RU2552589C1 - Power plant - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: power plant relates to the field of small power, namely to plants using energy of river flow. A power plant comprises a body, a hydraulic engine 27 is installed in it with a working element, a power generator 18, installed above the hydraulic engine 27. The working element is installed as capable of interaction with the water flow arriving via the receiving inlet into the working zone of the body, leaving it and being captured by the river flow, increasing the speed of flow outlet. The plant is equipped with a freewheeling clutch 29 and a wind engine 28 installed in series in a row above a power generator 18 and a hydraulic engine 27. Working elements of the hydraulic engine 27 are made as assembled from radial blades installed on axes between support rings mounted on the shaft by means of spikes. Blades are made as capable of rotation on axes to limiters and automatic installation into working and non-working position by the fluid flow. The wind engine 28 is made as acting similarly to the hydraulic engine 27. The plant is made as capable of rotation in the bearing installed on the head. The head is installed on the plant as fixed.

EFFECT: invention is aimed at provision of the possibility of continuous operation of a power plant.

5 dwg

Description

The power plant belongs to the field of small-scale energy, namely to installations for the use of river runoff energy. A number of devices for generating electricity by water sources are known.

An analogue (prototype) of the invention can be attributed to an electric power generation station installed in a horizontal position on the water surface of a river, open, freely moving, containing a housing, a hydraulic motor with a working body installed in it, an electric generator mounted above the hydraulic motor, while the working body is installed with the possibility of interacting with the water flow coming through the inlet to the working area of the building, exit from it and capture the general course of the river, contributing to an increase flow exit rates (see JP 2012102680 A, 05/31/2012, F03B 17/06).

The disadvantage of this power plant is the impossibility of its continuous operation.

The objective of the invention is the provision of the possibility of continuous operation of the power plant, the expansion of opportunities for mass use in places inaccessible for connection to the public power grid to the consumer of electricity.

This problem has been solved in an electric power generation station installed horizontally on a river’s water surface, open, freely moving, containing a housing, a hydraulic motor with a working body installed in it, an electric generator installed above the hydraulic motor, and the working body is installed with the possibility of interaction with water flow coming through the inlet to the working area of the building, exit from it and capture the general course of the river, contributing to an increase in the rate of exit of sweat and, according to the invention, the station is equipped with an overrunning clutch and a wind turbine mounted sequentially in a row above the electric generator and the hydraulic motor, the working bodies of which are made up of radial blades mounted on the axles between the support rings mounted on the shaft by means of spokes, while the blades are rotatable on the axes to the limiters and automatically set to working and inoperative position by the flow of the working fluid, and the wind turbine is made acting similar to a hydraulic motor oil, and the station is rotatable in a bearing mounted on the headband, and the headband is stationary at the station.

In FIG. 1 shows a station mounted on water, a side view, in section. In FIG. 2 shows a diagram of the movement of the working fluid in the working body with the position of the blades, in positions, in the working and non-working areas, inlet, outlet and water flow outside the hydraulic motor. In FIG. 3 shows the working body in a three-dimensional image. In FIG. 4 shows a station mounted on a support, side view, in section. In FIG. 5 shows a wind hydroelectric station mounted on water, side view.

The power plant is installed on the water surface of the river in a horizontal position, on the open, freely moving, natural kinetic energy of the flow and is fixed to the support 1 with a buoyer 2 (Fig. 1, 2). The station contains a hydraulic motor 27 with a working body consisting of blades 3 mounted on the axles 4 between the support rings 5. The support rings 5 are mounted on the shaft 6 by means of spokes 7. The working body is placed inside the housing 8 with an inner surface of a cylindrical shape, covering the working body, including a vertically located shaft 6 with radial blades 3. a shaft 6 is mounted on a raft 9 in the bearing 10. Under the raft 9 is a housing 8 in which the end of the shaft 6 is mounted in the bearing 11. The blades 3 are arranged to rotate the company on the axes 4 from the movement of the mass of the working fluid to the limiters 12 and automatic installation in the working 13 and idle 14 positions of the flow of the working fluid coming through the inlet 15 into the working area 16 of the housing 8, directing the fly vane 24. From the impact of the working fluid on the working surface 17 the blades 3, the blades 3 are rotated on the axes 4 and installed in the working position 13 and then move around the circle of the support rings 5, and through the axis 4 transmit the movement to the support rings 5, which rotate and transmit the rotation through the spokes 7 to the shaft 6 and to the electrog generator 18. Having given the kinetic energy of the flow to the work of the working body, the working fluid leaves the working area 16 through the outlet 31, and the blades 3 continue to move in a circle and enter the idle zone 19, where the pressure on the blades 3 is reduced by the action of the protective wall 20 of the housing 8. Weak pressure on the blades 3 from the oncoming mass of water, they are installed in the idle position 14, which reduces the resistance of the blades 3 of the working body and the hydraulic motor 27 as a whole. Next, the cyclical operation of the hydraulic motor 27 from the flow of the working fluid continues. The above-water part of the station from above and from the sides is closed by a casing 21 providing protection against natural precipitation.

When the station uses wind energy, the station is mounted in a horizontal position on a support 22 fixed in the ground 23 (Fig. 4).

The shaft 6 is mounted on a support 22 with the possibility of rotation in the bearing 10, the housing 8 and in the bearing 11 installed in the headband 25. During operation of the station, the station rotates on the support 22 in the bearing 26 mounted on the headband 25, mounting the station on the support 22. Golovinnik 25 is mounted on a support 22 motionless. A probe 30 is installed above the station.

The moving air mass enters through the inlet entrance 15 of the housing 8. The station is automatically installed with a fly-bar 24 and rotates in the wind on the bearing 26. When the station uses wind energy and river flow energy at the same time, the electric station consists of a hydraulic motor 27, a wind turbine 28, an electric generator 18 and overrunning clutch 29 mounted in series in a row one above the other.

The power station operates as follows.

A power plant installed on the water surface of the river receives flow energy. A moving stream washes the housing 8 from the outside. A part of the flow flows through the inlet 15 into the working area 16 of the housing 8, directed by the vane 24. The incoming working fluid acts on the blades 3. Initially, from the friction of the working fluid on the outer surface of the blades 3, the working body is rotated at a certain angle. Further, the working fluid continues to act on the working surfaces 17 of the blades 3. From this, the blades 3 rotate on the axes 4 to the limiter 12, occupy the working position 13 and receive the greatest energy of the working fluid, and the working body continues to turn and rotate when the parts interact: from the blades 3 on the axis 4, from the axis 4 to the support rings 5, from the support rings 5 to the spokes 7, from the spokes 7 to the shaft 6 and to the rotation of the generator 18. From receiving alternating continuous exposure of the working fluid to the blades 3, the working body is rotated along in a circle, and the blades 3 exit the working zone 16 and enter the non-working zone 14. The bulk of the working fluid goes outside through the exit 31. A reduced water flow enters the non-working zone 14. In the non-working zone 14, the flow is reduced by the protective wall 20. From the blades 3 passing into inoperative zone 14 towards a weak flow, the oncoming mass of water presses the blades 3 to the support rings 5. This position of the blades 3 provides a decrease in the resistance of the blades 3 to the working body and the electric generator 18. In the working zone 16, the blades 3 receive the greatest flow energy, predominantly azuya it into torque shaft 6, an electric generator 18, and a trailing zone 19 of the blade 3 does not create a resistance from the oncoming flow, eventually yielding a positive effect.

This design of a power plant operating from the energy of the flow of water can similarly work from wind energy. When the station produces electricity from wind energy, wind energy flows through the receiving input 15 of building 8, which is automatically installed by a fly lamp 24. During the station’s operation, the hydraulic motor 27 receives the river flow energy from the wind and river flow energy at the same time in the complex, continuously creating a rotation moment hydraulic motor 27 and transmitting to the shaft 6 of the electric generator 18 generating electricity. At this time, the upward movement of the air masses creates a moment of rotation for the wind turbine 28, the wind turbine 28, rotating, drives the overrunning clutch 29 and the electric generator 18. In the absence of upward air movement, the wind turbine 28 does not rotate. In this case, the freewheel 29 does not interfere with the rotation of the shaft 6 of the hydraulic motor 27, rotating from the energy of the water flow.

The use of natural phenomena in structural and technological solutions, together, will ensure the generation of cheap electricity with reliable operation of the power plant: - continuity of operation; in any season; any time of the day; in any seasonal and climatic conditions. The accumulation of electricity will create a condition for the stability of the power system.

Claims (1)

An electric power generation station installed in a horizontal position on the river’s water surface, open, freely moving, containing a housing, a hydraulic motor with a working body installed in it, an electric generator mounted above the hydraulic motor, and the working body is installed with the possibility of interaction with the water flow coming in through the inlet to the working area of the building, exit from it and capture the general course of the river, contributing to an increase in the rate of exit of the stream, characterized in that The ancestry is equipped with an overrunning clutch and a wind turbine installed sequentially in a row above the electric generator and a hydraulic motor, the working bodies of which are made up of radial blades mounted on the axles between the support rings mounted on the shaft by means of spokes, while the blades are made to rotate on the axes to the stops and automatic establishment in the working and non-working position by the flow of the working fluid, and the wind turbine is made acting similar to a hydraulic motor, and the station is made for rotatably bearing mounted on the end cap and the end cap is fixedly mounted at the station.

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