钢铁材料中第二相颗粒强韧化的研究进展
|
摘要
第二相颗粒是钢材强韧化的重要方法,可以同时兼顾钢材的强度、韧性以及其他服役性能。随着近年来对钢材强度要求的提高,研究人员开发出了一大批新型钢铁材料,第二相颗粒强韧化在这些新型钢材中亦发挥了重要作用。但与此同时,在这些新型钢铁材料中,第二相颗粒强韧化也面临着诸多挑战与机遇:纳米尺度颗粒的表征与调控、第二相颗粒与多相微观组织的相互作用以及钢材服役性能的优化等等。通过汽车轻量化用钢、超高强度马氏体时效钢、核反应堆用钢、高模量钢等不同钢材,总结了第二相颗粒对新型钢铁材料的强度、韧性、焊接性、成形性、抗氢致延迟断裂、蠕变、抗辐射损伤等性能的影响,并结合这些新型钢铁材料独特的微观组织、制备工艺、服役环境等特点,分析了其第二相颗粒强韧化的机理以及尚待解决的问题,旨在为钢中第二相颗粒强韧化领域的进一步研究与发展提供参考。
Second phase strengthening plays an important role in the strengthening and toughening of steels,which could improve simultaneously strength,toughness as well as other in-use properties. Recently,with the increasing demands for higher strength steels,second phase strengthening has been utilized in many newly-developed steels to improve strength and toughness. Despite the promising properties,second phase strengthening should overcome many difficulties in those advanced steels before practical application. Among these challenges are nanoscale characterization and control,interaction between multiphase structure and second phase particles,and optimization of in-use properties. This review focuses on the second phase strengthening and their influences on the strength,toughness,weldability,formability,delayed fracture resistance,creep strength and irradiation resistance of advanced steels. In particular,automotive steels for weight lightening,ultra-high strength maraging steels,fission and fusion reactor steels and high modulus steels are discussed here. Based on the special microstructures,manufacture techniques and applications of the different advanced steels,the strengthening and toughening mechanisms are analyzed,and the research gaps are proposed. The aim of this review is to provide a reference for further research and development of advanced steels with second phase strengthening.
Second phase strengthening plays an important role in the strengthening and toughening of steels,which could improve simultaneously strength,toughness as well as other in-use properties. Recently,with the increasing demands for higher strength steels,second phase strengthening has been utilized in many newly-developed steels to improve strength and toughness. Despite the promising properties,second phase strengthening should overcome many difficulties in those advanced steels before practical application. Among these challenges are nanoscale characterization and control,interaction between multiphase structure and second phase particles,and optimization of in-use properties. This review focuses on the second phase strengthening and their influences on the strength,toughness,weldability,formability,delayed fracture resistance,creep strength and irradiation resistance of advanced steels. In particular,automotive steels for weight lightening,ultra-high strength maraging steels,fission and fusion reactor steels and high modulus steels are discussed here. Based on the special microstructures,manufacture techniques and applications of the different advanced steels,the strengthening and toughening mechanisms are analyzed,and the research gaps are proposed. The aim of this review is to provide a reference for further research and development of advanced steels with second phase strengthening.
引文
[1]He B B,Hu B,Yen H W,et al.Science[J],2017,357(6355):1029-1032.
[2]Garcia C I.High Strength Low Alloyed(HSLA)Steels:Automotive Steels:Design,Metallurgy,Processing and Applications[M].Duxford-Cambridge-Kidlington:Woodhead Publishing,2016:145-167.
[3]Martin J W.Precipitation Hardening[M].Oxford-Woburn:Butterworth-Heinemann,1998.
[4]Jiao Z B,Luan J H,Miller M K,et al.Materials Today[J],2017,20(3):142-154.
[5]Li Y,Li W,Liu W,et al.Acta Materialia[J],2018,146:126-141.
[6]Park I,Jo S Y,Kang M,et al.Corrosion Science[J],2014,89:38-45.
[7]Odette G R,Alinger M J,Wirth B D.Annual Review of Materials Research[J],2008,38(1):471-503.
[8]Gwon H,Kim J,Shin S,et al.Materials Science and Engineering A[J],2017,696:416-428.
[9]Altuna M A,Iza-Mendia A,Gutiérrez I.Metallurgical and Materials Transactions A[J],2012,43(12):4571-4586.
[10]Chen M Y,GounéM,Verdier M,et al.Acta Materialia[J],2014,64:78-92.
[11]Hong S G,Kang K B,Park C G.Scripta Materialia[J],2002,46(2):163-168.
[12]Li Y,Crowther D N,Mitchell P S,et al.ISIJ International[J],2002,42(6):636-644.
[13]Bhole S D,Nemade J B,Collins L,et al.Journal of Materials Processing Technology[J],2006,173(1):92-100.
[14]Beidokhti B,Koukabi A H,Dolati A.Journal of Materials Processing Technology[J],2009,209(8):4027-4035.
[15]Sun Yaozu(孙耀祖),Wang Xu(王旭),Wang Yunling(王运玲),etal.Materials China(中国材料进展)[J],2015,6(34):475-481.
[16]Samei J,Zhou L,Kang J,et al.International Journal of Plasticity[J],2018.
[17]Senuma T.ISIJ international[J],2001,6(41):520-532.
[18]Bouaziz O,Allain S,Scott C P,et al.Current Opinion in Solid State and Materials Science[J],2011,15(4):141-168.
[19]Scott C,Remy B,Collet J,et al.International Journal of Materials Research[J],2011,102(5):538-549.
[20]Yen H,Huang M,Scott C P,et al.Scripta Materialia[J],2012,66(12):1018-1023.
[21]Koyama M,Akiyama E,Lee Y,et al.International Journal of Hydrogen Energy[J],2017,42(17):12706-12723.
[22]Malard B,Remy B,Scott C,et al.Materials Science and Engineering A[J],2012,536:110-116.
[23]Wang L,Speer J G.Metallography,Microstructure,and Analysis[J],2013,2(4):268-281.
[24]Edmonds D V,He K,Rizzo F C,et al.Materials Science and Engineering A[J],2006,438-440:25-34.
[25]Hsu T Y(Xu Zuyao).International Heat Treatment and Surface Engineering[J],2008,2(2):64-67.
[26]Malakondaiah G,Srinivas M,Rao P R.Progress in Materials Science[J],1997,42(1):209-242.
[27]Jiao Z,Liu C T.Science Bulletin[J],2017,62(15):1043-1044.
[28]Jiang S,Wang H,Wu Y,et al.Nature[J],2017,544(7651):460-464.
[29]Jiao Z B,Luan J H,Miller M K,et al.Scientific Reports[J],2016,6:21364.
[30]Zinkle S J,Was G S.Acta Materialia[J],2013,61(3):735-758.
[31]Alinger M J,Odette G R,Hoelzer D T.Acta Materialia[J],2009,57(2):392-406.
[32]Schneibel J H,Liu C T,Miller M K,et al.Scripta Materialia[J],2009,61(8):793-796.
[33]Marquis E A,Hyde J M,Saxey D W,et al.Materials Today[J],2009,12(11):30-37.
[34]Sheikhzadeh M,Sanjabi S.Materials&Design[J],2012,39:366-372.
[35]Nahme H,Lach E,Tarrant A.Journal of Materials Science[J],2009,44(2):463-468.
[36]Needleman A.Journal of the Mechanics and Physics of Solids[J],1990,38(3):289-324.
[37]Huang MX,He BB,Wang X,et al.Scripta Materialia[J],2015,99:13-16.
[38]Li Y Z,Luo Z C,Yi H L,et al.Metallurgical and Materials Transactions E[J],2016,3(3):203-208.
[39]Arsenault R J,Taya M.Acta Metallurgica[J],1987,35(3):651-659.
[2]Garcia C I.High Strength Low Alloyed(HSLA)Steels:Automotive Steels:Design,Metallurgy,Processing and Applications[M].Duxford-Cambridge-Kidlington:Woodhead Publishing,2016:145-167.
[3]Martin J W.Precipitation Hardening[M].Oxford-Woburn:Butterworth-Heinemann,1998.
[4]Jiao Z B,Luan J H,Miller M K,et al.Materials Today[J],2017,20(3):142-154.
[5]Li Y,Li W,Liu W,et al.Acta Materialia[J],2018,146:126-141.
[6]Park I,Jo S Y,Kang M,et al.Corrosion Science[J],2014,89:38-45.
[7]Odette G R,Alinger M J,Wirth B D.Annual Review of Materials Research[J],2008,38(1):471-503.
[8]Gwon H,Kim J,Shin S,et al.Materials Science and Engineering A[J],2017,696:416-428.
[9]Altuna M A,Iza-Mendia A,Gutiérrez I.Metallurgical and Materials Transactions A[J],2012,43(12):4571-4586.
[10]Chen M Y,GounéM,Verdier M,et al.Acta Materialia[J],2014,64:78-92.
[11]Hong S G,Kang K B,Park C G.Scripta Materialia[J],2002,46(2):163-168.
[12]Li Y,Crowther D N,Mitchell P S,et al.ISIJ International[J],2002,42(6):636-644.
[13]Bhole S D,Nemade J B,Collins L,et al.Journal of Materials Processing Technology[J],2006,173(1):92-100.
[14]Beidokhti B,Koukabi A H,Dolati A.Journal of Materials Processing Technology[J],2009,209(8):4027-4035.
[15]Sun Yaozu(孙耀祖),Wang Xu(王旭),Wang Yunling(王运玲),etal.Materials China(中国材料进展)[J],2015,6(34):475-481.
[16]Samei J,Zhou L,Kang J,et al.International Journal of Plasticity[J],2018.
[17]Senuma T.ISIJ international[J],2001,6(41):520-532.
[18]Bouaziz O,Allain S,Scott C P,et al.Current Opinion in Solid State and Materials Science[J],2011,15(4):141-168.
[19]Scott C,Remy B,Collet J,et al.International Journal of Materials Research[J],2011,102(5):538-549.
[20]Yen H,Huang M,Scott C P,et al.Scripta Materialia[J],2012,66(12):1018-1023.
[21]Koyama M,Akiyama E,Lee Y,et al.International Journal of Hydrogen Energy[J],2017,42(17):12706-12723.
[22]Malard B,Remy B,Scott C,et al.Materials Science and Engineering A[J],2012,536:110-116.
[23]Wang L,Speer J G.Metallography,Microstructure,and Analysis[J],2013,2(4):268-281.
[24]Edmonds D V,He K,Rizzo F C,et al.Materials Science and Engineering A[J],2006,438-440:25-34.
[25]Hsu T Y(Xu Zuyao).International Heat Treatment and Surface Engineering[J],2008,2(2):64-67.
[26]Malakondaiah G,Srinivas M,Rao P R.Progress in Materials Science[J],1997,42(1):209-242.
[27]Jiao Z,Liu C T.Science Bulletin[J],2017,62(15):1043-1044.
[28]Jiang S,Wang H,Wu Y,et al.Nature[J],2017,544(7651):460-464.
[29]Jiao Z B,Luan J H,Miller M K,et al.Scientific Reports[J],2016,6:21364.
[30]Zinkle S J,Was G S.Acta Materialia[J],2013,61(3):735-758.
[31]Alinger M J,Odette G R,Hoelzer D T.Acta Materialia[J],2009,57(2):392-406.
[32]Schneibel J H,Liu C T,Miller M K,et al.Scripta Materialia[J],2009,61(8):793-796.
[33]Marquis E A,Hyde J M,Saxey D W,et al.Materials Today[J],2009,12(11):30-37.
[34]Sheikhzadeh M,Sanjabi S.Materials&Design[J],2012,39:366-372.
[35]Nahme H,Lach E,Tarrant A.Journal of Materials Science[J],2009,44(2):463-468.
[36]Needleman A.Journal of the Mechanics and Physics of Solids[J],1990,38(3):289-324.
[37]Huang MX,He BB,Wang X,et al.Scripta Materialia[J],2015,99:13-16.
[38]Li Y Z,Luo Z C,Yi H L,et al.Metallurgical and Materials Transactions E[J],2016,3(3):203-208.
[39]Arsenault R J,Taya M.Acta Metallurgica[J],1987,35(3):651-659.