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Electroplasticity for Sustainable Metal Forming: A Comparative Energy Assessment
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 1051Electroplasticity for Sustainable Metal Forming: A...

Electroplasticity for Sustainable Metal Forming: A Comparative Energy Assessment

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Abstract:

Modern manufacturing increasingly demands energy-and resource-efficient solutions. Conventional metal forming often requires high temperatures to reduce flow stress, resulting in high energy consumption, especially for low-formability alloys. Electrically-Assisted Manufacturing (EAM) has emerged as a promising alternative, leveraging the electroplastic effect, i.e. electricity’s direct influence on plastic deformation. Documented benefits include reduced forming forces, improved ductility, and altered fracture modes. Indeed, integrating electroplasticity into manufacturing aligns with Industry 4.0 and decarbonization goals, enabling lower energy consumption, extended tool life, and greater compatibility with renewable energy sources. This study compares conventional tensile testing and electro-assisted tensile testing (EAM) of Ti6Al4V, evaluating both mechanical results and the energy consumption of the testing machine under different conditions. The comparison results highlight the potential of pulsed current to improve material formability while reducing energy consumption, offering a more sustainable approach to manufacturing.

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Sustainability on Material Forming

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Periodical:

Key Engineering Materials (Volume 1051)

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1-8

DOI:

https://doi.org/10.4028/p-ZK3upW

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Online since:

April 2026

Authors:

Luigi Benvenuto*, Ersilia Cozzolino, Agnese Testa, Chiara Mandolfino, Alessandro Simeone, Enrico Lertora, Luca Settineri, Antonello Astarita

Keywords:

Electroplasticity, Energy Consumption, Tensile Test, Titanium Alloy

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Creative Commons CC BY 4.0

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