Calculation of the maximum chip thickness for a radial-axial infeed in gear hobbing

A numerical penetration calculation was used to simulate the radial-axial infeed in gear hobbing for different tool/workpiece combinations. Taking into account 20,000 simulations, a nonlinear regression analysis was performed to establish a mathematical equation, describing the maximum chip thicknes...

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Hauptverfasser:	Troß, N, Brimmers, J, Bergs, T
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creator	Troß, N Brimmers, J Bergs, T
description	A numerical penetration calculation was used to simulate the radial-axial infeed in gear hobbing for different tool/workpiece combinations. Taking into account 20,000 simulations, a nonlinear regression analysis was performed to establish a mathematical equation, describing the maximum chip thickness as a function of the infeed angle and relevant gear, tool and process parameters. The equation was validated using a new set of simulation results. The calculated values are in good agreement with the simulated values. The developed equation allows the design of the radial-axial infeed according to the maximum chip thickness without the use of a simulation program.
doi_str_mv	10.1016/j.procir.2021.03.032
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Taking into account 20,000 simulations, a nonlinear regression analysis was performed to establish a mathematical equation, describing the maximum chip thickness as a function of the infeed angle and relevant gear, tool and process parameters. The equation was validated using a new set of simulation results. The calculated values are in good agreement with the simulated values. 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title	Calculation of the maximum chip thickness for a radial-axial infeed in gear hobbing
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