RU2631474C1 - Hydraulic power unit - Google Patents

Abstract

FIELD: electricity-producing industry.

SUBSTANCE: hydraulic power unit comprises a body 1 in the form of two chambers 17, 18 with the inlet and outlet ports 19-22 with the hatches 23-26, the floats 30, 31 that are housed within the chambers 17, 18, an accumulator tank 8, an operating main line 4, a cranked axle 37 with piston rods that are linked to the floats 30, 31. The unit is placed in parallel with the river bed or the channel, which is divided by the longitudinal baffle 3 into the operating and emergency main lines 4, 6 with dampers 5, 7. The tank 8 is formed in main line 4. The main line 6 is attached to the bypass line 9. The ports 19-22 are placed against each other suitable for connection with lines 4 and 9. The unit is equipped with the motor drives 41-44 that are fixed above the ports 19-22, the shaft of each of the drives is supplied with the drum 45, which is connected to the relevant hatch by the wire rope 46, and is equipped with the floating switches 48, 49 of the motor drives 41-44 and with the rod forked switches. The motor drives 41-44 are linked to the oscillator, which is connected to the shaft 37 with the gear unit.

EFFECT: enhancement of unit operating efficiency, unit performance reliability and construction simplification of the hatches lift and drop headgear.

2 cl, 3 dwg

Description

The invention relates to hydropower and can find application when using the energy of the water flow of rivers or channels to convert it into electrical energy.

A device is known for converting the energy of flowing water into electrical energy containing an electric generator, a housing, a power take-off shaft installed therein, floats pivotally connected to rods and a lever system associated with ratchet mechanisms (US Patent No. 168832, M. CL F03B 13/12 , 1928. Analog).

The known device has low efficiency and complexity of the means of converting the energy of flowing water into electrical energy.

The closest analogue is a hydro-power installation (hereinafter installation), comprising a housing made in the form of two chambers with inlet and outlet openings, floats installed in the chambers, an accumulation tank, a working line, a power take-off shaft made in the form of a crankshaft installed in bearings with connecting rods associated with floats, a flywheel mounted on a crankshaft (see RU 2176747 C2, F03B 17 / 02.10.12.2001 Prototype).

The disadvantage of the prototype is the slow filling of chambers with water through the pipes, as a result of which the buoyancy force, according to the Archimedes Law, carries out a slow rise and speed of movement of the floats, which limits the capacity of the installation. Even equipping it with additional inlet pipes connecting the storage tank with cameras along the height and perimeter did not eliminate this drawback. Another disadvantage of the known installation is the great effort to open the inlet and outlet openings of the chamber. The larger the diameter of the inlet and outlet openings and valve plates overlapping them, the greater the force of water on them. This reduces the operational reliability of the camshaft with cams and its drive mechanism associated with the crankshaft.

Common features of the prototype and application are: a hydro-power plant comprising a housing made in the form of two chambers with inlet and outlet openings, floats installed in the chambers, an accumulation tank, a working line, a power take-off shaft made in the form of a crankshaft with connecting rods installed in the bearings associated with floats, a flywheel mounted on a crankshaft.

The technical task of the invention is to increase the efficiency of the hydraulic power plant by quickly filling the chambers with a stream of water of a river or a channel and increasing operational reliability by significantly reducing the load on the crankshaft when opening and closing the inlet and outlet openings of the chambers.

The technical problem and the result are achieved by the fact that the hydraulic power plant comprises a housing made in the form of two chambers with inlet and outlet openings, floats installed in the chambers, an accumulation tank, a working line, a power take-off shaft made in the form of a crankshaft with connecting rods installed in the bearings associated with floats, a flywheel mounted on a crankshaft. The installation is installed parallel to the channel of the river or channel, divided by a longitudinal partition into the working and emergency lines, equipped with dampers for their overlap. The storage tank is formed in the working line, and the emergency line is in communication with the bypass line. The housing is located between the working and bypass highways, and the inlet and outlet openings of its chambers are located opposite each other with the possibility of communication with the working and bypass highways and are equipped with gates installed with the possibility of movement along vertical guides to overlap these holes. The installation is additionally equipped with electric motors installed above the inlet and outlet openings, the shaft of each of which is equipped with a drum connected by a cable with a corresponding shutter. The installation is equipped with float switches and switches, as well as rod-mounted fork switches of electric motors for opening and closing the corresponding valves, and electric motors are connected by an electric circuit to an electric current generator connected by a transmission to the crankshaft. Float switches and electric motor switches are made in the form of nozzles with a stem and a float valve and are installed in the chambers, and rod-type fork switches are installed on the shutters of the outlet openings of the chambers.

These signs are necessary and sufficient for the implementation of the invention and to achieve a technical result.

The causal relationship of new features and the achieved technical result is as follows. Installing a hydropower plant parallel to the river or channel, divided by a longitudinal partition into a working and emergency line, equipped with shutters to shut them off, allowed the water flow of the river or channel to be directed into the storage tank, and shutting off the working line and opening the emergency line turned off the unit.

Formation of an accumulation tank in the working line, communication of the emergency line with the bypass line, placement of the housing between the working and bypass lines and the arrangement of the inlet and outlet openings of its chambers against each other with the possibility of communication with the working and bypass lines, as well as the provision of shutters installed with the possibility of movement along the vertical guides to overlap these holes, it was possible to alternately let the water flow from the storage tank into the chambers and let out the worked flow of water from the chambers to the bypass line and to exclude the load on the crankshaft when opening and closing the valves.

Additional supply of the installation with electric motors installed above the inlet and outlet openings of the chambers, the shaft of each of which is equipped with a drum connected by a cable with a corresponding shutter, significantly reduced the power consumption for opening and closing the shutters by moving them along the vertical guides to overlap these openings.

Providing the installation with float switches and switches, as well as rod-type fork switches of electric motors for opening and closing the corresponding gates and connecting low-power electric motors with an electric circuit with an electric current generator connected by a transmission with a crankshaft, made it possible to turn on and off the electric motors with the electric current of the specified generator.

The implementation of float switches and electric motor switches in the form of nozzles with a rod and a float valve and their installation in chambers, and rod fork switches on the shutters of the chamber outlet openings, made it possible to clearly turn on and off the electric motors for opening and closing the chamber inlet and outlet openings with shutters.

In FIG. 1 shows a diagram of a hydraulic power plant, a top view; FIG. 2 - the same front view; FIG. 3 - section aa in FIG. 1, a float switch of an electric motor is shown.

The hydraulic power plant (Fig. 1) contains a housing 1, mounted parallel to the riverbed 2 or channel, separated by a longitudinal partition 3 on the working line 4 with a shutter 5 and the emergency line 6 with a shutter 7. A storage tank 8 is formed in the working line 4, and the emergency line 6 is in communication with the bypass line 9. The housing 1 is located between the emergency 6 and the bypass 9 lines and consists of risers 10 connected by longitudinal 11, extreme 12 and middle 13 transverse beams, under which longitudinal 14, extreme 15 and middle 16 transverse walls (Fig. 2). The middle transverse wall 16 divides the housing 1 into two chambers 17 and 18, and inlet walls 19, 20 and outlet 21, 22 are formed on the longitudinal walls 14, which are opposed to each other with the possibility of communication with the working 4 and bypass 9 highways and equipped with gates 23, 24 and 25, 26, which are mounted with the possibility of movement along vertical guides 27 in the longitudinal walls 14 and grooves 28 in the longitudinal beams 11. Three risers 29 are vertically fixed to the risers 10, and floats 30 and 31 are installed in the chambers 17 and 18, on which guides 32 and joints are fixed ennye them stiffening ribs 33, and at their intersection lugs 34 to which are attached cranks 35 and 36 connected to the crankshaft 37, fixed on the bearing 15 and the outer transverse secondary walls 16. The crankshaft 37, with a flywheel 38 mounted thereon, is connected by a gear 39 to a shaft 40 to which an electric current generator (not shown) is connected. The installation is equipped with electric motors 41, 42 and 43, 44 mounted on the front and rear longitudinal beams 11, respectively, above the inlet 19, 20 and outlet 21, 22 of the holes of the chambers 17 and 18. On the shafts of the electric motors 41, 42, 43 and 44, the drums 45 are fixed which are connected by ropes 46 through the bypass rollers 47 to the shutters 23, 24, 25 and 26. Float switch 48 of electric motor 41 and switch 49 of electric motor 43 and switch 49 of electric motor 43 are fixed to the middle transverse beam 13, and float switch 50 is attached to chamber 18 motor 42 and float switch 51 of the electric motor 44. The float switches 48, 50 and the switches 49, 51 of the electric motors 41, 42, 43 and 44 are made in the form of nozzles 52 connected respectively to the chambers 17 and 18, equipped with float valves 53 and spring-loaded rods 54 that close or open the electric circuit corresponding electric motor. On the shutters 25 and 26 of the chambers 17 and 18, a fork switch 55 for turning off the electric motor 43 and turning on the electric motor 42 and a fork switch 56 for turning off the electric motor 44 and turning on the electric motor 41 are respectively mounted. The hydraulic power plant operates as follows. In the inoperative position of the installation, all inlet 19, 20 and outlet 21, 22 holes of the chambers 17 and 18 formed in the housing 1, located between the working 4 and the bypass 9 lines, respectively closed by gates 23, 24 and 25, 26, and the working line 4 is closed by a shutter 5. The damper 7 of the emergency line 6 is open, and the water flow from the channel 2 of the river or channel flows directly through the specified line. Before the installation starts, the operator opens the working line 4 with the shutter 5, and closes the emergency line 6 with the shutter 7. The entire water flow through the working line 4 enters the storage tank 8, completely fills it, and excess water through the longitudinal wall 3 is poured into the emergency line 6 . After that, the operator portable battery (not shown, as not included in the design of the installation) includes an electric motor 41 above the inlet 19 of the chamber 17. The drum 45 with a cable 46 thrown over the bypass roller 47 raises the shutter 23, which slides along the vertical guides 27 in the front longitudinal wall 14 and the longitudinal groove 28 in the front longitudinal beam 11, without experiencing much resistance and high energy costs, as it moves in the vertical direction and is made lightweight - hollow or made of aluminum sheets. Water through the inlet 19 quickly fills the chamber 17 and the float 30 floats, moving guides 32 along the rollers 29, mounted on struts 10 connected by the extreme 12, middle 13 transverse and longitudinal 11 of the front and rear beams. A connecting rod 35, connected to the ears 34 of the stiffening ribs 33 of the float 30, rotates the crankshaft 37 by 180 degrees, and the float 31 in the empty chamber 18 by the connecting rod 36 is lowered to the lower position. A generator (not shown), connected by a shaft 40 and a transmission 39 with a crankshaft 37 and an electric circuit with low-power electric motors 41, 42, 43 and 44, generates an electric current that is supplied to their power. At the same time, water fills the nozzles 52 of the float switch 48 and the switch 49. The float valves 53 press the spring-loaded rods 54 and turn off the electric motor 41 and turn on the electric motor 43. The shutter 23 instantly goes down and closes the inlet 19 of the chamber 17, and the electric motor 43 lifts the shutter 25 with a cable 46 and opens the outlet 21. Water is discharged into the bypass channel 9 and through it to the emergency line 6, and the rod fork switch 55, mounted on the shutter 25 of the outlet 21 of the chamber 17, with one finger you turns on the electric motor 43, and with the other finger turns on the electric motor 42 at the inlet 20 of the chamber 18. The shutter 25 instantly lowers down and closes the opening 21, and the shutter 24 rises by the electric motor 42. Water from the storage tank 8 enters the chamber 18, the float 31 floats up and the connecting rod 36 rotates the crankshaft 37, which completes the full revolution. The flywheel 38 translates the connecting rods 35 and 36 through the upper and lower “dead points” and ensures smooth rotation of the crankshaft 37, which rotates the shaft 40 by transmission 39. In this case, the switch 50 similarly turns off the electric motor 42, and the switch 51 turns on the electric motor 44. The shutter 24 is lowered down and closes the hole 20, and the shutter 26 rises and the water through the hole 22 is discharged into the bypass line 9. The rod fork switch 56, mounted on the shutter 26 of the outlet 22 of the chamber 18, turns off the electric motor with one finger 44 and the shutter 26 overlaps the outlet 22, and with the other finger turns on the electric motor 41, which opens the inlet 19 of the chamber 17 with a shutter 23. Next, the operation of the hydraulic power plant is automatically repeated with the selection of a small part of the energy generated by the generator for alternately turning on the motors 41, 42 , 43 and 44. The use of a hydro-power installation allows the use of the energy of small rivers or canals to produce electrical energy for the needs of nearby areas.

Claims (2)

1. Hydro power installation comprising a housing made in the form of two chambers with inlet and outlet openings, floats installed in the chambers, an accumulation tank, a working line, a power take-off shaft made in the form of a crankshaft mounted in bearings with connecting rods connected to the floats, a flywheel mounted on a crankshaft, characterized in that the hydropower installation is installed parallel to the river or channel, divided by a longitudinal partition into a working and emergency lines equipped with a bed kam for their overlap, while the storage tank is formed in the working line, the emergency line is connected to the bypass line, the housing is located between the working and bypass lines, and the inlet and outlet openings of its chambers are located opposite each other with the possibility of communication with the working and bypass lines and equipped shutters installed with the possibility of moving along vertical rails to overlap these holes, while the installation is additionally equipped with electric motors installed hell of inlet and outlet openings, the shaft of each of which is equipped with a drum connected by a cable with a corresponding shutter, the installation being equipped with float switches and electric motor switches and rod-type fork switches for opening and closing the corresponding shutters, and the electric motors are connected by an electric circuit to an electric current generator connected by a transmission with crankshaft. 2. Hydro power installation according to claim 1, characterized in that the float switches and electric motor switches are made in the form of nozzles with a stem and a float valve and are installed in the chambers, and rod-type fork switches are installed on the shutters of the chamber outlet openings.

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