Experimental characterization and performance improvement evaluation of an electromagnetic transducer utilizing a tuned inerter

Author:

Sugiura Keita1,Watanabe Yuta1,Asai Takehiko2ORCID,Araki Yoshikazu3,Ikago Kohju4

Affiliation:

1. Graduate School of Systems and Information Engineering, University of Tsukuba, Japan

2. Faculty of Engineering, Information and Systems, University of Tsukuba, Japan

3. Graduate School of Environmental Studies, Nagoya University, Japan

4. International Research Institute of Disaster Science, Tohoku University, Japan

Abstract

This research reports on the experimental verification of an enhanced energy conversion device utilizing a tuned inerter called a tuned inertial mass electromagnetic transducer (TIMET). The TIMET consists of a motor, a rotational mass, and a tuning spring. The motor and the rotational mass are connected to a ball screw and the tuning spring interfaced to the ball screw is connected to the vibrating structure. Thus, vibration energy of the structure is absorbed as electrical energy by the motor. Moreover, the amplified inertial mass can be realized by rotating relatively small physical masses. Therefore, by designing the tuning spring stiffness and the inertial mass appropriately, the motor can rotate more effectively due to the resonance effect, leading to more effective energy generation. The authors designed a prototype of the TIMET and conducted tests to validate the effectiveness of the tuned inerter for electromagnetic transducers. Through excitation tests, the property of the hysteresis loops produced by the TIMET is investigated. Then a reliable analytical model is developed employing a curve fitting technique to simulate the behavior of the TIMET and to assess the power generation accurately. In addition, numerical simulation studies on a structure subjected to a seismic loading employing the developed model are conducted to show the advantages of the TIMET over a traditional electromagnetic transducer in both vibration suppression capability and energy harvesting efficiency.

Funder

Japan Society for the Promotion of Science

Publisher

SAGE Publications

Subject

Mechanical Engineering,Mechanics of Materials,Aerospace Engineering,Automotive Engineering,General Materials Science

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