Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSN › Conference contribution/Paper › peer-review
Model-based condition monitoring for wind turbines. / Cross, Philip; Ma, Xiandong.
Automation and Computing (ICAC), 2013 19th International Conference on. IEEE, 2013.Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSN › Conference contribution/Paper › peer-review
}
TY - GEN
T1 - Model-based condition monitoring for wind turbines
AU - Cross, Philip
AU - Ma, Xiandong
PY - 2013
Y1 - 2013
N2 - It is common for wind turbines to be installed in remote locations on land or offshore, leading to difficulties in routine inspection and maintenance. In addition, wind turbines in these locations are often subject to harsh operating conditions. These challenges mean there is a requirement for a high degree of maintenance.Consequently, monitoring and diagnostics of wind turbines play an increasingly important role in the competitive operation of wind farms. The data generated by monitoring systems can be used to obtain models of wind turbines operating under different conditions, and hence predict output signals based on known inputs. By comparing output data obtained from operational turbines with thosepredicted by the models, it is possible to detect changes that may be due to the presence of faults.This paper discusses model-based condition monitoring methods for wind turbines, in which the relationships between measured variables are modelled using linear models and artificial neural networks identified from dataacquired from operational turbines. The relationships between variables are also modelled using non-linear state dependent ‘pseudo’ transfer functions. Although these state dependent parameter models have been used extensively asthe basis of non-linear controllers, the research described here represents the first occasion for which they have been employed for a condition monitoring system. It is found that artificial neural network-based models outperform statedependent parameter models; however, the computing power required for the latter is considerably less. Finally, the monitoring data are used to develop adaptive threshold rules for critical output signals, forming the basis of an earlywarning system.
AB - It is common for wind turbines to be installed in remote locations on land or offshore, leading to difficulties in routine inspection and maintenance. In addition, wind turbines in these locations are often subject to harsh operating conditions. These challenges mean there is a requirement for a high degree of maintenance.Consequently, monitoring and diagnostics of wind turbines play an increasingly important role in the competitive operation of wind farms. The data generated by monitoring systems can be used to obtain models of wind turbines operating under different conditions, and hence predict output signals based on known inputs. By comparing output data obtained from operational turbines with thosepredicted by the models, it is possible to detect changes that may be due to the presence of faults.This paper discusses model-based condition monitoring methods for wind turbines, in which the relationships between measured variables are modelled using linear models and artificial neural networks identified from dataacquired from operational turbines. The relationships between variables are also modelled using non-linear state dependent ‘pseudo’ transfer functions. Although these state dependent parameter models have been used extensively asthe basis of non-linear controllers, the research described here represents the first occasion for which they have been employed for a condition monitoring system. It is found that artificial neural network-based models outperform statedependent parameter models; however, the computing power required for the latter is considerably less. Finally, the monitoring data are used to develop adaptive threshold rules for critical output signals, forming the basis of an earlywarning system.
KW - Wind turbines
KW - Condition monitoring
KW - Artificial neural network
KW - State dependent parameter model
M3 - Conference contribution/Paper
BT - Automation and Computing (ICAC), 2013 19th International Conference on
PB - IEEE
ER -