Document Type
Conference Object
Creative Commons License
This work is licensed under a Creative Commons Attribution 3.0 License.
Disciplines
Biomechanical Engineering | Engineering | Mechanical Engineering
Abstract
Novel implanted cardiac pacemakers that are powered by energy harvesters driven by the cardiac motion and have a 40 year lifetime are currently under development. To satisfy space constraints and energy requirements of the device, silicon-based MEMS energy harvesters are being developed in the EU project (MANpower). Such MEMS harvesters for vibration frequencies below 50 Hz have not been widely reported. In this paper, an analytical model and a 3D finite element model (FEM) to predict displacement and open circuit voltage, validated through experimental analysis using an off-the-shelf low frequency energy harvester, are presented. The harvester was excited through constant amplitude sinusoidal base displacement over a range of 20 to 70 Hz passing through its first mode natural frequency at 47 Hz. At resonance both models predict displacements with an error of less than 2% when compared to the experimental result. Comparing the two models, the application of the experimentally measured damping ratio differs for accurate displacement prediction and the differences in symmetry in the measured and modelled displacement and voltage data around the resonance frequency indicate the two piezoelectric voltage models use different fundamental equations.
Recommended Citation
Sunny Jay et al 2016 J. Phys.: Conf. Ser. 757 012038
Publication Details
Journal of Physics: Conference Series, Volume 757, 27th Micromechanics and Microsystems Europe Workshop 28–30 August 2016, Cork, Ireland.