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basics:building_physics_-_basics:thermal_bridges:tbcalculation:examples:unheatedb

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basics:building_physics_-_basics:thermal_bridges:tbcalculation:examples:unheatedb [2024/10/09 10:03] yaling.hsiao@passiv.debasics:building_physics_-_basics:thermal_bridges:tbcalculation:examples:unheatedb [2025/01/24 13:55] (current) – old revision restored (2025/01/23 11:52) mpatyna
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 The conductance $L_{iu}$ is now assigned to the floor slab, $L_{ie}$ is assigned to the exterior wall. The effect of this thermal bridge is therefore expressed by two Ψ-values. The following applies for the exterior wall: The conductance $L_{iu}$ is now assigned to the floor slab, $L_{ie}$ is assigned to the exterior wall. The effect of this thermal bridge is therefore expressed by two Ψ-values. The following applies for the exterior wall:
  
-<WRAP centeralign> +<WRAP centeralign> **Ψ-value (proportion of exterior wall)** </WRAP>
-**Ψ-value (proportion of exterior wall)**  +
-</WRAP>+
  
-<WRAP centeralign>  +<WRAP centeralign> $ \large{\Psi_g = L_{ie}-l_{AW} \cdot U_{AW}} $ </WRAP>
-$+
-\large{\Psi_g = L_{ie}-l_{AW} \cdot U_{AW}} +
-$$ +
-</WRAP>+
  
-<WRAP centeralign> +<WRAP centeralign> $ \large{\Psi_{exterior wall} = 0{.}231-1{.}830 \cdot 0{.}120 = 0{.}0114} $ </WRAP>
-$+
-\large{\Psi_{exterior wall} = 0{.}231-1{.}830 \cdot 0{.}120 = 0{.}0114} +
-$$ +
-</WRAP>+
  
 For the floor slab: For the floor slab:
  
-<WRAP centeralign> +<WRAP centeralign> **Ψ-value (proportion of floor slab)** </WRAP>
-**Ψ-value (proportion of floor slab)**  +
-</WRAP>+
  
-<WRAP centeralign>  +<WRAP centeralign> $ \large{\Psi_g = L_{iu}-0{.}5 \cdot B' \cdot U_{basement ceiling}} $ </WRAP>
-$+
-\large{\Psi_g = L_{iu}-0{.}5 \cdot B' \cdot U_{basement ceiling}} +
-$$ +
-</WRAP>+
  
-<WRAP centeralign> +<WRAP centeralign> $ \large{\Psi_{basement ceiling} = 0{.}5543-0{.}5 \cdot 8 \cdot 0{.}148 = -0{.}0377} $ </WRAP>
-$+
-\large{\Psi_{basement ceiling} = 0{.}5543-0{.}5 \cdot 8 \cdot 0{.}148 = -0{.}0377} +
-$$ +
-</WRAP>+
  
-In the [[planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package |PHPP]] $\Psi_{exterior wall}$  is entered as a normal thermal bridge. With $\Psi_{basement ceiling}$, $U_f$ for the basement ceiling is corrected in the Ground worksheet so that the overall resistance of the basement level can be calculated afterwards with the aid of the approximation functions.+In the [[:planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package|PHPP]] $\Psi_{exterior wall}$ is entered as a normal thermal bridge. With $\Psi_{basement ceiling}$, $U_f$ for the basement ceiling is corrected in the Ground worksheet so that the overall resistance of the basement level can be calculated afterwards with the aid of the approximation functions. 
 + 
 +<WRAP centeralign> $ \large{U_{f,corrected} = U_f + \dfrac{\Psi_{basement ceiling} \cdot P}{A}} $ </WRAP>
  
-<WRAP centeralign>  
-$$ 
-\large{U_{f,corrected} = U_f + \dfrac{\Psi_{basement ceiling} \cdot P}{A}} 
-$$ 
-</WRAP> 
  
 ===== Determining the minimum surface temperature and the f_Rsi factor ===== ===== Determining the minimum surface temperature and the f_Rsi factor =====
basics/building_physics_-_basics/thermal_bridges/tbcalculation/examples/unheatedb.1728460980.txt.gz · Last modified: by yaling.hsiao@passiv.de