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Heat and Cooling losses ...
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Foil
101, Its your Money! (reading time 6
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HEAT GAIN / LOSS IN BUILDINGS...
There are
three modes of heat transfer: CONDUCTION, CONVECTION, and
RADIATION (INFRARED). Of the three, radiation is the primary
mode; conduction and convection are secondary and come into play
only as matter interrupts or interferes with radiant heat transfer.
As matter absorbs radiant energy, it is heated and a gradient
temperature develops, which results in molecular motion (conduction
in solids) or mass motion (convection in liquids and gas). This is
to much knowledge.. I want the
Answer!
All
substances, including air spaces and building materials (such as
wood, glass, plaster and insulation), obey the same laws of nature
and TRANSFER heat. Solid materials differ only in the rate of
heat transfer, which is mainly affected by differences in density,
weight, shape, permeability and molecular structure. Materials which
transfer heat slowly can be said to RESIST heat flow.
Direction of heat
transfer is an important consideration. Heat is radiated and
conducted in all directions, but convected primarily upward. The
figures below show modes of heat loss by houses. In all cases,
radiation is the dominant mode.
 
CONDUCTION is direct heat flow
through matter (molecular motion). It results from actual PHYSICAL
CONTACT of one part of the same body with another part, or of one
body with another. For instance, if one end of an iron rod is
heated, the heat travels by conduction through the metal to the
other end; it also travels to the surface and is conducted to the
surrounding air, which is another, but less dense, body. An example
of conduction through contact between two solids is a cooking pot on
the solid surface of a hot stove. The greatest flow of heat possible
between materials is where there is a direct conduction between
solids. Heat is always conducted from warm to cold, never from cold
to warm, and always moves via the shortest and easiest
route.
In general,
the more dense a substance, the better conductor it is. Solid rock,
glass and aluminum-being very dense-are good conductors of heat.
Reduce their density by mixing air into the mass, and their
conductivity is reduced. Because air has low density, the percentage
of heat transferred by conduction through air is comparatively
small. Two thin sheets of aluminum foil with about one inch of air
space in between weigh less than one ounce per square foot. The
ratio is approximately 1 of mass to 100 of air, most important in
reducing heat flow by conduction. The less dense the mass, the less
will be the flow of heat by conduction.
CONVECTION is the transport of
heat within a gas or liquid, caused by the actual flow of the
material itself (mass motion). In building spaces, natural
convection heat flow is largely upward, somewhat sideways, not
downward. This is called "free convection."
For instance,
a warm stove, person, floor, wall, etc., loses heat by conduction to
the colder air in contact with it. This added heat activates (warms)
the molecules of the air which expand, becoming less dense, and
rise. Cooler, heavier air rushes in from the side and below to
replace it. The popular expression "hot air rises" is exemplified by
smoke rising from a chimney or a Fire. The motion is turbulently
upward, with a component of sideways motion. Convection may also be
mechanically induced, as by a fan. This is called "forced
convection."
RADIATION is the transmission of
electromagnetic rays through space. Radiation, like radio waves, is
invisible. Infrared rays occur between light and radar waves
(between the 3 -15 micron portion of the spectrum). Henceforth, when
we speak of radiation, we refer only to infrared rays. Each material
that has a temperature above absolute zero (-459-7 F.) emits
infrared radiation, including the sun, icebergs, stoves or
radiators, humans, animals, furniture, ceilings, walls, floors,
etc.
All objects
radiate infrared rays from their surfaces in all directions, in a
straight line, until they are reflected or absorbed by another
object. Traveling at the speed of light, these rays are invisible,
and they have NO TEMPERATURE, only ENERGY. Heating an object excites
the surface molecules, causing them to give off infrared radiation.
When these infrared rays strike the surface of another object, the
rays are absorbed and only then is heat produced in the object. This
heat spreads throughout the mass by conduction. The heated object
then transmits infrared rays from exposed surfaces by radiation if
these surfaces are exposed directly to an air space.
The amount of
radiation emitted is a function of the EMISSIVITY factor of the
source's surface. EMISSIVITY is the rate at which radiation
(EMISSION) is given off. Absorption of radiation by an object is
proportional to the absorptivity factor of its surface which is
reciprocal of its emissivity.
Although two
objects may be identical, if the surface of one were covered with a
material of 90% emissivity, and the surface of the other with a
material of 5% emissivity, the result would be a drastic difference
in the rate of radiation flow from these two objects. This is
demonstrated by comparison of four identical, equally heated iron
radiators covered with different materials. Paint one with aluminum
paint and another with ordinary enamel. Cover the third with
asbestos and the fourth with aluminum foil. Although all have the
same temperature, the one covered with aluminum foil would radiate
the least (lowest [3%] emissivity). The radiators covered with
ordinary paint or asbestos would radiate most because they have the
highest emissivity (even higher than the original iron). Painting
over the aluminum paint or foil with ordinary paint changes the
surface to 90% emissivity.
Materials
whose surfaces do not appreciably reflect infrared rays, i.e.:
paper, asphalt, wood, glass and rock, have absorption and emissivity
rates ranging from 80% to 93%. Most materials used in building
construction -- brick, stone, wood, paper, and so on -- regardless
of their color, absorb infrared radiation at about 90%. It is
interesting to note that a mirror of glass is an excellent reflector
of light but a very poor reflector of infrared radiation. Mirrors
have about the same reflectivity for infrared as a heavy coating of
black paint.
The surface
of aluminum has the ability NOT TO ABSORB, but TO REFLECT 97% of the
infrared rays which strike it. Since aluminum foil has such a low
mass to air ratio, very little conduction can take place,
particularly when only 3% of the rays are absorbed.
TRY THIS
EXPERIMENT: Hold a sample of FOIL INSULATION close to your face,
without touching. Soon you will feel the warmth of your own infrared
rays bounding back from the SURFACE. The explanation: The emissivity
of heat radiation of the surface of your face is 99%- The absorption
of aluminum is only 3%. It sends back 97% of the rays. The
absorption rate of your face is 99%. The net result is that you feel
the warmth of your face reflected.
REFLECTIVITY AND AIR
SPACES
In order to
retard heat flow by conduction, walls and roofs are build with
internal air spaces. Conduction and convection through these air
spaces combined represent only 20% to 35% of the heat which pass
through them. In both winter and summer, 65% to 80% of the heat that
passes from a warm wall to a colder wall or through a ventilated
attic does so by radiation.
The value of
air spaces as thermal insulation must include the character of the
enclosing surfaces. The surfaces greatly affect the amount of energy
transferred by radiation, depending on the material's absorptivity
and emissivity, and are the only way of modifying the total heat
transferred across a given space. The importance of radiation cannot
be overlooked in problems involving ordinary room
temperatures.
The following
test results illustrate how heat transfer across a given air space
may be modified. The distance between the hot and cold walls is
1-1/2" and the temperatures of the hot and cold surfaces are 212
degrees and 32 degrees, respectively. In CASE 1, the enclosing walls
are paper, wood, asbestos or other similar material. In CASE 2, the
walls are lined with aluminum foil. In CASE 3, two sheets of
aluminum foil are used to divide the enclosure into three 1/2"
spaces.
Conduction
21 BTU's
Convection
92 BTU's
Radiation
206 BTU's
TOTAL 319
BTU'S
CASE 1,
UNINSULATED WALL SPACE.
The surfaces of
ordinary building materials, including ordinary bulk insulation have
a radiation or emissivity rate of about 90%, a heat ray absorption
rate of over 90%. Air has low density, so conduction is slight (only
21 BTU'sJ Convection currents transfer 90 BTU's.
Conduction
21 BTU's
Convection
92 BTU's
Radiation
10 BTU's
TOTAL »123
BTU'S
CASE 2,
THE SAME WALL SPACE EXCEPT
that the
inner surfaces were lined with sheets of aluminum foil of 5%
emissivity and absorptivity.* Note the drastic drop in heat flow by
radiation, from 206 BTU's to 10 BTU's. Conduction and convection are
unchanged. The original total heat loss of 319 BTU's drops to 123
BTU's.
Conduction
23 BTU's
Convection
23 BTU's
Radiation
2 BTU's
TOTAL 48
BTU'S
CASE 3,
TWO SHEETS OF (5% EMISSIVE)
ALUMINUM
FOIL divide the wall space
into 3 reflective compartments. Heat loss by radiation drops 94%
from Case 1. The 2 interior sheets retard convection so that its
flow falls 75%. Conduction rises only 2 BTU's; from 21 BTU's to 23
BTU's. The
total heat loss drops 85% from Case 1.
Reflection
and emissivity by surfaces can ONLY occur in SPACE. The ideal space
is any dimension 3/4" or more. Smaller spaces are also effective,
but decreasingly so. Where there is no air space, we have conduction
through solids. When a reflective surface of a material is attached
to a ceiling, floor or wall, that particular surface ceases to have
radiant insulation value at the points in contact.
Heat control
with aluminum foil is made possible by taking advantage of its low
thermal emissivity and the low thermal conductivity of air. It is
possible with layered foil and air to practically eliminate heat
transfer by radiation and convection: a fact employed regularly by
the NASA space program. In the space vehicle Columbia,
ceramic tiles are imbedded with aluminum bits which reflect heat
before it can be absorbed. "Moon suits" are made of reflective foil
surfaces surrounding trapped air for major temperature
modification.
HEAT
LOSS THROUGH AIR
There is no
such thing as a "dead" air space as far as heat transfer is
concerned, even in the case of a perfectly airtight compartment such
as a thermos bottle. Convection currents are inevitable with
differences in temperature between surfaces, if air or some other
gas is present inside. Since air has some density, there will be
some heat transfer by conduction if any surface of a so-called
"dead" air space is heated. Finally, radiation, which accounts for
50% to 80% of all heat transfer, will pass through air (or a vacuum)
with ease, just as radiation travels the many million miles that
separate the earth from the sun.
Aluminum
foil, with its reflective surface, can block the flow of radiation.
Some foils have higher absorption and emissivity qualities than
others. The variations run from 2% to 72%, a differential of over
2000%. Most aluminum insulation has only a 5% absorption and
emissivity ratio. It is impervious to water vapor and convection
currents, and reflects 95% of all radiant energy which strikes its
air-bound surfaces.
HEAT
LOSS THROUGH FLOORS
Heat is lost
through floors primarily by radiation (up to 93%). When ALUMINUM
insulation is installed in the ground floors and crawl spaces of
cold buildings, it prevents the heat rays from penetrating down,
reflecting the heat back into the building and warming the floor
surfaces. Since aluminum is non-permeable, it is unaffected by
ground vapors.
CONDENSATION
Water vapor
is the gas phase of water. As a gas, it will expand or contract to
fill any space it may be in. In a given space, with the air at a
given temperature, there is a limited amount of vapor that can be
suspended. Any excess will turn into water. The point just before
condensation commences is called 100% saturation. The condensation
point is called dew point.
VAPOR
LAWS
1. The higher
the temperature, the more vapor the air can hold; the lower the
temperature, the less vapor.
2. The larger the space, the more
vapor it can hold; the smaller the space, the less vapor it can
hold.
3. The more vapor in a given space, the greater will be its
density.
4. Vapor will flow from areas of greater vapor density
to those of lower vapor density.
5. Permeability of insulation is
a prerequisite for vapor transmission; the less permeable, the less
vapor transfer.
The average
water vapor saturation is about 65%. If a room were vapor-proofed,
and the temperature were gradually lowered, the percentage of
saturation would rise until it reached 100%, although the amount of
vapor would remain the same. If the temperature were further
lowered, the excess amount of the vapor for that temperature in that
amount of space would fall out in the form of condensation. This
principle is visibly demonstrated when we breathe in cold places.
The warm air in our lungs and mouth can support the vapor, but the
quantity is too much for the colder air, and so the excess vapor for
that temperature condenses and the small particles of water become
visible.
In
conduction, heat flows to cold. The under surface of a roof, when
cold in the winter, extracts heat out of the air with which it is in
immediate contact. As a result, that air drops in temperature
sufficiently to fall below the dew point (the temperature at which
vapor condenses on a surface). The excess amount of vapor for that
temperature that falls out as condensation or frost attaches itself
to the underside of the roof.
Water vapor
is able to penetrate plaster and wood readily. When the vapor comes
in contact with materials within walls having a temperature below
the dew point of the vapor, moisture or frost is formed within the
walls. This moisture tends to accumulate over long periods of time
without being noticed, which in time can cause building
damage.
To prevent
condensation, a large space is needed between outer walls and any
insulation which permits vapor to flow through. Reducing the space
or the temperature converts vapor to moisture which is then
retained. The use of separate vapor barriers or insulation that is
also a vapor barrier are alternate methods to deal with this
problem. Aluminum is impervious to water vapor and with the trapped
air space is immune to vapor condensation.
TESTING
THERMAL VALUES
U FACTOR is
the rate of heat flow in BTU's in one hour through one sq. ft. area
of ceilings, roofs, walls or floors, including insulation (if any)
resulting from a 1 degree F. temperature difference between the air
inside and the air outside.
MEMORY
JOGGER: U = BTU'S flowing ONE hour, through ONE sq. ft. for ONE
degree change.
R FACTOR or
RESISTANCE to heat flow is the reciprocal of U; in other words, 1/U.
The smaller the U factor fraction, the larger the R factor, the
better the insulation's ability to stop conductive heat flow.
Note: Neither of these factors include radiation or convection
flow.
There are at
present two kinds of techniques generally used by accepted
laboratories to measure thermal values: the guarded hot plate and
the hot box methods. The results obtained seem to vary between the
two methods. Neither technique simulates heat flow through
insulation in actual everyday usage. Thermal conductivity
measurements, as made in the completely dry state in the laboratory,
will not match the performance of those same insulators under actual
field conditions. Most mass type insulating materials become better
conductors of heat when the relative humidity increases because of
the absorption of moisture by the insulator. (Try keeping your feet
in a pair of wet socks.) Therefore, mass insulators, which normally
contain at least the average amount of moisture which is in the air,
are first completely dried out before testing. In aluminum
insulation, there is no moisture problem. Aluminum foil is one of
the few insulating materials that is not affected by humidity, and
consequently, its insulating value remains unchanged from the "bone
dry" state to very high humidity conditions. In addition, when considering
adding more R's ... Remember, Fourier's Law of Thermodynamics,
"Upgrading from R-13 to R-32, reduces conductive heat flow by only
an additional 4%". That doesn't seem cost effective! And,
the R
Value of a mass type insulation is reduced by over 35% with only a
1-1/2% moisture content, (i.e.: from R13 to R8.3). The moisture
content of insulation materials in homes typically exceeds 1 -1/2%!
In
spite of the advances made by space technology in insulation systems
based on understanding and modifying the effects of radiation, no
universally accepted laboratory method has yet been devised to
measure and report the resistance to heat flow of multi-layer foil.
Until such a method that will satisfy rigorous laboratory demands is
devised, we must be content to make our judgments on the basis of
common sense and experience. There are many different types, grades,
and qualities of aluminum foil insulation designed for a variety of
applications. Matching the correct foil product to the specific job
is extremely important to maximize final performance.
Just in case this is not enough, the
reflective technological junkies are encouraged to jump to RIMA...
The "mother" of reflective associations. Just a click away
.... Here's RIMA
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