Tillage depth dynamic monitoring and precise control system

Kai Hu, Wenyi Zhang, Bin Qi, Yao Ji
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Abstract

The tillage depth (TD) serves as a pivotal criterion for assessing the operational excellence of rotary tillers, yet the current TD control methods are plagued by a myriad of issues including subpar precision and sluggish responsiveness. The present study aimed to develop a high-precision TD monitoring model that incorporates the tilting attitude of the tractor, and investigate the impact of tractor attitude inclination and lifting hydraulic cylinder stroke on TD. The TD stability control system based on electro-hydraulic control was developed, and the model identification method was adopted to derive the accurate control function. The fuzzy adaptive PID (FAPID) method was adopted to effectively improve the response speed and resisting disturbance capacity of the electro-hydraulic system. Then the co-simulation model of the electro-hydraulic control system was constructed. Under the excitation of step and sine functions, the FAPID control algorithm can reduce the rise time by more than 50%, and the displacement tracking error is also effectively reduced. To verify its effectiveness, the experimental platform was constructed, and then field test trials of TD were conducted. The test results indicate that, under various operational conditions, the developed TD control device can effectively reduce the standard deviation of TD by 0.302–0.464 and decrease the variation coefficient of TD by 2.47%–2.92%. The online monitoring and precise control device of TD investigated in this paper can effectively improve the quality of tillage machinery.
耕深动态监测和精确控制系统
耕作深度(TD)是评估旋耕机作业优劣的关键标准,但目前的耕作深度控制方法存在精度不高、反应迟缓等诸多问题。本研究旨在开发一种结合拖拉机倾斜姿态的高精度 TD 监测模型,并研究拖拉机姿态倾斜和升降液压缸行程对 TD 的影响。开发了基于电液控制的 TD 稳定控制系统,并采用模型识别方法得出了精确的控制函数。采用模糊自适应 PID(FAPID)方法有效提高了电液系统的响应速度和抗干扰能力。然后构建了电液控制系统的协同仿真模型。在阶跃函数和正弦函数的激励下,FAPID 控制算法的上升时间缩短了 50%以上,位移跟踪误差也有效减小。为了验证其有效性,我们搭建了实验平台,然后对 TD 进行了现场测试试验。试验结果表明,在各种运行条件下,所开发的 TD 控制装置可有效降低 TD 标准偏差 0.302-0.464,降低 TD 变异系数 2.47%-2.92%。本文研究的 TD 在线监测和精确控制装置可有效提高耕作机械的质量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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