'during operation.

In addition the monitoring of degraded tubes will give addi-tional assurance that the cracking mechanism is arrested.

B. Defect Detectability An eddy current inspection was conducted of 100* of the in-service tubes in both steam generators for the full length below the top ten inches of the upper tube sheet. The system that was used for this inspection was a .540 inch diameter.

standard differential probe with a effective gain of approxi-mately 60. Any high noise or otherwise difficult to interpret-indications were resolved in conjuncti.on with ~ data. from an eight 1

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I coil absolute probe. The selection of this system is documented in detail in Reference 20. The following summarizes the quali-I i

fication process which resulted in determining that this system demonstrated adequate sensitivity to detect defects that should be removed from service. This section discusses laboratory calibrations, comparison of field data to metallurgical inspec-I tions, measurement of laboratory grown cracks and comparison of differential probe data to absolute probe data.

(

The eddy current probe systems were tested against electro-discharge machined notch defects at the EPRI non-destructive l examination research center in Charlotte, NC. Circumferential machined notches of .187. 100, and .060 inches were machined on ene inside diameter of LG arenive aciam geners:or cue;a;. :en length of notch was machined to through wall depths of 20%, 40%,

60% and 80%. Minimum levels of detectability were determined by

- comparing defect signal to a field noise level of .3 volts.

The results of these calibrations for a .540 inch diameter dif- ,

ferential probe with a gain of 60 at a frequency of 400 HZ are shown in Figure IX-1. Cracks with geometries that fall to the

' right and above the curve are detectable, those to the left and below are undetectable. The perfectly horizontal geometry of the machined notch is not totally representative of the cracks in the steam generator, but it provides the'1 east detectable geometry for differential eddy current probes. This geometry, therefore, should provide a conservative estimate of defect detectability. Details of this qualification prog am are con-tained in Reference 20.

On three separate occasions tubes were removed from both steam generators for metallurgical examination. Details of these examinations are contained in References 3 and 4. One of the purposes of these examinations was to correlate the ECT signals with actual defect geometry. Eddy current reported thru-wall

- penetrations ranging from 40 to 95%; 39 of 42 cracks investi-gated in the laboratory had 100% wall penetration, and the three cracks were observed to penetrate 66, 70 and 70% through wall.

One possible explanation for the thru-wall discrepancy is that the cracks may not be open in-situ. Although the Intergranular.

attack penetrates the entire wall, sufficient continuity exists across the grain boundaries to give a less than thru-wall eddy current signal. There were no cases below the roll transition area in which a defect had not been detected by ECT. Details on metallurgical correlations are included in Reference 20

. The particular geometry of these defects were tight circum-ferential cracks that in most cases, were undetectable by visual e

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examination under microscope or even by high resolution radio-l graph. The primary means of detecting these cracks is by tube axial sectioning and reverse bending on a 1/4 inch mandrel to open up the cracks. Tubes were examined by this method not only in areas where defects had been detected by ECT but also in good areas of defective tubes and in good areas of tubes taken from '

low defect areas of the steam generators. In all, 24.6 feet of tubing was examined by this method and no defects were detected except where ECT inspection had indicated a defect. These results increase the confidence level that the sensitivity of the ECT inspection method is sufficient to detect all defects in the steam generator tubing.

To compare the absolute to the .540 high gain standard differen-

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- tial (S.D.), the sample of 3230 cubes previously tested by Absolute ECT (4x1) was retested using the .540 high gain S.D.

technique. The sample was predominantly from the high and low reject areas of OTSG "A". The first comparison using the normal S.D. .540 technique indicated a correlation of 99.5%. The quantity of tubes that did not correlate was 16 low level in-dications. With absolute data, it was determined that these indications were all one coil, suggesting that the circumferen-tial extent was relatively small. In reviewing the .540 scans, it also appeared that the 16 indications not detected we're consistently in the field of the high noise level. To better detect these 16 indications, an I.D. frequency mixing (to remove tube noise / chatter) was added to the S.D. .540 technique. With the added 1.D. mixing, S.D. 540 capabilities were enhanced to 100% correlation with the absolute technique as the remaining 16 indications were detected.

This ccmparison establishes that the normal S.D. .540 technique is as sensitive a method for flaw detection as the absolute.

B & W Alliance Research Center conducted a program to artifi-cially induce 1GSAC in archive Inconel tubing. Following exposure to thiosulf ate-bearing solutions, the tube specimens were eddy current tested. Scanning Electron Microscopy clearly showed the intergranular nature of the cracking and confirmed that the laboratory induced cracks reproduced the type of cracking and crack shape found in the service failures. For cracks investigated by successive grinding and polishing, measured axial extent ranged from .006 .017 inches. This ia somewhat larger than that of the EDM notches used during the previous 0.540" probe qualifications tests. This value is also larger than the .002" minimum seen during failure analysis on actual tubing. However, the measurements on service tubes were usually estimates made on SEM photos rather than metallographic i

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J I sections, and would be expected to be lower. The crack axial  ;

extent in service and laboratory induced cracking can th's u be 1 i concluded to be comparable.

Correlation of eddy current results with metallographic observa-tions was performed on samples with the following results. A summary is shown in Table IX-1.

1. The threshold of detectability appears to be comparable to that determined by the original qualification testing. A crack, .040" x 40%, was below the level previously found detectable and sas in fact not de-tacted. C-m e':s o f . ? 1.5 " t ? ' T n e d 0 .110" x ca% ere

detectabig by G.540" probe. This is illus

ratac further

-- - by plotting the points on Figure IX-1.

2. Using the GPUN ECT 2-step screening technique, 8 samples were tested. Four sa'mples were dispositioned as accep-table and four samples were dispositioned as having unacceptable defects. When confirmed by metallography there was 100% correlation.

From these tests it can be concluded that the detectability of ,

laboratory induced cracks confirms .the qualification of the .540 differential probe using actual steam generator tubing as well as EDM notches. Similar qualification programs were conducted to determine sensitivity of the 8x1 absolute probe, and to cor-

- relate sensitiv*ities of both probes in the high noise area of the tubesheet.

The ECT system used during the steam generator inspection has the sensitivity to detect crack of the sizes indicated in Figure IX-1. All defects above that size have been identified except' for a small number that may have been missed due to random equipment or interpretation errors. ,

C. Undetected Defects Some number of undetected defects or other tube surface anomalies may remain in' service after the repair is completed.

These defects fall into the following categories

1

1) Local Intergranular Attack l . 2) Below the detectable limits of ECT

3) Detectable by ECT but missed through random error i

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TA111.1-: IX - 1 I.AllOHATOltY IllDilCED CllACKS E/C COHitEl.ATIOli I

i EDDY CilitHEllT EXAtt _

!! ETA 1.LOGRAPilIC COHitEl.ATIOtt PIIYSICAL .510 .540 4x1 SAtlPI.E ID APPEARAtlCE GPuti 1 CIHC. Tilnu

& T.W. 1 T.W. I COILS DISP., d.EllGTil llIrl. AXIAI.

WALL t EXTEllT A - 1.75 5 DISTORTED 20 - OD llE 1 - ID R 0.2" 50% .014" A - 2.32 DISTORTED 35 - OD 11E 1 - ID R 0.17" 63%

• .017" 5

D - 3.32 DISTORTED 20 - OD 420 - OD 1 - ID A 0. "-0.5" 181 .006" C- . ~/ 6 ACCEPTABLE 20 - ID < 20 - ID llDD A SURPACE At10!!ALITY D - 1.9 ACCEPTADLE IIDD 35 - ID llDD A  !!O VISIBLE DEPECT E - 4.0 ACCEPTABLE IIDD 65 - ID 1 - ID R .315"!! 30% .0065 E - 4.3 ACCEPTA11LE IIDD llDD llDD A .030 251 P - 4.8 ACCEPTABLE 85 - ID 55 - ID 1 - ID R .14" p41 .012

1. R = REJECT A = ACCEPT 2.

IlE = Il0T EXAtilllED (TUDE ID REDUCTIO!1 DID 110T ALLOW PASSAt..:OP 0.540 PIOnE) 3.

IIIGil GAlti PARAMETEll S1HUI.ATED 0.540 SEllSITIVITY

4. Il = MLILTIPI.E

5. It is believed the physical OD distortion on the tube ha:. produced the

. OD differential eddy current response.

4 4

Specimens of actual OTSG tubing have exhibited areas of general surface IGA one to two grains deep. This local ICA is similar i to that seen in other Inconel 600 tubes and is generally agreed to be the result of the tube manufacturing process. A few isolated instances of IGA from 6 to 10 grains deep have been found; they are associated closely with visible multiple cracking.

One use of the long term " lead" corrosion testing program described in Section III will be to show that these phenomena .

i are not contributors to tube failure. Specimens selected for

' this test program will contain general surface ICA as well as j crack indications. IGA islands cannot be specifically included 1 as :a;; apecisans 24 L. ; ;;. Occur:2a;t 1 ::. Je , ir.c : : :-

not be detected other than by destructive examination. However, j b-'y~ bounding this condition with specimens containing surface IGA and actual cracks, the influence of this condition can be assessed especially on consideration of the fact that metallo-graphy has shown that the most extensive IGA is in the vicinity of major cracks. The development of IGA and/or cracks will also be assessed during the test program as specimens will be period-ically rem >ved from the test solutions and metallographically evaluated. Both the metallurgical examination program and the long term corrosion testing program provide a'ssurance that the steam generators can be operated safely with local ICA on the tubing.

l In addition to surface IGA, the existence of small cracks below I the threshold of eddy current detectability has been con- ,

i sidered. Corrosion tests have shown that crack propagation by 1 chemical means is unlikely. Stress analyses were conducted to determine whether small cracks could propagate under conditions of mechanical loading during normal operating, transient, or 1 accident conditions. The evaluation performed.had determined the maximum flaw size which will remain stable under ~

steady-state and transient loading. The acceptability of small cracks in service is based on demonstration that eddy current examinations have identified existing cracks of this maximum 9 flaw, and that the small cracks will not propagate rapidly to this size during operation.

The tube loads are derived in part from the design basis docu-

! ment (Ref. 52) and in part from measurements of the TMI-2 OISG -

tubes (Ref. 51). Recourse is made to field measurements because the steam generator performed better than design assumptions predicted. TVenty degrees more superheat is measured than i predicted.

4 l

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I

The axial load on the tube during anticipated transients, such as heat-ups , power changes, and reactor trips , and steady-state operation are due to:

a. Dif ferences in tube average temperature and the average temperature of the steam generator vessel wall.

b. By virtue of the end fixity of the tube', a longitudinal pressure stress evolves through Poissen's ratio.

1 c. A residual tube axial load component exists from fabrication.

d. Tbbesheet fixit" mitigstes axisi lead, especially near the unit center-line.

S'uperimposed on the steady axial load is a high cycle, flow

• induced vibration (FIV) bendin'g load. The frequency and dis-placement magnitude of FIV was measured at THI-2 (Ref. 51).

. Potential for crack propagation was evaluated in two ways, a fatigue fracture mechanics calculation incorporating FIV and normal operating transients , and solid mechanics calculations of one time transient and accident loads. These calc'ulations were l used to generate curves showing crack depth vs. circumferential extent for the maximum stable crack configurations. The results are shown in Figure IX-2.

D. OTSG Tbbe Failure Analysis for Unplugged Tubes (Proprietary)

Curve A in Figure IX-2 represents the maximum crack size found to be stable with respect to f atigue flaw growth over a 40 year lifetime. The fracture mechanics model uses a preexisting crack and evaluates its propagation under high cycle and low cycle fa tigue .

- During steady state operation the steam generator could have an axial tension of 500 lb. act on the tubes. In the analysis, the load cycle imposed on the tubes included mechanical and thermal factors. Low cycle, long duration loads were combined with high cycle flow induced vibration (F.I.V) loading. A graphical representation of the load cycle is shown in Figure IX-3. The analytical model, which used EPRI fracture mechanics code BIGIF, l cycled load about 500 lbs. axial tension, the steady-state value

! calculated from THI-2 test data. The F.I.V. deflection selected f corresponds to the largest peak deflection seen at a T41-2 sensor during a steady state condition. This is 3 mils, peak half-amplitude displacement. The sensor was located at a " lane" tube which experiences higher crossflo'w than the average tube.-

l -

.a

OTSG Tube Critical Crack Sizes i

2.00 -

0.D. MAX ARC-LENGTH g

,100 F/HR COOLDOWN \ 1

\ (w/140 F SHELL \

• TO TUBE AT) - \ \

\ (1107 W649 LBS) 1.75 - -

\

\-

\ LBS)

\1 D

ECT + -

\ \ ,

\1

- _ MSLB .

kN 1.50 -

LINE + \. MSLB s *

(3140 lbs) \, .

(1408 lbs) s,

\

@ \

5 1.25 -

\ '

E ,

8 H' ECT +

O 1.00 - '

8 's, I \

$ '\

g .75 -

' s ,.

+ s. s o

• c:" s

.50 -

s {l M AX INITIAL CRACK SIZE TO ALLOW 40 YRS. 0F STABLE CRACK PROP 0GATION.

AKth=4.0

.25 -

I l I 1

O 20 40 60 80 100 DEFECT DEPTH IN % WALL THICKNESS FIGUf1EIX 2 l

O

1 1

The vibrational load amplitude was selected for conservatism to be the maximum tube displacement seen under steady-state loading.

Combined with high cycle loading was the maximum tension excur-sion represented by the 100*F/hr. cooldown, which imposes an t

I axial load of 1107 lbs. The FIV and one cooldown comprise a l

load block as shown in Figure IX-3, with 'six cycle times per year.

Lapirically derived values were used to rdpresent tube 1cading.

The value of R (K minimum /K maximum) thus is approximately equi-valent to actual conditions.

Iha :s: ;ua calca.a i n ::na;. era. :. e lac: . . . .  :.; t: 2 a:

point at which small indwelling cracks have no ef fect on fatigue resistance (the endurance limit). This value of the stress intensity, below which cracks do not propogate, is the stress l intensity threshold (delta KTH)*

A modified Paris equation was incorporated in "BIGIF" with the feature that if the stress intensity range did not exceed threshold, no growth would occur.

The THI-1 calculation was performed using delta KTH=4.0 KSI (in) 1/2. This value is based on the empirical data for Inconcel 600 shown in Figure IX-4. The intercept of the abscissa is the threshold for propagation. The relationship has ,

been determined for threshold stress intensity and R values so that data taken at different R values has. been used to calculate the appropriate threshold for TMI-1 conditions. Delta KTH "

4.0 KS1 (in) 1/2 is judged a conservative value.

The evaluation has shown that the high cycle flow induced vibra- i tion does not contribute to propagation for ID circumferential  !

cracks. Low cycle loading from the startup and cooldown is the l significant contributor to stable crack growth'. Curve A in t Figure IX-2 represents the maximum crack size which can with-stand 40 years of heatup and cooldown cycles witnout reaching a size which will propagate rapidly to a through wall defect based l on the conservative analytical assumptions made. Since this curve is to the right and above the eddy current detectability curve, cracks of this size will not exist in the free span area of the repaired steam generator. l Curves B and C represent solid mechanics models of the ability {

of cracked tubing to withstand one time transient loads. The ,

, maximum accident axial loading on the tubes is during a main steam line break, and is defined as 3L40 lbs for peripheral tubes and 1408 lbs for core tubes in generic licensing FIGU RE IX-4 Fatique - Crack Propagation Behavior of inconel 600 da/dn vs AK forINCO SOO 10-4

_ A 75 JOURNAL OF ENGINEERING MATERIALS CURVE O 600 JOURNAL OF ENGINEERING MATERIALS CURVE

~

G 77* MIT CURVE

_ ^

O d54' MIT CURVE /

/

f. . '

O 10-5 _

e

, _ OC .

i? -

e

) _

l

{

l-4 -

2 a=,=

es/

il e

_ .10 - 6 g

A 1

A 608 POINT BORATED WATER l

\

l 10-7 ' ' ' ' ' ' ' '

1 100 110 LOG AK, KS1 O STRESS INTENSITY FACTOR RANGE .

I e

documents. The maximum axial loading during normal transients is the 100'F/hr cooldown, which corresponds to 1107 lbs tension i for peripheral tubes and 649 lbs for core tubes. These axial ,

loads include preload, pressure effects and tube-to-shell l temperature differentials. *  !

Curve C on Figure IX-2 was derived using the 1107 lbs transient axial loading, Curve B is for MSLB. In the analysis, the fact that a flawed tube will move laterally under the axial load is ,

included so that the centroid of the damaged cross section lines '

up with the line of action of.the load thr'ough the intact tube '

l centerline. With this model, the induced bending moment at the flaw is reduced. Assumptions on the tube stif fness remaining  !

. and the manner in which strain is absorbed in the area of the I cracA have acen se.ec:42 :: cada :aa rar;;;; cen;arr;;iii.

Curves B1 and C1 reflect conditione pertaining to the core -

~

f.

~

t'ubes .

Curves B and C show that the maximum crack sizes for failure under transient and accident loading is to the right and abova 1

ECT sensitivity. Thus the probability is very small that cracks of this size will remain in service after the completion of repairs.

The laboratory calibration results and the correlation of the differential production probe to the absolute probe results' provide confidence that all defects above the detectable size j l

l will be found. However, there is a small probability that some large cracks may not have been detected due to problems such as high noise levels, probe lift off or chatter, or data analysis errors. Because of this possibility, an evaluation was per-formed to determine if tube cracks.of the size that would pro-pagate can be detected due to leakage. ,

As discussed above in the OTSG tube stress analysis , the tube axial load is a function of several variables and may have either tensile or compressive values. The gre'atest uncertainty '

l is the tube tensile preload. Based on the TMI-2 test data at 97% full load a tube axial load of 500 lbs tension was cal-culated. In addition to this result, a calculation was per-formed on the basis of first principles in order to establish the tube loading. This calculation included the effects of dif ferential thermal . growth between shell and tube , preesure loadings and tubesheet deflection as well as a value for tube preload. The preload value was based on a gap measurement of 3/32 inch between parted tube surfaces. At THI-1 the result is

' a tube loading at full load to be approximately 500 lbs tension for peripheral tubes and 200 lbs tension for core tubes. The calculated results of tube loading' based on first principles

~- 84 -

, - , - -eemy.,wr-r-w--,*-v. y ~- , - ,-*w'v g -%4 ,y .--,y +

- =_ - - --

correspond fairly well with the values calculated from the TMI-2 '

test data. Therefore, we conclude that the model of tube load based on first principles is valid and that the tube is in ten-sion during operation.

After determining a conservatively small minimum crack opening displacement, leakage through the opening was calculated. The

! evaluati'on includes consideration of phase changes and pressure drop as the primary fluid passes through the crack.

Leak race has been calculated using various steady state tensile tube loads and through wall crack sizes. Figure IX-5 shows the relationship of tube leakare versus crack are length for various cuoe loaca waren coniroi cae C L. T.s ;c.iew ag :aaie . ..; - ,

shows the full pewer operational leak rates for peripheral and core tubes based on their respective critical crack size for a MSLB and for the Plant Technical Specification (100'F/hr) cool-down rate. -

Table IX-2 TMI-1 OTSG Tubes Critical Crack Sizes and Operating Leakrate Tube Location: Core Peripherv Tube Load 0100% Power (1bs.) 200 (tension) 500 (tension)

Transients:

1 - MSLB Transient Tube Load (1bs.) 1408 (tension) 3140 (tension)

Critical Crack Size (inches) 1.28 0.52 Leakrate (gph) 0100% .

Power Operation 14 6 2 - 100*F/Hr Cooldown (140'F Shell to Tube Delta T)

Transient Tube Load (1bs) 649 (tension) 1107 (tension Critical Crack Size (inches) 1.72 1.48 Leakrate (gph) @l00%

Power Operation 22 72 Fig. IX-5 was developed by Nuclear Safety Analysis Center (NSAC) based on a model for.two-phase flow through a crack with initial saturated or subcooled fluid, by Battelle, Collier, R'.P., et al., " Study-of Critical Two-Phase Flow Through Simulated Cracks", BCL-EPRI-80-1 Nov. 25, 1980. The curve was redrawn to include a 200 lb tensile tube load curve.

, , - ..-g

FIGURE IX.5 OTSG Leak Rate as a Function of l

Crack Length & Tube Tensile Load 100 -

i s0 -

1107 # tension  !

f

[ peripheral tube ,l

.. e ... . i .;;

[

_ 80 -

Cooldown 70 -

3 CL.

E 60 -

w 500 # tension Q

c=

peripheral tube load _ >

y @ Full Power w 50 - - -

a E

E 40 -

a ._

30 -

200 # tension 20 -

core tubs load

@ Full Power _

10 -

/ i i i i i i 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 1.1 1.2 1.3 TUBE CRACK 00 ARC LENGTH (INCHES)

I The leak rates indicated in Table IX-2 are above the detectable leakage shown in Section X.

An administrative limit on leakage has been established based on the lowest leakage value in Table IX-2. The tdministrative leak j rate limit assumes all increases in leakage to be from ene OISG  !

tube and has a value of 6 gph above the baseline on this basis. '

The action of that point will require bri,nging the plant to cold shutdown and leak testing the OTSG and repairing any identi-fiable leaks. Bubble tests are expected to identify individual leaking tubes. Bubble test sensitivity is .1 gpd/ tube. Thus, any cracks in service of a size which is or propagates to a

r 3 -3 0-1 size rill ' 3 3. d 2- t# f'. ? f .

_ In. addition to the' leakage limit, normal plant cooldowns will be accomplished at less than 100*F/hr and limit the OTSG shell to ,

tube delta T to 70*F. This will decrease the cooldown transient  ;

axial tube tensile load to app'roximately one half of the evaluated tensile load which results from 140*F OTSG shell to tube delta T.

E. Conclusions _

I Evaluations of tubing left in service have been performed to verify that they are acceptable for use. The possibility for j additional corrosion occurring after return to operation has ,

been considered and found unlikely. In considering existing i damage, the ability of cracked tubing to withstand steady state, j transient and accident loading has been examined. All cracks of I a size that could be expected to propagate under loading are I ,

within the range of detectability by eddy current testing. If a  !

through wall crack of critical size for growth has been in-  ;

advertently left in service, or grows at a later date, it will be detectable due to leakage before there is tube failure.

f i

l e

w -

r: l l

i X. OPERATIONAL CONS!DERATIONS The operational concerns of primary to secondary leakage were evaluated. Concerns included leakage monitoring during normal operations in both steaming and nonsteaming conditions, and sampling steps to be taken when leakage is detected. In additioh, a program has been formulated that includes procedure review and operator training which will provide improved operator guidelines for dealing with tube leakage and tube rupture events.

.e The operational guidelines discussed in this section are applicable during normal operation with low levels of primary to secondary leakage. A more detailed description of these euidelines can be found in reference 55. Fcr primary to sacencary leakage ra:_a v: ;U gpm or greater, these. guidelines will be superseded by tube rupture

' guidelines as discussed in Section X.B.

~

Operational concerns can be grouped into three general areas '

1 Primary to Secondary Leakage which includes leakage detection methods, and actions required based on primary to secondary leakage.

2. Radiological concerns which include detectio~n methods, worker protection measures and plant discharge limits.

3. Secondary side chemistry limits based on boron and lithium con-centrations. .

This section summarizes the guidelines for operating with tube leakage.

i A. primary to Secondary Leakage ,

During normal power operation the methods which will be used to

• detect and monitor leakage ares  ;

o%

1.' Offgas continuous monitor (RMA-5)

2. Tritium samples from the condensate and primary system.

3. Offgas grab samples 4 'N-16 activity measurements using portable steam line monitors I

i 5. Primary Leak Rate Calculation ,l '

I These methods are summarized in Table.X-1. l RMA-5 will be the first indication of increased -primary to i' secondary leakage. The monitor will continuously sample the t

?

l~

1 -.

- - , - -n., , , + , , . , -

,-n- .-

I l

l vacuum pump exhaust from the main condenser. Upon a 25% in-crease in 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> in RMA-5 count rate the primary and secondary systems will be sampled for tritium and the leak rate cal-culated. An of fgas grab sample will be taken and the primary to secondary leak rate will be calculated using Xe-133, Xe-135 and l

l total gas activities. The portable steam line monitor will l

detect N-16 activity and will be used to evaluate which steam generator is leaking.

Primary leak rate calculations which are done daily per Technical Specification requirement can also identify increased primary to secondary leakage. Since the leak rate cannot dis-tinguish between unidentified system leakage and primary to sacancary =..aga, ;; sn on.uan:::;25 .ncr4..e a . -.. ::::

occurs, a critium und offgas grab sample will be taken to allow for an accurate determination of the primary to secondary leak

. rate.

Shutdown limits based on primary to secondary leakage will con-sist of the Technical Specification limit of 1 gpm and an admin-istrative limit of 6 gph above a baseline leakage. Baseline leakage will be determined during the precritical hot testing program. When a leakage increase o'f 6 gph is reached the plant will be brought to a cold shutdown, the OTSG will be leak tested and the leaking tubes repaired. Tube leakage will be tested by the bubble test method. This method has a sensitivity of

.1 gal / day / tube or 4x10~4 gph/ tube, therefore if no leakage is ; '

detected during the bubble test it can be assumed that no individual tube has reached the critical crack size and primary I to secondary leakage is due to aggregate tube leakage. The baseline leak rate value will be redetermined based on an i evaluation of the OTSG leak rate test results and operating ('

history after the leak test is performed. When primary leakage reaches 6 gph greater than the new established baseline the ,

plant will again be shutdown and leak tested.~.

t

~

When shutdown is required by steam generator tube leakage, the  !

plant should be shutdown expeditiously but in.a manner to pre-clude reactor trip and subsequent lifting of relief valves or atmospheric dump valves. Cooldown rates should be limited to ,

100*F/hr and tube to shell delta T should be limited to further reduce the possibility of tube rupture during cooldown. j B. Radiological Concerns 1

- During normal operation with steam generator tube leakage,_

radiological concerns arise in the following areas: ,

l. General and specific area radiation level l

2. Turbine building sump activity (with respect to discharge to the environment).  ;

I

3. Powdex resin and backwash water activity.

Specific and General Area radiation limits will be determined and will be based on preventing the turbine building frem becoming an RWP area (greater than 5 mr/hr). Limits are needed due to the necessity for easy access into the turbine building .

during operation. Routine radiation surveys will be taken in the turbine building in the vicinity of the Powdex and Graver System vessel and in other selected areas. These areas will be l restricted if necessary to prevent unnecessary exposure to plant personnel . Precautions will also address secondary side system .

vent and drain operations.

In th e ?~<dex sunn. 9H and conductivity analysis will determine if the watar wnich has ceen processeo oy :ne (Ecocyne acaver s ,

-- Powdex Backwash Rec'overy system wi?1 be returned to the TMI-l condensate system or to the turbine building sump. Any radio-active powdex will be dewatered in High Integrity Con-tainers / Liners and shipped to commercial low Icvel waste burial sites.

C. Secondary Side Chemistry Secondary side chemistry limitations for Boron and' Lithium will  !

be based.on considerations of chemical introduction into the turbine.

D. Development of Procedural Guidelines for Steam Generator Tube Rupture A program has been formulated for providing improved operator guidelines for dealing with tube leakage and tube rupture events. The guidelines cover two categories of events. The first category addresses tube ruptures for which subcooling margin is maintained. The second category will deal with tube ruptures for which subcooling margin is not maintained and would include various contingencies including multiple tube ruptures in one or both SG's, loss of reactor coolant pumps and loss of condenser.

1. Contingencies for Consideration l

The following is an outline of the programs for developing guidelines for SG tube rupture.

a. Guidelines for Tube Ruptures for Which Subcooling Margin is Maintained The program to develop guid'elihes for tube ruptures for which subcooling margin is maintained will include the following basic assumptions.

---+.-_-m____ _ _ _ _ _ _ . _

TABLE X-1 LEAKAGE DETECTION METHODS

SUMMARY

TABLE Method Sensitivity Frecuency Soecial Actions RMA-5 0.48 gph with 3.8 uCi/cc Continuous strip When count rate and 20 cfm exhaust flow chart reading. increased by 25*

in 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br />, sample for tritium and take off gas grab sample.

' Tri:ium .3 gpm at .02 uC1/=1 S nours wl:a known leakage

_H3 after 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br />' Offgas Grab .01 gpm at 3.8 uCi/cc 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> Frequency increased Sanple and 20 cfm exhaust flow with known leakage Portable When leakage is ,

Steas Line detected deter-Monitor mine which generator is leaking i

h l

S

~ ~ - ,7

(1) Break size small enough to maintain subcooling margin.

(2) One OTSG affected.

(3) Reactor Coolant Pumps operating.

< (4) Condenser available.

(5) Decay heat removal from the non-af fected SG.

(6) SG steamed at 95% operating range level to assure natural circulation. .

Contingency considerations for ddsign basis tube ruptures include:

(1) PORV unavailable. *

' ' ?a:::c ~ ~ *.:n: ' 7: ;n2 ::'.: .t.

(3) No condenser available.

(a) High radiation release considerations.

(5) Steam line flooding consideration.

(6) Both SG's are affected.

b. Guidelines for Tube Ruptures For Which Subcooling Margin is Not Maintained The program to develop guidelines for tube ruptures for which subcooling margin is not maintained will include the following basic assumptions.

(1) Break size from one SG large enough to cause loss of subcooling.

(2) No reactor coolant pumps running (since subcooling margin is lost).

(3) Condenser available.

(4) PORV available.

(5) Unaf fected SG is steamed.

Contingency considerations include:

^

(1) PORV unavailable.

(2) RCS voiding keeps pressure above SG safety valve setpoint.

(3) Primary feed and bleed heat removal.

(a) With PORV available (b) Without PORV available Both the analyses employ the RETRAN code. This code models TMI-l and has been benchmarked from transients on both TMI-1 and TMI-2. Use of this code ensures that plant response under various primary-to-secondary leak scenarios is under-stood.

i f

l

, --n - -y

FIGURE X 9 Tube Ruptura Guidelines l

Primary to Secondary Leakage

> 50 gpm J\

l k Manual Automatic Shutdown Shutdown 1

t u,

Cooldown 2

4 ,,

Natural HPI Forced Circulation Cooling .

Circulation L J

& w4 Decay Heat Removal New Guidance:

- multiple tube ruptures

- ruptures in both steam generators

- HPI cooling

- Secondary water management Improved guidance

- Minimum subcooling reduced

- RCP trip criteria -

- tube to shell AT l - steam generator steaming, feeding, flooding l

O

+ _____

._____ _.___ _ , ___--7. . - --- . . . , _,, - ,7,, - -

i The guidelines developed from the RETRAN analysis for tube ruptures are summarized below and have been used for writing new procedures and revising old procedures. Operator training prior to restart includes response to tube rupture events using new and revised procedures.

2. Gaideline Summarv The symptoms of a tube rupture define. entry conditions for this emergency procedure. It is only 'used when leakage exceeds 50 gpm. k* hen conditions require it (as defined by high leakage or significant of fsite releases), the plant will be shutdown and cooled as expeditiously as possible, n: ::rt:in : :1 7 r.t 114ri t: C? 't r? 2 n rtal tuh a '-'e'.1 delta T, and fuel-in-compression limits ) are waived.

a. Immediate Action I

The tube leak in question may not be large enough to ,

cause a reactor trip. In such a case, the operator i begins a load reduction as rapidly as possible without I causing a reactor trip (10%/ min.). Avoiding a reactor trip prevents lifting of the OTSG safety valves.

I

b. Followup Actions (1) Subcooling Maintained and Reactor Coolant Pumps Available Once the load reduction is initiated or a reactor trip has occurred, the operator has several major goals to achieve while bringing the plant to a cold ,

shutdown condition. First, he prevents lif ting of '

the OISG safety valves; second, isolates the af-fected OTSG to prevent unnecessary radioactivity releases; third, minimizes primary 'to secondary leakage by minimizing primary to secondary dif-ferential pressure; and, fourth minimize stresses on the OTSG tubes by limiting tube /shell delta T.

Finally, the operator will minimize offsite dose by allowing the leakage OTSG to flood if of fsite doses are large enough (approaching levels at which a Site Emergency would be declared).

The major differences between the existing plant procedure and the new procedure would be the following.

(a) Maintain a Minimum Subcooling Margin Minimum subcooling margin means that primary to secondary differential pressure is minimized.

Minimum differential pressure means that leakage is reduced ; thus reducing off site dose i and making the event more manageable. In order to maintain the minimum subcooling margin, several plant limits have to be violated: fuel in compression limits and RCP NPSH limits. The  ;

former is acceptable to violate during emer-gency conditions , while the latter is being  ;

reevaluated to determine acceptable emergency ocerstion of the euro.

(b) St-eaming/ Isolation Criteria for the Af fected

~ - - '

OTS G  ;

The present procedure allows the operator to let the OTSG flood anytime that RCS pressure is below 1000 psig. . The revised procedure has the j operator steam the OTSG as necessary for the .

following purposes. First, to prevent lifting '

of the OTSG safety ' valves. As the OTSG level

! increases, steam generator pressure in the  ;

l isolated generator could increase to' ward the safety valve setpoints. Pressure should be l controlled to prevent a safety valve lift. l The generator is also steamed to prevent it

• from flooding. Flooding is undesirable because I an RCS pressure increase under this condition could cause water relief out of the OTSG safety valves. A flooded OTSG would also act as a second pressurizer and slow depressurization of the RCS (as occurred in the GINNA tube rupture).

The OTSG will be isolated under two conditions.

First, if BWST level goes below 21 ft. indi-cated level. At this level, there is still /;

sufficient inventory to fill up both OTSG's to i the main steam isolation valves and have 30,000 t gallons of water left to go on feed and bleed l l cooling. A second reason to isolate the OTSG '

is for radiological considerations. If the Radiological Assessment Coordinator (RAC) ,

determines that offsite doses are approaching l

. 'g I

- t 9

6

_ _ . _ - - . _ - _ - _ _ . _ _ _ _ - . _ _ - _ _ - - _ - _ _ ~

l the levels which would require declaration of a Site Emergency, (regardless of cause) the affected steam generator will be isolated.

(c) Tube-to-Shell Delta T l

Plant administrative limits and precautions j will require maintaining the OTSG average tube temperature within 70'F of the average shell i temperature. Under emergency conditions, this '

limit can be relaxed to 140*F (Tech Spec limit) without adversely affecting OISG tubes. j i

( 2) Less of Subcooling Mari3 n with Natural Circulation Cooling When RCS subcooling is lost, the operator must treat

• LOCA, as well as tube rupture symptons. First he j trips RCP's and then verifies HPI and EFW have ,

initiated. He is then able to pursue the follovup l tube rupture actions. All of the guidance for i I

followup actions without loss of subcooling apply, as well as the additional guidance provided below. f The objective in this portion of the procedure is to maintain natural circulation, reestablish subcooling margin, restart a reactor coolant pump, and return i to the section of the procedure for forced flev ,

cooldown. 3 i

When subcooling is regained in the RCS.- then HPI is  !

I throttled, RCP's are started and the operator con-tinues with 1.67F/ min cooldown. If subcooling can-not be restored, the operator cools the plant down on natural circulation, steaming as necessary to meet the objectives described in the forced flow

- section. .

If the affected OTSG cannot be steamed for either radiological or equipment reasons, then EFW is used to control OTSG pressure. Essentially, EFW is used as a pressurizer spray to keep the leaking generator slightly lower in pressure than the RCS. The bene-fits in controlling steam pressure are:

(a ) safeties will not lift.

(b ) the steam generator will not control RCS pres- f sure. i l

s

_ 94 -

l

._- _- ,~ _ , ,_ - . _ _ -

I (c) there will not be backleakage into the RCS of I unborated water.

(d) leakage from the RCS to the OTSG will be small i since differential pressure will be small and will also reduce tube tensile load due to pres-sure loads.

(e) the small flow through'the hot leg will help prevent void formation in the hot leg.

(3) Loss of Subcooling and Loss of Heat Sink 4

Natural circulation cooloown will continue uncil

~

subcooling is restored or the OTSG heat sink is lost (for example, due to loss of natural circulation in

~ ~

i +

. the unaffected loop). With no steam generator heat ,

sink, the operator must put the plant in a feed and bleed cooling mode. Feed and bleed cooling is ini-tiated by isolating the OTSG's, assuring full HPI is  !

operating, and opening the PORV. If RCS pressure j remains below 1000 psig, then the operator continues -

to control secondary side pressure just below RCS pressure. If the OTSG heat s. ink is restored, the i feed and bleed is terminated and a natural cir-  :

i culation cooldown is reinitiated. j If RCS pressure stays above 1000 psig during feed l and bleed cooling (e.g., the head bubble prevents

• depressurization or the PORV fails closed) then the secondary side safety valves have to be protected ,

from challenge. The operator controls OTSG pressure .

with whatever means are available (turbine bypass, EFW or ADV). When the OTSG is about to flood, the operator opens the ADV and leaves it open. This

. action minimizes the chances that safety valves will +

be forced to relieve water and/or steam and fail .

open. The steaming capacity of an ADV at 1000 psig exceeds decay heat levels within~ several minutes after reactor trip. HPI capacity exceeds the capacity of one ADV. Therefore, the RCS pressure ,

can be controlled at 1000 psig in this mode without -

lifting' safety valves. Subcooling margin can be regained and the plant cooled down in this mode '

until an OTSG heat sink can be restored or until the plant can be put on decay heat removal.

A simplified schematic of'the tube rupture guide-

! lines is shown in Figure X-1.

g ~ e

i I

A fourth possible scenario exists under current procedures which has not been considered a preferred

( course of action in formulating the guidelines:

l maintenance of subcooling margin but tripping of reactor coolant pumps on 1600 psi RCS pressure.

! Pump trip on loss of subcooling margin instead of RCS pressure allows the operator to maintain forced flow for about 3 ruptured tubes - 1600 psig SFAS is much more restrictive. Forced RC flow provides several benefits during a tube rupture.

1. It minimizes primary to secondary delta P and thus reduces tube leakage and tube tensile load.

2. Prevents steam formation in the RCS. (Steam votding prevents RCS depressurization.) l i

3. Provides pressurizer spray so that RCS pressure l control is not dependent on the PORV or pres-  ;

surizer vents.

Therefore, GPUNC is taking action to have the 1600 psi pressure pump trip requirement changed to trip on subcooling margin.

E. Conclusions Primary to secondary leakage will be monitored during non-steaming and steaming conditions. Sampling requirements on the detection of a primary to secondary leak have been established, and administrative limits on leakage are being considered.

The combination of analysis of tube ruptures, procedure improve-ment and training improvement give assurance that operators can safely respond to a primary to secondary leak.

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XI. ENVIRO! MENTAL D'. PACT A. Introduction The impact of operating TM1-1 with primary to secondary leakage was evaluated. Offsite dose estimates were determined at several leakage rates, using actual anticipated failed fuel percentages. These calculated estimates have been compared with Appendix I rechnical specificatien requirements.. The effect of leakage on onsite exposure was also consic'ered and found to be small. Exposures associated with steam generator work leading to return to service are also discussed below.

3.  :!!:i:- : 3 :2: :::

1 The maximum primary to secondary leakage rate at which TMI-l might operate can not be determined without operating ex- i perience. The offsite consequences of such operation will be  !

dependent on the failed fuel percentage and actual plant system )

and environmental conditions. Dose will be determined during operation by nonitoring. The technical specifications for THI-l incorporate the Appendix I offsite dose limitations. If offsite doses approach these limits due to primary to secondary leakage, it will be necessary to shut the plant down t'o look for leaks.

For planning purposes , two calculations were performed using different hypothetical leaks rates,1 lbm/hr and 6 gph. 1 lbm/hr is the repair leak, rate goal. 6 gph was selected as a leak rate with which similar plants have operating experience, and which is similar to the leak rate change at which admin-istrative procedures TMI-l would shutdown to look for leaks.

Both calculations assumed 0.03% failed fuel, which was seen at TMI-l at the end of cycle 4. Results of the two estimates are compared in Table XI-l to Appendix 1 technical specification limits. Source terms and methods for calculation can be found in Reference 11 and 54.

1

Table XI-l INpothetical Maximum Individual Offsite Dose (l) 0FFSITE DOSE AND FRACTION OF APP. I LIMIT 10 CFR 50 Source 1.0 LEM/HR 6 GPH App. I Dose  % o f App . Dose  % o f App . Limit j (mr/yr) I Limit (mr/hr) I Limit (mr/yr) ,

i Iodine & .7.68E-2 0.5 4.61 31 15 Particulates Noble Cases Ga=ma 5.68E-2 0.6 2.74 27 10 i e

Beta 6.96E-2 0.4 3.33 17 20 Liouid Effluent 1.6

• k'nole Body 1.04E-3 0.1 4.88E-2 3 (adults)  ;

• Liver 1. 52E-3 0.1 7. 28E-2 0.7 10 (teens)

(1) Based on 802 of the plant capacity factor. ,

i As can be seen in Table XI-1, offsite doses are not expected to approach Appendix I limits due to primary to secondary leakage.

However, monitoring of actual offsite exposure will be used to set leakage limits which prevent exceeding technical specifi-cation limits.

C. Exposure Estimates The projected man-rem exposures for the completed OTSG repair program are estimated to be 1260-1295 man-rem. Individual ac-tivities for the steam generator program are presented in Table XI-2, along with exposures to date. ,

1 0

.f

Table XI-2 Exposures f rom OTSG Program Actual to 2/23/83 Additional Projected

1. RCS Inspection 12 0 Eddy Current Testing 35 10

2. , _

3. Pre-Repair Testing 5 0 3 l 1 4 Tube Samole Pulling Plug.ging 120 0 anc staoill:ation n

--5. Plugging and Stabilization i

. a. E plugs - 75 l

. b. Stabilization 235

6. Kinetic Expansion L

a. Pre-expansion Preparation 16

b. First Pass Expansion 168 ,

O

c. First Pass Debris Removal 132 0

d. Second Pass Expansion 167 0

e. Second Pass Debris Removal 75 0

, 7. End Milling 125 0

8. Clean-up

a. Flush -

30

b. Soak and Clean -

30

c. Individual Tube Cleaning -

10-40*

9. Testing l

a. Drip Test -

5

.b. Bubble Test -

5

c. Final Inspection and Turnover -

5-10*

To tals 855 405-440

• Items for which planning is not complete.

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Table XI-3 Radiation Fields at THI-1 Location Upper and lower Heads 1.3 R /hr .

Manway 0.13 R/hr. .

Tent 0.01 R/hr. 1 Low Zone 0.001 R/hr. I Operating with the limited leakage associated with the repaired joint was also considered. The additional exposure is expected I

*:2 1 ~ .-

*: 2:!:' - -i:: d t.*t? 'ricti:11 "ill iden-tify any additional radiation areas and minimize related worker exposure in operating with a primary to secondary leak. The largest sources of radiation exposure are expected to be the Powdex Demineralizer vessels. , Associated contact radiation levels have been calculated for a 6 gph leak to range from 0.7 mr/hr for one day filter operation to 5 7 mr/hr for 15 day operation. In addition to these estimates, experience at simi-lar plants operating with small primary to secondary leakage has been exposure increases of less than one man rem per year.

Based on this information, the annual exposure at TMI-l is ex-pected to increase by less than 1% due to leakage.

D. Sampling and Monitoring Appropriate monitoring and sampling of all waste streams will be conducted per established Gaidelines. Modifications will be installed in the Turbine Building to provide radiation and con-tamination control and effluent release control / accountability.

These modifications will consist of Powdex and Turbine Building su=p painting, and liquid monitors to measure activity during operation.

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E. Conclusions The operation of Til-1 with small primary to secondary leakage is not expected to cause offsito doses nearing the Appendix I Technical Specification limits. Final verification of estimates will be by monitoring during operation. Should monitoring in-dicate that primary to secondary leakage is causing offsite doses to approach these limits , steps will be taken to reduce the activity contribution. Exposures onsite as a result of

- primary to secondary leakage are expected to be minimal compared l to prior plant experience. Exposure during the investigation of the steam generator problem, the repair, and testing afterwards , g is not expected to exceed 1260-1295 man-rem.

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XII. TECHNICAL SPECIFICATION COMPLIANCE This safety evaluation demonstrates that the TMI-1 OTSGs are operable per T.S. 3.1.1.2, and have met the surveillance conditions for operability given in T.S. 4.19, or as defined in the releated T.S. change request.

In addition, the following technical specifications were evaluated in light of the selected repairs. Operation with the repairs in place was found to be . acceptable in each case.'

SER Topic for Evaluation Reference T.S. Subject Section VIII 1.5.6 Heat Bal. Calib. .

Flow asymmetry Def 'n,- Quad. Pwr. Tilt Flow asymmetry Section VIII

-1. 6 Fig. 2. -1,2.1-3 Flow vs T Flow, flow asymmetry Section VIII 2.1

2. 3 Fig. 2. 3-2, Table 2. 3-1 ,

Nuclear Overp. Flow Section VIII Permissible pump. comb. Flow Section VIII 3.1.1.1.a 3.1.2 RCS heatup-cooldown Stress vs. Temp. change: Section V and assumes vessel as limit IX 3.1.4 RCS activity leakage Section X 3.1. 5 RCS chemistry Further attack in' conj.Section IV w/resid. S or following S distress 3.1.6 RCS leakage leakage Section IX Flow asymmetry Section VIII 3.52.4 Quad Pwr. Tilt 3 5.2 5 Quad. Bal. Flow asymmetry Section VIII 3.13 Secondary activity Appendix I w/ leakage Section X 3.22 Appendix I leakage Section X 1 3.23 Appendix I le akage Section X

4. 2 RCS:ISI Testing of RCS Components Section II.E 5 3.2.1 RCS code req. Repair qualification Section V 4

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I XIII.

SUMMARY

AND CONCLUSIONS The previous twelve sections along with the references and appen-dices associated with this safely evaluation provide a_ broad-ranging 7

discussion of the adequacy and safety of the TMI-1 OTSG repair and the ability of the plant to be safely returned to service. The main points associated with determining that the plant is safe to operate can be summarized as follows:

1. Knowledge of the failure scenario is sufficient to provide a firm technical basis for OTSG repair decisions, insure that the environment for such a damage mechanism is not established in the future, and provide a technical basis for assuring safe

arlernanca el

a3 T;J ::s=; be'..x :a= ar 2s el :a e nr. Join:.

~2. -Evaluation of operation of TMI-1 with small primary-to-secondary leakaSe has confirmed that Appendix I Technical Specification considerations are satisfied.,

3. All tubes with no defect indications below an elevation 8 inches above the lower face of the upper tubesheet (UTS+8) have been adequately repaired by the kinetic expansion process. The kinetic expansion process qualification program provides assurance that a load carrying and leak limiting joint acceptable for safe operation has' been formed.

! 4. The performance of the OTSG/RCS considering the tubes to be plugged is satisfactory and no power limitations are required.

Tubes with defect indications below the UTS+8 elevation will be removed from service by approved plugging methods. The OTSG/RCS

! performance with these tubes plugged has been evaluated for both normal operating and emergency conditions.

i 5. Circumferential defects smaller than the threshold detectability of-ECT or less than 40% through wall are acceptable. Fracture 4 Mechanics Analysis of circumferential tube defects has been conducted. The analysis identified crack geometries which would propagat'e from mechanical loads during both normal operating 'or accident conditions. Geometries which would propagate to a double ended tube rupture during 40 years of operation or during an accident were characterized as " unstable." The results have been compared to the ECT sensitivity for various geometries of circumferential defects. This' comparison shows'that the CpUNC

~

1 100% ECT inspection of the TMI-l OTSGs .vas sensitive enough to find " unstable" defect geometries.

6 .' The examination of Reactor Coolant System'(RCS) has confirmed that the aggressive environment that caused' damage to the OTSG tubes did not damage the remainder of the reactor coolant system.

The RCS examination results provide the basis for concluding

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that there are no corroded components in service which will preclude the RCS from functioning properly and supporting safe operation of TdI-1.

7. Analysis of design basis and higher primary-to-secondary leak rates confirms that the operating and emergency procedures are technically correct. The procedures provide adequate basis for training the operators to respond to normal and emergency primary-to-secondary leakage. The procedures are being modified to improve even further operator guidelincs and handle greater than design basis accidents.

8. Steam generator testing together with long life continuing i f; -9. : r;- t e c t .- . ii'. - : -id ? cenfirmsto-r data en recair stability and the 4osence of new high velocity cracking. The

- steam generator testing will be completed with essentially zero decay heat power and poses no safety risk.

Conclusion In conclusion, THI-l can be safely returned to service once the repairs and other activities discussed in this safety evaluation report are completed. This conclusion is based on.. sound analy-tical and empirical data developed by GPU Nuclear Corporation during ~ the OTSG repair program. The scope of technical evalu-ations has been broad based and the involvement of numerous independent technical experts has been extensive throughout the TMI-1 OTSG repair program. The mcthodical, technical approach to evaluating the various aspects of the problem in order to make the best and safest decisions provides a high' degree of confidence that TMI-l steam generators can be safely operated.

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FIGullE A-1 TMI-1 Restart

. Test Program Incimling OTSG Repair -

COMPLETE OTSG OTSG FILL & HCS I flESTORE OTSG - DRIP - DUDDLE - ECT A VENT HEPAIRS TEST TEST IICS _

l12 02 A

. IICS CLEANUP 1

SEC. PLANT HEADY TO -

SUPPOHT llEATUP

• 1 i

ESTABLISit MO OTSG/FW llEATUP OTSG COOL HO1 AH FOR OTSG HOTTEST FUNCTit..JAL POWER CllEMISTRY -- _ -

DOWN TO SUPPORT tlOT TEST ANDSOAK TESTit;G PilYSICS TESTS IIEATUP I

• 3 "4 NATURAL POWER RETURN OTSG ClHCULAllON ESCALATION TO'100% EDDY Di ._ _

CURRENT TESTING TESTING

. ~ 90 DAYS TEST

• FormalManagement Review I l 49 % 7S% 100%

i e

FIGullE A-2 TMI-1 OTSG Tulse Repair Precritical Test Program ,

o COMPLETE PERFORM PERFORM . EVALUAT' FILL AND

~ ~ ~ ~

PA i S OTSG DR P OTSG BUDBLE RESTORE h0 TEST TEST RCS 2 t

(2 DAYS) (2 DAYS) (3 DAYS)

Ph CONDUCT RE-ESTABLISH ll/U RCS CONDUCT TilERM AL t

' flCS 182 02 _ RCS _ 532* F/2155 # -

OPERATIONAL SOAK p CLEANUP CllEMISTRY FOR OTSO LEAK TESTING 532*F/2155 #

130*F/300 # FOR ll/U TUDE TESTS (2 WKS) (2 WKS) (2 DAYS) (2 DAYS) (1 WKl

. . L.

RCS RCS ll/U RCS THERMAL ll/U flCS t COOLDOWN COOLDOWN

@ 60*F/Hil. 532*F/2155 # -

532 F/ 155# @ 907/HR.

d32W2 m >

FOR 2 ilflS. FOft 2 ilRS. '

~

(1 2 1111S) (11 DAYS) (12 HilS)

TilERMAL flCS MNGNT SOAK COOLDOWN TO TO flFT p -

11EVIEW y TESTING 532*F/2155 # 130*F/300 #

(11 DAYS) (12 IIRS)

APPENDIX A PREGITICAL AND POST GITICAL TEST PROGRAMS

1. INTRODU CTION l

The IdI-l restart test program has been planned to provide a deliberate, methodical, well planned verification of proper installation and performance of the steam generator joint modifications , to verify conformance with design and licensing bases. Cold and hot precritical testing have been combined with the power escalation program to create a progressive testing progrea ior cae C %J4. raa prc;ra iac.cuas :ac f a' . .cwing:

~

~'.- Verification of the adequacy of the OTSG Tube Repair Program by pre-service leak testing of individual tubes

. Verification of the adequacy of the OTSG Tube Repair Program by operational leak testing and on-line monitoring throughout the test program

. Verification of the adequacy of the repaired OTSG tube joint and tubing in service to carry loads under normal operating transient conditions.

. Verification of acceptable system readiness and plant I operation with new and modified plant operating, surveillance, emergency, and abnormal procedures

. Performance of sufficient modified system / plant steady state and transient operations to provide operator ,

training and familiarization with modified system / plant )'

response throughout a range that is likely to be experienced during the design life of the plant The scope and chronology of testing planned to meet these goals are discussed below. The test sequence is summarized in Figure A-1.

II. PRECRITICAL TESTING Both hot and cold (pre-service) testing will be performed prior to criticality.

The overall objective for the pre-service program is to demonstrate the success of the repair by providing adequate assurance of the post-repair primary to secondary structural and leak tightness integrity of the steam generators.

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The specific post-repaired features of the steam generators to be l tested include the tubing kinetic expansions, the Westinghouse roll l plug installations , and the E&W weld plug and explosive plug installations. In addition, the testing will simulate operational loading of partial through wall defects in tubes remaining in l l

service.

The sequence of cold and hot precritical tests is shown in Figure A-2. ,

A. Pre-service Test Program Tests to be conducted prior to heat up include the following:

l. Drip test, whereby the primary side is drained completely, the secondary side pressurized to 150 psig, and water leakage from tube ends observed in the lower head. This method leak tests plugs installed in the lower tubesheet, the tubing expansions, and the full length of tubing remaining in service.

2. Bubble test, whereby the primary side is drained to a few inches above the upper tubesheet, secondary side water level is lowered and pressurized to 150 psig. Kinetic tube expansions , tubing above the lowered water level, and upper tubesheet plugs are leak tested by visually observing gas bubbles in the upper head. Based on experience at similar plants, this method is expected to have a lower limit of detectability of about 0.1 gal / day per tube (leakage at normal operating pressure and temperature).

3. Baseline eddy current testing, to verify that the kinetic expansion has not changed the condition of tubing, and to provide a baseline for post-critical ECT. Precritical ECT is discussed in greater detail in Section III with the post-critical program.

B. Hot Tes ting f The initial period of hot testing will be devoted solely to OTSG testing. Testing will be designed to include transients which will stress the OTSG tubes, open up any cracks which are on the threshold of propagation or open up any undetected cracks further. Large defects, if any, will then be detected prior to critical operation by leakage monitoring. In addition, the testing sequence and subsequent cooldown will simulate most of the same conditions in which original cracking initiated. This sequence will give confidence that the failure mechanism will not reactivate. It is anticipated l that the OTSG testing sequence will take approximately one g month.

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When the steam generator hot functional test sequence is complete, a management review of the results will be l conducted. If the results are satisfactory, the plant will l proceed with the normal precritical hot functional program, I and subsequently with critical operation.

l l The following tests will be performed as part of the OTSG hot functional test sequence: ,

1. Normal Heatup The RCS temperature and pressure will be raised to 532*F and 2155# in accordance with normal operating procedure.

2. Operational leak Test This test is required by technical specifications whenever 4 work has been performed in the reactor coolant system. l The pressure in the primary system will be raised to approximately 2285#, creating a differential pressure  :

between the primary and secondary of approximately 1400# i (maximum normal operating differential pressure). This is i expected to be the maximum differential pressure '

experienced by the repaired tubes.

3. First Thermal Soak l Conditions will te allowed to equilibrate at 532*F and 2155# for approximately one week, to provide baseline leakage data and to allow monitor of leakage for trends.

4. Normal Cooldown Transient i A controlled cooldown will be conducted according to normal procedure, at approximately 60*F/hr for approxi-mately three hours to 350*F. Tube to shell delta T will j be monitored to determine the stresses placed on the tube. leakage will be monitored throughout the transient.

Second Thermal Soak I 5.

The RCS temperature and pressure will be returned to 532*F and 2155#, and held there for eleven days. Leakage data will be obtained for comparison with the earlier thermal }

soak, and to monitor for developing trends. l

6. Accelerated Cooldown A controlled cooldown using emergency feedwater will be l conducted at close to the maximum rate permitted by 1

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6

---,- c ,,-- - - ,

l technical specifications , at approximately 90*F/hr for (

approximately two hours. This transient is expected to l apply greater loads to the repaired tubes than the earlier cooldown. Iube to shell delta T will be monitored to determine stresses. leakage will be monitored throughout the transient. ,

f

7. Third Thermal Soak t The RCS temperature and pressure wil'1 be returned to 532*F and 21550, and held there for approximately eleven days. ,

leakage data will be obtained for comparison with the earlier thermal soaks, and to monitor for trending.

3. Normal Plant Cooldown -

The plant will be cooled down to 130*F at 90*/hr or the maximum rate possible using normal feedwater if 90*F/hr is not attainable.. The plant will be maintained at 300#,

130*F pending management review of the OTSG hot functional results.

9. Flow Rate Testing -

Because tubes will be plugged during the repair process, the RCS flow rate must be measured af ter repair to verify compliance with technical specification. This test will be performed when the plant is at normal operating temperature and pressure. -

III. POST-CIITICAL PLANT TESTING The deliberate, methodical approach to testing will be maintained throughout the power ascension program. The normal program has been lengthened to permit ample time for leakage monitoring and trending, as well as'for familiarization with plant performance following the modification. After the power escalation program is complete, and again at the next refueling outage, special inservice inspection programs will be conducted to look for the effects of operation af ter the repair on tubing and components.

A. Power Escalation Testing Power escalation testing is expected to serve two purposes in testing the steam generators. First, the slow progression from power level to power level will permit monitoring of possibly changing plant conditions such as leakage. Se cond , ,

several of the tests already planned for start-up testing will apply loads to the steam generator tubes. Leakage monitoring before and after the transients will provide information on the condition of joints and tubing.

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The power escalation prograc is discussed chronologically below. Transient tests of interest are noted for each power it. vel .

1. Lower Power Testing Following hot functional testing and initial criticality, the normal plant zero power test will be conducted. After this approximately one week program, low power natural circulation testing will be performed.

This test verifies the tuning of the Integrated Control System (ICS) to maintain preset OTSG levels under loss of ,

main 'eedvater snd natural circulation conditions. It  !

also verifies proper response of cne DEW system as well as

~  !

the establishment and maintenance of natural circulation under varying conditions. Testing will be conducted at

• approximately 3% of rated thermal power to simulate the decay heat load that would correspond to significant core burnup. EFW initiation is expected to stress the OTSG tubes. This test will also verify that plugged tubes have  :

no effect on establishing natural circulation flow. l t

A management review will be conducted follcwing natural l circulation testing. Satisfactory OTSC and plant j performance will be necessary to increase power. I

2. Operation at less Than 50% Power .

Power escalation testing will be conducted for several days each at 15%, 25%, and 40-48% power. The 40-48%

plateau testing will include a loss of feedwater test. At a power level of approximately 40-48%, both main feedwater ,

pumps will be tripped. All three emergency feedwater i pumps will start automatically and OTSG level will be  !

controlled at 30 inches +2 in. - 10 in. by emergency feed-water. The use of EFW will cool and stress the OISG tubes.

t The RCS Overcooling Control test will demonstrate that the l control room operator can properly throttle EFW flow to prevent overcooling of the RCS following a loss of RCP's with OTSG 1evel initially at 30" on the startup range. {

The effects of this transient and of operation to date l will be monitored during a one month soak at approximately  !

48% power. The power level was selected as the minimum .

permitting two main feed pump operation. Some operator training will also be conducted during the soak. Prior to -

increasing power, another management review will be held ,

to evaluate test results and plant performance during the

• soak.

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l l 3. Power Escalation to 100% Power I Testing at 75* and 100% power will conclude the power escalation program. The 75% plateau will include approximately five days of testing followed by another one month soak to observe plant performance. Power will then be increased to 100% power for approximately one week of I

testing. Testing of interest at this plateau include the 100% turbine-generator trip.

i' A management review of plant performance will then be conducted before the plant procedes with normal power i

operation. l I

l E. Edcy Current Ies cing

~ Either 90 calendar days afte.r reaching full power, or 120

• calendar days af ter exceeding 50% power, the plant will be l shutdown for the performance *of eddy current testing. Test j results will be compared with a baseline taken prior to restart to verify the lack of defect propagation during normal operation. The baseline, 90 day, and next refueling ECT examinations are discussed in detail in Reference 56 and summarized in Table A-1. Testing listed for the' preservice baseline will be performed after repairs are complete to s

provide evidence that no changes have occurred since the 1982 100% record inspection. Any new or changed ECT indications

< found in the three inspections will be evaluated. If evaluation shows they are unacceptable, they will be treated as new defects with subsequent actions taken as required by Technical Specifications.

a 1

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Table A-1 Post Repair ECT Inspection Summary 9 I

90 F.P. Days Cycle 6 Inspection Refueling Outage Remarks SCOPE Pre-Service Inspection 0.540" S.D.ll.G. Repeated Repeated 1(a) All tubes 40% (i) i T.W. below the Full Length qual. length (ii) 8 x 1 to confirm S.D.

in both OTSG's Ind. & circumferential extent Repeated Repeated *Use ECT technique proven 1(b) All adjacent tubes

• Wear baseline exam. in by laboratory testing to to'10 selected area of interest. (Using be adequate for wear exam.

plugged unsta- ECT probe demonstrated bilized tubes adequate for wear examina- '

with defect tion in area near defect.)

in 15th, 10th &

Ist spans (10/Ea.

OTSG)

I Repeated Rep'eated *Use ECT technique proven C 1(c) All adjacent tubes.* Examine for 0.D. wear by laboratory testing to

'" baseline in the 16th span to 10 selected be adequate for wear exam.

' plugged unsta, (Using ECT probe demon-

. bilized tubes strated adequate for per each- ,

wear examination in area OTSG in the near defect.)

periphecy 8 x 1 absolute for 6" Q.L. Repeated Repeated 1(d) All. tubes had new indications ,

in the.6" qual.

length j , .__

0.540" S.D. high gain in- Repeated Repeated

,f l(e) 50 tubes"inLt:.e high . plugging spection for full length

!. density area

,- per each OTSG

i Table A-1 (Cont'd)

Post Repair ECT Inspection' Summary 9 i

. 90 F.P. Days Cycle 6 Pre-Service Inspection Inspection Refueling Outage- Remarks SCOPE 1(f) 3% of tubes in 8 x 1 examination in UTS Repeated THD s

addition to 1(d) ,

in each OTSG from top of 6" qual.

length to lower surface of UTS' Repeated Repeated *Use ECT technique proven 1(g) All adjacent tubes

• Wear baseline examination by laboratory testing to to 5' plugged at same elevation as defect be adequate for wear exam.

tubes per each indication in the plugged

• OTSC with 3V tube indications in lower part of OTSG's s

-0.540" S.D. high gain Repeated Repeated

[2 3% of tubes re-

"* maining in full length inspection 8 service per each See Note 1.

0TSG in addition -

.to above 1(a), ,

' (b), (c), (d),

(e) & (g)

No t. e 1: By doing pre-service examination in ab,ove categories 1(a) & 1(e), if'no new defere or no indication of defect growth from previous 0.540" high gain data, such data obtained in 1982 may be cos. ;idered representing condi-tions after expansion. No need to perform item (2) for the preservice baseline.

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APPENDIX B Responses to NRC Questions on TR-008

1. Clarify your position on removal of sulf ur from oxide films in the RCS. If will you intend to perform a sulfur removal process,Ifprovide inf ormation sulf ur removal is notwhich planned, demonstrate its safety and effectiveness.

provide information to demonstrate that future corrosion will not occur as a c:-satu res of extde-tourd sulfur,

-Resoonse: -

DPUN plans to remove sul f ur f rom oxide flims in the RCS using a hydrogen peroxide chemical cleaning process. A separate saf ety evaluation on chemical cleaning (Topical Report 010) has been supplled to the NRC.

2. On page 10, (e) you state that reduced sulfur is directly responsible for the cracking mechanism. On page 7, five sources of sul fur intrusion are listed, three of which were sodium thiosul f ate. What is the most probable source of sulur contamination that resulted in the observed corrosion? What specific steps have been taken to prevent re-introduction of sulfur? Make available for review those administrative procedures which addrus prevention of the impurity ingress to the RCS.

Response

As stated on page 8, sodlum thiosulf ate at levels of 4-5 ppm is considered to be most likely contaminant. Injection of leakage from the sodium thicsul f ate tank during reacter building spray system testing in May 1981 is the most probable source of the contamination.

The f ollowing steps have been taken to prevent reintroduction of sulfur or to identify sulfur if it were reintroduced.

a. The largest potential source for sulfur Introduction, the sodium thiosulf ate tank, has been drained and removed f rom service by cutting and blanking the supply line f rom the tank.

b. The breakers for chemical addltlon pumps CA-P-2, 3 and 4 are on the Locked Valve and Component List (Operating Procedure 1104-478).

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'c. An lon ' chromatograph has been purchased and procedures are being implemented for sul f ate analysis. ,

d. Bulk Chemical Specifications are being written to control ingress of contamination. Copies of the administrative procedures to control chemical contamination will be in place and available for review prior to restart.

3. On, page 18 It.Is stated that cracking found in the waste gas system is It is our understanding that sul f ur unrelated to the OTSG f ailure mechanism.

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If sulfur is the was defined as the corrosive species In the waste gas system.

cerrosive species in the waste gas system, why is It not related to the OTSG f ai l ure mechani sm? Additionally, what are the results from the inspections of supperting systems (LER 82-02).

Resocnse:

Failure of piping in the waste gas system has been characterized as lGSCC in the Analyses weld heat-af f ected zones (HAZ) at the 304SS socket weld connections.

of the corrosion products have confirmed that the HAZ's are sensitized and that iron pyrite.

the prima y contaminant is sulfur, predominantly in the form of Pl? ting and general corrosion have al so been identified in the PORVs put in  :

• -- *:2 *- *r- r-" un 1070 erd Julv 1081 Sulfur has been found in both valves. l These ecmponents, l i sa ine steem generarces, bonTu ca. , ;m:c prc.=2,

-and theref ore tne transport 6f sulfur to the corrosion site is not via an j aqueous medium. It can be postulated, theref ore, that a gaseous transport nfechanism was operative and corrosion was not the result of direct contact tsith thlosulf ste contaminated RCS coolant as was the case with the steam generator

tuces. It is logical to assume, hcwever, that thiosulfate did play a role in the

) cerrosi:n by providing a potential source of the production of sulfur bearing gases.

Further work to identify gaseous transport mechanism for, sulfur is underway and should provide insight to a possible corrosion scenario for the waste gas system and PORVs. When this work is completed, GPUN will then be better able to assess

' the relationships among the f ailure locations.

4. Provide informatien on the status of the RB spray system sodium thiosulf If not, ate tank (page 27). Has the tank been physically removed from the system?

wnat measures have been taken to ensure that all sodium thiosufate has been removec from the tank and its connecting lines.

Res:ense:

Fiping which connected the sodium thiosulf ate tank with the R3 Spray System has been cut and blanked.

5. On page 24 reference is made to corrosion test programs which In the event are in progress and will lead the actual OTSG by a minimum of 4 months.

these tests indicate progression or initiation of corrosion; how will this inf ormation be f actored into plant operations. Provide a schedule for completten of these tests and when the results will be supplied to the NRC.

Response

The long term corrosion test program will undcubtedly lead plant operation by a minimum of six months.

Should corrosion damage be observed on the tube samples a

during this test program, a more than adequate' time margin exists for evaluating this damage prior. to the steam generator tubes reaching the same operating time.

if the evaluation of th? 03 mage shows it to be relevant to plant experience,

corrective actions will be bken. Tests results will be made available to the if results' project manager and the resident inspector on a quarterly basis, indicare severe or rapidly propagating corrosion, notification will be given in a more timely manner. .

)

i

-)

i l

In the event the ccercslen observed is severe and/or rapidly propagating, the plant woulc be shut down until such a time that Evidence the corrosten of minorproblem attack such can be as i

assessed and appropriate actions defined. IGA would be trended, potentially leading to plan pitting er shallow Prior to this, however, the need for enemistry or for additional NDE.

operational changes would be evaluated and implemented as necessary.

In either event tne long term corrosion test program will be an integral part of the decision-making cn plant operation with data frcm this program being updated every 66 days via eddy current examination of the tube specimens and metallographic examination of C-rings.

Sz.  ;  : --- 20

ls--

GFUt. aiisi prov ice ecp i es e r a .;.c.rur , , ; . :,.r; .: tif severe and/or rapicly propagation

_ manager and _to the resident inspector, in a more corrosion is cbserved in the test specimens, the NRC will be informed expedit;ous manner.

in

6. On page 27 it is stated that sul f ate analysis will be perf ormed monthly the RCS. .What is the justification for a monthly analysis en a species which What wliI be the frequency of testing fr.r sul fur can be so potential!y harmful?

and ph-concuctivity balance during all pre-criticial testing periods when one or r.cre reacter coolant pumps are running?

Resconse:

Subsequent to the submittal of Topical Report 008, Rev. 1 the Chemistry Speelfication was revised and sulf ate analysis will be performed daily on a RCS sample. Tepical Report 008, Rev. 2 reflects this change.

During precritical testing periods, sulfur analysis will be performed daily and pH conductivity balances will be perfccmed five (5) times per week.

7. It is our understanding that a 3% ECT (plus special interest tubes) will be conducted subsequent to repairs. Additicnally, on page 65 it is stated that a second ECT will be performed following 90 days of full peser operation. What are the criteria for selecting the inspection pattern and 'the special interest tubes?

It is our position that the inspection pattern should utill:e both in the the 8 x 1 span free and

.540 probes and include all tubes with indications (10 or OD)

(below US + 8) plus a statistically significant sampling Further,of unplugged the post peripheral critical ECT tutes which are adjacent to block plugged zones.

should be conducted either 90 days af ter reaching full power operation or 120

, days af ter exceeding 50% power, whichever comes first.

Response: .

The criteria for tube selection in the baseline ECT, 90 day testing, and testing at the first ref ueling are discussed in Appendix A, Section 11.B of Topical Report 003, Rev. 2.

8. Subsequent to initial expansion a number (-12) of new Adaress indications were the effect reported within the 6-inch qualification zone on some tubes.

r , , .- -~ ry.. ,, - - . . .e.-----.-r

- - , - - - . , , , --.y -,-w -

l l

I current signal was noted and no ducille growth was found during metallurgical evaluation of these samples. These results are consistent with crack groath studies done earlier which examined expanded cracks metallographically, but not with eddy current, and found no ductile tearing.

Concurrently, in order to f urther characteri ze these new eddy current indications, f iberscope examinations were conducted on 4 tubes in OTSG B and 2 tubes in OTSG A. The fiberscope examinations concentrated on the new eddy c urr e nt indications, but also incl uded other locations within thoce tubes if visual indications of interest were noted. Table 3 summarizes the results of The visual inspection of these four tubes. An estimate of the circumferential and axial size of the visual indication seen is also provided, based on video Tape

?cc- . *s 3 esult 9 "e di m c m s m inrlm. i' ns cercluded Tkr #cr a c? Tne 6 Tuces examinec Tne nea eccy curren? incicaricas resui? Trem siTner

_ small pits _or. mechanical s c'r a te n e s . For the remaning 2 tubes, no visible indications were found. The mechanical scratches may have been caused by the

• wire brush used to clean tubes selected for the in-process testing immediately af ter expansion, to allow the insertion of the eddy current probe.

It was then undertaken to check the correlation of the ECT sensitivity curves with the indcations visible via the fiberscope. These indication sizes were compared with eddy current sensitivity curves. developed used ID notch specimens and samples of laboratory-induced IGSAC. Curve development is discussed in greater detail in Section IX.B of Topical Report 008, Rev. 2 . Various curves were developed for the .540" dif ferential and the 8x1 abosolute probes within the tubesheet and in the freespan. The sensitivity curves are shown in Figure 1.

It was determined that background noise in the tubesheet resulted in a reduction fo sensitivity f or the .540" probe, but not for the 8xt. The pit size estimates shown in Table 3 are at or below the threshold for .540" probe detectabillity in the tubesheet. They are in the lower range of detectability of the 8x1 probe.

It remained to ascertain the impact of small pits or cracks below ECT sensitivity thresholds within the expanded zone considering both load carrying and leak tightness.Section IX of Topical Report 008, Rev. 2 documents extensive werk cone to eval uate the maximum size crack which can- be left in service for the lif e of the plant and not cause tube failure under normal or accident tube loadings. Acceptable circumf erential extent vs. throughwall depth curves for various loading and analysis conditions in the free span are shown in Figure IX.3 of Topical Report 008, Rev. 2. The pits / indications found in the area of the joint are smaller than the crack size leading to f ailure by any mechanical means in the free span. These curves are conservative for indicatiens in the joint since loads imposed on the tubes are transmitted to the tubesheet in the crea of the expansion. Loads on tubing in the area of the defects will be equal to or I ss than those analyzed for the freespan. Leakage through any small def ects which are 100% throughwall is also expected to be less than or equal to

' 'similar cracks in the freespan. Unacceptable leakage will be identified during precritical testing and the tube will be either plugged or repaired. For these reasons, it is concluded that small pits or undetected crac,ks in the quellf ied area do not af fect the reliability of the new joint, it is expected that additional indications will be identified during the baseline 8x1 eddy current examination of the expanded region to be conducted following kinetic expansion. These indications will be re-examined during the 90-day'ECT and evaluated to confirm the conclusion that they are acceptable.

of these Indications on reliability of the qualification zone. Assuming additional Indications or defects are found in the qualification zone during the i

l l

post repair ECT, how will they be handled?

Rescense:

Eddy current examination using the absolute (8x1) probe was conducted for the first lot of kinetically expanded tubes in both steam generators. The scope of The eddy this examination included 151 tubes in OTSG B and 2B4 tubes in OTSG A.

current data was analyzed from the top of the 6" qualification length for kinetic expansion down through the bottom of the upper tubesheet. As a result l cf this data evaluation, 9 tubes in OTSG B and 6 tubes in OTSG A were reported as having indications which had not previously been detected by the .540" 00

. . g :.- g a s t; siac, : c ci i tsrut. : ,;r : : w .; u r: t ha.  :

generators. The 8x1 absokute probe hac been chosen f or inis in-process

-menitoring 1n the newly expanded area because the coining process of the

. expansion created so much background noise that the .540" standard dif ferential probe was not useful following kinetic expansion.

The 8x1 absolute probe provides 360' coverage. A judgment concerning defect arc length can be made depending on how many co!!s of the 8x1 probe detect an ,

Indication.- 1.aboratcry testing has shown that a 1 coil Indication can have an )

are length of 5' to 40, a 2-col i Indication has an are length up to 85', and a i 3 coil indication has an are length up to 130*. Althougn the 8x1 absolute probe can be used to quantify the circumferential extent of a particular indication, it cannot be used to accurately determine the percent thru-wall of the Indication.

The first post expansion eddy current examination was conducted in 151 tubes of OTSG B. Table 1 documents the characteristics of the eddy current signal from those 9 Indications found which had not previously been seen by the 540" .

standard dif f erential probe. No previous 8x1 data existed for the tubes within which the defect Indications were found, and therefore, it could not be determined whether the Indications existed prior to expansion or had been caused by kinetic expansion. In an ef f ort to better understand this issue, an 8x1 absolute probe baseline examination was conducted on the 284 tubes in the first loi of kinetic expansion in OTSG A prior to expasion.' As a result of this examination, three Indications were Identi f ied which had not previousl y been detected by .540" di f f erential probe. Following kinetic expansion, these tubes were again examined and evaluated from the top of the 6" Icng qualification zone through the bottom of the upper tubesheet. During this second examination, three additional indications were reported, shown by an

• on Table 2. Table 2 summarizes the location and signal charateristics of the Indications found in OTSG A.

" ~ Investigations were made to consider several possible explanattor.s for the new indications. Additional laboratory testing was undertaken to determine whether or not the kinetic expansion process was cat, sing. small cracks to open slightly, thus increasing their signal voltage. It was postulated that Indications which were previously below the threshold sensitivity might become detectable subsequent to kinetic expansion. The testing involved placing laboratory-induced intergranular cracks and TMl-1 tube samples with cracks-Inside mockup tubesheets and expanding over them. 8x1 examinations were conducted price to and af ter kinetic expansion. No significant change in eddy 9

6

,- - , , . , , . , _ , ._. -. ~ - - -

i l

OTSG B OTSG Post-Expansion Eddy Current Absolute (8x1) Res.ults II D.;;:xnf 151 tubes kinetically expanded and E/C examined. Nine (9) tubes were reported by 8x1 as having indications not seen by

.540 S.D.

Results -

• ABSOLUTE NOISE LEVEL S.D.

Row / Tube Location Coil Volts Distortion 400 Base Mix 4-19 US+11 1 .5 1 2V .6V 4-30 U S +12.9 2 2 2 -

3-27 U S + 9.4 3 6 2 2V .6V 3-25 US + 10.7 1 1 1 2V .6V 3-24 U S + 12.6 2 2 2 2V .6V 3-21 US+10 1 1 1 2V .6V 2-21 US+ 13.1 1 1 1 2V .6V

2:22 US + 13.2 4 1 (MULTIPLE) 2 1.8V .5V

'2-25 US+07 1 1 1 1.5V .5V

• New Kinetic Transition Table 1 6

l .

\

l 1

OTSG A OTSG Post-Expansion Eddy Current Absolute (8x1) Results 2 2 :h;.~ : x.7 d

~

284 tubes kinetically expanded and E/C examined before and after expansion. Six (6) tubes were reported by 8x1 as having indications not seen by .540 S.D.

Results - Absolute - - Level of Noise S.D. -

Row /Tuoe Location Coil Volts Distortion -

400 Base Mix AFTER EXPANSION ,

2-12 Not expanded .8V .4V 6-43 US+4 1 1 1 .8V .2V 7-54 US+1 TO 1 1 (MULTIPLE) 1 .6V .3V U S + 10.7 .

4-4 US+9.1 1 <1 1 2V 1V 4-32 US + 11.9 1 .5 1 1.8V IV 2-7 U S + 6.3 1 .5 1 1.2V .4V BEFORE EXPANSION ,

• 2-12 US-3 TO 1 <1 (MULTIPLE) 1 US+7 3 < .5 1

• S-43 US+4 1 <1 1

'7-54 US-8 TO 1 <1 (MULTIPLE) 1 US+13

• 8x1 Reported 3 tubes as having indications before expansion Table 2 l

i i

l l

l

i l

1

. l OTSG Post-Expansion Eddy Current Fiberscope Examination Summary VISUAL SIZE (in.) ECT OTSG ROW _ .. TUBE INDICATION LOCATION CIRC AXIAL COILS VOLTS B 3 24 Line of Pits U S'+ 13 .01 .02 2 2 B '2 22 Area of Pits US+13 .01 .06 4 2 B 3 27 Area of Pits US+10 .01- .03 3 6 B 2 25 Scratch US+7 >.05 - 1 1 A 4 32 No visible -

U S + 11.9 - -

1 <1 indications A 2 7 No visible U S + 6.3 - -

1 <1 indications Table 3 S

l

s FIGURE 1 s

I METALLURGIC AL CONFlRM ATION , ,,

OF ECT SENSITIVITY FOR IGSAC 360* 1.7 5" g-- x yg.. ...y. Metallurgical

" a~ ~ : ':^ Confirmation

&i- i ..

+:-

z: . :.:

Tubes pulled

a

nil!

35: with IGS AC 300* 1.46" E _h r..

. .ij. .:.i.-

pi- O Laboratorv inducea

lis IGSAC detected

. : ~: 15:

E 'wY i!!!!  !!!yii O Laboratory induced S i-Miii. IGSAC not detected

• 5 1.17" 240"  !.!: -

.i:J..ii.i

.'i_:i :n

.c

1;;;;;:

- i;i:!

-- Tested boundarles of E

E/C detection

• 1.0"  ::jjij o  !.7. !

z.:s E M!E " Projected

• 875" "" - --

180* -

f, E/C"f"ie"ld of ,

g g 4 ..... , jijh= boundaries of

!!detectabilit.yj; :i:i:i:i  :-

E/C detection i..:: _i

. = -

i!!!.jj Q . W.MM. . . E. .

120' .58" hdN!!!!

m+%.i:!

!!!d, 2

. ..--r

.~d:

'l. .

Undefined -i  !!!h .540 J' gain 60 fill factor 94%

boundar.nes Nes-9!K13. r:!

• i- . '

s.: . .... ....:.:. .

.:</ ~ .<.

sc .-

is. a 1

..;. f ' ". . .-.....w i:!('J1.!i .:.

GO' .30" ~

r i:!fytis.  :.:.;.:.

C*c~::i:q,!:i. ..

':::h::it:::..

"i . :p;;;. .

""w

. , :ib.. . Ji:i: < i:l.e.:.!:L.y Test standards for .187" 4:i:ii.:i:

, -";.::. .r.ii E/C qualification .100" . . ..:.

Notch width (.004") .000" ^ \. ......... .......

, , /.11 i i i i g i wpwis 10 20 30 40 50 GO 7 80 90 100

.540

.540 Below dTS  % Through Wall in UTS

9. On page 63 it is stated that flow induced vibration an inermal act ing will not cause crack propagation. Provide more detailed inf ore..ation to apport that j statoment . Specifically, address the concerns raised in Dr. McDont:1's letter of October 23,1982 (provided to you earlier).

Resoonse:

In Section I X.B of Topical Report 008, Rev. 2 sucinarize-. evaluations of crack propagation. Greater detail is available in GPUN TDR #388, lube Stress Report, j t Rev. I which has been supplied to the NRC. Much of the . ark reported in thess .

l documents has been completed since Dr. Mcdonald's October 23, 1982 letter, and n-- +: add m M s :: n "s.

10. In the tube plugging and stabilization discussion (page 50) there doesn't

_ appea- to be a reference to tubes within the 10th span whlen is a suspected high

. cross flow area. What is the plan for t'ubes with indications or defects in the i 10th span? -

Resoonse:

l' The 10th span is a region with some crossflow, but considurably less than the 4 high crossflow of the 16th span. Plans for plugging and sf abilization of the'

10th span and f or other regions of the OTSG are discussea in Section Vll.C of sopical Report 008, Rev. 2.

l

11. Figure IX-4 Identified the limit of detectability for tube leakage at .03%

1 FF as. 46 gph. This figure is cited many times in the SER es a basis for being able to detect propagating cracks during precritical test;og. Clarify if tnese j limits of detectability apply. for pre-critclal testing where no noble gases or lodines are present. Identify what the limit of cetectability.is for

precritical testing if it is not .46 gph.

Resoonse:

Ine. 48 gph limit of detectability applies to the precritical testing as well.

i Although this limit was originally set assuming the 7resence of noble gases and i lodines, this limit will still apply in their absence by employing a sultaoly j long soak time to allow boron concentration to buildup in the steam generator.  ;

i i 12. What are the adminsitrative limits for primary to soccodary leakage (page

! 74 )? What is the basis of establishing these limits? How co these leakage limits fit into leak before break?

i

Response

The bases for establishing administrative limits on leakage are su:rmarized in >

Topical Report 008, Rev. 2. Chapter X . Final'adminsitrative limits can De  :

i= made available at a later date.  !

, 13. Block plugging of tubes. will result in moisture carryover and increase the

erosion-corrosion potentlai for peripheral tubes (#7 above addresses ECT of.

l these tubes). Additionally, moisture carryover will increase the potential for. .

erosion of downstream components and piping. Provide an ISI program to monitor i g.

ya p , , ~ . ,

.-w~-.,.y. r -.w.. 4. n -,,w aw--, . ,7-w. , ,-,

potential erosion due to moisture carryover from the OTSG.

Response

A summary of the potential for moisture carryover erosion of tubes and piping is included in Section Vill .D of Topical Report 008, Rev. 2. ECT o f peripheral tubes is descrIDed in Appendix A, Section ll.B, and ISI of the steen system is summarized in Appendix A,Section II .C.

14 Provide single and multiple steam generator tube rupture guidelines for staf f review when they are available. (page 74)

%:mn .

_ Tube rupture. guidelines hav'e been sumarized in Topical heport 005, Rev. 2, in Section X. B. A more complete discussion will be availabl.a at a later date.

15. Provide additional information on the calculations and test dats (page 44) which are used to demonstrate that the instantaneous stresses f rom tne kinetic expansion. process are structurally acceptable.

Response

Additional information on the calculations was included in tne Kinetic Expansion Technical Report, GPUN-TDR-007, dated November 1982, which has been sJpp l ied to the NRC.

16. Chapter 7, Table 1 of your "TMI-1 Steam Generator Repair Safety Evaluation", you provided a breakdown of estimated men-rem doses for OTSG repairs from crevice drying through cleanup. The total estimated dos 3 for OTSG repairs, based on this table was 268 man-rems (327 man-rns if remote cleaning was not possible) . In the December 10, 1982 letter from P. Clark, GPU to D.

Eisenhut, NRC, you stated that 322 man-rems had resulted frcm repair activities as of November 30, 1982 with an additional estimated 700-80] man-rems envisioned to comp lete the OTSG repairs. Describe, in detall, why your current man-rem estimated for the OTSG repair is three to four times your originai estimate of 268 man-rems.

Resconse:

The exposure estimate upon which Table 1, in Chapter 7 of the TMI-1 Steam Generator Repair Safety Evaluation is based was calculated prior to the start of.

the kinetic expansion repair. The estimate included only those items in the steam generator program identi fied as pa. t of the kinetic expansion repair.

Other portions of the program such as investigation of tha damage and plugging '

were not included.

The December 10, 1982 letter f rom P. R Clar'k to D. Eisenhut included all j i

aspects of steam generator work not just the kinetic expansion. The following table shows the steam generator activities that were not included in the kinetic expansion review. The reasons for these activities are discussed in TR-0CS, Rev. 2. Approximately one half of the exposure estimate is associated witn l l

t these activities. Some tasks have been better def ined since the Cecember 10 l letter, but the total has not changed'significantly. The following table shows

~

t

Exposure Estimate Comparisons Table 1 Current Task Estimate Estimate

1. .RCS Inspection * '

12(A)

2. Pre-Repair Tube Work (sampling / stab / plugging)

• 120(A)

3. Pre-Reoair Testing (bubble /

zisarscopsa

. i.v 4 Eddy Current Testing ,

• 35(A)

. 5. Kinetic _ Expansion

e. Pre Expansion activities (precoat, crevice dry) 30 "

16(A)

b. First expansion 45 16B(A)

c. First pass insert removal 50 132(A)

d. Second expansion 35 167(A)

e. Second pass insert / debris removal 55 _75(A)

6. Cleaning

a. Fl ush 51 30

b. Soak

• 30 .

7. End Milling

• 125(A)

8. Plugging -

e. Plugging & Stabilization

• 235

b. W rolled plugs

• 75

9. Post Repair Testing

a. Bubole test

• 5

b. Drip test

• 5

c. Eddy current test

• 10

10. Post-Repale inspection

a. Tube free path

• 40 6, Final close out inspection 2 5-10 268 1260 - 1295

• Not included in Table 1 Estimate.

(A) Actual Exposure.

17. Provide a breakdown by job function of the currently estimated man-rem coses f or the OTSG repair (similar to Table 1 In Chapter 7 of your "TMI-1 Steam Generator Repair Safety Evaluation"). Include in' this table; 1) your original does estimates for each job; 2) the actual doses recorded to date f or each job,

-3) the -estimated cbses required for completion of each job. You should also outline the bases f or inclusion of any new job f unctions which'were not listed in the original dose estimate table.

See .respense to item 16' above.

-_h--___________._____

current estimates.

As can be seen, items 5, 6 and 10b on the table represent all items in Table 1 of the Kinetic Expansion saf ety eval uation. For these items,'the total has increesed from 266 to 623-628 man-rem. This increase is largely due to the equipment dif ficulties described in response to Q.18.

O e

• an -.

O e

4 4

4 .

4 i

m l

l l

t I

I j .

,n , , - en- e , -n. -.w , -, s- , . . ,

wwm.,. 4

I l

'3. Describe the ALARA features inccrporated during the OTSG repair program to control occupational doses. Describe any problem areas encountered (such as equipment breakcown or mal functlen) during the OTSG rspair which resulted in nigher than planned personnel deses, and hcw these problems were resolved.

-esconse:

I' detailed descriptior cf p l anning activities and descriptions of each individual work event are available on site as separate reports. All

replanning and preparaTica activities were performed so as to follow the

uidelines set forth in Regulatcry Guide 8.8. A summary of major activities is

rovided below.

A. Fiet c imp.emenTarice. f:r me :c,T.c3 .si neri c e, pr.as.cc. ra c i e pregc cm .n been preplanned and i r. a l.1 cases procedures have been validated by mockup training and cress rehearsal . Al so, where possible, .fleid tests for major job functions have been performed in a steam generator at B&W's manuf acturing works at Mt. Vernon, inciana. At these, f acilities, equipment and tooling has been tested and work techniques practiced for the following:

(1) Kinetic expansien device testing and installation training.

(2) Debris removal equipment testing and. procedure development.

(3) Fl ush system testing.

(4 ) Tube free path vert fIcation testing.

During these tests, ful! cress r.cckup training gwas conducted, tooling concepts evaluated and verifiec, and remote equipment operation critiqued and validated. While it is nct pcssible to quantif y the man-rem saved by this training / testing, the ex;osure savings is thought to be significant. Further mockup training anc ev al uation was also performed in the mockup training f acilities available on site. This ensured that each worker received training in the job he was to perform prior to actual steam generator entry. The training / testing also allcwed the evaluation of the use of temporary shielding to establish the optimu: ccnfigurations for use in the generator and enable the evaluation and control of potential air born contamination problems.

B. Af ter beginning process field implementation, several problem creas were

- discovered wnich raised actual exposures above estimates. Specifically in the area of equipment malfuncticn the following were Identified and changes made where possible to limit exposure.

(1) During tne performance of the expansion, there were problems maintaining the video camera in operating condition. A short study analyzed equipment cown time and concluded it was more man-rem ef ficient to spend the extra time prior to and af t.er ,each blast in moving the camera into and out of the generator than it was to perform with the camera in generator repairs. This recommendation was acted on.

! (2) . Debris Removal Device: There were several problems associated with l Initially making the cebris removal tool operational and reliable. Much of l the exposure received for this task segment is directly associated with y- -p -- = ,- ,t7 , - . = -e-a-wrw, -----r, v.-= - --,-e , n- - ---,..w g--, y 3 c -

y--

corrective maintenance required to keep the equipment cperational. All maintenance entries were monitored and documentec and the perfccmance optimized through the use of briefings and training. Through'the use of tight monitcring controls, exposure f or the perf ormance . of corrective maintenance was held to a minimum.

The lessons learned about equipment rel iabil ity were inecrporated into total equipment redesign. The redesi gned equipment was used for second pass debris removal with a marked increase in equipment reliability and per f ormance . The exposure received during first pass debris removal was 132 manrem compared to 75.2 manrem f or second pass debris removal .

(3) Misfire Pete: Durinq kinetic expansion, the rare of expansien 'inserts ~ ~:

was ccasi carras t m;w in, n yn := h ...: t- - --. - - -:

misfires were caused by p,roduction problems in the deTenation cevice, wnica

- were corrected, and by seepage of the liquid precoat into the inserts. The precoat insulated the detonating cord in the insert frcm the remainder of the detonation device. Each misfire required identification of the tube, removal of the Insert, replacement arid redetonation, thus adding to total exposure. After the precoat problem was identified, it was necessary to change the preccat - expansion procedure. The original procedure had an Individual enter the generator, remove insert debris, insert the next row, exit. Precoating was then done remotel y, and the tub _es were expanded. with After altering the procedure, two entry steps This wereincreased necessary, exposure precoating done prior to inserting the candles.

resulting fran this procedure change was unavoldable since the misfire rate was technically unacceptable.

(4) 141sfire Jump Out: When the first kinetic expansion was performed, the detonating cords attached to the inserts whipped in response to the force of the detonations. During the first pass, the whipping action pulled some inserts which had misfired free of the GTSG tube, adding to exposure. The unexpanded tube could only be identified by hand measurements of the tube by workers in the OTSG. This activity was pointless after the first expansion, and thus eliminated in the second expansion. Other actions were taken to prevent jumpers, including tne use of-hotd-down devices,

- additional debris removal to veri f y that jump-out had not occurred, and additional care in moving about the head area. These changes resulted in some increase in the time spent in the generator for the second expansion.

(5) Debris Renoval: Debris that had been evaluated in the qualification program was found to be less manageable in tne field. Detonated inserts broke apart during expansion, scattering pieces throughout the generator and forcing other pieces down in the tubes, in orcer to work in the confined head area, workers had to continuously take additional time to pick up p ieces. These pieces left in the tube were also more dif ficult to remove than the intact inserts anticipated.

The f acters described above resulted in the idinetic expansion exposure increase from 266 man-rem to 541 man-rem.

19. In Section XI, " Environmental impacts", of your December 10, 1982 letter, you provide a table of projected doses to an Individual frcm anticipated primary to secondary leaks. However, this section does not detail the specific 1

l .

.s --

-,.-.+-e . , , . ,% ,r.w--. $ w-m-ve- m -m-..

TABLE 7

!!YPOTHUTICAL MAXIMUM INDIVIDUAL OFFSIT2 DCSE( )

OFFSITE DOSE AND FRACTION OF APP.I LIMIT 10 CFR 50 ,

S Q.;; j 1.C ~ /li;; j 6 G?H "

ft Dose  % of App. Dose  % of' App.

(mr/yr) (mr/yr)

(mrjU)

T L!mit I Linit 9.22E-2 0. 6 4.61 31 15 Particulates Nobic C.1ses Can=a 5.48E-2 0.5 2.74 27 10 Be:a 6.66E-2 0.3 3.33 17 20 Licuid Effluent

'-lhala 3cdy

. 9. 7 6 E-4 m 0.1 4.88E-2 1.6 3 (adu*:s)

Liter 1.46E-3 << 0.1 7.28E-2 0.7 10

(:ae.s)

(1) Jased on 80% of the plant capacity factor.

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= 10 for all other Isotopes.

2. 73 sump capacity of 10,000 gallons.

3. Olscharge rate of 10,000 gallons per day (typical anticipated discharge rate).

4. The T3 sump water i s transferred to the Industrial Waste Treatment System collection Sump. This liquid waste is then diluted with the MDCT (Mechanical Draf t Ccoling Tower) water and discharged at a rate of 38,000 gpm to the river. Dilution parameters used in the analysis are given in Table 5.

/, Aaca: cr uccaric.n anc 7.n =ra ca .an.as. J:-s;ra cu p.2.:t. !:::: 2 .r a calculates basec cn grounc level releases and are listed in Taole 6.

,(G ) Hvoethetical Maximum Individual Of f-site Dose. The off-site doses were analyzec by using The TMI Of f site Dose CaJeulation Manual (ODCM), which is based en guidelines given in the NRC. Regulatory Guide 1.109. The results of the analyses are presented in To,le 7, which ref lects the most recent evaluation and should replace Table XI-1 of the earlier Safety Evaluation report. The major changes in the revised analysis include 80% rather than 100% plant capacity factor and direct release of 1% of radiolodines to the Air Ejector in the form of organic lodine rather than partitioning from the main condenscr. Both of these revisions are consistent with NUREG-C017 guidelines. In addition, a typographical error which reversed the beta and garrrna contribution from the noble gases was corrected.

20. With ref erence to the cracking observed in the 0-ring examination, state the basis for the contention that no stress corrosion cracking was observesd in the primary system. Specifically, cite ref erences which state that if cracking is r.ot intergranular it cannot be stress corrosion.

Res00nse:

Cejects observed in the reactor vessel 0-ring have been characterized as ductile rupture as indicated by the dimpled feature of the fracture surf aces. It was noted the intent of the report to indicate that a stress corrosion cracking mechanism could not exist in the absence of intergranular attack but rather that the surf ace topography of the existing defects was not Indicative of any typical SCC morphology.

Metallography revealed that the indications observed on the surf ace were very shal low ( .001" .002") and that when opened by bending revealed only ductile

. rupture. These def ects were most Ilkely due to deformation of the 0-ring near the seatin.g surf aces.

21. With reference to the Ultrasonic Testing of botting, state the sensitivity of this inspection method (i .e., the def ect size in the mockup). Further show that calculations assuming this defect size fer all bolts will previde adequate margin and conformance with design codes.

Response

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There was no in-place standard for UT examination of bolts from the head of the '

bolt. A test program was developed which wou ld detect a small ~ Indication without ambi guity. The sensitivity of ultrasonic testing of bolting is dependent in part on the size of the bolt and the depth of the threads, in some cases, defect depths of 10% of the bolt diameter are detectable. Where threads are deeper, 20% is the maximum detectable def ect depth. The " worst case" condition is the core barrel assembly bolts, which have a 20% detectability limit and are highly loaded. These inconel X-750 bolts had a preload of 24 to 30 KS1 at installation, and were exposed to sulfur in solution with the '

remainder of the RCS. It was concluded that at least one of the ninety-eight bolts inspected would be expected to exhibit detectable damage if the bolting were in an envlornment conducive to stress corrosion cracking. Noe--s damage was

.g. uty

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were a.l so i ncone l X-750, wete suoject te a simi l ar env i rcament, anc nigner stress -level s (100 KSI). The presence of a rejectable indication woula have resulted in f urther examinations.

A verlety of non destructive and destructive techniques were used in the RCS inspection, and a variety of dif ferent materials were sampled. tb portien of the program was intended to a be a rigorous requalification of a speci f ic item.

Instead, the program as a whole was planned to generate a large data base to assess possible areas or types of damage in the remainder of the RCS, All tests were negative.

22. What is the 100% RCS design flow rate (p. 53).

Resocnse:

The original design flow rate used for analysis in the pre-operation TMI-1 FSAR was defined as 100% RCS design flow rate.

Testing at TM1-1 showed that as-built ficw was significantly greater than 100%

design flow. After allowance was made fcr instrument error, etc., the minimum actual RCS f low rate was found to be 106.5% of the original design flow.

Based on the measured flow, DNBR calculations were redone using 106.5% design flow. Other calculations were left unchanged. Current technical specification limits en flow are based on 106.5% of the original design flow rate.

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C. Steam Fittings ISI Program GPUNC will inspect the main steam line fittings at TMI-I for The following criteria were potential water droplet erosion.

used (in descending order of erosion probability) to select monitoring data points.

1 - Fittings close or adjacent to the OTSG 2 - Fittings of 90* configuration 3 - Fittings from the "A" steam generatcr "B",

Since there are more tubes plugged in the "A" OTSG than the the "A" steam lines will have a higher probability of erosion.

TSs efere. inceeetions vill be made of steam linesr... from4the A OTSG. Based on the above tne folioving r. : r.gs

- inspected before start-up and at the next refueling outage following restart.

k Table A-2 Steam Line Fittings Inspection "A" OTSG Item Qty. Description 1 2 First 45' Ells after OTSG exit This inspection will be done using ultrasonic testing techniques for measuring pipe (fitting) wall thickness according to an adaptation of ASTM E 797-81 " Standard Practice for Measuring Thickness by Manual Ultrasonic Pulse - Echo Contact Method."

"' The ultrasonic data density (number of data points) of the pipe wall surf ace will correspond closely to that already done on the turbine extraction piping at TMI-I.

Future inspection frequency and scope will be determined after the results of the next refueling outage's inspection have been evaluated.

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' REFERENCES l i,

(1) OTSG Repair Safety Evaluation Report, Aug. 1982.

(2) TMI-1 OTSG Failure Analysis Report, July 1982.

(3) Final Report on Failure Analysis of Inconcel 600 Tubes from OTSG A and B of Three Mile Island Uni: 1, June 30,1982 - Battelle - Columbus l Laboratories.

(4) Final Report: Evaluation of Tube Samples from TMI-1, July 7,198 ;

B&W *RDD: 83:5390-03:01. -

(5) Technical Specification for 0T5G Tuse Plugging wt:h 35W 4eldec Caps and Stabilizers SP-1101-12-030.

! * (6) Nucicar Safety / Environmental Impact Evaluation for OTSG Tube Plugging Using B&W Welded Cap with Stabilizer.

(7) OTSG Tube Plugging Phase I SP-1101-12-029. ,

(8) GPUN Specification SP-1101-22-008. OTSG. Tube Repair-Long Term '

Corrosion Testing, Rev.1.

l:

(9) R. C. Newman, et. al. " Evaluation of SCC Test Methods for Inconel 600 in Low Temperature Aqueous Solutions." Symposium held at National Bureau of Standards, Gaithersburg, Maryland, April 26-28, 1982.

J j (10) NUREG 0565 " Generic Evaluation of Small Break Loss-of-Coolant Accident Behavior of B&W Designed 177FA Operating Plants."- January-1980.

(11) MPR Report, "TMI-1 OTSG Primary-to-Secondary Leakage," September 13, 1982.

(12) NUREG-0017,'" Calculation of Release of Radioactive Materials in i Gaseous & Liquid Effluent from PWR," April 1976.

(13) TMI-1 Plant Technical Specifications.

(14) EPRI NP-2146 Topical Report Dec.1981, " Static Strain Analysis of-I TMI-2 OTSG Tubes."

(15) ASPE Section XI -1980 Edition.

- (16) Westinghouse Electric Corporation Report WCAP-10084, TMI-1 Steam Generator Tube Rolled Plug Qualification, Test Report, April 1982. -

(17) GPUN TDR #388 Mechanical Integrity Analysis of TMI-1 OTSG Tubes.

(18) GPUN Spec SP-1101-22-006,-Rev. 5.

0 '

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REFERENCES - (Contd. )

(19) GPUN SP-1101-22-009 OTSG Kinetic Tube Expansion Process Monitoring and i Inspection, Rev. 5

( 20) Three Mile Island-1 OTSG Tubing Eddy Current Program Qualification, October , 1982. -Draf t (21) GPUN TDR 343 RCS Inspection, 6/14/82. ,

1 (22) J. D. Jones, OTSG Failure Analysis Operational History Final Report, CPUN TDR #336 May 12,1982.

t i 3) Three Mile Isiana :nt:-L - : :1 ::.r:ugn 1:: = :s:. : ::: :.a ; - - - ' . : :!. : '

Expansion Technical Report - G?UN-TDR-007 Rev .1, March 1983.

(24) J. C. Griess and J. H. DeVan, Oak Ridge National Laboratory, The Behavior of Inconel 600 in Sulfur Contaminated Boric Acid Solutions ,

September 29, 1982.

I (25) GPUN' Topical Report 010 TMI-1 OTSG Adequacy of Tube Plugging and '

Stabilizing Repair Criteria.

(26) GPUN TDR #368 Primary to Secondary Leak and Leak Ra'te Determination Methods.

(27) J. V. Monter, "TMI-1 OTSG Test Results - Interim Report," B&W Report

1. 543301-01, July 13,1982.

(28) GPUN TDR #359 Evaluation Criteria for a Primary to Secondary leak.

(29) GPUN SP-1101-22-007, Rev. 2, Short Term Corrosion Testing (30) Stress Report for OT36 Stabilizer Weld Cap, B&W 33-0231-00 (31) . Welded Taper Plug Stress Report, B&W 1002581C-02 (32) Stress Report for MK-1, B&W 32-1127439-00 (33) Stress Report for MK-3, B&W 32-1127439-01

( 34) OTSG Stabilizer Design Review, B&W 80-0150-00 (35) B&W Position paper on Use of Tube Stabilizers in THI-1, OTS6, B&W 51-1132-602-00

( 36) CHATA-Core Hydraulics and Thermal Analysis-Revision 4, BN4-230, Rev. 4, Babcock & Wilcox, June 1979. .

(37) CIPP-CHATA Input Processing System (38) TEMP-Thermal Enthalpy Mixing Prograu, B AW-321, Rev. 2 Babcock &

l Wilcox, June 1979

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I REFERENCES - (Contd. ) j (39) B&W Document No.. 32-1135 309-00, " Pump Code Certification for Oconee II" by D. J. Halteman, July 1982.

(40) NUREG 0565, " Generic Evaluation of Small Break Loss-of-Coolant Accident Behavior of B&W Designed 177FA Operating Plants." January 1980.

(41) Topical Report BAW 10092P Rev. 3, October 1982.

(42) BAW-177 " Preliminary Calculations of the Ef fect of Plugged Steam Generator Tubes on Plant Performance" March 1982.

_(43) . RETRAN-02, EPRI NP1850 CEM, May,1981.

444) Transient Model of Steam Generator Units in Nuclear Power Plants -

TRANSG-01 EPRI NP-1368, March 1980.

(45) Requests for Information on Steam Generator Feedwater Addition Events Letter from Thomas Cox of USNRC to J. H. Taylor, (B&W) dated June 20, 1982.

(46) Letter from G. T. Fairburn (B&W) to J. F. Fritzen (GPU) dated December 11, 1979, TMI-79-201.

(47) B&W Document 32-1138230-001 " Evaluation of Effects of 1500 Plugged Tubes on TMI-1 Post LOCA Core Safety, November 1982.

(48) B&W Document, Engineering Criteria for Tube Repair at TMI-l

1. 51-1137529-00.

(49) " AUX. A Fortran Program for Dynamic Simulation of Reactor Coolant System and Emergency Feedwater System." B&W Document NPGD581, August, 1981.

(50) Report in Response to NRC Staff-Recommended Requirements for Restart of Three Mile Island Nuclear Station Unit One - Amendment 25.

(51) Flow-Induced Vibration Analysis e ! IMI-2 OTSG Tubes, EPRI NP-1876, Vol.1, Proj. S140-1, Final P po. , June 1981.

(52) Determination of Minimun Be<glj Tube Wall Thickness for 177-FA OTSG's. BAW-10146, October 1980, (53) ~ Fracture Analysis of Steam Generator Tubes, Part II, Steam Intensity Factor and Crack Opening Displacement (COD) Displacements, by Prof.

F. Erdogan, Lehigh Univ. , Prepared for GPU Nuclear, 9/15/82.

(54) - TDR #399 Operation of TMI-l with Primary to Secondary OTSG. Leakage and l its Onsite/Offsite Radiological Impact.

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I REFERENCES - (Contd. )

(55) GPUN Safety Evaluation Ib. 120012-007 " Requirements for Cutting Upper OTS G Tbbe Ends , " Rev . 1; February 17, 1983.

(56) G PU N-S P-1101-22-014 , Technical Specification for Post Repair Eddy Current Inspection Program.

(57) Le tter Report, Examination of Three Mile Island'1 Third Pulling Sequence OTSG Tubes. RDD; 83:5068-03:03.

l (58) TDR 400, Guidelines for Plant Operation with Steam Generator Tube tenha ge - D-s f t

_(59) Evaluation of SBLOCA Operating Procedures and Effectiveness of i Emergency Feedwater Spray for B&W Designed Operating NSSS. .

i

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