Abstract
The large meridional expansion turbine stator leads to complex secondary flows and heat transfer characteristics in the blade endwall region, while the upstream tip clearance leakage flow of the rotor makes it more complex in flow and heat transfer. The influence of the upstream rotor tip clearance on the large meridian expansion stator is worth studying. The flow and heat transfer characteristics of the downstream large meridional expansion turbine stator were studied by comparing the tip leakage flow of 1.5-stage shrouded and unshrouded turbines using a three-dimensional Reynolds-Averaged Navier-Stokes (RANS) solver for viscous turbulent flows. Validation studies were performed to investigate the aerodynamics and heat transfer prediction ability of the shear stress transport (SST) turbulence model. The influence of different tip clearances of the rotor including unshrouded blade heights of 0%, 1% and 5% and a 1% shrouded blade height were investigated through numerical simulation. The results showed that the upper passage vortex separation was more serious and the separation, and attachment point of horseshoe vortex in the pressure side were significantly more advanced than that of non-expansion turbines. The tip leakage vortex obviously increased the negative incidence angle at the downstream inlet. Furthermore, the strength of the high heat transfer zone on the suction surface of the downstream stator was significantly increased, while that of the shrouded rotor decreased.
Highlights
The low-pressure turbine of marine gas turbines has a high endwall angle design.The large meridional expansion endwall can effectively reduce the large deflection angle of the blade profile to meet the expansion ratio requirement
It is of great value to study the influence of tip clearance of the rotor on the flow and the heat transfer characteristics of the downstream large meridional expansion stator
As the research aim of this paper was to study the influence of the tip clearance of R1 on the
Summary
The large meridional expansion endwall can effectively reduce the large deflection angle of the blade profile to meet the expansion ratio requirement. The large meridional expansion can cause a large secondary flow and flow separation at the endwall, and the endwall heat transfer is strongly affected by secondary effects. The difference between rotor tip leakage flow and the circumferential velocity of the main flow causes great mixing loss and exerts a strong effect on the boundary layer of the endwall. It is of great value to study the influence of tip clearance of the rotor on the flow and the heat transfer characteristics of the downstream large meridional expansion stator. More than one-third of flow loss in turbines is caused by tip clearance flow
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