LOUCAST 3000 Degree Dense Castable Refractory
50 pounds dry: Delivered Price
NOTE: NOT ELIGIBLE FOR FREE/FIXED SHIPPING TO AK or HI
Cast your own hard Fire Brick
Yield: 131 Pounds dry yields 1 cubic foot.
so 50 pound bag yields approximately 0.38 cubic feet
LOUCAST 3000 Degree Castable Refractory is a dense castable refractory mortar rated for 3000°F It is low iron content, with high purity.
This refractory mortar is designed to successfully withstand high sulphur fuel, reducing atmospheres, carbon deposition, erosion and abrasion. This castable refractory cement can be used for gunning, casting, troweling, or extruding. It is equivalent to
Offered here in 50Lb bag.
Please contact us to arrange economical delivery of large quantities.
Mix at a rate of 4.8 quarts / 100 Pounds
The installation procedures for castables are relatively
simple if the fundamentals are understood.
With proper supervision, relatively unskilled labor can be used and
still achieve excellent structural and thermal properties in the finished
The price shown is for the northeast United States (ME, NH, MA,RI, CT, VT, NY and NJ)
Please select "Zone B" if you are not in the Northeast
Castable refractories or refractory concretes, as they are
sometimes called, can be installed by one of several methods: (1) pouring into
forms, (2) tamping into place or (3) pneumatic gunning. When the installation is by pouring or
tamping, the mixing is done in a concrete mixer or preferably in a paddle type
mixer. Mixing can be done in a mortar
box by hand but this is not recommended.
Only good clear water, suitable for drinking, should be used because
there could be mineral or chemical contaminants in process water or dirty
water, which could completely destroy the effect of the bonding agent in the
refractory. The mixer must be free of
dirt and set-up concrete from previous mixes because if this material were to
flake off into the new castable, it could have a radical effect on the setting
characteristics of the new material. The
time of mixing, after the addition of water, should be sufficient to insure
that all of the dry material is thoroughly wetted but in no case should exceed
The proper water to cement ratio is of extreme importance when mixing a castable refractory mortar. Enough water has
to be used to hydrate the cement but an excessive amount of water will create
shrinkage and a considerable loss of strength.
There is a natural tendency for workmen to make the castable refractory mortar mix too wet because it will work and flow more easily in this state. As a result it is important to maintain
careful supervision over the mixing process and there should be little
variation in the water to material ration from the batch to batch. There is a simple test, called the
ball-in-hand test, to determine the proper consistency.Take a large handful of the castable refractory mortar mix and squeeze it between the hands as if making a snowball. The material should form compactly and have a light film of water on the
surface. When the ball is thrown about
12 inches into the air and caught with an open hand, the material should slump
only enough to just begin to penetrate between the fingers. A mixture of this consistency would be
correct for what is normally called a pouring mix. A tamping mix, by the same test as described
above, should have just enough water to form a compact ball with no water film
on the surface. When thrown as above it
should remain intact and not penetrate between the fingers at all. The temperature during mixing and casting is
mainly of importance due to its effect on the working time. Castables are stronger when cast in the warm
weather, 70 degrees Fahrenheit or above, but casting at temperatures as low as
40 degrees Fahrenheit generally gives good results if the castable is not
allowed to freeze before it cures. In
cold weather it is advisable to keep the castable stored in a warm place and
even to use warm water for mixing so that the temperature of the mixture at the
time of the pouring is around 70 degrees.
Placement and Working Time
The castable refractory mortar mixture should be poured into place immediately upon completion of the mixing cycle. The use
of a pencil vibrator is recommended to consolidate the material and to help
remove entrapped air. However, caution
must be exercised to avoid over vibrating which will cause water and cement to
migrate to the surface and create a weaker structure.
Immediately upon the addition of water to a castable refractory mortar, hydrates begin to form, which will eventually cause the mix to set. This setting process occurs in two steps:
SET: The castable becomes stiff, but not
hard. The placing of the material must
be completed before this stiffening occurs.
The time available between the addition of water and this initial set is
dependent on temperature, type and amount of castable. In warm weather the initial set occurs 10
20 minutes earlier than in cold winter weather.
Therefore, in the summer the working time of low and intermediate purity
castables are 30 40 minutes and that of high purity castables is 20 30
SET: The hardening of the castable refractory mortar is accompanied by the evolution of heat. This is the final set and occurs during the curing process.
Hydraulic setting castable refractory mortar requires 24 hours to develop their full strength. The strength depends
entirely upon the formation of the proper type and amount of hydrates and thus
during the curing process plenty of water should be available to insure the
conversion of the dry cement to hydrated cement. During casting, about twice as much water is
added to the castable as is needed for full hydration. Therefore the trick is to keep the water in
place. If proper precautions are not taken
the heat generated by the hydration reaction, especially in thick sections,
will evaporate the water before all of the cement is hydrated. Some helpful suggestions are:
sure that the forms used are waterproofed with a good coating of oil or paint. (This is not necessary with metal forms,
however a light coating of oil or grease on metal forms will help with mold
the surface of the castable with a waterproof coating, called a membrane curing
the surface wet with water sprays to replace the evaporated water or for small
installations cover with wet bags.
Note: If water spray is used, be sure not to apply
it until the mix is set enough so that the surface will not wash. This can be checked by gently rubbing with a
wetted finger. I the finger remains
clean the castable is set enough to apply light water spray.
The fact that the castable refractory mortar gets hot as a result of its own heat generation during curing is not important. It is not heat but humidity that is the controlling factor. Heat evolution generally starts 3 12 hours
after casting and is 90% complete after 24 hours. At this point the molds can be removed and
the dry out process started.
As installed, most castables are very dense and have
extremely low permeability. As a result
it is very difficult for moisture and vapor to escape. If the heat-up rate is too rapid, tremendous
steam pressures can build up inside the lining, even to the point of explosive
spalling. But even short of the point of
explosive spall, enough pressure can be generated to cause unseen flaws within
the lining, which can severely limit the working life of the castable. Therefore dry out and initial heat-up methodology
is very important.
As cured most castable refractory mortars contain about 10% total water. Approximately 50 75% of this water is free
water while the remainder is chemically bound.
The free water has to be removed during air-drying and for a period of
time at 230 degrees Fahrenheit. Actual
dry out schedules depend upon the thickness of the castable, ventilation
possibilities, etc. When casting against
a metal shell, weep holes should be drilled in the shell to facilitate moisture
escape. The castable should be allowed
to air dry 24 hours before any heat is applied.
When the castable is properly dried it still contains 2.5 to
5.0% water, which is chemically bound to the cement. This water is removed at various temperatures
but the majority comes off about 500 600 degreed Fahrenheit. For this reason it is recommended that the
temperature be increased at the rate of 50 degrees Fahrenheit per hour to 1000
degrees Fahrenheit with a hold at 600 degrees for one hour per inch of lining
thickness. After reaching 1000 degrees
Fahrenheit the heating rate can be increased up to 100 degrees Fahrenheit per
hour until operating temperature is reached.
No hard and fast heating schedule can be prescribed for all
installations. It is dependent upon the
mass and type of material installed and various other conditions. Obviously a suspended roof that is exposed
top and bottom for the escape of moisture could be heated more rapidly than a
wall, which is backed up with insulation and a steel casing. A typical safe heating schedule for an
AVERAGE installation is given below:
the temperature gradually to 230 degrees Fahrenheit and hold for twelve hours.
the temperature at 50 degrees Fahrenheit per hour to 600 degrees Fahrenheit and
hold for one hour per inch of lining thickness.
to raise the temperature at 50 degrees Fahrenheit per hour to 1000 degrees
Fahrenheit then 100 degrees Fahrenheit per hour to operating temperature.
The above temperatures are based on the hot face of the castable refractory mortar. Heat-up should be continuous
and uninterrupted. If excessive steaming
occurs hold but do not drop the temperature until the steaming is subsided.