Module 4 : Nonlinear elasticity Lecture 25 : Inflation of a baloon. The Lecture Contains. Inflation of a baloon

Similar documents
Mechanical Properties of Polymer Rubber Materials Based on a New Constitutive Model

2.1 Strain energy functions for incompressible materials

Comparative Study of Variation of Mooney- Rivlin Hyperelastic Material Models under Uniaxial Tensile Loading

Constitutive models. Constitutive model: determines P in terms of deformation

LITERATURE SURVEY SUMMARY OF HYPERELASTIC MODELS FOR PDMS

A Review On Methodology Of Material Characterization And Finite Element Modelling Of Rubber-Like Materials

Dynamic Finite Element Modeling of Elastomers

EXPERIMENTAL IDENTIFICATION OF HYPERELASTIC MATERIAL PARAMETERS FOR CALCULATIONS BY THE FINITE ELEMENT METHOD

Lectures on. Constitutive Modelling of Arteries. Ray Ogden

FEM model of pneumatic spring assembly

14 - hyperelastic materials. me338 - syllabus hyperelastic materials hyperelastic materials. inflation of a spherical rubber balloon

A FAILURE CRITERION FOR POLYMERS AND SOFT BIOLOGICAL MATERIALS

Determination of Mechanical Properties of Elastomers Using Instrumented Indentation

A comparison of the Hart-Smith model with the Arruda-Boyce and Gent formulations for rubber elasticity

The strain response of silicone dielectric elastomer actuators

Stress Analysis of Thick Spherical Pressure Vessel Composed of Transversely Isotropic Functionally Graded Incompressible Hyperelastic Materials

Continuum Mechanics and Theory of Materials

FREQUENCY BEHAVIOR OF RYLEIGH HYPER-ELASTIC MICRO- BEAM

Nonlinear Forced Vibration Analysis of Dielectric-Elastomer Based Micro-Beam with Considering Yeoh Hyper-Elastic Model

Comparative Study of Hyper Elastic Material Models

Evaluation of hyperelastic material properties based on instrumented indentation

Chapter 2. Rubber Elasticity:

A note on finite elastic deformations of fibre-reinforced non-linearly elastic tubes

Classification of Prostate Cancer Grades and T-Stages based on Tissue Elasticity Using Medical Image Analysis. Supplementary Document

Rigid Flexible Contact Analysis of an Inflated Membrane Balloon with Various Contact Conditions

Testing and Analysis

Benchmarkingfiniteelement simulation of rigid indenters in elastomers S.J. Jerrams, N. Reece-Pinchin

Final Project: Indentation Simulation Mohak Patel ENGN-2340 Fall 13

On Constitutive Models for Limited Elastic, Molecular Based Materials

Supplementary information

On Mooney-Rivlin Constants for Elastomers

COMPARISON OF CONSTITUTIVE HYPER-ELASTIC MATERIAL MODELS IN FINITE ELEMENT THEORY

Simple shear is not so simple

You may not start to read the questions printed on the subsequent pages until instructed to do so by the Invigilator.

Cavitation instability in rubber with consideration of failure

Numerical and Experimental Studies on Thermoforming Process. Sogang University

A Numerical Study of Finite Element Calculations for Incompressible Materials under Applied Boundary Displacements

AN ANISOTROPIC PSEUDO-ELASTIC MODEL FOR THE MULLINS EFFECT IN ARTERIAL TISSUE

Elasticity Models for the Spherical Indentation of Gels and Soft Biological Tissues

Nonlinear Structural Materials Module

The elastic behavior of a rubber-like material for composite glass

A new strain energy function for the hyperelastic modelling of ligaments and tendons

Transactions on Modelling and Simulation vol 10, 1995 WIT Press, ISSN X

Non-linear and time-dependent material models in Mentat & MARC. Tutorial with Background and Exercises

ANSYS Mechanical Basic Structural Nonlinearities

The Non-Linear Field Theories of Mechanics

Testing Elastomers and Plastics for Marc Material Models

Lecture 4 Implementing material models: using usermat.f. Implementing User-Programmable Features (UPFs) in ANSYS ANSYS, Inc.

A COMPARATIVE STUDY OF HYPERELASTIC CONSTITUTIVE MODELS FOR AN AUTOMOTIVE COMPONENT MATERIAL

1 Useful Definitions or Concepts

Slight compressibility and sensitivity to changes in Poisson s ratio

University Of Glasgow. School of Engineering. Department of Mechanical Engineering. Final Year Project

Neck development in metal/elastomer bilayers under dynamic stretchings

NCHRP FY 2004 Rotational Limits for Elastomeric Bearings. Final Report. Appendix I. John F. Stanton Charles W. Roeder Peter Mackenzie-Helnwein

Stability of Thick Spherical Shells

Creasing Critical Strain Dependence on Surface Defect Geometry. EN234 Final Project

SIMULATION OF MECHANICAL TESTS OF COMPOSITE MATERIAL USING ANISOTROPIC HYPERELASTIC CONSTITUTIVE MODELS

Modelling the effects of various contents of fillers on the relaxation rate of filled rubbers

Simulation of the mechanical behavior of a rubber pumping system under large deformations.

Module 3 : Equilibrium of rods and plates Lecture 15 : Torsion of rods. The Lecture Contains: Torsion of Rods. Torsional Energy

Solitary Shock Waves and Periodic Shock Waves in a Compressible Mooney-Rivlin Elastic Rod

Plane strain bending of strain-stiffening rubber-like rectangular beams

Constitutive Modelling of Elastomeric Seal Material under Compressive Loading

Fitting hyperelastic models to experimental data

Lecture 1 NONLINEAR ELASTICITY

Simple Shear Testing of Parallel-Fibered Planar Soft Tissues

Mechanics PhD Preliminary Spring 2017

Effects of Aging on the Mechanical Behavior of Human Arteries in Large Deformations

Two problems in finite elasticity

The Finite Element Method for the Analysis of Non-Linear and Dynamic Systems. Prof. Dr. Eleni Chatzi Lecture ST1-19 November, 2015

ANSYS problem. Situation:

Functional Grading of Rubber-Elastic Materials: From Chemistry to Mechanics

Inverse Design (and a lightweight introduction to the Finite Element Method) Stelian Coros

in this web service Cambridge University Press

Extension, inflation and torsion of a residually-stressed circular cylindrical tube

MODIFICATION IN ADINA SOFTWARE FOR ZAHORSKI MATERIAL

Hyperelasticity and the Failure of Averages

Spherical indentation on biological films with surface energy

A novel elastometer for soft tissue

Predicting the dynamic material constants of Mooney-Rivlin model in broad frequency range for elastomeric components

MITOCW MITRES2_002S10nonlinear_lec15_300k-mp4

A REALIZABLE CONSTITUTIVE MODEL FOR FIBER-REINFORCED NEO-HOOKEAN SOLIDS

Laurent Gornet, R. Desmorat, Gilles Marckmann, Pierre Charrier. To cite this version:

NUMERICAL INVESTIGATION OF OGDEN AND MOONEY-RIVLIN MATERIAL PARAMETERS

Module-4. Mechanical Properties of Metals

DEVELOPMENT OF A NOVEL BALLOON-SHAPE ELECTROACTIVE POLYMER (EAP) ACTUATOR by

Measurement of deformation. Measurement of elastic force. Constitutive law. Finite element method

UCD CompGeoMech Contributions to OpenSees: Deliverables

Modeling Transverse Behavior of Kevlar KM2 Single Fibers with Deformation-induced Damage

Slight compressibility and sensitivity to changes in Poisson s ratio

Law of behavior very-rubber band: almost incompressible material

Performance Evaluation of Various Smoothed Finite Element Methods with Tetrahedral Elements in Large Deformation Dynamic Analysis

Lecture #6: 3D Rate-independent Plasticity (cont.) Pressure-dependent plasticity

Lecture Outline Chapter 17. Physics, 4 th Edition James S. Walker. Copyright 2010 Pearson Education, Inc.

Electromechanical stability of a Mooney Rivlin-type dielectric elastomer with nonlinear variable permittivity

Theoretical investigation on the fatigue life of elastomers incorporating material inhomogeneities

Deflections of a rubber membrane $

An Exact Result for the Macroscopic Response of Particle-Reinforced Neo-Hookean Solids

NUMERICAL MODELLING AND EXPERIMENTAL INFLATION VALIDATION OF A BIAS TWO-WHEEL TIRE

Study Neo-Hookean and Yeoh Hyper-Elastic Models in Dielectric Elastomer-Based Micro-Beam Resonators

Transcription:

Lecture 25 : Inflation of a baloon The Lecture Contains Inflation of a baloon 1. Topics in finite elasticity: Hyperelasticity of rubber, elastomers, and biological tissues with examples, M. F Beatty, App. Mech. Rev. Vol. 40(12), pp. 1699-1734 (1987). file:///d /Dr.AK%20Ghatak/Dr.AK%20Ghatak/mechanics_soft_matrial/lecture25/25_1.html[4/26/2013 3:54:58 PM]

Lecture:25 : Inflation of a baloon Inflation of a balloon We model the balloon as an isotropic spherical membrane with uniform radius and thickness and that the spherical shape is preserved due to inflation. Uniform isotropic stretch of the membrane is described by the extension ratios ; and the stretch in the thickness coordinate is. Then due to incompressibility,. Then the strain energy stored in the balloon is (25.1) Now let s say, the balloon is inflated slightly, i.e. from radius to so that, the work done against the outside atmospheric pressure is Then the net work done is (25.2) This energy, which remains stored as the strain energy in the material of the balloon can be written as, (25.3) file:///d /Dr.AK%20Ghatak/Dr.AK%20Ghatak/mechanics_soft_matrial/lecture25/25_2.html[4/26/2013 3:54:58 PM]

Lecture 25 : Inflation of a baloon Balancing these energies, we have, (25.4) This is the expression for pressure for a neo = Hookean balloon. It is easy to see that pressure required to inflate the balloon is zero at and also at. Then there should be a maxima, which can be obtained by putting (25.5) which yields, The maximum pressure is then calculated as. The maximum pressure depends upon the ratio and also on the Young s modulus to, but the stretch at which the pressure becomes maximum remains constant and is equal. Pressure decreases to zero asymptotically. However, in experiments we do not see that. The pressure goes through a maxima, then a minima after which it increases again. The Hookean strain energy function can not capture this complex behavior of the pressure vs extension ratio. In order to explain it we need more involved relation, one such strain energy function is proposed by Mooney and Rivlin and is known as Mooney-Rivlin equation which can be written as, (25.6) Here and are constants signifying material properties such that equates the shear modulus. Notice that the principal extension ratios are actually obtained as the eigen values of the matrix 8.1, so that the quantities, and are invariant. We can file:///d /Dr.AK%20Ghatak/Dr.AK%20Ghatak/mechanics_soft_matrial/lecture25/25_3.html[4/26/2013 3:54:58 PM]

expand equation (25.6) as a power series in terms of which includes the terms for and, as a result, the Mooney Rivlin form of strain energy gives good agreement with experiment at small strains. The Neo-Hookean material is a subset of the Mooney-Rivlin material. file:///d /Dr.AK%20Ghatak/Dr.AK%20Ghatak/mechanics_soft_matrial/lecture25/25_3.html[4/26/2013 3:54:58 PM]

Lecture 25 : Inflation of a baloon For the balloon inflation problem, this relation simplifies to (25.7) Then the differential strain energy: (25.8) And the mechanical energy done to expand the volume: Balancing these two one obtains, (25.9) Then the condition for obtaining the two extremes translate to,, or, (25.10) Thus neo-hookean relation alone is not sufficient for the inflation of the balloon, we need a two parameter model like the Mooney-Rivlin equation to account for it. The Mooney Rivlin form agrees well with the experiment at small strains. However at modest strain beyond 10% the second term of the equation 12.61 looses importance, therefore there is a need for modifying this equation. This is done by replacing it by a logarithmic term as follows: (25.11) For soft rubbers the constants and are found to be 0.25-0.5 MPa. Many materials like rubber strain hardens at large strain which is not captured by the above equations. The strain hardening behaviour of rubber is accounted for further modification of equation (25.11) in which the maximum possible value of measured quantity is represented as : (25.12) Calculations from 25.1 to 25.5 can now be repeated. file:///d /Dr.AK%20Ghatak/Dr.AK%20Ghatak/mechanics_soft_matrial/lecture25/25_4.html[4/26/2013 3:54:58 PM]

file:///d /Dr.AK%20Ghatak/Dr.AK%20Ghatak/mechanics_soft_matrial/lecture25/25_4.html[4/26/2013 3:54:58 PM]

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback