Effect of in-service burnout effect on the transonic leakage flows over cavity tip model

Saleh, Zainab; Avital, Eldad; Korakianitis, Theodosios

doi:10.1177/09576509211012113

Proceedings of the Institution of Mechanical Engineers, Part A:

2021

DOI: 10.1177/09576509211012113

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Effect of in-service burnout effect on the transonic leakage flows over cavity tip model

Zainab Saleh

Eldad Avital

Theodosios Korakianitis

Abstract: Increasing the gas temperature at the inlet to the high pressure turbine of gas turbine engines is known as a proven method to increase the efficiency of these engines. However, this will expose the blades’ surface to very high heat load and thermal damages. In the case of the un-shrouded turbine blades, the blade tip will be exposed to a significant thermal load due to the developed leakage flows in the tip gap, this leads to in-service burnout which degrades the blade tip and shortens its operational life. T… Show more

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Cited by 3 publications

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Investigation of burnout effect in turbine blade tip leakage at transonic conditions: a numerical study

Boopalan,

Arumugam

et al. 2024

Eng. Res. Express

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In the aviation industry, turbine blade tip leakage significantly impacts the economy due to aerodynamic losses in the turbine. The tip leakage flow increases when the tip surface is exposed to high heat loads from the burnout effect, contributing to nearly 30% of the total loss in the turbine stage. This study numerically investigates two-dimensional flat tip and burnt-out tip models under different flow accelerations at transonic conditions. Variations in the discharge coefficient are examined for different pressure ratios across the tip gap. Flow and shockwave patterns for various blade tip geometries are obtained and analyzed. The burnt-out tip notably increases tip leakage, and a significant decrease in turbine efficiency is observed beyond a critical burnout limit. The quantified losses at different stages of blade tip burnout are used to predict the effective operational life of the blade. A correlation is developed to relate the non-dimensional tip-leakage flow parameters to the normalized blade-tip geometry.

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Investigation of burnout effect in turbine blade tip leakage at transonic conditions: a numerical study

Boopalan,

Arumugam

et al. 2024

Eng. Res. Express

View full text Add to dashboard Cite

show abstract

Sensitivity of Adiabatic Cooling Effectiveness to Mainstream and Coolant Temperatures in Transonic Flow Over an Idealized Blade Tip Model

Zeng

Dai

et al. 2022

Journal of Turbomachinery

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Film cooling has been studied profusely in subsonic flows, but in transonic flow, the determination of adiabatic cooling effectiveness faces a dilemma in the state of the art. Specifically, derivation of reference temperature, or local recovery temperature, in adiabatic effectiveness is disputable. Some researchers designate it to be the adiabatic wall temperature for the uncooled model (linear regression method, LRM), but others calculate it from an iterative procedure based on a pair of cooling tests which only differs in coolant temperature (dual linear regression technique, DLRT). As the first of the kind effort to explore this dilemma, this paper carried out transient thermal measurements by infrared thermography, for transonic flow over an idealized blade tip model. Heat transfer experiments were conducted for the uncooled and cooled cases, at two mainstream temperatures (340K and 325K), and two coolant temperatures (276K and 287K). Data from these six experiments were processed by LRM and DLRT respectively. It is found that heat transfer coefficient is insensitive to temperature boundary conditions and data reduction methods, as expected. However, for adiabatic effectiveness, LRM results are sensitive to the 11K decrease of coolant temperature in areas confined to the upstream of cooling injection, and much less so to the 15K rise in mainstream temperature. DLRT result reduces globally and conspicuously with 15K increase in mainstream temperature. Furthermore, adiabatic effectiveness obtained by LRM is qualitatively different to that by DLRT, which is attributed to the large discrepancy of reference temperature between the two methods.

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Effects of Leading-Edge Blowing Control and Reduced Frequency on Airfoil Aerodynamic Performances

Chen,

Avital,

Willams

et al. 2024

Journal of Fluids Engineering

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Aerofoil leading-edge fluid-blowing control is computationally studied to improve aerodynamic efficiency. The fluid injection momentum coefficient Cu (the ratio of injection to incoming square velocities times the slot's width to aerofoil's half chord-length), varies from 0.5% to 5.4%. Both static and dynamic conditions are investigated for a NACA0018 aerofoil at low speed and Reynolds number of 250k based on the aerofoil's chord-length. The aerofoil is dynamically pitched at at a reduced frequency (the pitching tangential speed to the free-stream speed ratio), varying between 0.0078 to 0.2. RANS and Unsteady RANS (URANS) are used in the simulations as based on the Transition SST and Spalart-Allmaras models, generally achieving good agreement with experimental results in lift and drag coefficients and in the pressure coefficient distributions along the aerofoil. It is found that oscillating the aerofoil can delay stall, as expected, in dynamic stall. Leading-edge blowing control can also significantly delay stall both in static and dynamic conditions as long as sufficient momentum is applied to the control. On the other hand, for a small Cu such as 0.5%, the leading-edge control worsens the performance and hastens the appearance of stall in both static and dynamic conditions. The aerofoil's oscillation reduces the differences between pitch-up and pitch-down aerodynamic performances. Detailed analysis of vorticity, pressure, velocity and streamline contours are given to provide plausible explanations and insight to the flow.

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Effect of in-service burnout effect on the transonic leakage flows over cavity tip model

Cited by 3 publications

References 54 publications

Investigation of burnout effect in turbine blade tip leakage at transonic conditions: a numerical study

Investigation of burnout effect in turbine blade tip leakage at transonic conditions: a numerical study

Sensitivity of Adiabatic Cooling Effectiveness to Mainstream and Coolant Temperatures in Transonic Flow Over an Idealized Blade Tip Model

Effects of Leading-Edge Blowing Control and Reduced Frequency on Airfoil Aerodynamic Performances

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