Modelling of droplet detachment in the laser droplet brazing process
Jeromen A, Held C, Govekar E, Schmidt M, Roth S (2014)
Publication Type: Journal article
Publication year: 2014
Journal
Book Volume: 214
Pages Range: 737-749
Journal Issue: 4
DOI: 10.1016/j.jmatprotec.2013.11.005
Abstract
The laser droplet brazing process has been recently experimentally considered for the electrical contacting of thermally sensitive components. In this process, a spherical brazing preform, placed in a tapering nozzle, is melted by a laser pulse, detached from the nozzle by a shielding gas overpressure, and deposited on the brazing spot. The detachment of the brazing droplet from the nozzle has been studied theoretically in this paper with the aim of providing guidance for the selection of the main process parameters, i.e. the gas overpressure and the droplet contact angle. The droplet detachment is described by two models: an algebraic droplet force balance model and a numerical isothermal two-phase fluid flow model. Using the droplet force balance based model, an algebraic expression defining the dependence of the maximum gas overpressure before droplet detachment on the droplet contact angle was obtained. The numerical model was used to determine the droplet detachment occurrence in terms of the main process parameters. Additionally, the nonlinear dependencies of the time of droplet detachment, the detached droplet velocity and vertical position, and the droplet shape on the gas overpressure and the brazing droplet contact angle were defined, and can be used for process parameter selection. It was also found that the detached droplet shape is influenced, beside the gas overpressure and the droplet contact angle, by oscillation of the droplet, which can be significant at droplet contact angle values of less than 75. Based on comparisons of the modelled and experimental results of droplet detachment time, vertical position of the detached droplet, and its shape, it was concluded that the contact angle of the CuSn11 brazing material on the WC/Co nozzle was, in the experiments, near 105. Furthermore, comparisons of the results indicated that the laser melting phase of the preform significantly influences droplet detachment, and should therefore be taken into consideration for the improvement of the numerical model. © 2013 Published by Elsevier B.V.
Authors with CRIS profile
Additional Organisation(s)
Involved external institutions
Bayerisches Laserzentrum gemeinnützige Forschungsgesellschaft mbH (BLZ)
Germany (DE)
University of Ljubljana (UL) / Univerza v Ljubljani
Slovenia (SI)
Germany (DE)
University of Ljubljana (UL) / Univerza v Ljubljani
Slovenia (SI)
How to cite
APA:
Jeromen, A., Held, C., Govekar, E., Schmidt, M., & Roth, S. (2014). Modelling of droplet detachment in the laser droplet brazing process. Journal of Materials Processing Technology, 214(4), 737-749. https://doi.org/10.1016/j.jmatprotec.2013.11.005
MLA:
Jeromen, Andrej, et al. "Modelling of droplet detachment in the laser droplet brazing process." Journal of Materials Processing Technology 214.4 (2014): 737-749.
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