Forwards Response to 900927 Request for Addl Info Re Seismic Design Considerations for Certain safety-related Vertical Steel Tanks

ML20066A847
Person / Time
Site:	Wolf Creek
Issue date:	12/28/1990
From:	Withers B WOLF CREEK NUCLEAR OPERATING CORP.
To:	NRC OFFICE OF INFORMATION RESOURCES MANAGEMENT (IRM)
References
WM-90-0204, WM-90-204, NUDOCS 9101040147
Download: ML20066A847 (36)
v • d • e

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WQ4.FCREEK NUCLEAR OPERATING CORPORATION Bert D. Withers Preement and CNef Enocottvo Omo,e December 28, 1990 WM 90-0204 U. S. Nuclear Regulatory Commission ATTN:

Document Control Desk Hall Station P1-137 Washington, D. C. 20$$$

Reference:

1) Letter dated May 25, 1989 from F. J. Hebdon, NRC to B. D. Withers, VCNOC

2) ET 89-0076, dated September 22, 1989 from F. T. Rhodes, WCNOC to NRC

3) Letter dated March 27, 1990 from D. V. Pickett, NRC to B. D. Withers, WCN00

4) VM 90 0118, dated July 5, 1990 from B. D. Withere.

WCNOC to NRC

5) Letter dated September 27, 1990 from D. V. Pickett, NRC to B. D. Withers, WCNOC

Subject:

Docket No 50-482: Response to Request for Additional Information Concerning Selsuic Design Considerations for Certain Safety-Related Vertical Steel Tanks l

Gentlemen:

i i provides Wolf Creek Nuclear Operating Corporation's (WCNOC) 3 response to the request for additional information which is documented in Reference 5.

The request for additional information concerned the seismic design considerations for certain safety-related vertical steel tanks.

Reference 1 reque0ted information concerning seismic design considerations for the Wolf areek Generating Station (WCGS) Refueling Water Storage Tank l

(RWST) which was subsequently provided in Reference 2.

Reference 2 provided the results of a reanalysis of the RWST which was performed in accordance with the guidance of Draft Revision 2 of the Standard Review Plan Section 3.7.3.

The Nuclear Regulatory Commission (NRC) Staff performed an audit of the reanalysis on February 14,

1990, which resulted in a request _ for additional information (Reference 3).

Reference 4 provided WCNOC's response to the request for additional information.

Reference 5 requested additional information for the staff to continue its review.

n1010'40147 901228.'

DR ADOCK 0500 RO. Ekx 411/ Burhngton, KS 66839 / Phone

(316) 364 8831 00

(; ',} P fi(;]

An EM opportunny EmrWoyer M F/HcWET

VM 90-0304 Page 2 of 2 If you have any questions concerning this matter, please contact me or Mr.11. K. Chernof f of my staf f.

Very truly yours, Lart D. Withers President and Chief Executive Officer BDW/jra Attachment cci A. T. Ilowell (NRC),w/a R. D. Martin (NRC), w/a D. V. Pickett (NRC, w/a H. E. Skow (NRC, w/a

Attachment to WM 90-0204 Page 1 of 3 RESPONSE TO REQUEST FOR ADDITIONAL INFORMATION REGARDING SEISMIC DESIGN CONSIDERATIONS FOR CERTAIN SAFETY-RELATED VERTICAL STEEL TANKS QUESTION 1:

During the audit on February 14,

1990, the licensee's consultant (Bechtel) had provided a handout of what was presented.

Provide revised Tables 2 and 3 and any other changes to the handout resulting from the reanalysis.

RESPONSE

The handout presented to the NRC during the audit on February 14, 1990 has been revised to indicate the subsequent results of the reanalysis. provides the revised handout including Tables 2 and 3.

Pages 18, 19, 26, 28 (Table 2),

29, and 31 (Table 3) of 31 have been revised as indicated by Revision bars on these pages.

New pages 20 and 30 are due to text ' carryover' from changes to previous pages.

Changes were made to Table 2 Flexible Analysis, Shell Course 6 OBE calculated and allowable stresses.

The calculated stress was revised to reflect the use of the licensed OBE level of 0.12g rather than the previous use of 0.138 The allowable stress was revised to reflect a more accurate interpolation of values from Figure VII-1102-4 of the ASME Code, 1974 Edition through Winter 1975 Addenda.

The Table 3 value for shear in a typical slab strip, calculated using flexible analysis, was revised per the response to question 3 below.

QUESTION 2:

Provide the maximum stress values (due to sloshing) in the angle welds at the roof-cylinder junction with stresses combined from the three components of earthquake (SSE),

Compare with the allowables.

RESPONSE

The maximum force on the 1/4 inch circumferential fillet weld of the steel angle connecting the tank roof to the tank cylinder was calculated with consideration given to the sloshing effects during an earthquake.

A comparison of the calculated maximum force with the allowable force is shown below.

CALCULATED HAXIMUM FORCE ALLOWABLE FORCE (KIPS / INCH)

(KIPS / INCH) 0.0253 3.00

Attachment to WM 90-0204 Pate 2 of 3 QUESTION 3:

Provide a summary of the maximum stresses in base slab (rebar and concrete),

including those under the sump.

Compare with the allowables.

RESPONSE

The table below provides values of the allowable moments and shears at various sections of the base slab and the corresponding maximum design values.

The maximum design values are based on factored loads and the allowable values are based on nominal strength multiplied by strength reduction factors in accordance with the American Concrete Institute code (ACI 318-1983).

ALLOWABLE HAXIMUM ALLOWABLE HAXIMUM HOMENT DESIGN /MOHENT SHEAR DESIGN SHEAR LOCATION (KIP-FT/ft)

(KIP-FT/ft)

(KIPS /ft)

(KIPS /ft) 1.

Typical 216.57 174.2 79.35 63.5 base slab strip 2.

Slab strip 568.3 494.0 79.35 74.5 around the sump pit 3.

Sump 88.5 13.2 32.9 11.9 pit slab (2'6' Thick)

QUESTION 4:

In response to question 2(a) of the previous RAI, it is indicated that the I

bolts will not experience any shear load because of the static friction between the tank bottom and the concrete slab.

This cannot be justified unless slotted or oversized bolt holes are used to allow for tank bending and flexibility.

Provide maximum calculated stresses in bolts under the l

three components of earthquake (SSE),

in pure tension as well as when l

tension and shear are combined.

Compare them with the corresponding l

allowables.

l l

RESPONSE

As requested in Reference 3 and reported in Reference 4, the anchor bolt analysis was revised using classical methods to be consistent with the foundation analysis.

The analysis for transmitting shear loads from the tank to the foundation vas also revised to utilize static friction between the tank bottom and the concrete footing.

With consideration given to this static friction, it was demonstrated that tank sliding did not occur, and therefore, the anchor bolts did not experience any shear loads.

l Attachment to eM 90 0204 P8ge 3,of 3

The tank base is anchored to the foundation by 2 inch diameter anchor bolts and the base plate is provided with 3 1/4 inch diameter holes for the bolts.

Since overcized bolt holes are used, the static friction utilized in the analysis for transferring shear loads is justified.

Based upon the

above, the anchor bolts have been adequately evaluated for pure tension resulting from uplift loads.

The maximum tension load calculated in any anchor bolt under the three components of the earthquake ($$E) is 9.864 kips and the corresponding allowable bolt tension value is 50.625 kips.

~ CALLAWAY & WOLF CREEK RWST SEISMIC ANALYSIS 1

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1. TANK MODEL - MASS l

1 MASS FOR CONVECTIVE (SLOSHING) EFFECTS 1 MASS FOR BASE SLAB 9 MASS POINTS FOR SHELL AND IMPULSIVE COMPONENTS OF FLUID l

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' RWST SEISMIC ANALYSIS

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STRUCTURE - 3D BEAMS (TANK SHELL ONLY)

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l RWST' SEISMIC ANALYSIS z

1. TANK MODEL - DAMPING BASED ON SNUPPS FSAR (REG. GUIDE 1.61)

STEEL TANK OBE-2% SSE - 4% 1 CONVECTIVE FLUID 1!2 % SOIL (BASED ON SNUPPS EM8!FEA STUDY APPROACH) PG.9 OF 31

l RWST SEISMIC ANALYSIS

2. FOUNDATION MEDIUM

- NRC SUGGESTION TO USE SIMPLIFIED APPROACH - CONSISTENT WITH EMSIFEA STUDY - RICHERT EQUATIONS - LAYERING BASED ON WEIGHTED AVERAGE (DEPTH = BASE DIM.) s) - USED DYNARN (BSAP"~""' FAMILY OF COMPUTER PROGRAMS PG.10 CF 31

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RWST SEISMIC ANALYSIS

3.

SUMMARY

OF RESPONSE - MODES: FREQ. MODE EFFECTIVE RANGE MASS (Hz) .22 (CONVECTIVE) 15% 4.6/6.2 (1ST HORIZ) 70 % 8.4/13.1 (1ST VERT) 93 % l i 1 ( PG.12 OF 31

// RWST SEISMIC ANALYSIS

4. TREATMENT OF MODES HORIZONTAL DIRECTIONS

- HYDRODYNAMIC COMPUTED PER NUREG CR-1161 (SRSS OF IMPULSE, SLOSHING AND i VERTICAL MODES - HYDROSTATIC & HYDRODYNAMIC SUMMED ABS ( PG.13 OF 31

' RWST SEISMIC ANALYSIS (

4. TREATMENT OF MODES HORIZONTAL DIRECTIONS:

(CONTINUED) - ONE HORIZ. ANALYSIS (DUE TO SYMMETRY) - 2ND HORIZ. DIRECTION IS 40% OF FIRST - ADDED NOZZLE LOADS FROM SEPARATE ANALYSIS FOR EACH DIRECTION PG.14 OF 31

RWST SEISMIC ANALYSIS

4. TREATMENT OF MODES (CONTINUED)

- COMBINED TWO HORIZ. DIRECTIONS AS VECTOR SUM - VERTICAL DIRECTION ( CONSERVATIVELY ADDED ABS TO HORIZ - USED MULTIMODE APROACH TO COMBINE ALL MODES IN A ' SPECIFIC DIRECTION ( PG.15 OF 31

~ RWST SEISMIC ANALYSIS l

5. SLOSHING HEIGHT

- BASED ON NUREG CR-1161 - CONSIDERED ROOF STRESSES - SNOW LOAD CONTROLLED PG.16 OF 31

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RWST SEISMIC ANALYSIS

6. UPLIFT POTENTIAL

-ANALYSIS BY CLASSICAL METHOD INDICATES UPLIFT ( l.E. TENSION IN BOLTS) -TANK DISPLACEMENTS CONSIDERED IN PIPE ANALYSIS 1 ( PG.18 OF 31

RWST SEISMIC ANALYSIS '7. OVERTURNING MOMENTS- -CONTROLLING CASES -FULL ThNK '//ISEISMIC -EMPTY TANK '//I'//IND -BOLTS DESIGN PER CLASSICAL METHOD, BOLTS TAKE TENSION LOAD ONLY -SHEAR LOAD TRANSFERRED TO CONCRETE FOOTING BY STATIC FRICTION BET //EEN TANK BOTTOM AND CONCRETE f OVERSIZED HOLES PROVIDED PG.19 OF 31

RWST SEISMIC ANALYSIS IN TANK BASE TO JUSTIFY THE ABOVE) l I i I l 'f PG.20 OF 31 i t.

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8. STRESSES IN SHELL

- BASED ON ORIGINAL SPEC. FOR TANKS - ASME SECTION III SUBSECTION NC I l l ( PG. 22OF 31 l.

s l( RWST SEISMIC ANALYSIS 9.

SUMMARY

- HOOP STRESS RIGID ANALYSIS:

-ONLY HYDROSTATIC PRESSURES CONSIDERED l 1 -PRESSURES COMPUTED AT BASE OF EACH COURSE I P G, 2 3 OF 31 . - l

RWST SEISMIC ANALYSIS z FLEXIBLE ANALYSIS: -HYDRODYNAMIC AND HYDROSTATIC PRESSURES WERE CONSIDERED -PRESSURES COMPUTED ONE FOOT ABOVE BASE OF EACH COURSE THICKNESS REQUIREMENTS COMPARED IN TABLE 1 ( PG. 24 OF 31

~ TABLE 1 ( Comparison of Required Shell course Thicknesses (inches) Shell Comeuted Recuired Thickness Actual Courses Ricid Analysis Florible Analysis Thickness 1 0.0520 0.1875

• 0.1875 2

0.1041 0.1875

• 0.1875 3

0.1563 0.2179 0.3125 4 0.2083 0.2789 0.3750 5 0.2605 0.3418 0.5000 6 0.3126 0.4061 0.5000 4

• Minimum Requirements Govern PG.25 OF 31

RWST SEISMIC ANALYSIS ( 9.

SUMMARY

- ROOF DESIGN

-SLOSH HEIGHT OF 3.36 FT (CALCULATED PER NUREG CR-1161) -PREVIOUS DESIGN LOADS (ROOF SNO// LOADS) CONTROL -CONNECTION // ELD BET //EEN TANK ROOF AND CYLINDER JUNCTION CHECKED t PG. 26 OF 31

RWST SEISMIC ANALYSIS 9.

SUMMARY

- COMPRESSION

-SEISMIC GOVERNED OVER WIND -SSE CONTROLLED RIGID ANALYSIS -FLEXIBLE ANALYSIS CONSIDERED OBE AND SSE COMPRESSION STRESSES COMPARED IN TABLE 2 l( l PG. 27 OF 31

j TABLE 2 k comparison of Longitudinal compression Stresses (PSI) Shell Ricid Analysis Flexible Analysis Courses. Stress Allowable Stress Allowable 1 13 4 (----) - 2698 (1484) 2 16 5 (----) 2698 (1484) 3 1912 3307 140 (----) 4200 (2310) 4 2925 3933 2670 (----) 5400 (2970) 5 4273 (2749) 7000 (3850) 6 4235 4964 6584 (3927 ) 7000 ( 3960 ) Signifies Negligible Course 5-was enveloped by Course 6 In flexible analysis, OBE values-are given in parenthesis, values shown as (----) were not computed since SSE stress was less than the CBE allowable. ( l l l l l i l l 1 PG.28 OF 31 l \\ .~, ,e.. ~+--,. ----. r-.. - - - - -, ~ - - -

g. RWST SEISMIC ANALYSIS 9.

SUMMARY

- FOUNDATION

-SOIL PRESSURES -SHEAR AND IAOIAENT IN ( BASE SLAB EVALUATED -SHEAR AND IAOldENT IN \\ BASE SLAB ADJACENT TO SUIAP PIT EVALUATED -SHEAR AND MOIAENT IN SUIAP PIT SLAB (2'-6" THICK) EVALUATED PG.29 OF 31

0 RWST SEISMIC ANALYSIS COMPARISONS PROVIDED IN TABLE 3 PG. 30 OF 31

C e

TABLE 3 Foundation Comparisons Item of Comoarison1 Ricid Analysis Flexible Anal'vsis Allowable Static Soil ,f Pressure (ksf) 3.36 3.27 20.00-Dynamic Soil J Pressure (ksf) 7.81 15.14-30.00 Shear in Typ. Slab Strip i (Vu in Kips /FT) 49.90 63.5 79.35 Moment in Typ. Slab' Strip (Mu in Kip-Ft/Ft) 107.90_ _174.~20 216.57 E Shear in Slab Strip i eroend the Sump Pit 74.5 79.35 (Vu in Kips /ft) Moment in Slab Strip 1 around the_ Sump Pit (Mu in - Kip-FT/ f t) 494.0-568.3 L Shear in 2'-6" thick Sump Pit Slab (Vu in Kips /ft) 11'.9 32.9- ^ Moment in 2'-6" thick Sump Pit Slab 13.2 88.E' l (Mu - in kip-FT/ f t) } I i l Fh3. 31-OF 31 .. _.. - _. - -..,. _. _ _}}