Coupled effects of typical thermodynamic parameters on the flow and heat transfer in a high-pressure turbine outer ring with impingement-film composite cooling structure

IF 4.9 2区工程技术 Q1 ENGINEERING, MECHANICAL International Journal of Thermal Sciences Pub Date : 2024-07-02 DOI:10.1016/j.ijthermalsci.2024.109243

Longfei Wang, Chengliang Lv, Junkui Mao, Ziqiang Li, Dewei Zhang, Shuai Bi

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Abstract

The research focused on a high-pressure turbine outer ring with an impingement-film composite cooling structure. Two methods of experimental measurements and numerical calculations were employed to investigate the outer ring cooling performance under typical thermodynamic parameters, such as the blowing ratio (M), temperature ratio (τ), and Mach number (Ma). The study aimed to elucidate the coupling effects between different thermodynamic parameters. It is revealed that increasing M led to improved cooling performance as it increased the cooling air flow rate and film hole outlet momentum. However, increasing Ma resulted in a less effective coverage of cooling air film on the outer ring, resulting in reduced cooling performance. Elevating the τ lowered the temperature of cooling air and outer ring but decreased the efficiency of cooling air utilization, leading to poorer cooling performance. The influence of M on the outer ring cooling property was independent of the τ, but M affected the magnitude of the change in cooling characteristics at different τ. A lower M enhanced τ effect on the cooling performance, while a higher M had the opposite effect. Increasing τ effectively mitigated the Ma impact on the outer ring cooling performance, especially at lower τ. Ma altered τ influence trend on the cooling performance. When 0.2 ≤ Ma < 0.6, increasing τ led to a decrease in cooling performance, but the extent of this decline decreased. When 0.6 < Ma ≤ 0.8, increasing τ resulted in an increase in cooling performance, but the improvement rate was moderated. Elevating the Ma enhanced M effect on the outer ring cooling performance. Specifically, when Ma is 0.2, increasing M from 0.7 to 3.0 elevates the outer ring overall cooling effectiveness from 0.3 to 0.45, reflecting a change of approximately 50 %. Similarly, when Ma is 0.8, an increase in M from 0.7 to 3.0 raises the overall cooling effectiveness from 0.1 to 0.35, indicating a more significant change of around 250 %.

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典型热力学参数对采用撞击膜复合冷却结构的高压涡轮外环中的流动和传热的耦合效应

研究的重点是采用撞击膜复合冷却结构的高压涡轮外环。采用实验测量和数值计算两种方法，研究了吹气比（M）、温度比（τ）和马赫数（Ma）等典型热力学参数下的外环冷却性能。研究旨在阐明不同热力学参数之间的耦合效应。结果表明，增加 M 会提高冷却空气流速和膜孔出口动量，从而改善冷却性能。然而，Ma 的增大导致冷却空气膜在外环上的有效覆盖率降低，从而降低了冷却性能。提高 τ 降低了冷却空气和外环的温度，但降低了冷却空气的利用效率，导致冷却性能降低。M 对外环冷却性能的影响与 τ 无关，但 M 会影响不同 τ 下冷却特性的变化幅度。增大 τ 能有效缓解 Ma 对外环冷却性能的影响，尤其是在较低τ 时。当 0.2 ≤ Ma < 0.6 时，τ 的增加会导致冷却性能下降，但下降的程度会减小。当 0.6 < Ma ≤ 0.8 时，τ 的增加会导致冷却性能的提高，但提高的幅度有限。提高 Ma 值增强了 M 对外环冷却性能的影响。具体来说，当 Ma 为 0.2 时，M 从 0.7 增加到 3.0 会使外环的整体冷却效果从 0.3 提高到 0.45，变化幅度约为 50%。同样，当 Ma 值为 0.8 时，M 值从 0.7 增加到 3.0，整体冷却效果从 0.1 提高到 0.35，表明变化更为显著，约为 250%。

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来源期刊

International Journal of Thermal Sciences 工程技术-工程：机械

CiteScore

8.10

自引率

11.10%

发文量

531

审稿时长

55 days

期刊介绍： The International Journal of Thermal Sciences is a journal devoted to the publication of fundamental studies on the physics of transfer processes in general, with an emphasis on thermal aspects and also applied research on various processes, energy systems and the environment. Articles are published in English and French, and are subject to peer review. The fundamental subjects considered within the scope of the journal are: * Heat and relevant mass transfer at all scales (nano, micro and macro) and in all types of material (heterogeneous, composites, biological,...) and fluid flow * Forced, natural or mixed convection in reactive or non-reactive media * Single or multi–phase fluid flow with or without phase change * Near–and far–field radiative heat transfer * Combined modes of heat transfer in complex systems (for example, plasmas, biological, geological,...) * Multiscale modelling The applied research topics include: * Heat exchangers, heat pipes, cooling processes * Transport phenomena taking place in industrial processes (chemical, food and agricultural, metallurgical, space and aeronautical, automobile industries) * Nano–and micro–technology for energy, space, biosystems and devices * Heat transport analysis in advanced systems * Impact of energy–related processes on environment, and emerging energy systems The study of thermophysical properties of materials and fluids, thermal measurement techniques, inverse methods, and the developments of experimental methods are within the scope of the International Journal of Thermal Sciences which also covers the modelling, and numerical methods applied to thermal transfer.