Effect of Misalignment at the Flat and Profiled Endwall of Nozzle Guide Vane on Heat Transfer

•The heat transfer characteristics was investigated that are exhibited with the occurrence of misalignment at flat and profiled endwall using naphthalene sublimation method.•The occurrence of misalignment in the flat endwall significantly increases the thermal load in the region upstream of the endw...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2024-09, Vol.230, Article 125750
Main Authors: Kim, JeongJu, Park, Hee Seung, Lee, JeongWon, Moon, Hee Koo, Bang, Minho, Cho, Hyung Hee
Format: Article
Language:English
Subjects:
Gas turbine
Heat transfer
Misalignment
Profiled endwall
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Summary:•The heat transfer characteristics was investigated that are exhibited with the occurrence of misalignment at flat and profiled endwall using naphthalene sublimation method.•The occurrence of misalignment in the flat endwall significantly increases the thermal load in the region upstream of the endwall.•There was no significant difference in heat transfer when a misalignment occurred in the profiled endwall.•A profiled endwall had a lower thermal load than a flat endwall, and is a robust design because the thermal load changes less even if misalignment occurred. Misalignment of gas turbine engines is caused by the difference in thermal expansion from the design point when starting or stopping the engine, or when operating at partial load. This study evaluated the differences in heat transfer characteristics between a flat endwall and a profiled endwall with misalignment. To ensure consistency with the flow conditions, experiments were conducted at an outlet Reynolds number of 300,000 for both geometries. The experiment was performed under three different conditions: a case without step, a case with a forward-facing step (h/Cx= -0.1), and a case with a backward-facing step (h/Cx= 0.1). In the flat endwall, the thermal load of the upstream region increases significantly with both step circumstances compared to the case without a step. The misalignment causes a recirculation flow to occur between the interface of the combustor and turbine. This leads to the mainstream reattaching upstream of the endwall. Nevertheless, the heat transfer characteristics of the profiled endwall differ from those of the flat endwall under step conditions. Most locations do not experience significant changes, with only a slight increase observed in the upstream region. The recirculation flow is crucially reduced due to the intensity of the secondary vortex in the profiled shape. Hence, the increase in the thermal load on the profiled endwall with step is considerably lower than that on the flat endwall. As a result, the thermal load on the profiled endwall has decreased by 25 % for the forward-facing step and 20.7 % for the backward-facing step compared to the flat endwall.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2024.125750