Abstract
To achieve higher aerodynamic performance, turbine usually works at tight clearance, which results in inevitable rub between the rotor and stator parts of labyrinth seal due to vibrations, misalignment, mechanical force, thermal stress, etc. In the rubbing events, contact between labyrinth fin and rotor part will commonly induce the teeth bending and mushrooming damages, which significantly affect the discharge performance of a labyrinth seal. To account for the influence of teeth bending and mushrooming on leakage performance of a straight-through labyrinth seal, the leakage rates and flow fields in the worn labyrinth seal are measured and also compared with the original design cases. With numerical methods, the discharge behaviors of the labyrinth seal with different degrees of bending and mushroom damages are analyzed. It shows that the predicted leakage performance and flow fields in the labyrinth seals match well with the experimental tests. For the bending cases, the leakage rates and flow patterns in labyrinth seals are dependent on the effective clearance and bending angle. The leakage ratio of forward bending case is smaller than that of backward bending case with the same geometrical dimensions. However, for the mushroomed labyrinth seals, the leakage rates and flow patterns are much dependent on the effective clearance but slightly dependent on the mushroom radius.
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Recommended by Associate Editor Hyoung-Bum Kim
Xin Yan is a Professor at Institute of Turbomachinery, Xi’an Jiaotong University. His main research interest has been in Computational Fluid Dynamics with emphasis in turbomachinery aerodynamics and heat transfer. He is also involved in experimental work to understand complex flow physics.
Xinbo Dai is a Ph.D. candidate at Institute of Turbomachinery, Xi’an Jiaotong University, China. His research interests include advanced sealing technology and thermal-fluid-solid interactions.
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Yan, X., Dai, X., Zhang, K. et al. Effect of teeth bending and mushrooming damages on leakage performance of a labyrinth seal. J Mech Sci Technol 32, 4697–4709 (2018). https://doi.org/10.1007/s12206-018-0917-y
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DOI: https://doi.org/10.1007/s12206-018-0917-y