02197nas a2200229 4500008003900000245013800039210006900177260001200246300001200258490000700270520138900277653005201666653003301718653001601751653002001767100001901787700002301806700002101829700002201850700002101872856007401893 2013 d00aA validation of a ray-tracing tool used to generate bi-directional scattering distribution functions for complex fenestration systems0 avalidation of a raytracing tool used to generate bidirectional s c12/2013 a404-4140 v983 a
Fenestration attachments are anticipated to produce significant reductions in building energy use because they can be deployed quickly at low-cost. New software tools enable users to assess the building energy impacts of optically complex fenestration systems (CFS) such as shades, Venetian blinds, or daylighting systems. However, such tools require users to provide bi-directional scattering distribution function (BSDF) data that describe the solar-optical performance of the CFS. A free, open-source Radiance tool genBSDF enables users to generate BSDF data for arbitrary CFS. Prior to genBSDF, BSDF data for arbitrary fenestration systems could only be produced using either expensive software or with expensive equipment. genBSDF outputs CFS data in the Window 6 XML file format and so can be used with CFS-enabled software tools to model multi-layered window systems composed of glazing and shading layers.
We explain the basis and use of the genBSDF tool and validate the tool by comparing results for four different cases to BSDF data produced via alternate methods. This validation demonstrates that BSDFs created with genBSDF are comparable to BSDFs generated analytically using TracePro and by measurement with a scanning goniophotometer. This tool is expected to support accelerated adoption of fenestration attachments and daylighting technologies.
10aBi-directional scattering distribution function10aComplex fenestration systems10adaylighting10aSolar heat gain1 aMcNeil, Andrew1 aJonsson, Jacob, C.1 aAppelfeld, David1 aWard, Gregory, J.1 aLee, Eleanor, S. uhttps://facades.lbl.gov/publications/validation-ray-tracing-tool-used01798nas a2200193 4500008003900000245013300039210006900172490000700241520111100248653003501359653003201394653001301426653001201439653001601451100002101467700001901488700002001507856007701527 2012 d00aAn Hourly-Based Performance Comparison of an Integrated Micro-Structural Perforated Shading Screen with Standard Shading Systems0 aHourlyBased Performance Comparison of an Integrated MicroStructu0 v503 aThis article evaluates the performance of an integrated micro structural perforated shading screen (MSPSS). Such a system maintains a visual connection with the outdoors while imitating the shading functionality of a venetian blind. Building energy consumption is strongly influenced by the solar gains and heat transfer through the transparent parts of the fenestration systems. MSPSS is angular-dependent shading device that provides an effective strategy in the control of daylight, solar gains and overheating through windows. The study focuses on using direct experimental methods to determine bi-directional transmittance properties of shading systems that are not included as standard shading options in readily available building performance simulation tools. The impact on the indoor environment, particularly temperature and daylight were investigated and compared to three other static complex fenestration systems. The bi-directional description of the systems was used throughout the article. The simulations were validated against outdoor measurements of solar and light transmittance.
10abuilding performance modelling10acomplex fenestration system10adaylight10ashading10asolar gains1 aAppelfeld, David1 aMcNeil, Andrew1 aSvendsen, Svend uhttps://facades.lbl.gov/publications/hourly-based-performance-comparison