Flow Resistance Coefficients of Porous Brush Seal as a Function of Pressure Load

Doğu, Yahya; Sertçakan, Mustafa C.; Gezer, Koray; Kocagül, Mustafa

doi:10.1115/1.4038994

Cited by 7 publications

(1 citation statement)

References 18 publications

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“…Further analysis of brush seal behaviour using porous medium models was carried out in studies by Doğu et al [22] [15] [23]. The complexity of the calculations heightened through the subsequent studies, with rotational motion accounted for and resistance coefficients calibrated as a function of applied pressure load in the most recent works.…”

Section: Porous Medium Modelling Of Brush Sealsmentioning

confidence: 99%

Fluid Dynamic Behavior of Conventional and Pressure Relieving Brush Seals

Bowen,

Bird,

Cross

et al. 2023

Journal of Engineering for Gas Turbines and Power

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Brush seals consist of a static ring of densely packed, flexible, fine wire bristles that provide resistance to the flow. Pressure relieving brush seals can be employed to overcome issues such as hysteresis that affect seal durability by reducing friction between the bristle pack and back plate surface. The impact of such designs on the fluid dynamic behaviour of brush seals was studied following a concomitant methodology that exploited the benefits of both engine representative and large-scale testing facilities. Leakage data were fitted using a porous medium model found in the literature to quantify viscous and inertial resistance coefficients. Shaft rotation was shown to cause a reduction in seal leakage and an increase in static pressure on the back plate surface. The pressure relieving back plates also resulted in increased static pressures at this location, causing a reduction in flow resistance that increased leakage through the porous bristle pack. Interrogation of the large-scale inter-bristle pressure field for the two back plate designs revealed the distributions of axial pressure diverged towards the rear of the bristle pack. The detail gathered using the large-scale study has been shown to be representative, hence the insight is generically applicable to brush seals.

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Section: Porous Medium Modelling Of Brush Sealsmentioning

confidence: 99%

Fluid Dynamic Behavior of Conventional and Pressure Relieving Brush Seals

Bowen,

Bird,

Cross

et al. 2023

Journal of Engineering for Gas Turbines and Power

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A Three-Dimensional Tube Bundle Model Analysis for Leakage Flow Characteristics of Variable Bristle Diameter Brush Seals With Bristle Pack Stratification

2021

Journal of Engineering for Gas Turbines and Power

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The leakage flow characteristics of the Variable Bristle Diameter (VBD) brush seals is numerically investigated using 3D tube bundle model considering bristle pack stratification. The discretization of the computational domain applies the multi-block structured mesh, which confirms that there is no need to set interfaces between the fluid domains of the bristle pack and cavities to eliminate interpolation errors. The bristle pack stratification is achieved using mesh motion technique. The effects of pressure ratio, axial rows of bristles, sealing clearance, bristle pack arrangements and bristles gapping on the leakage flow characteristics and aerodynamic forces of the brush seals are conducted. The recorded leakage flow of the 3D tube bundle model is multiplied by circumferential loop number to determine total leakage flow rate of the brush seal. The numerical results agreed well with the experimental data, which verifies the reliability of the numerical method. The numerical results indicate that the leakage flow rate increases linearly with the pressure ratio. The increase of bristle numbers has a distinct different effect on the relative rate of leakage flow for contacting and clearance brush seals. The use of large diameter bristle weakens the sealing performance of the brush seal, which is more pronounced when using large diameter bristles in the rear region. Bristle pack stratification could improve sealing performance of brush seals. The large diameter bristles increase the porosity and reduce the flow resistance coefficients. While, the bristle pack stratification decreases the porosity and rises the flow resistance coefficients in the rear region.

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Numerical Investigations on the Leakage Flow Characteristics of Brush Seal Based on the Three-Dimensional Staggered Tube Bundle Model

Zhang

et al. 2021

Journal of Engineering for Gas Turbines and Power

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To accurately predict the leakage flow and resistance characteristics of brush seals, the multi-block structured mesh and the mesh motion technique are applied to the three-dimensional (3D) staggered tube bundle model of brush seals. The multi-block structured mesh can easily add nodes and set boundary layers in the inter-bristle gap between adjacent bristles, which can ensure good mesh quality . The mesh motion technique realizes the overall axial compactness of the bristle pack. The effects of pressure ratio , sealing clearance c and bristle pack compactness on the leakage flow and resistance characteristics are investigated. To analyze the aerodynamic resistance of the brush seals, Euler number (Eu) is applied in the present study. The numerical results are in good agreement with the experimental data. Thus the accuracy of the presented numerical method is validated. For the contacting brush seal, ?"?S" ?_"x,i" has a significant effect on the leakage flow rate reduction. For the clearance brush seal, ?"?S" ?_"x,i" has little effect on the leakage flow rate reduction. The leakage flow passing through the sealing clearance keeps almost constant. As for aerodynamic resistance, the presence of the sealing clearance can effectively convert the pressure energy of the leakage flow into the kinetic energy. As a result, the leakage flow velocity exiting the bristle pack of the clearance brush seal is 1.5 to 2.0 times larger than that of the contacting brush seal.

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Flow Resistance Coefficients of Porous Brush Seal as a Function of Pressure Load

Cited by 7 publications

References 18 publications

Fluid Dynamic Behavior of Conventional and Pressure Relieving Brush Seals

Fluid Dynamic Behavior of Conventional and Pressure Relieving Brush Seals

A Three-Dimensional Tube Bundle Model Analysis for Leakage Flow Characteristics of Variable Bristle Diameter Brush Seals With Bristle Pack Stratification

Numerical Investigations on the Leakage Flow Characteristics of Brush Seal Based on the Three-Dimensional Staggered Tube Bundle Model

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