Design of A New Electromagnetic Launcher Based on the Magnetic Reluctance Control for the Propulsion of Aircraft-Mounted Microsatellites

IF 3.8 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS
Mohamed Magdy Mohamed Abdo, Haitham El-Hussieny, Tomoyuki Miyashita, Sabah M. Ahmed
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Abstract

Recent developments in electromagnetic launchers have created potential applications in transportation, space, and defense systems. However, the total efficiency of these launchers has yet to be fully realized and optimized. Therefore, this paper introduces a new design idea based on increasing the magnetic flux lines that facilitate high output velocity without adding any excess energy. This design facilitates obtaining a mathematical equation for the launcher inductance which is difficult to analytically represent. This modification raises the launcher efficiency to 36% higher than that of the ordinary launcher at low operating voltage. The proposed design has proven its superiority to traditional launchers, which are limited in their ability to accelerate microsatellites from the ground to low Earth orbit due to altitude and velocity constraints. Therefore, an aircraft is used as a flying launchpad to carry the launcher and bring it to the required height to launch. Meanwhile, it is demonstrated experimentally that magnetic dipoles in the projectile material allow the launcher coil’s magnetic field to accelerate the projectile. This system consists of the launcher coil that must be triggered with a high amplitude current from the high DC voltage capacitor bank. In addition, a microcontroller unit controls all processes, including the capacitor bank charging, triggering, and velocity measurement.
基于磁阻控制的新型机载微卫星电磁发射装置设计
电磁发射器的最新发展已经在运输、太空和国防系统中创造了潜在的应用。然而,这些发射器的总效率尚未得到充分实现和优化。因此,本文提出了一种新的设计思路,即在不增加多余能量的情况下增加磁通量线,从而提高输出速度。这种设计有助于获得难以解析表示的发射装置电感的数学方程。这种改进在低工作电压下将发射装置效率提高到比普通发射装置高36%。由于高度和速度的限制,传统的发射器在将微型卫星从地面加速到低地球轨道的能力上受到限制,所提出的设计已经证明了它的优越性。因此,一架飞机被用作飞行发射台,携带发射器并将其带到所需的高度进行发射。同时,实验证明了弹丸材料中的磁偶极子允许发射线圈的磁场加速弹丸。该系统由发射线圈组成,必须由高直流电压电容器组的高幅值电流触发。此外,微控制器单元控制所有过程,包括电容器组充电,触发和速度测量。
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
Applied System Innovation
Applied System Innovation Mathematics-Applied Mathematics
CiteScore
7.90
自引率
5.30%
发文量
102
审稿时长
11 weeks
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