Abstract

Flow-induced vibration of steam generator tubes results in fretting-wear damage due to impacting and rubbing of the tubes against their supports. This damage can be predicted by computing tube response to flow-induced excitation forces using analytical techniques, and then relating this response to resultant wear damage using experimentally derived wear coefficients. Fretting-wear of steam generator materials has been studied experimentally at Chalk River Laboratories for two decades. Tests are conducted in machines that simulate steam generator environmental conditions and tube-to-support dynamic interactions. Different tube and support materials, tube-to-support clearances, and tube support geometries have been studied. The effect of environmental conditions, such as temperature, oxygen content, pH and chemistry control additive, have been investigated as well. Early studies showed that damage was related to contact force as long as other parameters, such as geometry and motion, were held constant. Later studies have shown that damage is related to a parameter called work-rate, which combines both contact force and sliding distance. Results of short and long-term fretting-wear tests for CANDU steam generator materials at realistic environmental conditions are presented. These results demonstrate that work-rate is an appropriate correlating parameter for impact-sliding interaction.

1.
Axisa
F.
,
Antunes
J.
, and
Villard
B.
,
1988
, “
Overview of Numerical Methods for Predicting Flow-Induced Vibration
,”
ASME JOURNAL OF PRESSURE VESSEL TECHNOLOGY
, Vol.
110
, pp.
6
14
.
2.
Berthier
Y.
,
Colobie
Ch.
,
Vincent
L.
, and
Godet
M.
,
1988
, “
Fretting Wear Mechanisms and Their Effects on Fretting Fatigue
,”
ASME Journal of Tribology
, Vol.
110
, pp.
517
524
.
3.
Blevins, R. D., 1978, “Fretting Wear of Heat Exchanger Tubes, Part 1: Experiments,” Paper 78-JPG-NE-8, Joint Power Generation Conference, Dallas.
4.
Blevins
R. D.
,
1985
, “
Vibration-Induced Wear of Heat Exchanger Tubes
,”
ASME Journal of Engineering Materials and Technology
, Vol.
107
, pp.
61
67
.
5.
Cha
J. H.
,
Wambsganss
M. W.
, and
Jendrzejczyk
J. A.
,
1987
, “
Experimental Study on Impact/Fretting Wear in Heat Exchanger Tubes
,”
ASME JOURNAL OF PRESSURE VESSEL TECHNOLOGY
, Vol.
109
, pp.
265
274
.
6.
Fisher
N. J.
, and
Ingham
B.
,
1989
, “
Measurement of Tube-to-Support Dynamic Forces in Fretting-Wear Rigs
,”
ASME JOURNAL OF PRESSURE VESSEL TECHNOLOGY
, Vol.
111
, pp.
385
393
.
7.
Fisher, N. J., Taylor, C. E., and Pettigrew, M. J., 1990, “Fuel-Element Vibration and Bearing Pad to Pressure Tube Fretting,” AECL Report AECL-10164.
8.
Fisher, N. J., Ing, J. G., Pettigrew, M. J., and Rogers, R. J., 1991, “Fretting-Wear Damage Prediction in the Inlet Region of Nuclear Steam Generators,” Flow-Induced Vibrations, Paper No. C416/053, Fifth International Symposium of Flow-Induced Vibration and Noise, Brighton, UK, pp. 149–158.
9.
Fisher
N. J.
,
Ing
J. G.
,
Pettigrew
M. J.
, and
Rogers
R. J.
,
1992
, “
Tube-to-Support Dynamic Interaction for a Multispan Steam Generator Tube
,” Cross-Flow Induced Vibration of Cylinder Arrays,
ASME PVP
-Vol.
242
, pp.
301
316
.
10.
Frick, T. M., Sobek, T. E., and Reavis, J. R., 1984, “Overview on the Development and Implementation of Methodologies to Compute Vibration and Wear of Steam Generator Tubes,” Symposium on Flow-Induced Vibrations: Volume 3 Vibration in Heat Exchangers, ASME Special Publication, pp. 149–161.
11.
Hofmann, P. J., Schettler, T., and Steininger, D. A., 1986, “Pressurized Water Reactor Steam Generator Tube Fretting and Fatigue Wear Characteristics,” ASME Paper No. 86-PVP-2, Pressure Vessels and Piping Conference, Chicago, IL.
12.
Hofmann
P. J.
,
Schettler
T.
, and
Steininger
D. A.
,
1992
, “
PWR Steam Generator Tube Fretting and Fatigue Wear Phenomena and Correlations
,” FSI/FVI in Cylinder Arrays in Cross-Flow,
ASME HTD
-Vol.
230
, pp.
211
236
.
13.
Ko
P. L.
,
1979
, “
Experimental Studies of Tube Frettings in Steam Generators and Heat Exchangers
,”
ASME JOURNAL OF PRESSURE VESSEL TECHNOLOGY
, Vol.
101
, pp.
125
133
.
14.
Ko
P. L.
,
1980
, “
Fretting-Wear Studies of Heat Exchanger Tubes
,” Flow-Induced Heat Exchanger Tube Vibration—1980,
ASME HTD
-Vol.
9
, pp.
11
18
.
15.
Ko
P. L.
, and
Basista
H.
,
1984
, “
Correlation of Support Impact Force and Fretting-Wear for a Heat Exchanger Tube
,”
ASME JOURNAL OF PRESSURE VESSEL TECHNOLOGY
, Vol.
106
, pp.
69
77
.
16.
Ko, P. L., 1984, “A Brief Review of Tube Fretting-Wear in Heat Exchangers,” AECL Report AECL-8272.
17.
Ko
P. L.
,
1985
a, “
Heat Exchanger Tube Fretting-Wear: Review and Application to Design
,”
ASME Journal of Tribology
, Vol.
107
, pp.
149
156
.
18.
Ko
P. L.
,
1985
b, “
The Significance of Shear and Normal Force Components on Tube Wear due to Fretting and Periodic Impacting
,”
Wear
, Vol.
106
, pp.
261
281
.
19.
Ko, P. L., 1986, “Metallic Wear—A Review with Special References to Vibration-Induced Wear in Power Plant Components,” ASME Paper No. 86-PVP-1, Pressure Vessels and Piping Conference, Chicago, IL.
20.
Ko, P. L., 1993, “Wear Due to Flow-Induced Vibration,” Technology for the 90s, ASME Special Publication, pp. 865–896.
21.
Lim
S. C.
, and
Ashby
M. F.
,
1987
, “
Wear Mechanism Maps
,”
Acta Metallurgica
, Vol.
35
, pp.
1
24
.
22.
Magel, E. E., Ko, P. L., and Johnson, K. L., 1990, “Application of Shakedown Theory to Contact Deformation and Wear Modelling,” CSME Mechanical Engineering Forum, Toronto, Ontario, Canada, pp. 117–122.
23.
Pettigrew
M. J.
,
Carlucci
L. N.
,
Taylor
C. E.
, and
Fisher
N. J.
,
1991
, “
Flow-Induced Vibration and Related Technologies in Nuclear Components
,”
Nuclear Engineering and Design
, Vol.
131
, pp.
81
100
.
24.
Rao, M. S. M., Steininger, D. A., and Eisinger, F. L., 1988, “Numerical Simulation of Fluidelastic Vibration and Wear of Multispan Tubes with Clearances at Supports,” Flow-Induced Vibration and Noise—1988: Volume 5, Flow-Induced Vibration in Heat-Transfer Equipment, ASME, pp. 235–250.
25.
Rogers
R. J.
, and
Pick
R. J.
,
1976
, “
On the Dynamic Spatial Response of a Heat Exchanger Tube with Intermittent Baffle Contacts
,”
Nuclear Engineering and Design
, Vol.
36
, pp.
81
90
.
26.
Rogers
R. J.
, and
Pick
R. J.
,
1977
, “
Factors Associated with Support Plate Forces due to Heat Exchanger Tube Vibratory Contact
,”
Nuclear Engineering and Design
, Vol.
44
, pp.
247
253
.
27.
Sauve´
R. G.
, and
Teper
W. W.
,
1987
, “
Impact Simulation of Process Equipment Tubes and Support Plates—A Numerical Algorithm
,”
ASME JOURNAL OF PRESSURE VESSEL TECHNOLOGY
, Vol.
109
, pp.
70
79
.
28.
Suh, N. P., 1986, Tribophysics, Prentice-Hall Inc., Englewood Cliffs, NJ.
29.
Vingsbo
O.
, and
Soderberg
S.
,
1987
, “
On Fretting Maps
,”
Wear of Materials
, Vol.
2
, pp.
885
894
.
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