Greener manufacturing : superplastic-like forming
Conventional superplastic forming (SPF) is normally conducted at a slow forming rate (10−3 s−1 or slower) and high temperatures (typically 773 K or higher for aluminum alloys), which is not attractive for wider applications. Recently, SPF has revived as an attractive process in the automotive and ae...
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sg-ntu-dr.10356-958572020-03-07T13:22:16Z Greener manufacturing : superplastic-like forming Jarfors, Anders E. W. Liu, Jun Tan, Ming-Jen Lim, Samuel Chao Voon Fong, Kai-Soon Castagne, Sylvie School of Mechanical and Aerospace Engineering Conventional superplastic forming (SPF) is normally conducted at a slow forming rate (10−3 s−1 or slower) and high temperatures (typically 773 K or higher for aluminum alloys), which is not attractive for wider applications. Recently, SPF has revived as an attractive process in the automotive and aerospace industries, especially for forming of excellent precision, large, and complex-shaped work pieces. A hybrid superplastic forming process has exploited the usage of superplastic forming for faster times, lower temperatures, and also for use by non-superplastic materials by designing a process that combines stamping and gas blow forming in one operation to establish an energy-saving technology. With recent developments in these areas, the light-weight, yet inexpensive aluminum alloys are promising candidates for green manufacturing. In comparison with the conventional SPF process, the forming time has been shortened (typically from 30 min to 8 min), and the forming temperature has been lowered down (from 773 K to 673 K). Furthermore, as a greener manufacturing process, it uses the non-superplastic grade materials, which is more compatible with existing manufacturing processes with less material preparation time and expense cost. 2013-07-15T04:17:29Z 2019-12-06T19:22:24Z 2013-07-15T04:17:29Z 2019-12-06T19:22:24Z 2012 2012 Journal Article Liu, J., Tan, M. J., Jarfors, A. E. W., Lim, S. C. V., Fong, K. S., & Castagne, S. (2012). Greener manufacturing: Superplastic-like forming. Journal of Physics: Conference Series, 379, 012034. 1742-6596 https://hdl.handle.net/10356/95857 http://hdl.handle.net/10220/11397 10.1088/1742-6596/379/1/012034 en Journal of physics : conference series © 2012 IOP Publishing. |
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Conventional superplastic forming (SPF) is normally conducted at a slow forming rate (10−3 s−1 or slower) and high temperatures (typically 773 K or higher for aluminum alloys), which is not attractive for wider applications. Recently, SPF has revived as an attractive process in the automotive and aerospace industries, especially for forming of excellent precision, large, and complex-shaped work pieces. A hybrid superplastic forming process has exploited the usage of superplastic forming for faster times, lower temperatures, and also for use by non-superplastic materials by designing a process that combines stamping and gas blow forming in one operation to establish an energy-saving technology. With recent developments in these areas, the light-weight, yet inexpensive aluminum alloys are promising candidates for green manufacturing. In comparison with the conventional SPF process, the forming time has been shortened (typically from 30 min to 8 min), and the forming temperature has been lowered down (from 773 K to 673 K). Furthermore, as a greener manufacturing process, it uses the non-superplastic grade materials, which is more compatible with existing manufacturing processes with less material preparation time and expense cost. |
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School of Mechanical and Aerospace Engineering |
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School of Mechanical and Aerospace Engineering Jarfors, Anders E. W. Liu, Jun Tan, Ming-Jen Lim, Samuel Chao Voon Fong, Kai-Soon Castagne, Sylvie |
| format |
Article |
| author |
Jarfors, Anders E. W. Liu, Jun Tan, Ming-Jen Lim, Samuel Chao Voon Fong, Kai-Soon Castagne, Sylvie |
| spellingShingle |
Jarfors, Anders E. W. Liu, Jun Tan, Ming-Jen Lim, Samuel Chao Voon Fong, Kai-Soon Castagne, Sylvie Greener manufacturing : superplastic-like forming |
| author_sort |
Jarfors, Anders E. W. |
| title |
Greener manufacturing : superplastic-like forming |
| title_short |
Greener manufacturing : superplastic-like forming |
| title_full |
Greener manufacturing : superplastic-like forming |
| title_fullStr |
Greener manufacturing : superplastic-like forming |
| title_full_unstemmed |
Greener manufacturing : superplastic-like forming |
| title_sort |
greener manufacturing : superplastic-like forming |
| publishDate |
2013 |
| url |
https://hdl.handle.net/10356/95857 http://hdl.handle.net/10220/11397 |
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