Frequency response analysis of mechanoluminescence in ZnS:Cu for non-contact torque sensors

Frequency response analysis of mechanoluminescence in ZnS:Cu for non-contact torque sensors

•The ML enables to measure the dynamic torque in rotating shaft.•Experimental frequency response analysis of ML in ZnS:Cu is presented.•This study provides essential design information for non-contact torque sensors. This paper presents an experimental frequency response analysis of inverse mechanol...

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Veröffentlicht in:Sensors and actuators. A. Physical. 2016-04, Vol.240, p.23-30
Hauptverfasser: Gi-Woo, Kim, Min-Young, Cho, Ji-Sik, Kim
Format: Artikel
Sprache:eng
Schlagworte:
Dynamic tests
Dynamics
Frequency response
Frequency response analysis
Heuristic
Hysteresis
Inverse
Inverse mechanoluminescence (ML)
Loading rate-dependent hysteresis
Mechanoluminescence
Torque
ZnS:Cu microparticles
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Min-Young, Cho
Ji-Sik, Kim
description •The ML enables to measure the dynamic torque in rotating shaft.•Experimental frequency response analysis of ML in ZnS:Cu is presented.•This study provides essential design information for non-contact torque sensors. This paper presents an experimental frequency response analysis of inverse mechanoluminescence (ML) under dynamic cyclic torque excitation in copper doped zinc sulfide (ZnS:Cu) microparticle. The loading rate-dependent hysteresis of the inverse ML, caused by the phosphorescence quenching of ZnS:Cu in response to dynamic cyclic torsional loading, was first compensated for frequency response analysis using the simple heuristic compensation law according to an ad-hoc heuristic hysteresis model. This model characterizes the inverse ML intensity as a function of the rate of the applied torque input. Precision sinusoidal torque waveforms with frequencies ranging from 0.5 to 15Hz were employed to identify the frequency response functions (FRFs). By estimating the FRFs, we obtained essential design information that indicates the potential of ML for applications in non-contact torque measurement systems.
doi_str_mv 10.1016/j.sna.2016.01.039
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This paper presents an experimental frequency response analysis of inverse mechanoluminescence (ML) under dynamic cyclic torque excitation in copper doped zinc sulfide (ZnS:Cu) microparticle. The loading rate-dependent hysteresis of the inverse ML, caused by the phosphorescence quenching of ZnS:Cu in response to dynamic cyclic torsional loading, was first compensated for frequency response analysis using the simple heuristic compensation law according to an ad-hoc heuristic hysteresis model. This model characterizes the inverse ML intensity as a function of the rate of the applied torque input. Precision sinusoidal torque waveforms with frequencies ranging from 0.5 to 15Hz were employed to identify the frequency response functions (FRFs). 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subjects Dynamic tests
Dynamics
Frequency response
Frequency response analysis
Heuristic
Hysteresis
Inverse
Inverse mechanoluminescence (ML)
Loading rate-dependent hysteresis
Mechanoluminescence
Torque
ZnS:Cu microparticles
title Frequency response analysis of mechanoluminescence in ZnS:Cu for non-contact torque sensors
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