Investigation of Unsteady Flow Phenomena in First Vane Caused by Combustor Flow With Swirl

Jacobi, Simon; Mazzoni, Cosimo Maria; Rosic, Budimir; Chana, Krishan

doi:10.1115/1.4035073

Cited by 41 publications

(33 citation statements)

References 42 publications

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“…Finally, the aero-thermal behavior of the HPT is further complicated by the film cooling and the interaction with the combustor, which introduces time-dependent gradients in total pressure and total temperature as well as whirling flow at the stage inlet. These features were found to considerably affect the aerodynamics and the heat transfer [22][23][24] as well as the aero-acoustic behavior [25] of the HPT.…”

Section: Introductionmentioning

confidence: 99%

Coupled Effect of Expansion Ratio and Blade Loading on the Aerodynamics of a High-Pressure Gas Turbine

2017

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Abstract:The need of a continuous improvement in gas turbine efficiency for propulsion and power generation, as well as the more demanding operating conditions and power control required to these machines, still ask for great efforts in the design and analysis of the high pressure section of the turbo-expander. To get detailed insights and improve the comprehension of the flow physics, a wide experimental campaign has been performed in the last ten years at Politecnico di Milano on the unsteady aerodynamics of a high-pressure turbine stage considering several operating conditions. This paper presents and discusses the experimental results obtained for the stage operating with different expansion ratios and rotor loading. The turbine stage under study is representative of a modern high-pressure turbine and can be operated in both subsonic and transonic conditions. The experimental tools applied for the current research represents the state of the art when unsteady investigations are foreseen. The detailed flow field, the blade-rows interaction and the overall performance are described and discussed; efforts have been devoted to the discussion of the various contribution to the overall stage efficiency. The direct effects of the expansion ratio, affecting the Reynolds and the Mach numbers, have been highlighted and quantified; similarly, the indirect effects, accounting for a change in the rotor loading, have been commented and quantified as well, thanks to a dedicated set of experiments where different rotor loadings at the same expansion ratio have been prescribed.

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Section: Introductionmentioning

confidence: 99%

Coupled Effect of Expansion Ratio and Blade Loading on the Aerodynamics of a High-Pressure Gas Turbine

2017

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“…These vortices drive fluid away from the vane surface, thus thickening the boundary layer and decreasing heat transfer locally. They are induced by the low pressure zone at the inlet swirl core that causes the vortices to roll-up at the leading edge as described by Jacobi et al [19]. …”

Section: Heat Transfer and Wall Temperaturesmentioning

confidence: 99%

“…Different authors have studied the isolated effects of inlet swirl (Giller et al [14], Qureshi et al [15], Schmid et al [16], Beard et al [17], Insinna et al [18], and Jacobi et al [19]), hot streaks (He et al [20], Basol et al [21], and Beard et al [22]) and elevated turbulence (van Fossen et al [23]). However, there are few data, and no unifying theory exists with respect to their combined effects.…”

Section: Introductionmentioning

confidence: 99%

Parameterised Model of 2D Combustor Exit Flow Conditions for High-Pressure Turbine Simulations

Schneider

Schiffer

Lehmann

2017

IJTPP

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An algorithm is presented generating a complete set of inlet boundary conditions for Reynolds-averaged Navier-Stokes computational fluid dynamics (RANS CFD) of high-pressure turbines to investigate their interaction with lean and rich burn combustors. The method shall contribute to understanding the sensitivities of turbine aerothermal performance in a systematic approach. The boundary conditions are based on a set of input parameters controlling velocity, temperature, and turbulence fields. All other quantities are derived from operating conditions and additional modelling assumptions. The algorithm is coupled with a CFD solver by applying the generated profiles as inlet boundary conditions. The successive steps to derive consistent flow profiles are described and results are validated against flow fields extracted from combustor CFD.

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“…These features might significantly alter the blade surface temperature, with noteworthy implications on the rotor cooling effectiveness [2]. In addition to detailed investigations on the aerothermal features of the flow released by combustors ( [8], among others), recent studies have considered more realistic configurations, combining the hot streak with a local streamwise vorticity [9] and studying the potential for clocking between the burners and the stator blades [10]. The residual hot streak entering the rotor induces even more complex features within the rotor blade row, including the generation of further vorticity cores which are pushed towards the endwalls [11], altering the wall temperature in these regions and triggering the development of novel cooling techniques [12].…”

Section: Introductionmentioning

confidence: 99%

“…The device was allowed to reach 390 K in the core of the hot streak, as measured on a traverse placed one vane axial chord upstream of the vane leading edge. This temperature peak corresponds to an increase of 20% of the main stream temperature, which is a realistic representation of hot-streak-induced temperature perturbation; just to set a general context, [9,12] documented a temperature ratio of ~1.09 while [8,10] imposed a ratio greater than 1.5. The hot streaks were injected at 70% of the span in the stream-wise direction, with the aim of minimizing the injector blockage and of limiting the jet interaction with the vane secondary flows.…”

Section: Introductionmentioning

confidence: 99%

Hot Streak Evolution in an Axial HP Turbine Stage

Gaetani

Persico

2017

IJTPP

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This paper presents the results of an experimental study on the evolution of hot streaks generated by gas turbine burners in an un-cooled high-pressure turbine stage. The prescribed hot streaks were directed streamwise and characterized by a 20% over-temperature with respect to the main flow at the stage inlet. The hot streak was injected in four different circumferential positions with respect to the stator blade. Detailed temperature and aerodynamic measurements upstream and downstream of the stage, as well as in-between the blade rows, were performed. Measurements showed a severe temperature attenuation of the hot streaks within the stator cascade; some influence on the aerodynamic field was found, especially on the vorticity field, while the temperature pattern resulted in severe alteration depending on the injection position. Downstream of the rotor, the jet spread over the pitch above the midspan and was more concentrated at the hub. Rotor secondary flows were also enhanced by hot streaks.

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Investigation of Unsteady Flow Phenomena in First Vane Caused by Combustor Flow With Swirl

Cited by 41 publications

References 42 publications

Coupled Effect of Expansion Ratio and Blade Loading on the Aerodynamics of a High-Pressure Gas Turbine

Coupled Effect of Expansion Ratio and Blade Loading on the Aerodynamics of a High-Pressure Gas Turbine

Parameterised Model of 2D Combustor Exit Flow Conditions for High-Pressure Turbine Simulations

Hot Streak Evolution in an Axial HP Turbine Stage

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