2025 |
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| 1. |  | N. L. Mai, T. H. Vu, H. Vu, C. Doan, Y. K. Yong, T. X. Dinh, D. V. Dao, V. T. Dau Evaporation in electrohydrodynamic atomisation: A numerical and experimental investigation Journal Article In: International Communications in Heat and Mass Transfer, vol. 165, Part B, pp. 109079, 2025. Abstract | Links | BibTeX | Tags: Electrohydrodynamics, Evaporation @article{Mai2025b,In this paper, the influence of evaporation in electrohydrodynamic atomization (electrospray) is numerically and experimentally investigated. The simulation was performed utilizing the Taylor-Melcher's leaky-dielectric model and the d2 Law to simulate thermophysical processes in electrospray. Experiments were conducted to validate the numerical approach and to investigate the influence of evaporation on particle morphology. Results by simulations are consistent with experiments, showing agreement in both Taylor-cone captured by high-speed camera and vapour field visualized by Schlieren imaging. Experiments on different solvents suggest major impacts of interelectrode distance on the residual solvent on the collected particles. However, these impacts were less significant on particle size and morphology particularly when using solvents with medium to low volatility. Particle size is found to increase with temperature and solvent volatility, confirming the correlation reported in literature. Moreover, evaporation was determined to have limited effect on the overall shape of the Taylor-cone and spray jet, due to inherently high vapour concentration around the nozzle vicinity. These contributions will improve the understanding of evaporation process in electrospray and offer useful guidelines for optimizing the technique, particularly in situations where evaporation is a key factor controlling particle size and minimizing harmful residue. Keywords: Numerical methods; Evaporation; Electrospray; Electrohydrodynamic atomization; Experiments; Particle morphology |
2025 |
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| 1. | | Evaporation in electrohydrodynamic atomisation: A numerical and experimental investigation Journal Article In: International Communications in Heat and Mass Transfer, vol. 165, Part B, pp. 109079, 2025. |