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Wet-Spray Cellulose Quandary
Are you aware of any moisture problems from someone using wet spray
cellulose directly on basement cement walls? How about on the sill and
band joists in basements without any retaining device such as Sheetrock?
Will it stay put when dry?
A local homeowner wanted to wet-spray cellulose everywhere, including
the foundation walls and sill area. But the contractor was not comfortable
insulating this way, because he was concerned about moisture on the cement
walls below grade. He was also worried that the cellulose might shift after
it dried if there was no retaining system at the sill area.
Paul Schroeder, Technical Director
Hampden County Energy Office
Springfield, MA
Rick Ariagno, owner of the Illinois insulation
contracting firm Home Energy Control, Incorporated, responds: You asked
a couple of tricky questions that could warrant some concern if not handled
carefully. We spray rim joists all the time and find the material stays
put without a problem. Since the rim joist between the first and second
floor is always covered with drywall, we don't have to worry about anyone
disturbing the insulation, or about loose, dried material flaking off.
The exposed rim joist in the basement is a different story. We spray this
area wetter to get a higher density and a harder crust on the surface.
The installers have to thoroughly clean overspray off the plywood and floor
joist to prevent dried fuzzies from flaking onto the basement floor. If
the insulation is disturbed after installation--by an HVAC contractor,
for example -- it is easiest to replace disturbed insulation with a batt
and careful sealing.
Whenever you go below grade, you have to be cautious of moisture
problems. We have installed cellulose behind finished basement walls without
special protection and haven't had any complaints. Cellulose installed
below grade must be completely dry before it is covered with drywall. Since
the material can only dry to the inside and there may be less air movement
in the basement, drying below grade may take longer than usual. Fans can
decrease drying time. To be safe, we create a drainage plane behind the
insulation. This can be done by tacking 4-mil poly to the mud sill and
letting it drape down the wall before the studs go up. Quarter-inch or
half-inch foam sheathing behind the studs is even better for creating the
drainage plane. If water does eventually seep in, it will drain down the
wall and onto the floor rather than leaching into the spray-applied cellulose.
If the installation and budget permit, err on the side of caution rather
than spraying directly on the basement walls. Finally, if I knew a seepage
problem existed, I would use an alternate insulation system.
Making Sense of Heat Ratios
On page 15 of John Proctor's "If Bigger
Isn't Better, What Is?" (Sept/Oct '96), you recommend choosing air
conditioners with low sensible heat ratios (SHRs) in hot, wet climates.
I called my contact at the local Carrier/Bryant distributor and he said
this was not a criterion consumers could use to shop for air conditioners.
It sounded like the ratio was more or less constant throughout the product
line. SHRs aren't even given in the Air Conditioning and Refrigeration
Institute (ARI) guide.
On a related topic, the Rocky Mountain Institute's book
Homemade
Money recommends that readers close off air conditioning registers
in unused rooms. I would expect this to aggravate problems with low air
flow across the indoor coil.
Jonathan Beers
Madison Gas and Electric
Madison, Wisconsin
Author John Proctor responds: The relationship
between the latent capacity (moisture removal) and the sensible capacity
is a critical design consideration in selecting the correct air conditioner
for the local climate. All the major manufacturers (including Carrier)
and most of the minor manufacturers provide this information in extensive
performance tables. Most companies provide sufficient information to calculate
the SHR for their equipment under many different conditions.
Contrary to your distributor's comment, not all equipment is alike.
Different compromises are made in the design process. True, the ARI directory
does not provide SHR. But in general, the ARl directory does not
provide sufficient data to select equipment.
Your local distributor has the performance tables for all the equipment
it sells. Any installing contractor can obtain this performance data. If
the distributor refuses to share that information with you, you should
ask yourself if you want to deal with someone who either does not know
how the equipment performs or does not want you to know.
From the performance tables, you will see that the SHR decreases
significantly when the airflow across the inside coil is reduced. You
are certainly correct about the problems associated with closing registers
on a heat pump or air conditioning system. Starving the coil for air reduces
its efficiency and may cause failure if liquid refrigerant makes it back
to a reciprocating compressor. Gas furnaces, incidentally, are far less
sensitive to closed registers, but the efficiency is reduced and the heat
exchanger can be stressed by repeated overheating, especially if the burner
is often being turned off by the limit switch.
How Heat Pumps Compare
"If Bigger Isn't Better, What Is?"
was the best article I've seen on A/C sizing. I still have two questions.
How does a 24,000 Btu/h, 240V wall unit compare to a modern heat pump?
Also, what is the effect of using a dehumidifier to help with humidity
reduction?
Greg Gustin
Lake Placid, Florida
Author John Proctor responds: If the wall unit
in question is an electric resistance heater then a 1997 through-the-wall
heat pump will provide the same heat at less than half the cost. If it
is an old (circa 1970) through-the-wall heat pump, and there is no problem
with the old unit (are the coils clean?), then a 1997 whole-house heat
pump will probably use more energy. A through-the-wall heat pump heats
and cools the immediate area rather than the whole house and it does not
use a leaky and poorly insulated duct system to deliver the heating or
cooling.
Dehumidifiers remove moisture and deliver heat to your home. If you
are trying to cool and remove moisture, then dehumidifiers may be a necessary
evil. Your first choice would be to use an air conditioner that effectively
removes both sensible heat and moisture. A properly sized air conditioner
selected and installed to meet your specific needs is the best choice.
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