TY - JOUR
T1 - Research on a Novel Reliable MEMS Bistable Solid-State Switch
AU - He, Bo
AU - Lou, Wenzhong
AU - Feng, Hengzhen
AU - Zhao, Yuecen
N1 - Publisher Copyright:
© 2022, DESIDOC.
PY - 2022/7/1
Y1 - 2022/7/1
N2 - As a result of the unpredictable nature of extreme environments (including temperature, humidity, impact, and other factors), micro-electro-mechanical systems (MEMS) solid-state fuze control modules have an urgent requirement for a MEMS solid-state switch (MEMS-S3). In particular, this switch must remain stable without any energy input after a state transition (i.e., it must be bistable). In this paper, a MEMS bistable solid-state switch (MEMS-bS3) is designed that is based on the concept of producing a micro-explosion. The reliable state switching of the MEMS-bS3 is studied via heat conduction theory and verified via both simulations and experimental methods. The experimental results show that these switches can produce micro-explosions driven by 33 V/47 μF pulse energy. However, the metal film bridge (MFB) structures used in this switch with smaller dimensions (80×20 μm2, 90×30 μm2, and 100×40 μm2) could not enable the switch to realize a reliable state transition, and the state transition rate was less than 40%. When the MFB dimensions reached 120×60 μm2 or 130×70 μm2, the state transition rate exceeded 80%, and the response time was on the μs-scale.
AB - As a result of the unpredictable nature of extreme environments (including temperature, humidity, impact, and other factors), micro-electro-mechanical systems (MEMS) solid-state fuze control modules have an urgent requirement for a MEMS solid-state switch (MEMS-S3). In particular, this switch must remain stable without any energy input after a state transition (i.e., it must be bistable). In this paper, a MEMS bistable solid-state switch (MEMS-bS3) is designed that is based on the concept of producing a micro-explosion. The reliable state switching of the MEMS-bS3 is studied via heat conduction theory and verified via both simulations and experimental methods. The experimental results show that these switches can produce micro-explosions driven by 33 V/47 μF pulse energy. However, the metal film bridge (MFB) structures used in this switch with smaller dimensions (80×20 μm2, 90×30 μm2, and 100×40 μm2) could not enable the switch to realize a reliable state transition, and the state transition rate was less than 40%. When the MFB dimensions reached 120×60 μm2 or 130×70 μm2, the state transition rate exceeded 80%, and the response time was on the μs-scale.
KW - Experimental methods
KW - Heat conduction theory
KW - MEMS-bS,MEMS solid-state fuze, simulation
UR - http://www.scopus.com/inward/record.url?scp=85139001534&partnerID=8YFLogxK
U2 - 10.14429/dsj.72.17800
DO - 10.14429/dsj.72.17800
M3 - Article
AN - SCOPUS:85139001534
SN - 0011-748X
VL - 72
SP - 609
EP - 617
JO - Defence Science Journal
JF - Defence Science Journal
IS - 4
ER -