Natural convective heat removal from the heat generating electronics component using metallic porous extensions Article Swipe

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Sumit Kumar Mehta , Pranab Kumar Mondal , Somchai Wongwises ·

YOU? · · 2024 · Open Access · · DOI: https://doi.org/10.1063/5.0205306

We investigated free convective heat transfer within an electronics cooling system with a metallic porous extension. The finite element method is used to solve the associated transport equations. Changing fluidic and geometric parameters allows examination of the isotherm contour, streamlines, and heater average temperature. It is found that the presence of a metallic porous block causes higher temperature up to a greater height of the domain than the absence of a porous material. The strength of the vortex is greater in the case of porous extension than in the case of no extension. Furthermore, the effect of Darcy number (Da) on average heater temperature (θavg) is negligible. The value of θavg decreases as the height of the porous extension increases. Inferences obtained from this analysis are expected to provide an adequate basis for the effective design of small-scale thermal management devices/systems that are typically used in electronic cooling systems.

Related Topics

Streamlines, Streaklines, And Pathlines

Convection (Heat Transfer)

Composite Material

Engineering

Physics

Electrical Engineering

Concepts

Streamlines, streaklines, and pathlines Materials science Porous medium Electronics cooling Natural convection Heat transfer Porosity Mechanics Electronics Convection Convective heat transfer Thermodynamics Composite material Engineering Physics Electrical engineering

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Type: article
Language: en
Landing Page: https://doi.org/10.1063/5.0205306
PDF: https://pubs.aip.org/aip/acp/article-pdf/doi/10.1063/5.0205306/19958041/090001_1_5.0205306.pdf
OA Status: bronze
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DOI: https://doi.org/10.1063/5.0205306

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Title: Natural convective heat removal from the heat generating electronics component using metallic porous extensions

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Language: en

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Publication year: 2024

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Publication date: 2024-01-01

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Authors: Sumit Kumar Mehta, Pranab Kumar Mondal, Somchai Wongwises

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Landing page: https://doi.org/10.1063/5.0205306

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Concepts: Streamlines, streaklines, and pathlines, Materials science, Porous medium, Electronics cooling, Natural convection, Heat transfer, Porosity, Mechanics, Electronics, Convection, Convective heat transfer, Thermodynamics, Composite material, Engineering, Physics, Electrical engineering

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abstract_inverted_index.system	10
abstract_inverted_index.vortex	77
abstract_inverted_index.within	6
abstract_inverted_index.(θavg)	104
abstract_inverted_index.absence	68
abstract_inverted_index.average	42, 101
abstract_inverted_index.cooling	9, 147
abstract_inverted_index.element	18
abstract_inverted_index.fluidic	29
abstract_inverted_index.greater	61, 79
abstract_inverted_index.provide	128
abstract_inverted_index.thermal	138
abstract_inverted_index.Changing	28
abstract_inverted_index.adequate	130
abstract_inverted_index.analysis	124
abstract_inverted_index.contour,	38
abstract_inverted_index.expected	126
abstract_inverted_index.isotherm	37
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abstract_inverted_index.obtained	121
abstract_inverted_index.presence	49
abstract_inverted_index.strength	74
abstract_inverted_index.systems.	148
abstract_inverted_index.transfer	5
abstract_inverted_index.decreases	111
abstract_inverted_index.effective	134
abstract_inverted_index.extension	85, 118
abstract_inverted_index.geometric	31
abstract_inverted_index.material.	72
abstract_inverted_index.transport	26
abstract_inverted_index.typically	143
abstract_inverted_index.Inferences	120
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abstract_inverted_index.convective	3
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abstract_inverted_index.equations.	27
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abstract_inverted_index.small-scale	137
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cited_by_percentile_year
countries_distinct_count	2
institutions_distinct_count	3
sustainable_development_goals[0].id	https://metadata.un.org/sdg/7
sustainable_development_goals[0].score	0.7400000095367432
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citation_normalized_percentile.is_in_top_1_percent	False
citation_normalized_percentile.is_in_top_10_percent	False