焊接与连接领域科学基金资助浅析与发展趋势
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摘要
介绍了焊接与连接领域国家自然科学基金2018年度的申请情况,并分析了该领域近三年的资助情况和资助项目成果情况及热点研究方向.对焊接新方法、新技术与新原理、界面冶金行为与调控机制、焊接结构设计与可靠性评估、电弧增材制造形性调控机制等方向的基础科学问题进行了梳理,探讨了未来重点发展方向.
This article introduced the information of NSFC applications in the field of welding and joining in 2018,including the funding situation and the outcomes of the funded projects in the past three years, as well as the hot research directions in this field. The fundamental scientific problems in new methods, technologies and principles of welding, interface metallurgical behaviors and control mechanisms, welding structure design and reliability evaluation, and control mechanisms of wire arc additive manufacturing were also reviewed, based on which the main research directions in the future are discussed.
This article introduced the information of NSFC applications in the field of welding and joining in 2018,including the funding situation and the outcomes of the funded projects in the past three years, as well as the hot research directions in this field. The fundamental scientific problems in new methods, technologies and principles of welding, interface metallurgical behaviors and control mechanisms, welding structure design and reliability evaluation, and control mechanisms of wire arc additive manufacturing were also reviewed, based on which the main research directions in the future are discussed.
引文
[1]Singh K,Singh G,Singh H.Review on friction stir welding of magnesium alloys[J].Journal of Magnesium and Alloys,2018,6:399-416.
[2]马宗义,商乔,倪丁瑞,等.镁合金搅拌摩擦焊接的研究现状与展望[J].金属学报,2018,54(11):1597-1617.Ma Zongyi,Shang Qiao,Ni Dingrui,et al.Friction stir welding of magnesium alloys:a review[J].Acta Metallurgica Sinica,2018,54(11):1597-1617.
[3]Ni Z L,Ye F X.Ultrasonic spot welding of aluminum alloys:a review[J].Journal of Manufacturing Process,2018,35:580-594.
[4]姚燕生,王园园,李修宇.激光复合焊接技术综述[J].热加工工艺,2014,43(9):16-20,24.Yao Yansheng,Wang Yuanyuan,Li Xiuyu.Review on laser hybrid welding technology[J].Hot Working Technology,2014,43(9):16-20,24.
[5]赵耀邦,成群林,徐爱杰,等.激光-电弧复合焊接技术的研究进展及应用现状[J].航天制造技术,2014,4:11-14.Zhao Yaobang,Cheng Qunlin,Xu Aijie,et al.Recent advances in research and application of laser-arc hybrid welding technology[J].Aerospace Manufacturing Technology,2014,4:11-14.
[6]Wan L,Huang Y X.Friction stir welding of dissimilar aluminum alloys and steels:a review[J].International Journal of Advanced Manufacturing Technology,2018,99(5-8):1781-1811.
[7]齐铂金,范霁康,刘方军.脉冲束流电子束焊接技术综述[J].航空制造技术,2015,11:26-30.Qi Bojin,Fan Jikang,Liu Fangjun.An overview of pulsed electron beam welding technology[J].Aviation Manufacturing Technology,2015,11:26-30.
[8]Chen H Y,Cao J,Song X G,et al.Contributions of atomic diffusion and plastic deformation to the plasma surface activation assisted diffusion bonding of zirconium-based bulk metallic glass[J].Applied Physics Letters,2012,100(21):211602.
[9]Song X G,Cao J,Chen H Y,et al.Brazing TiAl intermetallics using TiNi-V eutectic brazing alloy[J].Materials Science and Engineering:A,2012,551:133-139.
[10]Yang Z W,Zhang L X,He P,et al.Interfacial structure and fracture behavior of Tib whisker-reinforced C/SiC composite and tial joints brazed with Ti-Ni-B brazing alloy[J].Materials Science and Engineering:A,2012,532:471-475.
[11]Xiong H P,Chen B,Pan Y,et al.Joining of Cf/SiC composite with a Cu-Au-Pd-V brazing filler and interfacial reactions[J].Journal of the European Ceramic Society,2014,34(6):1481-1486.
[12]Zhou Y.微连接与纳米连接[M].田艳红,王春青,刘威,译.北京:机械工业出版社,2011.
[13]Lin L C,Liu L,Musselman K,et al.Plasmonic-radiation-enhanced metal oxide nanowire heterojunctions for controllable multilevel memory[J].Advanced Functional Materials,2016,26(33):5979-5986.
[14]Xu J J,Gilles P,Duan Y G.Simulation and validation of weldingresidual stresses based on non-linear mixed hardening model[J].Strain,2012,48(5):406-414.
[15]Li S,Ren S D,Zhang Y B,et al.Numerical investigation of formation mechanism of welding residual stress in P92 steel multi-pass joints[J].Journal of Materials Processing Technology,2017,244:240-252.
[16]Zhao L,Xu L Y,Nikbin K.Predicting failure modes in creep and creep-fatigue crack growth using a random grain/grain boundary idealised microstructure meshing system[J].Materials Science and Engineering:A,2017,704:274-286.
[17]Zhao L,Xu L Y,Gao Z F,et al.Characterization crack growth behavior in creep-fatigue loading conditions through different specimen geometries[J].International Journal of Mechanical Sciences,2018,145:246-257.
[18]王东坡,龚宝明,吴世品,等.焊接接头与结构疲劳延寿技术研究进展综述[J].华东交通大学学报,2016,33(6):1-14.Wang Dongpo,Gong Baoming,Wu Shipin,et al.Research review on fatigue life improvement of welding joint and structure[J].Journal of East China Jiaotong University,2016,33(6):1-14.
[19]Ye Y,Zou G S,Long W M,et al.Diffusion brazing repair of In738 superalloy with crack-like defect:microstructure and tensile properties at high temperatures[J].Science and Technology of Welding and Joining,2019,24(1):52-62.
[20]Li H Z,Jing H Y,Xu L Y,et al.Life,dislocation evolution and fracture mechanism of a 41Fe-25.5Ni-23.5Cr alloy during low cycle fatigue at 700 degrees C[J].International Journal of Fatigue,2019,119:20-33.
[21]Wu D Q,Jing H Y,Xu L Y,et al.Enhanced models of creep crack initiation prediction coupled the stress-regime creep properties and constraint effect[J].European Journal of MechanicsA/Solids,2019,74:145-159.
[22]Wu D Q,Jing H Y,Xu L Y,et al.Analytical approaches of creep crack initiation prediction coupled with the residual stress and constraint effect[J].European Journal of Mechanics A/Solids,2018,71:1-15.
[23]王凯博,吕耀辉,徐滨士,等.基于焊接的镍基高温合金增材再制造技术综述[J].装甲兵工程学院学报,2016,30(1):81-86.Wang Kaibo,Lv Yaohui,Xu Binshi,et al.Review of the additive remanufacturing technology of Ni-based superalloy based on welding[J].Journal of Academy of Armored Force Engineering,2016,30(1):81-86.
[2]马宗义,商乔,倪丁瑞,等.镁合金搅拌摩擦焊接的研究现状与展望[J].金属学报,2018,54(11):1597-1617.Ma Zongyi,Shang Qiao,Ni Dingrui,et al.Friction stir welding of magnesium alloys:a review[J].Acta Metallurgica Sinica,2018,54(11):1597-1617.
[3]Ni Z L,Ye F X.Ultrasonic spot welding of aluminum alloys:a review[J].Journal of Manufacturing Process,2018,35:580-594.
[4]姚燕生,王园园,李修宇.激光复合焊接技术综述[J].热加工工艺,2014,43(9):16-20,24.Yao Yansheng,Wang Yuanyuan,Li Xiuyu.Review on laser hybrid welding technology[J].Hot Working Technology,2014,43(9):16-20,24.
[5]赵耀邦,成群林,徐爱杰,等.激光-电弧复合焊接技术的研究进展及应用现状[J].航天制造技术,2014,4:11-14.Zhao Yaobang,Cheng Qunlin,Xu Aijie,et al.Recent advances in research and application of laser-arc hybrid welding technology[J].Aerospace Manufacturing Technology,2014,4:11-14.
[6]Wan L,Huang Y X.Friction stir welding of dissimilar aluminum alloys and steels:a review[J].International Journal of Advanced Manufacturing Technology,2018,99(5-8):1781-1811.
[7]齐铂金,范霁康,刘方军.脉冲束流电子束焊接技术综述[J].航空制造技术,2015,11:26-30.Qi Bojin,Fan Jikang,Liu Fangjun.An overview of pulsed electron beam welding technology[J].Aviation Manufacturing Technology,2015,11:26-30.
[8]Chen H Y,Cao J,Song X G,et al.Contributions of atomic diffusion and plastic deformation to the plasma surface activation assisted diffusion bonding of zirconium-based bulk metallic glass[J].Applied Physics Letters,2012,100(21):211602.
[9]Song X G,Cao J,Chen H Y,et al.Brazing TiAl intermetallics using TiNi-V eutectic brazing alloy[J].Materials Science and Engineering:A,2012,551:133-139.
[10]Yang Z W,Zhang L X,He P,et al.Interfacial structure and fracture behavior of Tib whisker-reinforced C/SiC composite and tial joints brazed with Ti-Ni-B brazing alloy[J].Materials Science and Engineering:A,2012,532:471-475.
[11]Xiong H P,Chen B,Pan Y,et al.Joining of Cf/SiC composite with a Cu-Au-Pd-V brazing filler and interfacial reactions[J].Journal of the European Ceramic Society,2014,34(6):1481-1486.
[12]Zhou Y.微连接与纳米连接[M].田艳红,王春青,刘威,译.北京:机械工业出版社,2011.
[13]Lin L C,Liu L,Musselman K,et al.Plasmonic-radiation-enhanced metal oxide nanowire heterojunctions for controllable multilevel memory[J].Advanced Functional Materials,2016,26(33):5979-5986.
[14]Xu J J,Gilles P,Duan Y G.Simulation and validation of weldingresidual stresses based on non-linear mixed hardening model[J].Strain,2012,48(5):406-414.
[15]Li S,Ren S D,Zhang Y B,et al.Numerical investigation of formation mechanism of welding residual stress in P92 steel multi-pass joints[J].Journal of Materials Processing Technology,2017,244:240-252.
[16]Zhao L,Xu L Y,Nikbin K.Predicting failure modes in creep and creep-fatigue crack growth using a random grain/grain boundary idealised microstructure meshing system[J].Materials Science and Engineering:A,2017,704:274-286.
[17]Zhao L,Xu L Y,Gao Z F,et al.Characterization crack growth behavior in creep-fatigue loading conditions through different specimen geometries[J].International Journal of Mechanical Sciences,2018,145:246-257.
[18]王东坡,龚宝明,吴世品,等.焊接接头与结构疲劳延寿技术研究进展综述[J].华东交通大学学报,2016,33(6):1-14.Wang Dongpo,Gong Baoming,Wu Shipin,et al.Research review on fatigue life improvement of welding joint and structure[J].Journal of East China Jiaotong University,2016,33(6):1-14.
[19]Ye Y,Zou G S,Long W M,et al.Diffusion brazing repair of In738 superalloy with crack-like defect:microstructure and tensile properties at high temperatures[J].Science and Technology of Welding and Joining,2019,24(1):52-62.
[20]Li H Z,Jing H Y,Xu L Y,et al.Life,dislocation evolution and fracture mechanism of a 41Fe-25.5Ni-23.5Cr alloy during low cycle fatigue at 700 degrees C[J].International Journal of Fatigue,2019,119:20-33.
[21]Wu D Q,Jing H Y,Xu L Y,et al.Enhanced models of creep crack initiation prediction coupled the stress-regime creep properties and constraint effect[J].European Journal of MechanicsA/Solids,2019,74:145-159.
[22]Wu D Q,Jing H Y,Xu L Y,et al.Analytical approaches of creep crack initiation prediction coupled with the residual stress and constraint effect[J].European Journal of Mechanics A/Solids,2018,71:1-15.
[23]王凯博,吕耀辉,徐滨士,等.基于焊接的镍基高温合金增材再制造技术综述[J].装甲兵工程学院学报,2016,30(1):81-86.Wang Kaibo,Lv Yaohui,Xu Binshi,et al.Review of the additive remanufacturing technology of Ni-based superalloy based on welding[J].Journal of Academy of Armored Force Engineering,2016,30(1):81-86.