In addition to the steps taken to ensure optimal efficiency in industry, significant effort has been directed towards the green and sustainable manufacturing practices. In this paper, we review conventional and state-of-the-art manufacturing technologies to provide insight into energy consumption at the processing level. In the review, collected energy data were summarized for three manufacturing categories: conventional bulk-forming, subtractive, and additive manufacturing (AM) processes. Additive processes, in particular, are strongly emphasized in the Advanced Manufacturing Initiatives proposed recently by the United States government. Currently, the specific energy consumption (SEC) of additive processes is estimated to be ~100-fold higher than that of conventional bulk-forming processes, with subtractive processes showing intermediate values that varied over a wide range in terms of scale. Although SEC may vary with respect to the details, in general, the research showed a negative correlation with respect to the reciprocal logarithmic form of the productivity. In addition to the literature review presented, we performed case studies for the three manufacturing processes, to provide practical examples of energy consumption. Additionally, our results indicated that AM processes may require more extensive evaluation; i.e., an assessment of the entire manufacturing cycle, for more accurate prediction of the subsequent environmental impact.

/pdf/a-comparison-of-energy-consumption-in-bulk-forming-2tw6815zfm.pdf

A Comparison of Energy Consumption in Bulk Forming, Subtractive, and Additive Processes: Review and Case Study

Optimization of sheet metal forming processes by adaptive response surface based on intelligent sampling method

Sustainability issues in sheet metal forming processes: an overview

Multi-objective optimization of sheet metal forming process using Pareto-based genetic algorithm

https://lup.lub.lu.se/search/ws/files/2670823/1472331.pdf

Gašper Gantar

Papers

Optimization of sheet metal forming processes by the use of numerical simulations

Optimization of stamping processes aiming at maximal process stability

Sensitivity and stability evaluation of the deep drawing process

Increasing the stability of the deep drawing process by simulation-based optimization

Numerical simulations in optimisation of product and forming process