An iterative procedure was used to

An iterative procedure was used to solve the above equations and determine the
moisture removed for a given set of dryer dimensions.
In order to verify the models, experiments were performed on a prototype solar
dryer under a solar simulator at the University of Newcastle upon Tyne (UK). The
solar simulator uses Compact Source Metal Halide Lamps (Iodide) often called CSI
type. The CSI simulator is recommended for indoor testing of solar collectors and
although it does not provide the exact natural conditions, it produces radiant energy
that has a spectral distribution, intensity, uniformity in intensity, and direction close
to that of solar radiation, and is very reliable [18]. The solar simulator was set at
a constant radiation of 635.0 W/m2 and the mean ambient temperature during the
experiments was 27 °C. The geometry of the dryer is presented in Fig. 1 for the
mixed-mode and Fig. 2 for the indirect-mode, and the dimensions were W 
1.0m, L  1.0m, E  0.34m, s  0.05m, J  0.19m, and g  18.5°. The experimental
dryer capacity was 10 kg which gave a grain depth B, of 0.04 m. In the
mixed-mode operation, the drying chamber cover was glass whereas in the indirectmode
it was plywood. Moisture content variation with drying time obtained from
the experiments and that predicted by the simulation models were then compared as
shown in Fig. 4, giving mean relative deviations of 1.0 and 1.8% for the mixedmode
and indirect-mode dryers, respectively. The mean relative deviation gives an
idea of the mean departure of the measured data from the simulated data. The mean
relative deviation (MRD) as described by Sun and Woods [19] was used to estimate
the difference between the simulated results from the models and measured results
from the experiments. It is given by: