Impact of Installation Deviations on the Dynamic Characteristics of the Shaft System for 1 Gigawatt Hydro-Generator Unit

Machines Pub Date : 2024-07-12 DOI:10.3390/machines12070473
Gangyun Song, Xingxing Huang, Haijun Li, Zhengwei Wang, Dong Wang
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Abstract

The shaft system, transferring the kinetic energy of water flow into electrical energy, is the most critical component in hydropower plants. Installation deviations of the shaft system for a giant hydro-generator unit can have significant impacts on its dynamic characteristics and overall performance. In this investigation, a three-dimensional geometry of the shaft system of an operating hydro-generator unit prototype with a rated power of 1 GW is established. Then, the calculation model of the shaft system is generated accordingly with tetrahedral and hexahedral elements. By applying different boundary conditions, the finite-element method is used to analyze the influences of installation deviations, including shaft radial misalignment and angular misalignment, on the dynamic characteristics of the shaft system. The calculation results reveal that the installation deviations change the natural frequencies, critical speeds, and mode shapes of the shaft system to a certain degree. The natural frequencies of the backward precession motion with installation deviations are reduced by 23% and 38% for the rated speed and the maximum runaway speed. Furthermore, for the forward precession motion, they increased by 30% and 48%, respectively. The critical speeds for the shaft system with radial and angular deviations are 3.2% and 3% larger than the critical speed of the shaft system without any mounting deviations. The radial and angular installation deviations below the maximum permissible values will not result in the structural performance degradation of the 1 GW hydro-generator shaft system. The conclusion drawn in this research can be used as a valuable reference for installing other rotating machinery.
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安装偏差对 1 千兆瓦水轮发电机组轴系动态特性的影响
将水流动能转化为电能的轴系是水电站中最关键的部件。巨型水轮发电机组轴系的安装偏差会对其动态特性和整体性能产生重大影响。本研究建立了额定功率为 1 GW 的运行中水轮发电机组原型轴系的三维几何结构。然后,用四面体和六面体元素生成相应的轴系统计算模型。通过应用不同的边界条件,采用有限元方法分析了安装偏差(包括轴径向偏差和角度偏差)对轴系动态特性的影响。计算结果表明,安装偏差在一定程度上改变了轴系统的固有频率、临界转速和模态振型。在额定转速和最大失控转速下,存在安装偏差的后向预摆运动的固有频率分别降低了 23% 和 38%。此外,对于前冲运动,它们分别增加了 30% 和 48%。有径向和角度偏差的轴系统的临界速度比没有任何安装偏差的轴系统的临界速度分别高出 3.2% 和 3%。低于最大允许值的径向和角度安装偏差不会导致 1 GW 水轮发电机轴系统的结构性能下降。本研究得出的结论可为其他旋转机械的安装提供有价值的参考。
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