KR101389433B1 - Water pumping system of hydro-electric power plant - Google Patents

Abstract

The present invention relates to a pumping and power generation system, and a pumping and generating system according to the present invention includes: a first reservoir; and installed at a higher position than the first reservoir, wherein the water stored in the first reservoir is moved by a pump. A second reservoir having a discharge pipe for discharging the moved water; and a guide part having a guide vane receiving the water discharged from the discharge pipe and guiding downward; and a water guided by the guide vane and the outside. The water source is to be introduced into the first reservoir tank, the inlet tube is installed inside the generator; characterized in that it comprises.
According to the present invention as described above, the power generation is possible at all times, by using a pump pump to move the water stored in the lower reservoir to the upper reservoir to circulate by using a pump to perform the role of the base power plant At the same time, there is an advantage to use abundant water resources by introducing an external water source into the reservoir of the lower portion.

Description

Water pumping system of hydro-electric power plant

The present invention relates to a hydroelectric pumping system, and more specifically, it is possible to generate power at all times, and by using a pumping pump to control the amount of power generation, the water stored in the lower reservoir tank is moved to the upper reservoir tank and circulated. The present invention relates to a hydroelectric pumping system capable of generating power using abundant water resources by performing a role of a power plant and simultaneously introducing an external water source into a lower reservoir.

In general, it is desirable to hydroelectrically generate some of the water used for power generation economically. In general, pumping power is used to pump water at night when power consumption is low, and then use it for power generation. In such a power generation system, pumping power source for pumping water to a high position uses power generated during power generation.

Such a conventional hydroelectric generator is published, for example, in the domestic application No. 10-1984-0004941 (name of the invention: hydraulic pumping hydroelectric generator), such a conventional hydroelectric generator is stored in the reservoir tank It was a power generation method that generated millions of tons of water by opening the gate and making it vertically with the aberration blades, making this force the rotational force of the aberration, and increasing the rotational force through the gear transmission, and then driving the generator.

However, the conventional hydroelectric generator as described above is difficult to prepare a place because a storage tank for storing millions of tons of water must be provided separately, and once the dropped water cannot be reused, there is an economically undesirable problem. .

The present invention has been made to solve the above-mentioned problems, the object of the present invention is to always power generation, by using a pumping pump to control the amount of power generated by moving the water stored in the lower reservoir to the upper reservoir By circulating, it plays the role of a base power plant, and at the same time, it introduces a hydroelectric pumping system capable of generating power using abundant water resources by introducing external water sources into the lower reservoir.

In addition, a generator is installed inside the discharge pipe for discharging the water stored in the upper reservoir, and inside the inlet pipe through which the external water source flowing between the water discharged from the discharge pipe and the guide vane is simultaneously introduced. It is to provide a hydroelectric pumping system that can generate electricity.

In addition, since the water flow line is installed to increase the flow rate of the water driving the generator to increase the water flow rate to provide a hydro pumping power generation system with excellent power generation efficiency.

In addition, by forming a valley in the partition wall, and the end of the guide vane is bent in the direction of water inflow to provide a hydro pumping system that can use more of the external water source.

In addition, to increase the ease of work and at the same time to provide a hydroelectric pumping system that can be utilized for multi-purpose by forming a work road to be used for tourism.

In order to solve the above problems, the hydroelectric pumping system according to the present invention includes: a first reservoir tank; and installed at a higher position than the first reservoir tank, and the water stored in the first reservoir tank is moved by a pump pump. A second reservoir having a discharge pipe for discharging the moved water; and a guide part having a guide vane receiving the water discharged from the discharge pipe and guiding downward; and a water guided by the guide vane. The water source is to be introduced into the first reservoir, the inlet pipe is installed inside the generator; characterized in that it comprises.

In addition, the discharge pipe is provided with a plurality, the generator is installed in the interior of the discharge pipe; and the first water gate installed in the discharge pipe to control the flow of water stored in the second reservoir tank; and of the water passing through the discharge pipe Characterized in that it further comprises; a first water beam installed at the inlet of the discharge pipe to increase the water pressure.

In addition, a partition wall is formed on the outside of the guide portion, the guide vane is installed on the partition wall, the guide vane and the inlet pipe is provided with a plurality, the guide vane is the outer cross section of the outer edge so that the flow rate of the external water source is increased It is characterized by being manufactured in a mold.

In addition, a float suspended plate installed between the guide vanes so that foreign matter contained in an external water source is prevented from entering the inside of the inlet pipe; and a reverse flow to selectively block an external water source passing between the guide vanes. And a prevention shaft; and a rotating shaft installed at the non-return gate so that the non-return gate is rotated by the water pressure of an external water source passing between the guide vanes.

The apparatus may further include a flow rate increasing unit installed inside the floating plate to increase the flow rate of the external water source passing through the floating plate. The flow rate increasing unit may include a plurality of flow rate increasing plates spaced apart from the upper portion to the lower portion. Including, the upper flow rate increase plate is installed to be inclined downward so that the external water source is guided to the inlet pipe side, the slope is gradually installed from the upper side to the lower side, characterized in that the lower flow rate increase plate is installed horizontally .

In addition, the guide vane is inclined portion is formed to be inclined downward so that the water discharged to the discharge pipe is guided to the inlet pipe; and the second water beam connected to the lower side of the inclined portion so that the water pressure of the water guided to the inlet pipe is increased It is characterized in that it further comprises.

In addition, one side of the second water strip is connected to the inlet of the two inlet pipes of the plurality of inlet pipes, the other side is adjacent to the inclined portion to move the water along the inclined portion two of the plurality of inlet pipes It characterized in that the branched to the inlet pipe.

In addition, a rotary pump for making the inside of the inlet pipe to a lower pressure than the outside of the inlet pipe; and the second sluice installed in the inlet pipe; characterized in that it further comprises.

In addition, the discharge pipe and the inlet pipe is characterized in that the height of the outlet is installed lower than the height of the inlet.

In addition, the ribs formed on the partition wall; and a plurality of guide vanes formed on the partition wall; and the guide vane is manufactured in the form of a cross section of the outer side so as to increase the flow rate of the external water source, the outer side of the guide vane It is characterized in that the bent portion; bent in the direction in which the water flows.

In addition, the plurality of bones are continuously formed, the protrusions are formed to protrude outwardly to the plurality of bones to guide the external water source to the guide vane; characterized in that it further comprises.

According to the present invention as described above, the power generation is possible at all times, by using a pump pump to move the water stored in the lower reservoir to the upper reservoir to circulate by using a pump to perform the role of the base power plant At the same time, there is an advantage to use abundant water resources by introducing an external water source into the reservoir of the lower portion.

In addition, a generator is installed inside the discharge pipe for discharging the water stored in the upper reservoir, and inside the inlet pipe through which the external water source flowing between the water discharged from the discharge pipe and the guide vane is simultaneously introduced. It has the advantage of producing power.

In addition, there is an advantage that the power generation efficiency is excellent by increasing the flow rate of the water is installed because the flow line is installed to increase the flow rate of the water driving the generator.

In addition, the ribs are formed in the partition wall, and the ends of the guide vanes are bent in the direction of water inflow, so that the external water source can be used more.

In addition, there is an advantage that can be utilized for multi-purpose by forming a work road to enhance the ease of work and to use for tourism.

1 is a side view of a hydroelectric pumping system according to a preferred embodiment of the present invention.
2 is a plan view of a hydroelectric pumping system according to a preferred embodiment of the present invention.
3 is a conceptual view showing a water and an external water source stored in a second reservoir tank of a hydroelectric pumping system according to a preferred embodiment of the present invention flow into the inlet pipe.
Figure 4 is a side view of Figure 3;
5 is a plan view of the V type of the hydro pumping system according to a preferred embodiment of the present invention.
Figure 6 is a plan view of the W type of hydro pumping system according to a preferred embodiment of the present invention.
7 is a conceptual view showing the water and the external water source stored in the second reservoir in the V type and W type of the hydroelectric pumping system according to a preferred embodiment of the present invention flows into the inlet pipe.
8 is a conceptual diagram illustrating a state in which a hydro pumping system according to a preferred embodiment of the present invention is coupled to a dam.
Figure 9 is a side cross-sectional view of the flow rate increasing portion of the hydroelectric pumping system according to a preferred embodiment of the present invention.
FIG. 10 is a state diagram illustrating a state in which a backflow prevention gate of a hydroelectric pumping system according to a preferred embodiment of the present invention is rotated by an external water source.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. The same reference numerals shown in the drawings denote the same members. In describing the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as to avoid obscuring the subject matter of the present invention.

1 is a side view of a hydro pumping system according to a preferred embodiment of the present invention, Figure 2 is a plan view of a hydro pumping system according to a preferred embodiment of the present invention, Figure 3 is a hydro pumping system according to a preferred embodiment of the present invention Conceptual view showing the water stored in the second reservoir of the system and the external water source is introduced into the inlet pipe, Figure 4 is a side view of Figure 3, Figure 5 is a V type of hydro pumping system according to a preferred embodiment of the present invention 6 is a plan view of the W type of the hydro pumping system according to a preferred embodiment of the present invention, Figure 7 is a V-type and W type of the hydro pumping system according to a preferred embodiment of the present invention in the second reservoir 8 is a conceptual diagram illustrating a state in which water and an external water source are introduced into an inlet pipe, and FIG. 8 illustrates a state where a hydroelectric pumping system according to a preferred embodiment of the present invention is coupled with a dam. 9 is a side cross-sectional view of a flow rate increasing portion of a hydroelectric pumping system according to a preferred embodiment of the present invention, Figure 10 is a reverse flow prevention gate of the hydroelectric pumping system according to a preferred embodiment of the present invention by an external water source This is a state diagram showing the rotation.

Hydroelectric pumping system according to a preferred embodiment of the present invention includes a first reservoir 100, the second reservoir 200, the guide portion 300 and the inlet pipe 400, pumping pump 10, generator ( 20, 21, the work road 30, the discharge pipe 210, the first sluice 220, the first water beam 230, the partition wall 301, the valley 302, the protrusion 303, the guide vane 310 ), The floating block 320, the backflow prevention gate 330, the rotating shaft 331, the inclined portion 340, the bent portion 350, the flow rate increasing portion 360, the flow rate increasing plate 361, rotary pump ( 410 and the second water strip 500 may be further included.

In the present invention, the term "water resource" includes water stored in sea water, lakes and dams.

The first reservoir 100 serves to store the water resources, the water stored in the first reservoir 100 is an external water source introduced into the inlet pipe 400 to be described later, the first as described above The external water source introduced into the reservoir 100 is moved to the second reservoir 200 by the pump pump 10 to operate the generator 20, and then through the inlet pipe 400 to the inside of the first reservoir 100. Can be introduced again.

That is, water introduced into the first reservoir tank 100 may be circulated.

As shown in FIGS. 1 and 2, a plurality of pumping pumps 10 for moving water to the second reservoir 200 are installed in the first reservoir 100 as described above. 2, an inflow pipe 400 into which water moved from the reservoir 200 flows is installed.

The second reservoir 200 is a member for storing or moving the water moved from the first reservoir 100 by the pump pump 10 to the discharge pipe 210, the second reservoir 200 is shown in FIG. As shown in FIG. 3, the water moved from the first reservoir tank 100 to the second reservoir tank 200 has a potential energy.

In addition, the pump pump 10, as shown in Figure 2, the amount of water that can be stored in the first reservoir 100 and the second reservoir 200, that is, the first reservoir 100 and the second reservoir ( 200 may be installed according to the size of the pump, the pump pump 10 is a base station power plant by the present invention developed for 24 hours by moving the water stored in the first reservoir 100 to the second reservoir 200 It is to be able to play the role of.

In more detail, the pump pump 10 is a second reservoir tank to store the water stored in the first reservoir tank 100 to maintain the amount of power generation even if it is impossible to generate power to the external water source or the amount of the external water source is small. It is moved to 200 and used in a circular manner.

Meanwhile, as illustrated in FIG. 1, a plurality of discharge pipes 210 through which water moved to the second reservoir 200 is discharged is installed in the second reservoir 200.

The discharge pipe 210 as described above is preferably provided in a position opposite to the place where the water is introduced into the pump pump 10 in the second reservoir 200, the height of the outlet side than the inlet side to increase the flow rate of water It is good to be installed low. That is, the discharge pipe 210 may be installed to be inclined downward.

In addition, the first side beam 230 is preferably installed at the inlet side of the discharge pipe 210, the first water beam 230 is installed between the plurality of discharge pipe 210 and at the same time shown in FIG. As shown in FIG. 1, each of which is connected to the inlet of the two discharge pipes 210, the cross section is formed in a streamline shape, and is manufactured in the shape of a tip that is narrowed toward the end of the second reservoir 200 side. Induce water to the discharge pipe 210 and at the same time to increase the flow rate of water.

It is also preferable that the discharge pipe 210 as described above is provided with a generator 20 for converting the kinetic energy generated during the movement of water into electrical energy.

On the other hand, the upper part of the discharge pipe 210 is preferably provided with a work road 30 to facilitate the maintenance of the present invention, such a work road 30 will be open to the public at ordinary times may be used for tourism, Accordingly, safety fences or guardrails may be installed.

In addition, a separate first sluice 220 may be installed in the discharge pipe 210, and when the first sluice 220 is installed, water may be stored in the second reservoir 200.

Accordingly, when the amount of power generation is insufficient or a large amount of power generation is required, efficient power production may be achieved by opening the first gate 220. When the generation of power is sufficient by only an external source, the first gate 220 may be closed and the first reservoir may be formed. The stored water of 100 may be stored in the second reservoir 200 using the pump pump 10.

The guide portion 300 is a partition wall 301 is formed on the outside, a plurality of guide vanes 310 are installed on the partition wall 301, the external water source is present outside the partition wall 301 The guide vane 310 is positioned where water discharged from the discharge pipe 210 falls.

Here, the partition 301 serves to allow the external water source to be concentrated through the guide vane 310, but the external water source directly into the inlet pipe 400 which will be described later even when the partition wall 301 is not installed. Can be introduced. That is, although shown in the figure, in the present invention, the partition wall 301 is not necessarily a necessary member.

The guide vane 310 as described above is described by distinguishing the inside and the outside for convenience, where the inside of the guide vane 310 is the first reservoir 100 side, the outside is the side into which the external water source is introduced.

Inside the guide vane 310 as described above, the inclined portion 340 is formed to guide the water discharged from the discharge pipe 210 to the inlet pipe 400 to be described later.

On the other hand, the outer side of the guide vane 310, as shown in Figure 3, it is preferable to be manufactured in the form of a tip that narrows the width of the cross section toward the outside to increase the flow rate of the external water source.

As described above, the external water source introduced between the plurality of guide vanes 310 is introduced into the inlet pipe 400 to be described later, and at this time, the water discharged to the discharge pipe 210 may be simultaneously introduced into the inlet pipe 400. have.

On the other hand, as shown in Figure 3, between the guide vanes 310, it is preferable that the floating block 320 and the backflow prevention gate 330 is formed, the floating block 320 is shown in FIG. As shown in the partially enlarged view, it may be a mesh from which a certain particle or more is filtered out.

It is preferable that the flow rate increasing part 360 is installed inside the floating material stopping plate 320 such that the flow rate of the external water source passing through the floating material stopping plate 320 is increased. As shown in FIG. 9, a plurality of flow increase plates 361 are included.

The flow rate increasing plate 361 as described above is arranged a plurality of spaced apart from the top, the flow rate increasing plate 361 disposed on the top is installed to be inclined downward so that the external water source is directed to the inlet pipe side, the flow rate increases toward the bottom The inclination of the plate 361 is gentle, and the lower flow rate increasing plate 361 is provided horizontally.

The reason why the inclination of the flow rate increasing plate 361 is changed as described above is to guide the upper water source to the lower side of the external water source passing through the guide vane 310, and the lower water source is the inlet pipe 400. This is because the height is equal to or less than the difference, so no additional slope is required.

In addition, the backflow prevention gate 330 seals the space between the guide vanes 310 when the water level of the external water source is lower than the water level of the first reservoir tank 100 so that water falls out of the guide vanes 310. It acts to prevent outgoing phenomena, ie backflow of water.

As shown in FIG. 10, the non-return gate 330 is connected to the rotating shaft 331 so as to be rotatable, and a lower end thereof is bent toward the inflow pipe 400 to be described later. .

Accordingly, the reverse flow prevention gate 330 is opened while the external water source is introduced by the water pressure flowing therein, and the guide vane 310 is formed by the weight of the non-return gate 330 when the external water source is weak in water or there is no inflow. The space between the shells can be sealed to prevent backflow.

In addition, the non-return gate 330 as described above serves to prevent the water drained from the second reservoir 200 from leaking to the outside, and the water falling from the discharge pipe 210 is returned to the non-return gate 330. It is blocked by the bottom of the to prevent leakage to the outside.

The non-return gate 330 as described above is capable of preventing backflow in tidal power generation using only a difference between tides or in a dam or a reservoir.

Meanwhile, as shown in FIGS. 5 to 6, a plurality of valleys 302 may be formed in the partition wall 301. Due to the formation of the valleys 302, the partition wall 301 has a predetermined angle in the advancing direction of water. It is installed at an inclined angle, the valley 302 may be a rounded protrusion formed in the outer direction to facilitate the introduction of the external water source to the guide vane 310.

Accordingly, the partition wall 301 illustrated in FIGS. 5 to 6 has an area of contact with an external water source more than the partition wall 301 illustrated in FIG. 2, and the guide vane 310 installed in the partition wall 301 is increased. The number will also increase. The number of guide vanes 310 installed in the W type shown in FIG. 6 will be larger than the V type shown in FIG. 5.

Meanwhile, the width of the cross section of the guide vane 310 installed in the partition wall 301 having the valley 302 as described above decreases toward the outside, and at the same time, as shown in FIG. 7, the guide vane 310 On the outside is bent portion 350 is bent to one side is formed.

The bent portion 350 is characterized in that the inclination of the predetermined angle to match the direction of the water, accordingly, the flow rate and the flow rate of the external water source introduced between the guide vanes 310, the guide shown in FIG. It may remain the same as the vane 310.

In addition, FIG. 8 illustrates a hydroelectric pumping system in which the present invention and the dam are coupled, and when the present invention is installed in the dam, the amount of external water passing through the inlet pipe 400 is used as the water gate 40 of the dam. You can adjust the opening and closing.

The inlet pipe 400 is a member that serves to discharge the water guided by the inclined surface of the guide vane 310 and the external water source passing through the guide vane 310 to the first reservoir 100, such a Inside the inlet pipe 400 is preferably a generator 21 for converting the kinetic energy of the water into electrical energy.

As described above, the generator 21 installed inside the inlet pipe 400 preferably adopts a turbine type, but is not limited thereto.

In addition, a second water beam 500 may be installed at an inlet side of the inflow pipe 400. The second water beam 500 is shown in FIG. 3, one side of which is two of the plurality of inflow pipes. It is connected to the inlet of the two inlet pipe 400, the other side is adjacent to the inclined portion 340 of the guide vane 310 to move the water along the inclined portion 340 of the plurality of inlet pipe 400 It serves to branch to two of the inlet pipe (400).

The second water beam 500 is formed in the same cross-section, that is, the cross-section is streamlined as the first water beam 230 described above, the end of the side adjacent to the inclined surface is made in the shape of the tip to facilitate the branching of water. .

As described above, since the cross section of the second water beam 500 is manufactured in a streamlined shape, the width of the middle portion is larger than the end portion, thereby narrowing the space between the second water beam 500 and the guide vane 310. In addition, the flow rate of the branched water is increased.

As shown in FIG. 3, the water guided to the inlet pipe 400 by the second water line 500 is guided to two inlet pipes, and the water guided to the inlet pipe 400 is suspended by a suspended material plate ( It may be mixed with an external water source passed through 320).

On the other hand, the inlet pipe 400 may be provided with a rotary pump 410 to maintain the pressure in the inlet pipe 400 at a low pressure, when the rotary pump 410 is installed the pressure inside the inlet pipe 400 Since the pressure is relatively lower than the pressure at the side of the guide vane 310, the flow rate of water introduced into the inlet pipe 400 may be increased due to such a differential pressure.

In addition, the inflow pipe 400 is installed to be inclined downward toward the first reservoir 100, the flow rate of the water discharged to the first reservoir 100 and the external water source is preferably increased, the second sluice 420 is formed You can also adjust the amount of water that passes.

Meanwhile, another embodiment of the present invention is shown in FIGS. 5 and 6, and yet another embodiment of the present invention shown in FIGS. 5 and 6 moves more external water sources into the first reservoir 100. It is characterized in that the bone 302 is formed in the partition wall 301 of the guide portion 300 to be introduced.

When the valleys 302 are formed in the barrier rib 301 as described above, the total length of the barrier rib 301 may be long, and thus, the number of guide vanes 310, the discharge pipe 210, and the inlet pipe 400 may be increased. As the inflow of water can be increased, more power can be obtained than the preferred embodiment of the present invention shown in FIG.

As the valley 302 is formed as described above, the outer end of the guide vane 310 installed on the inclined partition wall 301 is bent to be guided to the water inlet pipe 400 as shown in FIG. Characterized by the 350 is formed.

In the hydro pumping system according to a preferred embodiment of the present invention having the configuration as described above will be described that the power is generated in accordance with the flow of water.

First, the non-return gate 330 is opened so that an external water source outside the partition 301 flows through the guide vane 310 and the inlet pipe 400 sequentially into the first reservoir 100. .

An external water source introduced through the guide vane 310 generates power while driving the generator 20 installed inside the inlet pipe 400.

Then, the water stored in the first reservoir tank 100 is moved to the second reservoir 200 by the pump pump 10, the moved water has a potential energy, the flow rate by the first tidebo 230 In this increased state is discharged to the outlet via the inlet of the discharge pipe (210).

At this time, when the generator 20 is installed inside the discharge pipe 210, power generation may be performed by the flow rate.

Thereafter, the water discharged from the outlet of the discharge pipe 210 is moved downward along the inclined portion 350 of the guide vane 310, the downwardly moved water is the two inlet pipe 400 by the second water beam 500 Branched into the ()), and at the same time the external water source may be introduced through the guide vane (310).

As described above, the water flowing through the second water beam 500 and the external water source pass through the generator 21 installed inside the inflow pipe 400 when the water flows into the first reservoir 100 and the kinetic energy is increased. It is converted into electrical energy to generate electricity.

That is, in the present invention, the power generation can be made in each of the generators 20 and 21 installed inside the discharge pipe 210 and the inlet pipe 400.

The best embodiments have been disclosed in the drawings and the specification. Herein, specific terms have been used, but they are used only for the purpose of illustrating the present invention and are not intended to limit the scope of the present invention as defined in the claims or the claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible from this. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10-pump pump 20,21-generator
30-work road 40-sluice
100-first reservoir
200-second reservoir 210-discharge pipe
220-first floodgate 230-first watershed
300-Guide Section 301-Bulk
302-Goal 303-Protrusion
310-guide vane 320-float jam
330-non-return gate 331-axis of rotation
340-Slant 350-Bent
360-speed increase 361-speed increase
400-inlet pipe 410-rotary pump
500-second strand

Claims (11)

First reservoir; and
A second reservoir installed at a position higher than the first reservoir, wherein a water stored in the first reservoir is moved by a pump, and a discharge pipe for discharging the moved water is provided;
A guide part having a guide vane for receiving water discharged from the discharge pipe and guiding downward; and
Includes the inlet pipe to the water guided by the guide vanes and the external water source is introduced into the first reservoir tank, the generator is installed therein;
The barrier rib is formed on the outside of the guide portion, the guide vane is installed on the barrier rib,
The guide vane and the inlet pipe is provided with a plurality,
The guide vane is made of a cutting-edge cross section of the outside so that the flow rate of the external water source is increased,
Floating material stopping plate is installed between the guide vanes to prevent foreign matter contained in an external water source is introduced into the inlet pipe; And
A backflow prevention gate for selectively blocking an external water source passing between the guide vanes; and
And a rotating shaft installed in the non-return gate to rotate the non-return gate by water pressure of an external water source passing between the guide vanes. First reservoir; and
A second reservoir installed at a position higher than the first reservoir, wherein a water stored in the first reservoir is moved by a pump, and a discharge pipe for discharging the moved water is provided;
A guide part having a guide vane for receiving water discharged from the discharge pipe and guiding downward; and
Includes the inlet pipe to the water guided by the guide vanes and the external water source is introduced into the first reservoir tank, the generator is installed therein;
The barrier rib is formed on the outside of the guide portion, the guide vane is installed on the barrier rib,
The guide vane and the inlet pipe is provided with a plurality,
The guide vane is made of a cutting-edge cross section of the outside so that the flow rate of the external water source is increased,
The guide vane has an inclined portion formed to be inclined downward so that the water discharged to the discharge pipe is guided to the inlet pipe; And
And a second water beam connected to the lower side of the inclined portion to increase the water pressure of the water introduced into the inflow pipe. First reservoir; and
A second reservoir installed at a position higher than the first reservoir, wherein a water stored in the first reservoir is moved by a pump, and a discharge pipe for discharging the moved water is provided;
A guide part having a guide vane for receiving water discharged from the discharge pipe and guiding downward; and
Includes the inlet pipe to the water guided by the guide vanes and the external water source is introduced into the first reservoir tank, the generator is installed therein;
The barrier rib is formed on the outside of the guide portion, the guide vane is installed on the barrier rib,
The guide vane and the inlet pipe is provided with a plurality,
The guide vane is made of a cutting-edge cross section of the outside so that the flow rate of the external water source is increased,
A valley formed in the partition wall; and
A plurality of guide vanes formed on the partition wall; and
The guide vane is made in the form of a cross-section of the outer side so that the flow rate of the external water source is increased, the bent portion bent in the direction in which water is introduced to the outside of the guide vane;
And a plurality of bones are continuously formed, and protruded outwardly to the plurality of bones to protrude an external water source to the guide vanes. The method according to any one of claims 1 to 3,
The discharge pipe is provided with a plurality,
A generator installed inside the discharge pipe; and
A first sluice installed in the discharge pipe to control the flow of water stored in the second reservoir;
And a first water beam installed at an inlet of the discharge pipe so that the water pressure of the water passing through the discharge pipe is increased. The method according to claim 1,
And a flow rate increasing part installed inside the suspended material suspended plate so as to increase the flow rate of the external water source passing through the suspended material suspended plate.
The flow rate increasing part includes a flow rate increasing plate spaced apart from the top to the bottom, the flow rate increase plate of the upper is installed to be inclined downward so that the external water source is guided to the inlet pipe side, the slope is gradually gradually from the top to the bottom Hydroelectric pumping system, characterized in that the installed, but the flow rate plate of the lower portion is installed horizontally. The method according to claim 2,
One side of the second water strip is connected to an inlet of two inlet pipes of the plurality of inlet pipes, and the other side is adjacent to the inclined portion and the water moved along the inclined portion of the inflow of two of the plurality of inlet pipes Hydro pumping system, characterized in that the branch to the pipe. The method according to any one of claims 1 to 3,
A rotary pump which makes the inside of the inlet pipe low pressure relative to the outside of the inlet pipe; and
Hydropower pumping system further comprises; the second sluice installed in the inlet pipe. The method according to any one of claims 1 to 3,
The discharge pipe and the inlet pipe is a hydroelectric pumping system, characterized in that the height of the outlet is installed lower than the height of the inlet. delete delete delete

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