MEMS Inertial Switch for Military Applications

Lee, Hyo-Nam; Jang, Seung-gyo; Lee, Sungryeol; Lee, Jeong-Sun; Hwang, Young-Suk

doi:10.3390/proceedings1040343

Cited by 7 publications

(5 citation statements)

References 6 publications

(7 reference statements)

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“…On the other, low-g inertial switches, widely used in the aviation and automotive industries, have acceleration responses ranging from several milli g to hundreds of g. Based on a feasibility study, Lior et al [84] proposed an idea of using a pair of bistable beams to suspend the proof mass and to sense the acceleration, in which the switch can be closed under sub-g inertias. Nam Lee et al [85] have developed an inertial switch with a threshold acceleration of no more than 10 g, and it can withstand unexpected shocks of up to 1000 g, making it suitable for harsh military environments. Rigid electrodes of MEMS switches have the problems of short contact time and signal bounce.…”

Section: Passive Inertial Switchesmentioning

confidence: 99%

“…Based on a feasibility study, Lior et al [ 84 ] proposed an idea of using a pair of bistable beams to suspend the proof mass and to sense the acceleration, in which the switch can be closed under sub- g inertias. Nam Lee et al [ 85 ] have developed an inertial switch with a threshold acceleration of no more than 10 g , and it can withstand unexpected shocks of up to 1000 g , making it suitable for harsh military environments.…”

Section: Classification Of Mems Switches Based On Driving Principlmentioning

confidence: 99%

See 1 more Smart Citation

Research Status and Development Trend of MEMS Switches: A Review

Cao

Zhao

2020

Micromachines

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MEMS switch is a movable device manufactured by means of semiconductor technology, possessing many incomparable advantages such as a small volume, low power consumption, high integration, etc. This paper reviews recent research of MEMS switches, pointing out the important performance indexes and systematically summarizing the classification according to driving principles. Then, a comparative study of current MEMS switches stressing their strengths and drawbacks is presented, based on performance requirements such as driven voltage, power consumption, and reliability. The efforts of teams to optimize MEMS switches are introduced and the applications of switches with different driving principles are also briefly reviewed. Furthermore, the development trend of MEMS switch and the research gaps are discussed. Finally, a summary and forecast about MEMS switches is given with the aim of providing a reference for future research in this domain.

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Section: Passive Inertial Switchesmentioning

confidence: 99%

Section: Classification Of Mems Switches Based On Driving Principlmentioning

confidence: 99%

Research Status and Development Trend of MEMS Switches: A Review

Cao

Zhao

2020

Micromachines

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“…The inertial switch is turned on when the missile is subjected to an acceleration at or above a predetermined threshold level. Lee et al [25] reported a MEMS switch that is applicable to the safe-and-arm device of a rocket motor ignition system for cold launched missiles. The main goal of the work is to realize a MEMS inertial switch, which can be triggered at a low-g level (about 10g) in the sensitive direction.…”

Section: Military Applicationmentioning

confidence: 99%

“…Therefore, micromachined inertial switches are designed for variety of different threshold levels, which can be applied to various applications. We can classify two main categories according to the threshold levels [23][24][25][26]: the relatively high-g (i.e. 100 g, 1000 g) switch and the low-g switch (i.e.…”

Section: Key Performance Parameters Of Micromachined Inertial Switchesmentioning

confidence: 99%

Micromachined threshold inertial switches: a review

Younis

2022

J. Micromech. Microeng.

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This paper presents a review of the recent advances on micromachined inertial switches/triggers. The review focuses on their advantages and disadvantages, sensitive directions, mechanisms of contact-enhancement, threshold accuracy, and the tunability of the acceleration threshold. Several applications of these sensors are highlighted including in healthcare, structural health monitoring, internet of things (IoT), and military. Recent contemporary research directions are also discussed, such as multi-directions/axis, multi-threshold sensors, and machine learning implementation. The article concludes with discussion on future development trends and performance improvements of inertial switches.

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“…The inertial impact switch is widely used as the priming control unit in fuze field. In the electromechanical trigger fuze, the inertia switch is used to control the working state of the first generation explosive element while it is used for the fuse proximity failure and landing backup firing in the shell radio fuze [1][2][3]. Due to the complex heat treatment process of materials, spring wire diameter , structural design as well as the adverse ballistic environment, most switches failure within the threshold range [4].…”

Section: Introductionmentioning

confidence: 99%

An Improving Model on Contact Time of The Inertial Impact Switch

Liang,

Liu,

Wang

et al. 2023

HSET

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Inertial impact switch is a widely used inertial force recognition element in electromechanical trigger fuze of missiles, rockets and artillery shells. In this paper, the impact responses of inertial switch are investigated with abundant acceleration loads through the dynamics analysis. Based on the Machete hammer experiment, the accuracy of the dynamics model is verified with a very small error. The systematic dynamic analysis shows that the contact time of impact proceeding keeps continuously increasing with greater pulse width and acceleration load. On the other hand, the threshold of switch decreases alone with the pulse time. To improve the performance index of the inertial impact switch, a spherical structure model is proposed. Surprisingly, a significant improvement of the contact time is discovered comparing with the cylindrical structural model. The proposed new structure will provide important technical reference for the practical application of devices in fuze technology field.

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MEMS Inertial Switch for Military Applications

Cited by 7 publications

References 6 publications

Research Status and Development Trend of MEMS Switches: A Review

Research Status and Development Trend of MEMS Switches: A Review

Micromachined threshold inertial switches: a review

An Improving Model on Contact Time of The Inertial Impact Switch

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