Hi,
I am currently using both WUFI Pro and WUFI 2D. To validate my model in WUFI 2D, I have created the exact same building envelope assembly as in my WUFI Pro model.
Although the interior and exterior climates, material properties, and initial conditions are set up identically in both software programs, I am getting different water content levels, especially i dont understand why in the exterior LP SmartSide siding material the result are not the same despite the exterior climate are the same. While the temperature profiles match closely across the envelope, the water content shows noticeable discrepancies.
Could you please help me understand why the water content is not the same and how to resolve this?
Additionally, is it theoretically possible to get the exact same results in WUFI Pro and WUFI 2D if all parameters are identical? Does this discrepancy typically depend on the numerical mesh generation, or are there underlying differences in the calculation engines for 1D vs. 2D transport?
Thanks in advance for your help!
Differences in water content results between WUFI Pro and WUFI 2D with identical setups
Re: Differences in water content results between WUFI Pro and WUFI 2D with identical setups
Update,
My issue regarding the exterior material has been resolved. However, I am still encountering difficulties in obtaining consistent relative humidity and water content values within my materials.
For example, within my envelope model, the studied surface is in contact with the OSB layer. Despite replicating the same mesh (by transferring values from WUFI Pro) and using identical calculation parameters (Maxit = 600, convergence criterion = 1e-6, URF matching WUFI Pro, and NSW = 1000) as well as identical materials and settings, I am unable to achieve the same relative humidity or overall water content in WUFI Pro and WUFI 2D.
When placing an observation point in WUFI Pro within the OSB layer and comparing it to the same location in WUFI 2D, the results differ. I am unsure of the cause of this discrepancy. Please see the attached figures for reference:
My issue regarding the exterior material has been resolved. However, I am still encountering difficulties in obtaining consistent relative humidity and water content values within my materials.
For example, within my envelope model, the studied surface is in contact with the OSB layer. Despite replicating the same mesh (by transferring values from WUFI Pro) and using identical calculation parameters (Maxit = 600, convergence criterion = 1e-6, URF matching WUFI Pro, and NSW = 1000) as well as identical materials and settings, I am unable to achieve the same relative humidity or overall water content in WUFI Pro and WUFI 2D.
When placing an observation point in WUFI Pro within the OSB layer and comparing it to the same location in WUFI 2D, the results differ. I am unsure of the cause of this discrepancy. Please see the attached figures for reference:
- OSB WUFI 1D Relative Humidity.png (25.65 KiB) Viewed 23 times
- OSB WUFI 2D Relative Humidity.png (19.71 KiB) Viewed 23 times
- WUFI envelop
- Capture d’écran 2026-06-18 142251.png (15.76 KiB) Viewed 23 times
-
Christian Bludau
- WUFI SupportTeam IBP
- Posts: 1277
- Joined: Tue Jul 04, 2006 10:08 pm -1100
- Location: IBP Holzkirchen, the home of WUFI
- Contact:
Re: Differences in water content results between WUFI Pro and WUFI 2D with identical setups
HI Cyprien,
could you share a direct comparison showing how large the deviations between the curves actually are? WUFI Pro and WUFI 2D results can be compared in one diagram using WUFI Graph.
It would also be helpful to check the numerical quality of both simulations:
Another important aspect is the discretization. In WUFI 2D, you currently have many elements in the y-direction. Unlike in 1D, this can introduce lateral redistribution effects. To achieve a more direct comparison between 1D and 2D, it is advisable to reduce the model to only one element in y-direction.
In addition, exterior air layers are often numerically challenging to converge. If not already done, you could try using the standard air layer material (short name), instead of “air layer without additional moisture storage”, as this sometimes improves convergence behaviour.
If you include rain in the simulation, it would be advisable to first perform a comparison without rain. The rain treatment can differ between the two versions, especially due to the larger extent of the construction in the y-direction.
I assume that all other settings (materials, boundary conditions, surface transfer coefficients, etc.) are identical in both models.
Christian
could you share a direct comparison showing how large the deviations between the curves actually are? WUFI Pro and WUFI 2D results can be compared in one diagram using WUFI Graph.
It would also be helpful to check the numerical quality of both simulations:
- In WUFI Pro, how do the balances look?
- In WUFI 2D, are there any convergence errors reported? How do the residuals deviate from the specified convergence criterion?
Another important aspect is the discretization. In WUFI 2D, you currently have many elements in the y-direction. Unlike in 1D, this can introduce lateral redistribution effects. To achieve a more direct comparison between 1D and 2D, it is advisable to reduce the model to only one element in y-direction.
In addition, exterior air layers are often numerically challenging to converge. If not already done, you could try using the standard air layer material (short name), instead of “air layer without additional moisture storage”, as this sometimes improves convergence behaviour.
If you include rain in the simulation, it would be advisable to first perform a comparison without rain. The rain treatment can differ between the two versions, especially due to the larger extent of the construction in the y-direction.
I assume that all other settings (materials, boundary conditions, surface transfer coefficients, etc.) are identical in both models.
Christian