李秀程等：低合金钢焊接热影响区的微观组织和韧性研究进展 ·653· Trans A,1991,22(2):489 [34]You Y,Wang X M,Shang C J.Influence of austenitizing tem- [23]Kim N J,Thomas G.Effects of morphology on the mechanical perature on the microstructure and impact toughness of a high behavior of a dual phase Fe/2Si/0.IC steel.Metall Trans A, strength low alloy HSLA100 steel.Acta Metall Sin,2012,48 1981,12(3):483 (11):1290 [24]Li X D,Ma X P,Suberamanian S V,et al.EBSD characteriza- (由洋，王学敏，尚成嘉.奥氏体化温度对HSLA100高强度 tion of secondary microcracks in the heat affected zone of a X100 低合金钢组织及冲击韧性的影响.金属学报，2012,48 pipeline steel weld joint.Int fract,2015,193(2):131 (11):1290) [25]Li J,Wang H,Qu S Y,et al.Effect of welding thermal cycle [35]Lambert A,Garat X.Sturel T,et al.Application of acoustic parameters on the microstructure and properties in the heat affect- emission to the study of cleavage fracture mechanism in a HSLA ed zone of steel EH40 for high heat input welding.J Unig Sci steel.Scripta Mater,2000,43(2):161 Technol Beijing,2012,34(7):788 [36]Fuluhara T,Kawata H,Morito S,et al.Variant selection in (李静，王华，曲圣昱，等.焊接热循环参数对大线能量焊接 grain boundary nucleation of upper bainite.Metall Mater Trans 用钢EH40热影响区组织和性能的影响.北京科技大学学 A,2008,39(5):1003 报.2012,34(7)：788) [37]Miao C L,Shang C J,Wang X M,et al.Microstructure and [26]Shi Y W,Han Z X.Effect of weld thermal cyele on microstruc- toughness of HAZ in X80 pipeline steel with high Nb content. ture and fracture toughness of simulated heat-affected zone for a Acta Metall Sin,2010,46(5):541 800 MPa grade high strength low alloy steel.I Mater Process (缪成亮，尚成嘉，王学敏，等.高NbX80管线钢焊接热影 Technol,.2008.207(1):30 响区显微组织与韧性.金属学报，2010,46(5)：541) [27]Guo J,Shang C J,Guo A M,et al.Effect of micro-zirconium [38]Yu Y N,Yang P,Qiang W J,et al.Materials Science Founda- addition on the carbonitride precipitation and austenite grain tion.2nd Ed.Beijing:Higher Education Press,2012 coarsening in Mn-Mo-Cu-Nb-B structure steel.J Unir Sci (余永宁，杨平，强文江，等.材料科学基础.2版.北京：高 Technol Beijing,2008,30(11):1236 等教育出版社，2012) (郭佳，尚成嘉，郭爱民，等.微量Zr添加对Mn-Mo-Nb- [39]Gourgues A F,Flower H M,Lindley T C.Electron backscatter- Cu-B钢晶粒长大倾向性的影响.北京科技大学学报，2008， ing diffraction study of acicular ferrite,bainite,and martensite 30(11):1236) steel microstructures.Mater Sci Technol,2000,16(1):26 [28]Wu H B,Hou M,Liang G L,et al.Effect of zirconium on the [40]You Y,Shang C J,Nie W J,et al.Investigation on the micro- low-temperature toughness of CGHAZ in F40 ship plates contai- structure and toughness of coarse grained heat affected zone in ning titanium.J Univ Sci Technol Beijing,2012,34(2):137 X-100 multi-phase pipeline steel with high Nb content.Mater (武会宾，侯敏，梁国俐，等.锆对含钛F40级船板钢粗品 Sci Eng A,2012,558:692 热影响区低温韧性的彩响.北京科技大学学报，2012,34 [41]Takayama N,Miyamoto G,Furuhara T.Effects of transformation (2):137) temperature on variant pairing of bainitic ferrite in low carbon [29]Wang X M,Shu W,Zheng CC.et al.Effects of Ti,O-MnS steel.Acta Mater.2012,60(5):2387 complex inclusions on the microstructure phase transformation of [42]Harrison P L,Farrar R A.Influence of oxygen-rich inclusions on heat affected zone in the welding of low carbon microalloyed the ya phase transformation in high-strength low-alloy (HS. steels.J Unir Sci Technol Beijing,2011,33(8):958 LA)steel weld metals.J Mater Sci,1981,16(8):2218 (王学敏，舒玮，郑超超，等.低碳微合金钢中Ti,0-MS型 [43]Wu K M,Inagawa Y,Enomoto M.Three-dimensional morpholo- 复合夹杂对焊接热影响区微观组织相变的影响.北京科技 gy of ferrite formed in association with inclusions in low-carbon 大学学报，2011,33(8)：958) steel.Mater Charact,2004,52(2):121 [30]Shang C J,Wang XX,Liu Q Y,et al.Weldability of low car- [44]Cheng L,Wu K M.New insights into intragranular ferrite in a bon and high niobium X80 pipeline steel and its engineering low-carbon low-alloy steel.Acta Mater,2009,57(13):3754 practice.Weld Pipe Tube,2012,35(12):11 [45]Wu K M.Three-dimensional analysis of acicular ferrite in a low- (尚成嘉，王晓香，刘清友，等.低碳高铌X80管线钢焊接 carbon steel containing titanium.Scripta Mater,2006,54(4): 性及工程实践.焊管，2012,35(12)：11) 569 [31]Bang K S,Jeong H S.Effect of nitrogen content on simulated [46]Enomoto M,Inagawa Y,Wu K M,et al.Three-dimensional ob- heat affected zone toughness of titanium containing thermome- servation of ferrite plate in low carbon steel weld.IS//Int, chanically controlled rolled steel.Mater Sci Technol,2002,18 2005,45(5):756 (6):649 (稷本正人，稻川庸平，吳開明，他.低炭素钢)溶接部！二生 [32]Loberg B,Nordgren A,Strid J,et al.The role of alloy composi- 成L大7xラ才卜T一卜)3次元觀察.铁匕鋼Ttsu-to- tion on the stability of nitrides in Ti-microalloyed steels during Hagane,2005,45(5):756) weld thermal cycles.Metall Trans A,1984,15(1):33 [47]Yang J R,Bhadeshia H K D H.Orientation relationships be- [33]Li X D,Ma X P,Subramanian S V,et al.Influence of prior aus- tween adjacent plates of acicular ferrite in steel weld deposits. tenite grain size on martensite-austenite constituent and toughness Mater Sci Technol,1989,5(1):93 in the heat affected zone of 700 MPa high strength linepipe steel. [48]Xiong Z H,Liu S L,Wang X M,et al.The contribution of in Mater Sci Eng A,2014,616:141 tragranular acicular ferrite microstructural constituent on impact李秀程等: 低合金钢焊接热影响区的微观组织和韧性研究进展 Trans A, 1991, 22(2): 489 [23] Kim N J, Thomas G. Effects of morphology on the mechanical behavior of a dual phase Fe / 2Si / 0. 1C steel. Metall Trans A, 1981, 12(3): 483 [24] Li X D, Ma X P, Suberamanian S V, et al. EBSD characteriza鄄 tion of secondary microcracks in the heat affected zone of a X100 pipeline steel weld joint. Int J Fract, 2015, 193(2): 131 [25] Li J, Wang H, Qu S Y, et al. Effect of welding thermal cycle parameters on the microstructure and properties in the heat affect鄄 ed zone of steel EH40 for high heat input welding. J Univ Sci Technol Beijing, 2012, 34(7): 788 (李静, 王华, 曲圣昱, 等. 焊接热循环参数对大线能量焊接 用钢 EH40 热影响区组织和性能的影响. 北京科技大学学 报, 2012, 34(7): 788) [26] Shi Y W, Han Z X. Effect of weld thermal cycle on microstruc鄄 ture and fracture toughness of simulated heat鄄affected zone for a 800 MPa grade high strength low alloy steel. J Mater Process Technol, 2008, 207(1): 30 [27] Guo J, Shang C J, Guo A M, et al. Effect of micro鄄zirconium addition on the carbonitride precipitation and austenite grain coarsening in Mn鄄鄄 Mo鄄鄄 Cu鄄鄄 Nb鄄鄄 B structure steel. J Univ Sci Technol Beijing, 2008, 30(11): 1236 (郭佳, 尚成嘉, 郭爱民, 等. 微量 Zr 添加对 Mn鄄鄄 Mo鄄鄄 Nb鄄鄄 Cu鄄鄄B 钢晶粒长大倾向性的影响. 北京科技大学学报, 2008, 30(11): 1236) [28] Wu H B, Hou M, Liang G L, et al. Effect of zirconium on the low鄄 temperature toughness of CGHAZ in F40 ship plates contai鄄 ning titanium. J Univ Sci Technol Beijing, 2012, 34(2): 137 (武会宾, 侯敏, 梁国俐, 等. 锆对含钛 F40 级船板钢粗晶 热影响区低温韧性的影响. 北京科技大学学报, 2012, 34 (2): 137 ) [29] Wang X M, Shu W, Zheng C C, et al. Effects of Ti xO鄄鄄 MnS complex inclusions on the microstructure phase transformation of heat affected zone in the welding of low carbon microalloyed steels. J Univ Sci Technol Beijing, 2011, 33(8): 958 (王学敏, 舒玮, 郑超超, 等. 低碳微合金钢中 Ti xO鄄鄄MnS 型 复合夹杂对焊接热影响区微观组织相变的影响. 北京科技 大学学报, 2011, 33(8): 958) [30] Shang C J, Wang X X, Liu Q Y, et al. Weldability of low car鄄 bon and high niobium X80 pipeline steel and its engineering practice. Weld Pipe Tube, 2012, 35(12): 11 (尚成嘉, 王晓香, 刘清友, 等. 低碳高铌 X80 管线钢焊接 性及工程实践. 焊管, 2012, 35(12): 11) [31] Bang K S, Jeong H S. Effect of nitrogen content on simulated heat affected zone toughness of titanium containing thermome鄄 chanically controlled rolled steel. Mater Sci Technol, 2002, 18 (6): 649 [32] Loberg B, Nordgren A, Strid J, et al. The role of alloy composi鄄 tion on the stability of nitrides in Ti鄄microalloyed steels during weld thermal cycles. Metall Trans A, 1984, 15(1): 33 [33] Li X D,Ma X P,Subramanian S V, et al. Influence of prior aus鄄 tenite grain size on martensite鄄austenite constituent and toughness in the heat affected zone of 700 MPa high strength linepipe steel. Mater Sci Eng A, 2014, 616: 141 [34] You Y, Wang X M, Shang C J. Influence of austenitizing tem鄄 perature on the microstructure and impact toughness of a high strength low alloy HSLA100 steel. Acta Metall Sin, 2012, 48 (11): 1290 (由洋, 王学敏, 尚成嘉. 奥氏体化温度对 HSLA100 高强度 低合金钢组织及冲击韧性的影响. 金属学报, 2012, 48 (11): 1290) [35] Lambert A, Garat X, Sturel T, et al. Application of acoustic emission to the study of cleavage fracture mechanism in a HSLA steel. Scripta Mater, 2000, 43(2): 161 [36] Fuluhara T, Kawata H, Morito S, et al. Variant selection in grain boundary nucleation of upper bainite. Metall Mater Trans A, 2008, 39(5): 1003 [37] Miao C L, Shang C J, Wang X M, et al. Microstructure and toughness of HAZ in X80 pipeline steel with high Nb content. Acta Metall Sin, 2010, 46(5): 541 (缪成亮, 尚成嘉, 王学敏, 等. 高 Nb X80 管线钢焊接热影 响区显微组织与韧性. 金属学报, 2010, 46(5): 541) [38] Yu Y N, Yang P, Qiang W J, et al. Materials Science Founda鄄 tion. 2nd Ed. Beijing: Higher Education Press, 2012 (余永宁, 杨平, 强文江, 等. 材料科学基础. 2 版. 北京: 高 等教育出版社, 2012) [39] Gourgues A F, Flower H M, Lindley T C. Electron backscatter鄄 ing diffraction study of acicular ferrite, bainite, and martensite steel microstructures. Mater Sci Technol, 2000, 16(1): 26 [40] You Y, Shang C J, Nie W J, et al. Investigation on the micro鄄 structure and toughness of coarse grained heat affected zone in X鄄鄄100 multi鄄phase pipeline steel with high Nb content. Mater Sci Eng A, 2012, 558: 692 [41] Takayama N, Miyamoto G, Furuhara T. Effects of transformation temperature on variant pairing of bainitic ferrite in low carbon steel. Acta Mater, 2012, 60(5): 2387 [42] Harrison P L, Farrar R A. Influence of oxygen鄄rich inclusions on the 酌寅琢 phase transformation in high鄄strength low鄄alloy ( HS鄄 LA) steel weld metals. J Mater Sci, 1981, 16(8): 2218 [43] Wu K M, Inagawa Y, Enomoto M. Three鄄dimensional morpholo鄄 gy of ferrite formed in association with inclusions in low鄄carbon steel. Mater Charact, 2004, 52(2): 121 [44] Cheng L, Wu K M. New insights into intragranular ferrite in a low鄄carbon low鄄alloy steel. Acta Mater, 2009, 57(13): 3754 [45] Wu K M. Three鄄dimensional analysis of acicular ferrite in a low鄄 carbon steel containing titanium. Scripta Mater, 2006, 54(4): 569 [46] Enomoto M, Inagawa Y, Wu K M, et al. Three鄄dimensional ob鄄 servation of ferrite plate in low carbon steel weld. ISIJ Int, 2005, 45(5): 756 (榎本正人, 稲川庸平, 呉開明, 他. 低炭素鋼瘴溶接部账生 成辗湛终支珠证秩肿朱ー秩瘴3 次元観察. 鉄杖鋼 Tetsu鄄鄄to鄄鄄 Hagan佴, 2005, 45(5): 756) [47] Yang J R, Bhadeshia H K D H. Orientation relationships be鄄 tween adjacent plates of acicular ferrite in steel weld deposits. Mater Sci Technol, 1989, 5(1): 93 [48] Xiong Z H, Liu S L, Wang X M, et al. The contribution of in鄄 tragranular acicular ferrite microstructural constituent on impact ·653·