Weld Design and Specification - University of Delaware

Weld Design and Specification ... IMaterial and the effects of heating ICost IDistortion ... Static Strength IStress - strain diagram Strain (ε) = Str...

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Weld Design and Specification

Jim Glancey, PE Depts. of Bioresources Engineering & Mechanical Engineering University of Delaware [email protected] http://udel.edu/~jglancey

I can’t explain everything . . .

1000 ft 4 in

6 in

1/4” Inside weld entire length

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Factors in Weld Design I Strength (static and/or fatigue) I Material and the effects of heating I Cost I Distortion I Residual Stresses I Easy to Weld

Static Strength I Stress

- strain diagram F A

Stress (σ) =

F A

Strain (ε) =

L

ultimate (tensile)

yield

∆L L

F

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Shear Strength I In

general, material fails in shear due to distortion (at a molecular level) I Criteria for failure: • Ductile: Shear Strength ~ 0.5 Tensile Strength • Brittle: Shear Strength ~ 0.75 Tensile Strength I Weld

strength analysis is generally based on Shear Strength

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Static Strength of Welds Butt F

Normal =

F 1/8 75o

Fillet

Shear = 3/8

1/4

2F

F w*h F w*h

F

F Max Normal = 0.618w * h

F

Max Shear =

F 0.707w * h

h = throat size!

Weld Size vs. Throat Size Butt h = plate thickness = weld size 1/8 75o

Fillet

3/8

1/4

h = 0.707 * plate thickness 0.707 * weld size

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Fatigue Strength Static Tensile Strength

Fatigue Strength

Endurance Limit Low Cycle

1

High Cycle

1000

Infinite Life

1,000,000

Cycles of Loading

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Endurance Limit I For Steel:

• Endurance Limit = 0.5 * Tensile Strength or 100 kpsi, which ever is lower. I For Aluminum:

• No endurance limit (cannot have an infinite life)

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Factors for Fatigue Stress Analysis

Type of Weld

Stress Increase

Butt Weld

1.2

Transverse Fillet

1.5

Parallel Fillet

2.7

T-butt with corners

2.0

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Strength Considerations I Try

to minimize the stresses in welds; make the parent materials carry highest stresses. I Butt welds are the most efficient I Avoid stress concentrations I Intermittent weld length should be at least 4 times the fillet size I Minimize weld size to reduce potential for fatigue failure

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Effects of Welding on Metallurgy I Depends on the alloy and welding process I In general, cracking is promoted by:

• stress concentrations • brittle parent material after welding (low carbon steels) • hydrogen in the weld metal • impurities in the weld metal

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Reducing Distortion I Prevent

overwelding I Intermittent welding I Minimize number of passes I Place welds near the neutral axis of the part I Balance welds around the neutral axis I Anticipate shrinkage forces I Residual stress relief

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Neutral Axis I The line (plane) where bending stresses are

zero.

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