KIT Computer Scientists Work on a Measurement System for Mobile End Devices to Compile a Pollution Map in Collaboration with Users using Participatory Sensing
Researchers developed a process for printing inexpensive, three-dimensional thermoelectric generators.
Feb 8th, 2021
Karlsruhe Institute of Technology
With the help of newly developed inks and special production techniques, such as origami, inexpensive thermoelectric generators can be produced for various applications.
Andres Rösch, KIT
Thermoelectric generators, TEGs for short, convert ambient heat into electrical power. They enable maintenance-free, environmentally friendly, and autonomous power supply of the continuously growing number of sensors and devices for the Internet of Things (IoT) and recovery of waste heat. Scientists of Karlsruhe Institute of Technology (KIT) have now developed three-dimensional component architectures based on novel, printable thermoelectric materials. This might be a milestone on the way towards use of inexpensive TEGs. The results are reported in
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IMAGE: With the help of newly developed inks and special production techniques, such as origami, inexpensive thermoelectric generators can be produced for various applications. view more
Credit: Andres Rösch, KIT
Thermoelectric generators, TEGs for short, convert ambient heat into electrical power. They enable maintenance-free, environmentally friendly, and autonomous power supply of the continuously growing number of sensors and devices for the Internet of Things (IoT) and recovery of waste heat. Scientists of Karlsruhe Institute of Technology (KIT) have now developed three-dimensional component architectures based on novel, printable thermoelectric materials. This might be a milestone on the way towards use of inexpensive TEGs. The results are reported in
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Credit: Photo: IMT/KIT
Use of waste heat contributes largely to sustainable energy supply. Scientists of Karlsruhe Institute of Technology (KIT) and T?hoku University in Japan have now come much closer to their goal of converting waste heat into electrical power at small temperature differences. As reported in
Joule, electrical power per footprint of thermomagnetic generators based on Heusler alloy films has been increased by a factor of 3.4. (DOI: 10.1016/j.joule.2020.10.019)
Many technical processes only use part of the energy consumed. The remaining fraction leaves the system in the form of waste heat. Frequently, this heat is released into the environment unused. However, it can also be used for heat supply or power generation. The higher the temperature of the waste heat is, the easier and cheaper is its reuse. Thermoelectric generators can use waste heat of low temperature for direct conversion into electrical power. Thermoelectric materials used so far, however,
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IMAGE: Thanks to its flexibility and adhesion, the biodegradable display can be worn directly on the hand. view more
Credit: Manuel Pietsch, KIT
In the next years, increasing use of electronic devices in consumables and new technologies for the internet of things will increase the amount of electronic scrap. To save resources and minimize waste volumes, an eco-friendlier production and more sustainable lifecycle will be needed. Scientists of Karlsruhe Institute of Technology (KIT) have now been the first to produce displays, whose biodegradability has been checked and certified by an independent office. The results are reported in the
Journal of Materials Chemistry. (DOI: 10.1039/d0tc04627b)