Sureshkumar Myilsamy scite author profile

In this research, the wire wear ratio (WWR), material removal rate (MRR) and surface roughness (SR) of cryogenic cooled near dry wire-cut electrical discharge machining (NDWEDM) is compared with the existing NDWEDM process. Cryogenic cooled and un-cooled molybdenum wires and Inconel 718 alloy have been used as the electrodes and work-material respectively. The novel experimental setup has been fabricated to mix the minimum amount of water with pressurized air as a dielectric fluid. The control variables such as Air pressure (P), Flow rate (F), Current (I), Pulse width (PW), and Pulse Interval (PI) are measured to conduct both NDWEDM experiments using the L27 Taguchi method. It was revealed from systematic studies that WWR of cryogenic cooled NDWEDM is reduced to 29%, MRR is increased to 15.6% and SR is reduced to 7.23% than existing NDWEDM due to an increase in electric conductivity and effective spark strengths by cryogenic cooled wire. It was revealed from SEM images that the macro crater in the existing NDWEDM and the micro crater of wire in the cryogenic NDWEDM process have been studied.

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Experimental Investigation of a Cryogenically Cooled Oxygen-mist Near-dry Wire-cut Electrical Discharge Machining Process

Boopathi¹,

Myilsamy²

2021

SV-JME

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In this paper, a novel method of cryogenically cooled (low-temperature nitrogen gas) wire tool is used during the oxygen-mist near-dry wire-cut electrical discharge machining (NDWEDM) process to cut Inconel 718 alloy material. The current, pulse-width, pulse-interval, and flow rate are the controllable variables for response characteristics, such as the material removal rate (MRR) and wire wear ratio (WWR). The Box-Behnken method is applied to design the experiments to collect the observations from experiments. The mathematical models for each response were developed using significant individual, interaction, and quadratic terms by the sequential sum of the square test. The response surfaces were developed. It was revealed from the analysis that 52.92 % of current, 24.63 % of Pulse-width, 12.81 % of pulse- interval and 5.75 % of flow rate contributed to MRR, while 14.89 % of current, 9.75 % of pulse-width, 62.20 % of pulse-interval, and 5.44 % of flow rate contributed to WWR. The pulse-width has more contribution on MRR due to the long period of spark between the wire and work materials. It was also observed that the pulse-interval has more effect on WWR due to the more ideal period (high spark-pause-time) between two consecutive high-temperature sparks in the wire tool. The wear of the wire tool has been analysed using scanning electron microscopy (SEM) photographs. The desirability principles were first applied to obtain multi-objective solutions with a combination of process parameters to achieve the optimal values of both responses. The predicted combination of results has been validated by data that were collected from confirmation experiments.

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Grey Relational Optimization of Powder Mixed Near-Dry Wire Cut Electrical Discharge Machining of Inconel 718 Alloy

Myilsamy¹,

Boopathi²

2017

Asia. Jour. Rese. Soci. Scie. and Human.

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