Photoelastic modeling of the fracture of viscoelastic orthotropic plates with a crack

Voitovich, L. V.; Malezhik, M. P.; Chernyshenko, I. S.

doi:10.1007/s10778-010-0355-8

Cited by 6 publications

(6 citation statements)

References 12 publications

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“…The singular equations in [1] are valid in the neighborhood of r << l. By increasing the neighborhood around the crack tip, we can more accurately determine the fringe order and SIF ( ) K . The simultaneous solution of the equations of orthotropic photoelasticity and fracture mechanics of materials with cracks yields the relationship between the fringe orders m and K, as was shown in [16].…”

Section: Introductionmentioning

confidence: 91%

“…The technology of such materials and a procedure for the analysis of their mechanical and optical properties are outlined in [5]. Restricted to the mechanical and optical properties of the material, Tables 1 and 2 give values of mechanical creep functions y ij t ( ), complex parameters s t j ( ), and optical creep functions P t ij ( ) [16]. For numerical purposes, we tested plates with circular holes of radius R and symmetric cracks of length 2l (Fig.…”

Section: Analysis Of the Stress Distribution In Plates By The Photoelmentioning

confidence: 99%

“…Use will be made of a procedure that produces more accurate results than in [16]. The mathematical model discussed below allows us to increase the neighborhood around the crack tip to improve the accuracy of determining the fringe orders and, hence, the SIFs.…”

Section: Introductionmentioning

confidence: 99%

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Stress state around cracks on the boundary of a hole in a photoelastic orthotropic plate under creep

2011

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The stress-strain state near cracks on the boundary of a circular hole in a linear elastic orthotropic composite plate under tension is analyzed. The distribution of stress intensity factors (SIFs) at the crack tip is found from photoelectric measurements. The dependence of the SIFs on the ratio of crack length to hole radius and on the mechanical properties of the material is established Keywords: photoelasticity, orthotropic composite plate, circular hole with two edge cracks, tension, stress intensity factor Introduction.Theoretical and experimental studies of the stress distribution in composite structural members (plates and shells with stress concentrators (holes, cracks)) are addressed in [1, 3, 6, 7, 11-16, etc.)].To determine the stress intensity factors (SIFs) around cracks propagating from the edges of a hole in elastic isotropic plates, use is made of numerical [1, 3], theoretical-and-experimental [2], and experimental [8] methods. The major results in the field have been obtained in the static case. Solutions to dynamic problems for anisotropic bodies with stress concentrators obtained by the photoelastic method can be found in [12][13][14][15].We will use photoelastic measurements to study the stress distribution around cracks on the boundary of a hole in linear elastic fiber-reinforced composite plates under a tensile force normal to the cracks. Use will be made of a procedure that produces more accurate results than in [16]. The mathematical model discussed below allows us to increase the neighborhood around the crack tip to improve the accuracy of determining the fringe orders and, hence, the SIFs.1. Problem Formulation. Procedure of Analysis. To describe the mechanical and optical behavior of the composite, we will assume that it is homogeneous and anisotropic. Consider a photoelastic plate under creep.The orthotropic plate is weakened by a crack on an interval ( ) 2l of the x-axis aligned with the principal axis of orthotropy of the material (Fig. 1). The plate is subject to a tensile force P = const applied far from the stress concentrator. In the case of plane stress state, the components of the stress tensor s s t

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Section: Introductionmentioning

confidence: 91%

Section: Analysis Of the Stress Distribution In Plates By The Photoelmentioning

confidence: 99%

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Stress state around cracks on the boundary of a hole in a photoelastic orthotropic plate under creep

2011

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“…To minimize the error of an experimental method, use is usually made of photoelastic materials with low viscoelastic characteristics, which is quite justified [3,4]. Photoelastic data on the dynamic stresses and fracture of orthotropic plates with cracks can be found in [1,9].The present paper proposes a method to calculate the difference of principal stresses and principal strains in compressible linear viscoelastic optically sensitive materials from a time-dependent fringe pattern. We will establish the relationship between the mechanical and optical characteristics of viscoelastic bodies under dynamic loading.…”

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confidence: 99%

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Relationship between the mechanical and optical characteristics of photoviscoelastic polymeric materials under dynamic loading

2011

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The paper presents a method to calculate the difference of principal stresses and strains in linear viscoelastic optically sensitive polymeric materials from a time-dependent fringe pattern. The governing equations are derived using the direct and inverse Laplace transforms Keywords: photoelasticity, linear viscoelastic optically sensitive polymeric material, direct and inverse Laplace transformsIntroduction. The current level of development of the photoelastic method allows solving engineering problems [3,5] in various fields. The dynamic photoelastic method has recently been developed to be used in the mechanics of anisotropic bodies [8].Optically sensitive polymeric materials used for photoelastic modeling are known [2, 4] to have viscoelastic properties; therefore, it is reasonable to ask the question whether viscoelastic materials can be used for modeling dynamic processes in elasticity [6]. To minimize the error of an experimental method, use is usually made of photoelastic materials with low viscoelastic characteristics, which is quite justified [3,4]. Photoelastic data on the dynamic stresses and fracture of orthotropic plates with cracks can be found in [1,9].The present paper proposes a method to calculate the difference of principal stresses and principal strains in compressible linear viscoelastic optically sensitive materials from a time-dependent fringe pattern. We will establish the relationship between the mechanical and optical characteristics of viscoelastic bodies under dynamic loading.1. Original Equations. The photoelastic modeling of the mechanical behavior of elastic bodies involves the selection of a modeling material with mechanical behavior similar to that of the modeled material, the determination of the stresses and strains in the model, and the transformation to the stresses and strains in the real material.In optical modeling, the stresses are determined from the linear dependence of the fringe order m on the stresses (s 1 , s 2 ) alone with stress optical coefficient Ñ s as a coefficient of proportionality or on the strains (e 1 , e 2 ) alone with strain optical coefficient Ñ e as a coefficient of proportionality:

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Development and application of radiowave photoelasticity for the fracture analysis of dielectrics

2011

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The radiowave photoelasticity method is developed and is justified for use in the fracture mechanics of dielectrics. The damage tensors of a material with microcracks are considered. The basic equations of the method are given. The time-dependence of microcrack density is analyzed. Numerical results are presented and analyzed Keywords: radiowave photoelasticity method, dielectrics, damage, microcrack density Introduction. The development of theoretical (analytic, numerical) and experimental methods for stress analysis of modern structures and their elements (plates, shells) made of homogeneous and inhomogeneous anisotropic materials is of importance for various branches of engineering. There is an increasingly urgent need for experimental methods for studying the time-dependent mechanical behavior of isotropic and anisotropic bodies, especially if they have crack-like stress concentrators.The most complete results on the development of the photoelastic method are presented in [8]. Among them are photoplasticity [8], photoviscoelasticity [13], integral photoelasticity [1], dynamic photoelasticity [6,8], and radiowave and infrared photoelasticity [9].The fracture of bodies (materials) involves the nucleation and propagation of cracks that create free surfaces under loading. This process is considered in static, kinematic, and dynamic aspects. The fracture of a material is known to be a complex process, even in the ideal case (isotropic homogeneous material). The process is even more complicated if the material is anisotropic or has plastic strains, residual strains, defects, or inhomogeneities. Fracture theory devotes particular attention to fatigue failure due to gradual crack growth under cyclic or long-term loading. In these cases, fatigue failure results from the accumulation of irreversible damage in the material. Cracks (changes in the material) start developing in bodies long before their failure (either plastic or brittle).Dynamic photoelasticity [6] in the macrofracture mechanics of anisotropic materials was addressed in the papers [14-18] which analyzed the stress-strain state (SSS) of isotropic and anisotropic plates with cracks subject to creep or dynamic loading.The present paper develops the radiowave photoelasticity method for the stress analysis of solid bodies. It is based on the distribution of electromagnetic waves in anisotropic and isotropic bodies (dielectrics and semiconductors including ceramics, plastics, ferrite, etc.) opaque to visible light. This method is advantageous over photoelasticity by making it possible to analyze the SSS of dielectrics using the invisible (ultrahigh frequency) spectrum of electromagnetic waves.Our goal is to justify the use of polarized radio-waves for examining (detecting and analyzing) microcracks in dielectrics.1. Macroscopic Damage Tensor. The nucleation and propagation of submicrocracks in dielectrics can be described based on the dislocation model [3] because cracks are generated by some type of incompatibility in a continuum. A crack is represented by a s...

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Photoelastic modeling of the fracture of viscoelastic orthotropic plates with a crack

Cited by 6 publications

References 12 publications

Stress state around cracks on the boundary of a hole in a photoelastic orthotropic plate under creep

Stress state around cracks on the boundary of a hole in a photoelastic orthotropic plate under creep

Relationship between the mechanical and optical characteristics of photoviscoelastic polymeric materials under dynamic loading

Development and application of radiowave photoelasticity for the fracture analysis of dielectrics

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