Design of an Intelligent MEMS Safety and Arming Device with a Condition Feedback Function

Wang, K.; Hu, Te; Zhao, Yulong; Ren, Wang; Wang, Yifei

doi:10.3390/mi14061130

Cited by 1 publication

(1 citation statement)

References 17 publications

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“…Fuze is the ultimate actuator for weapon systems to exert terminal damage effects, and its safety and reliability directly determine the success or failure of weapons [ 1 , 2 , 3 , 4 ]. An essential field of microelectromechanical systems (MEMS)’s application in fuze is MEMS safety and arming (S&A) devices [ 5 , 6 , 7 , 8 , 9 ]. MEMS S&A devices are significant components of fuze, and their sensitivity to the environment determines the reliability of the fuze function [ 10 , 11 ].…”

Section: Introductionmentioning

confidence: 99%

Simulation Methods for MEMS S&A Devices for 2D Fuze Overload Loading

Wu,

Zhang,

Sun

et al. 2023

Micromachines

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An experimental testing system for the two-dimensional (2D) fuze overload loading process was designed to address the loading issues of recoil overload and centrifugal overload in fuze safety and arming (S&A) device. By incorporating centrifuge rotation energy storage, impact acceleration simulation, and equivalent centrifugal rotation simulation, a block equipped with a fuze S&A device accelerated instantly upon having impact from a centrifuge-driven impact hammer, simulating recoil overload loading. The impact hammer was retracted instantaneously by adopting an electromagnetic brake, which resulted in the centrifugal rotation of the block around its track, to simulate the centrifugal overload loading. The dynamic equations of the experimental testing system and the equations of impact hammer motions were established, whereby the rotation speed of the centrifuge and the braking force of the electromagnetic brake were calculated and selected. A dynamic model of the collision between the impact hammer and block was established using ANSYS/LS-DYNA software for simulation analysis. The acceleration curves of the recoil overload and centrifugal overload with variations in the centrifuge speed, cushion material, and buffer thickness were obtained, which verified the feasibility of the proposed loading simulation method. Two-dimensional overload loading simulation tests were performed using the developed experimental testing system, and the acceleration curves of the recoil overload and centrifugal overload were measured. The test results indicated that the proposed system can accomplish 2D overload loading simulations for a recoil overload of several 10,000× g and centrifugal overload of several 1000× g.

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