Investigation on heat and mass transfer in hygroscopic random charged fiber webs

Hygroscopic charged fiber webs include a large number of interconnected capillaries formed by randomly distributed pores. The simultaneous heat and mass transfer in hygroscopic charged fiber webs is different from traditional flows in macro-channels resulted from the electrokinetic phenomena in micr...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2012-04, Vol.55 (9-10), p.2365-2376
Main Authors: Zhu, Q.Y., Xie, M.H., Yang, J., Liao, K.
Format: Article
Language:English
Subjects:
Applied sciences
Charging
Electrokinetic phenomena
Electrokinetics
Energy
Energy. Thermal use of fuels
Exact sciences and technology
Fibers
Heating, air conditioning and ventilation
Hygroscopic fiber webs
Liquids
Mass transfer
Mathematical models
Pore size distribution
Porosity
Technical data: comfort, insulation, loads, etc
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Summary:Hygroscopic charged fiber webs include a large number of interconnected capillaries formed by randomly distributed pores. The simultaneous heat and mass transfer in hygroscopic charged fiber webs is different from traditional flows in macro-channels resulted from the electrokinetic phenomena in micro-channels. In this paper, a mathematical model is presented with consideration of a quintic polynomial pore size distribution evaluated from a series of experiments and the electrokinetic phenomena resulting in a higher flow friction. The liquid diffusion coefficient in this model can be expressed as Dl(εl)=σcosφsin2β(rmax-rmin)nεln-14μ(1+A·Θ)ϕn-1Γ1Δ4-Ω1Γ2Δ4-Ω2Δ2. With specification of initial and boundary conditions, the governing equations are solved numerically and distributions of the temperature, the moisture concentration, and liquid water content in hygroscopic fiber webs are obtained. The comparison with the experimental measurements shows the rationality of this model in simulating the coupled heat and mass transfer in hygroscopic charged fiber webs with consideration of the electrokinetic phenomena.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2012.01.027