The pursuit of enhancing the quality and precision of final design models has become increasingly vital in modern production processes, particularly in the realm of university information signage. This research explores the application of advanced laser engraving and cutting technologies to achieve maximum accuracy in geometric shapes, fine details, and textual elements. A systematic methodology has been developed and implemented, focusing on the production of custom-designed metal information signs tailored to university environments. The article presents a comprehensive overview of the production stages, including optimized workflows for managing digital data, selection of appropriate file formats, and precise laser machine settings. By integrating digital design tools with laser technology, the study demonstrates how to streamline processes while maintaining exceptional quality and durability of signage. The research outcomes not only emphasize the technological advantages of laser systems—such as high-speed production, cost efficiency, and unparalleled precision—but also highlight their potential to transform design practices in educational settings. This study aims to contribute to the scientific and practical development of digital fabrication methods, inspiring wider adoption of laser-based innovations across design disciplines.

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Application of Laser Engraving and Cutting for Customized University Information Signage Creation

  • Mariela Todorova,
  • Tihomir Dovramadjiev,
  • Darina Dobreva,
  • Tsena Murzova,
  • Mariana Murzova,
  • Iliya Iliev,
  • Ventsislav Markov

摘要

The pursuit of enhancing the quality and precision of final design models has become increasingly vital in modern production processes, particularly in the realm of university information signage. This research explores the application of advanced laser engraving and cutting technologies to achieve maximum accuracy in geometric shapes, fine details, and textual elements. A systematic methodology has been developed and implemented, focusing on the production of custom-designed metal information signs tailored to university environments. The article presents a comprehensive overview of the production stages, including optimized workflows for managing digital data, selection of appropriate file formats, and precise laser machine settings. By integrating digital design tools with laser technology, the study demonstrates how to streamline processes while maintaining exceptional quality and durability of signage. The research outcomes not only emphasize the technological advantages of laser systems—such as high-speed production, cost efficiency, and unparalleled precision—but also highlight their potential to transform design practices in educational settings. This study aims to contribute to the scientific and practical development of digital fabrication methods, inspiring wider adoption of laser-based innovations across design disciplines.