Preventing wind turbine tower natural frequency excitation with a quasi‐LPV model predictive control scheme

Abstract: With the ever increasing power rates of wind turbines, more advanced control techniques are needed to facilitate tall towers that are low in weight and cost-effective but in effect more flexible. Such soft-soft tower configurations generally have their fundamental side-side frequency in the below-rated operational domain. Because the turbine rotor practically has or develops a mass imbalance over time, a periodic and rotor-speed dependent side-side excitation is present during below-rated operation. Persistent… Show more

“…J indicated by the solid line) are shown in Figure 3. 3 The natural frequency is in accordance with that provided in [21] for a land-based wind turbine. 4 This particular thrust coefficient has been selected arbitrarily.…”

“…The result provided in Theorem 1 entails that the invariant manifold of (15), which characterizes the exact solution of the associated nonlinear optimal control problem, can be stabilised by the addition of the virtual control input (21), yielding the controlled Hamiltonian dynamics (20). The result can be utilised to obtain a costate trajectory p which is arbitrarily close to the optimal one p .…”

“…Since it is not feasible to obtain analytic solutions of the HJB pde -not only in the context of the wind turbine model considered herein, but also in general -we exploit, following our aforementioned strategy, the result of Theorem 1 to provide an algorithm which utilises the solution of the ARE (19) and the corresponding quadratic function V = 1 2 x P x in place of the solution of the HJB pde. Namely, in the absence of the (21) with V = V q 5 Compute χ(t), p(t) solution of (20) solution of the HJB pde, we adopt a quadratic function 2 V in (21) and in the construction of the initial condition χ(0). The resulting open-loop strategy accounts for the nonlinearities in the model (as opposed to the linear quadratic approximation) through the dynamics (20) and requires (similarly to the LQ approximation) only the solution of the ARE (19).…”

Nonlinear optimal control of a ballast-stabilized floating wind turbine via externally stabilised Hamiltonian dynamics

“…J indicated by the solid line) are shown in Figure 3. 3 The natural frequency is in accordance with that provided in [21] for a land-based wind turbine. 4 This particular thrust coefficient has been selected arbitrarily.…”

“…The result provided in Theorem 1 entails that the invariant manifold of (15), which characterizes the exact solution of the associated nonlinear optimal control problem, can be stabilised by the addition of the virtual control input (21), yielding the controlled Hamiltonian dynamics (20). The result can be utilised to obtain a costate trajectory p which is arbitrarily close to the optimal one p .…”

“…Since it is not feasible to obtain analytic solutions of the HJB pde -not only in the context of the wind turbine model considered herein, but also in general -we exploit, following our aforementioned strategy, the result of Theorem 1 to provide an algorithm which utilises the solution of the ARE (19) and the corresponding quadratic function V = 1 2 x P x in place of the solution of the HJB pde. Namely, in the absence of the (21) with V = V q 5 Compute χ(t), p(t) solution of (20) solution of the HJB pde, we adopt a quadratic function 2 V in (21) and in the construction of the initial condition χ(0). The resulting open-loop strategy accounts for the nonlinearities in the model (as opposed to the linear quadratic approximation) through the dynamics (20) and requires (similarly to the LQ approximation) only the solution of the ARE (19).…”

Nonlinear optimal control of a ballast-stabilized floating wind turbine via externally stabilised Hamiltonian dynamics

“…2. In the baseline case, a standard K-omega-squared torque control is implemented in the below-rated regime [36,37], while the blade pitch angles are kept constant at the optimal power coefficient C P to ensure maximal power generation. In the above-rated regime (i.e., when the wind speed exceeds 11.4 ms À1 ), the torque is kept constant while the collective pitch angles are controlled to ensure rated power production.…”

On the Load Impact of Dynamic Wind Farm Wake Mixing Strategies

“…In addition, only negligible effects of the so-called aerodynamic damping is experienced, in contrast to the fore-aft motion [3]. In recent years, the most common control strategy used to mitigate prolonged side-side tower oscillation is the active damping by generator torque, such as the work done by Mulders, et al [4] and references therein. Although proven to be effective, power production can be affected as a side product of the load reduction activity, as demonstrated by Mulders, et al Alternatively, one may resort to the individual pitch control (IPC) to manipulate the blade in-plane forces' horizontal component; resulting in the side-side tower-top force counteracting the structural excitation [5].…”

Individual pitch control by convex economic model predictive control for wind turbine side-side tower load alleviation