Abstract
This paper proposes an electric field microsensor (EFM) with mutual shielding electrodes. Based on the charge-induction principle, the EFM consists of fixed electrodes and piezoelectric-driving vertically-movable electrodes. All the fixed electrodes and movable electrodes work as both sensing electrodes and shielding electrodes. In other words, all the fixed and movable electrodes are sensing electrodes, and they are mutually shielding electrodes simultaneously. The movable electrodes are driven to periodically modulate the electric field distribution at themselves and the fixed electrodes, and the induced currents from both movable and fixed electrodes are generated simultaneously. The electrode structure adopts an interdigital structure, and the EFM has been simulated by finite element methods. Simulation results show that, since the sensing area of this EFM is doubled, the variation of induced charge is twice, and therefore the output signal of the sensor is increased. The piezoelectric material, lead zirconate titanate (PZT), is prepared by the sol–gel method, and the microsensor chip is fabricated.
Highlights
Electric field sensors (EFSs) have a wide range of applications in many fields [1,2,3,4,5,6,7,8,9,10,11], such as aerospace, meteorology, power systems, etc
The size of the electrode width and gap will affect the number of mutual shielding electrode groups in a certain area
When the electrode width or the electrode gap decreases, the number of mutual shielding electrode groups increases in a certain area
Summary
Electric field sensors (EFSs) have a wide range of applications in many fields [1,2,3,4,5,6,7,8,9,10,11], such as aerospace, meteorology, power systems, etc. The value of the electric field strength is listed as one of the important conditions for the launch of a spacecraft. EFSs are used to monitor the atmospheric electric field before the flight to ensure the safety of the spacecraft during launch. In the field of meteorology [4,5,6,7], different weather conditions have different corresponding atmospheric electric field values. EFSs can be used to analyze the changing characteristics and laws of the atmospheric electric field under different weather to realize the monitoring and warning of lightning weather. EFSs can be applied to insulator defect detection [9], icing thickness detection on the surface of transmission lines [10], and electromagnetic environment detection around power systems [11], etc
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