Cavity Flow Modeling in an Industrial Centrifugal Compressor Stage at Design and Off-Design Conditions

Guidotti, Emanuele; Naldi, Giovanni; Tapinassi, Libero; Chockalingam, Valliappan

doi:10.1115/gt2012-68288

Cited by 5 publications

(2 citation statements)

References 16 publications

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“…The suction mode was beneficial to the mainstream flow, while the injection mode was harmful. Guidotti et al 20 numerically and experimentally investigated the effects of the cavity flow on the compressor performance. It was found that the three-dimensional numerical simulation including full cavity structure was excellent in predicting the overall performance and flow features details for the compressor.…”

Section: Introductionmentioning

confidence: 99%

Effect of the hub cavity leakage on the aerodynamic performance and strength characteristics of the 150 kW SCO₂ centrifugal compressor

Cao

Deng

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part A:

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The hub cavity leakage has large effect on the aerodynamic performance on the Supercritical carbon dioxide (SCO2) centrifugal compressor. In this paper, the aerodynamic performance and strength characteristics of the 150 kW SCO2 centrifugal compressor with the hub cavity were numerically investigated using three-dimensional Reynolds-Averaged Navier-Stokes (RANS) and [Formula: see text] turbulence model. The high precision physical properties tables of SCO2 were used to calculate the SCO2 property parameters across the centrifugal compressor flow passages. The aerodynamic performance of the 150 kW SCO2 centrifugal compressor without and with the hub cavity and the labyrinth seal at different mass flow coefficients was compared. The equivalent (von-Mises) stress and the deformation on the SCO2 centrifugal impeller were obtained by the combination of the aerodynamic pressure and centrifugal force calculation. The results show that the isentropic efficiency of the SCO2 centrifugal compressor without and with the hub cavity and the labyrinth seal at the designed flow coefficient equal 73.2% and 72.1% respectively. The effects of the hub cavity leakage on the pressure ratio of the SCO2 centrifugal compressor are limited. The hub cavity leakage decreases with the flow coefficient increasing. The similar isentropic efficiency of the SCO2 centrifugal compressor without and with the hub cavity and the labyrinth seal at the largest flow coefficient is obtained. The axial thrust of the SCO2 centrifugal compressor with the hub cavity and the labyrinth seal ranges from 1000N to 2000N at different flow coefficients, as well as keeps the same direction. The maximum equivalent (von-Mises) stress of the impeller is 109.95 MPa and less than the allowable stress 137 MPa (using 304 steel as the impeller material). The maximum deformation of the seal teeth is less than 0.003 mm. This work provides the reference of the compressor design and safety operation for the SCO2 centrifugal compressor.

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Section: Introductionmentioning

confidence: 99%

Effect of the hub cavity leakage on the aerodynamic performance and strength characteristics of the 150 kW SCO₂ centrifugal compressor

Cao

Deng

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part A:

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show abstract

“…Literature shows that the inclusion of rotor-stator cavities is crucial to the correct reproduction of stage characteristics: (Hu et al, 2017) and (Sun et al, 2009), amongst others, research centripetal flow through rotor-stator cavities and show how axial thrust and disk torque are affected. (Guidotti et al, 2012) show the influence of cavity modelling on the efficiency and pressure ratio. (Mischo et al, 2009) find that the shroud cavity leakage can induce flow separation and thereby severely influence compressor performance.…”

Section: Introductionmentioning

confidence: 99%

Conjugate Heat Transfer Study of a Centrifugal Compressor with Impeller Cavities

Stahl¹,

Franz²,

Ittern³

2019

GPPS Zurich19

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In this study the effects of heat transfer on the rotorstator cavity temperatures and the characteristics of one industrial, single stage centrifugal compressor are examined. A baseline Computational Fluid Dynamics (CFD) analysis of the fluid with adiabatic (AD) boundary conditions is conducted. The relevant solid bodies are added to the model and a Conjugate Heat Transfer (CHT) calculation of the machine is performed. The two models are compared and validated by experimental data. Most research regarding heat transfer in centrifugal compressors focusses on turbocharger or gas turbine applications, where a significant heat flux from the adjacent turbine is expected. Industrial compressors are often treated as adiabatic. Some publications include the solid body of the impeller in the calculation, but cavities are often not in the focus of the study. Efforts to obtain reliable Heat Transfer Coefficients (HTC) by employing simple correlations for the impeller flow in the presence of a shroud cavity leakage have not yet proven to be successful. When comparing the CHT and the adiabatic model, differences can be observed in wall-and cavity flow temperatures. The adiabatic approach exceeds the measured cavity temperatures by 40%, whereas the CHT calculation yields significantly better results and stays within a margin of error of 1-4%. Additionally, the qualitative temperature distribution and calculated frictional power loss of both models differ noticeably. The bulk flow seems nearly unchanged and the adiabatic approach proves to be sufficient to describe overall compressor performance. Differences in efficiency, total pressure ratio and total temperature ratio between the two models are negligible. For machines engineered to maximum mechanical loads, with tight restrictions in fluid temperature, or if thermal expansion of the components is critical (e.g. tight sealing clearances), a CHT simulation is recommended for more accurate temperature predictions.

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On the Influence of a Hubside Exducer Cavity and Bleed Air in a Close-Coupled Centrifugal Compressor Stage

Kaluza

Landgraf

Schwarz

et al. 2017

Journal of Turbomachinery

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In aero-engine applications, centrifugal compressors are often close-coupled with their respective diffusers to increase efficiency at the expense of a reduced operating range. The aim of this paper is to show that state-of-the art steady-state computational fluid dynamics (CFD) simulations can model a hubside cavity between an impeller and a close-coupled diffuser and to enhance the understanding of how the cavity affects performance. The investigated cavity is located at the impeller trailing edge, and bleed air is extracted through it. Due to geometrical limitations, the mixing plane is located in the cavity region. Therefore, the previous analyses used only a cut (“simple”) model of the cavity. With the new, “full” cavity model, the region inside the cavity right after the impeller trailing edge is not neglected anymore. The numerical setup is validated using the experimental data gathered on a state-of-the art centrifugal compressor test-rig. For the total pressure field in front of the diffuser throat, a clear improvement is achieved. The results presented reveal a drop in stage efficiency by 0.5%-points caused by a new loss mechanism at the impeller trailing edge. On the hubside, the fundamentally different interaction of the cavity with the coreflow increases the losses in the downstream components resulting in the mentioned stage efficiency drop. Finally, varying bleed air extraction is investigated with both cavity models. Only the full cavity (FC) model captures the changes measured in the experiment.

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Cavity Flow Modeling in an Industrial Centrifugal Compressor Stage at Design and Off-Design Conditions

Cited by 5 publications

References 16 publications

Effect of the hub cavity leakage on the aerodynamic performance and strength characteristics of the 150 kW SCO₂ centrifugal compressor

Effect of the hub cavity leakage on the aerodynamic performance and strength characteristics of the 150 kW SCO₂ centrifugal compressor

Conjugate Heat Transfer Study of a Centrifugal Compressor with Impeller Cavities

On the Influence of a Hubside Exducer Cavity and Bleed Air in a Close-Coupled Centrifugal Compressor Stage

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Cavity Flow Modeling in an Industrial Centrifugal Compressor Stage at Design and Off-Design Conditions

Cited by 5 publications

References 16 publications

Effect of the hub cavity leakage on the aerodynamic performance and strength characteristics of the 150 kW SCO2 centrifugal compressor

Effect of the hub cavity leakage on the aerodynamic performance and strength characteristics of the 150 kW SCO2 centrifugal compressor

Conjugate Heat Transfer Study of a Centrifugal Compressor with Impeller Cavities

On the Influence of a Hubside Exducer Cavity and Bleed Air in a Close-Coupled Centrifugal Compressor Stage

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Effect of the hub cavity leakage on the aerodynamic performance and strength characteristics of the 150 kW SCO₂ centrifugal compressor

Effect of the hub cavity leakage on the aerodynamic performance and strength characteristics of the 150 kW SCO₂ centrifugal compressor