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Introduction to Materials Joining

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Arc Welding Processes Welding processes that employ an electric arc are the most prevalent in industry Shielded Metal Arc Welding Gas Metal Arc Welding Flux Cored Arc ... – PowerPoint PPT presentation

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Title: Introduction to Materials Joining


1
Arc Welding Processes
2
Arc Welding Processes
  • Learning Activities
  • Read Handbook Pp 1-16,
  • Look up Keywords
  • View Slides
  • Read Notes,
  • Listen to
  • lecture
  • Do on-line workbook
  • Do homework
  • Lesson Objectives
  • When you finish this lesson you will understand
  • The similarities and difference between some of
    the various arc welding processes
  • Flux and gas shielding methods
  • Advantages and disadvantages of the arc welding
    processes
  • Need to select between the processes

Keywords Welding Flux, Inert Shielding Gas,
Shielded Metal Arc Welding (SMAW), Gas Metal Arc
Welding (GMAW), Metal Transfer Mode, Flux Cored
Arc Welding FCAW), Submerged Arc Welding (SAW),
3
Linnert, Welding Metallurgy, AWS, 1994
4
Arc Welding Processes
  • Welding processes that employ an electric arc are
    the most prevalent in industry
  • Shielded Metal Arc Welding
  • Gas Metal Arc Welding
  • Flux Cored Arc Welding
  • Submerged Arc Welding
  • Gas Tungsten Arc Welding
  • These processes are associated with molten metal

Electric Arc
5
Linnert, Welding Metallurgy, AWS, 1994
6
Protection of the Molten Weld Pool
  • Molten metal reacts with the atmosphere
  • Oxides and nitrides are formed
  • Discontinuities such as porosity
  • Poor weld metal properties
  • All arc welding processes employ some means of
    shielding the molten weld pool from the air

7
Welding Flux
  • Three forms
  • Granular
  • Electrode wire coating
  • Electrode core
  • Fluxes melt to form a protective slag over the
    weld pool
  • Other purposes
  • Contain scavenger elements to purify weld metal
  • Contain metal powder added to increase deposition
    rate
  • Add alloy elements to weld metal
  • Decompose to form a shielding gas

8
Shielding Gas
  • Shielding gas forms a protective atmosphere over
    the molten weld pool to prevent contamination
  • Inert shielding gases, argon or helium, keep out
    oxygen, nitrogen, and other gases
  • Active gases, such as oxygen and carbon dioxide,
    are sometimes added to improve variables such as
    arc stability and spatter reduction

Argon
Helium
Oxygen
Carbon Dioxide
9
Questions?
  • Turn to the person sitting next to you and
    discuss (1 min.)
  • What would happen if there was no flux on the
    wire to decompose into gas or no inert shielding
    gas was provided?
  • What would the weld metal look like?

10
Shielded Metal Arc Welding SMAW
11
Shielded Metal Arc Welding (SMAW)
12
SMAW Electrode Classification Example
  • E7018
  • E indicates electrode
  • 70 indicates 70,000 psi tensile strength
  • 1 indicates use for welding in all positions
  • 8 indicates low hydrogen

E7018-A1-H8R
13
  • ANSI/AWS - 5.1 Specification for Covered Carbon
    Steel
  • ANSI/AWS - 5.5 Specification for Low Alloy
    Steel
  • ANSI/AWS - 5.4 Specification for Corrosion
    Resistant Steel

AWS Website http//www.aws.org
14
Coating Materials -Partial List
Slipping Agents to Aid Extrusion Clay Talc
Glycerin Binding Agents Sodium Silicate
Asbestos Starch Sugar Alloying and
Deoxidizing Elements Si, Al, Ti, Mn, Ni, Cr
Arc Stabilizers Titania TiO2 Gas-Forming
Materials Wood Pulp Limestone
CaCO3 Slag-Forming Materials Alumina Al2O3
TiO2 SiO2 Fe3O4
15
Linnert, Welding Metallurgy AWS, 1994
16
Linnert, Welding Metallurgy AWS, 1994
17
SMAW Advantages
Shielded Metal Arc Welding
  • Easily implemented
  • Inexpensive
  • Flexible
  • Not as sensitive to part fit-up variances

18
Advantages
  • Equipment relatively easy to use, inexpensive,
    portable
  • Filler metal and means for protecting the weld
    puddle are provided by the covered electrode
  • Less sensitive to drafts, dirty parts, poor
    fit-up
  • Can be used on carbon steels, low alloy steels,
    stainless steels, cast irons, copper, nickel,
    aluminum

19
Quality Issues
Shielded Metal Arc Welding
  • Discontinuities associated with manual welding
    process that utilize flux for pool shielding
  • Slag inclusions
  • Lack of fusion
  • Other possible effects on quality are porosity,
    and hydrogen cracking

20
Limitations
Shileded Metal Arc Welding
  • Low Deposition Rates
  • Low Productivity
  • Operator Dependent

21
Other Limitations
  • Heat of welding too high for lead, tin, zinc, and
    their alloys
  • Inadequate weld pool shielding for reactive
    metals such as titanium, zirconium, tantalum,
    columbium

22
Questions?
  • Turn to the person sitting next to you and
    discuss (1 min.)
  • Wood (cellulose) and limestone are added to the
    coating on SMAW Electrodes for gas shielding.
    What gases might be formed?
  • How do these gases shield?

23
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24
Gas Metal Arc Welding
Gas Metal Arc Welding
25
GMAW Modes of Metal Transfer
Gas Metal Arc Welding
Globular
Spray
Pulsed Spray
Short Circuiting
26
GMAW Filler Metal Designations
Gas Metal Arc Welding
  • ER - 70S - 6

Composition 6 high silicon
Electrode
Solid Electrode
Rod (can be used with GMAW)
Minimum ultimate tensile strength of the weld
metal
27
AWS Specifications for GMAW Wire
AWS A5.18 - Carbon Steel Electrodes AWS A5.28 -
Low Alloy Steel Electrodes
28
Shielding Gas
Gas Metal Arc Welding
  • Shielding gas can affect
  • Weld bead shape
  • Arc heat, stability, and starting
  • Surface tension
  • Drop size
  • Puddle flow
  • Spatter

Ar
He
CO2
Ar-He
29
GMAW Advantages
Gas Metal Arc Welding
  • Deposition rates higher than SMAW
  • Productivity higher than SMAW with no slag
    removal and continuous welding
  • Easily automated

30
Quality
Gas Metal Arc Welding
  • Spatter
  • Droplets of electrode material that land outside
    the weld fusion area and may or may not fuse to
    the base material
  • Porosity
  • Small volumes of entrapped gas in solidifying
    weld metal

31
Limitations
Gas Metal Arc Welding
  • Equipment is more expensive and complex than SMAW
  • Process variants/metal transfer mechanisms make
    the process more complex and the process window
    more difficult to control
  • Restricted access
  • GMAW gun is larger than SMAW holder

32
Questions?
  • Turn to the person sitting next to you and
    discuss (1 min.)
  • When comparing processes that have spray and
    globular metal transfer, which type of transfer
    mode do you thnk results in more spatter? Why?

33
Flux Cored Arc Welding (FCAW)
Flux-Cored Arc Welding
34
Linnert, Welding Metallurgy, AWS, 1994
35
FCAW Electrode Classification
Flux-Cored Arc Welding
  • E70 T - 1

Electrode
Type Gas, Usability and Performance
Minimum UTS 70,000 psi
Flux Cored /Tubular Electrode
Position
American Welding Society Specification AWS A5.20
and AWS A5.29.
36
Linnert, Welding Metallurgy AWS, 1994
37
Advantages
Flux-Cored Arc Welding
  • High deposition rates
  • Deeper penetration than SMAW
  • High-quality
  • Less pre-cleaning than GMAW
  • Slag covering helps with larger out-of-position
    welds
  • Self-shielded FCAW is draft tolerant.

38
Limitations
Flux-Cored Arc Welding
  • Slag must be removed
  • More smoke and fumes than GMAW and SAW
  • Spatter
  • FCAW wire is more expensive
  • Equipment is more expensive and complex than for
    SMAW

39
Questions?
  • Turn to the person sitting next to you and
    discuss (1 min.)
  • What do you suppose would happen if the powder
    inside the core did not get compacted good?

40
(No Transcript)
41
Submerged Arc Welding
Submerged Arc Welding
42
SAW Flux / Filler Metal Compositions
Submerged Arc Welding
  • F7A2-EM12K
  • F indicates flux
  • 70-95 ksi UTS, 58 ksi minimum yield strength, 22
    elongation
  • A - as welded P - postweld heat treated
  • 2 - minimum impact properties of 20 ft-lbs _at_ 20F
  • E indicates electrode (EC - composite electrode)
  • M - medium manganese per AWS Specifications
  • 12 - 0.12 nominal carbon content in electrode
  • K - produced from a heat of aluminum killed steel

43
Advantages
Submerged Arc Welding
  • High deposition rates
  • No arc flash or glare
  • Minimal smoke and fumes
  • Flux and wire added separately - extra dimension
    of control
  • Easily automated
  • Joints can be prepared with narrow grooves
  • Can be used to weld carbon steels, low alloy
    steels, stainless steels, chromium-molybdenum
    steels, nickel base alloys

44
Limitations
Submerged Arc Welding
  • Flux obstructs view of joint during welding
  • Flux is subject to contamination Þ porosity
  • Normally not suitable for thin material
  • Restricted to the flat position for grooves -
    flat and horizontal for fillets
  • Slag removal required
  • Flux handling equipment

45
Homework
Do Homework Assignment 2, Arc Welding Processes
from the Assignment Page of the WE300 Website.
Turn in next Class Period.
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