Technológ - Ročník 17.; Číslo 3/2025

Permanent URI for this collectionhttps://drepo.uniza.sk/handle/hdluniza/1336

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Author: search.filters.author.Maláková, Silvia

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    Súčasné materiálové riešenia pre ozubené kolesá
    (University of Žilina, 2025) Kepeň Harachová, Daniela; Maláková, Silvia
    Gears are very common machine components that enable precise transmission of rotational motion and power transmission from shaft to shaft. High demands are placed on the function of gears in operation. They must enable precise, uniform transmission, must not cause noise, often have to transmit large forces, etc. Gears are manufactured from a variety of materials and with different performance specifications depending on the industrial application. Gear materials are required to have high strength, toughness and wear resistance because gears rely on their own design size and material strength to withstand external loads. Material manufacturability is also necessary due to the complex shape of the gear and the high precision requirements of the gear. This study highlights trends in gear materials that are moving towards ultra-high strength, high wear resistance, high temperature resistance, corrosion resistance, and low weight.
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    Interakcia medzi materiálom, tepelným spracovaním a pevnostným výpočtom v návrhu ozubených prevodov
    (University of Žilina, 2025) Maláková, Silvia; Kepeň Harachová, Daniela
    This paper investigates the complex interaction between material selection, heat treatment processes, and strength calculation methodologies in the design of gear transmissions. The mechanical performance and durability of gears are highly dependent on the choice of base material and the subsequent thermal treatments applied to optimize their microstructure and mechanical properties. We analysed how different heat treatment techniques, such as carburizing, quenching, and tempering, influence the microstructural characteristics and fatigue strength of common gear materials. Furthermore, the study evaluates how these material and heat treatment factors are integrated into strength calculation models used in gear design to predict operational lifespan and reliability. Experimental data and numerical simulations are employed to validate the correlation between processing parameters and gear performance. The findings highlight the critical role of a holistic design approach that considers material properties, heat treatment parameters, and accurate strength calculations to enhance gear transmission efficiency and longevity.