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Thermoelectric Energy Harvesting 2016-2026: Technologies, devices & applications for thermoelectric generators
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IDTechEx
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2016-04
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97 pages
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Report
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Table of Contents 1. EXECUTIVE SUMMARY AND CONCLUSIONS 1.1. Additional challenges and opportunities for thermoelectric devices 2. INTRODUCTION 2.1. The Seebeck and Peltier effects 2.2. Designing for thermoelectric applications 2.3. Thin film thermoelectric generators 2.4. Material choices 2.5. Organic thermoelectrics - PEDOT:PSS, not just a transparent conductor 2.6. Bi-functional thermoelectric generator/pre-cooler: DC power from aircraft bleed air 3. OTHER PROCESSING TECHNIQUES 3.1. Manufacturing of flexible thermoelectric generators 3.2. AIST technology details 4. APPLICATIONS 4.1. Automotive applications 4.1.1. BMW 4.1.2. Ford 4.1.3. Volkswagen 4.1.4. Challenges of Thermoelectrics for Vehicles 4.2. Wireless sensing 4.2.1. TE-qNODE 4.2.2. TE-CORE 4.2.3. EverGen PowerStrap 4.2.4. WiTemp 4.2.5. GE- Logimesh 4.3. Aerospace 4.4. Wearable/implantable thermoelectrics 4.5. Building and home automation 4.6. Other applications 4.6.1. Micropelt-MSX 4.6.2. PowerPot¢â 5. INTERVIEWS - COMMERCIALIZATION CONSIDERATIONS 5.1. Ford 5.2. Microsemi 5.3. MSX Micropelt 5.4. Rolls Royce 5.5. TRW 5.6. Volvo 6. MARKET FORECASTS 7. COMPANY PROFILES 7.1. Alphabet Energy, Inc. 7.2. EVERREDtronics Ltd 7.3. Ferrotec Corporation 7.4. Gentherm 7.5. Global Thermoelectric (now Gentherm) 7.6. GMZ Energy 7.7. greenTEG 7.8. Hi Z Technology, Inc 7.9. KELK Ltd. 7.10. Laird / Nextreme 7.11. Marlow 7.12. mc10 7.13. Micropelt GmbH 7.14. National Institute of Advanced Industrial Science & Technology (AIST) 7.15. Novus 7.16. O-Flexx 7.17. OTEGO 7.18. Perpetua 7.19. RGS Development 7.20. Romny Scientific 7.21. Tellurex Corporation 7.22. Thermolife Energy Corporation 7.23. Yamaha
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