Parametric mapping of linear deposition morphology in uniform metal droplet deposition technique

• Published in: Journal of materials processing technology Vol. 264; pp. 234 - 239
• Main Authors: Zhang, Daicong, Qi, Lehua, Luo, Jun, Yi, Hao, Xiong, Wei, Mo, Yuanbing
• Format: Journal Article
• Language: English
• Published: Amsterdam Elsevier B.V 01.02.2019; Elsevier BV
• Subjects: Charge coupled devices; Deposition; Drop size distribution; Droplet spacing; Droplets; Linear deposition morphology; Linear equations; Mapping; Mathematical models; Mathematical morphology; Metal droplet; Metals; Parameter identification; Parametric mapping; Process parameters; Solidification; Metal droplet; Parametric mapping; Linear deposition morphology; Droplet spacing
• ISSN: 0924-0136; 1873-4774
• DOI: 10.1016/j.jmatprotec.2018.08.048

The parametric mapping of linear deposition morphology with different droplet spacing is first proposed, which provides a baseline for parameter selection in uniform metal droplet deposition technique. Experiments related to linear deposition are carried out with deviating droplet size and deposition placement. Deposition morphology is first categorized into inclined region, wave-shaped region and horizontal region. Horizontal region is further classified into overlapped sub-region, clustered sub-region and discrete sub-region. Mathematical models about classification of deposition morphology are established by these initial parameters: offset ratio, merge ratio, solidification angle, and maximum spreading diameter. After mathematical models are established, boundaries between regions are extracted, and then verified by CCD (Charge-coupled Device) photographs and experimental data. Based on the above models and experiment results, the parametric mapping is found and verified. The following conclusions can be drawn: uncontrollable wave-shaped and clustered regions are not suitable for forming parts, hence the selected process parameters should be avoided in the above regions; Controllable inclined, overlapped and discrete regions can be used to forming part, hence the process parameters should fall into these regions. Furthermore, some possible applications are explored corresponding to three controllable regions with the help of the parametric mapping.