Equivalent circuit modeling and analysis of aerodynamic vortex-induced piezoelectric energy harvesting
Low-speed wind energy has potential to be captured for powering micro-electro-mechanical systems or sensors in remote inaccessible place by piezoelectric energy harvesting from vortex-induced vibration. Conventional theory or finite-element analysis mostly considers a simple pure resistance as inter...
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sg-ntu-dr.10356-1621072022-10-04T06:27:20Z Equivalent circuit modeling and analysis of aerodynamic vortex-induced piezoelectric energy harvesting Jia, Jinda Shan, Xiaobiao Zhang, Xingxu Xie, Tao Yang, Yaowen School of Civil and Environmental Engineering Engineering::Civil engineering Piezoelectric Energy Harvesting Equivalent Circuit Modeling Low-speed wind energy has potential to be captured for powering micro-electro-mechanical systems or sensors in remote inaccessible place by piezoelectric energy harvesting from vortex-induced vibration. Conventional theory or finite-element analysis mostly considers a simple pure resistance as interface circuit because of the complex fluid-solid-electricity coupling in aeroelastic piezoelectric energy harvesting. However, the output alternating voltage should be rectified to direct voltage to be used in practical occasions, where the theoretical analysis and finite-element analysis for complex interface may be cumbersome or difficult. To solve this problem, this paper presents an equivalent circuit modeling (ECM) method to analyze the performance of vortex-induced energy harvesters. Firstly, the equivalent analogies from the mechanical and fluid domain to the electrical domain are built. The linear mechanical and fluid elements are represented by standard electrical elements. The nonlinear elements are represented by electrical non-standard user-defined components. Secondly, the total fluid-solid-electricity coupled mathematical equations of the harvesting system are transformed into electrical formulations based on the equivalent analogies. Finally, the entire ECM is established in a circuit simulation software to perform system-level transient analyses. The simulation results from ECM have good agreement with the experimental measurements. Further parametric studies are carried out to assess the influences of wind speed and resistance on the output power of the alternating circuit interface and the capacitor filter circuit. At wind speed of 1.2 m s-1, the energy harvester could generate an output power of 81.71 μW with the capacitor filter circuit and 114.64 μW with the alternating circuit interface. The filter capacitance is further studied to ascertain its effects on the stability of output and the settling time. This work is financially supported by the National Natural Science Foundation of China (Grant No. 51875116), the National Natural Science Foundation of China (Grant No. 51677043) and the China Scholarship Council (Grant No. 201706120129). 2022-10-04T06:27:20Z 2022-10-04T06:27:20Z 2022 Journal Article Jia, J., Shan, X., Zhang, X., Xie, T. & Yang, Y. (2022). Equivalent circuit modeling and analysis of aerodynamic vortex-induced piezoelectric energy harvesting. Smart Materials and Structures, 31(3), 035009-. https://dx.doi.org/10.1088/1361-665X/ac4ab4 0964-1726 https://hdl.handle.net/10356/162107 10.1088/1361-665X/ac4ab4 2-s2.0-85125494666 3 31 035009 en Smart Materials and Structures © 2022 IOP Publishing Ltd. All rights reserved. |
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Engineering::Civil engineering Piezoelectric Energy Harvesting Equivalent Circuit Modeling Jia, Jinda Shan, Xiaobiao Zhang, Xingxu Xie, Tao Yang, Yaowen Equivalent circuit modeling and analysis of aerodynamic vortex-induced piezoelectric energy harvesting |
| description |
Low-speed wind energy has potential to be captured for powering micro-electro-mechanical systems or sensors in remote inaccessible place by piezoelectric energy harvesting from vortex-induced vibration. Conventional theory or finite-element analysis mostly considers a simple pure resistance as interface circuit because of the complex fluid-solid-electricity coupling in aeroelastic piezoelectric energy harvesting. However, the output alternating voltage should be rectified to direct voltage to be used in practical occasions, where the theoretical analysis and finite-element analysis for complex interface may be cumbersome or difficult. To solve this problem, this paper presents an equivalent circuit modeling (ECM) method to analyze the performance of vortex-induced energy harvesters. Firstly, the equivalent analogies from the mechanical and fluid domain to the electrical domain are built. The linear mechanical and fluid elements are represented by standard electrical elements. The nonlinear elements are represented by electrical non-standard user-defined components. Secondly, the total fluid-solid-electricity coupled mathematical equations of the harvesting system are transformed into electrical formulations based on the equivalent analogies. Finally, the entire ECM is established in a circuit simulation software to perform system-level transient analyses. The simulation results from ECM have good agreement with the experimental measurements. Further parametric studies are carried out to assess the influences of wind speed and resistance on the output power of the alternating circuit interface and the capacitor filter circuit. At wind speed of 1.2 m s-1, the energy harvester could generate an output power of 81.71 μW with the capacitor filter circuit and 114.64 μW with the alternating circuit interface. The filter capacitance is further studied to ascertain its effects on the stability of output and the settling time. |
| author2 |
School of Civil and Environmental Engineering |
| author_facet |
School of Civil and Environmental Engineering Jia, Jinda Shan, Xiaobiao Zhang, Xingxu Xie, Tao Yang, Yaowen |
| format |
Article |
| author |
Jia, Jinda Shan, Xiaobiao Zhang, Xingxu Xie, Tao Yang, Yaowen |
| author_sort |
Jia, Jinda |
| title |
Equivalent circuit modeling and analysis of aerodynamic vortex-induced piezoelectric energy harvesting |
| title_short |
Equivalent circuit modeling and analysis of aerodynamic vortex-induced piezoelectric energy harvesting |
| title_full |
Equivalent circuit modeling and analysis of aerodynamic vortex-induced piezoelectric energy harvesting |
| title_fullStr |
Equivalent circuit modeling and analysis of aerodynamic vortex-induced piezoelectric energy harvesting |
| title_full_unstemmed |
Equivalent circuit modeling and analysis of aerodynamic vortex-induced piezoelectric energy harvesting |
| title_sort |
equivalent circuit modeling and analysis of aerodynamic vortex-induced piezoelectric energy harvesting |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/162107 |
| _version_ |
1746219664059400192 |