Evaluation of Applicability of Thermophotovoltaic System in Combi Boiler

In this study, thermophotovoltaic (TPV) system components are examined and introduced, and theoretically, it is given information about the applicability of the system in a combi boiler. The latest developments in the components of the TPV system, heat source, emitter, filter and TPV cell, are explained. Also, the study state how the TPV system should be integrated into a combi boiler. It is estimated that the TPV system integrated into the combi boiler can produce 36.96 kWh per month in the case that it has 2% electrical efficiency. The study is stated that the higher TPV system electric power output can be achieved if the emitter, the filter and the TPV cell are matched in harmony with each other in the combi boiler, the distances of these components and the emitter-filter dimensions are arranged. Thus, a standard family in Turkey can be supplied a certain amount of monthly energy demand. Also, it is explained in the study the issues that should be taken into consideration when this system is integrated into the combi boiler.

Anahtar Kelimeler:

Thermophotovoltaic, combi boiler, electrical generation

Evaluation of Applicability of Thermophotovoltaic System in Combi Boiler

In this study, thermophotovoltaic (TPV) system components are examined and introduced, and theoretically, it is given information about the applicability of the system in combi boiler. The latest developments in the components of the TPV system, heat source, emitter, filter and TPV cell, are explained. In addition, the study state how the TPV system should be integrated into a combi boiler. It is estimated that TPV system integrated into the combi boiler can produce 36.96 kWh per month in the case that it has 2% electrical efficiency. The study is stated that the higher TPV system electric power output can be achieved if the emitter, the filter and the TPV cell are matched in harmony with each other in the combi boiler, the distances of these components and the emitter-filter dimensions are arranged. Thus, a standard family in Turkey can be supplied a certain amount of the monthly energy demand. In addition, it is explained in the study the issues that should be taken into consideration when this system is integrated into the combi boiler.

Keywords:

Thermophotovoltaic, Combi boiler, Electrical generation,

PDF

___

[1] https://www.enerji.gov.tr/tr-TR/Sayfalar/Dogal-Gaz, 04.07.2019. [2] http://www.tpao.gov.tr/?mod=sektore-dair&contID=43, 13.09.2019.[3] Mao L., and Ye H. “New development of one-dimensional Si/SiO2 photonic crystals filter for thermophotovoltaic applications”, Renewable Energy, 35(1), 249-256, (2010).[4] Sansoni P., Fontan, D., Francini F., Jafrancesco D., Gabetta G., Casale M., and Toniato G. “Evaluation of elliptical optical cavity for a combustion thermophotovoltaic system” Solar Energy Materials and Solar Cells, 171, 282-292, (2017).[5] Heide, J. V. D. “Thermophotovoltaics”, Elsevier pp. 603-618, (2012).[6] Bitnar B., Durisch W., and Holzner R. “Thermophotovoltaics on the move to applications”, Applied Energy, 105, 430-438, (2013).[7] Daneshvar H., Prinja R., and Kherani N. P. “Thermophotovoltaics: Fundamentals, challenges and prospects”, Applied Energy, 159, 560-575, (2015).[8] Alipoor A., and Saidi M. H. “Numerical study of hydrogen-air combustion characteristics in a novel micro-thermophotovoltaic power generator”, Applied energy, 199, 382-399, (2017).[9] Datas A., and Vaillon R. “Thermionic-enhanced near-field thermophotovoltaics”, Nano Energy, 61, 10-17, (2019).[10] Silva-Oelker G., Jerez-Hanckes C., and Fay P. “High-temperature tungsten-hafnia optimized selective thermal emitters for thermophotovoltaic applications”, Journal of Quantitative Spectroscopy and Radiative Transfer, 231, 61-68, (2019).[11] Bitnar B., Durisch W., Mayor J. C., Sigg H., and Tschudi H. R. “Characterisation of rare earth selective emitters for thermophotovoltaic applications”, Solar Energy Materials and Solar Cells, 73(3), 221-234, (2002).[12] Gentillon P., Southcott J., Chan Q. N., and Taylor R. A. “Stable flame limits for optimal radiant performance of porous media reactors for thermophotovoltaic applications using packed beds of alumina”, Applied Energy, 229, 736-744, (2018).[13] Shoaei E. “Performance assessment of thermophotovoltaic application in steel industry” Solar Energy Materials and Solar Cells, 157, 55-64, (2016).[14] Wu H., Kaviany M., and Kwon O. C “Thermophotovoltaic power conversion using a superadiabatic radiant burner”, Applied Energy, 209, 392-399, (2018).[15] Bermel P., Ghebrebrhan M., Chan W., Yeng Y. X., Araghchini M., Hamam R., and Johnson S. G. “Design and global optimization of high-efficiency thermophotovoltaic systems”, Optics Express, 18(103), A314-A334, (2010).[16] Zeyghami M., Stefanakos E., and Goswami, D. Y. “Development of one-dimensional photonic selective emitters for energy harvesting applications”, Solar Energy Materials and Solar Cells, 163, 191-199, (2017).[17] Lau J. Z. J., Bong V. N. S., and Wong B. T.“Parametric investigation of nano-gap thermophotovoltaic energy conversion”, Journal of Quantitative Spectroscopy and Radiative Transfer, 171, 39-49, (2016).[18] Kim J. M., Park K. H., Kim D. S., Hwang B. Y., Kim S. K., Chae H. M., and. Kim Y. S. “Design and fabrication of spectrally selective emitter for thermophotovoltaic system by using nano-imprint lithography”, Applied Surface Science, 429, 138-143, (2018). [19] Chen X. L., Tian C. H., Che Z. X., and Chen T. P. “Selective metamaterial perfect absorber for infrared and 1.54 μm laser compatible stealth technology”, Optik, 172, 840-846, (2018).[20] Binidra K., Miloua R., Khadraoui M., Kebbab Z., Bouzidi A., and Benramdane N. “Spectral control in thermophotovoltaic systems by optimized one-dimensional photonic crystals”, Optic, 156, 879-885, (2018).[21] Durisch, W. and Bitnar B. “Novel thin film thermophotovoltaic system”, Solar Energy Materials and Solar Cells, 94(6), 960-965, (2010).[22] Meharrar F. Z., Belfar A., Aouad I., Giudicelli E., Cuminal Y., and Aït-Kaci H. “Analysis of the GaSb-p+/GaSb-p/GaSb-n+/GaSb-n structure performances at room temperature, for thermo-photovoltaic applications”, Optik, 175, 138-147, (2018).[23] Barbieri E. S., Spina P. R., and Venturini M “Analysis of innovative micro-CHP systems to meet household energy demands”, Applied Energy, 97, 723-733 (2012).[24] Ferrari C., Melino F., Pinelli M., Spina P. R., and Venturini M. “Overview and status of thermophotovoltaic systems”, Energy Procedia, 45, 160-169.169, (2014).[25] Palfinger G., Bitnar B., Durisc W., Mayor J. C., Grützmacher D., and Gobrecht J. “Cost estimates of electricity from a TPV residential heating system”, In AIP Conference Proceedings ,653- 1, 29-37, (2003).[26] Qiu K., and Hayden A. C. S. “Implementation of a TPV integrated boiler for micro-CHP in residential buildings”, Applied Energy, 134, 143-149, (2014).[27]https://www.buderus.com/ocsmedia/optimized/full/o378404v272_TR_Buderus_LogamaxPlus_GB062_210x297_Brosur.pdf, 3.07.2019.[28] Kocaman B., “The Importance of Choosing the Tariff in the Use of Electronic Meter”, BEU Journal of Science, 1(1), 59-65 (2012).[29] Royne A., Dey C. J., and Mills D. R. “Cooling of photovoltaic cells under concentrated illumination: a critical review”, Solar Energy Materials and Solar Cells, 86(4), 451-483, (2005).[30] Kostić L. T., Pavlović T. M., and Pavlović Z. T. “Optimal design of orientation of PV/T collector with reflectors”, Applied Energy, 87(10), 3023-3029, (2010).[31]http://www.mevzuat.gov.tr/Metin.Aspx?MevzuatKod=7.5.19783&MevzuatIliski=0&sourceXmlSearch=sat%C4%B1%C5%9F%20sonras%C4%B1, 16.01.2019.