期刊文献+

Numerical modeling of friction stir welding using the tools with polygonal pins 被引量:5

Numerical modeling of friction stir welding using the tools with polygonal pins
下载PDF
导出
摘要 Friction stir welding using the tools with polygonal pins is often found to improve the mechanical strength of weld joint in comparison to the tools with circular pins. However, the impacts of pin profile on the peak temperature, tool torque and traverse force, and the resultant mechanical stresses experienced by the tool have been rarely reported in a systematic manner. An estimation of the rate of heat generation for the tools with polygonal pins is challenging due to their non-axisymmetric cross-section about the tool axis. A novel methodology is presented to analytically estimate the rate of heat generation for the tools with polygonal pins. A three-dimensional heat transfer analysis of friction stir welding is carried out using finite element method. The computed temperature field from the heat transfer model is used to estimate the torque, traverse force and the mechanical stresses experienced by regular triangular, square, pentagon and hexagon pins following the principles of solid mechanics. The computed results show that the peak temperature experienced by the tool pin increases with the number of pin sides. However, the resultant maximum shear stress experienced by the pin reduces from the triangular to hexagonal pins. Friction stir welding using the tools with polygonal pins is often found to improve the mechanical strength of weld joint in comparison to the tools with circular pins. However, the impacts of pin profile on the peak temperature, tool torque and traverse force, and the resultant mechanical stresses experienced by the tool have been rarely reported in a systematic manner. An estimation of the rate of heat generation for the tools with polygonal pins is challenging due to their non-axisymmetric cross-section about the tool axis. A novel methodology is presented to analytically estimate the rate of heat generation for the tools with polygonal pins, A three-dimensional heat transfer analysis of friction stir welding is carried out using finite element method. The computed temperature field from the heat transfer model is used to estimate the torque, traverse force and the mechanical stresses experienced by regular triangular, square, pentagon and hexagon pins following the principles of solid mechanics. The computed results show that the peak temperature experienced by the tool pin increases with the number of pin sides. However, the resultant maximum shear stress experienced by the pin reduces from the triangular to hexagonal pins.
出处 《Defence Technology(防务技术)》 SCIE EI CAS CSCD 2015年第3期229-236,共8页 Defence Technology
关键词 搅拌摩擦焊接 多边形 管脚 数值模拟 摩擦搅拌焊接 机械强度 峰值温度 机械应力 Friction stir welding Polygonal tool pin Aluminum alloy Numerical model Tool durability
  • 相关文献

参考文献35

  • 1Thomas WM, Nicholas ED, Friction stir welding for the transportation industries, Mater Des 1997; 18:269-73,.
  • 2Rowe CED, Thomas WM, Advances in tooling materials for friction stir welding, Technical report Cambridge, UK: TWI; 2005,.
  • 3Rai R, De A, Bhadeshia HKDH, DebRoy T Review: friction stir welding tools, Sci Technol Weld Join 2011; 16:325-42,.
  • 4Threadgill PL, Leonard AJ, Shercliff HR, Withers PI, Friction stir welding of aluminum alloys, Int Mater Rev 2009;54:49-93,.
  • 5Nandan R, DebRoy T, Bhadeshia HKDR Recent advances in friction-stir welding - process, weldment structure and properties. Prog Mater Sci 2008;53:980-1023.
  • 6Colegrove PA, Shercliff HR. Development of Trivex friction stir welding tool Part I - two-dimensional flow modeling and experimental validation. Sci Technol Weld Join 2004;9:345-51.
  • 7Colegrove PA, Shercliff HR. Two-dimensional CFD modeling of flow round profiled FSW tooling. Sci Technol Weld Join 2004;9:483-92.
  • 8Colegrove PA, Shercliff HR. CFD modeling of friction stir welding of thick plate 7449 aluminium allay. Sci Technol Weld Join 2006; II :429-41.
  • 9Zettler R, Lomolino S, dos Santos JF, Donath T, Beckmann F, Lippman T, et al. Effect of tool geometry and process parameters on material flow in FSW of an AA2024-T35I alloy. Weld World 2005;49:41-6.
  • 10Hattingh DG, Blignault C, van Niekerk TI, James MN. Characterization of the influences of FSW tool geometry on welding forces and weld tensile strength using an instrumented tool. J Mater Process Technol 2008;203:46-57.

同被引文献25

引证文献5

二级引证文献31

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部