MD1616Z - Vertical axis wind turbines with power control - Google Patents

Abstract

The invention relates to wind energy-to-electrical energy conversion devices, in particular to vertical axis wind turbines with power control.The wind turbine, according to the invention, comprises a support tower (1), on the platform (2) of which is installed by means of a bearing (3) a vertical rotating shaft (4), one end of which is connected to a generator with permanent magnets (5), and the other end, by means of levers (7) and tubular levers (10), is connected to inclined blades (8), according to the first embodiment, or to vertical blades, according to the second embodiment. The lower part of the inclined blades (8) or vertical blades is rigidly connected by means of rods (7) to a lower bushing (6), rigidly fixed on the shaft (4), and the upper part of the inclined blades (8) or vertical blades is rigidly connected by means of tubular rods (10) to an upper bushing (9), installed on the shaft (4). Inside the tubular rods (10) are placed inertial elements (11), connected by means of elastic elements (12) to the upper bushing (9).

Description

The invention relates to devices for converting wind energy into electrical energy, in particular to vertical axis wind turbines with power control.

A vertical axis wind turbine is known, which includes a tower, a tubular main shaft, a mechanism for braking the speed of the wind turbine rotor, based on the use of centrifugal balls, brake discs and elastic elements. When the speed of the wind rotor exceeds a limit value, the centrifugal balls move under the action of centrifugal forces in the radial direction outwards, acting on the brake disc, moving it until it contacts the second brake disc [1].

A vertical axis wind turbine is also known, which contains a vertical tower, on which a vertical rotating shaft is installed, one end of which is connected to a permanent magnet generator, and the second end, by means of rotating bars, is connected to blades with an aerodynamic profile, made with the possibility of varying the angle of attack [2].

These technical solutions present a number of disadvantages, such as the complexity of the construction, the reduced safety of protecting the electric generator against overloads at high wind speeds.

The problem solved by the invention consists in increasing the protection of the electric generator from overloads through automatic power control and increasing the reliability of the dynamic mechanical elements of the turbine.

The vertical axis wind turbine with power control, according to the first embodiment, eliminates the above-mentioned disadvantages by comprising a tower-support, on a platform of which a vertical rotating shaft is installed through a bearing, one end of which is connected to a permanent magnet generator, and the other end, by means of bars and tubular bars, is connected to inclined blades with an aerodynamic profile, made with the possibility of varying the angle of attack. The lower part of the blades is rigidly connected by means of bars to a lower bushing, rigidly fixed to the shaft, and the upper part of the blades is rigidly connected by means of tubular bars to an upper bushing, installed on the shaft. Inside the tubular bars, inertial elements are placed, connected by elastic elements to the upper bushing, on the upper flange, on the top of which a friction disc is fixed, and on the bottom of a flange of the support tower, another friction disc is fixed, concentric with the friction disc of the upper bushing.

The vertical axis wind turbine with power control, according to the second embodiment, eliminates the above-mentioned disadvantages by comprising a support tower, on a platform of which a vertical rotating shaft is installed through a bearing, one end of which is connected to a permanent magnet generator, and the other end, by means of bars and tubular bars, is connected to vertical blades with an aerodynamic profile, made with the possibility of varying the angle of attack. The lower part of the blades is rigidly connected by means of bars to a lower bushing, rigidly fixed to the shaft, and the upper part of the blades is rigidly connected by means of tubular bars to an upper bushing, installed on the shaft. Inside the tubular bars, inertial elements are placed, connected by elastic elements to the upper bushing, on the upper flange, on the bottom of which a friction disc is fixed, and on the top of a flange of the support tower, another friction disc is fixed, concentric with the friction disc of the upper bushing.

The technical result of the invention consists in protecting the electric generator from overloads through automatic power control and high reliability of the dynamic mechanical elements of the turbine.

The invention is explained by the drawings in Fig. 1 - 6, which represent:

- Fig. 1, general view of the vertical axis wind turbine with power control, according to the first embodiment (initial phase);

- Fig. 2, general view of the wind turbine, according to the first embodiment (final phase);

- Fig. 3, section A-A of Fig. 2;

- Fig. 4, section B-B of Fig. 3;

- Fig. 5, general view of the wind turbine, according to the second embodiment (initial phase);

- Fig. 6, general view of the wind turbine, according to the second embodiment (final phase).

The vertical axis wind turbine with power control (fig. 1-4), according to the first embodiment, contains the support tower 1, on the platform 2 of which the vertical rotating shaft 4 is installed through the bearing 3, one end of which is connected to the permanent magnet generator 5, and the other end, by means of bars 7 and tubular bars 10, is connected to the inclined blades 8 with an aerodynamic profile, made with the possibility of varying the angle of attack. The bottom of the blades 8 is rigidly connected by means of bars 7 to the lower bushing 6, rigidly fixed on the shaft 4, and the top of the blades 8 is rigidly connected by means of tubular bars 10 to the upper bushing 9, installed on the shaft 4. Inside the tubular bars 10 are located inertial elements 11, connected by means of elastic elements 12 to the upper bushing 9, on the upper flange, on the top of which the friction disc 13 is fixed, and on the bottom of the flange 14 of the support tower 1 the friction disc 15 is fixed, concentric with the friction disc 13 of the upper bushing 9.

The vertical axis wind turbine with power control (fig. 5, 6), according to the second embodiment, contains the support tower 1, on the platform 2 of which the vertical rotating shaft 4 is installed through the bearing 3, one end of which is connected to the permanent magnet generator 5, and the other end, by means of the bars 7 and the tubular bars 10, is connected to the vertical blades 16 with an aerodynamic profile, made with the possibility of varying the angle of attack. The bottom of the blades 16 is rigidly connected by means of bars 7 to the lower bushing 6, rigidly fixed on the shaft 4, and the top of the blades 16 is rigidly connected by means of tubular bars 10 to the upper bushing 9, installed on the shaft 4. Inside the tubular bars 10 are located the inertial elements 11, connected by means of elastic elements 12 to the upper bushing 9, on the upper flange, from the bottom, of which the friction disk 17 is fixed, and on the upper flange 14 of the support tower 1 the friction disk 18 is fixed, concentric with the friction disk 17 of the upper bushing 9.

The vertical axis wind turbine with power control, according to the first embodiment, operates in the following manner.

At the nominal wind speed (up to v=10 m/s), when the inclined blades 8 with a determined aerodynamic profile interact (according to research results, at a certain helical angle of installation of blades 8 with a determined aerodynamic profile, the efficiency of converting wind energy into electrical energy is maximum), lifting forces appear, under the combined action of which (from all blades 8) the rotating shaft 4 will be driven into rotational motion, which will be transmitted to the generator 5, which will produce electrical energy. When the wind speed (v=10…20 m/s) is exceeded, the speed of the shaft 4 will increase, reaching n=200-400 min-1. As a result, the inertial elements 11 will overcome the elastic force of the elastic elements 12, and under the action of centrifugal forces, will move inside the tubular bars 10 towards the outside of the shaft 4. In this case, the moment of inertia of the shaft 4 increases, transforming into a relative flywheel, which will lead to a certain degree of uniformity of the rotation of the shaft 4. At the same time, this moment of inertia, thanks to a certain degree of flexibility of the blades 8, will lead to the relative rotation of the upper bushing 9 in relation to the shaft 4, which will lead to the straightening of the blades 8 and, as a result, the modification of the angle of attack of the blades 8 with the aerodynamic profile and the movement of the upper flange of the upper bushing 9 upwards, approaching the friction disk 15 fixed on the flange 14 of the support tower 1. Due to the variation of the angle of attack of the blades 8 with the aerodynamic profile, the conversion efficiency will be reduced, reducing the amount of electricity produced by generator 5, thus the latter being protected from overloads.

As the wind speed continues to increase (v=20…40 m/s), the inertial elements 11 will occupy the extreme outer position, the moment of inertia of the shaft 4 will be maximum and, therefore, the dynamic flywheel moment will still reach the maximum level, which will lead to further relative rotation of the upper bushing 9 relative to the shaft 4, deformation of the blades 8 within the limits of the degree of flexibility, straightening of the inclined blades 8 and, as a result, the movement of the upper bushing 9 upwards, until the contact of the friction disk 13 with the friction disk 15, thus achieving the braking of the shaft 4 and the reduction of the speed. This leads to the protection of the dynamic mechanical elements of the wind turbine from mechanical destruction, an important moment in the context that vertical axis wind turbines are urban or suburban. After the wind speed decreases, the blades 8 return to the initial inclined position, disconnecting the friction discs 13 and 15, and returning to the optimal angle of attack of the blades 8 with the aerodynamic profile. In the event of a new increase in wind speed, the process is repeated.

The operating principle of the vertical axis wind turbine with power control, according to the second embodiment, is similar to that of the first embodiment. In this case, since there are aerodynamic profiles for the blades of the rotating shafts of the vertical axis turbines for vertical (straight) blades, the vertical blades 16 ensure optimal efficiency of conversion of wind energy into electrical (mechanical) energy at the nominal wind speed. In the case when the wind speed increases (v=10-20 m/s) the blades 16, within the limits of the degree of flexibility, which they possess, will tilt, the upper bushing 9 will rotate relative to the shaft 4, and the upper flange of the upper bushing 9 with the friction disk 17 will move downwards, reducing the conversion efficiency. As the wind speed further increases (v=20…40 m/s), the process with the inertial elements 11 is repeated similarly to the first embodiment, and the upper bushing 9 with the friction disc 17 will move downwards until the friction discs 17 and 18 come into contact.

The proposed technical solution ensures power control and protection of dynamic mechanical elements from overloads through the aerodynamic and mechanical braking process through relatively simple constructive solutions.

1. CN 101363402 A 2009.02.11

2. KR 101555922 B1 2015.09.30

Claims (2)

1. Vertical axis wind turbine with power control, comprising a support tower (1), on a platform (2) of which a vertical rotating shaft (4) is installed through a bearing (3), one end of which is connected to a permanent magnet generator (5), and the other end, by means of bars (7) and tubular bars (10), is connected to inclined blades (8) with an aerodynamic profile, made with the possibility of varying the angle of attack; the lower part of the blades (8) is rigidly connected by means of bars (7) to a lower bushing (6), rigidly fixed on the shaft (4), and the upper part of the blades (8) is rigidly connected by means of tubular bars (10) to an upper bushing (9), installed on the shaft (4), at the same time, inertial elements (11) are placed inside the tubular bars (10), connected by means of elastic elements (12) to the upper bushing (9), on the upper flange, on the top of which a friction disc (13) is fixed, and on the lower part of a flange (14) of the support tower (1) another friction disc (15) is fixed, concentric with the friction disc (13) of the upper bushing (9). 2. Vertical axis wind turbine with power control, comprising a support tower (1), on a platform (2) of which a vertical rotating shaft (4) is installed through a bearing (3), one end of which is connected to a permanent magnet generator (5), and the other end, by means of bars (7) and tubular bars (10), is connected to vertical blades (16) with an aerodynamic profile, made with the possibility of varying the angle of attack; the lower part of the blades (16) is rigidly connected by means of bars (7) to a lower bushing (6), rigidly fixed on the shaft (4), and the upper part of the blades (16) is rigidly connected by means of tubular bars (10) to an upper bushing (9), installed on the shaft (4), at the same time, inertial elements (11) are placed inside the tubular bars (10), connected by means of elastic elements (12) to the upper bushing (9), on the upper flange, at the bottom, of which a friction disc (17) is fixed, and on the upper part of a flange (14) of the support tower (1) another friction disc (18) is fixed, concentric with the friction disc (17) of the upper bushing (9).