Reactor Cooling Water Expansion Joint Bellows: The Role of the Seam Weld in Fatigue Crack Development

ASM Failure Analysis Case Histories: Power Generating Equipment Pub Date : 1992-12-01 DOI:10.31399/asm.fach.power.c9001682

S. West, D. Nelson, M. Louthan

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Abstract

The secondary cooling water system pressure boundary of Savannah River Site reactors includes expansion joints utilizing a thin-wall bellows. While successfully used for over thirty years, an occasional replacement has been required because of the development of small, circumferential fatigue cracks in a bellows convolute. One such crack was recently shown to have initiated from a weld heat-affected zone liquation microcrack. The crack, initially open to the outer surface of the rolled and seam welded cylindrical bellows section, was closed when cold forming of the convolutes placed the outer surface in residual compression. However, the bellows was placed in tension when installed, and the tensile stresses reopened the microcrack. This five to eight grain diameter microcrack was extended by ductile fatigue processes. Initial extension was by relatively rapid propagation through the large-grained weld metal, followed by slower extension through the fine-grained base metal. A significant through-wall crack was not developed until the crack extended into the base metal on both sides of the weld. Leakage of cooling water was subsequently detected and the bellows removed and a replacement installed.

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反应堆冷却水膨胀节波纹管:焊缝在疲劳裂纹发展中的作用

萨凡纳河反应堆二冷却水系统压力边界包括利用薄壁波纹管的膨胀节。虽然成功地使用了三十多年，但由于波纹管卷曲中出现了小的周向疲劳裂纹，因此偶尔需要更换。一个这样的裂纹最近被证明是由焊接热影响区液化微裂纹引起的。裂纹最初在轧制和接缝焊接的圆柱形波纹管截面的外表面打开，当弯曲的冷成形使外表面处于残余压缩状态时，裂纹被关闭。然而，波纹管在安装时被拉伸，拉伸应力重新打开了微裂纹。这种5 ~ 8晶粒直径的微裂纹是通过韧性疲劳过程扩展的。最初的扩展是通过大晶粒焊缝金属的相对快速的扩展，随后是通过细晶粒母材的缓慢扩展。直到裂纹扩展到焊缝两侧的母材时，才出现明显的穿壁裂纹。随后检测到冷却水泄漏，拆除了波纹管并安装了新的波纹管。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ASM Failure Analysis Case Histories: Power Generating Equipment

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