Turbine Vane Endwall Film Cooling and Pressure Side Phantom Cooling Performances With Upstream Coolant Flow at Various Injection Angles

Bai, Bo; Li, Zhigang; Li, Jun; Mao, Shuo; Ng, Wing

doi:10.1115/1.4054848

Journal of Thermal Science and Engineering Applications

2022

DOI: 10.1115/1.4054848

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Turbine Vane Endwall Film Cooling and Pressure Side Phantom Cooling Performances With Upstream Coolant Flow at Various Injection Angles

Bo Bai

Zhigang Li

Jun Li

et al.

Abstract: In this paper, the endwall film cooling and vane pressure side surface phantom cooling performances of a first nozzle guide vane (NGV) with endwall contouring, similar to an industry gas turbine, were experimentally and numerically evaluated at simulated realistic gas turbine operating conditions (high inlet freestream turbulence level of 16 %, exit Mach number of 0.85, exit Reynolds number of 1.7 × 106). A novel numerical method for the predictions of adiabatic wall film cooling effectiveness was proposed, ba… Show more

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Cited by 4 publications

References 32 publications

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Effects of Hole Blockage on Endwall Film Cooling and Vane Phantom Cooling Performances of a Transonic Turbine Vane

Bai

Zhang

et al. 2022

Journal of Engineering for Gas Turbines and Power

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Although the thermal-barrier coating (TBC) can protect the gas turbine components from the hot mainstream gas, it's not uncommon that the TBC partially blocks the film cooling holes during the spraying process. The film cooling hole blockage will alter the coolant flow behaviors and lead to a significant variation in film cooling performance. In this paper, a physical model of blockage holes, including two key parameters of blockage ratios (B) and blockage angles (a), was proposed to analyze the effects of hole blockage on endwall film cooling performance, phantom cooling performance of vane pressure side surface (PS) and vane passage aerodynamic performance. Based on a proposed double-coolant-temperature prediction method, the endwall film cooling effectiveness, phantom cooling effectiveness of the vane PS and total pressure loss coefficients (TPLC) of an actual vane passage were numerically calculated and analyzed, for the common holes and blockage holes (three different blockage ratios of B and three different blockage angle of a) at the similarly realistic operating conditions of a gas turbine. Results indicated the hole blockage is pernicious to endwall film cooling performance and vane passage aerodynamic performance, leading to a significant decrement of endwall film cooling effectiveness (up to 30 % at B = 0.4) and enhancement of TPLC (more than 2.2 % at B = 0.4), where the decrement magnitudes increase with increasing the blockage ratios (B).

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Effects of Hole Blockage on Endwall Film Cooling and Vane Phantom Cooling Performances of a Transonic Turbine Vane

Bai

Zhang

et al. 2022

Journal of Engineering for Gas Turbines and Power

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Turbine Blade Endwall Heat Transfer and Film Cooling Performance With Multigap Jets and Film Holes

Bai,

Li,

Hao

et al. 2023

Journal of Engineering for Gas Turbines and Power

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Due to manufacturing, assembly, and operational conditions, gaps are commonly presented in the turbine components, such as a slashface gap between two adjacent blade endwalls and a slot gap between the stator and rotor. The coolant ejected through these gaps not only limits hot mainstream gas ingestion into the disk cavity but also has the potential to provide endwall film cooling coverage. Nevertheless, the interaction of these gap jets, pre-designed film holes jet, and endwall secondary flows, significantly impacts endwall heat transfer and film cooling performances and leads to a more complicated flow field near the endwall. To further understand the endwall flow physical behaviors in this environment, the combined effects of film holes jet and multi-gap jets (slashface jet and slot jet) were experimentally studied in a transient wind tunnel with a six-blade linear cascade. The endwall heat transfer was measured and recorded by the IR technique at inlet average turbulence intensity (Tu) of 7.5% and an exit Mach number (Maex) of 0.4. In addition, detailed numerical predictions were also performed to discuss the flow physics near the endwall and the multi-gap jet flow behaviors. Results indicated that the slashface jet is an essential contributor to endwall film cooling performance in this endwall configuration. The slashface jet limits the development of the film holes jet, leading to an enhancement of film cooling performance downstream of the film holes.

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Uncertainty Analysis of Laser Drilling Imperfection and Impacts on the Cooling Performance of a Transonic Turbine Vane

Hao,

Bai,

Zhang

et al. 2024

Journal of Turbomachinery

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This work uses a double-coolant-temperature model to evaluate the cooling performance of a double-row film holes scheme employed in a high-pressure turbine nozzle guide vane, subjecting to the variability of film hole geometric parameters set by manufacturing deviation range. The numerical predictions are performed at engine-representative Maexit =0.85, inlet turbulence intensity of 16%, and Reexit, Cx =1.5%, design blowing ratio (BR=2.5) and typical high density ratio of DR=1.95. A dual non-deterministic analysis is conducted in this paper to analyze the cooling performance robustness under uncertain conditions of consistent and inconsistent film hole characteristic parameters. First, a fundamental uncertainty quantification framework, which combines a conical nozzle parameterized model, non-intrusion Polynomial Chaos UQ methodology, and k-Nearest Neighbor clustering algorithm, is built to quantify the cooling performance while geometric parameters of all film holes are consistent. With the same film hole imperfection characteristic parameters, the likelihood of all holes being on the edge of their tolerance range increases dramatically, which further leads to more extreme MFR fluctuations being observed, ranging from 0.51% to 2.31% (μ ± 3σ). Second, a flow parameter dimensionality reduction UQ approach (FPDR), which transforms the deviations of multiple geometric parameters into the fluctuations of several key flow parameters, is proposed to address the curse of dimensionality phenomenon in predicting the cooling performance under uncertain conditions of inconsistent film hole imperfection characteristic parameters.

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Turbine Vane Endwall Film Cooling and Pressure Side Phantom Cooling Performances With Upstream Coolant Flow at Various Injection Angles

Cited by 4 publications

References 32 publications

Effects of Hole Blockage on Endwall Film Cooling and Vane Phantom Cooling Performances of a Transonic Turbine Vane

Effects of Hole Blockage on Endwall Film Cooling and Vane Phantom Cooling Performances of a Transonic Turbine Vane

Turbine Blade Endwall Heat Transfer and Film Cooling Performance With Multigap Jets and Film Holes

Uncertainty Analysis of Laser Drilling Imperfection and Impacts on the Cooling Performance of a Transonic Turbine Vane

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