Binary eutectic mixtures of stearic acid-n-butyramide/n-octanamide as phase change materials for low temperature solar heat storage

Applied Thermal Engineering

Volumn 111, Issue , 2017, Pages 1052-1059

  Ma, Guixiang ^a,b   Liu, Shang ^a,b   Xie, Shaolei ^a   Jing, Yan ^a   Zhang, Quanyou ^a   Sun, Jinhe ^a   Jia, Yongzhong ^a  

^a QINGHAI INSTITUTE OF SALT LAKES   (China)

^b UNIVERSITY OF CHINESE ACADEMY OF SCIENCES   (China)

Author keywords

Binary mixtures; n Butyramide; n Octanamide; Phase change materials; Solid liquid phase behavior; Thermal properties

Indexed keywords

BINARY MIXTURES; BINS; EUTECTICS; HEAT STORAGE; LATENT HEAT; LIQUIDS; MIXTURES; PHASE EQUILIBRIA; SOLAR HEATING; SPECIFIC HEAT; STEARIC ACID; TEMPERATURE; THERMAL CONDUCTIVITY; THERMODYNAMIC PROPERTIES; THERMODYNAMICS;

BUTYRAMIDE; EUTECTIC COMPOSITION; HEAT ENERGY STORAGE; LATENT HEAT OF FUSION; SOLID LIQUID EQUILIBRIUM; SOLID-LIQUID PHASE; SOLID-LIQUID PHASE DIAGRAMS; THERMAL PERFORMANCE;

PHASE CHANGE MATERIALS;

EID: 84990821381     PISSN: 13594311     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.applthermaleng.2016.10.004     Document Type: Article

References (33)

1. [1] Pinel, P., Cruickshank, C.A., Beausoleil-Morrison, I., et al. A review of available methods for seasonal storage of solar thermal energy in residential applications. Renew. Sustain. Energy Rev. 15:7 (2011), 3341–3359.
2. [2] Fan, L., Khodadadi, J.M., Thermal conductivity enhancement of phase change materials for thermal energy storage: a review. Renew. Sustain. Energy Rev. 15:1 (2011), 24–46.
3. [3] Xia, L., Zhang, P., Thermal property measurement and heat transfer analysis of acetamide and acetamide/expanded graphite composite phase change material for solar heat storage. Sol. Energy Mater. Sol. Cells 95:8 (2011), 2246–2254.
4. [4] Agyenim, F., Hewitt, N., Eames, P., et al. A review of materials, heat transfer and phase change problem formulation for latent heat thermal energy storage systems (LHTESS). Renew. Sustain. Energy Rev. 14:2 (2010), 615–628.
5. [5] Wei, D., Han, S., Wang, B., Solid–liquid phase equilibrium study of binary mixtures of n-octadecane with capric, and lauric acid as phase change materials (PCMs). Fluid Phase Equilib. 373 (2014), 84–88.
6. [6] Yuan, Y., Zhang, N., Tao, W., et al. Fatty acids as phase change materials: a review. Renew. Sustain. Energy Rev. 29 (2014), 482–498.
7. [7] Rozanna, D., Chuah, T.G., Salmiah, A., et al. Fatty acids as phase change materials (PCMs) for thermal energy storage: a review. Int. J. Green Energy 1:4 (2005), 495–513.
8. [8] Sarı, A., Eutectic mixtures of some fatty acids for latent heat storage: thermal properties and thermal reliability with respect to thermal cycling. Energy Convers. Manage. 47:9 (2006), 1207–1221.
9. [9] Baran, G., Sari, A., Phase change and heat transfer characteristics of a eutectic mixture of palmitic and stearic acids as PCM in a latent heat storage system. Energy Convers. Manage. 44:20 (2003), 3227–3246.
10. [10] Sarı, A., Kaygusuz, K., Thermal performance of a eutectic mixture of lauric and stearic acids as PCM encapsulated in the annulus of two concentric pipes. Sol. Energy 72:6 (2002), 493–504.
11. [11] Sarı, A., Kaygusuz, K., Thermal energy storage system using stearic acid as a phase change material. Sol. Energy 71:6 (2001), 365–376.
12. [12] Karaipeklı, A., Sarı, A., Kaygusuz, K., Thermal properties and thermal reliability of capric acid/stearic acid mixture for latent heat thermal energy storage. Energy Sources, Part A 31:3 (2009), 199–207.
13. [13] Sarı, A., Eutectic mixtures of some fatty acids for low temperature solar heating applications: thermal properties and thermal reliability. Appl. Therm. Eng. 25:14 (2005), 2100–2107.
14. [14] Sarı, A., Sarı, H., Önal, A., Thermal properties and thermal reliability of eutectic mixtures of some fatty acids as latent heat storage materials. Energy Convers. Manage. 45:3 (2004), 365–376.
15. [15] Khodadadi, J.M., Fan, L., Babaei, H., Thermal conductivity enhancement of nanostructure-based colloidal suspensions utilized as phase change materials for thermal energy storage: a review. Renew. Sustain. Energy Rev. 24 (2013), 418–444.
16. [16] Harish, S., Orejon, D., Takata, Y., et al. Thermal conductivity enhancement of lauric acid phase change nanocomposite with graphene nanoplatelets. Appl. Therm. Eng. 80 (2015), 205–211.
17. [17] Alkan, C., Canik, G., Dünya, H., et al. Synthesis and thermal energy storage properties of ethylene dilauroyl, dimyristoyl, and dipalmitoyl amides as novel solid–liquid phase change materials. Sol. Energy Mater. Sol. Cells 95:4 (2011), 1203–1207.
18. [18] Chen, C.R., Sharma, A., Tyagi, S.K., et al. Numerical heat transfer studies of PCMs used in a box-type solar cooker. Renewable Energy 33:5 (2008), 1121–1129.
19. [19] Xiang, J., Chen, R., Wu, F., et al. Physicochemical properties of new amide-based protic ionic liquids and their use as materials for anhydrous proton conductors. Electrochim. Acta 56:22 (2011), 7503–7509.
20. [20] Nikolić, R., Ristić, G., Todorović, M., Binary eutectics of acetamide with inorganic nitrates: thermophysical properties relevant for heat storage. Sol. Energy Mater. Sol. Cells 28:1 (1992), 59–69.
21. [21] Dheep, G.R., Sreekumar, A., Influence of accelerated thermal charging and discharging cycles on thermo-physical properties of organic phase change materials for solar thermal energy storage applications. Energy Convers. Manage. 105 (2015), 13–19.
22. [22] Zhang, M.M., Reddy, R.G., Thermodynamic properties of C4mim [Tf2N] ionic liquids. Miner. Process. Extract. Metall. 119:2 (2010), 71–76.
23. [23] Grønvold, F., Heat capacity of indium from 300 to 1000 K: enthalpy of fusion. J. Therm. Anal. Calorim. 13:3 (1978), 419–428.
24. [24] Maximo, G.J., Carareto, N.D.D., Costa, M.C., et al. On the solid–liquid equilibrium of binary mixtures of fatty alcohols and fatty acids. Fluid Phase Equilib. 366 (2014), 88–98.
25. [25] Diarce, G., Gandarias, I., Campos-Celador, A., et al. Eutectic mixtures of sugar alcohols for thermal energy storage in the 50–90 °C temperature range. Sol. Energy Mater. Sol. Cells 134 (2015), 215–226.
26. [26] Abate, L., Badea, E., Blanco, I., et al. Heat capacities and enthalpies of solid− solid transitions and fusion of a series of eleven primary alkylamides by differential scanning calorimetry. J. Chem. Eng. Data 53:4 (2008), 959–965.
27. [27] Liston, L.C., Farnam, Y., Krafcik, M., et al. Binary mixtures of fatty acid methyl esters as phase change materials for low temperature applications. Appl. Therm. Eng. 96 (2016), 501–507.
28. [28] Wei, D., Zhang, X., Li, H., Solid–liquid phase equilibrium study of n-octadecane+ lauryl alcohol binary mixtures. J. Chem. Thermodyn. 60 (2013), 94–97.
29. [29] Lane, G.A., Low temperature heat storage with phase change materials. Int. J. Ambient Energy 1:3 (1980), 155–168.
30. [30] Kahwaji, S., Johnson, M.B., Kheirabadi, A.C., et al. Stable, low-cost phase change material for building applications: the eutectic mixture of decanoic acid and tetradecanoic acid. Appl. Energy 168 (2016), 457–464.
31. 3 mixture for latent heat storage. Sol. Energy Mater. Sol. Cells 140 (2015), 281–288.
32. [32] Sharma, A., Shukla, A., Thermal cycle test of binary mixtures of some fatty acids as phase change materials for building applications. Energy Build. 99 (2015), 196–203.
33. [33] Wang, T., Mantha, D., Reddy, R.G., Novel low melting point quaternary eutectic system for solar thermal energy storage. Appl. Energy 102 (2013), 1422–1429.