Unsteady Phenomena at the Combustor-Turbine Interface

IF 1.1 Q4 ENGINEERING, MECHANICAL Journal of the Global Power and Propulsion Society Pub Date : 2020-09-09 DOI:10.33737/gpps20-tc-150
Faisal Shaikh, B. Rosic
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引用次数: 1

Abstract

The combustor-turbine interface in a gas turbine is characterised by complex, highly unsteady flows. In a combined experimental and large eddy simulation (LES) study including realistic combustor geometry, the standard model of secondary flows in the nozzle guide vanes (NGV) is found to be oversimplified. A swirl core is created in the combustion chamber which convects into the first vane passages. Four main consequences of this are identified: variation in vane loading; unsteady heat transfer on vane surfaces; unsteadiness at the leading edge horseshoe vortex, and variation in the position of the passage vortex. These phenomena occur at relatively low frequencies, from 50–300 Hz. It seems likely that these unsteady phenomena result in non-optimal film cooling, and that by reducing unsteadiness designs with greater cooling efficiency could be achieved. Measurements were performed in a high speed test facility modelling a large industrial gas turbine with can combustors, including nozzle guide vanes and combustion chambers. Vane surfaces and endwalls of a nozzle guide vane were instrumented with 384 high speed thin film heat flux gauges, to measure unsteady heat transfer. The high resolution of measurements was such to allow direct visualisation in time of large scale turbulent structures over the endwalls and vane surfaces. A matching LES simulation was carried out in a domain matching experimental conditions including upstream swirl generators and transition duct. Data reduction allowed time-varying LES data to be recorded for several cycles of the unsteady phenomena observed. The combination of LES and experimental data allows physical explanation and visualisation of flow events.
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燃烧室-涡轮界面的非定常现象
燃气轮机的燃烧室-涡轮界面具有复杂、高度非定常流动的特点。在结合实验和大涡模拟(LES)的实验研究中,考虑了真实燃烧室的几何结构,发现标准的导叶二次流模型过于简化。在燃烧室中形成一个涡流芯,它对流进入第一叶片通道。确定了四个主要后果:叶片载荷的变化;叶片表面非定常传热;前缘马蹄形涡的非定常和通道涡位置的变化。这些现象发生在相对较低的频率,从50-300赫兹。这些非定常现象似乎可能导致非最佳气膜冷却,通过减少非定常设计可以实现更高的冷却效率。测量是在一个高速测试设备上进行的,该设备模拟了一个大型工业燃气轮机,该燃气轮机带有can燃烧室,包括喷嘴导叶和燃烧室。采用384片高速薄膜热流计测量喷嘴导叶叶片表面和端壁的非定常传热。测量的高分辨率是这样的,允许在时间上直接可视化在端壁和叶片表面上的大规模湍流结构。在包含上游涡流发生器和过渡管道的区域匹配实验条件下进行了匹配LES仿真。数据的简化使得随时间变化的LES数据可以被记录为观测到的不稳定现象的几个周期。LES和实验数据的结合允许对流动事件进行物理解释和可视化。
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来源期刊
Journal of the Global Power and Propulsion Society
Journal of the Global Power and Propulsion Society Engineering-Industrial and Manufacturing Engineering
CiteScore
2.10
自引率
0.00%
发文量
21
审稿时长
8 weeks
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