内冷式涡轮叶片蠕变损伤时空演变的多学科预测

Qingfu He, Zhongran Chi, S. Zang
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摘要

蠕变是造成燃气轮机喷嘴导叶(NGV)损坏的主要原因之一,它威胁着燃气轮机的安全性和可靠性。尽管蠕变寿命预测已应用于设计和维护,但蠕变损伤仍经常出现。由于对蠕变损伤的时空演变缺乏足够了解,因此很难评估和准确保护 NGV 免受异常蠕变损伤。本文提出了一种基于共轭传热计算流体动力学 (CFD) 和有限元法 (FEM) 的空热结构综合模拟方法,用于预测带有内部冷却结构的 NGV 中蠕变损伤的时空演变。在时间维度上,蠕变寿命由 Larson-Miller 参数计算得出。在空间维度上,蠕变损伤是通过参数建模和 CHT 网格生成程序表征的。预测结果表明,蠕变损伤会在应力集中的吸气侧前缘沿跨度形成沟槽或裂缝,这与实际 NGV 上经常观察到的损伤相似。讨论了蠕变损伤、流动和传热之间的相互作用。涡轮机入口温度的升高大大缩短了蠕变形成和演变所需的时间。研究表明,通过 NGV 壁的蠕变损伤可从根本上改变传热和流动,导致前缘平均温度上升 30K。因此,蠕变损伤的演变会自我加速。
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Multidisciplinary Prediction of Spatial-Temporal Evolution of Creep Damage on an Internally Cooled Turbine Vane
One of the main causes of damage to gas turbine nozzle guide vanes (NGVs) is creep, which threatens the safety and reliability of gas turbines. Although creep life prediction has been applied to design and maintenance, creep damage is still frequently observed. Inadequate knowledge of the spatial-temporal evolution of creep damage makes it difficult to evaluate and accurately protect NGVs against abnormal creep damage. An integrated aero-thermal-structural simulation method based on conjugate heat transfer (CHT) computational fluid dynamics (CFD) and finite element method (FEM) is proposed to predict the spatial-temporal evolution of creep damage in the NGVs with internal cooling structures. In the temporal dimension, creep life is calculated by Larson-Miller parameters. In the spatial dimension, creep damage is characterized by a parametric modeling and CHT mesh generation procedure. The predicted results show that creep damage forms a groove or crack along the span at the leading edge of the suction side where the stress concentrates, which is similar to the frequently observed damage on the actual NGVs. The interactions between creep damage, flow, and heat transfer are discussed. The increase in turbine inlet temperature significantly shortens the time required for creep formation and evolution. It is suggested that creep damage through the NGV wall could radically alter the heat transfer and flow, resulting in a 30K increase in average leading edge temperature. As a result, the evolution of creep damage is self-promotingly accelerated.
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