Design and performance analysis of tangential-axial flow threshing device for oat harvester
Abstract
Keywords: tangential-axial flow threshing device, oat, parameter optimization, threshing performance, crushing performance
DOI: 10.25165/j.ijabe.20211406.6173
Citation: Wang R X, Zhao X P, Ji J T, Jin X, Li B. Design and performance analysis of tangential-axial flow threshing device for oat harvester. Int J Agric & Biol Eng, 2021; 14(6): 61–67.
Keywords
Full Text:
PDFReferences
Liu W Y, Wang D, Zhou H Y, Zhang X Y, Meng H W. Visualization analysis of research hotspots in the field of plant protection on oats. Modern Agricultural Science and Technology, 2020; 3(4): 1-3, 5. (in Chinese)
Tado C J M, Wacker P, Kutzbach H D, Suministrado D C. Development of stripper harvesters: A review. Journal of Agricultural Engineering Research, 1998; 71(2): 103–112.
Craessaerts G, Saeys W, Missotten, B, Baerdemaeker J D. Identification of the cleaning process on combine harvesters, Part II: A fuzzy model for prediction of the sieve losses. Biosystems Engineering, 2010; 106(2): 97–102.
Liang Z W, Li Y M, Xu L Z, Zhao Z, Tang Z. Optimum design of an array structure for the grain loss sensor to upgrade its resolution for harvesting rice in a combine harvester. Biosystems Engineering, 2017; 157(1): 24–34.
Aenlle M L, Brincker R. Modal scaling in operational modal analysis using a finite element model. International Journal of Mechanical Sciences, 2013; 76(1): 86–101.
Alizadeh M R, Allameh A. Threshing force of paddy as affected by loading manner and grain position on the panicle. Research in Agricultural Engineering, 2011; 57(1): 8–12.
Boac J M, Casada M E, Maghirang R C, Harner J P. Material and interaction properties of selected grains and oil seeds for modeling discrete particles. Transactions of the ASABE, 2010; 53 (4): 1201–1216
Mekonnen G G, Josse D B, Martine B. Effect of a cross - flow opening on the performance of a centrifugal fan in a combine harvester: Computational and experimental study. Biosystems Engineering, 2010; 105(2): 247–256.
Li X P, Meng Y J, Zhang J L, Geng L X, Ji J T. Design and test of cleaning device for roller rubbing cylinder sieve of millet. Transactions of the CSAM, 2018; 49(10): 92–102. (in Chinese)
Kundu M, Krishnan P, Kotnala R K, Sumana G. Recent developments in biosensors to combat agricultural challenges and their future prospects. Trends in Food Science & Technology, 2019; 88: 157–178.
Miu P I, Kutzbach H D. Mathematical model of material kinematics in an axial threshing unit. Computers and Electronics in Agriculture, 2007; 58(2): 93–99.
Zhao Z, Li Y M, Chen J, Xu J J. Grain separation loss monitoring system in combine harvester. Computers and Electronics in Agriculture, 2011; 76(2): 183–185.
Su Y, Liu H, Xu Y, Cui T, Qu Z, Zhang D X. Optimization and experiment of spike-tooth elements of axial flow corn threshing device. Transactions of the CSAM, 2018; 49(S1): 265–272. (in Chinese)
Maertens K, Baerdemaeker J D. Flow rate based prediction of threshing process in combine harvesters. Applied Engineering in Agriculture, 2003; 19(4): 383–388.
Jun H J, Choi I S, Kang T G, Choi S, Choi Y, Choi D K, et al. Study on performance improvement of a head-feeding rice combine for foxtail millet harvesting. Journal of Biosystems Engineering, 2015; 40(1): 10–18.
Xu L Z, Li Y M, Wang C H, Xue Z. A combinational threshing and separating unit of combine harvester with a transverse tangential orthogonal and an axial rotor. Transactions of the CSAM, 2014; 45(2): 105–108. (in Chinese)
Wu T Y, Li Y M, Xu L Z, Huang J. Optimization Design of Transmission System for Tangential Longitudinal Threshing Separation Device. Journal of Agricultural Mechanization Research, 2019; 41(10): 242–248. (in Chinese)
Li Y, Xu L Z, Zhou Y, Li Y M. Effect of extractions feed-quantity on airflow field in multi-ducts cleaning device. Transactions of the CSAE, 2017; 33(12): 48–55. (in Chinese)
Li Y M, Wang J P, Xu, L Z, Tang Z, Xu Z H, Wang K J. Design and Experiment on Adjusting Mechanism of Concave Clearance of Combine Harvester Orthogonal. Transactions of the CSAM, 2018; 49(8): 68–75. (in Chinese)
Li Y M, Chen Y, Xu L Z, Li L. Optimization of structural parameters for threshing and separating device in oblique tangential-longitudinal combine. Transactions of the CSAM, 2016; 47(9): 56–61. (in Chinese)
Gebrehiwot M G, Baerdemaeker J D, Baelmans M. Numerical and experimental study of a cross-flow fan for combine cleaning shoes.
Biosystems Engineering, 2010; 106(4): 448–457.
Liao Q X, Xu Y, Yuan J C, Wan X Y, Jiang Y J. Design and experiment on combined tangential and throwing longitudinal axial flow threshing and separating device of rape combine harvester. Transactions of the CSAM, 2019; 50(7): 140–150. (in Chinese)
Yuko U, Masami M, Eiji I, Mori K, Okayasu T, Mitsuoka M. Turbulent flow characteristics of the cleaning wind in combine harvester. Engineering in Agriculture, Environment and Food, 2012; 5(3): 102–106.
Wang S S, Shi Q X, Geng L X, Luo H G. Development of test-bed of semi-feeding millet threshing mechanism. Journal of Chinese Agricultural Mechanization, 2016; 37(12): 27–30. (in Chinese)
Qian K, Wang R X, Geng L X, Jin X, Wang S S. Research on anti-winding performance of slender ductile stalks of tangential flow drum. Journal of Henan University of Science & Technology (Natural Science), 2019; 40(3): 66–71. (in Chinese)
Qian K. The performance experimental study on high-fineness and toughness crop of tangential-axial flow threshing device. Master dissertation. Luoyang, China: Henan University of Science and Technology, 2019; 66p. (in Chinese)
Chattopadhyay P S, Pandey K P. PM—Power and machinery: Impact cutting behaviour of sorghum stalk using a flail-cutter - a mathematical model and its experimental verification. Journal of Agricultural Engineering Research, 2001; 78(4): 369–376.
Copyright (c) 2021 International Journal of Agricultural and Biological Engineering
This work is licensed under a Creative Commons Attribution 4.0 International License.