N. H. Helwa scite author profile

Theoretical investigation of the physical process of solar drying of timber based on conventional heat and mass transfer equations is presented. The governing equations and boundary conditions of the mass diffusion through the wood timbers are derived; also the governing equations of the components of the solar kiln are presented. The finite difference technique is used to solve the set of these equations by means of a simulation program that is based on object-oriented approach. The simulation program is used to investigate the effect of several design parameters on the drying rate and duration of the wood timbers in order to accomplish the drying process with minimal drying defects. These parameters *Correspondence: M. I. Hashish, Researcher, ORDER REPRINTS include the ventilation conditions that control the drying schedule inside the solar kiln, wood volume as a ratio to the solar kiln absorber area, wood timber thickness, season of drying, the drying air velocity, and the stresses that formed on the timber boards due to drying with these several parameters, leading to derive the limit of damage for a selected local wood type. The selected local wood type is Casuarina, which is common in Egypt, and it is commonly used in many simple industries.

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Experimental Evaluation of Solar Kiln for Drying Wood

Helwa

Khater

Enayet

et al. 2004

Drying Technology

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Modification of urea–sodium acetate trihydrate mixture for solar energy storage

et al. 2003

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N. H. Helwa

Maximum power point traking controller for PV systems using neural networks

Estimation of the maximum power and normal operating power of a photovoltaic module by neural networks

Optimization of Solar Kiln for Drying Wood

Experimental Evaluation of Solar Kiln for Drying Wood

Modification of urea–sodium acetate trihydrate mixture for solar energy storage

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