Transient vibration control on coupled unit-plant structure of pumped storage power station based on MRD optimal layout

IF 7.9 1区 工程技术 Q1 ENGINEERING, MECHANICAL
Jinjian Zhang, Zhenyue Ma, Wenjie Xu, Xueni Wang, Kaiwen Zhang, Leike Zhang
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Abstract

To address the recurring vibration in the integrated unit-plant structure system during the transitional phases of pumped storage power station (PSPS), the magnetorheological damper (MRD) is introduced in this paper to investigate transient vibration control within the coupled unit-plant structure (CUPS). Firstly, taking an actual PSPS as a case study, a unit regulation system model is developed based on one-dimensional transient flow theory, the method of characteristics (MOC), and the improved Suter transformation. Secondly, integrating the position function of unit shaft system, a nonlinear dynamic model of MRD is constructed, and the MRD damping force accounting for axial position parameters is derived. Additionally, on the basis of Lagrange method and finite element method, a mathematical model of unit shaft system and a finite element model for plant structure under the coupling effects of multiple vibration sources are established. Finally, the response to a sudden 10% load increase in generator condition of pumped storage unit is calculated through numerical simulation, and the effects of different damper position functions on the vibration characteristics of rotor and runner are analyzed to identify the optimal installation position for effective vibration control. The research results indicate that, optimizing the damper layout position enables the MRD to effectively reduce the vibration amplitude of rotor and runner, enhancing spectral characteristics. Furthermore, optimizing MRD positions significantly improves the vibration performance of plant structure. After the optimization of MRD positions, the vibration attenuation rate of plant structure accelerates, leading to a quicker stabilization, particularly noticeable in the generator floor. The findings of this study offer valuable engineering guidance for managing transient vibration in the integrated unit-plant system of PSPS.
基于 MRD 优化布局的抽水蓄能电站耦合机组-厂房结构的瞬态振动控制
为解决抽水蓄能电站(PSPS)过渡阶段一体化机组-电站结构系统的反复振动问题,本文引入磁流变阻尼器(MRD)来研究耦合机组-电站结构(CUPS)内的瞬态振动控制。首先,以实际的 PSPS 为案例,基于一维瞬态流理论、特性法(MOC)和改进的 Suter 变换,建立了机组调节系统模型。其次,结合机组轴系统的位置函数,构建了 MRD 非线性动态模型,并推导出了 MRD 轴向位置参数阻尼力。此外,在拉格朗日法和有限元法的基础上,建立了多振源耦合效应下的机组轴系数学模型和厂房结构有限元模型。最后,通过数值模拟计算了抽水蓄能机组发电机工况下负荷突然增加 10%时的响应,并分析了不同阻尼器位置函数对转子和转轮振动特性的影响,从而确定了有效控制振动的最佳安装位置。研究结果表明,优化阻尼器布置位置可使 MRD 有效降低转子和转轮的振动振幅,增强频谱特性。此外,优化 MRD 位置还能显著改善设备结构的振动性能。优化 MRD 位置后,设备结构的振动衰减速度加快,从而更快地趋于稳定,这在发电机底板上尤为明显。本研究的结果为管理 PSPS 一体化机组-设备系统的瞬态振动提供了宝贵的工程指导。
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
Mechanical Systems and Signal Processing
Mechanical Systems and Signal Processing 工程技术-工程:机械
CiteScore
14.80
自引率
13.10%
发文量
1183
审稿时长
5.4 months
期刊介绍: Journal Name: Mechanical Systems and Signal Processing (MSSP) Interdisciplinary Focus: Mechanical, Aerospace, and Civil Engineering Purpose:Reporting scientific advancements of the highest quality Arising from new techniques in sensing, instrumentation, signal processing, modelling, and control of dynamic systems
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