A premium, high-performance weather barrier has four beneficial and essential functions – air resistance, water resistance, durability during construction, and the right level of vapor permeability.
Vapor permeability is probably the most ignored and least understood of the four. Yet, it can have the greatest impact on how a wall system performs.
Whether during installation or after the cladding goes up,the interior of walls do get wet. And if a wall system can’t dry out, it becomes vulnerable to moisture damage and mold.
That’s why vapor permeability, or breathability, is a key benefit of DuPont™ Tyvek® weather barriers. Tyvek® combines the right balance of air and water resistance and vapor permeability. So, when water does find its way into a wall system, the Tyvek® WRB is engineered to allow it to escape as moisture vapor.
Often referred to as breathability, vapor permeability describes a material’s ability to allow water vapor to pass through it. Unlike bulk water holdout, which refers to water in its liquid form, vapor permeability concerns water in its gas form.
Current building codes require the minimum measure of permeability to be around 5 perms. DuPont building scientists believe this threshold is too low to ensure consistent performance, and recommend weatherization barriers with moderate to high vapor permeability, like Tyvek® WRB.
Measurement of moisture vapor transmission rate (MVTR) is calculated per the test protocol of ASTM E96. This test indicates how much moisture can pass through a barrier in a 24-hour period.
Because this measurement is affected by vapor pressure, it is necessary to adjust for vapor pressure across the sample to determine moisture vapor permeance (MVP). ASTM E96 is used to give materials a relative rating that indicates how resistant each one is to allowing moisture vapor to pass through.
In the summer of 2002, DuPont conducted a field experiment in North Carolina during the worst drought in decades. Two different building wraps were randomly applied to the same wall structure. One with a vapor permeability of 58 perms, the other 6.7 perms.
The wall was wrapped for 3-4 weeks, and left in the framed stage of construction during this period. After 3-4 weeks had passed, moisture accumulation and elevated moisture levels clearly could be seen wherever the low- vapor permeability wrap was installed. Many areas had reached or exceeded saturation levels for sheathing, and moisture distress was evident to the naked eye.
By contrast, everywhere the high permeability wrap was installed, it was revealed that the sheathing had remained consistently clean and dry, regardless of location or directional orientation.
To better understand observations in the lab and in the field, DuPont did moisture modeling, using the internationally recognized WUFI Pro model. DuPont was able to simulate the field conditions to evaluate the wall system’s response to the formation of dew-like condensate.
Results showed that, in all climates, significantly lower moisture content was observed when a moderate-to-high vapor permeability wrap was used. These results are a further indication that moderate-to-high permeability allows drying, while low permeability impedes drying, and increases the potential for moisture-related issues.
DuPont™ Tyvek® weather barriers have a unique structure, with millions of extremely fine pores that resist bulk water and air penetration, but allow water vapor to pass through and escape the building.
For more than 30 years, DuPont material and building science expertise has brought innovations like Tyvek® weather barriers to the construction market.
Learn more about vapor permeability testing and Tyvek® performance.
Building Science Bulletin – The Truth About Vapor Permeability