Effect of Change of Reluctance Launcher Parameters on Projectile Velocity

Sari, Vekil

doi:10.1109/access.2023.3307016

Cited by 4 publications

(1 citation statement)

References 32 publications

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“…The magnitude and direction of the magnetic field and the size of the projectile to be used affect the value of the electromagnetic force. In addition, in a paper in the literature (Sari, 2023), a proposal is presented to increase the system efficiency by modifying the projectile starting position and size. In another study (Su et al, 2021), the effect of coil positions and distance between coils on the system efficiency of a launcher with multiple accelerator coils arranged in series is evaluated.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Area Defense: Magnetic Launcher and Sensor Integration

Kırıkcı,

Kahveci,

Akyazı

2024

Karadeniz Fen Bilimleri Dergisi

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In this article, the most appropriate design method for a field defense system that operates with magnetic field laws by taking audio and video signals as reference is described. The study is important because it eliminates the operator (soldier) factor in the battlefield. Taking into account the effect of capacitor voltage, capacitance value and accelerator winding inductance value, the main criteria for determining the power supply and armature structure of the electromagnetic launcher are proposed. This proposal is made with MATLAB/Simulink software based mathematical model and the differences are explained by comparing with ANSYS Maxwell simulation. The simulated results show that the speed difference between the models is 7%. Additionally, the design methods of the audio and video-based positioning systems that control the system are explained in the study. In this system where signal receiving microphones are positioned in triangular form, a linear algorithm using the time difference method is utilized. By comparing the theoretical mathematical model with the experimental simulation model, the accuracy of the method and the method function is proved. In this study, a deep learning-based target detection system that operates with the YOLO v2 algorithm is used to increase the system's mission execution capacity. The operator is eliminated by switching the system with the signal received from the positioning systems.

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Section: Introductionmentioning

confidence: 99%

Enhanced Area Defense: Magnetic Launcher and Sensor Integration

Kırıkcı,

Kahveci,

Akyazı

2024

Karadeniz Fen Bilimleri Dergisi

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Performance Analysis of Reluctance Coil Launchers Driven by Distributed Feeder Circuit

Lu,

Yi,

Yuan

et al. 2024

IEEE Access

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Reluctance coil launchers usually use a pulse current formed by capacitive discharge to excite the excitation coil when launching. The pulse current peaks are high, and the projectile usually undergoes deep magnetic saturation, resulting in low launching efficiency. To address this problem, this article proposes using distributed feeder circuit to drive reluctance coil launchers, replacing the traditional single set of large-capacity capacitor discharge scheme with multiple small-capacity capacitors discharged in a time-sequential manner, so as to reduce the peak current and suppress magnetic saturation problems. The study includes two main aspects, one is to study the effect of the driving method on the launch performance and analyze the reasons; the other is to propose the calculation of the time-varying data in the launch process by the time-segmented calculation method. The efficiency of the model described in the paper is only 1.301% when using a single high-capacity capacitor for launching, while the launching efficiency is increased to 3.535% when driven by the distributed feeder circuit, indicating that the method can effectively improve the launching performance.INDEX TERMS Reluctance coil launcher, magnetic saturation, distributed feeder circuit, flat-topped wave current, time-segmented calculation method.

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