Preparation, heat transfer and flow properties of microencapsulated phase change materials for thermal energy storage

Renewable and Sustainable Energy Reviews

Volumn 66, Issue , 2016, Pages 399-414

  Liu, Lingkun ^a   Alva, Guruprasad ^a   Huang, Xiang ^a   Fang, Guiyin ^a  

^a NANJING UNIVERSITY   (China)

Author keywords

Flow properties; Heat transfer properties; Microencapsulation; Phase change materials (PCMs); Thermal energy storage

Indexed keywords

ENERGY EFFICIENCY; FOOD STORAGE; HEAT STORAGE; HEAT TRANSFER; MICROENCAPSULATION; THERMAL ENERGY;

FLOW PROPERTIES; HEAT STORAGE SYSTEMS; HEAT TRANSFER AND FLOWS; HEAT TRANSFER FLUIDS; HEAT TRANSFER PROPERTIES; PHASE CHANGE MATERIAL; PRACTICAL MATERIALS; SOLAR ENERGY STORAGES; THERMAL ENERGY STORAGE; VOLUME CHANGE;

PHASE CHANGE MATERIALS;

EID: 84982295174     PISSN: 13640321     EISSN: 18790690     Source Type: Journal    
DOI: 10.1016/j.rser.2016.08.035     Document Type: Review

References (85)

1. [1] Xu, B., Li, P.W., Chan, C., Application of phase change materials for thermal energy storage in concentrated solar thermal power plants: a review to recent developments. Appl Energy 160 (2015), 286–307.
2. [2] Paloma, J.G., Martinez, M., Cabeza, L.F., Fernandez AI. Types, methods, techniques, and applications for microencapsulated phase change materials (MPCM): a review. Renew Sustain Energy Rev 53 (2016), 1059–1075.
3. [3] Fu, Z.J., Su, L., Li, J., Yang, R.Z., Zhang, Z.W., Liu, M.F., Li, J., Li, B., Elastic silicone encapsulation of n-hexadecyl bromide by microfluidic approach as novel microencapsulated phase change materials. Thermochim Acta 590 (2014), 24–29.
4. [4] Konuklu, Y., Paksoy, H.O., Unal, M., Nanoencapsulation of n-alkanes with poly(styrene-co-ethylacrylate) shells for thermal energy storage. Appl Energy 150 (2015), 335–340.
5. [5] Liu, C.Z., Rao, Z.H., Zhao, J.T., Huo, Y.T., Li, Y.M., Review on nanoencapsulated phase change materials: preparation, characterization and heat transfer enhancement. Nano Energy 13 (2015), 814–826.
6. [6] Jamekhorshid, A., Sadrameli, S.M., Farid, M., A review of microencapsulation methods of phase change materials (PCMs) as a thermal energy storage (TES) medium. Renew Sustain Energy Rev 31 (2014), 531–542.
7. [7] Su, W.G., Darkwa, J., Kokogiannakis, G., Review of solid–liquid phase change materials and their encapsulation technologies. Renew Sustain Energy Rev 48 (2015), 373–391.
8. [8] Jacob, R., Bruno, F., Review on shell materials used in the encapsulation of phase change materials for high temperature thermal energy storage. Renew Sustain Energy Rev 48 (2015), 79–87.
9. [9] Cao, H., Ye, H., Li, C., Zheng, L.L., Li, Y., Ouyang, Q.F., Effect of microencapsulated cell preparation technology andconditions on the catalytic performance of Penicillium purpurogenum Li-3 strain cells. Process Biochem 49 (2014), 791–796.
10. [10] Ilyasoglu, H., El, S.N., Nanoencapsulation of EPA/DHA with sodium caseinate-gum arabic complex and its usage in the enrichment of fruit juice. LWT-Food Sci Technol 56 (2014), 461–468.
11. [11] Martin, E.J., Rojas, T.A., Gharsallaoui, A., Carrascal, J.R., Palacios, T.P., Fatty acid composition in double and multilayered microcapsules of ω−3 as affected by storage conditions and type of emulsions. Food Chem 194 (2016), 476–486.
12. [12] Paloma, J.G., Konuklu, Y., Fernandez, A.I., Preparation and exhaustive characterization of paraffin or palmitic acid microcapsules as novel phase change material. Sol Energy 112 (2015), 300–309.
13. [13] Ma, Y.H., Sun, S.D., Li, J.G., Tang, G.Y., Preparation and thermal reliabilities of microencapsulated phase change materials with binary cores and acrylate-based polymer shells. Thermochim Acta 588 (2014), 38–46.
14. [14] Huang, J., Wang, T.Y., Zhu, P.P., Xiao, J.B., Preparation, characterization, and thermal properties of the microencapsulation of a hydrated salt as phase change energy storage materials. Thermochim Acta 557 (2013), 1–6.
15. [15] Qiu, X.L., Lu, L.X., Wang, J., Tang, G.Y., Song, G.L., Preparation and characterization of microencapsulated n-octadecane as phase change material with different n-butyl methacrylate-based copolymer shells. Sol Energy Mater Sol Cells 128 (2014), 102–111.
16. [16] Tang, X.F., Li, W., Zhang, X.X., Shi, H.F., Fabrication and characterization of microencapsulated phase change material with low supercooling for thermal energy storage. Energy 68 (2014), 160–166.
17. [17] Li, F.N., Wang, X.D., Wu, D.Z., Fabrication of multifunctional microcapsules containing n-eicosane core and zinc oxide shell for low-temperature energy storage, photocatalysis, and antibiosis. Energy Convers Manag 106 (2015), 873–885.
18. [18] Guo, X., Cao, J.Z., Peng, Y., Liu, R., Incorporation of microencapsulated dodecanol into wood flour/ high-density polyethylene composite as a phase change material for thermal energy storage. Mater Des 89 (2016), 1325–1334.
19. [19] Yuan, K.J., Wang, H.C., Liu, J., Fang, X.M., Zhang, Z.G., Novel slurry containing graphene oxide-grafted microencapsulated phase change material with enhanced thermo-physical properties and photo-thermal performance. Sol Energy Mater Sol Cells 143 (2015), 29–37.
20. [20] Krupa, I., Nogellova, Z., Spitalsky, Z., Janigova, I., Boh, B., Sumiga, B., Kleinova, A., Karkri, M., AlMaadeed, M.A., Phase change materials based on high-density polyethylene filled with microencapsulated paraffin wax. Energy Convers Manag 87 (2014), 400–409.
21. [21] Sariera, N., Onder, E., Ukuser, G., Silver incorporated microencapsulation of n-hexadecane and noctadecane appropriate for dynamic thermal management in textiles. Thermochim Acta 613 (2015), 17–27.
22. [22] Salaun, F., Bedek, G., Devaux, E., Dupont, D., Gengembre, L., Microencapsulation of a cooling agent by interfacial polymerization: Influence of the parameters of encapsulation on poly(urethane-urea) microparticles characteristics. J Membr Sci 370 (2011), 23–33.
23. [23] Hirech, K., Payan, S., Carnelle, G., Brujes, L., Legrand, J., Microencapsulation of an insecticide by interfacial polymerisation. Powder Technol 130 (2003), 324–330.
24. [24] Es-haghi, H., Mirabedini, S.M., Imani, M., Farnood, R.R., Preparation and characterization of pre-silane modified ethylcellulose-based microcapsules containing linseed oil. Colloids Surf A: Physicochem Eng Asp 447 (2014), 71–80.
25. [25] Jamekhorshid, A., Sadrameli, S.M., Bahramian, A.R., Process optimization and modeling of microencapsulated phase change material using response surface methodology. Appl Therm Eng 70 (2014), 183–189.
26. [26] Choi, Y., Lee, J.G., Kim, J.H., Yang, H., Preparation of microcapsules containing phase change materials as heat transfer media by in-situ polymerization. Ind Eng Chem 7:6 (2001), 358–362.
27. [27] Konuklu, Y., Paksoy, H.O., Unal, M., Konuklu, S., Microencapsulation of a fatty acid with Poly(melamine-urea-formaldehyde). Energy Convers. Manag. 80 (2014), 382–390.
28. [28] Liang, S.E., Li, Q.B., Zhu, Y.L., Chen, K.P., Tian, C.R., Wang, J.H., Bai, R.K., Nanoencapsulation of n-octadecane phase change material with silica shell through interfacial hydrolysis and polycondensation in miniemulsion. Energy 93 (2015), 1684–1692.
29. [29] Lazko, J., Popineau, Y., Legrand, Y., Soy glycinin microcapsules by simple coacervation method. Colloids Surf B: Biointerfaces 37 (2004), 1–8.
30. [30] Hawladera, M.N.A., Uddina, M.S., Khin, M.M., Microencapsulated, P.C.M., thermal-energy storage system. Appl Energy 74 (2003), 195–202.
31. [31] Konuklu, Y., Unal, M., Paksoy, H.O., Microencapsulation of caprylic acid with different wall materials as phase change material for thermal energy storage. Sol Energy Mater Sol Cells 120 (2014), 536–542.
32. [32] Santos, M.G., Bozza, F.T., Thomazini, M., Favaro-Trindade, C.S., Microencapsulation of xylitol by double emulsion followed by complex coacervation. Food Chem 171 (2015), 32–39.
33. [33] Piacentini, E., Giorno, L., Dragosavac, M.M., Vladisavljevic, G.T., Holdich, R.G., Microencapsulation of oil droplets using cold water fish gelatine/gum arabic complex coacervation by membrane emulsification. Food Res Int. 53 (2013), 362–372.
34. 2 hybrid shell for dual-functional phase change materials. Appl Energy 134 (2014), 456–468.
35. 2 with excellent cycling performance. Appl Energy 154 (2015), 361–368.
36. [36] Cao, L., Tang, F., Fang, G.Y., Synthesis and characterization of microencapsulated paraffin with titanium dioxide shell as shape-stabilized thermal energy storage materials in buildings. Energy Build 72 (2014), 31–37.
37. [37] Chen, Z., Cao, L., Shan, F., Fang, G.Y., Preparation and characteristics of microencapsulated stearic acid as composite thermal energy storage material in buildings. Energy Build 62 (2013), 469–474.
38. [38] Cao, L., Tang, F., Fang, G.Y., Preparation and characteristics of microencapsulated palmitic acid with TiO2 shell as shape-stabilized thermal energy storage materials. Sol Energy Mater Sol Cells 123 (2014), 183–188.
39. [39] He, F., Wang, X.D., Wu, D.Z., New approach for sol-gel synthesis of microencapsulated noctadecane phase change material with silica wall using sodium silicate precursor. Energy 67 (2014), 223–233.
40. [40] Sutaphanit, P., Chitprasert, P., Optimisation of microencapsulation of holy basil essential oil in gelatin by response surface methodology. Food Chem 150 (2014), 313–320.
41. [41] Dima, C., Cotarlet, M., Alexe, P., Dima, S., Microencapsulation of essential oil of pimento [Pimenta dioica (L) Merr.] by chitosan/k-carrageenan complex coacervation method. Innov Food Sci Emerg Technol 22 (2014), 203–211.
42. 2 as hybrid shell materials. Thermochim. Acta 617 (2015), 90–94.
43. [43] Fei, B., Lu, H.F., Qi, K.H., Shi, H.F., Liu, T.X., Li, X.Z., Xin, J.H., Multi-functional microcapsules produced by aerosol reaction. Aerosol Sci. 39 (2008), 1089–1098.
44. [44] Carvalho, A.G.S., Silva, V.M., Hubinger, M.D., Microencapsulation by spray drying of emulsified green coffee oil with two-layered membranes. Food Res Int 61 (2014), 236–245.
45. [45] Carneiro, H.C.F., Tonon, R.V., Grosso, C.R.F., Hubinger, M.D., Encapsulation efficiency and oxidative stability of flaxseed oil microencapsulated by spray drying using different combinations of wall materials. J Food Eng 115 (2013), 443–451.
46. [46] Rajam, R., Anandharamakrishnan, C., Spray freeze drying method for microencapsulation of Lactobacillus plantarum. J Food Eng 166 (2015), 95–103.
47. [47] Memon, S.A., Cui, H.Z., Lo, T.Y., Li, Q.S., Development of structural-functional integrated concrete with macro-encapsulated PCM for thermal energy storage. Appl Energy 150 (2015), 245–257.
48. [48] Yang, X., Gao, N., Hu, L.D., Li, J.L., Sun, Y.B., Development and evaluation of novel microcapsules containing poppy-seed oil using complex coacervation. J Food Eng 161 (2015), 87–93.
49. [49] Porras-Saavedra, J., Palacios-Gonzalez, E., Lartundo-Rojas, L., Garibay-Febles, V., Yanez-Fernandez, J., Hernandez-Sanchez, H., Gutierrez-Lopez, G., Alamilla-Beltrá, L., Microstructural properties and distribution of components in microparticles obtained by spray-drying. J Food Eng 152 (2015), 105–112.
50. [50] Ye, C.W., Chen, A., Colombo, P., Martinez, C., Ceramic microparticles and capsules via microfluidic processing of a preceramic polymer. J R Soc Interface 7 (2010), 461–473.
51. [51] Comunian, T.A., Abbaspourrad, A., Favaro-Trindade, C.S., Weitz, D.A., Fabrication of solid lipid microcapsules containing ascorbic acid using a microfluidic technique. Food Chem 152 (2014), 271–275.
52. [52] Vilanova, N., Rodríguez-Abreu, C., Fernandez-Nieves, A., Solans, C., Fabrication of novel silicone capsules with tunable mechanical properties by microfluidic techniques. Appl Mater Interfaces 5 (2013), 5247–5252.
53. [53] Moghaddam, M.K., Mortazavi, S.M., Khayamian, T., Preparation of calcium alginate microcapsules containing n-nonadecane by a melt coaxial electrospray method. J Electrost 73 (2015), 56–64.
54. [54] Sun, B.J., Shum, H.C., Holtze, C., Weitz, David A., Microfluidic Melt emulsification for encapsulation and Release of actives. Appl Mater Interfaces 2:12 (2010), 3411–3416.
55. [55] Loscertales, I., Barrero, G.A., Guerroro, I., Cortijo, R., Marquez, M., Ganan-Calvo, A., Micro/nano encapsulation via electrified coaxial liquid jets. Science 295 (2002), 1695–1698.
56. [56] Chen, L., Wang, T., Zhao, Y., Zhang, X.R., Characterization of thermal and hydrodynamic properties for microencapsulated phase change slurry (MPCS). Energy Convers Manag 79 (2014), 317–333.
57. [57] Chen, B.J., Wang, X., Zeng, R.L., Zhang, Y.P., Wang, X.C., Niu, J.L., An experimental study of convective heat transfer with microencapsulated phase change material suspension: laminar flow in a circular tube under constant heat flux. Exp Therm Fluid Sci 32 (2008), 1638–1646.
58. [58] Hu, X.X., Zhang, Y.P., Novel insight and numerical analysis of convective heat transfer enhancement with microencapsulated phase change material slurries: laminar flow in a circular tube with constant heat flux. Int J Heat Mass Transf 45 (2002), 3163–3172.
59. [59] Zhang, Y.P., Hu, X.X., Wang, X., Theoretical analysis of convective heat transfer enhancement of microencapsulated phase change material slurries. Heat Mass Transf 40 (2003), 59–66.
60. [60] Hamilton, R.L., Crosser, O.K., Thermal conductivity of heterogeneous two-component systems. Ind Eng Chem Res Fundam 1:3 (1962), 187–191.
61. [61] Jeffrey, D.J., Conduction through a random suspension of spheres. Proc. R. Soc. Lond. 335 (1973), 355–367.
62. [62] Rao, Z., Wang, S., Peng, F., Self diffusion of the nano-encapsulated phase change materials: a molecular dynamics study. Appl Energy 100 (2012), 303–308.
63. 3. Appl Energy 137 (2015), 731–737.
64. [64] Vand, V., Theory of viscosity of concentrated suspensions. Nature 155 (1945), 364–365.
65. [65] Yamagishi, Y., Takeuchi, H., Pyatenko, A.T., Kayukawa, N., Characteristics of MPCM slurry as a heat transfer fluid. AIChE J. 45 (1999), 696–707.
66. [66] Wang, X.C., Niu, J.L., Li, Y., Wang, X., Chen, B.J., Zeng, R.L., Song, Q.W., Zhang, Y.P., Flow and heat transfer behaviors of phase change material slurries in a horizontal circular tube. Int J Heat Mass Transf 50 (2007), 2480–2491.
67. [67] Wu, W., Chow, L.C., Wang, C.M., Su, M., Kizito, J.P., Jet impingement heat transfer using a Field's alloy nanoparticle HFE7100 slurry. Int J Heat Mass Transf 68 (2014), 357–365.
68. [68] Tumuluri, K., Alvarado, J.L., Taherian, H., Marsh, C., Thermal performance of a novel heat transfer fluid containing multiwalled carbon nanotubes and microencapsulated phase change materials. Int J Heat Mass Transf 54 (2011), 5554–5557.
69. [69] Zhang, G.H., Zhao, C.Y., Thermal property investigation of aqueous suspensions of microencapsulated phase change material and carbon nanotubes as a novel heat transfer fluid. Renew Energy 60 (2013), 433–438.
70. [70] Delgado, M., Lázaro, A., Mazo, J., Experimental analysis of a microencapsulated PCM slurry as thermal storage system and as heat transfer fluid in laminar flow. Appl Therm Eng 36 (2012), 370–377.
71. 3 nanoparticles and MEPCM particles on convection effectiveness in a circular tube. Int J Therm Sci 50 (2011), 736–748.
72. [72] Roy, S.K., Avanic, L.B., Turbulent transfer with phase change material suspensions. Int J Heat Mass Transf 44 (2001), 2277–2285.
73. [73] Song, S.H., Liao, Q., Shen, W.D., Laminar heat transfer and friction characteristics of microencapsulated phase change material slurry in a circular tube with twisted tape inserts. Appl Therm Eng 50 (2013), 791–798.
74. [74] Allouche, Y., Varga, S., Bouden, C., Oliveira, A.C., Experimental determination of the heat transfer and cold storage characteristics of a microencapsulated phase change material in a horizontal tank. Energy Convers Manag 94 (2015), 275–285.
75. [75] Zhang, Y.L., Rao, Z.H., Wang, S.F., Zhang, Z., Li, X.P., Experimental evaluation on natural convection heat transfer of microencapsulated phase change materials slurry in a rectangular heat storage tank. Energy Convers Manag 59 (2012), 33–39.
76. [76] Zeng, R.L., Wang, X., Chen, B.J., Zhang, Y.P., Niu, J.L., Wang, X.C., Di, H.F., Heat transfer characteristics of microencapsulated phase change material slurry in laminar flow under constant heat flux. Appl Energy 86 (2009), 2661–2670.
77. [77] Huang, Y., Xuan, Y.M., Li, Q., Experimental investigation on convective heat transfer of magnetic phase change microcapsule suspension. Appl Therm Eng 47 (2012), 10–17.
78. [78] Song, S.H., Liao, Q., Shen, W.D., Ruan, Y., Xu, J.F., Numerical study on laminar convective heat transfer enhancement of microencapsulated phase change material slurry using liquid metal with low melting point as carrying fluid. Int J Heat Mass Transf 62 (2013), 286–294.
79. [79] Alvarado, J.L., Marsh, C., Sohn, C., Phetteplace, G., Newell, T., Thermal performance of microencapsulated phase change material slurry in turbulent flow under constant heat flux. Int J Heat Mass Transf 50 (2007), 1938–1952.
80. [80] Taherian H, Alvarado JL, Tumuluri K, Thies C, Park CH. Heat transfer and fluid flow behavior of microencapsulated phase change material slurry in turbulent flow. Transactions of the ASME–Journal of Heat Transfer 2014; 136: 0161704-1–061704-7.
81. [81] Taherian H, Alvarado JL, Thies C. Improving heat transfer efficiency with an aqueous slurry of microencapsulated phase change material under turbulent flow conditions. In: Proceedings of the 239th ACS National Meeting, San Francisco, CA, 2010.
82. [82] Alvarado JL, Taherian H, Languri EM, Thies C. Heat transfer and fluid flow behavior of an economical microencapsulated phase change material slurry in turbulent flow. In: Proceedings of the 10th International Conference on Phase–Change Materials and Slurries for Refrigeration aND Air Conditioning, Kobe, JAPAN 2012.
83. [83] Rokni, HB, Mohseni Languri E, Taherian H, Masoodi R. Study on the flow of heat transfer fluid enhanced with microencapsulated phase change materials through coils. In: Proceedings of the Fifteenth Annual Early Career Technical Conference, The University of Alabama, Birmingham, AL, Nov. 2015.
84. [84] Taherian, H., Alvarado, J.L., System analysis of MPCM slurry enhanced with carbon nanotubes as heat transfer fluid. ASHRAE Trans, 116(part 2), 2010 AB-10-021.
85. [85] Diaconu, B.M., Varga, S., Oliveira, A.C., Experimental study of natural convection heat transfer in a microencapsulated phase change material slurry. Energy 35 (2010), 2688–2693.