Assessment of stress-strain constitutive models and failure models on the shock tube based impact forming of AA 5052-H32 sheet

In this paper, some representative hyperelastic constitutive models of rubber materials were reviewed from the perspectives of molecular chain network statistical mechanics and continuum mechanics. Based on the advantages of existing models, an improved constitutive model was developed, and the stress–strain relationship was derived. Uniaxial tensile tests were performed on two types of filled tire compounds at different temperatures. The physical phenomena related to rubber deformation were analyzed, and the temperature dependence of the mechanical behavior of filled rubber in a larger deformation range (150% strain) was revealed from multiple angles. Based on the experimental data, the ability of several models to describe the stress–strain mechanical response of carbon black filled compound was studied, and the application limitations of some constitutive models were revealed. Combined with the experimental data, the ability of Yeoh model, Ogden model (n = 3), and improved eight-chain model to characterize the temperature dependence was studied, and the laws of temperature dependence of their parameters were revealed. By fitting the uniaxial tensile test data and comparing it with the Yeoh model, the improved eight-chain model was proved to have a better ability to predict the hyperelastic behavior of rubber materials under different deformation states. Finally, the improved eight-chain model was successfully applied to finite element analysis (FEA) and compared with the experimental data. It was found that the improved eight-chain model can accurately describe the stress–strain characteristics of filled rubber.

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Characterization of Hyperelastic (Rubber) Material Using Uniaxial and Biaxial Tension Tests

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.570.1 ◽

2012 ◽

Vol 570 ◽

pp. 1-7

Author(s):

Yawar Jamil Adeel ◽

Ahsan Irshad Muhammad ◽

Azmat Zeeshan

Keyword(s):

Shear Test ◽

Biaxial Tension ◽

Constitutive Models ◽

Hyperelastic Material ◽

Strain Response ◽

Stress Strain ◽

Rubber Material ◽

Tension Tests ◽

Planar Shear

Hyperelastic material simulation is necessary for proper testing of products functionality in cases where prototype testing is expensive or not possible. Hyperelastic material is nonlinear and more than one stress-strain response of the material is required for its characterization. The study was focused on prediction of hyperelastic behavior of rubber neglecting the viscoelastic and creep effects in rubber. To obtain the stress strain response of rubber, uniaxial and biaxial tension tests were performed. The data obtained from these tests was utilized to find the coefficients of Mooney-Rivlin, Odgen and Arruda Boyce models. Verification of the behavior as predicted by the fitted models was carried out by comparing the experimental data of a planar shear test with its simulation using the same constitutive models.

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Identification of orthotropic material parameters for acute, necrotic, fibrotic and remodelling myocardial infarcts in the rat

10.1101/754754 ◽

2019 ◽

Author(s):

Mazin S. Sirry ◽

Laura Dubuis ◽

Neil H. Davies ◽

Jun Liao ◽

Thomas Franz

Keyword(s):

Constitutive Model ◽

Orthotropic Material ◽

Constitutive Models ◽

Biaxial Stress ◽

Percentage Error ◽

Fe Model ◽

Stress Strain ◽

Material Parameters ◽

Strain Data ◽

Tensile Experiment

AbstractFinite element (FE) models have been effectively utilized in studying biomechanical aspects of myocardial infarction (MI). Although the rat is a widely used animal model for MI, there is a lack of material parameters based on anisotropic constitutive models for rat myocardial infarcts in literature. This study aimed at employing inverse methods to identify the parameters of an orthotropic constitutive model for myocardial infarcts in the acute, necrotic, fibrotic and remodelling phases utilizing the biaxial mechanical data developed in a previous study. FE model was developed mimicking the setup of the biaxial tensile experiment. The orthotropic case of the generalized Fung constitutive model was utilized to model the material properties of the infarct. The parameters of Fung model were optimized so that the FE solution best fitted the biaxial experimental stress-strain data. A genetic algorithm was used to minimize the objective function. Fung orthotropic material parameters for different infarct stages were identified. The FE model predictions best approximated the experimental data of the 28 days infarct stage with 3.0% mean absolute percentage error. The worst approximation was for the 7 days stage with 3.6% error. This study demonstrated that the experimental biaxial stress-strain data of healing rat infarcts could be successfully approximated using inverse FE methods and genetic algorithms. The material parameters identified in this study will provide an essential platform for FE investigations of biomechanical aspects of MI and the development of therapies.

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Improving Methods of Assessment of a Stress State of Structures According to the Results of Coercive Measurements

Solid State Phenomena ◽

10.4028/www.scientific.net/ssp.284.1332 ◽

2018 ◽

Vol 284 ◽

pp. 1332-1336

Author(s):

N.L. Zaytsev

Keyword(s):

Stress State ◽

Strain State ◽

Steel Structures ◽

Stress Strain ◽

Stress Strain State ◽

Assessment Of Stress

At the present time the assessment of stress-strain state of steel structures uses the results of coercive measurements. However, the methods presented in various works are contradictory and not deprived of errors of a methodological nature, which may lead to erroneous conclusions. This article reveals the analysis of disadvantages of the known methods and proposes possible ways to eliminate these shortcomings.

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Temperature Effect on the Compressive Behavior and Constitutive Model of Plain Hardened Concrete

Materials ◽

10.3390/ma13122801 ◽

2020 ◽

Vol 13 (12) ◽

pp. 2801 ◽

Cited By ~ 2

Author(s):

Ayman El-Zohairy ◽

Hunter Hammontree ◽

Eddie Oh ◽

Perry Moler

Keyword(s):

Experimental Data ◽

Compressive Strength ◽

Temperature Effect ◽

Modulus Of Elasticity ◽

Constitutive Models ◽

Ultimate Strain ◽

Effect Of Temperature ◽

Hardened Concrete ◽

Compressive Behavior ◽

Stress Strain

Concrete is one of the most common and versatile construction materials and has been used under a wide range of environmental conditions. Temperature is one of them, which significantly affects the performance of concrete, and therefore, a careful evaluation of the effect of temperature on concrete cannot be overemphasized. In this study, an overview of the temperature effect on the compressive behavior of plain hardened concrete is experimentally provided. Concrete cylinders were prepared, cured, and stored under different temperature conditions to be tested under compression. The stress–strain curve, mode of failure, compressive strength, ultimate strain, and modulus of elasticity of concrete were evaluated between the ages of 7 and 90 days. The experimental results were used to propose constitutive models to predict the mechanical properties of concrete under the effect of temperature. Moreover, previous constitutive models were examined to capture the stress–strain relationships of concrete under the effect of temperature. Based on the experimental data and the proposed models, concrete lost 10–20% of its original compressive strength when heated to 100 °C and 30–40% at 260 °C. The previous constitutive models for stress–strain relationships of concrete at normal temperatures can be used to capture these relationships under the effect of temperature by using the compressive strength, ultimate strain, and modulus of elasticity affected by temperature. The effect of temperature on the modulus of elasticity of concrete was considered in the ACI 318-14 equation by using the compressive strength affected by temperature and the results showed good agreement with the experimental data.

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To assessment of stress-strain state in rock continua

IOP Conference Series Materials Science and Engineering ◽

10.1088/1757-899x/869/7/072019 ◽

2020 ◽

Vol 869 ◽

pp. 072019

Author(s):

Farkhadjan Adilov ◽

Shakhnoza Makhmudova ◽

Rustam Abirov ◽

Elyor Toshmatov ◽

Ikbal Maxmudova

Keyword(s):

Strain State ◽

Stress Strain ◽

Stress Strain State ◽

Assessment Of Stress

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Modelling of undrained shearing of soft natural clays

E3S Web of Conferences ◽

10.1051/e3sconf/20199215001 ◽

2019 ◽

Vol 92 ◽

pp. 15001

Author(s):

Alexandros L. Petalas ◽

Mats Karlsson ◽

Minna Karstunen

Keyword(s):

Triaxial Compression ◽

Constitutive Models ◽

Strain Response ◽

Rate Dependency ◽

Induced Anisotropy ◽

Stress Strain ◽

Soft Soils ◽

Model Simulations ◽

Rate Effects ◽

Natural Clays

stress-strain response of soft natural clays is characterised by anisotropy, destructuration and rate-dependency. An accurate constitutive description of these materials should take into consideration all of the characteristics above. In this paper, two constitutive models for soft soils, namely the SCLAY1S and Creep-SCLAY1S models are used to simulate the undrained response of two soft natural clays, Gothenburg clay from Sweden and Otaniemi clay from Finland. The SCLAY1S model accounts for the effect of inherent and induced anisotropy and destructuration, while the Creep-SCLAY1S accounts also for the creep and rate effects. The model simulations are compared against triaxial compression and extension tests on anisotropically consolidated samples. The results demonstrate the need to incorporate all features represented in the Creep-SCLAY1S model when modelling structured natural clays.

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Vipulanandan Constitutive Models to Predict the Rheological Properties and Stress–Strain Behavior of Cement Grouts Modified with Metakaolin

Journal of Testing and Evaluation ◽

10.1520/jte20180271 ◽

2018 ◽

Vol 48 (5) ◽

pp. 20180271 ◽

Cited By ~ 6

Author(s):

A. Mohammed ◽

A. Salih ◽

H. Raof

Keyword(s):

Rheological Properties ◽

Constitutive Models ◽

Stress Strain ◽

Strain Behavior ◽

Cement Grouts

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Development of a Flow Evolution Network Model for the Stress–Strain Behavior of Poly(L-lactide)

Journal of Biomechanical Engineering ◽

10.1115/1.4037071 ◽

2017 ◽

Vol 139 (9) ◽

Cited By ~ 4

Author(s):

Maureen L. Dreher ◽

Srinidhi Nagaraja ◽

Jorgen Bergstrom ◽

Danika Hayman

Keyword(s):

Finite Element ◽

Constitutive Model ◽

Computational Modeling ◽

Medical Devices ◽

Constitutive Models ◽

Constitutive Relationship ◽

Displacement Curve ◽

Stress Strain ◽

Strain Behavior ◽

Flow Evolution

Computational modeling is critical to medical device development and has grown in its utility for predicting device performance. Additionally, there is an increasing trend to use absorbable polymers for the manufacturing of medical devices. However, computational modeling of absorbable devices is hampered by a lack of appropriate constitutive models that capture their viscoelasticity and postyield behavior. The objective of this study was to develop a constitutive model that incorporated viscoplasticity for a common medical absorbable polymer. Microtensile bars of poly(L-lactide) (PLLA) were studied experimentally to evaluate their monotonic, cyclic, unloading, and relaxation behavior as well as rate dependencies under physiological conditions. The data were then fit to a viscoplastic flow evolution network (FEN) constitutive model. PLLA exhibited rate-dependent stress–strain behavior with significant postyield softening and stress relaxation. The FEN model was able to capture these relevant mechanical behaviors well with high accuracy. In addition, the suitability of the FEN model for predicting the stress–strain behavior of PLLA medical devices was investigated using finite element (FE) simulations of nonstandard geometries. The nonstandard geometries chosen were representative of generic PLLA cardiovascular stent subunits. These finite element simulations demonstrated that modeling PLLA using the FEN constitutive relationship accurately reproduced the specimen’s force–displacement curve, and therefore, is a suitable relationship to use when simulating stress distribution in PLLA medical devices. This study demonstrates the utility of an advanced constitutive model that incorporates viscoplasticity for simulating PLLA mechanical behavior.

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