Research project HCA 4 PInS
Development of a Method for Realistic Simulation of Pile Installation Using the HCA Model
Project name Development of a Method for Realistic Simulation of Pile Installation Using the HCA Model
Acronym HCA 4 PInS
Project partner
  • Technische Universität Darmstadt, Institut für Geotechnik
  • Ruhr-Universität Bochum (Lehrstuhl für Bodenmechanik, Grundbau und Umweltgeotechnik)
  • Bauhaus-Universität Weimar (Professur Geotechnik)
Grantor DFG (Project 526401246)
Duration 05.10.2023 to: 05.10.2026

Research field
 E+E
(E+E > Energy + Environment
I+I > Information + Intelligence
M+M > Matter + Materials)
Project content
As part of the energy transition and the “Climate Action Programme 2030,” a significant expansion of offshore wind energy to 25 GW is planned by 2030. This requires the use of the latest generation of wind turbines with capacities of up to 14 MW, whose foundations must be installed under strict environmental regulations. While conventional impact driving is only permissible with extensive noise reduction measures, low-emission vibratory pile driving presents an alternative. However, initial model and field tests show that the load-bearing capacity of vibrated piles is lower compared to that of driven piles. Common design methods neglect the influence of the installation process and apply an idealized “wished-in-place” assumption.

Preliminary numerical investigations by the applicants show that considering the installation process has a significant impact on the predicted load-bearing and deformation behavior of the pile after installation. This applies to both monotonic and cyclic lateral loads.

The goal of this research project is to develop a numerical calculation strategy that enables a realistic simulation of the entire installation process of monopile foundations. Based on the so-called “zipper-method” in combination with a high-cycle accumulation (HCA) model, the most decisive installation parameters, such as the actual installation time, frequency, load cycles, and partial drainage conditions, will be considered for the first time, while the pile-soil interaction will be modelled as accurately as possible. The developed methods will enable planning engineers and authorities to consider installation effects in the preliminary design phase and thus support the development of novel, efficient installation methods. A schematic representation of the calculation strategy is shown in one the attached figures.