Abstract: A cable suspension arrangement includes a first suspension means for suspending the first plurality of cables at a nacelle; a second suspension means which is attachable to the nacelle; a second plurality of spacer plates each including a suspension hole and each including a third plurality of cable through-holes; wherein the second suspension means is led through the suspension holes; a fixing means for fixing the spacer plates at different positions on the second suspension means such that they can at least not lower their respective position; wherein the cables can be slidably led through the through-holes.
Abstract: Some general aspects of the invention provide a method for operating a wind energy converter having a variable-ratio gear system mechanically coupled between a rotor and a generator, wherein the variable-ratio gear system includes a first hydraulic unit coupled to a first shaft and a second hydraulic unit coupled to a second shaft. The method comprises adjusting the variable-ratio gear system to a first gear ratio at which the first shaft substantially does not rotate; determining a wind speed or a related parameter (n, P, p); detecting whether the wind speed or the related parameter (n, P, p) has crossed a first threshold value in a first direction; and adjusting the variable-ratio gear system, when the wind speed or the related parameter (n, P, p) has crossed the first threshold value in the first direction, to a second gear ratio at which the second shaft substantially does not rotate.
Type:
Grant
Filed:
March 20, 2009
Date of Patent:
May 28, 2013
Assignee:
AMSC Austria GmbH
Inventors:
Martin Fischer, Peter Weichbold, Robert Tratnig
Abstract: A differential gear for a wind power plant includes a gearbox with three inputs and outputs. One input is connected to the rotor of the wind power plant, the first output is connected to a generator and the second output is connected to the input shaft of a continuously variable gearbox, the output shaft of which is connected to the generator side output of the gearbox. The input shaft of the continuously variable gearbox is connected to the output shaft of the gearbox via a variable gearbox.
Abstract: A method for retro-fitting wind-energy conversion system includes disconnecting a first set of multiple windings from active circuitry; shorting together the first set of multiple windings; and connecting a second set of multiple windings to the active circuitry.
Abstract: A method for adjusting a pivotally mounted rotor blade of a wind energy converter includes controlling a first drive and a second drive to collectively turn the rotor blade into an operating position; detecting whether a failure of the first drive has occurred; activating, when the failure of the first drive has occurred, a first activatable lockout connected to the rotor blade, which prevents turning of the rotor blade into the operating position while allowing turning of the rotor blade into a feathered position; and controlling, when the failure of the first drive has occurred, the second drive to turn the rotor blade into the feathered position.
Abstract: A wind energy converter configured for transmitting power to an electric grid includes a variable ratio gear system mechanically coupled between a rotor and a generator. A control system is configured to mechanically control a rotational speed of the generator so that, during a low voltage event, the wind energy converter can continue to operate and supply power to the grid.