Abstract
Many microslits are typically manufactured on quartz substrates and are used to improve their industrial performance. The fabrication of microslits on quartz is difficult and expensive to achieve using recent traditional machining processes due to its hardness, electrically insulating nature, and brittleness. The key objective of the current study was to demonstrate the fabrication of microslits on quartz material through a magnetohydrodynamics (MHD)-assisted traveling wire-electrochemical discharge micromachining process. Hydrogen gas bubbles were concentrated around the entire wire surface during electrolysis. This led to a less active dynamic region of the wire electrode, which decreased the adequacy of the electrolysis process and the machining effectiveness. The test results affirmed that the MHD convection approach evacuated the gas bubbles more rapidly and improved the void fraction in the gas bubble scattering layer. Furthermore, the improvements in the material removal rate and length of the cut were 85.28% and 48.86%, respectively, and the surface roughness was reduced by 30.39% using the MHD approach. A crossover methodology with a Taguchi design and ANOVA was utilized to study the machining performance. This exploratory investigation gives an unused strategy that shows a few advantages over the traditional TW-ECDM process.
Highlights
In recent times, the usage of miniature products and their applications has significantly increased
The patterns created in glass and ceramics are difficult to create due to the brittleness of quartz glass
Owing to its higher hardness, brittleness, and higher melting point, machining quartz is difficult [10] and quartz was used as the workpiece material for the study
Summary
The usage of miniature products and their applications has significantly increased. This has led to an increase in the demand to create complex geometries with precise dimensions and high quality. These devices are comprehensively studied, which allows for constructive applications for chemical and biological investigation [1]. The patterns created in glass and ceramics are difficult to create due to the brittleness of quartz glass. This led to glass and ceramics being replaced by polydimethylsiloxane (PDMS) in many applications [6]. Owing to its higher hardness, brittleness, and higher melting point, machining quartz is difficult [10] and quartz was used as the workpiece material for the study
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