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Phase change materials for thermal energy storage have been widely applied to clothing insulation, electronic products of heat energy storage. The thermal storage potential of the nanofiber membranes was analyzed using the differential scanning calorimetry. Effect of microstructure of the membrane on energy storage was analyzed, and its applications to electronic devices were elucidated.
PAPER REVISED: 2014-05-03
PAPER ACCEPTED: 2014-07-12
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THERMAL SCIENCE YEAR 2014, VOLUME 18, ISSUE Issue 5, PAGES [1141 - 1446]
  1. Darabi, J., Ekula, K., Development of a Chip-Integrated Micro Cooling Device, Microelectronics Journal, 34 (2003), 11, pp. 1067-1074
  2. Farid, M. M., et al., A Review on Phase Change Energy Storage: Materials and Applications, Energy Conversion and Management, 45 (2004), 9, pp. 1597-1615
  3. Mesalhy, O., et al., Carbon Foam Matrices Saturated with PCM for Thermal Protection Purposes, Carbon, 44 (2006), 10, pp. 2080-2088
  4. Garg, H. P., et al., Solar Thermal Energy Storage, Reidel Publishing Company, Dordrecht, The Netherlands, 1985
  5. Kaygusuz, K., The Viability of Thermal Energy Storage, Energy Sources, 21 (1999), 8, pp. 745-756
  6. Sari, A., Kaygusuz, K., Thermal Performance of Palmitic Acid as a Phase Change Energy Storage Material, Energy Conversion Manage, 43 (2002), 6, pp. 863-876
  7. Sari, A., Thermal Reliability Test of Some Fatty Acids as PCMs Used for Solar Thermal Latent Heat Storage Applications, Energy Conversion and Management, 44 (2003), 14, pp. 2277-2287
  8. He, J.-H., et al., Nanoeffects, Quantum-Like Properties in Electrospun Nanofibers, Chaos, Solitons & Fractals, 33 (2007), 1, pp. 26-37
  9. Baumgarten, P. K., Electrostatic Spinning of Acrylic Microfibers, Journal of Colloid and Interface Science, 36 (1971), 1, pp. 71-79
  10. Bergshoef, M. M., Vancso, G. J., Transparent Nanocomposites with Ultrathin, Electrospun Nylon-4, 6 Fiber Reinforcement, Advanced Materials, 11 (1999), 16, pp. 1362-1365
  11. Li, D., Xia, Y., Electrospinning of Nanofibers: Reinventing the Wheel, Advanced Materials, 16 (2004), 14, pp. 1151-1170
  12. Sun, Z., et al., Compound Core-Shell Polymer Nanofibers by Co-Electrospinning, Advanced Materials, 15 (2003), 22, pp. 1929-1932
  13. Koombhongse, S., et al., Flat Polymer Ribbons and other Shapes by Electrospinning, Journal of Polymer Science, Part B: Polymer Physics, 39 (2001), 21, pp. 2598-2606
  14. Zussman, E., et al., Tensile Deformation of Electrospun Nylon‐6,6 Nanofibers, Journal of Polymer Science, Part B: Polymer Physics, 44 (2006), 10, pp. 1482-1489
  15. Liu, Y., et al., Crystalline Morphology and Polymorphic Phase Transitions in Electrospun Nylon6 Nanofibers, Macromolecules, 40 (2007), 17, pp. 6283-6290
  16. Cai, Y., et al., Effects of NanoSiO2 on Morphology, Thermal Energy Storage, Thermal Stability, and Combustion Properties of Electrospun Lauric Acid/PET Ultrafine Composite Fibers as Form-Stable Phase Change Materials, Applied Energy, 88 (2011), 6, pp. 2106-2112
  17. Chen, C., et al., Electrospinning of Thermo-Regulating Ultrafine Fibers Based on Polyethylene Glycol/Cellulose Acetate Composite, Polymer, 48 (2007), 18, pp. 5202-5207

© 2024 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, National Institute of the Republic of Serbia, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence