Teses / dissertações sobre o tema "Immersed structures"
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O'Connor, Joseph. "Fluid-structure interactions of wall-mounted flexible slender structures". Thesis, University of Manchester, 2018. https://www.research.manchester.ac.uk/portal/en/theses/fluidstructure-interactions-of-wallmounted-flexible-slender-structures(1dab2986-b78f-4ff9-9b2e-5d2181cfa009).html.
Texto completo da fonteCorti, Daniele Carlo. "Numerical methods for immersed fluid-structure interaction with enhanced interfacial mass conservation". Electronic Thesis or Diss., Sorbonne université, 2024. http://www.theses.fr/2024SORUS176.
Texto completo da fonteThe present thesis is dedicated to the modeling, numerical analysis, and simu- lation of fluid-structure interaction problems involving thin-walled structures immersed in incompressible viscous fluid. The underlying motivation behind this work is the simulation of the fluid-structure interaction phenomena involved in cardiac valves. From a methodological standpoint, special focus is placed on unfitted mesh methods that guarantee accuracy without compromising computational complexity. An essential aspect is ensuring mass conservation across the fluid-structure interface. An extension of the unfitted mesh Nitsche-XFEM method reported in Alauzet et al. (2016) to three dimensions is first pro- posed, addressing both fully and partially intersected fluid domains. To achieve this, a robust general tessellation algorithm has been developed without relying on black-box mesh generators. Additionally, a novel approach for enforcing continuity in partially intersected domains is introduced. However, in situations involving contact phenomena with multiple interfaces, the computational implementation becomes exceedingly complex, particularly in 3D. Subsequently, an innovative low-order fictitious domain method is introduced, which mitigates inherent mass conservation issues arising from continuous pressure approximation by incorporating a single velocity constraint. A comprehensive a priori error analysis for a Stokes problem with a Dirichlet constraint on an immersed interface is provided. Finally, this fictitious domain approach is formulated within a fluid-structure interaction framework with general thin-walled solids and successfully applied to simulate the dynamics of the aortic valve
Kara, Mustafa Can. "Fluid-structure interaction (FSI) of flow past elastically supported rigid structures". Diss., Georgia Institute of Technology, 2013. http://hdl.handle.net/1853/51931.
Texto completo da fonteLeone, Giada <1995>. "The production of dative structures in Italian English-immersed late bilinguals: a comparative study on Language Attrition". Master's Degree Thesis, Università Ca' Foscari Venezia, 2022. http://hdl.handle.net/10579/22026.
Texto completo da fontePepona, Marianna. "Modèle de frontières immergées pour la simulation d'écoulements de fluide en interaction avec des structures poreuses". Thesis, Aix-Marseille, 2016. http://www.theses.fr/2016AIXM4349/document.
Texto completo da fonteA wide spectrum of engineering problems is concerned with fluid flows in interaction with porous structures, ranging from small length-scale problems to large ones. These structures, often of complex geometry, may move/deform in response to the forces exerted by the surrounding flow. Despite the advancements in computational fluid dynamics, the numerical simulation of such configurations - a valuable tool for the study of the flow physics involved - remains a challenging task.The aim of the present work is to propose a numerical model for the macroscopic simulation of fluid flows interacting with moving porous media of complex geometry, that is easy to implement and can be used in a range of applications. To achieve this, the Lattice Boltzmann method is employed for solving the flow in porous media at the representative elementary volume scale. For the implementation of the desired body motion, the concept of the Immersed Boundary method is adopted. In this context, a novel model is proposed for dealing with moving volumetric porous media, whose resistance to the surrounding flow obeys the Brinkman-Forchheimer-extended Darcy law. The algorithm is initially tested for flow past a static cylinder. The simplicity of this academic test case allows us to assess in detail the accuracy of the proposed method. The model is later used to simulate fluid flows around and through moving porous bodies, both in a confined geometry and in open space. We are able to demonstrate the Galilean invariance of the macroscopic volume-averaged flow governing equations. Excellent agreement with reference results is obtained in all cases
Nasar, Abouzied. "Eulerian and Lagrangian smoothed particle hydrodynamics as models for the interaction of fluids and flexible structures in biomedical flows". Thesis, University of Manchester, 2016. https://www.research.manchester.ac.uk/portal/en/theses/eulerian-and-lagrangian-smoothed-particle-hydrodynamics-as-models-for-the-interaction-of-fluids-and-flexible-structures-in-biomedical-flows(507cd0db-0116-4258-81f2-8d242e8984fa).html.
Texto completo da fonteSidibé, Yaya Yannick. "Aide à la décision pour la détection et l’analyse des défauts de surface dans les structures immergées". Thesis, Le Havre, 2015. http://www.theses.fr/2015LEHA0006/document.
Texto completo da fonteThis study concerns the damages detection and diagnosis for immersed structure. The structures are metallic plates. The proposed method focuses on the analysis of ultrasonic acoustic measurements obtained by submarine echography. It combines signal processing tools and Gaussian neural networks for classification purpose. Methods with and without reference models are proposed. The usual detection technics with contact are not applicable for the considered systems like stream turbines. This research consists to use a single and a single transducer under different incidence angles opposed to others technics using numerous sensors and their accurate location. The present research use Lamb wave according to their sensibility to the structural damages. The different stages are the following : - 1. Experimental setup for Lamb wave generation and acquisition. - 2. Study of the Lamb wave processing on immersed structures, in particular in metallic plate immersed in water. - 3 .Signal characterization for different types of damages. - 4. Estimation of the angle and lift-off distance
Benyo, Krisztian. "Analyse mathématique de l’interaction d’un fluide non-visqueux avec des structures immergées". Thesis, Bordeaux, 2018. http://www.theses.fr/2018BORD0156/document.
Texto completo da fonteThis PhD thesis concerns the mathematical analysis of the interaction of an inviscid fluid with immersed structures. More precisely it revolves around two main problems: one of them is the asymptotic analysis of an infinitesimal immersed particle, the other one being the interaction of water waves with a submerged solid object. Concerning the first problem, we studied a system of second order non-linear ODEs, serving as a toy model for the motion of a rigid body immersed in a two-dimensional perfect fluid. The unknowns of the model describe the position of the object, that is the position of its center of mass and the angle of rotation; the equations arise from Newton’s second law with the consideration of a Kutta-Joukowski type lift force. It concerns the detailed analysis of the dynamic of this system when the solid inertia tends to 0. For the evolution of the position of the solid’s center of mass, the study highlights similarities with the motion of a charged particle in an electromagnetic field and the wellknown “guiding center approximation”; it turns out that the motion of the corresponding guiding center is given by a point-vortex equation. As for the angular equation, its evolution is given by a slowly-in-time modulated non-linear pendulum equation. Based on the initial values of the system one can distinguish qualitatively different regimes: for small angular velocities, by the Poincaré-Lindstedt method one observes a modulation in the fast time-scale oscillatory terms, for larger angular velocities however erratic rotational motion is observed, a consequence of Melnikov’s observations on the presence of a homoclinic tangle. About the other problem, the Cauchy problem for the water waves equations is considered in a fluid domain which has a free surface on the upper vertical limit and a flat bottom on which a solid object moves horizontally, its motion determined by the pressure forces exerted by the fluid. Two shallow water asymptotic regimes are detailed, well-posedness results are obtained for both the Saint-Venant and the Boussinesq system coupled with Newton’s equation characterizing the solid motion. Using the particular structure of the coupling terms one is able to go beyond the standard scale for the existence time of solutions to the Boussinesq system with a moving bottom. An extended numerical study has also been carried out for the latter system. A high order finite difference scheme is developed, extending the convergence ratio of previous, staggered grid based models. The discretized solid mechanics are adapted to represent important features of the original model, such as the dissipation due to the friction term. We observed qualitative differences for the transformation of a passing wave over a moving solid object as compared to an immobile one. The movement of the solid not only influences wave attenuation but it affects the shoaling process as well as the wave breaking. The importance of the coefficient of friction is also highlighted, influencing qualitative and quantitative properties of the coupled system. Furthermore, we showed the hydrodynamic damping effects of the waves on the solid motion, reminiscent of the so-called dead water phenomenon
Boilevin-Kayl, Ludovic. "Modeling and numerical simulation of implantable cardiovascular devices". Thesis, Sorbonne université, 2019. http://www.theses.fr/2019SORUS039.
Texto completo da fonteThis thesis, taking place in the context of the Mivana project, is devoted to the modeling and to the numerical simulation of implantable cardiovascular devices. This project is led by the start-up companies Kephalios and Epygon, conceptors of minimally invasive surgical solutions for the treatment of mitral regurgitation. The design and the simulation of such devices call for efficient and accurate numerical methods able to correctly compute cardiac hemodynamics. This is the main purpose of this thesis. In the first part, we describe the cardiovascular system and the cardiac valves before presenting some standard material for the mathematical modeling of cardiac hemodynamics. Based on the degree of complexity adopted for the modeling of the valve leaflets, two approaches are identified: the resistive immersed surfaces model and the complete fluidstructure interaction model. In the second part, we investigate the first approach which consists in combining a reduced modeling of the valves dynamics with a kinematic uncoupling of cardiac hemodynamics and electromechanics. We enhance it with external physiological data for the correct simulation of isovolumetric phases, cornerstones of the heartbeat, resulting in a relatively accurate model which avoids the complexity of fully coupled problems. Then, a series of numerical tests on 3D physiological geometries, involving mitral regurgitation and several configurations of immersed valves, illustrates the performance of the proposed model. In the third and final part, complete fluid-structure interaction models are considered. This type of modeling is necessary when investigating more complex problems where the previous approach is no longer satisfactory, such as mitral valve prolapse or the closing of a mechanical valve. From the numerical point of view, the development of accurate and efficient methods is mandatory to be able to compute such physiological cases. We then consider a complete numerical study in which several unfitted meshes methods are compared. Next, we present a new explicit coupling scheme in the context of the fictitious domain method for which the unconditional stability in the energy norm is proved. Several 2D numerical examples are provided to illustrate the properties and the performance of this scheme. Last, this method is finally used for 2D and 3D numerical simulation of implantable cardiovascular devices in a complete fluid-structure interaction framework
Yang, Liang. "An immersed computational framework for multiphase fluid-structure interaction". Thesis, Swansea University, 2015. https://cronfa.swan.ac.uk/Record/cronfa42413.
Texto completo da fonteCai, Shang-Gui. "Computational fluid-structure interaction with the moving immersed boundary method". Thesis, Compiègne, 2016. http://www.theses.fr/2016COMP2276/document.
Texto completo da fonteIn this thesis a novel non-body conforming mesh formulation is developed, called the moving immersed boundary method (MIBM), for the numerical simulation of fluid-structure interaction (FSI). The primary goal is to enable solids of complex shape to move arbitrarily in an incompressible viscous fluid, without fitting the solid boundary motion with dynamic meshes. This novel method enforces the no-slip boundary condition exactly at the fluid-solid interface with a boundary force, without introducing any artificial constants to the rigid body formulation. As a result, large time step can be used in current method. To determine the boundary force more efficiently in case of moving boundaries, an additional moving force equation is derived and the resulting system is solved by the conjugate gradient method. The proposed method is highly portable and can be integrated into any fluid solver as a plug-in. In the present thesis, the MIBM is implemented in the fluid solver based on the projection method. In order to obtain results of high accuracy, the rotational incremental pressure correction projection method is adopted, which is free of numerical boundary layer and is second order accurate. To accelerate the calculation of the pressure Poisson equation, the multi-grid method is employed as a preconditioner together with the conjugate gradient method as a solver. The code is further parallelized on the graphics processing unit (GPU) with the CUDA library to enjoy high performance computing. At last, the proposed MIBM is applied to the study of two-way FSI problem. For stability and modularity reasons, a partitioned implicit scheme is selected for this strongly coupled problem. The interface matching of fluid and solid variables is realized through a fixed point iteration. To reduce the computational cost, a novel efficient coupling scheme is proposed by removing the time-consuming pressure Poisson equation from this fixed point interaction. The proposed method has shown a promising performance in modeling complex FSI system
Madani, Kermani Seyed Hossein. "Application of immersed boundary method to flexible riser problem". Thesis, Brunel University, 2014. http://bura.brunel.ac.uk/handle/2438/9605.
Texto completo da fonteMawson, Mark. "Interactive fluid-structure interaction with many-core accelerators". Thesis, University of Manchester, 2014. https://www.research.manchester.ac.uk/portal/en/theses/interactive-fluidstructure-interaction-with-manycore-accelerators(a4fc2068-bac7-4511-960d-41d2560a0ea1).html.
Texto completo da fonteDouteau, Louis. "CFD simulation with anisotropic mesh adaptation : application to floating offshore wind turbines". Thesis, Ecole centrale de Nantes, 2020. http://www.theses.fr/2020ECDN0003.
Texto completo da fonteThe simulation of Floating Offshore Wind Turbines (FOWTs) is a tool to help this technology reach an industrial scale. Nowadays, low-precision numerical methods are used for the dimensioning of the structures, as they involve a reduced computational effort. This PhD thesis focused on the development of highly-accurate numerical methods, with a potential to provide a thin description of the flows and efforts around FOWTs. The simulations presented in this thesis have been realized on the highly-parallelized software platform ICI-tech. A resolution of the Navier- Stokes equations in a Variational MultiScale formulation is performed using Stabilized Finite Elements. The representation of the different phases in the computational domain is achieved using immersed boundary methods. Several numerical tools have been implemented in ICItech towards an application to the simulation of FOWTs. A fluid-structure interaction paradigm has been set up, and a numerical wave tank has been defined. Verification and validation studies have been realized to assess the solver results for environmental conditions representative of those observed for operating FOWT. The accuracy achieved for both the aerodynamics at high Reynolds numbers and the propagation of wave fields has been disappointing. The influence of the anisotropic meshing on the results presented has been quantified. Several options aiming at increasing the accuracy of the simulations have been discussed
Yin, Y. "Turbulence model and immersed boundary method development in TELEMAC-3D for offshore structure modelling". Thesis, University of Liverpool, 2017. http://livrepository.liverpool.ac.uk/3006448/.
Texto completo da fonteLespagnol, Fabien. "A new numerical approach for the fluid-structure interaction of slender bodies immersed in three-dimensional flows". Electronic Thesis or Diss., Sorbonne université, 2024. http://www.theses.fr/2024SORUS158.
Texto completo da fonteThis PhD dissertation aims to develop a new modeling and computational approach for the simulation of slender bodies immersed in three dimensional flows (3D). Thanks to the special geometric configuration of the slender structures, we can model this problem by mixed-dimensional coupled equations in which the solid balance equations are formulated in a one-dimensional (1D) domain. The main advantages of the approach we present in this manuscript lies in its strong mathematical basis. Indeed, while many standard mixed-dimensional formulations yield solutions with poor regularity due to ill-posed trace operators, our reduced order method generates solutions within standard Hilbert spaces. In the second chapter, we establish the continuous formulation of the 3D fluid-structure interaction coupled problem using incompressible Navier-Stokes equations for the description of the fluid dynamics and a linear Timoshenko beam model for modeling the response of the slender structure. These two models are coupled with a mixed-dimensional version of fluid-structure interface conditions, combining the fictitious domain (FD) approach with the projection of kinematic coupling conditions onto a finite-dimensional Fourier space via Lagrange multipliers. We then develop a discrete formulation based on the finite element method and a semi-implicit treatment of the Dirichlet-Neumann coupling conditions. We establish the energy stability of the scheme and provide extensive numerical evidence of the accuracy and robustness of the discrete formulation.In the third and fourth chapter we conduct a mathematical analysis on the approximation error of our reduced order coupled method, examining both the modeling and numerical approximation errors resulting from the mixed-dimensional formulation and the fictitious domain finite element method, respectively. We explore these aspects in two simplified frameworks. We first consider a two-dimensional Poisson problem (2D) with a fixed immersed boundary and non-homogeneous Dirichlet boundary conditions. We then extend this analysis to the 2D stationary Stokes problem with rigid-body Dirichlet boundary conditions on the immersed interface. In both cases, after proving the existence of solutions for the reduced order problem, we prove its convergence, when the size of the obstacle is small, to the full order problem with standard Dirichlet boundary conditions. Subsequently, the numerical discretization of the reduced order problem is analyzed. In particular, to address the limitations of the fictitious domain approach, we propose and analyze two modified finite element method, one stabilized and one augmented. Finally, we develop a 2D fluid-structure interaction formulation where small particles are immersed in a Stokesian flow, applying reduced order interface coupling conditions. The properties of the reduced order model and the corresponding numerical methods are illustrated by some numerical experiments.Using a semi-implicit scheme for the resolution of the 3D fluid-structure interaction problem requires to iterate over the fluid and solid solvers multiple times, which can be computationally expensive. Subsequently, in the last chapter, we introduce a Robin-based loosely coupled scheme specifically designed for 3D mixed-dimensional formulation and prove its unconditional stability. We also provide numerical evidence of the accuracy of the explicit scheme through several test cases
Ni, Mong-Tang. "Analysis of fluid structure interaction problem using immersed boundary method with a finite element approach /". May be available electronically:, 2008. http://proquest.umi.com/login?COPT=REJTPTU1MTUmSU5UPTAmVkVSPTI=&clientId=12498.
Texto completo da fonteTschisgale, Silvio. "A numerical method for fluid-structure interactions of slender rods in turbulent flow". TUDpress - Thelem Universitätsverlag, 2018. https://tud.qucosa.de/id/qucosa%3A38706.
Texto completo da fonteGao, Haotian. "POD-Galerkin based ROM for fluid flow with moving boundaries and the model adaptation in parametric space". Diss., Kansas State University, 2018. http://hdl.handle.net/2097/38776.
Texto completo da fonteDepartment of Mechanical and Nuclear Engineering
Mingjun Wei
In this study, a global Proper Orthogonal Decomposition (POD)-Galerkin based Reduced Order model (ROM) is proposed. It is extended from usual fixed-domain problems to more general fluid-solid systems with moving boundaries/interfaces. The idea of the extension is similar to the immersed boundary method in numerical simulations which uses embedded forcing terms to represent boundary motions and domain changes. This immersed boundary method allows a globally defined fixed domain including both fluid and solid, where POD-Galerkin projection can be directly applied. However, such a modified approach cannot get away with the unsteadiness of boundary terms which appear as time-dependent coefficients in the new Galerkin model. These coefficients need to be pre-computed for prescribed periodic motion, or worse, to be computed at each time step for non-prescribed (e.g. with fluid-structure interaction) or non-periodic situations. Though computational time for each unsteady coefficient is smaller than the coefficients in a typical Galerkin model, because the associated integration is only in the close neighborhood of moving boundaries. The time cost is still much higher than a typical Galerkin model with constant coefficients. This extra expense for moving-boundary treatment eventually undermines the value of using ROMs. An aggressive approach is to decompose the moving boundary/domain to orthogonal modes and derive another low-order model with fixed coefficients for boundary motion. With this domain decomposition, an approach including two coupled low-order models both with fixed coefficients is proposed. Therefore, the new global ROM with decomposed approach is more efficient. Though the model with the domain decomposition is less accurate at the boundary, it is a fair trade-off for the benefit on saving computational cost. The study further shows, however, that the most time-consuming integration in both approaches, which come from the unsteady motion, has almost negligible impact on the overall dynamics. Dropping these time-consuming terms reduces the computation cost by at least one order while having no obvious effect on model accuracy. Based on this global POD-Galerkin based ROM with forcing term, an improved ROM which can handle the parametric variation of body motions in a certain range is also presented. This study shows that these forcing terms not only represent the moving of the boundary, but also decouple the moving parameters from the computation of model coefficients. The decoupling of control parameters provides the convenience to adapt the model for the prediction on states under variation of control parameters. An improved ROM including a shit mode seems promising in model adaptation for typical problems in a fixed domain. However, the benefit from adding a shit mode to model diminishes when the method is applied to moving-boundary problems. Instead, a combined model, which integrates data from a different set of parameters to generate the POD modes, provides a stable and accurate ROM in a certain range of parametric space for moving-boundary problems. By introducing more data from a different set of parameters, the error of the new model can be further reduced. This shows that the combined model can be trained by introducing more and more information. With the idea of the combined model, the improved global ROM with forcing terms shows impressive capability to predict problems with different unknown moving parameters, and can be used in future parametric control and optimization problems.
Lahjomri, Jawad. "Caractérisation de la structure des sillages M. H. D. Amont et aval d'un cylindre à petit nombre de Reynolds magnétique". Grenoble 1, 1988. http://www.theses.fr/1988GRE10046.
Texto completo da fonteMarco, Alacid Onofre. "Structural Shape Optimization Based On The Use Of Cartesian Grids". Doctoral thesis, Universitat Politècnica de València, 2018. http://hdl.handle.net/10251/86195.
Texto completo da fonteLa competitividad en la industria actual impone la necesidad de generar nuevos y mejores diseños. El tradicional procedimiento de prueba y error, usado a menudo para el diseño de componentes mecánicos, ralentiza el proceso de diseño y produce diseños subóptimos, por lo que se necesitan nuevos enfoques para obtener una ventaja competitiva. Con el desarrollo del Método de los Elementos Finitos (MEF) en el campo de la ingeniería en la década de 1970, la optimización de forma estructural surgió como un área de aplicación prometedora. El entorno industrial cada vez más exigente implica ciclos cada vez más cortos de desarrollo de nuevos productos. Por tanto, la naturaleza iterativa de los procesos de optimización de forma, que supone el análisis de gran cantidad de geometrías (para las se han de usar modelos numéricos de gran tamaño a fin de limitar el efecto de los errores intrínsecamente asociados a las técnicas numéricas), puede incluso disuadir del uso de estas técnicas. Esta Tesis se centra en la formulación de una metodología 3D basada en el Cartesian-grid Finite Element Method (cgFEM) como herramienta para un análisis numérico eficiente y robusto. Esta metodología pertenece a la categoría de técnicas de discretización Immersed Boundary donde el concepto clave es extender el problema de análisis estructural a un dominio de aproximación, que contiene la frontera del dominio físico, cuya discretización (mallado) resulte sencilla. El uso de mallados cartesianos proporciona una plataforma natural para la optimización de forma estructural porque el dominio numérico está separado del modelo físico, que podrá cambiar libremente durante el procedimiento de optimización sin alterar la discretización subyacente. Otro argumento positivo reside en el hecho de que la generación de malla se convierte en una tarea trivial. La discretización del dominio numérico y su manipulación, en coalición con la eficiencia de una estructura jerárquica de datos, pueden ser explotados para ahorrar coste computacional. Sin embargo, estas ventajas pueden ser cuestionadas por varios problemas numéricos. Básicamente, el esfuerzo computacional se ha desplazado. Del uso de costosos algoritmos de mallado nos movemos hacia el uso de, por ejemplo, esquemas de integración numérica elaborados para poder capturar la discrepancia entre la frontera del dominio geométrico y la malla de elementos finitos que lo embebe. Para ello, utilizamos, por un lado, una formulación de estabilización para imponer condiciones de contorno y, por otro lado, hemos desarrollado nuevas técnicas para poder captar la representación exacta de los modelos geométricos. Para completar la implementación de un método de optimización de forma estructural se usa una formulación adjunta para derivar las sensibilidades de diseño requeridas por los algoritmos basados en gradiente. Las derivadas no son sólo variables requeridas para el proceso, sino una poderosa herramienta para poder proyectar información entre diferentes diseños o, incluso, proyectar la información para crear mallas h-adaptadas sin pasar por un proceso completo de refinamiento h-adaptativo. Las mejoras propuestas se reflejan en los ejemplos numéricos presentados en esta Tesis. Estos análisis muestran claramente el comportamiento superior de la tecnología cgFEM en cuanto a precisión numérica y eficiencia computacional. En consecuencia, el enfoque cgFEM se postula como una herramienta adecuada para la optimización de forma.
Actualment, amb la competència existent en la industria, s'imposa la necessitat de generar nous i millors dissenys . El tradicional procediment de prova i error, que amb freqüència es fa servir pel disseny de components mecànics, endarrereix el procés de disseny i produeix dissenys subòptims, pel que es necessiten nous enfocaments per obtindre avantatge competitiu. Amb el desenvolupament del Mètode dels Elements Finits (MEF) en el camp de l'enginyeria en la dècada de 1970, l'optimització de forma estructural va sorgir com un àrea d'aplicació prometedora. No obstant això, a causa de la natura iterativa dels processos d'optimització de forma, la manipulació dels models numèrics en grans quantitats, junt amb l'error de discretització dels mètodes numèrics, pot fins i tot dissuadir de l'ús d'aquestes tècniques (o d'explotar tot el seu potencial), perquè al mateix temps els cicles de desenvolupament de nous productes s'estan acurtant. Esta Tesi se centra en la formulació d'una metodologia 3D basada en el Cartesian-grid Finite Element Method (cgFEM) com a ferramenta per una anàlisi numèrica eficient i sòlida. Esta metodologia pertany a la categoria de tècniques de discretització Immersed Boundary on el concepte clau és expandir el problema d'anàlisi estructural a un domini d'aproximació fàcil de mallar que conté la frontera del domini físic. L'utilització de mallats cartesians proporciona una plataforma natural per l'optimització de forma estructural perquè el domini numèric està separat del model físic, que podria canviar lliurement durant el procediment d'optimització sense alterar la discretització subjacent. A més, un altre argument positiu el trobem en què la generació de malla es converteix en una tasca trivial, ja que la discretització del domini numèric i la seua manipulació, en coalició amb l'eficiència d'una estructura jeràrquica de dades, poden ser explotats per estalviar cost computacional. Tot i això, estos avantatges poden ser qüestionats per diversos problemes numèrics. Bàsicament, l'esforç computacional s'ha desplaçat. De l'ús de costosos algoritmes de mallat ens movem cap a l'ús de, per exemple, esquemes d'integració numèrica elaborats per poder capturar la discrepància entre la frontera del domini geomètric i la malla d'elements finits que ho embeu. Per això, fem ús, d'una banda, d'una formulació d'estabilització per imposar condicions de contorn i, d'un altra, desevolupem noves tècniques per poder captar la representació exacta dels models geomètrics Per completar la implementació d'un mètode d'optimització de forma estructural es fa ús d'una formulació adjunta per derivar les sensibilitats de disseny requerides pels algoritmes basats en gradient. Les derivades no són únicament variables requerides pel procés, sinó una poderosa ferramenta per poder projectar informació entre diferents dissenys o, fins i tot, projectar la informació per crear malles h-adaptades sense passar per un procés complet de refinament h-adaptatiu. Les millores proposades s'evidencien en els exemples numèrics presentats en esta Tesi. Estes anàlisis mostren clarament el comportament superior de la tecnologia cgFEM en tant a precisió numèrica i eficiència computacional. Així, l'enfocament cgFEM es postula com una ferramenta adient per l'optimització de forma.
Marco Alacid, O. (2017). Structural Shape Optimization Based On The Use Of Cartesian Grids [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/86195
TESIS
Taymans, Claire. "Solving Incompressible Navier-Stokes Equations on Octree grids : towards Application to Wind Turbine Blade Modelling". Thesis, Bordeaux, 2018. http://www.theses.fr/2018BORD0157/document.
Texto completo da fonteThe subject of the thesis is the development of a numerical tool that allows to model the flow around wind blades. We are interested in the solving of incompressible Navier-Stokes equations on octree grids, where the smallest scales close to the wall have been modelled by the use of the so-called Wall Functions. An automatic Adaptive Mesh Refinement (AMR) process has been developed in order to refine the mesh in the areas where the vorticity is higher. The structural model of a real wind blade has also been implemented and coupled with the fluid model. Indeed, an application of the numerical tool is the study of the effects of wind gusts on blades. An experimental work has been conducted with an in-service wind turbine with the measurement of wind speed upstream. This data will allow to calibrate and validate the numerical models developed in the thesis
Benguigui, William. "Modélisation de la réponse dynamique d’une paroi solide mise en vibration par un écoulement fluide diphasique". Thesis, Université Paris-Saclay (ComUE), 2018. http://www.theses.fr/2018SACLY014/document.
Texto completo da fonteIn nuclear power plants, steam generator tubes vibrate because of steam/water cross-flows. In order to understant this phenomenon, reduced-scale experiments are performed. Numerical simulations have shown their ability to accurately reproduce the vibration induced by a single phase flow in a tube bundle. The aim of the present work is to do the same with two-phase flow and to characterize the effect of the mixture physical properties on vibration.To do so, a CFD code based on a two-fluid approach is used. A "discrete forcing" method is implemented in order to allow solid body motion in a two-phase flow. The validation is performed with simple and industrial cases using experimental and theoretical results.Using an existing implicit algorithm, a fluid-structure coupling based on the developed interface tracking method is implemented. Validated for single and two-phase flows, it is now possible to have solid motion induced by fluid forces.The different numerical models dedicated to two-phase flows are then evaluated on a freon/freon flow across an inclined tube bundle. The use of a multi-regime model is required. In order to investigate the role of the different physical properties on the vibration, three simple studies are performed.Finally, the industrial application, a freon/water flow across a square pitch tube bundle, is performed. First, it is compared to a steam/water flow in order to characterize the discrepancies when we are using a modeling mixture. Then, the vibration induced by single- and two-phase flows is reproduced by the developed method on feasibility test cases
Constant, Eddy. "Développement d’un solveur de frontières immergées dans OpenFOAM : vers le contrôle des vibrations induites par vortex dans le sillage d’un cylindre". Thesis, Aix-Marseille, 2017. http://www.theses.fr/2017AIXM0637/document.
Texto completo da fonteThis thesis is related to the simulation and the control of the vortex induced vibrations phenomenon (VIV), which can result from the fluid structure interactions between an unsteady wake and the body, when the shedding frequency in the wake is close to the natural frequency of the body. The control of VIV is a critical issue when optimizing many systems. An Immersed Boundaries Method (IBM) was implemented into the PISO algorithm as a new library of OpenFOAM, in order to perform reliable simulations of incompressible flows around bluff bodies.To compute the divergence of the momentum equation and the interpolation of the fluxes, an hybrid calculation with an analytical resolution of the quantities involving the force term (singular quantities) has been proposed. The mesh convergence of several errors was shown by means of a manufactured solution, allowing to analyze both the errors irelated to the discretization and to the IBM. The new algorithm was subsequently extended to the RANS and DDES formalism proposed in OpenFOAM for the simulation of turbulent flows. A wall law was integrated into theIBM method to model the boundary layers that develop around the bodies at large Reynolds numbers. Various 2D and 3D well-documented test cases of academic flows around fixed or moving solid bodies (cylinderand sphere) have been simulated and carefully validated against existing data from the literature in a large range of Reynolds numbers. With the objective of developing optimal control laws for VIV, based on the linear instability mechanisms of the coupled system within the framework of the control theory, a new adjoint solver was also developed and validated in OpenFOAM
Nadal, Soriano Enrique. "Cartesian grid FEM (cgFEM): High performance h-adaptive FE analysis with efficient error control. Application to structural shape optimization". Doctoral thesis, Universitat Politècnica de València, 2014. http://hdl.handle.net/10251/35620.
Texto completo da fonteCada d'¿a dise¿nos m'as complejos son requeridos por las industrias actuales. Para el dise¿no de nuevos componentes, los procesos tradicionales de prueba y error usados com'unmente ya no son v'alidos ya que ralentizan el proceso y dan lugar a dise¿nos sub-'optimos. Para componentes estructurales, una alternativa consiste en usar procesos de optimizaci'on de forma estructural los cuales dan como resultado dise¿nos 'optimos. Sin embargo, estas t'ecnicas requieren un alto coste computacional y tambi'en programas de Elementos Finitos (EF) extremadamente eficientes y robustos. Las compa¿n'¿as de programas de EF son conocedoras de que sus programas comerciales necesitan ser mejorados en este sentido y destinan importantes cantidades de recursos para mejorar sus c'odigos. En este trabajo proponemos usar el M'etodo de Elementos Finitos basado en mallados Cartesianos (cgFEM) como una herramienta eficiente y robusta para el an'alisis num'erico. La metodolog'¿a cgFEM desarrollada en esta tesis usa la sinergia entre varias t'ecnicas para lograr este prop'osito, cuyos dos ingredientes principales son el uso de los mallados Cartesianos de EF independientes de la geometr'¿a del componente que va a ser analizado y una eficiente estructura jer'arquica de datos. Estas dos caracter'¿sticas confieren a la tecnolog'¿a cgFEM de los requisitos necesarios para aumentar la eficiencia del c'odigo cgFEM con respecto a c'odigos comerciales. Como se indica en [1, 2], para garantizar la convergencia del proceso de optimizaci'on de forma estructural se necesita controlar el error en cada geometr'¿a analizada. En este sentido el c'odigo cgFEM tambi'en incorpora los apropiados estimadores de error. Estos estimadores de error han sido espec'¿ficamente adaptados al entorno cgFEM para aumentar su eficiencia. En esta tesis se introduce un proceso de recuperaci'on de la soluci'on, llamado SPR-CD, que en combinaci'on con el estimador de error de Zienkiewicz y Zhu [3], da como resultado medidas muy precisas del error de la soluci'on de EF. Adicionalmente, tambi'en se han desarrollado estimadores de error y cotas num'ericas en Magnitudes de Inter'es basadas en la t'ecnica SPR-CD para permitir un eficiente control de la calidad de la soluci'on num'erica. Respecto a la estimaci'on de error, tambi'en se presenta un proceso de estimaci'on de error para controlar la calidad del campo de tensiones recuperado obtenido mediante la t'ecnica SPR-CD. Ya que el campo recuperado es por lo general m'as preciso y tiene un mayor orden de convergencia que la soluci'on de EF, se propone sustituir la soluci'on de EF por la soluci'on recuperada para disminuir as'¿ el coste computacional del an'alisis num'erico. Todas estas mejoras se han reflejado en esta tesis mediante ejemplos num'ericos de problemas de optimizaci'on de forma estructural. Los resultados num'ericos muestran claramente un mejor comportamiento de la tecnolog'¿a cgFEM con respecto a implementaciones cl'asicas de EF com'unmente usadas en la industria.
Nadal Soriano, E. (2014). Cartesian grid FEM (cgFEM): High performance h-adaptive FE analysis with efficient error control. Application to structural shape optimization [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/35620
TESIS
Mohaghegh, Fazlolah. "A parallelized diffuse interface solver with applications to meso scale simulation of suspensions". Diss., University of Iowa, 2017. https://ir.uiowa.edu/etd/5971.
Texto completo da fonteHellou, Mustapha. "Etude numérique et expérimentale de l'écoulement à structure cellulaire engendré par la rotation d'un cylindre dans un canal". Poitiers, 1988. http://www.theses.fr/1988POIT2267.
Texto completo da fonteValdez, Andrés Ricardo. "On lattice Boltzmann method for solving fluid-structure interaction problems". Universidade Federal de Juiz de Fora (UFJF), 2017. https://repositorio.ufjf.br/jspui/handle/ufjf/6104.
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Neste trabalho são apresentados aspectos de modelagem computacional para o estudo de Interação Fluido-Estrutura (FSI). Numericamente, o Método de Lattice Boltzmann (LBM) é usado para resolver a mecânica dos fluidos, em particular as equações de Navier-Stokes incompressíveis. Neste contexto, são abordados problemas de escoamentos complexos, caracterizado pela presença de obstáculos. A imposição das restrições na interface fluido-sólido é feita utilizando princípios variacionais, empregando o Princípio de Balanço de Potências Virtuais (PVPB) para obter as equações de Euler-Lagrange. Esta metodologia permite determinar as dependências entre carregamentos cinematicamente compatíveis e o estado mecânico adotado. Neste sentido, as condições de interface fluido-sólido são abordadas pelo Método de Fronteira Imersa (IBM) visando técnicas computacionais de baixo custo. A metodologia IBM trata o equilíbrio das equações na interface fluido-sólido através da interpolação entre os nós Lagrangianos (sólidos) e os nós Eulerianos (fluidos). Neste contexto, uma modificação desta estratégia que fornece soluções mais precisas é estudada. Para mostrar as capacidades do acoplamento LBM-IBM são apresentados vários experimentos computacionais que demonstram grande fidelidade entre as soluções obtidas e as soluções disponíveis na literatura.
This work presents computational modeling aspects for studying Fluid-Structure Interaction (FSI). The Lattice Boltzmann Method (LBM) is employed to solve the fluid mechanics considering the incompressible Navier-Stokes equations. The flows studied are complex due to the presence of arbitrary shaped obstacles. The obstacles alters the bulk flow adding complexity to the analysis. In this work the Euler-Lagrange equations are obtained employing the Principle of Virtual Power Balance (PVPB). Consequently, the functional dependencies between the mechanical state and every kinematic compatible loadings are established employing variational arguments. This modeling technique allows to study the fluid-solid boundary constraint. In this context the fluid-solid interface is handled employing the Immersed Boundary Method (IBM). The IBM deals with the fluid-solid interface equilibrium equations performing an interpolation of forces between Lagrangian nodes (solid domain) and Eulerian Lattice grid (fluid domain). In this work a different version of this methodology is studied that allows to obtain more accurate solutions. To show the capabilities of the implemented LBM-IBM solver several experiments are done showing the agreement with the benchmarks results available in literature.
Mege, Romain. "Solutions analytiques en dynamique non-linéaire avec couplage fluide-structure". Thesis, Paris Est, 2013. http://www.theses.fr/2013PEST1126/document.
Texto completo da fonteAs the seismic loadings are increasing in accordance to the recent regulations regarding Earthquake design, the use of sliding devices in structures is becoming more common. These devices limitate the internal forces by creating a rigid body sliding. It is then necessary to estimate the global displacement of the structure, especially concerning structures that are immersed in a reservoir. In this case, the displacement must be well estimated in order to prevent impacts between the sliding structure and the boundaries of the reservoir. We can find such structures in : bridges, costal structures in brick and masonry, or in the nuclear industry with the underwater fuel storage racks, ...The governing equations for the behaviour of these structures are non linear and must be solved using time-consuming computer simulations which are not fit for a stochastic study. Our method consists in, firstly, evaluating analytically the added masses of the fluid-structure interaction, secondly, a semi-analytical solving of the governing equations including the updating of the dimensions of the fluid layers surrounding the sliding structure. The results of this new method are in accordance with the numerical simulations and can be obtained in a short time (1 or 2 seconds) which offers the possibility to make a stochastic analysis of the non linear behaviour
Gibaud, Etienne. "Numerical simulation of red blood cells flowing in a blood analyzer". Thesis, Montpellier, 2015. http://www.theses.fr/2015MONTS135/document.
Texto completo da fonteThe aim of this thesis is to improve the understanding of the phenomena involved in the measurement performed in a blood analyzer, namely the counting and sizing of red blood cells based on the Coulter effect. Numerical simulations are performed to predict the dynamics of red blood cells in the measurement regions, and to reproduce the associated electrical measurement used to count and size the cells. These numerical simulations are performed in industrial configurations using a numerical tool developed at IMAG, the YALES2BIO solver. Using the Front-Tracking Immersed Boundary Method, a deformable particle model for the red blood cell is introduced which takes the viscosity contrast as well as the mechanical effects of the curvature and elasticity on the membrane into account. The solver is validated against several test cases spreading over a large range of regimes and physical effects.The velocity field in the blood analyzer geometry is found to consist of an intense axial velocity gradient in the direction of the flow, resulting in a extensional flow at the micro-orifice, where the measurement is performed. The dynamics of the red blood cells is studied with numerical simulations with different initial conditions, such as its position or orientation. They are found to reorient along the main axis of the blood analyzer in all cases. In order to understand the phenomenon, analytical models are adapted to the case of extensional flows and are found to reproduce the observed trends.This thesis also presents the reproduction of the electrical measurement used to count red blood cells and measure their volume distribution. Numerous dynamics simulations are performed and used to generate the electrical pulse corresponding to the passage of a red blood cell inside the micro-orifice. The resulting electrical pulse amplitudes are used to characterize the electrical response depending on the initial parameters of the simulation by means of a statistical approach. A Monte-Carlo algorithm helps quantifying the errors on the measurement of cell depending on its orientation and position inside the micro-orifice. This allows the generation of a measured volume distribution of a well defined red blood cell population and the characterization of the associated measurement errors
Sarthou, Arthur. "Méthodes de domaines fictifs d'ordre élevé pour les équations elliptiques et de Navier-Stokes. Application au couplage fluide-structure". Phd thesis, Université Sciences et Technologies - Bordeaux I, 2009. http://tel.archives-ouvertes.fr/tel-00460206.
Texto completo da fonteBenguigui, William. "Modélisation de la réponse dynamique d’une paroi solide mise en vibration par un écoulement fluide diphasique". Electronic Thesis or Diss., Université Paris-Saclay (ComUE), 2018. http://www.theses.fr/2018SACLY014.
Texto completo da fonteIn nuclear power plants, steam generator tubes vibrate because of steam/water cross-flows. In order to understant this phenomenon, reduced-scale experiments are performed. Numerical simulations have shown their ability to accurately reproduce the vibration induced by a single phase flow in a tube bundle. The aim of the present work is to do the same with two-phase flow and to characterize the effect of the mixture physical properties on vibration.To do so, a CFD code based on a two-fluid approach is used. A "discrete forcing" method is implemented in order to allow solid body motion in a two-phase flow. The validation is performed with simple and industrial cases using experimental and theoretical results.Using an existing implicit algorithm, a fluid-structure coupling based on the developed interface tracking method is implemented. Validated for single and two-phase flows, it is now possible to have solid motion induced by fluid forces.The different numerical models dedicated to two-phase flows are then evaluated on a freon/freon flow across an inclined tube bundle. The use of a multi-regime model is required. In order to investigate the role of the different physical properties on the vibration, three simple studies are performed.Finally, the industrial application, a freon/water flow across a square pitch tube bundle, is performed. First, it is compared to a steam/water flow in order to characterize the discrepancies when we are using a modeling mixture. Then, the vibration induced by single- and two-phase flows is reproduced by the developed method on feasibility test cases
Gomes, Henrique Campelo. "Método dos elementos finitos com fronteiras imersas aplicado a problemas de dinâmica dos fluidos e interação fluido-estrutura". Universidade de São Paulo, 2013. http://www.teses.usp.br/teses/disponiveis/3/3144/tde-26122013-150059/.
Texto completo da fonteThis work is divided in three parts. Initially, it is presented a stabilized Finite Element Method formulation to solve fluid flow problems governed by the incompressible Navier-Stokes Equations. This formulation was implemented in a computer code and validated throughout several numeric simulations. Some well-known finite elements with different pairs of velocity/pressure approximations, as well as some other less popular elements, were investigated and their performance compared. The second part describes the Structural Problem formulation. This formulation is able to simulate nonlinear dynamic problems involving large displacements and finite strains during long period of time. In the final part of this work, it is proposed a Fluid-Structure Interaction method based on an immersed interface approach in opposition to classical ALE (Arbitrary Lagrangian Eulerian) approaches. Generalized Finite Elements, together with Lagrange Multipliers, are used to provide velocity and pressure discontinuities on the fluid domain across the immersed interface. To couple both fluid and structural problems, an implicit staggered scheme is adopted, which allows the easy implementation of already developed black box computer codes.
Tayllamin, Bruno. "Evaluation d'une méthode de Frontières immergées pour les simulations numériques d'écoulements cardiovasculaires". Thesis, Montpellier 2, 2012. http://www.theses.fr/2012MON20100.
Texto completo da fonteThe most common approach in Computational Fluid Dynamics(CFD) for simulating blood flow into vessel is to make use of a body-fitted me-thod. This approach has lead to accurate and useful simulations of blood flowinto arteries. However, generation of the body-fitted grid is time consuming andrequires from the user an engineering knowledge.The Immersed Boundary Method has emerged as an alternate method whichdoes not require from the user any grid generation task. Simulations are done on astructured Cartesian grid which can be automatically generated. Here we addressthe question of the capability of an Immersed Boundary Method to cope withcardiovascular flow simulations.In particular, we assess the impermeable and moving properties of the wallwhen using the Immersed Boundary Method on simple but relevant vascular flowcases. Then, we show more complex and realistic cardiovascular flow simulations.The first application consists of blood flow simulation inside an aorta cross model.Then, the simulation of blood flow inside a cardiac ventricle with moving wall isshown
Sigüenza, Julien. "Fluid-structure interaction problems involving deformable membranes : application to blood flows at macroscopic and microscopic scales". Thesis, Montpellier, 2016. http://www.theses.fr/2016MONTT301/document.
Texto completo da fonteThis thesis deals with several scientific aspects inherent to the numerical simulation of fluid-structure interaction problems involving thin deformable membranes. Two specific cases relevant to cardiovascular biomechanics are considered: the interaction of the blood flow with the aortic valve (which occurs at the macroscopic scale), and the interaction of the red blood cells membrane with its inner and outer fluids (which occurs at the microscopic scale). In both cases, the fluid-structure interaction coupling is handled using an immersed boundary formalism, representing the membrane by a Lagrangian mesh moving through an Eulerian fluid mesh.When dealing with red blood cells dynamics, the membrane is considered to be an infinitely thin and massless structure. The first question which is addressed in the present thesis work is how to model the complex microstructure of the red blood cells membrane. A possible way to characterize a suitable membrane model is to simulate the optical tweezers experiment, which is a well-controlled experimental configuration enabling to study the individual mechanics of an isolated red blood cell in a large range of deformation. Some relevant membrane models are identified, but the deformation characteristics measured during the optical tweezers experiment reveal to be not selective enough to be used in a validation context. Additional deformation measurements are proposed, which could allow a better characterization of the red blood cell membrane mechanics.Regarding the macroscopic configurations, an innovative numerical method is proposed to handle numerical simulations of 3D continuum membranes, still within the immersed boundary formalism. In this method, called immersed thick boundary method, the membrane has a finite thickness. The accuracy and robustness of the method are demonstrated through a variety of well-chosen test cases. Then, the proposed method is applied to a realistic fluid-structure interaction problem, namely the interaction of a pulsatile (blood) flow with a biomimetic aortic valve. A combined experimental and numerical study is led, showing that the method is able to capture the global dynamics of the valve, as well as the main features of the flow downstream of the valve.All the developments were performed within the YALES2BIO solver (http://www.math.univ-montp2.fr/~yales2bio/) developed at IMAG, which is thus available for further improvements, validations and applicative studies
OLIVIERI, STEFANO. "Elastically-bounded flapping plates for flow-induced energy harvesting". Doctoral thesis, Università degli studi di Genova, 2020. http://hdl.handle.net/11567/999997.
Texto completo da fontePauthenet, Martin. "Macroscopic model and numerical simulation of elastic canopy flows". Thesis, Toulouse, INPT, 2018. http://www.theses.fr/2018INPT0072/document.
Texto completo da fonteWe study the turbulent flow of a fluid over a canopy, that we model as a deformable porous medium. This porous medium is more precisely a carpet of fibres that bend under the hydrodynamic load, hence initiating a fluid-structure coupling at the scale of a fibre's height (honami). The objective of the thesis is to develop a macroscopic model of this fluid-structure interaction in order to perform numerical simulations of this process. The volume averaging method is implemented to describe the large scales of the flow and their interaction with the deformable porous medium. An hybrid approach is followed due to the non-local nature of the solid phase; While the large scales of the flow are described within an Eulerian frame by applying the method of volume averaging, a Lagrangian approach is proposed to describe the ensemble of fibres. The interface between the free-flow and the porous medium is handle with a One-Domain- Approach, which we justify with the theoretical development of a mass- and momentum- balance at the fluid/porous interface. This hybrid model is then implemented in a parallel code written in C$++$, based on a fluid- solver available from the \openfoam CFD toolbox. Some preliminary results show the ability of this approach to simulate a honami within a reasonable computational cost. Prior to implementing a macroscopic model, insight into the small-scale is required. Two specific aspects of the small-scale are therefore studied in details; The first development deals with the inertial deviation from Darcy's law. A geometrical parameter is proposed to describe the effect of inertia on Darcy's law, depending on the shape of the microstructure of the porous medium. This topological parameter is shown to efficiently characterize inertia effects on a diversity of tested microstructures. An asymptotic filtration law is then derived from the closure problem arising from the volume averaging method, proposing a new framework to understand the relationship between the effect of inertia on the macroscopic fluid-solid force and the topology of the microstructure of the porous medium. A second research axis is then investigated. As we deal with a deformable porous medium, we study the effect of the pore-scale fluid-structure interaction on the filtration law as the flow within the pores is unsteady, inducing time-dependent fluidstresses on the solid- phase. For that purpose, we implement pore-scale numerical simulations of unsteady flows within deformable pores, focusing for this preliminary study on a model porous medium. Owing to the large displacements of the solid phase, an immersed boundary approach is implemented. Two different numerical methods are compared to apply the no-slip condition at the fluid-solid interface: a diffuse interface approach and a sharp interface approach. The objective is to find the proper method to afford acceptable computational time and a good reliability of the results. The comparison allows a cross-validation of the numerical results, as the two methods compare well for our cases. This numerical campaign shows that the pore-scale deformation has a significant impact on the pressure drop at the macroscopic scale. Some fundamental issues are then discussed, such as the size of a representative computational domain or the form of macroscopic equations to describe the momentum transport within a soft deformable porous medium
Beltzung, Thibaud. "Simulation et modélisation des interactions fluide-structure en écoulements diphasiques Parallel geothermal numerical model with fractures and multi-branch wells". Thesis, Université Paris-Saclay (ComUE), 2019. http://www.theses.fr/2019SACLV052.
Texto completo da fonteSteam generators are a key component of nuclear power reactors, and an in-depth knowledge of their mechanisms is a major industrial challenge for the designer AREVA-NP and the operator EDF. Vibration of tube bundles induced by cross-flow is one of the problems encountered by the designer, thus needing to assess the vibration response to the excitation generated by the flow. The critical region is the U shape of the bundle (upper part of the steam generator), where two-phase cross-flow occurs with an important void fraction. In order to measure excitation induced by flow fluctuations on the tube bundle, some physical parameters have to be identified. For single-phase flows, it seems possible to link load on tubular structure to turbulence intensity of the flow, thanks to experimental data reduction methods together with numerical simulation methods. For two-phase flows, it is believed that forces induced on the tubes by the flow have other origins, and might be connected to dynamic contribution of each phase together with interfacial transfers. Nevertheless, relevant physical parameters which could predict the amplitude of the forces remain a subject of debate (void fraction, flow regime, etc.) and physical processes not yet fully understood. In order to study mechanical instabilities in two-phase flows, some analytic experiments a have been and continue to be conducted at CEA. These analytic experiments focuses on isolated tube or tube bundles (rigid or flexible), and on a large regime flow range (AMOVI and DIVA mockups at CEA). They aim to describe these mechanical instabilities (forces measurement on the obstacle) based upon average parameters of the flow (gas and liquid flow rates, "mean" void fraction, etc.), but also local parameters (local void fraction, bubble size, gas velocity, etc.). These measured or locally estimated parameters are used to conduct relevant nondimensionalization, both on the random excitation forces (two-phase excitation spectrum on a rigid tube) and the fluid-elastic coupling forces (single flexible tube or flexible bundle). Nonetheless, some dispersion remains on the results, physical mechanisms are not well understood, and the nondimensionalization process remains dependent on metrology. The aim of this PhD thesis is to conduct numerical simulations with front tracking in configurations close to the experiments conducted at CEA in order to expand the knowledge on phenomena leading to vibration of tube bundle in steam generators
Kitatani, Júnior Sigeo. "Modelagem matemática e simulação numérica para solução de problemas de interação fluido-estrutura utilizando metodologia de fronteira imersa". Universidade Federal de Uberlândia, 2009. https://repositorio.ufu.br/handle/123456789/14913.
Texto completo da fonteIn this work, the combined multi-direct forcing and immersed boundary method (IBM) were presented to simulate uid-structure interaction problems. The multi-direct forcing is used aim at satisfying the no-slip condition in the immersed boundary. For the numerical simulations was used a multi-purpose computer code that is being developed in the MFlab - Fluid Mechanics Laboratory of Federal University of Uberl^andia. Tests are made to validate the numerical schemes and routines were implemented to simulate uid-structures interaction problems. Furthermore, computational tools are developed to construct and manage and optimize the use of a Beowulf cluster where all the parallel simulations presented in this work were done. The Method of Manufactured Solutions has been used for order-of-accuracy verication in the computational uid dynamics code. Two uid-structure interaction problems were studied using this methodology. The rst is a ow over a sphere for some Reynolds numbers. The results were compared to empirical results, obtaining satisfactory approximations. The second one is a immersed simple pendulum. For this problem the results are in agreement with physics. Indeed, these are preliminar results. New tests must be done to make progress in the methodology. Improvements are proposed in the IBM, in the uid-structure model, in the turbulence model, in the method used to discretize the uid domain. It is also proposed to apply the methodology to real problems as risers and valves.
O presente trabalho tem como principal objetivo a aplicação do método multifoçagem (MMF) para solução numérica tridimensional de problemas de interação uidoestrutura, buscando-se garantir a condição de não-escorregamento na região da fronteira imersa. Para as simulações numéricas foi utilizado um código computacional multipropósito em desenvolvimento no MFlab - Laboratório de Mecânica dos Fluidos da Universidade Federal de Uberlândia. Foram feitas modificações nesse código para que se pudesse validá-lo para solução de problemas com fronteira imersa e foi implementada uma rotina para solução de um problema de interação uido-estrutura total. Além disso, foi desenvolvido um pacote de ferramentas computacionais que possibilitou instalar e melhorar o desempenho de um cluster do tipo Beowulf utilizado para o desenvolvimento das simulações num eriças em paralelo do presente trabalho. Utilizando o Método das Soluções Manufaturadas foram obtidas soluções sintetizadas para as equações de Navier-Stokes, o que possibilitou obter a ordem de convergência numérica do código computacional para problemas contínuos e a validação deste código para problemas envolvendo corpos imersos ao combinar a o método das soluções manufaturadas com a metodologia de fronteira imersa. Na sequência foi solucionado o problema de escoamento ao redor de uma esfera parada, cujos resultados foram comparados com referencias empíricas, obtendo-se boa aproximação. Ainda para esse caso foi feita a avalição da norma L2 para as soluções num eriças obtidas nos pontos lagrangianos verificando a garantia da condição de não-escorregamento e feita uma análise da inuência dos número de ciclos utilizados no método multi-forçagem. Foi vericado que a solução numérica obtida depende do número de ciclos o que faz com que seja necessário se estabelecer um critério de convergência para este método. Um segundo problema de interação uido-estrutura total foi estudado. Consiste em um pêndulo simples imerso em um uido que parte de uma dada posição angular inicial e oscila em torno da sua posição de equilíbrio, até parar. Para esse caso foram feitas análises quantitativas. Os resultados são preliminares mas coerentes com a física do problema, indicando que a metodologia é adequada para solução deste tipo de problema.
Mestre em Engenharia Mecânica
Brauer, Alexia de. "Simulation de modèles multi-matériaux sur maillage cartésien". Thesis, Bordeaux, 2015. http://www.theses.fr/2015BORD0152/document.
Texto completo da fonteWe are interested in the simulation of compressible multimaterial flows and especially influid/structure interactions in transient states and fast dynamics. We aim to describe the evolution of materials of very different constitutive laws with an unified model. The materials are only differentiated by their own constitutive laws and are separated by a sharp interface. They can be as well fluids or elastic solids and under go large de formations. The model is written in the Eulerian framework. The numerical scheme is solved on Cartesian grids for simulations in three dimensions. An extension of the elastic model is added to describe the plastic deformations of solids
Sarkis, Bruno. "Étude numérique de la relaxation de capsules confinées par couplage des méthodes Volumes Finis - Éléments Finis via la méthode des frontières immergées IBM : influence de l'inertie et du degré de confinement". Thesis, Sorbonne université, 2018. http://www.theses.fr/2018SORUS184/document.
Texto completo da fonteCapsules, made of a drop protected by an elastic membrane, are widly present in nature and in diverse industrial applications, but few studies have explored the transient phenomena governing their relaxation. The objective of the PhD is to study the influence of inertia and confinement on the relaxation of a spherical capsule (1) pre-deformed into an ellipsoid and released in a square channel where the fluid is quiescent, (2) flowing in a square channel with a sudden expansion (‘step’). The capsule is modeled as a Newtonian fluid in a hyperelastic membrane without thickness or viscosity and is simulated coupling the Finite Volume - Finite Element - Immersed Boundary Methods. Its relaxation in a quiescent fluid exhibits three phases: the initiation of the fluid motion, the rapid and then slow retraction phases of the membrane. Three regimes exist depending on the confinement ratio and the Reynolds to capillary number ratio: pure, critical or oscillating damping. A Kelvin-Voigt inertial model is proposed to predict the response time constants and also applied to a capsule flowing in the microfluidic channel with a step. The comparison to 3D simulations shows its relevance at short relaxation times. This work paves the way to the study of transient flows of capsules confined in microfluidic devices
Sanches, Rodolfo André Kuche. "Sobre o acoplamento fluido-casca utilizando o método dos elementos finitos". Universidade de São Paulo, 2011. http://www.teses.usp.br/teses/disponiveis/18/18134/tde-17042011-184131/.
Texto completo da fonteThis work consists of the development of computational tools for nonlinear geometric fluid-shell interaction analysis using the Finite Element Method (FEM). The fluid solver is explicit and its time integration based on characteristics. The computational code is able to simulate the Navier-Stokes equations for compressible flows written in the Eulerian description as well as in the arbitrary Lagrangian-Eulerian (ALE) description, enabling movements prescription for the fluid mesh. The structure is modeled in a total Lagrangian description, using a FEM formulation to deal with geometrical nonlinear dynamics of shells based on the minimum potential energy theorem written regarding nodal positions and generalized unconstrained vectors, not displacements and rotations, avoiding the use of large rotation approximations. Two partitioned coupling models are developed. The first model, ideal for simulations where the displacements scale is not very large compared to the fluid domain, is based on the ALE description and the coupling between the two different meshes is done by mapping the fluid boundary nodes local positions over the shell elements and vice-versa, avoiding the need for matching fluid and shell nodes. The fluid mesh is adapted using a simple approach based on shell nodal positions and velocities. The second model, ideal for problems with large scales of displacements such as inflatable structures, is based on immersed boundary and consists of a robust level-set based approach that integrates the Lagrangian shell finite and the Eulerian finite element high speed fluid flow solver, with no need for mesh adaptation, where the fluid representation relies on a fixed unstructured mesh larger or equal to the initial fluid domain and the fluid-shell interface inside the fluid mesh is tracked with level sets of a boundary signed distance function. Both models are tested with numerical examples, showing efficiency and robustness. Finally, as a suggestion for future development of this research, we started studies relatives to B-Spline functions. The use of this kind of functions should solve stability problems related to spurious oscillations due to the use of Lagrange polynomials for representing discontinuities.
Billon, Laure. "Génération et adaptation de maillage volume-couche limite dynamique pour les écoulements turbulents autour de géométries complexes". Thesis, Paris Sciences et Lettres (ComUE), 2016. http://www.theses.fr/2016PSLEM077/document.
Texto completo da fonteNumerical simulation of turbulent aerodynamics flows remains challenging. Such fluid-structure interaction problem involves generally a thin layer close to the wall where the fluid is slow down, called boundary layer. This latter requires a carefull study of the boundary layer since it is crucial regarding the accuracyof the complete flow computation. Therefore, a fine and structured mesh is needed close to the wall. In this work, we propose a novel automatic procedure to build a correct boundary layer mesh according to the theory and the flow parameters. Moreover, in order to describe exactly the behaviour of the flow on the whole domain, the boundary layer mesh is combined with a dynamic mesh adaptation method.It follows an advanced version of the edge based mesh adaptation method. Combined together, they ensure a fine and structured mesh in the boundarylayer while all the flow vortices are accurately resolved. This new method, called boundary-volume mesh adaptation, has been validated on several 2D and 3Dtest cases with complex geometries. Results emphasises the capacity ofthe approach and offer opportunities of improvement for numerical fluid mechanics mesh adaptation
Hovnanian, Jessica. "Méthode de frontières immergées pour la mécanique des fluides : application à la simulation de la nage". Phd thesis, Université Sciences et Technologies - Bordeaux I, 2012. http://tel.archives-ouvertes.fr/tel-00835013.
Texto completo da fonteOdhiambo, Ernest, e 歐內斯特. "Direct forcing immersed boundary simulation of vibrating structures in progressive waves". Thesis, 2016. http://ndltd.ncl.edu.tw/handle/38368802384683596504.
Texto completo da fonte國立臺灣科技大學
機械工程系
104
This thesis is concerned with the numerical modeling of the interaction between progressive waves and slender cylindrical structures. Maritime structures often comprise cylinders of small diameter relative to the prevailing wave length. We describe the Direct Forcing Immersed Boundary (DFIB) simulation of the hydroelastic behaviour of two rigid, horizontal circular cylinders and an elastic vertical cylinder in regular progressive waves. Fluid motions are numerically solved by the full Navier-Stokes equations, and the free surface by the Volume-of-Fluid (VOF) method. The motion of the elastic cylinder is solved by the Euler-Bernoulli equation. The rigid horizontal cylinders are modeled on a single-degree-of-freedom (SDOF) and two-degree-of-freedom (2DOF) bases , while the elastic vertical cylinder on a single-degree-of-freedom basis. Validation tests using analytical and experimental data have been successfully done. Three regimes are isolated for the SDOF rigid horizontal cylinder: lower beating; lock-in; and upper beating modes. For the 2DOF case the inline motion at lower reduced velocities responds to the wave frequency, while the transverse motion responds to the natural frequency for the intermediate and upper reduced velocity ranges. The deflection of the elastic cylinder to its maximum displacement in the direction contrary to the progressive wave is purely due to the action of vortices around the cylinder. However the deflection of the elastic cylinder to its maximum displacement in the direction of the progressive wave is due to the wave action. In both cases the stress state of the elastic cylinder is significantly amplified.
Nugroho, Giri, e 謝琦力. "Direct-forcing immersed boundary modeling of vortex-induced vibration of structures at moderate Reynolds numbers". Thesis, 2012. http://ndltd.ncl.edu.tw/handle/24393753525298834595.
Texto completo da fonte國立臺灣科技大學
機械工程系
100
Vortex-induced vibration (VIV) of structures is one of the practical interests in various engineering studies such as wind engineering, ocean engineering, aerospace engineering, and so on. When a structure is exposed to a flow field, the resultant hydrodynamic force may cause the vibrations of the structures. Furthermore, this vibration phenomenon may cause the failure of the structure especially for the so-called lock-in situation. In this present study, VIV of a circular cylinder placed in a uniform fluid flow at moderate Reynolds number is simulated using the direct-forcing immersed boundary method. The cylinder is allowed to vibrate in transverse direction and both in the in-line and transverse directions. The effect of reduced velocity on VIV is discussed in this study. Aerodynamic coefficients of a freely vibrating cylinder are analyzed in time and spectral domains. The maximums of the lift coefficient and the mean drag coefficient show hysteresis jumps at low end of the lock-in region. Hysteresis in the response of the cylinder is observed at the low end of the synchronization region. The ratio between the vortex shedding frequency and the natural frequency of the structure experiences the so-called soft lock-in. Moreover, the 2S vortex shedding mode can be found at low amplitudes of vibrations of the cylinder. The C(2S) mode is observed when the oscillation amplitude is large. Good agreements of the results with the previous experimental and numerical data prove the capability of the present method. This established model can be useful for the investigation of VIV of the structures.
Kumaresan, D. "Non-linear Vibration of Beam Immersed in Fluid". Thesis, 2018. https://etd.iisc.ac.in/handle/2005/5341.
Texto completo da fonteLi, Jia-Yang, e 李佳陽. "Fluid-Structure Interaction Method Development with Immersed Boundary Method". Thesis, 2017. http://ndltd.ncl.edu.tw/handle/n9r62u.
Texto completo da fonte國立清華大學
動力機械工程學系
105
The interaction between the elastic solid structure and the fluid field it immersed in is of great concern in many areas including wind turbine designing and upper nasal treatments. A new fluid-structure interaction method based on immersed boundary method is developed. Multigrid scheme is applied to trace the interface more accurately. Preliminary validation has been done in a fully developed tube flow model. The result is reasonable in trend, yet has obvious difference from the analytic solution. Advanced research is needed to improve the behavior of the computational program, especially where the two mesh domains transfer information that interacting with Poisson equation solving.
Lee, Tzu Jung, e 李紫榕. "Simulations of flow and structure interaction using Immersed Boundary Method". Thesis, 2016. http://ndltd.ncl.edu.tw/handle/43854489062264133251.
Texto completo da fonte國立清華大學
動力機械工程學系
104
In the present study, the problems of solid-fluid interaction using the immersed boundary strategy are investigated. The DKT phenomenon of two sedimenting spheres is presented. The DS phenomenon is observed in the case that the larger sphere is at the bottom. The duration of drafting term in the smallest initial gap in DS phenomenon is investigated at different diameter ratio in the case. On the other hand, in order to simulate the complex-shape object, the method of finding the boundary with the triangular facet surface is added into the numerical method. The triangular facet surface of the object is performed in Standard Tessellation Language (STL) format. In the STL format, the normal vector and three positions of points are recorded in x, y, z-directions. The STL files for the different objects are designed by using CAD. The characteristic of the STL format triangular facet surface is used in the identification of the points around and inside the solid object. The forcing points, decided by using the STL-format triangular facets, is tested in the sphere case and the location of the forcing points are matched with the location found by employing the equation of sphere surface. The parallel computing and altering position of shape are used and validated with the case of rotating ellipsoid. Then, the case of the viscous flow past a sphere is presented. Finally, the case of a rotating turbine with a static fluid domain is performed.
Chia-Lin, Chiu. "Finite Element Analysis with Immersed Boundary Method for Fluid-structure Interaction Problems". 2006. http://www.cetd.com.tw/ec/thesisdetail.aspx?etdun=U0001-2807200617271600.
Texto completo da fonte