Dynamics-Based Health Monitoring And Control Of Wind Turbine Rotors

WIT Transactions on State-of-the-art in Science and Engineering Pub Date : 2014-11-24 DOI:10.2495/978-1-78466-004-8/003

D. Adams, S. Dana, Joshua F. Kusnick, Noah J. Myrent

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引用次数: 1

Abstract

Automatic control and condition monitoring of wind turbines are usually treated as two distinct technical areas because control has a short-term focus, whereas condi- tion monitoring has a long-term focusIn practice, energy capture and condition monitoring actually have interrelated objectivesThe structural dynamic behav- iour of the rotor system is the link between control and condition monitoringThe aerodynamic loads that govern energy capture are converted by the dynamics of the rotor into drive train loads, which govern many of the failure modes in the turbineThis chapter will discuss two ways in which these rotor structural dynam- ics can be used to improve decision making in operation and maintenance of wind turbinesA horizontal axis wind turbine test bed is used to experimentally simulate the rotor structural dynamic response to uniform flow as well as horizontal and vertical shear flow across the rotor planeFirst, the vibrational characteristics of the rotor system are described in the context of modal analysis where each mode of vibration occurs at a particular frequency with a particular modal deflection shapeThese shapes dictate the effectiveness with which a given aerodynamic load couples into the rotor to produce mechanical power in addition to vibrations of the rotorIt is shown using operational modal analysis that changes in yaw and pitch set points change the degree to which the rotor modes of vibration are excited and, consequently, the energy that is captured from the wind and the fatigue loads that act on the turbineBy analysing the changes in rotor response in the flap, edge - wise and span directions, the source of power loss is classified so that corrective action can be taken in the form of rotor controlSecond, the effects of changes in the wind state on the sensitivity of condition monitoring data to damages in the turbine rotor are discussedIt is shown using modal filters that certain frequencies in the measured response of the wind turbine are sensitive to a change in condition of the rotor in the form of ice accretion or blade root damage for use in detecting

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基于动力学的风力发电机转子健康监测与控制

风力涡轮机的自动控制和状态监测通常被视为两个不同的技术领域，因为控制具有短期重点，而状态监测具有长期重点。能量捕获和状态监测实际上具有相互关联的目标。转子系统的结构动态行为是控制和状态监测之间的联系。控制能量捕获的气动载荷通过转子的动力学转化为传动系载荷。这一章将讨论两种方法，其中这些转子结构动力学可以用来改善风力发电机的运行和维护决策。一个水平轴风力发电机试验台用于实验模拟转子结构的动态响应均匀流以及水平和垂直剪切流穿过转子平面。转子系统的振动特性进行了模态分析,每个振动模式的背景下发生在一个特定的频率与特定的模态挠度shapeThese形状决定一个给定的空气动力载荷的有效性夫妇到转子产生的机械功率除了振动rotorIt显示使用运行模态分析偏航和音高的变化设置点的转子模式改变的程度通过分析转子在襟翼、边向和跨向上的响应变化，对功率损失的来源进行分类，以便以转子控制的形式采取纠正措施。讨论了风态变化对状态监测数据对风机转子损伤敏感性的影响。利用模态滤波器表明，在风力机的实测响应中，某些频率对以冰积或叶根损伤形式出现的转子状态变化是敏感的，可用于检测

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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WIT Transactions on State-of-the-art in Science and Engineering

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