韩豹, 杨亚楠, 王宏伟, 范伟. 苗间除草部件入土深度PID自动控制系统设计与台架试验[J]. 农业工程学报, 2018, 34(11): 68-77. DOI: 10.11975/j.issn.1002-6819.2018.11.009
    引用本文: 韩豹, 杨亚楠, 王宏伟, 范伟. 苗间除草部件入土深度PID自动控制系统设计与台架试验[J]. 农业工程学报, 2018, 34(11): 68-77. DOI: 10.11975/j.issn.1002-6819.2018.11.009
    Han Bao, Yang Ya'nan, Wang Hongwei, Fan Wei. Design of PID automatic control system for depth into earth of intra-row weeding components and its bench experiment[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2018, 34(11): 68-77. DOI: 10.11975/j.issn.1002-6819.2018.11.009
    Citation: Han Bao, Yang Ya'nan, Wang Hongwei, Fan Wei. Design of PID automatic control system for depth into earth of intra-row weeding components and its bench experiment[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2018, 34(11): 68-77. DOI: 10.11975/j.issn.1002-6819.2018.11.009

    苗间除草部件入土深度PID自动控制系统设计与台架试验

    Design of PID automatic control system for depth into earth of intra-row weeding components and its bench experiment

    • 摘要: 除草部件入土深度(松土深度)对苗间机械除草装置的作业性能有较大影响。为提高大豆苗间机械除草装置除草部件入土深度的稳定控制、降低伤苗率和埋苗率,该文提出了基于超声波测距的苗间机械除草部件入土深度控制方法。在梳齿式苗间机械除草装置研究基础上,设计了除草部件入土深度控制系统。建立了除草部件入土深度调节液压控制系统的数学模型,并对建立的传递函数在Matlab/Simulink中进行了仿真和PID校正。仿真结果表明:该系统采用PID控制算法对期望松土深度值进行跟踪调节,其稳态响应时间为0.48 s,静差为0.06~0.09 mm。在室内苗间除草台架上进行了超声测距动态试验与松土深度控制试验。超声测距试验表明:应用HC-SR04型超声波模块并结合设计的仿形台对地表进行动态测距不再受地表苗、草等影响,在0.278、0.556和0.833 m/s 3种行进速度下,针对各个样本点的位置与人工测量相比,二者平均对照误差分别为:4.95、5.36和5.90 mm,最大对照误差分别为:6.6、7.4和8.3 mm。除草部件入土深度控制台架试验表明:控制系统能够实现苗间机械除草作业松土深度的稳定控制,在土槽行进速度0.278 m/s时,松土深度可稳定控制在(30±8) mm范围内,满足苗间除草的深度控制要求。该研究为解决苗间除草部件松土深度稳定控制问题提供新思路和借鉴。

       

      Abstract: Abstract: Mechanical weeding is considered as an essential component in organic farming. It takes advantage of the features that crop seedlings have better developed root system whose distribution is broader and deeper than young weeds during intra-row mechanical weeding in farmland. According to above characteristics, young weeds between seedlings can be removed by claw-tooth and other mechanical components that loosen or move the intra-row topsoil. So, the claw-tooth loosening depth has great influence on mechanical weeding performance. However, existing intra-row mechanical weeders still have problem of poor working depth control due to their claw-tooth depth into earth controlled by the depth wheel walking between the crop rows. It is impossible for claw-tooth to be kept at stable loosening depth into earth during intra-row mechanical weeding, because of the variations in soil properties, including bulk density, moisture content and surface topography, which can lead to working depth variations. So the poor working depth control is one of the main reasons to high injury rate of seedlings and poor weeding effect during intra-row mechanical weeding. To improve depth control, an automatic control system, consisting of hydraulic system, regulating mechanism, ultrasonic distance measuring module, control unit and driving plate, was developed, which converts the difference between the desired spacing and the spacing measured by the ultrasonic distance measuring module into an input signal that is sent to the solenoid valve of hydraulic system. This will result in an extension or contraction movement of the hydraulic cylinder in the regulating mechanism, which changes the relative position of the weeding claw-tooth with respect to the soil surface and thus also its loosening depth and keeps the parts of soybean intra-raw mechanical weeding unit at a constant penetration depth. The aim of this work was to develop and evaluate the automatic control system based on ultrasonic distance measurement, which can be used to improve the working depth control of intra-row mechanical weeders. On the basis of research and development of comb-type intra-row weeding mechanism, an automatic control system for loosening depth of weeding parts was designed. A mathematical model of a hydraulic control system for the weeding parts' depth adjustment was established. Simulation and PID (proportion, integration, differentiation) emendation were carried out in MATLAB/Simulink based on the established transfer function. The simulation results showed that the steady-state response time was 0.48 s, and the static error range was 0.06-0.09 mm when the PID control algorithm was used to track control the desired loosening depth. And test and control test-bed research of the loosening depth for intra-row weeding parts based on the automatic control system were carried out. The experimental results of depth measurement showed that the control system was able to detect the depth in motion, and was not affected by the seedlings, grass and soil characteristics on the surface of the earth. At the working speed of 0.278, 0.556 and 0.833 m/s, the average contrast errors of measuring values were 4.95, 5.36 and 5.90 mm respectively, which were obtained by measurement with HC-SR04 ultrasonic module and manual measurement for the location of each sample point, and the maximum contrast errors were 6.6, 7.4 and 8.3 mm respectively. The experimental results of depth control showed that the stability control in loosening depth for weeding parts of intra-row mechanical weeding can be achieved. At the soil bin traveling speed of 0.278 m/s, the loosening depth variation of weeding parts could be controlled in the range of (30±8) mm, which could meet the deep control requirement of intra-row weeding. The research provides solution and idea to solve the problem of stable controlling in loosening depth of intra-row weeding parts, and also provides reference for research and development of soybean intra-row mechanical weeder with automatic control in depth and good working performance.

       

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