Everything about Cast Iron totally explained
Cast iron usually refers to
grey cast iron, but identifies a large group of
ferrous alloys, which solidify with a
eutectic. The color of a fractured surface can be used to identify an alloy.
White cast iron is named after its white surface when fractured due to its carbide impurities which allow cracks to pass straight through.
Grey cast iron is named after its grey fractured surface, which occurs because the graphitic flakes deflect a passing crack and initiate countless new cracks as the material breaks.
Iron (Fe) accounts for more than 95 %wt of the alloy material, while the main alloying elements are
carbon (C) and
silicon (Si). The amount of carbon in cast irons is 2.1-4 %wt. Cast irons contain appreciable amounts of silicon, normally 1-3 %wt, and consequently these alloys should be considered ternary Fe-C-Si alloys. Despite this, the principles of cast iron solidification are understood from the
binary iron-carbon phase diagram, where the
eutectic point lies at 1154 °C and 4.3 wt% carbon. Since cast iron has nearly this composition, its melting temperature of 1150 to 1200 °C is about 300 °C lower than the melting point of pure iron.
Cast iron tends to be
brittle, except for
malleable cast irons. With its low melting point, good fluidity, castability, excellent machinability and wear resistance, cast irons have become an engineering material with a wide range of applications, including pipes, machine and car parts.
Production
Cast iron is made by remelting
pig iron, often along with substantial quantities of scrap iron and scrap steel, and taking various steps to remove undesirable contaminants such as
phosphorus and
sulfur. Depending on the application, carbon and silicon content are reduced to the desired levels, which may be anywhere from 2% to 3.5% and 1% to 3% respectively. Other elements are then added to the melt before the final form is produced by
casting.
Iron is most commonly melted in a small
blast furnace known as a cupola (see
blast furnace for more details). After melting is complete, the molten iron is removed or
ladled from the forehearth of the
blast furnace. This process was devised by the
Chinese, whose innovative ideas revolutionized the field of
metallurgy. Previously, iron was melted in an air furnace, which is a type of
reverberatory furnace.
Varieties of cast iron
Grey cast iron
Silicon is essential to making
grey cast iron as opposed to white cast iron. When silicon is alloyed with ferrite and carbon in amounts of about 2 percent, the carbide of iron becomes unstable. Silicon causes the carbon to rapidly come out of solution as
graphite, leaving a matrix of relatively pure, soft iron. Weak bonding between planes of graphite lead to a high
activation energy for growth in that direction, resulting in thin, round flakes. This structure has several useful properties.
The metal expands slightly on solidifying as the graphite precipitates, resulting in sharp castings. The graphite content also offers good
corrosion resistance.
Graphite acts as a lubricant, improving wear resistance. The exceptionally high
speed of sound in graphite gives cast iron a much higher
thermal conductivity. Since ferrite is so different in this respect (having heavier atoms, bonded much less tightly)
phonons tend to scatter at the interface between the two materials. In practical terms, this means that cast iron tends to “damp” mechanical vibrations (including
sound), which can help machinery to run more smoothly.
All of the properties listed in the paragraph above ease the
machining of grey cast iron. The sharp edges of graphite flakes also tend to
concentrate stress, allowing cracks to form much more easily, so that material can be removed much more efficiently.
Easier initiation of cracks can be a drawback once an item is finished, however: grey cast iron has less
tensile strength and
shock resistance than steel. It is also difficult to weld.
Grey cast iron's high thermal conductivity and
specific heat capacity are often exploited to make
cast iron cookware and
disc brake rotors.
Other cast iron alloys
With a lower silicon content and faster cooling, the carbon in
white cast iron precipitates out of the melt as the
metastable phase
cementite, Fe
3C, rather than graphite. The cementite which precipitates from the melt forms as relatively large particles, usually in a eutectic mixture where the other phase is austenite (which on cooling might transform to martensite). These eutectic carbides are much too large to provide precipitation hardening (as in some steels, where cementite precipitates might inhibit
plastic deformation by impeding the movement of
dislocations through the ferrite matrix). Rather, they increase the bulk hardness of the cast iron simply by virtue of their own very high hardness and their substantial volume fraction, such that the bulk hardness can be approximated by a rule of mixtures. In any case, they offer
hardness at the expense of
toughness. Since carbide makes up a large fraction of the material, white cast iron could reasonably be classified as a
cermet. White iron is too brittle for use in many structural components, but with good hardness and abrasion resistance and relatively low cost, it finds use in such applications as the wear surfaces (
impeller and
volute) of slurry pumps, shell liners and lifter bars in ball mills and autogenous grinding mills, balls and rings in coal pulverisers and (conceivably?) balls for
rolling-element bearings and the teeth of a
backhoe's digging bucket (although the latter two applications would normally use high quality wrought high-carbon martensitic steels and cast medium-carbon martensitic steels respectively).
It is difficult to cool thick castings fast enough to solidify the melt as white cast iron all the way through. However, rapid cooling can be used to solidify a shell of white cast iron, after which the remainder cools more slowly to form a core of grey cast iron. The resulting casting, called a “
chilled casting”, has the benefits of a hard surface and a somewhat tougher interior.
White cast iron can also be made by using a high percentage of
chromium in the iron; Cr is a strong carbide-forming element, so at high enough percentages of chrome, the precipitation of graphite out of the iron is suppressed. High-chrome white iron alloys allow massive castings (for example, a 10-tonne impeller) to be sand cast, for example, a high cooling rate isn't required, as well as providing impressive abrasion resistance.
Malleable iron starts as a white iron casting, that's then
heat treated at about 900 °C. Graphite separates out much more slowly in this case, so that
surface tension has time to form it into spheroidal particles rather than flakes. Due to their lower
aspect ratio, spheroids are relatively short and far from one another, and have a lower
cross section vis-a-vis a propagating crack or phonon. They also have blunt boundaries, as opposed to flakes, which alleviates the stress concentration problems faced by grey cast iron. In general, the properties of malleable cast iron are more like mild steel. There is a limit to how large a part can be cast in malleable iron, since it's made from white cast iron.
A more recent development is
nodular or
ductile cast iron. Tiny amounts of
magnesium or
cerium added to these alloys slow down the growth of graphite precipitates by bonding to the edges of the graphite planes. Along with careful control of other elements and timing, this allows the carbon to separate as spheroidal particles as the material solidifies. The properties are similar to malleable iron but parts can be cast with larger sections.
Comparative qualities of cast irons>
| Name |
Nominal composition [%by weight] |
Form and condition |
Yield strength [ksi (0.2% offset)] |
Tensile strength [ksi] |
Elongation [%(in 2 inches)] |
Hardness [Brinell scale] |
Uses |
| Cast grey iron (ASTM A48) |
C 3.4, Si 1.8, Mn 0.5 |
Cast |
— |
25 |
0.5 |
180 |
Engine blocks, fly-wheels, gears, machine-tool bases |
| White |
C 3.4, Si 0.7, Mn 0.6 |
Cast (as cast) |
— |
25 |
0 |
450 |
Bearing surfaces |
| Malleable iron (ASTM A47) |
C 2.5, Si 1.0, Mn 0.55 |
Cast (annealed) |
33 |
52 |
12 |
130 |
Axle bearings, track wheels, automotive crankshafts |
| Ductile or nodular iron |
C 3.4, P 0.1, Mn 0.4, Ni 1.0, Mg 0.06 |
Cast |
53 |
70 |
18 |
170 |
Gears, cams, crankshafts |
| Ductile or nodular iron (ASTM A339) |
— |
Cast (quench tempered) |
108 |
135 |
5 |
310 |
— |
| Ni-hard type 2 |
C 2.7, Si 0.6, Mn 0.5, Ni 4.5, Cr 2.0 |
Sand-cast |
— |
55 |
– |
550 |
Strength |
| Ni-resist type 2 |
C 3.0, Si 2.0, Mn 1.0, Ni 20.0, Cr 2.5 |
Cast |
— |
27 |
2 |
140 |
Resistance to heat and corrosion |
Historical uses
Because cast iron is comparatively brittle, it isn't suitable for purposes where a sharp edge or flexibility is required. It is strong under compression, but not under tension. Cast Iron was first invented in
China (see also:
Du Shi), and poured into molds to make weapons and figurines. Historically, its earliest uses included cannon and shot. In
England, the
ironmasters of the
Weald continued producing these until the
1760s, and this was the main function of the
iron industry there after the
Restoration, though probably only a minor part of the industry there earlier.
Cast iron pots were made at many
English blast furnaces at that period. In 1707,
Abraham Darby patented a method of making pots (and kettles) thinner and hence cheaper than his rivals could. This meant that his
Coalbrookdale Furnaces became dominant as suppliers of pots, an activity in which they were joined in the
1720s and
1730s by a small number of other
coke-fired blast furnaces.
The development of the
steam engine by
Thomas Newcomen provided a further market for cast iron, since this was considerably cheaper than the
brass of which the engine cylinders were originally made. A great exponent of cast iron was
John Wilkinson, who amongst other things cast the cylinders for many of
James Watt's improved
steam engines until the establishment of the
Soho Foundry in
1795.
Cast iron bridges
The major use of cast iron for structural purposes began in the late
1770s when
Abraham Darby III built the
Iron Bridge, although short beams had been used prior to the bridge, such as in the blast furnaces at Coalbrookdale. This was followed by others, including
Thomas Paine, who patented one; cast iron bridges became common as the
Industrial Revolution gathered pace.
Thomas Telford adopted the material for his bridge upstream at
Buildwas, and then for a canal trough aqueduct at
Longdon-on-Tern on the
Shrewsbury Canal. It was followed by the spectacular
Chirk Aqueduct and the breath-taking
Pontcysyllte Aqueduct, both of which remain in use following recent restorations. Cast iron beam bridges were used widely by the early railways, such as the Water street bridge at the Manchester terminus of the
Liverpool and Manchester Railway. However, problems arose when such a bridge collapsed shortly after opening in 1846. The
Dee bridge disaster was caused by excessive loading at the centre of the beam by a passing train, and many similar bridges had to be demolished and rebuilt, often in
wrought iron. The bridge had been under-designed, being trussed with wrought iron straps, which were wrongly thought to reinforce the structure. Nevertheless, cast iron continued to be used for structural support, until the
Tay Rail Bridge disaster of 1879 created a crisis of confidence in the material. Further bridge collapses occurred, however, culminating in the
Norwood Junction rail accident of 1891. Thousands of cast iron rail under-bridges were eventually replaced by steel equivalents.
Textile mills
Another important use was in
textile mills. The air in these contained flammable fibres from the
cotton,
hemp, or
wool being spun. As a result,
textile mills had an alarming propensity to burn down. The solution was to build them completely of non-combustible materials, and it was found convenient to provide the building with an iron frame, largely of cast iron. This replaced flammable wood. The first such building was at
Ditherington in
Shrewsbury,
Shropshire. Many other warehouses were built using cast iron columns and beams, although there were many collapses owing to faulty designs, flawed beams or overloading.
During the
Industrial Revolution, cast iron was also widely used for the frame and other fixed parts of machinery, including spinning and later weaving machinery in the textile mills. Cast iron became a widespread material, and many towns had
foundries producing machinery, not only for industry but also
agriculture.
Further Information
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