Unsteady Flow in a Single Stage Turbine

Hilditch, M. A.; Smith, Graham C.; Singh, Udai K.

doi:10.1115/98-gt-531

Cited by 27 publications

(10 citation statements)

References 16 publications

(27 reference statements)

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“…It is a crucial procedure for temporal stability and spatial periodicity [14]. However, the introduction of tailboards causes shockwave reflections from the solid boundaries and promotes undesirable pressure fluctuations [30]. In order to negate this effect, which is an artifact of the test conditions, the tailboards include 3 mm perforations at 60 deg incline to the flow (Fig.…”

Section: Mechanical Designmentioning

confidence: 99%

Continuous Closed-Loop Transonic Linear Cascade for Aerothermal Performance Studies in Microturbomachinery

Yakirevich

Miezner

Leizeronok

et al. 2017

Journal of Engineering for Gas Turbines and Power

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The present work summarizes the design process of a new continuous closed-loop hot transonic linear cascade. The facility features fully modular design which is intended to serve as a test bench for axial microturbomachinery components in independently varying Mach and Reynolds numbers ranges of 0-1.3 and 2 Â 10 4 -6 Â 10 5 , respectively. Moreover, for preserving heat transfer characteristics of the hot gas section, the gas to solid temperature ratio (up to 2) is retained. This operational environment has not been sufficiently addressed in prior art, although it is critical for the future development of ultra-efficient high power or thrust devices. In order to alleviate the dimension specific challenges associated with microturbomachinery, the facility is designed in a highly versatile manner and can easily accommodate different geometric configurations (pitch, 620 deg stagger angle, and 620 deg incidence angle), absence of any alterations to the test section. Owing to the quick swap design, the vane geometry can be easily replaced without manufacturing or re-assembly of other components. Flow periodicity is achieved by the inlet boundary layer suction and independently adjustable tailboard mechanisms. Enabling test-aided design capability for microgas turbine manufacturers, aerothermal performance of various advanced geometries can be assessed in engine relevant environments.

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Section: Mechanical Designmentioning

confidence: 99%

Continuous Closed-Loop Transonic Linear Cascade for Aerothermal Performance Studies in Microturbomachinery

Yakirevich

Miezner

Leizeronok

et al. 2017

Journal of Engineering for Gas Turbines and Power

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“…It is also apparent that many embodiments of the airfoil bow can increase resonant stresses. Fortunately for the airfoil designer, improvements in gas-turbine computational fluid dynamics (CFD) have allowed for ever more sophisticated flowfield predictions (e.g., Dunn [21] and Adamczyk [22]), and it is now possible to predict both the time-averaged and time-resolved pressure loadings on transonic airfoils with good accuracy within constraints consistent with appropriate code validation (e.g., Rao et al [23], Busby et al [24], Hilditch et al [25], and many others [26][27][28][29]). Design-optimization systems have previously been used in conjunction with steady-state flow solvers with beneficial effects on transonic turbine airfoils (e.g., Jennions and Adamczyk [30] and Clark et al [20]).…”

Section: Optimization Using 3d Unsteady Rans Analysismentioning

confidence: 99%

Reducing Shock Interactions in Transonic Turbine via Three-Dimensional Aerodynamic Shaping

Hancock

Clark

2014

Journal of Propulsion and Power

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“…A small number of papers have described investigations into blade row interaction in high pressure turbines at engine representative conditions [9][10][11][12][13][14]. These papers have resulted in a good understanding of the interaction mechanism within the rst turbine stage.…”

Section: Introductionmentioning

confidence: 99%

Time-resolved vane-rotor-vane interaction in a transonic one-and-a-half stage turbine

Miller

Moss

Ainsworth

et al. 2001

Proceedings of the Institution of Mechanical Engineers, Part A:

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This paper describes the effect of both an upstream and a downstream vane on the timeresolved surface pressure eld around a high-pressure rotor blade. The geometry of the downstream vane considered is a large low aspect ratio vane located in a swan-necked diffuser duct, similar to those likely to be used in future engine designs. Two test geometries are considered: rstly, a high-pressure turbine stage coupled with a swan-necked diffuser exit duct; secondly, the same high-pressure stage but with a vane located in the downstream duct. Both tests were conducted at engine-representative Mach and Reynolds numbers, and experimental data were acquired using fast response pressure transducers mounted on the mid-height streamline of the high-pressure rotor blades. It is shown that the potential eld of the downstream vane causes a relatively large static pressure uctuation on the late rotor suction surface but that the early suction surface and pressure surface are unaffected by the presence of the vane. In addition to the two main interaction mechanisms (upstream vane-rotor and downstream vanerotor interactions) a third interaction is identi ed. This is shown to be caused by the interaction, within the rotor passage, between the ow eld associated with the upstream vane and the potential eld associated with the downstream vane. This new interaction mechanism is shown to cause static pressure uctuations on the late rotor suction surface at a frequency corresponding to the difference in the numbers of upstream and downstream vanes.

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Unsteady Flow in a Single Stage Turbine

Cited by 27 publications

References 16 publications

Continuous Closed-Loop Transonic Linear Cascade for Aerothermal Performance Studies in Microturbomachinery

Continuous Closed-Loop Transonic Linear Cascade for Aerothermal Performance Studies in Microturbomachinery

Reducing Shock Interactions in Transonic Turbine via Three-Dimensional Aerodynamic Shaping

Time-resolved vane-rotor-vane interaction in a transonic one-and-a-half stage turbine

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