مدلسازی و بهینه سازی خشک کردن شلتوک در یک خشک کن آزمایشگاهی هوای گرم-مادون قرمز بستر ارتعاشی

نوع مقاله : مقاله پژوهشی

نویسندگان

1 دانشجوی دکتری مهندسی بیوسیستم، دانشکده کشاورزی، دانشگاه شیراز، شیراز، ایران

2 دانشیار گروه مهندسی بیوسیستم، دانشکده کشاورزی، دانشگاه شیراز، شیراز، ایران

3 استاد گروه مکانیک، دانشکده مهندسی مکانیک، دانشگاه شیراز، شیراز، ایران

چکیده

 در این پژوهش یک مدل کاربردی با یک متغیر متاثر از شرایط خشک شدن به منظور پیش بینی اثر تابش مادون قرمز در روش ترکیبی خشک کردن شلتوک ارائه گردید. آزمایش ها در سه سطح تابش مادون قرمز (صفر، 1000و Wm-22000) و سه سطح دمای هوای ورودی (30، 40 و °C50) انجام پذیرفت. نتایج به دست آمده از  شبیه سازی مدل ارائه شده نشان داد مدل قادر است خصوصیت های خشک شدن شلتوک را در خشک کن ترکیبی به خوبی بیان کند. همچنین با توجه به بررسی اثر روش ترکیبی هوای گرم-مادون قرمز بر روی نرخ خشک شدن، نسبت افزایش ترک خوردگی، انرژی مورد نیاز برای شکستن دانه شلتوک و مصرف انرژی ویژه، یک روش بهینه ارائه گردید. بهترین روش برای کاهش مصرف انرژی و افزایش کیفیت دانه، روش ترکیبی هوای گرم در دمای °C40 و شدت تابش مادون قرمز در Wm-2 1000 است.

کلیدواژه‌ها

موضوعات


عنوان مقاله [English]

Modeling and Optimization of Rough Rice Drying under Hot Air-infrared Radiation in a Laboratory Scale Vibratory Bed Dryer

نویسندگان [English]

  • Mojtaba Nosrati 1
  • Dariush Zare 2
  • Mehdi Nasiri 2
  • Abdolabbas Jafari 2
  • Mohammad Eghtesad 3
1 PhD Student, Biosystems Engineering Department, College of Agriculture, Shiraz, Iran
2 Associate Professor, Biosystems Engineering Department, College of Agriculture, Shiraz University, Shiraz, Iran
3 Professor, Mechanical Engineering Department, College of Mechanic, Shiraz University, Shiraz, Iran
چکیده [English]

A practical model including a parameter as a function of drying condition were introduced to predict the effect of far-infrared radiation (FIR) in a combined rough rice drying process. Tests were conducted in three replication for four levels of FIR (0, 0.1, 0.2 and 0.3 Wcm-2) and three levels of inlet air temperature (30, 40 and 500C). The results obtained from the simulation of the proposed model demonstrated that the models were capable satisfactorily express the characteristics of drying rough rice in combined dryer. Also due to the effects of combination of hot air and FIR drying technique on drying rates, cracking enhancement ratio (CER), required breaking energy for grain, specific energy consumption (SEC) and optimal method was presented. Combination of hot air at temperature of 40 0C and FIR at intensity of 1000 W.m-2 is the best way to have lowest SEC and highest grain quality point of view.

کلیدواژه‌ها [English]

  • Rough rice
  • Far-infrared Radiation
  • Single Parameter Thin Layer Model
  • Combined Drying
AACC. (1995). Approved Method of the American of Cereal Chemists (9th ed). St. Paul, Minnesota.
Abe, T., & Afzal, T. M. (1997). Thin-Layer Infrared Radiation Drying of Rough Rice. Journal of Agricultural Engineering Research, 67, 289-297.
Afzal, T. M., & Abe, T. (1999). Energy an Quality Aspect During Combined FIR Convection Drying of Barley. Journal of Food Engineering, 42, 177-182.
Barzegar, M., Zare, D., & Stroshine, R. L. (2015). An integrated energy and quality approach to optimization of green peas drying in a hot air infrared-assisted vibratory bed dryer. Journal of Food Engineering, 166, 302-315.
Brooker, D. B., Bakker-Arkema, F. W., & Hall, C. W. (1992). Drying and storage of grain and oilseeds. New York: Van Nostrand Reinhold.
Chandra, P. K., & Singh, R. P. (1995). Applied Numerical Methods for Food and Agricultural Engineers. London: CRC Press.
Chen, C., & Jayas, D. S. (1998). Dynamic Equilibrium Moisture Content for Grain Drying. Journal of Canadian Agricultural Engineering, 40, 299-303.
Chen, C., & Wu, P. (2000). The Study of Interrupted Drying Technique for Rough Rice. Drying Technology. 18(10). 2381-2397.
Cnossen, A. G., Siebenmorgen, T. J., Yang, W., & Bautistad, R. C. (2001). An Application of Glass Transition Temperature to Explain Rice Kernel Fissure Occurrence During the Drying Process. Drying Technology, 19(8), 1661-1682.
El-Amin. M. (2011). Advanced Topics in Mass Transfer: Modeling Moisture Movement in Rice. (pp. 283-304). Croatia: Intech. 
Eshtiagh, A., & Zare, D. (2015). Modeling of thin layer hot air-infrared drying of green peas. Agric Eng Int: CIGR Journal, Special Issue 2015: 18th World Congress of CIGR: 246-258.
FAO. (2017). World Food Situation FAO Cereal Supply and Demand Brief: Food and Agriculture Organization of the United Nation.
Haghighi, K., & Segerlind, L. J. (1988). Modeling Simultaneous Heat and Mass Transfer in an Isotropic Sphere-A Finite Element Approach. Transactions of the ASAE, 32, 737-761.
Henderson, S. M. (1961). Grain drying theory I: Temperature effect on drying coefficient. Journal of Agricultural Engineering Research, 6, 169-174.
Henderson, S. M. (1974). Progress in developing the thin-layer drying equation. Journal of Food Technology, 18, 507-524.
Jelve, B. (2014). Design, Fabricated and Evaluation of an Infrared-assited Vibratory Bed Grain Dryer, A Case study: Paddy Drying. (M. S.), Shiraz University.
Khir, R., Pan, Z., Salim, A., & Thompson, J. F. (2007). Drying characteristics and quality of rough rice under infrared radiation heating. Paper presented at the ASABE Annual International Meeting, Minneapolis Convention Center, Minneapolis, Minnesota.
Lewis, W. K. (1921). The Rate of Drying of Solid Materials. Journal of Industrial & Engineering Chemistry, 13(5), 427-432.
Li, Y. B., Cao, C. W., & Zhong, Q. X. (1999). Study on Rough Rice Fissuring During Intermittent Drying. Drying Technology. 17(9), 1779-1793.
Luikov, A. V. (1966). Heat and Mass Transfer in Capillary Porous Bodies. New York: Pergamon Press.
Meeso, N., Nathakaranakule, A., Madhiyanon, T., & Soponronnarit, S. (2007). Modelling of far-infrared irradiation in paddy drying process. Journal of Food Engineering, 78, 1248–1258.
Meeso, N., Nathakaranakule, A., Madhiyanon, T., & Soponronnarit, S. (2008). Different Strategies of Far-Infrared Radiation Application in Paddy Drying. International Journal of Food Engineering, 4(3), 238-251.
Nassiri, S. M., & Etesami, S. M. (2016). Estimation of head rice yield by measuring the bending strength of kernels after drying by different drying methods. AgEngInt. CIGR Journal, 18, 368-377.
Page, C. (1949). Factors Influencing the Maximum Rate of Drying Shelled Corn in Layers. (M. S. Thesis), Purdue University, West Lafayette, Indiana.  
Prakash, B., & Pan, Z. (2009). Heat and Mass Transfer Modeling of Rough Rice under Convective and Infrared Drying. Paper presented at the ASABE Annual International Meeting, Grand Sierra Resort and Casino Reno, Nevada.
Siebenmorgen, T. J., & Qin, G. (2005). Relating Rice Kernel Breaking Force Distributions to Milling Quality. Transactions of the ASAE, 48(1), 223-228.
Verma, L. R., Bucklin, R. A., Endan, J. B., & Wratten, F. T. (1985). Effects of Drying Air Parameters on Rice Drying Models. Transactions of the ASAE, 28(1), 296-301.
Younis. M., Abdelkarim. D., & El-Abdein, A, Z. (2017). Kinetics and Mathematical Modeling of Infrared Thin-layer Drying of Garlic Slices. Saudi Journal of Biological Science, 17, 215-223.
Zare, D., Naderi, H., & Ranjbaran, M. (2014). Energy and Quality Attributes of Combined Hot Air-Infrared Drying of Paddy. Drying Technology, 33(5), 570-582.