在涡轮叶片内部前缘腔体内诱发大规模涡流的独特冷却剂供应通道安排

Energies Pub Date : 2024-07-11 DOI:10.3390/en17143404
Yang Cai, Xinzi Liu, Yu Sun, Xiaojun Fan, Jiao Wang
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引用次数: 0

摘要

燃气轮机广泛应用于多个领域,而叶片冷却是提高燃气轮机功率和效率的关键途径。为了探索一种高效的冷却方法,本文提出并探讨了一种具有独特冷却剂供应通道布置的新型变型配置。经过网格独立性计算和湍流模型验证后,采用数值模拟方法求解纳维-斯托克斯方程。结果表明,变体结构具有更好的流线分布,内腔和外腔都有双涡流。与原始结构相比,外腔的传热强度得到改善,全局平均努塞尔特数增加了 17.1%。均匀分布喷嘴的情况具有最佳的流动和传热性能。随着喷嘴数量的增加,总压力损失和摩擦系数减小,但传热先增加后减小。三个喷嘴的综合冷却性能最好。纵横比对双涡流冷却结构有重要影响。纵横比小的情况下,局部传热强度较高,但流动损失较大。纵横比为 4 的情况冷却效果最好。
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Unique Coolant Supply Passage Arrangements to Induce Large-Scale Vortex within Turbine Blade Interior Leading Edge Chambers
Gas turbines are widely applied in many fields, and blade cooling is a key way to improve gas turbines’ power and efficiency. In order to explore a high-efficiency cooling method, a new variant configuration with unique coolant supply passage arrangements is proposed and explored in this paper. The numerical simulation method of solving the Navier–Stokes equations is used after mesh independence calculation and turbulence model validation. The results show that the variant structure has better streamlines distribution with double vortex flows in both the inner and outer chambers. Compared to the original configuration, the heat transfer intensity in the outer chamber is improved, and the globally averaged Nusselt number is 17.1% larger. The case with uniformly distributed nozzles has the best flow and heat transfer performance. As the nozzle number increases, the total pressure loss and friction coefficient decrease, but the heat transfer increases first and then decreases. The case of three nozzles has the best comprehensive cooling behavior. The aspect ratio has important influences on the double-vortex cooling configuration. Cases with small aspect ratios have higher local heat transfer intensity, but the flow loss is larger. The case with aspect ratio 4 has the best cooling performance.
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