skip to context

Energy harvesting to power the Internet of Things


A new paper in EPJ Special Topics shows how energy can be harvested from vibrating micromagnets to power the now ubiquitous wireless sensors in the most efficient way.

New York | Heidelberg, 13 June 2022

Journal cover: The European Physical Journal Special TopicsThe wireless interconnection of everyday objects known as the Internet of Things depends on wireless sensor networks that need a low but constant supply of electrical energy. This can be provided by electromagnetic energy harvesters that generate electricity directly from the environment. Lise-Marie Lacroix from the Université de Toulouse, France, with colleagues from Toulouse, Grenoble and Atlanta, Georgia, USA, has used a mathematical technique, finite element simulation, to optimise the design of one such energy harvester so that it generates electricity as efficiently as possible. This work has now been published in EPJ ST.

The Internet of Things consists of an enormous number of generally small, portable devices, each of which needs its own sustainable micro-energy source. Batteries are unsatisfactory for this as they will often need to be replaced or recharged. Many different technologies are being considered instead, with one of the most promising solutions being electromagnetic energy harvesting.

An electromagnetic energy harvester consists of a vibrating plate holding an array of micromagnets facing and coupled with a parallel, static coil. Electrical energy is generated by the vibrating magnets and the amount of electricity that can enter a circuit depends on the design of the coil and magnet and the spacing between them.

Lacroix and her team studied a system in which the magnets were state-of-the-art NdFeB ones - that is, they were composed from an alloy of the rare earth metal neodymium with iron and boron. They found that power could be optimised through a trade-off between the spacing of the magnets in the array and the number of turns in the coil; reducing the distance between coil and array and increasing the thickness of the magnets can also increase it. “We are now producing harvesters using the guidelines that we have developed through this study,” she explains. These devices are likely to prove useful in the aerospace, automotive and biomedical sectors and others that have come to rely on the Internet of Things.

Reference: Lecerf, I., Moritz, P., Angulo-Cervera, J.E. et al. Optimization of a vibrating MEMS electromagnetic energy harvester using simulations. Eur. Phys. J. Spec. Top. (2022). https://doi.org/10.1140/epjs/s11734-022-00577-8

Further Information

For more information visit: www.epj.org

Services for Journalists

The full-text of the Editorial is available here.

Contact

Sabine Lehr | Springer | Physics Editorial Department
tel +49-6221-487-8336 | sabine.lehr@springer.com