Chapter 8 Strain hardening and annealing. Reading All of Ch. 8 except subsections in Sec. 8-1 on...
Transcript of Chapter 8 Strain hardening and annealing. Reading All of Ch. 8 except subsections in Sec. 8-1 on...
Chapter 8 Strain hardening and
annealing
Reading
All of Ch. 8 except subsections in Sec. 8-1 on strain-hardening
exponent, strain-rate sensitivity and Bauschinger Effect.
Homework No. 10
Problems 8-19, 8-22, 8-28, 8-54, 8-64
Strengthening mechanisms in metals
A correlation exists between dislocation motion and mechanical behavior of metals.
Macroscopic plastic deformation motion of large #s of dislocations.
The ability of a metal to plastically deform depends on the ability of dislocations to move.
Limiting the dislocation motion hardness and strength increase greater mechanical forces required to initiate
plastic deformation.
Strengthening mechanisms in metals
Strengthening principle: restricting or hindering dislocation motion renders a material harder and stronger.
Mechanisms for strengthening single phase metals:
grain size reduction
solid solution alloying
strain hardening
Strengthening by grain size reduction
A grain boundary poses a barrier to dislocation motion for two reasons:
A dislocation moving in grain A to pass into grain B of different orientation will have to change its direction of motion. This is rather difficult.
Slip planes are discontinuous from one grain to the other.
Strengthening by grain size reduction
Dislocation pile-up
Strengthening by grain size reduction
A fine grain material is harder and stronger than one that is coarse grained.
Toughness also improves with finer grain.
Small-angle grain boundaries are not as effective as large-angle grain boundaries in interfering with dislocation motion.
Solid-solution strengthening Alloys are almost always stronger than their pure metals,
because the solute atoms strain the solvent lattice.
These strain fields interact with those of the dislocations restricting the dislocation movement.
Solid-solution strengthening Solute atom and its segregation
towards dislocations causes reduction of the strain fields.
As solute atoms are attached to the dislocations, the resistance to slip is greater since dislocations have to be torn away from them to move.
Solid-solution strengthening
Hardness and strength increase with increase of alloy concentration.
Ductility usually decreases.
Solid-solution strengthening
Solid-solution strengthening
Solid-solution strengthening
Strain hardening (Work hardening)
Cold Work: Mechanical deformation of a metal at relatively low
temperatures (below about 1/3 of the melting temperature in K).
% C.W. is defined relative to the reduction in cross sectional area of the material.
1000
A
AACW% do
Strain hardening (Work hardening)
The fibrous grain structure of a low carbon steel produced by cold working: (a) 10% cold work, (b) 30% cold work, (c) 60% cold work, and (d) 90% cold work (250). (Source: From ASM Handbook Vol. 9, Metallography and Microstructure, (1985) ASM International, Materials Park, OH 44073. Used with permission.)
Common metal working methods
Rolling
Open die forging
Closed die forging
Direct extrusion
Indirect extrusion
Wire drawing
Stamping
Strain hardening Process whereby a metal is plastically deformed, making it
harder and stronger. Stress-strain diagram & strain hardening.
A material is stressed beyond the yield strength before the stress is removed.
Now the material has a higher yield strength and tensile strength but lower ductility.
By repeating the procedure, the strength continues to strength and the ductility continues to decrease until the material becomes very brittle.
Strain hardening
Dislocation multiplication and strain field interactions dislocation motion is hindered by the presence of other dislocations.
As the dislocation density increases, dislocation motion resistance by other dislocations becomes more pronounced.
Annealing
To make a material more ductile after cold working
Stages of annealing
Thermal recovery - Stress relief
- Dislocation rearrangement
Recrystallization - Birth of new strain-free grains
Grain growth
Effect of annealing time at a fixed annealing temperature
Brass
Cold-worked brass
After 3 s at 580°C, new grains appear.
After 4 s at 580°C, many more grains appear.
8 s at 580°C, complete recrystallization has occurred.
1 h at 580°C, substantial grain growth has occurred.
Effect of annealing temperature
Brass
Annealed at 400°C Twin boundaries
Annealed at 650°C
Annealed at 800°C
Recrystallization
Effect of prior cold work on recrystallization temperature
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During hot working, the elongated anisotropic grains immediately recrystallize. If the hot-working temperature is properly controlled, the final hot-worked grain size can be very fine.
Hot working