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Coupled thermoelectric devices: Theory and experiment

Entropy (2016) 18(7)
DOI: 10.3390/e18070255
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Abstract

In this paper, we address theoretically and experimentally the optimization problem of the heat transfer occurring in two coupled thermoelectric devices. A simple experimental set up is used. The optimization parameters are the applied electric currents. When one thermoelectric is analysed, the temperature difference ΔT between the thermoelectric boundaries shows a parabolic profile with respect to the applied electric current. This behaviour agrees qualitatively with the corresponding experimental measurement. The global entropy generation shows a monotonous increase with the electric current. In the case of two coupled thermoelectric devices, elliptic isocontours for ΔT are obtained in applying an electric current through each of the thermoelectrics. The isocontours also fit well with measurements. Optimal figure of merit is found for a specific set of values of the applied electric currents. The entropy generation-thermal figure of merit relationship is studied. It is shown that, given a value of the thermal figure of merit, the device can be operated in a state of minimum entropy production.

Figures

  • Figure 1. Sketch of the experimental device, not drawn to scale. The coordinate system we use is shown. The thermoelectric modules are denoted by Mi. The thermoelectric devices are actioned by imposing electric currents Ii with DC voltage power supplies Vi. The i denotes the first (1) and second (2) module. The rectangular plate is kept hot by circulating warm water in the reservoir. Temperature is measured in the top of module one (M1).
  • Figure 2. Scheme of two coupled thermoelectric devices. This study is devoted to the thermal analysis of the thermoelectric materials denoted by n type. The devices are actioned by injecting an electric current Ii. The thickness (width) is denoted by Li. The i denotes the first (1) and second (2) device.
  • Figure 3. ∆T as function of the electric current. (a) single device; (b) coupled devices—experimental measurements.
  • Figure 4. ∆T as function of the electric current. (a) single device; (b) coupled devices—theoretical predictions.
  • Figure 5. (a) temperature distribution along coupled devices; (b) entropy generation profile. For clarity in the Ṡ profile comparison, the blue line is multiplied by a factor of 3.98 and the left part of the black line (−1 < x < 0) is multiplied by 7.99—theoretical predictions.
  • Figure 6. Total entropy generation Ṡ as function of the applied electric current. (a) single device; (b) coupled devices—theoretical predictions.
  • Figure 7. Thermal figure of merit ZTh as a function of the total entropy generation Ṡ. (a) single device; (b) coupled devices. In (b), each of the curves displayed is generated by varying J2 from 0 to 1.6—theoretical predictions.

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CITATION STYLE

APA

Rojas, J. A., Rivera, I., Figueroa, A., & Vázquez, F. (2016). Coupled thermoelectric devices: Theory and experiment. Entropy, 18(7). https://doi.org/10.3390/e18070255

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