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Abstract

The demand for new methods to reduce CO₂ emission by reusing metal scrap has increased recently. This study deals with a new recycling technique utilizing a friction stir consolidation process. In this work, copper was directly recycled from machining chips in the solid-state form without any remelting to reduce environmental pollution and to increase the economic value of the waste material. During the process, copper chips were loaded into the chamber; then, a rotating tool was plunged into the chips at a specified rotational speed and feed rate. Due to the huge amount of heat generated, the softened material was compressed and synthesized to form a consolidated part. Microstructure, mechanical properties, and electrical conductivity of the finished samples were evaluated and compared with as-received material. Also, a numerical model was implemented to predict the evolution of the main field variables, including temperature, density, and strain.

Keywords

Friction stir consolidation copper recycling microstructure hardness electrical conductivity

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References

Dornfeld

Linke

BS.

Leveraging technology for a sustainable world. In: 19th CIRP conference on life cycle engineering, Berkeley, CA, USA, 23--25 May 2012.

Wright

Jahanshahi

Jorgensen

, et al. Is metal recycling sustainable? In: Green processing 2002 – proceedings: international conference on the sustainable processing of minerals, 2002, pp. 335–341.

EAA. Environmental profile report for the European Aluminium Industry April 2013 – data for the year 2010 Life Cycle Inventory data for aluminium production and transformation processes in Europe, https://european-aluminium.eu/media/1329/environmental-profile-report-for-the-european-aluminium-industry.pdf (2013, accessed 11 April 2013).

Wen

LH and

XL.

Mechanical properties and fracture behavior of Mg–2.4Nd–0.6Zn–0.6Zr alloys fabricated by solid recycling process. J Mater Process Technol 2009; 209: 2128–2134.

Chino

Jae-Seol

Nakaura

, et al. Mechanical properties of Mg–Al–Ca alloy recycled by solid–state recycling. Mater Trans 2005; 46: 2592–2595.

Ying

Zheng

, et al. Recycling of AZ91 Mg alloy through consolidation of machined chips by extrusion and ECAP. Trans Nonferrous Met Soc China 2010; 20.

Ding

Shen

Behnagh

, et al. Experimental analysis and microstructure modeling of friction stir extrusion of magnesium chips. J Manuf Sci Eng 2015; 138: 041008.

Catalini

Kaoumi

Reynolds

, et al. Friction consolidation of MA956 powder. J Nucl Mater 442: S112–S118.

Catalini

Kaoumi

Reynolds

, et al. Dispersoid distribution and microstructure in Fe-Cr-Al ferritic oxide dispersion-strengthened alloy prepared by friction consolidation. Metall Mater Trans A 2015; 46: 4730–4739.

10.

Whalen

Jana

Catalini

, et al. Friction consolidation processing of n-type bismuth-telluride thermoelectric material. J Electron Mater 2016; 45: 3390–3399.

11.

Narvan

Abdi Behnagh

Shen

, et al. Shear compaction processing of SiC nanoparticles reinforced magnesium composites directly from magnesium chips. J Manuf Process 2016; 22: 39–48.

12.

Behnagh

Fathi

Yeganeh

, et al. Production of seamless tube from aluminum machining chips via double-step friction stir consolidation. Int J Adv Manuf Technol 2019; 104: 4769–4777.

13.

Hwang

Joun

MS.

Analysis of hot-strip rolling by a penalty rigid-viscoplastic finite element method. Int J Mech Sci 1992; 34: 971–984.

14.

Lee

Jung

SB.

The joint properties of copper by friction stir welding. Mater Lett 2004; 58: 1041–1046.

15.

Riedel

Röber

Geßner

Electrical properties of copper films produced by MOCVD. Microelectron Eng 1997; 33: 165–172.

16.

Takata

Lee

S-H

Tsuji

Ultrafine grained copper alloy sheets having both high strength and high electric conductivity. Mater Lett 2009; 63: 1757–1760.

17.

Shima

Oyane

Plasticity theory for porous metals. Int J Mech Sci 1976; 18: 285–291.

Microstructure,mechanical properties,and electrical conductivity of the solid-state recycled pure copper machining chips

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