Boiler
Boiler, device for heating water
or generating steam above atmospheric pressure. All boilers consist of a
separate compartment where the fuel is burned and a compartment where water can
be evaporated into steam.
II
|
EARLY HISTORY
|
The first evidence of the
idea of using steam energy to produce power appeared in the Pneumatica
of the Greek inventor and mathematician Hero of Alexandria in the 1st century ad. In it he described an aeolipile, a
steam turbine consisting of a boiler connected by two hollow tubes to the poles
of a freely spinning hollow sphere. The sphere was equipped with two canted
nozzles that issued steam, causing the sphere to rotate. Other references are
found in works from the Middle Ages and Renaissance, but no practical devices
seem to have been built until the Italian architect and inventor Giovanni
Branca designed a boiler that emitted steam that struck blades projecting from
a wheel, causing it to rotate.
The first practical steam
engine, built by the English engineer Thomas Savery in 1698, used two copper
vessels alternately filled with steam from a boiler. Savery's engine was used
for pumping water out of mines, as was the one developed in 1712 by the British
inventor Thomas Newcomen.
The Scottish inventor James Watt
improved upon Newcomen's steam engine design and introduced the first
significant boiler advance, the spherical or cylindrical vessels heated from
below by an open fire. Watt's boiler, built in 1785, consisted of a horizontal
shell encased in brick, with flues to circulate the hot combustion gases over
the boiler. Watt was one of the first engineers to apply new knowledge about
the thermodynamic properties of steam in his design. He used the lever safety
valve, pressure gauges, and water cocks to control the flow of water and steam
in his boilers.
III
|
FIRE-TUBE BOILER
|
Savery, Watt, and Newcomen
engines all operated at pressures only slightly above atmospheric pressure. In
1800 the American inventor Oliver Evans built a high-pressure steam engine
utilizing a forerunner of the fire-tube boiler. Evans's boiler consisted of two
cylindrical shells, one inside the other; water occupied the region between
them. The fire grate and flue were housed inside the inner cylinder, permitting
a rapid increase in steam pressure. Simultaneously but independently, the
British engineer Richard Trevithick developed a similar “Cornish” boiler. The
first major improvement over Evans's and Trevithick's boilers was the fire-tube
“Lancashire Boiler,” patented in 1845 by the British engineer Sir William
Fairbairn, in which hot combustion gases were passed through tubes inserted
into the water container, increasing the surface area through which heat could
be transferred. Fire-tube boilers were limited in capacity and pressure and
were also, sometimes, dangerously explosive.
IV
|
WATER-TUBE BOILER
|
Boiler pressures, however,
remained limited until the first successful design of a water-tube boiler,
patented in 1867 by the American inventors George Herman Babcock and Stephen
Wilcox. In the water-tube boiler, water flowed through tubes heated externally
by combustion gases, and steam was collected above in a drum. This arrangement
used both the convection heat of the gases and the radiant heat from the fire
and the boiler walls. Wide application of the water-tube boiler became possible
in the 20th century with such developments as high-temperature steel alloys and
modern welding techniques, which made the water-tube boiler the standard type
for all large boilers.
Modern water-tube boilers can
operate at pressure in excess of 5000 psig (lb/sq in gauge) and generate more
than 9 million lb of steam per hour. Because combustion temperatures may exceed
1650° C (3000° F), the water flow is controlled by natural or forced
circulation. By using so-called superheaters, modern boilers can achieve almost
90 percent fuel efficiency. Air preheaters heat the incoming air with
combustion gases that are discharged to the stack; water preheaters use the
flue gases to heat the feedwater before it enters the boiler. Draft control and
chemical treatment of the water to avoid scale deposits and corrosion also
contribute to efficient operation.
No comments:
Post a Comment