分别用搅拌摩擦焊(FSW)和超声辅助搅拌摩擦焊(UAFSW)两种方法对1.8 mm 2024-T4铝合金进行对接焊接,并对焊缝的微观组织和力学性能进行了分析比较。结果表明:FSW和UAFSW两种方法焊接的1.8 mm 2024-T4铝合金均可得到成型美观、内部无缺陷...分别用搅拌摩擦焊(FSW)和超声辅助搅拌摩擦焊(UAFSW)两种方法对1.8 mm 2024-T4铝合金进行对接焊接,并对焊缝的微观组织和力学性能进行了分析比较。结果表明:FSW和UAFSW两种方法焊接的1.8 mm 2024-T4铝合金均可得到成型美观、内部无缺陷的焊缝,但UAFSW的焊缝力学性能优于FSW;在其它条件相同时,FSW的焊接强度达母材的74.14%,UAFSW的焊接强度可达到母材82.83%。金相组织分析表明,UAFSW焊缝区组织比FSW的更均匀,晶粒更细小。展开更多
The effect of strain hardening and strain softening behavior of flow stress changing with temperature on welding residual stress, plastic strain and welding distortion of ATN0 1-T4 aluminum alloy was studied by finite...The effect of strain hardening and strain softening behavior of flow stress changing with temperature on welding residual stress, plastic strain and welding distortion of ATN0 1-T4 aluminum alloy was studied by finite simulation method. The simulation results show that the weld seam undergoes strain hardening in the temperature range of 180-250 ℃, however, it exhibits strain softening at temperature above 250 ℃ during welding heating and cooling process. As a result, the strain hardening and strain softening effects counteract each other, introducing slightly influence on the welding residual stress, residual plastic strain and distortion. The welding longitudinal residual stress was determined by ultrasonic stress measurement method for the flat plates of A7N01-T4 aluminum alloy. The simulation results are well accordant with test ones.展开更多
文摘分别用搅拌摩擦焊(FSW)和超声辅助搅拌摩擦焊(UAFSW)两种方法对1.8 mm 2024-T4铝合金进行对接焊接,并对焊缝的微观组织和力学性能进行了分析比较。结果表明:FSW和UAFSW两种方法焊接的1.8 mm 2024-T4铝合金均可得到成型美观、内部无缺陷的焊缝,但UAFSW的焊缝力学性能优于FSW;在其它条件相同时,FSW的焊接强度达母材的74.14%,UAFSW的焊接强度可达到母材82.83%。金相组织分析表明,UAFSW焊缝区组织比FSW的更均匀,晶粒更细小。
基金Project(2007DFR70070) supported by China-Russia Government-to-Government Scientific and Technical Cooperation Foundation
文摘The effect of strain hardening and strain softening behavior of flow stress changing with temperature on welding residual stress, plastic strain and welding distortion of ATN0 1-T4 aluminum alloy was studied by finite simulation method. The simulation results show that the weld seam undergoes strain hardening in the temperature range of 180-250 ℃, however, it exhibits strain softening at temperature above 250 ℃ during welding heating and cooling process. As a result, the strain hardening and strain softening effects counteract each other, introducing slightly influence on the welding residual stress, residual plastic strain and distortion. The welding longitudinal residual stress was determined by ultrasonic stress measurement method for the flat plates of A7N01-T4 aluminum alloy. The simulation results are well accordant with test ones.