Brick Making
(ordinary
bricks that is)
with thanks to US Army Corps of Engineers
A brick is made from a ceramic structural material that, in modern
times, is made by pressing clay into blocks and firing them to the requisite
hardness in a kiln.
Bricks in their most primitive form were not fired but were
hardened by being dried in the sun. Sun-dried bricks were utilized for many
centuries and are used even today in regions with the proper climate.
Examples
from approximately 5,000 years ago have been discovered in the Tigris-Euphrates
basin, and the ancient races occupying this region may have been the first users
of brick.
In Babylonia there was a lack of both timber and stone, and the thick
clay deposited by the overflowing rivers was the only material adaptable to
building. The Persians and the Assyrians used sun-dried blocks of clay for walls
of great thickness, facing them with a protective coating of fired bricks. The
Egyptians and the Greeks used bricks only to a limited extent, as they had
access to plentiful supplies of stone and marble. The Romans manufactured fired
bricks in enormous quantities and gave them an important role as a basic
structural material in buildings throughout the Roman Empire.
Bricks played an
important part in early Christian architecture until the decline of the empire.
Whereas the Romans had usually concealed their brickwork beneath a decorative
facing of stone or marble, the Byzantines devised a technique for exposing the
bricks and giving them a full decorative expression. This technique influenced
the Romanesque style and brought especially good results in Lombardy and in
Germany, where bricks came to be arranged in immensely varied patterns.
Since
the Middle Ages, brickwork has been in constant use everywhere, adapting itself
to every sort of construction and to every change of architectural style. At the
beginning of the 19th cent. mechanical brick-making processes began to be
patented and by the latter half of the century had almost entirely replaced the
ancient hand-fashioning methods.
Good bricks are resistant to atmospheric action and
high temperatures and are more durable than stone. Where heat resistance is
especially important, fire bricks are used; these are made of special refractory
clays called fire clays and are fired at very high temperatures.
It
is important for industrial
archaeologists to have knowledge about
the architecture and layout of buildings
so that they can gain key insights about
the purposes for which the buildings
were used. Knowing how the
equipment within the buildings was
utilized plays a very important role in
our understanding the evolution of
technology. Archaeologists are
very interested in looking at the
changes in technology to see how they
may have affected the success or failure
of businesses.
In the
late nineteenth century, most brick works had similar components. First, soak pits were used to prepare and mix
clay. Clay was mixed with water and soaked overnight for softening. By doing
that the clay became more pliable so that it could be shaped into bricks using
wooden forms. Once technology began to take over, molding the bricks into the
proper shapes became easier by using a soft-mud brick machine. The machine
automatically shaped the pieces of clay into the form of bricks. A talented
brick maker could produce about 4,000 bricks per day by hand. By the 1890�s,
some brick machines could even produce up to 5,000 bricks per hour.
The next step in the process was drying the bricks so they would be hard and
durable. The brick-makers would put the soft bricks into a steam-heated drying
room. The drying room was generally the largest area of a brick works facility
because they had to accommodate such a large amount of bricks at a time.
Towards the end of the existence of the brick works, the company bought a drying
tunnel,
which allowed the bricks to move through the drying room by a conveyor belt with
steam heat blown on them. By using a drying tunnel as opposed to a drying room,
a much higher quantity of bricks could be dried and finished at a time, allowing
higher sales and saved labour. Before the technology of drying rooms and
tunnels, brick-makers had to lay bricks outside to dry naturally in the sun (and
hope that it didn�t rain).
The last part of the brick-making process was to fire the clay in kilns, which
produced a very high degree of heat to cook the clay before it went through a
final drying process. By cooking the clay, all of the finer elements were fused
with one another to create a stronger, more durable, solid mass. Once the clay
went through all of those processes, it had completed its metamorphosis to
brick.
There is evidence that by 1898, the Harmony Brick Works had eight kilns
altogether. There were five large kilns and three smaller ones. The kilns were
fuelled by natural gas and coal. By the end of the 1890�s, natural gas supplies
were diminishing, so workers were forced to resort to using a combination of
coke and slack coal to heat the kilns. At the Harmony Brick Works, it was
possible to fire many bricks at one time. According to an 1898 article about
the Harmony Brick Works, the five larger kilns could hold 375,000 bricks
apiece. The
three smaller kilns had a holding capacity of 150,000 bricks. The trade-off for
having a high quality of bricks that could be fired at once, was that it took
two weeks for each kiln, large or small, to complete the job. They were
slow-burned and cooked evenly and thoroughly. The bricks had to be laid out in
such a manner that all sides got fired. Sometimes it was necessary to lean them
against the wall on their corners to get heated thoroughly. The Harmony kilns
were of the periodic up-draft, open-top variety. That means that the kilns had
an open top and the bricks were stacked in the kilns so that they had spaces for
air circulation. The bricks were burned so that the fire and smoke rose upward
to escape from the tops of the kilns. This type of kiln is very efficient for
burning many bricks at a time.
The property also included buildings such as a boiler and an engine house to
convert energy to heat for firing and drying, storage sheds for quantities of
unused brick, a grinding house for grinding the finer elements of the clay, and
an office for accounting purposes.
The
layout and geographical location of the company�s structures were quite
practical. It made sense for brick factories to be located near a water source,
clay deposits, and natural heating resources such as coal or natural gas so that
there was increased availability of resources at a cheaper cost. Another
essential architectural component of brick facilities was the serviceability of
building related structures within close proximity of one another. For example,
the clay processing facility, the moulding and drying areas, and the kilns were
built in a cluster for the purpose of minimizing the time it would have taken to
transport all of the bricks from one area to another. In turn, it saved on
labour costs.
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