RU88399U1 - WIND POWER PLANT - Google Patents

Abstract

1. Wind power installation, including a base with a support mounted on it, on which a frame is mounted, a shank mounted on the frame, and an electric generator, characterized in that two multi-tier wind wheels are vertically mounted in the frame, and the drive gears of the bevel gears are installed on the shaft of each wind wheel gears, driven gears of which are placed on a common power take-off shaft, connected through a V-belt transmission with an electric generator. ! 2. The wind energy installation according to claim 1, characterized in that in each tier the wings of the blades of one wind wheel are at an angle of 90 ° to the wings of the other wind wheel. ! 3. The wind power installation according to claim 1, characterized in that the shaft of one of the wind wheels through a crank is connected to a rod of a large diameter pneumatic cylinder, and the shaft of another wind wheel through a crank is connected to a rod of a small diameter pneumatic cylinder, one suction cylinder is connected to the rod and piston cavities of each pneumatic cylinder and one discharge valve, and the inputs of the suction valves of the large diameter pneumatic cylinder communicate with the atmosphere, the outputs of the pressure valves of the large diameter pneumatic cylinder communicate with the inputs of the suction valves of the small diameter pneumatic cylinder and the low pressure receiver, and the outputs of the discharge valves of the small diameter pneumatic cylinder communicate with the high pressure receiver. ! 4. Wind power installation according to claim 1, characterized in that on the frame in front of the wind wheels two pairs of guides are installed, consisting of parallel plates mounted vertically and with a height equal to the height of the wind wheels, each pair being directed

Description

The utility model relates to wind energy, in particular to installations, with the axis of rotation of the rotor perpendicular to the direction of the wind and converting wind energy into energy of compressed air.

Known wind storage power plant (patent RU No. 2101562 C1, 6F03D 9/00, published 01.10.1998), which includes a wind turbine and a kinematically associated compressor, as well as a piping system for supplying compressed air.

Known rotary engine with a vertical shaft of rotation (patent RU No. 2263815 C1, 7F03D / 00, published 11.10.2005), containing a rotor, in which the working bodies are blades made in the form of a part of a hollow cylinder, mounted on a vertical shaft.

Closest to the proposed utility model is a wind farm (patent for utility model RU 79313 U1, F03D 3/00, published December 27, 2008), which has a frame with a rotor, on which a wind wheel is mounted, shutters for changing the direction of wind flow and a system for transmitting rotor rotation to an electric generator.

An increase in the power of such an installation is achieved by increasing the area of the rotor blades, and hence the area of the shutters that block the flow entering the non-working part of the blades, which leads to a heavier installation and lower its efficiency.

The technical result of the utility model is to increase the efficiency of the installation and expand its functionality.

The specified technical result is achieved by the fact that the wind power installation, which includes a base with a support mounted on it, on which a frame is mounted, a shank mounted on the frame and an electric generator, is equipped with two multi-tier wind wheels, bevel gears, driven gears are installed on the shaft of each wind wheel which are placed on a common power take-off shaft connected through a V-belt drive with an electric generator; in each tier, the wings of the blades of one wind wheel are at an angle of 90 ° to the wings of the other wind wheel; the shaft of one of the wind wheels through a crank is connected to the rod of a large diameter pneumatic cylinder, and the shaft of another wind wheel through a crank is connected to the rod of a cylinder of small diameter, one suction and one discharge valve are connected to the rod and piston cavities of each pneumatic cylinder, the inputs of the suction valves of a large diameter cylinder being connected with the atmosphere, the outputs of the discharge valves of the large diameter pneumatic cylinder communicate with the inputs of the suction valves of the small diameter pneumatic cylinder and a receiver of low pressure, and the outputs of the discharge valves of the pneumatic cylinder of small diameter communicate with the receiver of high pressure; two pairs of guides are installed on the frame in front of the wind wheels, consisting of parallel plates mounted vertically and with a height equal to the height of the wind wheels, each pair of guides forming a slotted channel, and the channel axes are located relative to each other at approximately an angle of 80 °; reflecting screens are vertically mounted on the frame behind the wind wheels, which form approximately one fourth of the cylindrical side surface.

The installation of two multi-tier windwheels, the wings of which in each tier are always located at an angle of 90 °, as well as the installation of guide and reflective screens, can increase the efficiency of the installation. The introduction of pneumatic cylinders of different diameters with a system of suction and discharge valves allows you to accumulate compressed air in the receivers of high and low pressure and thereby expand the functionality of the installation.

Figure 1 shows a schematic diagram of a wind power installation, figure 2 shows a top view of the installation.

On the base 1, a support 2 is fixed, on which a frame 4 is mounted in the movable sealed connection 3. On the frame 4, the shafts 5 and 6 of multi-tier (at least two tiers) wind wheels 7 and 8 are vertically mounted. The tier of each wind wheel includes max 9 (figure 2), mounted on the shaft, with blades 10 mounted on them (two in each tier). The blades 10 are made in the form of vertically arranged half cylinders. The swings of the adjacent tiers of each wind wheel form an angle of 180 °: n, where n is the number of tiers. Machs located in the same tier, but belonging to different windwheels, form a 90 ° angle between themselves.

On each of the shafts 5, 6 (Fig. 1), the bevel gears of the bevel gears 11 and 12 are installed, the driven gears of which are placed on the power take-off shaft 13. A V-belt drive pulley 14 is installed on the power take-off shaft 13, the driven pulley of which is mounted on the shaft electric generator 15.

The shaft 5 of the wind wheel 7 through the crank 16 is connected with the rod of the pneumatic cylinder 17, and the shaft 6 of the wind wheel 8 through the crank 18 is connected with the rod of the pneumatic cylinder 19, and the diameter of the pneumatic cylinder 17 is larger than the diameter of the pneumatic cylinder 19.

The piston cavity of the pneumatic cylinder 17 is connected with the outlet of the suction valve 20 and the inlet of the discharge valve 21, and the rod cavity of this pneumatic cylinder is connected with the output of the suction valve 22 and with the inlet of the discharge valve 23.

The piston cavity of the pneumatic cylinder 19 is connected with the outlet of the suction valve 24 and the inlet of the discharge valve 25, and the rod cavity of this pneumatic cylinder is connected with the output of the suction valve 26 and with the inlet of the discharge valve 27. The inputs of the valves 20 and 22 communicate with the atmosphere. The outputs of the valves 21 and 23 through the annular groove of the movable connection 3 are connected with the inputs of the valves 24 and 26, as well as with the low pressure receiver 28. The outputs of the valves 25 and 27 through the movable connection 3 are connected with the receiver of high pressure 29.

On the frame 4 (figure 2) in front of the wind wheels 7, 8 two pairs of guides 30 and 31 are installed. Each pair of guides consists of two parallel plates mounted vertically and with a height equal to the height of the wind wheels. Each pair of guides forms a slot channel 32 and 33, through which the air flow is directed to the working blades of the wind wheels. The axis of the channels 32 and 33 are located relative to each other at approximately an angle of 80 °.

Behind the wind wheels 7, 8, reflecting screens 34 and 35 are vertically mounted on the frame 4, which form approximately one fourth of the lateral cylindrical surface. Shank 36 is also attached to the frame.

Wind power installation works as follows.

The wind flow, acting on the shank 36, turns the frame 4 around the support 2 in a position in which the plane of the shank becomes parallel to the flow.

The wind flow passing through the slotted channels 32 and 33 acts on the concave planes of the blades 10 of the wind wheels 7 and 8. At the same time, the guides 30, 31 limit the wind flow acting on the convex planes of the blades 10. Thus, the wind wheel 7 rotates clockwise and the wind wheel 8 is counterclockwise.

Reflective screens 34 and 35 direct part of the wind flow to the concave planes of the blades 10, increasing torques. The torques created by the windwheels 7 and 8 (Fig. 1) are transmitted through bevel gears 11 and 12 to a common power take-off shaft 13 and, accordingly, to a drive belt pulley 14 of a V-belt drive, by means of which the shaft of the generator 15 is rotated.

The rotational movement of the wind wheel 7 by means of the crank 16 is converted into reciprocating motion of the piston with the rod of the pneumatic cylinder 17. When the rod of the pneumatic cylinder 17 is pulled in, the suction valve 21 opens and the discharge valve 23 closes, that is, air is sucked from the atmosphere into the rod cavity. At the same time, the suction valve 20 is closed and the pressure valve 21 is opened. Compressed air flows through the pipelines and through the movable tight connection 3 to the low pressure receiver 28. When the rod of the pneumatic cylinder 17 is extended, the suction valve 22 closes and the suction valve 20 opens. Atmospheric air is sucked into the piston cavity of the pneumatic cylinder 17. At the same time, the discharge valve 23 opens and the compressed air enters the low pressure receiver 28.

The rotational movement of the wind wheel 8 by means of the crank 18 is converted into a reciprocating motion of the piston with the rod of the pneumatic cylinder 19. When the rod of the pneumatic cylinder 19 is pulled in, the suction valve 26 opens and the pressure valve 27 closes, i.e., air is sucked from the low pressure receiver 28 into the rod cavity. At the same time, the suction valve 24 is closed and the discharge valve 25 is opened. Compressed air flows through the pipelines and through the movable tight connection 3 to the high pressure receiver 29. When the rod of the pneumatic cylinder 19 is extended, the suction valve 26 closes and the suction valve 24 opens. The air is sucked from the low pressure receiver 28 into the piston cavity of the pneumatic cylinder 19. At the same time, the discharge valve 27 opens and the compressed air enters the high pressure receiver 29.

Thus, the wind power installation allows you to receive both electrical energy and compressed air. During the operation of the machine, the wind wheels located in the same tier are always located relative to each other at an angle of 90 °. This allows mutual overlap of the blades of the wind wheels at the moment they are in the inoperative zone, to reduce the total width of the guides overlapping this zone, and by introducing reflective screens to increase the torque of both wind wheels and thereby increase the efficiency of the installation.

Claims (5)

1. Wind power installation, including a base with a support mounted on it, on which a frame is mounted, a shank mounted on the frame, and an electric generator, characterized in that two multi-tier wind wheels are vertically mounted in the frame, and the drive gears of the bevel gears are installed on the shaft of each wind wheel gears, driven gears of which are placed on a common power take-off shaft, connected through a V-belt transmission with an electric generator. 2. The wind energy installation according to claim 1, characterized in that in each tier the wings of the blades of one wind wheel are at an angle of 90 ° to the wings of the other wind wheel. 3. The wind power installation according to claim 1, characterized in that the shaft of one of the wind wheels through a crank is connected to a rod of a large diameter pneumatic cylinder, and the shaft of another wind wheel through a crank is connected to a rod of a small diameter pneumatic cylinder, one suction cylinder is connected to the rod and piston cavities of each pneumatic cylinder and one discharge valve, and the inputs of the suction valves of the large diameter pneumatic cylinder communicate with the atmosphere, the outputs of the pressure valves of the large diameter pneumatic cylinder communicate with the inputs of the suction valves of the small diameter pneumatic cylinder and the low pressure receiver, and the outputs of the discharge valves of the small diameter pneumatic cylinder communicate with the high pressure receiver. 4. The wind power installation according to claim 1, characterized in that on the frame in front of the wind wheels two pairs of guides are installed, consisting of parallel plates mounted vertically and with a height equal to the height of the wind wheels, each pair of guides forming a slotted channel, and the channel axes are located relative to each other at about an angle of 80 °. 5. Wind power installation according to claim 1, characterized in that reflective screens are vertically mounted on the frame behind the wind wheels, in shape representing approximately one fourth of the lateral cylindrical surface.