Author(s)

Habib Hammi, Abderrazak El Ouafi, Noureddine Barka, Ahmed Chebak

Mathematics, Computer Science and Engineering Department, University of Quebec at Rimouski, Rimouski, Canada.

This paper presents an investigation of non-stationary induction heating process applied to AISI 4340 steel spline shafts based on 3D simulation and experimental validation. The study is based on the knowledge, concerning the form of correlations between various induction heating parameters and the final hardness profile, developed in the case of stationary induction heating. The proposed approach focuses on analyzing the effects of variation of frequency, power and especially scanning speed through an extensive 3D finite element method simulation, comprehensive sensitivity study and structured experimental efforts. Based on coupled electromagnetic and thermal fields analysis, the developed 3D model is used to estimate the temperature distribution and the hardness profile. Experimentations conducted on a commercial dual-frequency induction machine for AISI 4340 steel splines confirm the feasibility and the validity of the proposed modelling procedure. The 3D model validation reveals a great concordance between simulated and measured results, confirms that the model can effectively be used as framework for understanding the process and for assessing the effects of various parameters on the hardening process quality and performance and consequently leads to the most relevant variables to use in an eventual hardness profile prediction model.

Induction Heating, Non-Stationary Induction Heating, Spline Shafts, Hardness Profile, Temperature Distribution, Finite Element Method, Induction Heating Parameters, Sensitivity Study, Prediction Model

Hammi, H. , El Ouafi, A. , Barka, N. and Chebak, A. (2017) Scanning Based Induction Heating for AISI 4340 Steel Spline Shafts-3D Simulation and Experimental Validation. Advances in Materials Physics and Chemistry, 7, 263-276. doi: 10.4236/ampc.2017.76021.