A Simple Technique for the Precise Establishment of the Working Gap in an Electrochemical Discharge Machining Process and Some Experimental Results Thereof

Sambathkumar, Saranya; Sankar, A. Ravi

doi:10.3390/mi13091367

Cited by 7 publications

(3 citation statements)

References 33 publications

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“…The machining has not occurred on the quartz beyond the work gap of 25 µm even though there is tool wear. 99 It is reported by Torabi and Razfar 83 that as the machining gap increases, the roughness increases as well as the width and depth decrease of the groove made in the PDMS. The machining gap varies in four levels, i.e., 20, 50, 100 and 150 µm, such a small gap is given with the help of the copper film shown in Figure 7.…”

Section: Parametersmentioning

confidence: 97%

Process capability of electrochemical discharge machining: A review

Prakash,

Kumar,

Ballav

2023

Proceedings of the Institution of Mechanical Engineers, Part L:

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Electrochemical discharge machining (ECDM) is a hybrid machining formed by combining the principles of electrochemical machining and electrical discharge machining. The ECDM is unconventional micromachining that can fabricate holes, blind holes, micro-cavities and grooves on brittle insulating materials such as quartz, glass, silicon wafers and different composites that are difficult to machine. These non-conducting materials have sundry applications such as Micro Electric-Mechanical Systems, biomedical and electronics items. The ECDM provides maximum material removal rate and good surface quality with minor tool wear. The study describes how different process parameters affect machining. The assessment mainly focuses on various tool electrode geometries and materials that are used in ECDM. The present article investigates the ramifications of different types of electrolytes and additives mixed in electrolytes used during the ECDM process on the machined zone. This paper comprehensively reviews the effect of change in applied voltage, machining gap and an inter-electrode gap in the ECDM and it also analyses the fabrication of different materials including glass, quartz, ceramics and composites.

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Section: Parametersmentioning

confidence: 97%

Process capability of electrochemical discharge machining: A review

Prakash,

Kumar,

Ballav

2023

Proceedings of the Institution of Mechanical Engineers, Part L:

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“…In this experiment, we opted for resistance value output as the electrical characteristic parameter to evaluate the properties of the tested sample. To accomplish this objective, we required the use of a precise multimeter [21] for resistance measurement. The principle of resistance measurement using a multimeter is based on Ohm's law, in which the internal voltage source of the multimeter is derived from an internal battery.…”

Section: Principle Of Measuring Electrical Characteristicsmentioning

confidence: 99%

Characterization of Sand and Dust Pollution Degradation Based on Sensitive Structure of Microelectromechanical System Flow Sensor

Chen,

Wen,

Huang

et al. 2024

Micromachines

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The effect of sand and dust pollution on the sensitive structures of flow sensors in microelectromechanical systems (MEMS) is a hot issue in current MEMS reliability research. However, previous studies on sand and dust contamination have only searched for sensor accuracy degradation due to heat conduction in sand and dust cover and have yet to search for other failure-inducing factors. This paper aims to discover the other inducing factors for the accuracy failure of MEMS flow sensors under sand and dust pollution by using a combined model simulation and sample test method. The accuracy of a flow sensor is mainly reflected by the size of its thermistor, so in this study, the output value of the thermistor value was chosen as an electrical characterization parameter to verify the change in the sensor’s accuracy side by side. The results show that after excluding the influence of heat conduction, when sand particles fall on the device, the mutual friction between the sand particles will produce an electrostatic current; through the principle of electrostatic dissipation into the thermistor, the principle of measurement leads to the resistance value becoming smaller, and when the sand dust is stationary for some time, the resistance value returns to the expected level. This finding provides theoretical guidance for finding failure-inducing factors in MEMS failure modes.

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“…Chuang et al [19] utilized the interaction of electrochemical and EDM compensating techniques for the machining of CrNiFe alloy material machining; the machining accuracy was characterized by electrical pulse signal matching, processing time was reduced by 80%, and the efficiency of the equipment was improved. Sambathkumar and Arunagirinathan [20] investigated the working gap (Wg) between the tool and the workpiece in ECDM affecting the process parameters, and the results showed that even a difference of 2 µm in the Wg significantly affects the ECDM process in terms of quality and quantitative metrics. Zhao et al [21] optimized the process without the loss of cathode tools by constructing a coupled multiphysics field model for electrochemical mask processing and combining it with numerical simulation analysis to realize the distribution state of multiphysics fields.…”

Section: Introductionmentioning

confidence: 99%

Experimental Study of Electrolytic Processing of Discharge-Assisted Jet Masks

Chen

Zhang³

et al. 2023

Coatings

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There has been some research on jet electrolytic processing at home and abroad, and the phenomenon of discharge during the process has been reported, but there has been little research on the mode of jet electrolysis with the aid of discharge. A jet mask electrolytic processing experiment was set up to prepare a blue oil mask on the surface of the workpiece using photolithography; two processing modes were achieved using different tool electrodes, the workpiece was processed by two types of motion, the processing micro-pits were observed morphologically using an optical microscope, and the test data were analyzed by plotting graphs. Experiments show that a blue oil mask with a thickness of 50 μm covers the workpiece to strengthen the fixity, and that jet electrolytic discharge machining can effectively improve the depth-to-width ratio by increasing the contribution to depth by 30%–38% and the contribution to width by 2%–18%, compared to jet electrolytic machining. The former has less island effect than the latter, with a flatter bottom and better-machined shape.

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A Simple Technique for the Precise Establishment of the Working Gap in an Electrochemical Discharge Machining Process and Some Experimental Results Thereof

Cited by 7 publications

References 33 publications

Process capability of electrochemical discharge machining: A review

Process capability of electrochemical discharge machining: A review

Characterization of Sand and Dust Pollution Degradation Based on Sensitive Structure of Microelectromechanical System Flow Sensor

Experimental Study of Electrolytic Processing of Discharge-Assisted Jet Masks

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