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contributor authorDenis Lepchev
contributor authorDaniel Weihs
date accessioned2017-05-09T00:38:12Z
date available2017-05-09T00:38:12Z
date copyrightJuly, 2010
date issued2010
identifier issn0098-2202
identifier otherJFEGA4-27423#071202_1.pdf
identifier urihttp://yetl.yabesh.ir/yetl/handle/yetl/143453
description abstractWe study the creeping flow of an incompressible fluid in spiral microchannels such as that used in DNA identifying “lab-on-a-chip” installations. The equations of motion for incompressible, time-independent flow are developed in a three-dimensional orthogonal curvilinear spiral coordinate system where two of the dimensions are orthogonal spirals. The small size of the channels results in a low Reynolds number flow in the system, which reduces the Navier–Stokes set of equations to the Stokes equations for creeping flow. We obtain analytical solutions of the Stokes equations that calculate velocity profiles and pressure drop in several practical configurations of channels. Both pressure and velocity have exponential dependence on the expansion/contraction parameter and on the streamwise position along the channel. In both expanding and converging channels, the pressure drop is increased when the expansion/contraction parameter k and/or the curvature is increased.
publisherThe American Society of Mechanical Engineers (ASME)
titleLow Reynolds Number Flow in Spiral Microchannels
typeJournal Paper
journal volume132
journal issue7
journal titleJournal of Fluids Engineering
identifier doi10.1115/1.4001860
journal fristpage71202
identifier eissn1528-901X
keywordsPressure
keywordsFlow (Dynamics)
keywordsChannels (Hydraulic engineering)
keywordsMicrochannels AND Equations
treeJournal of Fluids Engineering:;2010:;volume( 132 ):;issue: 007
contenttypeFulltext


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