Longitudinal Seam Welded Piping Assessment in Refinery Reformer Units

Volume 6B: Materials and Fabrication Pub Date : 2019-11-15 DOI:10.1115/pvp2019-93706

M. Dalal, J. Penso, David J. Dewees, Robert G. Brown

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Abstract

Creep is progressive deformation of material over an extended period when exposed to elevated temperature and stresses below the yield strength. Poor Creep ductility and cracking can be a problem above 900 °F (482°C) in the HAZ of low alloy (Cr-Mo) steel. High stress areas, including supports, hangers and fittings are more vulnerable to cracking. Creep cracking has occurred in longitudinal pipe welds with excessive peaking or welds with poor quality. Numerous incidents of cracking in low alloy (Cr-Mo) steel have been reported in the power industry and in refineries with major concern in longitudinal seam welds as well as highly stressed welds in reactors-heaters interconnecting piping. This paper presents the results of an assessment performed on reactors-heaters interconnecting piping in a catalytic reformer unit with a maximum operating temperature of about 950 °F (510 °C) at 250 psig (1.7 MPa) (> 40 years in-service). Comprehensive inspection including visual, dye penetrant testing, thickness measurements and peaking measurements have been performed. Phased Array Ultrasonic Testing (PAUT) was utilized to detect crack-like defects and flaws. Detailed pipe stress analysis and finite element analyses (FEA) were also performed.

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炼油厂重整装置纵缝焊接管道评价

蠕变是材料暴露在高温和低于屈服强度的应力下一段较长时间内的渐进变形。低合金(Cr-Mo)钢的热影响区在900°F(482°C)以上时，蠕变延展性差和开裂可能是一个问题。高应力区域，包括支架、吊架和配件更容易开裂。纵向管焊缝出现蠕变开裂，焊缝尖峰过高或焊缝质量较差。据报道，在电力工业和炼油厂中，低合金(Cr-Mo)钢发生了许多开裂事故，主要是纵向焊缝以及反应堆-加热器互连管道中的高应力焊缝。本文介绍了催化重整装置中反应器-加热器互连管道的评估结果，该装置在250 psig (1.7 MPa)下的最高工作温度约为950°F(510°C)(> 40年)。全面的检查包括目测、染料渗透测试、厚度测量和峰值测量。采用相控阵超声检测技术检测类裂纹缺陷和缺陷。对管道进行了详细的应力分析和有限元分析。

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 6B: Materials and Fabrication

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