Parametric analysis, modeling and optimization of the process parameters in electric discharge machining of aluminium metal matrix composite

• Published in: Engineering Research Express Vol. 6; no. 2; pp. 25542 - 25569
• Main Authors: Kumar, Harmesh, Wadhwa, Amandeep Singh, Akhai, Shalom, Kaushik, Arishu
• Format: Journal Article
• Language: English
• Published: IOP Publishing 01.06.2024
• Subjects: electric discharge machining; material erosion rate; modeling; surface roughness; teaching-learning-based optimization
• ISSN: 2631-8695; 2631-8695
• DOI: 10.1088/2631-8695/ad4ba9

Optimizing electric discharge machining (EDM) for aluminum/SiC p metal matrix composites poses challenges due to intricate machine parameters and process complexity, impacting process economy and elevating product costs. The research aims to find the optimal combination of process parameters which include pulse on-time, pulse current, duty cycle (%), gap voltage, sensitivity and flushing pressure for EDM of Al/SiC p -MMC using a copper electrode for the selected response factors such as material erosion rate and surface roughness, R a . The experiments were designed using the central composite design of response surface methodology and an advanced optimization technique known as Teaching–learning-based optimization (TLBO), is applied to find the optimal combination of process parameters to obtain maximum material erosion rate subject to the desired range of surface roughness (SR), R a . The combination of the high pulse on-time (i.e. 150 μ s) and high pulse current (i.e. 12A) results in high material removal rate with deep craters on the machined surface clearly visible in SEM images contrasting the minimized surface roughness at lower values of pulse on-time (50 μ s) and the pulse current (4A). Pulse on - time (T on ) is found to be the most significant factor for material erosion rate and surface roughness with percentage contribution of 70.86 and 54.9 respectively for optimization of the response. The regression models were developed at 95% confidence level for material removal rate and surface roughness with R 2 value of 0.93 and 0.95 respectively signifying high degree of accuracy in predicting the response. Confirmation tests conducted to check the adequacy of the established models revealed that the percentage error between the predicted and experimental responses is found to be within acceptable levels. Electron discharge machining of the aluminium metal matrix composite at the optimized conditions could provide economical aspect in the aerospace and automobile industry.