Abstract
The motivation for the research was the challenges faced in developing the robotic microplasma spraying technology for applying coatings from biocompatible materials onto medical implants of complex shape. Our task is to provide microplasmatron movement according to the complex trajectory during the surface treatment by microplasma and to solve the problem of choosing the speed of the microplasmatron movement, so as not to cause melting of the coating. The aim of this work was to elaborate mathematical modeling of temperature fields in two-layer heat absorbers: coating-substrate depending on the velocity of microplasmatron with a constant power density. A mathematical model has been developed for the distribution of temperature in two-layer absorbers when heated by a moving source and the heat equation with nonlinear coefficients has been solved by numerical methods.
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Acknowledgment
The study has been conducted with financial support of the Science Committee of the Ministry of Education and Science of the Republic of Kazakhstan within the framework of program-targeted financing for 2017–2019 years on the scientific and technical sub-program 0006/PCF-17 “Manufacture of titanium products for further use in medicine”.
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Alontseva, D.L., Krasavin, A.L., Nurekenov, D.M., Zhanuzakov, Y.T. (2019). Mathematical Modeling of Temperature Fields in Two-Layer Heat Absorbers for the Development of Robotic Technology for Microplasma Spraying of Biocompatible Coatings. In: Shokin, Y., Shaimardanov, Z. (eds) Computational and Information Technologies in Science, Engineering and Education. CITech 2018. Communications in Computer and Information Science, vol 998. Springer, Cham. https://doi.org/10.1007/978-3-030-12203-4_2
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