KR102502406B1 - Power providing system and method using pumped-storage hydroelectricity, photovoltaics and wind power generation - Google Patents

Abstract

The present invention relates to a power supply system and method using pumped storage power generation, solar power generation, and wind power generation. The power supply system, according to the present invention, comprises: a solar power generation apparatus; a wind power generation apparatus; a pumped storage power generation apparatus; and a power distribution control unit. According to the present invention, the shortcomings of each power generation method can be compensated for.

Description

Power providing system and method using pumped-storage hydroelectricity, photovoltaics and wind power generation

The present invention relates to a power supply system and method using pumped storage power generation, photovoltaic power generation, and wind power generation.

Pumped-storage power generation is a power generation method that obtains electricity by pumping water from the lower reservoir to the upper reservoir during late nights and weekends when electricity prices are low, and then dropping the water during the week and weekdays when the power usage rate increases. Pumped-storage power generation is widely used as a standby/alternative reserve resource because it has excellent start-up characteristics and does not require special standby costs.

Photovoltaic power generation is a power generation method that converts solar energy during the day into electrical energy. Photovoltaic power generation has the advantage of reducing greenhouse gas emissions, but has the disadvantage of irregular power generation dependent on the amount of sunlight.

Wind power generation is a power generation method that produces electricity using wind energy, and converts mechanical energy generated as blades rotate into electrical energy through a generator. Wind power generation also has a disadvantage in that it is difficult to obtain stable power due to natural wind volume changes.

The problem to be solved by the present invention is to provide a power supply system and method using pumped storage power generation, solar power generation, and wind power generation, which can compensate for the disadvantages of each power generation method by integrating pumped storage power generation, solar power generation, and wind power generation. is to provide

The problem to be solved by the present invention is not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

A power supply system using pumped storage power generation, photovoltaic power generation, and wind power generation according to the present invention for solving the above technical problems includes a photovoltaic power generation device for generating power using sunlight; Wind power generators that generate electricity using wind power; A pumped-storage power generation device, comprising: an upper storage tank that stores rainwater and is installed on a relatively high ground; A lower storage tank that stores groundwater and is installed in a relatively low-lying area; a first connection pipe connecting the upper storage tank and the lower storage tank; a first valve installed in the first connection pipe; a water pump installed in the first connection pipe to pump water stored in the lower storage tank to the upper storage tank through the first connection pipe; a second connection pipe connecting the upper storage tank and the lower storage tank; a second valve installed in the second connection pipe; a hydraulic turbine installed in the second connection pipe and driven as the water stored in the upper storage tank falls into the lower storage tank through the second connection pipe; and a generator generating electric power from driving the hydro turbine and supplying the electric power to a power system. and a power distribution control unit, comprising: a communication unit receiving information on required power of the power system; a photovoltaic power measurement unit measuring the power produced by the photovoltaic device; Wind power generation power measurement unit for measuring the power produced by the wind power generator; a pumped-storage power measurement unit measuring the power produced by the pumped-storage generator; Power supplied from the photovoltaic power generation device and the wind power generation device based on the required power of the power system, the power produced by the solar power generation device, the power produced by the wind power generation device, and the power produced by the pumped storage power generation device. A power distribution unit for distributing to the water pump and the power system; and opening each of the first valve and the second valve based on the required power of the power system, the power produced by the photovoltaic power generation device, the power produced by the wind power generator, and the power produced by the pumped-storage power generation device. and a power distribution control unit including a pumping/power generation mode controller controlling the pumped storage power generation device to one of a pumping mode, a power generation mode, a simultaneous pumping/power generation mode, and an idle mode by controlling closing.

When the sum of the power produced by the solar power generator and the power produced by the wind power generator is greater than the required power of the power system, the power distribution unit among the power supplied from the solar power generator and the wind power generator The pumped storage generator is operated by supplying as much power as required by the system to the power system and supplying remaining power to the pumping pump, and the pumping/generation mode controller opens the first valve and closes the second valve. mode can be controlled.

The pumped-storage power generation device further includes a water level measurement unit for measuring a water level stored in the upper storage tank, and when the water level is higher than a maximum critical water level, the power distribution unit is supplied from the photovoltaic power generation device and the wind power generator. All electric power is supplied to the power system, and the pumping/generation mode controller closes both the first valve and the second valve to control the pumped storage generator in the idle mode.

When the sum of the power produced by the solar power generator and the power generated by the wind power generator is not greater than the required power of the power system, the power distribution unit converts both the power supplied from the solar power generator and the wind power generator. supplied to the power system, and the pumping/power generation mode controller closes the first valve and opens the second valve so that the water stored in the upper reservoir falls through the second connection pipe to the lower reservoir The pumped-storage generator may be controlled in the power generation mode.

When the sum of the power produced by the photovoltaic generator, the power produced by the wind power generator, and the power produced by the pumped-storage generator is greater than the required power of the power system, the power distribution unit may include the photovoltaic generator and the wind power generator. Of the power supplied from the device, the power required by the power system minus the power generated by the pumped storage generator is supplied to the power system and the remaining power is supplied to the pump, and the pumped storage/generation mode control unit supplies the power to the pump. By opening both the first valve and the second valve, the pumped storage generator may be controlled in the simultaneous pumping/power generation mode.

The pumped-storage generator further includes a water level measuring unit for measuring a level of water stored in the upper storage tank, and all power supplied from the photovoltaic generator and the wind power generator is supplied to the power system by the power distribution unit. Then, the pumping/power generation mode control unit closes both the first valve and the second valve when the water level is not higher than the minimum critical level, thereby controlling the pumped storage power generation device in the idle mode, and If the water level is higher than the minimum critical water level, the pumped-storage generator may be controlled in the power generation mode.

In the power supply method of a power supply system using pumped storage power generation, photovoltaic power generation and wind power generation according to the present invention for solving the above technical problem, the power supply system includes photovoltaic power generation that generates power using sunlight. Device; Wind power generators that generate electricity using wind power; and a pumped-storage power generation device, comprising: an upper storage tank storing rainwater and installed on a relatively high ground; A lower storage tank that stores groundwater and is installed in a relatively low-lying area; a first connection pipe connecting the upper storage tank and the lower storage tank; a first valve installed in the first connection pipe; a water pump installed in the first connection pipe to pump water stored in the lower storage tank to the upper storage tank through the first connection pipe; a second connection pipe connecting the upper storage tank and the lower storage tank; a second valve installed in the second connection pipe; a hydraulic turbine installed in the second connection pipe and driven as the water stored in the upper storage tank falls into the lower storage tank through the second connection pipe; and a generator for generating electric power from driving the hydro turbine and supplying the electric power to a power system, wherein the power supply method includes: (a) receiving information on required power of the power system; (b) measuring the power produced by the photovoltaic device; (c) measuring the power produced by the wind turbine; and (d) the photovoltaic power generation device and the wind power generation device based on the required power of the power system, the power produced by the solar power generation device, the power produced by the wind power generation device, and the power produced by the pumped-storage power generation device. By distributing power supplied from the water pump and the power system and controlling the opening and closing of the first valve and the second valve, respectively, the pumped storage power generation device is operated in a pumping mode, a power generation mode, a simultaneous pumping/power generation mode, and a shutdown mode. It is characterized in that it includes the step of controlling in one of the modes.

In the step (d), when the sum of the power produced by the photovoltaic power generation device and the power produced by the wind power generation device is greater than the required power of the power system, the power supplied from the photovoltaic power generation device and the wind power generator supplying as much power as required by the power system to the power system and supplying the remaining power to the pumping pump; and opening the first valve and closing the second valve to control the pumped-storage generator in the pumping mode.

The pumped-storage power generation device further includes a water level measurement unit for measuring a water level stored in the upper storage tank, and in step (d), when the water level is equal to or higher than a maximum critical water level, the photovoltaic power generation device and the wind power generator supplying all of the power supplied from the power system to the power system; and controlling the pumped-storage generator to be in the idle mode by closing both the first valve and the second valve.

In the step (d), when the sum of the power produced by the photovoltaic power generation device and the power produced by the wind power generator is not greater than the required power of the power system, the photovoltaic power generation device and the wind power generator are supplied. supplying all power to the power system; And closing the first valve and opening the second valve so that the water stored in the upper storage tank falls to the lower storage tank through the second connection pipe, thereby controlling the pumped storage power generation device in the power generation mode. can include more.

The step (d) may include measuring the power produced by the pumped-storage generator; When the sum of the power produced by the solar power generation device, the power produced by the wind power generator, and the power produced by the pumped-storage generator is greater than the required power of the power system, supplied from the photovoltaic power generator and the wind power generator supplying power obtained by subtracting the power produced by the pumped-storage generator from the required power of the power system to the power system and supplying the remaining power to the pumped-storage pump; and opening both the first valve and the second valve to control the pumped storage generator in the simultaneous pumping/power generation mode.

The pumped-storage power generation device further includes a water level measurement unit for measuring a water level stored in the upper storage tank, and in the step (d), both the power supplied from the photovoltaic power generation device and the wind power generator are transmitted to the power system. After the supplying step, determining whether the water level is equal to or higher than a minimum critical water level; and controlling the pumped storage power generation device to be in the idle mode by closing both the first valve and the second valve when the water level is not higher than the minimum critical water level, wherein the pumped storage power generation device is set to the power generation mode. The step of controlling to may be performed when the water level is equal to or higher than the lowest critical water level.

According to the present invention described above, providing a power supply system and method using positive storage power generation, solar power generation, and wind power generation, which can compensate for the disadvantages of each power generation method by integrating pumped storage power generation, solar power generation, and wind power generation can do.

Effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below.

1 shows a configuration of a power supply system using pumped storage power generation, photovoltaic power generation, and wind power generation according to an embodiment of the present invention.
FIG. 2 shows a specific configuration of a power distribution control unit of the power supply system according to FIG. 1 .
3 is a flowchart of a power supply method using pumped storage power generation, photovoltaic power generation, and wind power generation according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. Substantially the same elements in the following description and accompanying drawings are indicated by the same reference numerals, respectively, and redundant description will be omitted. In addition, in describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

1 shows a configuration of a power supply system (hereinafter referred to as 'power supply system') using pumped storage power generation, photovoltaic power generation, and wind power generation according to an embodiment of the present invention.

A power supply system according to an embodiment of the present invention includes a photovoltaic device 100, a wind power generator 200, a power distribution control unit 300, a pumped storage device 400, and a power system 500.

The photovoltaic device 100 generates power using sunlight. The photovoltaic device 100 typically generates power only during daytime when sunlight is sufficient.

The wind power generator 200 generates power using wind power. The wind power generator 200 generates power only when a certain wind speed is given.

The power distribution control unit 300 receives power generated from the photovoltaic power generation device 100 and the wind power generation device 200, distributes it to the positive storage power generation device 400 and the power system 500, and pumps the power generation device 400 ) controls the pumping/generation mode.

The pumped storage generator 200 includes an upper storage tank 410, a lower storage tank 420, a first connection pipe 430, a first valve 435, a pump 440, a second connection pipe 450, and a second connection pipe 450. It includes a valve 455, a hydraulic turbine 460, a generator 470, and a water level measuring unit 480.

The upper reservoir 410 stores rainwater and water pumped from the lower reservoir 420 . The upper storage tank 410 is installed on a relatively high ground.

The lower storage tank 420 stores groundwater and water falling from the upper storage tank 410 . The lower storage tank 420 is installed in a relatively low lowland compared to the upper storage tank 410.

The first connection pipe 430 connects the upper storage tank 410 and the lower storage tank 420. The first valve 435 and the water pump 440 are installed in the first connection pipe 230. When the pumped storage generator 400 operates in pumping mode, the first valve 435 is opened, and the pump 440 transfers water stored in the lower storage tank 420 through the first connection pipe 430 to the upper storage tank. It is positive as (410). The water pump 440 is driven by using power produced by the photovoltaic device 100 and the wind power generator 200 and distributed through the power distribution control unit 300 .

The second connection pipe 450 connects the upper storage tank 410 and the lower storage tank 420 separately from the first connection pipe 430 . The second valve 455 and the hydraulic turbine 460 are installed in the second connection pipe 450. When the pumped-storage generator 400 operates in the power generation mode, the second valve 455 is opened, and the water stored in the upper reservoir 410 of the hydro turbine 460 passes through the second connection pipe 450 by a drop. It is driven as it falls into the lower storage tank 420 through the The generator 470 produces power from driving the hydro turbine 460. Electric power produced by the generator 470, that is, electric power produced by the pumped-storage generator 200 is supplied to the power system 500.

In the pumping mode of the pumped storage power plant 400, the first valve 435 is open and the second valve 455 is closed. In the power generation mode of the pumped storage generator 400, the second valve 455 is open and the first valve 435 is closed. The pumped storage power generation device 400 operates not only in the pumping mode and the power generation mode, but also in the simultaneous pumping/power generation mode and the idle mode. In the simultaneous pumping/power generation mode, both the first valve 435 and the second valve 455 are opened, and the pumping pump 440 first connects the water stored in the lower storage tank 420 by using the supplied power. At the same time as the water is pumped into the upper storage tank 410 through the pipe 430, the water stored in the upper storage tank 410 falls to the lower storage tank 420 through the second connection pipe 450 due to a fall, and the hydraulic turbine Electric power is produced via 460 and generator 470 . In the idle mode, both the first valve 435 and the second valve 455 are closed, and both the water pump 440 and the water turbine 460 do not operate.

The water level measurement unit 480 measures the level of water stored in the upper reservoir 410 . When the water level in the upper storage tank 410 is equal to or higher than the preset highest critical water level, the pumping of water from the lower storage tank 420 to the upper storage tank 410 needs to be stopped to prevent water from overflowing. On the other hand, when the water level in the upper storage tank 410 is below the preset minimum critical water level, power generation according to the opening of the second valve 455 needs to be stopped to prevent water depletion or the like.

FIG. 2 shows a specific configuration of the power distribution control unit 300 of the power supply system according to FIG. 1 .

The power distribution control unit 300 includes a communication unit 310, a solar power generation power measurement unit 320, a wind power generation power measurement unit 330, a pumped-storage generation power measurement unit 340, a power distribution unit 350, and a pumped-storage/generation unit. A mode controller 360 is included.

The communication unit 310 receives information about required power of the power system 500 from an operator of the power system 500 . Also, the communication unit 310 receives water level measurement information from the water level measuring unit 480 of the pumped storage power plant 400 .

The photovoltaic power measurement unit 320 measures the power produced by the photovoltaic device 100 .

The wind power generation power measurement unit 330 measures the power produced by the wind power generator 200 .

The pumped-storage power measurement unit 340 measures the power produced by the pumped-storage generator 400 .

The power distribution unit 350 is based on the required power of the power system 500, the power produced by the solar power generation device 100, the power produced by the wind power generator 200, and the power produced by the pumped storage power generation device 400. Thus, power supplied from the photovoltaic device 100 and the wind power generator 200 is distributed to the pumping pump 440 and the power system 500 of the pumped storage device 400 .

The pumping/generation mode control unit 360 includes the required power of the power system 500, the power produced by the solar power generation device 100, the power produced by the wind power generator 200, and the power produced by the pumped storage power generation device 400. Based on the above, by controlling the opening and closing of the first valve 435 and the second valve 455, the pumped storage generator 400 is set to any one of a pumping mode, a power generation mode, a simultaneous pumping/power generation mode, and an idle mode. Control.

Hereinafter, a detailed operation of the power distribution controller 300 will be described with reference to FIG. 3 .

3 is a flowchart of a power supply method using pumped storage power generation, photovoltaic power generation, and wind power generation according to an embodiment of the present invention.

In step S310, the communication unit 310 receives information on required power of the power system 500.

In step S315, the communication unit 310 receives water level measurement information from the water level measurement unit 480 of the pumped storage power generation device 400.

In step S320, the photovoltaic power measuring unit 320 measures the power produced by the photovoltaic device 100.

In step S325, the wind power generation power measurement unit 330 measures the power produced by the wind power generator 200.

In step S330 , the power distribution unit 350 determines whether the sum of the power produced by the photovoltaic device 100 and the power produced by the wind power generator 200 is greater than the required power of the power system 500 .

When the sum of the power produced by the solar power generation device 100 and the power produced by the wind power generation device 200 is greater than the required power of the power system 500, in step S335, the power distribution unit 350 performs the photovoltaic power generation device Of the power supplied from (100) and the wind power generator 200, as much power as required by the power system 500 is supplied to the power system 500, and the remaining power is supplied to the pumping pump 440.

In step S340, the pumping/generation mode control unit 360 opens the first valve 435 and closes the second valve 455 to control the pumped storage generator 400 in the pumping mode.

In step S345, when the water level stored in the upper storage tank 410 is equal to or higher than the highest critical water level, in step S350, the power distribution unit 350 supplies power from the photovoltaic device 100 and the wind power generator 200. All are supplied to the power system 500.

In step S355, the pumping/generation mode controller 360 closes both the first valve 435 and the second valve 455 to control the pumped storage generator 400 in the idle mode.

In step S330, when the sum of the power produced by the photovoltaic device 100 and the power produced by the wind power generator 200 is not greater than the required power of the power system 500, in step S360, the power distribution unit 350 ) supplies all of the power supplied from the photovoltaic device 100 and the wind power generator 200 to the power system 500.

In step S365, if the water level stored in the upper storage tank 410 is equal to or higher than the minimum critical level, in step S375, the pumping/power generation mode controller 360 closes the first valve 435 and turns the second valve 455 on. By opening, the water stored in the upper storage tank 410 is allowed to fall to the lower storage tank 420 through the second connection pipe 450, thereby controlling the pumped storage generator 400 in the power generation mode.

When the pumped storage generator 400 is controlled in the power generation mode, in step S380 , the pumped storage power generator 340 measures the generated power of the pumped storage generator 400 .

And in step S385, the power distribution unit 350 determines that the sum of the power produced by the solar power generation device 100, the power produced by the wind power generator 200, and the power produced by the pumped-storage power generation device 400 is the power system 500. Determine whether it is greater than the required power of

When the sum of the power produced by the photovoltaic power generation device 100, the power produced by the wind power generator 200, and the power produced by the pumped-storage generator 400 is greater than the required power of the power system 500, in step S390, power The distribution unit 350 generates power obtained by subtracting the power produced by the pumped-storage generator 400 from the required power of the power system 500 among the power supplied from the solar power generation device 100 and the wind power generation device 200. It is supplied to the system 500 and the remaining power is supplied to the pump 440 of the pumped storage generator 400. For example, the production power of the solar power generation device 100 is 100 MW, the production power of the wind power generation device 200 is 70 MW, the production power of the pumped-storage generator 400 is 50 MW, and the required power of the power system 500 is 180 MW. In other words, 220 MW, which is the sum of the power produced by the photovoltaic power generation device 100, the power produced by the wind power generator 200, and the power produced by the pumped-storage generator 400, is greater than the required power of the power system 500, 180 MW, Of the 170 MW of power supplied from the solar power generator 100 and the wind power generator 200, 130 MW, which is the power obtained by subtracting 50 MW of the power produced by the pumped-storage generator 400 from the required power of 180 MW of the power system 500, is the power. It is supplied to the grid 500, and the remaining power of 40 MW is supplied to the pump 440 of the pumped storage generator 400. At this time, power of 50 MW is supplied from the pumped-storage generator 400 to the power system 500 . That is, the pumped-storage generator 400 supplies power to the power system 500 and simultaneously receives power from the photovoltaic device 100 and the wind power generator 200 through the power distribution control unit 300.

In step S395, the pumping/power generation mode controller 360 opens both the first valve 435 and the second valve 455 to control the pumped storage generator 400 in the simultaneous pumping/power generation mode. Therefore, in the pumped storage generator 400, the pump 440 pumps the water stored in the lower storage tank 420 to the upper storage tank 410 through the first connection pipe 430 by the supplied power, and at the same time, As the water stored in the upper storage tank 410 falls to the lower storage tank 420 through the second connector 450 due to a fall, power is produced through the hydro turbine 460 and the generator 470 to supply power to the power system ( 500) is supplied.

According to an embodiment of the present invention, the sum of the power produced by the photovoltaic device 100, the power produced by the wind power generator 200, and the power produced by the pumped-storage generator 400 is greater than the required power of the power system 500. In the case of a large amount, the resulting surplus power is used for pumping of the pumped storage generator 400, so power loss can be minimized and power efficiency can be increased.

In step S365, if the water level stored in the upper storage tank 410 is not higher than the minimum critical water level, the pumping/power generation mode control unit 360 closes both the first valve 435 and the second valve 455 to generate pumped storage power. The device 400 is controlled in idle mode.

Combinations of each block of the block diagram and each step of the flowchart accompanying the present invention may be performed by computer program instructions. Since these computer program instructions may be loaded into a processor of a general-purpose computer, a special-purpose computer, or other programmable data processing equipment, the instructions executed by the processor of the computer or other programmable data processing equipment are each block of the block diagram or flowchart. In each step, means to perform the functions described are created. These computer program instructions may also be stored in a computer usable or computer readable memory that can be directed to a computer or other programmable data processing equipment to implement functionality in a particular way, such that the computer usable or computer readable memory It is also possible for the instructions stored in to produce an article of manufacture containing instruction means for performing the function described in each block of the block diagram or each step of the flow chart. The computer program instructions can also be loaded on a computer or other programmable data processing equipment, so that a series of operational steps are performed on the computer or other programmable data processing equipment to create a computer-executed process to generate computer or other programmable data processing equipment. It is also possible that the instructions performing the processing equipment provide steps for executing the functions described in each block of the block diagram and each step of the flowchart.

Additionally, each block or each step may represent a module, segment or portion of code that includes one or more executable instructions for executing specified logical function(s). It should also be noted that in some alternative embodiments it is possible for the functions recited in blocks or steps to occur out of order. For example, two blocks or steps shown in succession may in fact be performed substantially concurrently, or the blocks or steps may sometimes be performed in reverse order depending on their function.

The above description is merely an example of the technical idea of the present invention, and various modifications and variations can be made to those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed according to the claims below, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

Claims (12)

As a power supply system using pumped storage power generation, solar power generation and wind power generation,
A photovoltaic device that generates electricity using sunlight;
Wind power generators that generate electricity using wind power;
As a pumped-storage power plant,
An upper storage tank that stores rainwater and is installed on a relatively high ground;
A lower storage tank that stores groundwater and is installed in a relatively low-lying area;
a first connection pipe connecting the upper storage tank and the lower storage tank;
a first valve installed in the first connection pipe;
a water pump installed in the first connection pipe to pump water stored in the lower storage tank to the upper storage tank through the first connection pipe;
a second connection pipe connecting the upper storage tank and the lower storage tank;
a second valve installed in the second connection pipe;
a hydraulic turbine installed in the second connection pipe and driven as the water stored in the upper storage tank falls into the lower storage tank through the second connection pipe; and
A pumped-storage generator comprising a generator for generating power from the driving of the hydro turbine and supplying it to the power system; and
As a power distribution control unit,
a communication unit for receiving information on required power of the power system;
a photovoltaic power measurement unit measuring the power produced by the photovoltaic device;
Wind power generation power measurement unit for measuring the power produced by the wind power generator;
a pumped-storage power measurement unit measuring the power produced by the pumped-storage generator;
Power supplied from the photovoltaic power generation device and the wind power generation device based on the required power of the power system, the power produced by the solar power generation device, the power produced by the wind power generation device, and the power produced by the pumped storage power generation device. A power distribution unit for distributing to the water pump and the power system; and
The first valve and the second valve are opened and closed, respectively, based on the required power of the power system, the power produced by the photovoltaic power generation device, the power produced by the wind power generator, and the power produced by the pumped-storage power generation device. A power distribution control unit including a pumping / power generation mode control unit for controlling the pumped storage power generation device to one of a pumping mode, a power generation mode, a simultaneous pumping / power generation mode, and an idle mode by controlling
When the sum of the power produced by the photovoltaic power generation device and the power produced by the wind power generator is greater than the required power of the power system,
The power distribution unit supplies as much power as required by the power system among the power supplied from the photovoltaic power generation device and the wind power generator to the power system and supplies the remaining power to the pumping pump,
The pumping/generation mode control unit controls the pumping power generation device in the pumping mode by opening the first valve and closing the second valve,
When the sum of the power produced by the photovoltaic power generation device and the power produced by the wind power generator is not greater than the required power of the power system,
The power distribution unit supplies all of the power supplied from the photovoltaic power generation device and the wind power generation device to the power system,
The pumping/power generation mode control unit closes the first valve and opens the second valve so that the water stored in the upper storage tank falls to the lower storage tank through the second connection pipe, thereby driving the pumped storage power generation device to the power generation device. control mode,
When the pumped storage power generation device is controlled in the power generation mode, the pumped storage power generation power measurement unit measures the generated power of the pumped storage power generation device,
When the sum of the power produced by the photovoltaic power generation device, the power produced by the wind power generator, and the power produced by the pumped-storage generator is greater than the required power of the power system,
The power distribution unit supplies power obtained by subtracting the power produced by the pumped-storage generator from the required power of the power system among the power supplied from the photovoltaic power generation device and the wind power generator to the power system, and supplies the remaining power to the pumped-storage system. supplied by a pump,
The power supply system of claim 1 , wherein the pumping/generation mode control unit controls the pumped storage generator to be in the simultaneous pumping/generation mode by opening both the first valve and the second valve. delete According to claim 1,
The pumped-storage power generation device further includes a water level measuring unit for measuring the water level stored in the upper storage tank,
If the water level is above the highest critical water level,
The power distribution unit supplies all of the power supplied from the photovoltaic power generation device and the wind power generation device to the power system,
The power supply system of claim 1 , wherein the pumping/generation mode control unit controls the pumped storage generator to be in the idle mode by closing both the first valve and the second valve. delete delete According to claim 1,
The pumped-storage power generation device further includes a water level measuring unit for measuring the water level stored in the upper storage tank,
After all of the power supplied from the photovoltaic power generator and the wind power generator is supplied to the power system by the power distribution unit, the pumping/power generation mode control unit may perform the control unit if the water level is equal to or higher than the minimum critical level. The pumped storage generator is controlled in the idle mode by closing both the first valve and the second valve, and the pumped storage generator is controlled in the power generation mode when the water level is equal to or higher than the minimum critical water level. system. As a power supply method of a power supply system using pumped storage power generation, solar power generation, and wind power generation,
The power supply system,
A photovoltaic device that generates electricity using sunlight;
Wind power generators that generate electricity using wind power; and
As a pumped-storage power plant,
An upper storage tank that stores rainwater and is installed on a relatively high ground;
A lower storage tank that stores groundwater and is installed in a relatively low-lying area;
a first connection pipe connecting the upper storage tank and the lower storage tank;
a first valve installed in the first connection pipe;
a water pump installed in the first connection pipe to pump water stored in the lower storage tank to the upper storage tank through the first connection pipe;
a second connection pipe connecting the upper storage tank and the lower storage tank;
a second valve installed in the second connection pipe;
a hydraulic turbine installed in the second connection pipe and driven as the water stored in the upper storage tank falls into the lower storage tank through the second connection pipe; and
Including a generator for generating power from the driving of the hydro turbine and supplying it to the power system,
The power supply method,
(a) receiving information on required power of the power system;
(b) measuring the power produced by the photovoltaic device;
(c) measuring the power produced by the wind turbine; and
(d) based on the required power of the power system, the power produced by the solar power generation device, the power produced by the wind power generation device, and the power produced by the pumped-storage power generation device, from the photovoltaic power generation device and the wind power generator By distributing the supplied power to the pump and the power system and controlling the opening and closing of the first valve and the second valve, respectively, the pumped storage generator is operated in a pumping mode, a power generation mode, a simultaneous pumping/power generation mode, and an idle mode. Including the step of controlling with any one of,
In step (d),
When the sum of the power produced by the photovoltaic power generation device and the power produced by the wind power generator is greater than the required power of the power system,
supplying as much power required by the power system among the power supplied from the photovoltaic generator and the wind power generator to the power system and supplying the remaining power to the pumping pump;
controlling the pumped-storage generator in the pumping mode by opening the first valve and closing the second valve;
When the sum of the power produced by the photovoltaic power generation device and the power produced by the wind power generator is not greater than the required power of the power system,
supplying all of the power supplied from the photovoltaic generator and the wind power generator to the power system;
Closing the first valve and opening the second valve so that the water stored in the upper storage tank falls through the second connection pipe to the lower storage tank, thereby controlling the pumped-storage power generation device in the power generation mode;
measuring electric power produced by the pumped storage generator when the pumped storage generator is controlled in the power generation mode;
When the sum of the power produced by the photovoltaic power generation device, the power produced by the wind power generator, and the power produced by the pumped-storage generator is greater than the required power of the power system,
Among the power supplied from the photovoltaic power generation device and the wind power generation device, power required by the power system minus the power produced by the pumped storage generator is supplied to the power system and the remaining power is supplied to the pumping pump step; and
and controlling the pumped-storage generator to the simultaneous pumping/generation mode by opening both the first valve and the second valve. delete According to claim 7,
The pumped-storage power generation device further includes a water level measuring unit for measuring the water level stored in the upper storage tank,
In step (d),
If the water level is above the highest critical water level,
supplying all of the power supplied from the photovoltaic generator and the wind power generator to the power system; and
The power supply method of claim 1, further comprising controlling the pumped-storage generator to be in the idle mode by closing both the first valve and the second valve. delete delete According to claim 7,
The pumped-storage power generation device further includes a water level measuring unit for measuring the water level stored in the upper storage tank,
In step (d),
Following the step of supplying both the power supplied from the solar power generation device and the wind power generation device to the power system,
Determining whether the water level is equal to or higher than a minimum critical water level; and
If the water level is not higher than the minimum critical water level, closing both the first valve and the second valve to control the pumped-storage generator to be in the idle mode;
The step of controlling the pumped-storage generator in the power generation mode is performed when the water level is equal to or higher than a minimum critical water level.

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