Conjugate Heat Transfer Predictions of Gas Turbine Hot Walls Jets Cooling: Influence of Short Hole Grid Resolutions Using Computational Fluid Dynamics*

Abubakar M. El-Jummah, Shehu A. Abdulrahman, Alhaji S. Grema
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Abstract

Short hole investigations relevant to gas turbine (GT) hot walls cooling heat transfer techniques, were carried out using computational fluid dynamics (CFD) combined with conjugate heat transfer (CHT) code. The CFD software are commercial ones: ICEM for grid modelling and ANSYS Fluent for the numerical calculation, where symmetrical application prevails. The CFD CHT predictions were undertaken for Nimonic-75 metal walls with square (152.4 mm) arrays of 10 holes, whereby the lumped heat capacitance method was applied in order to determine the surface average heat transfer coefficient (HTC), h (W/m2 K) and the dimensionless Nusselt number, Nu. The major parameters considered for the short hole geometries are the pitch to diameter, X/D and length to diameter, L/D ratios and both were varied with range of D values, but X of 15.24 mm and L of 6.35 mm kept constant. Also applied, are variable mass flux, G (kg/s∙m2) and were used in predicting the flow aerodynamics in the short holes. The predictions were for classic thermal entry length into a round hole, as vena contracta, flow separation and reattachment dominates the holes, hence the development of thermal profile through the depth of the GT hot walls. Additionally, the acceleration of the flow along the wall surfaces as it approaches the holes, was a significant part of the overall heat transfer. This was shown to be independent of the hole length, even though the L/D parameter is a critical component to enhanced heat transfer. The CFD CHT predictions showed that validation of the HTC h, Nu and pressure loss, ∆P are in better agreement with measured data and within reasonable acceptance. The ∆P agreement signifies that the aerodynamics were predicted correctly, which is also the reason why the HTC expressed per wall hole approach surface area and Nu were better predicted. This illustrates how effective and efficient the wall internal heat transfer cooling is for gas turbine hot wall heat transfer using airflow jets cooling.
燃气轮机热壁射流冷却的共轭传热预测:使用计算流体动力学的短孔网格分辨率的影响*
采用计算流体力学(CFD)和共轭传热(CHT)程序对燃气轮机热壁冷却换热技术进行了短孔研究。CFD软件为商业软件:用于网格建模的ICEM和用于数值计算的ANSYS Fluent,其中以对称应用为主。对10孔方形(152.4 mm)排列的Nimonic-75金属壁进行CFD CHT预测,采用集总热容法确定表面平均换热系数(HTC) h (W/m2 K)和无因次努塞尔数Nu。考虑短孔几何形状的主要参数是节径比、X/D和长径比、L/D,两者随D值范围的变化而变化,但X值为15.24 mm, L值为6.35 mm不变。还应用了变质量通量G (kg/s∙m2),用于预测短孔内的流动空气动力学。预测的是典型的热进入圆孔的长度,因为孔洞主要是静脉收缩、流动分离和再附着,因此通过GT热壁深度的热剖面的发展。此外,流动在接近孔时沿壁面的加速度是整个传热的重要组成部分。结果表明,这与孔长无关,尽管L/D参数是增强传热的关键因素。CFD CHT预测表明,验证的HTC h、Nu和压力损失∆P与实测数据吻合较好,在合理的可接受范围内。∆P一致表明空气动力学预测正确,这也是表示每壁孔接近表面积的HTC和Nu较好预测的原因。这说明壁面内部传热冷却是如何有效和高效的燃气轮机热壁传热使用气流射流冷却。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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