Sommer, Andre, M.Sc.

Andre Sommer, M. Sc.

Department of Mechanical Engineering
Institute of Applied Mechanics (LTM, Prof. Steinmann)

  • Project B – Excitation-Conforming, Shape-Adaptive Mechano-Electrical Energy Conversion

    (Third Party Funds Group – Sub project)

    Overall project: IGK 2495 Energy Conversion Systems: From Materials to Devices
    Term: 1. January 2020 - 30. June 2024
    Funding source: DFG / Graduiertenkolleg (GRK)

    Mechano-electrical (ME) energy conversion is a promising and versatile option for devices that demand novel perspectives in energy supply and/or require non-invasive noise and vibration reduction. The objective of this project is twofold. Firstly, we tackle the challenge of autonomous energy supply for the operation of remotely located electrical devices. These include measuring devices in meteorology or environmental monitoring that are oftentimes located offshore or in the remote locations and that only consume low energy to support their measuring function and/or for further processing of the measured data. Secondly, electric motors for pure and hybridized electric vehicles (PEV, HEV), which often exhibit undesired noise and vibration characteristics during operation. Here, ME energy conversion is highly
    viable for simultaneous energy harvesting and reduction of operation-induced vibrational energy.

    This project focuses on novel excitation-conforming ME energy converters, which are able to efficiently exploit the energy contained in the EF spectrum of natural (e.g. wind or water) or defined technical excitations of actuator-driven shape-adaptation. This project will develop advanced continuum modeling, computational optimization and simulation tools that enable the design of shape-adaptive energy harvesting structures by combined shape and topology optimization. Thereby, the overarching goal is to optimize the energy harvesting efficiency of a ME system by adapting its natural frequency spectrum to a given excitation EF spectrum via suited stiffness modulations. We will affect stiffness modulations based on a feedback control via actuation of the shape-adaptive ME system at only a few distinct actuation points.

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