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Development of a vibration and shock sensor using piezoelectric ceramics

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dc.contributor.author De Silva, HTTM
dc.contributor.author Dayananda, RKAS
dc.contributor.author Adikary, SU
dc.contributor.editor Sivahar, V
dc.contributor.editor Sitinamaluwa, HS
dc.date.accessioned 2022-03-16T03:48:28Z
dc.date.available 2022-03-16T03:48:28Z
dc.date.issued 2019-01
dc.identifier.citation De Silva, H.T.T.M., Dayananda, R.K.A.S., & Adikary, S.U. (2019). Development of a vibration and shock sensor using piezoelectric ceramics [Abstract]. In V. Sivahar & H.S. Sitinamaluwa (Eds.), Dreams to reality through innovative materials (p. 19). Department of Materials Science and Engineering, University of Moratuwa. en_US
dc.identifier.uri http://dl.lib.uom.lk/handle/123/17383
dc.description.abstract When buildings are exposed to vibration or shock, those buildings can be damaged partially or fully depending on the energy of vibration. Hence, quantitative analysis of building vibration has become popular among researchers. In this research, a vibration sensor was developed using a piezoelectric ceramic cantilever beam and a tip mass to confirm that the vibration frequency of the building does not exceed the cosmetic damage range. As the first step, a mathematical model was developed to calculate the resonance frequency of the cantilever beam with a tip mass. At the resonance frequency, maximum amplitude could be achieved resulting in a higher output voltage of the piezoelectric sensor. The developed mathematical model and finite element analysis were used to determine the accurate dimensions of the cantilever beam based piezoelectric sensor. According to the calculations, width, length and thickness of the piezoelectric material, copper beam and tip mass are 10x20x1, 10x100x0.3 and 10x30x3 mm respectively. Hence, the piezoelectric sensor output voltage was calculated using finite element analysis at the vibration frequency range that corresponds to the cosmetic damage. According to the calculations, threshold voltage level and frequency of the sensor to activate the alarm were 4.35 mv and 9.5 Hz respectively. Arduino software was used to analyze the output signal of the sensor. Vibration source was used to verify the calculation steps. Finally, liquid crystal display and small buzzer were added to show the frequency and give a warning when vibration frequency exceeds the required level. en_US
dc.language.iso en en_US
dc.publisher Department of Materials Science and Engineering en_US
dc.subject Cosmetic damage to building en_US
dc.subject Piezoelectric sensor en_US
dc.subject Cantilever beam en_US
dc.subject Finite element analysis en_US
dc.title Development of a vibration and shock sensor using piezoelectric ceramics en_US
dc.type Conference-Abstract en_US
dc.identifier.faculty Engineering en_US
dc.identifier.department Department of Materials Science and Engineering en_US
dc.identifier.year 2019 en_US
dc.identifier.conference Materials Engineering Symposium on Innovations for Industry 2019 en_US
dc.identifier.place Katubedda en_US
dc.identifier.pgnos p. 19 en_US
dc.identifier.proceeding Dreams to reality through innovative materials en_US
dc.identifier.email suadi@uom.lk en_US


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