Dielectric flow observation at inter-electrode gap in micro-electro-discharge-milling process

Mullya, Satish; Karthikeyan, G.

doi:10.1177/0954405416662082

Cited by 22 publications

(2 citation statements)

References 25 publications

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“…As the variation in velocity is less even with the small gap width, the flushing will be effective. When compared with the ADV in the IEG using cylindrical tool, 25 the velocity in case of slotted tool is less for dissimilar gap width. The reason is vortex flow in the slot which reduces the velocity.…”

Section: Resultsmentioning

confidence: 99%

Simulation of flow-field and debris temperature analysis in micro-electrical discharge milling using slotted tools

Mullya¹,

Karthikeyan

Ganachari³

2022

Proceedings of the Institution of Mechanical Engineers, Part B:

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In micro-electrical discharge milling (μED-milling), the rotation and forward feed motion of the tool is the key element responsible for evacuation of the debris particles. The inability to eliminate debris from the interelectrode gap (IEG) causes secondary discharge, short-circuit, and hampers removal rate. This problem is predominant in electrical discharge machining (EDM) where the tool is stationary. Various methods have been devised in the literature to boost debris removal from the IEG. In this paper, the use of a slotted tool with different cross-sections is proposed. The dielectric flow-field, debris trajectory, and cooling rate are calculated using computational fluid dynamics (CFD). Effect of different parameters such as tool rotation, gap size, jet velocity, the shape of slots on the dielectric flow is determined. The slots on the tool create turbulence which enhances the debris removal from the IEG. It also provides the space to accumulate the debris particles, thereby increasing the removal rate. The variation in the dielectric flow-field greatly affects the debris flushing from the IEG. The trajectory of the debris particles depends on their initial position in the IEG and they cool rapidly, which is validated using simulation and mathematical approach.

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Section: Resultsmentioning

confidence: 99%

Simulation of flow-field and debris temperature analysis in micro-electrical discharge milling using slotted tools

Mullya¹,

Karthikeyan

Ganachari³

2022

Proceedings of the Institution of Mechanical Engineers, Part B:

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“…It was determined that many bubbles were generated during the discharge process, most of which were connected during discharge before expanding rapidly and pushing most etched particles to the edge of the bottom gap. Mullya and Karthikeyan 16 analyzed the fluid flow along the narrow gap of micro-electro-discharge-milling process for different machining conditions by computational fluid dynamics simulation, and the effect of different sized particles formed at various positions and their subsequent movement was also analyzed by particle simulation. The results showed that the average velocity of the fluid in the gap was affected by the change in the inlet nozzle velocity, and the eddies were created due to the change fluid pattern.…”

Section: Introductionmentioning

confidence: 99%

Arc characteristics in short electrical arc high-efficiency milling for GH4169

Zhou

Wang

et al. 2020

Proceedings of the Institution of Mechanical Engineers, Part B:

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To solve core problems of slow arc response and unstable combustion, arc movement characteristics and arc action rules in short electrical arc milling are studied using a high-speed acquisition system and the Phantom high-speed camera in this article. To improve arc reignition, the characteristic parameters of arc discharge are determined as a discharge gap of 0.053 mm and discharge time of 2180 μs. A short electrical arc milling experiment with nickel-based superalloy GH4169 is carried out, confirming that the continuous stable discharge of the arc can easily produce a material removal rate of 40 g/min and a tool wear ratio of 0.8%. An SU8010 scanning electron microscope and energy spectrum analyzer are then used to study the erosion mechanism of GH4169 in short electrical arc milling. This article aims to expand the processing range of short electrical arc machining in the field of special material processing to provide experimental and theoretical bases for the development of short electrical arc milling technology theory and methods.

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Comparative Study of Dielectric and Debris Flow in Micro-Electrical Discharge Milling Process Using Cylindrical and Slotted Tools

Mullya

Karthikeyan

2019

Lecture Notes on Multidisciplinary Industrial Engineering

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Dielectric flow observation at inter-electrode gap in micro-electro-discharge-milling process

Cited by 22 publications

References 25 publications

Simulation of flow-field and debris temperature analysis in micro-electrical discharge milling using slotted tools

Simulation of flow-field and debris temperature analysis in micro-electrical discharge milling using slotted tools

Arc characteristics in short electrical arc high-efficiency milling for GH4169

Comparative Study of Dielectric and Debris Flow in Micro-Electrical Discharge Milling Process Using Cylindrical and Slotted Tools

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