Numerical analysis on thermal performance of a PCM-filled double glazing roof

Energy and Buildings

Volumn 125, Issue , 2016, Pages 267-275

  Liu, Changyu ^a   Zhou, Yingming ^a   Li, Dong ^a   Meng, Fanbin ^a   Zheng, Yumeng ^a   Liu, Xiaoyan ^a  

^a NORTHEAST PETROLEUM UNIVERSITY   (China)

Author keywords

Double glazing roof; Phase change material (PCM); Thermal performance

Indexed keywords

ENERGY UTILIZATION; GLAZES; HEAT STORAGE; PHASE CHANGE MATERIALS; SOLAR ENERGY;

BUILDING ENERGY CONSUMPTION; DIFFERENT THICKNESS; DOUBLE GLAZINGS; EXTINCTION COEFFICIENTS; SEMI-TRANSPARENT; SOLAR TRANSMITTANCE; THERMAL PERFORMANCE; THICKNESS EFFECT;

ROOFS;

EID: 84970948422     PISSN: 03787788     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.enbuild.2016.05.002     Document Type: Article

References (38)

1. C. Erdem, C.H. Young, and B.R. Saffa Performance investigation of heat insulation solar glass for low-carbon buildings Energy Convers. Manage. 88 2014 834 841
2. D. Zhou, C.Y. Zhao, and Y. Tian Reviw on thermal energy storage with phase change materials (PCMs) in building applications Appl. Energy 92 2012 593 605
3. X.F. Kong, S.L. Lu, Y.R. Li, and et al. Numerical study on the thermal performance of building wall and roof incorporating phase change material panel for passive cooling application Energy Build. 81 2014 404 415
4. D. Li, Y.M. Zheng, and C.Y. Liu Numerical analysis on thermal performance of roof contained PCM of a single residential building Energy Convers. Manage. 17 2015 147 156
5. K.C.K. Vijaykumar, P.S.S. Srinivasan, and S. Dhandapani A performance of hollow tiles clay (HTC) laid reinforced cement concrete (RCC) roof for tropical summer climates Energy Build. 39 1 2007 886 892
6. M.C. Yew, N.H.R. Sulong, W.T. Chong, and et al. Intergration of thermal insulation coating and moving-air-cavity in a cool roof system for attic temperature reduction Energy Convers. Manage. 75 2013 241 248
7. K.M. Al-Obaidi, M. Ismail, and A.M.A. Rahman Design and performance of a novel innovative roofing system for tropical landed houses Energy Convers. Manage. 85 2014 488 504
8. W. Saman, F. Bruno, and E. Halawa Thermal performance of PCM thermal storage unit for a roof integrated solar heating system Sol. Energy 78 2005 341 349
9. A. Carbonari, M.D. Grassi, C.D. Perna, and et al. Numerical and experimental analyses of PCM containing sandwich panels for prefabricated walls Energy Build. 38 2006 472 483
10. H.B. Liu, X.W. Liao, Z.H. Chen, and Q. Zhang Thermal behavior of spatial structures under solar irradiation Appl. Energy 87 2015 328 335
11. F. Wang, K. Pichatwatana, S. Roaf, L.H. Zhao, Z.C. Zhu, and J.Y. Li Developing a weather responsive internal shading system for atrium spaces of a commercial building in tropical climates Build. Environ. 71 2014 259 274
12. J. Kośny, K. Biswas, W. Miller, and et al. Field thermal performance of naturally ventilated solar roof with PCM heat sink Sol. Energy 86 2012 2504 2514
13. A. Pasupathy, and R. Velraj Effect of double layer phase change material in building roof for year round thermal management Energy Build. 40 2008 193 203
14. A. Pasupathy, L. Athanasius, R. Velraj, and et al. Experimental investigation and numerical simulation analysis on the thermal performance of a building roof incorporating phase change material (PCM) for thermal management Appl. Therm. Eng. 28 2008 556 565
15. G. Barrios, G. Huelsz, J. Rojas, and et al. Envelope wall/roof thermal performance parameters for non air-conditioned buildings Energy Build. 50 2012 120 127
16. M.A. Izquierdo-Barrientos, J.F. Belmonte, D. Rodríguez-Sánchez, and et al. A numerical study of external building walls containing phase change materials (PCM) Appl. Therm. Eng. 7 47 2012 3 85
17. T. Kousksou, A. Arid, A. Jamil, and et al. Thermal behavior of building material containing microencapsulated PCM Thermochim. Acta 550 2012 42 47
18. G. Evola, L. Marletta, and F. Sicurella A methodology for investigating the effectiveness of PCM wallboards for summer thermal comfort in buildings Build. Environ. 51 59 2013 7 527
19. G. Evola, L. Marletta, and F. Sicurella Simulation of a ventilated cavity to enhance the effectiveness of PCM wallboards for summer thermal comfort in buildings Energy Build. 70 2014 480 489
20. M. Ozel Thermal, economical and environmental analysis of insulated building walls in a cold climate Energy Convers. Manage. 76 2013 674 684
21. H.M. Chou, C.R. Chen, and V.L. Nguyen A new design of metal-sheet cool roof using PCM Energy Build. 4 57 2013 2 50
22. S. Guichard, F. Miranville, D. Bigot, and et al. A thermal model for phase change materials in a building roof for a tropical and humid climate: model description and elements of validation Energy Build. 7 70 2014 1 80
23. N. Hichem, S. Noureddine, S. Nadia, and et al. Experimental and numerical study of a usual brick filled with PCM to improve the thermal inertia of buildings Energy Procedia 36 2013 766 775
24. B.L. Gowreesunker, and S.A. Tassou Effectiveness of CFD simulation for the performance prediction of phase change building boards in the thermal environment control of indoor spaces Build. Environ. 59 2013 612 625
25. E.M. Alawadhi, and H.J. Alqallaf Building roof with conical holes containing PCM to reduce the cooling load: numerical study Energy Convers. Manage. 52 2011 2958 2964
26. H.J. Alqallaf, and E.M. Alawadhi Concrete roof with cylindrical holes containing PCM to reduce the heat gain Energy Build. 61 2013 73 80
27. H. Weinlaeder, W. Koerner, M. Heidenfelder, and et al. Monitoring results of an interior sun protection system with integrated latent heat storage Energy Build. 43 2011 2457 2467
28. A. Gracia, L. Navarro, A. Castell, and et al. Experimental study of a ventilated façade with PCM during winter period Energy Build. 58 2013 324 332
29. T. Silva, R. Vicente, F. Rodrigues, and et al. Performance of a window shutter with phase change material under summer Mediterranean climate conditions Appl. Therm. Eng. 84 2015 246 256
30. F. Kuznik, J. Virgone, K. Johannes, and et al. In-situ study of thermal comfort enhancement in a renovated building equipped with phase change material wallboard Renew. Energy 145 36 2011 8 1462
31. F. Goia, M. Perino, V. Serra, and et al. Experimental analysis of the energy performance of a full-scale PCM glazing prototype Sol. Energy 100 2014 217 233
32. K.A.R. Ismail, C.T. Salinas, and J.R. Henriquez Comparison between PCM filled glass windows and absorbing gas filled windows Energy Build. 40 2008 710 719
33. K.C. Zhong, S.H. Li, G. Sun, and et al. Simulation study on dynamic heat transfer performance of PCM-filled glass window with different thermophysical parameters of phase change material Energy Build. 106 2015 87 95
34. D. Li, H.B. Qi, and G.Z. Wu Determined optical constants of liquid hydrocarbon fuel by a novel transmittance method Optik 126 2015 834 837
35. F.Q. Wang, J.Y. Tan, L.X. Ma, Y. Shuai, H.P. Tan, and Y. Leng Thermal performance analysis of porous medium solar receiver with quartz window to minimize heat flux gradient Sol. Energy 108 2014 348 359
36. G. Francesco, P. Marco, and H. Matthias A numerical model to evaluate the thermal behaviour of PCM glazing system configurations Energy Build. 14 54 2012 1 153
37. S.H. Li, K.C. Zhong, Y. Zhou, and et al. Comparative study on the dynamic heat transfer characteristics of PCM-filled glass window and hollow glass window Energy Build. 85 2014 483 492
38. B.L. Gowreesunker, S.B. Stankovic, S.A. Tassou, and et al. Experimental and numerical investigations of the optical and thermal aspects of a PCM-glazed unit Energy Build. 61 2013 239 249