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Sunday, 18 March 2012

Classification of Bricks

Classification of Bricks

Clay bricks can be classified according to their varieties, qualities, and classes.

1. Common Bricks

Common burnt clay bricks, which are accepted for use in general brick work with no special claim for attractive appearances. Walls built with common bricks require rendering or plastering.

2. Facing Bricks

Quality burnt clay bricks, which give attractive appearance in their color and texture. It is used without rendering, plastering, or other surface treatments.

3. Loadbearing Bricks

Loadbearing bricks, which can be either common or facing bricks, conform to specified average compressive strength limits depending on their classes as given in table below.

Class	Average Compressive Strength
Class	N/mm²	P.S.I.
1	7.0	1,000
2	14.0	2,000
3	20.5	3,000
4	27.5	4,000
5	34.5	5,000
7	48.5	7,000
10	69.0	10,000
15	103.5	15,000
* Based on British Standard 3921:1965

Engineering Bricks

Engineering bricks are bricks burnt at exceedingly high temperatures. They possess a dense and strong semi-vitreous body and conform to the defined limits for strength and water absorption. They are primarily used in civil engineering works that require high load bearing capacity, good damp-proof, and chemical resisting characteristics.

Engineering	Average Compressive Strength, (No less than) N/mm² U.S.A.	Average Water Absorption, % (No greater than)
A	69.0 (10,000 psi)	4.5
B	48.5 (7,000 psi)	7.0
* Based on British Standard 3921:1965

5. Damp Proof Course
Clay bricks of specified low water absorption used at the base of a wall (minimum two courses) to resist the upward movement of ground water. Their use is recommended for free standing wall where otherwise a sheet of DPC material would create a plane of weakness causing the wall to be vulnerable to lateral forces.

Strength
Bricks are well-known for their high compressive strength. Their compressive strength depends on:

The raw materials used
The manufacturing process
The shape and size

Bricks made by a de-aerated extruder and fired to sufficiently high temperature can easily withstand a compressive pressure exceeding 28 N/mm2 (4,000 psi). They are suitable for almost all structural building applications

Aesthetic appeal
Brick possesses the natural and pleasant colours of burnt clay. Its colour formation is achieved through a complicate physical chemical reaction during the firing process. In contrast to colour of stained body, brick colour is permanent and will not be faded during weathering process. Different clay compositions, firing temperatures or kiln atmosphere can lead to different colours of the burnt products. By proper control of these factors, bricks can be made to exhibit endless variety of natural and attractive colours.

Besides its richness in colour, bricks can be made to various textures. It is the combination of colour and texture that gives brick such distinctive feature which is everlasting and meadows with age. In view of the high cost to maintain the appearance of a building, the unique features of brick become an unparalleled advantage to housing design.

Porosity
Porosity is an important characteristic of brick. In contrast to other moulded or pre-cast building materials, the porosity of brick is attributed to its fine capillaries. By virtue of the capillary effect, the rate of moisture transport in the brick is ten times faster than in other building materials. Moisture is released during day-time and re-absorbed during night-time. The ability to release and re-absorb moisture (a "breathing" process) by capillary effect is one of the most useful properties of brick that helps to regulate the temperature and humidity of atmosphere in a house. This distinctive property makes brick an admirable building material, particularly suitable for houses in the tropics. On the other hand, all porous materials are susceptible to chemical attacks and liable to contamination from weathering agents like rain, running water and polluted air. Porosity of building material is an important factor to consider in respect its performance and applications.

Experiment results show that bricks with water absorption rate at 8% is 10 times more durable in resisting salt attack than that with water absorption rate at 20%. Well burnt brick has a normal water absorption rate less than 10% in contrast to that of concrete block and cement mortar exceeding 15%. This explains why brick walls require comparatively minimum maintenance in the course of time.

To mitigate the adverse effects but at the same time retain the advantages associated with porosity, the rate of water absorption of facing bricks for masonry brickwork should preferable be maintained around 10%.

A rarely known property of brick is its initial rate of absorption (IRA). It is in fact the initial rate of absorption that plays a key role in affecting the strength of bond between bricks and mortar during bricklaying. High value of IRA tends to remove excessive water from the mortar rapidly and thus hampers the proper hydration of cement. Experiments show that and an increase of IRA from 2 kg/m2/min to 4 kg/m2/min reduces the strength of brickwork by 50%. Generally, bricks with IRA exceeding 2 kg/m2/min will gives rise to difficulties in laying using common cement mortars. Modern brick extruder with de-airing action produces denser brick with lower IRA.

Fire Resistance
Brick is inherent with excellent fire resistance. A 100 mm brickwork with 12.5 mm normal plastering will provide a fire-resistance of 2 hours and a 200 mm non-plastered brickwork will give a maximum rating of 6 hours for non-load bearing purposes. Brick can support considerable load even when heated to 1000oC in contrast to concrete wall at only up to 450oC due to loss of water of hydration.

It is a fact that the non-combustibility of brick helps to promote its use in building houses against fire. There have been numerous examples in the past that people chose to use bricks for their houses after a devastating fire that burned down the whole city. Perhaps the most famous instance is the great London Fire in 1666, after which the rebuilding was largely done if not entirely in brick.

Sound Insulation
Brick wall shows good insulation property due to its dense structure. The sound insulation of brickwork is generally 45 decibels for a 4-1/2 in. thickness and 50 decibels for a 9-in. thickness for the frequency range of 200 to 2,000 Hz.

Thermal Insulation
Brick generally exhibits better thermal insulation property than other building materials like concrete. Perforation can improve the thermal insulation property of bricks to some extent. Besides, the mass and moisture of bricks help to keep the temperature inside the house relatively constant. In other words, bricks absorb and release heat slowly and thus keep the house cool during daytime and warm during nighttime.

Energy saving of a brick house is remarkable. A study commissioned by the Brick Institute of America had demonstrated that a brick house can save energy up to 30% when compared to that built of wood.

A comparison of the thermal conductivities of various materials is given in table below:-

Typical Thermal Conductivities of Various Building Materials
Material	Btu/(sq.ft.-hr-F/in.)	W/mK
Sand & gravel aggregate (dry)	9.0	1.30
Cement Mortar	5.0	0.70
Concrete (1:4)	5.28	0.77
Concrete Block (1:5) (four Oval-core)	5.2	0.75
Concrete Block (1:10) (four Oval-core)	6.6	0.95
Solid Brick (density:1925kg/m3)	5.0	0.72
Perforated Brick (25% perforation density:1400kg/m3)	4.0	0.58

Wear resistance

The wear resistance of a substance depends on its particulate bonds. Bricks shows high wear resistance because of its extremely strong ceramic bonds formed by the effect of heat at high temperature.

Efflorescence
Efflorescence is a phenomenon that soluble slats dissolved in water are carried, deposited and gradually accumulated on brick surfaces to form an unsightly scum. The soluble salts may be originated from the raw material of bricks. But in most cases, efflorescence is caused by salts from the external sources such as ground water, contaminated atmosphere, mortar ingredients and other materials in contacts with the bricks.

Flexibility in ApplicationsBrick is used for an extremely wide range of applications in an equally extensive range of building and engineering structures. In particular, it can be used for load bearing structures which greatly simply the construction process so as to save materials, time and labour. Besides, brick can be make into convenient shape and size to facilitate the construction work. It is very flexible and handy in application almost everywhere.

Durability
Brick is extremely durable and perhaps is the most durable man-made structural building materials so far. There has been numerous ancient brick-building standing for centuries as a testimony of the endurance of burnt-clay brick.

Technical Data

Facing Bricks

Dimensions: 215 x 102 x 70 mm

Size Tolerance: ± 2%

Dry Weight: 2.8 kg per piece

Compressive Strength: > 45N/mm²

Water Absorption: < 8%

Efflorescence: Nil

Colours: Super Red, Cream, Brown

Type: Smooth-Face, Bark-Face, Rock-Face, Wire-Cut.

Per Pallet: 500 pieces

Common Bricks ( 3 holes )

Dimensions: 215 x 96 x 70 mm

Compressive Strength:> 25mN/m²

Water Absorption:< 13.7%

Per Pallet: 500 pieces

Common Bricks ( full )

Dimensions:215 x 96 x 70 mm

Compressive strength: > 25mN/m²

Water absorption: < 13.5%

Thermal Conductivity: 1.04W/m K

Per Pallet: 500 pieces

Block Bricks ( 3 holes )

Dimensions: 220 x 97 x 140 mm

Compressive Strength: > 26.5mN/m²

Water Absorption: < 13.6%

Efflorescence: Nil

Soluble Salt: 0.16% per mm

Double Common Bricks ( 3 holes )

Dimensions: 220 x 90 x 140 mm

Compressive Strength: > 29mN/m²

Water Absorption: < 12.8% per mm

Efflorescence: Nil

Manufacturing of Bricks

Manufacturing of Bricks
The manufacturing process has six general phases.

1.) Mining and Storage.
Surface clays, shales and somefire clays are mined in open pits with power equipment. Then the clay or shale mixtures are transported to plant storage areas. Continuous brick production regardless of weather conditions is ensured by storing sufficient quantities of raw materials required for many days of plant operation. Normally, several storage areas (one for each source) are used to facilitate blending of the clays. Blending produces more uniform raw materials, helps control colour and allows raw material control for manufacturing a certain brick body.

2.) Preparing Raw Materials.
To break up large clay lumps and stones, the material is processed through size-reduction machines before mixing the raw material. Usually the material is processed through inclined vibrating screens to control particle size.

3.) Forming.
Tempering, the first step in the forming process, produces a homogeneous, plastic clay mass. Usually,this is achieved by adding water to the clay in a pug mill, a mixing chamber with one or morerevolving shafts with blade extensions. After pugging, the plastic clay mass is ready for forming. There are three principal processes for forming brick: stiff-mud, soft-mud and dry-press.

· Stiff-Mud Process - In the stiff-mud or extrusion process (see Photo 3), water in the range of 10 to 15percents is mixed into the clay to produce plasticity. After pugging, the tempered clay goes through a deairingchamber that maintains a vacuum of 15 to 29 in. (375 to 725 mm) of mercury. De-airing removesair holes and bubbles, giving the clay increased workability and plasticity, resulting in greater strength.Next, the clay is extruded through a die to produce a column of clay. As the clay column leaves the die,textures or surface coatings may be Anautomatic cutter then slices through the clay column to create the individual brick. Cutter spacing and diesizes must be carefully calculated to compensate for normal shrinkage that occurs during drying and firing. About 90 percents of brick in the
United States are produced by theextrusion process.

· Soft-Mud Process - The soft-mud or moulded process is particularly suitable for clays containing toomuch water to be extruded by the stiff-mud process. Clays are mixed to contain 20 to 30 percents waterand then formed into brick in moulds. To prevent clay from sticking, the moulds are lubricated with eithersand or water to produce “sand-struck” or “water-struck” brick. Brick may be produced in this manner bymachine or by hand.

· Dry-Press Process - This process is particularly suited to clays of very low plasticity. Clay is mixed witha minimal amount of water (up to 10 percent), then pressed into steel moulds under pressures from 500 to1500 psi (3.4 to 10.3 MPa) by hydraulic or compressed air rams.

4.) Drying.
Wet brick from moulding or cutting machines contain 7 to 30 percent moisture, depending upon the formingmethod. Before the firing process begins, most of this water is evaporated in dryer chambers at temperaturesranging from about 100 ºF to 400 ºF (38 ºC to 204 ºC). The extent of drying time, which varies with different clays,usually is between 24 to 48 hours. Although heat may be generated specifically for dryer chambers, it usually issupplied from the exhaust heat of kilns to maximize thermal efficiency. In all cases, heat and humidity must becarefully regulated to avoid cracking in the brick.

5.) Hacking.
Hacking is the process of loading a kiln car or kiln with brick. The number of brick on the kiln car isdetermined by kiln size. The brick are typically placed by robots or mechanical means. The setting pattern hassome influence on appearance. Brick placed face to face will have a more uniform colour than brick that are cross-set or placed face-to-back.

6.) Firing.
Brick are fired between 10 and 40 hours, depending upon kiln type and other variables. There are several types of kilns used by manufacturers. The most common type is a tunnel kiln, followed by periodic kilns. Fuel may be natural gas, coal, sawdust, methane gas from landfills or a combination of these fuels. In a tunnel kiln brick are loaded onto kiln cars, which pass through various temperature zones as they travel through the tunnel. The heat conditions in each zone are carefully controlled, andthe kiln is continuously operated. A periodic kiln is one that is loaded, fired, allowed to cool and unloaded, after which the same steps are repeated. Dried brick are set in periodic kilns according to a prescribed pattern that permits circulation of hot kiln gases.

7.) Cooling.
After the temperature has peaked and is maintained for a prescribed time, the cooling process begins. Cooling time rarely exceeds 10 hours for tunnel kilns and from 5 to 24 hours in periodic kilns. Cooling is an important stage in brick manufacturing because the rate of cooling has a direct effect on colour.

8.) De-hacking.
De-hacking is the process of unloading a kiln or kiln car after the brick have cooled, a job often performed by robots. Brick are sorted, graded and packaged. Then they are placed in a storage yard or loaded onto rail cars or trucks for delivery. The majority of brick today are packaged in self-contained, strapped cubes, which can be broken down into individual strapped packages for ease of handling on the jobsite. The packages and cubes are configured to provide openings for handling by forklifts.

Bricks

Take a look at this

How It's Made Bricks!

Bricks which are blocks of ceramic material that used mostly in construction, where there usually laid using different kinds of mortar. It has been known as one of the longest lasting and strongest building materials used throughout the history. Bricks are also the only man-made building materials that testify to their use since the early human civilization.

There are few types of clays where it occured in three principal forms, all of which have similar chemical compositions but different physical characteristics.

1. Surface Clays.

Surface clays may be the upthrusts of older deposits or of more recent sedimentary formations. Asthe name implies, they are found near the surface of the earth.

2. Shales.

Shales are clays that have been subjected to high pressures until they have nearly hardened into slate.

3. Fire Clays.

Fire clays are usually mined at deeper levels than other clays and have refractory qualities.

Surface and fire clays have a different physical structure from shales but are similar in chemical composition. Allthree types of clay are composed of silica and alumina with varying amounts of metallic oxides. Metallic oxides act as fluxes promoting fusion of the particles at lower temperatures. Metallic oxides (particularly those of iron, magnesium and calcium) influence the colour of the fired brick. The manufacturer minimizes variations in chemical composition and physical properties by mixing clays from different sources and different locations in the pit. Chemical composition varies within the pit, and the differences

are compensated for by varying manufacturing processes. As a result, brick from the same manufacturer will have slightly different properties in subsequent production runs. Further, brick from different manufacturers that have the same appearance may differ in other properties.

GO Green!

Sustainable technology – Green Concrete

Making cement for concrete involves heating pulverized limestone, clay, and sand to 1,450 °C with a fuel such as coal or natural gas. The process generates a lot of carbon dioxide: making one metric ton of commonly used Portland cement releases 650 to 920 kilograms of it. The 2.8 billion metric tons of cement produced worldwide in 2009 contributed about 5 percent of all carbon dioxide emissions. Nikolaos Vlasopoulos, chief scientist at London-based startup Novacem, is trying to eliminate those emissions with a cement that absorbs more carbon dioxide than is released during its manufacture. It locks away as much as 100 kilograms of the greenhouse gas per ton.
Vlasopoulos discovered the recipe for Novacem's cement as a grad student at Imperial College London. "I was investigating cements produced by mixing magnesium oxides with Portland cement," he says. But when he added water to the magnesium compounds without any Portland in the mix, he found he could still make a solid-setting cement that didn't rely on carbon-rich limestone. And as it hardened, atmospheric carbon dioxide reacted with the magnesium to make carbonates that strengthened the cement while trapping the gas. Novacem is now refining the formula so that the product's mechanical performance will equal that of Portland cement. That work, says Vlasopoulos, should be done "within a year."

Understanding towards Concrete..

Now, let us take a look at some example of Concrete Buildings/Structures

The Parthenon 447 and 438 B.C. (Europe, Greece)

The Colosseum (Rome,Italy)

Basic desired properties that we should know:

- Good workability

- High Strength and hardness

- Adequate durability

- Economy

Factors that affect the setting of concrete.

- Water Cement ratio

- Suitable Temperature

- Cement content

- Type of Cement

- Fineness of Cement

- Relative Humidity

- Admixtures

- Type and amount of Aggregate

Workability

The ability of a fresh (plastic) concrete mix to fill the form/mold properly with the desired work (vibration) and without reducing the concrete’s quality.

Higher workability concretes are easier to mix, transport (especially, place and compact. Higher workability of concrete can be achieved by one or a combination of the following:

1. Use of a well graded aggregate.

2. Use of smooth and well rounded, rather than irregularly shaped aggregate.

3. Use of air-entraining admixtures.

4. Use of plasticizers and superplasticisers.

5. Higher water/cement ratio.

Workability Test

1. Slump Test

2. Compacting Factor Test

3.Vebe Test

4.Flow Table Test

Concrete?! What is that??

WHAT IS THAT??!

>>Composite construction material composed primarily of

aggregate, cement and water.

Aggregate

Aggregates are added to cement with water to form concrete. Usually they occupy about 65-80% of the total concrete volume.

Why do we need aggregate in concrete??

- they greatly reduce cost

- they reduce heat output and therefore reduce thermal stress

- they reduce shrinkage of concrete

- they help to produce a concrete (when fresh) with satisfactory plastic properties

Desirable properties of aggregates:

- they must be sufficiently strong

- clean, free from constituents which can react harmfully with cement

- have small or no moisture movement

- be well graded

- right shape and texture so as not to adversely affect the properties of fresh and hardened concrete

- low thermal conductivity

Cement

The production process

Chalk & clay reduced to particle sizes ≤ 75 µm

│

Mixed in the required proportion

│

Mixture either mixed with water to

form a slurry or dried as powder

Figure 13.1

Calcining – base materials are heated to form oxides;

CaO (lime) = C

SiO₂(silica) = S

Al₂O₃(alumina) = A

Fe₂O₃(iron oxide) = F

Clinkering – oxides at high temperatures combine to form compounds mainly

calcium silicates, calcium aluminates and calcium aluminoferrites

The final products of the above processes, in the form of clinkers, are chiefly the calcium silicates and aluminates and smaller amounts of other compounds;

Tricalcium silicate = C₃S

Dicalcium silicate = C₂S

Tricalcium aluminate = C₃A

Tetracalcium aluminoferrite = C₄AF

Each grain of cement consists of a mixture of the above compounds.

After cooling a small amount of gypsum (calcium sulfate dehydrate, CaSO₄.2H₂O) is added to the clinker before the mixture is ground to a fine powder. The purpose of gypsum is to retard the curing process so as to prevent immediate stiffening of the cement paste during hydration.

Portland cement

Ordinary Portland Cement

Rapid-Hardening Portland Cement

Ultra high early strength Portland cementLow-Heat Portland cement

Sulphate resisting Portland cement

White Portland cement

Portland blast-furnace cement

Non Portland cement

High alumina cement

Supersulphated cement

Concrete

How concrete function ??

The cement and water combined to form a paste and when hardened, binds the aggregates particles together to form a monolithic whole. The cement and water hardened by a chemical reaction, called hydration.

Type of Concrete

Reinforced Concrete

Pre-stressed Concrete

Mass Concrete