The Formability and Elongation of Aluminum Alloys AA5083 and AA3003 for Micro-Truss Sandwiches Manufacturing

Tawfeeq, Arwa F.; Barnett, Matthew R.

doi:10.30684/etj.v38i9A.556

	The Formability and Elongation of Aluminum Alloys AA5083 and AA3003 for Micro-Truss Sandwiches Manufacturing
Engineering and Technology Journal
Article 14, Volume 38, 9A, 2020, Pages 1396-1405 PDF (1.13 M)
Document Type: Research Paper
DOI: 10.30684/etj.v38i9A.556
Authors
Arwa F. Tawfeeq^* ¹; Matthew R. Barnett²
¹Department of Materials Engineering, University of Technology, Baghdad, Iraq
²Institute for Frontier Materials, Deakin University, Geelong, Australia
Abstract
The development in the manufacturing of micro-truss structures has demonstrated the effectiveness of brazing for assembling these sandwiches, which opens new opportunities for cost-effective and high-quality truss manufacturing. An evolving idea in micro-truss manufacturing is the possibility of forming these structures in different shapes with the aid of elevated temperature. This work investigates the formability and elongation of aluminum alloy sheets typically used for micro-truss manufacturing, namely AA5083 and AA3003. Tensile tests were performed at a temperature in the range of 25-500 ○C and strain rate in the range of 2x10-4 -10-2 s-1. The results showed that the clad layer in AA3003 exhibited an insignificant effect on the formability and elongation of AA3003. The formability of the two alloys was improved significantly with values of m as high as 0.4 and 0.13 for AA5083 and AA3003 at 500 °C. While the elongation of both AA5083 and AA3003 was improved at a higher temperature, the elongation of AA5083 was inversely related to strain rate. It was concluded that the higher the temperature is the better the formability and elongation of the two alloys but at the expense of work hardening. This suggests a trade-off situation between formability and strength.
Keywords
Aluminum alloy 5083; aluminum alloy 3003; micro-truss; tensile; formability

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