Mathematical modeling and analysis of WEDM machining parameters of nickel-based super alloy using response surface methodology

Mathematical modeling and analysis of WEDM machining parameters of nickel-based super alloy using response surface methodology

Inconel 625 is one of the most versatile nickel-based super alloy used in the aerospace, automobile, chemical processing, oil refining, marine, waste treatment, pulp and paper, and power industries. Wire electrical discharge machining (WEDM) is the process considered in the present text for machinin...

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Bibliographic Details
Published in:Sadhana (Bangalore) Vol. 42; no. 6; pp. 981 - 1005
Main Authors: GARG, M P, KUMAR, ANISH, SAHU, C K
Format: Journal Article
Language:English
Published: New Delhi Springer India 01-06-2017
Springer Nature B.V
Subjects:
Alloys
Craters
Cutting parameters
Cutting speed
Deterioration
Electric discharge machining
Electric potential
Electric wire
Engineering
Globules
Machine tools
Mathematical models
Multiple objective analysis
Nickel base alloys
Optimization
Parametric analysis
Petroleum refining
Process parameters
Response surface methodology
Superalloys
Surface roughness
Topography
Waste treatment
desirability
cutting speed
gap current
surface roughness
surface topography
WEDM
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Summary:Inconel 625 is one of the most versatile nickel-based super alloy used in the aerospace, automobile, chemical processing, oil refining, marine, waste treatment, pulp and paper, and power industries. Wire electrical discharge machining (WEDM) is the process considered in the present text for machining of Inconel 625 as it can provide an effective solution for machining ultra-hard, high-strength and temperature-resistant materials and alloys, overcoming the constraints of the conventional processes. The present work is mainly focused on the analysis and optimization of the WEDM process parameters of Inconel 625. The four machining parameters, that is, pulse on time, pulse off time, spark gap voltage and wire feed have been varied to investigate their effects on three output responses, such as cutting speed, gap current, and surface roughness. Response surface methodology was used to develop the experimental models. The parametric analysis-based results revealed that pulse on time and pulse off time were significant, spark gap voltage is the least significant, and wire feed as a single factor is insignificant. Multi-objective optimization technique was employed using desirability approach to obtain the optimal parameters setting. Furthermore, surface topography in terms of machining parameters revealed that pulse on time and pulse off time significantly deteriorate the surface of the machined samples, which produce the deeper, wider overlapping craters and globules of debris.
ISSN:0256-2499
0973-7677
DOI:10.1007/s12046-017-0647-3