KR102362451B1 - Wave power generation apparatus and system and power generation prediction method using the same - Google Patents

Abstract

The present invention is a power generation apparatus that is buried in the coast and generates power using waves, the power generation apparatus comprising a power generation unit that generates power using wave pressure and a connection unit coupled to the power generation unit to connect the plurality of power generation units, wherein the power generation unit includes a power generation plate including a plurality of power generation elements that generate power using vibrations according to changes in wave pressure and water pressure and a cover disposed on the upper and lower sides of the power generation plate to transmit the vibration to the plurality of power generation elements and to protect the power generation plate from external impact.

Description

WAVE POWER GENERATION APPARATUS AND SYSTEM AND POWER GENERATION PREDICTION METHOD USING THE SAME }

The present invention relates to a wave power generation device and system and a method for predicting power generation using the same.

Recently, there is a growing interest in carbon reduction around the world, and conversion to new and renewable energy is being made. However, solar energy and wind energy, which are responsible for the main amount of power generation, have a disadvantage of very severe temporal fluctuations.

Due to these disadvantages, solar energy and wind energy have problems such as duck curves at sunrise and sunset, and therefore, the importance of a base power generator that provides a constant amount of power at all times increases.

A typical power generation device that can provide a constant amount of power generation at all times is a piezoelectric power generation device. Piezoelectric power generation using a piezo element can produce electricity using pressure or vibration as an energy source, but requires constant vibration (pressure), and the amount of power generated There is a disadvantage that it must be installed in a wide area to increase the size.

Waves along the coast where piezoelectric power is installed have a slight increase or decrease in wave height depending on the season, but because they provide continuous energy, wave power using them is being developed.

However, most of the methods use wave power directly at sea level. In this case, because the seabed topography of the coast is greatly deformed by waves, secondary environmental problems (e.g. erosion and over-sedimentation of nearby beaches) shoreline deformation).

Therefore, there is a need for a power generation device that does not cause damage to the natural landscape and deformation of the coastline, and can provide a base amount of power to respond to the duck curve.

It is an object of the present invention to provide a wave power generation device and system that is buried in the coast and generates power using vibrations caused by waves and changes in water pressure, and a method for predicting power generation using the same.

A wave power generation device according to one aspect for realizing the object of the present invention is a power generation device that is buried in the coast and generates power using waves, comprising: a power generation unit that generates power using wave pressure; and a connection unit coupled to the power generation unit to connect a plurality of the power generation units,

The power generation unit may include: a power generation plate including a plurality of power generation elements that generate power using vibrations according to changes in the wave pressure and water pressure; and a cover disposed on the upper and lower sides of the power generation plate to transmit the vibration to the plurality of power generation elements, and to protect the power generation plate from external impact.

The connection part is disposed on one side of the power generation plate, a first coupling part having a coupling protrusion; and a second coupling part disposed on the other side of the power generation plate and having a coupling groove into which the coupling protrusion is inserted.

Here, the coupling protrusion is formed in a spherical shape, the coupling groove is formed in a shape corresponding to the shape of the coupling protrusion, and the coupling protrusion is partially inserted into the coupling groove to be coupled to the coupling groove.

The first coupling part and the second coupling part are formed in a polygonal pyramid shape.

In addition, the first coupling part and the second coupling part, the bottom surface is coupled to the side surface of the power generation plate, the vertices formed by the plurality of side surfaces are arranged to face the outside.

In addition, the coupling protrusion is formed at the vertex of the first coupling part, and the coupling groove is formed at the vertex of the second coupling part.

In addition, the connection unit may further include a power transmission line that moves the power generated by the power generation plate by the coupling of the first coupling unit and the second coupling unit, and is connected to the power generation plate and through which the power moves.

In addition, a wave power generation system according to one feature for realizing the object of the present invention includes a plurality of wave power generation devices that are embedded in the coast and generate power using vibrations caused by waves and changes in water pressure power generation complex; and storing the power generated in the power generation complex, measuring the amount of power generation for each of the plurality of wave power generation devices, and measuring the wave pressure and water pressure to correlate the wave pressure and water pressure and the power generation amount according to terrain and weather conditions Including a control device for measuring, the plurality of wave power generation devices are connected to each other to move the power.

The control device may include: a power storage unit configured to store the power; a power generation measurement unit for generating power generation data by measuring the power generation amount of each of the plurality of wave power generation devices; a plurality of pressure sensors disposed in each of the plurality of wave power devices, and measuring the wave pressure and water pressure applied to each of the wave power devices to generate pressure data; and a control unit for predicting a change in the amount of power generation according to terrain and weather conditions by using terrain data, weather data, the power generation amount data, and the pressure data,

The terrain data includes information on the slope, height, and soil quality of the terrain in which the plurality of wave power generators are installed.

The control unit generates first variation data representing a change in the amount of power generation for each terrain according to the weather condition by using the terrain data, the weather data, and the generation amount data.

In addition, the control unit generates second variation data representing changes in the wave pressure and water pressure for each terrain according to the weather condition by using the terrain data, the weather data, and the pressure data.

In addition, the control unit generates correlation data indicating a correlation between the meteorological state, the topography, the wave pressure and water pressure, and the amount of power generation by using the first change amount data and the second change amount data.

In addition, the control unit receives the weather information, and predicts the wave pressure and the water pressure according to the weather information using the correlation data.

In addition, the control unit receives the weather information and predicts the amount of power generation according to the weather information by using the correlation data.

In addition, the generation amount prediction method according to one feature for realizing the object of the present invention, the method comprising the steps of measuring the generation amount of each of a plurality of wave power generation device to generate the amount of power generation data; generating pressure data by measuring wave pressure and water pressure due to waves applied to each of the plurality of wave power devices; generating correlation data indicating a correlation between the wave pressure and water pressure for each terrain according to weather conditions and the amount of power generation by using weather data, terrain data, the power generation amount data, and the pressure data; and estimating the amount of power generation of each of the plurality of wave power devices according to the weather condition by using the correlation data, wherein the topographic data includes the slope, height and soil quality of the terrain in which the plurality of wave power devices are installed. includes information about

Here, the generating of the correlation data may include: generating first variation data representing a change in the power generation amount for each terrain according to the weather condition using the terrain data, the weather data, and the generation amount data; generating second variation data representing changes in the wave pressure and water pressure for each terrain according to the weather conditions by using the terrain data, the weather data, and the pressure data; and generating correlation data indicating a correlation between the weather state, the topography, the wave pressure and water pressure, and the change in the amount of power generation by using the first change amount data and the second change amount data.

In addition, the step of predicting the amount of power generation, the step of receiving weather information; and predicting the amount of power generation according to the weather information by using the weather information and the correlation data.

The predicting of the amount of power generation further includes predicting the wave pressure and water pressure according to the weather information using the weather information and the correlation data.

According to the wave power generation device and system according to an embodiment of the present invention and a method for predicting power generation using the same,

First, it is buried in the coast and installed, and it is generated by the vibration of the wave pressure and water pressure, so that the impact on the environment can be minimized and a predetermined amount of power can be always generated.

Second, by the shape of the first coupling part and the second coupling part, even when a plurality of power generation units are connected to each other, they can move flexibly.

Third, it is possible to use the weather information to predict the amount of power generation according to the weather information, so it is possible to respond flexibly to changes in the amount of power generation.

Fourth, the amount of power generation can be predicted differently depending on the terrain in which a plurality of wave power generation devices are installed.

Fifth, wave pressure and water pressure can be predicted according to weather information, so that wave information can be provided.

1 is a perspective view of a wave power device according to an embodiment of the present invention.
Figure 2 is a side cross-sectional view of the wave power device shown in Figure 1;
FIG. 3 is a cross-sectional view illustrating a coupling structure of the connection part shown in FIG. 2 .
Figure 4 is an example of application of the wave power device according to an embodiment of the present invention.
5 is a cross-sectional view showing a portion A in FIG. 4 .
6 and 7 are conceptual views schematically showing a wave power system according to an embodiment of the present invention.
8 is a flowchart illustrating a method of predicting an amount of power generation according to an embodiment of the present invention.
9 is a flowchart illustrating a process of generating correlation data shown in FIG. 8 .
FIG. 10 is a flowchart for explaining a process of predicting the amount of power generation shown in FIG. 8 .

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. In this case, it should be noted that in the accompanying drawings, the same components are denoted by the same reference numerals as much as possible. In addition, detailed descriptions of well-known functions and configurations that may obscure the gist of the present invention will be omitted. For the same reason, some components are exaggerated, omitted, or schematically illustrated in the accompanying drawings.

1 is a perspective view of a wave power device according to an embodiment of the present invention, FIG. 2 is a side cross-sectional view of the wave power device shown in FIG. 1, and FIG. 3 is a cross-sectional view showing the coupling structure of the connection part shown in FIG.

Figure 4 is an exemplary view of application of the wave power device according to an embodiment of the present invention, Figure 5 is a cross-sectional view showing the portion A in Figure 4 .

The wave power generation device 100 of the present invention will be described with reference to FIGS. 1 to 5 .

The wave power generation device 100 of the present invention is a power generation device that is buried in the coast and generates power using waves, and includes a power generation unit 110 and a connection unit 120 .

The power generation unit 110 generates power using wave pressure, and includes a power generation plate 111 and a cover 112 .

The power generation plate 111 includes a plurality of power generation elements that generate power using vibrations according to changes in wave pressure and water pressure.

The cover 112 is disposed on the upper and lower sides of the power generation plate 111 to transmit vibration to the plurality of power generation elements, and protect the power generation plate 111 from external impact.

The connection unit 120 is coupled to the power generation unit 110 to connect the plurality of power generation units 110 to each other.

The connection part 120 includes a first coupling part 121 and a second coupling part 122 .

The first coupling portion 121 is disposed on one side of the power generation plate 111, a coupling protrusion 121a is formed, and the coupling protrusion 121a is formed in a spherical shape.

The second coupling portion 122 is disposed on the other side of the power generation plate 111, a coupling groove 122a into which the coupling protrusion 121a is inserted is formed, and the coupling groove 122a is formed with the shape of the coupling protrusion 121a. formed in a corresponding shape.

In addition, the coupling protrusion 121a is partially inserted into the coupling groove 122a to connect the plurality of power generation units 110 to each other.

The first coupling part 121 and the second coupling part 122 are formed in a polygonal pyramid shape, and the bottom surface is coupled to the side surface of the power generation plate 111 , and the vertices formed by the plurality of side surfaces are disposed to face the outside.

And, the coupling protrusion 121a is formed at the vertex formed by the plurality of side surfaces of the first coupling part, and the coupling groove 122a is formed at the vertex formed by the plurality of side surfaces of the second coupling part.

The coupling of the first coupling part 121 and the second coupling part 122 will be described with reference to FIG. 3 .

As shown in FIG. 3 , the coupling of the first coupling part 121 and the second coupling part 122 includes the coupling protrusion 121a of the first coupling part 121 through the coupling groove of the second coupling part 122 ( 122a) is partially inserted and coupled.

In addition, the connecting portion can move fluidly according to the shape of the first coupling portion 121 and the second coupling portion 122 and the shape of the coupling protrusion 121a and the coupling groove 122a.

For example, when two power generation units 110 are installed at the beginning of the flat ground 10 and the inclined portion 20, one power generation unit 110 is disposed on the ground 10 and the other The power generation unit 110 is disposed on the inclined portion 20 .

In this case, the shape of the coupling part of the first coupling part 121 and the second coupling part 122 may appear as shown in FIG. 4 .

Since the coupling protrusion 121a is formed in a spherical shape, it can be rotated without limitation in the direction, and due to the cone shape of the first coupling part 121 and the second coupling part 122, a collision part does not occur during rotation.

If the first coupling part 121 and the second coupling part 122 are formed in a columnar shape, the upper surfaces of the columns collide with each other during rotation, thereby reducing the rotation radius.

Accordingly, it is possible to minimize the influence on the topography of the coast to be buried by the connection structure of the plurality of power generation units 110 by the connection unit 120 and to respond flexibly to changes due to wave pressure and water pressure.

Additionally, the connection unit 120 synchronizes the power generated in the power generation plate 111 by the coupling of the first coupling unit 121 and the second coupling unit 122, and includes a power transmission line (not shown) for this purpose. .

A power transmission line (not shown) is connected to the power generation plate 111 to move the power generated by the power generation plate 111 .

6 and 7 are conceptual views schematically showing a wave power system according to an embodiment of the present invention.

A wave power generation system 1000 of the present invention will be described with reference to FIGS. 1, 6 and 7 .

The wave power generation system 1000 of the present invention includes a power generation complex 200 and a control device 300 .

The power generation complex 200 includes a plurality of wave power generation devices 100 that are embedded in the coast and generate power using vibrations caused by waves and changes in water pressure.

The power generation complex 200 has a structure in which the wave power generation devices 100 shown in FIG. 1 are connected to each other, and power generated by each wave power generation device 100 may move.

The control device 300 stores the power generated in the power generation complex 200, measures the amount of power generated for each of the plurality of wave power devices 100, and measures the wave pressure and water pressure according to the terrain. Measure the correlation.

To perform this, the control device 300 includes a power storage unit 310 , a power generation amount measurement unit 320 , a plurality of pressure sensors 330 , and a control unit 340 .

The power storage unit 310 stores the power generated in the power generation complex 200 , and the generation amount measurement unit 320 measures the amount of power generated by each of the plurality of wave power devices 100 to generate power generation data.

A plurality of pressure sensors 330 are disposed in each of the plurality of wave power devices 100, and generate pressure data by measuring the wave pressure and water pressure applied to each wave power device 100.

The control unit 340 predicts a change in the amount of generation of each of the plurality of wave power generation devices 100 according to the terrain and weather conditions by using the terrain data, weather data, power generation data and pressure data.

Here, the terrain data includes information on the slope, height, and soil quality of the terrain in which the plurality of wave power generation devices 100 are installed, and the weather data receives the weather information of the area where the power generation complex 200 is installed from the outside, or receives temperature and Information such as wind direction can be directly measured and generated.

The operation of the controller 340 will be described in detail. The controller 340 generates first variation data indicating a change in the amount of power generation for each terrain according to the weather condition by using the terrain data, the meteorological data, and the generation amount data.

In addition, the controller 340 generates second variation data representing changes in wave pressure and water pressure for each terrain according to weather conditions by using the terrain data, weather data, and pressure data.

Thereafter, the control unit 340 generates correlation data indicating a correlation between the meteorological state, topography, wave pressure, and water pressure and the amount of power generation by using the first change amount data and the second change amount data.

And, the control unit 340 may predict the amount of power generation and the wave pressure and water pressure of the wave using future weather information.

The control unit 340 receives future weather information, searches for correlation data, and predicts the amount of power generation corresponding to the received weather information and the wave pressure and water pressure of the waves.

Here, the predicted power generation amount, wave pressure, and water pressure may appear in a range having a minimum value and a maximum value.

Therefore, it is possible to flexibly cope with the fluctuations in the amount of power generation through the predicted power generation, and it is possible to provide the predicted wave pressure and water pressure information to the outside.

8 is a flowchart for explaining a method for predicting power generation according to an embodiment of the present invention, FIG. 9 is a flowchart for explaining a process of generating the correlation data shown in FIG. 8, and FIG. 10 is shown in FIG. This is a flow chart to explain the process of estimating the amount of power generation.

A power generation amount prediction method of the present invention will be described with reference to FIGS. 7 and 8 .

The generation amount measurement unit 320 generates generation data by measuring the generation amount of each of the plurality of wave power generation devices 100 (step S110).

A plurality of pressure sensors 330 generate pressure data by measuring the wave pressure and water pressure caused by the waves applied to each of the plurality of wave power generation devices 100 (step S120).

Then, the control unit 340 generates correlation data indicating the correlation between the wave pressure and water pressure and the power generation amount for each terrain according to the weather condition by using the weather data, the terrain data, the generation amount data, and the pressure data (step S130 ).

Here, the terrain data includes information on the slope, height, and soil quality of the terrain in which the plurality of wave power generation devices 100 are installed.

In addition, the control unit 340 predicts the amount of power generation of each of the plurality of wave power generation devices 100 according to the weather conditions by using the correlation data (step S140).

9 is a flowchart illustrating a process of generating correlation data shown in FIG. 8 .

A process (step S130) of generating the correlation data shown in FIG. 8 will be described with reference to FIGS. 7 and 9 .

The control unit 340 generates first change amount data indicating a change in the amount of power generation of the plurality of wave power generators 100 for each terrain according to the weather condition by using the terrain data, the weather data, and the generation amount data (step S131).

The control unit 340 generates second variation data representing changes in wave pressure and water pressure applied to each of the plurality of wave power generation devices 100 for each terrain according to the weather conditions by using the terrain data, weather data, and pressure data (step step) S132).

Then, the control unit 340 generates correlation data indicating a correlation between the change in the amount of electricity generated by the weather condition, topography, wave pressure, and water pressure by using the first change amount data and the second change amount data (step S133 ).

FIG. 10 is a flowchart for explaining a process of predicting the amount of power generation shown in FIG. 8 .

A process (step S140) of predicting the amount of power generation shown in FIG. 8 will be described with reference to FIGS. 7 and 10 .

The controller 340 receives weather information (step S141), searches for correlation data, and predicts the amount of power generation corresponding to the received weather information (step S142).

In addition, the control unit 340 searches for the correlation data to predict the wave pressure and water pressure corresponding to the received weather information (step S143).

Although it has been described with reference to the above embodiments, it will be understood by those skilled in the art that various modifications and changes can be made to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. will be able

110...Generation unit 111...Generation plate
112...cover 120...connection
121 ... first coupling part 121a ... coupling protrusion
122...Second coupling part 122a...Coupling groove
200...Generation Complex 300...Control Unit
310...Power storage unit 320...Power generation measuring unit
330...pressure sensor 340...control unit

Claims (18)

As a power generation device that is buried in the coast and generates electricity using waves,
a power generation unit that generates power using wave pressure; and
A connection unit coupled to the power generation unit to connect a plurality of the power generation units
including,
The power generation unit,
a power generation plate including a plurality of power generation elements that generate power using vibrations according to changes in the wave pressure and water pressure; and
A cover disposed on the upper and lower sides of the power generation plate to transmit the vibration to the plurality of power generation elements, and to protect the power generation plate from external impact
includes,
The connection part,
a first coupling part disposed on one side of the power generation plate and having a coupling protrusion; and
A second coupling part disposed on the other side of the power generation plate and having a coupling groove into which the coupling protrusion is inserted.
Including, wave power device. delete According to claim 1,
The coupling protrusion is formed in a spherical shape,
The coupling groove is formed in a shape corresponding to the shape of the coupling protrusion,
The coupling protrusion is partially inserted into the coupling groove to be coupled to the coupling groove, a wave power generation device. 4. The method of claim 3,
The first coupling portion and the second coupling portion,
Formed in a polygonal pyramid shape, a wave power device. 5. The method of claim 4,
The first coupling portion and the second coupling portion,
The bottom surface is coupled to the side of the power generation plate, the vertices formed by the plurality of side surfaces are arranged to face the outside, the wave power generation device. 6. The method of claim 5,
The coupling protrusion is formed at the vertex of the first coupling part,
The coupling groove is formed in the vertex of the second coupling portion, wave power generation device. 4. The method of claim 3,
The connection part,
Moving the power generated by the power generation plate by the coupling of the first coupling part and the second coupling part,
A power transmission line connected to the power generation plate and through which the power moves
Further comprising, a wave power device. A power generation complex including a plurality of wave power generation devices that are buried in the coast and generate power using vibrations caused by waves and changes in water pressure; and
Storing the power generated in the power generation complex, measuring the amount of power generation for each of the plurality of wave power generation devices, and measuring the wave pressure and water pressure to measure the correlation between the wave pressure and water pressure and the power generation amount according to terrain and weather conditions control device
including,
The plurality of wave power generation devices are connected to each other to move the power,
The wave power device,
a power generation unit that generates power using wave pressure; and
A connection unit coupled to the power generation unit to connect a plurality of the power generation units
including,
The power generation unit,
a power generation plate including a plurality of power generation elements that generate power using vibrations according to changes in the wave pressure and water pressure; and
A cover disposed on the upper and lower sides of the power generation plate to transmit the vibration to the plurality of power generation elements, and to protect the power generation plate from external impact
includes,
The connection part,
a first coupling part disposed on one side of the power generation plate and having a coupling protrusion; and
A second coupling part disposed on the other side of the power generation plate and having a coupling groove into which the coupling protrusion is inserted.
Including, wave power system. 9. The method of claim 8,
The control device is
a power storage unit for storing the power;
a power generation measurement unit for generating power generation data by measuring the power generation amount of each of the plurality of wave power generation devices;
a plurality of pressure sensors disposed in each of the plurality of wave power devices, and measuring the wave pressure and water pressure applied to each of the wave power devices to generate pressure data; and
A control unit for predicting a change in the amount of power generation according to terrain and weather conditions using terrain data, meteorological data, the power generation amount data, and the pressure data
including,
The topographic data, the wave power generation system, including information on the slope, height and soil quality of the terrain in which the plurality of wave power devices are installed. 10. The method of claim 9,
The control unit is
A wave power generation system for generating first variation data indicating a change in the power generation amount for each terrain according to the weather condition by using the topography data, the weather data, and the power generation data. 11. The method of claim 10,
The control unit is
A wave power generation system for generating second variation data representing changes in the wave pressure and water pressure for each terrain according to the weather condition by using the topography data, the weather data, and the pressure data. 12. The method of claim 11,
The control unit is
and generating correlation data indicating a correlation between the meteorological state, the topography, the wave pressure and water pressure and the amount of power generation by using the first variation data and the second variation data. 13. The method of claim 12,
The control unit is
A wave power generation system that receives weather information and predicts the wave pressure and water pressure according to the weather information using the correlation data. 13. The method of claim 12,
The control unit is
A wave power system that receives weather information and predicts the amount of power generation according to the weather information by using the correlation data. generating power generation data by measuring the power generation amount of each of a plurality of wave power generation devices;
generating pressure data by measuring wave pressure and water pressure due to waves applied to each of the plurality of wave power devices;
generating correlation data indicating a correlation between the wave pressure and water pressure for each terrain according to a meteorological condition and the power generation amount by using the weather data, the terrain data, the power generation amount data, and the pressure data; and
Predicting the amount of power generation of each of the plurality of wave power devices according to the weather conditions using the correlation data
including,
The terrain data includes information on the slope, height and soil quality of the terrain in which the plurality of wave power generation devices are installed,
The wave power device,
a power generation unit that generates power using wave pressure; and
A connection unit coupled to the power generation unit to connect a plurality of the power generation units
including,
The power generation unit,
a power generation plate including a plurality of power generation elements that generate power using vibrations according to changes in the wave pressure and water pressure; and
A cover disposed on the upper and lower sides of the power generation plate to transmit the vibration to the plurality of power generation elements, and to protect the power generation plate from external impact
includes,
The connection part,
a first coupling part disposed on one side of the power generation plate and having a coupling protrusion; and
A second coupling part disposed on the other side of the power generation plate and having a coupling groove into which the coupling protrusion is inserted.
Including, the power generation amount prediction method. 16. The method of claim 15,
The step of generating the correlation data comprises:
generating first change amount data representing a change in the amount of power generation for each terrain according to the weather condition by using the terrain data, the weather data, and the generation amount data;
generating second change amount data representing changes in the wave pressure and water pressure for each terrain according to the weather conditions by using the terrain data, the weather data, and the pressure data; and
generating correlation data indicating a correlation between the weather state, the topography, the wave pressure and water pressure, and the change in the amount of power generation by using the first variation data and the second variation data;
Including, the power generation amount prediction method. 17. The method of claim 16,
The step of predicting the amount of power generation,
receiving weather information; and
predicting the amount of power generation according to the weather information using the weather information and the correlation data
Including, the power generation amount prediction method. 18. The method of claim 17,
The step of predicting the amount of power generation,
Predicting the wave pressure and water pressure according to the weather information using the weather information and the correlation data
Further comprising, the power generation amount prediction method.

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