Residual Stress Measurement in 304 Stainless Steel Weld Overlay Pipes

Author:

Yen Hung-Ju1,Lin Mark Ching-Cheng1,Chen Lih-Jin1

Affiliation:

1. Materials Research Laboratories, Industrial Technology Research Institute, Bldg. 77, 195 Chunghsing Rd., Section 4, Chutung, Hsinchu, Taiwan

Abstract

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.

Publisher

ASME International

Subject

Mechanical Engineering,Mechanics of Materials,Condensed Matter Physics,General Materials Science

Reference34 articles.

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.

Cited by 6 articles. 订阅此论文施引文献 订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献

同舟云学术

1.学者识别学者识别

2.学术分析学术分析

3.人才评估人才评估

"同舟云学术"是以全球学者为主线,采集、加工和组织学术论文而形成的新型学术文献查询和分析系统,可以对全球学者进行文献检索和人才价值评估。用户可以通过关注某些学科领域的顶尖人物而持续追踪该领域的学科进展和研究前沿。经过近期的数据扩容,当前同舟云学术共收录了国内外主流学术期刊6万余种,收集的期刊论文及会议论文总量共计约1.5亿篇,并以每天添加12000余篇中外论文的速度递增。我们也可以为用户提供个性化、定制化的学者数据。欢迎来电咨询!咨询电话:010-8811{复制后删除}0370

www.globalauthorid.com

TOP

Copyright © 2019-2024 北京同舟云网络信息技术有限公司
京公网安备11010802033243号  京ICP备18003416号-3