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Air Barriers Not Vapor Barriers
The key to moisture control is the control of air transported moisture. This requires an air barrier system or air pressure control that may or may not be combined with an air barrier system.
There is a big difference between air transported moisture and vapor diffusion. Proponents of vapor barrier systems tend to confuse these two transport mechanisms do they control the vapor diffusion part, the air transport part or both? It is not always clear.
What is clear is that air transport is far more significant than vapor diffusion. What is also clear is that you do not need a 6-mil polyethylene barrier to control air transported moisture. Permeability values of materials are irrelevant in air barrier systems. Although 6-mil polyethylene is an excellent vapor barrier it is often a very poor air barrier.
I will agree that it is possible to install 6-mil polyethylene as an air barrier. The key point that needs to be made is that although air barriers are a good idea everywhere, vapor barriers are not.
Moisture flow by vapor diffusion is governed by the second law of thermodynamics (basic physics to some, not so basic to others). Moisture will flow by diffusion because of a concentration gradient as well as a temperature gradient (from "more to less" as well as "from warm to cold").
This means that it tends to go from the inside out up north and from the outside in down south. In the middle of the country part of the year it goes from inside out and part of the year it goes from outside in. It is easy to say lets put a vapor barrier on the inside up north and on the outside down south. It is much harder to define "north" and "south".
Everyone can agree to put a vapor barrier on the inside in Burlington, VT, and on the outside in Miami, FL. It is a little more difficult to agree on where to put a vapor barrier in other locations. If you put a vapor barrier on the inside in Washington, D.C., half of the year it will be in the wrong place.
You certainly do not want to put a vapor barrier on both sides of the wall. It's pretty obvious that you do not want a vapor barrier at all in most assemblies in mixed climates. "Flow-through" design makes more sense in mixed climates where vapor diffusion is slowed down, but not stopped. Hence, the term: vapor retarder.
When moisture storage effects are added, things get real interesting. Take a brick veneer cladding that experiences rain-wetting followed by exposure to solar radiation. The sun tends to drive moisture inward. It makes sense to put a vapor barrier behind a brick veneer to stop this inward flow.
But what happens when you install a vapor barrier behind a brick veneer in a cold climate? Do you also want to install a vapor barrier on the inside? I think that would be a vapor barrier on both sides. Maybe we want a vapor barrier on the outside behind the brick veneer and a vapor retarder on the inside.
Maybe we should use an insulating sheathing that is vapor semi-permeable on the outside with sufficient thermal resistance to elevate the temperature of the condensing surface during the heating season, and have a vapor permeable interior finish to permit drying to the interior? It sounds complicated and it is.
It turns out that the distinction between a vapor barrier and a vapor retarder is a necessity. Let us examine a common building material: kraft-faced fiberglass insulation. Is the kraft facing a vapor barrier or not?
It depends on the time of year. If the facing is installed towards the interior in a climate such as Washington, D.C., it is a vapor barrier in the winter and a vapor retarder in the summer.
How is this so? Well, kraft-facing is impregnated with bitumen and the paper-bitumen composite is hygroscopic. It adsorbs water as the relative humidity it is exposed to rises. As the quantities of adsorbed water increases, the vapor permeability of the composite changes.
This reflected by the differences between dry-cup permeability test values and wet-cup permeability test values. Under dry-cup testing, one side of the material is maintained at 0 percent r.h. and the other side is maintained at 50 percent r.h.
Under wet-cup testing one side of the material is maintained at 50 percent r.h. and the other side is maintained at 100 percent r.h. So under dry-cup testing the kraft facing has a perm rating of 1 perm, and under wet-cup testing the kraft facing has a perm rating of 5 perms.
In the winter months, when the inside relative humidity is high, we have a vapor retarder on the inside, that permits drying to the inside.
It sure would be a dumb idea to replace this kraft facing with a 6-mil polyethylene sheet that would trap water in the wall assembly during the summer.One of the problems in the building industry is that we have a spreading "cult-like" mentality that worships at the "church of polyethylene".
This cult views the answer to all moisture problems as the installation of a polyethylene vapor barrier condom on the inside of buildings. This cult is also responsible for many more building failures than building successes. It's time that the cult deprogramming started.
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