EN673+ISO 10077_Using THERM+WINDOW-LBNL_rev4.pdf
EN673+ISO 10077_Using THERM+WINDOW-LBNL_rev4.pdf EN673+ISO 10077_Using THERM+WINDOW-LBNL_rev4.pdf
1.2. MODELING IMPLEMENTATION:Figure 1-3. In Schematic representation of surfaces with an increased surface resistancedue to a reduced radiation/convection heat transfer1-6 SEPTEMBER 17, 2012
1.2. MODELING IMPLEMENTATION:Set Edge of Glass Dimensionand Glazing System Height to190 mm.Set Exterior BoundaryCondition to “CEN – Outdoor”Set Interior BoundaryCondition to “CEN – Indoor”Figure 1-4. In THERM, insert the glazing system using CEN criteria for Edge of Glass Dimension,Glazing System Height, and Boundary Conditions.8. Set the boundary condition to “CEN – Outdoor” on all of outdoor surfaces (glazing and frame)9. Set the remaining boundary conditions to “CEN – Indoor” on the indoor side, including the glazingand frame.SEPTEMBER 17, 2012 1-7
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1.2. MODELING IMPLEMENTATION:Set Edge of Glass Dimensionand Glazing System Height to190 mm.Set Exterior BoundaryCondition to “CEN – Outdoor”Set Interior BoundaryCondition to “CEN – Indoor”Figure 1-4. In THERM, insert the glazing system using CEN criteria for Edge of Glass Dimension,Glazing System Height, and Boundary Conditions.8. Set the boundary condition to “CEN – Outdoor” on all of outdoor surfaces (glazing and frame)9. Set the remaining boundary conditions to “CEN – Indoor” on the indoor side, including the glazingand frame.SEPTEMBER 17, 2012 1-7