LASER SURFACE TRANSFORMATION HARDENING WITH HIGH-POWER DIODE LASERS

Authors

  • Normunds Teirumnieks Bulgaria University of Transport, „Technique and construction technologies in transport” Faculty
  • Lyubomir Lazov Engineering Center, Rezekne Academy of Riga Technical University
  • Emil Yankov Engineering Center, Rezekne Academy of Riga Technical University
  • Edmunds Teirumnieks Engineering Center, Rezekne Academy of Riga Technical University
  • Prodan Prodanov Center of competence; Smart mechatronic, eco-and energy-saving systems and technologies; Faculty of Electrical Engineering and Electronic, Technical University of Gabrovo
  • Artis Teilans Engineering Center, Rezekne Academy of Riga Technical University

DOI:

https://doi.org/10.17770/etr2025vol4.8392

Keywords:

Austenite, High-Power Diode Laser, Laser surface hardening, Martensite, Phase Transformation

Abstract

Laser Surface Hardening (LSH) is an advanced technique applicable to a wide range of metals and alloys in modern industrial manufacturing, including the automotive sector. Among the various laser types used for hardening, CO₂, solid-state Nd: YAG, and fibre lasers have traditionally been the most common. However, with the development of high-power diode lasers (HPDLs), these have increasingly gained prominence in this field. In the LSH process, high-intensity laser radiation is focused on a localized area, rapidly heating and hardening the material's surface. The steep temperature gradients resulting from rapid heating and cooling induce structural transformations within the treated area. Additionally, the phase transformation from austenite to martensite occurs without the need for external cooling, simplifying the process. This review paper outlines the fundamental principles of laser hardening and its advantages over conventional hardening techniques. Key process parameters and influencing factors are discussed, along with a comparative analysis of LSH against other hardening methods. Furthermore, an overview of experimental research in this area is provided, with a particular focus on HPDL-based hardening. Various methods for analysing and evaluating laser-treated surfaces are also examined.

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Published

08.06.2025

Issue

Vol. 4 (2025): Environment. Technology. Resources. Proceedings of the 16th International Scientific and Practical Conference. Volume 4

Section

Laser Technologies

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Copyright (c) 2025 Normunds Teirumnieks, Lyubomir Lazov, Emil Yankov, Edmunds Teirumnieks, Prodan Prodanov, Artis Teilans

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This work is licensed under a Creative Commons Attribution 4.0 International License.

How to Cite

LASER SURFACE TRANSFORMATION HARDENING WITH HIGH-POWER DIODE LASERS. (2025). ENVIRONMENT. TECHNOLOGY. RESOURCES. Proceedings of the International Scientific and Practical Conference, 4, 503-510. https://doi.org/10.17770/etr2025vol4.8392