[1] [1] RAO V V, PARAMESHWARAN R, RAM V V. PCM-mortar based construction materials for energy efficient buildings: A review on research trends[J]. Energy Build, 2018, 158: 95-122.

[2] [2] GUO X, HUANG Y H, CAO J Z. Performance of a thermal energy storage composite by incorporating diatomite stabilized paraffin as phase change material[J]. Energy Build, 2018, 158: 1257-1265.

[3] [3] XU T, LI Y T, CHEN J Y, et al. Preparation and thermal energy storage properties of LiNO3-KCl-NaNO3/expanded graphite composite phase change material[J]. Sol Energy Mater Sol Cells, 2017, 169: 215-221.

[5] [5] WANG R, REN M, GAO X J, et al. Preparation and properties of fatty acids based thermal energy storage aggregate concrete[J]. Constr Build Mater, 2018, 165: 1-10.

[8] [8] LAMRANI B, JOHANNES K, KUZNIK F. Phase change materials integrated into building walls: An updated review[J]. Renew Sust Energ Rev, 2021, 140, 110751.

[10] [10] WEN R L, ZHANG X G, HUANG Y T, et al. Preparation and properties of fatty acid eutectics/expanded perlite and expanded vermiculite shape-stabilized materials for thermal energy storage in buildings[J]. Energy Build, 2017, 139: 197-204.

[11] [11] ZHANG N, YUAN Y P, WANG X, et al. Preparation and characterization of lauric-myristic-palmitic acid ternary eutectic mixtures/expanded graphite composite phase change material for thermal energy storage[J]. Chem Eng J, 2013, 231: 214-219.

[12] [12] JIN W Z, JIANG L H, CHEN L, et al. Enhancement of thermal conductivity by graphene as additive in lauric-stearic acid/treated diatomite composite phase change materials for heat storage in building envelope[J]. Energy Build, 2021, 246: 111087.

[13] [13] HEKIMOGLU G, NAS M, OUIKHALFAN M, et al. Thermal management performance and mechanical properties of a novel cementitious composite containing fly ash/lauric acid-myristic acid as form-stable phase change material[J]. Constr Build Mater, 2021, 274: 122105.

[14] [14] WEN R L, LIU Y F, YANG C, et al. Enhanced thermal properties of stearic acid/carbonized maize straw composite phase change material for thermal energy storage in buildings[J]. J Energy Storage, 2021, 36: 102420.

[16] [16] LIU F L, ZHU J Q, LIU J H, et al. Preparation and properties of capric-stearic acid/White Carbon Black composite for thermal storage in building envelope[J]. Energy Build, 2018, 158: 1781-1789.

[17] [17] RATHORE P K S, SHUKLA S K. Enhanced thermophysical properties of organic PCM through shape stabilization for thermal energy storage in buildings: A state of the art review[J]. Energy Build, 2021, 236: 110799.

[18] [18] MART?N M, VILLALBA A, INES FERNANDEZ A, et al. Development of new nano-enhanced phase change materials (NEPCM) to improve energy efficiency in buildings: lab-scale characterization[J]. Energy Build, 2019, 192: 75-83.

[19] [19] KHODADADI J M, FAN L W, BABAEI H. Thermal conductivity enhancement of nanostructure-based colloidal suspensions utilized as phase change materials for thermal energy storage: A review [J]. Renew Sust Energ Rev, 2013, 24: 418-444.

[20] [20] FEI H, DU W Q, HE Q, et al. Study of phase-transition characteristics of new composite phase change materials of capric acid-palmitic acid/expanded graphite[J]. ASC Omega, 2020, 5(42): 27522-27529.

[22] [22] WEN R L, ZHANG X G, HUANG Z H, et al. Preparation and thermal properties of fatty acid/diatomite form-stable composite phase change material for thermal energy storage[J]. Sol Energy Mater Sol Cells, 2018, 178: 273-279.

[23] [23] SUN W C, HUANG R, LING Z Y, et al. Two types of composite phase change panels containing a ternary hydrated salt mixture for use in building envelope and ventilation system[J]. Energy Convers Manag, 2018, 177: 306-314.

[24] [24] 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]. Appl Therm Eng, 2019, 150: 1177-1185.

[26] [26] KONUKLU Y, OSTRY M, PAKSOY H O, et al. Review on using microencapsulated phase change materials (PCM) in building applications[J]. Energy Build, 2015, 106: 134-155.

[27] [27] LI C C, WANG M F, XIE B S, et al. Enhanced properties of diatomite-based composite phase change materials for thermal energy storage[J]. Renew Energ, 2020, 147: 265-274.

[29] [29] JEONG S-G, WI S, CHANG S J, et al. An experimental study on applying organic PCMs to gypsum-cement board for improving thermal performance of buildings in different climates[J]. Energy Build, 2019, 190: 183-194.

[30] [30] ABDEN M J, TAO Z, PAN Z, et al. Inclusion of methyl stearate/ diatomite composite in gypsum board ceiling for building energy conservation[J]. Appl Energy, 2020, 259: 114113.

[31] [31] XIAO X, ZHANG P, LI M. Effective thermal conductivity of open-cell metal foams impregnated with pure paraffin for latent heat storage[J]. Int J Therm Sci, 2014, 81: 94-105.

[32] [32] SADEGHI E, HSIEH S, BAHRAMI M. Thermal conductivity and contact resistance of metal foams[J]. J Phys D, 2011, 44(12): 125406.