Impulsive parametric damping in energy harvesting
Impulsive parametric damping in energy harvesting
In this paper, an electro-mechanical system with a time-varying damper, which is capable of changing the damping coefficient impulsively, is considered. The effect of the impulsive parametric damping to the modal energy content of the mechanical system is investigated analytically as well as numerically. First, the governing differential equation is presented and then the solution of the system’s response is obtained through numerical integration. The energy dissipated by the damper is then calculated to investigate the amount of the energy that can be harvested, and the results are compared with the results from a system without parametric impulses. It is shown, that the amount of the harvested energy can be increased by introducing parametric impulses. Then, an analytical formulation is derived for the system using Dirac-Delta impulses and the analytical results are validated with numerical simulations. The device is subjected to an initial condition and therefore is vibrating freely without any base excitation. This could be used for applications such as harvesting energy from the passage of a train, where the train vibration can introduce an initial velocity to the harvester and the energy can then be extracted from the free vibration of the harvester.
1-10
Ghandchi Tehrani, Maryam
c2251e5b-a029-46e2-b585-422120a7bc44
Pumhoessel, Thomas
06a0016a-d4c7-4615-95ae-6f92f7c5d3d1
Ghandchi Tehrani, Maryam
c2251e5b-a029-46e2-b585-422120a7bc44
Pumhoessel, Thomas
06a0016a-d4c7-4615-95ae-6f92f7c5d3d1
Ghandchi Tehrani, Maryam and Pumhoessel, Thomas
(2016)
Impulsive parametric damping in energy harvesting.
Journal of Physics: Conference Series, .
(In Press)
Abstract
In this paper, an electro-mechanical system with a time-varying damper, which is capable of changing the damping coefficient impulsively, is considered. The effect of the impulsive parametric damping to the modal energy content of the mechanical system is investigated analytically as well as numerically. First, the governing differential equation is presented and then the solution of the system’s response is obtained through numerical integration. The energy dissipated by the damper is then calculated to investigate the amount of the energy that can be harvested, and the results are compared with the results from a system without parametric impulses. It is shown, that the amount of the harvested energy can be increased by introducing parametric impulses. Then, an analytical formulation is derived for the system using Dirac-Delta impulses and the analytical results are validated with numerical simulations. The device is subjected to an initial condition and therefore is vibrating freely without any base excitation. This could be used for applications such as harvesting energy from the passage of a train, where the train vibration can introduce an initial velocity to the harvester and the energy can then be extracted from the free vibration of the harvester.
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Accepted/In Press date: 12 August 2016
Organisations:
Signal Processing & Control Grp
Identifiers
Local EPrints ID: 399595
URI: http://eprints.soton.ac.uk/id/eprint/399595
ISSN: 1742-6588
PURE UUID: f5b3de8e-de40-417d-b780-b6f0aa889048
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Date deposited: 22 Aug 2016 08:33
Last modified: 15 Mar 2024 05:50
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Author:
Thomas Pumhoessel
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