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January 24, 2010 | History

Investigation of microchannel fabrication methods and particle-liquid flow characteristics in a microfluidic device 1 edition

Investigation of microchannel fabrication methods and particle-liquid ...
Clement Kim Man Kong

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Investigation of microchannel fabrication methods and particle-liquid flow characteristics in a microfluidic device.

Published 2006 .
Written in English.

About the Book

Microchannel fabrication methods and the particle-liquid flow characteristics in a microfluidic system were investigated experimentally. Combination of heat press and heat bonding was tested on polycarbonate and acrylic. In heat press, the best pressing temperatures for polycarbonate and acrylic were found to be 135°C and 65°C, respectively; and the optimum pressing times were both 120 minutes. In heat bonding, the best bonding temperatures for polycarbonate and acrylic were 135°C and 60°C at bonding times of 150 and 90 minutes, respectively.In the particle-liquid flow experiments, the effect of stirring in the inlet reservoir on the particle flow in a 75mum-diameter microchannel was examined. The number of particles that entered and flowed through the microchannel was found to increase with the liquid flow rate but decrease with stirring rate. Stirring in the reservoir was found to be detrimental to particle-liquid flow since it generated particle clusters within the reservoir.

Edition Notes

Source: Masters Abstracts International, Volume: 44-06, page: 2882.

Thesis (M.A.Sc.)--University of Toronto, 2006.

Electronic version licensed for access by U. of T. users.

ROBARTS MICROTEXT copy on microfiche.

The Physical Object

Pagination
73 leaves.
Number of pages
73

ID Numbers

Open Library
OL19215520M
ISBN 13
9780494163146

History Created December 11, 2009 · 2 revisions Download catalog record: RDF / JSON

January 24, 2010 Edited by WorkBot add more information to works
December 11, 2009 Created by WorkBot add works page