Best Practice Advice AC6-14: Difference between revisions

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==Discretisation and Grid Resolution==
==Discretisation and Grid Resolution==
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Most of the simulations that are available in the literature are done using licensed codes.
The open source codes are normally more sensitive to the non-orthogonality of the mesh.
The mesh quality is thus highly crucial in such simulations.
The maximum aspect ratio of a cell is around 400 close to the outlet of the draft tube.
The minimum angle is 18$^{\circ}$ for nine elements and occurs close to the hub in the
runner.
The computational domain contains several regions, where GGI is used at the interfaces
between the regions.
The resolution spacing in the normal directions to the interface should be similar at both
sides of the interface.
The total number of cells used in the computational domain for the high-Reynolds number
models is $5.05\times10^6$ and for the hybrid URANS-LES models is $13.25\times10^6$.
 
==Physical Modelling==
==Physical Modelling==
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<!--{{Demo_AC_BPA5}}-->

Revision as of 07:21, 12 April 2016


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Best Practice Advice

Swirling flow in a conical diffuser generated with rotor-stator interaction

Application Challenge AC6-14   © copyright ERCOFTAC 2024

Best Practice Advice

Key Fluid Physics

The main features of the flow are the on-axis recirculation region,the vortex rope and the vortex breakdown, and wakes of the blades. The separation from the blades, flow in inter-blade passages, separation in the divergent part of the draft tube and rotor-stator interaction are among other physical mechanisms which make the flow fields complicated and difficult to model.

Application Uncertainties

The complexity of the geometry, curved and bladed regions, tip-clearance and rotor-stator interaction, oscillation of the runner rotational speed which is absent in numerical simulations are some sources of uncertainties which make a high fidelity CFD model difficult to assemble.

Computational Domain and Boundary Conditions

The boundary conditions also play a prominent role to reproduce the physical mechanism of the vortex breakdown. The swirl intensity determines the occurrence of the vortex breakdown. The swirl depends on the axial and tangential velocity components, which are two dominant parameters and specify the physical mechanism of the breakdown. For swirling flows in a pipe, the former determines the radius of the vortex core and the later specifies the character of the on-axis axial velocity (jet- or wake-like). The inlet boundary condition is usually unknown at the draft tube inlet of the hydraulic turbomachines. To prevail this problem, the rotor-stator interaction, which is the interaction between the guide vane and the runner blades, is considered to retain the upstream effects on the flow in the draft tube.

Discretisation and Grid Resolution

Most of the simulations that are available in the literature are done using licensed codes. The open source codes are normally more sensitive to the non-orthogonality of the mesh. The mesh quality is thus highly crucial in such simulations. The maximum aspect ratio of a cell is around 400 close to the outlet of the draft tube. The minimum angle is 18$^{\circ}$ for nine elements and occurs close to the hub in the runner. The computational domain contains several regions, where GGI is used at the interfaces between the regions. The resolution spacing in the normal directions to the interface should be similar at both sides of the interface. The total number of cells used in the computational domain for the high-Reynolds number models is $5.05\times10^6$ and for the hybrid URANS-LES models is $13.25\times10^6$.

Physical Modelling

Recommendations for Future Work




Contributed by: A. Javadi, A. Bosioc, H Nilsson, S. Muntean, R. Susan-Resiga — Chalmers University of Technology

Front Page

Description

Test Data

CFD Simulations

Evaluation

Best Practice Advice


© copyright ERCOFTAC 2024