Article: Modelling and multi-response optimisation of sinking micro-electrical discharge machining of AISI 4140 steel Journal: International Journal of Industrial and Systems Engineering (IJISE) 2017 Vol.26 No.3 pp.397 - 424 Abstract: Improving productivity and surface quality in sinking micro-electrical discharge machining (S-MEDM) process is still a challenging task for manufacturing engineers. In order to fulfil these requirements, modelling and optimisation of the S-MEDM process is needed. In this paper, a prediction model for S-MEDM process has been developed using the coupled methodology of finite element method (FEM) and artificial neural network (ANN). First, a FEM-based model is developed incorporating realistic aspects such as Gaussian heat flux distribution, time dependent spark radius, temperature dependent workpiece material properties and phase change phenomenon. Further, an ANN model is developed utilising the data generated by FEM-based model for training and testing of the network. The trained ANN model has been used for the prediction of the material removal rate and surface roughness (Ra). Weighted principal component (WPC) method is effectively employed for multi-response optimisation of S-MEDM process using prediction data of ANN model. The optimum setting of process parameters gives an improvement of 22.68% in material removal rate and a decrease of 17.30% in surface roughness. Inderscience Publishers - linking academia, business and industry through research

Title: Modelling and multi-response optimisation of sinking micro-electrical discharge machining of AISI 4140 steel

Authors: Ajay Suryavanshi; Vinod Yadava; Audhesh Narayan

Addresses: Department of Mechanical Engineering, Motilal Nehru National Institute of Technology, Allahabad – 211004, India ' Department of Mechanical Engineering, Motilal Nehru National Institute of Technology, Allahabad – 211004, India ' Department of Mechanical Engineering, Motilal Nehru National Institute of Technology, Allahabad – 211004, India

Abstract: Improving productivity and surface quality in sinking micro-electrical discharge machining (S-MEDM) process is still a challenging task for manufacturing engineers. In order to fulfil these requirements, modelling and optimisation of the S-MEDM process is needed. In this paper, a prediction model for S-MEDM process has been developed using the coupled methodology of finite element method (FEM) and artificial neural network (ANN). First, a FEM-based model is developed incorporating realistic aspects such as Gaussian heat flux distribution, time dependent spark radius, temperature dependent workpiece material properties and phase change phenomenon. Further, an ANN model is developed utilising the data generated by FEM-based model for training and testing of the network. The trained ANN model has been used for the prediction of the material removal rate and surface roughness (Ra). Weighted principal component (WPC) method is effectively employed for multi-response optimisation of S-MEDM process using prediction data of ANN model. The optimum setting of process parameters gives an improvement of 22.68% in material removal rate and a decrease of 17.30% in surface roughness.

Keywords: sinking micro-electrical discharge machining; S-MEDM; finite element method; FEM; artificial neural network; ANN; weighted principal component method; process modelling; Gaussian distribution; optimisation.

DOI: 10.1504/IJISE.2017.084431

International Journal of Industrial and Systems Engineering, 2017 Vol.26 No.3, pp.397 - 424

Received: 22 Apr 2015
Accepted: 28 Jun 2015
Published online: 07 Jun 2017 *

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Title: Modelling and multi-response optimisation of sinking micro-electrical discharge machining of AISI 4140 steel

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