Optimizing the drying parameters of a fixed bed with reversing ventilation for peanut using computer simulation
Abstract
Keywords: peanut, fix bed drying, reversing ventilation, simulation, optimization
DOI: 10.25165/j.ijabe.20211405.6354
Citation: Yan J C, Xie H X, Wei H, Wu H C, You Z Y. Optimizing the drying parameters of a fixed bed with reversing ventilation for peanut using computer simulation. Int J Agric & Biol Eng, 2021; 14(5): 255–266.
Keywords
Full Text:
PDFReferences
FAOSTAT. Food Agric. Organ., United Nations, 2021. Available: http://www.fao.org/faostat/zh/#data/QC. Accessed on [2021-04-20].
Yan J, Xie H, Wei H, Wu H, Gao J, Xu H. Development of 5H-1.5A peanut reversing ventilation dryer. Transactions of the CSAE, 2019; 35(10): 9–18. (in Chinese)
Wang H, Hu Z, Chen S, Fu Q, Zhang W, Wang R, et al. Effects of different harvesting dates and drying methods on peanut quality. Transactions of the CSAE, 2017; 33(22): 292–300. (in Chinese)
Qu C, Wang Z, Wang X, Wang D. Prediction model of moisture in peanut kernel during hot air drying based on LF-NMR technology. Transactions of the CSAE, 2019; 35(12): 290–296. (in Chinese)
Butts C L, Dorner J W, Brown S L, Arthur F H. Aerating farmer stock peanut storage in the southeastern US. Transactions of the ASABE, 2006; 49(2): 457–465.
Wright F S, Desk S H, Cundiff J S. Storing peanut in trailer-sized containers. Peanut Science, 1996; 23(1): 43–45.
Cundiff J S, Baker K D. Curing quality peanuts in Virginia. Virgina Tech. Virgina, 2009; 442(62): 1–12.
Mujumdar A S. Handbook of Industrial Drying. Boca Raton: CRC press. 2014; 82 p.
Bloome P D, Kletke D, Sholar J R. Comparisons of on-farm peanut drying systems in the southwest. Peanut Science, 1983; 10(2): 69–72.
Baker K D, Cundiff J S, Wright F S. Peanut quality improvement through controlled curing. Peanut Science, 1993; 20(12): 12–16.
Butts C L. Comparison of peanut dryer control strategies. Peanut Science, 1996; 23(14): 86–90.
Nakai V K, Rocha L O, Goncalez E, Fonseca H, Ortega E M, Correa B. Distribution of fungi and aflatoxins in a stored peanut variety. Food Chemistry, 2008; 106(1): 285–290.
Butts C L, Williams E J, Sanders T H. Algorithms for automated temperature controls to cure peanuts. Postharvest Biology and Technology, 2002; 24 (3): 309–316.
Butts C L, Davidson J I, Lamb M C, Kandala C V, Troeger J M. Estimating drying time for a stock peanut curing decision support system. American Society of Agricultural Engineers, 2014; 47(3): 925–932.
Gao L X, Chen Z Y, Chen C, Butts L. Development course of peanut harvest mechanization technology of the United States and enlightenment to China. Transactions of the CSAE, 2017; 33(12): 1–9. (in Chinese)
Parti M, Young J H. Evaluation of a bulk drying model for peanuts. Peanut Science, 1992; 19(1): 1–7.
Chai L, Young J H. Simulated air flow rate effects on drying times and costs for conventional and recirculating peanut drying facilities. Peanut Science, 1995; 22(1): 8–14.
Yang C Y, Fon D S, Lin T T. Simulation and validation of thin-layer models for peanut drying. Drying Technology, 2017; 25(9): 1515–1526.
Yan J, Wei H, Xie H, You Z. Performance index simulation and analysis of peanut ventilation drying in barrel-shaped fixed bed. Transactions of the CSAE, 2020; 36(1): 292–302. (in Chinese)
Aregba A W, Sebastian P, Nadeau J P. Stationary deep-bed drying: A comparative study between a logarithmic model and a non-equilibrium model. Journal of Food Engineering, 2006; 77(1): 27–40.
Aregba A W, Nadeau J P. Comparison of two non-equilibrium models for static grain deep-bed drying by numerical simulation. Journal of Food Engineering, 2007; 78(4): 1174–1187.
Martinello M A, Munoz D J, Giner S A. Mathematical modeling of a low temperature drying of maize: Comparison of numerical methods for solving the differential equations. Biosystems Engineering, 2013; 114(2): 187–194.
Lopes D C, Neto A S, Santiago J K. Comparison of equilibrium and logarithmic models for grain drying. Biosystems Engineering, 2014; 118(2): 105–114.
Giner S A. Estimation of the influence of variable boundary conditions when using thin layer equations for grain dryer simulation. Biosystems Engineering, 2019; 186(10): 228–233.
Ruiz-Lopez I, Martine-Sanchez C E, Cobos-Vivaldo R, Herman-Lara E. Mathematical modeling and simulation of batch drying of foods in fixed beds with airflow reversal. Journal of Food Engineering, 2008; 89(3): 310–318.
Khatchatourian O A, Vielmo H A, Bortolaia L A. Modelling and simulation of cross-flow grain dryers. Biosystems Engineering, 2013; 116(2): 335–345.
Yan J, Xie H, Hu Z, Wei H, You Z, Xue H. Simulation and process optimization of upward and downward reversing ventilating drying by the fixed bed. Transactions of the CSAE, 2015; 31(22): 292–300. (in Chinese)
Jia C, Wang L, Guo W, Liu C. Effect of swing temperature and alternating airflow on drying uniformity in deep-bed wheat drying. Applied Thermal Engineering, 2016; 106(8): 774–783.
Albini G, Freire F B, Freire J T. Barley: Effect of airflow reversal on fixed bed drying. Chemical Engineering & Processing: Process Intensification, 2018; 134(11): 97–104.
Yan J, Hu Z, Xie H, Wang H, Yu Z. Studies of thin-layer drying characteristics and model for peanut pods. Journal of Chinese Agricultural Mechanization, 2013; 34(6): 205–210. (in Chinese)
Zare D, Chen G N. Evaluation of a simulation model in predicting the drying parameters for deep-bed paddy drying. Computers and Electronics in Agriculture, 2009; 68(1): 78–87.
Sahdev R K, Kumar M, Dhingra A K. Present status of peanuts and progression in its processing and preservation techniques. Agric Eng Int: CIGR Journal, 2015; 17(3): 309–327.
Bitra V S, Banu S, Ramakrishna P, Narender G, Womac A R. Moisture dependent thermal properties of peanut pods, kernels, and shells. Biosystems Engineering, 2010; 106(4): 503–512.
Wright M E, Porterfield J G. Specific heat of Spanish peanuts. Transaction of the ASAE, 1970; 13(4): 508–510.
Correa P C, Goneli A L, Jaren C, Ribeiro D M, Resende O. Sorption isotherms and isosteric heat of peanut pods, kernels and hulls. Food Science and Technology International, 2007; 13(3): 231–238.
Chen C C. A rapid method to determine the sorption isotherms of peanuts. Journal of Agriculture Engineering Research, 2000; 75(4): 401–408.
Tohidi M, Sadeghi M, Harchegani M T. Energy and quality aspect for fixed deep bed drying of paddy. Renewable and Sustainable Energy Reviews, 2017; 70(2): 519–528.
Tao J, Wu J. New study on determining the weight of index in synthetic weighted mark method. Systems Engineering-theory & Practice, 2001; 8: 43–48.
Zhang M. Methods and practice for the quality assessment of composite
indicators. Shanghai: Shanghai People's Press. 2017; 46 p.
ASABE. Moisture measurement-peanut, 2020; S410.3–2020.
International Standards Organization. Foodstuffs-determination of aflatoxin B1, and the total content of aflatoxins B1, B2, G1, and G2 in cereals, nuts, and derived products-High-performance liquid chromatographic method, 2003; ISO 16050-2003.
International Standards Organization. Animal and vegetable fats and oils- determination of acid value and acidity, 2009; ISO 660-2009.
International Standards Organization. Animal and vegetable fats and oils-Determination of peroxide value-Iodometric (visual) endpoint determination, 2017; ISO 3960-2017.
International Standards Organization. Sensory analysis-Methodology- General guidance, 2017; ISO 6658-2017.
Fang K, Liu M, Qin Y. Theory and application of uniform experimental designs. Beijing: Science Press, 2018; 155 p.
Standardization Administration of the PRC. National food safety standard nuts and seeds, 2014; GB 19300-2014. (in Chinese)
Copyright (c) 2021 International Journal of Agricultural and Biological Engineering
This work is licensed under a Creative Commons Attribution 4.0 International License.