MD681Z - Wind turbine - Google Patents

Abstract

The invention relates to wind-power engineering, namely to wind turbines designed for individual consumers.The wind turbine comprises a rotor with blades (1) with aerodynamic profile, fixed into a gondola (2), mounted with the possibility of rotation around a mast by means of a kinematic chain consisting of two worm gearings, two tail-vane wheels, symmetrically placed on a common shaft on both sides of the gondola (2), and an electric or thermal energy generator (7), mounted between the sections of the mast. The rotor shaft (5) is kinematically connected to the shaft (6) of the energy generator (7) via a multiplier (8) with bevel gearwheels (9, 10). The output shaft (11) of the multiplier (8), rigidly connected to the bevel gearwheel (10), is connected to the shaft (6) of the energy generator (7) via a coupling (12), a torsion shaft (13) and a toroidal coupling with elastic element (14). The worm wheel of one of the worm gearings, which is meshed with the worm wheel of the tail-vane wheels, is rigidly installed on a tubular frame, fixed with a flange on the upper end of the mast. The output shaft (11) of the multiplier (8) is installed with the possibility of rotation on the journal-thrust bearings inside the tubular frame. The gondola (2) is installed by means of a self-adjustable roller bearing and a radial bearing on the outer surface of the tubular frame with the possibility of rotation around the axis of the mast.

Description

The invention relates to wind energy, namely to wind turbines intended for individual consumers.

A horizontal-axis wind turbine is known, the rotor of which drives an eddy-current heater. The magnetic field is generated in the space between the rotor and the stator of the heater. The heat generated by the rotor is transported by air currents to the outside to the beneficiary for heating a house or other space. The excitation of the magnetic field, and therefore the amount of heat generated, is controlled as a function of such parameters as wind speed, ambient temperature and the temperature produced by the eddy-current heater. Ensuring the transformation of wind energy directly into thermal energy, the technical solution nevertheless has a complicated construction, based on the use of a whole system of sensors and offers limited functional possibilities [1].

A horizontal axis wind turbine is also known, which includes a tower, on which a rotor with blades is installed, located on a hub in a nacelle, installed with the possibility of rotation around the tower, as well as an electric generator, the shaft of which is directly connected to the shaft of the rotor with blades, at the same time the nacelle is installed on a plate with the possibility of its rotation in the horizontal plane around the vertical axis of the tower and in the vertical plane around the axis of the rotor. A hydraulic cylinder is installed in the nacelle, the housing of which is hingedly connected to the plate at a set distance from the axis of rotation of the wind rotor, and the stock of the hydraulic cylinder is connected to the nacelle. The angle of inclination of the nacelle in the vertical plane is a function of the voltage generated at the terminals of the electric generator, at the same time on both sides of the nacelle a wind wheel is located, installed on a common shaft, kinematically connected with a drive mechanism with a high transmission ratio, with the possibility of orienting the rotor with blades in the direction of the wind. Having a relatively simple construction, the known technical solution offers, however, relatively limited functional possibilities, a relatively low conversion efficiency of wind energy into useful energy [2].

The problem that the invention solves consists in increasing conversion efficiency, simplifying construction and broadening functional possibilities.

The problem is solved by the fact that the wind turbine contains a rotor with blades with an aerodynamic profile, fixed in a nacelle, installed with the possibility of rotation around the tower by means of a kinematic chain consisting of two worm gears, two wind wheels, symmetrically placed on a common shaft on both sides of the nacelle, and an electric or thermal energy generator, mounted between the tower sections. The rotor shaft is kinematically connected to the energy generator shaft by means of a multiplier with bevel gears, at the same time the output shaft of the multiplier, rigidly connected to the bevel gear, is connected to the energy generator shaft by means of a coupling, a torsion shaft and a toroidal coupling with an elastic element. A worm wheel of a worm gear, which meshes with the worm wheel of the wind wheels, is rigidly installed on a tubular casing, fixed with a flange on the upper end of the tower. The output shaft of the multiplier is mounted with the possibility of rotation on radial-axial bearings inside the tubular housing. The nacelle is mounted by means of a self-aligning roller bearing and a radial bearing on the outer surface of the tubular housing with the possibility of rotation around the axis of the tower.

The thermal energy generator can be with eddy currents or with the effect of transforming mechanical energy directly into thermal energy.

The multiplier can be selected so that the angular velocity of the input shaft of the power generator is greater than the angular velocity of the rotor.

The "windshield-nacelle-tower" kinematic chain is equipped with two worm gears with both left-hand (or both right-hand) worms, so that the windshield wheels under the action of air currents are placed in the downstream area of the aerodynamic rotor, and the wheel of one of the worm gears is installed fixedly on a vertical tubular casing fixed to the tower, on which the nacelle is placed with the possibility of its rotation around the tower and, respectively, the body of the energy generator.

The output shaft of the bevel gear multiplier is kinematically connected to the power generator shaft by means of a torsion shaft equipped at both ends with a coupling, one of which at high speeds brakes the power generator rotor shaft.

The wind turbine according to the invention provides the following advantages:

- constructive simplicity, electronics being replaced by aerodynamic orientation, does not include an energy collector, which allows the wind turbine to rotate around the tower in one direction, orienting itself to the direction of the wind;

- it has increased efficiency in transforming wind energy into useful (thermal) energy, starting with the minimum rotor speeds, while in the electric version the batteries are charged only when the wind rotor speed is > 80 min-1;

- also, the wind turbine can transform wind energy into thermal energy with increased efficiency even when the wind rotor speed is >180 min-1 (in the case of the electric version, when the wind rotor speed is >180 min-1, the rotor must be removed from the wind);

- the wind turbine is simpler to operate and more reliable and can be used in rural areas for heating.

The invention is explained by the drawings in Fig. 1-7, which represent:

- Fig. 1, wind turbine with energy generator, side view;

- Fig. 2, wind turbine with energy generator, front view;

- Fig. 3, the connection node of the three-bladed wind turbine rotor shaft with the energy generator shaft;

- fig. 4, node I from fig. 3;

- Fig. 5, three-dimensional view of node I in Fig. 3;

- Fig. 6, view A of Fig. 1;

- fig. 7, section B-B of fig. 6.

The wind turbine according to Fig. 1 and 2 includes a rotor with blades 1 with an aerodynamic profile, fixed in a nacelle 2, installed with the possibility of rotation around the tubular tower 3, made in sections, two wind wheels 4, symmetrically placed on both sides of the nacelle. The shaft 5 (fig. 3, 4) of the rotor is kinematically connected to the shaft 6 of the energy generator 7 by means of a multiplier 8 with bevel gears 9, 10. The output shaft 11 of the multiplier 8, rigidly connected to the bevel gear 10, is connected to the shaft 6 of the energy generator 7 by means of a coupling 12, a torsion shaft 13 and a toroidal coupling with an elastic element 14. The shaft 15 (fig. 6, 7), on the ends of which the windlass wheels 4 are installed, is rigidly connected to the worm 16 of the first stage of the worm transmission, which meshes with the worm wheel 17, rigidly installed on the end of the worm 18 of the second stage of the worm transmission. The worm wheel 19 of the second stage of the worm transmission, which meshes with the worm 18, is rigidly installed on a tubular housing 20, fixed with a flange 21 on the upper end of the tower 3. At the same time, the output shaft 11 of the multiplier 8, rigidly connected with the bevel gear 10, is installed with the possibility of rotation on the radial-axial bearings 22 inside the tubular housing 20. The gondola 2 is installed by means of a self-adjusting roller bearing 23 and a radial bearing 24 on the outer surface of the tubular housing 20 with the possibility of rotation around the axis of the tower 3. Both worms 16 and 18 are right-handed or left-handed.

The wind turbine operates in the following way.

When the rotor 1 interacts with the air currents, it is driven into a rotational motion, which is transmitted to the shaft 5. The rotational motion of the shaft 5, multiplied in the multiplier 8 by the pair of bevel gears 9 and 10, is transmitted to the shaft 11, which through the torsion shaft 13 drives the rotor of the energy generator 7 into a multiplied rotational motion, producing electrical energy, thermal energy with eddy currents or thermal energy with the effect of transforming mechanical energy directly into thermal energy through internal friction forces in the fluid or through pressure differences.

When the wind direction changes, the blades of the wind wheel 4 interact with the air currents, driving the wind wheel 4, rigidly installed on the shaft 15, into rotation. The rotational movement of the shaft 15 is transmitted to the worm 16 and reduced in the worm gears of the first stage (worm 16 and worm wheel 17) and the second stage (worm 18 and worm wheel 19), thus the worm wheel 19 is given a reduced rotational movement with increased torque. Due to the fact that the worm wheel 19 is rigidly connected by the tubular casing 20 to the tubular tower 3 of the wind turbine, which is immobile, the reactive torque drives the nacelle 2, installed on bearings on the fixed tubular casing 20, into rotational motion around the axis of the tower 3 until the rotor is oriented in the direction of the wind. In this position, the wind wheels 4 will be removed from the action of the wind and will stop rotating. The process is repeated in the event of a change in the wind direction.

In case of high wind speeds, the toroidal coupling will ensure braking of the shaft 6 of the energy generator 7.

Due to the execution of both screws 16 and 18 with the right or left propeller direction, self-braking is ensured, excluding arbitrary rotation of the gondola 2 around the tower 3.

Thus, the proposed wind turbine ensures:

- constructive simplicity, electronic orientation to the wind direction being replaced with aerodynamic orientation;

- does not include an energy collector, because, by orienting itself to the wind direction, the wind turbine can rotate around the tower in only one direction;

- increased efficiency of transforming wind energy into useful (thermal) energy, starting with minimum rotor speeds, while in the electric version the batteries are charged only when the wind rotor speed is > 80 min-1;

- operation with increased efficiency of the transformation of wind energy into thermal energy also when wind rotor > 180 min-1 (in the case of the electric variant when wind rotor > 180 min-1 the rotor must be removed from the action of the wind);

- simplicity in operation and increased reliability.

1. US 4421967 A 1983.12.20

2. MD 4219 B1 2013.04.30

Claims (3)

1. Wind turbine, comprising a rotor with blades (1) with an aerodynamic profile, fixed in a nacelle (2), installed with the possibility of rotation around the tower (3) by means of a kinematic chain consisting of two worm gears, two wind wheels (4), symmetrically placed on a common shaft (15) on both sides of the nacelle (2), and an electric or thermal energy generator (7), mounted between the sections of the tower (3); the rotor shaft (5) is kinematically connected to the shaft (6) of the energy generator (7) by means of a multiplier (8) with bevel gears (9, 10), at the same time the output shaft (11) of the multiplier (8), rigidly connected to the bevel gear (10), is connected to the shaft (6) of the energy generator (7) by means of a coupling (12), a torsion shaft (13) and a toroidal coupling with an elastic element (14); a worm wheel (19) of a worm transmission, which meshes with the worm wheel (18) of the wind wheels (4), is rigidly installed on a tubular housing (20), fixed with a flange (21) on the upper end of the tower (3); the output shaft (11) of the multiplier (8) is installed with the possibility of rotation on radial-axial bearings (22) inside the tubular housing (20); the nacelle (2) is installed by means of a self-adjusting roller bearing (23) and a radial bearing (24) on the outer surface of the tubular housing (20) with the possibility of rotation around the axis of the tower (3). 2. Wind turbine, according to claim 1, characterized in that the thermal energy generator is with eddy currents or with the effect of transforming mechanical energy directly into thermal energy. 3. Wind turbine according to claim 1, characterized in that the multiplier (8) is selected such that the angular velocity of the input shaft of the energy generator (7) is greater than the angular velocity of the rotor.