青贮机铁磁性金属异物智能检测报警系统

doi:10.12133/j.smartag.SA202306010

摘要/Abstract

摘要：

目的/意义 青贮机作业时，田间遗落的铁丝等铁磁性金属异物如果混入其喂入系统，将会对青贮机的关键零部件和牲畜脏器造成严重损伤。为了确保青贮机在田间作业时能准确、高效地检测出金属异物，本研究开发了一套性能优良的金属探测系统。方法首先分析了青贮机金属检测原理，然后对平面螺旋线圈与圆柱线圈进行了仿真计算，选择平面螺旋线圈作为研究对象，通过使用非支配排序遗传算法（Nondominated Sorting Genetic Algorithm-II, NSGA-II）结合有限元仿真分析的方式，确定了线圈的线径、内径、外径、层数以及频率，并对弯曲线圈与未弯曲线圈以及阵列线圈进行了仿真计算。最后进行了系统集成，搭建了青贮机模拟试验台进行了模拟试验。 结果和讨论 仿真分析结果显示，平面螺旋线圈磁通密度模变化范围明显大于圆柱线圈，且其电感灵敏度、电阻灵敏度和被测物涡流损耗要明显高于圆柱线圈；另一方面，平面线圈弯曲后电感灵敏度、电阻灵敏度大幅度提高，有利于增强探测线圈的响应度。通过模拟台架试验，验证了该金属探测系统在探测距离小于70 mm，对直径0.6 mm、长度20 mm铁丝报警率达到100%，且经过计算，系统响应时间为0.105 0 s，小于安全运输时间，系统可以在金属物到达切碎系统前及时停止。结论本研究设计出了一套青贮机金属异物探测系统，提出了一套金属探测线圈的优化方法，并开发了相应的金属探测软硬件系统，通过试验验证了金属探测系统的功能，为青贮机安全运行提供了有力技术支撑。

关键词: 青贮机, 金属探测系统, 电磁感应, 平面螺旋线圈, 非支配排序遗传算法, 有限元仿真

Abstract:

Objective During the operation of the silage machine, the inclusion of ferrous metal foreign objects such as stray iron wires can inflict severe damage to the machine's critical components and livestock organs. To safeguard against that, a metal detection system with superior performance was developed in this research to enable precise and efficient identification of metal foreign bodies during field operations, ensuring the integrity of the silage process and the well-being of the animals. Methods The ferrous metal detection principle of silage machine was firstly analyzed. The detection coil is the probe of the metal detection system. After being connected in parallel with a capacitor, it is connected to the detection module. The detection coil received the alternating signal generated by the detection module to generate an alternating magnetic field. After the metal object entered the magnetic field, it affects the equivalent resistance and equivalent inductance of the detection coil. The detection module detected the change of the equivalent resistance and equivalent inductance, and then transmited the signal to the control module through the serial peripheral interface (SPI). The control module filtered the signal and transmited it to the display terminal through the serial port. The display terminal could set the threshold. When the data exceeded the threshold, the system performed sound and light alarm and other processing. Hardware part of the metal detection system of silage machine were firstly design. The calculation of the planar spiral coil and the cylindrical coil was carried out and the planar spiral coil was selected as the research object. By using the nondominated sorting genetic algorithm-Ⅱ (NSGA-II) combined with the method of finite element simulation analysis, the wire diameter, inner diameter, outer diameter, layer number and frequency of the coil were determined, and the calculation of the bent coil and the unbent coil and the array coil was carried out. The hardware system was integrated. The software system for the metal detection system was also designed, utilizing an STM32 microcontroller as the control module and LabView for writing the primary program on the upper computer. The system continuously displayed the read data and time-equivalent impedance graph in real-time, allowing for the setting of upper and lower alarm thresholds. When a metal foreign object was detected, the warning light turned red and an alarm sound was emitted, causing the feed roll to stop. To simulate the scenario of metal detection during the operation of a silage machine, a test bench was set up to validate the performance of the metal detection system. Results and Discussions The test results of the metal detection function showed that for a metal wire with a diameter of 0.6 mm and a length of 20 mm, as the inner diameter of the detection coil increased, the maximum alarm distance increased first and then decreased. The maximum alarm distance occured when the inner diameter was 35 mm, which was consistent with the optimization result. The maximum alarm distance was the largest when the detection coil was two layers, and there was no data readout when it was three layers. Therefore, the optimal thickness of the detection coil for this metal detection system was two layers. When the detection distance was greater than 80 mm, the alarm rate began to decrease, and the detection effect was weakened. When the detection distance was within 70 mm, the metal detection system could achieve a 100% alarm rate. The test results of the system response time showed that the average system response time was 0.105 0 s, which was less than the safe transportation time of 0.202 0 s. The system can give an alarm before the metal foreign object reaches the cutter, so the system is safe and effective. Conclusion In this study, a metal detection system for silage machines was designed. A set of optimization methods for metal detection coils was proposed, and the corresponding metal detection software and hardware systems were developed, and the functions of the metal detection system were verified through experiments, which could provide strong technical support for the safe operation of silage machines.

Key words: silage machine, ferrous metal detection system, electromagnetic induction, planar spiral coil, non-dominated sorting genetic algorithm, finite element simulation

张庆, 李洋, 尤泳, 王德成, 惠云婷. 青贮机铁磁性金属异物智能检测报警系统[J]. 智慧农业(中英文), 2024, 6(1): 111-122.

ZHANG Qing, LI Yang, YOU Yong, WANG Decheng, HUI Yunting. Intelligent Detection and Alarm System for Ferrous Metal Foreign Objects in Silage Machines[J]. Smart Agriculture, 2024, 6(1): 111-122.

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线圈层数	Q值	电感灵敏度	电阻灵敏度	涡流损耗/W	等效阻抗/kΩ
1层	12.21	3.59	5.74	37.60	19.44
2层	17.01	3.57	7.49	9.39	27.08
3层	17.07	3.55	7.91	4.17	27.17
4层	15.64	3.53	7.20	2.34	24.89
5层	14.00	3.52	6.40	1.49	22.28

线圈类别	电感/uH	电阻/Ω	Q值	电感灵敏度	电阻灵敏度	涡流损耗/W
未弯曲线圈	9 881.874 3	22.694 6	437.739 6	5.352 9×10^-5	0.000 741 5	2.594 2×10^-9
弯曲线圈	9 410.466 1	22.687 0	416.997 8	1.415 1×10^-3	0.135 898 0	1.658 7×10^-9

线圈类型	电感L	电阻R	Q值
线圈1	92.18	22.40	41.31
线圈2	90.68	22.34	40.80
线圈3	92.18	22.21	41.73
单个线圈	98.82	22.69	43.77