[en] LINEAR ELASTIC FRACTURE MECHANICS ANALYSIS OF FATIGUE CRACK GROWTH UNDER COMPLEX LOADING USING THE DIGITAL IMAGE CORRELATION TECHNIQUE / [pt] ANÁLISE DO CRESCIMENTO DE TRINCAS DE FADIGA PELA MECÂNICA DE FRATURA ELASTICA LINEAR SOB CARGA COMPLEXA UTILIZANDO A TÉCNICA DE CORRELAÇÃO DE IMAGENS DIGITAIS

JORGE GUILLERMO DIAZ RODRIGUEZ

25 January 2019

[pt] A avaliação da propagação de trincas de fadiga inclui a identificação da direção da trinca, o conhecimento do Fator de Intensidade de Tensões (SIF) equivalente, a determinação de uma taxa de crescimento de comprimento de trinca por número de ciclos da/dN e o estabelecimento de uma regra de propagação de trinca conectando SIF e da/dN, como uma regra de tipo Paris. Quando ocorrem cargas mistas e não proporcionais, esses parâmetros ainda não são totalmente compreendidos. Esta tese trata de algumas das variáveis que influenciam a propagação de trincas sob carregamento no modo misto não proporcional. A técnica de Correlação de Imagens Digitais (DIC) foi utilizada para a aquisição de imagens de corpos de prova submetidos a carregamento proporcional e não proporcional cíclico. Dois tipos de corpos de prova foram utilizados. Primeiramente, dois corpos de prova planos foram testados; um disk compact tension (DCT, em inglês) e um compact tension modificado (C (T) em inglês). Eles foram submetidos a carregamento cíclico induzindo o modo I de abertura de trinca ou modos I e II de abertura de trinca proporcionais. Em segundo lugar, os dados DIC adquiridos anteriormente, e em outro lugar, para cinco tubos finos sujeitos a carregamento cíclico foram analisados. Os tubos finos tiveram entalhes usinados a partir dos quais as trincas por fadiga iniciaram e se propagaram. Esses cinco tubos finos foram submetidos a diferentes casos de carga proporcional e não proporcional. Um corpo de prova tipo tubo fino foi exposto a carga axial e apresentou modo de abertura de trinca tipo I. Os outros quatro foram submetidos a carregamento de torção ou carga axial-torcional mista e exibiram todos os três modos de abertura de trinca I, II e III. Os campos de deslocamento adquiridos experimentalmente com a técnica DIC foram processados para calcular independentemente o SIF para cada modo de abertura existente usando formulações de mecânica de fratura elástica linear (MFLE). Uma formulação delas utilizou dados de deslocamento de campo completos adquiridos em pequenas áreas que circundavam a ponta da trinca. Outra formulação usou dados adquiridos de um par de pontos localizados ao longo dos flancos opostos das faces da trinca. Os SIFs determinados foram usados para encontrar os SIFs equivalentes e faixas de SIF equivalentes usando o critério da tensão máxima de tração (para ambas as versões 2D e 3D de combinações dos modos I-II e modos I-II-III respectivamente) que implicitamente incluíram o ângulo de propagação de trinca. Verificou-se que a inclusão do SIF no modo III experimentalmente determinado efetivamente faz diferença nas faixas do SIF e dos SIF equivalentes estimados. A curva da/dN versus faixa do SIF equivalente foi elaborado com as taxas de crescimento de trinca medidas experimentalmente e as faixas de SIF que foram encontradas usando a suposição amplamente aceita de que as trincas cresceram na direção que maximiza a tensão de tração. Para isso, extensões do modelo de Schollmann et. al. e bem como o modelo de Erdogan-Sih, que são geralmente aplicados ao carregamento proporcional, foram usados para determinar os SIFs equivalentes e faixas de SIF equivalentes para os casos de carregamento proporcional e não proporcional. Finalmente, a segunda zona da regra de Paris (da/dN versus faixa do SIF equivalente) foi plotada para os cinco casos de carregamento nos tubos finos mostrando que eles caíram dentro de uma faixa razoavelmente fina e dispersa. / [en] Fatigue crack propagation assessment includes identifying the crack direction, knowing the equivalent Stress Intensity Factor (SIF) range, determining a crack length growth rate per number of cycles (da/dN), and establishing a crack propagation rule connecting the equivalent SIF and da/dN rate, such as a Paris type of rule. When mixed and non-proportional loading occur, those parameters are not fully understood yet. This thesis deals with some of the variables that influence crack propagation under non-proportional mixed mode loading. The Digital Image Correlation (DIC) technique was used to acquire images of test specimens subjected to cyclic proportional and non-proportional loading. Two types of specimen samples were used. Firstly, two different plate test specimens were tested; a disk compact tension (DCT), and a modified compact tension, C(T). They were subjected cyclic loading inducing crack opening mode I or proportional crack opening modes I and II. Secondly, the previously and elsewhere acquired DIC data for five thin tubes subject to cyclic loading were analyzed. The thin tubes had pre-fabricated slit-notches from which fatigue cracks initiated and propagated. Those five thin tubes were subjected to different cases of proportional and non- proportional loading. One tube specimen was exposed to axial loading and presented mode I crack opening. The other four were subjected to torsion loading or mixed axial-torsional loading and exhibited all three I, II and III crack-opening modes. The experimentally acquired DIC displacement fields were processed to independently calculate SIF for each existing opening mode using linear elastic fracture mechanics (LEFM) formulations. One formulation used full field displacement data acquired in small areas that surrounded the crack tip. Another formulation used data acquired from a pair of points located along the opposite crack flanks. The determined SIFs were used to find equivalent SIFs and equivalent SIF ranges using the maximum tensile stress criterion (for both 2D and 3D versions of combinations of modes I-II and modes I-II-III respectively) which implicitly included the crack propagation angle. It was found that the inclusion of the experimentally determined mode III SIF indeed makes a difference in the determined equivalent SIF and equivalent SIF ranges. A da/dN versus equivalent SIF ranges plot was drafted with the experimentally measured crack growth rates and the SIF ranges that were found by using the widely accepted assumption that the cracks grew in the direction that maximizes the tensile stress. For this, extensions of the Schollmann et. al. model as well as of the Erdogan-Sih model, which are generally applied to proportional loading, were used to determine equivalent SIFs and equivalent SIF ranges for the cases of proportional and non-proportional loading. Finally, the second stage of the Paris rule (da/dN versus SIF range) was plotted for the five thin tubes loading cases showing that they fell inside a reasonably thin scattered band.

[pt] CARREGAMENTO MULTIAXIAL

[en] MULTIAXIAL LOADING

[pt] FATOR DE INTENSIDADE DE TENSAO

[en] STRESS INTENSITY FACTORS

[pt] MECANICA DE FRATURA LINEAR ELASTICA

[en] LINEAR ELASTIC FRACTURE MECHANICS

[pt] ABERTURA DA PONTA DA TRINCA

[en] DIGITAL IMAGE CORRELATION

[pt] METODO DOS MINIMOS QUADRADOS

[en] LEAST SQUARE METHOD

[pt] CARREGAMENTOS NAO PROPORCIONAIS

[en] NON-PROPORTIONAL LOADING

Novel Compression Fracture Specimens And Analysis of Photoelastic Isotropic Points

Kamadi, V N Surendra

January 2015

Compression fracture specimens are ideally suited for miniaturization down to tens of microns. Fracture testing of thermal barrier coatings, ceramics and glasses are also best accomplished under compression or indentation. Compression fracture specimen of finite size with constant form factor was not available in the literature. The finite-sized specimen of edge cracked semicircular disk (ECSD) is designed which has the property of constant form factor. The novel ECSD specimen is explored further using weight function concept. This thesis, therefore, is mainly concerned with the design, development and geometric optimization of compression fracture specimen vis a vis their characterization of form factors, weight functions and isotropic points in the uncracked geometry. Inspired by the Brazilian disk geometry, a novel compression fracture specimen is designed in the form of a semicircular disk with an edge crack which opens up due to the bending moment caused by the compressive load applied along its straight edge. This new design evolved from a set of photoelastic experiments conducted on the Brazilian disk and its two extreme cases. Surprisingly, normalized mode-I stress intensity factor of the semicircular specimen loaded under a particular Hertzian way, is found constant for a wide range of relative crack lengths. This property of constant form factor leads to the development of weight function for ECSD for deeper analysis of the specimen. The weight function of a cracked geometry does not depend on loading configuration and it relates stress intensity factor to the stress distribution in the corresponding uncracked geometry through a weighted integral. The weight function for the disk specimen is synthesized in two different ways: using the conventional approach which requires crack opening displacement and the dual form factor method which is newly developed. Since stress distribution in the uncracked specimen is required in order to use weight function concept, analytical solution is attempted using linear elasticity theory. Since closed form solution for stresses in the uncracked semicircular disk is seldom possible with the available techniques, a new semi-analytical method called partial boundary collocation (PBC), is developed which may be used for solving any 2-D elasticity problem involving a semi-geometry. In the new method, part of the boundary conditions are identically satisfied and remaining conditions are satisfied at discrete boundary points. The classical stress concentration factor for a semi-in finite plate with a semicircular edge notch re-derived using PBC is found to be accurate to the eighth decimal. To enhance the form factor in order to test high-toughness materials, edge cracked semicircular ring (ECSR) specimen is designed in which bending moment at the crack-tip is increased significantly due to the ring geometry. ECSR is analyzed using nite element method and the corresponding uncracked problem is analyzed by PBC. Constant form factor is found possible for the ring specimen with tiny notch. In order to avoid varying semi-Hertzian angle during practice and thereby ensure consistent loading conditions, the designs are further modified by chopping at the loading zones and analyzed. Photoelastic isotropic points (IPs) which are a special case of zeroth order fringe (ZOF) are often found in uncracked and cracked specimens. An analytical technique based on Flamant solution is developed for solving any problem involving circular domain loaded at its boundary. Formation of IPs in a circular disk is studied. The coefficients of static friction between the surfaces of disk and loading fixtures, in photoelastic experiments of three-point and four-point loadings, are explored analytically to confirm with experimental results. The disk under multiple radial loads uniformly spaced on its periphery is found to give rise to one isolated IP at the center. Splitting of this IP into a number of IPs can be observed when the symmetry of normal loading is perturbed. Tangential loading is introduced along with normal loading to capture the effect of the composition on formation of IPs. Bernoulli's lemniscate is found to fit fringe order topology local to multiple IPs. Isotropic points along with other low fringe order zones including ZOF are ideal locations for material removal for weight reduction. Making a small hole in the prospective crack path at the IP location in the uncracked geometry might provide dual benefits: 1. Form factor enhancement; 2. Crack arrestor. Thus, this thesis describes experimental, theoretical and computational investigations for the design, development and calibration of novel compact compression fracture specimens.

Photoelastic Isotropic Point

Linear Elastic Fracture Mechanics

Compression Fracture Specimens

Weight Functions

Fracture Mechanics

Isotropic Points

Edge Cracked Semicircular Disk (ECSD)

Semicircular Photoelastic Disk

Brazilian Disk

Hertzian Load

Flamant Solution

Stress Intensity Factor (SIF)

Stress Concentration Factor (SCF)

Photoelastic Pattern Recognition

Photoelastic Digital Image Analysis

Photoelastic IPs

Mechanical Engineering

Vyhodnocení lomově-mechanických parametrů betonu po vystavení vysokým teplotám / Mechanical fracture parameters of concrete after exposure to high temperatures

Bejček, Michal

January 2018

The diploma thesis is focused on the evaluation of mechanical fracture parameters of concrete after exposure to high temperatures. In the introductory theoretical part general principles of fracture mechanics with the concentration on a linear elastic fracture mechanics and non-linear fracture models for the concrete are summarized. The meaning of the three-point bending fracture test used for determination of fracture parameters is also explained. Further the influence of high temperatures on the partial components of concrete and general modeling of temperature loading is described. The practical part is concerned with the evaluation of fire experiments on the concrete panels including numerical simulations using GiD and ATENA software. The evaluation of data obtained from the three-point bending test carried out on specimens with initial stress concentrator taken from concrete panels is a main part of the diploma thesis. The values of modulus of elasticity, effective fracture toughness, work of fracture and fracture energy are determined from the measured F–d and F–CMOD diagrams after their proper corrections in the GTDiPS application. The evaluation of the selected mechanical fracture parameters was performed by StiCrack software using effective crack model and work of fracture method and DKFM_BUT software using the double-K fracture model. Finally, the attention is paid to the analysis of the obtained data.

Popis šíření trhlin v polích silně nehomogenních a reziduálních napětí / Description of Crack Propagation in the Fields of Strongly Non-Homogeneous and Residual Stresses

Štegnerová, Kateřina

January 2019

This Ph.D. thesis was written under the supervision of Assoc. Prof. Luboš Náhlík, Ph.D. and Assoc. Prof. Pavel Hutař, Ph.D. Thesis is focused mainly on application of generalized linear elastic fracture mechanics, which allows description of crack behaviour propagating from general singular stress concentrators, such as material interfaces or sharp V-notches, and verification of validity of used fracture criteria. The obtained results were used in the next part of the thesis, which deals with the issue of crack propagating in ceramic composites, where the stress distribution field is strongly influenced by the existence of material interface and presence of residual stresses, that arise during manufacturing process of composite.

Napjatost v okolí velmi ostrých bimateriálových vrubů / Stress distribution near sharp orthotropic bi-material notch tips

Krepl, Ondřej

January 2013

Presented diploma thesis is concerned with problems of a stress singularity exponent and a generalized stress intensity factor determination, by dint the stress field in the vicinity of the stress concentrator can be consecutively determined. This task is possible to sectionalize into three parts. The first part summarizes basic information about linear anisotropic materials, deals with fundamentals of the linear elastic fracture mechanics and introduces its generalization to the case of the generalized stress intensity factors. The second part is dedicated to a special theory of anisotropic elasticity - Lekhnitskii-Eshelby-Stroh formalism (LES). Furthermore, a theory of the psi-integral is introduced, by dint the stress intensity factor is determined. The final part applies the LES theory and the psi-integral to the concrete material configuration of a crack on the bimaterial interface, a special example of a sharp bimaterial notch. By means of analytical-numerical algorithm in ANSYS and Silverforst FNT95 software the stress singularity exponents and generalised stress intensity factors are consecutively computed.

[en] CRACK MODELING IN ASPHALT MIXTURES BY THE DISCRETE ELEMENT METHOD / [pt] MODELAGEM DO TRINCAMENTO DE MISTURAS ASFÁLTICAS PELO MÉTODO DOS ELEMENTOS DISCRETOS

JULIANA MARIA MEZA LOPEZ

28 October 2021

[pt] O trincamento de camada de mistura asfáltica é o principal tipo de deterioração das rodovias, e o presente estudo pretende contribuir para conhecimento dos processos de fissuramento com o objetivo de incorporar novos parâmetros mecânicos para melhorar projetos de pavimentação rodoviária . A modelagem computacional através do Método dos Elementos Discretos (MED), permitiu fazer uma simulação da iniciação e da propagação do trincamento em um ensaio de tração direta chamado de Disco Circular com Fenda (Disk Shaped compact), considerando uma abordagem da teoria da mecânica da fratura elástica linear (MFEL) e a incorporação do modelo constitutivo de zona coesiva (MZC). As modelagens realizadas permitiram inferir o comportamento de corpos de prova de Disco Circular com Fenda DC(T) feitos em laboratório. O método dos elementos discretos monstrou-se uma ferramenta apropriada para realizar este tipo de simulação. Também foram feitas análises da sensibilidade da resposta do modelo em relação a diversos parâmetros mecânicos do material: módulo de Young (E), resistência à tração (RT) e energia da fratura (Gf). Este último parâmetro foi obtido da área sob a curva tração-deslocamento da abertura da boca da trinca (CMOD). A análise foi realizada considerando o corpo como material homogêneo atribuindo-se a todas as partículas propriedades idênticas. A modelagem numérica 2D foi executada através do programa comercial PFC2D baseado no MED. / [en] The cracking of asphalt mixture layers is the main type of deterioration of roads in Brazil, and this study aims to contribute to improve the knowledge of cracking processes in order to incorporate new mechanical parameters into road pavement projects. Computer modeling by the Discrete Element Method (DEM), permitted the simulation of the initiation and the propagation of cracking in a tensile test called Direct Circular Slotted Disc (Disk Shaped Compact), whose interpretation is based on the theory of linear elastic fracture mechanics and considering an specific elastoplastic model known as the cohesive zone model (CZM). Results of Direct Circular Slotted Disc tests were obtained in laboratory and interpreted by numerical simulations using the discrete element method, with good results. The sensitivity of model response with respect to various mechanical parameters, such as the Young s modulus (E), the tensile strength (RT) and the fracture energy (Gf) was also analyzed. This last parameter (Gf) was obtained considering the area under the traction-displacement curve from the Crack Mouth Opening Displacement (CMOD) test. The analyses were carried out considering the body as a homogeneous material, assigning to all particles identical properties. The 2D numerical model was analyzed using the commercial software PFC2D based on the discrete element method (MED).

[pt] METODO DO ELEMENTO FINITO

[pt] PFC-2D

[pt] MODELAGEM NUMERICO

[pt] PROCESSO DE ZONA DE FRATURA

[pt] TRINCAMENTO DE PAVIMENTOS

[pt] MISTURAS ASFALTICAS

[pt] PROPAGACAO DE TRINCAS

[en] FINITE ELEMENT METHOD

[en] PFC2D

[en] NUMERICAL MODELING

[en] FRACTURING PROCESS ZONE

[en] CRACKING OF PAVEMENTS

[en] ASPHALT MIXTURES

[en] CRACK PROPAGATION