Metal Joining Process

WELDING PROCESSES
1. Arc Welding
2. Resistance Welding
3. Oxyfuel Gas Welding
4. Other Fusion Welding Processes
5. Solid State Welding
6. Weld Quality
7. Weldability

Two Categories of Welding Processes
 Fusion welding - coalescence is accomplished
by melting the two parts to be joined, in some
cases adding filler metal to the joint
 Examples: arc welding, resistance spot
welding, oxyfuel gas welding
 Solid state welding - heat and/or pressure are
used to achieve coalescence, but no melting of
base metals occurs and no filler metal is added
 Examples: forge welding, diffusion welding,
friction welding

Arc Welding (AW)
A fusion welding process in which coalescence of
the metals is achieved by the heat from an
electric arc between an electrode and the work
 Electric energy from the arc produces
temperatures ~ 10,000 F (5500 C), hot enough
to melt any metal
 Most AW processes add filler metal to increase
volume and strength of weld joint

What is an Electric Arc?
An electric arc is a discharge of electric current
across a gap in a circuit
 It is sustained by an ionized column of gas
(plasma) through which the current flows
 To initiate the arc in AW, electrode is brought
into contact with work and then quickly
separated from it by a short distance

A pool of molten metal is formed near electrode
tip, and as electrode is moved along joint,
molten weld pool solidifies in its wake
Figure 31.1 Basic configuration of an arc welding process.
Arc Welding

Two Basic Types of AW Electrodes
 Consumable – consumed during welding
process
 Source of filler metal in arc welding
 Nonconsumable – not consumed during
welding process
 Filler metal must be added separately

Consumable Electrodes
 Forms of consumable electrodes
 Welding rods (a.k.a. sticks) are 9 to 18
inches and 3/8 inch or less in diameter and
must be changed frequently
 Weld wire can be continuously fed from
spools with long lengths of wire, avoiding
frequent interruptions
 In both rod and wire forms, electrode is
consumed by arc and added to weld joint as
filler metal

Nonconsumable Electrodes
 Made of tungsten which resists melting
 Gradually depleted during welding
(vaporization is principal mechanism)
 Any filler metal must be supplied by a separate
wire fed into weld pool

Arc Shielding
 At high temperatures in AW, metals are
chemically reactive to oxygen, nitrogen, and
hydrogen in air
 Mechanical properties of joint can be
seriously degraded by these reactions
 To protect operation, arc must be shielded
from surrounding air in AW processes
 Arc shielding is accomplished by:
 Shielding gases, e.g., argon, helium, CO2
 Flux

Flux
A substance that prevents formation of oxides
and other contaminants in welding, or dissolves
them and facilitates removal
 Provides protective atmosphere for welding
 Stabilizes arc
 Reduces spatter

Various Flux Application Methods
 Pouring granular flux onto welding operation
 Stick electrode coated with flux material that
melts during welding to cover operation
 Tubular electrodes in which flux is contained in
the core and released as electrode is
consumed

Power Source in Arc Welding
 Direct current (DC) vs. Alternating current (AC)
 AC machines less expensive to purchase
and operate, but generally restricted to
ferrous metals
 DC equipment can be used on all metals
and is generally noted for better arc control

Consumable Electrode AW Processes
 Shielded Metal Arc Welding
 Gas Metal Arc Welding
 Flux Cored Arc Welding‑
 Electrogas Welding
 Submerged Arc Welding

Shielded Metal Arc Welding (SMAW)
Uses a consumable electrode consisting of a filler
metal rod coated with chemicals that provide
flux and shielding
 Sometimes called "stick welding"
 Power supply, connecting cables, and
electrode holder available for a few thousand
dollars

Figure 31.3 Shielded metal arc welding (SMAW).
Shielded Metal Arc Welding

Figure 31.2 Shielded
metal arc welding (stick
welding) performed by a
(human) welder (photo
courtesy of Hobart
Brothers Co.).
Shielded Metal Arc Welding

SMAW Applications
 Used for steels, stainless steels, cast
irons, and certain nonferrous alloys
 Not used or rarely used for aluminum
and its alloys, copper alloys, and
titanium

Gas Metal Arc Welding (GMAW)
Uses a consumable bare metal wire as
electrode and shielding accomplished by
flooding arc with a gas
 Wire is fed continuously and automatically
from a spool through the welding gun
 Shielding gases include inert gases such as
argon and helium for aluminum welding, and
active gases such as CO2 for steel welding
 Bare electrode wire plus shielding gases
eliminate slag on weld bead - no need for
manual grinding and cleaning of slag

Figure 31.4 Gas metal arc welding (GMAW).
Gas Metal Arc Welding

GMAW Advantages over SMAW
 Better arc time because of continuous wire
electrode
 Sticks must be periodically changed in
SMAW
 Better use of electrode filler metal than SMAW
 End of stick cannot be used in SMAW
 Higher deposition rates
 Eliminates problem of slag removal
 Can be readily automated

Flux Cored Arc Welding (FCAW)‑
Adaptation of shielded metal arc welding, to
overcome limitations of stick electrodes
 Electrode is a continuous consumable tubing
(in coils) containing flux and other ingredients
(e.g., alloying elements) in its core
 Two versions:
 Self shielded FCAW - core includes‑
compounds that produce shielding gases
 Gas shielded FCAW - uses externally‑
applied shielding gases

Figure 31.6 Flux cored arc welding. Presence or absence of externally‑
supplied shielding gas distinguishes the two types: (1) self shielded,‑
in which core provides ingredients for shielding, and (2) gas shielded,‑
which uses external shielding gases.
Flux-Cored Arc Welding

Electrogas Welding (EGW)
Uses a continuous consumable electrode, either
flux cored wire or bare wire with externally‑
supplied shielding gases, and molding shoes to
contain molten metal
 When flux cored electrode wire is used and no‑
external gases are supplied, then special case
of self shielded FCAW‑
 When a bare electrode wire used with shielding
gases from external source, then special case
of GMAW

Figure 31.7 Electrogas welding using flux cored electrode wire:‑
(a) front view with molding shoe removed for clarity, and (b)
side view showing molding shoes on both sides.
Electrogas Welding

Submerged Arc Welding (SAW)
Uses a continuous, consumable bare wire
electrode, with arc shielding provided by a
cover of granular flux
 Electrode wire is fed automatically from a
coil
 Flux introduced into joint slightly ahead of arc
by gravity from a hopper
 Completely submerges operation,
preventing sparks, spatter, and radiation

Figure 31.8 Submerged arc welding.
Submerged Arc Welding

SAW Applications and Products
 Steel fabrication of structural shapes (e.g.,
I beams)‑
 Seams for large diameter pipes, tanks, and
pressure vessels
 Welded components for heavy machinery
 Most steels (except hi C steel)
 Not good for nonferrous metals

Non-consumable Electrode Processes
 Gas Tungsten Arc Welding
 Plasma Arc Welding
 Carbon Arc Welding
 Stud Welding

Gas Tungsten Arc Welding (GTAW)
Uses a non-consumable tungsten electrode
and an inert gas for arc shielding
 Melting point of tungsten = 3410°C (6170°F)
 A.k.a. Tungsten Inert Gas (TIG) welding
 In Europe, called "WIG welding"
 Used with or without a filler metal
 When filler metal used, it is added to
weld pool from separate rod or wire
 Applications: aluminum and stainless steel
most common

Figure 31.9 Gas tungsten arc welding.
Gas Tungsten Arc Welding

Advantages / Disadvantages of GTAW
Advantages:
 High quality welds for suitable applications
 No spatter because no filler metal through
arc
 Little or no post-weld cleaning because no
flux
Disadvantages:
 Generally slower and more costly than
consumable electrode AW processes

Plasma Arc Welding (PAW)
Special form of GTAW in which a constricted
plasma arc is directed at weld area
 Tungsten electrode is contained in a nozzle
that focuses a high velocity stream of inert gas
(argon) into arc region to form a high velocity,
intensely hot plasma arc stream
 Temperatures in PAW reach 28,000°C
(50,000°F), due to constriction of arc,
producing a plasma jet of small diameter and
very high energy density

Figure 31.10 Plasma arc welding (PAW).
Plasma Arc Welding

Advantages / Disadvantages of PAW
Advantages:
 Good arc stability
 Better penetration control than other AW
 High travel speeds
 Excellent weld quality
 Can be used to weld almost any metals
Disadvantages:
 High equipment cost
 Larger torch size than other AW
 Tends to restrict access in some joints

Resistance Welding (RW)
A group of fusion welding processes that use a
combination of heat and pressure to
accomplish coalescence
 Heat generated by electrical resistance to
current flow at junction to be welded
 Principal RW process is resistance spot
welding (RSW)

Figure 31.12 Resistance
welding, showing the
components in spot
welding, the main
process in the RW
group.
Resistance Welding

Components in Resistance Spot Welding
 Parts to be welded (usually sheet metal)
 Two opposing electrodes
 Means of applying pressure to squeeze parts
between electrodes
 Power supply from which a controlled current
can be applied for a specified time duration

Advantages / Drawbacks of RW
Advantages:
 No filler metal required
 High production rates possible
 Lends itself to mechanization and automation
 Lower operator skill level than for arc welding
 Good repeatability and reliability
Disadvantages:
 High initial equipment cost
 Limited to lap joints for most RW processes

Resistance Spot Welding (RSW)
Resistance welding process in which fusion of
faying surfaces of a lap joint is achieved at one
location by opposing electrodes
 Used to join sheet metal parts using a series of
spot welds
 Widely used in mass production of
automobiles, appliances, metal furniture, and
other products made of sheet metal
 Typical car body has ~ 10,000 spot welds
 Annual production of automobiles in the
world is measured in tens of millions of units

Figure 31.13 (a) Spot welding cycle, (b) plot of squeezing force & current
in cycle (1) parts inserted between electrodes, (2) electrodes close,
force applied, (3) current on, (4) current off, (5) electrodes opened.
Spot Welding Cycle

Resistance Seam Welding (RSEW)
Uses rotating wheel electrodes to produce a
series of overlapping spot welds along lap
joint
 Can produce air tight joints‑
 Applications:
 Gasoline tanks
 Automobile mufflers
 Various other sheet metal containers

Figure 31.15 Resistance seam welding (RSEW).
Resistance Seam Welding

Resistance Projection Welding (RPW)
A resistance welding process in which
coalescence occurs at one or more small
contact points on parts
 Contact points determined by design of parts to
be joined
 May consist of projections, embossments,
or localized intersections of parts

Figure 31.17 Resistance projection welding (RPW): (1) start of operation,
contact between parts is at projections; (2) when current is applied,
weld nuggets similar to spot welding are formed at the projections.
Resistance Projection Welding

Oxyfuel Gas Welding (OFW)
Group of fusion welding operations that burn
various fuels mixed with oxygen
 OFW employs several types of gases, which is
the primary distinction among the members of
this group
 Oxyfuel gas is also used in flame cutting
torches to cut and separate metal plates and
other parts
 Most important OFW process is oxyacetylene
welding

Oxyacetylene Welding (OAW)
Fusion welding performed by a high temperature
flame from combustion of acetylene and
oxygen
 Flame is directed by a welding torch
 Filler metal is sometimes added
 Composition must be similar to base metal
 Filler rod often coated with flux to clean
surfaces and prevent oxidation

Figure 31.21 A typical oxyacetylene welding operation (OAW).
Oxyacetylene Welding

Acetylene (C2H2)
 Most popular fuel among OFW group because
it is capable of higher temperatures than any
other up to 3480‑ °C (6300°F)
 Two stage chemical reaction of acetylene and
oxygen:
 First stage reaction (inner cone of flame):
C2H2 + O2 → 2CO + H2 + heat
 Second stage reaction (outer envelope):
2CO + H2 + 1.5O2 → 2CO2 + H2O + heat

 Maximum temperature reached at tip of inner
cone, while outer envelope spreads out and
shields work surfaces from atmosphere
Figure 31.22 The neutral flame from an oxyacetylene torch
indicating temperatures achieved.
Oxyacetylene Torch

Alternative Gases for OFW
 Methylacetylene Propadiene (MAPP)‑
 Hydrogen
 Propylene
 Propane
 Natural Gas

Other Fusion Welding Processes
FW processes that cannot be classified as arc,
resistance, or oxyfuel welding
 Use unique technologies to develop heat for
melting
 Applications are typically unique
 Processes include:
 Electron beam welding
 Laser beam welding
 Electroslag welding
 Thermit welding

Electron Beam Welding (EBW)
Fusion welding process in which heat for welding
is provided by a highly focused, high intensity‑ ‑
stream of electrons striking work surface
 Electron beam gun operates at:
 High voltage (e.g., 10 to 150 kV typical) to
accelerate electrons
 Beam currents are low (measured in
milliamps)
 Power in EBW not exceptional, but power
density is

EBW Advantages / Disadvantages
Advantages:
 High quality welds, deep and narrow profiles‑
 Limited heat affected zone, low thermal
distortion
 High welding speeds
 No flux or shielding gases needed
Disadvantages:
 High equipment cost
 Precise joint preparation & alignment required
 Vacuum chamber required
 Safety concern: EBW generates x rays‑

Laser Beam Welding (LBW)
Fusion welding process in which coalescence is
achieved by energy of a highly concentrated,
coherent light beam focused on joint
 Laser = "light amplification by stimulated
emission of radiation"
 LBW normally performed with shielding gases
to prevent oxidation
 Filler metal not usually added
 High power density in small area, so LBW often
used for small parts

Comparison: LBW vs. EBW
 No vacuum chamber required for LBW
 No x rays emitted in LBW‑
 Laser beams can be focused and directed by
optical lenses and mirrors
 LBW not capable of the deep welds and high
depth to width ratios of EBW‑ ‑
 Maximum LBW depth = ~ 19 mm (3/4 in),
whereas EBW depths = 50 mm (2 in)

Thermit Welding (TW)
FW process in which heat for coalescence is
produced by superheated molten metal from
the chemical reaction of thermite
 Thermite = mixture of Al and Fe3O4 fine
powders that produce an exothermic reaction
when ignited
 Also used for incendiary bombs
 Filler metal obtained from liquid metal
 Process used for joining, but has more in
common with casting than welding

Figure 31.25 Thermit welding: (1) Thermit ignited; (2) crucible
tapped, superheated metal flows into mold; (3) metal solidifies to
produce weld joint.
Thermit Welding

TW Applications
 Joining of railroad rails
 Repair of cracks in large steel castings and
forgings
 Weld surface is often smooth enough that no
finishing is required

Solid State Welding (SSW)
 Coalescence of part surfaces is achieved by:
 Pressure alone, or
 Heat and pressure
 If both heat and pressure are used, heat
is not enough to melt work surfaces
 For some SSW processes, time is also a
factor
 No filler metal is added
 Each SSW process has its own way of creating
a bond at the faying surfaces

Success Factors in SSW
 Essential factors for a successful solid state
weld are that the two faying surfaces must be:
 Very clean
 In very close physical contact with each
other to permit atomic bonding

SSW Advantages over FW Processes
 If no melting, then no heat affected zone, so
metal around joint retains original properties
 Many SSW processes produce welded joints
that bond the entire contact interface between
two parts rather than at distinct spots or seams
 Some SSW processes can be used to bond
dissimilar metals, without concerns about
relative melting points, thermal expansions,
and other problems that arise in FW

Solid State Welding Processes
 Forge welding
 Cold welding
 Roll welding
 Hot pressure welding
 Diffusion welding
 Explosion welding
 Friction welding
 Ultrasonic welding

Forge Welding
Welding process in which components to be
joined are heated to hot working temperature
range and then forged together by hammering
or similar means
 Historic significance in development of
manufacturing technology
 Process dates from about 1000 B.C., when
blacksmiths learned to weld two pieces of
metal
 Of minor commercial importance today except
for its variants

Roll Welding (ROW)
SSW process in which pressure sufficient to
cause coalescence is applied by means of
rolls, either with or without external heat
 Variation of either forge welding or cold
welding, depending on whether heating of
workparts is done prior to process
 If no external heat, called cold roll welding
 If heat is supplied, hot roll welding

Figure 31.26 Roll welding (ROW).
Roll Welding

Roll Welding Applications
 Cladding stainless steel to mild or low alloy
steel for corrosion resistance
 Bimetallic strips for measuring temperature
 "Sandwich" coins for U.S mint

Diffusion Welding (DFW)
SSW process uses heat and pressure, usually in
a controlled atmosphere, with sufficient time for
diffusion and coalescence to occur
 Temperatures ≤ 0.5 Tm
 Plastic deformation at surfaces is minimal
 Primary coalescence mechanism is solid state
diffusion
 Limitation: time required for diffusion can range
from seconds to hours

DFW Applications
 Joining of high strength and refractory metals‑
in aerospace and nuclear industries
 Can be used to join either similar and dissimilar
metals
 For joining dissimilar metals, a filler layer of
different metal is often sandwiched between
base metals to promote diffusion

Explosion Welding (EXW)
SSW process in which rapid coalescence of two
metallic surfaces is caused by the energy of a
detonated explosive
 No filler metal used
 No external heat applied
 No diffusion occurs - time is too short
 Bonding is metallurgical, combined with
mechanical interlocking that results from a
rippled or wavy interface between the metals

Commonly used to bond two dissimilar metals,
in particular to clad one metal on top of a
base metal over large areas
Figure 31.27 Explosive welding (EXW): (1) setup in the
parallel configuration, and (2) during detonation of the
explosive charge.
Explosive Welding

Friction Welding (FRW)
SSW process in which coalescence is achieved
by frictional heat combined with pressure
 When properly carried out, no melting occurs at
faying surfaces
 No filler metal, flux, or shielding gases normally
used
 Process yields a narrow HAZ
 Can be used to join dissimilar metals
 Widely used commercial process, amenable to
automation and mass production

Figure 31.28 Friction welding (FRW): (1) rotating part, no contact; (2)
parts brought into contact to generate friction heat; (3) rotation
stopped and axial pressure applied; and (4) weld created.
Friction Welding

Applications / Limitations of FRW
Applications:
 Shafts and tubular parts
 Industries: automotive, aircraft, farm
equipment, petroleum and natural gas
Limitations:
 At least one of the parts must be rotational
 Flash must usually be removed
 Upsetting reduces the part lengths (which must
be taken into consideration in product design)

Ultrasonic Welding (USW)
Two components are held together, oscillatory
shear stresses of ultrasonic frequency are
applied to interface to cause coalescence
 Oscillatory motion breaks down any surface
films to allow intimate contact and strong
metallurgical bonding between surfaces
 Although heating of surfaces occurs,
temperatures are well below Tm
 No filler metals, fluxes, or shielding gases
 Generally limited to lap joints on soft materials
such as aluminum and copper

Figure 31.29 Ultrasonic welding (USW): (a) general setup for
a lap joint; and (b) close up of weld area.‑
Ultrasonic Welding

USW Applications
 Wire terminations and splicing in electrical
and electronics industry
 Eliminates need for soldering
 Assembly of aluminum sheet metal panels
 Welding of tubes to sheets in solar panels
 Assembly of small parts in automotive
industry

Weldability
Capacity of a metal or combination of metals to
be welded into a suitably designed structure,
and for the resulting weld joint(s) to possess
the required metallurgical properties to perform
satisfactorily in intended service
 Good weldability characterized by:
 Ease with which welding process is
accomplished
 Absence of weld defects
 Acceptable strength, ductility, and
toughness in welded joint

Metal Joining Process

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