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Laser specific energy consumption: How do laser systems compare to other manufacturing processes?

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journal contribution
posted on 2022-11-01, 09:33 authored by Lewis JonesLewis Jones, Nicholas Goffin, Jinglei Ouyang, Nazanin Mirhossein, Jiaji Xiong, Yufeng Li, Lin Li, John TyrerJohn Tyrer, Zhu Liu, Elliot WoolleyElliot Woolley, Yan He, Gaoyang Mi, Paul Mativenga
Laser material interactions are routinely praised for their selective processing and high processing rates. However, this does not guarantee that the total manufacturing system has a low energy intensity compared to conventional manufacturing processes. This paper presents the results of a collaborative UK and China research project to improve the comprehension of the total energy consumption and carbon emissions for laser-based manufacturing. A range of individual laser cutting, welding, and cleaning processes were studied to assess their energy efficiency, including the laser and its ancillary subsystems (e.g., cooling and extraction). The project developed a systematic analysis method, adapted from BS ISO 14955-1:2017, which incorporated time and subsystem level studies to quantify all energy consumption components of a laser system. Previous research has identified that the laser system's most significant contributor to the total energy consumption are the auxiliary or supporting subsystems, not the laser emission. This identified that using only the absorbed radiation to evaluate manufacturing efficiency is misleading. All the processes evaluated followed a negative correlation between processing rate (kg/h) and specific energy consumption (J/kg). The new data conclude that laser processes have a relatively high energy intensity compared to conventional manufacturing alternatives. The results can be used to identify where the most significant improvements to individual laser systems can be made. The comprehensive comparison of processes allows manufacturers to select processes to improve environmental impact.

Funding

Research on the theory and key technology of laser processing and system optimisation for low carbon manufacturing (LASER-BEAMS)

Engineering and Physical Sciences Research Council

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Basic theory and key technologies of laser processing technology and system optimization for low-carbon manufacturing

National Natural Science Foundation of China

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History

School

  • Mechanical, Electrical and Manufacturing Engineering

Published in

Journal of Laser Applications

Volume

34

Issue

4

Publisher

Laser Institute of America

Version

  • VoR (Version of Record)

Rights holder

© 2022 Author(s)

Publisher statement

This is an Open Access article published by AIP Advances. All article content, except where otherwise noted, is licensed under a Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).

Acceptance date

2022-09-13

Publication date

2022-10-25

Copyright date

2022

ISSN

1042-346X

eISSN

1938-1387

Language

  • en

Depositor

Dr Lewis Jones. Deposit date: 25 October 2022

Article number

042029

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