Chapter 9

Question 1

Discontinuities Def?

Types?

Groups types?

Answer 1

• Irregularities in weld or weldment
• Interruption in the uniform nature of an item
• Types: Cracks, porosity, undercut, incomplete fusion, etc

Linear and nonlinear Discontinuities

Question 2

Defect

Answer 2

specific discontinuity which can impair the suitability of that structure for its intended purpose

“Rejectable Discontinuity”

Question 3

“Rejectable Discontinuity”

Answer 3

defect

Question 4

Linear Discontinuities

critical?

Answer 4

lengths which are much greater than their widths

Far more critical - can cause failure

Question 5

nonlinear Discontinuities

critical?

Answer 5

lengths and widths that are the same

less critical

Question 6

End condition

Answer 6

specific sharpness at its extremities - more likely to propagate the sharper it is

Question 7

Discontinuities in order of sharpest

Answer 7

Cracks, incomplete fusion incomplete joint penetration, slag inclusion porosity,

Question 8

Cracks
characteristics?
linear or nonlinear ?
causes?

Answer 8

• Most critical discontinuities
• Linear
• Very shard end conditions
• Tendency to grow or propagate is a stress is applied
• if a metal is overloaded

Question 9

Cold Cracks

Answer 9

• occur after metal has cooled to ambient temp
• cracks resulting from hydrogen
• ## intergranular or transgranular (between or through Individual grains

Question 10

Hot Cracks

Answer 10

• Usually occur as metal solidifies at an elevated temp.
• Intergranular (cracks occur between individual grains
• -

Question 11

Transverse Cracks

Cause ?

Answer 11

Those lying in a direction perpendicular to the longitudinal axis

Caused by the longitudinal shrinkage stresses of welding acting on the low ductility of the weld or bas metal

Question 12

longitudinal cracks

Cause?

Answer 12

Those lying in a direction parallel to the longitudinal axis

Transverse shrinkage stresses of welding or stresses associated with service conditions

Question 13

Throat cracks?
longitudinal or Transverse ? 
hot or cold?
other name? 
Causes?

Answer 13

• cracks along the weld throat
• longitudinal &
• hot cracks
• Also called centerline cracks

causes 
- Weld cross section is small
- thin root pass
- concave fillet welds
their reduced cross section may not be sufficient to withstand the transfers weld shrinkage stresses

Question 14

Root cracks
longitudinal or Transverse ?
hot or cold?
Causes?

Answer 14

• cracks along the weld root
• longitudinal
• hot cracks
• weld shrinkage stresses from welding
• Improperly fitted or prepared joints
• Large root openings

Question 15

Toe cracks
hot or cold?
Causes?

Answer 15

• Cracks at the toe
• cold cracks
• from weld reinforcement or convexity may provide a stress riser at the welds’ toes
• transverse shrinkage stresses of welding, or service stresses
• Fatigue loading of weld components

Question 16

Crater cracks
Other name?
hot or cold?

Answer 16

occur at the TERMINATION POINT of individual weld passes.
“star cracks” technique and arc does not provide for complete filling of the molten weld puddle -will result in a crater or shallow spot
- Also a result of filler material having flow characteristics which produce concave profiles when solidified.
considered hot cracks since they occur at the solidification of the molten puddle.

Question 17

Underbead
other name?
Causes

Answer 17

• cracks located in HAZ instead of weld metal
• parallel to fusion line
• delayed cracks (final inspection 48-72hr after weld has cooled. (effect high strength steal)
• usually sub-surface but could propagate to the surface
• form from the presence of hydrogen in the weld zone- during welding their is room for hydrogen atoms but as it cools there is less room for them and the metal attempts to much it out causing a crack.
  or filler material, surrounding atmosphere or surface contaminants.

Question 18

Incomplete fusion
Other name?
Causes

Answer 18

discontinuity that occurs between weld metal and fusion face or weld beads

also called cold lap

• fusion is less than specified
• significant weld discontinuity
• often because of slag inclusion from insufficient cleaning
• not enough concentrated heat to melt metal
• improper manipulation of welding electrode by welder
• configuration of the weld joint
• insufficient groove angle
• extreme contamination or mill scale

Question 19

Incomplete joint penetration
Other name?
Causes?

Answer 19

• associated only with groove welds
• weld metal does not extend entirely through the joint thickness when complete penetration is required
• some codes/specs allow incomplete joint penetration some don’t.
• also called partial joint penetration or lack of penetration
• improper technique, or joint configuration ot excessive contamination.

Question 20

Inclusion

Answer 20

entrapped foreign solid material , such as slag, flux, tungsten, or oxide

when the welding process uses some type of flux shielding

causes
improper manipulation of welding electrode
insufficient cleaning
undesirable weld profile that hinders cleaning
A lot of Tungsten inclusion (white on radiograph)
, spatter, overheating of electrode, inadequate or improper shielding gas, excessive electrode size or current, to small of electrode.

Question 21

Porosity

Answer 21

• Cavity-type discontinuities formed by gas entrapment during solidification
• voids or gas pockets within the solidified weld metal
• least detrimental discontinuity unless id pressure lines
• spherical in shape
• caused by contaminants or moisture

Question 22

Uniform scattered porosity

Answer 22

numerous cavities which occur throughout the weld in no particular pattern

Question 23

Cluster porosity

Answer 23

specific patterns of several cavities in a group

Question 24

linear porosity

Answer 24

specific patterns of several cavities in a straight line

Question 25

Undercut

Answer 25

• surface discontinuity at the base metal adjacent to the weld
• the BASE METAL has been melted away during welding & insufficient filler metal deposited to fill the depression
• detrmental to fatigue load structures
  causes
• improper technique
• welding to fast
• weld heat is too high, causing excessive melting of BM

Question 26

Underfill
also alled
causes

Answer 26

• surface discontinuity in WELD METAL - loss of material in cross section
• not sufficient filler metal deposited
• can occur and the face and root
• also called suck back or internal concavity
• caused by incomplete welds / not understanding perimeters / excessive heat / excessive travel speed
• visually detected

Question 27

Overlap

Answer 27

-protrusion or overflow of the weld metal beyond the weld toe or root
-visually detected
- significant discontinuity
- can hide cracks that will come out later
causes
-travel speed to low - too much time to metal to melt
- more weld metal without fusing

Question 28

Convexity

causes

Answer 28

discontinuity of fillet welds only
- bulging wels
- uses excessive material
causes sharp edges causing problem with fatigue
- slight convexity is ok and desirable but not too much

causes

travel speed too slow / not enough heat / improper technique

Question 29

Weld reinforcement

Answer 29

Similar to convexity but for groove welds only

• face reinforcement / root reinforcement
• the greater the reinforcement angle the less fatigue resistance
  uses excessive material
  causes sharp edges causing problem with fatigue

causes

travel speed too slow / not enough heat / improper technique

Question 30

Arc Strikes

Answer 30

the arc in initiated on the base metal away from the weld joint

• detrimental
• base metal is melted and rapidly cooled due to the massive heat sink

Question 31

Spatter
issues with spatter
causes

Answer 31

• metal particles expelled during fusion welding that do not form a part of the weld.
• some globules may have enough heat to cause localized HAZ on the base metal similar to an ark struck
• can be a local stress riser
  cause problems for coatings

causes - high welding currents (turbulence)
- some welding applications cause more than others
GMAW - FCAW

Question 32

Lamination

Delimitation

Answer 32

• Base metal flaw
• nonmetallic inclusion which occur in steel when being produced (form of oxide)
  ________________________
• the separation of a lamination under stress

Question 33

Lamellar Tear

3 conditions that must exists ?

Answer 33

• Terrace like fracture in the base metal - parallel to the rolled surface and weld.
• occurs with high stress in the Z direction or thickness direction
• resulting from weld shrinkage
• the thicker the material the higher the inclusion content, the greater the possibility of experiencing tearing
• 3 conditions that must exist
  1- Through-thickness direction
  2- susceptible joint configuration
  3 material with high inclusion content

Question 34

Seams & Laps

Answer 34

Base metal discontinuity during steel making

• opened to the rolled surface of the metal instead of the edge

seems - straight line longitudinal crevices or openings that may appear on the surface of steel - caused by imperfections in steel ingot

laps - result from overfilling in the rolling mill passes that cause fins or projections

Question 35

Dimensional discontinuities

Answer 35

Dimensional irregularities in size or shape imperfections

inspect by taking measurements of weld sizes and lengths to insure there is sufficient weld metal to transmit the applied load

make suer heat didn’t cause distortion or warpage

Question 36

Discontinuities (laser & Electron Beam welding)

Answer 36

Missed joint
root porosity
inconsistant penetration or spiking

Question 37

Missed joint

Discontinuities (laser & Electron Beam welding)

Answer 37

Beam is deflected off the joint - caused by axis of the laser is not aligned with the joint root

Question 38

root porosity

Discontinuities (laser & Electron Beam welding)

Answer 38

Formation of void at the bottom of the weld

caused by gasses that didn’t have time to escape through deep weld metal

Question 39

inconsistant penetration or spiking

Discontinuities (laser & Electron Beam welding)

Answer 39

mainly in high power deer penetrating welds

Caused by variations in power density