一种高速直线电机定位测速系统硬件在环仿真

doi:10.19595/j.cnki.1000-6753.tces.L10010

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摘要高精度高实时性的定位测速系统对高速直线电机的稳定运行至关重要。为验证基于激光阵列的定位测速系统对高速直线电机控制系统的适用性,该文首先分析了激光阵列式编码器的工作原理,推导了定位测速系统参数设计的约束条件。其次建立了编码器及激光传感器阵列的数学模型,根据给定的位置信息产生脉冲信号驱动激光器,以模拟传感器在不同速度下产生的光脉冲信号,根据检测的光脉冲信号来计算动子位置和速度。最后基于所研制采集器、脉冲发生器、多通道模拟器及控制器,构建了一套定位测速硬件在环仿真系统。通过对比给定的位置/速度与检测到的位置/速度的数据结果,量化测量误差。通过与电机控制系统的硬件在环闭环系统联合仿真,验证了该方法的有效性,且能够为位置与速度检测算法的改进与仿真验证提供良好的测试平台。

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关键词 ：高速直线电机, 定位测速, 硬件在环仿真

Abstract：For the high-speed linear motor, the stability of control is very sensitive to speed measurement errors, so high-precision and real-time position and speed measurement system is crucial for the stable operation of high-speed linear motors. The current position and speed measurement methods applied to maglev trains and electromagnetic catapults can only meet the requirements of position and speed detection at speeds below 600 km/h. However,it is not yet clear for speeds above 1 000 km/h with these methods. Optical encoders have the advantages of fast response frequency and high measurement accuracy, and are widely used for position and speed measurement for rotating motors. Its applications in linear electric fields are mainly concentrated in the field of small machining machines. In the field of large-scale linear motor applications, the operating environment of the system is complex, and lasers are prone to interference. Therefore, there is still limited research on the application of optoelectronic encoders in this field. In this paper, a laser array-based position and speed measurement system for high-speed linear motor control systems is proposed. By closed-loop joint hardware-in-the-loop simulation with motor control system, it accurately measures the position and speed of the rotator and the motor system operates well in the high-speed section.
Firstly, according to the mathematical model of a high-speed linear motor, the normalized thrust F_e/F_emax of the motor was calculated as a function of the speed measurement error δ at different speeds. Then, the impact of grating ruler vibration and yaw on speed measurement error is analyzed. The constraints condition for grating ruler and sensor spot diameter is derived. The position and speed measurement algorithm are given. In order to realize high precision speed measurement in all speed range, traditional T method and tracking differentiator are used.
Secondly, a hardware-in-the-loop simulation system for position and speed measurement was constructed based on the developed collector, pulse generator, multi-channel simulator, and controller. A mathematical model of the encoder and laser sensor array was established in the pulse generator. Pulse signals were generated based on the given position information to drive the laser, simulating the optical pulse signals generated by the encoder at different speeds. Based on the detected optical pulse signals, the position and speed of the rotor were calculated. The measurement error is quantified by comparing the data results of the given position/speed with the detected position/speed. Finally, a closed-loop joint hardware-in-the-loop simulation was conducted with the motor control system.
The experiment shows that the pulse wave after filter is good and can meet the requirements of position and speed detection at highest design speed. Simulation results show that the speed measurement error is basically stable at 0.5 m/s, with a maximum value of 0.6 m/s in all speed range by comparing the reference speed and position curve and measurement results. The speed measurement error can meet the error requirements of the motor control system in the full speed range. From the closed-loop joint hardware-in-the-loop simulation, it can be seen that the motor operates stably and the thrust remains basically unchanged in the entire process.
The following conclusions can be drawn from the simulation analysis: The hardware-in-the-loop simulation system for position and speed measurement based on the developed distributed acquisition equipment, pulse generator, laser generator, multi-channel simulator, and system controller has a high degree of compatibility with the actual system. It can perform hardware-in-the-loop simulation experiments on different position and speed detection algorithms, extract and analyze simulation results data at any time to quantify speed measurement errors At the same time, hardware-in-the-loop simulation was conducted with the motor control system based on RT-LAB, verifying the effectiveness of the position and speed measurement system topology network and speed measurement algorithm. The system has high integration and strong applicability, which is beneficial for improving research on position and speed algorithms, fault detection and analysis methods, and redundant control strategy. It has high guiding significance and reference value for engineering practice.
Based on the constructed hardware-in-the-loop simulation system, the fault diagnosis and fault-tolerant control algorithms, speed sensorless control method for segmented linear induction motors will be researched in the future work.

Key words： High-speed linear motor position and speed measurement hardware-in-the-loop simulation

收稿日期: 2023-03-18

PACS:

TM341

基金资助:国家重点研发计划资助项目（2016YFB1200602-19）

通讯作者: 史黎明男,1964年生,研究员,博士生导师,研究方向为特种电机、直线电机控制等。E-mail：limings@mail.iee.ac.cn

作者简介: 范满义男,1988年生,助理研究员,研究方向为大功率无线电能传输、高速直线电机控制、感应电机无速度传感器控制等。E-mail：fanmanyi@mail.iee.ac.cn

引用本文:

范满义, 史黎明, 李子欣, 徐飞, 周世炯. 一种高速直线电机定位测速系统硬件在环仿真[J]. 电工技术学报, 2023, 38(zk1): 80-90. Fan Manyi, Shi Liming, Li Zixin, Xu Fei, Zhou Shijiong. A Hardware-in-the-Loop Simulation for Position and Speed Measurement System of High-Speed Linear Motor. Transactions of China Electrotechnical Society, 2023, 38(zk1): 80-90.

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