Abstract
In order to improve efficiency in turbomachinery, brush seal replaces labyrinth seals widely in the secondary air system. A 2-d staggered tube bank model is adopted to simulate the gas states and the pressure character in brush seal, and computational fluid dynamics (CFD) is used to solve the model in this paper. According to the simulation results, the corrected formula of the Euler number and dimensionless pressure are given. The results show that gas expands when flow through the bristle pack, and the gas expansion closes to an isotherm process. The dynamic pressure increases with decreasing static pressure. The Euler number can reflect the seal performance of brush seals in leakage characteristics. Compared with increasing the number of rows, the reduction of the gap is a higher-efficiency method to increase the Euler number. The Euler number continually increases as the gap decreases. However, with the differential pressure increasing, Euler number first increases and then decreases as the number of rows increases. Finally, the pressure distribution on the surface of end rows is asymmetric, and it may increase the friction between the bristles and the back plate.
Highlights
The brush seal has been widely used in aero-engines and turbomachines in recent years because of its excellent sealing performance
The brush seal can be combined with the labyrinth seal to improve seal performance, which results in 50% improvement of seal performance compared with the straight type of the labyrinth seal [2]
X−Xu XP−d−PXd u Pu − Pd where Xu is the coordinates of the upstream boundary, Xd is the coordinates of the downstream boundary, Pd is the pressure of the bristle pack downstream, Pu is the pressure of the bristle pack upstream, and ∆P is the pressure difference between upstream and downstream
Summary
The brush seal has been widely used in aero-engines and turbomachines in recent years because of its excellent sealing performance. Compared with the labyrinth seal, the brush seal can reduce leakage by 70% [1]. The brush seal can be combined with the labyrinth seal to improve seal performance, which results in 50% improvement of seal performance compared with the straight type of the labyrinth seal [2]. The experiment is one important way to study brush seals. With the fast development of computer technology, computational fluid dynamics (CFD) has been widely used in the analysis of seal performance. Li [5] investigated the leakage flow characteristics of labyrinth brush seal with CFD software. Lee [6] evaluated the impact of the position of brush seal on the rotor dynamic coefficients with numerical simulation
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