TY - JOUR
T1 - Vibration Modeling of Arc-Based Cantilevers for Energy Harvesting Applications
AU - Apo, Daniel J.
AU - Sanghadasa, Mohan
AU - Priya, Shashank
N1 - Funding Information:
The authors acknowledge the financial support from the National Science Foundation (NSF) through the INAMM program (S.P.) and through the ARMDEC (D.A.).
Publisher Copyright:
© 2014 by De Gruyter 2014.
PY - 2014
Y1 - 2014
N2 - Cantilever beams are widely used for designing transducers for low-frequency vibration energy harvesting. However, in order to keep the dimensions within reasonable constraints, a large tip mass is generally required for reducing the resonance frequency below 100 Hz which has adverse effect on the reliability. This study provides a breakthrough toward realizing low-frequency micro-scale transduction structures. An analytical out-of-plane vibration model for standalone arc-based cantilever beams was developed that includes provisions for shear and rotary inertia, multidirectional arcs, and multiple layers. The model was applied to a multilayered cantilever beam (10-mm wide and 0.1-mm thick) composed of three arcs, and the results indicate that the fundamental bending mode of the beam was 38 Hz for a silicon substrate thickness of 100 μm. The model was validated with modal experimental results from an arc-based cantilever made out of aluminum.
AB - Cantilever beams are widely used for designing transducers for low-frequency vibration energy harvesting. However, in order to keep the dimensions within reasonable constraints, a large tip mass is generally required for reducing the resonance frequency below 100 Hz which has adverse effect on the reliability. This study provides a breakthrough toward realizing low-frequency micro-scale transduction structures. An analytical out-of-plane vibration model for standalone arc-based cantilever beams was developed that includes provisions for shear and rotary inertia, multidirectional arcs, and multiple layers. The model was applied to a multilayered cantilever beam (10-mm wide and 0.1-mm thick) composed of three arcs, and the results indicate that the fundamental bending mode of the beam was 38 Hz for a silicon substrate thickness of 100 μm. The model was validated with modal experimental results from an arc-based cantilever made out of aluminum.
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U2 - 10.1515/ehs-2013-0002
DO - 10.1515/ehs-2013-0002
M3 - Article
AN - SCOPUS:85126307804
SN - 2329-8774
VL - 1
SP - 57
EP - 68
JO - Energy Harvesting and Systems
JF - Energy Harvesting and Systems
IS - 1-2
ER -