Skin friction calculation for PU/PIR against steel duct using CFD
The PU/PIR duct has texture of 0.5mm height along the duct. This study focus on the frictional loss of flow through a rectangular duct of PU/PIR duct. As a compariosn a steel duct with surface roughness is also simulated. The duct considered in this study has a cross-section of 300mm X 300mm and len...
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my.uniten.dspace-307432023-12-29T15:52:19Z Skin friction calculation for PU/PIR against steel duct using CFD Munisamy K.M. Yusoff Mohd.Z. Soon S.P. Cheong P.W. 15035918600 7003976733 35779124700 35777612800 CFD PU/PIR duct Skin friction Computational fluid dynamics Friction Skin friction Surface roughness Sustainable development Textures Tribology CFD Coefficient of frictions Computational nodes Flow condition Flowthrough Frictional loss In-buildings Non-uniform mesh PU/PIR duct Rectangular ducts Small geometry Tetrahedral elements Ducts The PU/PIR duct has texture of 0.5mm height along the duct. This study focus on the frictional loss of flow through a rectangular duct of PU/PIR duct. As a compariosn a steel duct with surface roughness is also simulated. The duct considered in this study has a cross-section of 300mm X 300mm and length of 1500mm. The two designs are simulated in FLUENT proprietry software. The Hybrid tetrahedral element grids are used in building non-uniform mesh. The total computational nodes involved in the calculation are about 3 million cells. This is due to the small geometry of the PU/PIR duct texture at the wall. The appropriate boundary setting and numerical setting is explained in proceeding section. The geometry generated is then simulated for 200CFM, 400CFM, 800CFM, and 1200CFM flow conditions. (CFM = cubic feet per minute) The mesh generated and the results are presented. The coefficient of friction is calculated from CFD and plotted. The velocity and pressure distribution are also illustrated for all CFM simulated. �2009 IEEE. Final 2023-12-29T07:52:19Z 2023-12-29T07:52:19Z 2009 Conference paper 10.1109/ICEENVIRON.2009.5398615 2-s2.0-77949586379 https://www.scopus.com/inward/record.uri?eid=2-s2.0-77949586379&doi=10.1109%2fICEENVIRON.2009.5398615&partnerID=40&md5=ca4f73d8de4ca38299b507110e9d96f8 https://irepository.uniten.edu.my/handle/123456789/30743 5398615 393 401 Scopus |
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CFD PU/PIR duct Skin friction Computational fluid dynamics Friction Skin friction Surface roughness Sustainable development Textures Tribology CFD Coefficient of frictions Computational nodes Flow condition Flowthrough Frictional loss In-buildings Non-uniform mesh PU/PIR duct Rectangular ducts Small geometry Tetrahedral elements Ducts |
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CFD PU/PIR duct Skin friction Computational fluid dynamics Friction Skin friction Surface roughness Sustainable development Textures Tribology CFD Coefficient of frictions Computational nodes Flow condition Flowthrough Frictional loss In-buildings Non-uniform mesh PU/PIR duct Rectangular ducts Small geometry Tetrahedral elements Ducts Munisamy K.M. Yusoff Mohd.Z. Soon S.P. Cheong P.W. Skin friction calculation for PU/PIR against steel duct using CFD |
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The PU/PIR duct has texture of 0.5mm height along the duct. This study focus on the frictional loss of flow through a rectangular duct of PU/PIR duct. As a compariosn a steel duct with surface roughness is also simulated. The duct considered in this study has a cross-section of 300mm X 300mm and length of 1500mm. The two designs are simulated in FLUENT proprietry software. The Hybrid tetrahedral element grids are used in building non-uniform mesh. The total computational nodes involved in the calculation are about 3 million cells. This is due to the small geometry of the PU/PIR duct texture at the wall. The appropriate boundary setting and numerical setting is explained in proceeding section. The geometry generated is then simulated for 200CFM, 400CFM, 800CFM, and 1200CFM flow conditions. (CFM = cubic feet per minute) The mesh generated and the results are presented. The coefficient of friction is calculated from CFD and plotted. The velocity and pressure distribution are also illustrated for all CFM simulated. �2009 IEEE. |
author2 |
15035918600 |
author_facet |
15035918600 Munisamy K.M. Yusoff Mohd.Z. Soon S.P. Cheong P.W. |
format |
Conference paper |
author |
Munisamy K.M. Yusoff Mohd.Z. Soon S.P. Cheong P.W. |
author_sort |
Munisamy K.M. |
title |
Skin friction calculation for PU/PIR against steel duct using CFD |
title_short |
Skin friction calculation for PU/PIR against steel duct using CFD |
title_full |
Skin friction calculation for PU/PIR against steel duct using CFD |
title_fullStr |
Skin friction calculation for PU/PIR against steel duct using CFD |
title_full_unstemmed |
Skin friction calculation for PU/PIR against steel duct using CFD |
title_sort |
skin friction calculation for pu/pir against steel duct using cfd |
publishDate |
2023 |
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1806425557203681280 |