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In an oscillating water column (OWC) assembly power may be generated based on a power reference that is derived from an estimate of the available mechanical power in the air turbine 2 or a measured pressure drop across the turbine. The power reference is used to derive a power control torque referen

In an oscillating water column (OWC) assembly power may be generated based on a power reference that is derived from an estimate of the available mechanical power in the air turbine 2 or a measured pressure drop across the turbine. The power reference is used to derive a power control torque reference within a power controller 14. A speed controller 16 uses a comparison of a measured speed of the generator 8 and a maximum speed limit to derive a speed control torque reference. A selector function 22 selects whichever of the power control and speed control torque references is the maximum at any time instant. The selected torque reference is input to an anti stall torque function 24 where it is selectively modified by applying a speed dependent gain that decreases with decreasing turbine speed, preferably so that the main torque reference is zero for a minimum speed limit.

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1. An assembly comprising: a turbine that is driven to rotate by moving fluid;a generator having a rotor that is driven by an output shaft of the turbine;a power converter; anda controller providing a main torque reference (Mref) to the power converter to control the torque of the generator;wherein

1. An assembly comprising: a turbine that is driven to rotate by moving fluid;a generator having a rotor that is driven by an output shaft of the turbine;a power converter; anda controller providing a main torque reference (Mref) to the power converter to control the torque of the generator;wherein the controller includes: a power reference function block for providing a power reference (Pref) derived from an estimate of the available mechanical power in the turbine or a measured pressure drop (Δp) across the turbine;a power controller function block that uses the power reference (Pref) to derive a power control torque reference (MrefPo), the power control torque reference (MrefPo) being configured for continuously tracking the main torque reference (Mref); anda speed controller function block that uses a comparison of a measured speed (ω) of the generator and a maximum speed limit (ωmax) to derive a speed control torque reference (Mrefω), the speed control torque reference (Mrefω) being configured for continuously tracking the main torque reference (Mref). 2. The assembly of claim 1, further comprising anti stall torque limit function block that selectively modifies whichever of the power control and speed control torque references (MrefPo,Mrefω) is the maximum at any time instant to derive the main torque reference (Mref) by applying a speed dependent gain that decreases with decreasing turbine speed so that the main torque reference (Mref) is zero for a minimum speed limit. 3. The assembly of claim 1, wherein the power controller function block includes a proportional-integral (PI) controller and the speed controller function block includes a PI controller. 4. The assembly of claim 1, wherein the power controller function block and the speed controller function block both use the main torque reference (Mref) to drive the power control and speed control torque references (MrefPo,Mrefω), respectively. 5. The assembly of claim 1, wherein the estimate of the available mechanical power in the turbine is derived from an estimate of the mechanical turbine torque ({tilde over (M)}air) and a measured speed (ω) of the generator or from a measured pressure drop (Δp) across the turbine and known torque characteristics of the turbine. 6. The assembly of claim 5, wherein the estimate of the mechanical turbine torque ({tilde over (M)}air) is further derived using a measured generated power (Pfb) or an estimate of generated power ({tilde over (P)}gen) that is derived from the main torque reference (Mref), known generator characteristics, and a measure speed (ω) of the generator. 7. The assembly of claim 1, wherein the estimate of the available mechanical power is filtered before it is used by the power reference function block to derive the power reference (Pref). 8. The assembly of claim 1, wherein the power controller function block further uses a measured generator power (Pfb) to derive the power control torque reference (MrefPo). 9. The assembly of claim 1, wherein the power controller function block further uses an estimate of generated power ({tilde over (P)}gen) to derive the power control torque reference (MrefPo), the estimate of generated power ({tilde over (P)}gen) being derived from the main torque reference (Mref), known generator characteristics, and a measured speed (ω) of the generator. 10. A control strategy for an assembly comprising: a turbine that is driven to rotate by moving fluid; a generator having a rotor that is driven by an output shaft of the turbine; a power converter; and a controller providing a main torque reference (Mref) to the power converter to control the torque of the generator; wherein the control strategy includes the steps of: providing a power reference (Pref) that is derived from an estimate of the available mechanical power in the turbine or a measured pressure drop (Δp) across the turbine;using the power reference (Pref) to derive a power control torque reference (MrefPo), the power control torque reference)(MrefPo) being configured for continuously tracking the main torque reference (Mref);using a comparison of a measured speed (ω) of the generator and a maximum speed limit (ωmax) to derive a speed control torque reference (Mrefω), the speed control torque reference (Mrefω) being configured for continuously tracking the main torque reference (Mref). 11. The control strategy of claim 10, further comprising the step of selectively modifying whichever of the power control and speed control torque references (MrefPo,Mrefω) is the maximum at any time instant to derive the main torque reference (Mref) by applying a speed dependent gain that decreases with decreasing turbine speed so that the main torque reference (Mref) is zero for a minimum speed limit. 12. The control strategy of claim 10, wherein the power reference (Pref) follows one or more of: (i) a moving average of the estimated available mechanical power in the turbine, and (ii) an instantaneous estimate of the available mechanical power in the turbine. 13. The control strategy of claim 10, wherein the main torque reference (Mref) is used to derive the power control and speed control torque references (MrefPo,Mrefω). 14. The control strategy of claim 10, wherein the estimate of the available mechanical power in the turbine is derived from an estimate of the mechanical turbine torque ({tilde over (M)}air) and a measured speed (ω) of the generator or a measured drop (Δp) across the turbine and known torque characteristics of the turbine. 15. The control strategy of claim 10, wherein the estimate of the mechanical turbine torque is further derived using a measured generated power (Pfb) or an estimate of generated power ({tilde over (P)}gen) that is derived from the main torque reference (Mref), known generator characteristics, and a measure speed (ω) of the generator. 16. The control strategy of claim 10, wherein the estimate of the available mechanical power is filtered before it is used by the power reference function block to derive the power reference (Pref). 17. The control strategy of claim 10, wherein a measured generated power (Pfb) is used to derive the power control torque reference (MrefPo). 18. The control strategy of claim 10, wherein an estimate of generated power ({tilde over (P)}gen) is used to derive the power control torque reference (MrefPo), the estimate of generated power ({tilde over (P)}gen) being derived from the main torque reference (Mref), known generator characteristics, and the measured speed (ω) of the generator.