Due to the rapid progress in computer hardware and software, CFD became a powerful and effective tool for implementation turbulence modeling in defined combustion mathematical models in the complex boiler geometries. In this paper the commercial CFD package, ANSYS FLUENT was used to model fluid flow through the boiler, in order to define velocity field and predict pressure drop. Mathematical modeling was carried out with application of Standard, RNG, and Realizable k-ε turbulence model using the constants presented in literature. Three boilers geometry were examined with application of three different turbulence models with variants, which means consideration of 7 turbulence model arrangements in FLUENT. The obtained model results are presented and compared with data collected from experimental tests. All experimental tests were performed according to procedures defined in the standard SRPS EN 303-5 and obtained results are presented in this paper for all three examined geometries. This approach was used for improving construction of boiler fired by solid fuel with heat output up to 35 kW and for selection of the most convenient construction.
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机译:由于计算机硬件和软件的飞速发展,CFD成为了在复杂锅炉几何中定义的燃烧数学模型中实施湍流建模的强大而有效的工具。在本文中,商用CFD软件包ANSYS FLUENT用于对流经锅炉的流体进行建模,以定义速度场并预测压降。使用标准,RNG和可实现的k-ε湍流模型,使用文献中提供的常数进行数学建模。应用三种不同的湍流模型(带有变体)检查了三种锅炉的几何形状,这意味着要考虑FLUENT中的7种湍流模型布置。呈现获得的模型结果,并与从实验测试中收集的数据进行比较。根据标准SRPS EN 303-5中定义的程序执行所有实验测试,并针对所有三种检查的几何结构在本文中介绍了获得的结果。该方法用于改善由固体燃料燃烧的锅炉的结构,该锅炉的热量输出高达35 kW,并用于选择最方便的结构。
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