G. T. Houlsby scite author profile

The driven monopile is currently the preferred foundation type for most offshore wind farms. While the static capacity of the monopile is important, a safe design must also address issues of accumulated rotation and changes in stiffness after long-term cyclic loading. Design guidance on this issue is limited. To address this, a series of laboratory tests were conducted where a stiff pile in drained sand was subjected to between 8000 and 60 000 cycles of combined moment and horizontal loading. A typical design for an offshore wind turbine monopile was used as a basis for the study, to ensure that pile dimensions and loading ranges were realistic. A complete non-dimensional framework for stiff piles in sand is presented, and applied to interpret the test results. The accumulated rotation was found to be dependent on relative density, and was strongly affected by the characteristics of the applied cyclic load. Particular loading characteristics were found to cause a significant increase in the accumulated rotation. The pile stiffness increased with number of cycles, which contrasts with the current methodology where static load-displacement curves are degraded to account for cyclic loading. Methods are presented to predict the change in stiffness and the accumulated rotation of a stiff pile due to long-term cyclic loading. The use of the methods developed is demonstrated for a typical fullscale monopile.KEYWORDS: laboratory tests; piles; repeated loading; sands; settlement; stiffness Le monopieu battu est actuellement le type de fondation préféré pour la plupart des parcs éoliens en mer. Bien que la capacité statique du monopieu soit importante, une conception sans danger doit également tenir compte des problèmes de la rotation accumulée et de variations dans la rigidité, à la suite d'efforts cycliques de longue durée. Les conseils et indications conceptuels relatifs à cette question étant limités, on a procédé à une série d'essais en laboratoire, dans le cadre desquels on a soumis un pieu rigide, enfoncé dans du sable drainé, à un nombre de cycles de moment de charge et de charges horizontales allant de 8000 à 60 000. On a utilisé, comme élément de base de cette étude, un modèle typique de monopieu pour éolienne en mer, afin d'assurer que les dimensions du pieu et les plages de charge étaient réalistes. Pour interpréter les résultats de cet essai, on présente et on applique un cadre non dimensionnel complet pour pieux rigides dans le sable. La rotation cumulée, qui s'est avérée tributaire du poids spécifique, était affectée dans une grande mesure par les caractéris-tiques de la charge cyclique appliquée. On s'est aperçu que certaines caractéristiques particulières de la charge engendraient une augmentaiton significative de la rotation cumulée. La rigidité du pieu augmentait avec le nombre de cycles, contrairement à la méthodologie actuelle, dans laquelle les courbes charge statique/déplace-ment sont dégradées pour tenir compte des charges cycliques. La communication présente des méthodes permettant de prédire les ...

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Application of thermomechanical principles to the modelling of geotechnical materials

Collins

Houlsby

1997

Proc. R. Soc. Lond. A

408

296

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A thermodynamic framework is presented for the plasticity modelling of geotechnical materials. The framework is capable of modelling rigorously both friction and non-associated flow, and the strong connection between these phenomena is demonstrated. The formulation concentrates on the development of constitutive models from hypotheses about the form of an energy potential and a dissipation function. The reformulation of previous work, in which the Helmholtz free energy was used, to a new approach starting from the Gibbs free energy is found to be valuable. The relationship between the new functions and classical plasticity concepts (yield surface, plastic potential, isotropic and kinematic hardening, friction, dilation) is demonstrated. Comments are made on elastic-plastic coupling. Implications of the new approach for critical state soil models are discussed.

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The limiting pressure on a circular pile loaded laterally in cohesive soil

1984

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In the analysis of the undrained loading of laterally loaded piles an important quantity is the ultimate lateral resistance at depth to purely horizontal movement. If the soil is modelled as a perfectly plastic cohesive material then the calculation of this quantity reduces to a plane strain problem in plasticity theory, in which the load is calculated on a long cylinder which moves laterally through an infinite medium. An exact calculation of the load on such a cylinder is presented. If this load is non-dimensionalized with respect to the soil strength and the diameter of the pile, it is found that the load factor varies between for a perfectly smooth pile and for a perfectly rough pile. This result is discussed in the context of previous calculations for the lateral load capacity of piles and is compared with approximate calculations using cavity expansion theory and a wedge failure near the soil surface. La résistance latérale limite en profondeur au seul mouvement horizontal représente un paramètre important de l'analyse du chargement non-drainé des pieux chargés latéralement. Si le sol est modelisé comme une matériau cohérent parfaitement plastique le calcul de ce paramètre devient un problème de déformation plane dam la théorie de la plasticité, dans laquelle la charge se calcule sur un long cylindre qui se déplace latéralement dans un milieu infini. L'article presente un calcul prtcis de la charge d'un tel cylindre. Si cette charge est rendue sans dimensions eu égard à la résistance du sol et du diamètre du pieu on trouve que le facteur de chargement varie entre pour un pieu parfaitement lisse et pour un pieu parfaitement rugueux. L'article discute ce résultat dans le contexte des calculs précédents de la capacité de chargement des pieux et le compare avec des calculs approximatifs employant la theorie de l'expansion des cavités et un coin de rupture prés de la surface du sol.

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The work input to an unsaturated granular material

1997

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G. T. Houlsby

Response of stiff piles in sand to long-term cyclic lateral loading

Application of thermomechanical principles to the modelling of geotechnical materials

The limiting pressure on a circular pile loaded laterally in cohesive soil

The work input to an unsaturated granular material

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