In this diploma thesis, the operation of fiber lasers was investigated. The aim of the thesis was to examine the influence of laser parameter settings on the engraving quality of various materials, with the goal of determining the optimal parameters for achieving the highest engraving quality across different materials. The study analyzed how individual materials respond to different settings and what adjustments are required to achieve the best results. The experimental part was carried out using a fiber laser with a wavelength of 1064 nm and a power of 30 W. Testing was performed on various materials, including metals (aluminum, stainless steel, copper, galvanized iron), plastics (ABS, polycarbonate), natural materials (cardboard, genuine and synthetic leather), and surface-treated materials (anodized aluminum, powder-coated iron). During engraving, the power was systematically varied in the range of 20% to 80%, the frequency from 20 kHz to 80 kHz, and the speed from 1000 mm/s to 10,000 mm/s. The results showed that specific settings are required for different materials, as universal values do not guarantee optimal results. For metals, lower frequencies and higher power proved to be the most effective, enabling deeper and more contrasting engravings. For plastics and painted surfaces, higher frequency and lower power were most suitable, as they prevented deformation and burn marks. For natural materials, such as wood and leather, it was necessary to adjust the power and speed to avoid uneven engraving or excessive material removal. A special part of the research focused on producing a printing plate for pad printing as a method of evaluating the practical applicability of laser engraving. This approach made it possible to directly assess the engraving results through print quality, which further confirmed the findings regarding the optimal parameters. It was found that proper parameter adjustment improves engraving precision, reduces errors, and increases result repeatability. The practical findings of the research are applicable both in industrial production and in individual uses of laser engraving, as they enable a better understanding of the influence of settings on various materials. Further research could include the automation of parameter adjustments using artificial intelligence, as well as the examination of the impact of different types of protective coatings on engraving quality.
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