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

Gaetani, Paolo; Persico, Giacomo; Spinelli, Andrea

doi:10.3390/app7030259

Cited by 18 publications

(17 citation statements)

References 29 publications

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“…In this section, the combustor simulator, the wind tunnel and the measurement techniques are described. A description of the turbine test facility is proposed in [17]. Here, the results are discussed for an operating condition, called OP3 in [17], that exploits a stage expansion ratio of 1.4 with a flow Mach number approaching the stator of 0.14.…”

Section: Methodsmentioning

confidence: 99%

Design and Commissioning of a Combustor Simulator Combining Swirl and Entropy Wave Generation

Notaristefano

Gaetani

2020

IJTPP

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Modern aero-engine combustion chambers burn a lean and premixed mixture, generating a turbulent flame which involves large heat-release fluctuations, thus producing unsteady temperature phenomena commonly referred to as entropy waves (EWs). Furthermore, to enhance the fuel air mixing, combustion air is swirled, leading to vorticity disturbances. These instabilities represent one of the biggest challenges in gas turbine design. In this paper, the design and testing of a novel entropy wave generator (EWG) equipped with a swirler generator (SG) are described. The novel EWG will be used in future works on the high-speed test rig at Politecnico di Milano to study the combustor–turbine interaction. The paper shows the process of the EWG geometry and layout. The EWG is able to produce an engine-representative EW, the extreme condition is at the maximum frequency of 110 Hz, a peak-to-valley temperature value of 20 °C and swirling angles of ±25° are measured. By virtue of these results, the proposed system outperforms other EWG devices documented in the literature. Furthermore, the addition of a swirling generator makes this device one of a kind.

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Section: Methodsmentioning

confidence: 99%

Design and Commissioning of a Combustor Simulator Combining Swirl and Entropy Wave Generation

Notaristefano

Gaetani

2020

IJTPP

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“…In fact, given a total pressure loss coefficient of about 5.9% for the reference condition [14], the increase on the single stator channel (ΔY%) due to the hot streak injection is within 0.2% to 0.6%, as reported in Table 3, i.e., one order of magnitude lower and, for some cases, within the measurement uncertainty. The total temperature increase (ΔTt) is slightly changing with the minimum for the leading edge case, where the hot streak interacts directly with the blade and, for this, an effect of the heat exchange with the blade wall is expected, even though very difficult to quantify.…”

Section: Stator Performancementioning

confidence: 68%

“…The impact of the hot streak on the blade wake can be observed in Figure 5, which reports the total pressure loss coefficient distributions for the reference and the hot streak conditions, as well as their difference; the wake retains its general width and deficit, even though a small tangential shift is found especially above the midspan. The stator-exit vorticity field, not reported for sake of brevity, does not show a specific effect of the hot streak on the stator secondary flow for LE injection (the reader is referred to [14] for a comprehensive discussion of the stator aerodynamics in the absence of hot streak injection). Overall, the hot streak injection slightly changes the cascade loss coefficient, especially above the midspan (namely, where the jet impinges on the blade), as reported in Figure 6.…”

Section: Le Injection Casementioning

confidence: 99%

“…Table 1 provides relevant information on the turbine geometry, as well as the reference operating conditions of the present tests. For this first study on hot-streak migration in the turbine, subsonic conditions were considered (even though measurements in transonic conditions have been recently published in [14]). The aerodynamics of the turbine operated in subsonic conditions was extensively studied in the last decade and can be found in [15][16][17].…”

Section: Introductionmentioning

confidence: 99%

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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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“…In fact, when the rotor loading increases, the rotor suction side boundary layer is more prone to instability and the rotor vortical structure more intense, making all of them more sensitive to any variation coming from upstream. Figure 11, shows the relative total pressure coefficient and deviation angle standard deviations, calculated among the different time instants, for a negative incidence conditions (Figure 11a, incidence at midspan = −10°) and a positive one (Figure 11b, incidence at midspan = +10°) [35].…”

Section: Off Design Conditionsmentioning

confidence: 99%

Stator-Rotor Interaction in Axial Turbine: Flow Physics and Design Perspective

Gaetani¹

2018

Aircraft Technology

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The stator-rotor interaction is an important issue in turbomachinery design when the highest performances are targeted. Different characters mark the interaction process in high-pressure or low-pressure turbines depending both on the blade height and on the Reynolds number. For small blade heights, being the stator secondary flows more important, a more complex interaction is found with respect to the high blades, where the stator blade wake dominates. In low-pressure turbines, the stator wake promotes the transition to turbulent boundary layer, allowing for an efficient application of ultra-high lift blades. First, a detailed discussion of the flow physics is proposed for high-and low-pressure turbines. Some off-design conditions are also commented. Then, a design perspective is given by discussing the effect of the axial gap between the stator and the rotor and by commenting the effects of three-dimensional design on the interaction.

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

Cited by 18 publications

References 29 publications

Design and Commissioning of a Combustor Simulator Combining Swirl and Entropy Wave Generation

Design and Commissioning of a Combustor Simulator Combining Swirl and Entropy Wave Generation

Hot Streak Evolution in an Axial HP Turbine Stage

Stator-Rotor Interaction in Axial Turbine: Flow Physics and Design Perspective

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