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Journal articles on the topic 'Cyclic plasticity model'

Author: Grafiati
Published: 3 June 2025
Last updated: 31 July 2025

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1

Chiang, Dar-Yun. "A Phenomenological Model for Cyclic Plasticity." Journal of Engineering Materials and Technology 119, no. 1 (1997): 7–11. http://dx.doi.org/10.1115/1.2805979.

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A phenomenological model is proposed for cyclic plasticity based on the concept of distributed elements, which is capable of reflecting microstructural behavior of real materials under multiaxial cyclic loading conditions. By investigating the detailed behavior of the model, various important phenomena and effects of materials in cyclic plasticity can be elucidated. Generalization of the model is also done to include cyclic hardening effects. A thorough understanding of these complicated response mechanisms and material properties provides useful insight and guidelines for validating analytica
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2

Borja, Ronaldo I., and Alexander P. Amies. "Multiaxial Cyclic Plasticity Model for Clays." Journal of Geotechnical Engineering 120, no. 6 (1994): 1051–70. http://dx.doi.org/10.1061/(asce)0733-9410(1994)120:6(1051).

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3

McDowell, David L. "Simple Experimentally Motivated Cyclic Plasticity Model." Journal of Engineering Mechanics 113, no. 3 (1987): 378–97. http://dx.doi.org/10.1061/(asce)0733-9399(1987)113:3(378).

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4

Yoshida, Fusahito. "A constitutive model of cyclic plasticity." International Journal of Plasticity 16, no. 3-4 (2000): 359–80. http://dx.doi.org/10.1016/s0749-6419(99)00058-3.

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5

Sajjad, Hafiz Muhammad, Stefanie Hanke, Sedat Güler, Hamad ul Hassan, Alfons Fischer, and Alexander Hartmaier. "Modelling Cyclic Behaviour of Martensitic Steel with J2 Plasticity and Crystal Plasticity." Materials 12, no. 11 (2019): 1767. http://dx.doi.org/10.3390/ma12111767.

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In order to capture the stress-strain response of metallic materials under cyclic loading, it is necessary to consider the cyclic hardening behaviour in the constitutive model. Among different cyclic hardening approaches available in the literature, the Chaboche model proves to be very efficient and convenient to model the kinematic hardening and ratcheting behaviour of materials observed during cyclic loading. The purpose of this study is to determine the material parameters of the Chaboche kinematic hardening material model by using isotropic J2 plasticity and micromechanical crystal plastic
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6

Ohno, N., and Y. Kachi. "A Constitutive Model of Cyclic Plasticity for Nonlinear Hardening Materials." Journal of Applied Mechanics 53, no. 2 (1986): 395–403. http://dx.doi.org/10.1115/1.3171771.

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A constitutive model is proposed for cyclic plasticity of nonlinear hardening materials. The concept of a cyclic nonhardening range, which enables us to describe the dependence of cyclic hardening on the amplitude of cyclic straining or stressing, is employed together with the idea of a two-surface plasticity model. Results of the proposed model are compared with experiments of 304 and 316 stainless steels in several cases of cyclic loading in which mean strain is zero or nonzero and strain limits are fixed or variable. Thus, it is shown that the model successfully describes both the cyclic ha
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7

Šumarac, D., Z. Perović, D. Vatić, T. Curić, I. Nurković, and M. Cao. "Preisach Mathematical Model of Hysteresis." Scientific Publications of the State University of Novi Pazar Series A: Applied Mathematics, Informatics and mechanics 15, no. 2 (2023): 61–72. http://dx.doi.org/10.46793/spsunp2302.061s.

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Hysteretic nonlinear phenomena occur in many physical processes: ferromagnetism, adsorption, cyclic plasticity in mechanics, phase transformations, economics, etc. It is characterized by the fact that the same instantaneous values of input can give different outputs depending on the history of the input applied. It means that the relationship is not only nonlinear but also multivalued making it very difficult to model and control. In this paper, accent was given to the application to mechanics i.e. to cyclic plasticity of trusses.
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8

Halama, Radim, Jaromír Fumfera, Petr Gál, Tadbhagya Kumar, and Alexandros Markopoulos. "Modelling the Strain Range Dependent Cyclic Hardening of SS304 and 08Ch18N10T Stainless Steel with a Memory Surface." Metals 9, no. 8 (2019): 832. http://dx.doi.org/10.3390/met9080832.

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This paper deals with the development of a cyclic plasticity model suitable for predicting the strain range dependent behavior of austenitic steels. The proposed cyclic plasticity model uses the virtual back-stress variable corresponding to a cyclically stable material under strain control. This new internal variable is defined by means of a memory surface introduced in the stress space. The linear isotropic hardening rule is also superposed. First, the proposed model was validated on experimental data published for the SS304 material (Kang et al. Constitutive modeling of strain range dependen
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9

Iai, Susumu, Yasuo Matsunaga, and Tomohiro Kameoka. "Strain Space Plasticity Model for Cyclic Mobility." Soils and Foundations 32, no. 2 (1992): 1–15. http://dx.doi.org/10.3208/sandf1972.32.2_1.

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10

Xu, Biqiang, and Yanyao Jiang. "A cyclic plasticity model for single crystals." International Journal of Plasticity 20, no. 12 (2004): 2161–78. http://dx.doi.org/10.1016/j.ijplas.2004.05.003.

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11

Kenk, K. "A MODEL FOR CYCLIC SHEAR IN PLASTICITY." Proceedings of the Estonian Academy of Sciences. Engineering 6, no. 3 (2000): 186. http://dx.doi.org/10.3176/eng.2000.3.02.

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12

Wang, Xigang, Liling Jin, Yang Xing, and Mingfu Fu. "Fuzzy Plastic Constitutive Model and Its Application to Subgrade." Advances in Civil Engineering 2021 (September 23, 2021): 1–18. http://dx.doi.org/10.1155/2021/3005467.

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The subgrade of a road is subjected to cyclic loading and unloading under the action of traffic loads. To study this mechanical response, the plastic membership function was introduced into the modified Cambridge model, and thus, the fuzzy plastic Cambridge constitutive model was obtained. With the continuous evolution of the plastic membership function from 0 to 1, the fuzzy plastic Cambridge constitutive model continuously transitions the plastic properties inside and outside the initial yield surface. The evolution of the plastic membership function can replace the complex hardening law. Th
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13

Schenk, T., T. Seifert, and H. Brehm. "A Simple Analogous Model for the Determination of Cyclic Plasticity Parameters of Thin Wires to Model Wire Drawing." Journal of Engineering Materials and Technology 129, no. 3 (2007): 488–95. http://dx.doi.org/10.1115/1.2744436.

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Cyclic stress-strain measurements have to be performed in order to determine the cyclic plasticity parameters of material models describing the Bauschinger effect. For thin wires, the performance of tensile tests is often not possible due to necking of the specimen on exceeding the yield stress, whereas compression tests are uncritical. This paper presents an approach to determine the cyclic plasticity parameters by performance of compression tests for wires before and after drawing. Here, a simple analogous model is used instead of finite-element (FE) simulations. This approach has been appli
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14

HAMADA, Kazuaki, Kenji YOSHIYAMA, Takeshi UEMORI, and Fusahito YOSHIDA. "Numerical Simulation of Cyclic Plasticity by Finite Element Crystal Plasticity Model." Proceedings of Conference of Chugoku-Shikoku Branch 2004.42 (2004): 119–20. http://dx.doi.org/10.1299/jsmecs.2004.42.119.

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15

Tu, Wen Feng, Xiao Gui Wang, and Zeng Liang Gao. "Modeling of Fatigue Crack Growth Based on Two Cyclic Plasticity Models." Advanced Materials Research 44-46 (June 2008): 111–18. http://dx.doi.org/10.4028/www.scientific.net/amr.44-46.111.

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Based on two different cyclic plasticity models, fatigue crack growth for 16MnR steel specimens is simulated by using the same multi-axial fatigue damage criterion. The first plasticity model is the Jiang and Sehitoglu model and the second plasticity model is the simple nonlinear kinematic hardening model. The elastic-plastic stress-strain field near the crack tip is obtained respectively by using the two plasticity models. According to the same fatigue criterion, different fatigue damage near the crack tip is determined on the basis of stress-strain responses. The first plasticity model can a
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16

Babaei, A., MM Mashhadi, and F. Mehri Sofiani. "Crystal plasticity modeling of grain refinement in aluminum tubes during tube cyclic expansion-extrusion." Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications 232, no. 6 (2016): 481–94. http://dx.doi.org/10.1177/1464420716634745.

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In the present study, a crystal plasticity finite element model was developed for simulating the microstructure evolution and grain refinement during tube cyclic expansion-extrusion as a severe plastic deformation method for tubular materials. A new approach was proposed for extracting the real deformation history of a representative volume element during severe plastic deformation methods. The deformation history of a representative volume element during four cycles of tube cyclic expansion-extrusion was extracted by the proposed approach. Then, in a crystal plasticity finite element model, t
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17

Su, Luo Chuan, Jian Guo Li, Wei Xu Zhang, and Tie Jun Wang. "Effect of Temperature-Dependent Properties on Cyclic Plasticity of Bond Coat in Thermal Barrier Systems." Key Engineering Materials 535-536 (January 2013): 193–96. http://dx.doi.org/10.4028/www.scientific.net/kem.535-536.193.

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The accumulation of cyclic plasticity in bond coat (BC) is a key factor controlling the displacement instability of the thermally grown oxide (TGO) in thermal barrier systems. The cyclic plasticity is affected by the component material properties, which vary observably with the service temperature. A numerical model with the behavior of creep and thermal growth in TGO under thermal cycling is used to explore the effect of temperature-dependent properties on cyclic plasticity in BC. The influence of temperature-dependent Young's modulus of thermal barrier coating (TBC), TGO, BC and substrate, t
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18

Obataya, Yoichi, and Takaya Kato. "Multiple Strata Cyclic Plasticity Model for Polycrystalline Metal." Key Engineering Materials 177-180 (April 2000): 29–34. http://dx.doi.org/10.4028/www.scientific.net/kem.177-180.29.

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19

Barsanti, M., M. Beghini, M. Loffredo, G. Macoretta, B. D. Monelli, and A. Bagattini. "Multiaxial cyclic plasticity model including elastic modulus variation." IOP Conference Series: Materials Science and Engineering 1038, no. 1 (2021): 012079. http://dx.doi.org/10.1088/1757-899x/1038/1/012079.

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20

Tsutsumi, Seiichiro, Masahiro Toyosada, and Fionn Dunne. "Phenomenological cyclic plasticity model for high cycle fatigue." Procedia Engineering 2, no. 1 (2010): 139–46. http://dx.doi.org/10.1016/j.proeng.2010.03.015.

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21

Krenk, S., and L. Tidemann. "A compact cyclic plasticity model with parameter evolution." Mechanics of Materials 113 (October 2017): 57–68. http://dx.doi.org/10.1016/j.mechmat.2017.07.012.

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22

Ristinmaa, M. "Cyclic plasticity model using one yield surface only." International Journal of Plasticity 11, no. 2 (1995): 163–81. http://dx.doi.org/10.1016/0749-6419(94)00044-1.

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23

Halama, Radim, Alexandros Markopoulos, Roland Jančo, and Matěj Bartecký. "Implementation of MAKOC cyclic plasticity model with memory." Advances in Engineering Software 113 (November 2017): 34–46. http://dx.doi.org/10.1016/j.advengsoft.2016.10.009.

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24

Manzari, Majid T., and Rung Prachathananukit. "On integration of a cyclic soil plasticity model." International Journal for Numerical and Analytical Methods in Geomechanics 25, no. 6 (2001): 525–49. http://dx.doi.org/10.1002/nag.140.

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25

De Jesus, Abı´lio M. P., Alfredo S. Ribeiro, and Anto´nio A. Fernandes. "Finite Element Modeling of Fatigue Damage Using a Continuum Damage Mechanics Approach." Journal of Pressure Vessel Technology 127, no. 2 (2005): 157–64. http://dx.doi.org/10.1115/1.1858927.

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In this paper, a fatigue model formulated in the framework of the continuum damage mechanics (CDM) is presented. The model is based on an explicit definition of fatigue damage and introduces a kinematic damage differential equation formulated directly as a function of the number of cycles and the stress cycle parameters. The model is initially presented for uniaxial problems, which facilitates the identification of its constants. An extension of the fatigue model to multiaxial problems is also proposed. This model was implemented in a nonlinear finite element code in conjunction with a constit
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26

ÇAYLAK, Melih, Toros Arda AKŞEN, and Mehmet FIRAT. "Evaluating the effectiveness of combined hardening models to determine the behavior of a plate with a hole under combined loadings." European Mechanical Science 6, no. 2 (2022): 97–104. http://dx.doi.org/10.26701/ems.1051057.

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Geometrical discontinuities in a material such as holes and notches on machine elements are called as critical regions due to the stress concentrations. They are the potential failure initiation locations Therefore, researchers put significant effort on the prediction of the material response in these discontinuities under repetitive loadings. 
 Cyclic plasticity is concerned with the nonlinear material response under cyclic loadings. In this study, numerical cyclic stress – strain response of a plate with a hole was evaluated under the combined loadings which are cyclic bending and tensi
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27

Zhang, Rui, and Sun Yi. "Cyclic Plasticity and Fatigue Crack Growth." Key Engineering Materials 324-325 (November 2006): 603–6. http://dx.doi.org/10.4028/www.scientific.net/kem.324-325.603.

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The relation between material’s cyclic plastic behavior and fatigue crack growth is investigated. The present model is proposed on the dislocation-free zone (DFZ) theory. A cohesive zone theory is developed to determine the stress field of the DFZ and the value of J-integer under cyclic loading. The crack growth criterion is proposed based on J-integral. The calculated curve of fatigue crack growth rate da/dN is agreement with the general propagation pattern and the predicted threshold accords with the experiment threshold well. It is found that the near threshold characteristics are most dete
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28

Kourousis, Kyriakos I. "A Cyclic Plasticity Model for Advanced Light Metal Alloys." Applied Mechanics and Materials 391 (September 2013): 3–8. http://dx.doi.org/10.4028/www.scientific.net/amm.391.3.

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Advanced light metals have recently attracted the interest of the aerospace and automotive industry. The need for accurate description of their cyclic inelastic response under various loading histories becomes increasingly important. Cyclic mean stress relaxation and ratcheting are two of the phenomena under investigation. A combined kinematic isotropic hardening model is implemented for the simulation of the behavior of Aluminum and Titanium alloys in uniaxial mean stress relaxation and ratcheting. The obtained results indicate that the model can perform well in these cases. This preliminary
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29

Tu, Yuhui, Seán B. Leen, and Noel M. Harrison. "A high-fidelity crystal-plasticity finite element methodology for low-cycle fatigue using automatic electron backscatter diffraction scan conversion: Application to hot-rolled cobalt–chromium alloy." Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications 235, no. 8 (2021): 1901–24. http://dx.doi.org/10.1177/14644207211010836.

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The common approach to crystal-plasticity finite element modeling for load-bearing prediction of metallic structures involves the simulation of simplified grain morphology and substructure detail. This paper details a methodology for predicting the structure–property effect of as-manufactured microstructure, including true grain morphology and orientation, on cyclic plasticity, and fatigue crack initiation in biomedical-grade CoCr alloy. The methodology generates high-fidelity crystal-plasticity finite element models, by directly converting measured electron backscatter diffraction metal micro
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30

Fincato, Riccardo, Senchiro Tsutsumi, and Kenjiro Terada. "2912 ON CONVERGENCE RATE OF CUTTING-PLANE ALGORITHM IN NUMERICALANALYSES OF A CYCLIC PLASTICITY MODEL." Proceedings of The Computational Mechanics Conference 2013.26 (2013): _2912–1_—_2912–3_. http://dx.doi.org/10.1299/jsmecmd.2013.26._2912-1_.

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31

Mo, Yafei, Rou Du, and Xiaoming Liu. "Effect of mixed plastic hardening on the cyclic contact between a sphere and a rigid flat." Journal of Physics: Conference Series 2285, no. 1 (2022): 012018. http://dx.doi.org/10.1088/1742-6596/2285/1/012018.

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Abstract This paper studies the effect of mixed plasticity mode (combined with isotropic and kinematic hardening law) on the cyclic contact between an elastic-plastic sphere and a rigid flat. Assuming power-law hardening with different levels of mixed plasticity for the sphere, we derived a semi-analytical expression of load versus interference during the first loading and unloading process. During cyclic loading, our results indicate that the isotropic plasticity model shows no variation of residual interference, while kinematic plasticity has the cyclic effect on the residual interference, a
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32

Srnec Novak, Jelena, Francesco De Bona, and Denis Benasciutti. "An Isotropic Model for Cyclic Plasticity Calibrated on the Whole Shape of Hardening/Softening Evolution Curve." Metals 9, no. 9 (2019): 950. http://dx.doi.org/10.3390/met9090950.

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This work presents a new isotropic model to describe the cyclic hardening/softening plasticity behavior of metals. The model requires three parameters to be evaluated experimentally. The physical behavior of each parameter is explained by sensitivity analysis. Compared to the Voce model, the proposed isotropic model has one more parameter, which may provide a better fit to the experimental data. For the new model, the incremental plasticity equation is also derived; this allows the model to be implemented in finite element codes, and in combination with kinematic models (Armstrong and Frederic
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33

Xie, C. L., S. Ghosh, and M. Groeber. "Modeling Cyclic Deformation of HSLA Steels Using Crystal Plasticity." Journal of Engineering Materials and Technology 126, no. 4 (2004): 339–52. http://dx.doi.org/10.1115/1.1789966.

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High strength low alloy (HSLA) steels, used in a wide variety of applications as structural components are subjected to cyclic loading during their service lives. Understanding the cyclic deformation behavior of HSLA steels is of importance, since it affects the fatigue life of components. This paper combines experiments with finite element based simulations to develop a crystal plasticity model for prediction of the cyclic deformation behavior of HSLA-50 steels. The experiments involve orientation imaging microscopy (OIM) for microstructural characterization and mechanical testing under uniax
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34

Biswas, Abhishek, Dzhem Kurtulan, Timothy Ngeru, Abril Azócar Guzmán, Stefanie Hanke, and Alexander Hartmaier. "Mechanical Behavior of Austenitic Steel under Multi-Axial Cyclic Loading." Materials 16, no. 4 (2023): 1367. http://dx.doi.org/10.3390/ma16041367.

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Low-nickel austenitic steel is subjected to high-pressure torsion fatigue (HPTF) loading, where a constant axial compression is overlaid with a cyclic torsion. The focus of this work lies on investigating whether isotropic J2 plasticity or crystal plasticity can describe the mechanical behavior during HPTF loading, particularly focusing on the axial creep deformation seen in the experiment. The results indicate that a J2 plasticity model with an associated flow rule fails to describe the axial creep behavior. In contrast, a micromechanical model based on an empirical crystal plasticity law wit
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35

Yoshida, Fusahito, Takeshi Uemori, and S. Abe. "Modeling of Large-Strain Cyclic Plasticity for Accurate Springback Simulation." Key Engineering Materials 340-341 (June 2007): 811–16. http://dx.doi.org/10.4028/www.scientific.net/kem.340-341.811.

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This paper describes a model of large-strain cyclic plasticity and its verification by some experiments of cyclic plasticity and biaxial stretching. The performance of this model in springback simulation is discussed by comparing the calculated results for S-rail forming with the experimental data on high strength steel sheet (HSS) of 980MPa-TS. The results of numerical simulations of the springback agree well with the corresponding experimental data, including the torsion-type springback appearing in S-rail forming.
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36

HIRAI, Hiroyoshi. "An anisotropic hardening model for cyclic plasticity of sand." Doboku Gakkai Ronbunshu, no. 382 (1987): 217–25. http://dx.doi.org/10.2208/jscej.1987.382_217.

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37

Skallerud, B., and P. K. Larsen. "A UNIAXIAL CYCLIC PLASTICITY MODEL INCLUDING TRANSIENT MATERIAL BEHAVIOUR." Fatigue & Fracture of Engineering Materials and Structures 12, no. 6 (1989): 611–25. http://dx.doi.org/10.1111/j.1460-2695.1989.tb00567.x.

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38

Abu‐Lebdeh, Taher M., and George Z. Voyiadjis. "Plasticity‐Damage Model for Concrete under Cyclic Multiaxial Loading." Journal of Engineering Mechanics 119, no. 7 (1993): 1465–84. http://dx.doi.org/10.1061/(asce)0733-9399(1993)119:7(1465).

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39

IWATA, Koji. "OS0202 A temperature dependent two-surface cyclic plasticity model." Proceedings of the Materials and Mechanics Conference 2009 (2009): 138–40. http://dx.doi.org/10.1299/jsmemm.2009.138.

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40

IWATA, Koji. "OS1202 A Temperature Dependent Multi-linear Cyclic Plasticity Model." Proceedings of the Materials and Mechanics Conference 2011 (2011): _OS1202–1_—_OS1202–3_. http://dx.doi.org/10.1299/jsmemm.2011._os1202-1_.

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41

Voyiadjis, George Z., and Ganesh Thiagarajan. "A cyclic anisotropic-plasticity model for metal matrix composites." International Journal of Plasticity 12, no. 1 (1996): 69–91. http://dx.doi.org/10.1016/s0749-6419(95)00045-3.

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42

Park, Honggun, and Jae-Yo Kim. "Hybrid plasticity model for reinforced concrete in cyclic shear." Engineering Structures 27, no. 1 (2005): 35–48. http://dx.doi.org/10.1016/j.engstruct.2004.08.013.

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43

Voyiadjis, G. Z., and I. N. Basuroychowdhury. "A plasticity model for multiaxial cyclic loading and ratchetting." Acta Mechanica 126, no. 1-4 (1998): 19–35. http://dx.doi.org/10.1007/bf01172796.

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44

Greshnov, V. M., and I. V. Puchkova. "Plasticity model for metals under cyclic large-strain loading." Journal of Applied Mechanics and Technical Physics 51, no. 2 (2010): 280–87. http://dx.doi.org/10.1007/s10808-010-0038-6.

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45

Seidalinov, Gaziz, and Mahdi Taiebat. "Bounding surface SANICLAY plasticity model for cyclic clay behavior." International Journal for Numerical and Analytical Methods in Geomechanics 38, no. 7 (2013): 702–24. http://dx.doi.org/10.1002/nag.2229.

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46

Laloui, L., and C. Cekerevac. "Non-isothermal plasticity model for cyclic behaviour of soils." International Journal for Numerical and Analytical Methods in Geomechanics 32, no. 5 (2008): 437–60. http://dx.doi.org/10.1002/nag.629.

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47

Devaney, Ronan J., Heiner Oesterlin, Padraic E. O’Donoghue, and Sean B. Leen. "Cyclic plasticity and low cycle fatigue damage characterisation of thermally simulated X100Q heat affected zone." MATEC Web of Conferences 165 (2018): 03002. http://dx.doi.org/10.1051/matecconf/201816503002.

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This paper presents the cyclic plasticity and low cycle fatigue (LCF) damage characterisation of thermally simulated heat affected zone (HAZ) for API 5L X100Q weldments. Microstructures representative of the HAZ for two cooling rates are generated using a Gleeble thermomechanical simulator for manufacture of strain-controlled cyclic plasticity test specimens. The simulated HAZ specimens are subjected to a strain controlled test programme which examines the cyclic effects of strain-range and the tensile response at room temperature. A modified version of the Chaboche rate independent plasticity
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48

Zub, Ciprian Ionut, Aurel Stratan, and Dan Dubina. "Modelling the cyclic response of structural steel for FEM analyses." ITM Web of Conferences 29 (2019): 02011. http://dx.doi.org/10.1051/itmconf/20192902011.

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Modelling the cyclic response of structural steel plays an important role in the design and performance assessment of steel structures. Up to date, several mathematical models were developed to simulate metal plasticity, but only some of them were implemented in Finite Element Method (FEM) based software packages such as Abaqus, by using incremental plasticity procedures. Within this article, the “built-in” combined isotropic/kinematic hardening model is used to model metal plasticity under cyclic loading regime. A brief description of the constitutive model together with the calibration proce
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49

Litrop, Aljaž, Jernej Klemenc, Marko Nagode, and Domen Šeruga. "Enhanced Cyclically Stable Plasticity Model for Multiaxial Behaviour of Magnesium Alloy AZ31 under Low-Cycle Fatigue Conditions." Materials 17, no. 18 (2024): 4659. http://dx.doi.org/10.3390/ma17184659.

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Magnesium alloys, particularly AZ31, are promising materials for the modern automotive industry, offering significant weight savings and environmental benefits. This research focuses on the challenges associated with accurate modelling of multiaxial cyclic plasticity at small strains of AZ31 under low-cycle fatigue conditions. Current modelling approaches, including crystal plasticity and phenomenological plasticity, have been extensively explored. However, the existing models reach their limits when it comes to capturing the complexity of cyclic plasticity in magnesium alloys, especially unde
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50

Okorokov, V., D. MacKenzie, Y. Gorash, M. Morgantini, Rijswick R. van, and T. Comlekci. "High cycle fatigue analysis in the presence of autofrettage compressive residual stress." Fatigue and Fracture of Engineering Materials and Structures 41, no. 11 (2018): 2305–20. https://doi.org/10.1111/ffe.12866.

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An experimental and numerical investigation of the effect of residual compressive stress on the high cycle fatigue life of notched low carbon steel test specimens is presented. Experimentally determined cyclic stress strain curves for S355 low carbon steel are utilized in a Finite Element Analysis plasticity modelling framework incorporating a new cyclic plasticity material model representative of cyclic hardening and softening, cyclic mean stress relaxation and ratcheting behaviors. Fatigue test results are presented for standard tensile fatigue test specimens and novel double notch specimens
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