Numerical Simulation of a Gas Flow in a Stage-Diffuser System in a Wide Range of Modes with Experimental Verification

Q3 Mathematics
M. G. Cherkasova, V. A. Chernikov, E. Yu. Semakina
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Abstract

Usually at the design stage of a gas turbine unit (GTU) the nominal operating mode is considered. This mode is defined by the axial exit of the flow from the turbine, in order to reduce losses with the exhaust velocity. Axial entry into the diffuser is optimal, due to the absence of incidence angle on the support struts. Struts are the integral part of the diffuser, where the rear bearing support of the turbine rotor is located. However, the GTU operates for a long time both in the nominal and in variable modes. Partial modes are characterized by significant incidence angles on the struts, which leads to flow separation and a notable increase in pressure losses in the diffuser. Maintaining a satisfactory flow in the diffuser in a wide range of modes is an important issue. In this paper, the stage-diffuser system is studied by experimental and numerical methods in a wide range of modes. This study shows that at the last stage when the flow angle is less than 50°, the flow in the diffuser acquires an asymmetric character with the developed vortices. This means that numerical simulation in an engineering approach cannot repeat the nature of the flow at low load modes. Nevertheless, a comparison of the total parameters of the experiment and simulation shows close agreement (a difference of about 5%) even for modes with large incidence angles on the diffuser struts.

Abstract Image

分级扩散器系统中多种模式气体流的数值模拟与实验验证
摘要 通常在燃气轮机组(GTU)的设计阶段会考虑额定运行模式。该模式由涡轮机气流的轴向出口决定,目的是降低排气速度带来的损失。由于支撑杆上没有入射角,因此轴向进入扩散器是最佳模式。支撑杆是扩散器的组成部分,涡轮转子的后轴承支撑就位于扩散器中。然而,GTU 可在额定模式和可变模式下长期运行。局部模式的特点是支撑杆的入射角较大,从而导致流量分离和扩散器中压力损失的显著增加。在各种模式下保持扩散器内令人满意的流量是一个重要问题。本文通过实验和数值方法研究了各种模式下的阶段扩散器系统。研究结果表明,在最后一个阶段,当流动角小于 50°时,扩散器中的流动会随着涡流的发展而呈现出不对称的特征。这意味着工程方法中的数值模拟无法重复低负荷模式下的流动性质。尽管如此,对实验和模拟的总参数进行比较后发现,即使在扩散器支杆入射角较大的模式下,两者的参数也非常接近(相差约 5%)。
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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来源期刊
Mathematical Models and Computer Simulations
Mathematical Models and Computer Simulations Mathematics-Computational Mathematics
CiteScore
1.20
自引率
0.00%
发文量
99
期刊介绍: Mathematical Models and Computer Simulations  is a journal that publishes high-quality and original articles at the forefront of development of mathematical models, numerical methods, computer-assisted studies in science and engineering with the potential for impact across the sciences, and construction of massively parallel codes for supercomputers. The problem-oriented papers are devoted to various problems including industrial mathematics, numerical simulation in multiscale and multiphysics, materials science, chemistry, economics, social, and life sciences.
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