Carbon steels are produced in greater tonnage and have wider
use than any other metal because of their versatility and low
cost. There were several reasons why carbon steels proved
satisfactory on reappraisal:
- their hardenability, though less than that of
alloy steels, was adequate for many parts, and for some parts
shallower hardening was actually an advantage because of
minimized quench cracking;
- refinements in heat treating methods, such as
induction hardening, flame hardening, and "shell quenching",
made it possible to obtain higher properties from carbon
steels than previously; and
- new compositions were added to the carbon steel
group, permitting more discriminating selection.
There are now almost 50 grades available in the
nonresulfurized series 1000 carbon steels and nearly 30
grades in the resulfurized series 1100 and 1200. The
versatility of the carbon steel group has also been extended
by availability of the various grades with lead additions.
Carbon steels can be divided into three arbitrary
classifications based on carbon content.
Steels with 0.10 to 0.25% C. Three principal types of
heat treatment are used for this group of steels:
- conditioning treatments, such as process
annealing, that prepare the steel for certain fabricating
operations,
- case hardening treatments, and
- quenching and tempering to improve mechanical
properties.
The improvement in mechanical properties that can be gained
by straight quenching and tempering of the low-carbon steels
is usually not worth the cost.
An example of process annealing is in the treatment of
low-carbon cold-headed bolts made from cold drawn wire.
Sometimes the strains introduced by cold working weaken the
heads so much that they break through the most severely
worked portion under slight additional strain. Process
annealing overcomes this condition. Since the temperatures
used are close to the lower transformation temperature, this
treatment results in considerable reduction of the normal
mechanical properties of the shank of the cold headed bolt.
A more suitable treatment is stress relieving at about 1000oF
(540oC). This treatment is used in order to retain
much of the strength acquired in cold working and to provide
ample toughness. A common practice is to combine a
stress-relieving treatment with a quench from the upper
transformation temperature, or slightly above, producing
mechanical properties that approach those of cold drawn
stock. A common quenching medium is a water solution of
soluble oil, the use of which produces two desirable
results:
- the surface of the parts acquires a pleasing black color
accepted as a commercial finish, and
- the speed of the quench is slowed to the point where
fully quenched hardness is not produced, so it is not
necessary to temper the parts.
Heat treatments are frequently employed to improve
machinability. The generally poor machinability of the
low-carbon steels, except those containing sulfur or other
special alloying elements, results principally from the fact
that the proportion of free ferrite to carbide is high. This
situation cannot be changed fundamentally, but the
machinability can be improved by putting the carbide in its
most voluminous form, pearlite, and dispersing this pearlite
evenly throughout the ferrite mass. Normalizing is commonly
used with success, but best results are obtained by quenching
the steel in oil from 1500 to 1600oF
(815-870oC). With the exception of steels 1024
and 1025, no martensite is formed, and the parts do not
require tempering.
Steels with 0.25 to 0.55% C. Because of their higher
carbon content, these steels are usually used in the hardened
and tempered condition. By selection of quenching medium and
tempering temperature a wide range of mechanical properties
can be produced. They are the most versatile of the three
groups of carbon steels and are most commonly used for
crankshafts, couplings, tie rods and many other machinery
parts where the required hardness values are within the
range from 229 to 447 HB. This group of steels shows a
continuous change from water-hardening to oil-hardening
types. The hardenability is very sensitive to changes in
chemical composition, particularly to the content of
manganese, silicon and residual elements, and to grain size;
the steels are sensitive to section changes.
The rate of heating parts for quenching has a marked effect
on hardenability under certain conditions. If the structure
is non-uniform, as a result of severe banding or lack of
proper normalizing or annealing, extremely rapid heating such
as may be obtained in liquid baths, will not allow sufficient
time for diffusion of carbon and other elements in the
austenite. As a result, non-uniform or low hardness will be
produced unless the duration of heating is extended. In
heating steels that contain free carbide (for example,
spheroidized material), sufficient time must be allowed for
the solution of the carbides; otherwise the austenite at the
time of quenching will have a lower carbon content than is
represented by the chemical composition of the steel, and
disappointing results may be obtained.
These medium-carbon steels should usually be either
normalized or annealed before hardening, in order to obtain
the best mechanical properties after hardening and tempering.
Parts made from bar stock are frequently given no treatment
prior to hardening, but it is common practice to normalize
or anneal forgings. Most of bar stocks, both, hot finished
and cold finished, are machined as received, except the
higher-carbon grades and small sizes, which require annealing
to reduce the as-received hardness. Forgings are usually
normalized, since this treatment avoids the extreme softening
and consequent reduction of machinability that result from
annealing.
In some instances a "cycle treatment" is used. In this
practice the parts are heated as for normalizing, and are
then cooled rapidly in the furnace to a temperature somewhat
above the nose of the S-curve - that is, within the
transformation range that produces pearlite. Then the parts
are held at temperature or cooled slowly until the desired
amount of transformation has taken place; thereafter they are
cooled in any convenient manner. Specially arranged furnaces
are usually required. Details of the treatments vary widely
and are frequently determined by the furnace equipment
available.
Cold headed products are commonly made from these steels,
especially from the ones containing less than 0.40% C.
Process treating before cold working is usually necessary
because the higher carbon decreases the workability. For
certain uses, these steels are normalized or annealed above
the upper transformation temperature, but more frequently a
spheroidizing treatment is used. The degree of
spheroidization required depends on the application. After
shaping operations are finished, the parts are heat treated
by quenching and tempering.
These medium-carbon steels are widely used for machinery
parts for moderate duty. When such parts are to be machined
after heat treatment, the maximum hardness is usually held to
321HB, and is frequently much lower.
Salt solutions are often successfully used. Salt solutions
are not dangerous to operators but their corrosive action on
iron or steel parts of equipment is very serious.
When the section is light or the properties required after
heat treatment are not high, oil quenching is often used.
This nearly always eliminates the breakage problem and is
very effective in reducing distortion.
A wide range in austenitizing temperatures is made necessary
in order to meet required conditions. Lower temperatures
should be used for the higher-manganese steels, light
sections, coarse-grained material and water quenching;
higher temperatures are required for lower manganese, heavy
sections, fine grain and oil quenching.
From these steels are made many common hand tools, such as
pliers, open-end wrenches, screwdrivers, and a few edged
tools - for example, tin snips and brush knives. The cutting
tools are necessarily quenched locally on the cutting edges,
in water, brine or caustic, and are subsequently given
suitable tempering treatments. In some instances the edge is
time quenched; then the remainder of the tool is oil quenched
for partial strengthening. When made of these grades of steel,
pliers, wrenches and screwdrivers are usually quenched in
water, either locally or completely, and are then suitably
tempered.
Steels with 0.55 to 1.00% C. Carbon steels with these higher
carbon contents are more restricted in application than the
0.25 to 0.55% C steels since they are more costly to
fabricate, because of decreased machinability, poor
formability and poor weldability. They are also more brittle
in the heat treated condition.
Higher-carbon steels such as 1070 to 1095 are especially
suitable for springs where resistance to fatigue and
permanent set are required. They are also used in the nearly
fully hardened condition (Rockwell C 55 and higher) for
applications where abrasion resistance is the primary
requirement, as for agricultural tillage tools such as
plowshares, and knives for cutting hay or grain.
Forged parts should be annealed because refinement of the
forging structure is important in producing a high-quality
hardened product, and because the parts come from the hammer
too hard for cold trimming of the flash or for economical
machining. Ordinary annealing practice, followed by furnace
cooling to 1100oF (590oC), is
satisfactory for most parts.
Most of the parts made from steels in this group are hardened
by conventional quenching. However, special technique is
necessary sometimes. Both oil and water quenching are used -
water, for heavy sections of the lower-carbon steels and for
cutting edges and oil, for general use. Austempering and
martempering are often successfully applied; the principal
advantages from such treatments are considerably reduced
distortion, elimination of breakage, in many instances, and
greater toughness at high hardness.
For heavy machinery parts, such as shafts, collars and the
like, steels 1055 and 1061 may be used, either normalized and
tempered for low strength, or quenched and tempered for
moderate strength. Other steels in the list may be used, but
the combination of carbon and manganese in the two mentioned
makes them particularly well adapted for such applications.
It must be remembered that even with all hardenability
factors favorable, including the use of a drastic quench,
these steels are essentially shallow hardening, as compared
with alloy steels, because carbon alone, or in combination
with manganese in the amounts involved here, does not promote
deep hardening to any significant extent. Therefore, the
sections for which such steels are suited will be definitely
limited. In spite of this limitation the danger of breakage
is real and must be carefully guarded against when such parts
are being treated, especially whenever changes in section
are involved.
Hand tools made from these steels include open-end wrenches,
Stillson wrenches, hammers, mauls, pliers and screw
drivers and cutting tools, such as hatchets, axes, mower
knives and band knives. The combination of carbon and
manganese in the steels used may vary widely for the same
type of tool, depending partly on the equipment available for
manufacture and partly on personal experience with, or
preference for, certain combinations. A manganese content
lower than standard will be used in some tools. This is
justified when it makes a particular carbon range easier to
handle, but it should be understood that for many
applications, a combination of lower carbon and higher
manganese would serve just as well.