Numerical simulations of stagnation region heat transfer for laminar and turbulent freestreams have been performed using a commercial CFD code CFX-TASCflow. Prior to the stagnation region simulations, some classical flow problems were solved to validate the CFD code and evaluate the different turbulence models. Simulations were performed for flow in a square driven cavity, laminar and turbulent boundary layers on a flat plate and flow over a backward facing step. The simulation results are in good agreement with previous simulation results, experiment and theory. The simulations of stagnation region heat transfer with a laminar freestream are performed at Reynolds numbers ranging from 6.5 x 103 to 6.5 x 105. The laminar freestream simulations were performed to obtain an appropriate grid structure and simulation parameters. The laminar simulation results are in good agreement with results of Rigby and VanFossen. The simulations for a turbulent freestream are performed at Reynolds numbers of 1.3 x 10 4, 5 x 104 and 1 x 105, turbulence intensities of 1%, 3% and 5% and the ratio of integral length scales to leading edge diameter (lambda/D) of 0.4282, 0.5709 and 0.7136. The k-&egr; turbulence model proposed by Kato-Launder is used for the simulation. The heat transfer results from the simulations are compared with the empirical solution of VanFossen, et al. The heat transfer increases with Reynolds number and turbulence intensity, and decreases with integral length scale.
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机译:使用商业CFD代码CFX-TASCflow对层流和湍流自由流的停滞区域传热进行了数值模拟。在停滞区域仿真之前,解决了一些经典的流动问题,以验证CFD代码并评估不同的湍流模型。对方形驱动腔中的流动,平板上的层流边界层和湍流边界层进行了模拟,并进行了朝后的台阶流动。仿真结果与以往的仿真结果,实验和理论吻合良好。使用层流自由流的滞流区域传热模拟在6.5 x 103到6.5 x 105的雷诺数下进行。进行层流自由流模拟以获得合适的网格结构和模拟参数。层流仿真结果与Rigby和VanFossen的结果非常吻合。湍流自由流的模拟是在雷诺数为1.3 x 10 4、5 x 104和1 x 105,湍流强度为1%,3%和5%以及积分长度比例与前缘直径的比率(λ/ D)为0.4282、0.5709和0.7136。 k-&egr;仿真中使用了Kato-Launder提出的湍流模型。模拟的传热结果与VanFossen等人的经验解进行了比较。传热随着雷诺数和湍流强度的增加而增加,并随着积分长度的尺度而减小。
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