Multiscale modelling of shelly carbonate sands for foundation design of offshore structures (MuMShell)

Completed

Renewable Energy Sources(Ocean Energy)
Renewable Energy Sources(Wind Energy)
Fossil Fuels: Oil Gas and Coal(Oil and Gas, Other oil and gas)

Basic and strategic applied research
Applied Research and Development

ENGINEERING AND TECHNOLOGY (Mechanical, Aeronautical and Manufacturing Engineering)

Not Cross-cutting

Dr J Fonseca
Sch of Engineering and Mathematical Sci
City University

Standard

EPSRC

01 April 2016

31 July 2017

16 months

£99,782

Civil eng. & built environment

London

Manufacturing : Manufacturing

Dr J Fonseca, Sch of Engineering and Mathematical Sci, City University

Project Contact, Norwegian Geotechnical Institute
Project Contact, Fugro GeoServices Ltd
Project Contact, The University of Manchester
Project Contact, California Institute of Technology

Carbonate soils cover over 40% of the world's seabed, where offshore structures, pipelines, artificial islands and other marine structures are founded. For the most part, carbonate soils are of biogenic origin comprising skeleton bodies and shells of small organisms, the shelly carbonate sands. These soils are a complex and poorly understood material as evidenced by a number of accidents reported during platform installation in the 80s. As a consequence, shelly sands have been placed into a niche classification of "problematic soils" in most design guides. While failures are now relatively rare, conservative methods and high factors of safety are commonly used. Understanding the behaviour of shelly carbonate sand is critical for the design of foundations for offshore structures. In particular, understanding the physical phenomena taking place at the microscale has the potential to spur the development of robust computational methods to be integrated into novel or existing design approaches.Image-based geomechanics is a fascinating research field that has the potential to transform the way soils are investigated and modeled. The ability to follow deformation at the microscale has helped to answer fundamental questions about the soil behaviour observed at the macro-scale. The proposed research uses 4D synchrotron x-ray imaging and post analysis to investigate the kinematics and the strain maps of a shelly carbonate sand under compression. The outcomes will contribute scientific understanding on the multiscale behaviour of shelly carbonate sands. This will form the basis to develop fabric-informed constitutive models to better predict the soil response, thus improving design practices for foundations of offshore structures. The ambition of this project is to contribute towards safer, less conservative and more sustainable ground structures and reduce the financial risks associated with unforeseen ground response during construction of offshore foundations. This multiscale methodology and image algorithms here developed, will be valuable to the broad granular media community to simulate mechanical processes in additive manufacturing, mining, food and pharmaceutical industries.

24/08/16