Centrifugal Casting: In this group of processes
the molten metal is forced to distribute into the mold cavity due to centrifugal
acceleration. Centrifugal casting processes can be classified as true centrifugal
casting, which, when the molten metal is poured into the cavity, forces it against
the mold walls where it solidifies into a hollow cylinder; semicentrifugal casting,
which differs from true centrifugal casting in that the mold cavity is completely
filled with molten metal so that the core, which is later removed, is subjected
to low pressure and is where air and inclusions are trapped and the centrifuging
method in which molten metal is poured into a number of mold cavities which
are connected to a central down sprue and which rotate around the central axis
of the sprue, which is shifted from the central axis of the castings and causes
the mold cavities to be filled under high pressure.
Continuous Casting: In continuous casting, a stream of molten
metal comes out of a water-cooled orifice and forms a continuous strip or rod
which is then cut by a circular saw. One of the newer techniques, usually referred
to as rotary continuous casting, involves the water-cooled orifice (mold) oscillating
and rotating at about 120 revolutions per minute during the casting process.
Continuous casting has a very high metal yield, about ninety-eight percent compared
to eighty-seven percent in conventional ingot-mold practices, excellent quality
of cast, controlled grain size and the ability of casting special cross-sectional
shapes.
Die Casting: Die casting processes force the molten metal into
the cavity of a steel mold, called a die, under very high pressure, from 1000
to 30,000 psi. Classification of die casting involves the types of machine used,
the two primary types being hot-chamber machines and cold-chamber machines.
Hot-Chamber Machines: The main components of the hot-chamber machine
are a steel pot with molten metal in it and a pumping system consisting
of a pressure cylinder, a plunger, a gooseneck passage and a nozzle. When
the plunger is in the up position molten metal flows by gravity through
the intake ports into the hot-chamber. When the power cylinder pushes down
the plunger it shuts off the intake ports and forces the metal through the
gooseneck passage and nozzle into the die cavity. High pressure is maintained
to allow the casting to completely solidify, then the two halves of the
die are pushed apart and the ejector pin knocks out the casting. Finally
the die cavity is cleaned and lubricates and the cycle begins again. The
advantages to hot-chamber casting include: high production rates, improved
conductivity, superior surface finish, close tolerances and the ability
to produce intricate shapes with thin walls. It does have limitations, however.
Only low melting point alloys like zinc, tin and lead can be used because
the parts of the pumping system are in direct contact with the molten metal
for long periods of time. The process is also usually only suitable for
making small castings that weigh less than ten pounds.
Cold-Chamber Machines: For cold-chamber machines the molten metal
reservoir is separate from the casting machine and just enough metal for
one shot is ladled on every stroke. The metal is poured into the pouring
hole of the shot chamber while the two halves of the die are locked together.
Then the plunger moves forward, closing the pouring hole and forcing the
molten metal into the die cavity. After solidification the die is opened
and the casting is ejected from the die. As the chamber and plunger are
in contact with the molten metal for shorter times, metals with higher melting
points, such as aluminum, magnesium and brass, can be used in the process.
It is also possible to produce large parts weighing up to fifty pounds by
this process, but it does have a longer cycle than hot-chamber die casting.
Slush Casting: Slush casting is a process for making hollow
articles by inverting the mold after partial freezing on the surface in order
to drain out the still liquid metal at the center. Solidification begins at
the walls because they are relatively cool and works inward, so the thickness
of the shell is controlled by the amount of time allowed before the mold is
drained. This is a relatively inexpensive process, however only low melting
point alloys with narrow freezing ranges can be used and it is a slow method,
requiring close temperature control of the liquid metal.
Please submit any questions or comments concerning this website to njsalamon@psu.edu.
© by Meghan Henty & N. J. Salamon 1999, 2000. All rights reserved.
Redesigned by William C. Chow 2000.