ac

Improving the Effectiveness of Heat Pipe solar Connector by using Nano fluid

Authors

  • Mohammed Ridha H Alhakeem Ministry of Oil, Midland Refineries company , Baghdad, Iraq

DOI:

10.47709/brilliance.v2i3.1716

Keywords:

Solar Energy, Nano fluid, Nano technology

Dimension Badge Record



Abstract

This article provides a thorough analysis of current developments in the use of nano fluids in the sun collectors with heat pipes. Theoretical, numerical, and experimental papers that are current and relevant to the Applications of nanotechnology in this class of solar collectors. To provide a thorough overview of the effect of the nano fluid in enhancing heat pipe solar collectors, a large body of literature has been thoroughly researched and summarized. The effectiveness of heat pipe solar collectors can be significantly increased by using nano fluid, it was discovered certain tools.

Google Scholar Cite Analysis
Abstract viewed = 109 times

References

Al-Bahrani M, Bouaissi A, Cree A. Mechanical and electrical behaviors of self-sensing nanocomposite-based MWCNTs material when subjected to twist shear load. Mechanics of Advanced Materials and Structures. 2021 Jun 23;28(14):1488-97.

Javadi F., Saidur R. , Kamalisarvestani , M. Investigating performance improvement of solar collectors by using nanofluids . Renewable and Sustainable Energy Reviews 2013 ; 28 : 232-245.

Suman S., Khan M. , Pathak , M. Performance enhancement of solar collectors - A review .Renewable and Sustainable Energy Reviews 2015 ; 49 : 192–210.

Al-Bahrani M, Cree A. In situ detection of oil leakage by new self-sensing nanocomposite sensor containing MWCNTs. Applied Nanoscience. 2021 Sep;11(9):2433-45.

Xia X., Xia J. , Virkar A. Evaluation of potential for developing renewable sources of energy to facilitate development in developing countries. Proceedings of the Asia-Pacific power and energy engineering conference 2010 Chengdu ,China : 1-3.

Allamraju K. Materials used for renewable energy resources. Advanced Materials Manufacturing and Characterization 2013 ; 3 : 243-248.

Hussein A. Applications of nanotechnology in renewable energies - a comprehensive overview and understanding . Renewable and Sustainable Energy Reviews 2015 ; 42 : 460-476.

Thirugnanasambandam M., Iniyan S. , Goic , R. A review of solar thermal technologies. Renewable and Sustainable Energy Reviews 2010 ; 14 : 312-322.

Choi S. Enhancing thermal conductivity of fluids with nanoparticles. Developments and Applications of NonNewtonian Flows, ASME FED,Vol. 231/MD-66 1995 : 99-105.

Li Y. , Zhou J., Tung , S. , Schneider , E. , Xi , S. A review on development of nanofluid preparation and characterization . Powder Technology 2009 ; 196 : 89-101.

Bejan A., Karaus A. Heat Transfer Handbook . John Wiley and Sons 2003.

Faiz F., Zahir E. A comparative study of nanofluids for tuneable filter operation. International Journal of Engineering Research 2014 ; 3 : 9-12.

Hone J. Carbon nanotubes: thermal properties . In Dekker Encyclopedia of Nanoscience and Nanotechnology 2004.

Assael M., Chen C., Metaxa , N. , Wakeham , W. Thermal conductivity of suspensions of carbon nanotubes in water . International Journal of Thermophysics 2004 ; 25 : 971-985.

Al-Abboodi H, Fan H, Mhmood IA, Al-Bahrani M. The dry sliding wear rate of a Fe-based amorphous coating prepared on mild steel by HVOF thermal spraying. Journal of Materials Research and Technology. 2022 May 1;18:1682-91.

Adil A. , Gupta, S. , Ghosh , P. Numerical prediction of heat transfer characteristics of nanofluids in a minichannel flow. Journal of Energy 2014 ; Article ID 307520 : 1-7.

Chieruzzi M., Cerritelli G. , Miliozzi A. , Kenny J. Effect of nanoparticles on heat capacity of nanofluids based on molten salts as PCM for thermal energy storage . Nanoscale Research Letters 2013 ; 8 : 448-456.

Al-Bahrani M. The Manufacture and Testing of Self-Sensing CNTs Nanocomposites for Damage Detecting Applications (Doctoral dissertation, University of Plymouth).

Rashid F. , Dawood K., Hashim, A. Maximizing of solar absorption by (TiO2-water) nanofluid with glass mixture . International Journal of Research in Engineering & Technology 2014 ; 2 : 87-90.

Saidur R. , Leong K. , Mohammad H. A review on applications and challenges of nanofluids . Renewable and Sustainable Energy Reviews 2011 ; 15 : 1646-1668.

Shukla R. , Sumathy , K. , Erickson , P. , Gong , J. Recent advances in the solar water heating systems: A review . Renewable and Sustainable Energy Reviews 2013 ; 19 : 173–190.

Al?Bahrani M, Majdi HS, Abed AM, Cree A. An innovated method to monitor the health condition of the thermoelectric cooling system using nanocomposite?based CNTs. International Journal of Energy Research. 2022 May;46(6):7519-28.

Kalogirou S. Solar thermal collectors and applications. Progress in Energy and Combustion Science 2004 ; 30 : 231-295.

Jaisankar S. , Ananth J. , Thulasi S. , Jayasuthakar S. , Sheeba K. A comprehensive review on solar water heaters . Renewable and Sustainable Energy Reviews 2011 ; 15 : 3045-3050.

Wang Z., Yang W., Qiu F. , Zhang X. , Zhao X. Solar water heating : from theory, application , marketing and research. Renewable and Sustainable Energy Reviews 2015 ; 41 : 68-84.

Mishra R. , Garg V. , Tiwari G. Thermal modeling and development of characteristic equations of evacuated tubular collector (ETC) . Solar Energy 2015 ; 116 : 165-176.

Yu W., Xie H. A review on nanofluids : preparation, stability mechanisms and applications . Journal of Nanomaterials 2012 ; Article ID 435873 : 1-17.

Du B., Hu E., Kolhe M. An experimental platform for heat pipe solar collector testing . Renewable and Sustainable Energy Reviews 2013 ; 17 : 119-125.

Lu L., Liu Z., Xiao H. Thermal performance of an open thermosyphon using nanofluids for high-temperature evacuated tubular solar collectors Part 1: Indoor experiment . Solar Energy 2011 ; 85 : 379-387.

Senthil Kumar R., Manimaran R. , Ramadoss K. , Shankar N. Experimental analysis of nano fluid-charged solar water heater by solar tracking system. Archives of Applied Science Research 2012 ; 4 : 2582-2590.

Chougule S., Pise A. , Madane A. Performance of nanofluid-charged solar water heater by solar tracking system. International Conference on Advances in Engineering , Science and Management (ICAESM) , Nagapattinam , Tamil Nadu 2012 ; 247-253.

Moorthy M., Chui L. , Sharma K., Anuar S. Performance evaluation of evacuated tube solar collector using water-based titanium oxide (TiO2) nanofluid. Journal of Mechanical Engineering and Sciences 2012 ; 3 : 301-310. [34] Liu Z., Hu R. , Lu L., Zhao F. , Xiao H. Thermal performance of an open thermosyphon using nanofluid for evacuated tubular high temperature air solar collector . Energy Conversion and Management 2013 ; 73 : 135-143.

Chougule S., Sahu S. , Pise A. Thermal performance of two phase thermosyphon on flat-plate solar collectors using nanofluid. Journal of Solar Energy Engineering 2013 ; 136 : 1-5.

Aruna V., Channakaiah D., Murali , G. . A study on a flat plate type of solar water heater with an thermosyphon using different working fluid . Singaporean Journal of Scientific Research 2014 ; 6 : 132-135. [37] Saravanan M., Karunakaran N. Experimental analysis of heat pipe with V-trough solar collector. International Journal of Research in Advent Technology 2014 : 13-17.

Downloads

ARTICLE Published HISTORY

Submitted Date: 2022-09-11
Accepted Date: 2022-09-11
Published Date: 2022-09-11

How to Cite

Alhakeem, M. R. H. (2022). Improving the Effectiveness of Heat Pipe solar Connector by using Nano fluid. Brilliance: Research of Artificial Intelligence, 2(3), 171-176. https://doi.org/10.47709/brilliance.v2i3.1716

Issue

Vol. 2 No. 3 (2022): Brilliance: Research of Artificial Intelligence, Article Research November 2022

Section

Articles

License

Copyright (c) 2022 Mohammed Ridha H Alhakeem

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.