posted on 2018-05-18, 09:28authored byRamy Mesalam, Hugo R. Williams, Richard M. Ambrosi, Jorge García-Cañadas, Keith Stephenson
Thermoelectric devices have potential energy conversion applications ranging from space exploration
through to mass-market products. Standardised, accurate and repeatable high-throughput measurement of their
properties is a key enabling technology. Impedance spectroscopy has shown promise as a tool to parametrically
characterise thermoelectric modules with one simple measurement. However, previously published models which
attempt to characterise fundamental properties of a thermoelectric module have been found to rely on heavily
simplified assumptions, leaving its validity in question. In this paper a new comprehensive impedance model is
mathematically developed. The new model integrates all relevant transport phenomena: thermal convection,
radiation, and spreading-constriction at junction interfaces. Additionally, non-adiabatic internal surface boundary
conditions are introduced for the first time. These phenomena were found to significantly alter the low and high
frequency response of Nyquist spectra, showing their necessity for accurate characterisation. To validate the
model, impedance spectra of a commercial thermoelectric module was experimentally measured using a new and
parametrically fitted. Technique precision is investigated using a Monte-Carlo residual resampling approach. A
complete characterisation of all key thermoelectric properties as a function of temperature is validated with
material property data provided by the module manufacturer. Additionally, by firstly characterising the module in
vacuum, the ability to characterise a heat transfer coefficient for free and forced convection is demonstrated. The
model developed in this study is therefore a critical enabler to potentially allow impedance spectroscopy to
characterise and monitor manufacturing and operational defects in practical thermoelectric modules across
multiple sectors, as well as promote new sensor technologies.
Funding
Funding for RM was provided in part via EPSRC grants EP/L505006/1, EP/M506564/1 and
EP/M508081/1. The authors gratefully acknowledge the assistance provided by chief technician Tony Crawford
at Leicester’s Space Research Centre, Dr D. Weston and Dr S. Gill, the European Space Agency and the role of
the EPSRC Thermoelectric Network in fostering the collaboration.
History
Citation
Applied Energy, 2018, 226, pp. 1208-1218
Author affiliation
/Organisation/COLLEGE OF SCIENCE AND ENGINEERING/Department of Engineering
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