Print Email Facebook Twitter A non-collocated method to quantify plastic deformation caused by impact pile driving Title A non-collocated method to quantify plastic deformation caused by impact pile driving Author Meijers, P.C. (TU Delft Offshore Engineering) Tsouvalas, A. (TU Delft Offshore Engineering) Metrikine, A. (TU Delft Offshore Engineering; TU Delft Engineering Structures) Department Engineering Structures Date 2018-11-01 Abstract The use of bolted connections between the tower and a support structure of an offshore wind turbine has created the need for a method to detect whether a monopile foundation plastically deforms during the installation procedure. Small permanent deformations are undesirable, not only because they can accelerate fatigue of the structure; but also because they can lead to misalignment between the tower and the foundation. Since direct measurements at the pile head are difficult to perform, a method based on non-collocated strain measurements is highly desirable. This paper proposes such a method. First, a physically non-linear one-dimensional model is proposed, which accounts for wave dispersion, effects that are relevant for large-diameter piles currently used by the industry. The proposed model, combined with an energy balance principle, gives an upper bound for the amount of plastic deformation caused by an impact load based on simple strain measurements. This is verified by a lab-scale experiment with a uni-axial stress state. Second, measurement data collected during pile driving of a large-diameter pile show that the proposed one-dimensional model, while able to predict the peak stresses, fails to accurately predict the full time history of the measured stress state. In contrast, an advanced model based on shell membrane theory is able to do that, showing that a bi-axial stress state is needed for these type of structures. This requires an extension of the theory for plasticity quantification presented in this paper. Subject Impact pile drivingPlastic deformationWave dispersion To reference this document use: http://resolver.tudelft.nl/uuid:8a6e430a-eccf-4cd1-bb1e-0268fb624b7c DOI https://doi.org/10.1016/j.ijmecsci.2018.08.013 Embargo date 2020-08-25 ISSN 0020-7403 Source International Journal of Mechanical Sciences, 148, 1-8 Part of collection Institutional Repository Document type journal article Rights © 2018 P.C. Meijers, A. Tsouvalas, A. Metrikine Files PDF accepted.pdf 1.23 MB Close viewer /islandora/object/uuid:8a6e430a-eccf-4cd1-bb1e-0268fb624b7c/datastream/OBJ/view