Quantifying the impact of heat in support seal configuration for aero engines

P. Sun, C. Liu
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Abstract

Leakage, deformations, power loss, heat generation in the support seal system and other issues are typical when support seals are developed. The design of the support seal system has progressively evolved over recent decades as part of an ongoing effort to provide effective cooling for the aero engine secondary air system. In particular, oil heat management in the oil chamber has strict requirements, which limit the heat generation of the support seal system. The potential of supporting seal research with an oil system is investigated in this work. The combination of the CFD/FEA method and quantifying the heat generation entering the oil chamber allows for improvements not just to the individual buffer air seal unit, but the oil seal together. The analysis relies on the combination of quantifying heat generation entering the oil chamber to provide a mutual influence of neighbouring labyrinth seals. The mutual influence requires further analysis, considering the thermal deformation of the rotor/stator to provide further accurate geometry parameters in preliminary seal designs. The experimental test was conducted to verify the preliminary CFD-FEA loosely coupled analysis result, which reveals that in a turbine support seal system, the radius of the buffer air seal has a significant influence on the leakage flow rate and power loss of the oil seal, which should take into account the integral influence of the pressure difference of the oil seal caused by the radius change of the buffer air seal and the running clearance of the oil seal.
航空发动机支撑密封结构中热量影响的量化
支撑密封系统的泄漏、变形、功率损失、发热等问题是开发支撑密封时的典型问题。近几十年来,作为为航空发动机二次空气系统提供有效冷却的持续努力的一部分,支撑密封系统的设计已经逐步发展。特别是油腔内的油热管理有严格的要求,这限制了支撑密封系统的热量产生。在这项工作中,研究了油系统支持密封研究的潜力。CFD/FEA方法与量化进入油室的热量产生相结合,不仅可以改进单个缓冲空气密封单元,还可以改进整个油封。分析依赖于量化进入油室的热量产生,以提供邻近迷宫密封的相互影响。相互影响需要进一步分析,考虑转子/定子的热变形,以便在初步密封设计中提供进一步准确的几何参数。通过试验验证了初步的CFD-FEA松耦合分析结果,表明在涡轮支撑密封系统中,缓冲气封半径对油封泄漏流量和功率损失有显著影响,应综合考虑缓冲气封半径变化引起的油封压差和油封运行间隙的综合影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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