TP347H锅炉钢管失效机理研究进展
Research Progress on Failure Mechanisms of TP347H Boiler Steel Tube
摘 要
TP347H奥氏体耐热钢广泛应用于火电机组锅炉受热面管。结合奥氏体耐热钢管服役性能和TP347H钢管爆管失效案例,综述了TP347H钢制受热面管在锅炉服役运行中常见的6种失效机理,包括晶间腐蚀、应力腐蚀开裂、组织老化、氧化腐蚀、原始缺陷和马氏体转变,并介绍了失效特征、分析方法和预防措施。
奥氏体耐热钢
TP347H钢
失效分析
失效机理
thermal power unit
austenitic heat-resistant steel
TP347H steel
failure analysis
failure mechanism
Abstract
The austenitic heat-resistant steel TP347H is widely used in heating tubes of thermal power unit boilers. Combining the service performance of austenitic heat-resistant steel tubes and the failure cases of TP347H steel tube bursts, the six common failure mechanisms, including intergranular corrosion, stress corrosion cracking, microstructure aging, oxidative corrosion, original defects and martensite transformation, of TP347H steel heating tubes during boiler operation are reviewed. The failure characteristics, analysis methods and preventive measures are described.
中图分类号 TG142.25 DOI 10.11973/jxgccl202102002
所属栏目 综述
基金项目
收稿日期 2020/3/19
修改稿日期 2020/11/17
网络出版日期
作者单位点击查看
备注张骏(1990-),男,陕西汉中人,工程师,硕士
引用该论文: ZHANG Jun,ZHENG Zhunbei,YANG Zhanjun,SUN Xingxin,LI Mengyang,ZHANG Jianwei. Research Progress on Failure Mechanisms of TP347H Boiler Steel Tube[J]. Materials for mechancial engineering, 2021, 45(2): 7~14
张骏,郑准备,杨占君,孙兴新,李梦阳,张建伟. TP347H锅炉钢管失效机理研究进展[J]. 机械工程材料, 2021, 45(2): 7~14
共有人对该论文发表了看法,其中:
人认为该论文很差
人认为该论文较差
人认为该论文一般
人认为该论文较好
人认为该论文很好
参考文献
【1】迟成宇,于鸿垚,谢锡善.600℃超超临界电站锅炉过热器及再热器管道用先进奥氏体耐热钢的研究与发展[J].世界钢铁,2012,12(4):50-65. CHI C Y, YU H Y, XIE X S. Research and development of austenitic heat-resistant steels for 600℃ superheat/reheater tubes of USC power plant boilers[J]. World Iron & Steel, 2012, 12(4):50-65.
【2】杨宏辉.TP304H,TP347H钢的材料特性与金属监督[J].湖南电力,2000,20(6):51-52. YANG H H. Material properties and metal supervision of TP304H, TP347H steel[J].Hunan Electric Power,2000,20(6):51-52.
【3】王伟,王志武,李文胜,等.不同Cr、Ni含量下TP347H钢的热力学平衡相[J].金属热处理,2016,41(10):99-101. WANG W, WANG Z W, LI W S, et al. Thermodynamic equilibrium phases of TP347H steel with different Cr and Ni content[J]. Heat Treatment of Metals,2016,41(10):99-101.
【4】VISWANATHAN R, BAKKER W. Materials for ultrasupercritical coal power plants-Boiler materials:Part 1[J].Journal of Materials Engineering and Performance,2001,10(1):81-95.
【5】CHEN G H,SONG Y M,WANG J Q,et al.High-temperature short-term tensile test and creep rupture strength prediction of the T92/TP347H dissimilar steel weld joints[J].Engineering Failure Analysis,2012,26:220-229.
【6】彭孙鸿.固溶热处理对1Cr19Ni11Nb钢持久强度的影响[J].特殊钢,1995,16(2):10-12. PENG S H. Effect of solution heat treatment on creep rupture strength of steel 1Cr19Ni11Nb[J]. Special Steel, 1995,16(2):10-12.
【7】魏宝明.金属腐蚀理论及应用[M].北京:化学工业出版社,1984. WEI B M. Theory and application of metal corrosion[M].Beijing:Chemical Industry Press, 1984.
【8】罗宏,龚敏.奥氏体不锈钢的晶间腐蚀[J].腐蚀科学与防护技术,2006,18(5):357-360. LUO H, GONG M. On intergranular corrosion of austenitic stainless steel[J]. Corrosion Science and Protection Technology, 2006, 18(5):357-360.
【9】KASPAROVA O V.Peculiarities of intergranular corrosion of silicon-containing austenitic stainless steels[J].Protection of Metals,2004,40(5):425-431.
【10】HWANG E R, KANG S G. Intergranular corrosion of stainless steels in molten carbonate salt[J]. Journal of Materials Science Letters, 1997, 16(16):1387-1388.
【11】孙旭,宁玉恒,刘群.末级再热器用TP347H不锈钢管爆管原因分析[J].热加工工艺,2017,46(8):250-252. SUN X, NING Y H, LIU Q. Causes analysis of explosion of TP347H stainless steel tube for final reheater[J]. Hot Working Technology,2017,46(8):250-252.
【12】李戈,陈鹏磊,张林.600 MW超临界机组TP347H奥氏体不锈钢高温再热器管爆管失效分析[J].发电与空调,2016,37(2):1-8. LI G, CHEN P L, ZHANG L. Failure analysis of TP347H austenitic stainless steel tube of the 600 MW high temperature reheater[J]. Power Generation & Air Condition,2016,37(2):1-8.
【13】赵勇.TP347H奥氏体不锈钢高温过热器爆管原因分析[J].吉林电力,2012,40(1):50-51. ZHAO Y. Analysis on tube-bursting of TP347H austenitic stainless steel high-temperature super-heater[J]. Jilin Electric Power,2012,40(1):50-51.
【14】李振梁,王甲安,肖旻砚.高温再热器SA-213TP347H钢管爆管原因分析[J].金属热处理,2015,40(8):191-194. LI Z L, WANG J A, XIAO M Y. Failure analysis of SA-213TP347H steel reheater tube[J]. Heat Treatment of Metals,2015,40(8):191-194.
【15】崔雄华,郑坊平,张磊,等.供货热处理状态对奥氏体不锈钢锅炉管安全运行性能的影响[J].热力发电,2010,39(3):49-52. CUI X H, ZHENG F P, ZHANG L, et al. Influence of heat treatment status for the furnished austenite stainless steel boiler tubes upon their safe operation performance[J]. Thermal Power Generation, 2010, 39(3):49-52.
【16】马官兵,李晓红,谢阿萌.锅炉高温受热面TP347H管短期开裂分析[J].武汉大学学报(工学版),2007,40(3):80-84. MA G B, LI X H, XIE A M. Short-time cracking analysis of TP347H tubes of high temperature heat delivery surfaces of boilers[J]. Engineering Journal of Wuhan University, 2007, 40(3):80-84.
【17】王甲安,李剑平,李建,等.600 MW超临界机组SA-213TP347H高温再热器频繁爆管原因探究[J].材料热处理学报,2015,36(增刊1):122-127. WANG J A, LI J P, LI J, et al. Failure analysis of tube-burst of SA-213TP347H high-temperature reheater of 600 MW supercritical unit[J]. Transactions of Materials and Heat Treatment,2015,36(S1):122-127.
【18】魏泉泉,牛玉静.某电厂高温再热器出口TP347H材质管段泄漏原因分析[J].华电技术,2017,39(5):52-54. WEI Q Q, NIU Y J. A power plant's high temperature reheater outlet TP347H material pipeline leakage cause analysis[J]. Huadian Technology, 2017, 39(5):52-54.
【19】张述林,李敏娇,王晓波,等.18-8奥氏体不锈钢的晶间腐蚀[J].中国腐蚀与防护学报,2007,27(2):124-128. ZHANG S L, LI M J, WANG X B, et al. Intergranular corrosion of 18-8 austenitic stainless steel[J]. Journal of Chinese Society for Corrosion and Protection,2007,27(2):124-128.
【20】杨百勋,李益民,曹剑峰.火电机组设备质量缺陷及控制[M].北京:中国电力出版社,2019. YANG B X, LI Y M, CAO J F. Quality defect and control of thermal power unit equipment[M]. Beijing:China Electric Power Press, 2019.
【21】褚武扬,乔利杰,李金许.氢脆和应力腐蚀-典型体系[M].北京:科学出版社,2013. CHU W Y, QIAO L J, LI J X. Hydrogen embrittlement and stress corrosion cracking[M].Beijing:Science Press,2013.
【22】李晓刚.材料腐蚀与防护[M].长沙:中南大学出版社,2009. LI X G. Corrosion and protection of materials[M].Changsha:Central South University Press,2009.
【23】陈国星,周龙,赵可昕,等.TP347H不锈钢管表面裂纹的产生原因[J].机械工程材料,2010,34(3):80-83. CHEN G X, ZHOU L, ZHAO K X, et al. Analysis of surface cracks on TP347H stainless steel tube[J]. Materials for Mechanical Engineering,2010,34(3):80-83.
【24】吴立新,曾静,姚中海,等.TP347H过热器管爆管原因分析[J].武钢技术,2007,45(2):1-4. WU L X, ZENG J, YAO Z H, et al. Analysis on crack of TP347H superheated steam tube[J]. Wuhan Iron and Steel Corporation Technology,2007,45(2):1-4.
【25】张捷,杨行炳,林翔,等.高温再热器SA-213TP347H钢管裂纹原因分析[J].失效分析与预防,2018,13(4):214-217. ZHANG J, YANG H B, LIN X, et al. Crack analysis of SA213TP347H steel pipe in high temperature reheater[J]. Failure Analysis and Prevention,2018,13(4):214-217.
【26】杨首恩,刘盛波. 锅炉高温过热器不锈钢管开裂分析[C]//2009年全国失效分析学术会议论文集.上海:中国机械工程学会理化检验分会,中国机械工程学会失效分析分会,2009. YANG S E, LIU S B. Cracking analysis of stainless steel tube used for boiler super-heater[C]//Proceedings of the 2009 National Failure Analysis Conference. Shanghai:Physical Testing and Chemical Analysis Institution of CMES, Chinese Failure Analysis Institution of CMES, 2009.
【27】王海琦,车鹏程,刘焱.某电站锅炉后屏过TP347H爆管问题分析[J].锅炉制造,2019(4):19-24. WANG H Q, CHE P C, LIU Y. Failure analysis of rear superheater TP347H tube of a certain power plant[J]. Boiler Manufacturing, 2019(4):19-24.
【28】胡建军,张永芳.浅谈氯离子对奥氏体不锈钢的腐蚀[J].化工装备技术,2017,38(6):35-37. HU J J, ZHANG Y F. Corrosion of austenitic stainless steel by chloride ion[J].Chemical Equipment Technology,2017,38(6):35-37.
【29】于成,毕文军.奥氏体不锈钢应力腐蚀与防护[J].化工设计通讯,2018,44(2):50-50. YU C, BI W J. Austenitic stainless steel stress corrosion and protection[J]. Chemical Engineering Design Communications,2018,44(2):50-50.
【30】吴奭登,何卫忠.某电厂再热器泄漏原因分析[J].腐蚀科学与防护技术,2010,22(5):458-460. WU S D, HE W Z. Leakage analysis of reheater tube of power plant[J].Corrosion Science and Protection Technology, 2010, 22(5):458-460.
【31】刘杰,赵永峰,刘翔,等.600 MW超临界锅炉TP347H高温过热器管爆管的显微分析[J].热加工工艺,2020,49(2):159-162. LIU J, ZHAO Y F, LIU X, et al. Microscopic analysis on tube explosion of TP347H high temperature superheater pipe for 600 MW supercritical boiler[J]. Hot Working Technology, 2020, 49(2):159-162.
【32】高荣,张少军.TP347H不锈钢高温过热器爆管原因分析[J].内蒙古电力技术,2013,31(1):116-118. GAO R, ZHANG S J. Tube burst analysis of TP347H stainless steel high temperature superheater[J].Inner Mongolia Electric Power,2013,31(1):116-118.
【33】任文,叶建锋,李鹏刚.超临界机组TP347H末级过热器爆管分析[J/OL].[2020-11-28].http://kns.cnki.net/kcms/detail/33.1405.TH.20190911.0927.004.html. REN W, YE J F, LI P G. Failure analysis on the bursting TP347H final super-heater in a super-critical power plant[J/OL].[2020-11-28]. http://kns.cnki.net/kcms/detail/33.1405.TH.20190911.0927.004.html.
【34】田泽,叶建锋,熊宇.某电厂超临界机组TP347H高温过热器管爆管原因分析[J].湖北电力,2018,42(2):36-40. TIAN Z, YE J F, XIONG Y. Analysis on causes of tube burst of TP347H superheater in supercritical unit of a certain power plant[J]. Hubei Electric Power, 2018, 42(2):36-40.
【35】杜保华,王大鹏,董雷,等.超超临界1000 MW机组锅炉高温受热面炉内壁温测量及分析[J].热力发电,2013,42(7):118-122. DU B H, WANG D P, DONG L, et al. Measurement and analysis of tube wall temperature for heating surface of an ultra-supercritical 1000 MW unit boiler[J]. Thermal Power Generation,2013,42(7):118-122.
【36】周江,俞明芳,杨卓军.超超临界1000 MW机组锅炉高温受热面壁温变化规律分析[J].热力发电,2013,42(2):117-120. ZHOU J, YU M F, YANG Z J. Wall temperature variation of high temperature heating surface in boiler of an ultra supercritical 1000 MW unit[J]. Thermal Power Generation,2013,42(2):117-120.
【37】黄兴德,周新雅,游喆, 等. 超(超)临界锅炉高温受热面蒸汽氧化皮的生长与剥落特性[J].动力工程,2009, 29(6):602-608. HUANG X D, ZHOU X Y, YOU Z, et al. Oxide scale growth and exfoliation behavior on high temperature heat-absorbing surface exposed to steam for supercritical (ultrasupercritical) boilers[J]. Journal of Power Engineering, 2009, 29(6):602-608.
【38】OTSUKA N,SHIDA Y,FUJIKAWA H.Internal-external transition for the oxidation of Fe-Cr-Ni austenitic stainless steels in steam[J].Oxidation of Metals,1989,32(1/2):13-45.
【39】CARL W.Theoretical analysis of the diffusion processes determining the oxidation rate of alloys[J].Journal of the Electrochemical Society,1952,99(10):369-369.
【40】DOOLEY R B,WRIGHT I G, TORTORELLI P F. Program on technology innovation:Oxide growth and exfoliation on alloys exposed to steam[R]. Palo Alto:EPRI, 2007.
【41】邓勇,刘盛波,彭芳芳,等.600 MW超临界锅炉TP347H屏式过热器管高温蒸气氧化腐蚀探讨[J].腐蚀与防护,2009,30(2):124-127. DENG Y, LIU S B, PENG F F, et al. High temperature steam oxidization resistance of TP347H panel division super-heater tubes for 600 MW super-critical boiler[J].Corrosion & Protection,2009,30(2):124-127.
【42】张山山.TP347H钢高温过热器内壁氧化皮失效分析[J].发电与空调,2017,38(3):18-22. ZHANG S S. Failure analysis of TP347H high temperature superheater tube's oxide layer[J]. Power Generation & Air Condition,2017,38(3):18-22.
【43】HUGHES A, DOOLEY B, PATERSON S. Oxide exfoliation of 347HFG in high temperature boilers[C]//7th International Conference and Exhibition on Operating Pressure Equipment. Palo Alto:OPE, 2003:2-4.
【44】WRIGHT J I, PATERSON S, DOOLEY R. Oxidation and exfoliation[C]//EPRI Conference on Advances in Materials Technology for Fossil Power Plants. Palo Alto:EPRI, 2004:370.
【45】蔡建.TP347H不锈钢管屏制造工艺浅析[J].工业锅炉,2017(3):54-56. CAI J. Discussion about manufacture process of the TP347H pipe panel[J]. Industrial Boiler,2017(3):54-56.
【46】张晓昱,欧阳杰,郭立峰,等.18-8型奥氏体钢锅炉管高温运行后失效原因分析[J].热力发电,2007,36(9):92-94. ZHANG X Y, OUYANG J, GUO L F, et al. Causes leading to failure of boiler tubes made from 18-8 type austenitic steel after operation under high temperature[J]. Thermal Power Generation,2007,36(9):92-94.
【47】李长毅.电站锅炉用TP347H不锈钢无缝钢管的开发[J].冶金标准化与质量,2006,44(5):42-45. LI C Y. The development of TP347H stainless steel seamless pipe for utility boiler[J]. Metallurgical Standardization & Quality,2006,44(5):42-45.
【48】方旭东,徐鸿麟.电站锅炉用TP347H不锈钢无缝管工艺的开发[J].特殊钢,2007,28(2):49-50. FANG X D, XU H L. Development of process for precipitation-hardening stainless steel TP347H seamless tube for power station boiler[J].Special Steel,2007,28(2):49-50.
【49】郭玲.连铸TP347H管坯的缺陷分析及探讨[J].特钢技术,2012,18(4):18-22. GUO L. Analysis and discussion on defect of continuous cast TP347H blank[J]. Special Steel Techonlogy,2012,18(4):18-22.
【50】王志军,杨永超.夹杂物对TP347H不锈钢φ108 mm×15 mm荒管裂纹缺陷的影响和工艺改进[J].特殊钢,2018,39(3):17-19. WANG Z J, YANG Y C. Effect of inclusions on cracks defect of φ108 mm×15 mm tube shell of stainless steel TP347H and process improvement[J]. Special Steel,2018,39(3):17-19.
【51】魏星,唐丽英.TP347H过热器管爆管原因分析[J].浙江电力,2016,35(2):60-62. WEI X, TANG L Y. Cause analysis on tube burst of TP347H superheater[J].Zhejiang Electric Power,2016,35(2):60-62.
【52】YU H Y, CHI C Y, DONG J X, et al. 650℃ long-time aging structure stability study on TP347H austenitic heat-resistant steel[J]. Scientific Journal of Materials Science, 2011,1(1):15-23.
【53】张建国,张瑞刚,陈恩山,等.高温再热器TP347H管爆管分析[J].热加工工艺,2013,42(18):198-199. ZHANG J G, ZHANG R G, CHEN E S, et al. Analysis on tube-burst of high temperature reheater TP347H steel[J]. Hot Working Technology,2013,42(18):198-199.
【54】王婀娜,彭海龙,尹人洁,等.TH347H奥氏体不锈管内表面"鼓泡"缺陷分析研究[J].四川冶金,2016,38(3):68-71. WANG E N, PENG H L, YI R J, et al. Analysis of discussion internal surface "bubble" defect of TP347H austenitic stainless steel pipe[J].Sichuan Metallurgy,2016,38(3):68-71.
【55】杨钢,黄崇湘,吴世丁,等.ECAP变形下304L奥氏体不锈钢的形变诱导马氏体相变[J].金属学报,2009,45(8):906-911. YANG G, HUANG C X, WU S D, et al. Strain-induced martensitic transformation in 304L austenitic stainless steel under ECAP deformation[J].Acta Metallurgica Sinica,2009,45(8):906-911.
【56】刘伟,李志斌,王翔,等.应变速率对奥氏体不锈钢应变诱发α'-马氏体转变和力学行为的影响[J].金属学报,2009,45(3):285-291. LIU W, LI Z B, WANG X, et al. Effect of strain rate on strain induced α'-martensite transformation and mechanical response of austenitic stainless steels[J]. Acta Metallurgica Sinica,2009,45(3):285-291.
【57】陈浩,高克玮,褚武扬,等.304不锈钢应力腐蚀促进马氏体相变[J].金属学报,2002,38(8):857-860. CHEN H, GAO K W, CHU W Y, et al. Stress corrosion cracking enhancing martensite transformation of type 304 stainless steel[J]. Acta Metallurgica Sinica,2002,38(8):857-860.
【58】史志刚,马红,崔雄华,等.S30432奥氏体不锈钢高温应力时效后的马氏体组织[J].材料热处理学报,2016,37(6):120-124. SHI Z G, MA H, CUI X H, et al. Martensitic structure of S30432 steel after high-temperature stress aging[J].Transactions of Materials And Heat Treatment,2016,37(6):120-124.
【59】史志刚,董红年,李益民,等.S30432锅炉管高温服役后磁性转变试验研究[J].动力工程学报,2014,34(8):660-667. SHI Z G, DONG H N, LI Y M, et al. Experimental study on magnetic transformation of S30432 boiler tubes after high-temperature service[J].Journal of Chinese Society of Power Engineering,2014,34(8):660-667.
【60】史志刚,何晓东,马红,等.奥氏体耐热钢锅炉管磁性能实验分析[J].热力发电,2018,47(12):53-59. SHI Z G, HE X D, MA H, et al. Experimental study on magnetic properties of austenitic heat-resistant steel for boiler tubes[J].Thermal Power Generation,2018,47(12):53-59.
【61】史志刚,马红,梅宝,等.S30432钢出现马氏体组织时的力学性能试验研究[J].中国电力,2017,50(5):156-162. SHI Z G,MA H,MEI B, et al. Experimental study on mechanical properties of S30432 steel containing martensitic structure[J].Electric Power,2017,50(5):156-162.
【62】方智,吴荫顺,张琳,等.形变诱发马氏体对304不锈钢在活化状态下电化学行为的影响[J].腐蚀科学与防护技术,1997,9(1):75-78. FANG Z, WU Y S, ZHAN L, et al. Effect of deformation induced martensite on electrochemical behaviors of type 304 stainless steel in the active state[J].Corrosion Science and Protection Technology,1997,9(1):75-78.
【2】杨宏辉.TP304H,TP347H钢的材料特性与金属监督[J].湖南电力,2000,20(6):51-52. YANG H H. Material properties and metal supervision of TP304H, TP347H steel[J].Hunan Electric Power,2000,20(6):51-52.
【3】王伟,王志武,李文胜,等.不同Cr、Ni含量下TP347H钢的热力学平衡相[J].金属热处理,2016,41(10):99-101. WANG W, WANG Z W, LI W S, et al. Thermodynamic equilibrium phases of TP347H steel with different Cr and Ni content[J]. Heat Treatment of Metals,2016,41(10):99-101.
【4】VISWANATHAN R, BAKKER W. Materials for ultrasupercritical coal power plants-Boiler materials:Part 1[J].Journal of Materials Engineering and Performance,2001,10(1):81-95.
【5】CHEN G H,SONG Y M,WANG J Q,et al.High-temperature short-term tensile test and creep rupture strength prediction of the T92/TP347H dissimilar steel weld joints[J].Engineering Failure Analysis,2012,26:220-229.
【6】彭孙鸿.固溶热处理对1Cr19Ni11Nb钢持久强度的影响[J].特殊钢,1995,16(2):10-12. PENG S H. Effect of solution heat treatment on creep rupture strength of steel 1Cr19Ni11Nb[J]. Special Steel, 1995,16(2):10-12.
【7】魏宝明.金属腐蚀理论及应用[M].北京:化学工业出版社,1984. WEI B M. Theory and application of metal corrosion[M].Beijing:Chemical Industry Press, 1984.
【8】罗宏,龚敏.奥氏体不锈钢的晶间腐蚀[J].腐蚀科学与防护技术,2006,18(5):357-360. LUO H, GONG M. On intergranular corrosion of austenitic stainless steel[J]. Corrosion Science and Protection Technology, 2006, 18(5):357-360.
【9】KASPAROVA O V.Peculiarities of intergranular corrosion of silicon-containing austenitic stainless steels[J].Protection of Metals,2004,40(5):425-431.
【10】HWANG E R, KANG S G. Intergranular corrosion of stainless steels in molten carbonate salt[J]. Journal of Materials Science Letters, 1997, 16(16):1387-1388.
【11】孙旭,宁玉恒,刘群.末级再热器用TP347H不锈钢管爆管原因分析[J].热加工工艺,2017,46(8):250-252. SUN X, NING Y H, LIU Q. Causes analysis of explosion of TP347H stainless steel tube for final reheater[J]. Hot Working Technology,2017,46(8):250-252.
【12】李戈,陈鹏磊,张林.600 MW超临界机组TP347H奥氏体不锈钢高温再热器管爆管失效分析[J].发电与空调,2016,37(2):1-8. LI G, CHEN P L, ZHANG L. Failure analysis of TP347H austenitic stainless steel tube of the 600 MW high temperature reheater[J]. Power Generation & Air Condition,2016,37(2):1-8.
【13】赵勇.TP347H奥氏体不锈钢高温过热器爆管原因分析[J].吉林电力,2012,40(1):50-51. ZHAO Y. Analysis on tube-bursting of TP347H austenitic stainless steel high-temperature super-heater[J]. Jilin Electric Power,2012,40(1):50-51.
【14】李振梁,王甲安,肖旻砚.高温再热器SA-213TP347H钢管爆管原因分析[J].金属热处理,2015,40(8):191-194. LI Z L, WANG J A, XIAO M Y. Failure analysis of SA-213TP347H steel reheater tube[J]. Heat Treatment of Metals,2015,40(8):191-194.
【15】崔雄华,郑坊平,张磊,等.供货热处理状态对奥氏体不锈钢锅炉管安全运行性能的影响[J].热力发电,2010,39(3):49-52. CUI X H, ZHENG F P, ZHANG L, et al. Influence of heat treatment status for the furnished austenite stainless steel boiler tubes upon their safe operation performance[J]. Thermal Power Generation, 2010, 39(3):49-52.
【16】马官兵,李晓红,谢阿萌.锅炉高温受热面TP347H管短期开裂分析[J].武汉大学学报(工学版),2007,40(3):80-84. MA G B, LI X H, XIE A M. Short-time cracking analysis of TP347H tubes of high temperature heat delivery surfaces of boilers[J]. Engineering Journal of Wuhan University, 2007, 40(3):80-84.
【17】王甲安,李剑平,李建,等.600 MW超临界机组SA-213TP347H高温再热器频繁爆管原因探究[J].材料热处理学报,2015,36(增刊1):122-127. WANG J A, LI J P, LI J, et al. Failure analysis of tube-burst of SA-213TP347H high-temperature reheater of 600 MW supercritical unit[J]. Transactions of Materials and Heat Treatment,2015,36(S1):122-127.
【18】魏泉泉,牛玉静.某电厂高温再热器出口TP347H材质管段泄漏原因分析[J].华电技术,2017,39(5):52-54. WEI Q Q, NIU Y J. A power plant's high temperature reheater outlet TP347H material pipeline leakage cause analysis[J]. Huadian Technology, 2017, 39(5):52-54.
【19】张述林,李敏娇,王晓波,等.18-8奥氏体不锈钢的晶间腐蚀[J].中国腐蚀与防护学报,2007,27(2):124-128. ZHANG S L, LI M J, WANG X B, et al. Intergranular corrosion of 18-8 austenitic stainless steel[J]. Journal of Chinese Society for Corrosion and Protection,2007,27(2):124-128.
【20】杨百勋,李益民,曹剑峰.火电机组设备质量缺陷及控制[M].北京:中国电力出版社,2019. YANG B X, LI Y M, CAO J F. Quality defect and control of thermal power unit equipment[M]. Beijing:China Electric Power Press, 2019.
【21】褚武扬,乔利杰,李金许.氢脆和应力腐蚀-典型体系[M].北京:科学出版社,2013. CHU W Y, QIAO L J, LI J X. Hydrogen embrittlement and stress corrosion cracking[M].Beijing:Science Press,2013.
【22】李晓刚.材料腐蚀与防护[M].长沙:中南大学出版社,2009. LI X G. Corrosion and protection of materials[M].Changsha:Central South University Press,2009.
【23】陈国星,周龙,赵可昕,等.TP347H不锈钢管表面裂纹的产生原因[J].机械工程材料,2010,34(3):80-83. CHEN G X, ZHOU L, ZHAO K X, et al. Analysis of surface cracks on TP347H stainless steel tube[J]. Materials for Mechanical Engineering,2010,34(3):80-83.
【24】吴立新,曾静,姚中海,等.TP347H过热器管爆管原因分析[J].武钢技术,2007,45(2):1-4. WU L X, ZENG J, YAO Z H, et al. Analysis on crack of TP347H superheated steam tube[J]. Wuhan Iron and Steel Corporation Technology,2007,45(2):1-4.
【25】张捷,杨行炳,林翔,等.高温再热器SA-213TP347H钢管裂纹原因分析[J].失效分析与预防,2018,13(4):214-217. ZHANG J, YANG H B, LIN X, et al. Crack analysis of SA213TP347H steel pipe in high temperature reheater[J]. Failure Analysis and Prevention,2018,13(4):214-217.
【26】杨首恩,刘盛波. 锅炉高温过热器不锈钢管开裂分析[C]//2009年全国失效分析学术会议论文集.上海:中国机械工程学会理化检验分会,中国机械工程学会失效分析分会,2009. YANG S E, LIU S B. Cracking analysis of stainless steel tube used for boiler super-heater[C]//Proceedings of the 2009 National Failure Analysis Conference. Shanghai:Physical Testing and Chemical Analysis Institution of CMES, Chinese Failure Analysis Institution of CMES, 2009.
【27】王海琦,车鹏程,刘焱.某电站锅炉后屏过TP347H爆管问题分析[J].锅炉制造,2019(4):19-24. WANG H Q, CHE P C, LIU Y. Failure analysis of rear superheater TP347H tube of a certain power plant[J]. Boiler Manufacturing, 2019(4):19-24.
【28】胡建军,张永芳.浅谈氯离子对奥氏体不锈钢的腐蚀[J].化工装备技术,2017,38(6):35-37. HU J J, ZHANG Y F. Corrosion of austenitic stainless steel by chloride ion[J].Chemical Equipment Technology,2017,38(6):35-37.
【29】于成,毕文军.奥氏体不锈钢应力腐蚀与防护[J].化工设计通讯,2018,44(2):50-50. YU C, BI W J. Austenitic stainless steel stress corrosion and protection[J]. Chemical Engineering Design Communications,2018,44(2):50-50.
【30】吴奭登,何卫忠.某电厂再热器泄漏原因分析[J].腐蚀科学与防护技术,2010,22(5):458-460. WU S D, HE W Z. Leakage analysis of reheater tube of power plant[J].Corrosion Science and Protection Technology, 2010, 22(5):458-460.
【31】刘杰,赵永峰,刘翔,等.600 MW超临界锅炉TP347H高温过热器管爆管的显微分析[J].热加工工艺,2020,49(2):159-162. LIU J, ZHAO Y F, LIU X, et al. Microscopic analysis on tube explosion of TP347H high temperature superheater pipe for 600 MW supercritical boiler[J]. Hot Working Technology, 2020, 49(2):159-162.
【32】高荣,张少军.TP347H不锈钢高温过热器爆管原因分析[J].内蒙古电力技术,2013,31(1):116-118. GAO R, ZHANG S J. Tube burst analysis of TP347H stainless steel high temperature superheater[J].Inner Mongolia Electric Power,2013,31(1):116-118.
【33】任文,叶建锋,李鹏刚.超临界机组TP347H末级过热器爆管分析[J/OL].[2020-11-28].http://kns.cnki.net/kcms/detail/33.1405.TH.20190911.0927.004.html. REN W, YE J F, LI P G. Failure analysis on the bursting TP347H final super-heater in a super-critical power plant[J/OL].[2020-11-28]. http://kns.cnki.net/kcms/detail/33.1405.TH.20190911.0927.004.html.
【34】田泽,叶建锋,熊宇.某电厂超临界机组TP347H高温过热器管爆管原因分析[J].湖北电力,2018,42(2):36-40. TIAN Z, YE J F, XIONG Y. Analysis on causes of tube burst of TP347H superheater in supercritical unit of a certain power plant[J]. Hubei Electric Power, 2018, 42(2):36-40.
【35】杜保华,王大鹏,董雷,等.超超临界1000 MW机组锅炉高温受热面炉内壁温测量及分析[J].热力发电,2013,42(7):118-122. DU B H, WANG D P, DONG L, et al. Measurement and analysis of tube wall temperature for heating surface of an ultra-supercritical 1000 MW unit boiler[J]. Thermal Power Generation,2013,42(7):118-122.
【36】周江,俞明芳,杨卓军.超超临界1000 MW机组锅炉高温受热面壁温变化规律分析[J].热力发电,2013,42(2):117-120. ZHOU J, YU M F, YANG Z J. Wall temperature variation of high temperature heating surface in boiler of an ultra supercritical 1000 MW unit[J]. Thermal Power Generation,2013,42(2):117-120.
【37】黄兴德,周新雅,游喆, 等. 超(超)临界锅炉高温受热面蒸汽氧化皮的生长与剥落特性[J].动力工程,2009, 29(6):602-608. HUANG X D, ZHOU X Y, YOU Z, et al. Oxide scale growth and exfoliation behavior on high temperature heat-absorbing surface exposed to steam for supercritical (ultrasupercritical) boilers[J]. Journal of Power Engineering, 2009, 29(6):602-608.
【38】OTSUKA N,SHIDA Y,FUJIKAWA H.Internal-external transition for the oxidation of Fe-Cr-Ni austenitic stainless steels in steam[J].Oxidation of Metals,1989,32(1/2):13-45.
【39】CARL W.Theoretical analysis of the diffusion processes determining the oxidation rate of alloys[J].Journal of the Electrochemical Society,1952,99(10):369-369.
【40】DOOLEY R B,WRIGHT I G, TORTORELLI P F. Program on technology innovation:Oxide growth and exfoliation on alloys exposed to steam[R]. Palo Alto:EPRI, 2007.
【41】邓勇,刘盛波,彭芳芳,等.600 MW超临界锅炉TP347H屏式过热器管高温蒸气氧化腐蚀探讨[J].腐蚀与防护,2009,30(2):124-127. DENG Y, LIU S B, PENG F F, et al. High temperature steam oxidization resistance of TP347H panel division super-heater tubes for 600 MW super-critical boiler[J].Corrosion & Protection,2009,30(2):124-127.
【42】张山山.TP347H钢高温过热器内壁氧化皮失效分析[J].发电与空调,2017,38(3):18-22. ZHANG S S. Failure analysis of TP347H high temperature superheater tube's oxide layer[J]. Power Generation & Air Condition,2017,38(3):18-22.
【43】HUGHES A, DOOLEY B, PATERSON S. Oxide exfoliation of 347HFG in high temperature boilers[C]//7th International Conference and Exhibition on Operating Pressure Equipment. Palo Alto:OPE, 2003:2-4.
【44】WRIGHT J I, PATERSON S, DOOLEY R. Oxidation and exfoliation[C]//EPRI Conference on Advances in Materials Technology for Fossil Power Plants. Palo Alto:EPRI, 2004:370.
【45】蔡建.TP347H不锈钢管屏制造工艺浅析[J].工业锅炉,2017(3):54-56. CAI J. Discussion about manufacture process of the TP347H pipe panel[J]. Industrial Boiler,2017(3):54-56.
【46】张晓昱,欧阳杰,郭立峰,等.18-8型奥氏体钢锅炉管高温运行后失效原因分析[J].热力发电,2007,36(9):92-94. ZHANG X Y, OUYANG J, GUO L F, et al. Causes leading to failure of boiler tubes made from 18-8 type austenitic steel after operation under high temperature[J]. Thermal Power Generation,2007,36(9):92-94.
【47】李长毅.电站锅炉用TP347H不锈钢无缝钢管的开发[J].冶金标准化与质量,2006,44(5):42-45. LI C Y. The development of TP347H stainless steel seamless pipe for utility boiler[J]. Metallurgical Standardization & Quality,2006,44(5):42-45.
【48】方旭东,徐鸿麟.电站锅炉用TP347H不锈钢无缝管工艺的开发[J].特殊钢,2007,28(2):49-50. FANG X D, XU H L. Development of process for precipitation-hardening stainless steel TP347H seamless tube for power station boiler[J].Special Steel,2007,28(2):49-50.
【49】郭玲.连铸TP347H管坯的缺陷分析及探讨[J].特钢技术,2012,18(4):18-22. GUO L. Analysis and discussion on defect of continuous cast TP347H blank[J]. Special Steel Techonlogy,2012,18(4):18-22.
【50】王志军,杨永超.夹杂物对TP347H不锈钢φ108 mm×15 mm荒管裂纹缺陷的影响和工艺改进[J].特殊钢,2018,39(3):17-19. WANG Z J, YANG Y C. Effect of inclusions on cracks defect of φ108 mm×15 mm tube shell of stainless steel TP347H and process improvement[J]. Special Steel,2018,39(3):17-19.
【51】魏星,唐丽英.TP347H过热器管爆管原因分析[J].浙江电力,2016,35(2):60-62. WEI X, TANG L Y. Cause analysis on tube burst of TP347H superheater[J].Zhejiang Electric Power,2016,35(2):60-62.
【52】YU H Y, CHI C Y, DONG J X, et al. 650℃ long-time aging structure stability study on TP347H austenitic heat-resistant steel[J]. Scientific Journal of Materials Science, 2011,1(1):15-23.
【53】张建国,张瑞刚,陈恩山,等.高温再热器TP347H管爆管分析[J].热加工工艺,2013,42(18):198-199. ZHANG J G, ZHANG R G, CHEN E S, et al. Analysis on tube-burst of high temperature reheater TP347H steel[J]. Hot Working Technology,2013,42(18):198-199.
【54】王婀娜,彭海龙,尹人洁,等.TH347H奥氏体不锈管内表面"鼓泡"缺陷分析研究[J].四川冶金,2016,38(3):68-71. WANG E N, PENG H L, YI R J, et al. Analysis of discussion internal surface "bubble" defect of TP347H austenitic stainless steel pipe[J].Sichuan Metallurgy,2016,38(3):68-71.
【55】杨钢,黄崇湘,吴世丁,等.ECAP变形下304L奥氏体不锈钢的形变诱导马氏体相变[J].金属学报,2009,45(8):906-911. YANG G, HUANG C X, WU S D, et al. Strain-induced martensitic transformation in 304L austenitic stainless steel under ECAP deformation[J].Acta Metallurgica Sinica,2009,45(8):906-911.
【56】刘伟,李志斌,王翔,等.应变速率对奥氏体不锈钢应变诱发α'-马氏体转变和力学行为的影响[J].金属学报,2009,45(3):285-291. LIU W, LI Z B, WANG X, et al. Effect of strain rate on strain induced α'-martensite transformation and mechanical response of austenitic stainless steels[J]. Acta Metallurgica Sinica,2009,45(3):285-291.
【57】陈浩,高克玮,褚武扬,等.304不锈钢应力腐蚀促进马氏体相变[J].金属学报,2002,38(8):857-860. CHEN H, GAO K W, CHU W Y, et al. Stress corrosion cracking enhancing martensite transformation of type 304 stainless steel[J]. Acta Metallurgica Sinica,2002,38(8):857-860.
【58】史志刚,马红,崔雄华,等.S30432奥氏体不锈钢高温应力时效后的马氏体组织[J].材料热处理学报,2016,37(6):120-124. SHI Z G, MA H, CUI X H, et al. Martensitic structure of S30432 steel after high-temperature stress aging[J].Transactions of Materials And Heat Treatment,2016,37(6):120-124.
【59】史志刚,董红年,李益民,等.S30432锅炉管高温服役后磁性转变试验研究[J].动力工程学报,2014,34(8):660-667. SHI Z G, DONG H N, LI Y M, et al. Experimental study on magnetic transformation of S30432 boiler tubes after high-temperature service[J].Journal of Chinese Society of Power Engineering,2014,34(8):660-667.
【60】史志刚,何晓东,马红,等.奥氏体耐热钢锅炉管磁性能实验分析[J].热力发电,2018,47(12):53-59. SHI Z G, HE X D, MA H, et al. Experimental study on magnetic properties of austenitic heat-resistant steel for boiler tubes[J].Thermal Power Generation,2018,47(12):53-59.
【61】史志刚,马红,梅宝,等.S30432钢出现马氏体组织时的力学性能试验研究[J].中国电力,2017,50(5):156-162. SHI Z G,MA H,MEI B, et al. Experimental study on mechanical properties of S30432 steel containing martensitic structure[J].Electric Power,2017,50(5):156-162.
【62】方智,吴荫顺,张琳,等.形变诱发马氏体对304不锈钢在活化状态下电化学行为的影响[J].腐蚀科学与防护技术,1997,9(1):75-78. FANG Z, WU Y S, ZHAN L, et al. Effect of deformation induced martensite on electrochemical behaviors of type 304 stainless steel in the active state[J].Corrosion Science and Protection Technology,1997,9(1):75-78.
相关信息
