Usage Areas and Thermal Performance of Nanofluids and Nanoparticles

Edip Taşkesen; Khandan Roshanaeı; Mehmet Özkaymak

Research Article

Usage Areas and Thermal Performance of Nanofluids and Nanoparticles

Year 2021, Volume: 2 Issue: 2, 79 - 84, 15.12.2021

Edip Taşkesen Khandan Roshanaeı Mehmet Özkaymak

Abstract

In the study, it has been observed that there are many alternatives for the usage areas of nanofluids formed by dispersing solid particles of nanometric size (1-100 nm) in a basic fluid, as well as these fluids are efficient in both solar energy systems and other thermal systems. In this study, widely used nanofluids in heating and cooling systems and their application areas were investigated. It was observed that when nanofluids with different parameters are used, it affects thermal conductivity efficiency.

Keywords

Nanofluids, heat transfer, applications

References

Colla, L., Fedele, L., Manca, O., Marinelli, L., and Nardini, S., ‘Experimental and numerical investigation on forced convection in circular tubes with nanofluids’, Heat Transfer Engineering, 37 (13–14): 1201–1210 (2016).
Yu, W. and Choi, S. U. S., ‘The role of interfacial layers in the enhanced thermal conductivity of nanofluids: a renovated Maxwell model’, Journal Of Nanoparticle Research, 5 (1): 167–171 (2003).
Arshad, A., Jabbal, M., Yan, Y., and Reay, D., ‘A review on graphene based nanofluids: Preparation, characterization and applications’, Journal Of Molecular Liquids, 279: 444–484 (2019).
Devendiran, D. K. and Amirtham, V. A., ‘A review on preparation, characterization, properties and applications of nanofluids’, Renewable And Sustainable Energy Reviews, 60: 21–40 (2016).
Bashirnezhad, K., Bazri, S., Safaei, M. R., Goodarzi, M., Dahari, M., Mahian, O., Dalkılıça, A. S., and Wongwises, S., ‘Viscosity of nanofluids: a review of recent experimental studies’, International Communications In Heat And Mass Transfer, 73: 114–123 (2016).
Aglawe, K. R., Yadav, R. K., and Thool, S. B., ‘Preparation, applications and challenges of nanofluids in electronic cooling: A systematic review’, Materials Today: Proceedings, (2021).
Tawfik, M. M., ‘Experimental studies of nanofluid thermal conductivity enhancement and applications: A review’, Renewable And Sustainable Energy Reviews, 75 (November 2016): 1239–1253 (2017).
Choi, S. S. and Eastman, A. A., ‘Enhancing thermal conductiivity of fluids with nanoparticles’, (1995).
Heris, S. Z., Etemad, S. G., and Esfahany, M. N., ‘Experimental investigation of oxide nanofluids laminar flow convective heat transfer’, International Communications In Heat And Mass Transfer, 33 (4): 529–535 (2006).
Abbassi, Y., Talebi, M., Shirani, A. S., and Khorsandi, J., ‘Experimental investigation of TiO2/Water nanofluid effects on heat transfer characteristics of a vertical annulus with non-uniform heat flux in non-radiation environment’, Annals Of Nuclear Energy, 69: 7–13 (2014).
Ali, H. M., Ali, H., Liaquat, H., Maqsood, H. T. Bin, and Nadir, M. A., ‘Experimental investigation of convective heat transfer augmentation for car radiator using ZnO–water nanofluids’, Energy, 84: 317–324 (2015).
Li, Q. and Xuan, Y.-M., ‘Flow and Heant Transfer Performances of Nanofluids Inside Small Hydraulic Diameter Flat Tube’, Journal Of Engineering Thermophysics, 25 (2): 305–307 (2004).
Tekir, M., Taskesen, E., Aksu, B., Gedik, E., and Arslan, K., ‘Comparison of bi-directional multi-wave alternating magnetic field effect on ferromagnetic nanofluid flow in a circular pipe under laminar flow conditions’, Applied Thermal Engineering, 179: 115624 (2020).
Baskar, S., Chandrasekaran, M., Vinod Kumar, T., Vivek, P., and Karikalan, L., ‘Experimental studies on convective heat transfer coefficient of water/ethylene glycol-carbon nanotube nanofluids’, International Journal Of Ambient Energy, 41 (3): 296–299 (2020).
Saidur, R., Leong, K. Y., and Mohammed, H. A., ‘A review on applications and challenges of nanofluids’, Renewable And Sustainable Energy Reviews, 15 (3): 1646–1668 (2011).
Elango, T., Kannan, A., and Murugavel, K. K., ‘Performance study on single basin single slope solar still with different water nanofluids’, Desalination, 360: 45–51 (2015).
Olfian, H., Ajarostaghi, S. S. M., and Ebrahimnataj, M., ‘Development on evacuated tube solar collectors: A review of the last decade results of using nanofluids’, Solar Energy, 211: 265–282 (2020).

Year 2021, Volume: 2 Issue: 2, 79 - 84, 15.12.2021

Edip Taşkesen Khandan Roshanaeı Mehmet Özkaymak

Abstract

References

Colla, L., Fedele, L., Manca, O., Marinelli, L., and Nardini, S., ‘Experimental and numerical investigation on forced convection in circular tubes with nanofluids’, Heat Transfer Engineering, 37 (13–14): 1201–1210 (2016).
Yu, W. and Choi, S. U. S., ‘The role of interfacial layers in the enhanced thermal conductivity of nanofluids: a renovated Maxwell model’, Journal Of Nanoparticle Research, 5 (1): 167–171 (2003).
Arshad, A., Jabbal, M., Yan, Y., and Reay, D., ‘A review on graphene based nanofluids: Preparation, characterization and applications’, Journal Of Molecular Liquids, 279: 444–484 (2019).
Devendiran, D. K. and Amirtham, V. A., ‘A review on preparation, characterization, properties and applications of nanofluids’, Renewable And Sustainable Energy Reviews, 60: 21–40 (2016).
Bashirnezhad, K., Bazri, S., Safaei, M. R., Goodarzi, M., Dahari, M., Mahian, O., Dalkılıça, A. S., and Wongwises, S., ‘Viscosity of nanofluids: a review of recent experimental studies’, International Communications In Heat And Mass Transfer, 73: 114–123 (2016).
Aglawe, K. R., Yadav, R. K., and Thool, S. B., ‘Preparation, applications and challenges of nanofluids in electronic cooling: A systematic review’, Materials Today: Proceedings, (2021).
Tawfik, M. M., ‘Experimental studies of nanofluid thermal conductivity enhancement and applications: A review’, Renewable And Sustainable Energy Reviews, 75 (November 2016): 1239–1253 (2017).
Choi, S. S. and Eastman, A. A., ‘Enhancing thermal conductiivity of fluids with nanoparticles’, (1995).
Heris, S. Z., Etemad, S. G., and Esfahany, M. N., ‘Experimental investigation of oxide nanofluids laminar flow convective heat transfer’, International Communications In Heat And Mass Transfer, 33 (4): 529–535 (2006).
Abbassi, Y., Talebi, M., Shirani, A. S., and Khorsandi, J., ‘Experimental investigation of TiO2/Water nanofluid effects on heat transfer characteristics of a vertical annulus with non-uniform heat flux in non-radiation environment’, Annals Of Nuclear Energy, 69: 7–13 (2014).
Ali, H. M., Ali, H., Liaquat, H., Maqsood, H. T. Bin, and Nadir, M. A., ‘Experimental investigation of convective heat transfer augmentation for car radiator using ZnO–water nanofluids’, Energy, 84: 317–324 (2015).
Li, Q. and Xuan, Y.-M., ‘Flow and Heant Transfer Performances of Nanofluids Inside Small Hydraulic Diameter Flat Tube’, Journal Of Engineering Thermophysics, 25 (2): 305–307 (2004).
Tekir, M., Taskesen, E., Aksu, B., Gedik, E., and Arslan, K., ‘Comparison of bi-directional multi-wave alternating magnetic field effect on ferromagnetic nanofluid flow in a circular pipe under laminar flow conditions’, Applied Thermal Engineering, 179: 115624 (2020).
Baskar, S., Chandrasekaran, M., Vinod Kumar, T., Vivek, P., and Karikalan, L., ‘Experimental studies on convective heat transfer coefficient of water/ethylene glycol-carbon nanotube nanofluids’, International Journal Of Ambient Energy, 41 (3): 296–299 (2020).
Saidur, R., Leong, K. Y., and Mohammed, H. A., ‘A review on applications and challenges of nanofluids’, Renewable And Sustainable Energy Reviews, 15 (3): 1646–1668 (2011).
Elango, T., Kannan, A., and Murugavel, K. K., ‘Performance study on single basin single slope solar still with different water nanofluids’, Desalination, 360: 45–51 (2015).
Olfian, H., Ajarostaghi, S. S. M., and Ebrahimnataj, M., ‘Development on evacuated tube solar collectors: A review of the last decade results of using nanofluids’, Solar Energy, 211: 265–282 (2020).

There are 17 citations in total.

Details

Primary Language	English
Subjects	Engineering
Journal Section	Research Articles
Authors	Edip Taşkesen 0000-0002-3052-9883 Khandan Roshanaeı 0000-0002-1469-8812 Mehmet Özkaymak 0000-0002-4575-8988
Publication Date	December 15, 2021
Submission Date	June 19, 2021
Published in Issue	Year 2021 Volume: 2 Issue: 2

Cite

APA	Taşkesen, E., Roshanaeı, K., & Özkaymak, M. (2021). Usage Areas and Thermal Performance of Nanofluids and Nanoparticles. Journal of Soft Computing and Artificial Intelligence, 2(2), 79-84.
AMA	Taşkesen E, Roshanaeı K, Özkaymak M. Usage Areas and Thermal Performance of Nanofluids and Nanoparticles. JSCAI. December 2021;2(2):79-84.
Chicago	Taşkesen, Edip, Khandan Roshanaeı, and Mehmet Özkaymak. “Usage Areas and Thermal Performance of Nanofluids and Nanoparticles”. Journal of Soft Computing and Artificial Intelligence 2, no. 2 (December 2021): 79-84.
EndNote	Taşkesen E, Roshanaeı K, Özkaymak M (December 1, 2021) Usage Areas and Thermal Performance of Nanofluids and Nanoparticles. Journal of Soft Computing and Artificial Intelligence 2 2 79–84.
IEEE	E. Taşkesen, K. Roshanaeı, and M. Özkaymak, “Usage Areas and Thermal Performance of Nanofluids and Nanoparticles”, JSCAI, vol. 2, no. 2, pp. 79–84, 2021.
ISNAD	Taşkesen, Edip et al. “Usage Areas and Thermal Performance of Nanofluids and Nanoparticles”. Journal of Soft Computing and Artificial Intelligence 2/2 (December 2021), 79-84.
JAMA	Taşkesen E, Roshanaeı K, Özkaymak M. Usage Areas and Thermal Performance of Nanofluids and Nanoparticles. JSCAI. 2021;2:79–84.
MLA	Taşkesen, Edip et al. “Usage Areas and Thermal Performance of Nanofluids and Nanoparticles”. Journal of Soft Computing and Artificial Intelligence, vol. 2, no. 2, 2021, pp. 79-84.
Vancouver	Taşkesen E, Roshanaeı K, Özkaymak M. Usage Areas and Thermal Performance of Nanofluids and Nanoparticles. JSCAI. 2021;2(2):79-84.