• Refine Query
  • Source
  • Publication year
  • to
  • Language
  • 3
  • 1
  • Tagged with
  • 4
  • 4
  • 3
  • 3
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 1
  • 1
  • 1
  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Internal stability of geosynthetic reinforced soil walls : Calculations procedures for practical design

Davidsson, Emil January 2022 (has links)
Reinforced soil constructions have a long history, and various types of the soil reinforcement havebeen in use since the medieval period. Geosynthetic reinforced soil walls (GRS-walls) while beingcommon throughout the world, in not included in the current Eurocode for geotechnical design, SSEN1997-1. The Swedish transportation authority design guidelines (TK Geo 13 and TR Geo 13)provides requirements regarding the utilization of the bearing capacity of the reinforcedgeosynthetic layer and suggestions for the calculation model, but the design is free to choose asuitable design model. Since geosynthetics are very flexible, the load distribution between thegeosynthetic layers in the GRS-wall will be dependent on the stress-strain response of the soil andthe geosynthetic layers. This thesis evaluates the importance of the design model on the ultimatelimit state (ULS) as well as the serviceability limit state (SLS) on a typical GRS wall. The resultsshows that a full numerical model including the stress-strain development gives less utilization ofthe geosynthetic layers at a comparable surcharge load compared to a limit equilibrium model(LEM) suggested by TR Geo. Furthermore, the redistribution of the load between the geosyntheticlayers result in a significantly larger maximum load before a collapse state compared to the LEMcalculation. In such structures the serviceability conditions will control the design. Theconsequences for practical design and the limitation to various design models are elaborated andrecommendations are given.
2

Predicting surfacing internal erosion in moraine core dams

Rönnqvist, Hans January 2010 (has links)
<p>Dams that comprise broadly and widely graded glacial materials, such as moraines, have been found to be susceptible to internal erosion, perhaps more than dams of other soil types. Internal erosion washes out fine-grained particles from the filling material; the erosion occurs within the material itself or at an interface to another dam zone, depending on the mode of initiation. Whether or not internal erosion proceeds depend on the adequacy of the filter material. If internal erosion is allowed, it may manifest itself as sinkholes on the crest, increased leakage and muddy seepage once it surfaces, which here is called surfacing internal erosion (i.e. internal erosion in the excessive erosion or continuation phase). In spite of significant developments since the 1980s in the field of internal erosion assessment, the validity of methods developed by others on broadly graded materials are still less clear because most available criteria are based on tests of narrowly graded granular soils. This thesis specifically addresses dams that are composed of broadly graded glacial soils and investigates typical indicators, signs and behaviors of internal erosion prone dams. Based on a review of 90+ existing moraine core dams, which are located mainly in Scandinavia as well as North America and Australia/New Zealand, this thesis will show that not only the filter’s coarseness needs to be reviewed when assessing the potential for internal erosion to surface (i.e., erosion in the excessive or continuing phase); in addition, the grading stability of the filter and the core material as well as non-homogeneities that are caused by filter segregation need to be studied. Cross-referencing between these aspects improves the assessment of potential for internal erosion in dams of broadly graded soils and furthermore it provides aid-to-judgment.</p> / QC 20100715
3

Predicting surfacing internal erosion in moraine core dams

Rönnqvist, Hans January 2010 (has links)
Dams that comprise broadly and widely graded glacial materials, such as moraines, have been found to be susceptible to internal erosion, perhaps more than dams of other soil types. Internal erosion washes out fine-grained particles from the filling material; the erosion occurs within the material itself or at an interface to another dam zone, depending on the mode of initiation. Whether or not internal erosion proceeds depend on the adequacy of the filter material. If internal erosion is allowed, it may manifest itself as sinkholes on the crest, increased leakage and muddy seepage once it surfaces, which here is called surfacing internal erosion (i.e. internal erosion in the excessive erosion or continuation phase). In spite of significant developments since the 1980s in the field of internal erosion assessment, the validity of methods developed by others on broadly graded materials are still less clear because most available criteria are based on tests of narrowly graded granular soils. This thesis specifically addresses dams that are composed of broadly graded glacial soils and investigates typical indicators, signs and behaviors of internal erosion prone dams. Based on a review of 90+ existing moraine core dams, which are located mainly in Scandinavia as well as North America and Australia/New Zealand, this thesis will show that not only the filter’s coarseness needs to be reviewed when assessing the potential for internal erosion to surface (i.e., erosion in the excessive or continuing phase); in addition, the grading stability of the filter and the core material as well as non-homogeneities that are caused by filter segregation need to be studied. Cross-referencing between these aspects improves the assessment of potential for internal erosion in dams of broadly graded soils and furthermore it provides aid-to-judgment. / QC 20100715
4

Modélisation micromécanique des couplages hydromécaniques et des mécanismes d'érosion interne dans les ouvrages hydrauliques / Modeling micro-mechanical couplings and internal erosion mechanisms

Tong, Anh Tuan 15 January 2014 (has links)
Les matériaux granulaires multiphasiques occupent une place très importante dans notre environnement qui suscitent un grand intérêt de nombreuses communautés scientifiques, notamment celles de la mécanique des sols ou de la géotechnique. Le caractère divisé permet les milieux granulaires multiphasiques d'avoir un comportement mécanique global qui trouve leur origine, leur distribution et interactions entre les phases de composition. Un modèle de couplage hydromécanique est présenté dans ce travail de thèse pour l'application à la modélisation microscopique des couplages hydromécaniques dans les matériaux granulaires saturés. Le modèle numérique est basé sur un couplage de la méthode des éléments discrets (DEM) avec une formulation en volumes finis, à l'échelle des pores (PFV), du problmème de l'écoulement d'un fluide visqueux incompressible. Le solide est modélisé comme un arrangement de particules sphériques avec des interactions de type élasto-plastique aux contacts solide-solide. On considère un écoulement de Stokes incompressible, en supposant que les forces inertielles sont négligeables par rapport aux forces visqueuses. La géométrie des pores et leur connectivité sont définies sur la base d'une triangulation régulière des sphères, qui aboutit à un maillage tétrahédrique. La définition des conductivités hydrauliques à l'échelle des pores est un point clef du modèle, qui se rapproche sur ce point à des modèles de type pore-network. Une importance particulière réside dans les lois d'interactions fluide-solide permettant de déterminer des forces de fluide appliquées sur chacune des particules, tout en assurant un coût de calcul acceptable pour la modélisation en trois dimensions avec plusieurs millieurs des particules. Des mesures de perméabilités sur des assemblages bidisperses de billes de verre sont présentées et comparées aux prédictions du modèle et aux formules empiriques/semi-empiriques dans la littérature, ce qui valide la définition de la conductivité locale et met en évidence le rôle de la distribution granulométrique et la porosité. Une approche numérique pour analyser l'interaction mécanique fluide-solide et les mécanismes d'érosion interne est finalement présentée. / Multiphase granular materials occupy a very important place in our environment that are of great interest to many scientific communities, including those of soil mechanics or geotechnical engineering. The divided nature allows multiphase granular media to have a global mechanical behaviour which originates from all component phases, their distribution and interactions. Acoupled hydromechanical model is presented in this work for the application to microscopic modeling of coupled hydromechanical in saturated granular materials. The numerical model uses a combination of the discrete element method (DEM) with a pore-scale finite volume (PFV) formulation of flow problem of an incompressible viscous fluid. The solid is modeled as an assembly of spherical particles, where contact interactions are governed by elasto-plasticrelations. Stokes flow is considered, assuming that inertial forces are small in comparison with viscous forces. Pore geometry and pore connections are defined locally through regular triangulation of spheres, from which a tetrahedral mesh arises. The definition of pore-scale hydraulic conductivities is a key aspect of this model. In this sense, the model is similar to a pore-network model. The emphasis of this model is, on one hand the microscopic description of the interaction between phases, with the determination of the forces applied on solid particles by the fluid, on the other hand, the model involves affordable computational costs, that allow the simulation of thousands of particles in three dimensional models. Permeability measurements on bidispersed glass beads are reported and compared with model predictions and empirical formulas/semi-empirical in the literature, validating the definition of local conductivities and bringing out the role of particle size distribution and porosity. A numerical approach to analyze the fluid-solid mechanical interaction and mechanisms of internal erosion is finally presented.

Page generated in 0.1065 seconds