KR101085907B1 - Wave power generating apparatus of Oscillating water column type - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a vibration frequency generator type wave power generating apparatus that generates power by using air flow energy in an air chamber caused by waves. More specifically, the size of the air chamber is changed, By varying the internal volume of the chamber, preferably the width, the present invention relates to a frequency-driven wave power generator capable of efficiently responding to changes in wave height, wave period, and the like caused by waves.

In particular, regardless of changes in wave height, wave period, etc. due to waves, not only can generate power stably, but also have high power density, and it is possible to more efficiently integrate wave power including wind energy existing in the ocean. It is an advantage.

Blue, energy, vibration, air chamber, power generation device

Description

Wave power generating apparatus of oscillating water column type

The present invention relates to a vibration-driven wave power generator that generates power by using air flow energy in an air chamber caused by waves. The vibration-driven wave power generator is capable of efficiently coping with changes in wave height and wave period caused by waves. It is about.

Korea currently has the highest energy source unit (consumption energy per gross domestic product) in the world, and the dependence on energy abroad is 97% of total consumption (September 20, 2004), and most of them are from fossil fuels and nuclear power generation. will be.

Renewable energy is only less than 2% of total consumption. As such, the necessity for the use of energy in consideration of the current environment is rapidly emerging, and the development of renewable energy is not an option but an essential situation.

Ocean wave energy for this purpose can be said to be infinite clean energy that is not depleted even if used together with solar energy.

In addition, research on the available energy extraction method has been conducted for a long time due to the great expectation as an alternative energy source for the future of mankind, and the wave energy, the ocean wave energy, has many advantages, and active development is being developed in the developed countries.

More specifically, among the existing power generation systems, the most efficient power generation system is aberration power generation. The aberration power generation converts the potential energy of water, that is, water head difference × flow rate into electrical energy with an efficiency of 95% or more using aberrations (Francis aberration, Felton aberration, etc.).

However, it is difficult to secure potential energy with predictability and sustainability, which lowers the operational efficiency and costs a lot such as dam construction costs.

As one of the powers for implementing the aberration power generation, the wave power can be said to be an infinite clean energy that is not depleted, and research on the available energy extraction method has been conducted for a long time with great expectation as an alternative energy source for human future.

Such wave energy is more predictable than solar energy or wind energy, and can be dispatched using a power grid, which is highly profitable.

In addition, the strength of wave energy is that it has a high power density, and it is easier to integrate wave power including wind energy existing in the ocean.

Due to the above advantages, generators using wave energy have been developed in various ways, and typically there is a vibration-type wave power generator.

The oscillation-type wave power generator is a concept that the air in the air chamber reciprocates by the blue wave, and converts the wave energy into the flow energy of the air first and converts it into the mechanical rotational energy using the air turbine again. Concept is used.

More specifically, Figure 1 is a vibration-type power generation apparatus according to the prior art, using the volume change of the closed space (air chamber) according to the change in the water level to drive the air turbine.

In other words, the volume of the sealed space is not changed by changing the size of the sealed space, such as the volume of the sealed space.

However, in the conventional vibration frequency wave device as described above, by varying the volume of the space depending only on the wave, a situation in which air can not be compressed at high pressure in accordance with the state of the wave frequently occurs.

In summary, the prior art does not generate power when the wave digging frequency of the wave is insignificant as the volume changes according to the state of the blue, not the volume of the air chamber. There was a problem.

The present invention is to solve the above-described problems, by varying the size of the air chamber, by varying the internal volume, preferably the width of the air chamber, it can efficiently respond to changes in wave height, wave period, etc. caused by the wave. An object of the present invention is to provide a vibration-type wave power generator, characterized in that.

In particular, the present invention can not only stably generate power, but also have a high power density, and more efficiently integrate wave power including wind energy existing in the ocean regardless of changes in wave height, wave period, etc. caused by waves. The advantage is that you can.

In order to achieve the above object, the present invention includes an air chamber in which a lower part is closed by a fluid having a blue wave, and in the vibration-type wave power generation apparatus generating power by using air flow energy in the air chamber by the blue wave. It provides a vibration-type wave power generator, characterized in that for changing the size of the air chamber, varying the internal volume of the air chamber.

On the other hand, the vibration-type wave power generation device may include a pillar support and a variable air chamber fixed to the upper side of the pillar support.

The variable air chamber may include a first chamber part and a second chamber part which is moved forward and backward in a state coupled to the first chamber part to change an internal width of the air chamber.

The variable air chamber may further include a driving unit for moving the second chamber unit.

In addition, the variable air chamber may further comprise a wave detection sensor for measuring the state of the blue.

The vibration-type wave power generator according to the present invention by the above-mentioned problem solving means can generate power stably regardless of the wave height, wave period, etc. caused by the wave, in particular, wave wave, wave period, etc. Regardless of the change, it is possible not only to generate power stably, but also to have high power density, and to efficiently integrate wave power including wind energy existing in the ocean.

The objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and effect of the preferred embodiment of the present invention.

2 is a perspective view of a vibration-type wave-powered device according to an embodiment of the present invention, Figure 3 is an exploded perspective view of the vibration-type wave power device according to an embodiment of the present invention, the present invention, by changing the size of the air chamber To vary the internal volume of the air chamber, it comprises a columnar support (10) and a variable air chamber (20).

The pillar support 10 is a support for fixing and installing the variable air chamber 20 to be described later, such as a rock wall of the coast.

The variable air chamber 20 is an air chamber whose size is changed in a state fixed to an upper side of the pillar support 10, and includes a first chamber portion 21 and a second chamber portion 22. .

The first chamber portion 21 is configured to be fixed to the pillar support 10, the pillar support 10 may be configured in one piece or separate, the upper surface of the conventional nozzle (21a) Is formed.

The nozzle 21a is a passage for supplying compressed air generated in the variable air chamber 20 to a normal air turbine, which is generated when the second chamber portion 22, which will be described later, moves completely backward (second Preferably, the chamber 22 and the first chamber 21 are spaced apart from each other by a predetermined distance (in the direction of the pillar support 10).

The second chamber portion 22 is configured to change the width W of the variable air chamber 20 by moving forward and backward in a state coupled to the first chamber portion 21. For the hydraulic cylinder, such as a separate drive unit 30 may be provided.

On the other hand, when the second chamber portion 22 is moved forward and backward, the reference is due to changes in wave height, wave period, etc. due to the blue, the wave detection sensor 40 for measuring the state of the blue It is provided.

The blue sensor 40 may be configured in the front portion of the second chamber portion 22, but considering the damage caused by the wave, the variable due to the collision of the wave and the second chamber portion 22, the It is effective to be spaced apart from the second chamber portion 22 in the direction of the front portion by a predetermined interval, and as shown, it is preferable to be manufactured and installed in a floating manner to flow in response to the blue.

That is, the drive unit 30 is driven in response to the measured value and the calculated value by the wave detection sensor 40, thereby moving the second chamber portion 22 forward and backward.

On the other hand, the program for calculating the measured value by the wave sensor 40 and the hardware for operating the program can be configured integrally in the drive unit 30, when considering the environment and work efficiency of the beach, etc. It is preferable to have a separate control unit for controlling the wave detection sensor 40 and the driving unit 30, and to configure the remote control by monitoring the control unit in another space.

Figure 4 is a cross-sectional view showing the operation of the vibration frequency wave device according to an embodiment of the present invention, with reference to this, look at the operation and operation principle as follows.

(a) When the blue wave is generated, the wave is detected by the wave sensor 40 installed at a predetermined interval on the front of the second chamber part 22, and the wave period is measured.

(b) The measured value is calculated by the control unit (Newton-Raphson, etc.) so that the appropriate width of the variable air chamber 20 (W, the width that can generate power more efficiently than the measured value) A range is set, and the second chamber part 22 moves forward or backward to correspond to the range by controlling the driving unit 30 through the control unit.

Looking at the calculation method of the measured value for controlling the width (W) range of the air chamber 20 by the control unit in detail,

(b1) Measure the wave period [T (unit: second, s)] from the blue sensor.

(b2) The frequency [f = 1 / T in hertz, Hz] is obtained from the measured wave period.

(b3) An angular frequency [ω = 2πf (unit, rad / s)] is obtained from the frequency.

(b4), then find out the dispersion of waves using the following equation,

From the stomach

g: acceleration of gravity

H: depth

(b5) The W (the width of the air chamber) is obtained from the angular frequency ω by using the above-described dispersibility relationship and the Newton-Raphson method. It will control the width (W) range.

Therefore, according to the present invention, by changing the width W of the variable air chamber 20 as described above, it is possible to efficiently cope with changes in wave height, wave period, and the like caused by blue waves.

On the other hand, Figure 5 is a perspective view of a vibration frequency wave device according to another embodiment of the present invention, as the embodiment (see Figs. 2 to 4), the second chamber portion 22 is the first chamber portion 21 ), But as shown in FIG. 5, the second chamber portion 22 ′ is configured to move forward or backward in a state in which the second chamber portion 22 ′ is inserted into the first chamber portion 21 ′. In addition, it is possible to apply a variety of configurations that can change the width (W) of the variable air chamber 20 in addition to.

In addition, the present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope of the technical idea of the present invention. It will be apparent to those of ordinary skill in the art.

1 is a cross-sectional view of the vibration frequency wave device according to the prior art

Figure 2 is a perspective view of the vibration frequency wave device according to an embodiment of the present invention

Figure 3 is an exploded perspective view of the vibration frequency wave device according to an embodiment of the present invention

Figure 4 is a cross-sectional view showing the operation of the vibration frequency wave device according to an embodiment of the present invention

5 is a perspective view of a vibration-type wave force device according to another embodiment of the present invention

<Description of the symbols for the main parts of the drawings>

10: pillar support 20: variable air chamber

21: first chamber portion 21a: nozzle

22: second chamber portion 30: driving portion

40: blue detection sensor

Claims (5)

An oscillating water wave type power generating apparatus having an air chamber in which a lower surface is closed by a fluid having a blue color, and generating power by using air flow energy in the air chamber by blue color, Column support; And It is fixed to the upper side of the pillar support, the variable air chamber of which the size is changed; is configured to include, The variable air chamber may include a first chamber part; And a second chamber part moving forward and backward in a state coupled to the first chamber part to change an internal width of the air chamber, thereby changing the size of the air chamber to increase the internal volume of the air chamber. Vibration-type wave power generator characterized in that the variable. delete delete The method of claim 1, The variable air chamber, Vibration-type wave power generator characterized in that it further comprises a drive unit for moving the second chamber portion. The method of claim 1, The variable air chamber, Vibration-type wave power generator characterized in that it further comprises a wave detection sensor for measuring the state of the blue.

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