A Review of Molten Metal Flow by Synchronizing of Computational Fluid Dynamics and Validation Through Algorithm Techniques
Keywords:
Molten, Algorithm, CFD, Flow, ReviewAbstract
Computational Fluid Dynamics (CFD) is treading numerical simulation algorithm which is occupying an enormous variety of transitions and different critical modeled which helps in inbounded validation. In this study a justified review of molten metal flow, investigating by CFD analysis, continuity of flow of equation, self-magnetic breakage forces experiment and several validation experiment are been endorsed.Many research paper are been reviewed but with the help of CFD analysis and validation with different algorithm equations but fluidity of molten flow was missing. However, the outcome of the study is to develop an algorithm to measure the effectiveness of forces in molten metal flow.
References
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Chapelle, P., et al. "High-speed imaging and CFD simulations of a deforming liquid metal droplet in an electromagnetic levitation experiment." Journal of materials science 43.9 (2008): 3001-3008.
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Lan, Wenjie, et al. "CFD simulation of droplet formation in microchannels by a modified level set method." Industrial & Engineering Chemistry Research 53.12 (2014): 4913-4921.
Mishima, K., et al. "Visualization study of molten metal–water interaction by using neutron radiography." Nuclear engineering and design 189.1-3 (1999): 391-403.
Nemchinsky, Valerian A. "Electrode melting during arc welding with pulsed current." Journal of Physics D: Applied Physics 31.20 (1998): 2797.
Nemchinsky, Valerian A. "Heat transfer in a liquid droplet hanging at the tip of an electrode during arc welding." Journal of Physics D: Applied Physics 30.7 (1997): 1120.
Simpson, S. W., and Peiyuan Zhu. "Formation of molten droplets at a consumable anode in an electric welding arc." Journal of Physics D: Applied Physics 28.8 (1995): 1594.
Sotowa, K?I., et al. "Droplet formation by the collision of two aqueous solutions in a microchannel and application to particle synthesis." Chemical Engineering & Technology: Industrial Chemistry?Plant Equipment?Process Engineering?Biotechnology 30.3 (2007): 383-388.
Sussman, Mark, and Elbridge Gerry Puckett. "A coupled level set and volume-of-fluid method for computing 3D and axisymmetric incompressible two-phase flows." Journal of computational physics 162.2 (2000): 301-337.
Thorsen, Todd, et al. "Dynamic pattern formation in a vesicle-generating microfluidic device." Physical review letters 86.18 (2001): 4163.
Weber, Michael W., and Robin Shandas. "Computational fluid dynamics analysis of microbubble formation in microfluidic flow-focusing devices." Microfluidics and Nanofluidics 3.2 (2007): 195-206.
Xu, J. H., et al. "Shear force induced monodisperse droplet formation in a microfluidic device by controlling wetting properties." Lab on a Chip 6.1 (2006): 131-136.
Zheng, Bo, Joshua D. Tice, and Rustem F. Ismagilov. "Formation of Arrayed Droplets by Soft Lithography and Two?Phase Fluid Flow, and Application in Protein Crystallization." Advanced Materials 16.15 (2004): 1365-1368.
Zheng, Bo, Joshua D. Tice, and Rustem F. Ismagilov. "Formation of droplets of alternating composition in microfluidic channels and applications to indexing of concentrations in droplet-based assays." Analytical chemistry 76.17 (2004): 4977-4982.
Amson, J. C. "Lorentz force in the molten tip of an arc electrode." British Journal of Applied Physics 16.8 (1965): 1169.
Chakraborty, Suman. "Analytical investigations on breakup of viscous liquid droplets on surface tension modulation during welding metal transfer." Applied physics letters 86.17 (2005): 174104.
Chin, R. K., J. L. Beuth, and C. H. Amon. "Thermomechanical modeling of molten metal droplet solidification applied to layered manufacturing." Mechanics of Materials 24.4 (1996): 257-271.
Chapelle, P., et al. "High-speed imaging and CFD simulations of a deforming liquid metal droplet in an electromagnetic levitation experiment." Journal of materials science 43.9 (2008): 3001-3008.
De Menech, Mario. "Modeling of droplet breakup in a microfluidic T-shaped junction with a phase-field model." Physical Review E 73.3 (2006): 031505.
Haidar, J., and J. J. Lowke. "Predictions of metal droplet formation in arc welding." Journal of Physics D: Applied Physics 29.12 (1996): 2951.
Jones, L. A., T. W. Eagar, and J. H. Lang. "Magnetic forces acting on molten drops in gas metal arc welding." Journal of Physics D: Applied Physics 31.1 (1998): 93.
Lan, Wenjie, et al. "CFD simulation of droplet formation in microchannels by a modified level set method." Industrial & Engineering Chemistry Research 53.12 (2014): 4913-4921.
Mishima, K., et al. "Visualization study of molten metal–water interaction by using neutron radiography." Nuclear engineering and design 189.1-3 (1999): 391-403.
Nemchinsky, Valerian A. "Electrode melting during arc welding with pulsed current." Journal of Physics D: Applied Physics 31.20 (1998): 2797.
Nemchinsky, Valerian A. "Heat transfer in a liquid droplet hanging at the tip of an electrode during arc welding." Journal of Physics D: Applied Physics 30.7 (1997): 1120.
Simpson, S. W., and Peiyuan Zhu. "Formation of molten droplets at a consumable anode in an electric welding arc." Journal of Physics D: Applied Physics 28.8 (1995): 1594.
Sotowa, K?I., et al. "Droplet formation by the collision of two aqueous solutions in a microchannel and application to particle synthesis." Chemical Engineering & Technology: Industrial Chemistry?Plant Equipment?Process Engineering?Biotechnology 30.3 (2007): 383-388.
Sussman, Mark, and Elbridge Gerry Puckett. "A coupled level set and volume-of-fluid method for computing 3D and axisymmetric incompressible two-phase flows." Journal of computational physics 162.2 (2000): 301-337.
Thorsen, Todd, et al. "Dynamic pattern formation in a vesicle-generating microfluidic device." Physical review letters 86.18 (2001): 4163.
Weber, Michael W., and Robin Shandas. "Computational fluid dynamics analysis of microbubble formation in microfluidic flow-focusing devices." Microfluidics and Nanofluidics 3.2 (2007): 195-206.
Xu, J. H., et al. "Shear force induced monodisperse droplet formation in a microfluidic device by controlling wetting properties." Lab on a Chip 6.1 (2006): 131-136.
Zheng, Bo, Joshua D. Tice, and Rustem F. Ismagilov. "Formation of Arrayed Droplets by Soft Lithography and Two?Phase Fluid Flow, and Application in Protein Crystallization." Advanced Materials 16.15 (2004): 1365-1368.
Zheng, Bo, Joshua D. Tice, and Rustem F. Ismagilov. "Formation of droplets of alternating composition in microfluidic channels and applications to indexing of concentrations in droplet-based assays." Analytical chemistry 76.17 (2004): 4977-4982.
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Published
2022-02-22
How to Cite
Saha, A. K. ., & Majumdar, S. . (2022). A Review of Molten Metal Flow by Synchronizing of Computational Fluid Dynamics and Validation Through Algorithm Techniques. Proceeding International Conference on Religion, Science and Education, 1, 507–511. Retrieved from http://sunankalijaga.org/prosiding/index.php/icrse/article/view/830
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