Developments in Hot-Streak Simulators for Turbine Testing

Povey, Thomas; Qureshi, Imran

doi:10.1115/1.2987240

Cited by 64 publications

(40 citation statements)

References 25 publications

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“…"Inlet profile generators" are then used to approximate the combustor exit flow supplied to the turbine rig. State-of-the-art work along these lines include, most recently, the work of Colban and co-workers [3,4], Barringer and co-workers [5,6], Povey and Qureshi [7,8], and Simone et al [9]. These past approaches have led to an improved understanding of the sensitivity of the turbine to the various inflow parameters separately, e.g., OTDF level.…”

Section: Introductionmentioning

confidence: 95%

Experimental and Numerical Investigation of Combustor-Turbine Interaction Using an Isothermal, Nonreacting Tracer

Chong

Hong

Ireland

et al. 2012

Journal of Engineering for Gas Turbines and Power

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Understanding the interaction between the combustor and turbine subsystems of a gas turbine engine is believed to be key in developing focused strategies for improving turbine performance. Past studies have approached the problem starting with an existing turbine rig with inlet conditions provided by "representative" hardware which attempts to mimic some key flow features exiting the combustor. In this paper, experiments are performed which center around complete engine hardware of the combustor, including engine geometry turbine nozzle guide vanes (NGVs) to solely represent the upstream impact of the complete turbine. This domain ensures that the traditional interface between combustor and turbine is sufficiently encompassed and not compromised by obfuscating or limiting effects due to approximating combustor hardware. The full-annular experimental measurements include all components of the velocity and pressure fields at various planar sections perpendicular to the primary flow direction. These include detailed, two-dimensional measurements both upstream and downstream of the NGVs. The combustor is a classic rich-burn design. Passive scalar (CO2) tracing measurements are peiformed to gain insight into the flow responsible for the temperature fields in the coupled system, including the impact of the NGVs on the upstream flow at the conventional combustor-turbine inteiface. CFD simulations are used to develop a complete picture of the combustor-turbine interface and the coupling between the two subsystems. The complementary experimental and simulation datasets are together intended to provide a benchmark for future, more traditional turbine rig tests and turbine CFD simulations where inlet conditions are at the exit plane of the combustor.

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Section: Introductionmentioning

confidence: 95%

Experimental and Numerical Investigation of Combustor-Turbine Interaction Using an Isothermal, Nonreacting Tracer

Chong

Hong

Ireland

et al. 2012

Journal of Engineering for Gas Turbines and Power

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“…Povey and Qureshi [1] provided a comprehensive review of facilities which were adapted for use in hot-streak (ITD) studies. Among the earlier facilities discussed (The Warm Core Turbine Test Facility at the NASA Lewis Research Center [2], The Large Scale Rotating Rig at the United Technologies Research Center [3], and The Rotating Blow-Down Facility at MIT [4,5]) experimental studies focused on the introduction of ITD and the investigation of ITD migration through the UP stage.…”

Section: Introductionmentioning

confidence: 99%

Design of a Nonreacting Combustor Simulator With Swirl and Temperature Distortion With Experimental Validation

Hall

Chana

Povey

2014

Journal of Engineering for Gas Turbines and Power

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Nonuniform combustor outlet flows have been demonstrated to have significant impact on the first and second stage turbine aerothermal performance. Rich-burn combustors, which generally have pronounced temperature profiles and weak swirl profiles, primarily affect the heat load in the vane but both the heat load and aerodynamics of the rotor. Lean burn combustors, in contrast, generally have a strong swirl profile which has an additional significant impact on the vane aerodynamics which should be accounted for in the design process. There has been a move towards lean burn combustor designs to reduce NOx emissions. There is also increasing interest in fully integrated design proc esses which consider the impact of the combustor flow on the design of the high pressure vane and rotor aerodynamics and cooling. There are a number of current large research projects in scaled (low temperature and pressure) turbine facilities which aim to provide validation data and physical understanding to support this design philosophy. There is a small body of literature devoted to rich burn combustor simulator design but no open lit erature on the topic of lean burn simulator design. The particular problem is that in non reacting, highly swirling and diffusing flows, vortex instability in the form of a precessing vortex core or vortex breakdown is unlikely to be well matched to the reacting case. In reacting combustors the flow is stabilized by heat release, but in low temperature simula tors other methods for stabilizing the flow must be employed. Unsteady Reynoldsaveraged Navier-Stokes and large eddy simulation have shown promise in modeling swirling flows with unstable features. These design issues form the subject of this paper.

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“…There is a big variety in the temperature ratios used in combustors depending on the design field of application. Compared to the study of Povey et al [13], this ratio is in the range observed in modem annular combustors used in aircraft engines. The peak temperature was approximately positioned at midspan and midpassage between the two stator blades.…”

Section: Experimental Methodsmentioning

confidence: 61%

Integrated Combustor Turbine Design for Improved Aerothermal Performance: Effect of Dilution Air Control

Basol

Regina

Kalfas

et al. 2012

Journal of Engineering for Gas Turbines and Power

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The effect of dilution air control in a combustor on the heat load distribution of an axial turbine with nonaxisymmetric endwall profiling is examined. Endwall profiling is a more common design feature in new engine types, due to its effectiveness in reducing secondary fiows and their associated losses. In the present work, the effect of dilution air control is examined by using two different circumferentially nonuniform hot-streak shapes; the two cases differ in their spanwise extents either side of the stator and, therefore, represent different approaches for dilution air control. This numerical study details the impact of these two different strategies for dilution air control on the rotor blade heat load distribution. The inlet boundary conditions simulate the experiment that is conducted in the axial research turbine facility LISA at ETH Zurich. A circumferential nonuniformity in the spanwise migration pattern of the hot streak inside the stator is observed that is found to be alleviated by the effect of the endwall profiling. Due to the observed spanwise migration pattern inside the stator the two hot-streak cases result in considerably different heat toad distributions on the rotor blade, emphasizing the importance of the integrated combustor turbine approach. Finally, the implications for dilution air control on the liner are discussed for the realization of the simulated hot-streak shapes in real combustors.

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Developments in Hot-Streak Simulators for Turbine Testing

Cited by 64 publications

References 25 publications

Experimental and Numerical Investigation of Combustor-Turbine Interaction Using an Isothermal, Nonreacting Tracer

Experimental and Numerical Investigation of Combustor-Turbine Interaction Using an Isothermal, Nonreacting Tracer

Design of a Nonreacting Combustor Simulator With Swirl and Temperature Distortion With Experimental Validation

Integrated Combustor Turbine Design for Improved Aerothermal Performance: Effect of Dilution Air Control

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