Aerodynamic Performance of Low Speed Axial Flow Compressor Rotors with Sweep and Tip Clearance

Ramakrishna, P. V.; Govardhan, M.

doi:10.1080/19942060.2009.11015265

Cited by 7 publications

(5 citation statements)

References 8 publications

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“…Finally, validation-calibration of CFD codes for predicting the extremely challenging areas of separated flows can be also carried out (Pachidis et al, 2006). The increased computational power available nowadays throughout the research community has increased the application of high-fidelity numerical approaches on every kind of flow prediction, starting from pure aerodynamic phenomena occurring at inlets or compressors and extending them in combustion or turbine cooling research, employing multidisciplinary tools of chemical or heat transfer nature (Chaluvadi et al, 2003;Ramakrishna et al, 2009;Ummiti et al, 2009). In case of far off-design turbomachinery performance studies such as the above-described ones, the availability of experimental datasets is the only aspect that prevents the numerical tools from being further validated and at a second stage further improved.…”

Section: Introductionmentioning

confidence: 99%

Experimental and Numerical Investigation of a Compressor Cascade at Highly Negative Incidence

Zachos

Grech

Charnley

et al. 2011

Engineering Applications of Computational Fluid Mechanics

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ABSTRACT:The performance prediction of axial flow compressors and turbines still relies on the stationary testing of blade cascades. Most of the blade testing studies are done for operating conditions close to the design point or in off-design areas not too far from it. However, blade-and consequently engine-performance remain unexplored at relatively far off-design conditions, such as windmilling or sub-idle. Such regimes are dominated by blade operation under extremely low mass flows and rotational speeds that imply highly negative values of incidence angle, thus totally separated flows on the pressure side of the blades. Those flow patterns are difficult to be measured and even more difficult to be numerically predicted as the current modelling capability of separated internal flows is of limited reliability. In this paper, the performance of a 3-dimensional linear compressor cascade at highly negative incidence angle is initially experimentally investigated. The main objective of the study is to derive the total pressure loss and outlet flow angle through the blades and use the data for the validation-calibration of a numerical solver enhancing its capability to predict highly separated flows. The development of the CFD model and the simulation strategy followedare also presented.The numerical results are compared against the derived test data demonstrating a good agreement. In addition, most trends of the properties of interest have been captured sufficiently, therefore the physical phenomena are considered to be well captured, allowing the numerical tool to be used for further studies on similar test cases.

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Section: Introductionmentioning

confidence: 99%

Experimental and Numerical Investigation of a Compressor Cascade at Highly Negative Incidence

Zachos

Grech

Charnley

et al. 2011

Engineering Applications of Computational Fluid Mechanics

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show abstract

“…The Fig. 4 Flow domain with the given boundary conditions results obtained with these two turbulence models were compared with the available experimental results (given in reference [17]). Grid independency study was also conducted and the mesh size was optimized to about 700 000 mesh elements for the rotor and 450 000 elements for the stator.…”

Section: Computational Methodologymentioning

confidence: 99%

“…Grid independency study was also conducted and the mesh size was optimized to about 700 000 mesh elements for the rotor and 450 000 elements for the stator. Details of the mesh, grid independence study, wall function treatment and y+ pertaining to the present study can be found in Ramakrishna and Govardhan [17]. Details of the flow domain with the given boundary conditions are shown in Fig.…”

Section: Computational Methodologymentioning

confidence: 99%

On loading corrections and loss distributions in low-speed forward swept axial compressor rotors

Ramakrishna

Govardhan

2011

Proceedings of the Institution of Mechanical Engineers, Part A:

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Loading of a swept aerofoil blade is typically reduced as its lifting line is inclined (at the sweep angle) with the radial direction. Various estimations are available in the literature about the correction to be made on the loading of a wing when the same is swept. However, it is difficult to obtain an accurate and a more general estimation of correction for a range of sweep angles and for a range of mass flowrates. This article presents two aspects of the flow field in forward swept compressor blade passages: (a) Loading of swept rotors from the present computational study (on a baseline unswept rotor and forward swept rotors of 20 • , 30 • , and 40 • sweep angles; for different tip clearance and stagger configurations) is compared with a number of load correction estimations reported in the literature. Loading of the swept rotors obtained through numerical simulations is compared with the existing estimations obtained from the loading of unswept rotor. A correction factor blend is evaluated, which is found to provide good estimations of loading characteristics for various sweep configurations. (b) Spanwise and streamwise resolved loss coefficient distributions are studied, which showed that the high endwall losses observed in the unswept rotor were significantly reduced with blade sweeping. However, tip clearance is found to result in increased overall loss in the swept rotors.

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“…Details of the computational methodology adopted in the present work, numerical validation and so forth, have been presented in Ref. [17][18][19] in detail; and will not be repeated here. High quality hexahedral grids have been employed in the computations.…”

Section: The Computational Modelmentioning

confidence: 99%

Inception of Casing Wall Flow Instabilities and Downstream Flow Evolution in Subsonic Axial Compressor Rotors At High Rotor Stagger Angles

Ramakrishna,

Govardhan

2023

joast

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Two critical aspects of the casing wall flow structure in a subsonic axial flow compressor are studied in this paper: flow mechanism leading to stalling at different stagger angle configurations; and the effect of tip leakage flows on these flow phenomena. In some of the previous works, casing wall flow instabilities similar to the ones discussed in the present paper were reported, typically for high stagger angle rotor designs. However under what conditions flow tends to take such shapes were not discussed in detail. This work attempts to address this through a detailed numerical study on unswept and forward swept rotors, for different stagger angle settings, and for varied levels of rotor tip gaps. Three candidate rotors (unswept, 20° true swept, 20° axially swept) are studied with three tip clearances (0.0%, 0.7%, and 2.7% of the blade chord) for three stagger angle changes (0°, +3° and +5°). Stagger angle is found to have significant effect on suction surface flow separations. Tip clearance is observed to be critical on the inception of casing wall flow instabilities, especially at higher stagger angles. Hub endwall flow structure and the downstream flow evolution are also discussed in the paper.

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Aerodynamic Performance of Low Speed Axial Flow Compressor Rotors with Sweep and Tip Clearance

Cited by 7 publications

References 8 publications

Experimental and Numerical Investigation of a Compressor Cascade at Highly Negative Incidence

Experimental and Numerical Investigation of a Compressor Cascade at Highly Negative Incidence

On loading corrections and loss distributions in low-speed forward swept axial compressor rotors

Inception of Casing Wall Flow Instabilities and Downstream Flow Evolution in Subsonic Axial Compressor Rotors At High Rotor Stagger Angles

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