In order to find out the matching principle of excitation force and energy consumption of reciprocating vibrating Chinese wolfberry picking device, the energy consumption mechanism of reciprocating vibrating Chinese wolfberry picking device is studied. According to the structural characteristics and operating principle of the picking device, the no-load and load movement and force characteristics of the crank bearing and vibrating component are analyzed, and the theoretical model of energy consumption of the reciprocating vibration picking device is jointly constructed, and the simulation analysis is carried out. The results show that the vibrating component and load mass have a significant influence on torque, the load air resistance phase has a significant effect on torque, and the load air resistance and friction coefficient have no significant influence on torque. Subsequently, by building an AC servo motor torque detection system and a torque sensing detection system, verification experiments are carried out, the maximum torque of the preset system is 1.3 N∙m, the rated power is 400 W, the motor frequency is 20 Hz, the amplitude is 15 mm, and the total mass of the vibrating component is 0.143 kg. Test results show that, the no-load operation, the change trend of detected torque is consistent with simulation, the torque model is verified to be accurate. The maximum torque of simulation and detection are 0.52 N∙m and 0.57 N∙m respectively, and the error between test and simulation is 9.6%. For load operation, the maximum torque of five groups of branch loads of 20 g, 60 g, 100 g, 140 g, 180 g and 220 g are detected to be 0.73 N∙m, 0.74 N∙m, 0.75 N∙m, 0.82 N∙m and 0.83 N∙m, respectively, and the relationship model between load and torque is obtained by fitting. The research results can provide a theoretical basis which can configure a suitable motor in the reciprocating vibration Chinese wolfberry picking device with a certain load limit.
Key words: Chinese wolfberry branches; vibration component; load; torque; power
DOI: 10.25165/j.ijabe.20241704.8939

Citation: Mei S, Tang D B, Shi Z G, Song Z Y, Shen C. Energy consumption mechanism simulation and experimental study of reciprocating vibration for Chinese wolfberry picking. Int J Agric & Biol Eng, 2024; 17(4): 146–155.

Chinese wolfberry branches; vibration component; load; torque; power

Ma J W. Research status and prospect of the mechanized technology of picking wolfberry in China. Mechanical Research & Application, 2017; 30(4): 151–153. (in Chinese)

Cao L, Zhang A L. Study on present situation development stages and trends of Chinese wolfberry industry. Forest Resources Management, 2015(2): 4–8, 30. (in Chinese

Wang Y J, An W, Shi Z G, Zhao J H. Research progress in wolfberry medicinal properties. Journal of Anhui Agricultural Science, 2020; 36(30): 13213–13214, 13218. (in Chinese

Luo X W. Artificial intelligence and plant protection mechanization. Journal of Intelligent Agricultural Mechanization, 2020; 1(1): 1–6. (in Chinese

Sun Y T, Chen G, Li Q L, Sun Y J, Shen J X, Yan N. Application and development trend of intelligent agriculture. Journal of Intelligent Agricultural Mechanization, 2020; 1(1): 56–59. (in Chinese

Song Z Y, Mei S, Xiao H R, Shi Z G, Wang J P, Zhao Y, Ding W Q. Comparative test and analysis on the harvesting methods of Chinese wolfberry fruit. Journal of Chinese Agricultural Mechanization, 2019; 40(10): 110–116. (in Chinese

Li C, Xing J J, Xu L M, He S L, Li S J. Design and experiment of wine grape threshing mechanism with flexible combing striping monomer. Transactions of the CSAE, 2015; 31(6): 290–296. (in Chinese

Ye L Q, Li Q, Chen J Y, An W. Study on picking performance of portable wolfberry picker. Ningxia Journal of Agriculture and Forestry Science and Technology, 2009; 4: 4–5, 56. (in Chinese

Zhang W Q, Zhang M M, Zhang J X, Li W. Design and experiment of vibrating wolfberry harvester. Transactions of the CSAM, 2018; 49(7): 97–102. (in Chinese

Cao Y L. Chinese wolfberry picker: China Patent, ZL201020520858.8. 2011.08. 31. (in Chinese

Zhao Y W, Huang H R, Liu X M, Zhang W Y, Geng D X. Design and Grasping Experiments. Transactions of the CSAM, 2023; 54(9): 74–84. (in Chinese

Qin Z Y, Gao S, Shi T F, Chen Y. One kind of vibrating Chinese wolfberry picking machine: China patent, ZL201922364289.6. 2020.10. 13. (in Chinese

Shi B G, Yang W Z. Development status and countermeasures of organic wolfberry industry in Qinghai Province. Journal of Anhui Agricultural Science, 2019; 47(7): 229–231. (in Chinese

He M, Li C S, Wang L H, Zhang Y O, Yang L T, Wu S. Research status of the harvesting device of Lycium barbarum L. Journal of Anhui Agricultural Science, 2015; 43(33): 367‐369, 385. (in Chinese

Zhang Z, Xiao H R, Ding W Q, Mei S. Mechanism simulation analysis and prototype experiment of Chinese wolfberry harvest by vibration mode. Transaction of the CSAE, 2015; 31(10): 20–28. (in Chinese

Liu W H. Development and experimental effect of self-propelled large Lycium barbarum picker. Agriculture Machinery Technology Extension, 2014; 1: 47–48. (in Chinese

Peng Y, Zhang Z Y, Liu Y, Xu T S, Wang R J. Design and experiment of accurate clamping vibration wolfberry harvesting machine. Mechanical Research & Application, 2018; 31(6): 123–129, 132. (in Chinese)

Silva F C D, Silva F M D, Alves MC, Ferraz G A E S, Sales RS. Efficiency of coffee mechanical and selective harvesting in different vibration during harvest time. Coffee Science, 2015; 10(1): 56–64.

Du X Q, Li D W, He L Y, Wu C Y, Lin L P. Fruit motion analysis in process of mechanical vibration harvesting based on electronic fruit technique. Transactions of the CSAE, 2017; 33(17): 58–64. (in Chinese)

Liu J Z, Tang S Q, Shan S, Ju J, Zhu X X. Simulation and test of grape fruit cluster vibration for robotic harvesting. Transactions of the CSAM, 2016; 47(5): 1–7. (in Chinese)

Challa V R, Prasad M G, Shi Y, Fisher F T. A vibration energy harvesting device with bidirectional resonance frequency tunability. Smart Materials & Structures, 2008; 17(1): 15035–15010.

Mei S, Xiao H R, Shi Z G, Jiang Q H, Zhao Y, Ding W Q. Design and test of low-loss Chinese wolfberry harvesting technology and equipment based on reciprocating vibration method. Journal of Chinese Agricultural Mechanization, 2019; 40(11): 100–105, 208. (in Chinese)

Mei S, Wang J P, Song Z Y, Tang D B, Shen C. Mechanism and experimental study on the fruit detachment of Chinese wolfberry through reciprocating vibration. Int J Agric & Biol Eng, 2024; 17(2): 47–58.

Mei S, Pei F Q, Song Z Y, Tong Y F. Design and testing of accurate dicing control system for fruits and vegetables. Actuators, 2022; 11(9): 1–19.