KR101258068B1 - Small hydropower generating apparatus - Google Patents

Abstract

The present invention relates to a small hydro power generating apparatus having a multi-turbine turbine, and more specifically, two or more turbines are installed inside a small hydro power generator that generates electricity by using a drop of water. In this way, high energy can be obtained even at a low head, and high speed energy and torque of the turbine can be increased by the water pressure generated at a large flow rate, so that high electric energy can be obtained.
To this end, the present invention is an auxiliary drive shaft which is formed extending in the vertical direction to the lower end of the drive shaft, and is connected to the lower end of the auxiliary drive shaft and when the high-pressure water flows in turn and the auxiliary turbine to increase the high speed torque and torque while rotating in the same direction as the turbine and And an auxiliary jet nozzle which is formed below the jet nozzle and installed on the inner wall 130 so as to spray the high pressure water to the turbine and the auxiliary turbine, and is formed between the turbine and the auxiliary turbine and the jet nozzle and the auxiliary jet nozzle. Its feature is that it consists of a plate-shaped diaphragm to prevent the collision of high-pressure water injected from.

Description

Small hydropower generating apparatus with multiple turbulent turbines

The present invention relates to a small hydro power generating apparatus having a multi-turbine turbine, and more specifically, two or more turbines are installed inside a small hydro power generator that generates electricity by using a drop of water. Hydropower generation with multiple turgo turbines that allow high energy to be obtained at low heads and that are blown by water pressure generated at high flow rates and that the high torque and torque of the turbine are further increased to obtain high electrical energy. Relates to a device.

In general, hydrophobic power plants using drops of valley water, waterfalls, small dams, or reservoir water can be largely divided into impulse turbines and reaction turbines.

Impact aberrations are Pelton and Turgo. These shock aberrations require high heads, but can be generated at low flow rates.

Reaction aberrations are Francis, Kaplan, and Tubular aberrations. These reactions require a low head and require large flow rates. ought.

In the case of impact aberration, a small hydropower device is mainly applied because a high head and a large flow rate of 100m or more are required to obtain high electrical energy. Therefore, in the case of topographical problems and impact aberration, the turbine size is known to be inefficient for large flow rates.

[Patent Document 1] Publication No. 10-2010-0135580 (Hydro Power Plant) [Patent Document 2] Publication No. 10-2010-013579 (Hydro Power Plant)

Accordingly, an object of the present invention is to devise in view of the above-described conventional problems, to provide a separate hydro-power generator capable of producing electricity from the kinetic energy of the fluid, such as valley water, waterfalls, small dams, reservoirs, and the like The generator is to provide a hydroelectric power generation apparatus having a multi-turbine turbine that can be generated by the high-pressure water generated in the drop of 20-40m and the turbine is rotated at high speed to produce and generate electrical energy.

It is another object of the present invention to install two or more turbines inside a hydropower generator that generates electricity by using a drop of water so that a large flow rate is supplied to the turbine side, so that high energy can be obtained even at a low head, and a large flow rate is achieved. It is to provide a hydropower generator having a multi-turbine turbine that is turned off by the water pressure generated in the turbine and the high-speed rotational force and torque of the turbine are further increased to obtain high electrical energy.

As a means for achieving the above object, the present invention, the auxiliary drive shaft is formed extending in the vertical direction to the lower end of the drive shaft,

It is connected to the lower end of the auxiliary drive shaft and when the high-pressure water flows in the auxiliary turbine to increase the high-speed rotational force and torque while rotating in the same direction as the turbine;

An auxiliary jet nozzle which is formed below the jet nozzle and installed in the inner wall 130 so as to spray the high pressure water toward the turbine by the auxiliary blower;

 The technical feature of the technical configuration is that it is composed of a plate-shaped diaphragm formed between the turbine turbine and the auxiliary turbine turbine to prevent the collision of high-pressure water injected from the jet nozzle and the auxiliary jet nozzle.

As described above, according to the present invention, there is provided a separate hydropower generator capable of producing electricity from the kinetic energy of the fluid such as valley water, waterfall, small dam, and reservoir. The hydrophobic generator as described above can be easily produced and generated electric energy because it is burst by the high-pressure water generated in the drop of 20 to 40m and the turbine rotates at high speed.

In addition, in the present invention, two or more turbine turbines, that is, turbine turbines and auxiliary turbine turbines, are installed in the hydropower generator to constitute a multi-turbine turbine. Such a configuration is able to obtain high energy even at a low head because a large flow rate is exploded and can be supplied to the turbine side.

In addition, due to the water pressure generated at a large flow rate, the turbine and the subsidiary turbine turbine has a high rotational force and torque is increased, so that high electrical energy can be obtained.

1 is a block diagram of a hydropower generator having a multi-turbine turbine according to the present invention.
Figure 2 is a cross-sectional configuration of a hydropower unit having a multi-turbine turbine according to the present invention.
Figure 3 is a perspective view of the main portion of the hydropower unit having a multi-turbine turbine according to the present invention.
4 is a plan view of a turgo turbine according to the present invention;
5 is a plan view of a disk according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Before describing the main configuration of the present invention, the hydrophobic power generator 100 used in the present invention has one end connected to the storage facility 400 for storing water as shown in FIGS. 1 to 5 and the other end is piped downward. Small hydro power generator that produces electricity by being installed and fixed in a pipe line 300 for moving the stored water downward, and installed at a lower position than the storage facility 400 and falling along the pipe line 300. 100 and the inverter 500 for converting the DC power generated from the hydro-power generator 100 into an AC power.

The hydropower generator 100 has a distributor 131 having an outer wall 140 and an inner wall 130 formed at regular intervals, and a space 141 therebetween, and positioned at upper and lower ends of the distributor 131, respectively. The upper plate 120 and the lower plate 110, one end is connected to the outer wall 140 and the other end is connected to the pipe line 300, the connecting pipe 200 for introducing water into the space 141 and the, Installed at regular intervals on the inner wall 130 and rotated at high speed by a jet nozzle 190 for spraying water introduced through the connecting pipe 200 at high pressure, and high pressure water sprayed from the jet nozzle 190. Turbine turbine 170, the discharge port 111 is formed in the middle of the lower plate 110 to be used and discharged to the outside, and the hydrophobic power generator 100 is formed in the vertical direction at the bottom of the lower plate 110 Mounting table 112 to be installed at a predetermined distance from the bottom surface, and the turbine turbine When the drive shaft 151 is connected to the adapter 160 formed at the top of the 170 and the turbine 170 rotates, the generator 150 is configured to generate and generate electric power.

Turbine turbine 170 is a disk 171 is formed a plurality of connection grooves 172 at regular intervals on the outer circumferential surface, and a connecting portion 182 connected to each other and fixed to the connection groove 172 is formed on one side and Consists of a cup cup 180 having a concave receiving groove 181 to receive the high-pressure water injected from the jet nozzle 190 and to rotate the turbine 170.

Here, the protective cover 600 is formed on the distributor 131 to prevent the generator 150 from being interfered with from the outside.

In more detail, the jet nozzle 190 installed on the inner wall 130 is blown so that the water sprayed from the jet nozzle 190 blows toward the center of the cup 180 to maximize the rotational force of the turbine 170. As described above, the jet nozzle 190 is blown and installed above the cup 180, but is preferably installed by tilting 20 ° diagonally toward the center of the cup 180. This is because the high pressure water passing through the jet nozzle 190 bursts out and collides with the receiving groove 181 of the cup 180 and then quickly exits downward, thereby colliding with the water hitting the cup 180 first and the high pressure water following it, Alternatively, the cup 180 collides with the crashed water and prevents the phenomenon of reducing rotational energy.

The jet nozzle 190 is composed of a nozzle cap 191 and the pipe 192, the nozzle cap 191 and the pipe 192 is coupled in a threaded type. It has a function of easily removing foreign substances by replacing the nozzle cap 191 or opening the nozzle cap 191 when the jet nozzle 190 is clogged by foreign matter during long-term use.

Turbine turbine 170 is a large-sized cup 180, a circular disk 171 for fixing the bursting cup 180, the drive shaft 151 and the disk of the generator 150 in the upper middle of the disk 171 ( It consists of the adapter 160 which fixes 171. Blowing cup 180 is made of a durable polycarbonate material, the jet nozzle 190 is installed on the inner wall 130 to be inclined in an oblique direction in the upper 20 ° direction.

The center of the disk 171 is fixed to the drive shaft 151 and the adapter 160 of the generator 150 is configured to transmit the rotational force of the disk 171 to the generator 150, the force of the water from the jet nozzle 190 The generator 150 is operated while the disk 171 rotates by the reaction force that pushes the cup 180 to the edge formed on the disk 171. The rotation speed of the turbine turbine 170 is 400 to 1000 rpm. Rotate to and the electricity is generated by the generator 150.

The generator 150 is installed on the upper portion of the hydro power generator 100, and a protective cover 600 made of reinforced glass fiber material is installed to protect the generator 150. Therefore, the hydrophobic power generator 1000 according to the present invention is provided with a distribution tank 131, a jet nozzle 190, and a turbine 170, and a generator 150 is installed at the top, so that the hydropower generator 1000 is manufactured as a single module. Not only is the site installation simple, but the installation area is small.

The present invention configured as described above is connected to the lower end of the auxiliary drive shaft 700 and the auxiliary drive shaft 700 is formed in the vertical direction extending to the lower end of the drive shaft 151 in order to use the hydrophobic power generator 100 more effectively and high pressure When the water flows, the secondary turbine 710 increases the rotational force and torque while rotating at a high speed in the same direction as the turbine 170 and the jet nozzle 190, which is formed below the jet turbine 190 and the high pressure water toward the secondary turbine 710. Auxiliary jet nozzle 720 is installed on the inner wall 130 so as to be sprayed between the turbine turbine 170 and the auxiliary turbine turbine 710 is formed in the jet nozzle 190 and the auxiliary jet nozzle 720 It consists of a plate-shaped diaphragm 730 to prevent the collision of the high pressure water is injected.

Meanwhile, the auxiliary drive shaft 700, the auxiliary turbine turbine 710, and the auxiliary jet nozzle 720 used in the present invention have the same structure and function as the driving shaft 151, the turbine turbine 170, and the jet nozzle 190. Is formed. Therefore, detailed description thereof will be omitted.

In the present invention configured as described above, the water stored in the storage facility 400 is dropped downward along the pipe line 300, and the dropped water is the outer wall 130 of the distribution tank 131 through the connection pipe 200. And is temporarily stored on the space 141 formed between the inner wall 140.

Temporarily stored water is evenly distributed to each jet nozzle 190 and the auxiliary jet nozzle 720, and the water sprayed and sprayed to the outside bursts and is sprayed in the center of the receiving groove 181 of the cup 180 to turn the turbine ( 170 and the auxiliary turbine is rotated at a high speed. At this time, when the rotational force of the turbine 170 and the auxiliary turbine 710 rotating at a high speed is transmitted to the generator 150 through the drive shaft 151 and the auxiliary drive shaft 700, the generator 150 generates electricity. The high pressure water used is discharged to the outside through the discharge port 111.

100; Small hydro generator 110; Bottom plate
111; Outlet 112; Installation
120; Top plate 130; inside wall
131; Distributor 140; outer wall
141; Space 150; generator
151; Drive shaft 160; Adapter
170; Turbine turbine 171; disk
172; Connecting groove 180; Popping cup
181; Receiving groove 182; Connection
190; Jet nozzles 191; Nozzle cap
192; Piping 200; Connection
300; Piping line 400; Storage facility
500; Inverter 600; Protective cover
700; Auxiliary drive shaft 710; Auxiliary Turgo Turbine
720; Auxiliary jet nozzle 730; Plate

Claims (1)

The outer wall 140 and the inner wall 130 are formed at regular intervals, and the distributor 131 having a space 141 therebetween, and the upper plate 120 and the lower plate respectively located at the upper and lower ends of the distributor 131. 110 and one end is connected to the outer wall 140 and the other end is connected to the pipe line 300, the connection pipe 200 for introducing water into the space 141 and the inner wall 130 is constant A jet nozzle 190 installed at intervals and spraying water introduced through the connecting pipe 200 at a high pressure, and a turbine 170 rotating at high speed by the high pressure water injected from the jet nozzle 190; A discharge port 111 formed in the middle of the lower plate 110 and used to discharge the high-pressure water to the outside is formed in a vertical direction at the bottom of the lower plate 110, and the hydropower generator 100 has a constant distance from the bottom surface. Mounting stand 112 to be placed and installed, and the top formed on the turbine 170 When teogo turbine 170 rotates in dapta 160. The drive shaft 151 is connected to the state for the hydro power generator using a solid foundation turbine consisting of a generator 150 to produce electric power and power,
Auxiliary drive shaft 700 is formed extending in the vertical direction to the lower end of the drive shaft 151, and is formed connected to the lower end of the auxiliary drive shaft 700, when the high-pressure water is blown and rotates at a high speed in the same direction as the turbine 170 and the rotational force and Auxiliary turbo turbine 710 that increases torque and an auxiliary jet nozzle 720 which is formed below the jet nozzle 190 and installed on the inner wall 130 so as to spray high pressure water toward the turbo turbine 710 side. And a plate-shaped diaphragm 730 formed between the turbine turbine 170 and the auxiliary turbine turbine 710 to prevent collision of the high pressure water sprayed from the jet nozzle 190 and the auxiliary jet nozzle 720. Small hydroelectric power generation apparatus having a multi-turbine turbine, characterized in that the.

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