The present invention relates to the field of numerical simulation, in particular to a multiaxial creep-fatigue prediction method.
With the increasing demand for large-scale, high-performance, and long-life performance of high-temperature rotating parts, the structural integrity assessment of structures containing geometric discontinuities in complex and harsh environments has become one of the key technical bottlenecks that need to be resolved. The multiaxial stress-strain state caused by geometric discontinuities and complex loading history inevitably limit the service life of such parts. In recent years, the development of finite element software can satisfy people's understanding of complex stress-strain behavior and provides the feasibility of accurate life prediction in this state.
Nowadays, the creep-fatigue analysis and life prediction for complex structures can be divided into three types. The first is the finite element theory of crystal plasticity based on microscopic analysis methods in recent years, which characterizes the creep-fatigue evolution process by means of fatigue indicator factors such as accumulated plastic slip band and stored energy dissipation. The second is the theory of continuous damage mechanics that can describe the stages of crack initiation and propagation, which introduces a unified creep-fatigue constitutive model through damage variables to describe the process of damage accumulation to fracture of materials under cyclic loading. The third is popular in the current design criteria, which describes the creep-fatigue behavior through a non-unified constitutive model, and predicts the creep life through the separately calculated creep damage and fatigue damage equations and the phenomenological envelope. However, the three methods have their own shortcomings: the first method is only suitable for describing the stress-strain behavior at the micro level, and is not applicable to large high-temperature parts at the macro level; the second method focuses on describing the creep-fatigue behavior in the stage of crack propagation, and the programming complexity, poor convergence and high computational cost determine that it does not have strong universal applicability. Although the third method has the characteristics of strong operability, it is mostly used to analyze the uniaxial stress-strain behavior under the steady state and is not accurate for creep-fatigue analysis and prediction under complex stress-strain state and complex loading history.
Based on this, it is expected to obtain a new creep-fatigue prediction method which has strong practicability, to better realize the creep-fatigue analysis of geometric discontinuous structures under multiaxial stress-strain state, and obtain more intuitive and accurate results.
The purpose of the present invention is to provide a multiaxial creep-fatigue prediction method based on ABAQUS, which can better realize the creep-fatigue analysis of geometric discontinuous structures under multiaxial stress-strain state, and obtain more intuitive and accurate results. In addition, the creep-fatigue prediction method has strong practicability.
According to the above mentioned purpose of the invention, the present invention proposes a multiaxial creep-fatigue prediction method based on ABAQUS, which comprises steps:
S1: establishing an ABAQUS finite element model, and defining the viscoplastic constitutive equation of the material to be tested in the process of cycling loads by means of the user subroutine UMAT;
S2: determining the model parameters required by the viscoplastic constitutive equation;
S3: establishing the fatigue damage calculation model and creep damage calculation model of the multiaxial stress-strain state of the material to be tested;
S4: establishing an ABAQUS finite element model under the multiaxial stress-strain state, and calculating the stress-strain tensor of each cycle based on the viscoplastic constitutive equation defined by the user subroutine UMAT in S1 and the model parameters in S2;
S5: calculating the equivalent stress and equivalent plastic strain by means of the user subroutine USDFLD, and superimposing the fatigue damage and creep damage of each cycle according to the linear cumulative damage criterion to obtain the crack initiation life of the material to be tested based on the fatigue damage calculation model and creep damage calculation model in S3 in combination with the stress-strain tensor obtained in S4.
In the multiaxial creep-fatigue prediction method based on ABAQUS of the present invention, the user subroutine UMAT in S4 can calculate the stress-strain tensor of each node. The functions of the user subroutine USDFLD set in S5 are as follows: (1) extracting the stress-strain tensor of S4 and performing a scalar calculation to calculate the equivalent stress-strain value; (2) inputting the fatigue damage calculation model and the creep damage calculation model of S3 into the user subroutine USDFLD to obtain the fatigue damage and creep damage of each cycle; the calculation of the above mentioned damage can be based on the equivalent stress-strain; (3) superimposing the damage of each cycle by performing the linear cumulative damage to obtain the crack initiation life.
Further, in the multiaxial creep-fatigue prediction method based on ABAQUS of the present invention, in S2, the material to be tested is subjected to a uniaxial tensile test at a given temperature and uniaxial creep-fatigue tests with different strain amplitudes and holding time at the given temperature, such that the high-temperature tensile curve, the cyclic softening curve, the stress relaxation curve and the hysteresis loop are obtained to determine the model parameters required by the viscoplastic constitutive equation.
Further, in the multiaxial creep-fatigue prediction method based on ABAQUS of the present invention, in S2, the high-temperature tensile curve, the cyclic softening curve, the stress relaxation curve and the hysteresis loop of the ABAQUS finite element model are simulated by trial parameter method, making them consistent with the experimental results. That is to say, the curves obtained by the trial parameter method have a good degree of fitting with the curves obtained by the experiment such that the model parameters required by the viscoplastic constitutive equation are obtained.
Further, in the multiaxial creep-fatigue prediction method based on ABAQUS of the present invention, in S1, the viscoplastic constitutive equation comprises: the master equation of the viscoplastic constitution, the viscoplastic equation of the viscoplastic constitution, the inelastic follow-up strengthening equation for the back stress tensor of the viscoplastic constitution and the isotropic strengthening equation of the viscoplastic constitution.
Further, in the multiaxial creep-fatigue prediction method based on ABAQUS of the present invention, S1 also comprises: S11: describing the master equation of the viscoplastic constitution by using the following formula (1) and formula (2):
In the formulas, εt is the total strain tensor, and εe is the elastic strain tensor, and εin is the inelastic strain tensor, and E is the elastic modulus, and ν is the Poisson's ratio, and σ is the stress tensor, and trσ is the track of the stress tensor, and I is the second-order unit tensor.
S12: describing the viscoplastic equation of the viscoplastic constitution by using the following formula (3), formula (4) and formula (5):
In the formulas, {dot over (ε)}in is the inelastic strain rate tensor, and {dot over (p)} is the cumulative inelastic strain rate, and s is the deflection of the stress tensor, and a is the deflection of the back stress tensor, and J(σ−α) is the Von-Mises stress space distance, and α is the back stress tensor, and K and n are rate-related material parameters, and R is the isotropic deformation resistance, and κ is the initial size of the elastic region, and “:” represents the inner product of the tensor.
S13: describing the inelastic follow-up strengthening equation for the back stress tensor of the viscoplastic constitution by using the following formula (6) and formula (7):
{dot over (α)}i=ζi(⅔ri{dot over (ε)}in−αi{dot over (p)})−γ[J(αi)]m(q)αi (6);
m(q)=ϕ1e−q/ω+ϕ2 (7);
In the formulas, αi represents each part of several back stress tensor parts, and ζi and ri are the material parameters of each part of the back stress tensor, and γ is the material parameter describing the static recovery term, and m(q) is the exponential equation describing the static recovery term, and q is the plastic strain amplitude, and ϕ1, ϕ2 and ω are the three material parameters in the exponential equation, and J(αi) represents the second invariant of the back stress, and e represents the exponential function based on the natural constant, and {dot over (α)}i represents the stress change rate of each part of the back stress tensor.
S14: describing the isotropic strengthening equation of the viscoplastic constitution by using the following formula (8):
{dot over (R)}=b(Q−R){dot over (p)}+H(1+bp){dot over (p)} (8);
In the formula, Q is the asymptotic value of the isotropic resistance softening rapidly in the first stage, and b is the speed parameter close to the asymptotic value, and H is the slope-related parameter of linear softening in the second stage, and p is the cumulative inelastic strain, and {dot over (R)} represents the isotropic enhancement rate.
Further, in the multiaxial creep-fatigue prediction method based on ABAQUS of the present invention, the back stress tensor is divided into 8 parts, namely, α=Σi=18αi.
Further, in the multiaxial creep-fatigue prediction method based on ABAQUS of the present invention, in S3, the fatigue damage calculation model of the multiaxial stress-strain state is:
In the formula, “( )max” represents the maximum fatigue damage factor on the critical plane, and τmax is the maximum shear stress on the critical plane, and is the constant of shear fatigue strength, and Δγ/2 is the shear strain amplitude on the critical plane, and σn,max is the maximum normal stress on the critical plane, and is the constant of fatigue strength, and Δεn/2 is the normal strain amplitude on the critical plane, and G is the shear modulus, and df is the fatigue damage of one cycle, and b0 is the index of fatigue strength, and is the constant of shear fatigue ductility, and c0 is the index of fatigue ductility.
The creep damage calculation model of the multiaxial stress-strain state is:
In the formula, dc is the creep damage of one cycle, and th is the holding time of one cycle, and Z is the elastic following factor, and t represents the time from the start of loading in one cycle, and φ1 is the first linear regression parameter of creep damage, and MDF is the multiaxial ductility factor, and n1 is the second linear regression parameter of creep damage, and wf,trans is the plateau value of the failure strain energy density, and
Further, in the multiaxial creep-fatigue prediction method based on ABAQUS of the present invention, in S4, an ABAQUS finite element model under the multiaxial stress-strain state is established, and boundary conditions and external loads are applied, and the model mesh is divided, so as to get the stress-strain tensor for each cycle of each integration point.
Further, in the multiaxial creep-fatigue prediction method based on ABAQUS of the present invention, S5 further comprises:
S51: extracting the stress tensor and strain tensor of each node in the ABAQUS model by means of the user subroutine USDFLD;
S52: obtaining the equivalent stress and the equivalent plastic strain at each moment and the elastic following factor within the holding time of each cycle through scalar calculations, by means of the user subroutine USDFLD in combination with S51, to finally achieve the fatigue damage and creep damage of each cycle;
S53: calculating the total damage under the multiaxial creep-fatigue condition through the user subroutine USDFLD by using the following formula (11):
D
(n)=Σi=1ndf(i)+dc(f) (11);
In the formula, D(n) is the cumulative total damage of the preceding n cycles, dj(i) is the fatigue damage generated in the i-th cycle, dc(i) is the creep damage generated in the i-th cycle.
Wherein, when the total damage stack rate of a node first reaches the failure value 1, it can be defined as the most dangerous node and the crack initiation life ni can be determined.
It should be noted that, the crack initiation life is characterized by cycle times ni in the technical solution of the present invention.
The multiaxial creep-fatigue prediction method based on ABAQUS of the present invention has the following advantages and beneficial effects:
(1) The multiaxial creep-fatigue prediction method of the present invention defines the viscoplastic constitutive equation of the material to be tested by using the user-based subroutine UMAT, so as to obtain the creep-fatigue behavior under the multiaxial stress-strain state;
(2) The multiaxial creep-fatigue prediction method of the present invention calculates the equivalent stress and equivalent plastic strain by using the user-based subroutine USDFLD, so as to obtain the creep damage, the fatigue damage and the total damage values of each integration point in each cycle;
(3) The multiaxial creep-fatigue prediction method of the present invention has strong intuitiveness, and can intuitively obtain the crack initiation position of the geometric discontinuous structures and the crack initiation life of the position.
These and other features and advantages of this application will become more apparent to those skilled in the art from the detailed description of preferred embodiment. The drawings that accompany the description are described below.
The followings are used to further illustrate the present application with specific embodiments. It should be understood that the following embodiments is only used to explain the present application but not to limit the scope of the present application.
As shown in
S1: establishing an ABAQUS finite element model, and defining the viscoplastic constitutive equation of the material to be tested in the process of cycling loads by means of the user subroutine UMAT;
S2: determining the model parameters required by the viscoplastic constitutive equation;
S3: establishing the fatigue damage calculation model and creep damage calculation model of the multiaxial stress-strain state of the material to be tested;
S4: establishing an ABAQUS finite element model under the multiaxial stress-strain state, and calculating the stress-strain tensor of each cycle based on the viscoplastic constitutive equation defined by the user subroutine UMAT in S1 and the model parameters in S2;
S5: calculating the equivalent stress and equivalent plastic strain by means of the user subroutine USDFLD, and superimposing the fatigue damage and creep damage of each cycle according to the linear cumulative damage criterion to obtain the crack initiation life of the material to be tested based on the fatigue damage calculation model and creep damage calculation model in S3 in combination with the stress-strain tensor obtained in S4.
Wherein, in S2, the material to be tested is subjected to a uniaxial tensile test at a given temperature and uniaxial creep-fatigue tests with different strain amplitudes and loading time at the given temperature, such that the high-temperature tensile curve, the cyclic softening curve, the stress relaxation curve and the hysteresis loop are obtained to determine the model parameters required by the viscoplastic constitutive equation. In addition, the high-temperature tensile curve, the cyclic softening curve, the stress relaxation curve and the hysteresis loop of the ABAQUS finite element model are simulated by trial parameter method to obtain the model parameters required by the viscoplastic constitutive equation.
Wherein, in S1, the viscoplastic constitutive equation comprises: the master equation of the viscoplastic constitution, the viscoplastic equation of the viscoplastic constitution, the inelastic follow-up strengthening equation for the back stress tensor of the viscoplastic constitution and the isotropic strengthening equation of the viscoplastic constitution, which can be obtained by the following steps:
S11: describing the master equation of the viscoplastic constitution by using the following formula (1) and formula (2):
In the formulas, εt is the total strain tensor, and εe is the elastic strain tensor, and εin is the inelastic strain tensor, and E is the elastic modulus, and ν is the Poisson's ratio, and σ is the stress tensor, and trσ is the track of the stress tensor, and I is the second-order unit tensor.
S12: describing the viscoplastic equation of the viscoplastic constitution by using the following formula (3), formula (4) and formula (5):
In the formulas, {dot over (ε)}in is the inelastic strain rate tensor, and {dot over (p)} is the cumulative inelastic strain rate, and s is the deflection of the stress tensor, and a is the deflection of the back stress tensor, and J(σ−α) is the Von-Mises stress space distance, and α is the back stress tensor, and K and n are rate-related material parameters, and R is the isotropic deformation resistance, and κ is the initial size of the elastic region, and “:” represents the inner product of the tensor.
S13: describing the inelastic follow-up strengthening equation for the back stress tensor of the viscoplastic constitution by using the following formula (6) and formula (7):
αi=ζi(⅔ri{dot over (ε)}in−αi{dot over (p)})−γ[J(αi)]m(q)αi (6);
m(q)=ϕ1e−q/ω+ϕ2 (7)
In the formulas, αi represents each part of several back stress tensor parts, and ζi and ri are the material parameters of each part of the back stress tensor, and γ is the material parameter describing the static recovery term, and m(q) is the exponential equation describing the static recovery term, and q is the plastic strain amplitude, and ϕ1, ϕ2 and ω are the three material parameters in the exponential equation, and J(αi) represents the second invariant of the back stress, and e represents the exponential function based on the natural constant, and {dot over (α)}i represents the stress change rate of each part of the back stress tensor.
S14: describing the isotropic strengthening equation of the viscoplastic constitution by using the following formula (8):
{dot over (R)}=b(Q−R){dot over (p)}+H(1+bp){dot over (p)} (8);
In the formula, Q is the asymptotic value of the isotropic resistance softening rapidly in the first stage, and b is the speed parameter close to the asymptotic value, and H is the slope-related parameter of linear softening in the second stage, and p is the cumulative inelastic strain, and R represents the isotropic enhancement rate.
It should be noted that the back stress tensor is divided into 8 parts in the above steps, namely, α=Σi=18αi.
And in S3, the fatigue damage calculation model of the multiaxial stress-strain state is:
In the formula, “( )max” represents the maximum fatigue damage factor on the critical plane, and τmax is the maximum shear stress on the critical plane, and {dot over (τ)}f is the constant of shear fatigue strength, and Δγ/2 is the shear strain amplitude on the critical plane, and σn,max is the maximum normal stress on the critical plane, and {dot over (σ)}f is the constant of fatigue strength, and Δεn/2 is the normal strain amplitude on the critical plane, and G is the shear modulus, and df is the fatigue damage of one cycle, and b0 is the index of fatigue strength, and is the constant of shear fatigue ductility, and c0 is the index of fatigue ductility.
The creep damage calculation model of the multiaxial stress-strain state is:
In the formula, dc is the creep damage of one cycle, and th is the holding time of one cycle, and Z is the elastic following factor, and t represents the time from the start of loading in one cycle, and φ1 is the first linear regression parameter of creep damage, and MDF is the multiaxial ductility factor, and n1 is the second linear regression parameter of creep damage, and wf,trans is the plateau value of the failure strain energy density, and
While in S4, an ABAQUS finite element model under the multiaxial stress-strain state is established, and boundary conditions and external loads are applied, and the model mesh is divided, so as to get the stress-strain tensor for each cycle of each integration point.
In this embodiment, S5 can further comprise:
S51: extracting the stress tensor and strain tensor of each node in the ABAQUS model by means of the user subroutine USDFLD;
S52: obtaining the equivalent stress and the equivalent plastic strain at each moment and the elastic following factor within the holding time of each cycle through scalar calculations, by means of the user subroutine USDFLD in combination with S51, to finally achieve the fatigue damage and creep damage of each cycle;
S53: calculating the total damage under the multiaxial creep-fatigue condition through the user subroutine USDFLD by using the following formula (11):
D
(n)=Σi=1ndf(i)+dc(i) (11);
In the formula, D(n) is the cumulative total damage of the preceding n cycles, df(i) is the fatigue damage generated in the i-th cycle, dc(i) is the creep damage generated in the i-th cycle.
Wherein, when the total damage stack rate of a node first reaches the failure value 1, it can be defined as the most dangerous node and the crack initiation life ni can be determined.
In order to better illustrate the prediction effect of the multiaxial creep-fatigue prediction method based on ABAQUS of the present invention, a unilateral notched specimen with a notch radius of 8 mm will be used for verification.
The material of the unilateral notched specimen used in the verification is the super alloy GH4169 with high-temperature nickel base, and the creep-fatigue test is carried out in an air environment of 650° C. During the test, the sum of external loads applied at both ends of the specimen is the overall strain control. The weakest part of the notch root is in a state of multiaxial stress-strain due to the geometric discontinuity of the unilateral notched specimen. Prior to this, a uniaxial tensile test in an air environment of 650° C. and uniaxial creep-fatigue tests with different strain amplitudes and holding time under this environment are required. The obtained test results are used to determine the material parameters required by the viscoplastic constitutive equations of formulas (1) to (8).
The simulation result of the uniaxial tensile test is adjusted by trial parameter method, so that it can be in good agreement with the uniaxial tensile test.
As shown in
As shown in
As shown in
At the same time, the exponential equation of the static recovery term in formula (7) is fitted, and the fitting result is shown in
As shown in
In an embodiment of the present invention, the selected data is: the total strain range of is 1.0%, the holding time at the maximum strain in each cycle is 3600 s, and the unilateral notched creep-fatigue test is in an air environment of 650° C. The creep-fatigue cracks originate on the subsurface of the notch root, and the crack initiation life is 76 cycles.
As shown in
It can be seen from
With the aid of the creep-fatigue damage interactive map, the most dangerous integration points of the subsurface near the notch root can be traced. As shown in
It should be noted that the curve XIII in
In another embodiment of the present invention, the selected data is: the total strain range of is 1.0%, the holding time at the maximum strain in each cycle is 60 s, and the unilateral notched creep-fatigue test is in an air environment of 650° C. The creep-fatigue cracks originate on the surface of the notch root, and the crack initiation life is 480 cycles.
As shown in
It can be seen from
With the aid of the creep-fatigue damage interactive map, the most dangerous integration points of the subsurface near the notch root can be traced. As shown in
It should be noted that the curve XVIII in
In summary, it can be seen that the multiaxial creep-fatigue prediction method of the present invention defines the viscoplastic constitutive equation of the material to be tested by using the user-based subroutine UMAT, so as to obtain the creep-fatigue behavior under the multiaxial stress-strain state.
In addition, the multiaxial creep-fatigue prediction method of the present invention calculates the equivalent stress and equivalent plastic strain by using the user-based subroutine USDFLD, so as to obtain the creep damage, the fatigue damage and the total damage values of each integration point in each cycle.
Moreover, the multiaxial creep-fatigue prediction method of the present invention has strong intuitiveness, and can intuitively obtain the crack initiation position of the geometric discontinuous structures and the crack initiation life of the position.
It should be noted that the part of prior art in the protection scope of the present invention is not limited to the embodiments given in this application document, and all prior art that is not inconsistent with the solution of the present invention, including but is not limited to the prior patent documents, prior publications, prior public use, etc., can all be incorporated in the protection scope of the present invention.
In addition, the combination of various technical features in this application is not limited to the combination described in the claims or described in the specific embodiments. All technical features described in this application can be freely combined or incorporated in any way, unless contradictions arise between each other.
It should also be noted that the above-listed embodiments are only specific embodiments of the present invention. Obviously, the present invention is not limited to the above embodiments, and the subsequent similar changes or modifications can be directly derived from or easily associated with the disclosure of the present invention by those skilled in the art, and should fall within the protection scope of the present invention.
Number | Date | Country | Kind |
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201910026871.3 | Jan 2019 | CN | national |
This application is a national application of PCT/CN2019/114718, filed on Oct. 31, 2019 and claims the priority of it. The contents of PCT/CN2019/114718 are all hereby incorporated by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/CN2019/114718 | 10/31/2019 | WO |
Number | Date | Country | |
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20220026326 A1 | Jan 2022 | US |