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RESEARCH PRODUCT
Design, assembly and characterization of silicide-based thermoelectric modules
Gunstein SkomedalLennart HolmgrenHugh MiddletonI. S. EreminG. N. IsachenkoMartin JaegleKarina TarantikNikolas VlachosMaria ManoliTheodora KyratsiDavid BerthebaudNhi Y. Dao TruongFranck GascoinGunstein SkomedalLennart HolmgrenHugh MiddletonI. S. EreminG. N. IsachenkoMartin JaegleKarina TarantikNikolas VlachosMaria ManoliTheodora KyratsiDavid BerthebaudNhi Y. Dao TruongFranck Gascoinsubject
Energy storageThermoelectric equipment02 engineering and technology7. Clean energyThermal expansionBismuthchemistry.chemical_compoundDegradationMagnesium silicideHigher manganese silicideSilicide0202 electrical engineering electronic engineering information engineeringHigher manganese silicidesMagnesiumThermo-Electric materialsThermal expansion mismatchDirect energy conversion[CHIM.MATE]Chemical Sciences/Material chemistryThermoelectric materialsMagnesium silicides[CHIM.THEO]Chemical Sciences/Theoretical and/or physical chemistryConversion directeFuel TechnologyThermal expansionSilicidesMaterials scienceMaximum power principleCharacterization020209 energyEnergy Engineering and Power Technologychemistry.chemical_elementMagnesium silicideThermoelectric moduleThermo-electric modulesElectronic engineering[CHIM.CRIS]Chemical Sciences/Cristallography[CHIM]Chemical SciencesManganeseRenewable Energy Sustainability and the EnvironmentEquivalent circuitsThermoelectricityEngineering physicsLead tellurideThermoelectric generatorCross-section areaNuclear Energy and EngineeringchemistryEnergy transferConventional materialsÉnergieMaterials propertiesThermoelectric generatorsMaterials testingdescription
ID: 1143 In: Energy conversion and management, 13-21. Summary: Highlights•Novel silicide-based thermoelectric modules were experimentally investigated.•The modules produced high power of 1.04 W at 405 °C and 3.24 W at 735 °C.•An estimated module efficiency of 5.3% represent the highest reported for silicide systems.AbstractSilicides have attracted considerable attention for use in thermoelectric generators due mainly to low cost, low toxicity and light weight, in contrast to conventional materials such as bismuth and lead telluride. Most reported work has focused on optimizing the materials properties while little has been done on module testing. In this work we have designed and tested modules based on N-type magnesium silicide Mg2(Si–Sn), abbreviated MGS, and P-type Higher Manganese Silicide, abbreviated HMS. The main novelty of our module design is the use of spring loaded contacts on the cold side which mitigate the effect of thermal expansion mismatch between the MGS and the HMS. We report tests carried out on three modules at different temperatures and electric loads. At a hot side temperature of 405 °C we obtained a maximum power of 1.04 W and at 735 °C we obtained 3.24 W. The power per thermoelectric material cross section area ranged from 1 to 3 W cm−2. We used the modeling tool COMSOL to estimate efficiencies at 405 and 735 °C and obtained values of 3.7% and 5.3% respectively – to our knowledge the highest reported value to date for silicide based modules. Post-test examination showed significant degradation of the N-type (MGS) legs at the higher hot side temperatures. Further work is underway to improve the lifetime and degradation issues.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2016-02-01 |