Open Access
Subscription Access
Determination of Limit Drawing Ratio of SS 304 Steel Using Sheet Hydroforming Process with Female Die
Sheet hydroforming with female die process (SHF-D) is easily applicable without controlling of pressure and blank holder force paths compared to the hydroforming with punch process. Shallow parts can be produced easily with using SHF-D process which is used a lower cost production method in a wide variety of sectors. Limiting drawing ratio (LDR) is indication of formability of sheet metals is determined by using cylindrical punch die. In this study, for the first time, the LDRs of the SS 304 material with different thicknesses was determined experimentally by using the SHF-D instead of sheet hydroforming with punch unlike in the literature. FEA of SHF-D process has been performed. The results showed that relatively shallow sheet metal parts can be easily produced without there is no need to be optimizethe pressure and blank holder force paths by means of SHF-D using obtained LDR. It is important to know the forming limit in the SHF-D, since it can be a more economical production method, especially in the manufacture of shallow and large parts used in the automotive and aerospace industries and obtain more quality products than that from classical deep drawing process. By knowing these ratios, die design and parts manufacturing can be realized less costly. The LDR was experimentally obtained as 1.82 with using the SHF-Dfor the SS 304. The FEA results are in good agreement with experimental results. So, it is useful to analyze the FEA before designing the dies that will be used with the SHF-D.
Keywords
Hydromechanical Deep Drawing, Limiting Drawing Ratio, Sheet Hydro Forming with Female Die, SS 304 Stainless Steel.
User
Font Size
Information
- Altan T, Stamping J - An FMA Publication, 40-41 (2006)
- Zhang SH, Wang ZR, Xu Y, Wang ZT & Zhoua LX, J Mater Process Tech, 151 (2004) 237
- Singh H, Soc Manuf Eng, (2003)
- Lee, K & KimK, Indian J Sci and Tech 9 (2016) 1
- Guannan C & Feng L, Indian J Eng & Mat Sci, 17 (2010) 13
- Zhang SH, J Mat Process Tech, 91 (1999) 236
- Zampaloni M, Abedrabbo N & Pourboghrat F, Int J Mech Sci, 45 (2003) 1815
- Lang L, Danckert J & Nielsen KB, Proc Inst Mech Eng, Part B: J Eng Manuf, 218 (2004) 845
- Lang L, Danckert J & Nielsen KB, Int J Mach Tools & Manuf, 44 (2004) 649
- Kandil A, J of Mat Process Tech, 134 (1) (2003) 70
- Çetin M, Ugur A, Yigit O, Gokkaya H & Arcaklioglu E, Arabian J Sci and Eng, 40 (9) (2015) 2763
- Zhang SH, Jensen MR, Nielsen KB, Danckert J, Lang LH & Kang DC, J Mat Process Tech, 142 (2003) 544
- Lang LH, Wang ZR, Kang DC, Yuan SJ, Zhang SH, Danckert J & Nielsen KB, J Mat Process Tech, 151 (2004) 165
- Zhang SH & Danckert J, J of Mat Process Tech, 83 (1998) 14
- Shirizly A, Yossifon S & Tirosh J, Int J Mech Sci, 36 (1994) 121
- Tirosh J, Neuberger A & Shirizly A, Int J Mech Sci, 38 (1996)839
- Pennington JN, Mod Met, 52 (7) (1996) 32
- Hsu TC & Hsieh SJ, J Manuf Sci and Eng, 118 (1996) 434
- Yang DY, Kim JB & Lee DW, CIRP Annals, 44 (1995) 255
- Palumbo G, Pinto S, Sorgente D & Tricarico L, AIP Conf Proc, 712 (2004) 1875
- Gather U, Homberg W, Kleiner M, Klimmek C & Kuhnt S, Proc of the 7th Intl Conf on the Tech of Plast ICTP, Yokohama, Japan (2002) 1003
- Wu J, Balendra R & Qin Y, J Mat Process Tech, 145 (2004) 242
- Khandeparkar T & Liewald M, J Mat Process Tech, 202 (2008) 246
- Verma RK & Chandra S, J Mat Process Tech, 172 (2006) 218
- Hatipoğlu HA, Master Thesis, Middle East Technical University (2007)
- Dachang K, Yu C & Yongchao X, J Mat Process Tech, 166 (2005) 243
- Abedrabbo N, Zampaloni MA & Pourboghrat F, Int J Mech Sci, 47 (2005) 333
- Lang L, Li T, Zhou X, Danckert J & Nielsen KB, J Mat Process Tech, 187-188 (2007) 304
- Qin Y & Balendra R, J Mat Process Tech, 145 (2004) 163
- Palumbo G, Pinto S & Tricarico L, J Mat Process Tech, 155-156 (2004) 1435
- Önder E & Tekkaya AE, Int J Mach Tools & Manuf, 48 (2008) 532
Abstract Views: 118
PDF Views: 64