A second-law comparison of irreversibilities is used to determine the optimum duct geometry which minimizes losses for a range of laminar flows and constant heat flux. The duct geometries used are circular, square, equilaterally triangular, rectangular with an aspect ratio of 1/2, and sinusoidal with an aspect ratio of . Hydraulic diameters are used for the different geometries. The circular geometry is best, especially when the frictional contributions of entropy generation become important. Triangular and rectangular duct geometries are inferior choices for both entropy generation and pumping power.
Description
ScienceDirect - Energy : Irreversibilities in various duct geometries with constant wall heat flux and laminar flow
%0 Journal Article
%1 Sahin1998
%A Şahin, Ahmet Z.
%D 1998
%J Energy
%K 1998 EGM SLA entropy flow friction laminar
%N 6
%P 465--473
%R 10.1016/S0360-5442(98)00010-3
%T Irreversibilities in various duct geometries with constant wall heat flux and laminar flow
%U http://dx.doi.org/10.1016/S0360-5442(98)00010-3
%V 23
%X A second-law comparison of irreversibilities is used to determine the optimum duct geometry which minimizes losses for a range of laminar flows and constant heat flux. The duct geometries used are circular, square, equilaterally triangular, rectangular with an aspect ratio of 1/2, and sinusoidal with an aspect ratio of . Hydraulic diameters are used for the different geometries. The circular geometry is best, especially when the frictional contributions of entropy generation become important. Triangular and rectangular duct geometries are inferior choices for both entropy generation and pumping power.
@article{Sahin1998,
abstract = {A second-law comparison of irreversibilities is used to determine the optimum duct geometry which minimizes losses for a range of laminar flows and constant heat flux. The duct geometries used are circular, square, equilaterally triangular, rectangular with an aspect ratio of 1/2, and sinusoidal with an aspect ratio of . Hydraulic diameters are used for the different geometries. The circular geometry is best, especially when the frictional contributions of entropy generation become important. Triangular and rectangular duct geometries are inferior choices for both entropy generation and pumping power.},
added-at = {2011-01-19T18:07:24.000+0100},
author = {Şahin, Ahmet Z.},
biburl = {https://www.bibsonomy.org/bibtex/28393a015a4ac6b6928e6c6c4645f83d6/thorade},
description = {ScienceDirect - Energy : Irreversibilities in various duct geometries with constant wall heat flux and laminar flow},
doi = {10.1016/S0360-5442(98)00010-3},
interhash = {a5a2c28cd72dfaac96f4929ba529e9a6},
intrahash = {8393a015a4ac6b6928e6c6c4645f83d6},
issn = {0360-5442},
journal = {Energy},
keywords = {1998 EGM SLA entropy flow friction laminar},
number = 6,
pages = {465--473},
timestamp = {2012-11-02T19:52:13.000+0100},
title = {Irreversibilities in various duct geometries with constant wall heat flux and laminar flow},
url = {http://dx.doi.org/10.1016/S0360-5442(98)00010-3},
volume = 23,
year = 1998
}