Numerical investigation of unsteady flow interactions in a transonic single stage high pressure turbine

This paper presents an experimental study of the unsteady flow field downstream of a high pressure turbine with ejected purge flows, with a special focus on a flow field discussion using the mode detection approach according to the theory of Tyler and Sofrin. Measurements were carried out in a product-representative one and a half stage turbine test setup, which consists of a high-pressure turbine stage followed by an intermediate turbine center frame and a low-pressure turbine vane row. Four independent purge mass flows were injected through the forward and aft cavities of the unshrouded high-pressure turbine rotor. A fast-response pressure probe was used to acquire time-resolved data at the turbine center frame duct inlet and exit. The interactions between the stator, rotor, and turbine center frame duct are identified as spinning modes, propagating in azimuthal direction. Time-space diagrams illustrate the amplitude variation of the detected modes along the span. The composition of the unsteadiness and its major contributors are of interest to determine the role of unsteadiness in the turbine center frame duct loss generation mechanisms and to avoid high levels of blade vibrations in the low-pressure turbine which can in turn result in increased acoustic emissions. This work offers new insight into the unsteady flow behavior downstream of a purged high-pressure turbine and its propagation through an engine-representative turbine center frame duct configuration.

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Development of New Single and High-Density Heat-Flux Gauges for Unsteady Heat Transfer Measurements for a Rotating Transonic Turbine

Volume 7C: Heat Transfer ◽

10.1115/gt2020-14527 ◽

2020 ◽

Author(s):

Richard Celestina ◽

Spencer Sperling ◽

Louis Christensen ◽

Randall Mathison ◽

Hakan Aksoy ◽

...

Keyword(s):

Heat Transfer ◽

Heat Flux ◽

High Pressure ◽

Pressure Ratio ◽

High Density ◽

Secondary Flows ◽

Single Stage ◽

High Pressure Turbine ◽

Transonic Turbine ◽

New Generation

Abstract This paper presents the development and implementation of a new generation of double-sided heat-flux gauges at The Ohio State University Gas Turbine Laboratory (GTL) along with heat transfer measurements for film-cooled airfoils in a single-stage high-pressure transonic turbine operating at design corrected conditions. Double-sided heat flux gauges are a critical part of turbine cooling studies, and the new generation improves upon the durability and stability of previous designs while also introducing high-density layouts that provide better spatial resolution. These new customizable high-density double-sided heat flux gauges allow for multiple heat transfer measurements in a small geometric area such as immediately downstream of a row of cooling holes on an airfoil. Two high-density designs are utilized: Type A consists of 9 gauges laid out within a 5 mm by 2.6 mm (0.20 inch by 0.10 inch) area on the pressure surface of an airfoil, and Type B consists of 7 gauges located at points of predicted interest on the suction surface. Both individual and high-density heat flux gauges are installed on the blades of a transonic turbine experiment for the second build of the High-Pressure Turbine Innovative Cooling program (HPTIC2). Run in a short duration facility, the single-stage high-pressure turbine operated at design-corrected conditions (matching corrected speed, flow function, and pressure ratio) with forward and aft purge flow and film-cooled blades. Gauges are placed at repeated locations across different cooling schemes in a rainbow rotor configuration. Airfoil film-cooling schemes include round, fan, and advanced shaped cooling holes in addition to uncooled airfoils. Both the pressure and suction surfaces of the airfoils are instrumented at multiple wetted distance locations and percent spans from roughly 10% to 90%. Results from these tests are presented as both time-average values and time-accurate ensemble averages in order to capture unsteady motion and heat transfer distribution created by strong secondary flows and cooling flows.

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Numerical investigation of impingement heat transfer on smooth and roughened surfaces in a high-pressure turbine inner casing

International Journal of Thermal Sciences ◽

10.1016/j.ijthermalsci.2019.106186 ◽

2020 ◽

Vol 149 ◽

pp. 106186 ◽

Cited By ~ 3

Author(s):

Fujuan Tong ◽

Wenxuan Gou ◽

Zhenan Zhao ◽

Wenjing Gao ◽

Honglin Li ◽

...

Keyword(s):

Heat Transfer ◽

High Pressure ◽

Numerical Investigation ◽

High Pressure Turbine ◽

Impingement Heat Transfer

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Using CFD to Reduce Resonant Stresses on a Single-Stage, High-Pressure Turbine Blade

Volume 4: Turbo Expo 2002, Parts A and B ◽

10.1115/gt2002-30320 ◽

2002 ◽

Cited By ~ 13

Author(s):

J. P. Clark ◽

A. S. Aggarwala ◽

M. A. Velonis ◽

R. E. Gacek ◽

S. S. Magge ◽

...

Keyword(s):

High Pressure ◽

Turbine Blade ◽

Guide Vane ◽

Turbine Blades ◽

Suction Side ◽

Lessons Learned ◽

Single Stage ◽

Navier Stokes ◽

High Pressure Turbine ◽

Time Resolved

The ability to predict levels of unsteady forcing on high-pressure turbine blades is critical to avoid high-cycle fatigue failures. In this study, 3D time-resolved computational fluid dynamics is used within the design cycle to predict accurately the levels of unsteady forcing on a single-stage high-pressure turbine blade. Further, nozzle-guide-vane geometry changes including asymmetric circumferential spacing and suction-side modification are considered and rigorously analyzed to reduce levels of unsteady blade forcing. The latter is ultimately implemented in a development engine, and it is shown successfully to reduce resonant stresses on the blade. This investigation builds upon data that was recently obtained in a full-scale, transonic turbine rig to validate a Reynolds-Averaged Navier-Stokes (RANS) flow solver for the prediction of both the magnitude and phase of unsteady forcing in a single-stage HPT and the lessons learned in that study.

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Design and Test Results of a Ultra High Loaded Single Stage High Pressure Turbine

Volume 6A: Turbomachinery ◽

10.1115/gt2013-94055 ◽

2013 ◽

Cited By ~ 2

Author(s):

Harjit S. Hura ◽

Scott Carson ◽

Rob Saeidi ◽

Hyoun-Woo Shin ◽

Paul Giel

Keyword(s):

High Pressure ◽

Total Pressure ◽

High Speed ◽

Pressure Ratio ◽

Single Stage ◽

Test Results ◽

High Pressure Turbine ◽

Technology Program ◽

High Pressure Ratio ◽

Expected Performance

This paper describes the engine and rig design, and test results of an ultra-highly loaded single stage high pressure turbine. In service aviation single stage HPTs typically operate at a total-to-total pressure ratio of less than 4.0. At higher pressure ratios or energy extraction the nozzle and blade both have regions of supersonic flow and shock structures which, if not mitigated, can result in a large loss in efficiency both in the turbine itself and due to interaction with the downstream component which may be a turbine center frame or a low pressure turbine. Extending the viability of the single stage HPT to higher pressure ratios is attractive as it enables a compact engine with less weight, and lower initial and maintenance costs as compared to a two stage HPT. The present work was performed as part of the NASA UEET (Ultra-Efficient Engine Technology) program from 2002 through 2005. The goal of the program was to design and rig test a cooled single stage HPT with a pressure ratio of 5.5 with an efficiency at least two points higher than the state of the art. Preliminary design tools and a design of experiments approach were used to design the flow path. Stage loading and through-flow were set at appropriate levels based on prior experience on high pressure ratio single stage turbines. Appropriate choices of blade aspect ratio, count, and reaction were made based on comparison with similar HPT designs. A low shock blading design approach was used to minimize the shock strength in the blade during design iterations. CFD calculations were made to assess performance. The HPT aerodynamics and cooling design was replicated and tested in a high speed rig at design point and off-design conditions. The turbine met or exceeded the expected performance level based on both steady state and radial/circumferential traverse data. High frequency dynamic total pressure measurements were made to understand the presence of unsteadiness that persists in the exhaust of a transonic turbine.

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Time-Averaged and Time-Accurate Aero-Dynamics for the Recessed Tip Cavity of a High-Pressure Turbine Blade and the Outer Stationary Shroud: Comparison of Computational and Experimental Results

Volume 5: Turbo Expo 2004, Parts A and B ◽

10.1115/gt2004-53443 ◽

2004 ◽

Cited By ~ 4

Author(s):

Brian R. Green ◽

John W. Barter ◽

Charles W. Haldeman ◽

Michael G. Dunn

Keyword(s):

High Pressure ◽

Turbine Blade ◽

Computational Models ◽

Turbine Rotor ◽

Single Stage ◽

Cfd Modeling ◽

Blade Surface ◽

High Pressure Turbine ◽

Pressure Transducers ◽

Blade Tip

The unsteady aero-dynamics of a single-stage high-pressure turbine blade operating at design corrected conditions has been the subject of a thorough study involving detailed measurements and computations. The experimental configuration consisted of a single-stage high-pressure turbine and the adjacent, downstream, low-pressure turbine nozzle row. All three blade-rows were instrumented at three spanwise locations with flush-mounted, high frequency response pressure transducers. The rotor was also instrumented with the same transducers on the blade tip and platform and the stationary shroud was instrumented with pressure transducers at specific locations above the rotating blade. Predictions of the time-dependent flow field around the rotor were obtained using MSU-TURBO, a 3D, non-linear, computational fluid dynamics (CFD) code. Using an isolated blade-row unsteady analysis method, the unsteady surface pressure for the high-pressure turbine rotor due to the upstream high-pressure turbine nozzle was calculated. The predicted unsteady pressure on the rotor surface was compared to the measurements at selected spanwise locations on the blade, in the recessed cavity, and on the shroud. The rig and computational models included a flat and recessed blade tip geometry and were used for the comparisons presented in the paper. Comparisons of the measured and predicted static pressure loading on the blade surface show excellent correlation from both a time-average and time-accurate standpoint. This paper concentrates on the tip and shroud comparisons between the experiments and the predictions and these results also show good correlation with the time-resolved data. These data comparisons provide confidence in the CFD modeling and its ability to capture unsteady flow physics on the blade surface, in the flat and recessed tip regions of the blade, and on the stationary shroud.

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Large Eddy Simulation of Combustor and Complete Single-Stage High-Pressure Turbine of the FACTOR Test Rig

Volume 2A: Turbomachinery ◽

10.1115/gt2019-91206 ◽

2019 ◽

Author(s):

Martin Thomas ◽

Jerome Dombard ◽

Florent Duchaine ◽

Laurent Gicquel ◽

Charlie Koupper

Keyword(s):

High Pressure ◽

Large Eddy Simulation ◽

Combustion Chamber ◽

Measurement Data ◽

Single Stage ◽

High Pressure Turbine ◽

Lean Burn ◽

Eddy Simulation ◽

Large Eddy ◽

Compact Design

Abstract Development goals for next generation aircraft engines are mainly determined by the need to reduce fuel consumption and environmental impact. To reduce NOx emissions lean combustion technologies will be applied in future development projects. The more compact design and the absence of dilution holes in this type of engines shortens residence times in the combustion chamber and reduces mixing which results in higher levels of swirl, turbulence and temperature distortions at the exit of the combustion chamber. For these engines interactions between components are more important, so that the traditional engine design approach of component-wise optimization will have to be adapted. To study new lean burn architectures the European FACTOR project investigates the transport of hot streaks produced by a non-reactive combustor simulator through a single stage high-pressure turbine. In this work high-fidelity Large Eddy Simulation (LES) of combustor and complete high-pressure turbine are discussed and validated against experimental data. Measurement data is available on P40 (exit of the combustion chamber), P41 (exit of the stator) and P42 (exit of the rotor) and generally shows a good agreement to LES data.

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