Erosion Corrosion Behavior and Mechanism of 35CrMo Steel in Solution Containing Guargum and Sand
摘 要
采用失重法、微观形貌观察法和电化学法研究了35CrMo钢在胍胶溶液、含砂水溶液和含砂胍胶溶液中的冲刷腐蚀行为和机理。结果显示:溶液的侵蚀性由高到低排序为含砂胍胶溶液、含砂水溶液和胍胶溶液;在含砂水中加入胍胶可明显抑制冲刷腐蚀;相比于胍胶溶液,35CrMo钢在含砂胍胶溶液中腐蚀电流密度的增大说明砂粒的存在能显著提高由力学作用引起的腐蚀增量。
Abstract
The erosion corrosion behavior and mechanism of 35CrMo steel in guanidine gum solution, sand water solution and sand guanidine gum solution were investigated by weight-loss method, microstructure observation, and the electrochemical method. The results showed that the descending order of solution erodibility was as following:sand guanidine gum solution, sand water solution and guanidine gum solution. Guanidine gum added into the sand water solution could reduce erosion corrosion. The corrosion current density of 35CrMo steel was higher in the sand guanidine gum solution than in the guanidine gum solution, indicating that the presence of sand can significantly raise the corrosion increment caused by mechanical action.
中图分类号 TG172 DOI 10.11973/fsyfh-202305003
所属栏目 试验研究
基金项目 国家自然科学基金面上项目(51971229);中国科学院核用材料与安全评价重点实验室开放课题项目(2019NMSAKF02)
收稿日期 2021/12/14
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引用该论文: FU Dengwei,ZHENG Kexin,LI Bolun,REN Qiannan,QIU Fushou,HU Hongxiang,ZHENG Yugui. Erosion Corrosion Behavior and Mechanism of 35CrMo Steel in Solution Containing Guargum and Sand[J]. Corrosion & Protection, 2023, 44(5): 13
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参考文献
【1】李雪松. 中国油气井压裂井口保护器技术现状[J]. 非常规油气, 2016, 3(6):113-117.
【2】陈红. 一种新型酸压井口保护器[J]. 油气井测试, 2004, 13(5):95-96, 110.
【3】王尊策, 张书进, 庞鑫峰, 等. 压裂管柱内突扩两相湍流数值模拟[J]. 科学技术与工程, 2009, 9(22):6776-6778, 6789.
【4】王尊策, 张书进, 庞鑫峰, 等. 压裂管柱内突扩两相湍流数值模拟[J]. 科学技术与工程, 2009, 9(22):6776-6778, 6789.
【5】张书进. 压裂管柱内固液两相流动特性及磨损机理研究[D]. 大庆:大庆石油学院, 2010.
【6】ZHANG L M, MA A L, HU H X, et al. Effect of microalloying with Ti or Cr on the corrosion behavior of Al-Ni-Y amorphous alloys[J]. Corrosion, 2018, 74(1):66-74.
【7】E M, HU H X, GUO X M, et al. Comparison of the cavitation erosion and slurry erosion behavior of cobalt-based and nickel-based coatings[J]. Wear, 2019, 428/429:246-257.
【8】LIU M M, HU H X, ZHENG Y G. Effects of three sealing methods of aluminum phosphate sealant on corrosion resistance of the Fe-based amorphous coating[J]. Surface and Coatings Technology, 2017, 309:579-589.
【9】HU H X, ZHENG Y G. The effect of sand particle concentrations on the vibratory cavitation erosion[J]. Wear, 2017, 384/385:95-105.
【10】张福祥, 巴旦, 刘洪涛, 等. 压裂过程超级13Cr油管冲刷腐蚀交互作用研究[J]. 石油机械, 2014, 42(8):89-93.
【11】ZHANG J X, KANG J A, FAN J C, et al. Study on erosion wear of fracturing pipeline under the action of multiphase flow in oil & gas industry[J]. Journal of Natural Gas Science and Engineering, 2016, 32:334-346.
【12】DESALE G R, GANDHI B K, JAIN S C. Particle size effects on the slurry erosion of aluminium alloy (AA 6063)[J]. Wear, 2009, 266(11/12):1066-1071.
【13】HU H X, WANG Z B, CHEN J A. The effects of sand particles on the synergy of cavitation erosion-corrosion of MIG welding stainless steel coating in saline water[J]. Scanning, 2020, 2020:1-10.
【14】郑玉贵, 姚治铭, 李生春, 等. 泥浆型冲蚀中冲刷和腐蚀的交互作用[J]. 中国腐蚀与防护学报, 1993, 13(4):390-395.
【15】李强. 管线钢油/水/砂多相流冲刷局部腐蚀研究[D].青岛:中国石油大学(华东), 2013.
【16】张安峰, 王豫跃, 邢建东, 等. 两种涂层和两种钢在液/固两相流中冲刷与腐蚀的交互作用[J]. 金属学报, 2004, 40(4):411-415.
【17】GUO H X, LU B T, LUO J L. Interaction of mechanical and electrochemical factors in erosion-corrosion of carbon steel[J]. Electrochimica Acta, 2005, 51(2):315-323.
【18】GUO H X, LU B T, LUO J L. Study on passivation and erosion-enhanced corrosion resistance by Mott-Schottky analysis[J]. Electrochimica Acta, 2006, 52(3):1108-1116.
【19】LU B T, LUO J L, GUO H X, et al. Erosion-enhanced corrosion of carbon steel at passive state[J]. Corrosion Science, 2011, 53(1):432-440.
【20】NEVILLE A, HU X. Mechanical and electrochemical interactions during liquid-solid impingement on high-alloy stainless steels[J]. Wear, 2001, 251:1284-1294.
【21】王军军, 李志均, 黄伟九. 沙粒粒径和外电位对黄铜腐蚀磨损的影响[J]. 摩擦学学报, 2016, 36(4):406-412.
【22】HUMPHREY J A C. Fundamentals of fluid motion in erosion by solid particle impact[J]. International Journal of Heat and Fluid Flow, 1990, 11(3):170-195.
【23】CLARK H M. On the impact rate and impact energy of particles in a slurry pot erosion tester[J]. Wear, 1991, 147(1):165-183.
【24】KESANA N R, THRONEBERRY J M, MCLAURY B S, et al. Effect of particle size and liquid viscosity on erosion in annular and slug flow[J]. Journal of Energy Resources Technology, 2014, 136(1):012901.
【25】CHEN Z X, HU H X, ZHENG Y G, et al. Effect of groove microstructure on slurry erosion in the liquid-solid two-phase flow[J]. Wear, 2021, 466/467:203561.
【26】计时鸣, 马宝丽, 谭大鹏. 结构化表面环境下软磨粒流的流场数值分析[J]. 光学精密工程, 2011, 19(9):2092-2099.
【27】KESANA N R, GRUBB S A, MCLAURY B S, et al. Ultrasonic measurement of multiphase flow erosion patterns in a standard elbow[J]. Journal of Energy Resources Technology, 2013, 135(3):032905.
【2】陈红. 一种新型酸压井口保护器[J]. 油气井测试, 2004, 13(5):95-96, 110.
【3】王尊策, 张书进, 庞鑫峰, 等. 压裂管柱内突扩两相湍流数值模拟[J]. 科学技术与工程, 2009, 9(22):6776-6778, 6789.
【4】王尊策, 张书进, 庞鑫峰, 等. 压裂管柱内突扩两相湍流数值模拟[J]. 科学技术与工程, 2009, 9(22):6776-6778, 6789.
【5】张书进. 压裂管柱内固液两相流动特性及磨损机理研究[D]. 大庆:大庆石油学院, 2010.
【6】ZHANG L M, MA A L, HU H X, et al. Effect of microalloying with Ti or Cr on the corrosion behavior of Al-Ni-Y amorphous alloys[J]. Corrosion, 2018, 74(1):66-74.
【7】E M, HU H X, GUO X M, et al. Comparison of the cavitation erosion and slurry erosion behavior of cobalt-based and nickel-based coatings[J]. Wear, 2019, 428/429:246-257.
【8】LIU M M, HU H X, ZHENG Y G. Effects of three sealing methods of aluminum phosphate sealant on corrosion resistance of the Fe-based amorphous coating[J]. Surface and Coatings Technology, 2017, 309:579-589.
【9】HU H X, ZHENG Y G. The effect of sand particle concentrations on the vibratory cavitation erosion[J]. Wear, 2017, 384/385:95-105.
【10】张福祥, 巴旦, 刘洪涛, 等. 压裂过程超级13Cr油管冲刷腐蚀交互作用研究[J]. 石油机械, 2014, 42(8):89-93.
【11】ZHANG J X, KANG J A, FAN J C, et al. Study on erosion wear of fracturing pipeline under the action of multiphase flow in oil & gas industry[J]. Journal of Natural Gas Science and Engineering, 2016, 32:334-346.
【12】DESALE G R, GANDHI B K, JAIN S C. Particle size effects on the slurry erosion of aluminium alloy (AA 6063)[J]. Wear, 2009, 266(11/12):1066-1071.
【13】HU H X, WANG Z B, CHEN J A. The effects of sand particles on the synergy of cavitation erosion-corrosion of MIG welding stainless steel coating in saline water[J]. Scanning, 2020, 2020:1-10.
【14】郑玉贵, 姚治铭, 李生春, 等. 泥浆型冲蚀中冲刷和腐蚀的交互作用[J]. 中国腐蚀与防护学报, 1993, 13(4):390-395.
【15】李强. 管线钢油/水/砂多相流冲刷局部腐蚀研究[D].青岛:中国石油大学(华东), 2013.
【16】张安峰, 王豫跃, 邢建东, 等. 两种涂层和两种钢在液/固两相流中冲刷与腐蚀的交互作用[J]. 金属学报, 2004, 40(4):411-415.
【17】GUO H X, LU B T, LUO J L. Interaction of mechanical and electrochemical factors in erosion-corrosion of carbon steel[J]. Electrochimica Acta, 2005, 51(2):315-323.
【18】GUO H X, LU B T, LUO J L. Study on passivation and erosion-enhanced corrosion resistance by Mott-Schottky analysis[J]. Electrochimica Acta, 2006, 52(3):1108-1116.
【19】LU B T, LUO J L, GUO H X, et al. Erosion-enhanced corrosion of carbon steel at passive state[J]. Corrosion Science, 2011, 53(1):432-440.
【20】NEVILLE A, HU X. Mechanical and electrochemical interactions during liquid-solid impingement on high-alloy stainless steels[J]. Wear, 2001, 251:1284-1294.
【21】王军军, 李志均, 黄伟九. 沙粒粒径和外电位对黄铜腐蚀磨损的影响[J]. 摩擦学学报, 2016, 36(4):406-412.
【22】HUMPHREY J A C. Fundamentals of fluid motion in erosion by solid particle impact[J]. International Journal of Heat and Fluid Flow, 1990, 11(3):170-195.
【23】CLARK H M. On the impact rate and impact energy of particles in a slurry pot erosion tester[J]. Wear, 1991, 147(1):165-183.
【24】KESANA N R, THRONEBERRY J M, MCLAURY B S, et al. Effect of particle size and liquid viscosity on erosion in annular and slug flow[J]. Journal of Energy Resources Technology, 2014, 136(1):012901.
【25】CHEN Z X, HU H X, ZHENG Y G, et al. Effect of groove microstructure on slurry erosion in the liquid-solid two-phase flow[J]. Wear, 2021, 466/467:203561.
【26】计时鸣, 马宝丽, 谭大鹏. 结构化表面环境下软磨粒流的流场数值分析[J]. 光学精密工程, 2011, 19(9):2092-2099.
【27】KESANA N R, GRUBB S A, MCLAURY B S, et al. Ultrasonic measurement of multiphase flow erosion patterns in a standard elbow[J]. Journal of Energy Resources Technology, 2013, 135(3):032905.
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