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热模拟2205DSS焊接HAZ的点蚀实验研究 被引量:6

Pitting Corrosion Property of Simulated Welding HAZ in 2205DDS
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摘要 采用热模拟法模拟焊接热过程,研究了2205双相不锈钢(DSS)的模拟焊接粗晶区的耐点蚀性能和金相组织的关系,探讨了冷却时间t8/5对模拟热影响区(HAZ)组织与点蚀性能的影响。结果表明:冷却时间t8/5对组织及点蚀性能有较大的影响,随冷却时间t8/5的增加,铁素体含量减少,奥氏体含量增加,模拟HAZ的点蚀率和点蚀相对面积降低,但仍大于母材,而最大点蚀深度增大,但低于母材。当冷却时间t8/5为100s左右时,模拟HAZ的抗点蚀性能接近母材的抗点蚀性能。 The relationship of the microstructures and pitting corrosion property of simulated welding heat affected zone (HAZ) in 2205 duplex stainless steel was investigated using thermal simulator and pitting corrosion testing. The effects of cooling time on the pitting corrosion property of simulated HAZ were studied at the same time. The results showed that the cooling time had influences on the pitting corrosion property of the simulated HAZ, that the ferrite content decreased and precipitate of carbide and nitride in ferrite increases as increasing cooling time, that pitting corrosion rate and pitting corrosion area ratio were higher in simulated HAZ than in base metal and decreased with the increase of the cooling time, that the maximum pitting corrosion depth was lower in simulated HAZ than that in base metal and increases with the cooling time t8/5, and that the pitting corrosion property of the simulated HAZ was the same as base metal when the cooling time was about 100s.
作者 张建勋 李庆琰 李为卫 张田宏 刘亚旭
机构地区 西安交通大学金属材料强度国家重点实验室 中国石油天然气集团公司石油管力学和环境行为重点实验室 洛阳船舶材料研究所
出处 《材料工程》 EI CAS CSCD 北大核心 2006年第8期28-32,共5页 Journal of Materials Engineering
基金 石油管力学和环境行为重点实验室基金资助项目(ZYT0404)
关键词 2205双相不锈钢 热模拟 点蚀 2205 duplex stainless steel thermal simulation pitting corrosion
分类号 TG401 [金属学及工艺—焊接]
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参考文献4

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  • 1[1]Nelson D E, Baeslack W A III, Lippold J C. An investigation of weld hot cracking in duplex stainless steels [J]. Welding Journal, 1987, 66(8): 241-250.
  • 2[2]Matsuda F, Nakagawa H, Kato I, et al. Solidification crack susceptibility in weld metal of duplex stainless steels [J]. Welding Research Abroad, 1987, 33(6/7): 17-30.
  • 3[3]Baeslack W A, Lippold J C. Phase transformation behavior in duplex stainless steel weldments [J]. Metal Construction, 1988, 20(1): 26R-30R.
  • 4[4]Tamaki K, Yasuda K, Kimura M, et al. Optimizing welding condition for excellent corrosion resistance in duplex stainless steel linepipe [J]. Welding Research Abroad, 1989, 35(5): 2-8.
  • 5[5]Shinozaki K, Ke L, North T H. Hydrogen cracking in duplex stainless steel weld metal [J]. Welding Journal, 1992, 71(11): 387-396.
  • 6[6]Karlsson L, Ryen L, Pak S. Precipitation of intermetallic phases in 22%Cr duplex stainless weld metals [J]. Welding Journal, 1995, 74(1): 28-40.
  • 7[7]Gooch T G. Corrosion behavior of welded stainless steel [J]. Welding Journal, 1996, 75(5): 135-153.
  • 8[8]Damian KI. Welding stainless steel [J]. Advanced Materials & Processes, 1999, 155(5): 41-44.
  • 9[9]Barnhouse E J, Lippold J C. Microstructure/property relationships in dissimilar welds between duplex stainless steels and carbon steels [J]. Welding Journal, 1998, 77(12): 477-487.
  • 10[10]Li L, Messler R W Jr. The effects of phosphorous and sulfur on susceptibility to weld hot cracking in austenitic stainless steels [J]. Welding Journal, 1999, 78(12): 387-396.

共引文献43

同被引文献63

引证文献6

二级引证文献16

材料工程
2006年 第8期

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