PREFACE
In the preparation of this work, the object has been to cover not only the
several processes of welding, but also those other processes which are so
closely allied in method and results as to make them a part of the whole subject
of joining metal to metal with the aid of heat.
The workman who wishes to handle his trade from start to finish finds that it is
necessary to become familiar with certain other operations which precede or
follow the actual joining of the metal parts, the purpose of these operations
being to add or retain certain desirable qualities in the materials being
handled. For this reason the following subjects have been included: Annealing,
tempering, hardening, heat treatment and the restoration of steel.
In order that the user may understand the underlying principles and the
materials employed in this work, much practical information is given on the uses
and characteristics of the various metals; on the production, handling and use
of the gases and other materials which are a part of the equipment; and on the
tools and accessories for the production and handling of these materials.
An examination will show that the greatest usefulness of this book lies in the
fact that all necessary information and data has been included in one volume,
making it possible for the workman to use one source for securing a knowledge of
both principle and practice, preparation and finishing of the work, and both
large and small repair work as well as manufacturing methods used in metal
working.
An effort has been made to eliminate all matter which is not of direct
usefulness in practical work, while including all that those engaged in this
trade find necessary. To this end, the descriptions have been limited to those
methods and accessories which are found in actual use today. For the same
reason, the work includes the application of the rules laid down by the
insurance underwriters which govern this work as well as instructions for the
proper care and handling of the generators, torches and materials found in the
shop.
Special attention has been given to definite directions for handling the
different metals and alloys which must be handled. The instructions have been
arranged to form rules which are placed in the order of their use during the
work described and the work has been subdivided in such a way that it will be
found possible to secure information on any one point desired without the
necessity of spending time in other fields.
The facts which the expert welder and metalworker finds it most necessary to
have readily available have been secured, and prepared especially for this work,
and those of most general use have been combined with the chapter on welding
practice to which they apply.
The size of this volume has been kept as small as possible, but an examination
of the alphabetical index will show that the range of subjects and details
covered is complete in all respects. This has been accomplished through careful
classification of the contents and the elimination of all repetition and all
theoretical, historical and similar matter that is not absolutely necessary.
Free use has been made of the information given by those manufacturers who are
recognized as the leaders in their respective fields, thus insuring that the
work is thoroughly practical and that it represents present day methods and
practice.
THE AUTHOR.: Pierre du Plessis
CONTENTS
CHAPTER I
METALS AND ALLOYS--HEAT TREATMENT:--The Use and Characteristics of the
Industrial Alloys and Metal Elements--Annealing, Hardening, Tempering and Case
Hardening of Steel
CHAPTER II
WELDING MATERIALS:--Production, Handling and Use of the Gases, Oxygen and
Acetylene--Welding Rods--Fluxes--Supplies and Fixtures
CHAPTER III
ACETYLENE GENERATORS:--Generator Requirements and Types--Construction--Care and
Operation of Generators.
CHAPTER IV
WELDING INSTRUMENTS:--Tank and Regulating Valves and Gauges--High, Low and
Medium Pressure Torches--Cutting Torches--Acetylene-Air Torches
CHAPTER V
OXY-ACETYLENE WELDING PRACTICE:--Preparation of Work--Torch Practice-- Control
of the Flame--Welding Various Metals and Alloys--Tables of
Information Required in Welding Operations
CHAPTER VI
ELECTRIC WELDING:--Resistance Method--Butt, Spot and Lap Welding--Troubles and
Remedies--Electric Arc Welding
CHAPTER VII
HAND FORGING AND WELDING:--Blacksmithing, Forging and Bending--Forge Welding
Methods
CHAPTER VIII
SOLDERING, BRAZING AND THERMAL WELDING:--Soldering Materials and Practice--
Brazing--Thermal Welding
CHAPTER IX
OXYGEN PROCESS FOR REMOVAL OF CARBON
CHAPTER I
METALS AND THEIR ALLOYS--HEAT TREATMENT
THE METALS
Iron.--Iron, in its pure state, is a soft, white, easily worked metal. It is the
most important of all the metallic elements, and is, next to aluminum, the
commonest metal found in the earth.
Mechanically speaking, we have three kinds of iron: wrought iron, cast iron and
steel. Wrought iron is very nearly pure iron; cast iron contains carbon and
silicon, also chemical impurities; and steel contains a definite proportion of
carbon, but in smaller quantities than cast iron.
Pure iron is never obtained commercially, the metal always being mixed with
various proportions of carbon, silicon, sulphur, phosphorus, and other elements,
making it more or less suitable for different purposes. Iron is magnetic to the
extent that it is attracted by magnets, but it does not retain magnetism itself,
as does steel. Iron forms, with other elements, many important combinations,
such as its alloys, oxides, and sulphates.
Image Figure 1.--Section Through a Blast Furnace
Cast Iron.--Metallic iron is separated from iron ore in the blast furnace
(Figure 1), and when allowed to run into moulds is called cast iron. This form
is used for engine cylinders and pistons, for brackets, covers, housings and at
any point where its brittleness is not objectionable. Good cast iron breaks with
a gray fracture, is free from blowholes or roughness, and is easily machined,
drilled, etc. Cast iron is slightly lighter than steel, melts at about 2,400
degrees in practice, is about one-eighth as good an electrical conductor as
copper and has a tensile strength of 13,000 to 30,000 pounds per square inch.
Its compressive strength, or resistance to crushing, is very great. It has
excellent wearing qualities and is not easily warped and deformed by heat.
Chilled iron is cast into a metal mould so that the outside is cooled quickly,
making the surface very hard and difficult to cut and giving great resistance to
wear. It is used for making cheap gear wheels and parts that must withstand
surface friction.
Malleable Cast Iron.--This is often called simply malleable iron. It is a form
of cast iron obtained by removing much of the carbon from cast iron, making it
softer and less brittle. It has a tensile strength of 25,000 to 45,000 pounds
per square inch, is easily machined, will stand a small amount of bending at a
low red heat and is used chiefly in making brackets, fittings and supports where
low cost is of considerable importance. It is often used in cheap constructions
in place of steel forgings. The greatest strength of a malleable casting, like a
steel forging, is in the surface, therefore but little machining should be done.
Wrought Iron.--This grade is made by treating the cast iron to remove almost all
of the carbon, silicon, phosphorus, sulphur, manganese and other impurities.
This process leaves a small amount of the slag from the ore mixed with the
wrought iron.
Wrought iron is used for making bars to be machined into various parts. If drawn
through the rolls at the mill once, while being made, it is called "muck bar;"
if rolled twice, it is called "merchant bar" (the commonest kind), and a still
better grade is made by rolling a third time. Wrought iron is being gradually
replaced in use by mild rolled steels.
Wrought iron is slightly heavier than cast iron, is a much better electrical
conductor than either cast iron or steel, has a tensile strength of 40,000 to
60,000 pounds per square inch and costs slightly more than steel. Unlike either
steel or cast iron, wrought iron does not harden when cooled suddenly from a red
heat.
Grades of Irons.--The mechanical properties of cast iron differ greatly
according to the amount of other materials it contains. The most important of
these contained elements is carbon, which is present to a degree varying from 2
to 5-1/2 per cent. When iron containing much carbon is quickly cooled and then
broken, the fracture is nearly white in color and the metal is found to be hard
and brittle. When the iron is slowly cooled and then broken the fracture is gray
and the iron is more malleable and less brittle. If cast iron contains sulphur
or phosphorus, it will show a white fracture regardless of the rapidity of
cooling, being brittle and less desirable for general work.
Steel.--Steel is composed of extremely minute particles of iron and carbon,
forming a network of layers and bands. This carbon is a smaller proportion of
the metal than found in cast iron, the percentage being from 3/10 to 2-1/2 per
cent.
Carbon steel is specified according to the number of "points" of carbon, a point
being one one-hundredth of one per cent of the weight of the steel. Steel may
contain anywhere from 30 to 250 points, which is equivalent to saying, anywhere
from 3/10 to 2-1/2 per cent, as above. A 70-point steel would contain 70/100 of
one per cent or 7/10 of one per cent of carbon by weight. The percentage of
carbon determines the hardness of the steel, also many other qualities, and its
suitability for various kinds of work. The more carbon contained in the steel,
the harder the metal will be, and, of course, its brittleness increases with the
hardness. The smaller the grains or particles of iron which are separated by the
carbon, the stronger the steel will be, and the control of the size of these
particles is the object of the science of heat treatment.
In addition to the carbon, steel may contain the following:
Silicon, which increases the hardness, brittleness, strength and difficulty of
working if from 2 to 3 per cent is present.
Phosphorus, which hardens and weakens the metal but makes it easier to cast.
Three-tenths per cent of phosphorus serves as a hardening agent and may be
present in good steel if the percentage of carbon is low. More than this weakens
the metal.
Sulphur, which tends to make the metal hard and filled with small holes.
Manganese, which makes the steel so hard and tough that it can with difficulty
be cut with steel tools. Its hardness is not lessened by annealing, and it has
great tensile strength.
Alloy steel has a varying but small percentage of other elements mixed with it
to give certain desired qualities. Silicon steel and manganese steel are
sometimes classed as alloy steels. This subject is taken up in the latter part
of this chapter under Alloys, where the various combinations and their
characteristics are given consideration.
Steel has a tensile strength varying from 50,000 to 300,000 pounds per square
inch, depending on the carbon percentage and the other alloys present, as well
as upon the texture of the grain. Steel is heavier than cast iron and weighs
about the same as wrought iron. It is about one-ninth as good a conductor of
electricity as copper.
Steel is made from cast iron by three principal processes: the crucible,
Bessemer and open hearth.
Crucible steel is made by placing pieces of iron in a clay or graphite crucible,
mixed with charcoal and a small amount of any desired alloy. The crucible is
then heated with coal, oil or gas fires until the iron melts, and, by absorbing
the desired elements and giving up or changing its percentage of carbon, becomes
steel. The molten steel is then poured from the crucible into moulds or bars for
use. Crucible steel may also be made by placing crude steel in the crucibles in
place of the iron.
This last method gives the finest grade of metal and the crucible process in
general gives the best grades of steel for mechanical use.
Image Figure 2.--A Bessemer Converter
Bessemer steel is made by heating iron until all the undesirable elements are
burned out by air blasts which furnish the necessary oxygen. The iron is placed
in a large retort called a converter, being poured, while at a melting heat,
directly from the blast furnace into the converter. While the iron in the
converter is molten, blasts of air are forced through the liquid, making it
still hotter and burning out the impurities together with the carbon and
manganese. These two elements are then restored to the iron by adding
spiegeleisen (an alloy of iron, carbon and manganese). A converter holds from 5
to 25 tons of metal and requires about 20 minutes to finish a charge. This makes
the cheapest steel.
Image Figure 3.--An Open Hearth Furnace
Open hearth steel is made by placing the molten iron in a receptacle while
currents of air pass over it, this air having itself been highly heated by just
passing over white hot brick (Figure. 3). Open hearth steel is considered more
uniform and reliable than Bessemer, and is used for springs, bar steel, tool
steel, steel plates, etc.
Aluminum is one of the commonest industrial metals. It is used for gear cases,
engine crank cases, covers, fittings, and wherever lightness and moderate
strength are desirable.
Aluminum is about one-third the weight of iron and about the same weight as
glass and porcelain; it is a good electrical conductor (about one-half as good
as copper); is fairly strong itself and gives great strength to other metals
when alloyed with them. One of the greatest advantages of aluminum is that it
will not rust or corrode under ordinary conditions. The granular formation of
aluminum makes its strength very unreliable and it is too soft to resist wear.
Copper is one of the most important metals used in the trades, and the best
commercial conductor of electricity, being exceeded in this respect only by
silver, which is but slightly better. Copper is very malleable and ductile when
cold, and in this state may be easily worked under the hammer. Working in this
way makes the copper stronger and harder, but less ductile. Copper is not
affected by air, but acids cause the formation of a green deposit called
verdigris.
Copper is one of the best conductors of heat, as well as electricity, being used
for kettles, boilers, stills and wherever this quality is desirable. Copper is
also used in alloys with other metals, forming an important part of brass,
bronze, German silver, bell metal and gun metal. It is about one-eighth heavier
than steel and has a tensile strength of about 25,000 to 50,000 pounds per
square inch.
Lead.--The peculiar properties of lead, and especially its quality of showing
but little action or chemical change in the presence of other elements, makes it
valuable under certain conditions of use. Its principal use is in pipes for
water and gas, coverings for roofs and linings for vats and tanks. It is also
used to coat sheet iron for similar uses and as an important part of ordinary
solder.
Lead is the softest and weakest of all the commercial metals, being very pliable
and inelastic. It should be remembered that lead and all its compounds are
poisonous when received into the system. Lead is more than one-third heavier
than steel, has a tensile strength of only about 2,000 pounds per square inch,
and is only about one-tenth as good a conductor of electricity as copper.
Zinc.--This is a bluish-white metal of crystalline form. It is brittle at
ordinary temperatures and becomes malleable at about 250 to 300 degrees
Fahrenheit, but beyond this point becomes even more brittle than at ordinary
temperatures. Zinc is practically unaffected by air or moisture through becoming
covered with one of its own compounds which immediately resists further action.
Zinc melts at low temperatures, and when heated beyond the melting point gives
off very poisonous fumes.
The principal use of zinc is as an alloy with other metals to form brass,
bronze, German silver and bearing metals. It is also used to cover the surface
of steel and iron plates, the plates being then called galvanized.
Zinc weighs slightly less than steel, has a tensile strength of 5,000 pounds per
square inch, and is not quite half as good as copper in conducting electricity.
Tin resembles silver in color and luster. Tin is ductile and malleable and
slightly crystalline in form, almost as heavy as steel, and has a tensile
strength of 4,500 pounds per square inch.
The principal use of tin is for protective platings on household utensils and in
wrappings of tin-foil. Tin forms an important part of many alloys such as
babbitt, Britannia metal, bronze, gun metal and bearing metals.
Nickel is important in mechanics because of its combinations with other metals
as alloys. Pure nickel is grayish-white, malleable, ductile and tenacious. It
weighs almost as much as steel and, next to manganese, is the hardest of metals.
Nickel is one of the three magnetic metals, the others being iron and cobalt.
The commonest alloy containing nickel is German silver, although one of its most
important alloys is found in nickel steel. Nickel is about ten per cent heavier
than steel, and has a tensile strength of 90,000 pounds per square inch.
Platinum.--This metal is valuable for two reasons: it is not affected by the air
or moisture or any ordinary acid or salt, and in addition to this property it
melts only at the highest temperatures. It is a fairly good electrical
conductor, being better than iron or steel. It is nearly three times as heavy as
steel and its tensile strength is 25,000 pounds per square inch.
ALLOYS
An alloy is formed by the union of a metal with some other material, either
metal or non-metallic, this union being composed of two or more elements and
usually brought about by heating the substances together until they melt and
unite. Metals are alloyed with materials which have been found to give to the
metal certain characteristics which are desired according to the use the metal
will be put to.
The alloys of metals are, almost without exception, more important from an
industrial standpoint than the metals themselves. There are innumerable possible
combinations, the most useful of which are here classed under the head of the
principal metal entering into their composition.
Steel.--Steel may be alloyed with almost any of the metals or elements, the
combinations that have proven valuable numbering more than a score. The
principal ones are given in alphabetical order, as follows:
Aluminum is added to steel in very small amounts for the purpose of preventing
blow holes in castings.
Boron increases the density and toughness of the metal.
Bronze, added by alloying copper, tin and iron, is used for gun metal.
Carbon has already been considered under the head of steel in the section
devoted to the metals. Carbon, while increasing the strength and hardness,
decreases the ease of forging and bending and decreases the magnetism and
electrical conductivity. High carbon steel can be welded only with difficulty.
When the percentage of carbon is low, the steel is called "low carbon" or "mild"
steel. This is used for rods and shafts, and called "machine" steel. When the
carbon percentage is high, the steel is called "high carbon" steel, and it is
used in the shop as tool steel. One-tenth per cent of carbon gives steel a
tensile strength of 50,000 to 65,000 pounds per square inch; two-tenths per cent
gives from 60,000 to 80,000; four-tenths per cent gives 70,000 to 100,000, and
six-tenths per cent gives 90,000 to 120,000.
Chromium forms chrome steel, and with the further addition of nickel is called
chrome nickel steel. This increases the hardness to a high degree and adds
strength without much decrease in ductility. Chrome steels are used for
high-speed cutting tools, armor plate, files, springs, safes, dies, etc.
Manganese has been mentioned under Steel. Its alloy is much used for high-speed
cutting tools, the steel hardening when cooled in the air and being called
self-hardening.
Molybdenum is used to increase the hardness to a high degree and makes the steel
suitable for high-speed cutting and gives it self-hardening properties.
Nickel, with which is often combined chromium, increases the strength,
springiness and toughness and helps to prevent corrosion.
Silicon has already been described. It suits the metal for use in high-speed
tools.
Silver added to steel has many of the properties of nickel.
Tungsten increases the hardness without making the steel brittle. This makes the
steel well suited for gas engine valves as it resists corrosion and pitting.
Chromium and manganese are often used in combination with tungsten when
high-speed cutting tools are made.
Vanadium as an alloy increases the elastic limit, making the steel stronger,
tougher and harder. It also makes the steel able to stand much bending and
vibration.
Copper.--The principal copper alloys include brass, bronze, German silver and
gun metal.
Brass is composed of approximately one-third zinc and two-thirds copper. It is
used for bearings and bushings where the speeds are slow and the loads rather
heavy for the bearing size. It also finds use in washers, collars and forms of
brackets where the metal should be non-magnetic, also for many highly finished
parts.
Brass is about one-third as good an electrical conductor as copper, is slightly
heavier than steel and has a tensile strength of 15,000 pounds when cast and
about 75,000 to 100,000 pounds when drawn into wire.
Bronze is composed of copper and tin in various proportions, according to the
use to which it is to be put. There will always be from six-tenths to
nine-tenths of copper in the mixture. Bronze is used for bearings, bushings,
thrust washers, brackets and gear wheels. It is heavier than steel, about 1/15
as good an electrical conductor as pure copper and has a tensile strength of
30,000 to 60,000 pounds.
Aluminum bronze, composed of copper, zinc and aluminum has high tensile strength
combined with ductility and is used for parts requiring this combination.
Bearing bronze is a variable material, its composition and proportion depending
on the maker and the use for which it is designed. It usually contains from 75
to 85 per cent of copper combined with one or more elements, such as tin, zinc,
antimony and lead.
White metal is one form of bearing bronze containing over 80 per cent of zinc
together with copper, tin, antimony and lead. Another form is made with nearly
90 per cent of tin combined with copper and antimony.
Gun metal bronze is made from 90 per cent copper with 10 per cent of tin and is
used for heavy bearings, brackets and highly finished parts.
Phosphor bronze is used for very strong castings and bearings. It is similar to
gun metal bronze, except that about 1-1/2 per cent of phosphorus has been added.
Manganese bronze contains about 1 per cent of manganese and is used for parts
requiring great strength while being free from corrosion.
German silver is made from 60 per cent of copper with 20 per cent each of zinc
and nickel. Its high electrical resistance makes it valuable for regulating
devices and rheostats.
Tin is the principal part of babbitt and solder. A commonly used babbitt is
composed of 89 per cent tin, 8 per cent antimony and 3 per cent of copper. A
grade suitable for repairing is made from 80 per cent of lead and 20 per cent
antimony. This last formula should not be used for particular work or heavy
loads, being more suitable for spacers. Innumerable proportions of metals are
marketed under the name of babbitt.
Solder is made from 50 per cent tin and 50 per cent lead, this grade being
called "half-and-half." Hard solder is made from two-thirds tin and one-third
lead.
Aluminum forms many different alloys, giving increased strength to whatever
metal it unites with.
Aluminum brass is composed of approximately 65 per cent copper, 30 per cent zinc
and 5 per cent aluminum. It forms a metal with high tensile strength while being
ductile and malleable.
Aluminum zinc is suitable for castings which must be stiff and hard.
Nickel aluminum has a tensile strength of 40,000 pounds per square inch.
Magnalium is a silver-white alloy of aluminum with from 5 to 20 per cent of
magnesium, forming a metal even lighter than aluminum and strong enough to be
used in making high-speed gasoline engines.
HEAT TREATMENT OF STEEL
The processes of heat treatment are designed to suit the steel for various
purposes by changing the size of the grain in the metal, therefore the strength;
and by altering the chemical composition of the alloys in the metal to give it
different physical properties. Heat treatment, as applied in ordinary shop work,
includes the three processes of annealing, hardening and tempering, each
designed to accomplish a certain definite result.
All of these processes require that the metal treated be gradually brought to a
certain predetermined degree of heat which shall be uniform throughout the piece
being handled and, from this point, cooled according to certain rules, the
selection of which forms the difference in the three methods.
Annealing.--This is the process which relieves all internal strains and
distortion in the metal and softens it so that it may more easily be cut,
machined or bent to the required form. In some cases annealing is used only to
relieve the strains, this being the case after forging or welding operations
have been performed. In other cases it is only desired to soften the metal
sufficiently that it may be handled easily. In some cases both of these things
must be accomplished, as after a piece has been forged and must be machined. No
matter what the object, the procedure is the same.
The steel to be annealed must first be heated to a dull red. This heating should
be done slowly so that all parts of the piece have time to reach the same
temperature at very nearly the same time. The piece may be heated in the forge,
but a much better way is to heat in an oven or furnace of some type where the
work is protected against air currents, either hot or cold, and is also
protected against the direct action of the fire.
Image Figure 4.--A Gas pipe Annealing Oven
Probably the simplest of all ovens for small tools is made by placing a piece of
ordinary gas pipe in the fire (Figure 4), and heating until the inside of the
pipe is bright red. Parts placed in this pipe, after one end has been closed,
may be brought to the desired heat without danger of cooling draughts or
chemical change from the action of the fire. More elaborate ovens may be bought
which use gas, fuel oils or coal to produce the heat and in which the work may
be placed on trays so that the fire will not strike directly on the steel being
treated.
If the work is not very important, it may be withdrawn from the fire or oven,
after heating to the desired point, and allowed to cool in the air until all
traces of red have disappeared when held in a dark place. The work should be
held where it is reasonably free from cold air currents. If, upon touching a
pine stick to the piece being annealed, the wood does not smoke, the work may
then be cooled in water.
Better annealing is secured and harder metal may be annealed if the cooling is
extended over a number of hours by placing the work in a bed of
non-heat-conducting material, such as ashes, charred bone, asbestos fiber, lime,
sand or fire clay. It should be well covered with the heat retaining material
and allowed to remain until cool. Cooling may be accomplished by allowing the
fire in an oven or furnace to die down and go out, leaving the work inside the
oven with all openings closed. The greater the time taken for gradual cooling
from the red heat, the more perfect will be the results of the annealing.
While steel is annealed by slow cooling, copper or brass is annealed by bringing
to a low red heat and quickly plunging into cold water.
Hardening.--Steel is hardened by bringing to a proper temperature, slowly and
evenly as for annealing, and then cooling more or less quickly, according to the
grade of steel being handled. The degree of hardening is determined by the kind
of steel, the temperature from which the metal is cooled and the temperature and
nature of the bath into which it is plunged for cooling.
Steel to be hardened is often heated in the fire until at some heat around 600
to 700 degrees is reached, then placed in a heating bath of molten lead, heated
mercury, fused cyanate of potassium, etc., the heating bath itself being kept at
the proper temperature by fires acting on it. While these baths have the
advantage of heating the metal evenly and to exactly the temperature desired
throughout without any part becoming over or under heated, their disadvantages
consist of the fact that their materials and the fumes are poisonous in most all
cases, and if not poisonous, are extremely disagreeable.
The degree of heat that a piece of steel must be brought to in order that it may
be hardened depends on the percentage of carbon in the steel. The greater the
percentage of carbon, the lower the heat necessary to harden.
Image Figure 5.--Cooling the Test Bar for Hardening
To find the proper heat from which any steel must be cooled, a simple test may
be carried out provided a sample of the steel, about six inches long can be
secured. One end of this test bar should be heated almost to its melting point,
and held at this heat until the other end just turns red. Now cool the piece in
water by plunging it so that both ends enter at the same time (Figure 5), that
is, hold it parallel with the surface of the water when plunged in. This serves
the purpose of cooling each point along the bar from a different heat. When it
has cooled in the water remove the piece and break it at short intervals, about
1/2 inch, along its length. The point along the test bar which was cooled from
the best possible temperature will show a very fine smooth grain and the piece
cannot be cut by a file at this point. It will be necessary to remember the
exact color of that point when taken from the fire, making another test if
necessary, and heat all pieces of this same steel to this heat. It will be
necessary to have the cooling bath always at the same temperature, or the
results cannot be alike.
While steel to be hardened is usually cooled in water, many other liquids may be
used. If cooled in strong brine, the heat will be extracted much quicker, and
the degree of hardness will be greater. A still greater degree of hardness is
secured by cooling in a bath of mercury. Care should be used with the mercury
bath, as the fumes that arise are poisonous.
Should toughness be desired, without extreme hardness, the steel may be cooled
in a bath of lard oil, neatsfoot oil or fish oil. To secure a result between
water and oil, it is customary to place a thick layer of oil on top of water. In
cooling, the piece will pass through the oil first, thus avoiding the sudden
shock of the cold water, yet producing a degree of hardness almost as great as
if the oil were not used.
It will, of course, be necessary to make a separate test for each cooling medium
used. If the fracture of the test piece shows a coarse grain, the steel was too
hot at that point; if the fracture can be cut with a file, the metal was not hot
enough at that point.
When hardening carbon tool steel its heat should be brought to a cherry red, the
exact degree of heat depending on the amount of carbon and the test made, then
plunged into water and held there until all hissing sound and vibration ceases.
Brine may be used for this purpose; it is even better than plain water. As soon
as the hissing stops, remove the work from the water or brine and plunge in oil
for complete cooling.
Image Figure 6.--Cooling the Tool for Tempering
In hardening high-speed tool steel, or air hardening steels, the tool should be
handled as for carbon steel, except that after the body reaches a cherry red,
the cutting point must be quickly brought to a white heat, almost melting, so
that it seems ready for welding. Then cool in an oil bath or in a current of
cool air.
Hardening of copper, brass and bronze is accomplished by hammering or working
them while cold.
Tempering is the process of making steel tough after it has been hardened, so
that it will hold a cutting edge and resist cracking. Tempering makes the grain
finer and the metal stronger. It does not affect the hardness, but increases the
elastic limit and reduces the brittleness of the steel. In that tempering is
usually performed immediately after hardening, it might be considered as a
continuation of the former process.
The work or tool to be tempered is slowly heated to a cherry red and the cutting
end is then dipped into water to a depth of 1/2 to 3/4 inch above the point
(Figure 6). As soon as the point cools, still leaving the tool red above the
part in water, remove the work from the bath and quickly rub the end with a fine
emery cloth.
As the heat from the uncooled part gradually heats the point again, the color of
the polished portion changes rapidly. When a certain color is reached, the tool
should be completely immersed in the water until cold.
For lathe, planer, shaper and slotter tools, this color should be a light straw.
Reamers and taps should be cooled from an ordinary straw color.
Drills, punches and wood working tools should have a brown color.
Blue or light purple is right for cold chisels and screwdrivers.
Dark blue should be reached for springs and wood saws.
Darker colors than this, ranging through green and gray, denote that the piece
has reached its ordinary temper, that is, it is partially annealed.
After properly hardening a spring by dipping in lard or fish oil, it should be
held over a fire while still wet with the oil. The oil takes fire and burns off,
properly tempering the spring.
Remember that self-hardening steels must never be dipped in water, and always
remember for all work requiring degrees of heat, that the more carbon, the less
heat.
Case Hardening.--This is a process for adding more carbon to the surface of a
piece of steel, so that it will have good wear-resisting qualities, while being
tough and strong on the inside. It has the effect of forming a very hard and
durable skin on the surface of soft steel, leaving the inside unaffected.
The simplest way, although not the most efficient, is to heat the piece to be
case hardened to a red heat and then sprinkle or rub the part of the surface to
be hardened with potassium ferro-cyanide. This material is a deadly poison and
should be handled with care. Allow the cyanide to fuse on the surface of the
metal and then plunge into water, brine or mercury. Repeating the process makes
the surface harder and the hard skin deeper each time.
Another method consists of placing the piece to be hardened in a bed of powdered
bone (bone which has been burned and then powdered) and cover with more powdered
bone, holding the whole in an iron tray. Now heat the tray and bone with the
work in an oven to a bright red heat for 30 minutes to an hour and then plunge
the work into water or brine.
As you can see from the preface and the first chapter above, this e-book is very well written, with expert knowledge revealed inside it. The nine chapters reveal pure expert knowledge in 92 pages. You can get this e-book with Private Label Rights, together with more than 1000 other products, when you join our Career Builders Club as a Pro Member. Click the image below to see the sales page. Join here. You can also buy this manual right now by going to the sales page here.
