In view of the problems of poor working quality and low efficiency caused by traditional hitch mechanisms, which cannot make farm implements adapt to hillside fields for terrain-adaptive working after leveling the body of hilly tractors, a new type of terrain-adaptive hitch mechanism was designed which can adjust the transverse posture of farm implements to meet the ploughing requirements of complicated terrain in hilly and mountainous areas. The mechanism was mainly composed of the original hitch device and the newly added rotating device. The kinematic model of each sub-mechanism was established, as well as the mathematical relation of significant performance indexes of the whole mechanism, such as lifting capacity, transverse inclination angle and tillage depth. Genetic algorithm was used to optimize the lifting performance of this hitch mechanism in Matlab, so that the minimum vertical lifting force at the center of gravity of farm implements increased by 14.1%, which met the requirements of national standards. Through ADAMS simulation calculation, it was found that different working slopes had a certain influence on the external load of each component, and terrain-adaptive hitch mechanism had little effect on the vibration characteristics of hilly tractors. The fatigue analysis and optimization design of the key component, rotating shaft, were carried out in ANSYS Workbench, and the mass of this part reduced by 64%. A real vehicle test platform was set up to test and verify the power lifting range and working slope range of terrain-adaptive hitch mechanism. The test results showed that the actual power lifting ranged in 185-857 mm, and the maximum error from the theoretical range was only 3.1%, while the actual working slope range was from –25.9° to +23.2°, and the maximum error from the theoretical range was only 4.5%. Therefore, the terrain-adaptive hitch mechanism can meet the requirements of power lifting performance, and simultaneously can adjust the transverse posture of farm implements for adapting to hillside fields of no less than 20°.
Keywords: hilly tractors, hitch mechanism, terrain-adaptive working, transverse posture, optimal design
DOI: 10.25165/j.ijabe.20231604.6992

Citation: Xin Z, Jiang Q B, Zhu Z X, Shao M X. Design and optimization of a new terrain-adaptive hitch mechanism for hilly tractors. Int J Agric & Biol Eng, 2023; 16(4): 134–144.

hilly tractors, hitch mechanism, terrain-adaptive working, transverse posture, optimal design

Luo X W. Thoughts on the development of agricultural mechanization in hilly and mountainous areas. Agriculture Machinery Technology Extension, 2011; 2: 17–20. (in Chinese)

Wang S S, Geng L X. Development situation and countermeasures of agricultural mechanization in hilly and mountain areas. Agricultural Engineering, 2016; 6(5): 1–4. (in Chinese)

Wu Q F. Technological development of mountain multi-purpose tractors in foreign countries. Tractor & Farm Transporter, 2011; 38(6): 1–5. (in Chinese)

Ahmadi I. Dynamics of tractor lateral overturn on slopes under the influence of position disturbances (model development). Journal of Terramechanics, 2011; 48: 339–346.

Pijuan J, Comellas M, Nogués M, Roca J, Potau X. Active bogies and chassis levelling for a vehicle operating in rough terrain. Journal of Terramechanics, 2012; 49(3-4): 161–171.

Kumar A, Pranav P K, Kumar S. Computer simulation of three-point linkage parameters for virtual hitch point and optimum depth of operation. Engineering in Agriculture, Environment and Food, 2018; 11(3): 114-121.

Lanusse P, Oustaloup A, Ceyral C, Nouillant M. Optimal crone control of a tractor hitch system. International Federation of Automatic Control, 1992: 25(13): 301–307.

Ju W P. Development status of tractor hitch system at home and abroad. Jiangsu Agricultural Mechanization, 2006; 6: 40. (in Chinese)

Lang T, Harms H H. A new concept for the three-point-hitch as a mechatronic system. Proceedings of the Conference on Automation Technology for Off-Road Equipment, 2002; pp.246–251. doi: 10.13031/2013.10013.

Matikainen V, Backman J, Visala A. Cartesian control of an advanced tractors rear hitch: Geometric solution. International Federation of Automatic Control, 2013; 4: 270–275.

Matikainen V, Backman J, Visala A. Cartesian control of an advanced tractors rear hitch: Damped least-squares solution. International Federation of Automatic Control, 2014; 19: 11565–11570.

Haun R D, Trefz H J. Mower deck leveling system. US: 20150296711, 2015–10–22.

Kumar R, Raheman H. Design and development of a variable hitching system for improving stability of tractor trailer combination. Engineering in Agriculture, Environment and Food, 2015; 8(3): 187-194.

Xia C G, Yang H T, Han J Y, Chen C, Jiang Z H. Research status and development trend of hilly mountain tractor leveling system. Journal of China Agricultural University, 2018; 23(10): 130–136. (in Chinese)

Gao Q M, Gao F, Tian L, Li L J, Ding N G, Xu G Y, et al. Design and development of a variable ground clearance, variable wheel track self-leveling hillside vehicle power chassis (V2-HVPC). Journal of Terramechanics, 2014; 56: 77–90.

Sun J B, Meng C, Zhang Y Z, Chu G P, Zhang Y J, Yang F Z, et al. Design and physical model experiment of an attitude adjustment device for a crawler tractor in hilly and mountainous regions. Information Processing in Agriculture, 2020; 7(3): 466-478.

Sun X W, Yuan H L. Robust control of farm tractors on variable sloped terrains based on sliding-mode observers. Proceedings of the 39th Chinese Control Conference, 2020; pp.5479–5484. doi: 10.23919/CCC50068.2020.9189165.

Qin J H, Wu A B, Song Z S, He Z Z, Suh C S, Zhu Z X, et al. Recovering tractor stability from an intensive rollover with a momentum flywheel and active steering: System formulation and scale-model verification. Computers and Electronics in Agriculture, 2021; 190: 106458. doi: 10.1016/j.compag.2021.106458.

Zhou H, Hu L, Luo X W, Zhao R M, Xu Y, Yang W W. Design and experiment on auto leveling system of rotary tiller. Transactions of the CSAM, 2016; 47(S1): 117–123. (in Chinese)

Wang W D. Automatic leveling device and method for measuring and leveling the traction board of agricultural tractors. Chinese Patent: CN 105830571, 2016–08–10. (in Chinese)

Yang S Q, Li G Y, Xu F, Zhang L, Meng C Y, Yang H T, et al. Analysis of automatic measurement method of tillage depth: Based on mountain tractor with body leveling function. Modern Agricultural Science and Technology, 2020; 13: 154–156,160. (in Chinese)

Liu L. Studies on the leveling system of tillage implement based on tractor three-point suspension system. Changsha: Hunan Agricultural University, 2014. (in Chinese)

Jiang J, Zhang J, Feng Y J, Jiang R C, Peng X Y, Jin B D, et al. The design and simulation analysis of the electro-hydraulic hitch system in the tractor. Journal of Zhejiang Normal University (Natural Sciences), 2019; 42(1): 31–35. (in Chinese)

Shao M X, Xin Z, Jiang Q B, Zhang Y A, Du Y F, Yang H F. Fuzzy PID control for lateral pose adjustment of tractor rear suspension. Transactions of the CSAE, 2019; 35(21): 34–42. (in Chinese)

Yang F Z, Niu H L, Sun J B, Liu Z J, Li Y L, Chu H L. Design and experiment of the attitude cooperative control system of mountain crawler tractor and farm tools. Transactions of the CSAM, 2022; 53(1): 414-422. (in Chinese)

Cheng Y S. Tractor design. China Agricultural Machinery Press, 1981. (in Chinese)

GB/T 3871.4–2006. Agricultural tractors–Test procedures–Part 4: Rear three-point linkage lifting capacity. (in Chinese)

GB/T 1593–2015, Agricultural wheeled tractor–Rear-mounted three-point linkage. (in Chinese)

Abderazek H, Yildiz A R, Mirjalili S. Comparison of recent optimization algorithms for design optimization of a cam-follower mechanism. Knowledge-Based Systems, 2019; 191: 105237. doi: 10.1016/j.knosys.2019.105237.

Azimi-Nejadian H, Karparvarfard S H, Naderi-Boldaji M, et al. Combined finite element and statistical models for predicting force components on a cylindrical mouldboard plough. Biosystems Engineering, 2019; 186: 168–181.

Li M S. Research on the dynamics performance of electro-hydraulic hitch system in big-power tractor. Doctoral dissertation, Beijing: China Agricultural University, 2013. (in Chinese)

Ni W Q, Jiang Q, Xu L Y, Zhang X J, Jiang D D. Effects of suspension parameters on vibration characteristics of tractor. Journal of Huazhong Agricultural University, 2020; 39(4): 175–181. (in Chinese)

Liu W, Zheng E L, Zhou Y Q, Yao H P, Zhu Y. Vibration characteristics analysis of wheeled tractor/implement system under plough operation condition. Journal of Nanjing Agricultural University, 2021; 44(5): 1002–1012. (in Chinese)