Authors have methodically investigated the alternative energy technologies based upon thermoelectricity generation. Firstly, its power is systematically investigated under various work conditions in thermoelectric applications. In addition, they have modelled, designed, and constructed the thermoelectric power system. Moreover, they have invented a state-of-the-art table-top instrument that may evaluate several critical thermoelectric characters in situ. Several aspects of the thermoelectric features are characterized in situ that include the efficiency, force response curve, current-voltage (i.e., I-V) curve, power-voltage (P-V) curve, and the power versus temperature (P-T) responses. Furthermore, they have successfully built a high-power heat harvester and have applied to the automotive case study in details. Finally, they have obtained the multi-stack thermoelectric devices that have improved characters; e.g., both the power output and the thermoelectric efficiency have improved in comparison to the devices commercially available. The investigation leads to 19+% efficiency in triple stack devices and 10+% in dual-stack.
| Published in |
American Journal of Science, Engineering and Technology (Volume 5, Issue 2)
This article belongs to the Special Issue Advances in Thermoelectric Generation and Renewable Energies |
| DOI | 10.11648/j.ajset.20200502.15 |
| Page(s) | 80-88 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Thermoelectric Efficiency, High Power Harvester, In Situ Characterization
| [1] | The Paris Agreement.https://unfccc.int/process-and-meetings/the-paris-agreement/the-paris-agreement. |
| [2] | Brass J N, Carley S, Maclean L M, et al (2012). Power for Development: A Review of Distributed Generation Projects in the Developing World. Social Science Electronic Publishing. 37 (9): 107-136. |
| [3] | Clark W W (2010). Sustainable Communities Design Handbook. Germany, Elsevier Press. 65-81. |
| [4] | CHEN Gang (2011). Theoretical Efficiency of Solar Thermoelectric Energy Generators. Journal of Applied Physics. 109 (10): 104908. |
| [5] | DENG Yueguang, LIU Jing (2009). Recent Advances in Direct Solar Thermal Power Generation. Journal of Renewable Sustainable Energy. 1 (5): 052701. |
| [6] | Tritt T M, Subramanian M A (2006). Thermoelectric Materials, Phenomena, and Applications: A Bird’s Eye View. MRS Bulletin, 31 (03): 188-198. |
| [7] | Baranowski L L, Warren E L, Toberer E S (2014). High-Temperature High-Efficiency Solar Thermoelectric Generators. Energy Procedia. 49 (6): 1460-1469. |
| [8] | Thomson W (1857). On a Mechanical Theory of Thermoelectric Currents. Proceedings of the Royal Society of Edinburgh. 3: 91-98. |
| [9] | Weisse J M. Thermoelectric Generators. http://large.stanford.edu/courses/2010/ph240/weisse1/. |
| [10] | JIN Anjun, LIU Dawei, PENG Wenbo, et al (2013). Research and Applications of the High-Power Thermoelectric Generation Technology. Sustainable Energy. 3: 1-7. |
| [11] | YANG Dajiang, YIN Huiming (2011). Energy Conversion Efficiency of a Novel Hybrid Solar System for Photovoltaic, Thermoelectric, and Heat Utilization. IEEE Transactions on Energy Conversion. 26 (2): 0-670. |
| [12] | GAO Min, Rowe D M (2007). Conversion Efficiency of Thermoelectric Combustion Systems. IEEE Transactions on Energy Conversion. 22 (2): 528-534. |
| [13] | HUA Tian, NA Jiang, QI Jia, et al (2015). Comparison of Segmented and Traditional Thermoelectric Generator for Waste Heat Recovery of Diesel Engine. Energy Procedia. 75: 590-596. |
| [14] | Quan, R., Liu, G., Zhou, W., & Huang, L. (2018). Energy Management of Automobile Exhaust Thermoelectric Hybrid Power Based on Maximum Power Point Tracking and Fuzzy Logic Control. International Forum on Management, Education & Information Technology Application. |
| [15] | COOK B, CHAN T, DEZSI G, et al (2014). High-performance three-stage cascade thermo- electric devices with 20% efficiency. Electron. Mater. 44 (6): 1936-1942. |
| [16] | LIU Dawei, JIN Anjun, et al (2016). Preparation and characterization of segmented stacking for thermoelectric power generation. Clean Technologies and Environmental Policy. 18 (4): 1203-1210. |
| [17] | JUN Mao, LIU Zihang, REN Zhifeng (2016). Size Effect in Thermoelectric Materials. Nature. 1 (1): 16028. |
| [18] | LIU Dawei, JIN Anjun, et al (2015). Developing instrumentation to characterize thermoelectric generator modules. Review of Scientific Instruments. 86 (3): 034703. |
| [19] | NOLAS G, SHARP J, GOLDSMID H (2001). Thermoelectrics basic principles and new material developments. Berlin: Springer. |
| [20] | CRANE D, KOSSAKOVSKI D, BELL L (2009). Modeling the building blocks of a 10% efficient segmented thermoelectric power generator. Journal of Electronic Materials. 38 (7): 1382-1386. |
| [21] | JIN Anjun, LIU Dawei. Test System Of Thermoelectric Module and Test Method for Thermoelectric Modules: USPCT-16659195 [P]. http://www.freepatentsonline.com/y2017/0115245.html. |
| [22] | SOLLA S, RIEDEL E (1981). Vortex excitations and specific heat of the planar model in two dimensions. Physical Review B Condensed Matter. 23 (11): 6008-6012. |
| [23] | Bao LL, AJ Jin et al (2016). Studies of thermoelectric device for automobile tail-pipe energy harvest: design, fabrication and performance. Chinese Journal of Power Sources. (12): 2463-2468. |
| [24] | Notes: SolidWorks is a solid modeling computer-aided design (CAD) and computer-aided engineering (CAE) computer program. SolidWorks Copyright is owned by SOLIDWORKS Corp, USA. |
| [25] | Matlab™ provides a multi-paradigm numerical computing environment. Matlab Copyright is owned by The MathWorks, Inc, USA. |
| [26] | JIN Anjun, ZHANG Yuanming (2017), Systematic studies on building the high output thermoelectric power generation. International Journal of Science, Technology and Society. 4 (5): 112-119. |
| [27] | WOJCIECHOWSKI K, ZVBALA R, LESZCZYNSKI J, et al (2012). Performance characterization of high-efficiency segmented Bi2Te3/CoSb3 unicouples for thermo- electric generators [C]. 9th European Conference on Thermoelectric. Aalborg. Aalborg University. 667-470. |
| [28] | HU Xiaokai, JOOD P, OHTA M, et al (2016). Power generation from nanostructured PbTe-based thermoelectrics: comprehensive development from materials to modules. Energy & Environmental Science. 9 (2): 517-529. |
| [29] | Wojciechowski KT, Zybala R, Leszczynski J, et. al. (2012) Performance characterization of high-efficiency segmented Bi2Te3/CoSb3 unicouples for thermo- electric generators. 9th European Conference on Thermoelectric. 667-470 |
| [30] | Hu XK, Jood P, Ohta M, Kunii M, et. al. (2015) Power generation from nanostructured PbTe-based thermoelectrics. |
APA Style
Zhihao Li, Jiapeng Su, Dawei Liu, Anjun Jin. (2020). Systematic Studies of the High Output Thermoelectric Power Generation. American Journal of Science, Engineering and Technology, 5(2), 80-88. https://doi.org/10.11648/j.ajset.20200502.15
ACS Style
Zhihao Li; Jiapeng Su; Dawei Liu; Anjun Jin. Systematic Studies of the High Output Thermoelectric Power Generation. Am. J. Sci. Eng. Technol. 2020, 5(2), 80-88. doi: 10.11648/j.ajset.20200502.15
AMA Style
Zhihao Li, Jiapeng Su, Dawei Liu, Anjun Jin. Systematic Studies of the High Output Thermoelectric Power Generation. Am J Sci Eng Technol. 2020;5(2):80-88. doi: 10.11648/j.ajset.20200502.15
Share This Article
Twitter
Linked In
Facebook
Copy
Download@article{10.11648/j.ajset.20200502.15,
author = {Zhihao Li and Jiapeng Su and Dawei Liu and Anjun Jin},
title = {Systematic Studies of the High Output Thermoelectric Power Generation},
journal = {American Journal of Science, Engineering and Technology},
volume = {5},
number = {2},
pages = {80-88},
doi = {10.11648/j.ajset.20200502.15},
url = {https://doi.org/10.11648/j.ajset.20200502.15},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajset.20200502.15},
abstract = {Authors have methodically investigated the alternative energy technologies based upon thermoelectricity generation. Firstly, its power is systematically investigated under various work conditions in thermoelectric applications. In addition, they have modelled, designed, and constructed the thermoelectric power system. Moreover, they have invented a state-of-the-art table-top instrument that may evaluate several critical thermoelectric characters in situ. Several aspects of the thermoelectric features are characterized in situ that include the efficiency, force response curve, current-voltage (i.e., I-V) curve, power-voltage (P-V) curve, and the power versus temperature (P-T) responses. Furthermore, they have successfully built a high-power heat harvester and have applied to the automotive case study in details. Finally, they have obtained the multi-stack thermoelectric devices that have improved characters; e.g., both the power output and the thermoelectric efficiency have improved in comparison to the devices commercially available. The investigation leads to 19+% efficiency in triple stack devices and 10+% in dual-stack.},
year = {2020}
}
TY - JOUR T1 - Systematic Studies of the High Output Thermoelectric Power Generation AU - Zhihao Li AU - Jiapeng Su AU - Dawei Liu AU - Anjun Jin Y1 - 2020/05/19 PY - 2020 N1 - https://doi.org/10.11648/j.ajset.20200502.15 DO - 10.11648/j.ajset.20200502.15 T2 - American Journal of Science, Engineering and Technology JF - American Journal of Science, Engineering and Technology JO - American Journal of Science, Engineering and Technology SP - 80 EP - 88 PB - Science Publishing Group SN - 2578-8353 UR - https://doi.org/10.11648/j.ajset.20200502.15 AB - Authors have methodically investigated the alternative energy technologies based upon thermoelectricity generation. Firstly, its power is systematically investigated under various work conditions in thermoelectric applications. In addition, they have modelled, designed, and constructed the thermoelectric power system. Moreover, they have invented a state-of-the-art table-top instrument that may evaluate several critical thermoelectric characters in situ. Several aspects of the thermoelectric features are characterized in situ that include the efficiency, force response curve, current-voltage (i.e., I-V) curve, power-voltage (P-V) curve, and the power versus temperature (P-T) responses. Furthermore, they have successfully built a high-power heat harvester and have applied to the automotive case study in details. Finally, they have obtained the multi-stack thermoelectric devices that have improved characters; e.g., both the power output and the thermoelectric efficiency have improved in comparison to the devices commercially available. The investigation leads to 19+% efficiency in triple stack devices and 10+% in dual-stack. VL - 5 IS - 2 ER -
Information
Email: