A review on process capabilities of electrochemical micromachining and its hybrid variants

Saxena, Krishna Kumar; Qian, Jun; Reynaerts, Dominiek

doi:10.1016/j.ijmachtools.2018.01.004

Cited by 193 publications

(59 citation statements)

References 205 publications

(294 reference statements)

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“…Electrochemical micromachining is today widely used for manufacturing semiconductor elements and thin metallic films [6]. In addition, electrochemical micromachining can be easily hybridised with other processes to broaden the process capabilities and material processing window [7].…”

Section: Introductionmentioning

confidence: 99%

Pulsed Electrochemical Micromachining in Stainless Steel

Rodríguez¹,

Hidalgo²,

Labarga³

2021

Nanofibers - Synthesis, Properties and Applications

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This chapter presents research on pulsed electrochemical micromachining of stainless steel. Suitable equipment to study the process is described as well as a fitting procedure to machine and measure the variables involved. The pulse on-time must be maintained in the order of ns to achieve a good current confinement since the tool is active. Some experiments were carried out to assess the most important variables of the process: current confinement, surface roughness, material removal rate and efficiency. The current confinement has been observed to worsen when the pulse on-time increases, as well as the surface roughness. The material removal rate and efficiency increase with the voltage amplitude and the pulse on-time. The voltage amplitude must be higher than 12 V so that the phenomenon of passivation does not affect the process. There is a compromise in the choice of the variables, so a suitable combination of parameters is determined in order to achieve a good material removal rate with an acceptable result.

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Section: Introductionmentioning

confidence: 99%

Pulsed Electrochemical Micromachining in Stainless Steel

Rodríguez¹,

Hidalgo²,

Labarga³

2021

Nanofibers - Synthesis, Properties and Applications

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“…Electrochemical micromachining (ECMM) is a promising technology for fabricating surface structures [ 1 ]. In contrast to chemical etching (CE) which uses caustic acids/alkalis as a medium, ECMM uses a neutral saline solution [ 2 ].…”

Section: Introductionmentioning

confidence: 99%

Fast Fabrication of Complex Surficial Micro-Features Using Sequential Lithography and Jet Electrochemical Machining

Saxena

Guo

et al. 2020

Micromachines

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This paper presents fabrication of complex surficial micro-features employing a cross-innovative hybrid process inspired from lithography and Jet-ECM. The process is referred here as mask electrolyte jet machining (MEJM). MEJM is a non-contact machining process which combines high resolution of lithography and greater flexibility of Jet-ECM. It is a non-contact process which can fabricate variety of microstructures on difficult-to-machine materials without need of expensive tooling. The presented work demonstrates the process performance of this technology by statistical analysis and multivariate kernel density estimation (KDE) based on probabilistic density function. Micro-letters are fabricated as an example of complex surficial structure comprising of multiple intersecting, straight and curved grooves. The processing response is characterized in terms of geometrical size, similarity ratio, and cumulative shape deviation. Experimental results demonstrated that micro letters with good repeatability (minimum SD of shape error ratio 0.297%) and shape accuracy (minimum shape error of 0.039%) can be fabricated with this technology. The results suggest MEJM could be a promising technology for batch manufacturing of surface microstructures with high productivity.

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“…Over the years, different variants and hybridizations of this process have been developed by an ever-growing spectrum of the areas of applications. 1 Hybridizations, such as laser-assisted jet ECM, 2,3 electrochemical (EC) spark machining, 4 EC grinding, and so on, involve the amalgamation of two separate modes of material removal to form a novel technique having significant advantages over their parent techniques. Variants include processes, such as ECT, EC milling, EC polishing/ finishing, 5 jet ECM, 6 and so on, where the relative motion between the tool and workpiece is manipulated in order to impart the desired shape to the workpiece.…”

Section: Introductionmentioning

confidence: 99%

Experimental and analytical investigations into wire electrochemical micro turning

Tyagi

Sharma

Patel

et al. 2019

Journal of Micromanufacturing

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Notations d w = wire (tool) diameter E = electrochemical equivalent of workpiece material F = Faraday's constant (96,500 coulombs) f = radial feed rate of tool IEG frontal = frontal minimum inter-electrode gap (b) IEG side = side inter-electrode gap (s) K eff = effective electrical conductivity of electrolyte K o = initial electrical conductivity of electrolyte K d = electrical conductivity of dispersed medium T = temperature of electrolyte V = applied electric potential ΔV = overpotential of the circuit V b = Volume fraction of gas bubbles V s = Volume fraction of sludge α, β, γ = constants ∅ = electric potential ƞ = system current efficiency Ξ = temperature coefficient of specific conductance ρ m = density of workpiece material

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A review on process capabilities of electrochemical micromachining and its hybrid variants

Cited by 193 publications

References 205 publications

Pulsed Electrochemical Micromachining in Stainless Steel

Pulsed Electrochemical Micromachining in Stainless Steel

Fast Fabrication of Complex Surficial Micro-Features Using Sequential Lithography and Jet Electrochemical Machining

Experimental and analytical investigations into wire electrochemical micro turning

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