Sanicro 25耐热钢的研究现状及应用前景
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摘要
综述了Sanicro 25耐热钢的显微组织、低温和高温力学性能、耐腐蚀性能、加工性能、焊接性能等,并对Sanicro 25耐热钢的应用现状进行了总结,对Sanicro 25耐热钢的应用前景进行了展望。
The microstructure,mechanical properties at high and low temperatures,corrosion resistance,processability and weldability of Sanicro 25heat-resistant steel were reviewed.The application status of Sanicro 25heat-resistant steel was summarized.The application prospect of Sanicro 25heat-resistant steel was expected.
The microstructure,mechanical properties at high and low temperatures,corrosion resistance,processability and weldability of Sanicro 25heat-resistant steel were reviewed.The application status of Sanicro 25heat-resistant steel was summarized.The application prospect of Sanicro 25heat-resistant steel was expected.
引文
[1]毛健雄,毛健全.当前我国燃煤火电机组降低CO2排放的途径[J].电力建设,2011,32(11):5-10.
[2]何振东,华洪渊,张志伦,等.1 000 MW超超临界锅炉设计探讨[J].东方电力评论,2005,19(2):59-62.
[3]陈仁杰.上海外高桥第三发电厂工程设计特点[J].电力勘测设计,2010,77(3):34-38.
[4]孙锐,赵敏,秦丰,等.推广应用600 MW超超临界机组的必要性和可行性研究[J].中国电力,2005,38(8):37-40.
[5]超超临界发电技术进入攻坚期:630~650℃机组成下步火电建设重要目标[EB/OL].(2016-12-12)[2017-09-16].http://news.bjx.com.cn/html/20161212/795875.shtml.
[6]张新,张志刚,王晓茹,等.电站锅炉用耐热钢管焊接接头再热裂纹研究进展[J].机械工程材料,2017,41(2):8-14.
[7]周荣灿.超超临界火电厂材料技术研究综述[C]//中国科协2004年学术年会论文集.博鳌:中国科协2004年学术年会大会执委会,2004:19-25.
[8]毛健雄.700℃超超临界机组高温材料研发的最新进展[J].电力建设,2013,34(8):69-76.
[9]朱传志,袁勇,尹宏飞,等.超超临界机组用Sanicro 25耐热钢研究进展[J].材料导报,2017,31(7):78-84.
[10] RUTKOWSKI B,GIL A,CZYRSKA-FILEMONOWICZ A.Microstructure and chemical composition of the oxide scale formed on the Sanicro 25steel tubes after fireside corrosion[J].Corrosion Science,2016,102:373-383.
[11] VISWANATHAN R,HENRY J F,TANZOSH J,et al.Program on materials technology for ultra-supercritical coal power plants[J].Journal of Materials Engineering and Performance,2013,22:2904-2915.
[12] ZHOU R, ZHU L, LIU Y,et al.Precipitates and precipitation strengthening of Sanicro 25 welded joint base metal crept at 973K[J].Steel Research International,2017,88(8):1600414.
[13]赵博.W含量对Sanicro 25钢组织和性能的影响[D].昆明:昆明理工大学,2013.
[14] RAUTIO R,BRUCE S.Alloy for ultra-supercritical coal fired boiler[R].Sweden:Sandvik Group,2008.
[15]毕艳艳.Sanicro 25新型超超临界燃煤电厂锅炉用高强度奥氏体耐热钢[C]//第五届火力发电厂金属材料与焊接技术交流2016年会论文集.杭州:中国电力科技网,2016.
[16]刁旺战,王萍,欧海燕,等.先进超超临界锅炉用钢Sanicro 25焊接接头性能的试验研究[J].锅炉制造,2017(1):51-53.
[17]乔加飞,王斌,陈寅彪,等.630℃高效超超临界二次再热机组关键技术研究[J].煤炭工程,2017(增刊1):109-113.
[18]张显.超超临界锅炉用奥氏体耐热钢Sanicro 25的性能[J].发电设备,2015,29(6):439-442.
[19]迟成宇,于鸿垚,董建新,等.富铜纳米析出相在18Cr9Ni3CuNbN奥氏体耐热钢中的时效强化[J].材料热处理学报,2011,32(4):58-63.
[20]王崇斌,诸育枫,王煜,等.700℃超超临界机组锅炉过热器选材分析[J].发电设备,2016,30(3):168-172.
[21] HECZKOA M,POLKA J,KRUML T.Microstructure and dislocation arrangements in Sanicro 25 steel fatigued at ambient and elevated temperatures[J].Materials Science and Engineering:A,2017,680:168-181.
[22]孙珍宝,朱谱藩.合金钢手册(上册)[M].北京:冶金工业出版社,1984:9.
[23] SAWARAGI Y. Development of the economical 18-8stainless steel having high elevated temperature strength for fossil fired boilers[J].Sumitomo Search,1992,1:48.
[24] SAWARAGI Y,OTSUKA N.Properties of a new 18-8austenitic steel tube(Super304H)for fossil fired boilers after service exposure with high elevated temperature strength[J].Sumitomo Search,1994,10:56.
[25] RUTKOWSKI B, GILA A, AGEROA, et al.Microstructure,chemical-and phase composition of Sanicro25austenitic steel after oxidation in steam at 700°C[J].Oxidation of Metals,2018,89(1/2):183-195.
[26] SHIM J H,KOZESCHNIK E,JUNG W S,et al.Numerical simulation of long-term precipitate evolution in austenitic heat-resistant steels[J].Calphad,2010,34:105-112.
[27]赵庆权.国产化Super304H钢管组织性能及持久强度研究[D].兰州:兰州理工大学,2008.
[28] BI Y Y.Sanicro 25(Tube and pipe,seamless),material data sheet of Sandvik[R].Sweden:Sandvik Group,2011.
[29] INTISO L,JOHANSSON L G,SVENSSON J E,et al.Oxidation of Sanicro 25(42Fe22Cr25NiWCuNbN)in O2and O2+H2O environments at 600-750℃[J].Oxidation of Metals,2015,83(3/4):367-391.
[30] NARUMANCHI K.Sandvik Sanicro 25—New heat resistant steel for A-USC[R].Sweden:Sandvik Group,2012.
[31]程世长,刘正东,包汉生.700℃超超临界火电机组锅炉合金进展[C]//第九届电站金属材料学术年会论文集.成都:中国电机工程学会火力发电分会,2011:273-277.
[32] ZHOU R,ZHU L,LIU Y,et al.Microstructural evolution and the effect on hardness of Sanicro 25 welded joint base metal after creep at 973K[J].Journal of Materials Science,2017,52(11):6161-6172.
[33]赖仙红,杨红英.Sanicro 25奥氏体耐热钢管性能简述[J].东方锅炉,2012(4):28-33.
[34]陈亮,卢征然.700℃超超临界锅炉高温过热器再热器用Sanicro 25新材料焊接工艺研究[J].锅炉技术,2015,46(5):49-53.
[35] JAMROZIK P,SOZA'NSKA M.High-temperature corrosion resistance of welded joints in Sanicro 25steel[J].Solid State Phenomena,2015,227:401-404.
[36]王永发.Sanicro25高温时效及与T92焊接接头组织性能研究[D].天津:天津大学,2016.
[37]王斌,梁军,荆洪阳,等.焊接材料对Sanicro 25/T92异种钢接头组织及力学性能的影响[J].焊接技术,2016,45(6):27-30.
[38] POLK J,PETRˇSR,HECZKO M,et al.Evolution of the cyclic plastic response of Sanicro 25steel cycled at ambient and elevated temperatures[J].International Journal of Fatigue,2016,83:75-83.
[39] ZUREK J,YANG S M,LIN D Y,et al.Microstructural stability and oxidation behavior of Sanicro 25during longterm steam exposure in the temperature range 600-750℃[J].Materials and Corrosion,2015,66(4):315-327.
[40]迟成宇,于鸿篧,谢锡善.世界700℃等级先进超超临界电站关键高温材料[J].世界钢铁,2013,13(2):42-59.
[41]王崇斌,徐雪元,诸育枫,等.蒸汽温度700℃超超临界锅炉受热面选材研究[J].压力容器,2015,32(4):51-59.
[42] SUN R,CUI Z Z,TAO Y.Progress of China 700℃USC development program[C]//The 7th International Conference on Advances in Materials Technology for Fossil Power Plants.Hawaii,USA:Electric Power Research Institute,2013.
[2]何振东,华洪渊,张志伦,等.1 000 MW超超临界锅炉设计探讨[J].东方电力评论,2005,19(2):59-62.
[3]陈仁杰.上海外高桥第三发电厂工程设计特点[J].电力勘测设计,2010,77(3):34-38.
[4]孙锐,赵敏,秦丰,等.推广应用600 MW超超临界机组的必要性和可行性研究[J].中国电力,2005,38(8):37-40.
[5]超超临界发电技术进入攻坚期:630~650℃机组成下步火电建设重要目标[EB/OL].(2016-12-12)[2017-09-16].http://news.bjx.com.cn/html/20161212/795875.shtml.
[6]张新,张志刚,王晓茹,等.电站锅炉用耐热钢管焊接接头再热裂纹研究进展[J].机械工程材料,2017,41(2):8-14.
[7]周荣灿.超超临界火电厂材料技术研究综述[C]//中国科协2004年学术年会论文集.博鳌:中国科协2004年学术年会大会执委会,2004:19-25.
[8]毛健雄.700℃超超临界机组高温材料研发的最新进展[J].电力建设,2013,34(8):69-76.
[9]朱传志,袁勇,尹宏飞,等.超超临界机组用Sanicro 25耐热钢研究进展[J].材料导报,2017,31(7):78-84.
[10] RUTKOWSKI B,GIL A,CZYRSKA-FILEMONOWICZ A.Microstructure and chemical composition of the oxide scale formed on the Sanicro 25steel tubes after fireside corrosion[J].Corrosion Science,2016,102:373-383.
[11] VISWANATHAN R,HENRY J F,TANZOSH J,et al.Program on materials technology for ultra-supercritical coal power plants[J].Journal of Materials Engineering and Performance,2013,22:2904-2915.
[12] ZHOU R, ZHU L, LIU Y,et al.Precipitates and precipitation strengthening of Sanicro 25 welded joint base metal crept at 973K[J].Steel Research International,2017,88(8):1600414.
[13]赵博.W含量对Sanicro 25钢组织和性能的影响[D].昆明:昆明理工大学,2013.
[14] RAUTIO R,BRUCE S.Alloy for ultra-supercritical coal fired boiler[R].Sweden:Sandvik Group,2008.
[15]毕艳艳.Sanicro 25新型超超临界燃煤电厂锅炉用高强度奥氏体耐热钢[C]//第五届火力发电厂金属材料与焊接技术交流2016年会论文集.杭州:中国电力科技网,2016.
[16]刁旺战,王萍,欧海燕,等.先进超超临界锅炉用钢Sanicro 25焊接接头性能的试验研究[J].锅炉制造,2017(1):51-53.
[17]乔加飞,王斌,陈寅彪,等.630℃高效超超临界二次再热机组关键技术研究[J].煤炭工程,2017(增刊1):109-113.
[18]张显.超超临界锅炉用奥氏体耐热钢Sanicro 25的性能[J].发电设备,2015,29(6):439-442.
[19]迟成宇,于鸿垚,董建新,等.富铜纳米析出相在18Cr9Ni3CuNbN奥氏体耐热钢中的时效强化[J].材料热处理学报,2011,32(4):58-63.
[20]王崇斌,诸育枫,王煜,等.700℃超超临界机组锅炉过热器选材分析[J].发电设备,2016,30(3):168-172.
[21] HECZKOA M,POLKA J,KRUML T.Microstructure and dislocation arrangements in Sanicro 25 steel fatigued at ambient and elevated temperatures[J].Materials Science and Engineering:A,2017,680:168-181.
[22]孙珍宝,朱谱藩.合金钢手册(上册)[M].北京:冶金工业出版社,1984:9.
[23] SAWARAGI Y. Development of the economical 18-8stainless steel having high elevated temperature strength for fossil fired boilers[J].Sumitomo Search,1992,1:48.
[24] SAWARAGI Y,OTSUKA N.Properties of a new 18-8austenitic steel tube(Super304H)for fossil fired boilers after service exposure with high elevated temperature strength[J].Sumitomo Search,1994,10:56.
[25] RUTKOWSKI B, GILA A, AGEROA, et al.Microstructure,chemical-and phase composition of Sanicro25austenitic steel after oxidation in steam at 700°C[J].Oxidation of Metals,2018,89(1/2):183-195.
[26] SHIM J H,KOZESCHNIK E,JUNG W S,et al.Numerical simulation of long-term precipitate evolution in austenitic heat-resistant steels[J].Calphad,2010,34:105-112.
[27]赵庆权.国产化Super304H钢管组织性能及持久强度研究[D].兰州:兰州理工大学,2008.
[28] BI Y Y.Sanicro 25(Tube and pipe,seamless),material data sheet of Sandvik[R].Sweden:Sandvik Group,2011.
[29] INTISO L,JOHANSSON L G,SVENSSON J E,et al.Oxidation of Sanicro 25(42Fe22Cr25NiWCuNbN)in O2and O2+H2O environments at 600-750℃[J].Oxidation of Metals,2015,83(3/4):367-391.
[30] NARUMANCHI K.Sandvik Sanicro 25—New heat resistant steel for A-USC[R].Sweden:Sandvik Group,2012.
[31]程世长,刘正东,包汉生.700℃超超临界火电机组锅炉合金进展[C]//第九届电站金属材料学术年会论文集.成都:中国电机工程学会火力发电分会,2011:273-277.
[32] ZHOU R,ZHU L,LIU Y,et al.Microstructural evolution and the effect on hardness of Sanicro 25 welded joint base metal after creep at 973K[J].Journal of Materials Science,2017,52(11):6161-6172.
[33]赖仙红,杨红英.Sanicro 25奥氏体耐热钢管性能简述[J].东方锅炉,2012(4):28-33.
[34]陈亮,卢征然.700℃超超临界锅炉高温过热器再热器用Sanicro 25新材料焊接工艺研究[J].锅炉技术,2015,46(5):49-53.
[35] JAMROZIK P,SOZA'NSKA M.High-temperature corrosion resistance of welded joints in Sanicro 25steel[J].Solid State Phenomena,2015,227:401-404.
[36]王永发.Sanicro25高温时效及与T92焊接接头组织性能研究[D].天津:天津大学,2016.
[37]王斌,梁军,荆洪阳,等.焊接材料对Sanicro 25/T92异种钢接头组织及力学性能的影响[J].焊接技术,2016,45(6):27-30.
[38] POLK J,PETRˇSR,HECZKO M,et al.Evolution of the cyclic plastic response of Sanicro 25steel cycled at ambient and elevated temperatures[J].International Journal of Fatigue,2016,83:75-83.
[39] ZUREK J,YANG S M,LIN D Y,et al.Microstructural stability and oxidation behavior of Sanicro 25during longterm steam exposure in the temperature range 600-750℃[J].Materials and Corrosion,2015,66(4):315-327.
[40]迟成宇,于鸿篧,谢锡善.世界700℃等级先进超超临界电站关键高温材料[J].世界钢铁,2013,13(2):42-59.
[41]王崇斌,徐雪元,诸育枫,等.蒸汽温度700℃超超临界锅炉受热面选材研究[J].压力容器,2015,32(4):51-59.
[42] SUN R,CUI Z Z,TAO Y.Progress of China 700℃USC development program[C]//The 7th International Conference on Advances in Materials Technology for Fossil Power Plants.Hawaii,USA:Electric Power Research Institute,2013.