JP7292111B2 - wave power generator - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wave power generation device that generates power based on the power of waves that strike a coast or the like, among marine energy sources.

In recent years, in the "Basic Plan on Ocean Policy" formulated based on the Basic Act on Ocean Policy, regarding natural energy that is endowed in the sea area under its jurisdiction and has the potential to become an energy source in the future, it is necessary from the perspective of global warming countermeasures. The direction of the country's efforts is indicated as promoting efforts and considerations. In line with this policy, power generators and power generation equipment that generate power using wave energy among ocean energy have been proposed.
A wave power generation device is a power generation method that uses the energy of waves such as seawater to generate power, and there are various types of devices such as those that use ocean currents and those that use vertical vibrations of waves.

For example, in the wave power pump device described in Patent Document 1, a pressure receiving plate is supported below the mounting shaft via a support rod, and the pressure receiving plate moves like a pendulum around the mounting shaft in accordance with the vertical movement of the wave. can be oscillated to When the piston, which is connected to the pressure receiving plate, advances and retreats inside the cylinder, the pump device connected to the cylinder operates the check valve to pump liquid or gas, and the hydraulic motor rotates to generate electricity.

Further, in the wave power generation device described in Patent Document 2, an anchor installed on the seabed supports a support via a mooring rope, and a float is installed around the support so that it can move up and down. A pinion gear and a power generator are installed inside the column, and the float is connected to a rack member that extends into the column and meshes with the pinion gear. Therefore, the pinion gear is rotated in conjunction with the float that moves up and down under wave force to drive the generator.

JP-A-8-114171 JP 2017-172480 A

However, the wave power pump device described in Patent Document 1 requires installation of a pendulum type wave power absorption device, a pump device that moves the piston back and forth in the cylinder to operate the check valve, etc., and the equipment is large. However, there is a problem that the cost becomes high in order to make it more flexible. In addition, the wave power generation device described in Patent Document 2 also requires the anchor to be submerged in the sea and the pillar to be moored via a rope, and the pillar is not fixed, so it is unstable. Moreover, it requires a float, a wave sensor, etc., having a rack member extending inside the column, and there is a problem that the size of the equipment is increased and the cost is increased.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a wave power generator that has a simple configuration, can be installed in a short period of time, and can be manufactured at a low cost.

A wave power generation device according to the present invention includes a wave receiving member that receives waves, a float that is provided on the front surface of the wave receiving member and that can be raised and lowered by the force of the waves, a rack member or pinion that is provided on the back surface of the float, A pinion provided on the wave receiving member and meshing with the rack member, or a rack member meshing with the pinion, and a power generator connected to the pinion and generating power in conjunction with rotation of the pinion. do.
According to the present invention, when the float provided on the front surface of the wave receiving member is lifted by the force of the waves, the rear surface of the float, the rack member provided on the wave receiving member, and the pinion mesh with each other, thereby preventing the float from rising. Since the pinion rotates accordingly, the power generating device receives the rotation of the pinion and generates power.

Further, it is preferable that a guide member having a guide groove for slidably supporting the float is provided on the front surface of the wave receiving member.
Since the float moves up and down along the guide groove of the guide member, the rack and pinion can be reliably engaged with each other to rotate the pinion.

Further, a roller for guiding the up-and-down movement of the float may be provided on one of the front surfaces of the wave receiving member facing the back surface of the float.
When the float receives a wave and moves up and down, the roller guides the up and down movement of the float, which makes the up and down movement of the float smoother.

In addition, it is preferable that the float is formed with a projecting wave-receiving portion for receiving waves at the bottom.
Since the wave receiving portion is formed in the portion of the float that receives the wave, the load of the wave can be more reliably converted into the rising motion of the float.

The float may also be made of steel and hollow inside.
Since the float is light, it can be smoothly converted into a lifting operation under the load of waves.

In the wave power generation device according to the present invention, the float provided on the front surface of the wave receiving member receives the wave and moves up and down when the wave rushes. By rotating the pinion, the generator can generate electricity. Moreover, since the float can be attached to the wave receiving member, which is a breakwater, so that the power generation device can generate electricity, there are few mounting members for the float and the power generation device, etc., and the simple structure enables installation in a short period of time, and the manufacturing cost is low. can be done.
In addition, the structure of the wave power generator is simple, and the float is exposed on the wave receiving member, so maintenance can be easily performed. Furthermore, since a plurality of floats and power generators can be installed along the wave receiving member, installation efficiency is also good.

1 is a side view of a wave power generation device according to an embodiment of the invention; FIG. FIG. 2 is a front view showing the positional relationship of the wave receiving float with respect to the upper concrete member shown in FIG. 1; A float and a guide member are shown, (a) is a front view, (b) is a top view. It is a back view of a float. It is a figure of the electric power generating apparatus provided in the inside of a concrete member. It is a figure which shows the float which receives a wave and goes up and down.

A wave power generation device 1 according to an embodiment of the present invention will be described below with reference to FIGS. 1 to 6. FIG.
The wave power generation device 1 shown in FIG. 1 is installed, for example, on the seashore, on the boundary between land and sea, or on the sea. In the wave power generation device 1, for example, the covering crushed stone 2 is installed on the land of the coast, and the upper part is covered with the covering stone 3 in layers. A caisson 4 is installed on top of the covering crushed stone 2, and the circumference of the caisson 4 is covered with covering stones 3. - 特許庁The caisson 4 is a large box-like structure made of concrete or steel used as an underwater structure such as a breakwater or used when constructing an underground structure.
A wave-dissipating block (not shown) such as a tetrapod is installed on the sea side of the caisson 4, or on the sea side and the land side. The caissons 4 are arranged along the crushed cladding 2 and cladding 3 laid on the shore. An upper concrete 6 is installed on the upper part of the caisson 4 as a breakwater to prevent waves from passing over it.

The upper concrete 6 has a high portion 6a on the sea side to prevent waves from entering, and a low portion 6b on the land side, which is lower than the high portion 6a. As shown in FIG. 2, a plurality of wave receiving floats 7 that can move up and down are arranged at predetermined intervals along the extending direction of the upper concrete 6 on the sea-side front surface 6c of the high portion 6a of the upper concrete 6. there is As shown in FIG. 3, on the front surface 6c of the upper concrete 6, steel materials having an H-shaped cross section are fixed as guide members 8 at predetermined intervals. A guide groove 8d is formed in the vertical direction in the portion.
The rear surface 8b of the guide member 8 on the side of the upper concrete 6 may be directly fixed to the front surface 6c of the upper concrete 6 with bolts or the like, or as shown in FIG. 9 may be installed and the steel plate 9 and the rear surface 8b may be fixed by welding, bolts, or the like.

As shown in FIG. 3, the wave receiving float 7 has a rectangular plate shape and is hollow inside, and is made of steel, for example. Both sides of the wave receiving float 7 are thin plate portions 7b thinner than the plate thickness of the central portion 7a, and are attached to the guide grooves 8d on both sides of the guide member 8 so as to be vertically movable. Moreover, the wave receiving float 7 is formed with a projecting wave receiving portion 7c projecting forward at the lower end of the central portion 7a. Therefore, the wave receiving float 7 is formed in a substantially L shape when viewed from the side. When the wave receiving portion 7c receives the surging wave, the wave receiving float 7 is lifted by the force and rises along the guide groove 8d of the guide member 8. descend by

In FIG. 4, for example, two rack members 11 are vertically attached to the back surface of the wave receiving float 7 . A plurality of, for example, four rollers 12 are rotatably embedded outside the rack member 11 . Each roller 12 is installed on the back surface, for example, on the left and right sides, respectively, on the upper side and the lower side. The rollers 12 can smooth the up-and-down movement of the wave-receiving float 7 with respect to the upper concrete 6 or the steel plate 9 when the wave-receiving float 7 moves up and down.
The roller 12 may be provided on the front surface 6c of the upper concrete 6 instead of the wave receiving float 7.

In FIG. 5, a box-shaped space 14 is formed in the front surface 6c of the high portion 6a of the upper concrete 6. As shown in FIG. In this space 14, a pinion 15 meshing with the rack member 11 on the back surface of the wave receiving float 7, and a power generator 16 for receiving the rotation of the pinion 15 and directly connected to its rotating shaft to generate power are installed. . Two pinions 15 and two power generators 16 are installed in one space 14 corresponding to the two rack members 11 of the wave receiving float 7 .
Moreover, in the wave power generation device 1, the wave receiving float 7 that moves up and down and the guide member 8 having the guide groove 8d that guides the moving up and down of the wave receiving float 7 are exposed on the surface, so maintenance can be easily performed.

When the wave-receiving float 7 is raised and lowered, an upper limit stopper that defines the upper limit of the rising position of the wave-receiving float 7 and a lower limit stopper that defines the lower limit of the lowering position are preferably installed on the upper concrete 6, the caisson 4, or the like. As a result, when a large wave such as a typhoon or tsunami occurs, the rack member 11 of the wave-receiving float 7 may be disengaged from the pinion 15 due to excessive wave force, and when the wave-receiving float 7 descends, the rack member 11 may be separated from the pinion 15. You can prevent it from coming off downward. The upper limit stopper and the lower limit stopper may be provided in the guide groove 8d of the guide member 8. By providing an upper limit stopper and a lower limit stopper in the guide groove 8d, it is possible to prevent the wave receiving float 7 from dropping out of the guide groove 8d of the guide member 8 when the wave receiving float 7 moves up and down. If the elevation is within this range, it is possible to prevent the rack member 11 from coming off the pinion 15 .

The wave power generation device 1 according to this embodiment has the above-described configuration, and the method of use thereof will now be described. It is preferable to install the wave power generation device 1 according to the present embodiment, for example, on a coast such as the Sea of Japan where waves are rough.
On the coast or the like, waves hit the caisson 4 of the breakwater, the upper concrete 6, or the like. At that time, part of the surging wave hits the wave receiving portion 7c at the bottom of the wave receiving float 7 from below. The wave receiving portion 7c is pushed by the waves, so that the wave receiving float 7 moves upward along the guide groove 8d, and the rollers 12 guide smooth running. As the wave receiving float 7 moves upward, the rack member 11 rises to rotationally drive the pinion 15 that meshes with it. When the pinion 15 is driven to rotate, the rotating shaft rotates and the generator 16 generates power.

Further, when the force of the wave disappears at the position where the wave receiving float 7 has completely risen or stopped at the upper limit stopper, the wave receiving float 7 then begins to descend due to its own weight, and the pinion 15 meshing with the rack member 11 is reversed. rotate in the direction As a result, the pinion 15 is rotationally driven to rotate the power generating device 16 via its rotating shaft to generate power. At the lowered position, the wave receiving float 7 is stopped by the lower limit stopper, and can be prevented from coming off the guide groove 8d of the guide member 8. As shown in FIG.
In this manner, the wave receiving float 7 is repeatedly moved up and down by the guide groove 8d of the guide member 8 due to the force of the waves that come in and return, whereby the power generator 16 performs the power generation work. Moreover, as shown in FIG. 6, the plurality of wave receiving floats 7 arranged on the upper concrete 6 of the caisson 4 are individually lifted and lowered by receiving waves having different wavelengths and periods.

As described above, according to the wave power generation device 1 according to the present embodiment, the structure is simple, and since most of the wave receiving float 7, the guide member 8, etc. are exposed to the outside, maintenance can be easily performed. Moreover, the wave power generation device 1 according to the present embodiment utilizes an existing caisson 4 installed on the coast, or incorporates the wave power generation device 1 when installing a new caisson 4, thereby eliminating unnecessary foundations and new structures. can be installed in a short period of time, and the installation cost is low. In addition, since a plurality of wave power generators 1 can be easily installed, installation efficiency is good.

Although the wave power generation device 1 according to the embodiment of the present invention has been described in detail above, the present invention is not limited to the above-described embodiment, and can be changed or replaced without departing from the scope of the present invention. are possible, and they are all included in the present invention. Modifications and the like of the present invention will be described below, but the same reference numerals will be used for the same or similar parts and members as in the above-described embodiment, and the description will be omitted.

For example, in the above-described embodiment, the rack member 11 is provided on the back surface of the wave receiving float 7, and the pinion 15 and the power generator 16 that mesh with the rack member 11 are installed in the space 14 on the front surface 6c of the upper concrete 6. However, the invention is not limited to such a configuration. For example, the pinion 15 and the power generator 16 may be provided on the back surface of the wave receiving float 7, and the rack member 11 may be provided on the front surface 6c of the upper concrete 6 and meshed with the pinion 15.
Alternatively, the roller 12 may be provided on the front surface 6c of the upper concrete 6. FIG. Although the wave receiving float 7 has the wave receiving portion 7c at its lower portion and is formed in an L-shape when viewed from the side, the wave receiving portion 7c may be placed above the lower portion of the wave receiving float 7. FIG. Alternatively, if the thickness of the wave receiving float 7 can be secured and waves can be received, the wave receiving portion 7c may be omitted.
Further, although the wave power generator 1 is installed on the coast in the above-described embodiment, it may be installed on the sea away from the coast to receive wave power and generate power.
The upper concrete 6 is included in the wave receiving member, and the wave receiving float is included in the float.

1 wave power generation device 4 caisson 6 upper concrete 6c front surface 7 wave receiving float 7b thin plate portion 7c wave receiving portion 8 guide member 8d guide groove 11 rack member 12 roller 14 space 15 pinion 16 power generation device

Claims (5)

a wave receiving member that receives waves;
A float that is provided on the front surface of the wave receiving member and can be raised and lowered by the force of the waves, a rack member or pinion provided on the back surface of the float, and a rack member that is provided on the wave receiving member and meshes with the rack member. a pinion or a rack member meshing with the pinion;
a power generator connected to the pinion and generating power by rotation of the pinion ;
with _
The float is in the shape of a rectangular plate, and has a projecting wave-receiving portion for receiving waves at the bottom,
A guide member having a guide groove for slidably supporting the float is provided on the front surface of the wave receiving member,
The guide member has a length in the height direction shorter than that of the wave receiving member,
A wave power generation device characterized by : an upper limit stopper that defines the upper limit of the rising position of the float;
a lower limit stopper that defines the lower limit of the lowering position of the float;
The wave power generation device of claim 1, comprising: 3. The wave power generation device according to claim 2, wherein said upper limit stopper and said lower limit stopper are provided in said guide groove of said guide member. 4. The wave power generator according to any one of claims 1 to 3, wherein one of the front surfaces of the wave receiving member facing the back surface of the float is provided with a roller for guiding the lifting and lowering of the float. 5. A wave power generator according to any one of claims 1 to 4, wherein said float is made of steel and is hollow inside.

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