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Welding
Process
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Abstract:
The welding processes, in their official groupings. The letter
designation assigned to the process can be used for identification
on drawings, tables, etc. Allied and related processes include
adhesive bonding, thermal spraying, and thermal cutting. Capillary
attraction distinguishes the welding processes grouped under
"Brazing" and "Soldering" from "Arc Welding", "Gas Welding",
"Resistance Welding", "Solid State Welding", and "Other Processes."
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The American Welding Society has made each welding process definition
as complete as possible so that it will suffice without reference
to another definition. They define a process as "a distinctive progressive
action or series of actions involved in the course of producing
a basic type of result".
The official listing of processes and their grouping is shown by
Figure 1., the AWS Master Chart of Welding and Allied Processes.
The welding society formulated process definitions from the operational
instead of the metallurgical point of view. Thus the definitions
prescribe the significant elements of operation instead of the significant
metallurgical characteristics.
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| Figure
1. AWS master chart of welding and allied processes. |
The
AWS definition for a welding process is "a materials joining process
which produces coalescence of materials by heating them to suitable
temperatures with or without the application of pressure or by the
application of pressure alone and with or without the use of filler
material".
AWS has grouped the processes together according to the "mode of
energy transfer" as the primary consideration. A secondary factor
is the "influence of capillary attraction in effecting distribution
of filler metal" in the joint. Capillary attraction distinguishes
the welding processes grouped under "Brazing" and "Soldering" from
"Arc Welding", "Gas Welding", "Resistance Welding", "Solid State
Welding", and "Other Processes."
The welding processes, in their official groupings, are shown by
Table 1. This table also shows the letter designation for
each process. The letter designation assigned to the process can
be used for identification on drawings, tables, etc. Allied and
related processes include adhesive bonding, thermal spraying, and
thermal cutting.
| Table
1. Welding processes and letter designation. |
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Group |
Welding Process |
Letter Designation |
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Arc welding |
Carbon Arc |
CAW |
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Flux Cored Arc |
FCAW |
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Gas Metal Arc |
GMAW |
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Gas Tungsten Arc |
GTAW |
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Plasma Arc |
PAW |
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Shielded Metal Arc |
SMAW |
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Stud Arc |
SW |
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Submerged Arc |
SAW |
|
Brazing |
Diffusion Brazing |
DFB |
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Dip Brazing |
DB |
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Furnace Brazing |
FB |
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Induction Brazing |
IB |
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Infrared Brazing |
IRB |
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Resistance Brazing |
RB |
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Torch Brazing |
TB |
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Oxyfuel Gas Welding |
Oxyacetylene Welding |
OAW |
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Oxyhydrogen Welding |
OHW |
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Pressure Gas Welding |
PGW |
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Resistance Welding |
Flash Welding |
FW |
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High Frequency Resistance |
HFRW |
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Percussion Welding |
PEW |
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Projection Welding |
RPW |
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Resistance-Seam Welding |
RSEW |
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Resistance-Spot Welding |
RSW |
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Upset Welding |
UW |
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Solid State Welding |
Cold Welding |
CW |
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Diffusion Welding |
DFW |
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Explosion Welding |
EXW |
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Forge Welding |
FOW |
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Friction Welding |
FRW |
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Hot Pressure Welding |
HPW |
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Roll Welding |
ROW |
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Ultrasonic Welding |
USW |
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Soldering |
Dip Soldering |
DS |
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Furnace Soldering |
FS |
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Induction Soldering |
IS |
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Infrared Soldering |
IRS |
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Iron Soldering |
INS |
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Resistance Soldering |
RS |
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Torch Soldering |
TS |
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Wave Soldering |
WS |
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Other Welding Processes |
Electron Beam |
EBW |
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Electroslag |
ESW |
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Induction |
IW |
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Laser Beam |
LBW |
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Thermit |
TW |
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Arc Welding
The
arc welding group includes eight specific processes, each separate
and different from the others but in many respects similar.
The carbon arc welding (CAW) process is the oldest of all
the arc welding processes and is considered to be the beginning
of arc welding. The Welding Society defines carbon arc welding as
"an arc welding process which produces coalescence of metals by
heating them with an arc between a carbon electrode and the work-piece.
No shielding is used. Pressure and filler metal may or may not be
used." It has limited applications today, but a variation or twin
carbon arc welding is more popular. Another variation uses compressed
air for cutting.
The development of the metal arc welding process soon followed the
carbon arc. This developed into the currently popular shielded
metal arc welding (SMAW) process defined as "an arc welding
process which produces coalescence of metals by heating them with
an arc between a covered metal electrode and the work-piece. Shielding
is obtained from decomposition of the electrode covering. Pressure
is not used and filler metal is obtained from the electrode."
Automatic welding utilizing bare electrode wires was used in the
1920s, but it was the submerged arc welding (SAW) process
that made automatic welding popular. Submerged arc welding is defined
as "an arc welding process which produces coalescence of metals
by heating them with an arc or arcs between a bare metal electrode
or electrodes and the work piece. Pressure is not used and filler
metal is obtained from the electrode and sometimes from a supplementary
welding rod." It is normally limited to the flat or horizontal position.
The need to weld nonferrous metals, particularly magnesium and aluminum,
challenged the industry. A solution was found called gas tungsten
arc welding (GTAW) [also known as tungsten inert gas (TIG) welding]
and was defined as "an arc welding process which produces coalescence
of metals by heating them with an arc between a tungsten (non-consumable)
electrode and the work piece. Shielding is obtained from a gas or
gas mixture."
Plasma
arc welding (PAW) is defined as "an arc welding process which
produces a coalescence of metals by heating them with a constricted
arc between an electrode and the work piece (transferred arc) or
the electrode and the constricting nozzle (non-transferred arc).
Shielding is obtained from the hot ionized gas issuing from the
orifice which may be supplemented by an auxiliary source of shielding
gas." Shielding gas may be an inert gas or a mixture of gases. Plasma
welding has been used for joining some of the thinner materials.
Another welding process also related to gas tungsten arc welding
is known as gas metal arc welding (GMAW). It was developed
in the late 1940s for welding aluminum and has become extremely
popular. It is defined as "an arc welding process which produces
coalescence of metals by heating them with an arc between a continuous
filler metal (consumable) electrode and the work piece. Shielding
is obtained entirely from an externally supplied gas or gas mixture."
The electrode wire for GMAW is continuously fed into the arc and
deposited as weld metal. This process has many variations depending
on the type of shielding gas, the type of metal transfer, and the
type of metal welded.
A variation of gas metal arc welding has become a distinct welding
process and is known as flux-cored arc welding (FCAW). It
is defined as "an arc welding process which produces coalescence
of metals by heating them with an arc between a continuous filler
metal (consumable) electrode and the work piece. Shielding is provided
by a flux contained within the tubular electrode." Additional shielding
may or may not be obtained from an externally supplied gas or gas
mixture.
The final process within the arc welding group of processes is known
as stud arc welding (SW). This process is defined as "an
arc welding process which produces coalescence of metals by heating
them with an arc between a metal stud or similar part and the work
piece". When the surfaces to be joined are properly heated they
are brought together under pressure. Partial shielding may be obtained
by the use of ceramic ferrule surrounding the stud.
Brazing (B)
Brazing
is "a group of welding processes which produces coalescence of materials
by heating them to a suitable temperature and by using a filler
metal, having a liquidus above 450oC and below the solidus
of the base materials. The filler metal is distributed between the
closely fitted surfaces of the joint by capillary attraction."
A braze is a very special form of weld, the base metal is theoretically
not melted. There are seven popular different processes within the
brazing group. The source of heat differs among the processes. Braze
welding relates to welding processes using brass or bronze filler
metal, where the filler metal is not distributed by capillary action.
Oxy Fuel Gas Welding (OFW)
Oxy
fuel gas welding is "a group of welding processes which produces
coalescence by heating materials with an oxy fuel gas flame or flames
with or without the application of pressure and with or without
the use of filler metal."
There are four distinct processes within this group and in the case
of two of them, oxyacetylene welding and oxyhydrogen welding,
the classification is based on the fuel gas used. The heat of the
flame is created by the chemical reaction or the burning of the
gases. In the third process, air acetylene welding, air is
used instead of oxygen, and in the fourth category, pressure
gas welding, pressure is applied in addition to the heat from
the burning of the gases. This welding process normally utilizes
acetylene as the fuel gas. The oxygen thermal cutting processes
have much in common with this welding processes.
Resistance Welding (RW)
Resistance
welding is "a group of welding processes which produces coalescence
of metals with the heat obtained from resistance of the work to
electric current in a circuit of which the work is a part, and by
the application of pressure". In general, the difference among the
resistance welding processes has to do with the design of the weld
and the type of machine necessary to produce the weld. In almost
all cases the processes are applied automatically since the welding
machines incorporate both electrical and mechanical functions.
Other Welding Processes
This
group of processes includes those, which are not best defined under
the other groupings. It consists of the following processes: electron
beam welding, laser beam welding, thermit welding, and other miscellaneous
welding processes in addition to electroslag welding
which was mentioned previously.
Soldering (S)
Soldering
is "a group of joining processes which produces coalescence of materials
by heating them to a suitable temperature and by using a filler
metal having a liquidus not exceeding 450 oC (840 oF)
and below the solidus of the base materials. The filler metal is
distributed between the closely fitted surfaces of the joint by
capillary attraction." There are a number of different soldering
processes and methods.
Solid State Welding (SSW)
Solid
state welding is "a group of welding processes which produces coalescence
at temperatures essentially below the melting point of the base
materials being joined without the addition of a brazing filler
metal. Pressure may or may not be used."
The oldest of all welding processes forge welding belongs
to this group. Others include cold welding, diffusion welding,
explosion welding, friction welding, hot pressure welding, and
ultrasonic welding. These processes are all different and
utilize different forms of energy for making welds.
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