Development of wireless MEMS inclination sensor system for swing monitoring of large-scale hook structures

Yan Yu; Jinping Ou; Jun Zhang; Chunwei Zhang; Luyu Li

Development of wireless MEMS inclination sensor system for swing monitoring of large-scale hook structures

Yan Yu, Jinping Ou, Jun Zhang, Chunwei Zhang, Luyu Li

Research output: Contribution to journal › Article

82 Citations (Scopus)

Abstract

A modular wireless microelectromechanical system (MEMS) inclination sensor system (WMISS) is developed and tested for providing structural health monitoring of large-scale hook structures. The operating principle of a 3-D-MEMS-based dual-axis inclinometer is analyzed. A wireless MEMS sensor is integrated using sensing disposal, wireless communication, and power units. The WMISS is calibrated by using a laser displacement sensor in a pendular structure. The maximal error of the wireless MEMS inclination sensor is about 1%. The resolution is Ã‚Â±0.0025Ã‚Â°. With the new-type tuned mass damper control module, an experiment on a WMISS for the swing monitoring of a Lanjiang hook model is developed. Experimental results indicate that the developed WMISS is highly precise, convenient, stable, and low cost and has long range, and thus, a WMISS can accurately and conveniently monitor the swing of a Lanjiang hook model.

Original language	English
Number of pages	7
Journal	IEEE Transactions on Industrial Electronics
Publication status	Published - 2009

Keywords

composite micromechanics
hook structures
structural health monitoring
swing monitoring
three dimensional
wireless microelectromechanical systems

Cite this

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title = "Development of wireless MEMS inclination sensor system for swing monitoring of large-scale hook structures",

abstract = "A modular wireless microelectromechanical system (MEMS) inclination sensor system (WMISS) is developed and tested for providing structural health monitoring of large-scale hook structures. The operating principle of a 3-D-MEMS-based dual-axis inclinometer is analyzed. A wireless MEMS sensor is integrated using sensing disposal, wireless communication, and power units. The WMISS is calibrated by using a laser displacement sensor in a pendular structure. The maximal error of the wireless MEMS inclination sensor is about 1%. The resolution is {\~A}‚{\^A}±0.0025{\~A}‚{\^A}°. With the new-type tuned mass damper control module, an experiment on a WMISS for the swing monitoring of a Lanjiang hook model is developed. Experimental results indicate that the developed WMISS is highly precise, convenient, stable, and low cost and has long range, and thus, a WMISS can accurately and conveniently monitor the swing of a Lanjiang hook model.",

keywords = "composite micromechanics, hook structures, structural health monitoring, swing monitoring, three dimensional, wireless microelectromechanical systems",

author = "Yan Yu and Jinping Ou and Jun Zhang and Chunwei Zhang and Luyu Li",

year = "2009",

language = "English",

journal = "IEEE Transactions on Industrial Electronics",

issn = "1557-9948",

publisher = "Institute of Electrical and Electronics Engineers",

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TY - JOUR

T1 - Development of wireless MEMS inclination sensor system for swing monitoring of large-scale hook structures

AU - Yu, Yan

AU - Ou, Jinping

AU - Zhang, Jun

AU - Zhang, Chunwei

AU - Li, Luyu

PY - 2009

Y1 - 2009

N2 - A modular wireless microelectromechanical system (MEMS) inclination sensor system (WMISS) is developed and tested for providing structural health monitoring of large-scale hook structures. The operating principle of a 3-D-MEMS-based dual-axis inclinometer is analyzed. A wireless MEMS sensor is integrated using sensing disposal, wireless communication, and power units. The WMISS is calibrated by using a laser displacement sensor in a pendular structure. The maximal error of the wireless MEMS inclination sensor is about 1%. The resolution is Ã‚Â±0.0025Ã‚Â°. With the new-type tuned mass damper control module, an experiment on a WMISS for the swing monitoring of a Lanjiang hook model is developed. Experimental results indicate that the developed WMISS is highly precise, convenient, stable, and low cost and has long range, and thus, a WMISS can accurately and conveniently monitor the swing of a Lanjiang hook model.

AB - A modular wireless microelectromechanical system (MEMS) inclination sensor system (WMISS) is developed and tested for providing structural health monitoring of large-scale hook structures. The operating principle of a 3-D-MEMS-based dual-axis inclinometer is analyzed. A wireless MEMS sensor is integrated using sensing disposal, wireless communication, and power units. The WMISS is calibrated by using a laser displacement sensor in a pendular structure. The maximal error of the wireless MEMS inclination sensor is about 1%. The resolution is Ã‚Â±0.0025Ã‚Â°. With the new-type tuned mass damper control module, an experiment on a WMISS for the swing monitoring of a Lanjiang hook model is developed. Experimental results indicate that the developed WMISS is highly precise, convenient, stable, and low cost and has long range, and thus, a WMISS can accurately and conveniently monitor the swing of a Lanjiang hook model.

KW - composite micromechanics

KW - hook structures

KW - structural health monitoring

KW - swing monitoring

KW - three dimensional

KW - wireless microelectromechanical systems

UR - http://handle.uws.edu.au:8081/1959.7/512208

M3 - Article

SN - 1557-9948

SN - 0278-0046

JO - IEEE Transactions on Industrial Electronics

JF - IEEE Transactions on Industrial Electronics

ER -

Development of wireless MEMS inclination sensor system for swing monitoring of large-scale hook structures

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