燃气轮机模型的研制

O. Nagornaya, V. Gorbunov, A. Pavlov, P.A. Mineev
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引用次数: 1

摘要

由于世界工业的发展,对电力的需求正在增长。因此,使用使用二次能源的装置获得能源的问题是相关的。在这方面,重要的是对这些设施的运行进行研究。汽轮机作为一种利用二次能源的发电装置,其运行研究方法多种多样。为了达到这个目的,像ANSYS这样的可视化环境可以让你得到一个可视化的涡轮运行的三维表示。因此,迫切需要在ANSYS CFX软件包中开发数值确定的涡轮模型,并根据实验数据进行调整。基于数值实验的模型可用于寻找提高输出功率的方法。以顶压回收式汽轮机GUBT-25为研究对象。在研究过程中,使用了专业的分析软件ANSYS CFX来解决热、水、气动力学问题。采用BladeGen等软件模块设计固态模型,TurboGrid创建网格。ANSYS CFX软件采用以下基本方程对涡轮内气体膨胀问题进行数值求解:能量方程、动量方程和连续性方程。首次在ANSYS CFX分析软件中建立了GUBT-25涡轮的数值确定模型。此外,基于OJSC“Severstal”涡轮机上进行的工业实验结果,对该模型进行了初步验证。此外,为了证明该模型的能力,本文用图形表示了涡轮一级的温度和速度分布等特征。所建立的GUBT-25涡轮数值模型存在一系列限制条件,影响了仿真结果。通过对仿真数据的比较,得出了与实验数据不一致的结论。在模型较复杂的情况下,可以更准确地模拟GUBT-25的实际过程。
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Development of combustion-gas turbine model
The demand for electricity is growing due to industry development in the world. Thus, the issue to obtain energy using installations that use secondary energy resources is relevant. In this regard, it is important to carry out the research on the operation of such installations. There are many ways to study the operation of turbines as one of the types of installations that uses secondary energy resources. For this purpose, such visual environment as ANSYS allows you to get a visual 3D representation of the turbine operation. Thus, an urgent task is to develop a numerical determined turbine model in the ANSYS CFX package and then adapt it based on experimental data. The model based on numerical experiments can be used to find ways to increase the electricity output. The top-pressure recovery turbine GUBT-25 is chosen as the object of the research. During the research the professional analytical ANSYS CFX software has been used to solve thermal-, hydro-, and gas-dynamic problems. Also, such software module as BladeGen is applied to design a solid-state model and TurboGrid is to create a grid. ANSYS CFX software uses the following basic equations for the numerical solution of the gas expansion problem in a turbine: the energy equation, the momentum equation, and the continuity equation. For the first time a numerical determined model of the GUBT-25 turbine has been developed in the ANSYS CFX analytical software. Also, a preliminary verification of the model has been carried out based on the results of the industrial experiment conducted at the OJSC “Severstal” turbine. In addition, to demonstrate the capabilities of the model the article graphically presents such characteristics as distribution of temperature and velocity in the first stage of the turbine. The developed numerical model of the GUBT-25 turbine has series of restrictions that affect the simulation results. The results of comparing the data obtained during the simulation differ from the experimental data. In case the model is more complicated, it will be possible to simulate the real processes of GUBT-25 more accurately.
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