Heat transfer and pressure drop characteristics of Al2O 3-R141b nanorefrigerant in horizontal smooth circular tube

Procedia Engineering

Volumn 56, Issue , 2013, Pages 323-329

  Mahbubul, I M ^a   Saidur, R ^a   Amalina, M A ^a  

^a UNIVERSITY OF MALAYA   (Malaysia)

Author keywords

Flow boiling heat transfer coefficient; Nanofluid; Vapor quality; Volume concentration

Indexed keywords

EID: 84891698895     PISSN: 18777058     EISSN: None     Source Type: Conference Proceeding    
DOI: 10.1016/j.proeng.2013.03.126     Document Type: Conference Paper

References (15)

1. Peng, H., Ding, G., Hu, H., 2011. Influences of refrigerant-based nanofluid composition and heating condition on the migration of nanoparticles during pool boiling. Part I: Experimental measurement, International Journal of Refrigeration 34, p. 3770.
2. Wang, K., Ding, G., Jiang, W., 2005. "Development of nanorefrigerant and its rudiment property, "- 8th International Symposium on Fluid Control, Measurement and Visualization, Chengdu, China: China Aerodynamics Research Society.
3. Mahbubul, I.M., Fadhilah, S.A., Saidur, R., Leong, K.Y., Amalina, M.A., 2012. Thermophysical properties and heat transfer performance of Al2O3/R- 134a nanorefrigerants, International Journal of Heat and Mass Transfer [HMT9361; DOI: 10.1016/j.ijheatmasstransfer.2012.10.007].
4. Jiang, W., Ding, G., Peng, H., 2009. Measurement and model on thermal conductivities of carbon nanotube nanorefrigerants, International Journal of Thermal Sciences 48, p. 1108.
5. Park, K., Jung, D., 2007. Boiling heat transfer enhancement with carbon nanotubes for refrigerants used in building air-conditioning, Energy and Buildings 39, p. 1061.
6. Kedzierski, M.A., 2011. Effect of Al2O3 nanolubricant on R134a pool boiling heat transfer, International Journal of Refrigeration 34, p. 498.
7. Henderson, K., Park, Y-G., Liu, L., Jacobi, A.M., 2010. Flow-boiling heat transfer of R-134a-based nanofluids in a horizontal tube, International Journal of Heat and Mass Transfer 53, p. 944.
8. Ould Didi, M., Kattan, N., Thome, J., 2002. Prediction of two-phase pressure gradients of refrigerants in horizontal tubes, International Journal of Refrigeration 25, p. 935.
9. Peng, H., Ding, G., Jiang, W., Hu, H., Gao, Y., 2009. Measurement and correlation of frictional pressure drop of refrigerant-based nanofluid flow boiling inside a horizontal smooth tube, International Journal of Refrigeration 32, p. 1756.
10. Lemmon, E.W., McLinden, M.O., Huber, M.L., 2002. NIST Reference Fluid Thermodynamic and Transport Properties - Refprop 7.0, NIST Std, in Database: Boulder.
11. Peng, H., Ding, G., Jiang, W., Hu, H., Gao, Y., 2009. Heat transfer characteristics of refrigerant-based nanofluid flow boiling inside a horizontal smooth tube, International Journal of Refrigeration 32, p. 1259.
12. Saitoh, S., Daiguji, H., Hihara, E., 2007. Correlation for boiling heat transfer of R-134a in horizontal tubes including effect of tube diameter, International Journal of Heat and Mass Transfer 50, p. 5215.
13. Dittus, F., Boelter, L., 1930. Heat Transfer In Automobile Radiators of the Tubuler Type, University of California Publications in Engineering 2, p. 443.
14. Müller-Steinhagen, H., Heck, K., 1986. A simple friction pressure drop correlation for two-phase flow in pipes. Chemical Engineering and Processing 20, p. 297.
15. Mahbubul, I.M., Saidur, R., Amalina, M.A., 2012. Investigation of viscosity of R123-TiO2 nanorefrigerant, International Journal of Mechanical and Materials Engineering 7, p. 146.