Highly resolved simulations of turbulence, cavitation, and fluid-structure interaction in blade cascades during transients
Title: Highly resolved simulations of turbulence, cavitation, and fluid-structure interaction in blade cascades during transients
SNIC Project: SNIC 2020/14-95
Project Type: SNIC Small Storage
Principal Investigator: Håkan Nilsson <hakan.nilsson@chalmers.se>
Affiliation: Chalmers tekniska högskola
Duration: 2021-01-01 – 2022-01-01
Classification: 20306
Homepage: http://www.chalmers.se/sv/personal/Sidor/hakan-nilsson.aspx


Renewable electric energy production often involves unsteady flow in blade cascades. The unsteadiness can be caused by: * Turbulence: The high Reynolds numbers gives a wide range of temporal and spatial scales. The numerical modeling techniques must be capable of resolving both the small and large scales, which yields short time steps during long events. * Cavitation: A two-phase flow phenomenon that appears as the local pressure passes the vaporization pressure. The numerical techniques require extreme mesh resolution, short time steps, and long real-time simulations. * Rotor-stator interaction: The passing of moving blades through the wakes of steady blades require numerical techniques for the relative motion of blades, and the coupling between different mesh regions. Simulations must be long enough to fully develop the interaction before the results can be used for analysis. Flow instabilities, such as rotating stall, requires even longer time to be fully established. * Varying operating conditions: The deregulated energy market forces the production units to regulate at a wide range of time-scales. Highly resolved flow simulations usually assume a periodic behavior in both time and space, which is not applicable in energy production units operating under varying operating conditions. The entire process of the variations must be included in the simulations, at the same time that the short time scales must be resolved. This means that highly detailed turbulent flow simulations must be done for a much longer time than is usually the case. Flow instabilities during such operation, such as large-scale vortex breakdown, are highly dependent on accurate representation of the smaller turbulent scales. Our present focus is on: 1: Transients between different operating conditions in hydraulic turbines: Very long time scales need to be included, related to those of the transient processes. Very fine meshes and short time steps need to be used to resolve the small scales of turbulence and cavitation. There is therefore a need for a substantial amount of computational resources. These studies will be done in three separate projects, looking at already established hydraulic turbines v.s. a novel counter-rotating design for pumped-hydro. 2: Fan blades in electric generators: The flow unsteadiness makes the blades vibrate and eventually break, causing great damages to the machines. We will use LES and Fluid-Structure-Interaction methodologies to study the physical processes of the fan blade vibrations. That requires excessive computational meshes, and thus a substantial amount of computational resources. Due to the fact that we will be studying transients between different operating conditions, we need to save data at many time steps, in order to be able to post-process the results after finishing the simulations. I.e., this is not regular 'unsteady' simulations, but the conditions are also varying. We also need to install several versions of OpenFOAM and related software, which takes a lot of space and has many files.