The Manufacturing Steel Pipe
Steel Pipe
Steel pipes are long, hollow tubes that are used for a variety of purposes. They are produced by two distinct methods which result in either a welded or seamless pipe. In both methods, raw steel is first cast into a more workable starting form. It is then made into a pipe by stretching the steel out into a seamless tube or forcing the edges together and sealing them with a weld. The first methods for producing steel pipe were introduced in the early 1800s, and they have steadily evolved into the modern processes we use today. Each year, millions of tons of steel pipe are produced. Its versatility makes it the most often used product produced by the steel industry.
Steel pipes are found in a variety of places. Since they are
strong, they are used underground for transporting water and gas throughout
cities and towns. They are also employed in construction to protect electrical
wires. While steel pipes are strong, they can also be lightweight. This makes
them perfect for use in bicycle frame manufacture. Other places they find
utility is in automobiles, refrigeration units, heating and plumbing systems,
flagpoles, street lamps, and medicine to name a few.
History
People have used pipes for thousands of years. Perhaps the
first use was by ancient agriculturalists who diverted water from streams and
rivers into their fields. Archeological evidence suggests that the Chinese used
reed pipe for transporting water to desired locations as early as 2000 B.C.
Clay tubes that were used by other ancient civilizations have been discovered.
During the first century A.D. , the first lead pipes were constructed in
Europe. In tropical countries, bamboo tubes were used to transport water.
Colonial Americans used wood for a similar purpose. In 1652, the first waterworks
was made in Boston using hollow logs.
Development of the modern day welded steel pipe can be
traced back to the early 1800s. In 1815, William Murdock invented a coal
burning lamp system. To fit the entire city of London with these lights,
Murdock joined together the barrels from discarded muskets. He used this
continuous pipeline to transport the coal gas. When his lighting system proved
successful a greater demand was created for long metal tubes. To produce enough
tubes to meet this demand, a variety of inventors set to work on developing new
pipe making processes.
An early notable method for producing metal tubes quickly
and inexpensively was patented by James Russell in 1824. In his method, tubes
were created by joining together opposite edges of a flat iron strip. The metal
was first heated until it was malleable. Using a drop hammer, the edges folded
together and welded. The pipe was finished by passing it through a groove and
rolling mill.
Russell's method was not used long because in the next year,
Comelius Whitehouse developed a better method for making metal tubes. This
process, called the butt-weld process is the basis for our current pipe-making
procedures. In his method, thin sheets of iron were heated and drawn through a
cone-shaped opening. As the metal went through the opening, its edges curled up
and created a pipe shape. The two ends were welded together to finish the pipe.
The first manufacturing plant to use
Welded pipe is formed by rolling steel strips through a
series of grooved rollers that mold the material into a circular shape. Next,
the unwelded pipe passes by welding electrodes. These devices seal the two ends
of the pipe together.
Welded pipe is formed by rolling steel strips through a
series of grooved rollers that mold the material into a circular shape. Next,
the unwelded pipe passes by welding electrodes. These devices seal the two ends
of the pipe together.
this process in the United States was opened in 1832 in
Philadelphia.
Gradually, improvements were made in the Whitehouse method.
One of the most important innovations was introduced by John Moon in 1911. He
suggested the continuous process method in which a manufacturing plant could
produce pipe in an unending stream. He built machinery for this specific purpose
and many pipe manufacturing facilities adopted it.
While the welded tube processes were being developed, a need
for seamless metal pipes arouse. Seamless pipes are those which do not have a
welded seam. They were first made by drilling a hole through the center of a
solid cylinder. This method was developed during the late 1800s. These types of
pipes were perfect for bicycle frames because they have thin walls, are
lightweight but are strong. In 1895, the first plant to produce seamless tubes
was built. As bicycle manufacturing gave way to auto manufacturing, seamless
tubes were still needed for gasoline and oil lines. This demand was made even
greater as larger oil deposits were found.
As early as 1840, ironworkers could already produce seamless
tubes. In one method, a hole was drilled through a solid metal, round billet.
The billet was then heated and drawn through a series of dies which elongated
it to form a pipe. This method was inefficient because it was difficult to
drill the hole in the center. This resulted in an uneven pipe with one side
being thicker than the other. In 1888, an improved method was awarded a patent.
In this process the solid billed was cast around a fireproof brick core. When
it was cooled, the brick was removed leaving a hole in the middle. Since then
new roller techniques have replaced these methods.
Design
There are two types of steel pipe, one is seamless and
another has a single welded seam along its length. Both have different uses.
Seamless tubes are typically more light weight, and have thinner walls. They
are used for bicycles and transporting liquids. Seamed tubes are heavier and
more rigid. The have a better consistency and are typically straighter. They
are used for things such as gas transportation, electrical conduit and
plumbing. Typically, they are used in instances when the pipe is not put under
a high degree of stress.
Certain pipe characteristics can be controlled during
production. For example, the diameter of the pipe is often modified depending
how it will be used. The diameter can range from tiny pipes used to make
hypodermic needles, to large pipes used to transport gas throughout a city. The
wall thickness of the pipe can also be controlled. Often the type of steel will
also have an impact on pipe's the strength and flexibility. Other controllable
characteristics include length, coating material, and end finish.
Raw Materials
The primary raw material in pipe production is steel. Steel
is made up of primarily iron. Other metals that may be present in the alloy
include aluminum, manganese, titanium, tungsten, vanadium, and zirconium. Some
finishing materials are sometimes used during production. For example, paint
may be
Seamless pipe is manufactured using a process that heats and
molds a solid billet into a cylindrical shape and then rolls it until it is
stretched and hollowed. Since the hollowed center is irregularly shaped, a
bullet-shaped piercer point is pushed through the middle of the billet as it is
being rolled.
Seamless pipe is manufactured using a process that heats and
molds a solid billet into a cylindrical shape and then rolls it until it is
stretched and hollowed. Since the hollowed center is irregularly shaped, a
bullet-shaped piercer point is pushed through the middle of the billet as it is
being rolled.
used if the pipe is coated. Typically, a light amount of oil
is applied to steel pipes at the end of the production line. This helps protect
the pipe. While it is not actually a part of the finished product, sulfuric
acid is used in one manufacturing step to clean the pipe.
The Manufacturing
Process
Steel pipes are made by two different processes. The overall
production method for both processes involves three steps. First, raw steel is
converted into a more workable form. Next, the pipe is formed on a continuous
or semicontinuous production line. Finally, the pipe is cut and modified to
meet the customer's needs.
Ingot production
1 Molten steel is made by melting iron ore and coke (a
carbon-rich substance that results when coal is heated in the absence of air)
in a furnace, then removing most of the carbon by blasting oxygen into the
liquid. The molten steel is then poured into large, thick-walled iron molds,
where it cools into ingots.
2 In order to form flat products such as plates and sheets,
or long products such as bars and rods, ingots are shaped between large rollers
under enormous pressure.
Producing blooms and slabs
3 To produce a bloom, the ingot is passed through a pair of
grooved steel rollers that are stacked. These types of rollers are called
"two-high mills." In some cases, three rollers are used. The rollers
are mounted so that their grooves coincide, and they move in opposite
directions. This action causes the steel to be squeezed and stretched into
thinner, longer pieces. When the rollers are reversed by the human operator,
the steel is pulled back through making it thinner and longer. This process is
repeated until the steel achieves the desired shape. During this process,
machines called manipulators flip the steel so that each side is processed
evenly.
4 Ingots may also be rolled into slabs in a process that is
similar to the bloom making process. The steel is passed through a pair of
stacked rollers which stretch it. However, there are also rollers mounted on
the side to control the width of the slabs. When the steel acquires the desired
shape, the uneven ends are cut off and the slabs or blooms are cut into shorter
pieces.
Further processing
5 Blooms are typically processed further before they are
made into pipes. Blooms are converted into billets by putting them through more
rolling devices which make them longer and more narrow. The billets are cut by
devices known as flying shears. These are a pair of synchronized shears that
race along with the moving billet and cut it. This allows efficient cuts
without stopping the manufacturing process. These billets are stacked and will
eventually become seamless pipe.
6 Slabs are also reworked. To make them malleable, they are
first heated to 2,200° F (1,204° C). This causes an oxide coating to form on
the surface of the slab. This coating is broken off with a scale breaker and
high pressure water spray. The slabs are then sent through a series of rollers
on a hot mill and made into thin narrow strips of steel called skelp. This mill
can be as long as a half mile. As the slabs pass through the rollers, they
become thinner and longer. In the course of about three minutes a single slab
can be converted from a 6 in (15.2 cm) thick piece of steel to a thin steel
ribbon that can be a quarter mile long.
7 After stretching, the steel is pickled. This process
involves running it through a series of tanks that contain sulfuric acid to
clean the metal. To finish, it is rinsed with cold and hot water, dried and
then rolled up on large spools and packaged for transport to a pipe making
facility.
Pipe making
8 Both skelp and billets are used to make pipes. Skelp is
made into welded pipe. It is first placed on an unwinding machine. As the spool
of steel is unwound, it is heated. The steel is then passed through a series of
grooved rollers. As it passes by, the rollers cause the edges of the skelp to
curl together. This forms an unwelded pipe.
9 The steel next passes by welding electrodes. These devices
seal the two ends of the pipe together. The welded seam is then passed through
a high pressure roller which helps create a tight weld. The pipe is then cut to
a desired length and stacked for further processing. Welded steel pipe is a
continuous process and depending on the size of the pipe, it can be made as
fast as 1,100 ft (335.3 m) per minute.
10 When seamless pipe is needed, square billets are used for
production. They are heated and molded to form a cylinder shape, also called a
round. The round is then put in a furnace where it is heated white-hot. The
heated round is then rolled with great pressure. This high pressure rolling
causes the billet to stretch out and a hole to form in the center. Since this
hole is irregularly shaped, a bullet shaped piercer point is pushed through the
middle of the billet as it is being rolled. After the piercing stage, the pipe
may still be of irregular thickness and shape. To correct this it is passed
through another series of rolling mills.
Final processing
11 After either type of pipe is made, they may be put
through a straightening machine. They may also be fitted with joints so two or
more pieces of pipe can be connected. The most common type of joint for pipes
with smaller diameters is threading—tight grooves that are cut into the end of
the pipe. The pipes are also sent through a measuring machine. This information
along with other quality control data is automatically stenciled on the pipe.
The pipe is then sprayed with a light coating of protective oil. Most pipe is
typically treated to prevent it from rusting. This is done by galvanizing it or
giving it a coating of zinc. Depending on the use of the pipe, other paints or
coatings may be used.
Quality Control
A variety of measures are taken to ensure that the finished
steel pipe meets specifications. For example, x-ray gauges are used to regulate
the thickness of the steel. The gauges work by utilizing two x rays. One ray is
directed at a steel of known thickness. The other is directed at the passing steel
on the production line. If there is any variance between the two rays, the
gauge will automatically trigger a resizing of the rollers to compensate.
Pipes are also inspected for defects at the end of the
process. One method of testing a pipe is by using a special machine. This
machine fills the pipe with water and then increases the pressure to see if it
holds. Defective pipes are returned for scrap.
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