基于神经网络的风力发电系统故障检测

2017 IEEE Technological Innovations in ICT for Agriculture and Rural Development (TIAR) Pub Date : 2017-04-07 DOI:10.1109/TIAR.2017.8273694

M. Nithya, S. Nagarajan, P. Navaseelan

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引用次数: 8

摘要

风能发电是世界上发展最快的发电方式之一。风中的动能使风力发电系统中的转子叶片旋转，从而产生电能。由于风力发电机组系统由多个部件组成，其故障发展的可能性较大。系统故障会导致机械部件退化加剧，严重降低资产性能，并直接增加年度维护成本。风力发电机组系统可能出现的故障有叶片角度不对称和偏航不对中。本文主要研究了利用人工神经网络(NN)对风力发电系统进行故障检测。利用神经网络对汽轮机系统进行实时数据建模。随机抽取600个样本，用于训练神经网络系统;另外取300个样品进行验证。采用模型误差建模方法实现阈值限制。对于无故障系统，输出应该在阈值范围内。比较了能准确检测系统故障的最佳模型。

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Fault detection of wind turbine system using neural networks

Electricity produced from wind energy is one of the rapid growing power generation methods in the world. Kinetic energy in wind rotates the rotor blade in wind turbine system thus generating power. As the wind turbine system has many components, chance of fault development is more in the turbine system. System faults can lead to increased mechanical component degradation, severe reduction of asset performance, and a direct increase in annual maintenance costs. Possible faults in wind turbine system are blade angle asymmetry and yaw misalignment. This work focuses on the detection of faults in the wind turbine system using Artificial Neural Networks (NN). Modeling of turbine system is done by neural networks with the real time data. 600 samples are taken randomly and are used to train the neural network system; another 300 samples are taken for validation. Threshold limits are done by model error modeling method. For a fault free system, output should present inside the threshold limits. The best model is compared which precisely detect fault in the system.

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2017 IEEE Technological Innovations in ICT for Agriculture and Rural Development (TIAR)

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