Villeneuve, Guillaume, Leclair, Jean-Philippe, Wuthrich, Rolf et Hof, Lucas A.. 2025. « Precision machining of glass in the submillimeter scale using thermochemically-assisted grinding ». Communication lors de la conférence : CSME-CFDSC-CSR 2025 International Congress (Montreal, QC, Canada, May 25-28, 2025).
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Résumé
The mechanical, optical, and thermal properties of glass make it well-adapted for use in Micro-Electromechanical Systems, optics, and microfluidics. However, micromachining glass and other SiO2-based materials poses significant challenges due to their hardness and brittleness. Mechanical, thermal, and chemical machining processes face constraints related to processing speed, feature precision, and high costs. Additionally, the demand for glass microsystems is growing, and there is a lack of processes adapted to small-batch production and rapid prototyping of sub-millimeter scale glass parts.Spark-Assisted Chemical Engraving (SACE), or Electro-Chemical Discharge Machining, is a hybrid machining process combining chemical and thermal effects to remove material. A tool-electrode applies electrochemical discharges near a nonconductive workpiece submerged in an electrolytic solution, accelerating the chemical etching through localized heating. This process removes material with minimal damage.In the past years it was proposed to use abrasive tool-electrodes for simultaneous material removal through electrochemical discharges and mechanical grinding, improving material removal rates, while conserving the advantages of SACE, such as the absence of material redeposition and good surface quality. While some studies demonstrate the synergy between grinding and thermochemical etching, understanding the underlying mechanism of this hybrid machining process remains limited. This work aims to better characterize the interactions of the two material removal mechanisms and thus define a range of operating parameters to improve processing speed, reliability and cutting quality.Borosilicate glass workpieces were submerged in 27% (wt.) potassium hydroxide (KOH). The tool-electrode, a 0.8 mm diameter diamond-coated grinding bit with cobalt binder, was used to grind and apply electrochemical discharges to create 0.8-mm wide channels in the workpiece. The effects of varying machining voltage, tool rotation speed, feed rate and depth of cut were studied. The measured response parameters were machining force, surface roughness and frequency of chipping of the material. Different cutting regimes were identified based on the relative intensity of the mechanical and chemical attacks.It was found that the proposed thermochemically-assisted grinding process produces better surface quality with less chipping than grinding alone. In conventional machining, machining forces on the tool increase linearly with material removal rate (MRR). When electrochemical attack is combined with mechanical grinding, this relation is no longer linear; machining forces do not intervene at all for lower MRR and are greatly reduced at higher MRR.It was shown that thermochemically-assisted grinding offers higher processing speed than SACE, improving potential for economically viable manufacturing of millimeter-scale glass parts in small batches.
| Type de document: | Communication (Communication) |
|---|---|
| Informations complémentaires: | Progress in Canadian Mechanical Engineering, Volume 8. Co-chairs: Lucas A. Hof, Giuseppe Di Labbio, Antoine Tahan, Marlène Sanjosé, Sébastien Lalonde and Nicole R. Demarquette. |
| Professeur: | Professeur Hof, Lucas |
| Affiliation: | Génie mécanique |
| Date de dépôt: | 18 déc. 2025 14:55 |
| Dernière modification: | 18 déc. 2025 14:55 |
| URI: | https://espace2.etsmtl.ca/id/eprint/32258 |
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