%0 Journal Article
%T STUDY OF SHELLED CORN SHRINKAGE IN A MICROWAVE-ASSISTED FLUIDIZED BED DRYER USING ARTIFICIAL NEURAL NETWORK
%A Momenzadeh L. and Zomorodian A.
%J International Journal of Agriculture Sciences
%D 2012
%I Bioinfo Publications
%X Grain drying is a vital unit operation in many processing plants. An undesirable change associated with this operation is shrinkage of dried product which results in decreased quality. Recently many attempts have been made to decrease the shrinkage of food stuff during drying. Microwave-assisted fluidized bed drying has particularly been proposed as a potentially effective method. In the present study, at each drying operating condition, the volume of shelled corn was calculated by measuring the three principal characteristic dimensions. The variation of the ratio of mean diameter of the kernel to its initial mean diameter was investigated for different operating conditions. It has been shown that employing microwave in fluidized bed drying reduces the shrinkage of particles considerably. Also, in this study, Artificial Neural Networks (ANN) analysis was employed to predict the extent of shelled corn shrinkage. In the construction of the network, three independent variables: microwave heat source, drying air temperature and moisture content were chosen as the input parameters and shrinkage of dried sample was set as the output parameter (dependent variable). The ANN model with 5 neurons was selected for studying the influence of transfer functions and training algorithms. It has been observed that back-propagation networks with logsig transfer function and trainlm algorithm were the most appropriate ANN configuration for predicting shrinkage. Results from the experiments and modeling showed good agreement. In order to test the ANN model the random errors were within an acceptable range of กภ5% with a correlation coefficient (R2) of 98%.
%K Shelled corn
%K shrinking effect
%K Artificial Neural Network.
%U http://www.bioinfopublication.org/viewhtml.php?artid=BIA0000009