Comprehensive evaluations of heat transfer performance with conjugate heat dissipation effect in high-speed rotating free-disk modeling of aero-engines

IF 6.2 3区 综合性期刊 Q1 Multidisciplinary
Aqiang Lin , Gaowen Liu , Ran Chang , Yan Chen , Qing Feng
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Abstract

Thermal boundary conditions of the turbine disk cavity system are of great importance in the design of secondary air systems in aero-engines. This study aims to investigate the complex heat transfer mechanisms of a rotating turbine disk under high-speed conditions. A high-speed rotating free-disk model with Dorfman empirical solutions is developed to evaluate the heat transfer performance considering various factors. Specifically, the influence of compressibility, variable properties, and heat dissipation is determined using theoretical and numerical analyses. In particular, a novel combined solution method is proposed to simplify the complex heat transfer problem. The results indicate that the heat transfer performance of a free disk is primarily influenced by the rotating Mach number, rotating Reynolds number, Rossby number, and wall temperature ratio. The heat transfer temperature and Nusselt number of the free disk are strongly correlated with the rotating Mach number and rotating Reynolds number. Analysis reveals that heat dissipation is a critical factor affecting the accurate evaluation of the heat transfer performance of the turbine disk. Thus, the combined solution method can serve as a reference for future investigations of flow and heat transfer in high-speed rotating turbine disk cavity systems in aero-engines.

Abstract Image

航空发动机高速旋转自由盘系统共轭散热传热性能综合评价
涡轮盘空腔系统的热边界条件对航空发动机二次空气系统的设计非常重要。本研究旨在研究高速条件下旋转涡轮盘的复杂传热机制。研究建立了一个高速旋转自由盘模型,该模型采用 Dorfman 经验解法,用于评估考虑了各种因素的传热性能。具体而言,通过理论和数值分析确定了可压缩性、可变特性和散热的影响。特别是提出了一种新颖的组合求解方法,以简化复杂的传热问题。结果表明,自由圆盘的传热性能主要受旋转马赫数、旋转雷诺数、罗斯比数和壁温比的影响。自由盘的传热温度和努塞尔特数与旋转马赫数和旋转雷诺数密切相关。分析表明,散热是影响涡轮盘传热性能准确评估的关键因素。因此,该组合求解方法可为今后研究航空发动机高速旋转涡轮盘空腔系统中的流动和传热提供参考。
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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来源期刊
Fundamental Research
Fundamental Research Multidisciplinary-Multidisciplinary
CiteScore
4.00
自引率
1.60%
发文量
294
审稿时长
79 days
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