A Coupled Thermal–Hydrological–Mechanical Damage Model and Its Numerical Simulations of Damage Evolution in APSE

In order to establish the relation between acoustic emission parameter and rock mechanical damage mechanism, as well as to better figure out landscape limestone damage and deformation influenced by uniaxial compression, MTS815 rock mechanical electro-hydraulic servo test system and 8CHSPCI-2 acoustic emission and detection system are applied to implement a test and research on damage evolution of limestone under uniaxial compression and the corresponding acoustic emission feature. On this basis, the acoustic emission feature of limestone under uniaxial compression is analyzed. Moreover, based on the damage variable of normalized accumulated emission ringing count, the uniaxial compression limestone damage model based on acoustic emission feature is established, and the damage evolution curve and equation of limestone is figured out as well. Shown by the research, acoustic emission information reflects the internal damage of limestone, and is closely related with densification of inner original fracture, as well as emerging, developing, and merging of new fractures. The acoustic emission feature of limestone perfectly describes its deformation and damage evolution.

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Enhancement of Lemaitre Model to Predict Cracks at Low and Negative Triaxialities in Sheet Metal Forming

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.639.427 ◽

2015 ◽

Vol 639 ◽

pp. 427-434 ◽

Cited By ~ 4

Author(s):

Kerim Isik ◽

Maria Doig ◽

Helmut Richter ◽

Till Clausmeyer ◽

A. Erman Tekkaya

Keyword(s):

Damage Evolution ◽

Damage Model ◽

Mechanical Damage ◽

High Strength Steels ◽

High Strength ◽

High Energy ◽

Weighting Factor ◽

Forming Limit ◽

Model Parameters ◽

Shear Stresses

Advanced high strength steels are still one of the best alternatives for light weight design in the automotive industry. Due to their good performances like high strength and high energy absorption, those steel grades are excellent for body in white components. Because of their restricted ductility, which sometimes leads to the formation of cracks without or low necking during forming operations, conventional forming limit diagrams may fall short. As a remedy, an enhanced variant of the Lemaitre continuum mechanical damage model (CDM) is presented in this work.Previous model extensions of the Lemaitre model improved the damage prediction for the shear and compression dominated stress states by introducing an additional weighting factor for the influence of compression on damage evolution, the so called crack closure parameter h. However, the possible range of the fracture behavior predicted by such models for low and negative stress triaxialities is limited. In this work, the Lemaitre CDM has been enhanced by considering the maximal shear stress to predict the fracture occurrence under shear. Previous models for the effect of void closure on damage evolution are reviewed and a novel model enhancement taking into account the maximal shear stresses is described. The determination of the damage model parameters is presented for a dual phase steel. For this particular material, the response of model enhancement on the failure prediction is discussed for a test part.

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A Modified Phase-Field Damage Model for Metal Plasticity at Finite Strains: Numerical Development and Experimental Validation

Metals ◽

10.3390/met11010047 ◽

2020 ◽

Vol 11 (1) ◽

pp. 47

Author(s):

Jelena Živković ◽

Vladimir Dunić ◽

Vladimir Milovanović ◽

Ana Pavlović ◽

Miroslav Živković

Keyword(s):

Phase Field ◽

Damage Evolution ◽

Deformation Gradient ◽

Damage Model ◽

Steel Structures ◽

Plasticity Model ◽

Metal Plasticity ◽

Damage And Fracture ◽

Von Mises ◽

Von Mises Plasticity

Steel structures are designed to operate in an elastic domain, but sometimes plastic strains induce damage and fracture. Besides experimental investigation, a phase-field damage model (PFDM) emerged as a cutting-edge simulation technique for predicting damage evolution. In this paper, a von Mises metal plasticity model is modified and a coupling with PFDM is improved to simulate ductile behavior of metallic materials with or without constant stress plateau after yielding occurs. The proposed improvements are: (1) new coupling variable activated after the critical equivalent plastic strain is reached; (2) two-stage yield function consisting of perfect plasticity and extended Simo-type hardening functions. The uniaxial tension tests are conducted for verification purposes and identifying the material parameters. The staggered iterative scheme, multiplicative decomposition of the deformation gradient, and logarithmic natural strain measure are employed for the implementation into finite element method (FEM) software. The coupling is verified by the ‘one element’ example. The excellent qualitative and quantitative overlapping of the force-displacement response of experimental and simulation results is recorded. The practical significances of the proposed PFDM are a better insight into the simulation of damage evolution in steel structures, and an easy extension of existing the von Mises plasticity model coupled to damage phase-field.

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An improved nonlinear damage model of rocks considering initial damage and damage evolution

International Journal of Damage Mechanics ◽

10.1177/1056789520909531 ◽

2020 ◽

Vol 29 (7) ◽

pp. 1117-1137 ◽

Cited By ~ 3

Author(s):

Wenlin Feng ◽

Chunsheng Qiao ◽

Shuangjian Niu ◽

Zhao Yang ◽

Tan Wang

Keyword(s):

Damage Evolution ◽

Least Squares Method ◽

Damage Model ◽

Creep Damage ◽

Secondary Creep ◽

Nonlinear Creep ◽

Creep Failure ◽

Initial Damage ◽

Nonlinear Damage Model ◽

Creep Damage Model

The experimental results show that the creep properties of the rocks are affected by the initial damage, and the damage evolution also has a significant impact on the time-dependent properties of the rocks during the creep. However, the effects of the initial damage and the damage evolution are seldom considered in the current study of the rocks' creep models. In this paper, a new nonlinear creep damage model is proposed based on the multistage creep test results of the sandstones with different damage degrees. The new nonlinear creep damage model is improved based on the Nishihara model. The influences of the initial damage and the damage evolution on the components in the Nishihara model are considered. The creep damage model can not only describe the changes in three creep stages, namely, the primary creep, the secondary creep, and the tertiary creep, but also reflect the influence of the initial damage and the damage evolution on creep failure. The nonlinear least squares method is used to determine the parameters in the nonlinear creep damage model. The consistency between the experimental data and the predicted results indicates the applicability of the nonlinear damage model to accurately predict the creep deformation of the rocks with initial damage.

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Damage Evolution and Failure Modeling in Unidirectional Graphite/Epoxy Composite

10.1115/imece2001/ad-25302 ◽

2001 ◽

Author(s):

G. P. Tandon ◽

R. Y. Kim

Keyword(s):

Damage Evolution ◽

Failure Modes ◽

Epoxy Composite ◽

Damage Model ◽

Tensile Loading ◽

Unidirectional Composite ◽

Concentric Cylinder ◽

Failure Modeling ◽

Stress Levels

Abstract A study is conducted to examine and predict the micromechanical failure modes in a unidirectional composite when subjected to tensile loading parallel to the fibers. Experimental observations are made at some selected stress levels to identify the initiation and growth of micro damage during loading. The axisymmetric damage model of a concentric cylinder is then utilized to postulate and analyze some failure scenarios.

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Ductile Damage Model Based On Void Growth Analysis for Application to Ductile Crack Growth Simulation

Journal of Pressure Vessel Technology ◽

10.1115/1.4050774 ◽

2021 ◽

Author(s):

Takehisa Yamada ◽

Mitsuru Ohata

Keyword(s):

Crack Growth ◽

Void Growth ◽

Damage Evolution ◽

Damage Model ◽

Crack Growth Resistance ◽

Growth Behavior ◽

Ductile Crack ◽

Growth Simulation ◽

Crack Growth Simulation ◽

Ductile Crack Growth

Abstract The aim of this study is to propose damage model on the basis of the mechanism for ductile fracture related to void growth and to confirm the applicability of the proposed model to ductile crack growth simulation for steel. To figure out void growth behavior, elasto-plastic finite element analyses using unit cell model with an initial void were methodically performed. From the results of those analyses, it was evident that the relationships between normalized void volume fraction and normalized strain by each critical value corresponding to crack initiation were independent of stress-strain relationship of material and stress triaxiality state. Based on this characteristic associated with void growth, damage evolution law was derived. Then, using the damage evolution law, simple and phenomenological ductile damage model reflecting void growth behavior and ductility of material was proposed. To confirm the validation and application of proposed damage model, the damage model was implemented in finite element models and ductile crack growth resistance was simulated for cracked components were performed. Then, the simulated results were compared with experimental ones and it was found that the proposed damage model could accurately predict ductile crack growth resistance and was applicable to ductile crack growth simulation.

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Numerical simulations of crashworthiness performance of multi-cell structures considering damage evolution criteria

ITM Web of Conferences ◽

10.1051/itmconf/20171507009 ◽

2017 ◽

Vol 15 ◽

pp. 07009

Author(s):

Quirino Estrada ◽

Dariusz Szwedowicz ◽

Alejandro Rodriguez-Mendez ◽

Jesús Silva-Aceves ◽

Javier S. Castro ◽

...

Keyword(s):

Numerical Simulations ◽

Damage Evolution ◽

Cell Structures

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Failure Predictions for DP Steel Cross-die Test using Anisotropic Damage

International Journal of Damage Mechanics ◽

10.1177/1056789511407646 ◽

2011 ◽

Vol 21 (5) ◽

pp. 713-754 ◽

Cited By ~ 18

Author(s):

M. S. Niazi ◽

H. H. Wisselink ◽

T. Meinders ◽

J. Huétink

Keyword(s):

Strain Rate ◽

Damage Evolution ◽

Damage Model ◽

Anisotropic Damage ◽

Continuum Damage ◽

Anisotropic Plasticity ◽

Continuum Damage Model ◽

Damage Models ◽

Isotropic Damage ◽

Failure Predictions

The Lemaitre's continuum damage model is well known in the field of damage mechanics. The anisotropic damage model given by Lemaitre is relatively simple, applicable to nonproportional loads and uses only four damage parameters. The hypothesis of strain equivalence is used to map the effective stress to the nominal stress. Both the isotropic and anisotropic damage models from Lemaitre are implemented in an in-house implicit finite element code. The damage model is coupled with an elasto-plastic material model using anisotropic plasticity (Hill-48 yield criterion) and strain-rate dependent isotropic hardening. The Lemaitre continuum damage model is based on the small strain assumption; therefore, the model is implemented in an incremental co-rotational framework to make it applicable for large strains. The damage dissipation potential was slightly adapted to incorporate a different damage evolution behavior under compression and tension. A tensile test and a low-cycle fatigue test were used to determine the damage parameters. The damage evolution was modified to incorporate strain rate sensitivity by making two of the damage parameters a function of strain rate. The model is applied to predict failure in a cross-die deep drawing process, which is well known for having a wide variety of strains and strain path changes. The failure predictions obtained from the anisotropic damage models are in good agreement with the experimental results, whereas the predictions obtained from the isotropic damage model are slightly conservative. The anisotropic damage model predicts the crack direction more accurately compared to the predictions based on principal stress directions using the isotropic damage model. The set of damage parameters, determined in a uniaxial condition, gives a good failure prediction under other triaxiality conditions.

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A Strain Rate-Dependent Damage Evolution Model for Concrete Based on Experimental Results

Advances in Civil Engineering ◽

10.1155/2021/6643263 ◽

2021 ◽

Vol 2021 ◽

pp. 1-8

Author(s):

Bin Xu ◽

Xiaoyan Lei ◽

P. Wang ◽

Hui Song

Keyword(s):

Strain Rate ◽

Uniaxial Compression ◽

Damage Evolution ◽

Damage Model ◽

Evolution Model ◽

Experimental Results ◽

Strain Rates ◽

Compression Tests ◽

Stress Strain ◽

Actual Damage

There are various definitions of damage variables from the existing damage models. The calculated damage value by the current methods still could not well correspond to the actual damage value. Therefore, it is necessary to establish a damage evolution model corresponding to the actual damage evolution. In this paper, a strain rate-sensitive isotropic damage model for plain concrete is proposed to describe its nonlinear behavior. Cyclic uniaxial compression tests were conducted on concrete samples at three strain rates of 10−3s−1, 10−4s−1, and 10−5s−1, respectively, and ultrasonic wave measurements were made at specified strain values during the loading progress. A damage variable was defined using the secant and initial moduli, and concrete damage evolution was then studied using the experimental results of the cyclic uniaxial compression tests conducted at the different strain rates. A viscoelastic stress-strain relationship, which considered the proposed damage evolution model, was presented according to the principles of irreversible thermodynamics. The model results agreed well with the experiment and indicated that the proposed damage evolution model can accurately characterize the development of macroscopic mechanical weakening of concrete. A damage-coupled viscoelastic constitutive relationship of concrete was recommended. It was concluded that the model could not only characterize the stress-strain response of materials under one-dimensional compressive load but also truly reflect the degradation law of the macromechanical properties of materials. The proposed damage model will advance the understanding of the failure process of concrete materials.

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A Rational Methodology for Determination of Service Life for a Delayed Coker Drum

Volume 3: Design and Analysis ◽

10.1115/pvp2015-45028 ◽

2015 ◽

Author(s):

John J. Aumuller ◽

Jie Chen ◽

Vincent A. Carucci

Keyword(s):

Service Life ◽

Low Cycle Fatigue ◽

Damage Model ◽

Mechanical Damage ◽

Damage Mechanism ◽

Modern Trend ◽

Cold Spot ◽

Chromium Alloy ◽

Cycle Fatigue ◽

Service Environment

Delayed unit coker drums operate in a severe service environment that precludes long term reliability due to excessive shell bulging and cracking of shell joint and shell to skirt welds. Thermal fatigue is recognized as the leading damage mechanism and past work has provided an idealized description of the thermo-mechanical mechanism via local hot and cold spot formation to quantify a lower bound life estimate for shell weld failure. The present work extends this idealized thermo-mechanical damage model by evaluating actual field data to determine a potential upper bound life estimate. This assessment also provides insight into practical techniques for equipment operators to identify design and operational opportunities to extend the service life of coke drums for their specific service environments. A modern trend of specifying higher chromium and molybdenum alloy content for drum shell material in order to improve low cycle fatigue strength is seen to be problematic; rather, the use of lower alloy materials that are generally described as fatigue tough materials are better suited for the high strain-low cycle fatigue service environment of coke drums. Materials such as SA 204 C (C – ½ Mo) and SA 302 B (C – Mn – ½ Mo) or SA 302 C (C – Mn – ½ Mo – ½ Ni) are shown to be better candidates for construction in lieu of low chromium alloy steel materials such as SA 387 grades P11 (1¼ Cr – ½ Mo), P12 (1 Cr – ½ Mo), P22 (2¼ Cr – 1 Mo) and P21 (3 Cr – 1 Mo).

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