J.R. Vinod Kumaar scite author profile

J.R. Vinod Kumaar

4Publications

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Effect of different electrolytes on electrochemical micro-machining of SS 316L

Kumaar¹,

Thanigaivelan²,

Soundarrajan³

2022

CI&CEQ

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The use of stainless steel 316L (SS 316L) in industries such as medical, marine, aerospace, bio-medical, and automobile sectors is increasing rapidly. Electrochemical micro-machining (ECMM) is the apt method for machining SS 316L due to its burr-free machining surface, no residual stress, and high precision. However, there are some limitations found in the usage of strong electrolytes such as HCl, H2SO4, KOH, NaNO3, and NaCl, which are reportedly facing difficulties in disposing it to the environment and handling issues. Hence, this paper addresses to overcome the disadvantages faced in ECMM process when using strong electrolytes to machine SS 316L, so therefore different organic electrolytes such as tartaric acid (C4H6O6), citric acid (C6H8O7), and a combination of tartaric and citric acid electrolyte (mixed electrolyte) are considered to select the best electrolyte. Process parameters like machining voltage, duty cycle, and electrolyte concentration are included in determining the performance of machining. The performance of ECMM is evaluated using material removal rate (MRR) and overcut. The overcut of tartaric acid electrolyte is found to be 179% less than mixed electrolyte for the parameter combination of 12 g/l, 11 V, and 85%. The mixed electrolyte shows 114.2% higher MRR than the tartaric acid electrolyte for the parameter solutions of 25%, 11 V, and 20 g/l. Furthermore, the citric acid electrolyte shows the second lowest overcut and higher MRR in all aspects of machining performance. Field emission scanning electron microscope (FESEM) studies are carried out to realise the effect of electrolyte on the machining surface.

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Performance of magnetic field-assisted citric acid electrolyte on electrochemical micro-machining of SS 316L

Kumaar¹,

Thanigaivelan²

2020

Materials and Manufacturing Processes

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A performance study of electrochemical micro-machining on SS 316L using suspended copper metal powder along with stirring effect

Kumaar¹,

Thanigaivelan²,

Soundarrajan³

2022

Materials and Manufacturing Processes

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A Study on the Effect of Oxalic Acid Electrolyte on Stainless Steel (316L) Through Electrochemical Micro-machining

Kumaar¹,

Thanigaivelan²,

Dharmalingam³

2019

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J.R. Vinod Kumaar

Effect of different electrolytes on electrochemical micro-machining of SS 316L

Performance of magnetic field-assisted citric acid electrolyte on electrochemical micro-machining of SS 316L

A performance study of electrochemical micro-machining on SS 316L using suspended copper metal powder along with stirring effect

A Study on the Effect of Oxalic Acid Electrolyte on Stainless Steel (316L) Through Electrochemical Micro-machining

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