Viscoplasticity
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In contrast to elastic theories, plasticity is the behavior,
where the material would undergo unrecoverable deformations due to
the response of applied forces. There are several models for
plasticity. Viscoplasticity, for instance, is one of the famous
models of plasticity. It is defined as a rate-dependent plasticity
model. Rate dependent plasticity is important for (high-speed)
transient plasticity calculations. It should be used, however, in
combination with a plasticity law. In that aspect, viscoplastic
solids exhibit permanent deformations after the application of
loads but continue to undergo a creep flow as a function of time
under the influence of the applied load (equilibrium is
impossible). Similar to viscoelasticity, such materials are
represented by a combination of non-linear dashpot elements,
Hookean spring elements and sliding frictional elements. As shown
in Fig1, E is the modulus of elasticity, is the viscosity parameter
and N is another parameter that represents non-linear dashpot
[(d/dt)= = (d/dt)(1/N)]. It is good to mention that the sliding
element could have a yield stress that is strain rate dependent, or
even constant, as shown in Fig 1c. In that aspect, dashpot
contributes to the viscosity of the material, while the spring
contributes to the elastic behavior. Some rheological models will
be presented throughout this text.[1] In this text, a brief
overview is presented about the viscoplasticity theory, starting
with the background history, and ending with some proposed models
with their response to creep, stress relaxation and strain
hardening tests.
Fig1: Elements of ViscoplasticityContents
[hide]
1 Background 2 Domain of validity and use 3 Phenomenological
aspects
3.1 Strain hardening test 3.2 Creep test 3.3 Relaxation test 4
Rheological models
4.1 Perfectly viscoplastic solid 4.2 Elastic perfectly
viscoplastic solid 4.3 Elastoviscoplastic hardening solid 5
Strain-rate dependent plasticity models
5.1 Perzyna formulation 5.2 DuvautLions formulation 5.3 Flow
stress models
5.3.1 JohnsonCook flow stress model 5.3.2
SteinbergCochranGuinanLund flow stress model 5.3.3 ZerilliArmstrong
flow stress model 5.3.4 Mechanical threshold stress flow stress
model 5.3.5 PrestonTonksWallace flow stress model 6 See also 7
References
[edit] Background
The research work about plasticity started in 1864, while
studying the maximum shear criterion. Another criterion is the von
Mises theory. In 1930, Prager and Hohenemser proposed the first
model for the maximum shear criterion. This was a generalization of
Bingham model. However, the application of these established
theories did not begin before 1950, where limit theorems were
discovered. In viscoplasticity, the development of a mathematical
model heads back to 1910 with the representation of primary creep
by Andrews law. In 1929, Norton developed a model which links the
rate of secondary creep to the stress. Basically, that simple model
was represented by a dashpot. In 1934, Odqvists generalization, of
Nortons law to the multi-axial case, was established.[1]In 1960,
the first IUTAM Symposium Creep in Structures organized by Hoff
provided a great development in viscoplasticity with the works of
Hoff, Rabotnov, Perzyna, Hult, and Lemaitre for the isotropic
hardening laws, and those of Kratochvil, Malinini and Khadjinsky,
Ponter and Leckie, and Chaboche for the kinematic hardening laws.
For instance, Perzyna, in 1963, introduced a viscosity coefficient
that is temperature and time dependent.[2] The formulated models
were supported by the thermodynamics of irreversible processes and
the phenomenological standpoint.[1] Furthermore, several
constitutive laws have been presented, taking into account the
material characteristic such as: perfectly viscoplastic,
viscoplasticity with isoropic or kinematic hardening etc.
In general, viscoplasticity theories are considered in areas
such as:
The calculation of permanent deformations
The prediction of the plastic collapse of structures
The investigation of stability
Crash simulations
Systems exposed to high temperatures such as turbines in
engines, e.g. a power plant
Dynamic problems and systems exposed to high strain rates
[edit] Domain of validity and use
In contrast to plasticity, the viscoplasticity theory explains
the flow by creep, which is time dependent. For metals and alloys,
it corresponds to a mechanism linked to the movement of
dislocations in grains deviation, polygonization-with superposed
effects of inter-crystalline gliding. The mechanism begins to arise
as soon as the temperature is greater than approximately one third
of the absolute melting temperature. However, certain alloys
exhibit viscoplasticity at room temperature (300K). Time effect
must be taken into consideration as well. For polymers, wood, and
bitumen, the theory of viscoplasticity must be used as soon as the
load has passed the limit of elasticity or viscoelasticity.[1] Some
materials, where viscoplasticity is highly required, at high strain
rates, are:
- Polymers
- Wood and bitumen
- Metals exposed to extremely high temperatures
[edit] Phenomenological aspects
For a qualitative analysis, several characteristic tests are
performed to describe the phenomenology of viscoplastic materials.
Some examples of these tests are (i) hardening tests at constant
stress or strain rate, (ii) creep tests at constant force, and
(iii) stress relaxation at constant elongation.
[edit] Strain hardening test
One consequence of yielding is that as plastic deformation
proceeds, an increase in stress is required to produce additional
strain. This phenomenon is known as Strain/Work hardening.[3]For a
viscoplastic material the hardening curves are not significantly
different from those of plastic material. Nevertheless, three
essential differences are apparent:
Fig2:(a) Strain Hardening (b) Immediate response to different
strain Rate- At the same strain, the higher the rate of strain is,
the higher the stress will be.
- A change in the rate of strain during the test results in an
immediate change in the stressstrain curve. (See Fig 2b)
- The concept of a plastic yield limit is no longer strictly
applicable.
The hypothesis of partitioning the strains by decoupling is
still applicable in most cases (where the strains are small):
= e + pwhere:
e = the linear elastic strain.
p = the viscoplastic strain.
[edit] Creep test
Fig3: Creep testCreep is the tendency of a solid material to
slowly move or deform permanently under constant stresses. Creep
tests measure the strain response due to a constant stress as shown
in Fig3. The classical creep curve represents the evolution of
strain as a function of time in a material subjected to uniaxial
stress at a constant temperature. The creep test, for instance, is
performed by applying a constant force/stress and analyzing the
strain response of the system. See Fig 3a. In general, this curve
usually shows three phases or periods of behavior: [3]- A primary
creep stage, also known as transient creep, is the starting stage
during which hardening of the material leads to a decrease in the
rate of flow which is initially very high. (0 1)
- The secondary creep stage, also known as the steady state, is
where the strain rate is constant. (1 2)
- A tertiary creep phase in which the usual increase in the
strain rate up to the fracture strain. (2 R)
[edit] Relaxation test
Fig4: Relaxation testAs shown in Fig 4, the relaxation test[1]
is defined as the stress response due to a constant strain for a
period of time. In viscoplastic materials, Relaxation tests
demonstrate the stress relaxation in uniaxial loading at a constant
strain. In fact, these tests characterize the viscosity and can be
used to determine the relation which exists between the stress and
the rate of viscoplasticity strain. Hence, the decompositon of
strain rate is shown as follows:
d/dt = de/dt + dp/dtWhere the linear elasticity de/dt =
(d/dt)/E. Thus, each point on the relaxation curve (t) gives the
stress and rate of viscoplastic strain.
For a total of zero strain rate, substituting both equations we
get
dp/dt = (d/dt)/E.
[edit] Rheological models
Several constitutive models for viscoplasticity have been
developed. The most famous models are the following:[1]- Perfectly
viscoplastic solid,
- Elastic perfectly viscoplastic solid
- Elastoviscoplastic Hardening Solid
Before illustrating the earlier defined models, it is good to
note that:
- In series connection, the strain is additive while the stress
is equal in each element.
- In parallel connection, the stress is additive while the
strain is equal in each element.
[edit] Perfectly viscoplastic solid
Fig5: Norton Model for perfectly viscoplastic solid
Considering the simple Norton Model, the perfectly viscoelastic
solid is represented in Fig5. The rate of stress (as for viscous
fluids) is a function of the rate of permanent strain:
(d/dt)= = (d/dt)(1/N)N = a fitting parameter, when N = 1.0, the
solid is viscoelastic. These models could be applied in metals and
alloys at temperatures higher than one third of their absolute
melting point (in kelvins) and polymers/asphalt at elevated
temperature. = The kinematic viscosity of the material. The
responses for strain hardening, creep, and relaxation tests of such
material are shown in Fig 7.[1][edit] Elastic perfectly
viscoplastic solid
Fig6: The elastic perfectly viscoplastic materialUsing
BinghamNorton model (Bingham plastic), the elasticity is no longer
considered negligible but the rate of plastic strain is only a
function of the stress . There is no influence of hardening. See
Fig 6 for such model. The sliding material shown in the following
figure represents a constant yielding stress when the elastic limit
is exceeded irrespective of the strain.
|| < y = e = /E|| y = e + pd/dt = (d/dt)/E + f()The responses
for strain hardening, creep, and relaxation tests of such material
are shown in Fig 8.[1][edit] Elastoviscoplastic hardening solid
This is the most complex schematic representation because the
stress depends on the plastic strain rate and on the plastic strain
itself. The elastoviscoplastic material is similar to the elastic
perfectly viscoplastic solid, but after exceeding the yield stress,
the stress starts to increase beyond the yielding point (Strain
Hardening). Basically, the yield stress in the sliding element
increases with strain, as shown below: || < s = e = E || s = e +
p = Ee = f(p, dp/dt) This model is adopted when metals and alloys
are at medium and higher temperatures and wood under high loads.[1]
The responses for strain hardnenning, creep, and relaxation tests
of such material are shown in Fig 9.
Fig7: The response of perfectly viscoplastic solid to hardening,
creep and relaxation tests[1]
Fig8: The response of elastic perfectly viscoplastic solid to
hardening, creep and relaxation tests[1]
Fig9: The response of elastoviscoplastic hardening solid to
hardening, creep and relaxation tests[1][edit] Strain-rate
dependent plasticity models
Classical, phenomenological, viscoplasticity models for small
strains are usually categorized into two types:[4] the Perzyna
formulation
the DuvautLions formulation
[edit] Perzyna formulation
In the Perzyna formulation the plastic strain rate is assumed to
be given by a constitutive relation of the form
where f(.,.) is a yield function, is the Cauchy stress, is a set
of internal variables, is a relaxation time.
[edit] DuvautLions formulation
The DuvautLions formulation is equivalent to the Perzyna
formulation and may be expressed as
where is the closest point projection of the stress state on to
the boundary of the region that bounds all possible elastic stress
states.
[edit] Flow stress models
The quantity represents the evolution of the yield surface. The
yield function f is often expressed as an equation consisting of
some invariant of stress and a model for the yield stress (or
plastic flow stress). An examaple is von Mises or J2 plasticity. In
those situations the plastic strain rate is calculated in the same
manner as in rate-independent plasticity. In other situations, the
yield stress model provides a direct means of computing the plastic
strain rate.
Numerous empirical and semi-empirical flow stress models are
used the computational plasticity. The following temperature and
strain-rate dependent models provide a sampling of the models in
current use:
1. the JohnsonCook model
2. the SteinbergCochranGuinanLund model.
3. the ZerilliArmstrong model.
4. the Mechanical Threshold Stress model.
5. the PrestonTonksWallace model.
The JohnsonCook (JC) model [5] is purely empirical and is the
most widely used of the five. However, this model exhibits an
unrealistically small strain-rate dependence at high temperatures.
The SteinbergCochranGuinanLund (SCGL) model [6]
HYPERLINK "http://en.wikipedia.org/wiki/Viscoplasticity" \l
"cite_note-Steinberg89-6" [7] is semi-empirical. The model is
purely empirical and strain-rate independent at high strain-rates.
A dislocation-based extension based on [8] is used at low
strain-rates. The SCGL model is used extensively by the shock
physics community. The ZerilliArmstrong (ZA) model [9] is a simple
physically-based model that has been used extensively. A more
complex model that is based on ideas from dislocation dynamics is
the Mechanical Threshold Stress (MTS) model [10]. This model has
been used to model the plastic deformation of copper, tantalum
[11], alloys of steel [12]
HYPERLINK "http://en.wikipedia.org/wiki/Viscoplasticity" \l
"cite_note-Banerjee05b-12" [13], and aluminum alloys [14]. However,
the MTS model is limited to strain-rates less than around 107/s.
The PrestonTonksWallace (PTW) model [15] is also physically based
and has a form similar to the MTS model. However, the PTW model has
components that can model plastic deformation in the overdriven
shock regime (strain-rates greater that 107/s). Hence this model is
valid for the largest range of strain-rates among the five flow
stress models.
[edit] JohnsonCook flow stress model
The JohnsonCook (JC) model [5] is purely empirical and gives the
following relation for the flow stress (y)
where is the equivalent plastic strain, is the plastic
strain-rate, and A,B,C,n,m are material constants.
The normalized strain-rate and temperature in equation (1) are
defined as
where is a user defined plastic strain-rate, T0 is a reference
temperature, and Tm is a reference melt temperature. For conditions
where T * < 0, we assume that m = 1.
[edit] SteinbergCochranGuinanLund flow stress model
The SteinbergCochranGuinanLund (SCGL) model is a semi-empirical
model that was developed by Steinberg et al.[6] for high
strain-rate situations and extended to low strain-rates and bcc
materials by Steinberg and Lund[7]. The flow stress in this model
is given by
where a is the athermal component of the flow stress, is a
function that represents strain hardening, t is the thermally
activated component of the flow stress, (p,T) is the pressure- and
temperature-dependent shear modulus, and 0 is the shear modulus at
standard temperature and pressure. The saturation value of the
athermal stress is max. The saturation of the thermally activated
stress is the Peierls stress (p). The shear modulus for this model
is usually computed with the SteinbergCochranGuinan shear modulus
model.
The strain hardening function (f) has the form
where ,n are work hardening parameters, and is the initial
equivalent plastic strain.
The thermal component (t) is computed using a bisection
algorithm from the following equation [8]
HYPERLINK "http://en.wikipedia.org/wiki/Viscoplasticity" \l
"cite_note-Steinberg89-6" [7].
where 2Uk is the energy to form a kink-pair in a dislocation
segment of length Ld, kb is the Boltzmann constant, p is the
Peierls stress. The constants C1,C2 are given by the relations
where d is the dislocation density, Ld is the length of a
dislocation segment, a is the distance between Peierls valleys, b
is the magnitude of the Burgers vector, is the Debye frequency, w
is the width of a kink loop, and D is the drag coefficient.
[edit] ZerilliArmstrong flow stress model
The ZerilliArmstrong (ZA) model [9]
HYPERLINK "http://en.wikipedia.org/wiki/Viscoplasticity" \l
"cite_note-Zerilli93-15" [16]
HYPERLINK "http://en.wikipedia.org/wiki/Viscoplasticity" \l
"cite_note-Zerilli04-16" [17] is based on simplified dislocation
mechanics. The general form of the equation for the flow stress
is
In this model, a is the athermal component of the flow stress
given by
where g is the contribution due to solutes and initial
dislocation density, kh is the microstructural stress intensity, l
is the average grain diameter, K is zero for fcc materials, B,B0
are material constants.
In the thermally activated terms, the functional forms of the
exponents and are
where 0,1,0,1 are material parameters that depend on the type of
material (fcc, bcc, hcp, alloys). The ZerilliArmstrong model has
been modified by [18] for better performance at high
temperatures.
[edit] Mechanical threshold stress flow stress model
The Mechanical Threshold Stress (MTS) model [10]
HYPERLINK "http://en.wikipedia.org/wiki/Viscoplasticity" \l
"cite_note-Goto00a-18" [19]
HYPERLINK "http://en.wikipedia.org/wiki/Viscoplasticity" \l
"cite_note-Kocks01-19" [20]) has the form
where a is the athermal component of mechanical threshold
stress, i is the component of the flow stress due to intrinsic
barriers to thermally activated dislocation motion and
dislocation-dislocation interactions, e is the component of the
flow stress due to microstructural evolution with increasing
deformation (strain hardening), (Si,Se) are temperature and
strain-rate dependent scaling factors, and 0 is the shear modulus
at 0 K and ambient pressure.
The scaling factors take the Arrhenius form
where kb is the Boltzmann constant, b is the magnitude of the
Burgers' vector, (g0i,g0e) are normalized activation energies, ()
are constant reference strain-rates, and (qi,pi,qe,pe) are
constants.
The strain hardening component of the mechanical threshold
stress (e) is given by an empirical modified Voce law
where
and 0 is the hardening due to dislocation accumulation, IV is
the contribution due to stage-IV hardening, (a0,a1,a2,a3,) are
constants, es is the stress at zero strain hardening rate, 0es is
the saturation threshold stress for deformation at 0 K, g0es is a
constant, and is the maximum strain-rate. Note that the maximum
strain-rate is usually limited to about 107/s.
[edit] PrestonTonksWallace flow stress model
The PrestonTonksWallace (PTW) model [15] attempts to provide a
model for the flow stress for extreme strain-rates (up to 1011/s)
and temperatures up to melt. A linear Voce hardening law is used in
the model. The PTW flow stress is given by
with
where s is a normalized work-hardening saturation stress, s0 is
the value of s at 0K, y is a normalized yield stress, is the
hardening constant in the Voce hardening law, and d is a
dimensionless material parameter that modifies the Voce hardening
law.
The saturation stress and the yield stress are given by
where is the value of s close to the melt temperature, () are
the values of y at 0 K and close to melt, respectively, (,) are
material constants, , (s1,y1,y2) are material parameters for the
high strain-rate regime, and
where is the density, and M is the atomic mass.
[edit] See also
Viscoelasticity Bingham plastic Dashpot Creep Plasticity
(physics) Continuum mechanics[edit] References
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retrieved 2009-05-13Retrieved from
"http://en.wikipedia.org/wiki/Viscoplasticity"
Categories: Continuum mechanics | Plasticity
