Synthesis and heat transfer performance of phase change microcapsule enhanced thermal fluids

Journal of Heat Transfer

Volumn 137, Issue 9, 2015, Pages

  Cao, Fangyu ^a   Kalinowski, Paul ^b   Lawler, John ^b   Lee, Hak Seung ^a   Yang, Bao ^a  

^a UNIVERSITY OF MARYLAND   (United States)

^b ATEC Inc   (United States)

Author keywords

heat transfer fluids; phase change materials (PCM); thermal conductivity

Indexed keywords

ELECTRONIC COOLING; EMULSIFICATION; EMULSION POLYMERIZATION; FLUIDS; HEAT SINKS; HEAT TRANSFER; HEAT TRANSFER COEFFICIENTS; PHASE CHANGE MATERIALS; SILVER; THERMAL CONDUCTIVITY;

ELECTRONICS COOLING; HEAT TRANSFER PERFORMANCE; LOW THERMAL CONDUCTIVITY; MICRO CHANNEL HEAT SINKS; PARTICLE ACCUMULATION; PHASE CHANGE MATERIAL PARTICLES; POLYALPHAOLEFINS; THERMAL PERFORMANCE;

THERMAL CONDUCTIVITY OF LIQUIDS;

EID: 84929378241     PISSN: 00221481     EISSN: 15288943     Source Type: Journal    
DOI: 10.1115/1.4030234     Document Type: Article

References (30)

1. Wang, X.-Q., and Mujumdar, A. S., 2008, "A Review on Nanofluids-Part I: Theoretical and Numerical Investigations," Braz. J. Chem. Eng., 25(4), pp. 613-630.
2. Wang, J. J., Zheng, R. T., Gao, J. W., and Chen, G., 2012, "Heat Conduction Mechanisms in Nanofluids and Suspensions," Nano Today, 7, pp. 124-136.
3. Han, Z. H., Cao, F. Y., and Yang, B., 2008, "Synthesis and Thermal Characterization of Phase-Changeable Indium/Polyalphaolefin Nanofluids," Appl. Phys. Lett., 92(24), p. 243104.
4. Han, Z. H., and Yang, B., 2008, "Thermophysical Characteristics of Water-In-FC72 Nanoemulsion Fluids," Appl. Phys. Lett., 92(1), p. 013118.
5. Buongiorno, J., Venerus, D. C., Prabhat, N., McKrell, T., Townsend, J., Christianson, R., Tolmachev, Y. V., Keblinski, P., Hu, L. W., Alvarado, J. L., Bang, I. C., Bishnoi, S. W., Bonetti, M., Botz, F., Cecere, A., Chang, Y., Chen, G., Chen, H. S., Chung, S. J., Chyu, M. K., Das, S. K., Di Paola, R., Ding, Y. L., Dubois, F., Dzido, G., Eapen, J., Escher, W., Funfschilling, D., Galand, Q., Gao, J. W., Gharagozloo, P. E., Goodson, K. E., Gutierrez, J. G., Hong, H. P., Horton, M., Hwang, K. S., Iorio, C. S., Jang, S. P., Jarzebski, A. B., Jiang, Y. R., Jin, L. W., Kabelac, S., Kamath, A., Kedzierski, M. A., Kieng, L. G., Kim, C., Kim, J. H., Kim, S., Lee, S. H., Leong, K. C., Manna, I., Michel, B., Ni, R., Patel, H. E., Philip, J., Poulikakos, D., Reynaud, C., Savino, R., Singh, P. K., Song, P. X., Sundararajan, T., Timofeeva, E., Tritcak, T., Turanov, A. N., Van Vaerenbergh, S., Wen, D. S., Witharana, S., Yang, C., Yeh, W. H., Zhao, X. Z., and Zhou, S. Q., 2009, "A Benchmark Study on the Thermal Conductivity of Nanofluids," J. Appl. Phys., 106(9), p. 094312.
6. Fan, J., and Wang, L. Q., 2010, "Constructal Design of Nanofluids," Int. J. Heat Mass Transfer, 53(19-20), pp. 4238-4247.
7. Fan, J., and Wang, L. Q., 2011, "Review of Heat Conduction in Nanofluids," ASME J. Heat Transfer, 133(4), p. 040801.
8. He, P., and Qiao, R., 2008, "Self-Consistent Fluctuating Hydrodynamics Simulations of Thermal Transport in Nanoparticle Suspensions," J. Appl. Phys., 103, p. 094305.
9. Xuan, Y., and Li, Q., 2003, "Investigation on Convective Heat Transfer and Flow Features of Nanofluids," ASME J. Heat Transfer, 125(1), pp. 151-155.
10. Wen, D. S., and Ding, Y. L., 2004, "Experimental Investigation Into Convective Heat Transfer of Nanofluids at the Entrance Region Under Laminar Flow Conditions," Int. J. Heat Mass Transfer, 47(24), pp. 5181-5188.
11. Heris, S. Z., Etemad, S. G., and Esfahany, A. N., 2006, "Experimental Investigation of Oxide Nanofluids Laminar Flow Convective Heat Transfer," Int. Commun. Heat Mass Transfer, 33(4), pp. 529-535.
12. Heris, S. Z., Esfahany, M. N., and Etemad, S. G., 2007, "Experimental Investigation of Convective Heat Transfer of Al2O3/Water Nanofluid in Circular Tube," Int. J. Heat Fluid Flow, 28(2), pp. 203-210.
13. Chen, H., Yang, W., He, Y., Ding, W., Zhang, L., Tan, C., Lapkin, A. A., and Bavykin, D. V., 2008, "Heat Transfer and Flow Behaviour of Aqueous Suspensions of Titanate Nanotubes (nanofluids)," Powder Technol., 183(1), pp. 63-72.
14. Chein, R., and Chuang, J., 2007, "Experimental Microchannel Heat Sink Performance Studies Using Nanofluids," Int. J. Therm. Sci., 46(1), pp. 57-66.
15. Delgado, M., Lazaro, A., Mazo, J., and Zalba, B., 2012, "Review on Phase Change Material Emulsions and Microencapsulated Phase Change Material Slurries: Materials, Heat Transfer Studies and Applications," Renewable Sustainable Energy Rev., 16(1), pp. 253-273.
16. Mehling, H., and Cabeza, L. F., 2008, Heat and Cold Storage With PCM: An Up to Date Introduction Into Basics and Applications, Springer, Berlin.
17. Farid, M. M., Khudhair, A. M., Razack, S. A. K., and Al-Hallaj, S., 2004, "A Review on Phase Change Energy Storage: Materials and Applications," Energy Convers. Manage., 45(9-10), pp. 1597-1615.
18. Xu, B., and Li, Z., 2013, "Paraffin/Diatomite Composite Phase Change Material Incorporated Cement-Based Composite for Thermal Energy Storage," Applied Energy, 105, pp. 229-237.
19. Zhao, C. Y., and Zhang, G. H., 2011, "Review on Microencapsulated Phase Change Materials (MEPCMs): Fabrication, Characterization and Applications," Renewable Sustainable Energy Rev., 15(8), pp. 3813-3832.
20. Oró, E., de Gracia, A., Castell, A., Farid, M. M., and Cabeza, L. F., 2012, "Review on Phase Change Materials (PCMs) for Cold Thermal Energy Storage Applications," Appl. Energy, 99, pp. 513-533.
21. Mondal, S., 2008, "Phase Change Materials for Smart Textiles-An Overview," Appl. Therm. Eng., 28(11-12), pp. 1536-1550.
22. Cao, F. Y., and Yang, B., 2014, "Supercooling Suppression of Microencapsulated Phase Change Materials by Optimizing Shell Composition and Structure," Appl. Energy, 113, pp. 1512-1518.
23. Rao, Y., Dammel, F., Stephan, P., and Lin, G., 2007, "Convective Heat Transfer Characteristics of Microencapsulated Phase Change Material Suspensions in Minichannels," Heat Mass Transfer, 44(2), pp. 175-186.
24. Dammel, F., and Stephan, P., 2012, "Heat Transfer to Suspensions of Microencapsulated Phase Change Material Flowing Through Minichannels," ASME J. Heat Transfer, 134(2), p. 020907.
25. Xu, C., Zhou, R., Chen, H., Hou, X., Liu, G., and Liu, Y., 2014, "Silver-Coated Glass Fibers Prepared by a Simple Electroless Plating Technique," J. Mater. Sci: Mater. Electron., 25(10) pp. 4638-4642.
26. Bao, Y., Lai, C., Zhu, Z., Fong, H., and Jiang, C., 2013, "SERS-Active Silver Nanoparticles on Electrospun Nanofibers Facilitated Via Oxygen Plasma Etching," RSC Adv., 3(23), pp. 8998-9004.
27. Montazer, M., Alimohammadi, F., Shamei, A., and Rahimi, M. K., 2012, "In Situ Synthesis of Nano Silver on Cotton Using Tollens' Reagent," Carbohydr. Polym., 87(2), pp. 1706-1712.
28. Yang, B., and Han, Z. H., 2006, "Temperature-Dependent Thermal Conductivity of Nanorod-Based Nanofluids," Appl. Phys. Lett., 89(8), p. 083111.
29. Yang, B., and Han, Z. H., 2006, "Thermal Conductivity Enhancement in Water-In-FC72 Nanoemulsion Fluids," Appl. Phys. Lett., 88(26), p. 261914.
30. Lundgren, T. S., Sparrow, E. M., and Starr, J. B., 1964, "Pressure Drop Due to the Entrance Region in Ducts of Arbitrary Cross Section," ASME J. Fluids Eng., 86(3), pp. 620-626.