Three-dimensional asymptotic suction of compressible flow

Regenerative flow compressors (RFCs) are rotodynamic machines capable of producing high heads at very low flowrates. They have very low specific speed and share some of the characteristics of positive displacement machines such as a roots blower, but without the problems of lubrication and wear. They can produce heads equivalent to that of several centrifugal stages from a single rotor with comparable tip speed. The compression process is usually not regarded as efficient. Typically they produce efficiency of less than 50 per cent but still they have found many applications because they allow the use of fluid dynamic compressors in place of positive displacement compressors for duties requiring high heads at low flowrates. There are very few mathematical models in the literature that explain the behaviour of regenerative turbomachines and predict the performance. Most of these models assumed incompressible flow, thus limiting their use to only pumps and blowers. Moreover, they needed extensive experimental support for performance prediction. Hence, it is very interesting from an industrial point of view to find efficient theoretical means that are able to forecast regenerative compressor performances, using easy to find geometric and fluid dynamic parameters. A compressible flow theory is thus presented for the first time in this paper to describe complex three-dimensional corkscrew flow patterns in regenerative compressors. Conventional RFC were designed with radial, non-radial or semicircular impeller blades. In the present investigation, the authors have discussed RFCs with aerofoil blades and an annular flow channel containing a core to direct circulating flow to the blades with a minimum amount of losses. The effects of various geometric elements on the performance of RFCs are studied. All the major sources of losses in blade and channel region are identified. Governing equations for the flow in the compressor are derived and a performance prediction code based on governing equations and loss models is developed. Theoretical performance results are compared with published test data on aerofoil blade RFCs. Based on sensitivity analysis from the code, design changes are suggested for performance improvement.

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Numerical stability in three-dimensional compressible flow calculations

International Journal of Heat and Fluid Flow ◽

10.1016/0142-727x(80)90017-x ◽

1980 ◽

Vol 2 (4) ◽

pp. 233-243 ◽

Cited By ~ 1

Author(s):

C. Bosman ◽

D. Ahrabian

Keyword(s):

Compressible Flow ◽

Numerical Stability ◽

Three Dimensional

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Method for the determination of the three dimensional aerodynamic field of a rotor-stator combination in compressible flow

10.2514/6.1987-1742 ◽

1987 ◽

Author(s):

SRIDHAR RAMACHANDRA ◽

LAWRENCE BOBER ◽

SURESH KHANDELWAL

Keyword(s):

Compressible Flow ◽

Three Dimensional ◽

Aerodynamic Field

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Three-dimensional instabilities in compressible flow over open cavities

Journal of Fluid Mechanics ◽

10.1017/s0022112007009925 ◽

2008 ◽

Vol 599 ◽

pp. 309-339 ◽

Cited By ~ 142

Author(s):

GUILLAUME A. BRÈS ◽

TIM COLONIUS

Keyword(s):

Compressible Flow ◽

Stokes Equations ◽

Three Dimensional ◽

Low Frequency ◽

Vortical Flow ◽

Cavity Flows ◽

Two Dimensional ◽

Mean Flow ◽

Aspect Ratios ◽

Open Cavities

Direct numerical simulations are performed to investigate the three-dimensional stability of compressible flow over open cavities. A linear stability analysis is conducted to search for three-dimensional global instabilities of the two-dimensional mean flow for cavities that are homogeneous in the spanwise direction. The presence of such instabilities is reported for a range of flow conditions and cavity aspect ratios. For cavities of aspect ratio (length to depth) of 2 and 4, the three-dimensional mode has a spanwise wavelength of approximately one cavity depth and oscillates with a frequency about one order of magnitude lower than two-dimensional Rossiter (flow/acoustics) instabilities. A steady mode of smaller spanwise wavelength is also identified for square cavities. The linear results indicate that the instability is hydrodynamic (rather than acoustic) in nature and arises from a generic centrifugal instability mechanism associated with the mean recirculating vortical flow in the downstream part of the cavity. These three-dimensional instabilities are related to centrifugal instabilities previously reported in flows over backward-facing steps, lid-driven cavity flows and Couette flows. Results from three-dimensional simulations of the nonlinear compressible Navier–Stokes equations are also reported. The formation of oscillating (and, in some cases, steady) spanwise structures is observed inside the cavity. The spanwise wavelength and oscillation frequency of these structures agree with the linear analysis predictions. When present, the shear-layer (Rossiter) oscillations experience a low-frequency modulation that arises from nonlinear interactions with the three-dimensional mode. The results are consistent with observations of low-frequency modulations and spanwise structures in previous experimental and numerical studies on open cavity flows.

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