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A new perspective of constructal networks cooling a finite-size volume generating heat

descriptionPublicationkeyboard_double_arrow_right Article , Journal 01 Feb 2011 France Publisher:Elsevier BVJournal:Energy Conversion and Management, volume 52, pages 1,033-1,046 (issn: 0196-8904,

Authors:

Jean-Luc Harion; Gilles Marck; Gilles Marck; Maroun Nemer;

Daniel Bougeard;

Serge Russeil;

doi: 10.1016/j.enconman.2010.08.032

A new perspective of constructal networks cooling a finite-size volume generating heat

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Abstract

Abstract Constructal theory has been used in several scientific fields since it has been established a decade ago. It mainly treats of the “area to point” flow problem, which has been first-written in the frame of the cooling of a finite-size volume generating heat. This problem, widely discussed in literature, has been optimized thanks to constructal theory formulated by Bejan, with a deterministic approach. However, some of the physical and mathematical assumptions made to simplify the problem are questionable, especially the ones regarding the high-conductivity material constituting the tree-shaped structure. In this paper, the performances of constructal designs are evaluated using a finite volume method, which allows making a comparison between different constructal geometries. An algorithm has been developed which has the ability for restraining constructal networks inside a finite-size area, without overconstraining the structure. All things considered, this paper examines constructal theory from a new point of view thanks to analytical and numerical investigations, in the frame of a finite-size volume generating heat.

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Keywords

Optimization, [ SPI.ENERG ] Engineering Sciences [physics]/domain_spi.energ, 621, High-conductivity materials, [SPI.ENERG]Engineering Sciences [physics]/domain_spi.energ, Constructal theory, Tree-networks, Flow problems, [SPI.ENERG] Engineering Sciences/domain_spi.energ, Deterministic approach, Numerical investigations

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