RU97100823A - MULTI-INSTALLING ROTOR VANE SYSTEM AS A UNITED WIND TURBINE - Google Patents

Claims (7)

1. A multi-installation, rotor blade single wind turbine consists of a rotor turbine (100) located downwind of the main rotor blade (110), including an input differential gear mechanism (130) located at the rear of the gearbox assembly (300), containing a bevel and planetary gears, located against the wind of the additional rotor blade (210) of the rotor turbine (200), connected with a fixed device, rotatably connected to the front of the gearbox assembly (300), containing a conical and planetary gear In addition, the rotor turbine (200) takes part in the rotation of the rotor blade (110), while in an alternative embodiment, the super-large wind turbine consists of three main multi-element rotor turbines (500), each of which has a rotor blade (531) installed on hollow supporting extenders (511) of the input axial shaft (510) of the rotor turbines (500), while the rotational forces are transmitted to the input bevel gears (520), (521) through the extensions (511) and are connected to the bevel gears (132, 132) that revolve around stationary bevel gears (131) of the hub of the main rotor unit, and a pair of input bevel gears (310), a set of planetary gears (320), which are mounted on the cylindrical inner surface of four bevel gears (310), respectively, of the gear unit (300), which effectively increases the rotational force of two low-speed horizontal axial shafts (150), (230), and a high-speed rotational output axial shaft (420), through which the output force is transmitted to perpendicular located generator (410).  2. A multistage, rotor blade single wind turbine according to claim 1, wherein the diameter of rotation of the additional rotor blade (210) of the turbine (200) is almost equal to the dimensions of the extensions (111) of the rotor turbine (100), so that normal wind force is applied to the wind of the main rotor blade (110) of the rotor turbine (100) without any turbulent effects caused by the additional rotor blade.  3. A multi-seat, rotor blade single wind turbine according to claim 1, wherein the differential gear parts (130) of the input rotor hub of the rotor turbine (100) include a bevel gear (131) attached to a frame (140) of a rotational vertical bevel gear (133), attached during rotation to the rotor turbine (100), and the input shaft (150) and three input bevel gears (132), rotatably attached to one end of the three extension (111) of the rotor blade (110) and connected with bevel gear a gear (133) rotating in engagement with a bevel gear (131) in order to align the rotational angular velocity of both rotor turbines (100) and (200) aerodynamically.  4. A multistage, rotor blade single wind turbine according to claim 1, wherein the actuators (120), (220) and (532) of the turbine blade pitch control system comprise a microprocessor-controlled actuator (124) that can rotate clockwise or counterclockwise arrows together with an executive gear part (123) and an associated worm gear (122) attached to the worm gear (121), which is mounted on one end of the extension cord (111), (211), (530), and these mechanisms are activated for achieving an optimal angle for n obtaining the optimal coefficient of angular velocity in order to obtain maximum efficiency during operation at a given wind speed, and regulating flow stall during storm control or stopping in case of danger.  5. A multi-seat, rotary blade single wind turbine according to claim 1, wherein the gearbox assembly (300) comprising a bevel and planetary gears consists of a bevel gear located at the top (311) and a bevel gear located at the bottom (312), which are engaged with respect to a pair of input bevel gears (314) and (313) that are mounted on one end of the axial shafts (150) and (230), while an alternative embodiment of the combined gearbox assembly (300) comprising a bevel gearbox and planetary gears, equipped with an additional bevel gear located at the top (311-1) and a bevel gear located at the bottom (312-1), which are engaged with a bevel gear having a double diameter (314-1), instead a bevel gear (314) attached to one end of the input rotor shaft (150), and planetary gear parts (320) are located in the central cylindrical space and contain vertical bevel gears (314-1), (313) installed which can be rotated in opposite directions, and pairs of horizontal, located at the top and bottom, rotating in opposite directions, bevel gears (311), (311-1) and (312), (312-1), respectively. 6. Multipurpose, rotor blade single wind turbine according to paragraphs. 1 and 7, in which the gearbox assembly (300), comprising a bevel and planetary gears, comprises a planetary gear carrier consisting of a set of three planetary gears (323) perpendicular to 120 ^o with respect to the horizontal bevel gear mounted at the top (311) located on the upper surface and facing down, and the ring gear (322), perpendicular to the bottom and facing up to the lower horizontal bevel gear (312), while the planetary gear carrier (311), including planetary gears (323), and the ring gear (312) rotate in opposite directions at the same speed, while the planetary gear (323) rotates around a centrally located sun wheel (321) associated with vertical rotational shaft (420), thereby determining the gearing coefficient at the output of the gear unit (300) as 1 + 2ZR / ZS, where ZS denotes the number of teeth of the sun wheel (321), ZR denotes the number of teeth of the ring gear (322).  7. A multi-seat, rotary blade single wind turbine according to claim 1, wherein the input bevel gear (132, 132 ′) is attached to one end of the input rotary axial shaft (510, 111), and is connected to the input conical gear from the other end. a gear (521), which is connected to a bevel gear (520), respectively, of the rotor turbine (500), while all the elements rotate in the engagement position with the perimeter of the bevel gear (131) of the hub of the rotor assembly of an extra-large wind turbine.