Experimental Formability Study of Ti6Al4V Sheet Metal using Friction Stir Heat Assisted Single Point Incremental Forming Process

被引：0

作者：

Golakiya V.D. ^{[1
]}

Chudasama M.K. ^{[2
]}

机构：

[1] Mechanical Engineering Department, Dr S& S S Ghandhy Government Engineering College Surat, Gujarat Technology University, Gujarat

[2] Mechanical Engineering Department, Government Engineering College Surat, Gujarat Technology University, Gujarat

来源：

International Journal of Engineering, Transactions B: Applications | 2022年 / 35卷 / 03期

关键词：

Formability; Friction Stir Incremental Forming; Single Point Incremental Forming; Ti6Al4V;

D O I：

10.5829/ije.2022.35.03c.08

中图分类号：

学科分类号：

摘要：

Single Point Incremental Forming (SPIF) process is a novel approach of flexible sheet metal forming method in which 3D component can be allowed to form. The process is characterized by die less flexible, lower lead time and higher formability as compare to conventional stamping process. The present work involves set of experiments of 1 mm thick Ti6Al4V sheet using the friction stir SPIF process at room temperature and investigating the effect of wall angle, speed, feed and step size on formability of the sheet. The results revealed that, the maximum formability of frustum cone specimen was obtained at wall angle of 45° and wall angle is the most significant parameter. With an increase in wall angle and feed, the formability of sheet blank decreases while increases in tool rotational speed, the formability found to increase. In addition, it is also observed that, there was no significant influence of step size on formability of sheet. © 2022 Materials and Energy Research Center. All rights reserved.

引用

页码：560 / 566

页数：6

共 19 条

[11] Fan G., Gao L., Hussain G., Wu Z.J.I.J.o.M.T., Manufacture, Electric hot incremental forming: A novel technique, International Journal of Machine Tools and Manufacture, 48, 15, pp. 1688-1692, (2008)
[12] Fan G., Sun Fengtao, Meng X., Gao Lin, Tong G., Electric hot incremental forming of ti-6al-4v titanium sheet, The International Journal of Advanced Manufacturing Technology, 49, 9-12, pp. 941-947, (2010)
[13] Rahmani F., Seyedkashi S., Hashemi S.J.I.J.o.E., Experimental study on warm incremental tube forming of aa6063 aluminum tubes, International Journal of Engineering, Transactions C: Aspects, 33, 9, pp. 1773-1779, (2020)
[14] Xu D., Lu B., Cao T., Zhang H., Chen J., Long H., Cao J.J.M., Enhancement of process capabilities in electrically-assisted double sided incremental forming, Materials & Design, 92, pp. 268-280, (2016)
[15] Buffa G., Campanella D., Fratini L.J.T.I.J.o.A.M.T., On the improvement of material formability in spif operation through tool stirring action, The International Journal of Advanced Manufacturing Technology, 66, 9-12, pp. 1343-1351, (2013)
[16] Otsu M., Katayama Y., Muranaka T., Effect of difference of tool rotation direction on forming limit in friction stir incremental forming, Key Engineering Materials, Trans Tech Publ, 622, pp. 390-397, (2014)
[17] Ambrogio G., Gagliardi F.J.T.I.J.o.A.M.T., Temperature variation during high speed incremental forming on different lightweight alloys, The International Journal of Advanced Manufacturing Technology, 76, 9-12, pp. 1819-1825, (2015)
[18] Chausov M., Pylypenko A., Berezin V., Volyanska K., Maruschak P., Hutsaylyuk V., Markashova L., Nedoseka S., Menou A.J.T., Influence of dynamic non-equilibrium processes on strength and plasticity of materials of transportation systems, Transport, 33, 1, pp. 231-241, (2018)
[19] Grun P., Uheida E., Lachmann L., Dimitrov D., Oosthuizen G.J.T.I.J.o.A.M.T., Formability of titanium alloy sheets by friction stir incremental forming, The International Journal of Advanced Manufacturing Technology, 99, 5, pp. 1993-2003, (2018)

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