Měření posunů a přetvoření střešní konstrukce / Deformation Measurement of Roof Structure

Hubáček, David

January 2020

The thesis deals with the evaluation of displacements and deformation of the large span wooden roof structure of the aquapark hall in Brno - Kohoutovice. The task of this work is to compare and verify the applicability of the laser scanning method for the evaluation of displacements and deformation. The comparison was performed with regard to the polar method with quantities measured by the total station. As part of the work, two-stage measurements were performed on the basis of which a comparison of both methods was performed. The data obtained by the polar method were processed using LSM, the data from laser scanning were processed in an Excel spreadsheet. A comparison of the two methods shows that we have achieved a similar level of accuracy with the laser scanning method when compared to the polar method. It is therefore possible to use the laser scanning method to measure displacements and deformation.

Výpočetní analýza provozních deformací válcové jednotky vznětového motoru / Computational analysis of operational deformations of the diesel engine cylinder unit

Zalibera, Tomáš

January 2020

Submitted diploma thesis deals about operational deformations in the cylinder unit of turbocharged diesel engine used in commercial vehicles. Introductory part analyses combustion engines computational modelling based on finite element method. The next step is the creation of computational models for thermal-structural analyses of the piston and engine block. In order to determine material characteristics of the head gasket, experiment is performed on the OEM gasket to determine its real behaviour under compressive load. The results shows strong nonlinear behaviour which justifies the decision of making such an experiment in the first place. The results of computational models are radial deformations of the piston and cylinder liners during load conditions. The last chapter deals with the application of these results to an advanced computational piston assembly dynamics model.

Analýza zbytkových napětí ve stěně tepny / Analysis of residual stresses in arterial wall

Novák, Kamil

January 2013

This thesis deals with computational modeling of the influence of residual stresses in idealized geometry of blood vessels and subsequent application of acquired knowledge to abdominal aortic aneurysm. In the terms of quality of the computational model, we reduced the uncertainties that are included in the computational model without considering the influence of residual stresses. The basic assumption of homogenization significant peaks of the stress between inner and outer vessel wall was met for each level of the computational model Methods that have been used are: deformation method (opening angle method), inverse mechanics of large deformations, fictitious temperature – for linear elastic material and hyperelastic material defined by the constitutive model. Numerical verification was carried out using program ANSYS.

Parameter identification problems for elastic large deformations - Part I: model and solution of the inverse problem

Meyer, Marcus

20 November 2009

In this paper we discuss the identification of parameter functions in material models for elastic large deformations. A model of the the forward problem is given, where the displacement of a deformed material is found as the solution of a n onlinear PDE. Here, the crucial point is the definition of the 2nd Piola-Kirchhoff stress tensor by using several material laws including a number of material parameters. In the main part of the paper we consider the identification of such parameters from measured displacements, where the inverse problem is given as an optimal control problem. We introduce a solution of the identification problem with Lagrange and SQP methods. The presented algorithm is applied to linear elastic material with large deformations.

info:eu-repo/classification/ddc/510

ddc:510

Inverses Problem

identification problem

large elastic deformations

material laws

nonlinear inverse problem

sequential quadratic programming

Efektivita edukace dětských pacientů s vrozenou deformitou hrudní stěny ve FN Motol / Efficacy of education regarding child patients with congenital deformations of pectoral wall in University Hospital Motol

Popková, Zuzana

January 2014

The aim of this paper was, at first, to evaluate the effectiveness of education of child patients with inborn deformation of pectoral wall in the University Hospital Motol in the MIRPE (Minimally Invasive Pectus Excavatum) operation correcting the inborn deformation of pectoral wall by using of a metal bar and for its surgery extraction after three years. At second, to map the effectiveness of education of child patients done by the hospital personnel during their hospitalization in the University Hospital Motol. This paper also presents its own opinions of both groups of respondents on the current system of education done in the clinical practice. According to the available sources there was not in the Czech Republic any similar study about this problem realized up to now. There were 116 respondents involved in the research who went through the MIRPE surgery and the extraction of their bar in the University Hospital Motol. The data that were received by the method of own constructive form was further statistically processed. From the analysis of the results came up a need to improve the education in the pre-surgery time, and to better develop the system of education during the hospitalization of child patients. There was an interest confirmed from the researched respondents about printed...

Časosběrný monitoring aktivních svahových deformací pomocí elektrické odporové tomografie / Time-lapse monitoring of active slope deformations using electrical resistivity tomography

Belov, Tomáš

January 2014

The diploma thesis deals with time-lapse electrical resistivity tomography (TL-ERT) of active slope deformations. Slope deformations represent one of the important land-forming processes. Frequently, they can cause considerable property damages and can endanger health and lives of inhabitants. Therefore, we can consider them as potentially dangerous so complete understanding of their dynamics, and their mechanisms of origin, is essential. Electrical resistivity tomography (ERT) then represents an effective geophysical tool for slope deformation investigation. Within diploma thesis, the evaluation of the several different time-series of the ERT measurements was performed. Based on findings of the one- year (August 1013 to July 2014) monitoring of resistivity changes by ERT, and also, based on daily and hourly recurrences of measured resistivity data, the optimum measuring interval has been determined, namely 12 hours. The most applicable electrode arrays and their combinations were suggested based on a testing of different electrode configurations. The results of detailed measurement with 1 m electrode spacing offered the idea of shortening of the total length of the present permanent TL-ERT profile as well as shortening the electrode spacing. These conclusions and proposed adjustments then resulted in...

Highly Stretchable Miniature Strain Sensor for Large Dynamic Strain Measurement

Yao, Shulong

05 1900

This thesis aims to develop a new type of highly stretchable strain sensor to measure large deformation of a specimen subjected to dynamic loading. The sensor was based on the piezo-resistive response of carbon nanotube(CNT)/polydimethysiloxane (PDMS) composites thin films, some nickel particles were added into the sensor composite to improve the sensor performance. The piezo-resistive response of CNT composite gives high frequency response in strain measurement, while the ultra-soft PDMS matrix provides high flexibility and ductility for large strain measuring large strain (up to 26%) with an excellent linearity and a fast frequency response under quasi-static test, the delay time for high strain rate test is just 30 μs. This stretchable strain sensor is also able to exhibit much higher sensitivities, with a gauge factor of as high as 80, than conventional foil strain gauges.

strain sensor

stretchable

CNT/PDMS composite

piezo-resistive response

frequency response

Materials -- Dynamic testing.

Elasticity.

Deformations (Mechanics)

Composite materials.

Thin films.

Polydimethylsiloxane.

Carbon nanotubes.

Modélisation du comportement thermomécanique et cyclique des matériaux à mémoire de forme en transformations finies / Constitutive Modeling of the Thermomechanical and Cyclic Behavior of Shape Memory Alloys in Finite Deformations

Wang, Jun

22 September 2017

Cette thèse présente une approche globale de la modélisation du comportement thermomécanique et cyclique des alliages à mémoire de forme (AMF) en grandes déformations. Cette approche s’articule en trois étapes : i) La généralisation du modèle ZM de comportement des AMF en grandes déformations dans le cadre de la thermodynamique des processus irréversibles. Pour ce faire, le gradient de la transformation totale est décomposé sous la forme du produit de trois gradients : le gradient de transformation lié à la déformation élastique, le gradient lié au changement de phase et le gradient de transformation lié à la réorientation de la martensite. Cette décomposition permet ainsi la modélisation de la réponse des structures en AMF dans le cas de chargements multiaxiaux non-proportionnels en transformations fi nies. ii) La prise en compte du couplage thermomécanique en transformations fi nies. Pour ce faire, la déformation de Henckya été introduite. Le modèle obtenu intègre trois caractéristiques thermomécaniques importantes des AMF, à savoir l’effet de la coexistence de l’austénite et de deux variantes de martensites distinctes, la variation de la taille de la boucle d’hystérésis avec la température et la transition du processus de changement de phase, d’abrupt à doux. iii) Enfin, en vue de prédire la réponse des structures en AMF sous chargement thermomécanique cyclique, le modèle développé dans la deuxième étape est généralisé pour décrire la pseudoélasticité cyclique des AMF polycristallins. Le modèle obtenu permet la prise en compte de quatre caractéristiques fondamentales liées au comportement cyclique des AMF : la déformation résiduelle accumulée, la dégénérescence de la boucle d’hystérésis, l’évolution de la transformation de phase, d’abrupte à douce. La mise en œuvre numérique de ces modèles s’appuie sur des algorithmes d’intégration appropriés. Des exemples numériques on été traités pour valider chaque étape. / Shape Memory Alloys (SMAs) are a class of smart materials that possess two salient features known as pseudoelasticity (PE) and shape memory effect(SME). In industrial applications, SMA structures are typically subjected to complex service conditions, such as large deformations, thermomechanically coupled boundaries and loadings, and cyclic loadings. The reliability and durability analysis of these SMA structures requires a good understanding of constitutive behavior in SMAs. To this end, this work develops a comprehensive constitutive modeling approach to investigate thermomechanical and cyclic behavior of SMAs in fi nite deformations. The work is generally divided into three steps. First, to improve accuracy of SMA model infinite deformation regime, the ZM model proposed by Zaki and Moumni (2007b) is extended within a fi nite-strain thermodynamic framework. Moreover, the transformation strain is decomposed into phase transformation and martensite reorientation components to capture multi-axial non-proportional response. Secondly, in addition to the fi nite deformation, thermomechanical coupling effect is taken into account by developing a new fi nite-strain thermomechanical constitutive model. A more straightforward approach is obtained by using the fi nite Hencky strain. This model incorporates three important thermomechanical characteristics, namely the coexistence effect between austenite and two distinct martensite variants, the variation with temperature of hysteresis size, and the smooth transition at initiation and completion of phase transformation. Finally, with a view to studying SMA behavior under cyclic loading, the model developed in the second step is generalized to describe cyclic pseudoelasticity of polycrystalline SMAs. The generalized model captures four fundamental characteristics related to the cyclic behavior of SMAs: large accumulated residual strain, degeneration of pseudoelasticity and hysteresis loop, rate dependence, and evolution of phase transformation from abrupt to smooth transition. Numerical implementation of these models are realized by introducing proper integration algorithms. Finite element simulations, including orthodontic archwire, helical and torsion spring actuators, are carried out using the proposed models. The future directions of this work mainly involve plasticity and fatigue analysis of SMA structures.

Alliages à mémoire de forme

Modèle constitutif

Simulation numérique

Transformations finies

Couplage thermomécanique

Comportement cyclique

Shape memory alloys

Constitutive model

Numerical simulation

Finite deformations

Thermomechanical coupling

Cyclic behavior

620.1

Physically motivated modelling of magnetoactive elastomers

Chougale, Sanket Vijay

27 June 2022

Magnetoactive elastomers (MAEs) are polymer composites containing magnetically soft or hard particles incorporated into an elastomer matrix during the crosslinking procedure. In the presence of a magnetic field, the induced magnetic interactions and the corresponding particle rearrangements significantly alter the mechanical properties in dependence on the initial particle distribution and sample shape. In addition, applying magnetic fields also changes the macroscopic shape of an MAE. This thesis investigates the magneto-mechanical coupled behaviour of MAEs by means of analytical and numerical methods. The effects of particle distribution and sample shape have been studied with the help of a physically motivated model of MAEs that considers dipole-dipole interactions between magnetizable particles. The presence of a magnetic field leads to a mechanical anisotropy in MAEs with isotropic particle distribution, and the induced anisotropy is directed along the orientation of the field. Thus, MAEs exhibit direction-dependent mechanical properties with distinct elastic moduli along and perpendicular to the field direction when the MAE sample is subjected to uniaxial deformation. A good agreement is reported between the physically motivated approach and conventional transversely isotropic material models. Furthermore, we investigate the important interplay between the particle distribution and the sample shape of MAEs, where a simple analytical expression is derived based on geometrical arguments to describe the particle distribution inside MAEs. We show that the enhancement of elastic moduli arises not only from the induced dipole-dipole interactions but also considerably from the change in the particle microstructure. Moreover, the magneto-mechanical behaviour of isotropic MAEs under shear deformations is studied. Three principal geometries of shear deformation are investigated with respect to the orientation of the applied magnetic field. We show that the Cauchy stress tensor of MAEs is not always symmetric due to the generation of a magnetic torque acting on an anisometric MAE sample under shear loadings. The theoretical study of magneto-mechanical behaviour of MAEs confirms that the effect of sample shape is quite significant and cannot be neglected. On the other hand, the initial particle distribution and presumed rearrangements due to the magnetic field additionally influence the material response of MAEs. Finally, the physically motivated model of MAEs could be transformed into an invariants-based model enabling its implementation in commercial finite element software. Therefore, we have uncovered a new pathway to model MAEs based on dipole-dipole interactions, leading to a constitutive relation analogous to the macro-scale continuum approach and revealing a synergy between both modelling strategies.

info:eu-repo/classification/ddc/620

ddc:620

Development and Application of the Boundary Singularity Method to the Problems of Hydrodynamic and Viscous Interaction.

Mikhaylenko, Maxim A.

January 2015

No description available.

Mechanical Engineering

Boundary Singularity Method

stokes equations

microfluidics

allocation of singularities

matrix condition number

quasi-steady approach

viscous deformations

sub-micron and nano-fibers

FVM and BSM coupling