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Measurement of the principal permeability with the channel flow experiment

Measurement of the principal permeability with the channel flow experiment
Measurement of the principal permeability with the channel flow experiment
A framework for channel flow permeability measurement in resin transfer molding (RTM) is developed in this paper. For the channel flow experiment, five possible experimental configurations are identified, of which two have not yet been mentioned in the literature. Starting from effective permeability, the entity measured in the experiment, explicit formulas for principal permeability and its orientation in two and three dimensions are developed. These formulas are applied to (published) experimental results that demonstrate their validity. The practical problems that prevent three-dimensional permeability measurement are discussed. Next, a framework for two-dimensional channel flow permeability measurement is proposed. All known channel flow permeability measurement methods are classified according to this new framework, and where appropriate, differences are discussed. An important finding emerging from this comparison is that two different definitions of Darcy's law are used today in permeability measurement.
0272-8397
321-335
Weitzenbock, J.R.
1312d711-2965-4202-b1f4-e37c33138140
Shenoi, R.A.
a37b4e0a-06f1-425f-966d-71e6fa299960
Wilson, P.A.
8307fa11-5d5e-47f6-9961-9d43767afa00
Weitzenbock, J.R.
1312d711-2965-4202-b1f4-e37c33138140
Shenoi, R.A.
a37b4e0a-06f1-425f-966d-71e6fa299960
Wilson, P.A.
8307fa11-5d5e-47f6-9961-9d43767afa00

Weitzenbock, J.R., Shenoi, R.A. and Wilson, P.A. (1999) Measurement of the principal permeability with the channel flow experiment. Polymer Composites, 20 (2), 321-335. (doi:10.1002/pc.10359).

Record type: Article

Abstract

A framework for channel flow permeability measurement in resin transfer molding (RTM) is developed in this paper. For the channel flow experiment, five possible experimental configurations are identified, of which two have not yet been mentioned in the literature. Starting from effective permeability, the entity measured in the experiment, explicit formulas for principal permeability and its orientation in two and three dimensions are developed. These formulas are applied to (published) experimental results that demonstrate their validity. The practical problems that prevent three-dimensional permeability measurement are discussed. Next, a framework for two-dimensional channel flow permeability measurement is proposed. All known channel flow permeability measurement methods are classified according to this new framework, and where appropriate, differences are discussed. An important finding emerging from this comparison is that two different definitions of Darcy's law are used today in permeability measurement.

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Published date: April 1999
Related URLs:
Organisations: Fluid Structure Interactions Group

Identifiers

Local EPrints ID: 50957
URI: http://eprints.soton.ac.uk/id/eprint/50957
DOI: doi:10.1002/pc.10359
ISSN: 0272-8397
PURE UUID: 2c7beef4-3af8-43eb-9072-fedbeb25dd69
ORCID for P.A. Wilson: ORCID iD orcid.org/0000-0002-6939-682X

Catalogue record

Date deposited: 22 Apr 2008
Last modified: 16 Mar 2024 02:35

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Contributors

Author: J.R. Weitzenbock
Author: R.A. Shenoi
Author: P.A. Wilson ORCID iD

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