Abstract
Critical experiments and predictive models reveal that water rise through a cellulose foam is initially by capillary rise, followed by non-linear diffusion in the presence of trapping sites. Classical ideas on capillary rise are supported by observations that the Washburn law is obeyed up to the Jurin height. However, water rise continues beyond the Jurin height, and this subsequent phase is diffusion-controlled according to the following evidence: the nature of the quantitative dependence of water rise upon time, the insensitivity of water rise to the direction of gravity, and the fact that the water front continues to rise in the foam after the water reservoir has been removed. Water diffusion occurs through the cellulose fibre network, along with trapping/de-trapping at molecular sites. The diffusion equations are solved numerically, and, upon comparing the predictions with the observed response, values are obtained for the diffusion constant and for the ratio of trap density to lattice density. The diffusion model explains why the drying of a damp foam is a slow process: the emptying of filled traps requires diffusion through an adjacent lattice of low water content.
Highlights
Rising damp is ubiquitous in porous materials ranging from bricks and concrete to fibrebased materials such as wood, mineral wool insulation and cotton fabrics
The mechanism of liquid transport involves capillary rise and/or diffusion, but the precise details are lacking due to a paucity of appropriate experiments. This is in part due to a lack of suitable experimental techniques: only recently has it become possible to scan the distribution of water content through the thickness of these materials by micro Computed Tomography (CT), for example
An alternative strategy was adopted to distinguish between diffusion and capillary rise: we measured the density profile within the foam in a postcut V(RF) test in order to distinguish between water rise by capillary flow and by diffusion
Summary
Several industries such as textile, fabric design, printing technology, food processing, timber construction and the paper industry. The mechanism of liquid transport involves capillary rise and/or diffusion, but the precise details are lacking due to a paucity of appropriate experiments. This is in part due to a lack of suitable experimental techniques: only recently has it become possible to scan the distribution of water content through the thickness of these materials by micro Computed Tomography (CT), for example. As first given by Washburn (1921) Note that this is the solution for Darcy flow (Darcy, 1856) in a porous medium, upon taking the permeability of the porous medium to be d 2 32 in terms of a representative pore diameter d.
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