煤制合成天然气管道材料适用性评价方法
Applicability Evaluation Method of Coal Synthetic Natural Gas Pipeline Material
摘 要
通过对现有输氢管道及储氢容器的标准进行梳理,结合相关文献资料,对煤制气管道在含氢环境中的适用性评价方法进行总结。从管道的强度,塑性,断裂韧性,疲劳等几个方面提出氢脆敏感性的评价方法和判断依据,为含氢煤制合成天然气管道材料的服役适用性评价和安全运行提供了技术支持。
管线钢
氢脆
适用性评价
coal gas
pipeline steel
hydrogen embrittlement
applicability evaluation
Abstract
Through combing the existing standards of hydrogen pipelines and hydrogen storage vessels, combined with relevant literature, the applicability evaluation methods of coal gas pipelines in hydrogen-containing environment are summarized. From the aspects of strength, plasticity, fracture toughness and fatigue of pipelines, the evaluation methods and judgment basis of hydrogen embrittlement sensitivity are proposed, which provides technical support for the evaluation of serviceability and safe operation of hydrogen-containing coal-made synthetic natural gas pipeline materials.
中图分类号 TG172.4 DOI 10.11973/fsyfh-201901010
所属栏目 应用技术
基金项目
收稿日期 2017/8/7
修改稿日期
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引用该论文: SHI Hao,XING Yunying,WANG Xiuyun,WNAG Jing. Applicability Evaluation Method of Coal Synthetic Natural Gas Pipeline Material[J]. Corrosion & Protection, 2019, 40(1): 48
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参考文献
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【2】NANNINGA N E,LEVY Y S,DREXLER E S,et al. Comparison of hydrogen embrittlement in three pipeline steels in high pressure gaseous hydrogen environments[J]. Corrosion Science,2012,59:1.
【3】褚武扬,乔立杰,李金许,等. 氢脆和应力腐蚀[M]. 北京:科学出版社,2013.
【4】张体明,王勇,赵卫民,等. 高压煤制气环境下X80及热影响区的氢渗透参数研究[J]. 金属学报,2015,51(9):1101-1110.
【5】张体明,王勇,赵卫民,等. 模拟煤制气环境下X80管线钢及HAZ的氢脆敏感性[J]. 焊接学报,2015,36(9):43-46.
【6】MENG B,GU C H,ZHANG L,et al. Hydrogen effects on X80 pipeline steel in high-pressure natural gas/hydrogen mixtures[J]. International Journal of Hydrogen energy,2016(5):1-6.
【7】关鸿鹏,林振娴,李瑜仙,等. X70管线钢及焊缝在模拟煤制气含氢环境下的氢脆敏感性[J]. 北京科技大学学报,2017,39(4):535-541.
【8】褚武扬. 氢损伤与滞后断裂[M]. 北京:冶金工业出版社,1988.
【9】CHATZIDOUROS E V,PAPAZOGLOU V J,TSIOURVA T E,et al. Hydrogen effect on fracture toughness of pipeline steel welds,with in situ hydrogen charging[J]. International Journal of Hydrogen Energy,2011,36(19):12626-12627.
【10】MARCHI C S,SOMERDAY B P,NIBUR K A,et al. Fracture and fatigue of commercial grade API pipeline steels in gaseous hydrogen[C]//Proceedings of the ASME 2010 Pressure Vessels & Piping Division/K-PVP Conference. Bellevue:[s.n.],2010:18.
【11】DOUGLAS S,TODD B,DARREN B,et al. Continued microstructure and mechanical property performance evaluation of commercial grade API pipeline steels in high pressure gaseous hydrogen[C]//Proceedings of the 20129th International Pipeline Conference.[S.l]:[s.n.],2012.
【12】BRIOTTET L,BATISSE R,DINECHIN G D,et al. Recommendations on X80 steel for the design of hydrogen gas transmission pipelines[J]. Int J Hydrogen Energy,2012,37(11):9423-9430.
【13】BRIOTTET L,MORO I,LEMOINE P. Quantifying the hydrogen embrittlement of pipeline steels for safety considerations[J]. Int J Hydrogen Energy,2012,37(22):17616-17623.
【14】YOSHIOKA A,KUMASAWA M,DEMIZU M,et al. Fatigue crack growth behavior in hydrogen gas environment[C]//Fatigue 87. Charlottesville:[s.n.],1987:697-706.
【15】CLARK W G. The effect of hydrogen gas on the fatigue crack growth rate behavior of HY-80 and HY-130 steels[C]//Hydrogen in Metals:Proc International Conf on the Effects of Hydrogen on Materials Properties and Selection and Structural Design Champion.[S.l.]:[s.n.],1974:149-164.
【16】DREXLER E S,SLIFRA A J,AMARO R L,et al. Fatigue crack growth rates of API X70 pipeline steel in a pressurized hydrogen gas environment[J]. Fatigile & Fracture of Engineering Materials & Stuctures,2014(5):517-525.
【17】周惠久,黄明志. 金属材料强度学[M]. 北京:科学出版社,1989.
【18】BRIOTTET L,BATISSE R,DINECHIN G de. Recommendations on X80 steel for the design of hydrogen gas transmission pipelines[J]. International Journal of Hydrogen Energy,2012,37(11):9423-9430.
【19】惠卫军,董瀚,翁宇庆. 高强度钢耐延迟断裂性能的评价方法[J]. 理化检验-物理分册,2001,37(6):231-235.
【20】LAM P S,SINDELAR R L. Literature survey of gaseous hydrogen effects on mechanical properties of carbon and low alloy steels[J]. Materials of Fabication,2007(10):26730-26736.
【21】DUNCAN A,LAM P S,ADAMS T. Recommendations on X80 steel for the design of hydrogen gas transmission pipelines[C]//Proceedings of the 2007 ASME Pressure Vessels and Piping/CREEP8 Conference.[S.l.]:[s.n.],2007:6.
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