利用射流冲击冷却通道优化涡轮叶片冷却

IF 1.1 Q3 TRANSPORTATION SCIENCE & TECHNOLOGY
Adham Ahmed Awad Elsayed Elmenshawy, Iyad Alomar, A. Arshad
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引用次数: 0

摘要

摘要应用射流冲击法对涡轮叶片冷却通道进行优化。本文选取了NASA 3CX涡轮叶片的实验数据,并利用solidworks软件建立了3D模型,并创建了计算流体动力学(CFD)模拟,用于模拟叶片中冷却剂的流动和温度分布,同时进行实验测试,可以验证CFD结果,并为冷却系统的性能提供额外的见解。采用ANSYS FLUENT代码作为CFD求解器,采用ANSYS ICEM-CFD进行网格生成。利用MATLAB代码对实验数据进行计算,有助于仿真。传热耦合分析基于海温剪切应力分析K-ω湍流模型。结果得出结论,提供了关于冷却通道的额外信息,以及它们在比较研究中的不同之处。结果表明:随着冷却通道向叶片尾缘的拉近,冷却通道的水力直径显著减小(最大可达49.70% ~ 69.55%);这可能会对传热系数和冷却系统的性能产生重大影响。观察到涡轮叶片的压力侧遵循Hylton模型,而目前的研究预测涡轮叶片头部周围和吸力侧的大部分传热系数过高。两种模型的平均换热系数相差23.36%。结果表明,优化后的射流冲击模型对整个叶片的冷却效率为0.4892,与优化后的射流冲击模型的冷却效率为0.6936进行了对比,对比结果表明,优化后的射流冲击模型具有明显更高的冷却效率。整个叶片的冷却效率提高了29.46%,尾缘的冷却效率提高了28.823%,表明优化后的射流冲击设计提高了冷却性能。这些结果突出了考虑涡轮叶片优化冷却设计以保持高效和安全运行的重要性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optimization Turbine Blade Cooling by Applying Jet Impingement Cooling Channels
Abstract The aim of this paper is to optimize turbine blade cooling channels by applying jet impingement Method. The selection of experiment data for NASA 3CX turbine blade, and 3D model using solidworks software and create computational fluid dynamics (CFD) simulations used to model the coolant flow and temperature distribution in the vane, while experimental testing can validate the CFD results and provide additional insights into the cooling system's performance., ANSYS FLUENT code was used as a CFD solver, and ANSYS ICEM-CFD was used for mesh generation. MATLAB code is used for calculation using experiment data and this was helpful for simulations. Heat transfer conjugation analysis bases SST shear stress analyses K-ω turbulent model. The results conclude that providing additional information about the cooling channels and how they differ in the studies being compared. The results demonstrate that the cooling channels' hydraulic diameter decreases by a significant percentage (up to 49.70%–69.55%) as they are drawn to the trailing edge of the blade. This can have a significant impact on the heat transfer coefficients and the performance of the cooling system. The pressure side of the turbine blade is observed to follow the Hylton Model, while the current study predicts a large over-anticipated heat transfer coefficient around the Turbine blade head and on the bulk of the suction side. In terms of average heat transfer coefficient, the two models differ by 23.36%. The authors found that the cooling effectiveness for the Optimized jet impingement model is 0.4892 for whole blade and compared it with the cooling effectiveness for the optimized jet impingement model, which is 0.6936, The results of the comparison between the base model and the optimized jet impingement model suggest that the optimized model has a significantly higher cooling effectiveness. The increase in cooling effectiveness of 29.46% for the whole blade and 28.823% for the trailing edge indicates that the optimized jet impingement design provides improved cooling performance. These results highlight the importance of considering optimized cooling designs for turbine blades to maintain efficient and safe operation.
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来源期刊
Transport and Telecommunication Journal
Transport and Telecommunication Journal TRANSPORTATION SCIENCE & TECHNOLOGY-
CiteScore
3.00
自引率
0.00%
发文量
21
审稿时长
35 weeks
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