Absolute Position Detection in 7-Phase Sensorless Electric Stepper Motor

2022 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) Pub Date : 2022-10-23 DOI:10.1109/IROS47612.2022.9981190

V. Groenhuis, Gijs Rolff, Koen Bosman, L. Abelmann, S. Stramigioli

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Abstract

Absolute position detection in sensorless electric stepper motors potentially allows for higher space efficiency, improved shock resistance, simplified installation, reduced number of parts and lowered cost. A prototype is demonstrated measuring 42 × 42 × 34 mm3 with seven coils arranged in a star configuration. The rotor is ϕ 25.8 × 12.5 mm2 and has 51 teeth which are irregularly spaced. At the driver side, the coil currents are measured during motion in order to reconstruct the absolute position of the motor. Calibration and smoothing techniques are used to reduce systematic and stochastic measurement errors, respectively. The motor is able to detect and correct its position after externally-induced stalls at the tested motor speeds from 40 rpm to 108 rpm. The holding torque is 0.23 N m at an armature current of 1 A; on average the torque is 7% lower than that of a reference bipolar stepper motor with the same dimensions. The results show that dynamic position sensing and correction are possible for a range of velocities, but not at standstill. The driver requires seven current sensors and sufficient computational power, and proper calibration of motor intrinsics is required beforehand. The presented technology could make existing 3-D printers and other machines with open-loop stepper motors more robust and increase the range of operating speeds and accelerations, without the adverse side-effects of increased complexity and cost associated with dedicated position sensors.

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7相无传感器步进电机的绝对位置检测

无传感器电动步进电机的绝对位置检测可能会提高空间效率，提高抗震性，简化安装，减少零件数量并降低成本。演示了一个尺寸为42 × 42 × 34 mm3的原型，其中七个线圈排列成星形结构。转子的φ为25.8 × 12.5 mm2，有51个不规则间距的齿。在驱动端，在运动过程中测量线圈电流，以重建电机的绝对位置。校准和平滑技术分别用于减少系统和随机测量误差。在测试的电机转速从40转/分到108转/分的情况下，电机能够在外部引起的失速后检测并纠正其位置。在电枢电流为1a时，保持转矩为0.23 N m;平均扭矩比具有相同尺寸的参考双极步进电机低7%。结果表明，在一定的速度范围内，动态位置传感和校正是可能的，但在静止状态下则不行。该驱动器需要7个电流传感器和足够的计算能力，并且需要事先对电机的特性进行适当的校准。该技术可以使现有的3d打印机和其他带有开环步进电机的机器更加坚固，并增加运行速度和加速度的范围，而不会产生与专用位置传感器相关的复杂性和成本增加的不利副作用。

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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来源期刊

2022 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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