GENERAL OVERVIEW OF BRICK MANUFACTURING

Transcription

GENERAL OVERVIEW OF BRICK MANUFACTURING
INTRODUCTION
Brick is one of man’s oldest building materials. Although equipment and technology has improved the quality and appearance of
the brick produced, the basic raw material and manufacturing steps remain the same.
RAW MATERIAL
Clay is one of the most abundant mineral materials on earth. However, not all clay possesses the properties to be used in modern
brick production. There are three general types of clay used in brick manufacturing.
1. Surface Clay: May be the up thrusts of older deposits or of more recent sedimentary formations. They are formed near the surface.
2. Shale: Clays that have been subjected to high pressures until they have hardened almost to the form of slate.
3. Fire Clay: Usually mined at deeper levels than the other two clays and have refractory qualities.
MANUFACTURING
There are six general phases in the manufacture of brick.
1. Winning - the mining of clay or shale and transportation of it to the manufacturing site.
2. Preparation - crushing, grinding and mixing the clay into a uniform raw material.
3. Forming - mixing water with the prepared clay in a plug mill. The amount of water used will determine the plasticity of the clay.
The process used to form the brick will determine the plasticity required.
Stiff-Mud Process - the clay with 12 to 15% moisture content is extruded through a die to produce a column of clay.
This column is then cut into the desired sizes.
Soft-Mud Process - the clay with 20 to 30% moisture content is too soft to go through a die. It is formed in molds. To
prevent the clay from sticking, the molds are lubricated with either sand (sand-struck) or water (water-struck).
Dry-Press Process - the clay with less than 10% moisture content is formed in steel molds under pressure from
hydraulic or compressed air rams.
4. Drying - after the wet clay is formed it is dried to remove the moisture through evaporation. The drying time is usually 24 to 48 hours.
5. Firing and Cooling - firing, one of the most specialized steps in the manufacturing of brick, requires from 40 to 150 hours
depending upon kiln type and other variables. Firing may be divided into six general stages: 1) water-smoking (evaporating free
water), 2) dehydration, 3) oxidation, 4) vitrification, 5) flashing and 6) cooling. All except flashing and cooling are associated with
rising temperatures in the kiln. After the temperature has reached the maximum and is maintained for a prescribed time, the cooling
process begins. Because the cooling has a direct effect on color and because excessively rapid cooling will cause cracking and
checking of the ware, cooling is an important stage in the flashing process.
6. Drawing - the process of unloading a kiln after cooling and packing the brick for shipment.
COLOR
The color of fired clay depends upon its chemical composition, the firing temperatures and the method of firing control. Of
all the oxides commonly found in clays, iron probably has the greatest effect on color. Regardless of its natural color, clay
containing iron in practically any form will burn red when exposed to an oxidizing fire. A general rule of thumb is the darker the
brick, the higher the firing temperature.
TEXTURE AND COATINGS
Many brick have smooth or sand-finished textures produced by the dies or molds used in forming, in the stiff-mud process,
many textures may be applied by attachments which cut, scratch, roll, brush or otherwise roughen the surface as the clay
column leaves the die. Many plants apply engobes (slurries) of finely ground clay, coloring agents and water to the roughened
column. Sands can be rolled into the slurry coating to create interesting and distinctive patterns in the finished products.
The Detering Company, Houston, Texas • Telephone: 713.869.3761 • Fax: 713.869.4595
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BRICK CLASSIFICATIONS
ASTM
(American Society for Testing and Materials)
ASTM is the world’s leader in the development of voluntary consensus
standards for materials, products, systems and services. Its 140 standards
writings committees annually publish over 7,000 standards to meet the needs of
numerous industries and services.
ASTM C216-04
ASTM C216-04 is the standard specification for Facing Brick.
EXPOSURE (WEATHERING)
Because of the varying climates throughout the country, and a different
application of brick, specific grades of brick are required. Brick must meet
a grade of SW or MW based on the weathering index and the exposure of
the brick. The weathering index is the product of the average annual number
of freezing cycle days and the average annual winter rainfall in inches. The
exposure is related to either a vertical or horizontal surface and whether the unit
will be in contact with the earth. A higher weathering index or a more severe
exposure will require a face brick to meet the SW requirements of the brick.
The grade is typically based on physical properties of the brick.
WEATHERING REGIONS
Appearance
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Brick types are related to the appearance of the unit, and specifically to limit
on dimensional tolerances, distortion tolerances and chippage of the unit. The
brick type can be selected depending upon whether: a high degree of precision
is necessary; a wider range of color or size is permitted; or a characteristic
architectural effect is desired. The three appearance grade for ASTM C216 brick
are: FBX, FBS and FBA. (Note: FBA grades is as specified by the purchaser)
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50
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MODERATE WEATHERING
SEVERE WEATHERING
Dimensional Tolerances
Maximum Permissible Variation (In.) +
-
ASTM
Standard
C 216
Over 3 to 4 in.
< 3 in.
FBX
FBS
FBA
1/16
3/32
Over 4 to 6 in.
3/32
1/8
Over 6 to 8 in.
Over 8 to 12 in. Over 12 to 16 in.
1/8
5/32
3/16
1/4
As Specified by the Purchaser
7/32
5/16
9/32
3/8
Distortion Tolerances
ASTM
Standard
C 216
FBX
FBS
FBA
Maximum Permissible Variation (In.)
< 3 in.
Over 3 to 4 in.
1/16
3/32
3/32
1/8
Over 4 to 6 in.
1/8
5/32
Maximum Permissible Range of Chippage
C216
FBX
FBS1
FBS2
FBA
Percent
Allowed
95% to 100%
90% to 100%
85% to 100%
Chippage in From
Edge (in)
Corner (in)
0-1/8
0-1/4
0-5/16
Percent
Allowed
5% or less
0-1/4
10% or less
0-3/8
15% or less
0-1/2
Chippage in From
Edge (in)
Corner (in)
1/8-1/4
1/4-5/16
5/16-7/16
1/4-3/8
3/8-1/2
1/2-3/4
1
Smooth texture - die skin finish.
2
Rough texture - sanded, combed, scratched, wire cut.
For Additional information visit “Online Tech Notes” on BIA (Brick Industry Association) Website at http://www.brickinfo.org
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Brick Sizes
Bricks are available in many varied sizes and have been called by different names. To eliminate this confusion, in
1993 the Brick Institute of America and the National Association of Brick Distributors, collaborated to establish
standard brick dimensions. The established standards represent roughly 90% of all sizes currently manufactured.
Bricks are identified by three dimensions: width, height and length.
Face Brick
H
L
W
Modular
3-5/8” x 2-1/4” x 7-5/8”
Utility
3-1/2” x 3-1/2” x 11-1/2”
Standard
3-5/8” x 2-1/4” x 8”
King
3” x 2-5/8” x 9-5/8”
Queen
3” x 2-3/4” x 8”
Oversized
3-1/2” x 2-3/4” x 7-5/8”
Modular
3-5/8” x 2-1/4” x 7-5/8”
4x8
4” x 2-1/4” x 8”
Pavers
Thin Modular
3-5/8” x 1-1/4” x 7-5/8”
Thin 4 x 8
4” x 1-1/4” x 8”
For additional information visit “Online Tech Notes” on BIA (Brick Industry Association)
web site at www.brickinfo.org
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BRICK MASONRY JOINTS
Mortar joint finishes fall into two classes: tooled and troweled joints. In the tooled joint a special tool is used to compress and shape
the mortar in the joint. In the troweled joint the excess mortar is cut off (struck) with the trowel with no further finishing.
Of the mortar joints illustrated below only the concave, v-shaped, grapevine, and weathered are recommended for exterior applications.
BRICK PATTERNS
Your home can have distinct character when brick patterns are incorporated into the brickwork. Below are the basic patterns which
have endless possibilities of applications. Some of the locations where pattern brickwork can be placed are under a feature window,
above your garage door(s), on a chimney or fireplace, or on a large wall area which has no windows or openings.
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Brick Bond Patterns
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ARCHES
Brick masonry arches have been used to add beauty and distinction to buildings for centuries. The wonder
of the brick masonry arch is that it not only is aesthetic but serves a practical purpose. Structurally
speaking, under the uniform load of the brick arch, the induced stresses are principally compressive. Brick
masonry has greater resistance to compression than it does to tension, therefore making the masonry arch
very effective for spaning openings. Arch shapes are created by using tapered mortar joints, tapered brick
shapes, or a combination of both.
Illustrated below are a number of different types of arches that have been developed over hundreds of
years, which can be used to add distinction to any contemporary structure. By modifying a basic arch, a
mason can create many desirable shapes.
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BRICK PAVING
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MORTAR FOR BRICK MASONRY
Mortar is the bonding agent that integrates brick into a masonry wall. Mortar must be strong, durable,
and capable of keeping the wall intact. In addition, it must help in creating a water resistant barrier and
it must accommodate dimensional variations and physical properties of the brick when laid. Because
concrete and mortar contain the same principal ingredients, it is often erroneously assumed that good
concrete practice is also good mortar practice. In reality, mortar differs from concrete in working
consistencies, methods of placement and structural performance. Mortar is used to bind masonry units
into a single element, developing a complete, strong and durable bond. Concrete, however, is usually a
structural element in itself. Mortar is usually placed between absorbent masonry units and loses water
upon contact with the units. Concrete is usually placed in non-absorbent metal or wooden forms, which
absorb little, if any water. The importance of the water-cement ratio for concrete is significant, whereas
for mortar it is less important. Mortars have a high water-cement ratio when mixed, but this ratio changes
to a lower value when the mortar comes in contact with the absorbent unit.
Historically, mortars have been made from a variety of materials. Burned gypsum and sand were used
to make mortar in ancient Egypt, while lime and sand were used extensively in this country before
the 1900’s. Currently, the basic dry ingredients for mortar include Portland cement, masonry cement,
hydrated lime and sand. Each of these materials makes a definite contribution to mortar performance.
There are four general mortar types:
Type M. A high compressive strength mortar specifically recommended for masonry below grade and
in contact with earth.
Type S. A mortar recommended for use in masonry where maximum flexural strength is required.
Type N. A medium strength mortar suitable for general use in exposed masonry above grade and
specifically recommended for parapets, chimneys and exterior walls subjected to severe weathering
conditions.
Type 0. A relatively low compressive strength mortar suitable for limited exterior use and general
interior use in load bearing and non-load bearing masonry. Type 0 mortar should not be used where it
will be subject to freezing in the presence of moisture.
No single type of mortar is best for all purposes. The basic rule for the selection of a mortar for a
particular project is: Never use a mortar that is stronger (in compression) than is required by the structural
requirements of the project.
Type N Portland cement-lime mortar is recommended for brick veneer, except that Type M Portland
cement-lime mortar should be used for brick veneer below grade where the brickwork is in contact with
earth. The Portland cement-lime mortar is recommended because they have a long history of proven
performance in brick veneer construction.
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Mortar is perhaps the last building material in history that is still manufactured at the project site.
The following on site practices should be followed to insure the quality of mortar meets the required
specifications:
1. Cementitious materials and aggregates shall be stored in such a manner as to prevent deterioration or
contamination by foreign materials.
2. The method of measuring materials for the mortar used in construction shall be by either volume or
weight, and such that the specified proportions of the mortar materials can be controlled and accurately
maintained. Measurement of sand by shovel shall not be permitted. Table 1 list proportion requirements
of the various mortar types. Note that a Type N masonry cement may be combined with Portland cement
to produce Type S or Type M mortar.
3. All cementitious materials and aggregate shall be mixed for at least 3 minutes and not more than 5
minutes in a mechanical batch mixer, with the maximum amount of water to produce a workable
consistency.
4. Mortars that have stiffened because of evaporation of water from the mortar may be retempered by
adding water as frequently as needed to restore the required consistency. Mortars should be used and
placed in final position within 2-1/2 hours after initial mixing.
5. When coloring mortar, use the minimum quantity of pigments that will produce the desired results;
excess may seriously impair strength and durability. The maximum permissible quantity of most metallic
oxide pigments is 10 percent of the cement content by weight. Although carbon black is a very effective
coloring agent, it will greatly reduce mortar strength when used in greater proportions. Therefore, limit
carbon black to 2 percent of the cement by weight.
TABLE 1
Proportion Specification Requirements
NOTE—Two air-entraining materials shall not be combined in mortar.
Proportions by Volume (Cementitious Materials)
Mortar
Cement-lime
Masonry cement
Type
Portland
Cement or
Blended
Cement
Masonry Cement
Hydrated Lime
or Lime Putty
M
S
N
1
...
...
...
1
S
1
...
...
...
over 1/4 to 1/2
N
1
...
...
...
over 1/2 to 1/4
O
1
...
...
...
over 11/4 to 1/2
M
1
...
...
1
...
M
1
...
...
...
S
...
1
/2
...
...
1
...
S
...
...
1
...
...
N
...
...
...
1
...
O
...
...
...
1
...
M
Aggregate Ratio (Measured in
Damp, Loose Conditions)
/4
Not less than 21/4 and not more than
3 times the sum of the separate volumes
of cementitious materials.
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BRICK CLEANING
The bucket and brush cleaning is the most widely used method of cleaning newly constructed brick walls in both small and
large jobs. A minimum amount of equipment is needed and workmen do not need to he highly skilled.
This method may be used for cleaning all colors and textures of brick. However, care must be used in selecting the proper
cleaning solution for the job.
The safest way to determine the proper cleaning solution for a given type of brick is to ask the brick manufacturer for his
recommendation. Listed below are some of the recommended commercial cleaning compounds:
Sure Klean 101, 600 and Vanatrol
Superior 800 series
Goldblatt Brick Bath
Diedrich 200, 202, 202 Vana-Stop
Formulation of most commercial cleaners is so complicated that the users should rely on the chemical manufacturers’
recommendations as found on the containers and on the recommendations of the brick manufacturers.
The Detering Company DOES NOT recommend the uses of muriatic acid for the cleaning of any brick lines they represent.
THE FOLLOWING PROCEDURES are RECOMMENDED FOR CLEANING BY THE BUCKET AND
BRUSH METHOD;
1. Schedule cleaning at least seven days after the brick masonry is completed. Mortar must be thoroughly set and cured.
Prolonged time periods between the completion of the masonry work and the actual cleaning should be avoided when possible.
2. Remove large mortar particles by hand with wooden paddles, non-metallic scrape hoes or chisels.
3. Protect metal, glass, wood, limestone and cast stone surfaces. Mask or otherwise protect windows, doors and
ornamental trim from cleaning solutions.
4. Presoak or saturate the area to be cleaned. Flush with water from the top down. Saturated brick masonry will not absorb
the cleaning solution or dissolved mortar particles. Areas below should also be saturated in order to prevent absorption
of the run-off from above.
5. Starting at the top, apply the cleaning solution. Use a long handled stiff fiber brush or other type as recommended by
the cleaning solution manufacturer. Allow the solution to remain on the brickwork 5 to 10 minutes. For proprietary compounds follow the manufacturer’s instructions for application and scrubbing. Wooden paddles or other non-metallic tools
may be used to remove stubborn particles. Do not use metal scrapers or chisels. Metal marks will oxidize and cause staining.
6. Heat, direct sunlight, warm masonry and drying winds will affect the drying time and reaction rate of cleaning solutions.
Ideally, the cleaning crew should be working on shaded areas to avoid rapid evaporation.
7. Rinse thoroughly!! Flush walls with large amounts of clean water from top to bottom before they can dry. Failure to
completely flush the wall of cleaning solution and dissolve materials from top to bottom may result in the formation of
“white scum”.
8. Work on a small area. The size of the “wash down” area should be determined after a trial run. This will permit the
cleaning crew to examine the work for initial results.
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Manufacturer’s Specifications
Manufacturer
Product
Size/Inch
Weight/Coverage SF w/
Packaging
W x H x L
Pound
3/8" Mortar Joint
American Eagle Brick
King
3 X 2-5/8 X 9-5/8
4
4.8
496 EA/CUBE
ANTIQUE brick
MODULAR
3-5/8 x 2-1/4 x 7-5/8
4.5 (approx) 6.5
530 EA/PALLET
boulder creek stone
Varies by pattern. Contact Detering’s Brick Selection Center
for box quantities and coverage specifications.
D’hanis brick
modular
3-5/8 x 2-1/4 x 7-5/8
4
6.75
525 ea/cube
5.2 (paver - dry set)
525 ea/cube
4.5 (paver - mortar set) 525 ea/cube
Interstate Brick
Advantage
3 X 2-5/8 X 8-5/8
3.9
5.33
530 EA/CUBE
(comparable to Queen)
KING
3 X 2-5/8 X 9-5/8
4.4
4.8
424 EA/CUBE
NATURAL TEXAS limestone
nominal
varies/pallet chop stone L: 4" to 10"
40 to 45
SF/Ton
2000lb/
W: 3" to 5"
H: 2" to 10"
builderIrregular, larger than
35 to 40 SF/Ton
varies/
pallet
a dinner plate
W: 3" to 5"
PINE HALL BRICK
QUEEN
3 X 2-3/4 X 8
3.6
6.75
520 EA/CUBE
robinson BRICK
Modular
3-5/8 x 2-1/4 x 7-5/8
3.6
6.75
500 ea/cube
robinson thin brick
veneer
2-1/4 x 1/2 x 7-5/8
0.7
7.1
50 ea/box
corners
0.9
4.75
25 ea/box
robinson thin natural STONE
veneer, flat
varies 1" - 6"
45 lb/
5sf/
varies/box
boxbox
veneer, flat
varies 1" - 6"
1800 lb/
100sf/
varies/pallet
palletpallet
corner
varies 1" - 6"
54 lb/
5 lf/
varies/box
boxbox
corner
varies 1" - 6"
900 lb/
100 lf/
varies/pallet
PalletPallet
Snyder Brick
Pioneer
2-5/8 X 2-5/8 X 8-1/8
3.1
5.3 (w/1/2" Mortar Joint) 575 EA/
CUBE
(comparable to Queen)
claystone
2-5/8 X VARIES X 8-1/2 17.27 LB/SF 110 (w/1/2" Mortar Joint)/520 EA/CUBE
COVERAGE CUBEAPPROXIMATE
Tecno ind.
stone
3 x 3 x 10
7.606
3.9 488 EA/CUBE
sPLIT FACE/ROCK FACE 3 x 3 x 10
7.606
3.9 (1/2 joint)408/pallet
king
2.5 x 2.87 x 9.5
5.401
executive
3 x 2.87 x 10
6.834
35

GENERAL OVERVIEW OF BRICK MANUFACTURING

Transcription

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