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Abstrakty
Daylight is important in the design of the healthy and energy efficient indoor environment. Until now the main criterion for indoor daylighting evaluation is the Daylight Factor assuming exterior overcast sky conditions. This criterion represents minimum daylight availability needed for visual tasks and work processes. However, various outdoor daylight situations can occur during any year including also sunny, cloudy, foggy states etc. The classification of sky luminance distributions that occur in nature was done and fifteen typical sky patterns were proposed for standardisation. This result was adopted and published as ISO 15469:2004/CIE S011/E:2003 Spatial distribution of daylight - CIE Standard general sky. The standard allows to calculate typical relative sky luminance distribution which can serve to predetermine sky luminances and exterior daylight illuminance in arbitrary time and locality. The ISO/CIE Standard General Sky concept is presented together with sky luminance calculations in relative and absolute photometric units. Such an approach can orientate building physic research activities to find new criteria, methods and procedures for daylight evaluations in interiors considering more realistic daylight conditions.
Czasopismo
Rocznik
Tom
Strony
23--28
Opis fizyczny
Bibliogr. 28 poz.
Twórcy
autor
autor
- Institute of Construction and Architecture, Slovak Academy of Sciences, usarsdar@savba.sk.
Bibliografia
- [1] STN 73 0580-1 Denné osvetlenie budov, Čast` I - Základné požiadavky (Daylighting in buildings, Part. 1 - Basic requirements).
- [2] ČSN 73 0580-1 Denni osvěleni budov - Část 1: Základni požadavky (Daylighting in buildings - Part 1: Basic Requierements).
- [3] DIN 5034-1 Tageslicht in Innenräumen - Teil 1: Allgemeine Anforderungen (Daylighting in indoors - Part 1 - General requirements).
- [4] BS 8206-2:2008 Lighting for Buildings Code of Practice for daylighting.
- [5] SNIP 23-05-95 Estestvennoe i iskystvennoye osveshcheniye (Natural and artificial lighting).
- [6] Perez, R., et al., An all-weather model for sky luminance distribution. Solar Energy 50 (1991) 3 235-245.
- [7] Igawa, N., et al., Model of Sky Radiance Distribution and Sky Luminance Distribution. Solar Energy 77 (2004) 2 137-157.
- [8] Littlefair, P., The luminance distribution of an average sky. Light. Res. and Technol., 13 (1981) 4 192-198.
- [9] Perraudeau, M., Luminance models. Nat. Light.Conf. and Daylighting Coll. Cambridge. 1988.
- [10] Kittler, R., Darula, SW., Perez, R., A set of standard skies characterizing daylight conditions for computer and energy conscious design, Polygrafia, Bratislava 1998.
- [11] ISO 15469:2004/CIE S011/E:2003 Spatial distribution of daylighting-CIE Standard General Sky.
- [12] Darula, S., Kittler, R., New trends in daylight theory based on the new ISO/CIE Sky Standard 1, Zenith luminance on overcast skies. Building Research Journal, 52 (2004) 3 181-197.
- [13] Darula, S., Kittler, R., New trends in daylight theory based on the new ISO/CIE Sky Standard 2, Typology of cloudy skies and their zenith luminance. Building Research Journal 52 (2004) 4 245-255.
- [14] Darula, S., Kittler, R., New trends in daylight theory based on the new ISO/CIE Sky Standard 3, Zenith luminance formula verified by measurement data under cloudless skies. Building Research Journal 53 (2005) 19-31.
- [15] Dogniaux, R., Distribution des luminances zenithales pour des conditions de ciel serein. Communication CIE, E-3,2 Meeting Barcelona 14. 9. 1971.
- [16] Nakamura, H., Oki, M., Riga, S., Standardization of the zenith luminance in Japan. Proc. of the daylight symposium, Techn, Univ, Berlin 1980, p. 51-58.
- [17] Navvab M., et al., Analysis of atmospheric turbidity for daylight calculations Energy and Buildings 6 (1984) 293-303.
- [18] Kittler, R., Pulpitlová, J., Základy využivania prirodného svetla (Basis of the utilisation of daylight).Veda,Bratislava 1988.
- [19] Muneer, T., Solar radiation and daylight models for the energy efficient design of buildings. Architectural Press, Oxford 1997.
- [20] Soler, A., Gopinathan, K.K., A study of zenith luminance on Madrid cloudless skies. Solar Energy 69 (2000) 5 403-411.
- [21] Soler, A., Gopinathan, K.K., Relation between zenith luminances for cloudless, partly cloudy and overcast skies at Madrid. Energy Conver. and Manag. 45(2004) 15-16 2583-2590.
- [22] Rybár, P., et al., Denni osvětleni a osluněni budov (Day-lighting and insolation in buildings).ERA group, Brno 2002.
- [23] Darula, S., Kittler, R., Sekvencie situácii dennej osvetlenosti v Bratislave (Sequences of daylight situations in Bratislava). Proc. 5th Int. Conf, Licht 2002, Brno, Česka společnost pro osvětlováni 2002 p. 20-24.
- [24] Darula, S., Kittler, R. CIE General Sky standard defining luminance distributions. The bi-annual conf. of IBPSA Canada eSim 2002, http://www.esim.ca/2002/documents/Proceedinss/other2.vdf.
- [25] Kittler, R. et al., Advantages of New Sky Standards: More realistic modelling of daylight conditions in energy and environmental studies. International Journal of Energy, Environment and Economics. 8 (1999) 1 65-72.
- [26] Kasten F. and Young A.T., Revised optical air mass tables and approximation formula. Appl. Optics 28 (1989)4735-4738.
- [27] Clear R., Calculation of turbidity and direct sun illuminance. Memo to Daylight Group, LBL Berkeley, Cal. (1982).
- [28] Roy, G.G., Kittler, R., Darula, S. An implementation of the Method of Aperture Meridians for the ISO/CIE Standard General Sky. Lighting Research and Technology. 39 (2007) 3 253-264.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-LOD6-0009-0004