To solve the problems of the traditional orchard conveyor, such as inflexible steering, a complex structure, poor stability and no power grid coverage, a remote-controlled rail conveyor powered by hydraulic pressure for mountainous orchards was designed and manufactured. Climbing stress analysis was carried out on a full-load trailer to obtain the maximum traction force, which meets the requirement of the climbing slope of the transport mechanism. The key components of the conveyor were developed, such as the hydraulic transmission, the control system, safety protection devices, limiting devices, the throttle and decompression actuator, the counterweight tension and the battery. Through the theoretical calculations of key components, an orchard conveyor powered by diesel and hydraulic pressure was designed. Finally, the working performance of the transporter was tested through functionality, driving speed, system pressure and remote-controlled tests. The test results showed that the climbing angle of the transporter can reach 50°, the uphill load can reach 840 kg, the downhill load can reach 1100 kg, and the average running speed is 0.77 m/s; the driving speed ranges from 0.29 m/s to 1.08 m/s, and the system pressure ranges from 3.2 MPa to 10 MPa. The driving speed and system pressure are significantly affected by the load, and the remote control distance can reach 455 m. The technical specifications of the transporter meet all the design requirements, and the problem of stable operation of the transporter without power grid coverage has been addressed. The research results can well meet the practical application requirements of mountain orchard transportation without power grid coverage and provide theoretical reference for the design of key components of mountain orchard transportation machinery.
Keywords: mountain orchard, conveyor, hydraulic drive, remote control
DOI: 10.25165/j.ijabe.20211402.5844

Citation: Li J X, Li S J, Zhang Y L, Liu M D, Gao Z Y. Development and test of hydraulic driven remote transporter. Int J Agric & Biol Eng, 2021; 14(2): 72–80.

mountain orchard, conveyor, hydraulic drive, remote control

Zou B L, Liu F L, Zhang Z B, Hong T S, Wu W B, Lai S X. Mechanization of mountain orchards: development bottleneck and foreign experiences. Journal of Agricultural Mechanization Research, 2019; 41(9): 254–260. (in Chinese)

Pu Y J, Toudeshki A, Ehsani R, Yang F Z. Design and evaluation of a two-section canopy shaker with variable frequency for mechanical harvesting of citrus. Int J Agric & Biol Eng, 2018; 11(5): 77–87.

Wu W B, Zhao B, Zhu Y Q, Wang H L, Zhi L, Feng Z F. Research progress of hilly orchard transporter. Journal of Huazhong Agricultural University, 2013; 32(4): 135–142. (in Chinese)

Lü Q, Cai J R, Liu B, Deng L, Zhang Y J. Identification of fruit and branch in natural scenes for citrus harvesting robot using machine vision and support vector machine. Int J Agric & Biol Eng, 2014; 7(2): 115–121.

Giuseppe M, Emanuele C, Rita P, Roberta S, Biagio P. Performance evaluation of digestate spreading machines in vineyards and citrus orchards: preliminary trials. Heliyon, 2020, 6: e04257. doi: 10.1016/ j.heliyon.2020.e04257.

Zhao Y, Xiao H R, Mei S, Song Z Y, Ding W Q, Jing Y, et al. Current status and development strategies of orchard mechanization production in China. Journal of China Agricultural University, 2017; 22(6): 116–127. (in Chinese)

Bagheri N, Bordbar M. Factor analysis of agricultural mechanization challenges in Iran. Agriculrural Engineering International: CIGR Journal, 2014; 16(1): 167–172.

Zhang B, Zhang L X, Fu Z T, Wang J Q. Analysis on agricultural organizations' application requirements for agricultural machinery and factors affecting purchasing behavior. Journal of Agricultural Mechanization Research, 2018; 40(5): 10–17. (in Chinese)

Sheng L L, Song S R, Hong T S, Li Z, Dai Q F. The present situation and development and development of mountainous orchard mechanization in Guangdong province. Journal of Agricultural Mechanization Research, 2017; 39(11): 257–262. (in Chinese)

Hong T S, Su J, Zhu Y Q, Yang Z, Yue X J, Song S R. Circular chain ropeway for cargo transportation in mountain citrus orchard. Transactions of the Chinese Society for Agricultural Machinery, 2011; 42(6): 108–111. (in Chinese)

Wen T, Hong T S, Su J, Zhu Y Q, Kong F B, Chileshe J M. Tension detection device for circular chain cargo transportation ropeway in mountain orchard. Transactions of the Chinese Society for Agricultural Machinery, 2011; 42(8): 80–84. (in Chinese)

Li S J, Xing J J, Zhang Y L, Meng L, Fan Q Z. 7YGS-45 type self-propelled dual-track mountain orchard transport. Transactions of the Chinese Society for Agricultural Machinery, 2011; 42(8): 85–88. (in Chinese)

Li S J, Xing J J, Zhang Y L, Li X J, Fan Q Z. Construction of 7YGS-45 type orchard transport automatic control test platform. Advanced Materials Research, 2011; 1169: 1396–1401.

Li X J, Zhang Y L, Zhang W Y, Ling X P. Design and improvement of the remote control self-propelled monorail transporter for mountainous orchard. Journal of Huazhong Agricultural University, 2014; 33(5): 117–122. (in Chinese)

Zhang J F, Li J Y, Zhang Y L, Li S J, Meng L. Design of remote control monorail transporter for mountainous orchard. Transactions of the Chinese Society for Agricultural Machinery, 2012; 43(2): 90–94. (in Chinese)

Shamshiri R R, Weltzien C, Hameed I A, Yule I J, Grift T E, Balasundram S K, et al. Research and development in agricultural robotics: A perspective of digital farming. Int J Agric & Biol Eng, 2018; 11(4): 1–14.

Meng L, Zhang Y L, Zhang W Y, Li J, Li S J, Li M Z. Design of trailed trackless mountain orchard transporter with remote control. Journal of Huazhong Agricultural University, 2015; 34(4): 125–129. (in Chinese)

Zhang J F, Zhang T J, Zhang Y L. Design of the remote control traction transporter for mountainous orangery. Hubei Agricultural Sciences, 2012; 51(10): 2111–2113, 2131. (in Chinese)

Li S J, Liu H, Zhang Y L, Che H, Meng L, Ma P Y, et al. Optimization of rack tooth forms of monorail mountain orchard transporter. Transactions of the Chinese Society for Agricultural Machinery, 2018; 34(6): 52–57. (in Chinese)

Li H, Li S J, Zhang Y L, Ma P Y, Chen M. Mechanical simulation and experiment of self-propelled monorail mountain orchard transporter under different racks. Journal of Huazhong Agricultural University, 2019; 38(2): 114–122. (in Chinese)

Liu Y, Li Z, Hong T S, Lu S L, Song S R, Huang S P. Design of drive system for battery-drive monorail transporter for mountainous orchard. Transactions of the Chinese Society for Agricultural Machinery, 2017; 33(19): 34–40. (in Chinese)

Raheleh F, Alireza K, Seyyed S M. Estimation of a mechanization index in apple orchard in iran. Journal of Agricultural Science, 2010; 2(4): 180–185.

Tang X L. Design of 7YGD－45 type single-track orchard transport. Wuhan: Huazhong Agricultural University, 2012. (in Chinese)

Li Z, Hong T S, Sun T B, Ou Y Y P, Luo Y Q. Design of battery powered monorail transporter for mountainous orchard. Journal of Northwest A & F University (Nat. Sci. Ed.), 2016; 44(6): 221–227, 234. (in Chinese)

Huazhong Agricultural University. A hydraulically driven remote control rail transport device. Chinese Patent, 2017213508586, 2018-06-01.

Huazhong Agricultural University. Hydraulically driven remote control rail transportation system and control method. Chinese Patent, 2017109804914. 2018-02-27.

Li S J. Characteristic analysis and experimentation study on driving wheelset of self-propelled dual-track orchard transport. Wuhan: Huazhong Agricultural University, 2012. (in Chinese)

Song W, Li Y F, Zhang H B, Wang D H. Design of control and hydraulic drive system for high-altitude live working vehicle. The Journal of Engineering, 2019; 2019(23): 8561–8565.

Tomarov G V, Nikolaev A E, Semenov V N, Shipkov A A, Shepelev S V. Study of the causes and identification of the dominant mechanisms of failure of bellows expansion joints used in district heating system pipelines at MOEK. Thermal Engineering, 2015; 62(6): 456–463.

Liu Y G, Gao X H, Pei Z C, Zhang H. Research of impact load in large electrohydraulic load simulator. Mathematical Problems in Engineering, 2014.

Zhang J F. Research on remote control key technology and device of mountain orchard monorail transporter. Wuhan: Huazhong Agricultural University, 2012. (in Chinese)