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Design and Construction of a Cabinet Dryer for Food Waste and Evaluation of its Kinetics and Energy Consumption

Document Type : Research Article

Authors

1 Department of Biosystems Engineering, Islamic Azad University, Branch of Eghlid, Iran

2 Agricultural Engineering Research Institute, Agricultural Research, Education and Extension Organization (AREEO), Karaj, Iran

3 Department of Biosystems Engineering, Science and Research Branch, Eslamic Azad University, Tehran, Iran

Abstract

Introduction
Providing new solutions to control wet waste is one of the most important issues in maintaining public health. Drying will reduce the harmful effects on the environment by reducing moisture and the smell of wastes as well as easy transportation and disposal costs. The purpose of the design and development of the household dryer is to dry food waste in order to reduce its volume and prevent the spread of its pollution in the air, water, and soil. To study the drying behavior of food waste, an experimental cabinet dryer was designed, fabricated, and evaluated for drying food waste.
Materials and Methods
The dryer consisted mainly of the drying chamber, electric heater, fan, air inlet channel, mesh tray, air distribution plates, temperature sensor, and control panel. Different parts of the dryer were made of a stainless galvanized sheet. The dryer was modeled using Catia 2019 software and its various parts were designed. The heating power was calculated as 2.7 kW. A centrifugal fan with an air volume of 310 m3h-1, 2800 rpm, and 110 Pa was used to supply airflow in the dryer. In the drying process, a tray with medium and lateral air passage was fabricated and applied. Food waste was obtained from fruit and vegetable waste, homemade food, and fruit shops. And nonfood items such as glass, paper, plastics, and metals were separated from the waste and crushed with a shredder, and reduced to sizes less than 20 mm. First, the product was placed in the environment for one hour and then pressed with a mechanical press with the same pressure to eliminate part of the water. An anemometer UT363 model made in China was used to measure the air velocity. The temperature was measured and controlled by a temperature thermostat of G-sense model made in Iran. The effect of three temperatures of 50, 60, and 70 °C and three inlet velocities of 1, 1.5, and 2 m s-1 on the kinetics and intensity of drying of food waste and energy consumption of food waste with a thickness of 3 cm was investigated. Moisture ratio and drying intensity diagrams were extracted. Diffusion, activation energy, and energy consumption were determined.
Results and Discussion
Drying kinetics diagrams showed that temperature had a significant effect on moisture variation of food waste during drying. Drying period decreased with increasing temperature. The slope of the drying intensity diagrams increased with the increase of the dryer temperature. Drying rate was decreased at the temperature of 70 °c and it had a steeper slope that indicates the more intensity of the drying process in this condition. The drying process of all three samples occurred in the falling rate stage. The air duct on the side and in the middle of the tray caused hot air conducted above the tray and increased energy consumption. Effective moisture diffusivity of food waste during the drying process was in the range of 3.65×10-9-4.56×10-9 (m2 s-1). The effective moisture diffusivity at temperatures of 50 °C and 60 °C was less than 70 °C. Because at the temperature of 70 °C, the membrane resistance of the cell destroyed by high heat and increased the diffusion coefficient in the material.
Conclusion
Increasing temperature caused the drying period decreased and the drying occurred in the falling rate stage. Temperature and the interaction of velocity and temperature had a significant effect on the drying process. The highest drying intensity and the lowest drying time were observed at the temperature of 70 °C and a velocity of
2 m s-1. Energy consumption had the maximum value at the temperature of 70 °C and a velocity of 2 m s-1 and a minimum value at the temperature of 50 °C and a velocity of 1 ms-1. The amount of activation energy for the food waste mass at three velocities was equal to 10417.44 J mol-1.

Keywords

Main Subjects

Open Access

©2022 The author(s). This article is licensed under Creative Commons Attribution 4.0 International License (CC BY 4.0), which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source.

References
  1. Adzimah, K. S., & Seckley, E. (2009). Improvement on the design of a cabinet grain dryer. American Journal of Engineering and Applied Science, 2, 217-228. https://doi.org/10.3844/ajeassp.2009.217.228
  2. Al-Harahsheh, M., AL-Muhtaseb, A., & Magee, T. R. A. (2009). Microwave drying kinetics of tomato pomace: Effect of osmotic dehydration. Chemical Engineering and Processing, 48, 524-531. https://doi.org/10.1016/j.cep.2008.06.010
  3. Alibas, I. (2007). Energy consumption and colour characteristics of nettle leaves during microwave, vacuum and convective drying. Biosystems Engineering, 96, 495-502. https://doi.org/10.1016/j.biosystemseng.2006.12.011
  4. Amiri Chayan, R., Khoshtaghaza, M. H., & Kianmehr, M. H. (2004). Design principle of experimental fluidizid bed dryer for some agriculture products. Journal of Agricultural Engineering Research, 5, 36-52. (in Persian).
  5. Arslan, D., & Ozcan, M. M. (2010). Study the effect of sun, oven and microwave drying on quality of onion slices. LWT-Food Science and Technology, 43, 1121-1128. https://doi.org/10.1016/j.lwt.2010.02.019
  6. Ayadi, M., Mabrouk, S. B., Zouari, I., & Ahmed, B. (2014). Kinetic Study of the Conective Drying of Spearmint. Journal of Saudi Society of Agriculture Sciences, 13(1), 1-7. https://doi.org/10.1016/j.jssas.2013.04.004
  7. Chaji, H., Ghasem zadeh, H., & Ranjbar, I. (2008). Effect of Pre- treatments Using Ethyl oleate, Hot & Warm Water on Drying Characteristics of Barberry. 5th National Congress of Agricultural Machinery Engineering and Mechanization. Mashad. Iran. (in Persian).
  8. Ehiem, J. C. (2008). Design and development of an indus-trial fruit and vegetable dryer. Thesis report. University of Agriculture, Makurdi, Nigeria.
  9. Ertekin, C., & Yaldiz, O. (2004). Drying of Eggplant and selection of a suitable thin layer drying model. Journal of Food Engineering, 63, 349-359. https://doi.org/10.1016/j.jfoodeng.2003.08.007
  10. Ferreira, A. G., Gonçalves, L. M., & Miai, C. B. (2013). Experimental analysis of industrial solid waste solar drying. 22nd International Congress of Mechanical Engineering. Brazil.
  11. Gazor, H. R., Minaee, S., & Rostami, M. A. (2005). Influence of temperature and thickness on pistachio drying in batch dryers. Journal of Agricultural Sciences, 11, 81-93. (in Persian).
  12. Ghasemkhani, H., Rafiei, S., Kayhani, A., & Dalvand, M. B. (2018). Evaluation of drying apple slices using a rotary dryer equipped with a heat exchanger. Journal of Agricultural Machinery Mechanical Research, 7, 9-19. (in Persian).
  13. Ikem, I. A., Osim, A. D., Nyong, O. E., & Takim, S. A. (2016). Determination of loading capacity of a direct solar boiler dryer. International Journal of Engineering and Technology, 8, 1386-1396.
  14. İsmail, O., Beyribey, B., & Doymaz, I. (2016). Effect of drying methodes on drying characttrstic, Energy Consumption and Color of Nectarine. Journal of Thermal Engineering Technical University Press, 2, 801-806.
  15. Jo, J. H., Kim, S. S., Shin, J. W., Lee.Y. E., & Yoo, Y. S. (2017). Pyrolysis characteristics and kinetics of food wastes. Energies. https://doi.org/10.3390/en10081191.
  16. Kim, B. S., Kang, C. N., & Jeong, J. H. (2014). A study on a high efficiency dryer for food waste. Journal of the Korean Society for Power System Engineering, 18, 153-158. https://doi.org/10.9726/kspse.2014.18.6.153.
  17. Lewis, M. J. (1990). Physical Properties of Foods and Food Processing Systems. Physical Properties of Foods and Food Processing Systems. Woodhead Publishing, U.K.
  18. Liu, Y., Peng, J., Kansha, Y., Ishizuka, M., Tsutsumi, A., Jia, D., Bi, X. T., Lim, C. J., & Sokhansanj, S. (2014). Novel fluidized bed dryer for biomass drying. Fuel Processing Technology, 122, 170-175. https://doi.org/10.1016/j.fuproc.2014.01.036
  19. López, G. A., Iguaz, A., Esnoz, A., & Vírseda, P. (2000). Thin-layer drying behavior of vegetable waste from wholesale market. Drying Technology, 18, 995-1006. https://doi.org/10.1016/j.fuproc.2014.01.036
  20. Mazandarani, Z., Aghajani, N., Daraei Garmakhany, A., Bani Ardalan, M. J., & Nouri, M. (2017). Mathematical modeling of thin layer drying of pomegranate (Punica granatum) arils: Various drying methods. Journal of Agricultural Science and Technology, 19, 1527-1537.
  21. Montero, I., Miranda, M. T., Sepulveda, F. J., Arranz, J. I., Rojas, C. V., & S. Nogales. (2015). Solar dryer application for olive oil mill wastes. Energies, 8(12), 14049-14063. https://doi.org/10.3390/en81212415
  22. Motevali, A., Abbaszadeh, A., Minaei, M., Khoshtaghaza, M. H., & Ghobadian, B. (2012). Effective moisture diffusivity, activation energy and energy consumption in thin-layer drying of JuJube (Zizyphus JuJube Mill). Journal of Agricultural Science and Technology, 14, 523-532.
  23. Nijmeh, M. N., Ragab, A. S., Emish, M. S., & Jubran, B. (1998). Design and testing of solar dryers for processing food wastes. Applied Thermal Engineering, 18, 1337-1346. https://doi.org/10.1016/S1359-4311(98)00002-7
  24. Ogulata, R. T. (2004). Utilization of waste-heat recovery in textile drying. Applied Energy, 79, 41-49. https://doi.org/10.1016/j.apenergy.2003.12.002
  25. Rostami Baroji, R., Seiiedlou Heris, S. S., & Dehghannya, J. (2017). Mathematical simulation of heat and mass transfer in convectional drying of carrot, pretreated by ultrasound and microwave. Journal of Agricultural Machinery, 7, 97-113. (in Persian with English abstract). https://doi.org/10.22067/jam.v7i1.38881
  26. Roustapour, O. R., Azimi, O., & Gazor, H. R. (2019). Computational fluid dynamics analysis in a corn air flow paddy dryer with two types of passing air flow of lateral and central patterns. Journal of Biosystem Engineering, 50, 115-128. (in Persian).
  27. Roustapour, O. R., Maftoonazad, N., & Khaloahmadi, A. (2014). Study of drying kinetics and shrinkage of potato slices in a parallel flow dryer. Journal of Food Science and Technology (Iran), 12, 109-122. (in Persian).
  28. Shin, H. S., & Youn, J. H. (2005). Conversion of food waste into hydrogen by thermophilic acidogenesis. Biodegradation, 16, 33-44. https://doi.org/10.1007/s10531-004-0377-9
  29. Shirinbakhsh, M., & Amidpour, M. (2017). Design and optimization of solar- assisted conveyer-belt dryer for biomass. Energy Equipment and Systems, 5, 10-15. (in Persian).
  30. Singh, P. R., & Heldman, D. R. (2009). Introduction to Food Engineering. Elsevier, USA.
  31. Tun, M. M., & Juchelkova, D. (2019). Drying methods for municipal solid waste quality improvement in the developed and developing countries: A review. Environmental Engineering Research, 24(4), 529-542. https://doi.org/10.4491/eer.2018.327.
  32. Environmental Engineering Research, 24(4), 529-542. https://doi.org/10.4491/eer.2018.327.
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Journal of Agricultural Machinery
Volume 12, Issue 4 - Serial Number 26
December 2022
Pages 467-480
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History
  • Receive Date: 09 May 2021
  • Revise Date: 05 August 2021
  • Accept Date: 08 August 2021
  • First Publish Date: 10 August 2021
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