GLASS INFORMATION
Commercial
Glass:
The main
constituent of practically all-commercial glass is sand. Sand by itself can be
fused to produce glass but the temperature at which this can be achieved is
about 1700˚ C. Adding other chemicals to sand can considerably reduce the
temperature of the fusion. The addition of sodium carbonate (NA2O), known as
soda ash, in a quantity to produce a fused mixture of 75% silica (SiO2) and 25%
of sodium oxide (NA2O), will reduce the temperature of fusion to about 800†
C.
However, a
glass of this composition is water-soluble and is known as water glass. In order
to give the glass stability, other chemicals like calcium oxide (CaO) and
magnesium oxide (MgO) are needed. The raw materials used for introducing CaO and
MgO are their carbonates CaCO3 (limestone) and MgCO3 (dolomite), which when
subjected to high temperatures gives off carbon dioxide leaving the oxides in
the glass.
Soda-lime
Glass:
The chemical
and physical properties of soda-lime glass make it suitable for visible light
and hence applications. The nominally colorless types transmit a very high
percentage of visible light and have been used for windows since at least the
time of the Romans. Soda-lime glass containers are virtually inert, and
therefore do not contaminate the contents inside. Their resistance to chemical
attack from aqueous solutions is good enough to withstand repeated boiling (as
in the cast of preserving jars) without any significant changes in the glass
surface.
One of the main
disadvantages of soda-lime glass is their relatively high thermal expansion.
Silica does not expand very greatly when heated but the addition of soda has a
dramatic effect in increasing the expansion rate. In general, the higher the
soda content of glass, the poorer its resistance will be to sudden changes of
temperature (thermal shock). Thus, care is needed when soda-lime containers are
filled with hot liquids to prevent breakage due to rapid thermal
expansion.
Borosilicate
Glass:
As the name
implies, borosilicate glass is composed mainly of silica (70-80%) and boric
oxide (7-13%) with smaller amounts of alkalis (sodium and potassium oxides) and
aluminum oxide. They are characterized by the relatively low alkali content and
consequently have good chemical durability and thermal shock resistance. Thus
they are permanently suitable for process plants in the chemical industry, for
laboratory apparatuses, for ampoules and other pharmaceutical containers, for
various high intensity lighting applications and as glass fibers for textile and
plastic reinforcement. In the home they are familiar in the form of ovenware and
other heat-resisting ware, possibly better known under the trade name
Pyrex, the first
glass of this type to be placed on the consumer market.
The Float Glass
Process:
The float glass
process, invented by Pilkington Brothers PLC and introduced in 1959, is now the
principal method of producing flat glass around the world.
The glass is
held in a chemically controlled atmosphere at a high enough temperature (1000†
C) for a long enough time for irregularities to melt out and for the surface to
become flat and parallel. Because the surface of molten tin is flat, the glass
becomes flat and the thickness of the ribbon, in the range of 2.5mm to 25mm, is
controlled at this stage. The ribbon is cooled down while still advancing along
the molten tin until the surface is hard enough (600† C) for it to be lifted
onto the conveyor rollers without marking the bottom surface. The ribbon passes
through the annealing chamber to the automatic warehouse where computers govern
the cutting of the ribbon to match custom orders. A large modern float glass
plant will produce 5000 tons of glass per week. The glass produced has a uniform
thickness and bright fire-polished surfaces.