1 |
Huang X, Zhu C Q, Lin Y X, et al. Thermal properties and applications of microencapsulated PCM for thermal energy storage: a review[J]. Applied Thermal Engineering, 2019, 147: 841-855.
|
2 |
Iten M, Liu S, Shukla A. A review on the air-PCM-TES application for free cooling and heating in the buildings[J]. Renewable and Sustainable Energy Reviews, 2016, 61: 175-186.
|
3 |
Villasmil W, Fischer L J, Worlitschek J. A review and evaluation of thermal insulation materials and methods for thermal energy storage systems[J]. Renewable and Sustainable Energy Reviews, 2019, 103: 71-84.
|
4 |
Oró E, de Gracia A, Castell A, et al. Review on phase change materials (PCMs) for cold thermal energy storage applications[J]. Applied Energy, 2012, 99: 513-533.
|
5 |
Zhang H, Zhang L, Li Q, et al. Preparation and characterization of methyl palmitate/palygorskite composite phase change material for thermal energy storage in buildings[J]. Construction and Building Materials, 2019, 226: 212-219.
|
6 |
Marani A, Nehdi M L. Integrating phase change materials in construction materials: critical review[J]. Construction and Building Materials, 2019, 217: 36-49.
|
7 |
Huang R, Feng J X, Ling Z Y, et al. A sodium acetate trihydrate-formamide/expanded perlite composite with high latent heat and suitable phase change temperatures for use in building roof[J]. Construction and Building Materials, 2019, 226: 859-867.
|
8 |
Fu L L, Wang Q H, Ye R D, et al. A calcium chloride hexahydrate/expanded perlite composite with good heat storage and insulation properties for building energy conservation[J]. Renewable Energy, 2017, 114: 733-743.
|
9 |
Sharma A, Tyagi V V, Chen C R, et al. Review on thermal energy storage with phase change materials and applications[J]. Renewable and Sustainable Energy Reviews, 2009, 13(2): 318-345.
|
10 |
Zhou D, Zhao C Y, Tian Y. Review on thermal energy storage with phase change materials (PCMs) in building applications[J]. Applied Energy, 2012, 92: 593-605.
|
11 |
Miró L, Gasia J, Cabeza L F. Thermal energy storage (TES) for industrial waste heat (IWH) recovery: a review[J]. Applied Energy, 2016, 179: 284-301.
|
12 |
Li Q, Li C, Du Z, et al. A review of performance investigation and enhancement of shell and tube thermal energy storage device containing molten salt based phase change materials for medium and high temperature applications[J]. Applied Energy, 2019, 255: 113806.
|
13 |
Wei G, Wang G, Xu C, et al. Selection principles and thermophysical properties of high temperature phase change materials for thermal energy storage: a review[J]. Renewable and Sustainable Energy Reviews, 2018, 81: 1771-1786.
|
14 |
Wong-Pinto L S, Milian Y, Ushak S. Progress on use of nanoparticles in salt hydrates as phase change materials[J]. Renewable and Sustainable Energy Reviews, 2020, 122: 109727.
|
15 |
Kumar N, Hirschey J, LaClair T J, et al. Review of stability and thermal conductivity enhancements for salt hydrates[J]. Journal of Energy Storage, 2019, 24: 100794.
|
16 |
Xia Y, Zhang X S. Experimental research on a double-layer radiant floor system with phase change material under heating mode[J]. Applied Thermal Engineering, 2016, 96: 600-606.
|
17 |
Barrio M, Font J, López D O, et al. Floor radiant system with heat storage by a solid-solid phase transition material[J]. Solar Energy Materials and Solar Cells, 1992, 27(2): 127-133.
|
18 |
Sattari S, Farhanieh B. A parametric study on radiant floor heating system performance[J]. Renewable Energy, 2006, 31(10): 1617-1626.
|
19 |
Lin K, Zhang Y, Xu X, et al. Experimental study of under-floor electric heating system with shape-stabilized PCM plates[J]. Energy and Buildings, 2005, 37(3): 215-220.
|
20 |
Li J, Xue P, He H, et al. Preparation and application effects of a novel form-stable phase change material as the thermal storage layer of an electric floor heating system[J]. Energy and Buildings, 2009, 41(8): 871-880.
|
21 |
Cheng W, Xie B, Zhang R, et al. Effect of thermal conductivities of shape stabilized PCM on under-floor heating system[J]. Applied Energy, 2015, 144: 10-18.
|
22 |
Lin K, Zhang Y, Xu X, et al. Modeling and simulation of under-floor electric heating system with shape-stabilized PCM plates[J]. Building and Environment, 2004, 39(12): 1427-1434.
|
23 |
Barzin R, Chen J J J, Young B R, et al. Application of PCM underfloor heating in combination with PCM wallboards for space heating using price based control system[J]. Applied Energy, 2015, 148: 39-48.
|
24 |
Devaux P, Farid M M. Benefits of PCM underfloor heating with PCM wallboards for space heating in winter[J]. Applied Energy, 2017, 191: 593-602.
|
25 |
El Mays A, Ammar R, Hawa M, et al. Using phase change material in under floor heating[J]. Energy Procedia, 2017, 119: 806-811.
|
26 |
Faraj K, Faraj J, Hachem F, et al. Analysis of underfloor electrical heating system integrated with coconut oil-PCM plates[J]. Applied Thermal Engineering, 2019, 158: 113778.
|
27 |
Akeiber H, Nejat P, Majid M Z A, et al. A review on phase change material (PCM) for sustainable passive cooling in building envelopes[J]. Renewable and Sustainable Energy Reviews, 2016, 60: 1470-1497.
|
28 |
Fang Y T, Ding Y F, Tang Y F, et al. Thermal properties enhancement and application of a novel sodium acetate trihydrate-formamide/expanded graphite shape-stabilized composite phase change material for electric radiant floor heating[J]. Applied Thermal Engineering, 2019, 150: 1177-1185.
|
29 |
Yun B Y, Yang S, Cho H M, et al. Design and analysis of phase change material based floor heating system for thermal energy storage[J]. Environmental Research, 2019, 173: 480-488.
|
30 |
Fu W W, Zou T, Liang X H, et al. Thermal properties and thermal conductivity enhancement of composite phase change material using sodium acetate trihydrate-urea/expanded graphite for radiant floor heating system[J]. Applied Thermal Engineering, 2018, 138: 618-626.
|