Strain measurement using oscillator circuit sensor with high sampling frequency

A strain measurement system based on astable multivibrator using CMOS inverter has been developed. This system could omit an amplifier, filter and A/D converter unlike conventional Wheatstone bridge type sensor, because strain is measured by counting frequency of circuit voltage output due to resist...

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Published in	Kikai Gakkai ronbunshū = Transactions of the Japan Society of Mechanical Engineers Vol. 86; no. 881; p. 19-00203
Main Authors	KITAMURA, Shumpo, UTSUNOMIYA, Takao, SAITO, Atsushi, KANDA, Atsushi
Format	Journal Article
Language	Japanese
Published	The Japan Society of Mechanical Engineers 2020
Subjects	Fatigue crack propagation Measurement accuracy Oscillator circuit Sensor Strain gauge Strain measurement
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Abstract	A strain measurement system based on astable multivibrator using CMOS inverter has been developed. This system could omit an amplifier, filter and A/D converter unlike conventional Wheatstone bridge type sensor, because strain is measured by counting frequency of circuit voltage output due to resistance changes of a strain gauge. In the previous studies, it was shown that static strain could be measured with the same level of accuracy as Wheatstone bridge circuit. However, it was found that the sampling frequency for counting was not high (around 1 Hz) and it was difficult to measure dynamic strain. A reciprocal counting method has been applied to the system to improve sampling frequency in this study. Fatigue tests of a notched specimen were carried out and strain was measured during the tests to compare performance between the developed sensor and original sensor. As a result, strain could be measured with high frequency by the developed sensor. It is also found that strain measurements with high frequency could detect crack propagation state during the fatigue tests.
AbstractList	A strain measurement system based on astable multivibrator using CMOS inverter has been developed. This system could omit an amplifier, filter and A/D converter unlike conventional Wheatstone bridge type sensor, because strain is measured by counting frequency of circuit voltage output due to resistance changes of a strain gauge. In the previous studies, it was shown that static strain could be measured with the same level of accuracy as Wheatstone bridge circuit. However, it was found that the sampling frequency for counting was not high (around 1 Hz) and it was difficult to measure dynamic strain. A reciprocal counting method has been applied to the system to improve sampling frequency in this study. Fatigue tests of a notched specimen were carried out and strain was measured during the tests to compare performance between the developed sensor and original sensor. As a result, strain could be measured with high frequency by the developed sensor. It is also found that strain measurements with high frequency could detect crack propagation state during the fatigue tests.
Author	SAITO, Atsushi KITAMURA, Shumpo KANDA, Atsushi UTSUNOMIYA, Takao
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References	Kitamura, S., Utsunomiya, T., Saito, A. and Kanda, A., Improvement of strain measurement accuracy by small type of wireless sensor using oscillator circuit, Proceedings of the 24th Kanto branch of The Japan Society of Mechanical Engineers (2018), OS0717 (in Japanese). Fujino, Y. et al., Huge structural health monitoring, NTS (2015) (in Japanese). Kanda, A., Utsunomiya, T. and Saito, A., Development of strain sensor using oscillator circuit, Journal of the Japan Society for Aeronautical and Space Science, Vol. 62, No. 2 (2014), pp. 63–68 (in Japanese). Takahashi, S., Introduction of strain measurement, Maeda Printing (2005) (in Japanese). Inaudi, D., Bolster, M., Deblois, R., French, C., Phipps, A., Sebasky, J. and Western, K., Structural health monitoring system for the new I-35W St Anthony Falls Bridge, 4th International Conference on Structural Health Monitoring on Intelligent Infrastructure (2009). Kanda, A., Utsunomiya, T. and Saito, A., Development of strain sensor using oscillator circuit, Transactions of the Japan Society for Aeronautical and Space Science, Vol. 57, No. 5 (2014), pp. 272–278. Moreu, F., Kim, R. and Spencer, F., Railroad bridge monitoring using wireless smart sensors, Structural Control and Health Monitoring, Vol. 24, No. 2 (2016), DOI:10.1002/stc.1863. Inaba, T., Design and application of oscillator circuit, CQ Publishing (1993) (in Japanese). Utsunomiya, T., Kanda, A. and Saito, A., Strain measurement by oscillator circuit sensor using dummy gauge, Transactions of the JSME (in Japanese), Vol. 81, No. 830 (2014), DOI:10.1299/transjsme.15-00269 (in Japanese). Suzuki, Y., How to use of CMOS circuit II, Diichi Shiryo Printing (1989) (in Japanese). Potma, T., Strain gauges: Theory and application, Kyoritsu Shuppan Co., Ltd. (1974) (in Japanese). Okamura, H., Introduction of linear fracture mechanics, Baifukan (1981), pp. 80-81 (in Japanese). Yoshimura, K., Kuramochi, N. and Agui, T., Basics and structure of radio waves and frequencies, Sanshodo print (2010), pp. 158-165 (in Japanese).
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SubjectTerms	Fatigue crack propagation Measurement accuracy Oscillator circuit Sensor Strain gauge Strain measurement
Title	Strain measurement using oscillator circuit sensor with high sampling frequency
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