A novel MEMS inertial switch with a reinforcing rib structure and electrostatic power assist to prolong the contact time

A novel inertial micro-switch with polymer-metal composite fixed electrode has been designed based on non-silicon surface micromachining technology. The micro-switch can sense the applied accelerations from positive z-axis. It can realize a flexible contact between the electrodes, eliminate the bouncing phenomenon and prolong the contact time. The dynamic contact simulation of the micro-switch has been implemented under the half-sine wave shock with 80g peak value, and its vertical response time is about ~80μs.

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A laterally-driven micromachined inertial switch with a compliant cantilever beam as the stationary electrode for prolonging contact time

Journal of Micromechanics and Microengineering ◽

10.1088/0960-1317/24/6/065020 ◽

2014 ◽

Vol 24 (6) ◽

pp. 065020 ◽

Cited By ~ 9

Author(s):

Wenguo Chen ◽

Yan Wang ◽

Yongliang Wang ◽

Bin Zhu ◽

Guifu Ding ◽

...

Keyword(s):

Cantilever Beam ◽

Contact Time ◽

Stationary Electrode ◽

Inertial Switch

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The Design, Simulation and Fabrication of an Omnidirectional Inertial Switch with Rectangular Suspension Spring

Micromachines ◽

10.3390/mi12040440 ◽

2021 ◽

Vol 12 (4) ◽

pp. 440

Author(s):

Wenguo Chen ◽

Rui Wang ◽

Huiying Wang ◽

Shulei Sun

Keyword(s):

Dynamic Response ◽

Contact Time ◽

Horizontal Direction ◽

Suspension Spring ◽

Threshold Distribution ◽

Spring Suspension ◽

Coupling Stiffness ◽

Inertial Switch ◽

High Consistency ◽

Sensitive Direction

An omnidirectional inertial switch with rectangular spring is proposed in this paper, and the prototype has been fabricated by surface micromachining technology. To evaluate the threshold consistency and stability of omnidirectional inertia switch, the stiffness of rectangular suspension springs is analyzed. The simulation result shows that the coupling stiffness of the rectangular spring suspension system in the non-sensitive direction is a little more than that in the sensitive direction, which indicated that the omnidirectional switching system’s stability is reinforced, attributed to the design of rectangular springs. The dynamic response simulation shows that the threshold of the omnidirectional inertial switch using the rectangular suspension spring has high consistency in the horizontal direction. The prototype of an inertial switch is fabricated and tested successfully. The testing results indicate even threshold distribution in the horizontal direction. The threshold acceleration of the designed inertial switch is about 58 g in the X direction and 37 g in the Z direction; the contact time is about 18 μs.

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Simulation and Experiment of a MEMS Omnidirectional Inertial Switch

Volume 10: Micro- and Nano-Systems Engineering and Packaging ◽

10.1115/imece2014-39737 ◽

2014 ◽

Author(s):

Y. Cao ◽

J. Wang ◽

Z. W. Xi ◽

W. R. Nie ◽

X. J. Wang ◽

...

Keyword(s):

Contact Time ◽

Threshold Value ◽

Shock Acceleration ◽

Test Device ◽

Fe Method ◽

Shock Test ◽

Simulation And Experiment ◽

Spring System ◽

Inertial Switch ◽

Mass Spring

A MEMS omnidirectional inertial switch was designed and fabricated based on non-silicon surface micromachining technology. The switch consists of mass-spring system, flexible radial electrodes and axial electrode. It has omnidirectional sensitivities in a half sphere. The modal analysis of the switch was performed. The system stiffness of the mass-spring system and the response displacement of the mass in all directions under the applied shock acceleration of 450g was obtained by using the FE method, as a result, the switch has good omnidirectional performance and small distributed threshold acceleration. The fabricated switches were tested by a shock test device. The results show that the threshold acceleration of the switches is within the range of 270g to 450g. As an acceleration exceeding the threshold value acting along the X-axis or Z-axis, the switch can be reliably closed and have a long contact time.

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Analysis of Closure Characteristics of a MEMS Omnidirectional Inertial Switch under Shock Loads

Shock and Vibration ◽

10.1155/2015/604047 ◽

2015 ◽

Vol 2015 ◽

pp. 1-10 ◽

Cited By ~ 1

Author(s):

Yun Cao ◽

Zhanwen Xi ◽

Jiong Wang ◽

Weirong Nie

Keyword(s):

Contact Time ◽

Theoretical Method ◽

Dynamic Contact ◽

Shock Acceleration ◽

Fe Method ◽

Prolonged Contact ◽

Spring System ◽

Inertial Switch ◽

Mass Spring ◽

Theoretical Results

A preliminary theoretical method for calculating contact time of a dual mass-spring system applied to shock acceleration was proposed based on the MEMS omnidirectional inertial switch. The influence of relevant parameters on the contact time was analyzed, and the theoretical results were in agreement with the simulation predictions. The theoretical method could provide the design of MEMS inertial switch for prolonged contact time. The system stiffness of the mass-spring system in all directions was obtained by using the FE method. Dynamic contact simulation results of contact time in typical directions under the applied shock acceleration indicate that the switch has a contact time within the range of 33 μs to 95 μs and has an enhanced contact effect with the dual mass-spring system in the MEMS inertial switch. The fabricated switches were tested by a shock test device. The results show that the switch can be reliably closed in all directions under the applied shock acceleration and has a long contact time, which is basically in accordance with the theoretical results.

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The Analysis of the Influence of Threshold on the Dynamic Contact Process of a Fabricated Vertically Driven MEMS Inertial Switch

Micromachines ◽

10.3390/mi10110791 ◽

2019 ◽

Vol 10 (11) ◽

pp. 791

Author(s):

Wenguo Chen ◽

Rui Wang ◽

Huiying Wang ◽

Dejian Kong ◽

Shulei Sun

Keyword(s):

Response Time ◽

Contact Time ◽

Contact Process ◽

Dynamic Contact ◽

Simply Supported Beam ◽

Simply Supported ◽

Analytical Simulation ◽

Fixed Electrode ◽

Inertial Switch ◽

G Value

In this work, to evaluate the influence of the threshold on the dynamic contact process, five models (number 1, 2, 3, 4, 5) with different thresholds were proposed and fabricated with surface micromachining technology. The contact time and response time were used to characterize the dynamic contact performance. The dynamic contact processes of the inertial switches with gradually increasing thresholds were researched using analytical, simulation, and experimental methods. The basic working principle analysis of the inertial switch shows that the contact time of the inertial switch with a low-g value can be extended by using a simply supported beam as the fixed electrode, but the high-G inertial needs more elasticity for fixed electrode. The simulation results indicate that the response time and contact time decrease with the increment in the designed threshold. Prototypes were tested using a dropping hammer system, and the test result indicates that the contact time of the inertial switch with a fixed electrode of the simply supported beam is about 15 and 5 μs when the threshold is about 280 and 580 g, respectively. Meanwhile, the contact time can be extended to 100 μs for the inertial switch using a spring as the fixed electrode when the threshold is about 280 and 580 g. These test results not only prove that the spring fixed electrode can effectively extend the contact time, but also prove that the style of the fixed electrode is the deciding factor affecting the contact time of the high-G inertial switch.

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