Welding overlay repair (WOR) is commonly employed to rebuild piping systems suffering from intergranular stress corrosion cracking (IGSCC). To understand the effects of this repair, it is necessary to investigate the distribution of residual stresses in the welded pipe. The overlay welding technique must induce compressive residual stress at the inner surface of the welded pipe to prevent of IGSCC. To understand the bulk residual stress distribution, the stress profile as a function of location within wall is examined. In this study the full destructive residual stress measurement technique—a cutting and sectioning method—is used to determine the residual stress distribution. The sample is type 304 stainless steel weld overlay pipe with an outside diameter of 267 mm. A pipe segment is cut from the circular pipe; then a thin layer is removed axially from the inner to the outer surfaces until further sectioning is impractical. The total residual stress is calculated by adding the stress relieved by cutting the section away to the stress relieved by axially sectioning. The axial and hoop residual stresses are compressive at the inner surface of the weld overlay pipe. Compressive stress exists not only at the surface but is also distributed over most of the pipe’s cross section. On the one hand, the maximum compressive hoop residual stress appears at the pipe’s inner surface. The magnitude approaches the yield strength of the material; the compressive stress exists from the inner surface out to 7.6 mm (0.3 in.) radially. On the other hand, compressive axial residual stress begins at depths greater than 2.5 mm (0.1 in.); its maximum value is located at 10.7 mm (0.42 in.) with magnitude close to four-tenths of yield strength. The thermal-mechanical induced crack closure from significant compressive residual stress is discussed. This crack closure can thus prevent IGSCC very effectively.

Issue Section:
Technical Papers
Topics:
Overlays (Materials engineering), Pipes, Stainless steel, Stress, Compressive stress, Cutting, Fracture (Materials), Maintenance, Residual stresses, Stress concentration, Welding, Yield strength, Piping systems, Stress corrosion cracking
1.
Bush, S. H., 1992, “Failure Mechanisms in Nuclear Power Plant Piping Systems,” ASME Journal of Pressure Vessel Technology, pp. 389–395.
2.
N. R. C, 1988, Technical Report on Material Selection and Processing Guidelines for BWR Coolant Pressure Boundary Piping. NUREG-0313.
3.
Cheng, C. F., Ellingson, W. A., Kupperman, D. S., Park, J. Y., Poeppel, R. B., Reimann, K. J., and Yamada, H., “Corrosion Studies of Nuclear Piping in BWR Environments,” Quarterly Report for Quarter Ending December 31 1975, Argonne National Laboratories, Argonne, IL.
4.
Park, J. Y., Kupperman, D. S., and Schack, W., 1984, “Examination of Overlay Pipe Weldments Removed from Hatch-2 Reactor,” Argonne National Laboratory, Argonne, IL.
5.
Diercks, D. R., 1990, TMI-2 Vessel Investigation Project (VIP) Metallurgical Program. NUREG/CR-5524, Vol. 2, Argonne National Laboratory, Argonne, IL.
6.
Nickola, W. E., 1984, “Post-Yield Effects on Center Hole Residual Stress Measurement,” Proceeding 5th International Conference on Experimental Mechanics, SESA.
7.
Schajer, G. S., 1992, “Non-uniform Residual Stress Measurements by the Hole Drilling Method,” Strain, pp. 19–22.
8.
Hu, Chung-Nong, 1986, “Recent Developments Achieved in China about the Centre Hole Relaxation Technique for Residual Stress Measurement,” Strain, pp. 119.
9.
Yen, H. J., and Lin, Mark C. C, 1993, “Measurement of Residual Stresses in the Weld Overlay of Piping Components,” Accepted for publication in Experimental Mechanics.
10.
Nickola, W. E., 1986, “Practical Subsurface Residual Stress Evaluation by the Hole-Drilling Method,” Proceedings of the Spring Conference on Experimental Mechanics, Society for Experimental Mechanics, pp. 47–58.
11.
Rybicki
E. F.
,
McGuire
P. A.
,
Merrick
E.
, and
Wert
J.
,
1982
, “
The Effect of Pipe Thickness on Residual Stresses due to Girth Welds
,”
Trans. ASME
, Vol.
104
, pp.
204
209
.
12.
Brown, D. K., and Owens, A., 1986, “Comparison of Technique for Residual Stress Determination in a Bead on Plate Titanium Sample,” Strain, pp. 71–76.
13.
Shealy, W. S., Shadley, J. R., and Rybicki, E. F., 1984, “An Improved Back-Computation Procedure for the Parting-Out Step of a Destructive Method for Measuring Residual Stresses in Pipes,” Strain, pp. 117–122.
14.
Shack, W. J., Ellingson, W.A., and Pahis, L. E., 1980, “Measurement of Residual Stresses in Type 304 Stainless Steel Piping Butt Weldment,” EPRI NP-1413, Argonne National Laboratory, Argonne, IL.
15.
Rybicki, E. F., Shadley, J. R., and Rybicki, E. F., 1983, “A Consistent Splitting Model for Experimental Residual Stress Analysis,” Experimental Mechanics, pp. 438–446.
16.
Park, A. P., 1981, The Mechanics of Fracture and Fatigue, E. and F. N. Spon Ltd., London.
17.
Elber
E.
,
1970
, “
Crack Closure
,”
Engineering Fracture Mechanics
, Vol.
2
, pp.
37
45
.
18.
Ritchie, R. O., 1984, “Near Threshold Fatigue: An Overview of the Role of Microstructure and Environment,” Proceedings of the 2nd International Conference on Fatigue and Fatigue Thresholds, C. J. Beevers, eds., pp. 1833–1863.
19.
Taylor
D.
,
1988
, “
Fatigue Threshold: Their Applicability to Engineering Situations
,”
International Journal of Fatigue
, Vol.
10
, pp.
67
79
.
20.
IHI, 1989, Weld Overlay Pipes. Ishikawajima Harima Heavy Industries Co. Ltd. Japan. Maintenance Engineering Dept. Nuclear Power Division.
21.
Shadley
J. R.
,
Sorem
J. R.
, and
Rybicki
E. F.
,
1989
, “
A Fourier Series Back-Computation Method for the Parting-Out Step in Residual Stress Measurements in Pipes
,”
ASME Journal of Pressure Vessel Technology
, Vol.
111
, pp.
225
233
.
22.
Ritchie, D., and Leggatt, R. H., 1987, “The Measurement of the Distribution of Redidual Stress through the Thickness of a Welded Joint,” Strain, pp. 61–70.
23.
Weng, C. C., Lin, Y. C., and Chou, C. P., 1993, “A Study on the Induced Drilling Stresses in the Centre Hole Method of Residual Stress Measurement,” Strain, pp. 45–51.
24.
Lin
Mark C. C.
, and
Yen
H. J.
,
1993
, “
Failure Analysis of Nine Stages Centrifugal Pump
,”
Journal of Machinery
, Vol.
224
, pp.
195
206
.(in Chinese).
25.
Gruber, G. J., 1986, “Monitoring of Intergranular Stress Corrosion Cracks in Pipes with Weld Overlays,” International Journal of Pressure Vessel and Piping, pp. 225–232.
26.
Shack, W. J., 1982, “Measurement of Throughwall Residual Stresses in Large Diameter Type 304 Stainless Steel Piping Butt Weldments,” ANL-82–15, Argonne National Laboratory, Argonne, IL.
27.
Cheng
W. L.
, and
Finnie
I.
,
1987
, “
A New Method for Measurement of Residual Axial Stresses Applied to a Multi-Pass Butt-Welded Cylinder
,”
ASME JOURNAL OF ENGINEERING MATERIALS AND TECHNOLOGY
, Vol.
109
, pp.
337
342
.
28.
Rybicki, E. F., Stonesifer, R. B., and Shack, W., 1986, “The Effect of Length of Weld Overlay Residual Stresses,” presented at the 1986 Joint PVP and Computer Engineering Division Conference, Chicago, IL, July 20–24.
29.
Oddy, A. S., Goldak, J. A., and McDill, J. M., “Transformation Plasticity and Residual Stresses in Single-Pass Repair Welds,” pp. 13–18.
30.
Sorem, J. R., Shadley, J. R., and Rybicki, E. F., 1990, “Experimental Method for Determining Through Thickness Residual Hoop Stresses in Thin Walled Pipes and Tubes Without Inside Access,” Strain, pp. 7–14.
31.
Zhao, Huaipu, 1992, “A New Method for Measurement of Three Dimensional Residual Stresses in a Multi-Pass Butt Welded Joint,” Strain, pp. 13–17.
32.
Nelson, D. V., 1982, “Effects of Residual Stress on Fatigue Crack Propagation. Residual Stress Effects in Fatigue,” ASTM STP 776, pp. 172–194.
33.
Todd
J. A.
,
Liu
G.
, and
Raman
V.
,
1988
, “
A New Mechanism of Crack Closure in Cathodically Protected ASTM A710 Steel
,”
Scripta Metallurgica
, Vol.
22
, pp.
745
750
.
34.
Hucek, H. J., 1983, Structural Alloys Handbook, Battelle Columbus Laboratories, Columbus, Ohio.
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