SCADA数据在风力机故障检测中的应用综述

IF 1.6 4区 工程技术 Q3 INSTRUMENTS & INSTRUMENTATION
Junyan Ma, Yiping Yuan
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引用次数: 1

摘要

目的随着全球风力涡轮机安装数量的快速增加,维护需求和费用也大幅增加。WT的状态监测为预防性维护提供了强有力的“软保障”。监控与数据采集(SCADA)系统记录了大量的状态数据,已成为CM的有效手段。本研究的主要目的是总结SCADA数据在风力发电机故障检测中的应用,分析其优缺点,并预测未来利用SCADA数据进行故障检测的潜力。设计/方法/方法作者首先回顾了WT CM的方法,并根据SCADA数据总结了CM的特点。为了保证SCADA数据的质量,对数据预处理方法进行了分析和比较。然后,讨论了关键部件的故障模式,并比较了用于每个部件故障检测的SCADA数据。此外,对WT的故障检测方法进行了分类,并提出了故障检测的通用框架。最后,对基于SCADA数据的WT故障检测方法中存在的问题进行了综述。发现基于所进行的分析发现,尽管基于SCADA数据的故障检测精度相对较差,但它具有较低的资本支出和较低的计算成本。更具体地说,当故障数据稀少时,可以使用正常的SCADA数据来检测故障时间。但是,无法通过这种方式识别特定的故障类型。当SCADA系统中积累了大量的故障数据时,它不仅可以检测故障的发生时间,还可以识别特定的故障类型。原创性/价值本研究的主要贡献是总结了SCADA数据的预处理方法、关键部件故障检测所需的数据以及故障检测模型的特点。然后,我们提出了一个基于SCADA数据的风力涡轮机通用故障检测框架,维护人员可以根据不同的故障检测要求和数据资源选择合适的故障检测方法。本文有望为基于时间序列传感器信号的故障检测提供指导,并引起研究人员、维护人员和管理人员的兴趣。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Application of SCADA data in wind turbine fault detection – a review
Purpose With the rapid increase in the number of installed wind turbines (WTs) worldwide, requirements and expenses of maintenance have also increased significantly. The condition monitoring (CM) of WT provides a strong “soft guarantee” for preventive maintenance. The supervisory control and data acquisition (SCADA) system records a huge amount of condition data, which has become an effective means of CM. The main objective of the present study is to summarize the application of SCADA data to fault detection in wind turbines, analyze its advantages and disadvantages and predict the potential of future investigations on the use of SCADA data for fault detection. Design/methodology/approach The authors first review the means of WT CM and summarize the characteristics of CM based on SCADA data. To ensure the quality of SCADA data, data preprocessing methods are analyzed and compared. Then, the failure modes of the key components are discussed and the SCADA data used for fault detection of each component are compared. Moreover, the fault detection methods for WT are classified and a general framework for fault detection is proposed. Finally, the issues in the WT fault detection method based on SCADA data are reviewed. Findings Based on the performed analyses, it is found that although the fault detection accuracy based on SCADA data is relatively poor, it has low capital expenses and low computational cost. More specifically, when there is scarce fault data, the normal SCADA data can be used to detect the fault time. However, the specific fault type cannot be identified in this way. When a large amount of fault data are accumulated in the SCADA system, it can not only detect the occurrence time of the fault but also identify the specific fault type. Originality/value The main contribution of the present study is to summarize the pre-processing methods for SCADA data, the data required for fault detection of key components and the characteristics of the fault detection model. Then we propose a general fault detection framework for wind turbines based on SCADA data, where the maintenance workers can choose the appropriate fault detection method according to different fault detection requirements and data resources. This article is expected to provide guidance for fault detection based on time-series sensor signals and be of interest to researchers, maintenance workers and managers.
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来源期刊
Sensor Review
Sensor Review 工程技术-仪器仪表
CiteScore
3.40
自引率
6.20%
发文量
50
审稿时长
3.7 months
期刊介绍: Sensor Review publishes peer reviewed state-of-the-art articles and specially commissioned technology reviews. Each issue of this multidisciplinary journal includes high quality original content covering all aspects of sensors and their applications, and reflecting the most interesting and strategically important research and development activities from around the world. Because of this, readers can stay at the very forefront of high technology sensor developments. Emphasis is placed on detailed independent regular and review articles identifying the full range of sensors currently available for specific applications, as well as highlighting those areas of technology showing great potential for the future. The journal encourages authors to consider the practical and social implications of their articles. All articles undergo a rigorous double-blind peer review process which involves an initial assessment of suitability of an article for the journal followed by sending it to, at least two reviewers in the field if deemed suitable. Sensor Review’s coverage includes, but is not restricted to: Mechanical sensors – position, displacement, proximity, velocity, acceleration, vibration, force, torque, pressure, and flow sensors Electric and magnetic sensors – resistance, inductive, capacitive, piezoelectric, eddy-current, electromagnetic, photoelectric, and thermoelectric sensors Temperature sensors, infrared sensors, humidity sensors Optical, electro-optical and fibre-optic sensors and systems, photonic sensors Biosensors, wearable and implantable sensors and systems, immunosensors Gas and chemical sensors and systems, polymer sensors Acoustic and ultrasonic sensors Haptic sensors and devices Smart and intelligent sensors and systems Nanosensors, NEMS, MEMS, and BioMEMS Quantum sensors Sensor systems: sensor data fusion, signals, processing and interfacing, signal conditioning.
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