Your search keyword '"Dane Quinn, D."' showing total 2 results

1. High-frequency vibration energy harvesting from impulsive excitation utilizing intentional dynamic instability caused by strong nonlinearity.

Author

Remick, Kevin, Dane Quinn, D., Michael McFarland, D., Bergman, Lawrence, and Vakakis, Alexander

Subjects

*VIBRATION (Mechanics), *ENERGY harvesting, *ELECTRONIC excitation, *DYNAMIC stability, *NONLINEAR theories, *ELECTROMAGNETIC coupling

Abstract

The authors investigate a vibration-based energy harvesting system utilizing essential (nonlinearizable) nonlinearities and electromagnetic coupling elements. The system consists of a grounded, weakly damped linear oscillator (primary system) subjected to a single impulsive load. This primary system is coupled to a lightweight, damped oscillating attachment (denoted as nonlinear energy sink, NES) via a neodymium magnet and an inductance coil, and a piano wire, which generates an essential geometric cubic stiffness nonlinearity. Under impulsive input, the transient damped dynamics of this system exhibit transient resonance captures (TRCs) causing intentional large-amplitude and high-frequency instabilities in the response of the NES. These TRCs result in strong energy transfer from the directly excited primary system to the light-weight attachment. The energy is harvested by the electromagnetic elements in the coupling and, in the present case, dissipated in a resistive element in the electrical circuit. The primary goal of this work is to numerically, analytically, and experimentally demonstrate the efficacy of employing this type of intentional high-frequency dynamic instability to achieve enhanced vibration energy harvesting under impulsive excitation. [ABSTRACT FROM AUTHOR]

Published

2016

2. On the Role of Nonlinearities in Vibratory Energy Harvesting: A Critical Review and Discussion.

Author

Daqaq, Mohammed F., Masana, Ravindra, Erturk, Alper, and Dane Quinn, D.

Subjects

*NONLINEAR theories, *ENERGY harvesting, *PERFORMANCE evaluation, *STORAGE batteries, *MICROFABRICATION, *POWER resources

Abstract

The last two decades have witnessed several advances in microfabrication technologies and electronics, leading to the development of small, low-power devices for wireless sensing, data transmission, actuation, and medical implants. Unfortunately, the actual implementation of such devices in their respective environment has been hindered by the lack of scalable energy sources that are necessary to power and maintain them. Batteries, which remain the most commonly used power sources, have not kept pace with the demands of these devices, especially in terms of energy density. In light of this challenge, the concept of vibratory energy harvesting has flourished in recent years as a possible alternative to provide a continuous power supply. While linear vibratory energy harvesters have received the majority of the literature's attention, a significant body of the current research activity is focused on the concept of purposeful inclusion of nonlinearities for broadband transduction. When compared to their linear resonant counterparts, nonlinear energy harvesters have a wider steady-state frequency bandwidth, leading to a common belief that they can be utilized to improve performance in ambient environments. Through a review of the open literature, this paper highlights the role of nonlinearities in the transduction of energy harvesters under different types of excitations and investigates the conditions, in terms of excitation nature and potential shape, under which such nonlinearities can be beneficial for energy harvesting. [ABSTRACT FROM AUTHOR]

Published

2014