This thesis seeks to examine both permeability measurement and material
characterisation of Continuous Filament Mat (CFM) glass fibre reinforcements. As
an alternative to fabrics, which generally provide higher in-place properties, CFMs
are often employed as low cost, 'lofty' (high uncompressed thickness, and
therefore good specific flexural stiffness), easy to process reinforcements for
Resin Transfer Moulded (RTM) parts.
Within this project, investigation of permeability measurement has involved the
development of two (radial and linear) liquid flow permeability techniques to
provide a reliable and robust data set for a specific CFM (Unifilo U813-300). Then
two novel (radial and linear) airflow techniques were developed for the
measurement of CFMs, these providing comparative results with the liquid flow
measurements. The benefits of airflow versus liquid flow include cleaner, lower
pressured flow using a fluid that may be produced by compressor rather than
stored, therefore having significant benefits for both laboratory and industrial
measurements of permeability.
Material characterisation is necessary to analytically investigate reinforcement
materials, as permeability has a non-linear relationship with overall porosity.
Permeability is therefore considered as a function of pore distribution, which
encompasses the two scales of intra and inter fibre-bundle flow. Two areas have
been investigated, these involving permeability measurement and microstructure
characterisation. Comparative permeability measurements of a second CFM
(Unifilo U850-300), consisting of a different arrangement of fibre bundle sizes,
were undertaken using the 1D airflow method, and inter-laminar flow was
investigated using the radial airflow method. These resulted in a permeability ratio
of between 0.54 and 0.64 (U813/U850) across a 0.1 to 0.3 fibre volume fraction
range for the two CFMs, and no significant inter-laminar pore space effect.
Microstructural characterisation initiated with image analysis of electron
micrographs, providing measurement of fibre diameters and intra-bundle porosity.
Kozeny-Carman modelling then showed the permeability of intra-bundle areas to
be insignificant resulting in a focus on inter-bundle flow. Although limited by
assumptions made for various material parameters, semi-empirical models to
provide inter-bundle porosity and fibre bundle geometries were developed.
Relation with permeability was then achieved through calculating hydraulic radius
and mean hydraulic radius and provision of a range of Kozeny constants (0.55 to
6.17) and coefficients to replace the Kozeny constant, which provide upper and
lower bounds for the remaining factors of permeability.
The overall future industrial benefits for material engineers rely on the addressing
of these limitations for quantifying geometries, so as to provide clarity of the
relationship between controllable material parameters and permeability. Towards
this goal, suggestions of further work here investigate employing micro-CT
imaging and the use of 3D modelling that have the potential to use real-world
images rather than idealised geometrical models.
Date of Award | 2009 |
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Original language | English |
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Awarding Institution | |
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Supervisor | Stephen Grove (Other Supervisor) & John Summerscales (Other Supervisor) |
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Permeability characterisation of continuous filament mats for resin transfer moulding
Pomeroy, R. (Author). 2009
Student thesis: PhD