Optimization of PMEDM process parameter for maximizing material removal rate by Taguchi’s method

The electrical discharge machining process is hampered by a low material removal rate (MRR), high tool wear, and low quality of machined surface, which limit its applicability. The use of powder mixed electrical discharge machining helps overcome this drawback and increases the efficiency of the mac...

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Bibliographic Details
Published in:International journal of advanced manufacturing technology 2016-11, Vol.87 (5-8), p.1929-1939
Main Authors: Long, Banh Tien, Phan, Nguyen Huu, Cuong, Ngo, Jatti, Vijaykumar S.
Format: Article
Language:English
Subjects:
CAE) and Design
Computer-Aided Engineering (CAD
Die steels
Electric currents
Electric discharge machining
Electrode materials
Electrodes
Engineering
Identification methods
Industrial and Production Engineering
Machine shops
Material removal rate (machining)
Mechanical Engineering
Media Management
Optimization
Original Article
Parameter identification
Polarity
Process parameters
Taguchi methods
Titanium
Tool wear
Variance analysis
Wear rate
Workpieces
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Summary:The electrical discharge machining process is hampered by a low material removal rate (MRR), high tool wear, and low quality of machined surface, which limit its applicability. The use of powder mixed electrical discharge machining helps overcome this drawback and increases the efficiency of the machining process. This study focused on the machining of SKD61, SKD11, and SKT4 die steels using titanium powder. Taguchi methods and analysis of variance were employed to identify the main parameters that affect the MRR. The other process parameters considered were the electrode material, workpiece material, electrode polarity, pulse-on time, pulse-off time, electric current, and titanium powder concentration. The results indicated that electric current, electrode material, and powder concentration were the most significant parameters that influenced the MRR. A powder concentration of 20 g/l increased the MRR by 42.1 %, as compared with no-powder machining. Further, the optimal value of the MRR was determined to be 45.734 mm 3 /min.
ISSN:0268-3768
1433-3015
DOI:10.1007/s00170-016-8586-4