Abstract
In practice, there are some considerations to study stability, reliability, and output power optimization of a thermoelectric thin film operating dynamically. In this study stability and performance of a zinc antimonide thin film thermoelectric (TE) specimen is evaluated under transient with thermal and electrical load conditions. Thermoelectric behavior of the specimen and captured energy in each part of a thermal cycle are investigated. Glass is used as the substrate of the thin film, where the heat flow is parallel to the length of the thermoelectric element. In this work, the thermoelectric specimen is fixed between a heat sink exposed to the ambient temperature and a heater block. The specimen is tested under various electrical load cycles during a wide range of thermal cycles. The thermal cycles are provided for five different aimed temperatures at the hot junction, from 160 to 350 °C. The results show that the specimen generates approximately 30% of its total electrical energy during the cooling stage and 70% during the heating stage. The thin film generates maximum power of 8.78, 15.73, 27.81, 42.13, and 60.74 kW per unit volume of the thermoelectric material (kW/m3), excluding the substrate, corresponding to hot side temperature of 160, 200, 250, 300, and 350 °C, respectively. Furthermore, the results indicate that the thin film has high reliability after about one thousand thermal and electrical cycles, whereas there is no performance degradation.
Highlights
Thermoelectric systems have been implemented from many years ago as a credible and reliable technology of energy conversion for various applications such as conversion of the thermal energy into electricity directly as power generation and cooling systems [1,2]
Thermoelectric characteristics of the specimen are investigated by thermal cycling without applying electrical load resistance
The electrical load is not applied during the heating stage
Summary
Thermoelectric systems have been implemented from many years ago as a credible and reliable technology of energy conversion for various applications such as conversion of the thermal energy into electricity directly as power generation and cooling systems [1,2]. The thermoelectric (TE) material’s efficiency is investigated by using the dimensionless figure of merit as ZT = α2 T/(ρ·κ), where α is the Seebeck coefficient, T is the absolute temperature, ρ is the electrical resistivity, and κ is the total thermal conductivity, involving the lattice effect, κL , and the charge carrier effect, κe [3,4]. Most engineers and researchers consider bulk materials for high-scale applications, such as waste heat recovery from high temperature industrial furnaces and concentrated solar energy [5,6], thin films’ low power applications are attractively evident.
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