The invention concerns a method of operating a wind power installation in which the rotor is brought to a halt and fixed, comprising the steps: braking the rotor, positioning the rotor at a stopped position, and fixing the rotor in the stopped position. According to the invention it is provided that an end position is predetermined, the rotor is braked in regulated fashion to a stopped position associated with the end position, and for positioning for the predetermined end position the rotor is braked in an automated procedure until stopped at the stopped position, and for fixing in the stopped position a mechanical fixing device is applied, in particular automatically.

A wind turbine including a generator with a stator and a rotor, a cooling arrangement, a wind turbine brake including a brake disk and a caliper with brake pads is provided. An air duct with a filter is located near the brake pads of the caliper. During the operation of the cooling arrangement, a part of the air flow is guided via the brake pads. The brake dust produced by the brake pads during operation of the brake will be reduced by the filter of the air duct.

A disk brake for a brake disk ring of an azimuth drive of a wind turbine includes a brake housing which has two housing halves that, on opposite sides, flank receiving jaws for the brake disk ring. At least two brake pistons which hydraulically act upon friction lining carriers assigned to the receiving jaws are mounted in each housing half. At least one housing half has a cleaning channel, extending from a rear side of the housing and towards a front housing area, in which the receiving jaws and the friction lining carriers are provided.

A rotor arresting device for a wind turbine, to a wind turbine and to methods for arresting and for moving a rotor of a wind turbine. A rotor arresting device for a wind turbine having a rotor and a rotation assembly which is connected to the rotor in a rotationally rigid manner, comprising at least one coupling device which can be arranged on a static assembly, which is positionally fixed relative to the rotation assembly, of the wind turbine, having a first actuator, a second actuator, and a coupling element which is connected to the first and the second actuator, and a counterpart coupling element which can be arranged on the rotation assembly, wherein the coupling element and the counterpart coupling element are releasably connected, preferably in a form-fitting manner, in an arresting position of the coupling device.

A system for controlling pitch angle of a blade of a wind turbine is provided. The system may comprise a switched reluctance motor and an inverter. The motor may be configured to be positioned at a hub of the wind turbine and coupled to the blade. The motor may have a stator and a rotor. The stator may have: (i) multiple stator poles and (ii) coil windings around each of the multiple stator poles. The rotor may be rotatably mounted with respect to the stator. The rotor may have multiple rotor poles and a rotor shaft configured to be coupled to the blade to control the pitch angle of the blade. The inverter may be configured to supply electrical power to the coil windings to control motion of the rotor shaft in response to receiving a pitch angle control signal from a pitch angle control system of the wind turbine.

A wind power generating device includes: a power source assembly and a power generating assembly, the power source assembly including a brake disc and a brake actuator, the brake actuator being configured to swing around a lever fulcrum, and the brake actuator being provided with a wind collector on one side with respect to the lever fulcrum to receive wind force and a brake pad corresponding to the brake disc on the other side such that when the wind collector swings backward because of wind force from the front, the brake pad relatively swings frontward to touch the brake disc by leverage so as to apply a brake force to a rotor component of the power source assembly, and the power generating assembly including a maximum power point tracker (MPPT) such that the generated electric energy is stored to an energy storage element under control of the MPPT.

An airborne device comprising a wind turbine with an axis of rotation, an airborne structure configured to support the wind turbine, a lift system configured to keep the airborne structure in flight, at least one belt for transmitting a rotational movement of the wind turbine to a ground station, said belt being guided by at least one ground-based return pulley, wherein each ground-based return pulley is rigidly secured to a pivoting shaft, is positioned in a guide plane perpendicular to the pivoting shaft and is configured to guide the belt, wherein the axis of rotation of the wind turbine and the guide plane of each ground-based return pulley form an angle of less than 60.

The present disclosure is directed to a tool for removing a brake piston from a brake assembly of a wind turbine. The tool includes a base member configured for placement on a surface of a brake piston sleeve. The tool also includes a puller assembly configured for insertion into an inner cavity defined by the brake piston. The puller assembly includes a first shaft and a collet coupled to the first shaft. The first shaft is moveable relative to the base member. The collet is configured to engage an inner surface of the brake piston. Moving the first shaft relative to the base member slides the brake piston relative to the brake piston sleeve.

A servicing system (30 or 300) for servicing a brake device (24) of a brake system comprising the brake device (24) and a brake disc (22) is described. The servicing system (30 or 300) includes a frame (32 or 302), and the servicing system (30 or 300) is further configured for mounting the frame (32 or 302) in a fixed position relative to the brake disc (22), supporting the brake device (24) to allow the brake device (24) to be moved on the frame (32 or 302) relative to the brake disc (22) and lifting the brake device (24) to allow the brake device (24) to be raised or lowered relative to the brake disc (22).

The present invention relates to adjustment and/or drive units which can be used in wind power plants for adjusting the azimuth angle of the nacelle of the wind power plant or the pitch angle of the rotor blades, wherein such an adjustment and/or drive unit has at least two adjusting drives for rotating two assemblies which are mounted so as to be rotatable relative to each other, and has a control device for controlling the adjusting drives. Said control device controls the adjusting drives in such a manner that the adjusting drives are braced relative to each other during the rotation of the two assemblies and/or when the assemblies are at standstill. The invention further relates to a wind power plant comprising such an adjustment and/or drive unit, and to a method for controlling such an adjustment and/or drive unit. According to the invention, the control device comprises a bracing-adjustment device for variably adjusting the intensity of the bracing of the adjusting drives as a function of a variable external load on the assemblies being adjusted, wherein said intensity can be determined by means of a load determining device. According to another aspect of the invention, an overload protection is included, wherein the individual loads of the individual adjusting drives are determined by load determining devices and, in the event that an adjusting drive reaches overload, the distribution of the drive torques is modified in such a manner that the adjusting drive reaching overload is relieved or at least not further loaded, and at least one further adjusting drive is more heavily loaded in a supporting manner or is less heavily loaded in a bracing manner.