Thermomagnetic generators (TMGs) are devices designed to convert waste heat into electricity using the principles of thermomagnetic effects. These generators are a type of thermoelectric generator (TEG) that operate based on the Seebeck effect and the magnetocaloric effect. Here's a basic explanation of how electricity is generated in thermomagnetic generators for waste heat recovery:
Seebeck Effect: The Seebeck effect is the phenomenon where a temperature difference across a material causes an electric voltage to be generated. In a TMG, a thermoelectric material is used that exhibits the Seebeck effect. This material is often composed of two dissimilar semiconductors connected to form a thermocouple.
Temperature Gradient: The thermoelectric material used in the TMG is exposed to a temperature gradient. One side of the material is heated, while the other side is kept cooler.
Electron Flow: Due to the temperature difference, electrons in the thermoelectric material move from the hot side to the cold side, creating a flow of charge carriers. This electron flow generates an electric current in the thermocouple.
Magnetic Field Application: In a standard thermoelectric generator, this would be the end of the process. However, in a thermomagnetic generator, an additional step is introduced to enhance the efficiency of electricity generation. A magnetic field is applied perpendicular to the direction of the temperature gradient.
Magnetocaloric Effect: When the magnetic field is applied, the thermoelectric material experiences the magnetocaloric effect, which means its temperature changes in response to the magnetic field. As the material moves in and out of the magnetic field, it experiences heating and cooling cycles.
Increased Voltage Generation: The magnetocaloric effect, combined with the Seebeck effect, increases the voltage generated across the thermocouple. This leads to higher efficiency and improved waste heat recovery.
Electrical Output: The electric current generated by the thermomagnetic generator can be collected and used to power electronic devices or recharge batteries, providing a valuable source of electricity from waste heat.
Thermomagnetic generators have the advantage of potentially being more efficient in waste heat recovery compared to conventional thermoelectric generators because they utilize the additional magnetic field effect. However, they are still in the research and development phase, and their widespread commercial implementation is yet to be realized.