Abstract
• The state-of-the-art of thermoelectric generators is reviewed comprehensively. • The materials used in TEGs, Figure of Merit, improvement techniques are introduced. • Different configurations of experimental set-ups and prototypes are explored. • The performance of TEGs is investigated with different simulation software packages. Nowadays humans are facing difficult issues, such as increasing power costs, environmental pollution and global warming. In order to reduce their consequences, scientists are concentrating on improving power generators focused on energy harvesting. Thermoelectric generators (TEGs) have demonstrated their capacity to transform thermal energy directly into electric power through the Seebeck effect. Due to the unique advantages they present, thermoelectric systems have emerged during the last decade as a promising alternative among other technologies for green power production. In this regard, thermoelectric device output prediction is important both for determining the future use of this new technology and for specifying the key design parameters of thermoelectric generators and systems. Moreover, TEGs are environmentally safe, work quietly as they do not include mechanical mechanisms or rotating elements and can be manufactured on a broad variety of substrates such as silicon, polymers and ceramics. In addition, TEGs are position-independent, have a long working life and are ideal for bulk and compact applications. Furthermore, Thermoelectric generators have been found as a viable solution for direct generation of electricity from waste heat in industrial processes. This paper presents in-depth analysis of TEGs, beginning with a comprehensive overview of their working principles such as the Seebeck effect, the Peltier effect, the Thomson effect and Joule heating with their applications, materials used, Figure of Merit, improvement techniques including different thermoelectric material arrangements and technologies used and substrate types. Moreover, performance simulation examples such as COMSOL Multiphysics and ANSYS-Computational Fluid Dynamics are investigated.
Highlights
When generating electricity in power stations, around two thirds of the energy is lost in the form of waste heat that is discharged from cooling towers [1]
It can be shown that the surface temperature of the heat exchanger (HEX) is clearly lower than the temperature of the air
It can be noted that there is a significant drop in temperature along with a downward flow of air, for the traditional Thermoelectric generators (TEGs) method
Summary
When generating electricity in power stations, around two thirds of the energy is lost in the form of waste heat that is discharged from cooling towers [1]. The main reason is that the gas or steam-powered turbine systems, that operate to produce most of the electrical power, primarily function by burning fuel to produce energy in the form of heat. This is followed by the conversion of this heat energy into mechanical energy within the turbine, and turning the mechanical energy into electrical energy in a generator [2]. The reduction of greenhouse emission from the reduced wastage would be beneficial for the environment as less fuel is burned for the same amount of electricity produced
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