171 research outputs found
A correction to the enhanced bottom drag parameterisation of tidal turbines
Hydrodynamic modelling is an important tool for the development of tidal
stream energy projects. Many hydrodynamic models incorporate the effect of
tidal turbines through an enhanced bottom drag. In this paper we show that
although for coarse grid resolutions (kilometre scale) the resulting force
exerted on the flow agrees well with the theoretical value, the force starts
decreasing with decreasing grid sizes when these become smaller than the length
scale of the wake recovery. This is because the assumption that the upstream
velocity can be approximated by the local model velocity, is no longer valid.
Using linear momentum actuator disc theory however, we derive a relationship
between these two velocities and formulate a correction to the enhanced bottom
drag formulation that consistently applies a force that remains closed to the
theoretical value, for all grid sizes down to the turbine scale. In addition, a
better understanding of the relation between the model, upstream, and actual
turbine velocity, as predicted by actuator disc theory, leads to an improved
estimate of the usefully extractable energy. We show how the corrections can be
applied (demonstrated here for the models MIKE 21 and Fluidity) by a simple
modification of the drag coefficient
Turbulence-resolving simulations of wind turbine wakes
Turbulence-resolving simulations of wind turbine wakes are presented using a
high--order flow solver combined with both a standard and a novel dynamic
implicit spectral vanishing viscosity (iSVV and dynamic iSVV) model to account
for subgrid-scale (SGS) stresses. The numerical solutions are compared against
wind tunnel measurements, which include mean velocity and turbulent intensity
profiles, as well as integral rotor quantities such as power and thrust
coefficients. For the standard (also termed static) case the magnitude of the
spectral vanishing viscosity is selected via a heuristic analysis of the wake
statistics, while in the case of the dynamic model the magnitude is adjusted
both in space and time at each time step. The study focuses on examining the
ability of the two approaches, standard (static) and dynamic, to accurately
capture the wake features, both qualitatively and quantitatively. The results
suggest that the static method can become over-dissipative when the magnitude
of the spectral viscosity is increased, while the dynamic approach which
adjusts the magnitude of dissipation locally is shown to be more appropriate
for a non-homogeneous flow such that of a wind turbine wake
Interface and surface analysis for pharmaceutical applications: challenges and recent advances
Innovation in R&D is a key target for the pharmaceutical sector to address some of the challenges it currently faces. This review discusses these challenges in the context of pharmaceutically relevant surfaces and interfaces. The surface properties of materials determine many pharmaceutically important interactions and can be drastically different from the material’s bulk properties. We first introduce current challenges in the surface and interface analysis of pharmaceutical materials in the context of material design, administration and fabrication. We then review recent scientific and technological advances aimed to address these issues and discuss examples that illustrate the capabilities of these techniques
Integrating Research Data Management into Geographical Information Systems
Ocean modelling requires the production of high-fidelity computational meshes
upon which to solve the equations of motion. The production of such meshes by
hand is often infeasible, considering the complexity of the bathymetry and
coastlines. The use of Geographical Information Systems (GIS) is therefore a
key component to discretising the region of interest and producing a mesh
appropriate to resolve the dynamics. However, all data associated with the
production of a mesh must be provided in order to contribute to the overall
recomputability of the subsequent simulation. This work presents the
integration of research data management in QMesh, a tool for generating meshes
using GIS. The tool uses the PyRDM library to provide a quick and easy way for
scientists to publish meshes, and all data required to regenerate them, to
persistent online repositories. These repositories are assigned unique
identifiers to enable proper citation of the meshes in journal articles.Comment: Accepted, camera-ready version. To appear in the Proceedings of the
5th International Workshop on Semantic Digital Archives
(http://sda2015.dke-research.de/), held in Pozna\'n, Poland on 18 September
2015 as part of the 19th International Conference on Theory and Practice of
Digital Libraries (http://tpdl2015.info/
Interface and surface analysis for pharmaceutical applications: challenges and recent advances
Innovation in R&D is a key target for the pharmaceutical sector to address some of the challenges it currently faces. This review discusses these challenges in the context of pharmaceutically relevant surfaces and interfaces. The surface properties of materials determine many pharmaceutically important interactions and can be drastically different from the material’s bulk properties. We first introduce current challenges in the surface and interface analysis of pharmaceutical materials in the context of material design, administration and fabrication. We then review recent scientific and technological advances aimed to address these issues and discuss examples that illustrate the capabilities of these techniques
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