Abstract
Foundation of an off-shore wind mill is submitted throughout its existence to a very high number of cycles coming from lateral actions such as waves or wind. These actions have a strong aleatory character which makes them very hard to predict, quantify and analyse. Therefore, in current design practice, these actions are being considered as pseudo-static force at their maximum values, with the cyclic phenomenon being neglected. This can lead to an inappropriate design of the foundation, which could have a negative impact on the future structure. This type of structure is generally built on a monopile foundation, a single, large diameter pile, which will be submitted to thousands lateral cycles. The pile diameter plays an important role, influencing the behaviour of the entire structure. Centrifuge experiments on small-scale models are very useful to study such complex problem as piles under lateral cyclic loads. Several researches have been carried out internationally and the results can be used for calibrating numerical models, which is obviously a more accessible method of design, compared to an experimental approach. This has been precisely the starting point of this paper. The purpose of the present paper is to analyse the influence of the pile diameter, by using a FEM a numerical model, previously calibrated based on centrifuge experiments carried out at IFSTTAR Nantes. For the numerical modelling the software CESAR-LCPC 3D has been used. Several pile diameters have been considered, as follows: 0.72 m, 1.08 m, 1.44 m, 1.80 m, 2.16 m and 2.52 m. The results are taking into account the lateral displacement and bending moment of the piles, for static and cyclic loading. The main objective was to determine the stabilisation rate of the most important two design elements (pile head displacement and maximum bending moment) after “n” cycles and to eventually conclude the diameter value beyond which no more influence of cycles is recorded. The numerical model considered 15 cycles and the results have been used extrapolated in order to determine the cycle “n” of stabilisation (for displacement and bending moment).
Highlights
Current design practice of piles submitted to lateral cyclic actions coming from waves or wind is often ignoring the cyclic effect of the loading due to the complexity of the soil-structure interaction involved
In order to study the influence of a single pile submitted to lateral cyclic action in sandy soil, a numerical model has been developed, using the 3D finite element software CESAR-LCPC, which has been previously calibrated based on centrifuge tests on smallscale pile model
Using a previously calibrated numerical model based on small-scale centrifuge tests and developed using CESAR-LCPC 3D software, the paper analyses the influence of the diameter of a monopile submitted to lateral cyclic actions, coming from waves or wind, in sandy soil
Summary
Current design practice of piles submitted to lateral cyclic actions coming from waves or wind is often ignoring the cyclic effect of the loading due to the complexity of the soil-structure interaction involved. Numerical models are widely used nowadays, but they have to be calibrated based on experimental results to be further used in design practice. Given the fact that most of the time offshore windmills are founded on a monopile, this paper analyses the influence of the pile diameter on its cyclic behaviour. In order to study the influence of a single pile submitted to lateral cyclic action in sandy soil, a numerical model has been developed, using the 3D finite element software CESAR-LCPC, which has been previously calibrated based on centrifuge tests on smallscale pile model. The numerical model was used for studying the influence of the pile diameter
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