Recent advancement in BIPV product technologies: A review

Energy and Buildings

Volumn 140, Issue , 2017, Pages 188-195

  Shukla, Akash Kumar ^a   Sudhakar, K ^a,b   Baredar, Prashant ^a  

^a MAULANA AZAD NATIONAL INSTITUTE OF TECHNOLOGY   (India)

^b University of Malaysia   (Malaysia)

Author keywords

BIPV; Facades; Fill factor; GHG; LCA; Rooftops

Indexed keywords

FACADES; LIFE CYCLE; STANDARDS;

BIPV; BUILDING INTEGRATED PHOTOVOLTAIC; ENERGY PAY BACK TIME; FILL FACTOR; PRODUCT TECHNOLOGY; ROOFTOPS; SUSTAINABLE ASSESSMENT; ZERO EMISSION BUILDINGS;

GREENHOUSE GASES;

EID: 85012065215     PISSN: 03787788     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.enbuild.2017.02.015     Document Type: Review

References (57)

1. [1] Enkvist, A.P., Dinkel, J., Lin, C., Impact of the Financial Crisis on Carbon Economics: Version 2.1 of the Global Greenhouse Gas Abatement Cost Curve. 2010, McKinsey & Company.
2. [2] Peng, J., Lu, L., Yang, H., Review on life cycle assessment of energy payback and greenhouse gas emission of solar photovoltaic systems. Renew. Sustain. Energy Rev. 19 (2013), 255–274.
3. [3] Li, G., Comprehensive investigations of life cycle climate performance of packaged air source heat pumps for residential application. Renew. Sustain. Energy Rev. 43 (2015), 702–710.
4. [4] Seng, L.Y., Lalchand, G., Lin, G.M., Economical, environmental and technical analysis of building integrated photovoltaic systems in Malaysia. Energy Policy 36:6 (2008), 2130–2142.
5. [5] Li, G., Review of Thermal Energy Storage Technologies and Experimental Investigation of Adsorption Thermal Energy Storage for Residential Application. Thesis. 2013, University of Maryland at College Park, United States.
6. [6] Pacca, S., Sivaraman, D., Keoleian, G.A., Parameters affecting the life cycle performance of PV technologies and systems. Energy Policy 35:6 (2007), 3316–3326.
7. [7] Li, G., Hwang, Y., Radermacher, R., Chun, H.H., Review of cold storage materials for subzero applications. Energy 51 (2013), 1–7.
8. [8] Raugei, M., Bargigli, S., Ulgiati, S., Life cycle assessment and energy pay-back time of advanced photovoltaic modules: CdTe and CIS compared to poly-Si. Energy 32:8 (2007), 1310–1318.
9. [9] Li, G., Hwang, Y., Radermacher, R., Experimental investigation on energy and exergy performance of adsorption cold storage for space cooling application. Int. J. Refrig. 44 (2014), 23–35.
10. [10] Alsema, E.A., de Wild-Scholten, M.J., Fthenakis, V.M., Environmental impacts of PV electricity generation-acritical comparison of energy supply options. Proceedings of the 21st European Photovoltaic Solar Energy Conference, Dresden, Germany, Sep 4, 2006 (p. 3201).
11. [11] Li, G., Hwang, Y., Radermacher, R., Review of cold storage materials for air conditioning application. Int. J. Refrig. 35:8 (2012), 2053–2077.
12. [12] Ito, M., Kato, K., Komoto, K., Kichimi, T., Kurokawa, K., A comparative study on cost and life cycle analysis for 100 MW very large-scale PV (VLS-PV) systems in deserts using m-Si,a-Si, CdTe, and CIS modules. Progr. Photovolt. Res. Appl. 16:1 (2008), 17–30.
13. [13] Li, G., Liu, D., Xie, Y., Xiao, Y., Study on effect factors for CO2 hydrate rapid formation in a water spraying apparatus. Energy Fuels 24:8 (2010), 4590–4597.
14. [14] Held, M., Ilg, R., Update of environmental indicators and energy payback time of CdTe PV systems in Europe. Progr. Photovolt. Res. Appl. 19:August (5) (2011), 614–626.
15. [15] European commission, Communication from the commission to the European parliament, the Council, the European Economic and social committee and the committee of the regions 20 20 by 2020 Europe's climate change opportunity.Com; 2008, 30 final.
16. [16] Hammond, G.P., Harajli, H.A., Jones, C.I., Winnett, A.B., Whole systems appraisal of a UK Building Integrated Photovoltaic (BIPV) system: energy, environmental, and economic evaluations. Energy Policy 40 (2012), 219–230.
17. [17] Parida, B., Iniyan, S., Goic, R., A review of solar photovoltaic technologies. Renew. Sustain. Energy Rev. 15:3 (2011), 1625–1636.
18. [18] Wilson, R., Young, A., The embodied energy payback period of photovoltaic installations applied to buildings in the UK. Build. Environ. 31:4 (1996), 299–305.
19. [19] Raugei, M., Frankl, P., Life cycle impacts and costs of photovoltaic systems: current state of the art and future outlooks. Energy 34:3 (2009), 392–399.
20. [20] Shukla, K.N., Sudhakar, K., Rangnekar, S., Comparative study of isotropic and anisotropic sky models to estimate solar radiation incident on tilted surface: a case study for Bhopal, India. Energy Rep. 1 (2015), 96–103.
21. [21] D. Prasad, M. Snow, Designing with solar power: a source book for building integrated photovoltaics (BIPV). Routledge; 2014, Apr 23.
22. [22] Shukla, A.K., Sudhakar, K., Baredar, P., Simulation and performance analysis of 110 kWp grid-connected photovoltaic system for residential building in India: a comparative analysis of various PV technology. Energy Rep. 2 (2016), 82–88.
23. [23] Pagliaro, M., Ciriminna, R., Palmisano, G., BIPV: merging the photovoltaic with the construction industry. Progr. Photovolt. Res. Appl. 18:1 (2010), 61–72.
24. [24] Sudhakar, K., Srivastava, T., Energy and exergy analysis of 36W solar photovoltaic module. Int. J. Ambient Energy, 2013 http://dx.doi.org/10.1080/01430750.2013.770799.
25. [25] Peng, C., Huang, Y., Wu, Z., Building-integrated photovoltaic (BIPV) in architectural design in China. Energy Build. 43:12 (2011), 3592–3598.
26. [26] Kumar, B.S., Sudhakar, K., Performance evaluation of 10 MW grid connected solar photovoltaic power plant in India. Energy Rep. 1 (2015), 184–192.
27. [27] J. Neuwald. All you need to know About Building Integrated Photovoltaic- part 2, roof consuit, [accessed 09.11.11].
28. [28] Shukla, K.N., Sudhakar, K., Rangnekar, S., Estimation and validation of solar radiation incident on horizontal and tilted surface at Bhopal, Madhya Pradesh, India. Am. Eur. J. Agric. Environ. Sci. 15 (2015), 129–139.
29. [29] Posnansky, M., Szacsvay, T., Eckmanns, A., Jürgens, J., New electricity construction materials for roofs and façades. Renew. Energ. 15:1 (1998), 541–544.
30. [30] Shukla, K.N., Sudhakar, K., Rangnekar, S., Mathematical modelling of solar radiation incident on tilted surface for photovoltaic application at Bhopal, M.P., India. Int. J. Ambient Energy, 2015 http://dx.doi.org/10.1080/01430750.2015.102383(04/2015).
31. [31] Benemann, J., Chehab, O., Schaar-Gabriel, E., Building-integrated PV modules. Sol. Energy Mater. Sol. Cells 67:1 (2001), 345–354.
32. [32] Shukla, K.N., Sudhakar, K., Rangnekar, S., A comparative study of exergetic performance of amorphous and polycrystalline solar PV modules. Int. J. Energy 17 (2015), 433–455.
33. [33] Fraile, D., Despotou, E., Latour, M., Slusaz, T., Weiss, I., Caneva, S., Helm, P., Goodal, J., Fintikakis, N., Schellekens, E., PV Diffusion in the Building Sector. 2008, European Photovoltaic Industry Association, Sunrise Project.
34. [34] Shukla, A.K., Sudhakar, K., Baredar, P., Exergetic analysis of building integrated semitransparent photovoltaic module in clear sky condition at Bhopal India. Case Studies in Thermal Engineering 8 (2016), 142–151.
35. [35] ISO.ISO 14040: Environmental management: life cycle assessment: principles and framework-Management environmental: analyze du cycle de vie: principles et cadre. Geneva: International Standards for Organization; 2006.
36. [36] Shukla, A.K., Sudhakar, K., Baredar, P., Design, simulation and economic analysis of standalone roof top solar PV system in India. Sol. Energy 136 (2016), 437–449.
37. [37] ISO.ISO 14044: Environmental management: life cycle assessment: requirements and guidelines-Management environmemental: analyse du cycle de vie: exigencies et lignes directrices. Geneva: International Standards for Organization; 2006.
38. [38] Shukla, A.K., Sudhakar, K., Baredar, P., Exergetic assessment of BIPV module using parametric and photonic energy methods: a review. Energy Build. 119 (2016), 62–73.
39. [39] Smith, A.W., Rohatgi, A., Ray tracing analysis of the inverted pyramid texturing geometry for high efficiency silicon solar cells. Sol. Energy Mater. Sol. Cells 29:1 (1993), 37–49.
40. [40] Shukla, A.K., Sudhakar, K., Baredar, P., A comprehensive review on design of building integrated photovoltaic system. Energy Build. 128 (2016), 99–110.
41. [41] Grätzel, M., Dye-sensitized solar cells. J. Photochem. Photobiol. C: Photochem. Rev. 4:2 (2003), 145–153.
42. [42] Tripathy, M., Sadhu, P.K., Panda, S.K., A critical review on building integrated photovoltaic products and their applications. Renew. Sustain. Energy Rev. 61 (2016), 451–465.
43. [43] Jørgensen, M., Norrman, K., Krebs, F.C., Stability/degradation of polymer solar cells. Sol. Energy Mater. Sol. Cells 92:7 (2008), 686–714.
44. [44] Ecotec Energy AG Inc., Standard test conditions. [accessed 11.11.11].
45. [45] Science Daily, Taking nature's cue for cheaper solar power; April6, 2007 [accessed 19.11.10].
46. [46] European committee for Electrotechnical Standardizations. Photovoltaic (PV) module safety qualification-Part 1: requirements for construction, EN61730-1, European Standard; 2007.
47. [47] European committee for Electrotechnical Standardization. Crystalline Silicon Terrestrial Photovoltaic (PV) modules-design qualification and type approval, EN 61215, European Standard; 2005.
48. [48] European committee for Electrotecnical Standardization. Photovoltaic (PV) module safety qualification-Part 2: requirements for construction, EN61730-2, European Standard; 2007.
49. [49] European committee for Electrotechnical Standardization. Thin-film terrestrial photovoltaic (PV) modules −design qualification and type approval, EN 61646, European Standard; 2008.
50. [50] Underwriters Laboratories Inc. UL1703UL standard for safety flat-plate photovoltaic modules and panels; 2002.
51. [51] Amadelli, R., Argazzi, R., Bignozzi, C.A., Scandola, F., Design of antenna-sensitizer poly nuclear complexes: sensitization of titanium dioxide. J. Am. Chem. Soc. 112:20 (1990), 7099–7103.
52. [52] Posnansky, M., Szacsvay, T., Eckmanns, A., Jürgens, J., New electricity construction materials for roofs and façades. Renew. Energ. 15:1 (1998), 541–544.
53. [53] Benemann, J., Chehab, O., Schaar-Gabriel, E., Building-integrated PV modules. Sol. Energy Mater. Sol. Cells 67:1 (2001), 345–354.
54. [54] Tripathy, M., Yadav, S., Sadhu, P.K., Panda, S.K., Determination of optimum tilt angle and accurate insolation of BIPV panel influenced by adverse effect of shadow. Renew. Energy 104 (2017), 211–223.
55. [55] Ng, P.K., Mithraratne, N., Lifetime performance of semi-transparent buildingintegrated photovoltaic (BIPV) glazing systems in the tropics. Renew. Sustain. Energy Rev. 31 (2014), 736–745.
56. [56] Lu, L., Yang, H.X., Environmental payback time analysis of a roof-mounted building-integrated photovoltaic (BIPV) system in Hong Kong. Appl. Energy 87 (2010), 3625–3631.
57. [57] Keoleian, G.A., Lewis, G.M., Modeling the life cycle energy and environmental performance of amorphous silicon BIPV roofing in the US. Renew. Energy 28 (2003), 271–293.