Methods and arrangements for controlling power generators

The invention claimed is: 1. A method of transitioning a power generator, from an initial reactive power state to a desired reactive power state, the power generator belonging to a power farm, the power generator having a local voltage controller, the power farm having a central reactive power controller, the reactive power generated by the power generator during the initial and desired reactive power states being determined based on values of reactive power demand sent by the central reactive power controller, the method comprising the steps of: detecting an absolute change of voltage above a predetermined voltage threshold at the power generator; transitioning, with a dead-time compensator, the reactive power state of the power generator from the initial reactive power state to a first reactive power state, wherein the reactive power generated by the power generator during the first reactive power state is determined by the local voltage controller in response to the detected change of voltage; receiving the values of reactive power demand at the power generator sent from the central reactive power controller, the values corresponding to demands for reactive power generation; identifying a received value of reactive power demand as a trigger value when the absolute difference between the received value of reactive power demand and a previously received value of reactive power demand is above a predetermined reactive power threshold; transitioning to a second reactive power state when the trigger value is detected, wherein the reactive power generated by the power generator at any given moment during the second reactive power state is set based on a calculation made by a transition controller, the calculation being a function of a last received value of reactive power demand and a value of reactive power at a previous setting moment; transitioning to the desired reactive power state when the calculation fulfils a predetermined criterion. 2. The method according to claim 1 , wherein the transition to the first reactive power state is initiated within a predetermined first time period. 3. The method according to claim 2 , wherein the first time period is 0.2 sec after detecting the absolute change of voltage. 4. The method according to any of claim 1 , wherein the calculation includes calculating a series of error values, each error value being calculated between a value of a received reactive power demand and the value of the current actual reactive power. 5. The method according to claim 4 , wherein a first error value is the difference between the trigger value and the value of the actual reactive power generated when the value of reactive power demand is received during the first reactive power state. 6. The method according to claim 1 , wherein the transitioning to the second reactive power state is initiated substantially immediately after the trigger value is received. 7. The method according to claim 6 , wherein the reactive power at time t that is set within the second reactive power state period, (Q convt ), is defined by the equation: Q convt =Q conv _ state1 +K p ( Q refWF −Q conv(t-1) )+ K i ∫ 0 t ( Q refWF −Q conv(t-1) ) dt wherein, Q con _ state1 is the value of the last actual reactive power during the first reactive power state, Q refWF is the value of the reactive power demanded by the power farm, Q cont(t-1) is the reactive power during a previous setting step, Q refWF −Q conv(t-1) is the error value during a current setting step, and K p and K i are constants selected to provide a desired convergence characteristic to the second power state, as the reactive power during the second power state converges towards the value of the reactive power demand. 8. The method according to claim 1 , wherein the predetermined criterion for transitioning to the desired reactive power state is a predetermined percentage deviation of the value of the reactive power from the reactive power demand value. 9. The method according to claim 8 , wherein the predetermined percentage deviation is 5%. 10. A device for controlling the reactive power state of a power generator during a transition period from an initial reactive power state to a desired reactive power state, the power generator belonging to a power farm, the power generator having a local voltage controller and a ΔV generator for generating voltage change values that correspond to deviations in voltage as seen from the power generator, the power farm having a central reactive power controller, the initial and desired power states being determined by the central reactive power controller, the device comprising: a voltage change detector, coupled to the ΔV generator, for detecting an absolute voltage change at the power generator above a first predetermined threshold; a reactive power demand change detector, coupled to the central reactive power controller, for detecting a reactive power demand change above a second predetermined threshold between successive reactive power demand values sent from the central reactive power controller; a transition controller, for determining the reactive power state of the power generator; a dead-time compensator, coupled to the voltage change detector, to the reactive power demand change detector and to the transition controller, for determining a value of the reactive power, the dead-time compensator being controllable by instructions received from the transition controller; a converter reactive power controller coupled to the dead-time compensator for setting the reactive power of the power generator based on the value of the reactive power received from the dead-time compensator. 11. The device according to claim 10 , wherein the dead-time compensator comprises: means for transitioning the reactive power state of the power generator from an initial reactive power state to a first reactive power state, wherein the reactive power generated by the power generator during the first reactive power state is defined by the local voltage controller in response to the detected voltage change; means for transitioning the reactive power state of the power generator from the first reactive power state to a second reactive power state, wherein the reactive power generated by the power generator during the second reactive power state is based on a calculation of a transition controller, the calculation being a function of the received reactive power demand value and a previous value of the reactive power; and means for transitioning to the desired reactive power state when the calculation of the transition controller fulfils a predetermined criterion, whereby the reactive power generated by the power generator during the desired reactive power state is based on the desired reactive power sent by the central reactive power controller. 12. A power generator comprising: a local voltage controller; a ΔV generator for generating voltage change values that correspond to deviations in voltage as seen from the power generator; a device for controlling the reactive power state of the power generator during a transition period from an initial reactive power state to a desired reactive power state, the power generator belonging to a power farm, the power farm having a central reactive power controller, the initial and desired power states being determined by the central reactive power controller, the device comprising: a voltage change detector, coupled to the ΔV generator, for detecting an absolute voltage change at the power generator above a first predetermined threshold; a reactive power demand change detector, coupled to the central reactiv