高精度推力测量系统的设计与研制

Muzamil Ali, Muhammad Dawood Bashir, G. Hussain, R. Ullah, M. Faisal
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引用次数: 0

摘要

科学技术应用的一个基本步骤是测量这些应用中涉及的物理量。然而,这些物理量的测量并不总是微不足道的。在美国国家航空航天局(NASA)等科技巨头未来太空探索任务的飞向卫星校准、微等离子体推进器等需要非常精确的姿态和位置控制的应用中,测量是需要解决的关键问题。其中一个应用是低成本的推力测量系统。本文介绍了利用光干涉原理成功测量20 μN以下推力的系统的设计和研制。短持续时间的微牛顿脉冲是用设置在钟摆尖端的电磁推力器施加的。摆随后进行振荡,然后用光学干涉仪精确测量摆的偏转。然后校准最大挠度以获得施加的推力。根据摆头最大挠度的最优几何参数设计摆头,使推力响应持续100毫秒。为了实验验证,在高分辨率示波器上获得干扰信号,然后对其进行处理,得到摆的精确挠度,从而得到精确推力。该装置成功地测量了18.44 μN的最小推力。精度受到环境条件的限制,而不是设备本身的限制。
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Design and Development of a High Precision Thrust Measurement System
One of the fundamental steps in the applications of science and technology is the measurement of physical quantities involved in those applications. The measurement of these physical quantities is, however, not always trivial. In the applications such as the calibration of femto-satellites, and micro-plasma thrusters for future space exploration missions of NASA and other technological giants, where very precise attitude and position control is required, the measurement is a key issue to be addressed. One of such applications is a low-cost thrust measurement system. This paper presents the design and development of such a system, capable of successfully measuring the thrust of magnitude less than 20 μN by utilizing the principles of optical interference. The micro newtons pulse of a short duration is applied using an electromagnetic thruster setup on the tip of a pendulum. The pendulum subsequently performs the oscillations, and then an optical interferometer is used to precisely measure the deflection of the pendulum. The maximum deflection is then calibrated to obtain the applied thrust. The pendulum is designed based on optimal geometric parameters for maximum deflection of the pendulum tip for a response of thrust lasting for 100 milliseconds. For experimental validation, the interference signal is obtained in high resolution oscilloscope, which is subsequently processed to find the precise deflection of the pendulum and thus the precise thrust. The device successfully measures a minimum thrust of 18.44 μN. The precision is restricted due to environmental conditions and is not the limitation of the device itself.
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