Abstract
This paper details an experimental investigation, using a linear cascade, into the effects of real geometry features on the aerodynamic performance of stator blade rows within axial flow compressors. The specific geometric features investigated include shroud cavities, inter-platform gaps, vane-pack gaps and the effects of misalignment of the platform endwalls due to manufacturing tolerances. A computational investigation into these effects is also included. To ensure that the linear cascade measurements are representative of a multi-stage compressor environment a novel experimental technique was developed to generate a hub endwall boundary layer which had skew. The boundary layer skew generation method involves injecting flow along the cascade endwall in such a manner as to control both the displacement thickness and tangential momentum thickness of the resulting boundary layer. Without the presence of the endwall boundary layer skew the linear cascade could not reproduce the flow features typically observed in a multi-stage compressor. The investigation reveals that real geometry features can have a significant impact on the flowfield within a blade passage. For a shrouded stator, increasing the leakage flow rate increases the stagnation pressure loss coefficient. However, high levels of whirl pickup of the leakage flow as it passes through the stator-shroud cavity can offset the natural secondary flow within the stator passage and thus reduce the stagnation pressure loss. All of the steps and gaps that were observed to be present in real compressors were found to increase the stagnation pressure loss relative to that of a smooth endwall. It is also shown that the computational method is capable of capturing the trends observed in the experiments.
Highlights
The International Air Transport Association (IATA, 2017) forecast that in 2018 the total fuel bill for airlines would be $156 billion which is approximately 20% of the average operating costs
The construction and assembly of an axial compressor blade row introduces a number of geometric features that are likely to be undesirable from an aerodynamic standpoint
While the primary focus has been to investigate the impacts of real geometry features on the performance of a blade row, the investigation highlighted the importance of boundary layer skew
Summary
The International Air Transport Association (IATA, 2017) forecast that in 2018 the total fuel bill for airlines would be $156 billion which is approximately 20% of the average operating costs. The hub platforms are not welded together to allow for the effects of vibration and thermal expansion This results in an axial inter-platform gap at the hub between each blade passage, which is estimated to be up to 1% of pitch. Due to manufacturing tolerances, the hub endwalls within the vane-packs can have misalignments along the inter-platform gaps resulting in a step in the flow path which is estimated to be in the order of 1% of span. The hub platforms are located in a circular c-ring, which is usually manufactured in two parts, resulting in a leakage flow path None of these gaps and steps are routinely considered during the aerodynamic design. This paper will first focus on the impact of the stator-shroud leakage flow and the associated whirl pick-up on the blade row aerodynamic performance. The impact of the real geometry features, such as inter-platform gaps, vane-pack gaps and misaligned endwalls, on the aerodynamic performance will be investigated
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