Computational fluid-dynamics modeling of the hydrodynamics of fluidization in the sand surrounding a lost-foam casting pattern
In many modern industries, complex shapes arise which require advanced metal casting processes to produce a component. The problem with these cast parts is the empiricism required to develop the casting process and the accompanying time and expense involved. The PHOENICS commercial software package...
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| Veröffentlicht in: | Metallurgical and materials transactions. B, Process metallurgy and materials processing science Process metallurgy and materials processing science, 2002-08, Vol.33 (4), p.565-575 |
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| container_title | Metallurgical and materials transactions. B, Process metallurgy and materials processing science |
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| creator | HUDSON, Nathanael BHAVNANI, Sushil H OVERFELT, Ruel A |
| description | In many modern industries, complex shapes arise which require advanced metal casting processes to produce a component. The problem with these cast parts is the empiricism required to develop the casting process and the accompanying time and expense involved. The PHOENICS commercial software package was amended to simulate the flow around the precasting foam geometry. Employing a two-fluid approach, each phase was considered a fluid that interpenetrates the other phase. The modification required that the kinetic theory of granular flow for the sand phase be incorporated into the recompilable PHOENICS code. The results of this study consisted of time-averaged voidage patterns, with voidage being defined as the volume fraction of air in the mixture around the foam pattern submerged in a 2D fluidized bed. The model was benchmarked against fluidized-bed experiments performed by previous investigators. In order to elucidate the dependence of the voidage around the lost-foam pattern, selected physical parameters were varied, and the resultant void-fraction maps were predicted with the model. Physical parameters such as the aspect ratio of the width to length of the foam pattern, the placement of the mixing jet, and different mixing-jet velocities were varied to illustrate the dependence of the time-averaged void fraction on those variables. The simulations identified the presence of channeling around the lost-foam pattern, with the extent of the channeling and void formation reliant to a greater degree upon the placement of the mixing jet and, to a lesser degree, on the mixing-jet velocity and aspect ratio. The placement of the mixing jet halfway between the internal foam pattern and the right wall had the desirable benefit of granting the sand-churning benefits of a penetrating jet. (Author) |
| doi_str_mv | 10.1007/s11663-002-0036-z |
| format | Article |
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The problem with these cast parts is the empiricism required to develop the casting process and the accompanying time and expense involved. The PHOENICS commercial software package was amended to simulate the flow around the precasting foam geometry. Employing a two-fluid approach, each phase was considered a fluid that interpenetrates the other phase. The modification required that the kinetic theory of granular flow for the sand phase be incorporated into the recompilable PHOENICS code. The results of this study consisted of time-averaged voidage patterns, with voidage being defined as the volume fraction of air in the mixture around the foam pattern submerged in a 2D fluidized bed. The model was benchmarked against fluidized-bed experiments performed by previous investigators. In order to elucidate the dependence of the voidage around the lost-foam pattern, selected physical parameters were varied, and the resultant void-fraction maps were predicted with the model. Physical parameters such as the aspect ratio of the width to length of the foam pattern, the placement of the mixing jet, and different mixing-jet velocities were varied to illustrate the dependence of the time-averaged void fraction on those variables. The simulations identified the presence of channeling around the lost-foam pattern, with the extent of the channeling and void formation reliant to a greater degree upon the placement of the mixing jet and, to a lesser degree, on the mixing-jet velocity and aspect ratio. The placement of the mixing jet halfway between the internal foam pattern and the right wall had the desirable benefit of granting the sand-churning benefits of a penetrating jet. 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B, Process metallurgy and materials processing science</title><description>In many modern industries, complex shapes arise which require advanced metal casting processes to produce a component. The problem with these cast parts is the empiricism required to develop the casting process and the accompanying time and expense involved. The PHOENICS commercial software package was amended to simulate the flow around the precasting foam geometry. Employing a two-fluid approach, each phase was considered a fluid that interpenetrates the other phase. The modification required that the kinetic theory of granular flow for the sand phase be incorporated into the recompilable PHOENICS code. The results of this study consisted of time-averaged voidage patterns, with voidage being defined as the volume fraction of air in the mixture around the foam pattern submerged in a 2D fluidized bed. The model was benchmarked against fluidized-bed experiments performed by previous investigators. In order to elucidate the dependence of the voidage around the lost-foam pattern, selected physical parameters were varied, and the resultant void-fraction maps were predicted with the model. Physical parameters such as the aspect ratio of the width to length of the foam pattern, the placement of the mixing jet, and different mixing-jet velocities were varied to illustrate the dependence of the time-averaged void fraction on those variables. The simulations identified the presence of channeling around the lost-foam pattern, with the extent of the channeling and void formation reliant to a greater degree upon the placement of the mixing jet and, to a lesser degree, on the mixing-jet velocity and aspect ratio. The placement of the mixing jet halfway between the internal foam pattern and the right wall had the desirable benefit of granting the sand-churning benefits of a penetrating jet. 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B, Process metallurgy and materials processing science</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>HUDSON, Nathanael</au><au>BHAVNANI, Sushil H</au><au>OVERFELT, Ruel A</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Computational fluid-dynamics modeling of the hydrodynamics of fluidization in the sand surrounding a lost-foam casting pattern</atitle><jtitle>Metallurgical and materials transactions. B, Process metallurgy and materials processing science</jtitle><date>2002-08-01</date><risdate>2002</risdate><volume>33</volume><issue>4</issue><spage>565</spage><epage>575</epage><pages>565-575</pages><issn>1073-5615</issn><eissn>1543-1916</eissn><coden>MTTBCR</coden><abstract>In many modern industries, complex shapes arise which require advanced metal casting processes to produce a component. The problem with these cast parts is the empiricism required to develop the casting process and the accompanying time and expense involved. The PHOENICS commercial software package was amended to simulate the flow around the precasting foam geometry. Employing a two-fluid approach, each phase was considered a fluid that interpenetrates the other phase. The modification required that the kinetic theory of granular flow for the sand phase be incorporated into the recompilable PHOENICS code. The results of this study consisted of time-averaged voidage patterns, with voidage being defined as the volume fraction of air in the mixture around the foam pattern submerged in a 2D fluidized bed. The model was benchmarked against fluidized-bed experiments performed by previous investigators. In order to elucidate the dependence of the voidage around the lost-foam pattern, selected physical parameters were varied, and the resultant void-fraction maps were predicted with the model. 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| subjects | Applied sciences Exact sciences and technology Foundry engineering Metals. Metallurgy Molding materials. Mold making. Core making Production techniques |
| title | Computational fluid-dynamics modeling of the hydrodynamics of fluidization in the sand surrounding a lost-foam casting pattern |
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