HongCWangYGuZYuCW. Cool facades to mitigate urban heat island effects. Indoor Built Environ2022; 31(10): 2373–2377. DOI: 10.1177/1420326X221115369.
2.
KouFShiSZhuNSongYZouYMoJWangX. Improving the indoor thermal environment in lightweight buildings in winter by passive solar heating: an experimental study. Indoor Built Environ2022; 31(9): 2257–2273. DOI: 10.1177/1420326X221091448.
3.
BurattiCMorettiE. Lighting and energetic characteristics of transparent insulating materials: experimental data and calculation. Indoor Built Environ2011; 20(4): 400–411. DOI: 10.1177/1420326X11409470.
4.
XuCMaXYuCWF. Photovoltaic double-skin façade: a combination of active and passive utilizations of solar energy. Indoor Built Environ2019; 28(8): 1013–1017. DOI: 10.1177/1420326X19856710.
5.
YilmazYSansalKEAscigil-DincerMKulturSTanrioverSH. A methodology to determine appropriate façade aperture sizes considering comfort and performance criteria: a primary school classroom case. Indoor Built Environ2022; 31(7): 1874–1891. DOI: 10.1177/1420326X221080566.
6.
WangZAkhlaghiYGTianQChengY. The performance of a novel window with energy-saving potential in cold regions of China. Indoor Built Environ2022; 31(1): 245–264. DOI: 10.1177/1420326X20979727.
7.
FokaidesPAKyliliAKalogirouSA. Phase change materials (PCMs) integrated into transparent building elements: a review. Mater Renew Sustain Energy2015; 4(2): 6. DOI: 10.1007/s40243-015-0047-8.
8.
JunaidMFRehmanZUCekonMCurpekJFarooqRCuiHKhanI. Inorganic phase change materials in thermal energy storage: a review on perspectives and technological advances in building applications. Energy Build2021; 252: 111443. DOI: 10.1016/j.enbuild.2021.111443.
9.
MaMXieMAiQ. Study on photothermal properties of Zn-ZnO/paraffin binary nanofluids as a filler for double glazing unit. Int J Heat Mass Transf2022; 183: 122173. DOI: 10.1016/j.ijheatmasstransfer.2021.122173.
10.
ZhangGWangZLiDWuYAriciM. Seasonal thermal performance analysis of glazed window filled with paraffin including various nanoparticles. Int J Energy Res2020; 44(4): 3008–3019. DOI: 10.1002/er.5129.
11.
XieNNiuJWuTGaoXFangYZhangZ. Fabrication and characterization of CaCl2·6H2O composite phase change material in the presence of CsxWO3 nanoparticles. Sol Energy Mater Sol Cell2019; 200: 110034. DOI: 10.1016/j.solmat.2019.110034.
12.
LiDZhangCLiQLiuCAriciMWuY. Thermal performance evaluation of glass window combining silica aerogels and phase change materials for cold climate of China. Appl Therm Eng2020; 165: 114547. DOI: 10.1016/j.applthermaleng.2019.114547.
13.
ZhangSHuWLiDZhangCAriciMYildizCZhangXMaY. Energy efficiency optimization of PCM and aerogel-filled multiple glazing windows. Energy2021; 222: 119916. DOI: 10.1016/j.energy.2021.119916.
14.
LiuCWuYZhuYLiDMaL. Experimental investigation of optical and thermal performance of a PCM-glazed unit for building applications. Energy Build2018; 158: 794–800. DOI: 10.1016/j.enbuild.2017.10.069.
15.
DurakovicBTorlakM. Experimental and numerical study of a PCM window model as a thermal energy storage unit. Int J Low Carbon Technol2016; 12(3): 272–280. DOI: 10.1093/ijlct/ctw024.
16.
WeinladerHBeckAFrickeJ. PCM-facade-panel for daylighting and room heating. Solar Energy2005; 78(2): 177–186. DOI: 10.1016/j.solener.2004.04.013.
17.
LiuCZhangGAriciMBianJLiD. Thermal performance of non-ventilated multilayer glazing facades filled with phase change material. Solar Energy2019; 177: 464–470. DOI: 10.1016/j.solener.2018.11.044.
18.
AlawadhiEM. Using phase change materials in window shutter to reduce the solar heat gain. Energy Build2012; 47: 421–429. DOI: 10.1016/j.enbuild.2011.12.009.
19.
GoiaFBiancoLCasconeYPerinoMSerraV. Experimental analysis of an advanced dynamic glazing prototype integrating PCM and thermotropic layers. Energy Proced2014; 48: 1272–1281. DOI: 10.1016/j.egypro.2014.02.144.
20.
KhetibYAlotaibiAAAlshahriAHRawaMCheraghianGSharifpurM. Impact of phase change material on the amount of emission in the double-glazed window frame for different window angles. J Energy Storage2021; 44: 103320. DOI: 10.1016/j.est.2021.103320.
21.
LiSZhouYZhongKZhangXJinX. Thermal analysis of PCM-filled glass windows in hot summer and cold winter area. Int J Low Carbon Technol2016; 11(2): 275–282. DOI: 10.1093/ijlct/ctt073.
22.
LiSZhongKZhouYZhangX. Comparative study on the dynamic heat transfer characteristics of PCM-filled glass window and hollow glass window. Energy Build2014; 85: 483–492. DOI: 10.1016/j.enbuild.2014.09.054.
23.
KarthickAAthikesavanMMPasupathiMKKumarNMChopraSSGhoshA. Investigation of inorganic phase change material for a semi-transparent photovoltaic (STPV) module. Energies2020; 13(14): 3582. DOI: 10.3390/en13143582.
24.
VignaIBiancoLGoiaFSerraV. Phase change materials in transparent building envelopes: a strengths, weakness, opportunities and threats (SWOT) analysis. Energies2018; 11(1): 111. DOI: 10.3390/en11010111.
25.
GoiaF.. Thermo-physical behaviour and energy performance assessment of PCM glazing system configurations: a numerical analysis. Front Archit Res2012; 1: 341–347.
26.
GiovanniniLGoiaFLo VersoVRMSerraV. A Comparative analysis of the visual comfort performance between a PCM glazing and a conventional selective double glazed unit. Sustainability2018; 10(10): 3579. DOI: 10.3390/su10103579.
27.
LiQWangYMaLAriciMLiDYildizCZhuY. Effect of sunspace and PCM louver combination on the energy saving of rural residences: Case study in a severe cold region of China. Sustain Energy Technol Assess2021; 45: 101126. DOI: 10.1016/j.seta.2021.101126.
28.
KeWJiJWangCZhangCXieHTangYLinY. Comparative analysis on the electrical and thermal performance of two CdTe multi-layer ventilated windows with and without a middle PCM layer: a preliminary numerical study. Renew Energy2022; 189: 1306–1323. DOI: 10.1016/j.renene.
29.
BuddhiDSharmaSD. Measurements of transmittance of solar radiation through stearic acid: a latent heat storage material. Energy Convers Manag1999; 40: 1979–1984.
30.
SoaresNCostaJJGasparARSantosP. Review of passive PCM latent heat thermal energy storage systems towards buildings’ energy efficiency. Energy Build2013; 59: 82–103.
