Abstract
Virtual prototyping of production machines leads not only to lower the development costs but also to lower the overall price for the development of the production machine. Virtual prototyping tools are continually improving and refining. It is often possible to achieve results between the output of the virtual prototyping and the experiment output at a deviation of less than 5%. This deviation value may often be less due to inaccuracies and simplification of the calculation as a variance created by measurement, material inhomogeneity, improper installation, operation, and other factors affecting the overall machine accuracy. The results of combining FEM analysis and virtual prototyping will determine the machine group that has the greatest impact on resulting uncertainty. To eliminate inaccuracy, the largest source of total machine inaccuracy is.
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Acknowledgments
The chapter was supported by grant projects: VEGA 1/0437/17 Research and development of rotary module with an unlimited degree rotation, KEGA 039TUKE-4/2016 Creation of virtual laboratories based on WEB technologies to support the educational process in the field of Manufacturing Technology, VEGA 1/124/15 Research and development of advanced methods for virtual prototyping of manufacturing machines and APVV-15-0149 Research of new measuring methods of machine condition.
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Svetlík, J., Kováč, J., Dudová, P., Dobránsky, J., Považan, M. (2019). Manufacturing Precision of the CNC Milling Machine with Three Controlled Axes. In: Knapčíková, L., Balog, M. (eds) Industry 4.0: Trends in Management of Intelligent Manufacturing Systems. EAI/Springer Innovations in Communication and Computing. Springer, Cham. https://doi.org/10.1007/978-3-030-14011-3_8
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