A wind power plant has at least one rotor. The rotor has at least two rotor blades and each rotor blade is rotatable about a substantially radially aligned adjustment axis. At least one angle adjustment device is provided for adjustment of the rotor blades. The angle adjustment device has a control disk and at least two cam disks interacting with the control disk. Each cam disk is rotatably mounted about a rotation axis. The rotation axis of the respective cam disk coincides, and is in particular superimposed, together with the respective adjustment axis of the respective rotor blade. The noise development, the maintenance expense, and/or costs of a wind power plant are reduced in that the cam disks are functionally effectively permanently coupled via at least one coupling element.

To provide a wind power generation device in which wind received at the convex-side surface of concave panel parts is guided into a front edge airflow reservoir, thereby making it possible to improve the reliability of starting at startup and to increase the amount of power generated.

Wind-receiving paddles 5 have: concave panel parts 51, which have a vertically elongated shape and which curve or bend in a concave shape on an inner-side surface 516 or an outer-side surface 515 in plan view; and front edge airflow reservoirs 52 formed in a projecting manner on a concave-side-surface 511 side along the longitudinal direction of front edge parts 513 of the concave panel parts 51 with respect to the direction of rotation, the tip section of the front edge airflow reservoirs 52 curving or bending towards the rear-edge side. Airflow guide paths 53 for guiding an airflow that strikes a convex-side surface 512 from the rear-edge side toward the concave-side-surface 511 side and to the front edge airflow reservoirs 52 are formed, on the concave panel parts 51, along the longitudinal direction of the wind-receiving paddles 5.

In one embodiment, a turbine shaft transmits mechanical power, a vane support structure is coupled to the turbine shaft, a vane is coupled to the vane support structure through a vane shaft, a balancing weight is coupled to a first location of the vane, and an alignment weight is coupled to a second location of the vane.

A variable-pitch vertical axis wind turbine comprises a hub supported for rotation about a central axis and a blade pivotally mounted to the hub so as to permit relative rotation between the blade and the hub. The blade and the hub define a pitch angle therebetween. The wind turbine comprises a mechanism configured to produce reciprocating motion during rotation of the hub about the central axis. The wind turbine comprises a linkage configured to transfer the reciprocating motion produced by the mechanism to the blade so as to vary the pitch angle.

A wind power plant has at least one rotor. The rotor has at least two rotor blades and each rotor blade is rotatable about a substantially radially aligned adjustment axis. At least one angle adjustment device is provided for adjustment of the rotor blades. The angle adjustment device has a control disk and at least two cam disks interacting with the control disk. Each cam disk is rotatably mounted about a rotation axis. The rotation axis of the respective cam disk coincides, and is in particular superimposed, together with the respective adjustment axis of the respective rotor blade. The noise development, the maintenance expense, and/or costs of a wind power plant are reduced in that the cam disks are functionally effectively permanently coupled via at least one coupling element.

A pitch control system characterized by a hub with at least two blade housings on the hub that are disposed around the hub axis. The blade housings have corresponding blades that engage with them. The blades spiral along housing longitudinal axes toward and away from the hub axis about a segment of helical path to effect a change in the pitch of each blade. One or more elastic members draw the blades toward the hub axis, either directly or indirectly. There are pitch mechanisms effective to facilitate blades to spiral around housing-longitudinal axes. A blade will spiral away from the hub axis when the centrifugal force exerted on the blade exceeds the opposing elastic force in the housing-longitudinal direction (neglecting other forces). Conversely, blades spiral toward the hub axis when said centrifugal force is less than said elastic force. There is an imaginary plane orthogonal to the hub axis. Housing-longitudinal axes have angles with respect to the imaginary plane of not more than 30 degrees.

A vertical axis wind turbine with shielded blade support includes a wind wheel rotating about a vertical rotation axis determined by a bearing body. The wheel includes a wheel frame rotatably connected to the bearing body and blades distributed on periphery of the frame. Upper and lower portions of the frame respectively have a blade support group. A baffle is connected to a tail section or end of each blade support distant from the axis and located between the tail section of the corresponding blade support and blade, or the edge of the baffle and the tail end of the corresponding blade support are integrally formed. The baffle at the upper portion corresponds to the respective baffle at the lower portion, and a corresponding blade is connected between the corresponding baffles. Two ends of the blade are connected to the corresponding baffles directly or connected via a connecting piece.

Methods and apparatuses for wind turbine vane pitch control are described. In one embodiment, a turbine shaft transmits mechanical power, a vane support structure is coupled to the turbine shaft, a vane is coupled to the vane support structure through a vane shaft, a balancing weight is coupled to a first location of the vane, and an alignment weight is coupled to a second location of the vane.

The present invention relates to a blade pitch control apparatus for a small size wind power generator. More specifically, the present invention relates to a blade pitch control apparatus for a small size wind power generator configured to accomplish continuous generation by continuously maintaining the necessary rotating force of the blade by systematically operating the ball screw, spinner driver, and pitch angle controller when the rotation number of blades exceeds the reference rotation number by over wind speed, so that the blade pitch is automatically controlled. To this end, the present invention comprises a blade combined with an outer circumference surface of a rotator, rotating by wind; a spinner box installed and fixed in the middle of the front surface of the blade; a ball screw formed with speed control wings at one end in a state positioned in the longitudinal direction in the middle of the spinner box and having screws at the other end; a spinner driver screw-combined with the screw of the ball screw, and moving to the front and back when the rotation number of blades exceeds the reference rotation number by over wind speed or when the wind speed decreases; and a pitch angle controller connected between the spinner driver and blade, folding and unfolding the blade according to the movement direction of the spinner driver to control the pitch angle of the blade.

The invention disclosed a vertical axis wind turbine with automatic blade adjustment of blade angle, comprising a pillar, a rotational axis disposed at the pillar, and a plurality of wind turbine assemblies rotating around the pillar. Each wind turbine assembly comprises a blade, a support, and a swing axis. The swing axis comprises an axial core element and an axis element, fixed to the blade and uses the axial core element to engage the support to make the blade to swing on the axial core element with an angle within 90. The blade comprises first and second blade areas, with an imaginary line of center of gravity dividing first and second blade areas. When the blade is at 0, the imaginary line overlaps the projection of centrifugal force direction of an extension line of axis of the swing axis, but the line shall not actually overlap the extension line.