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PART THREE – CONSTRUCTION OF CONTROLLED SPACE
To prepare any space for humidity control,
certain precautions are necessary, regardless of the type of air
drying equipment or the method used to do the drying.
Satisfactory moisture control-better known as customer satisfaction-depends
on many variables. Some are listed below.
THE NATURE OF WATER VAPOR
Consider two closed rooms, adjacent to one
another. If the partial pressure of the water vapor in room #1 are
greater than the partial pressure of the water vapor in room #2,
then the water vapor will travel through the wall into room #2 regardless
of the composition of the wall.
Let's take the hypothetical example a step
further. If the absolute humidity of the air in room #1 is greater
than that of the air in room #2, then the water vapor pressure will
be higher in room #1. Therefore, when drying room #2, the problem
of new water coming through the wall from room #1 must be considered.
A vapor barrier can slow down the passage
of vapor from wet to drier areas, but it cannot keep water out;
it can only slow the rate of penetration.
The choice of vapor barrier is based on
the degree of dryness required in the controlled space, the efficiency
of the equipment being used for drying, and the cost of construction.
Commercial vapor barriers-moisture resistant
construction material, paints, and other coatings-offer a variety
of design alternatives. Manufacturers of vapor barrier materials
can supply specific information on their products.
In addition to the vapor barrier, certain
aspects of construction must be given careful attention.
CONSTRUCTION
CONSIDERATIONS
Several techniques control the permeation of water vapor:
1. Any vapor barrier must be continuous, without breaks or tears.
2. All lap joining must be tightly closed (this is particularly
critical when mechanical or caulked joints are used).
3. Insulation between vapor barriers can be a potential problem:
if construction occurs in humid weather, water can be "sealed
in" between the two vapor barriers.
Sealed-in vapor will travel into
the controlled space and impose an extra drying load on the drying
equipment. This extra load lasts only until the insulation dries
out, but meanwhile, humidity control is difficult.
If a heat source is present (even heat
from the sun), serious damage can be caused by the expanding trapped
vapor. There have been cases when so-called "non-permeable"
materials have split open at a joint because of vapor pressure.
Examples include a floor or tiled wall that has literally lifted
from its mounting surface because the surface was wet during application.
4. Final inside vapor barriers should
be applied only after the enclosed area has been dried. Drying equipment
should be used to withdraw as much moisture as possible before the
final barrier is applied. Of course, without a barrier in place
equipment cannot dry the air to design specifications, but a significant
amount of moisture can and should be removed before all the vapor
barrier material is in place.
(Although this strategy runs counter
to most industrial planning suggestions, the concept of drying the
structure before applying the final vapor barrier is a precaution
that is often overlooked and can help prevent customer dissatisfaction.)
5. All doors-service or personnel-should
be weather-stripped or air-locked through vestibules if the desired
dryness warrants it. Any crack or opening around a door will admit
vapor.
6. When conveyor openings or similar
elements are used, a drop curtain, shroud, or tunnel can restrain
the movement of water vapor.
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