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© 2011 Autodesk Vasari Talk – How accurate is Vasari? Wednesday 11 th October 2012.

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Presentation on theme: "© 2011 Autodesk Vasari Talk – How accurate is Vasari? Wednesday 11 th October 2012."— Presentation transcript:

1 © 2011 Autodesk Vasari Talk – How accurate is Vasari? Wednesday 11 th October 2012

2 © 2011 Autodesk Outline of discussion topics…  Energy analysis (20-25 min):  The purpose of Vasari / Conceptual Energy Analysis  Main drivers of energy use/cost (and analysis) of buildings  Computational accuracy Vs. Information accuracy  DOE2 simulation engine strengths and weaknesses  Key things to watch out for  Solar analysis (5-10 min):  Outline of the computational method  Wind analysis (5-10 min):  Computational Fluid Dynamics  2D & 3D / Meshing / Turbulence  Validation  Q&A (15-30 min)

3 © 2011 Autodesk Energy analysis… The purpose of Vasari / Conceptual Energy Analysis:  BIM based (parametric) conceptual modeling  Application to early design stage e.g. master planning, concept  Rapid model development and feedback on performance  Building form and envelope ‘optimization’  ‘Directionally accurate’ analysis

4 © 2011 Autodesk Driver Design / Operational ComponentsVasari Information / Assumptions ClimateOperational Air temperature Relative humidity Direct & Diffuse solar radiation Wind speed & direction Typical Meteorological Years (TMYs) 1.2 million+ worldwide (2004 & 2006) Exact location and period specific (GBS) Form / LayoutDesign Orientation Massing Percentage glazing Exterior shading Conceptual masses with auto-zoning MaterialsDesign Layer Density, Specific Heat Capacity and Conductivity Element Absorptance, Roughness Glazing U-value, SHGC, VLT Conceptual constructions (broad brush - typical, high or low performance options) SystemsDesign Lighting, Equipment Primary heating and cooling Secondary distribution Controls ASHRAE building / space type data (fixed) ASHRAE baseline system types (‘generally’ / fixed) UseOperational Occupancy Hours of operation Set-points ASHRAE building / space type data (fixed) TariffsOperational $ / kWh electricity $ / kWh fuel State wide flat rate averages Energy analysis... Main drivers of energy use / cost (and analysis) of buildings: Goal of Vasari / CEA Reliable / Consistent Set by building / space type Reasonable assumptions

5 © 2011 Autodesk DriverComponents Climate Air temperature Relative humidity Direct & Diffuse solar radiation Wind speed & direction Form / Layout Orientation Massing Percentage glazing Exterior shading Materials Layer Density, Specific Heat Capacity and Conductivity Element Absorptance, Roughness Glazing U-value, SHGC, VLT Systems Lighting, Equipment Primary heating and cooling Secondary distribution Controls Use Occupancy Hours of operation Set-points Tariffs $ / kWh electricity $ / kWh fuel Energy Analysis… Computational accuracy Vs. Information accuracy: External and internal heat losses and gains via conduction, convection & radiation + HVAC system efficiency Main Computational Components: Well understood and proven… Main Information Components: Information, understanding and time are by far the weakest links…

6 © 2011 Autodesk Energy analysis…  DOE2 simulation engine strengths and weaknesses: + Whole building dynamic thermal energy simulation + Well understood and proven + Very fast - Hourly time steps - Decoupled building and HVAC system simulation - Some simplification of building thermal mass - Some simplification of solar radiation transfer - Limited inter-zonal air exchange (‘bulk’ airflow simulation) - Advanced HVAC systems e.g. displacement ventilation, radiant heating/cooling etc.

7 © 2011 Autodesk Energy analysis…  Key things to watch out for:  Large open spaces  Highly glazed areas  Advanced materials e.g. transparent insulation  Advanced systems e.g. displacement ventilation, radiant h/c  Passive solar features e.g. natural ventilation  Building type detail e.g. an office vs a house  Thermal bridging ‘Thermally complex’ like atria, double skin facades

8 © 2011 Autodesk Solar analysis…  Outline of the computational method  Conceptual masses / surfaces  Latitude, Longitude and Site Elevation  Solar Azimuth & Altitude  Direct and Diffuse solar radiation:  Hourly values from climate data (can be downloaded from GBS)  Different climate data yields different results  Validation

9 © 2011 Autodesk Wind analysis  Computational Fluid Dynamics  Derived from Autodesk Moldflow (aka Falcon) and includes:  Automatic voxel based meshing  2D & 3D Navier Stokes  Incompressible fluid / Finite volume  Large Eddy Simulation (LES) Smagorinksy Turbulence model  Transient i.e. simulates change over time  Climate data driven to help understand local wind effects  Validation Very fast!

10 © 2011 Autodesk Q&A…

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