WRI

1
INTRODUCTION TO WELDING
PROCESSES
6/16/2012
JOINING OF MATERIALS
AN INTRODUCTION
1. Requirements of a weld
2. Welding processes
3. Metallurgy of materials to be joined
4. Welding symbols
5. Welding instruction
6. Welding economics –Total Welding Management (TWM)
7. Welding standards
8. Welding inspection
9. Health & safety
6/16/2012
3
definition
 Welding – A joining process of two materials, metals/non-
metals, that coalesced by the application of pressure
and/or temperature.
 Welding – Local coalescence of two similar or dissimilar
metallic parts at their faying surfaces.
 Weldment – The assemblage of two or more elements
 Sometime a filler material is needed to facilitate
coalescence in Arc/Fusion welding process.
 Autogenous welding – without filler materials
Dr G Buvanashekaran, WRI 6/16/2012

Classification of welding processes
4 Welding
Soldering and brazing
Solid state welding Fusion welding

Resistance welding Soldering
Cold welding Brazing
Friction welding
Diffusion welding Electrical energy Chemical energy
Flash welding Oxyacetylene welding
Ultrasonic welding Oxyfuel gas welding
Explosion welding
Non
Consumable consumable Other processes
Gas metal arc welding electrode electrode
Shielded metal arc welding
Gas tungsten arc welding Laser beam welding
Submerged arc welding
Atomic hydrogen welding Thermit welding
Flux cored arc welding
Plasma arc welding Electron beam welding
Electrogas welding
Electroslag welding

Requirements of a weld
5
Butt joint
Weld
Interface
Reinforcement
Fusion zone
HAZ
BM
 Fusion zone: a mixture of filler metal and base metal

melted together homogeneously due to convection as in
casting. Epitaxial grain growth (casting)
 Weld interface – a narrow boundary immediately
solidified after melting.
 Heat Affected Zone (HAZ) – below melting but substantial
microstructural changeDr in the base material (heat treating)
G Buvanashekaran, WRI 6/16/2012
6
Fillet weld
Mehod of measuring

7
Types of joints
 Butt joint
 Corner joint
 Lap joint
 Tee joint
 Edge joint

8
Types of Welds
 Fillet weld
 Groove weld
 Plug and slot welds
 Spot and Seam welds
 Flange and Surfacing welds

Metallurgy of materials to be joined
9
Physics of welding
 Coalescing Mechanism: Fusion via high-density energy
 More time is needed for a lower power density process, more
so due to the conduction.
 For metallurgical reason, high energy over small area is better.
 Process Choice
 The rate at which welding can be performed
 The size of the area to be melted
 Power Density for Fusion Welding

Metallurgy of materials to be joined
10
Physics of welding
P
 Powder density (PD in W/mm2) PD
A
 In reality, Pre & post-heating are nonuniform
 For metallurgical reason, less energy and high
heat density are desired.
 Heat input = (I x U)/S = VAs/cm = J/cm
• Heat Utilisation:
1. Heat waste between heat source and surface (heat
transfer efficiency, f1) and
2. Conduction (melting efficiency, f2)
Modes of Welding
Weld Bead Geometries
Conduction Mode Cond+Penet. Mode Penetration Mode
102 w/cm2 104 w/cm2 105 w/cm2
11 Dr G Buvanashekaran, WRI 6/16/2012

Welding processes
Shielded Metal Arc Welding (SMAW)

Welding processes
13
Arc Welding – Shielded Metal Arc Welding (SMAW)

 A fusion welding where the coalescence of the metals
(base metals as well as filler) is achieved by the heat
from electric arc.
 Productivity: Arc time AC or DC
power
source
 Technical issues
 Electrodes – consumable and non-consumable electrodes
 Arc Shielding – To shield the arc from the surrounding
gas. Helium and argon are typically used. Flux does a
similar function.
 Power source – dc for all metals or ac for typically steels
 Heat loss due to convection, conduction and radiation

Welding processes
14
Shielded Metal Arc Welding (SMAW)

 A consumable electrode – a filler
metal rod coated with chemicals for
flux and shielding (230-460mm
long and 2.5-9.4mm in diameter)
 The filler metal must be comparable
with base metals.
 Current: 30-300A and Voltage: 15-
45V
 Cheaper and portable than oxy-
fuel welding
 Less efficient and variation in
current due to the change in length
of consumable electrodes during the
process. Dr G Buvanashekaran, WRI 6/16/2012
Welding processes
MIG diagram
Gas Metal Arc Welding (GMAW)

Welding processes
16
Gas Metal Arc Welding

Heat is produced by an electric arc
between the continuously fed metal
electrode and the base metal. Both the
base metal and the filler are melt. The
weld area is protected by inert shield
gases.
Weldable metals:
-steel carbon
- steel low-alloy
- steel stainless
- aluminum
- copper and its alloys
- nickel and its alloys
- magnesium
- reactive metal (titanium,
Characteristics of the weld joint by GMAW zirconium, tantalum)

Welding processes
17
Gas Metal Arc Welding
 Use a bare consumable

electrode
 Flooding the arc with a
gas which depends on the
metal
 No slag build-up and
higher deposition rate than
SMAW
 Metal Inert Gas (MIG) or
CO2 welding
Welding processes
18
Flux-Cored Arc Welding (FCAW)

 Use a continuous consumable tube with
flux and others such as deoxidizer and
alloying elements
 Two types
 Self-shielded – flux has an
ingredient for shielding
 Gas-shielded – external gas
 Produce high quality weld joint

Welding processes
19
Electro-Gas Welding (EGW)
 Flux-cored or bare electrode

with external shield gas and
water-cooled molding shoes
 Longitudinal and circumferential
joints.
 Thickness up to 40mm
 Used in Power plant component
manufacture and shipbuilding
applications

Welding processes
Submerged Arc Welding-SAW
Wire feeding nozzle
Flux recovery Flux delivery
Wire feeding nozzle
Slag layer
Flux shield layer
Flux
Slag layer
Flux
Schematic of SAW

Welding processes
21
Submerged Arc Welding -SAW

Thickness range:
3mm to any thickness
Power supply:
AC, DC
DC e+: Welding
DC e- : Surfacing
Shielding:Granular flux
Applications:
Large & Heavy structures

Welding processes
Principle - TIG process
In TIG welding an arc is formed between a nonconsumable tungsten electrode and the
metal being welded. Gas is fed through the torch to shield the electrode and molten
weldpool. If filler wire is used, it is added to the weld pool separately.

Welding processes
23
Gas Tungsten Arc Welding (GTAW)
TIG welding of
titanium pipe with
trailing shield
Trail shielding
With or without a filler metal; Tungsten melts at 3410 C

Shielding gas: argon, helium or a mixture
All metals (commonly Al and Stainless steels) in a wide range of thickness
Slow and costly but high quality weld for thin sections

Welding processes
24
Gas Tungsten Arc Welding (GTAW)
Limitations
 Requires greater welder dexterity than MIG or
stick welding
 Lower deposition rates
 more costly for welding thick
sections
Benefits
 Superior quality welds
 Welds can be made with or without filler metal
 Precise control of welding variables (heat)
 Free of spatter; Low distortion

Plasma Arc Welding
25
Plasma Arc Welding – a special form of GTAW but with a constricted

plasma gas to attain a higher temperature
Plasma TIG

Welding processes
Plasma Welding Advantages
 Constricted arc
 High power density
• Protected electrode allows for more welds before electrode

contamination
• Arc standoff distance not as critical as in TIG
• Gentle Arc Transfer
• Stable, stiffer arc reduces arc wander
• No high-frequency arc starting noise
• Extremely short duration welds possible for spot welding of wires,
needles, and micro components.
• Higher weld speeds possible in specific applications

Welding processes
27
Resistance Welding
 RW – heat and pressure to accomplish coalescence.
 Power source: heat generated H I 2 Rt Force
 Resistance Welding Processes + electrode
 Resistance spot welding
Weld nugget
 Electrodes – Cu-based or refractory(Cu+W)
 Rocker-arm spot welders
- electrode
 Resistance seam welding
 Resistance projection welding (RPW)
 Flash welding (FW) – butt joint

Force
 Upset welding – similar to FW but pressed during heating and upsetting.
 Percussion welding – similar to FW but shorter duration
 High-frequency (induction and resistance) welding

Resistance welding
28
process
SPOT Upset
Projection
Flash butt
SEAM
Welding processes
29
Spot Welding Cycle
(1) (5)
(2) (3) (4)
Force, Current
Force
Current
(1) (2) (3) (5) time

(4)
Welding processes
Spot welding machine Seam Welding machine
Bench Mounted
Spot Welder
Capacity: 3-30KVA
Pneumatically actuated with

Matching controls
Machine suitable for small

but
Precision job, more Capacity:
particularly 50 to 200 KVA
Electronic, switch gear
industries
Used for manufacture of drums and barrels,
fuel tanks, Silencer, muffler, shock absorber etc.

Welding processes
31
Oxy-fuel gas Welding
Outer Envelope (1260 C)

 Oxyfuel gas welding (OFW) – Use
various fuels mixed with oxygen
 Oxyacetylene welding – A mixture Acetylene feather
of acetylene and oxygen (2090 C)
Inner cone
(3480ºC)
 Total heat: 55x106J/m3

 Acetylene: odorless but commercial acetylene has a garlic order.
 Unstable at 1atm thus dissolved in acetone.

 Other gases : Hydrogen, Propylene, Propane and Natural gas

Welding processes
Oxy-Fuel Welding

Welding processes
33
Soldering or brazing
In these processes, only the filler metals which join the
two pieces to be welded are melted and not the base
metal. The braze metals have higher melting
temperatures than the solder metals.
Filler metal: brass or solder
Base metal
Characteristics of a brazed or soldered joint

Other Fusion Welding
34 Electron beam Welding
 High focused high-intensity stream of electrons
 Power density and Multiple degrees of
vacuum
Beam of electrons are generated applying

a very high voltage in the order of kilovolts
in between an anode and a filament. The
beam, i.e, the flow of electrons are
focused using a magnetic focusing coil so
that the energy is constricted in a very
narrow area. Since the welding is carried
out in vacuum at higher speeds, there is
no need of any heat treatment operations
and the stress levels are pretty low

Electron beam Welding
Applications of EBW
Turbo charger
Precombustion
Wheel
chamber
Cardiac Gas
pacemakers turbine

36
Laser Beam Welding
 Laser beam Welding – no filler metal
 Highquality, and narrow heat affected zone.
 No vacuum chamber but no deep weld (small part)
Laser medium Laser output
Mirror Mirror
(100% reflective) (partially transparent)
Excitation
source
Laser beam welding Application

Laser Beam Welding
Applications
2kwatt solid state laser facility at WRI
3mm OD SS tube 0f 0.5mm thick
Temperature
transducer
Dissimilar thickness joint – SS to coated steel
Pressure Transducer

Welding processes
39
Solid-State Welding
 No filler metals but w/o local melting with either pressure-alone or heat and
pressure.
 Intimate contact is necessary by a through cleaning or other means.
 Solid-state Welding Processes
 Forge welding – Samurai sword
 Cold welding – high pressure
 Roll welding
 Hot-pressure welding
 Diffusion welding at 0.5Tm
 Explosive welding – mechanical locking
 Friction welding – friction to heat
 Ultrasonic welding – oscillatory shear stresses of ultrasonic

Solid-State Welding

Solid-State Welding
Diffusion bonding

Welding processes
Resistance Welding- Flash butt
Rail Flash butt welder Boiler tubing

Capacity: 650KVA, DC Capacity: 50 to 250KVA

Magnetically Impelled Arc Welding (MIAB)
Basic Principle

Solid-State Welding
Friction welding

Friction welding
45
process stages

FRICTION STIR WELDING
Load
ADVANCING LEADING
EDGE OF
END OF WELD TOOL
SHOULDER
SUBMERGED
PIN
PIN REAR WELD

FRICTION STIR WELDING
Suitable for Aluminium,

copper
Application: Al bus duct
Research towards friction

stir welding of steel
Friction stir welding of aluminium alloy

Explosive welding
48

Weld Quality
49
 Residual Stress and Distortion

 Welding fixtures, Heat sink,Tack welding, control weld condition, Preheating, Stress-
relief heat treatment, Proper design
 Welding Defects
 Cracks, Cavities, Solid Inclusions, Incomplete Fusion
 Imperfect shape, Miscellaneous Defects such as arc strike and excessive spatter.
 Inspection and testing
 Visual Inspection – dimensional, warpage, crack
 Nondestructive – dye- and fluorescent-penetrant, Magnetic particle testing, Ultrasonic
and radiograph
 Destructive – mechanical & metallurgical tests

50
Design Considerations
 Design for welding
 Minimum parts
 Arc Welding
 Good fit-up of parts
 Access room for welding
 Flat welding is advised
 Spot welding
 Low carbon steel up to 3.2mm
 For large components: reinforcing part or flanges
 Access room for welding
 Overlap is required

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1

Dr G Buvanashekaran, WRI 6/16/2012

Solid state welding Fusion welding

Dr G Buvanashekaran, WRI 6/16/2012

 Fusion zone: a mixture of filler metal and base metal

Dr G Buvanashekaran, WRI 6/16/2012

Dr G Buvanashekaran, WRI 6/16/2012

 Plug and slot welds

 Spot and Seam welds

 Flange and Surfacing welds

Dr G Buvanashekaran, WRI 6/16/2012

Dr G Buvanashekaran, WRI 6/16/2012

Conduction Mode Cond+Penet. Mode Penetration Mode

102 w/cm2 104 w/cm2 105 w/cm2

11 Dr G Buvanashekaran, WRI 6/16/2012

Shielded Metal Arc Welding (SMAW)

Arc Welding – Shielded Metal Arc Welding (SMAW)

 Heat loss due to convection, conduction and radiation

Shielded Metal Arc Welding (SMAW)

Gas Metal Arc Welding (GMAW)

Gas Metal Arc Welding

Dr G Buvanashekaran, WRI 6/16/2012

Gas Metal Arc Welding

 Use a bare consumable

Flux-Cored Arc Welding (FCAW)

Dr G Buvanashekaran, WRI 6/16/2012

Electro-Gas Welding (EGW)

 Flux-cored or bare electrode

Dr G Buvanashekaran, WRI 6/16/2012

Wire feeding nozzle

20 Dr G Buvanashekaran, WRI 6/16/2012

Submerged Arc Welding -SAW

Dr G Buvanashekaran, WRI 6/16/2012

22 Dr G Buvanashekaran, WRI 6/16/2012

Gas Tungsten Arc Welding (GTAW)

With or without a filler metal; Tungsten melts at 3410 C

Dr G Buvanashekaran, WRI 6/16/2012

Gas Tungsten Arc Welding (GTAW)

Dr G Buvanashekaran, WRI 6/16/2012

Plasma Arc Welding – a special form of GTAW but with a constricted

Dr G Buvanashekaran, WRI 6/16/2012

• Protected electrode allows for more welds before electrode

26 Dr G Buvanashekaran, WRI 6/16/2012

 Resistance projection welding (RPW)

 Flash welding (FW) – butt joint

Dr G Buvanashekaran, WRI 6/16/2012

Spot Welding Cycle

(1) (2) (3) (5) time

Pneumatically actuated with

Machine suitable for small

30 Dr G Buvanashekaran, WRI 6/16/2012

Oxy-fuel gas Welding

Outer Envelope (1260 C)

 Total heat: 55x106J/m3

 Unstable at 1atm thus dissolved in acetone.

Dr G Buvanashekaran, WRI 6/16/2012

32 Dr G Buvanashekaran, WRI 6/16/2012

Characteristics of a brazed or soldered joint

Beam of electrons are generated applying