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Transcript of 1 Typical Textures, part 2: Thermomechanical Processing (TMP) of bcc Metals 27-750 Advanced...
![Page 1: 1 Typical Textures, part 2: Thermomechanical Processing (TMP) of bcc Metals 27-750 Advanced Characterization and Microstructural Analysis A.D. Rollett.](https://reader035.fdocuments.net/reader035/viewer/2022062407/56649c3f5503460f948ea8f0/html5/thumbnails/1.jpg)
1
Typical Textures, part 2:Thermomechanical Processing (TMP)
of bcc Metals
27-750
Advanced Characterization and Microstructural Analysis
A.D. RollettCarnegie
Mellon
MRSEC
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Objectives
• Introduce you to experimentally observed textures in a wide range of (bcc) materials.
• Develop a taxonomy of textures based on deformation type.
• Prepare you for relating observed textures to theoretical (numerical) models of texture development, especially the Taylor model.
• See chapter 5 in Kocks, Tomé & Wenk.
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Taxonomy
• Deformation history more significant than alloy.• Crystal structure determines texture through slip
(and twinning) characteristics.• Alloy (and temperature) can affect textures, e.g.
through planarity of slip; e.g. through frequency of shear banding.
• Annealing (recrystallization) sometimes produces a drastic change in texture, although this is less important than in fcc alloys.
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Why does deformation result in texture development?
• Deformation means that a body changes its shape, which is quantified by the plastic strain, p.
• Plastic strain is accommodated in crystalline materials by dislocation motion, or by re-alignment of long chain molecules in polymers.
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Dislocation glide grain reorientation
• Dislocation motion at low (homologous temperatures) occurs by glide of loops on crystallographic planes in crystallographic directions: restricted glide.
• Restricted glide throughout the volume is equivalent to uniform shear.
• In general, shear requires lattice rotation in order to maintain grain alignment: compatibility
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Re-orientation Preferred orientation
• Reorientations experienced by grains depend on the type of strain (compression versus rolling, e.g.) and the type of slip (e.g. {110}<111> in bcc).
• The Taylor model is a useful first order (crystal plasticity) model that correctly predicts the main features of deformation textures, although more sophisticated models are required for quantitative matching.
• In general, some orientations are unstable (f(g) decreases) and some are stable (f(g) increases) with respect to the deformation imposed, hence texture development.
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Texture Development in Low C Steel During Cold Rolling & Annealing
(R.K. Ray et al., International Materials Reviews, 1994, Vol.39, p. 129)
rolling and recrystallization texture - to - transformation
Transformed hot band texture
Cold rolling texture
Cold Rolling
ND fiber, <111> ND RD fiber, <110> RD
Annealing textureND fiber sharpens RD fiber weakens
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Deformation systems (typical)
In deformed materials, texture or preferred orientation exists due to the anisotropy of slip. While slip in bcc metals generally occurs in the <111> type direction, it may be restricted to {110} planes or it may involve other planes (T. H. Courtney, Mechanical Behavior of Materials, McGraw-Hill, New York, 1990.)
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Axisymmetric deformation: Extrusion, Drawing
5.000
05.00
00
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bcc uniaxial textures
92% rolled TaTensile test inoriginal RD tostrain of 0.6:<110> fiber(a) Normal and rolling direction inverse pole figures (equal area projection) of 92% rolled Ta and (b) Prior normal and rolling direction inverse pole figures for (a) tested in tension to a strain of 0.6 (tensile direction coincident to prior rolling direction).
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Rolling
RD
ND
Rolling ~ plane strain deformation means extension or compression in a pair of directions with zero strain in the third direction: a multiaxial strain.
00
000
00
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Rolling Textures
bcc
{110} and {100} pole figures (equal area projection; rolling direction vertical) for (a) low-carbon steel cold rolled to a reduction in thickness of 80% (approximate equivalent strain of 2); (b) tantalum, unidirectionally rolled at room temperature to a reduction in thickness of 91%. [Kocks]
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{100} Pole figure for certain components of rolled bcc metals
Note how very different components tend to overlap in a pole figure.
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Fiber Texture in bcc Metals
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bcc fibers: the 2 = 45° section
<111>||ND<110>||RD
<110>||TD
Goss
Bunge Euler angles
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Theoretical bcc rolling
textureCalculated using LApp, starting from a random texture with a strain of 50% (about 35% reduction). The gamma fiber is approximately in the center of each section.
The 45° section of the COD shows a strong alpha fiber and only partial development of the gamma fiber at this low strain
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Dependence on Rolling Reduction
TD
RD
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Crystallite Orientation Distribution in Polar Space
RD
TD
-fiber
-fiber
-fiber
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Alpha fiber plot, <110> // RD
0
2
4
6
8
10
12
14
0 20 40 60 80
Alpha fiber
20% CR50 % CR60% CR80 % CR70% CR BA
Inte
nsity
Phi (°)
{001}<110> {112}<110> {111}<110> {110}<110>
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Gamma Fiber, <111> ND
0
1
2
3
4
5
6
60 65 70 75 80 85 90
Gamma Fiber
20% CR50% CR60% CR80% CR70% CR BAIn
tens
ity
1 (°)
{111}<110> {111}<112>
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Ta, Fe rolling textures
Note: in these plots, the Euler anglesare Roe angles:axes transposedwith horizontal, (=1-90°)vertical.
45° sections, contours at 1,2 … 7(a) low-C steel before cold rolling(b) Low-C steel reduced 90%(c) Tantalum rolled to 91%
45° sections, contours at 1,2,3,4 … (a) 0% Si steel before cold rolling(b) 2% Si steel before cold rolling(c) 0% Si steel cold rolled 75 %;
{112}<110> strongest(d) 2% Si steel cold rolled 75 %;
{111}<110> strongest
a b
c dmax
max
<111>//ND
<110>//RD
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Fe, Fe-Si rolling,
fiber plots
Note the marked alloy dependencein the alpha fiber;smaller variationsin the gamma fiber.
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Parameters for Optimizing <111> Fiber Texture
• Fine hot band grain size• Low concentrations of C, N, Mn• Additions of Ti, Nb• Long holding times in annealing• High annealing temperatures• Large cold reduction ratio• Control of coiling & rolling temperatures• Anneal before Cold Rolling (austenite)
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Mechanical Properties
Plastic Strain Ratio (r-value)
)2(2
1)(
)2(4
1)(
)/ln(
)/ln(
)/ln(
)/ln(
90450
90450
rrranisotropyplanarr
rrrvaluerr
WLWfL
WfW
TfTi
WfWr
m
iif
ii
Large rm and small ∆r required for deep drawing
LiWi
Rolling Direction
4590
0
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Correlation between rm and I{111}/I{100} texture ratio in Steels
(J.F. Held, 'Mechanical Working and Steel Processing IV', 1965)
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Variation of r-value with Texture
These plots make it clear that the two main gamma fiber components complement each other to give high r-values; other components in the alpha fiber tend to lower the r-value and make it anisotropic
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Shear Texture• Shear strain means that displacements are tangential
to the direction in which they increase.• Shear direction=1, Shear Plane 2-axis
12
1 = Shear Direction = <uvw>
2 =Torsion
Axis= {hkl}
d 0 0
0 0 0
0 0 0
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Torsion Textures: twisting of a hollow cylinder specimen
(a)
(b)(c)
Torsion Axis
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{100} Pole figuresMontheillet et al.,
Acta metall., 33, 705, 1985
fcc bcc
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bcc torsion textures: Fe
Ideal |{100} pole figures
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bcc torsion textures: Ta
(a) initial texturefrom swaged rod;(b) torsion texture
Ideal |{100} pole figures
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Summary: part 2
• Typical textures illustrated for shear textures and for bcc metals.
• Pole figures are recognizable for standard deformation histories but orientation distributions provide much more detailed information.
• For bcc rolling textures, the 45° section often provides most of the information needed.
• As an example of the connection to mechanical properties, the plastic strain ratio (r-value) is highly sensitive to texture. For deep drawing, the gamma fiber should be optimized. For use in motors as electrical sheet steel, the <100>//ND fiber should be optimized (not yet a solved problem).