Embodiments herein describe operating a first wind turbine using an auxiliary control system when a high-voltage link coupling a wind park to a grid is not functioning. When using the auxiliary control system, the first wind turbine provides power to a local AC grid which can be used to power auxiliary system in a second wind turbine while the second wind turbine is shutdown. However, when the high-voltage link is functional, the first and second wind turbines provide power to the high-voltage link using a primary control system.

A method of performing a black start in a wind farm is provided, the wind farm including a primary black start enabled wind turbine, at least one secondary black start enabled wind turbine, and a wind farm grid interconnecting at least a part of the wind turbines in the wind farm, the method including (a) starting the primary black start enabled wind turbine in black start mode in order to supply voltage to the wind farm grid, (b) monitoring, at the at least one secondary black start enabled wind turbine, an electric parameter value in the wind farm grid, and (c) starting the at least one secondary black start enabled wind turbine in black start mode in order to supply voltage to the wind farm grid when the monitored electric parameter value meets a predetermined condition. A corresponding wind farm is also provided.

Provided is a rotation device for rotating a wind turbine generator configured to be rotated by wind and to convert wind energy into electrical energy. The rotation device includes at least one rotary device configured to couple with an outer surface of the wind turbine generator, and a motor device for driving the rotary device such as to thereby rotate the wind turbine generator about a generator rotation axis. The wind turbine generator can be rotated in a state in which the wind turbine is not operating. This can be useful for training purposes in a training nacelle, for maintenance purposes when storing the nacelle or during assembly of the nacelle.

The detecting a shadow is determined by a modeling of at least a portion of a wind turbine. First and second sensors are arranged relative to the model such that the first sensor detects a light and the second sensor detects a shadow during the conditions where the shadow would be produced.

A method of controlling a power system that includes an electrical machine, e.g., wind turbine generator, a power converter, a DC circuit and a dynamic braking system (DBS) having a braking circuit having a braking resistor and being connected in series to the DC circuit, is provided. The method includes operating the DBS and controlling operation of the electrical machine based on a prevailing temperature of the braking circuit, stopping the electrical machine and controlling the electrical machine to be restarted at its rated output power once the prevailing temperature of the braking resistor reaches or falls below a lower temperature threshold. The electrical machine may be restarted at a lower output power and after restarting, its output power can be increased based on a power starting profile as the braking resistor cools.

Provided is a wind turbine meteorological data collection and processing system that includes at least one wind turbine having a plurality of sensors configured to sense data including weather-related data, a controller configured to control the plurality of sensors, a processor configured to process the data, and a transmitter configured to transmit the data. The system also includes a computing platform in communication with the at least one wind turbine and to receive the data from the at least one wind turbine, and sort the data based on geographical location of the at least one wind turbine.

A wind generator, comprising: at least one wind wheel which is mounted to be rotatable around a rotational axis, and which has one or more blades or other wind-guiding surfaces for converting flow energy of wind into rotational energy, at least one generator, which is coupled to a hub or shaft of the wind wheel or to an output shaft of a gear connected thereto, for converting the rotational energy into electrical energy, wherein a center of gravity of the wind wheel, together with a hub and rotor shaft and rotatable parts which are coupled to the hub or rotor shaft and rotate around the same rotational axis, is translationally movable in a horizontal or approximately horizontal direction, characterized in that: the generator is either a direct current generator or is on its output side coupled to a rectifier to provide the electrical energy as direct current, and at least one energy storage is coupled to a direct current output of the generator or of the rectifier for receiving and storing the electrical energy.

A system for generating its own air currents to run electric turbines. The system includes: a vertical tower or support provided with a rotating disk at its upper end, up to four laterally extending arms connected to the disk, each arm carrying a wind turbine generator with rotating blades/rotors attached at its outer end, a planetary gear system having a central sun gear and motor associated with the rotating disk and a main controller system connected to the vertical tower base, wherein the main control system controlling the startup input source from a state power supply system and a solar system supply operating the central motor.

A method for operating a plurality of wind energy installations configured for supplying electric power to an electrical supply system, that each have an aerodynamic rotor with rotor blades and an electrical generator and also operating equipment, is disclosed. The wind energy installations are operated while they are not connected to the electrical supply system, where at least one of the wind energy installations produces electric power and inputs the electric power into a local DC voltage system that connects the wind energy installations if the at least one of the wind energy installations currently produces more power than needed for supplying its own operating equipment. Additionally or alternatively, the operating equipment is supplied totally or in part with power from the local DC voltage system if the at least one of the wind energy installations currently produces less power than needed for supplying its operating equipment.

An embodiment provides controllers modules that allow for an energy generation module, such as a wind turbine, to be restarted locally and remotely. To restart the energy generation module remotely, care is taken to ensure the module is not in lock down mode. Further, the adding the ability to remotely restart the module does not alter the code or logic used to locally restart the module. Other embodiments are described herein.