RU2611139C2 - Hydro-wind power installation - Google Patents

Abstract

FIELD: mechanical engineering.

SUBSTANCE: unit is designed for converting the water or wind flow energy and comprises a base 1, a shaft 3, the rotor 4 is rigidly mounted on a shaft 3 rotatable about its own axis, the blades 10 mounted with the possibility to change its position in relation to the flow, the loading device. The installation is provided with a housing 2, mounted on the base 1, which accommodates a shaft 3, rotatable sleeve 5, mounted in the bore of the rotor 4, the arms with rollers, which are rigidly attached to the rotary sleeve 5, the main cam 8 with projections and depressions, seated on the disk 9, mounted on the housing 2, a chain drive 16 for transmitting the rotational loading device from the blades 10, springs. The blades 10 are mounted in the holes of rotor 4 perpendicularly to the axis of rotor rotation 4. Rollers with levers are mounted for rolling on the protrusions and depressions of the primary cam 8, overcoming the spring force, and turning vanes 90º and back along with the setting of the blade 10, perpendicular to the flow in the working phase and in broken along the flow.

EFFECT: creation of a powerful and user-friendly operation of the plant.

5 cl, 15 dwg

Description

Technical field

The invention relates to the field of power mechanisms, namely to wind and water engines, and can be used to drive a fan when ventilating rooms, a pump when pumping liquids, a ship's propeller, but this invention has the main value in the field of electric power when working with an electric generator as a load device connected by a unit driving element, for example an asterisk.

The hydro-wind power installation of the GVSU can be used both for converting wind energy, and for converting the energy of the water of rivers, seas, outgoing water after turbines and instead of turbines of hydroelectric power stations where there is only water movement.

A hydro-wind power installation, in principle the same installation, can be used as an APU wind-power installation for converting wind energy and as a hydro-power GSU for converting water energy depending on where it is installed in water or on the surface.

Existing installations for converting wind or water energy are complex and structurally inefficient.

The prototype of this decision is the patent of the Russian Federation RU 2392490 C1, 06/20/10.

Changing the position of the blades using a chain drive, according to the prototype, is difficult constructively and ineffective, because a significant part of the energy is lost and the adjustment of the blades in the direction of the wind is complicated, because electric drive required. The main difference between the present invention and the existing ones is the rotation of the blades by 90 ° and vice versa in order to maximize the use of the energy of the flow of water or wind.

Description of the invention.

The hydro-wind power installation contains a base, rigidly sitting on it a shaft housing, a shaft, on one end of which a rotor sits rigidly with holes located perpendicular to the axis of rotation of the shaft, equal to the number of blades, rotary bushings sit in the holes of the rotor for quick assembly and disassembly with the ability to rotate around their axis, have grooves, which include stops that limit rotation by more than 90 ° and exclude longitudinal movements, the axis of the blades rigidly sit in the rotary bushings, the levers are rigidly mounted on the rotary bushings with rollers and springs, for example torsion. A disk with a cam sits on the shaft housing, rigidly, with the possibility of regulation, for the gas control system and freely for the APU, but rigidly connected to the weather vane with the help of knitting needles, the roller, rolling along the main cam, running onto the protrusions and depressions together with the lever, overcoming the spring resistance and the latch rotates the blades 90 ° and vice versa, namely, they are installed perpendicular to the water flow and the wind, working as part of the trajectory as a sail, creating maximum torque during the working phase, and not working, installing along the stream and wind, create a minimum oprotivlenie. The torque created by the blades is transmitted through the rotor, which is rigidly seated on the shaft, and, for example, an asterisk, rigidly sitting on the other end of the shaft, a chain drive and a driven sprocket, rotate the load device, for example, a generator for generating electric energy.

For installations of high power, a cam rim with a cross-section, for example, of a U-shape, rigidly connected to the main cam with knitting needles, working synchronously with it for stability of the blades and turning them from both ends, the main one at the attachment point and at the periphery, for which purpose at the end of the blade the axis is rigidly fixed, there is a carriage with rollers, a spring, for example, torsion, with a stop, allowing the axis to rotate 90 ° and back, the lever with the roller sits rigidly on the axis, the lower shelf is partially removed from the cam rim, and at the transitional place, reamer, and a non-operating phase, part of the shelf is folded and reinforced with gusset, creating a cam roller which is incident to a lever rigidly seated on the axis, the blade rotates, with the wind direction, because the main cam and cam rim are rigidly connected by a weather vane.

The hydro-wind power installation is configured to operate on horizontal and vertical planes and with the arrangement of blades and cams on both ends (see Fig. 7) and the possibility of rotation of the stator and the armature in different directions, increasing the effect of using the flow and can only rotate the armature, rotating in one side, and with a shifted arrangement of the blades of rotation will be smooth.

Hydro-wind power installation is made with the possibility of placing on one rack one above the other 2 gas control systems in water or 2 or more aircraft on the surface, operating on a vertical plane, and 2 or more gas systems and aircraft working on a horizontal plane, creating large power in one place .

Hydro power installation can be installed permanently, i.e. one installation of the gas control system or the armed forces, 2 or more pieces. on one platform of the gas control system or APU, 2 or more paired below the gas control system in the water at the top of the APU on the same platform - combinations may be different. FIG. 9, 11, 13, 13, 14, 15.

The installation was made with the possibility of using hydroelectric power stations instead of turbines, as allows you to more fully use the water column, namely, to locate the power take-off shaft closer to the lower water level, because in the transition zone from the working to non-working and the reverse stroke of resistance, the minimum instead of turbines can be used by gas control systems operating both on a vertical plane and on a horizontal one.

The hydro-wind power installation, the loading device can be located outside the installation, and on the side, for example, the power distribution system in water or under water, under ice, and the loading device is on the shore, and the movement is transmitted, for example, by a flexible shaft.

Hydro-wind power plants can be installed both stationary and on moving vehicles that move at low speed, for example, on excavators when loading ore or digging trenches, agricultural machines, on water vehicles: on barges, on rafts, on platforms during mining minerals, on ships, on ships to drive a propeller or to generate electricity, drive a pump, on aircraft, for example, on airships, on balloons. APU can be installed on buildings and structures and on houses, where there is the possibility of strength characteristics and roof construction.

Hydro-wind power plants can be collapsible, for which a swivel sleeve is provided, and portable for tourists, geologists, fishermen, since the installation creates large capacities with small dimensions.

It can be installed at polar stations.

GSU is made with the possibility of use on small rivers with shallow depth and will be widely used.

Hydro power installation can be performed in a toy version.

The invention is illustrated by drawings.

In FIG. 1 shows a General view of the hydro power plant GSU with a partial cutout of the casing and the shaft housing for clarity and where the river level is conventionally indicated by the letter S the level of the bottom by the letter R.

In FIG. 2 - the same section AA, indicating that the rotary sleeve has a groove where the stop enters, restricting the rotation by more than 90 ° and preventing movement along, and a latch that fixes the blade in extreme positions.

In FIG. 3 - the same, section BB for clarity, that the rotary sleeve and the blade are rigidly connected.

In FIG. 4 shows a General view of the hydro-power GSU and wind-power APU installations located on the same platform and working on a horizontal plane with a partial section of the shaft housing and the rotor.

In FIG. 5 is the same, view G with a partial cutout of the rim-cam and knitting needles for clarity.

In FIG. 6 - the same, section DD with an overview on the rim-cam in the transition phase.

In FIG. 7 shows a vertical section of an APU wind-powered installation operating on a vertical plane and having blades at both ends, rigidly connected by a stator and an anchor, rotating in different directions.

In FIG. Figure 8 shows the end view of the APU operating on a vertical plane, where the wind direction is indicated by the letter V, the direction of rotation is by the letter W, with a partial cut-out of the casing - a guide for clarity.

In FIG. 9 shows a General view of the hydro-power gas-turbine and the wind-power APU of plants located on the same platform operating on a vertical plane with a partial section of the body of the hydro-power plant and the axis of rotation of the wind-power plant for clarity, where the letter S denotes the water level.

In FIG. 10 depicts the option of using the gas control system instead of the turbines of the hydroelectric power station, a cross section and the application of the gas control system at the place of the leaving water after the turbines of the hydroelectric power station, where the letter S denotes the water level

In FIG. 11 is the same, section E-E variant of paired installations on a common shaft with cams on both ends.

In FIG. 12 shows a variant of the placement of wind power plants APU, operating on a vertical plane and located one above the other.

In FIG. 13 shows a variant of the placement of the APU working on a horizontal plane and located one above the other, the cam rim is conventionally not shown.

In FIG. 14, an embodiment of the hydro power plants of the GSU operating on a vertical plane and located one above the other is shown.

In FIG. 15 depicts an option for the placement of GSU working on a horizontal plane and located one above the other.

Description of the design of a hydroelectric power plant.

On the base (1), the shaft housing (2) is installed, the shaft (3) is installed in it, the rotor (4) is rigidly mounted on one shaft end, the rotary sleeve (5) is installed in the rotor hole, the lever (6) is rigidly fixed on the rotary sleeve with a roller (7) that rolls along the main cam (8), sitting on the disk (9), mounted on the shaft housing (2) rigidly for the power steering and freely for the armed forces, a blade (10) is installed in the rotary sleeve (5) and fixed bolt (11), a stop (12) is installed on the rotor (4), entering the groove of the rotary sleeve, limits rotation by more than 90 ° and excludes longitudinal Swivel sleeve housing with blade. To fix the position of the blade, a lock (13) is provided and the spring (14) provides contact between the roller and the cam and the position of the blade, for example, an asterisk (15) sits rigidly on the second end of the shaft, rotation is transmitted through the chain transmission (16) of the driven sprocket (17) a loading device, for example a generator (18), for the protection of moving parts, a casing (19) and for determining the position and safety of a beacon (20). Buoyancy is provided by a float (21). The wind power installation is installed on the mast (22), the movement is transmitted to the generator through the gearbox (23), the weather vane (24) is rigidly connected with the help of a spoke (25) to the cam disk (9), for large powers a cam rim (26), a lever ( 27) with a roller (28) rigidly sit on an axis (29), rigidly fixed on the periphery of the blade (10), a carriage (30) is installed on the axis with a roller (31), a spring (32), a stop (33) that allows the axis to rotate (29) 90 ° and vice versa. A housing (35) is installed on the mast (34), in which an axis (36) is mounted, rigidly connected to the installation housing 37, in which the stator (38) and rotor (39) are mounted on the bearings, a casing - guide (40) is fixed on the housing with scallops (41) to improve establishment, helping the wind vane downwind.

The mast (34) is installed on an intermediate basis (42), with the vertical position of the GCU and the rotation of the blades on different sides, the rotation is transmitted to the main shaft, for example, by conical wheels (43, 44, 45) located in the installation casing (46).

For a wider application of the installations, accommodation options are provided, namely, with the deployment option of the APU operating on a vertical plane, the racks (47) are located one above the other and the common axis (48) is rigidly connected to the weather vane, with the deployment option of the APU working on a horizontal the planes on the rack (49) of the installation are located one above the other, and the rack is made with the ability to rotate relative to the axis (50) using a weather vane, rigidly connected with the rack, with the option of placing the GSU working on a vertical gloss on the rack (51) are located one above the other and the common shaft (52) rotates the actuator, for example the generator (18), with the option of locating the power supply units working on a horizontal plane on the rack, (53) are located one above the other, where the installation housing is mounted rigidly on the bracket (54) of the rack and each installation performs work separately, for example, drives the pump.

Claims (5)

1. Installation, designed to convert the energy of the flow of water or wind, containing a base, shaft, rotor, rigidly mounted on the shaft with the possibility of rotation around its axis, blades mounted with the possibility of changing their position relative to the flow, a loading device, characterized in that the installation is equipped with a housing mounted on the base in which the shaft is located, a rotary sleeve installed in the rotor hole, levers with rollers rigidly mounted on the rotary sleeve, the main cam with a protrusion pits and troughs, sitting on a disk mounted on the housing, by a chain transmission for transferring rotation to the load device from the blades, by springs, while the blades are installed in the rotor holes perpendicular to the axis of rotation of the rotor, and the rollers together with levers are mounted with the possibility of rolling along the protrusions and troughs of the main cam, overcoming the efforts of the springs, and turning the blades 90 ° and vice versa, setting the blades perpendicular to the flow during the working phase and along the flow during non-working. 2. Installation according to claim 1, characterized in that when converting the energy flow of water, the main cam is rigidly mounted on the shaft housing. 3. Installation according to claim 1, characterized in that when converting the flow of wind energy, the installation is equipped with a weather vane for orientation in the direction of the wind, while the main cam is mounted freely on the shaft housing, but is rigidly connected to the weather vane. 4. The installation according to p. 3, characterized in that it is made with the possibility of rotation of the blades from two ends and is equipped with an additional axis on which a carriage with rollers, a spring, a stop and a cam rim with a U-shaped cross section is installed, while the rim - the cam is rigidly connected to the main cam with knitting needles with the possibility of synchronous operation with it and is rigidly connected to the weather vane, and at the end of the blade an additional axis is rigidly fixed and a carriage with rollers, a spring, an emphasis with the ability to rotate the axis 90 ° and back is installed on it y o ode-cam bottom shelf partially removed, and the place of transition from the working phase to trailing portion of the lower flange is bent and strengthened scarf, and clip with the lever raids the primary cam mounted rotatably to the blade axis 90 ° and back. 5. Installation under item 1, characterized in that it is made collapsible.

Images