SIMULATION AND PRACTICAL INVESTIGATIONS OF INDUCTIVELY ASSISTED MACHINING USING THE EXAMPLE OF TURNING OPERATIONS

Frank ARNOLD, Niranjan Manur KRISHNAMURTHY, Johannes PRASSE, Lars PENTER, Steffen IHLENFELDT

Abstract


Due to the increasing use of hard-to-cut materials, machining processes face the challenge of overcoming technologically determined limits of machinability. Hybrid manufacturing processes combine different mechanisms of action into one process and are a promising approach to shift the limits of the individual processes. One approach for improving efficiency through hybrid manufacturing processes is thermally assisted machining. By softening the material in the heated area, machining forces can be reduced and surface quality can be improved. In comparison to other heating methods, induction is an easy-to-use and highly efficient option. Currently, there is no consistent method for simulating this process. The paper shows approaches for the Finite Element Method simulation and implementation of induction-assisted turning. The simulation model developed by the authors predicted temperatures and cutting forces with the validation and reduction of forces are proven by the practical tests.

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References


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