KR102522842B1 - Tidal Generator Test device - Google Patents

Abstract

The present invention relates to a tidal generator test device, which allows an experiment for measuring the amount of power generation of a tidal generator in various environments, comprising: a water storage tank (10) with a pump unit (11); an open seawater tank unit (20) for receiving and storing seawater; an inland seawater tank unit (30) installed adjacent to the open seawater tank unit (20); and a control unit for measuring the amount of power generation of a tidal generator (G).

Description

Tidal Generator Test device {Tidal Generator Test device}

The present invention relates to a test device for a tidal power generator, and more particularly, realizes the environment of creative power generation using high tide and ebb generation using low tide through the level of seawater stored in an open sea water tank and an inland sea water tank, and open sea water An experiment to drive a tidal power generator by the movement of seawater due to the difference in the level of seawater stored in the tank and the inland seawater tank. It relates to a tidal power generator test device that allows an experiment to measure the amount of power generated by a tidal power generator.

In general, tidal power generation is a power generation method in which potential energy is converted into kinetic energy from a water level difference between tides and low tides and converted into electrical energy.

In other words, from low tide to high tide, the sea level gradually rises and the water level rises.

At this time, tidal power generation is a method in which an aberration is installed on the inflow side of the tide to utilize the water level difference between the tides, the aberration is rotated by the tide, and a generator is driven by the rotational force to produce electric power.

Here, tidal power generation is divided into creative power generation that uses the water level difference between the open sea and the inland sea when the tide comes in to turn an aberration wheel, and on the contrary, tidal power generation that uses the water level difference between the open sea and the inland sea when the tide goes out. , there is single-current power generation that utilizes one direction and double-current power generation that utilizes both directions.

Therefore, Korean Patent Registration No. 10-2099385 'Tidal Power Generation Device' proposed a method of utilizing creative power generation and sunset power generation by opening and closing the water gate.

However, tidal power generation has many limitations in space, the tidal difference varies depending on the location, the rate at which the water level changes is not constant, and the surrounding environment is changed as much as the generation is generated by blocking the flow of seawater. Before installation, it was necessary to be able to present sufficient grounds to convince residents who are affected by sufficient preliminary review and the surrounding environment to be installed.

Therefore, there is a need for a tidal generator test device that can measure the efficiency of the tidal power generator in an environment with various water level differences and the time when the tide and ebb change, etc., and in the environment of creative power generation and ebb generation.

Republic of Korea Patent Registration No. 10-2099385 (2020.04.03.)

The present invention has been made to solve the above problems, and an object of the present invention is to provide a tidal power generator test device, the water level of the open sea tank and the inland sea tank to match the tidal water level difference corresponding to the different external environments. It is to provide a tidal power generator test device capable of controlling a car.

In addition, it is to provide a tidal power generator test device capable of confirming the amount of power generation that changes with time by implementing the water level difference that changes with time in the external environment and the time of high tide and low tide.

In addition, it is to provide a tidal generator test apparatus that can help select a tidal power generation method suitable for the environment by allowing both single-flow and double-flow tests to be performed in an environment having the same water level difference.

The objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, in the tidal generator test apparatus for testing the tidal generator (G) according to the present invention, the seawater used in the test of the tidal generator (G) is stored, and the pump unit supplies the seawater to the outside (11) is equipped with a water storage tank (10); A first supply valve 23 for receiving and storing the seawater and opening and closing the supply line 21 supplying seawater to the tidal generator (G), and an inflow into which the seawater passing through the tidal generator (G) is introduced An open sea water tank unit 20 equipped with a first inlet valve 24 that opens and closes the line 22; A second supply valve 31 installed adjacent to the open sea water tank unit 20 and opening and closing the supply line 21 for supplying seawater to the tidal generator G, and passing through the tidal generator G an inland water tank unit 30 provided with a second inlet valve 32 that opens and closes the inlet line 22 into which seawater flows; A test standard according to the test is set, and the operation of the pump unit 11, the first supply valve 23, the second supply valve 31, and the first inflow corresponding to the test standard It includes a valve 24 and a controller that controls opening and closing of the second inlet valve 32 and measures the amount of power generated by the tidal generator (G).

And, the storage tank 10 is characterized in that the magnet filter 12 is provided on one side to adsorb metal foreign substances floating in the seawater.

In addition, the tidal power generator test apparatus is characterized in that a vortex prevention wall is provided on the inner wall of the space where the seawater is stored to reduce the height deviation of the sea level caused by the vortex.

In addition, the tidal power generator test apparatus is provided with a level gauge that measures the level of the seawater and outputs a height value, and the control unit generates an alarm when the height value exceeds the test standard.

In addition, the control unit is provided with a sensor unit for measuring seawater data including at least one of a temperature value, a water pressure value, and a flow rate value of the seawater passing through both ends of the tidal generator (G), and the control unit is provided with a sensor unit for measuring the seawater It is characterized in that an alarm is generated when the data exceeds the test criteria.

In addition, the height at which the supply line 21 is installed is higher than the height at which the inlet line 22 is installed.

In addition, the open sea water tank part 20 is provided with a floor lifting part 26 that moves up and down to adjust the height of the lower surface at the lower part, so that the water level difference between the bottom surface of the open sea water tank part 20 and the inland sea water tank part 30 is provided. It is characterized by being able to adjust.

In addition, the control unit operates the pump unit 11 to supply the seawater to the open sea water tank unit 20, and when the seawater level in the open sea water tank unit 20 exceeds the test standard, When the first supply valve 23 and the second inlet valve 32 are opened, the seawater stored in the open sea water tank part 20 moves to the inland sea water tank part 30 via the tidal power generator G. It is characterized in that for measuring the amount of power generated.

In addition, the control unit controls the pump unit 11 so that the water level difference between the open sea water tank unit 20 and the inland sea water tank unit 30 is constant, so that the tidal power generator G generates power at a constant flow rate. to be

In addition, the inland seawater tank unit 30 is provided with a second recovery line 33 on one side to discharge and recover the seawater to the water storage tank 10 so that the water level in the inland seawater tank unit 30 is constant. characterized by being maintained.

In addition, the control unit stops the operation of the pump unit 11 when the power generation amount of the tidal power generator G is less than the test standard, and the first supply valve 23 and the second inlet valve 32 ), and the second supply valve 31 and the first inlet valve 24 are opened so that the seawater stored in the inland sea water tank part 30 passes through the tidal power generator (G) and the open sea water tank part 20 ) and characterized in that it moves to and develops.

In addition, the open sea water tank unit 20 is provided with a first recovery line 25 on one side to discharge and recover the seawater to the water storage tank 10 so that the water level in the open sea water tank unit 20 is constant. characterized by being maintained.

In addition, the tidal generator test device can be installed by adjusting the number of the supply line 21 and the inlet line 22 so as to adjust the amount of seawater required according to the range of use of the tidal generator (G). to be characterized

The tidal power generator test apparatus according to the present invention has an effect of controlling the water level difference between the open sea tank and the inland sea tank to match the tidal water level difference corresponding to different external environments.

In addition, there is an effect of confirming the amount of power generation that changes with time by implementing the water level difference that changes according to the time of the external environment and the time of high tide and low tide.

In addition, by allowing both single-flow and double-flow tests to be performed in an environment having the same water level difference, there is an effect of helping to select a tidal power generation method suitable for the environment.

1 is a schematic diagram of a tidal power generator test apparatus according to the present invention.
Figure 2 is a schematic diagram of the tidal power generator test apparatus of the present invention for creative power generation.
Figure 3 is a schematic diagram of the tidal power generator test apparatus of the present invention for the standby state.
Figure 4 is a schematic diagram of the tidal power generator test apparatus of the present invention for sunset power generation.
Figure 5 is a schematic diagram of the floor elevation according to the present invention.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms, only these embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to fully inform the holder of the scope of the invention, and the present invention is only defined by the scope of the claims.

With reference to the accompanying drawings below, specific details for the practice of the present invention will be described in detail. Like reference numbers refer to like elements, regardless of drawing, and "and/or" includes each and every combination of one or more of the recited items.

Although first, second, etc. are used to describe various components, these components are not limited by these terms, of course. These terms are only used to distinguish one component from another. Accordingly, it goes without saying that the first component mentioned below may also be the second component within the technical spirit of the present invention.

Terms used in this specification are for describing the embodiments and are not intended to limit the present invention. In this specification, singular forms also include plural forms unless specifically stated otherwise in a phrase. As used herein, "comprises" and/or "comprising" does not exclude the presence or addition of one or more other elements other than the recited elements.

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used in a meaning commonly understood by those of ordinary skill in the art to which the present invention belongs. In addition, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless explicitly specifically defined.

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

1 is a schematic diagram of a tidal power generator test apparatus according to the present invention.

As shown, the tidal power generator (G) test apparatus according to the present invention is largely provided with a water storage tank 10, an open sea water tank unit 20, an inland sea water tank unit 30, and a control unit (not shown).

First, the reservoir 10 stores seawater used for testing the tidal power generator G, and is provided with a pump unit 11 supplying the seawater to the outside.

In addition, the water tank 10 is connected to a water supply line (not shown) for supplying seawater used in the test from the outside, and to the external seawater tank unit 20 and the inland seawater tank unit 30, respectively, so that the water level can be adjusted by releasing seawater. The first recovery line 25 and the second recovery line 33 are provided, and the first recovery line 25 and the second recovery line 33 are provided with a magnet filter 12 at the end side and used for the test. It is preferable to adsorb foreign substances and metal foreign substances floating in the seawater.

In addition, the tidal power generator test apparatus of the present invention measures the amount of power generation of the tidal power generator (G) through the water level difference between the open sea water tank part 20 and the inland sea water tank part 30, A vortex prevention wall (not shown) is provided on the inner surface of the inland seawater tank 30, that is, on the inner wall of the space where seawater is stored, to reduce the vortex generated by the pump unit 11 or the flow rate, thereby increasing the height of the sea level by the vortex By reducing the deviation, the instantaneous deviation of the flow rate and pressure of seawater used for power generation of the tidal power generator (G) is reduced.

That is, the tidal generator test apparatus composed of the reservoir 10, the open sea water tank 20, and the inland sea water tank 30 is equipped with a vortex prevention wall on the inner wall of the space where seawater is stored to prevent the height deviation of the sea level caused by the vortex. reduce

At this time, the external appearance of the water tank 10, the outdoor water tank part 20, and the inland sea water tank part 30 is not particularly limited, but the capacity of seawater that can be stored inside can be displayed so that the amount of seawater used in the test can be reduced. It is desirable to make it clear to the tester.

Next, the outdoor seawater tank unit 20 stores seawater supplied through the pump unit 11 provided in the water tank 10, and opens and closes the supply line 21 for supplying seawater to the tidal generator G. A first supply valve 23 and a first inlet valve 24 for opening and closing an inlet line 22 into which seawater passing through the tidal generator (G) is introduced are provided.

Next, the inland sea water tank unit 30 is installed adjacent to the outdoor sea water tank unit 20, and the second supply valve 31 opens and closes the supply line 21 for supplying seawater to the tidal power generator G, A second inlet valve 32 is provided to open and close the inlet line 22 into which seawater passing through the tidal generator G is introduced.

In addition, the reservoir 10, the open sea water tank unit 20, and the inland sea water tank unit 30 are provided with level gauges that measure the level of the sea water and output a height value, and the control unit determines that the height value meets the test standard. If exceeded, an alarm is generated.

In other words, the control unit stores the maximum height value and minimum height value of seawater as test standards, and generates an alarm when the height value measured through the level gauge exceeds the maximum height value stored as test standard or is less than the minimum height value. .

Here, the level gauge can be installed on one side of the outer circumferential surface so that the tester can check the heights of the water storage tank 10, the open sea tank part 20, and the inland sea water tank part 30, and the control unit measures the height of the water tank where the alarm occurred for a high level alarm. It is possible to prevent seawater from overflowing the water tank by opening the return line and controlling the discharge of seawater into the water tank 10, and it is preferable to operate the pump unit 11 to supply more seawater to the water tank in response to a low water level alarm. .

At this time, the heights of the above-described first supply valve 23 and the second supply valve 31 and the heights of the first inlet valve 24 and the second inlet valve 32 are installed in parallel, respectively, and the first supply valve ( 23) and the second supply valve 31 are preferably installed higher than the heights of the first inlet valve 24 and the second inlet valve 32, and a detailed description of the height difference will be described later.

In other words, the supply line 21 and the inlet line 22 connecting the open sea water tank unit 20 and the inland sea water tank unit 30 are installed horizontally side by side with each other so that the conditions for performing creative power generation and sunset power generation are the same. is to do it

Next, the control unit sets test criteria according to the test, and in response to the test criteria, the operation of the pump unit 11, the first supply valve 23, the second supply valve 31, and the The opening and closing of the first inlet valve 24 and the second inlet valve 32 is controlled, and the amount of power generated by the tidal generator (G) is measured.

In addition, the control unit is provided with a sensor unit (not shown) for measuring seawater data including one or more of a temperature value, a water pressure value, and a flow rate value of seawater passing through the tidal power generator (G), and the measured seawater data is transmitted to the control unit. By outputting, the amount of power generated for the environment in which the tidal generator (G) generates power is measured.

At this time, the sensor unit is provided on one side of the first supply valve 23 and the second supply valve 31 to measure seawater data of seawater flowing into the tidal generator (G), and the first inlet valve 24 and It is provided on one side of the second inlet valve 32 to measure seawater data of seawater discharged from the tidal generator (G).

In other words, it is installed between the supply line 21 and the tidal generator (G) to measure seawater data of seawater flowing into the tidal generator (G), and between the inlet line 22 and the tidal generator (G). It is installed and can measure seawater data of seawater passing through the tidal power generator (G).

That is, the sensor unit measures seawater data of seawater passing through the tidal power generator G, and the location of the sensor unit is not limited.

Through this, it is preferable that the control unit generates an alarm when the seawater data exceeds the test standard so that the tester can know this.

However, the control unit may use a computer including a storage device, a mechanical device capable of switch operation through DAQ (Data Acquisition), a PLC (Programmable Logic Controller), and a similar digital device, and may be used in a form mounted inside a panel. It does not exclude a design that is installed on one side of one of the components and controlled in the field or a design that is controlled from the outside using a communication module (not shown), and the above-mentioned alarm outputs text, sound, vibration, light, video, etc. At least one of the shapes can be designed to be output through the control unit, and accordingly, the control unit is not limited to the shape of a warning light and can be implemented in various forms such as a display, a speaker, an LED module, a vibration generating means, etc. It is not.

In addition, the types of tests are the creation test and the eclipse test. The creation test is a method of generating tidal power generator (G) with the difference in the water level between the sea level of the open sea tank and the sea level of the inland sea tank, and the eclipse test is The tidal power generator (G) is generated by a water level difference in which the sea level of the inland sea water tank is higher than the sea level of the open sea water tank, and a detailed description will be described later.

Figure 2 is a schematic diagram of the tidal power generator test device of the present invention for creative power generation.

As shown, the first supply valve 23 is installed on the upper part of the open sea water tank unit 20, and the first inlet valve 24 is installed on the lower part, and the second supply valve (24) is installed on the upper part of the inland sea water tank unit 30. 31), the second inlet valve 32 is installed at the lower part, and the tidal generator G is disposed therebetween.

Then, seawater is introduced into the upper part of the tidal generator (G) and discharged to the lower part, and power is generated by rotating the turbine of the tidal generator (G).

In other words, the height of the first supply valve 23 and the second supply valve 31 and the height of the water level between the first inlet valve 24 and the second inlet valve 32 are provided so that the tidal power generator ( G) to develop.

Here, the control unit sets the test standard to the creation test, and operates the pump unit 11 in response to the test standard of the creation test to supply the seawater to the open sea water tank unit 20 to adjust the water level in the open sea water tank unit 20. Raise it to correspond to the test standard.

At this time, the control unit sets the level of seawater stored in the open sea water tank unit 20 to be higher than the level of seawater stored in the inland sea water tank unit 30 so that the seawater flows from the open sea water tank unit 20 toward the inland sea water tank unit 30, The first supply valve 23 and the second inlet valve 32 are opened to allow seawater to move from the open sea water tank part 20 to the inland sea water tank part 30, thereby testing the tidal power generator G for creative power generation. gets started

That is, when the level of the seawater in the open sea water tank unit 20 exceeds the test standard, the first supply valve 23 and the second inlet valve 32 are opened.

In addition, the control unit controls the operating time of the pump unit 11 in consideration of the water level difference in the area where the tidal power generator G is used to control the water level of the open sea water tank unit 20, and recovers the inland sea water tank unit 30 By opening and closing the line 33, it is possible to control the time during which seawater fills the internal seawater tank unit 30.

In addition, the control unit keeps the water level in the open sea water tank unit 20 constant through the pump unit 11, and opens the recovery line 33 of the inland sea water tank unit 30 to keep the water level in the inland sea water tank unit 30 constant. By maintaining this, the pressure and flow rate of seawater applied to the tidal power generator (G) can be kept constant and the amount of power generation can be measured, so it is possible to secure the reliability of the amount of power generated.

3 is a schematic diagram of the tidal generator test apparatus of the present invention for standby conditions, and FIG. 4 is a schematic diagram of the tidal generator test apparatus of the present invention for sunset power generation.

As shown, the tidal power generator G generates power until the height of the seawater in the inland seawater tank unit 30 is equal to the maximum height of the seawater in the openwater tank unit 20 by the above-described creation test, and the amount of power generation is Over time, the water level becomes similar, so it goes down.

In addition, the heights of the sea level of the outdoor sea tank part 20 and the inland sea water tank part 30 are in parallel, so that the tidal generator G does not generate power, and the control unit sets the test standard to the eclipse test. 1 The supply valve 23, the first inlet valve 24, the second supply valve 31, and the second inlet valve 32 are all shielded.

After that, the recovery line 33 connected to the open sea water tank unit 30 is opened to lower the level of sea water to correspond to the test standard.

In addition, the second supply valve 31 and the first inlet valve 24 are opened so that the seawater moves from the inland sea water tank part 30 to the open sea water tank part 20, and the tidal power generator (G) powers the sunset by the water level difference. this is going on

That is, when the amount of power generated by the tidal generator G is less than the test standard, the operation of the pump unit 11 is stopped, and the second supply valve 31 and the first inlet valve 24 are opened to generate the tidal generator ( G) proceed with the development of the eclipse.

At this time, the control unit opens the first recovery line 25 so that the seawater contained in the inland sea water tank unit 30 moves to the open sea water tank unit 20, but the water level in the open sea water tank unit 20 does not rise. It is preferable to measure the amount of falling water generation of the tidal power generator (G) so that the seawater contained in the seawater tank unit 30 is lowered over time and the sea level of the open seawater tank unit 20 does not rise.

In other words, the controller of the tidal power generator test device of the present invention pumps seawater into the open sea water tank 20 using the pump unit 11 to keep the height of the open sea water tank 20 constant at the maximum height for creative power generation. supply, and to recover seawater to the water storage tank 10 by opening the recovery line 33 to keep the height of the open sea water tank unit 20 constant at the minimum height with respect to ebb generation.

Therefore, the tidal generator test apparatus of the present invention has the above-described configuration, and the tidal generator ( The total amount of seawater passing through G) can be calculated, and the amount of power generation that changes over time can be calculated.

In addition, the total amount of seawater passing through the tidal power generator (G) can be calculated through the flow rate value and water pressure value of the seawater in the inland seawater tank unit 30 moving to the outdoor seawater tank unit 20 and the time during which the ebb generation test is conducted, , it becomes possible to calculate the amount of power generation that changes over time.

Therefore, the control unit of the present invention includes the first supply valve 23, the second supply valve 31, the first inlet valve 24, the second inlet valve 32, and the first recovery line 25 And, while controlling the opening and closing of the second recovery line 33, it is provided to adjust the open area so that various test environments can be established by adjusting the amount of seawater passing through the tidal generator (G).

In addition, in the correct embodiment of the present invention, the first supply valve 23 and the second supply valve 31 are displayed as two flow paths, and the first inlet valve 24 and the second inlet valve 32 and , The recovery line 33 is shown as one flow path, but it is natural that the number of flow paths may vary according to the amount of seawater used in the test, and the number is not limited.

However, the tidal generator test apparatus of the present invention is provided with one or more supply lines 21 and inlet lines 22 so as to adjust the amount of seawater required according to the range of use of the tidal generator G, so that a wider range of The tidal generator (G) can be tested.

That is, the tidal generator test device may be installed by adjusting the number of the supply line 21 and the inlet line 22 so as to adjust the amount of seawater required according to the range of use of the tidal generator G.

5 is a schematic diagram of a floor elevation unit according to the present invention.

As shown, the open sea water tank unit 20 is provided with a floor lifting unit 26 that moves up and down to adjust the height of the lower surface at the bottom thereof, so that the water level difference between the bottom surface of the open sea water tank unit 20 and the inland sea water tank unit 30 is provided. can be adjusted.

In other words, since the amount of seawater stored in the water tank 10 is limited, the water level difference between the open sea water tank 20 and the inland sea water tank 30 is also limited. ) By increasing the water level, the tidal generator test apparatus of the present invention can implement a wider range of water level differences.

Therefore, the tidal generator test apparatus of the present invention has an effect of controlling the water level difference between the open sea tank and the inland sea tank to match the tidal water level difference corresponding to different external environments.

In addition, the first supply valve 23, the second supply valve 31, the first inlet valve 24, the second inlet valve 32, the first recovery line 25, the second recovery It is possible to control the number of passages or the range of opening and closing of the line 33 so that the amount of seawater used for power generation of the tidal generator (G) can be adjusted so that the water level difference that changes over time in the external environment and the tide By embodying the time of ebb tide, there is an effect of checking the amount of power generation that changes over time.

Through this, there is an effect of helping to select a method of tidal power generation suitable for the environment by allowing both single-flow and double-flow tests to be performed in an environment having the same water level difference.

Although the embodiments of the present invention have been described with reference to the above and accompanying drawings, those skilled in the art to which the present invention pertains can implement the present invention in other specific forms without changing the technical spirit or essential features. You will understand that there is Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

10: water tank
11: pump unit 12: magnet filter
20: open sea water tank
21: supply line 22: inlet line
23: first supply valve 24: first inlet valve
25: first recovery line 26: floor elevation
30: inland sea water tank
31: second supply valve 32: second inlet valve
33: second recovery line

Claims (13)

In the tidal generator test apparatus for testing the tidal generator (G),
A water storage tank 10 storing seawater used in the test of the tidal power generator (G) and having a pump unit 11 supplying the seawater to the outside;
A first supply valve 23 for receiving and storing the seawater and opening and closing the supply line 21 supplying seawater to the tidal generator (G), and an inflow into which the seawater passing through the tidal generator (G) is introduced An open sea water tank unit 20 equipped with a first inlet valve 24 that opens and closes the line 22;
A second supply valve 31 installed adjacent to the open sea water tank unit 20 and opening and closing the supply line 21 for supplying seawater to the tidal generator G, and passing through the tidal generator G an inland water tank unit 30 provided with a second inlet valve 32 that opens and closes the inlet line 22 into which seawater flows;
A test standard according to the test is set, and the operation of the pump unit 11, the first supply valve 23, the second supply valve 31, and the first inflow corresponding to the test standard A control unit for controlling the opening and closing of the valve 24 and the second inlet valve 32 and measuring the amount of power generated by the tidal generator G; tidal generator test apparatus comprising a. According to claim 1,
The water storage tank 10 is provided with a magnet filter 12 on one side to adsorb metal foreign substances floating in the seawater. According to claim 1,
The tidal generator test apparatus is characterized in that the vortex prevention wall is provided on the inner wall of the space in which the seawater is stored to reduce the height deviation of the sea level caused by the vortex. According to claim 1,
The tidal power generator test device is provided with a level gauge that measures the level of the seawater and outputs a height value,
The control unit generates an alarm when the height value exceeds the test standard. According to claim 1,
The control unit,
A sensor unit is provided for measuring seawater data including at least one of a temperature value, a water pressure value, and a flow rate value of the seawater passing through both ends of the tidal generator (G),
The control unit generates an alarm when the seawater data exceeds the test standard. According to claim 1,
The tidal generator test apparatus, characterized in that the height at which the supply line 21 is installed is higher than the height at which the inlet line 22 is installed. According to claim 1,
The open sea water tank part 20 is provided with a floor lifting part 26 that moves up and down to adjust the height of the lower surface at the lower part to adjust the water level difference between the bottom surfaces of the open sea water tank part 20 and the inland sea water tank part 30. A tidal generator test apparatus, characterized in that it can. According to claim 1,
The control unit,
Operating the pump unit 11 to supply the seawater to the open sea water tank unit 20,
When the level of the seawater in the open sea water tank unit 20 exceeds the test standard,
When the first supply valve 23 and the second inlet valve 32 are opened, the seawater stored in the open sea water tank part 20 moves to the inland sea water tank part 30 via the tidal power generator G. A tidal generator test apparatus, characterized in that for measuring the amount of power generated. According to claim 8,
The control unit,
The tidal generator test apparatus characterized in that the tidal generator (G) generates power at a constant flow rate by controlling the pump unit (11) so that the water level difference between the open sea water tank part (20) and the inland sea water tank part (30) is constant . According to claim 8,
The seawater tank unit 30,
A tidal power generator test apparatus, characterized in that the water level of the inland sea water tank part 30 is kept constant by providing a second recovery line 33 on one side to discharge and recover the sea water into the water storage tank 10. According to claim 8,
The control unit,
When the amount of power generated by the tidal generator (G) is less than the test standard,
Stop the operation of the pump unit 11,
The first supply valve 23 and the second inlet valve 32 are shielded,
By opening the second supply valve 31 and the first inlet valve 24, the seawater stored in the inland sea water tank part 30 moves to the open sea water tank part 20 via the tidal generator G and generates power. A tidal generator test apparatus, characterized in that to do. According to claim 11,
The open sea water tank unit 20,
A tidal power generator test apparatus, characterized in that the first recovery line 25 is provided on one side to discharge and recover the seawater to the water storage tank 10, so that the water level of the open sea water tank unit 20 is kept constant. According to claim 1,
The tidal generator test device is characterized in that it can be installed by adjusting the number of the supply line 21 and the inlet line 22 so as to adjust the amount of seawater required according to the range of use of the tidal generator (G) tidal power generator test device.

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