Experimental and Theoretical Investigation of Rough Rice Drying in Infrared-assisted Hot Air Dryer Using Artificial Neural Network
Authors: D. Zare, H. Naderi, A. A. Jafari
Abstract:
Drying characteristics of rough rice (variety of lenjan) with an initial moisture content of 25% dry basis (db) was studied in a hot air dryer assisted by infrared heating. Three arrival air temperatures (30, 40 and 500C) and four infrared radiation intensities (0, 0.2 , 0.4 and 0.6 W/cm2) and three arrival air speeds (0.1, 0.15 and 0.2 m.s-1) were studied. Bending strength of brown rice kernel, percentage of cracked kernels and time of drying were measured and evaluated. The results showed that increasing the drying arrival air temperature and radiation intensity of infrared resulted decrease in drying time. High bending strength and low percentage of cracked kernel was obtained when paddy was dried by hot air assisted infrared dryer. Between this factors and their interactive effect were a significant difference (p<0.01). An intensity level of 0.2 W/cm2 was found to be optimum for radiation drying. Furthermore, in the present study, the application of Artificial Neural Network (ANN) for predicting the moisture content during drying (output parameter for ANN modeling) was investigated. Infrared Radiation intensity, drying air temperature, arrival air speed and drying time were considered as input parameters for the model. An ANN model with two hidden layers with 8 and 14 neurons were selected for studying the influence of transfer functions and training algorithms. The results revealed that a network with the Tansig (hyperbolic tangent sigmoid) transfer function and trainlm (Levenberg-Marquardt) back propagation algorithm made the most accurate predictions for the paddy drying system. Mean square error (MSE) was calculated and found that the random errors were within and acceptable range of ±5% with coefficient of determination (R2) of 99%.
Keywords: Rough rice, Infrared-hot air, Artificial Neural Network
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1330353
Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1829References:
[1] D. Zare, D.S., Jayas, C.B. Singh, "A generalized dimensionless model for deep bed drying of paddy," Drying Technol.: An Int. J. vol. 30, pp. 44-51. 2012.
[2] D. Zare, S. Minai, M. Mohamad Zadeh, M. H. Khoshtaghaza, "Computer Simulation of Rough Rice Drying in a Batch Dryer," Energy Conv. & Mang. vol.47, pp. 3241-3254, 2006.
[3] R. Lu, T.J. Seibenmorgen, "Correlation of HRY to selected physical and mechanical properties of rice kernel," Trans. ASAE. vol.38, pp. 889- 894, 1995.
[4] S. Bal, F. T. Wratten, J. L.Chesnen, M. D. Faulkner, "An analytical and experimental study of radiant heating of rice grain," Transactions of the ASAE, vol. 13(5), pp. 644-652, 1970.
[5] L. Momenzadeh, A. Zomorodian, D. Mowl, "Experimental and theoretical investigation of shelled corn drying in a microwave-assisted fluidized bed dryer using Artificial Neural Network," Food and Bioproducts Processing., vol. 89, pp.15-21, 2011.
[6] I. Farkas, P. Remenyi, A. Biro, "Modeling aspects of grain drying with a neural network". Comput Electron Agric, vol. 29, pp. 99-113, 2000.
[7] G. Cakmak, C. Yildiz, The prediction of seedy grape drying rate using a neural network method. Computers and Electronics in Agriculture, vol.75, pp. 132-138, 2011.
[8] S. Junling, P. Zhongli., H. Tara., Z. Mc., W. Delilah., H. Edward, O. Don, "Drying and quality characteristics of fresh and sugar-infused blueberries dried with infrared radiation heating,". LWT - Food Science and Technology. vol. 41, pp.1962-1972, 2008.
[9] Q. Zhang, W. Yang , Z. Sun," Mechanical Properties of sound and fissured rice kernel and their implication for rice breakage," Journal of Food Engineering. vol. 68, pp. 65-67, 2005.
[10] T.J. Siebenmorgen, G. Qin, "Influence of drying on rice fissure formation and mechanical strength distribution," Trans. ASAE. vol. 48, pp. 1835-41, 2005.
[11] S. Satish, Y. Pydi Setty, "Modeling of a continuous fluidized bed dryer using artificial neural networks," Int Commun Heat Mass Transfer, vol. 32, 539-547, 2004.
[12] S. Erenturk, K. Erenturk, "Comparison of genetic algorithm and neural network approaches for the drying process of carrot," J Food Engineering., vol. 78, pp. 905-912, 2007.
[13] P.P. Tripathy S. Kumar, "Neural network approach for food temperature prediction during solar drying". Int J Thermal Sci, vol. 48, pp. 1452- 1459, 2008.
[14] T. M. Afzal, T.Abe., Y. Hikida. "Energy and quality aspects during combined FIR-convection drying of barley," Food Engineering. vol 42, pp. 177-182, 1999.
[15] T. M. Afzal, T.Abe, "Some fundamental attributes of far infrared radiation drying of potato," Drying Technology, vol. 17(1&2), pp. 137- 155, 1999.