Multi-objective parametric optimization on machining of Inconel-825 using wire electrical discharge machining

Wire electrical discharge machining is a thermal energy-based non-conventional machining process which can machine conductive materials with high precision. In this present work, machining of Inconel-825 was performed using wire electrical discharge machining. Multi-objective parametric optimization...

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Bibliographic Details
Published in:Proceedings of the Institution of Mechanical Engineers. Part C, Journal of mechanical engineering science Journal of mechanical engineering science, 2020-10, Vol.234 (20), p.4056-4068
Main Authors: Shandilya, Pragya, Rouniyar, Arun Kumar, Saikiran, D
Format: Article
Language:English
Subjects:
Cutting parameters
Electric discharge machining
Genetic algorithms
Machine learning
Machine shops
Multiple objective analysis
Nickel base alloys
Optimization
Optimization techniques
Response surface methodology
Superalloys
Surface roughness
Thermal energy
Variance analysis
Wire
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Summary:Wire electrical discharge machining is a thermal energy-based non-conventional machining process which can machine conductive materials with high precision. In this present work, machining of Inconel-825 was performed using wire electrical discharge machining. Multi-objective parametric optimization was performed for maximum cutting rate and minimum surface roughness using teaching–learning-based optimization, grey relational analysis, and genetic algorithm. Four wire electrical discharge machining parameters, namely spark off time (SOFF), spark on time (SON), peak current (IP), and angle of cutting (A) were considered. Comparison of optimum wire electrical discharge machining parameters through teaching–learning-based optimization, grey relational analysis, and genetic algorithm was performed. The better optimum solution for wire electrical discharge machining parameters was obtained using teaching–learning-based optimization and optimum values were at IP (1 A), SON (30 µs), SOFF (12.5 µs), and A (44.8°) with cutting rate as 19.744 mm/min and surface roughness as 1.331 µm. The optimum results obtained using optimization techniques were validated with the experimental results and error was observed to be within 5%. Moreover, response surface models were developed to predict the cutting rate and surface roughness in terms of wire electrical discharge machining parameters using analysis of variance.
ISSN:0954-4062
2041-2983
DOI:10.1177/0954406220917706