Research Status and Prospects of Chassis Leveling Technology in Agricultural Machinery

doi:10.12133/j.smartag.SA202512012

Abstract

Abstract:

[Significance] Hilly and mountainous areas are characterized by complex topography, rugged roads, steep and narrow slopes, and fragmented, discontinuous farmland plots, making it difficult for traditional agricultural machinery to adapt to such conditions. These terrain-related limitations have become a major bottleneck restricting the development of agricultural mechanization and modernization in such areas. Therefore, the research, development, and promotion of agricultural machinery and equipment suitable for hilly and mountainous areas are urgently needed. As a key technology for improving the terrain adaptability and operation quality of agricultural machinery, chassis leveling has become a research hotspot in the field of domestic agricultural machinery equipment. [Progress] A comprehensive review of research on evaluation indicators, leveling devices, and control systems for agricultural machinery chassis leveling is presented. This review focuses on summarizing the categories and applicable scopes of static and dynamic indicators, and analyzing the principles, performance characteristics, and applicable scenarios of two types of leveling mechanisms, namely, three-point support and four-point support. In this review, multisource information fusion schemes, such as attitude sensing, displacement measurement, load monitoring and terrain perception are summarized; the technical characteristics of chassis leveling control strategies, including the angle error control method and the position error control method, are expounded; and the evolutionary path of intelligent algorithms from traditional proportional-integral-derivative (PID) control to fuzzy control, sliding mode control, and neural networks is reviewed. Evaluation indicators, such as roll angle, pitch angle, leveling speed, mean tilt angle, and standard deviation of tilt angle, can provide a relatively comprehensive assessment of the operational performance of chassis leveling systems. Representative three-point support leveling devices include mechanisms based on lateral leveling, hydraulic differential-height adjustment, double guide columns, double parallel four-bar linkages, left-right eccentric wheel swing, and left-right transmission rocker arms. Representative four-point support leveling devices include adaptive balanced rocker suspension, four-point guide-column lifting mechanisms, Y-shaped adjustable suspension, four-hydraulic-cylinder leveling structures, hinged multi-link mechanisms, and articulated three-layer frames. These devices can calculate the required compensation according to the inclination state of the chassis and then realize body attitude adjustment through mechanical structures, hydraulic systems, and other actuating devices. By dynamically adjusting the vehicle body and operating components, they can effectively redistribute the center of gravity of agricultural machinery and improve operational stability on sloping terrain. Meanwhile, combined with high-precision sensors, intelligent control strategies, and efficient control algorithms, chassis leveling systems can achieve adaptive leveling under complex terrain conditions with steep and narrow slopes. [Conclusions and Prospects] Existing chassis leveling technologies for agricultural machinery can basically satisfy the leveling requirements of large-scale machinery operating on broad and relatively gentle farmland, and have already seen preliminary applications. However, in the complex terrain of hilly and mountainous areas, the following limitations still exist: Chassis leveling models and performance evaluation standards have not yet been established; The reliability and universality of existing leveling devices are still insufficient; The integration level of chassis leveling control systems remains limited, and the intelligence and adaptability of control algorithms require further improvement; False leg phenomenon is still difficult to identify, while engineering verification, practical promotion, and field application remain inadequate. In view of the current research status, existing problems, and future development demands, this paper proposes several priority directions for future study aimed at improving the adaptability of agricultural machinery to hilly and mountainous terrain. These include: Constructing a leveling mechanism and evaluation system that are closely integrated with agronomic practices; Developing highly reliable and universal chassis leveling devices; Developing intelligent cooperative adjustment control systems with multisensor integration; Suppressing False Leg phenomenon and low-cost engineering verification leveling technology. This review is expected to provide reference data for the research and development of advanced agricultural machinery equipment applicable to hilly and mountainous areas of China.

Key words: agricultural machinery chassis, complex terrain, leveling devices, control

CLC Number:

YANG Wencai, CHEN Hongkun, ZHAO Hengliang, ZHU Longtu, SHANG Xiaobiao, ZHANG Hongyang, ZHEN Guangqi. Research Status and Prospects of Chassis Leveling Technology in Agricultural Machinery[J]. Smart Agriculture, doi: 10.12133/j.smartag.SA202512012.

Figures/Tables 21

Table 1

Comparison of three-point support chassis leveling devices in agricultural machinery

装置类型	研发机构	调平原理	适用场景
侧向调平机构	伊朗科技大学^［24］	通过液压缸调节车体绕底盘传动侧倾中心轴旋转，在保持动力传动功能的同时调整车辆质心位置，从而实现车体姿态调平	轮式拖拉机；平缓丘陵地
侧向调平机构	广东省现代农业装备研究所等^［25］	在活动架与固定架之间增加侧向调平液压缸实现横向±12°调平	果园作业；平缓丘陵地
液压差高机构	西北农林科技大学等^［26］	通过远程遥控液压缸伸出长度，调节两侧相对平行的支撑架，使车桥与车架姿态同步调整，快速实现在0°~23°坡地作业时的横向调平和离地间隙调整	履带式拖拉机；平缓坡地等高线作业
液压差高机构	山东大学等^［27］	通过左右支撑架升降液压缸，在4 s内实现车身在坡度±10°的横向调平	马铃薯联合收获机；平缓丘陵地
双导柱机构	北京林业大学^{［28， 29］}	通过调节两液压缸同时伸缩或一缩一伸，实现在20°坡度条件下的全向调平作业	平缓坡地
双导柱机构	山东理工大学等^［30］	前轮采用被动减震技术，后轮采用双导柱式伺服电缸，降低高频扰动影响的同时实现底盘在±0.2°精度、±9°范围内的全向调平	平缓丘陵地；动态调平
左右传动摇臂机构	山东工业大学；歌尔股份有限公司等^{［31， 32］}	在保证动力传输的基础上，通过控制左右传动摇臂机构实现横向高度差调节，可在6 s内完成±0.3°精度、-16.34°~16.12°的横向姿态调整	小型轮式玉米收获机；陡峭丘陵地
双平行四边形机构	四川农业大学；德阳金星农业机械制造有限公司等^［17］	通过液压缸伸缩，对后摆臂施加压力，使摆臂绕支撑底座做旋转运动，改变底盘上下两段的相对距离，实现在±7.5°倾斜角度下底盘的横向调平，调平时间和角度偏差分别控制在3.6 s和±0.4°以内	水稻联合收割机；动态调平；平缓丘陵地
双平行4杆机构（前轮）+左右偏心轮摆动机构（后轮）	上海交通大学；山东五征集团^［33-35］	前轮通过双平行4杆机构，在实现转向和动力传输功能的同时，根据路面起伏和后桥姿态绕前桥托架左右摆动，保持始终与地面的垂直；后轮通过蜗轮蜗杆装置驱动偏心轮顺时针或逆时针摆动，调节左右车轮高度，兼顾动力传输，在±15.79°丘陵地上实现车身刚性结构的柔性动态横向调整	轮式拖拉机；陡峭丘陵地；动态调平
双对称平行4杆机构（前轮）+滑块摇杆机构（后轮）	吉林大学^［36］	通过平行4杆机构使上底盘架前端抬升和下降，实现±17.5°的车身左右横向调平；通过滑块摇杆机构完成上底盘架后端的抬升和下降，实现最大角度分别为17.5°和11°的前倾和后倾调平	自走轮式玉米收获机；陡峭丘陵地
双对称平行4杆机构（前轮）+滑块摇杆机构（后轮）	燕山大学等^［37］	在后轮采用对称双轮胎结构实现仿形行走的同时，通过液压缸调节双对称平行4杆机构和滑块摇杆机构各支撑点高度，实现车身姿态全向调平及离地间隙调整	陡峭丘陵地
曲柄+滚珠滑块机构	日本久保田株式会社^［38-40］	通过控制升降机构调节单侧履带底盘高度，以补偿机身的横向倾斜，保持清选装置水平，避免清选物在倾斜状态下单侧堆积	履带式全喂入式联合收割机；平缓丘陵地
	日本洋马农机株式会社^{［41， 42］}	通过液压缸控制履带底盘左右平衡机构独立升降13 cm，在湿烂田块作业时克服机体倾斜，保持机体与割台水平	履带式全喂入联合收割机；平缓丘陵地
	广西大学；广西民族大学等^［43］	通过左右对称布置的底盘调平机构，可有效改变整机质心，实现横向姿态调整，调平精度≤0.5°，调平时间1 s，最大调平角10°	履带式甘蔗收获机；平缓丘陵地

Table 1

Table 2

Comparison of four-point support chassis leveling devices in agricultural machinery

装置类型	研发机构	调平原理	适用场景
自适应平衡摇臂悬架机构	北京航空航天大学等^［44］	在车轮仿形行走的同时，摇臂悬架通过手动控制或依靠自重作用，实现离地间隙调节、轮距调节和车身自调平功能	轮式拖拉机；平缓坡地
4点液压升降机构	石河子大学^［45］	通过4个对称分布的液压缸调整底盘机架横梁实现0°~17°的横向调平	自走轮式番茄收获机；陡峭丘陵地
4点液压升降机构	中国铁建重工集团新疆有限公司^{［46， 47］}	通过控制4液压缸伸缩可实现在0°~10°坡地上的横向调平	番茄收获机；平缓丘陵地
平面连杆双向调节机构	华南农业大学等^［48］	根据1条直线和直线外的1点唯一确定1个平面的原则，可实现坡度20°以内的全向调平作业	履带式果园作业；平缓坡地
可调悬架悬臂机构	中国农业大学等^［49］	通过倾角传感器实时测量车身倾斜角度，计算4组悬架悬臂夹角的瞬时调节量并精确调整，可实现底盘最大侧倾角和俯仰角为22.71°和15.58°，精度1°范围内的动态补偿调平	平缓坡地；动态调平
平行4杆机构	湖南农业大学等^{［50， 51］}	通过液压缸驱动、平行4杆机构执行升降，完成离地间隙调节和机身调平	高地隙轮式植保作业；平缓丘陵地
平行4杆机构（横向）+双车架机构（纵向）	西北农林科技大学等^［52］	通过横向调平液压缸改变平行四边形形状，实现0°~15°丘陵地的横向姿态调整，同时优化整机离地间隙；由纵向调平液压缸驱动，带动上层车架绕下层车架后桥半轴旋转一定角度，实现0°~10°丘陵地的纵向姿态调整	履带式拖拉机；陡峭丘陵地；动态调平
绕轴旋转机构	北京林业大学；中国农业大学等^［53］	通过液压调平系统协调4个对称分布的液压缸伸缩，实现机架绕其中心轴旋转完成±8°的侧倾调平；通过控制双液压缸同步伸缩，使工作台绕剪叉机构顶端支撑轴旋转完成±10°的俯仰调平，但当工作台升至最高点时，仰调平角度降至6.5°	履带式果园作业；平缓丘陵地
4点导柱升降机构	法国克莱蒙大学等^［54］	通过4轮独立液压调平机构调整车身倾斜状态，实现车身在0°~10°的全向调平，并动态检测车身横向载荷和实时坡度	平缓丘陵地
	吉林大学等^［55-57］	采用调平液压缸与锥齿轮副组成的4点导柱升降机构，在保持动力输出的同时，实现在复杂工况下0°~15°的车身动态横向调平	轮式拖拉机；陡峭丘陵地；动态调平
	湖南农业大学^［58］	通过独立控制调节4气囊气压可在5.35 s内实现±8.5°俯仰调平、±10°横向调平及0~280 mm离地间隙调节，倾斜度调节误差最大值为0.44°	高地隙轮式植保作业；平缓丘陵地
铰接“3层车架”机构	江苏大学；江苏新能源汽车研究院有限公司^{［59， 60］}	通过液压缸的伸缩分别控制横向和纵向调平层，使其上方车架绕铰接点旋转，分别在3.4 s和3.6 s内实现机身横向20°，纵向25°调平，精度达±1.5°	履带式作业机；平缓坡地；动态调平
Y形可调悬架机构	中国农业大学^［61］	通过协调调节4组Y形可调悬架的高度，实现底盘姿态±0.5°精度内的自适应仿形调平补偿	平缓丘陵地；动态调平
	西南大学等^［62］	通过控制4电动推杆的伸缩实现±8°的全向调平	轮式辣椒苗移栽机；平缓丘陵地
	江苏大学^［18］	通过采集倾角信息，控制轮毂电机驱动实现行走，驱动电缸实现姿态调平	轮式果园作业；平缓丘陵地
变幅轮腿机构+3自由度铰接体机构	福建农林大学；北京林业大学^［63］	通过3自由度铰接体机构和对称分布的4变幅轮腿可在坡面倾角小于15.29°时调节车架实现横向调平	陡峭丘陵地
仿生昆虫后足多连杆机构	中国农业大学等^［64］	基于仿生昆虫后足和多连杆机构原理，构建全向调平装置，实现0°~16°的俯仰调平、0°~27°的侧倾调平和0~574 mm的离地间隙调整，平均调平时间约为1.2 s，平均调平误差为0.8°	陡峭坡地
4液压缸调平机构	美国约翰迪尔公司；凯斯公司^{［65， 66］}	美国John Deere公司生产的S系列联合收割机和Case-IH公司生产的CH、CS系列联合收割机配备Hillco Technologies山坡调平系统，能够通过斜率感应测角仪实时监测机身倾斜状况，实现快速、平稳的27%斜率补偿，精度可达±0.5°	联合收割机；平缓丘陵地；动态调平
	美国麦赛福格森公司^［67］	美国Massey Ferguson公司生产的MF Beta AL4型联合收割机采用由4个液压缸驱动的调平系统，上下坡补偿分别达35%和8%斜率，横向坡度补偿高达38%斜率	联合收割机；平缓坡地；动态调平
	德国芬特公司^［68］	德国Fendt公司生产的5275 C SL型联合收割机通过配备4液压缸调平系统，可提供上坡35%、下坡8%及横向38%的斜率补偿	联合收割机；平缓坡地；动态调平
	德国科乐收公司^［69］	德国CLAAS公司生产的LEXION 7700 MONTANA型联合收割机配备全自动边坡补偿功能，横向补偿能力最高可达18%，纵向补偿能力最高可达6%	联合收割机；平缓丘陵地；动态调平
铰链多连杆机构	南京农业机械化研究所；山东理工大学^［15］	通过电液控制系统控制双曲柄铰链5杆机构，完成底盘双侧升降，实现纵向-5°~7°、横向±6.5°、离地间隙0~130 mm的姿态调整，平均调节时间4.2 s，倾斜度调节误差最大值为0.67°	履带式联合收获机；平缓丘陵地；动态调平
铰链多连杆机构	江苏大学；沃德农业机械股份有限公司等^［70-73］	4点可调式升降机构对称分布于底盘左右两侧，通过液压缸调节离地间隙、横向倾角和纵向倾角，其中离地间隙调节范围为0~140 mm，横向倾角和纵向倾角的调节范围分别为-5.18°~5.55°和-4.06°~5.2°，调平精度达±0.4°	履带式联合收割机；平缓丘陵地
双4连杆机构（横向）+4升降机构（纵向）	甘肃省机械科学研究院有限责任公司等^［74］	在液压驱动下，调整液压缸带动4连杆悬架，实现0°~15°的横向调平；通过4升降液压缸共同抬起或推低机架，使前后侧升降液压缸组形成一定的高度差，实现0°~30°的纵向调平	陡峭丘陵地
双层悬架机构（横向）+铰链杆块机构（纵向）	吉林大学；长春中达拖拉机制造有限公司^［16］	由上下两级调平机构组成，通过液压缸伸缩控制调平盘和上悬架转动，形成高度差，分别实现±43.1°横向与-10°~17°纵向姿态的独立调平，最快调平速率可达0.233 s/（°），调平均方根误差为±0.78°	履带式玉米收获机；陡峭坡地
顶升机构	印度理工学院^［75］	通过液压缸顶起或放下举升机构实现0~245 mm的离地间隙调节和±15.2°的车身侧倾调平	履带式联合收获机；平缓丘陵地
轮毂调平机构	浙江理工大学等^［76］	通过伺服电机的转动适应不同垄高及0°~12°的不平地块，并在9.1 s内完成调平，实现单侧上垄的移栽作业	设施蔬菜移栽机；平缓丘陵地
伸缩机构+偏转机构	西北农林科技大学等^［14］	采用自适应机构保持作业机具方向稳定，并通过调整支腿和旋转偏转机构，减少控制件个数，降低控制难度，在2.5 s内实现调平精度达2.2°、适应0°~20°的全向调平	履带式山地茶园作业；陡峭丘陵地；动态调平

Table 2

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Table 6

Comparison of typical chassis leveling control algorithms

控制类型	算法名称	控制原理	优势	劣势	参考文献
线性控制	传统PID	比例-积分-微分反馈调节	结构简单、实时性好、易工程实现	难以应对强非线性与时变工况	［105］
	增量式PID	控制增量Δu，抑制积分饱和	抗干扰能力较好，适合数字控制	响应偏慢、大范围动态适应性不足	［53］
	前馈PID	前馈补偿+反馈控制	响应快、抑制外部干扰	依赖建模精度、参数整定困难	［95］
	闭环PID	闭环误差最小化控制	结构简单、调试方便	控制精度与动态性能受限	［96］
	双闭环PID	外环位置+内环速度/电流	动态响应快、抗干扰能力强	结构与调参复杂	［33］
非线性控制	模糊PID	模糊规则在线调节PID参数	适应性强、鲁棒性好	规则设计复杂、计算量较大	［108-111］
	双闭环模糊PID控制	模糊PID外环位置+内环速度控制	精度高、稳定性好	规则数量多、调试难度大	［34］
	模糊分层变结构	模糊调节+变结构切换	控制精度高、鲁棒性强	结构复杂、工程实现难	［112］
	神经网络PID	神经网络自整定PID参数	适应强非线性与时变系统	训练复杂、泛化能力受限	［106］
	滑模同步	滑模保持多执行器同步	多系统协调能力强	通信需求高、结构复杂	［100］
	带微分观测的三阶滑模	状态估计+高阶滑模面	控制精度高、估计误差小	对噪声敏感、计算量大	［107］
融合控制	模糊-卡尔曼	模糊控制+卡尔曼估计	抗噪能力强、控制平滑	依赖模型、参数敏感	［50， 51］
	卡尔曼-模糊PID	状态估计+模糊调参	精度高、抗干扰能力强	实时性受限	［62］
	GA-BP神经网络	遗传算法优化BP网络	全局搜索、优化能力强	易陷局部最优、泛化不足	［103］
	QBP-PID	强化学习+神经网络调参	智能优化、自学习能力强	收敛慢、结构和调参复杂	［99］
	Backstepping-滑模双闭环	非线性反步+滑模控制	鲁棒性强、控制精度高	参数多、调试工作量大	［113］
	模糊滑模变结构	模糊调节滑模增益	抗扰能力强、控制灵活	规则设计和结构复杂	［114］
	自适应模糊滑模	滑模+模糊+自适应	自适应与鲁棒性兼顾	控制结构复杂、调参难度大	［115］
	ADLCCS-SLM	自适应双闭环+阶梯调平	复杂地形适应性强	参数耦合、结构复杂、调参难度大	［37］

Table 6

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调平传感器类型	主要功能	安装位置	精度
姿态检测传感器	实时获取侧倾角与俯仰角等姿态信息	底盘中心或关键支撑点	0.01°~0.1°
位移传感器	测量支腿/液压缸伸缩量，反馈执行状态	支腿伸缩机构或液压缸	0.05~1 mm
载荷检测传感器	监测支撑载荷分布，识别并抑制“虚腿”	支腿或液压缸支撑部位	0.05%~0.5% Full Scale （F.S）
地形测量传感器	感知前方地形变化，实现主动调平	底盘顶部或底部	1~10 mm

位置误差控制调平法	优势	劣势	适用场景
“中心点”不动调平法	重心变化小、调平行程短、调平时间短、调平余量充足	对初始姿态敏感	动态行走作业；坡度变化频繁的复杂地形
“最高点”不动调平法	只升不降、可抑制“虚腿”	调平时间长、调平余量逐步减少、重心升高	高地隙作业机械；静态调平；大面积平缓坡地
“最低点”不动调平法	重心降低、稳定性与抗侧倾能力强	影响通过性、调平时间较长	稳定性优先场景；静态调平；大面积平缓坡地

调平控制策略	优势	劣势	适用场景
角度误差控制调平法	算法结构简单、响应速度快、控制精度高	多方向角度耦合，需多次迭代调整、调平时间较长、传感器精度要求高、载荷不均时易诱发“虚腿”	动态调平；地形起伏频繁、坡度快速变化的复杂地形
位置误差控制调平法	支腿位置调节精确、调平次数少、调平时间较短	计算和控制逻辑复杂、响应速度较慢、载荷分布不均时仍可能出现“虚腿”	静态调平或动静态兼顾；大面积平缓坡地