Analysis of Tristable Energy Harvesters Under Random Excitations
01 Jan 2020-pp 517-528
TL;DR: In this paper, the performance of tristable energy harvesters under Gaussian white noise excitation was analyzed through numerical simulations and it was shown that beyond a certain critical amplitude of excitation, the harvester undergo inter-well oscillations and harvest more power.
Abstract: This manuscript analyzes the performance of a tristable vibration energy harvester under Gaussian white noise excitation. Broadband vibration energy harvesting has attracted significant research attention and is targeted toward obtaining large power output over a wide range of frequencies. Nonlinearity can be introduced into vibration energy harvesting systems through multi-stability. In cantilever-type vibration energy harvesters, multi-stability could be achieved by the introduction of magnetic interactions. When two external magnets are used, the harvester can have up to three stable static equilibrium positions. The harvester with two stable states has been explored widely, both theoretically and experimentally. Recently, the harvester with three stable states is shown to perform better than its bistable counterpart in the presence of a linearly increasing harmonic sweep excitation. Ambient vibrations are random in nature, and the performance of tristable energy harvesters under such excitations needs to be studied. To begin with, we study the performance of tristable energy harvesters under Gaussian white noise excitation through numerical simulations. The simulations show that beyond a certain critical amplitude of excitation, the harvesters undergo inter-well oscillations and harvest more power. This implies that if the variance of the random ambient excitation is known, then the harvester could be optimized so that the mean harvested power is maximized.
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TL;DR: In this paper, an elongated ferromagnetic cantilevered beam having a base and an opposing end is used for scavenging vibrational energy from an external excitation source.
Abstract: The present invention relates to the field of energy harvesting. More particularly, embodiments of the invention relate to methods, systems, and devices for scavenging vibration- based energy from an ambient vibration source. Specific embodiments of the present invention include an energy harvesting device comprising: a) an elongated ferromagnetic cantilevered beam having a base and an opposing end; b) a plurality of piezoceramic elements operably connected to the base of the beam; c) a first support member for supporting the beam at its base; and d) two permanent magnets disposed on a second support member; wherein the base end of the beam is operably connected to the support member such that the beam is suspended lengthwise from the support member at its base and the opposing end of the beam is free and is disposed a selected distance above and between the magnets; and wherein the piezoceramic elements are operably connected in parallel to each other, such that during operation the beam is capable of scavenging vibrational energy from an external excitation source and the piezoceramic elements are capable of converting the harmonic or random vibrational energy into electrical energy. The piezo-magneto-elastic generator results in a 200% increase in the open- circuit voltage amplitude (hence promising an 800% increase in the power amplitude). The inventive piezo-magneto-elastic generator can be applied for use in piezoelectric energy harvesting, as well as in electromagnetic, electrostatic and magnetostrictive energy harvesting techniques and their hybrid combinations with similar devices.
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TL;DR: In this paper, a nonlinear piezomagneto-elastic energy harvester driven by stationary Gaussian white noise is considered and the simulated response of this validated model to random base excitation is considered.
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