Failure of a Repair Weld on a Crankshaft Because of Inclusions and Porosity

ASM Failure Analysis Case Histories: Improper Maintenance, Repair, and Operating Conditions Pub Date : 2019-06-01 DOI:10.31399/asm.fach.usage.c0047545

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Abstract

The AISI 1080 steel crankshaft of a large-capacity double-action stamping press broke in service and was repair welded. Shortly after the crankshaft was returned to service, the repair weld fractured. The repair-weld fracture was examined ultrasonically which revealed many internal reflectors, indicating the presence of slag inclusions and porosity. A low-carbon steel flux-cored filler metal was used in repair welding the crankshaft, without any preweld or postweld heating. This resulted in the formation of martensite in the HAZ. The repair weld failed by brittle fracture, which was attributed to the combination of weld porosity, many slag inclusions and the formation of brittle martensite in the HAZ. A new repair weld was made using an E312 stainless steel electrode, which provides a weld deposit that contains considerable ferrite to prevent hot cracking. Before welding, the crankshaft was preheated to a temperature above which martensite would form. After completion, the weld was covered with an asbestos blanket, and heating was continued for 24 h. During the next 24 h, the temperature was slowly lowered. The result was a crack-free weld.

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曲轴修补焊缝因夹杂物和气孔而失效

某大容量双动冲压机AISI 1080钢曲轴在使用中发生断裂，进行了焊接修复。曲轴恢复使用后不久，修复焊缝断裂。对补焊断口进行超声检查，发现内部有许多反射物，表明存在夹渣和气孔。采用低碳钢焊剂芯填充金属对曲轴进行补焊，焊前和焊后均不加热。这导致在热影响区形成马氏体。修复焊缝发生脆性断裂，其原因是焊缝气孔、大量夹渣和热影响区内脆性马氏体的形成。使用E312不锈钢电极进行了新的修复焊缝，该电极提供了含有大量铁素体的焊缝沉积，以防止热裂。焊接前，将曲轴预热到马氏体形成的温度。焊接完成后，用石棉毯覆盖焊缝，继续加热24小时。在接下来的24小时内，温度慢慢降低。结果是无裂纹焊接。

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: Improper Maintenance, Repair, and Operating Conditions

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