### NONLINEAR DYNAMICAL CHARACTERISTICS OF HYBRID TRI-STABLE PIEZOELECTRIC ENERGY HARVESTER BASED ON ROTATIONAL MOTION

**DOI Number**

**First page**

**Last page**

#### Abstract

#### Keywords

#### Full Text:

PDF#### References

Panchal, R.A., Koratkar, N.A., 2024, Energy harvesting from water flow through porous reduced graphene oxide networks, The Journal of Engineering, 2024(1), e12338.

Khalil, A.R., Hussain, M.I., Shah, M.H., Muhimeed, T. I., Nazir, G., Hussain, F., Mumtaz, U., 2024, The exploration of physical properties of 2D MXenes M3N2 (M= Ti, Hf, Zr, Mo) through the first principles approach: The energy harvesting materials, Computational Materials Science, 238, 112947.

Chatterjee, R., Shah, C.L., Gupta, S., Sarkar, S., 2024, Energy harvesting in a flow-induced vibrating flapper with biomimetic gaits, International Journal of Mechanical Sciences, 272, 109150.

Ullah, N., Islam, M.S., Hoque, A., Kirawanich, P., Alamri, S., Alsaif, H., Islam, M. T., 2024, Compact dual-band metamaterial absorber: Enhancing electromagnetic energy harvesting with polarization-insensitive and wide-angle capabilities, Optics and Laser Technology, 175, 110829.

Khatun, H., Sharma, C., Sarma, U., 2024, Investigation of ambient vibration sources for direct energy harvesting by optimizing resonant frequency using proof mass, Measurement Science and Technology, 35, 055101.

Saurabh, N., Limbore, S., Kuldeep, H., Patel, S., 2024, Simulation and experimental study of NBT-BT based compositions for thermal energy harvesting, Materials Today Communications, 38, 108331.

Erturk, A., Inman, D.J., 2011, Broadband piezoelectric power generation on high-energy orbits of the bistableDuffing oscillator with electromechanical coupling, Journal of Sound and Vibration, 330(10), pp. 2339-2353.

He, J.H., Abd Elazem, N.Y., 2022, The carbon nanotube-embedded boundary layer theory for energy harvesting, Facta Universitatis-Series Mechanical Engineering, 20(2), pp. 211-235.

Stepancikova, R., Olejnik, R., Matyas, J., Masar, M., Hausnerova, B., Slobodian, P., 2024, Pressure-Driven Piezoelectric Sensors and Energy Harvesting in Biaxially Oriented Polyethylene Terephthalate Film, Sensors, 24(4), 1275.

Anang, F.E.B., Wei, X., Xu, J., Cain, M., Li, Z., Brand, U., Peiner, E., 2024, Area-Selective Growth of Zinc Oxide Nanowire Arrays for Piezoelectric Energy Harvesting, Micromachines, 15(2), 261.

Golabek, J., Strankowski, M., 2024, A Review of Recent Advances in Human-Motion Energy Harvesting Nanogenerators, Self-Powering Smart Sensors and Self-Charging Electronics, Sensors, 24(4), 1069.

Manoujan, A.Z., Riasi, A., 2024, Optimal selection of parallel pumps running as turbines for energy harvesting in water transmission lines considering economic parameters, Applied Energy, 359, 122687.

Qian, F., Zhou, S.X., Zou, L., 2020, Approximate solutions and their stability of a broadband piezoelectric energy harvester with a tunable potential function, Communication in Nonlinear Science and Numerical Simulation, 80, 104984.

Liu, H.C., Fu, H.L., Sun, L.N., Lee, C.K., Yeatman, E.M., 2020, Hybrid energy harvesting technology: from materials, structural design,system integration to applications, Renew and Sustainable Energy Reviews, 137, 110473.

Stanton, S.C., McGehee, C.C., Mann, B.P., 2010, Nonlinear dynamics for broadband energy harvesting: investigation of a bistable piezoelectric inertial generator, Physica D, 239, pp. 640-653.

Stanton, S.C., Erturk A., Mann, B.P., Inman, D.J., 2010, Nonlinear piezoelectricity in electroelastic energy harvesters: modeling and experimental identification, Journal of Applied Physics, 108, 074903.

Zhou, S.X., Cao, J.Y., Inman, D.J., Lin, J., Liu, S.S., Wang, Z.Z., 2014, Broadband tristable energy harvester: modeling and experiment verification, Applied Energy, 133, pp. 33-39.

Cao, J.Y., Zhou, S.X., Wang, W., Lin, J., 2015, Influence of potential well depth on nonlinear tristable energy harvesting, Applied Physics Letters, 106, 173903, http://dx.doi.org/10.1063/1.4919532

Zhao, D., Gan M.Y., Zhang, C.H., Wei, J.D., Liu, S.G., 2018, Analysis of broadband characteristics of two degree of freedom bistable piezoelectric energy harvester, Materials Research Express, 5(8), 085704

Wang, H.Y., Tang, L.H., 2017, Modeling and experiment of bistable two-degree-of-freedom energy harvester with magnetic coupling, Mechanical Systems and Signal Processing, 86, pp. 29-39.

Wang, G.Q., Zhao, Z.X., Liao, W.H., Tan, J.P., Ju, Y., Li, Y., 2020, Characteristics of a tri-stable piezoelectric vibration energy harvester by considering geometric nonlinearity and gravitation effects, Mechanical Systems and Signal Processing, 139, 106571.

Zhu, P., Ren, X.M., Qin, W.Y., Yang, Y.F., Zhou, Z.Y., 2017, Theoretical and experimental studies on the characteristics of a tri-stable piezoelectric harvester, Archive of Applied Mechanics, 87, pp. 1541-1554.

Yang, T., Cao, Q.J., 2019, Dynamics and performance evaluation of a novel tristable hybrid energy harvester for ultra-low level vibration resources, International Journal of Mechanical Sciences, 156, pp. 123-136.

Zhou, Z.Y., Qin, W.Y., Yang, Y.F., Zhu, P., 2017, Improving efficiency of energy harvesting by a novel penta-stable configuration, Sensors & Actuators: A. physical, 265, pp. 297-305.

Rui, X.B., Zhang, Y., Zeng, Z.M., Yue, G.X. Huang, X.J., 2020, Design and analysis of a broadband three-beam impact piezoelectric energy harvester for lowfrequency rotational motion, Mechanical Systems and Signal Processing, 149, 107307.

Wang, Y.L., Yang, Z.B., Cao, D.Q., 2021, On the offset distance of rotational piezoelectric energy harvesters, Energy, 220, 119676.

Khameneifar, F., Moallem, M., Arzanpour, S., 2011, Modeling and analysis of a piezoelectric energy scavenger for rotary motion applications, Journal of Vibration and Acoustics, 133, 011005.

Zhang, Y.S., Zheng, R.C., Nakano, K., Cartmell, M.P., 2018, Stabilising high energy orbit oscillations by the utilisation of centrifugal effects for rotating-tyre-induced energy harvesting, Applied Physics Letters, 112, 143901.

Mei, X.T., Zhou, S.X., Yang, Z.C., Kaizuka, T., Nakano, K., 2019, A tri-stable energy harvester in rotational motion: modeling, theoretical analyses and experiments, Journal of Sound Vibration, 469, 115142.

Man, D.W., Zhang, Y., Xu, G.Z., Kuang, X.C., Xu, H.M., Tang, L.P., Han, T.T., 2023, Improving energy harvesting from low-frequency excitations by a hybrid tri-stable piezoelectric energy harvester, Alexandria Engineering Journal, 76, pp. 153-165.

DOI: https://doi.org/10.22190/FUME240118033M

### Refbacks

- There are currently no refbacks.

ISSN: 0354-2025 (Print)

ISSN: 2335-0164 (Online)

COBISS.SR-ID 98732551

ZDB-ID: 2766459-4