Abstract
Service properties of gears are formed at the stages of their finishing processes, such as gear grinding, shaving, gear honing, lapping, running-in, etc. Determining the optimal parameters and structure of the technological system that provide the specified gear properties is the task of synthesizing such a system. These task is multivariate and limited by the lack of general principles for their solution. The article proposes the synthesis principles of a technological system based on a systematic approach by representing the technological system as a generalized design object. The synthesis is implemented as a logical design scheme, which is interpreted by the morphological model. This model regulates the process of synthesis by information, optimization and algorithmic systems of a design object, regardless of the processing type. Developed objects of the information system: simulation models of the machining geometry, tooth profile shaping, the dynamic interaction of the technological system links and the model of the process technological characteristics, describe the relationships between real objects of the technological system. An optimization system was selected from the information system by which an algorithmic design system was developed. Using the developed method, a number of technological systems have been synthesized for the gears finishing.
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Storchak, M. (2021). Parametric Synthesis of Technological Systems for Gear Finishing. In: Barmina, N., Trubachev, E. (eds) Gears in Design, Production and Education. Mechanisms and Machine Science, vol 101. Springer, Cham. https://doi.org/10.1007/978-3-030-73022-2_9
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DOI: https://doi.org/10.1007/978-3-030-73022-2_9
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