Wind turbines experience countless shutdowns during their lifetimes. A shutdown is a transient process characterised by a pitch-to-feather manoeuvre of three blades. Such a pitch manoeuvre is often collective, open-loop, and can substantially slow the rotor speed within several seconds. However, undesirable structural responses may arise because of the imbalanced aerodynamic loads acting on the rotor. To address this issue, this paper proposes a method that actively adjusts the individual pitch rate of each blade during an emergency shutdown. This method is founded on a minimal intervention principle and uses the blade-root bending moment measurements as the only inputs. The control objective is to minimise the differences in the blade-root...
Offshore wind turbines suffer from asymmetrical loading (blades, tower, etc), leading to enhanced st...
Reducing the loads experienced by wind turbine rotor blades can lower the cost of energy of wind tur...
A novel approach to reducing the unbalance rotor loads by pitch control is presented in this paper. ...
Wind turbines experience countless shutdowns during their lifetimes. A shutdown is a transient proce...
The paper presents a novel approach for the synthesis of the open-loop pitch profile during emergenc...
In this paper we study the use of individual blade pitch control as a way to reduce ultimate loads. ...
In this paper we study the use of individual blade pitch control as a way to reduce ultimate loads. ...
It has been well established that non-torque main shaft loads influence the internal drive train loa...
Individual pitch control (IPC) provides an important means of attenuating harmful fatigue and extrem...
Improvements to current pitch control strategies are explored by analysing the addition of a dynamic...
Wind turbines with floating support structures are blessed with their potential in generating high q...
This paper describes an optimization-based approach to reducing extreme structural loads during rapi...
Large wind turbines are subjected to the harmful loads that arise from the spatially uneven and temp...
Significant fore-and-aft tower vibrations of large wind turbines due to wind shear can be reduced us...
Offshore wind turbines suffer from asymmetrical loading (blades, tower, etc), leading to enhanced st...
Reducing the loads experienced by wind turbine rotor blades can lower the cost of energy of wind tur...
A novel approach to reducing the unbalance rotor loads by pitch control is presented in this paper. ...
Wind turbines experience countless shutdowns during their lifetimes. A shutdown is a transient proce...
The paper presents a novel approach for the synthesis of the open-loop pitch profile during emergenc...
In this paper we study the use of individual blade pitch control as a way to reduce ultimate loads. ...
In this paper we study the use of individual blade pitch control as a way to reduce ultimate loads. ...
It has been well established that non-torque main shaft loads influence the internal drive train loa...
Individual pitch control (IPC) provides an important means of attenuating harmful fatigue and extrem...
Improvements to current pitch control strategies are explored by analysing the addition of a dynamic...
Wind turbines with floating support structures are blessed with their potential in generating high q...
This paper describes an optimization-based approach to reducing extreme structural loads during rapi...
Large wind turbines are subjected to the harmful loads that arise from the spatially uneven and temp...
Significant fore-and-aft tower vibrations of large wind turbines due to wind shear can be reduced us...
Offshore wind turbines suffer from asymmetrical loading (blades, tower, etc), leading to enhanced st...
Reducing the loads experienced by wind turbine rotor blades can lower the cost of energy of wind tur...
A novel approach to reducing the unbalance rotor loads by pitch control is presented in this paper. ...