Failure Analysis of Duplex Stainless Steel in an Atmospheric Tower

Volume 5: High-Pressure Technology; ASME Nondestructive Evaluation, Diagnosis and Prognosis Division (NDPD); Rudy Scavuzzo Student Paper Symposium and 26th Annual Student Paper Competition Pub Date : 2018-07-15 DOI:10.1115/PVP2018-84348

Chengsi Zheng, Gang Wang, Xiang Wu, Z. Ai

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引用次数: 1

Abstract

An atmospheric tower head, manufactured using a clad plate of carbon steel + 2205 duplex stainless steel (DSS), was reported to show clear cracks in the DSS layer after serving for four years at an atmospheric distillation unit of a refinery. The cracks propagated in a dendritic manner within the heat-affected zone (HAZ) and the weld metal, accompanying locations with a higher hardness than that of locations without cracks. Some nondestructive methods were used to analyze the chemical composition, microstructure, hardness of the base metal, HAZ and weld metal. An analysis based on these results and the statistical data of an HCl-H2S-H2O corrosion environment was proposed to explain the formation of cracks from the viewpoint of physical metallurgy. The analysis showed that there were conditions favorable for the precipitation of the sigma (σ) phase in the DSS layer during the manufacturing process of the head, resulting in the occurrence of stress corrosion cracking (SCC) in the DSS layer under the harsh HCl-H2S-H2O environment. Moreover, some solutions, i.e., the enhancement of anticorrosion measures, the optimized microstructure of the DSS, and modified welding parameters were recommended to avoid a similar failure.

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常压塔双相不锈钢失效分析

常压塔头采用碳钢+ 2205双相不锈钢(DSS)复合板制造，在炼油厂常压蒸馏装置使用四年后，DSS层出现明显裂纹。裂纹在热影响区(HAZ)和焊缝金属内以枝晶方式扩展，伴随出现硬度高于无裂纹位置的裂纹。采用无损分析方法对母材、热影响区和焊缝金属的化学成分、显微组织、硬度进行了分析。根据这些结果和HCl-H2S-H2O腐蚀环境的统计数据，从物理冶金的角度解释了裂纹的形成。分析表明，在恶劣的HCl-H2S-H2O环境下，封头制造过程中存在有利于DSS层中σ相析出的条件，导致DSS层出现应力腐蚀开裂(SCC)。提出了加强防腐蚀措施、优化DSS组织、修改焊接参数等解决方案，避免了类似失效的发生。

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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Volume 5: High-Pressure Technology; ASME Nondestructive Evaluation, Diagnosis and Prognosis Division (NDPD); Rudy Scavuzzo Student Paper Symposium and 26th Annual Student Paper Competition

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