Pressure drop and friction factor for different shapes of microchannels
A numerical investigation has been performed on the pressure drop and friction factor of water flow in three different shapes of microchannel heat sinks which are rectangular, trapezoidal, and triangular for Reynolds number range of 100-1000. The three-dimensional steady, laminar flow and heat trans...
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my.uniten.dspace-307402023-12-29T15:52:14Z Pressure drop and friction factor for different shapes of microchannels Gunnasegaran P. Mohammed H. Shuaib N.H. 35778031300 15837504600 13907934500 Friction factor Microchannels Numerical simulation Pressure drop Channel flow Computer simulation Friction Heat sinks Hydraulics Laminar flow Pressure drop Reynolds number Sustainable development Tribology Diameter ratio Friction factor Friction factors Geometrical parameters Governing equations Height ratio Hydraulic diameter Micro channel heat sinks Numerical investigations Numerical simulation Poiseuille numbers Rectangular microchannels Tip angle Transition Reynolds number Trapezoidal microchannels Triangular microchannels Water flows Width ratio Microchannels A numerical investigation has been performed on the pressure drop and friction factor of water flow in three different shapes of microchannel heat sinks which are rectangular, trapezoidal, and triangular for Reynolds number range of 100-1000. The three-dimensional steady, laminar flow and heat transfer governing equations are solved using the finite volume method. It is found that the values of Poiseuille number and friction factor depend greatly on different geometrical parameters. It is also inferred that the heat sink having the smallest hydraulic diameter for each type of shapes under consideration has better performance among the other heat sinks studied. The values of Poiseuille number and friction factor increase with the increase of width-height ratio (Wc/Hc) for rectangular microchannels. For trapezoidal microchannels, the Poiseuille number and friction factor increase with the increase of bottom-to-top width ratio (b/a), increase with the decrease of height-to-top width ratio (h/a), increase with the decrease of length-tohydraulic diameter ratio (L/Dh). While for triangular microchannels, the Poiseuille number and friction factor increase with the increase of its tip angle (?). It is identified that the transition Reynolds number from laminar flow to turbulent flow is occurred at 1100. �2009 IEEE. Final 2023-12-29T07:52:14Z 2023-12-29T07:52:14Z 2009 Conference paper 10.1109/ICEENVIRON.2009.5398611 2-s2.0-77949643494 https://www.scopus.com/inward/record.uri?eid=2-s2.0-77949643494&doi=10.1109%2fICEENVIRON.2009.5398611&partnerID=40&md5=4ad686189787c2142c1cbe4e29ea3a78 https://irepository.uniten.edu.my/handle/123456789/30740 5398611 418 426 Scopus |
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Friction factor Microchannels Numerical simulation Pressure drop Channel flow Computer simulation Friction Heat sinks Hydraulics Laminar flow Pressure drop Reynolds number Sustainable development Tribology Diameter ratio Friction factor Friction factors Geometrical parameters Governing equations Height ratio Hydraulic diameter Micro channel heat sinks Numerical investigations Numerical simulation Poiseuille numbers Rectangular microchannels Tip angle Transition Reynolds number Trapezoidal microchannels Triangular microchannels Water flows Width ratio Microchannels |
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Friction factor Microchannels Numerical simulation Pressure drop Channel flow Computer simulation Friction Heat sinks Hydraulics Laminar flow Pressure drop Reynolds number Sustainable development Tribology Diameter ratio Friction factor Friction factors Geometrical parameters Governing equations Height ratio Hydraulic diameter Micro channel heat sinks Numerical investigations Numerical simulation Poiseuille numbers Rectangular microchannels Tip angle Transition Reynolds number Trapezoidal microchannels Triangular microchannels Water flows Width ratio Microchannels Gunnasegaran P. Mohammed H. Shuaib N.H. Pressure drop and friction factor for different shapes of microchannels |
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A numerical investigation has been performed on the pressure drop and friction factor of water flow in three different shapes of microchannel heat sinks which are rectangular, trapezoidal, and triangular for Reynolds number range of 100-1000. The three-dimensional steady, laminar flow and heat transfer governing equations are solved using the finite volume method. It is found that the values of Poiseuille number and friction factor depend greatly on different geometrical parameters. It is also inferred that the heat sink having the smallest hydraulic diameter for each type of shapes under consideration has better performance among the other heat sinks studied. The values of Poiseuille number and friction factor increase with the increase of width-height ratio (Wc/Hc) for rectangular microchannels. For trapezoidal microchannels, the Poiseuille number and friction factor increase with the increase of bottom-to-top width ratio (b/a), increase with the decrease of height-to-top width ratio (h/a), increase with the decrease of length-tohydraulic diameter ratio (L/Dh). While for triangular microchannels, the Poiseuille number and friction factor increase with the increase of its tip angle (?). It is identified that the transition Reynolds number from laminar flow to turbulent flow is occurred at 1100. �2009 IEEE. |
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35778031300 |
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35778031300 Gunnasegaran P. Mohammed H. Shuaib N.H. |
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Conference paper |
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Gunnasegaran P. Mohammed H. Shuaib N.H. |
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Gunnasegaran P. |
title |
Pressure drop and friction factor for different shapes of microchannels |
title_short |
Pressure drop and friction factor for different shapes of microchannels |
title_full |
Pressure drop and friction factor for different shapes of microchannels |
title_fullStr |
Pressure drop and friction factor for different shapes of microchannels |
title_full_unstemmed |
Pressure drop and friction factor for different shapes of microchannels |
title_sort |
pressure drop and friction factor for different shapes of microchannels |
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2023 |
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1806428182572695552 |
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13.222552 |