<p>In this study, microstructure evolution and the interface bond of linear friction welded dissimilar Ti<sub>2</sub>AlNb/Ti60 joint were studied. The relationship of microstructure to tensile and impact strength of the joint were analyzed. The results show that continuous dynamic recrystallization occurred on two weld zones during welding, forming equiaxed fine grains which were smaller than those of the two base metals. On the Ti60 side thermo-mechanically affected zone, α grains were elongated under the high temperature and shear force effects; while on the Ti<sub>2</sub>AlNb side, the large B2 grains were elongated where a large number of O phases were dissolved. In the Ti<sub>2</sub>AlNb side heat-affected zone, the B2 grains were not deformed, and the O phases inside B2 grains were decomposed, as the welding temperature was lower than that in the TMAZ. The interface metallurgical bond was achieved through mutual diffusion of Ti, Al, and Nb, producing an element transition layer of 1.54&#xa0;µm composed of TiAl<sub>3</sub> and NbAl<sub>3</sub> intermetallic compounds. The tensile strength of the joint was 920&#xa0;MPa, which is 97.9% of the Ti60 BM, but elongation was 1.7%. Failure of joint during tensile strength testing was located at the junction of Ti<sub>2</sub>AlNb side TMAZ and HAZ, where the O phases dissolved and there was no dynamic recrystallization of the B2 grains. The impact energy at interface was measured to be 13.0&#xa0;J/cm<sup>2</sup>, which is higher than that of Ti<sub>2</sub>AlNb BM, as the toughness of the interface is better than that of Ti<sub>2</sub>AlNb BM, which is related to TiAl<sub>3</sub> and NbAl<sub>3</sub> intermetallic compounds forming at the interface element transition layer.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Insights into microstructure evolution and mechanical properties of linear friction welding of dissimilar Ti2AlNb and Ti60 alloys

  • Jiaying Li,
  • Tiejun Ma,
  • Hongbo Zhang,
  • Xiawei Yang,
  • Wenya Li,
  • Achilles Vairis

摘要

In this study, microstructure evolution and the interface bond of linear friction welded dissimilar Ti2AlNb/Ti60 joint were studied. The relationship of microstructure to tensile and impact strength of the joint were analyzed. The results show that continuous dynamic recrystallization occurred on two weld zones during welding, forming equiaxed fine grains which were smaller than those of the two base metals. On the Ti60 side thermo-mechanically affected zone, α grains were elongated under the high temperature and shear force effects; while on the Ti2AlNb side, the large B2 grains were elongated where a large number of O phases were dissolved. In the Ti2AlNb side heat-affected zone, the B2 grains were not deformed, and the O phases inside B2 grains were decomposed, as the welding temperature was lower than that in the TMAZ. The interface metallurgical bond was achieved through mutual diffusion of Ti, Al, and Nb, producing an element transition layer of 1.54 µm composed of TiAl3 and NbAl3 intermetallic compounds. The tensile strength of the joint was 920 MPa, which is 97.9% of the Ti60 BM, but elongation was 1.7%. Failure of joint during tensile strength testing was located at the junction of Ti2AlNb side TMAZ and HAZ, where the O phases dissolved and there was no dynamic recrystallization of the B2 grains. The impact energy at interface was measured to be 13.0 J/cm2, which is higher than that of Ti2AlNb BM, as the toughness of the interface is better than that of Ti2AlNb BM, which is related to TiAl3 and NbAl3 intermetallic compounds forming at the interface element transition layer.