Abstract
In this study, the authors proposed an approach for calculating the distribution of the temperature field with simulation at the stages of input and output of an electron beam on the basis of mathematical models of the thermal field, considering the thermophysical parameters of the product material and its geometric dimensions. The approach considered by the authors for calculating the thermal field at the stages of input and output of an electron beam, at the weld seam, based on the developed mathematical models, taking into account the geometric dimensions of the product and the thermophysical parameters of the product material, will reduce the cost of setting up the technological process when welding new material alloys and other thicknesses, and will also reduce the number of defects in the used technological modes in production. Thus, the purpose of the study is to develop a new modeling approach for developing a technological process with its further application for a more conscious choice of technological parameters when developing a new technological process for electron beam welding of other materials and alloys and obtaining a stable quality of a weld. #CSOC1120
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Acknowledgments
The reported study was funded by RFBR, Government of the Krasnoyarsk Territory and the Regional Science Foundation, project number 19-48-240007 “Mathematical and algorithmic support of the electron-beam welding of thin-walled aerospace structures”.
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Kurashkin, S., Tynchenko, V., Murygin, A., Seregin, Y., Tynchenko, V., Bocharov, A. (2021). Modeling the Temperature Field Distribution at the Stages of Input-Output of the Electron Beam. In: Silhavy, R. (eds) Software Engineering and Algorithms. CSOC 2021. Lecture Notes in Networks and Systems, vol 230. Springer, Cham. https://doi.org/10.1007/978-3-030-77442-4_28
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