kr9700137 kaeri/tr-865/97 development status and research
TRANSCRIPT
IllKR9700137
KAERI/TR-865/97
Development Status and Research Directions on the
Structural Components of the Fuel Assembly
2 8 «« 2 2
KAERI/TR-865/97
as
Development Status and Research Directions on the
Structural Components of the Fuel Assembly
SUMMARY
Survey on the structural components of the state-of-the art of the PWR fuel
assembly developed by various nuclear fuel vendors has been performed. As a
result, some developmental directions and mechanical/structural basic technology to
be established for these structural components have been drawn out.
The developmental directions are as follows: The top end piece shall be
designed in shape to reduce its height to accomodate the fuel rod growth for high
bumup and to have a function for easy reconstitution of the fuel assembly. The
bottom end piece shall be designed in shape to reduce its height to accomodate
the fuel rod growth for high burnup and to have a function of debris protection.
The spacer grid shall be designed in shape to have a function of enhancing the
thermal margin and maintaining the fuel rod integrity without fuel failure due to
fuel rod fretting and vibration.
The mechanical/structural basic technology which must be established is as
follows: The stress analysis results shall comply with the stress criteria specified
in the ASME code stress limits and the shape optimization technology shall be
developed for the top/bottom end pieces. For the spacer grid cell, the nonlinear
-analysis model of the fuel rod and the analysis model on the flow-induced fuel
rod vibration, and a study of the mechanism and a quantified model on the fuel
rod fretting wear shall be developed. In addition, numerical analysis model to
estimate the buckling strength of the spacer grid assembly shall be developed.
Besides above technology, technology related the verification test should be
developed.
- 11 -
I.
II. .8. ^
III. Abstract
IV. List of Figures
1. *1 £ 1
2. q$ TEt^gs) TU^S* 3
2.1 -#2^*11 3
2.1.1
2.1.2
2.1.3
2.1.4
2.2 «Va-Ji^^ 8
2.2.1
2.2.2
2.2.3
2.2.4 ^WTf l^Vadoi i c f l ^
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2.3.i
2.3.2
2.3.3
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3.1.3
3.1.4
3.2 *
32.1
32.2
32.3
3.2.4
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24
4.
4.1 tf
4.1.1
4.1.2
4.2 *l
4.2.1
4.2.2
4.2.3
4.2.4
47
47
48
-5. 57
- IV -
List of Figures
Figure 1. KOFA 17x17 Type Fuel Assembly
Figure 2. ABB-CE's 16x16 Type Fuel Assembly
Figure 3. Quick Release Top Nozzle (Westinghouse)
Figure 4. Upper Tie Plate (ABB-CE)
Figure 5. Upper Tie Plate Assembly (SPC)
Figure 6. Top End Piece (Siemens/KWU)
Figure 7. Fuel Failure Inspection Results (ABB-CE)
Figure 8. Axial Evaluation of Debris-Induced Fuel Rod Failure (ABB-CE)
Figure 9. Debris Filter Bottom Nozzle (Westinghouse)
Figure 10. Triple Protection Against Debris (Westinghouse)
Figure 11. Lower End Fitting (ABB-CE)
Figure 12. GUARDIAN™ Grid (ABB-CE)
Figure 13. FUELGUARD™ Lower Tie Plate (SPC)
Figure 14. Bottom End Piece with Debris Separation Sieve (Siemens/KWU)
Figure 15. Integrated Debris Filter(IDF)
Figure 16. Debris Filter Bottom Nozzle(DFBN) in addition to Longer End Plug
Figure. 17 Debris Filter Grid in combination with Low Pressure-drop Bottom
Nozzle (Mitsubish)
Figure 18. Fine-Mesh Debris Filter Attached to New Type Bottom Nozzle
(Mitsubish)
Figure 19. Anti-Debris Drilled Hole Type Model (KAERI)
Figure 20. Anti-Debris Fin and Anti-Debris Double Fin Type Model (KAERI)
Figure 21. Westinghouse's Spacer Grid
Figure 22. Zircaloy Spacer Grid (ABB-CE)
Figure 23. Siemens/KWU's Spacer Grid
Figure 24. Vantage 5H Fuel Assembly Vibration Test Results
Figure 25. SPC's HTP Spacer Grid
- v -
Figure 26. SPC's IFM Grid
Figure 27. Configuration of I-type Grid and Spring
Figure 28. Finite Element Model of Fragema's Top End Piece
Figure 29. Finite Element Model of KOFA's Bottom End Piece
Figure 30. Finite Element Model of KOFA's Top End Piece
- vi -
1. *\ ۥ
TT Figure 1 3 Figure 2% £<>1 UO2
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Siemens l
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^-8-^:(Reaction Plate), Ml 7l)fil aV-g-^^ig (Reaction Spring), Ml 7flfil afl^
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90° ^ ^ A l ^ l ^ £.2:5.=?-*
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514.
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; EBW)-g-
2.1.2.5 Fragema
Fragema-M-fc KWUAV14
FragemaA>£
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- 6 -
2.2
2.2.1
Plate) « £ .
^0] 304^ i iEf lufoiE^ iEflojefl^7j-^ A > ^ - ^ ^ 7l?l|7>* ^ ^ CF-8
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27%!- *M*|-jl ^ ^ ( F i g u r e 7).
8).
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^^ol^^(Debris FUter Bottom Nozzle; DFBN)
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Si .(Figure 9 ^ 10 ^-2:) S $ a^-^s] ^ - ^ ^ - 0.05%
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- 9 -
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2.2.2.1 ABB Combustion Engineering (ABB-CE)
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2.2.2.3 Siemens Power Corporation (SPC)
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2.2.2.5 Fragema
(Anti Debris Filter)* AFA-2G ^ MK-BW^iS«| ^-8-«r^4.1117) Fragema
^ 3mm ^ o ] ^
- 11 -
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a f ^ J i ^ ^ -fi-S.^sl ^ ^ - i - Figure 164 £
^^(Debris Filter Bottom Nozzle ; DFBN)4
^^(Debris-trapping Filter Grid)!-
Pressure Drop Bottom Nozzle; LPBN)» 4-8-«!-J1 Slfe^l (Figure
17 # a ) ©ll-^ ^ 4 ^ ^ r ^ A mL* ^ ^ H £A]e|
Debris Filter Grid^ strap
Debris Filter Grid^
meshl- * J I Xi^ filter*
3|(Figure 18
- 12 -
2.2.3
2.2.3.1
KAERI4 SPOl-fc- ABB-CE^
1995\!°fl
FUELGUARD™^
2.2.3.2
7H 7>^-^^ o^^ig^(Anti-debris
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Siemens/KWU44
Vendorl-^
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44
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2.3 xl
2.3.1
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(ZIRLO
ABB-CEA>, Siemens/KWUAl-
4 * T= Si4(Figure 21, 22, 23).
Grid-to-rod fretting^^H tftQ
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Performance*1'
-Ajofl (Figure 24)
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IFM)7l- 1983^ W 4 ^ VANTAGE 5
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25, 26).
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., ABB-CE42? TURBO™^^ 4 ^^ 'I'spring, Mitsubishi^} <9s.I8)2] 'I'
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mixing vane^- -?-^-«r^ 7]A^ Q^^Z. ^7^^ £S .^? i£ . -g-ol*>j7
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Seismic
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, Siemens/KWU^g
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3.1.1
ANS/ANS-51.1^25' 4 .1 .2^^^ core components.^
? £ # (core support structure)-!- ^ S r J L tt^
ASME code Section m NB-3000^
4»D . KOFA #3. f-)
ASME code Section m NB-3000°fl^
5000 /MABB-CE4
RESAR-3S
Condition I , Q
Condition IB, IV
Non-Operational(Shipping & Handling)
Note : PmP.Pb
s0sm
=0y
C u
ASME Sec.ffl
Level A, B
Level C, D
Stress Category
Pm
Pi
Pm + PiPm + Secondary
Pm
Pm + Pb
ConditionI . OS* * ^
Stress Limit
s m1.5 Sm
1.5 Sm
3.0 Sm
2.4 Sm or 1.07 Su
3.6 Sm or 1.05 S»
-
Primary Membrane Stress IntensityLocal Membrane Stress IntensityPrimary Bending Stress IntensityUltimate StrengthStress Intensitymin. of the {l/3<rymm, 2/3<rymm, 2/3<T«.T, 0S<>U.O2T)
0.2% offset yield stress,Ultimate Stress
- 21 -
3.1.2 #.
3.1.2.1
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3.1.2.2
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3.3.
3g7].
Siemens/KWU4
3.1.2.3
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JE.«i
- 22 -
TIG
3.1.3
3.1.
cf.
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ASME codes] 7
K O F A (KOrean Fuel Assembly)^
£°J ANSYS codes] 3*]-*)
^ ( F i g u r e 29 $ 30 #i)S}-:n. n
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3.1.4
3.1.4.1
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- 23 -
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3.2.1
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fs = vortex shedding frequency
D =
U =
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Strauhal number^; #$7} 7)2\ &<m, Re > 100,00041^ *?-
strauhal number^ Re 2f ^^ISio] 0.18 - 0.22
LS^ ^-^l^- vortex shedding
vortex shedding ^7lfil 2afloflA
(fn)7l- o ] ^ vertex shedding^7]fif
Strauhal number (S)fe 0.3 < S < 0.7
vortex shedding0!!
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turbulence-induced vibration'°fl S]«r^ ^*<>1 -n-^€ *r Si 4 . turbulent
- 42 -
buffeting^
(shapped band-pass filter)*] 3 *r-8-*M \*fi-
vertex shedding 4 turbulence buffeting^
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(self-excited vibration)^ ej-JL tbcf. °11-^1
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2 ) 1 7 2Uc / fn D = 9.9 (m* / pD2)172 (2)
m = ^ ^ c ] ^ ^ (hydrodynamic mass
8 = logarithmic decrement
P =
Connors^
- 43 -
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Connors^
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by Peake, K= 3.3 by Pettigrew
fluidelastic instabiUty
3.2.4.2.2
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turbulent buffeting^ -fr4«|-7fl
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10"
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(3)
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TMI-l, Angra,
Beaver VaUy #4.36)
fluidelastic instability^
- 44 -
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- 46 -
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- 50 -
fluidelastic instability
1) self-excited
2) forced vibration
3) parametric excitation
371-xlf1 2$*«3 forced vibration^
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Chen, nelJL Wambsganss *«>1 A
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- 52 -
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(2)
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- 53 -
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AECL( Atomic Energy Canada Limited) £) CRNL(Chalk River Nuclear
4.2.4
- 55 -
REFERENCES
[I] Fuel presentation to KNFC, Westinghouse Presentation Material, 1996.
[2] S.L. Davidson, Reference Core Report VANTAGE 5 Fuel Assembly,
WCAP 10444-P-A, Westinghouse, 1985.
[3] C.L. Cling et al, "ABB Combustion Engineering Nuclear Fuel
Performance Target : Zero Defects, " Proceedings of the 10th KAIF/KNS
Annual Conference, 1995.
[4] TURBO and Korea, ABB-CE Presentation Material, 1996.
[5] R.B. Stout et al, "Presentation to KAERI on Siemens Fuel Group and
the HTP Fuel Design," 1995.
[6] Siemens Fuel Group and the HTP Fuel Design, SPC Presentation
Material, 1996.
[7] R.B. Stout et al, Presentation to KAERI on the HTP Fuel Design,
1994.
[8] FOCUS and HTP Fuel Assemblies for Pressurized Water Reactors,
- Siemens Brochure, 1990.
[9] Advanced Design Features for FOCUS Fuel Assembly, Siemens
Brochure, 1990.
[10] R. Holzer et al, "Fuel Design Advancements by Application of
Siemens FOCUS Technology," Proceedings of the 7th KAIF/KNS Annual
Conference, 1992.
[II] Fragema's Mechanical Design Report, 900 MWe STD Fuel Assembly,
ITB/84/4093, Rev.0, 1988.
[12] Fragema Upgrades the AFA, Fragema Brochure, 1990.
[13] £-§-S*1 13S!,"«I£3. -¥•§• 7)^7^: KAERI/RR-1026/90.
- 58 -
[14] H. W. Wilson et al., "Westinghouse Fuel Performance in Today's
Aggressive Plant Operating Environment," ibid, pp.23-30.
[15] Z. E. Karoutas et al., "ABB-CE's Advanced PWR Fuel Design," The
Fifth International Topical Meeting on Nuclear Thermal Hydraulics,
Operations and Safety(NUTHOS-5), Beijing, China, Apr. 14-18, 1997, pp.
U3-1-U3-8.
[16] K. N. Woods et al., "Siemens Fuel Performance Overview, "ibid, pp.
272-279.
[17] Gilles Ravier et al., "Framatone and FCF Recent Operating Experience
and Advanced Features to Increase Performance and Reliability," ibid, pp.
31-36.
[18] S. Abeta et al., "Design and Performance of Mitsubishi PWR Fuel for
Increased Reliability," Procedeeings of the 1997 International Topical
Meeting on LWR Fuel Performance, Portland,Oregon, Mar.2-6,1997,
pp.309-317.
[19] °}4%, ° ) # ^ ^ 4 SJ-^JI^^I 7fl£, KAERI/RR-1266/93, 1993.
[20] « a ^ ^ , °1*D3, s i -^a l^^ l -ffS.#£] ^ M %%#, KAERJ/TR-518/95,
1995.
[21] U34, £^a , 3^3. **<&s- *t#5L$n *s.#s\ ^n %*m, j . Of
the KNS, Vol. 27, No. 6, 1995.
[22] Advanced Light Water Reactor Utility Requirement Document, Rev. 5,
EPRI, 1992.
[23] *Hje $ 2U -frft-fi-i'S* «l-8-^ *]x}qx\ ^ 5 ^ ^ ^RJ*I)4H
^ ^ , KAERI/TR-523/95, 1995.
[24] £ 3 3 : , ^^fl 'SS.-g- ^1^1^-^^ ajl#,g- ^ ^ S-'fi 7m, KAERI >
-, 1995.
- 59 -
[25] ANSI/ANS-51.1-1983, American National Standard Nuclear Safety
Criteria for the Design of Stationary Pressurized Water Reactor Plants,
[26] W.D. Rabenstein, Mechanical Tests and Evaluation of the 17x17
Optimized Fuel Assembly and Components, WCAP-9363, 1979.
[27] K.N. Song, "Design of the Fuel Assembly Structure with Zircaloy
Spacer Grids," KWU Work Report, U6 312/87/e278, 1987.
[28] K.N. Song and D.S. Sohn, "A Study for the Improvement of Top End
Piece Structural Strength," J. of the Korean Nuclear Society, Vol. 21,
No. 3, 1989.
[29] M.D. Beaumont and J. Skaritka, Verification Testing and Analyses of
the 17X17 Optimized Fuel Assembly, WCAP-9401, 1979.
[30] L. Gesinski, Mechanical Test and Evaluation of the 17X17 Fuel
Assembly, WCAP-8286, 1974.
[31] F. Garzarolli et al, "9th International Symposium on Zirconium in the
Nuclear Industries," 1990.
[32] L.G. Stephens, Bi-metallic Spacer Friction Forces and High Thermal
Performance Friction Forces, Cell Sizes, and Doublet Stiffness Tests,
ANF-DTA-457, Rev. 2.
[33] K.N. Song and K.S. Seo, "A Characteristic Analysis on the Elastic
Stiffness of the Tapered-width Leaf Type Holddown Spring Assembly
Designed in KOFA's Design Space," J. of the Korean Nuclear Society,
Vol. 28, No. 6, 1996.
[34] K.A. Elliott, Results of the 1000 Hours Fretting Test for the ANF 17
X17 HTP Fuel Assembly, EMF-92-123(P), Rev.O.
[35] 3 3 ^ 3 , 3.<&±^ «I^^L 7J11M- Jfl# 7}#7]<g « ! T \ KEPRI94Z-J05,
!, 1995.
- 60 -
[36] M.W. Ken-ard et al, A Study cf Grid-to-Rod Fretting Wear in PWR
Fuel Assemblies, The S.M. Stoller Corporation, 1995.
[37] J.F. Archard, "Contact and Rubbing of Flat Surfaces," J. of Applied
Physics, Vol. 24, No. 8, 1953.
[38] Robert D. Blevins, Flow-Induced Vibration, Van Nostrand Reinhol&
1990
[39] M. J. Pettigrew, "Vibration analysis of heat exchanger and steam
generator designs," Nuclear Engineering and Design Vol. 48(1978) pp.
97-115
[40] R.M.C. So and Savkar, "Buffeting forces on rigid circular cylinders in
cross flows," Journal of Fluid Mechanics VoL 105 (1981) pp. 397-425
[41] M. J. Pettigrew and D. J. Gorman, Vibration of heat exchange
components in liquid and two-phase cross flow, paper 2.3 in Proceedings
BNES International conference, 1978
[42] M. J. Pettigrew and D. J. Gorman, "Vibration of heat exchanger tube
bundles in liquid and two-phase cross flow," PVP-Vol. 52(1981) pp.
89-110
[43] M. P. Paidoussis, "A review of flow-induced vibrations in reactor
components," Nuclear Engineering and Design, Vol. 74(1982) pp. 31-60
[44] H.J. Jr. Connors, "Fluidelastic vibration of tube arrays excited by
cross flow," ASME-Flow-induced vibration in heat exchangers, New
York (1970) pp. 42-56
[45] R.D. Blevins, "Fluidelastic whirling of tube rows and tube arrays,"
ASME-Joumal of Fluid Engineering VoL 99(1977) pp. 457-460
[46] R.D. Blevins, "Fluid damping and whirling instability of tube arrays,"
S.S Chen (eds) ASME-Fluid-Induced vibrations, (1979) pp. 35-39
- 61 -
[47] M.W. Wambsganss, T.M. Mulcahy, Flow-induced vibration of nuclear
reactor fuel'- Part I, Modeling,
[48] M.P. Paidoussis, "Fluidelastic vibration of cylinder arrays in axial and
cross flow, state of the art," Journal of Sound and Vibrations, Vol. 76
(1981) 326-360
[49] Shin, Y.W., Two-phase flow-induced vibrations of Rods in parallel
flow: A state of the art review, GEAT-24148/ANL-CL-78-18/C004175-4
(1978)
[50] L. V. Corsetti et al., Improved BWR and PWR Fuel Designs and
Operating Experience at ABB, pp. 280-286.
[51] Aisch and Schmucker, Minimum Necessary Spacer Springs Force,
KWU Work Report, B12/el67/79, 1979.
[52] R. E. Peterson, " Stress Concentration Factors," 1974, John Wiley &
Sons, New York.
[53] R. S. Miller et al., "Westinghouse Fuel Operating at High Burnup and
with Advanced Features," International Topical Meeting on LWR Fuel
Performance, 1994.
[54] & « 3 9^, " tf.*r# 5
-H," KAERI/TR-866/97, 1997.
- 62 -
j ^ UPPER END FITTING ASSEMBLY
taasmSMCUGIID
OTTO 8QIK1UU
OCBKt 5MCEI GRID
LOHEK END FITtttB
Figure 2. ABB-CE's 16x16 Type Fuel Assembly
- 64 -
Top Plate L-ORTN L SupportEdge Joini(iG) insert
location (0)
InslrumenlTube Hole
^ n s * n Sleeve^ (Umgaan
GuW» Tlwntrie!
Figure 3. Quick Release Top Nozzle (Westinghouse)
- 65 -
FUEL ASSEMBLYSERIAL NUKBER
OUTER POST (4)
HOLOOOUN PLATE ( I )
HOLOOOVM SPRING (4)
CEHTER POST ( I )
FLOW PLATE ( I )
Figure 4. Upper Tie Plate (ABB-CE)
- 66 -
Debris Fret t ing66% Unknown Cause
27%
Grid- to-Rod Frett ing7%
Figure 7. Fuel Failure Inspection Results (ABB-CE)
- 69 -
ApproilmaieElevation olCenter a< LowarSupport A/th*( l . U Incnesl
IncfMS•ollom of
Elevation olLower Cage olflrw u X UG/td Ctae12-30 incites)
\
Solid Meiom ^\j O . .ol Fuel Hi-'End Cap(O.J« I
7 V V
Actual Cl««atian ol C M I M T II< Support Arcn^47 lnen«a. tmorior Suip. 2M IDCIMC. Cst««Mton Slnp
4.0
3.0
2.0
ia) 4 Fud
App<aatnui«Cloviriofl olCenter ol LowerSupport
\A 1
Lowar (oo* olK m if X K
Solid Moiohlol fuel Hod
(0.C3 Indies)
I
•noesFro*•oiiom olfuel Aod
1.0
1.0
0
Actual eievalion o< Cemer ol Support'Arcn2.00 Inches. MNenor Strip. 2.04 Incite*. Etttmion Strip
f\tm\ Hod erlorawon
fuel Hod w«ar
<h> Iri.xlrj
Figure 8. Axial Evaluation of Debris-Induced Fuel Rod Failure (ABB-CE)
- 70 -POORCMMUTYI
ORiam
Fuel Rod
flow Hole
Grid Dimple
Bollom View
Figure 9. Debris Filter Bottom Nozzle (Westinghouse)
- 71 -
Coated cladding
Protective grid,fonger-«nd *plugs
DFBN
Coated CladdingN. fifejR Bottom<Support Grid
InnerStrapHeight
ProtectiveGrid
Solid Bottom End P1u«
Figure 10. Triple Protection Against Debris (Westinghouse)
- 72 -
OOOQOOQQQOCDee
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• FLOW HOLE
U i LV^> I Kli :
CIRCUUR GROOVE FORRECEIVING THE CENTERGUIOE TUBE
LEAO-IN FOR THE IN-CORE INSTR,
Figure 11. Lower End Fitting ( A B B - C E )
- 73 -
BOTTOM NOZZLEFLOW HOLE
FUEL RODS
GUARDIAN STIUIM-VG FEATURES
Figure 12. GUARDIAN™ Grid (ABB-CE)
_ 74 _
Hods
QoltoittSpacer \ J • '
Luv/er I: mlCap
f.owcrtie IM.He
Cut veilni;«ics
OOllOliOIIUflollli
Figure 13. FUELGUARD™ Lower Tie Plate (SPC)
- 75 -
/ll II II II 1 (,
11 I I I I I I Jl I I 11-11 I I I I . I I S
V
/ | n i . . L L t in 1,1.. lt
\ \
•41II II
\
I I J l • I I I I - .11. I I . . I I . . I I V
Figure 14. Bottom End Piece with Debris Separation Sieve (Siemens/KWU)
- 76 -
[Original Bottom Nozzle]
[OFBN]
Fig. 16. Debris Filter Bottom Nozzle(DFBN) in addition to Longer End Plug
- 78 -
] Grid a * Debris Filter
Grid
LP8N |
[zifcaloy Grfd FuaQ
Fig.17 Debris Filter Grid in combination withLow Pressure-drop Bottom Nozzle (mitsubishn)
Fig. 18 Fine-Mesh Debris Filter Attached to New
Type Bottom Nozzle (Mitsubishi)
- 79 -
I I
SECTIDN B - B
3 Type Hole
2 ) < ^ 4 = 1 0 . ,3 ) 0i=lO.5mr%
Figure 19. Anti-Debris Drilled Hole Type Model (KAERI)
- 80 -
Guide Thirtle Sleeve Guide Vanes
Mixing Vanes
Guide Tabs
Grid Spring Support Qtapie
IdentificationHole
Figure 21. Westinghouse's Spacer grid
- 8 2 -
BACKUP ARCH
SPRING TAB
ARCH
INTERSECTIONWELO
GUIOE TUBELOCATIONS
ROD PITCH
SEAM WELD LEAD-IN TAB
Figure 22. Zircaloy Spacer Grid (ABB-CE)
- 83 -
Vibration Amplitude
LWithout Corrective Actions
With Rotated Gods —
r With Redesijped Grids
1200 1300 1400 1500 1600 1700
Flow Rdl# (Qpffl)
1800 1900 2000
Figure 24. VANTAGE 5H Fuel Assembly Vibration Test Results
- 85 -
FUEL ROD
FLOWDIRECTION
GUIDE TUBE
SPOT WELDINTERNAL. STRIP ASSEMBLY
FLOW MIXING NOZZLES
• SPRINGS COMPRESSED
SPRINGS UNLOADED
Figure 25. SPC's HTP Spacer grid
- 86 -
!
I
k*GSC5 ( t lx*d ac):kaOSfS.i . c-15 . 5 . O-45-5 { 19 . 5/ -Otnra)
51]
H 1
Si
1i
1
Figure 29. Finite Element Model of KOFA's Bottom End Piece
- 90 -
^ *1 3 Ji <£ Q
*********
KAERI/TR-865/97
(TR.AR°] 3-f T*1*H
Hi ^ O t j ^-
92 pages
INIS
•^^T?" ^ -S-^ •§•'^•5., I8'3<l!?i ( ^ T S . ^ ^
£ S. 5fl*( v ), « » ( )
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3 7l 19x26 Cm.
± ^(15-2O#M1^)
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^ ^ Jl^^fi) ^4- ASME code*) •8-^/y7fl7l^«H| Jf^-^fe -tlsl^ •££
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BIBLIOGRAPHIC INFORMATION SHEET
Performing Org.
Report No.
Sponsoring Org.
Report No.
Stamdard Report
No.INIS Subject Code
KAERI/TR-86B/W
Title/SubfitteDevelopment Status and Research Directions onthe Structural Components of the Fuel Assembly
Projectland Department
fSong. Kee Nam(LWR Fuel Development Team)
Researcher and
Department
Kim, Hyung Kyu; Kang, Heung Seok;
Yoon, Kyung Ho; Bang, Je Geon
(LWR Fuel Development Team)Publication
PlaceTaejon Publisher KAERI
Publication
Date1997. 06.
Page 92 p. 111. & Tab. Yes( V ), No ( ) Size 19x26 CmNote
ClassifiedOpen(V), Restricted(
Class DocumentReport Type Research Report
Sponsoring Org. Contract No.
Abstract
(15-20 Lines)
Survey on the structural components of the state-of-the art of the PWRfuel assembly developed by various nuclear fuel vendors has been performed.As a result, some developmental directions and mechanical/structural basictechnology to be established for these structural components have been drawnout The developmental directions are as follows-' The top end piece shall bedesigned in shape to reduce its height to accomodate the fuel rod growth forhigh burnup and to have a function for easy reconstitution of the fuel assembly.The bottom end piece shall be designed in shape to reduce its height toaccomodate the fuel rod growth for high bumup and to have a function ofdebris protection. The spacer grid shall be designed in shape to have a functionof enhancing the thermal margin and maintaining the fuel rod integrity withoutfuel failure due to fuel rod fretting and vibration. The mechanical/structuralbasic technology which must be established is as follows: The stress analysisresults shall comply with the stress criteria specified in the ASME code stresslimits and the shape optimization technology shall be developed for thetop/bottom end pieces. For the spacer grid cell, the nonlinear analysis model ofthe fuel rod and the analysis model on the flow-induced fuel rod vibration, anda study of the mechanism and a quantified model on the fuel rod fretting wearshall be developed. In addition, numerical analysis model to estimate thebuckling strength of the spacer grid assembly shall be developed. Besides abovetechnology, technology related the verification test should be developed.
Subject Keywords(About 10 words)
Top End Piece, Bottom End Piece, Spacer Grid, Fuel Rod FrettingWear, Flow Induced Vibration, Buckling Strength