JPH06101218A - Wave absorbing device - Google Patents

Abstract

PURPOSE:To prevent waves from being inverted by a wall surface of a course side edge section and to make it possible to surely absorb waves. CONSTITUTION:A plurality of float members 3 are stored inside a cylindrical shell 2 formed of a net material having specific intervals to from a wave absorbing device 1, and the wave absorbing device 1 is placed on the surface of the water. According to the constitution, waves propagated on the surface of the water are dissipated when they pass through among meshes of the shell 2 of the wave absorbing device 1, and waves are effectively dissipated without being inverted.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wave canceling device, and more particularly to a device installed on a water surface for attenuating a wave generated on the water surface to cancel the wave.

[0002]

2. Description of the Related Art For example, when a wave is generated on the water surface of a course at a boat race, the wave adversely affects the running of the boat, and it is desirable to suppress the wave as much as possible. There is a request such as. In particular, in the situation where the waves generated on the course as the boat travels and propagates toward the side edge of the course are reversed by the wall surface of the side edge of the course and returned to the center of the course again. There is a demand to avoid it.

In order to meet this demand, various means have hitherto been adopted. For example, a wave breaker made of styrofoam should be installed in a floating state in the vicinity of the wall of the course side edge, and this wave breaker should prevent waves generated on the course from colliding with the wall of the course side edge. Alternatively, a wave-dissipating member such as a tetra pot is installed on the wall surface of the side edge of the course so that the propagated wave is crushed by this wave-dissipating member.

Further, when each boat is waiting in the pit before the start of the race, the same wave cancellation as above is required for the waves generated around the pit.

[0005]

However, in the above-mentioned foam wave breaking member made of styrofoam, although it is possible to prevent the wave from colliding with the wall surface of the course side edge portion,
The wave-dissipating member itself inverts the wave, and the inverted wave is returned to the center of the course. On the other hand, when installing a wave breaking member such as a tetra pot,
A large amount of labor is required for the installation work, and also in this case, the wave is inverted by the wave-eliminating member, so that sufficient wave-eliminating cannot be performed. Further, since such a structure cannot be applied to the peripheral portion of the pit, the wave generated in the peripheral portion of the pit cannot be extinguished.

[0006] As described above, the conventional structure cannot sufficiently suppress the wave, and it has not been possible to sufficiently suppress the wave on the course.

The present invention has been made in view of this point, and can prevent the wave from being inverted by the wall surface of the course side edge portion and can surely perform the wave canceling. Aim to get.

[0008]

In order to achieve the above object, the present invention attenuates a wave by allowing the wave to pass through a net material installed on the water surface. Specifically, the invention according to claim 1 is directed to a wave canceling device installed on the water surface so as to attenuate and cancel the wave generated and propagating on the water surface. Then, an outer shell formed in a tubular shape by a net material formed of meshes at predetermined intervals is provided, and a plurality of float members are accommodated inside the outer shell.

According to a second aspect of the present invention, in the wave canceller according to the first aspect, a plurality of float members are arranged at regular intervals in the extensional direction of the outer shell, while the float members are provided below the float member. On the side, an anchor for fixing the position of the entire device is connected, and a pipe member extending in the extension direction of the outer shell is disposed. The float member and the pipe member are connected via a connecting plate.

According to a third aspect of the present invention, in the wave canceller according to the second aspect, both end portions in the longitudinal direction of the pipe member are closed by caps to form a sealed space inside the pipe member. The buoyancy can be adjusted by injecting water and adjusting the injection amount.

[0011]

With the above construction, the present invention provides the following actions. According to the first aspect of the present invention, when the wave generated and propagated on the water surface reaches the wave-eliminating device, the wave is attenuated when the wave passes between the meshes of the outer shell of the wave-eliminating device. become. This wave is attenuated not only when passing from the outside of the outer shell toward the inside thereof, but also when passing from the inside of the outer shell toward the outside thereof. Therefore, this wave canceling device can effectively attenuate the wave while suppressing the reversal of the wave.

According to the second aspect of the present invention, since the float members are arranged at regular intervals in the extension direction of the outer shell, uniform buoyancy can be obtained in the entire apparatus and a stable installation state can be obtained. To be Further, since the pipe members are arranged below the float member and are connected to each other, the floating state of the float member can be stably obtained.

According to the third aspect of the invention, the buoyancy of the wave canceling device can be adjusted to a desired value by adjusting the amount of water injected into the closed space of the pipe member, and the floating state of this device can be set arbitrarily. It is possible to change the wave-removing performance.

[0014]

An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram in which a part of the wave canceling device 1 according to the present example is shown on a course of a boat racecourse and is omitted. Specifically, this wave canceller 1 is installed along the extension direction of this wall surface at a position close to the wall surface of the side edge of the course. The wave-eliminating device 1 is configured by accommodating a plurality of float members 3, 3, ..., Pipe members 4 and the like inside an outer shell 2 made of a net material formed of meshes with small intervals. Hereinafter, each member will be described.

The float member 3 is a hollow substantially spherical body made of a hard vinyl chloride material, and its diameter is set to 430 mm, for example. The diameter can be set arbitrarily. Also, as shown in FIG. 2, the left and right sides of the float member 3 have protruding pieces 3a, 3a that are erected on the outer wall surface of the float member 3.
And a small-diameter connecting hole penetrating in the horizontal direction is formed in the center of the protruding piece 3a.

On the other hand, the pipe member 4 is made of a zinc drawing tube and extends along the extension direction of the wave breaking device 1 (the left-right direction in FIG. 1). The float member 3 and the pipe member 4 described above are connected by the connecting plate 5. A bolt insertion hole 5a is opened at the upper end of the connecting plate 5, and the positions of the bolt insertion hole 5a and the connecting hole formed in the projecting piece 3a of the float member 3 are aligned with each other. An auxiliary plate 6 having substantially the same shape as the protruding piece 3a and having a bolt insertion hole 6a opened at a position corresponding to the connecting hole is in contact with a surface of the protruding piece 3a opposite to the contact surface of the connecting plate 5. With the projecting piece 3a sandwiched between the auxiliary plate 6 and the connecting plate 5 in this manner, the bolt B is inserted into each hole and the nut N is attached to the bolt B as shown in FIG. The three members 3a, 5 and 6 are integrally assembled by screwing. The lower end of the connecting plate 5 is welded to the upper portion of the pipe member 4. In this way, the float member 3 and the pipe member 4 are connected by the connecting plate 5.

The outer shell 2 has a cylindrical main body portion 2a for accommodating the float member 3, the pipe member 4 and the connecting plate 5, and the left and right end portions of the main body portion 2a. The main body portion 2a is integrally assembled with the lid portion 2b arranged so as to close the left and right opening portions. That is, the diameter of the main body portion 2a is set so as to match the dimension (for example, 600 mm) from the upper end of the float member 3 to the lower end of the pipe member 4, and the lid portion 2b also corresponds to the shape of the main body portion 2a. Is formed.

With such a configuration, when the float member 3, the pipe member 4 and the connecting plate 5 are accommodated in the outer shell 2, as shown in FIG. 1, the upper end portion of the float member 3 and the pipe member 4 are The lower ends are in contact with the inside of the main body 2a of the outer shell 2, and both ends of the pipe member 4 are close to the inside of the lid 2b.

Then, the dimensions of the single wave breaking device 1 (see FIG. 1)
The horizontal dimension of the part indicated by the solid line is 25000 mm, for example.
Is. That is, the longitudinal dimension of the outer shell 2 and the longitudinal dimension of the pipe member 4 are each formed to be 25000 mm, and 25 float members 3 are arranged in series in the outer shell 2 at regular intervals. It is housed (this number can also be set arbitrarily). Further, as shown in FIG. 3, the pipe member 4 includes a plurality of pipes of plural types (for example, length
(5500 mm, 3000 mm, etc.) are connected in series by the joint member 4c, and the whole is of the above-mentioned predetermined length (25000 m).
m) are formed. Further, as shown in FIG. 2, the opening portions at the left and right ends of the pipe member 4 are closed by caps 4a, and the inside thereof is a closed space. Further, anchor connecting brackets 4b are welded to a plurality of places (three places in the case of the present example) of the lower end portion of the pipe member 4, and as shown in FIG. Anchors 8 are connected to each other via the like, and the anchors 8 are locked to the bottom part of the water surface, whereby the wave canceller 1 is fixed in position.

The wave-eliminating device 1 having the above-mentioned structure
Are configured to allow two or more connections. That is, the connecting bracket 9 is attached to the right protruding piece 3a of the float member 3 located on the rightmost side in FIG. The connecting bracket 9 is formed by twisting a rectangular plate member by 180 ° at the central portion in the longitudinal direction, and another wave-eliminating device 1 shown by an imaginary line.
Float member located on the leftmost side of ´ (not shown)
Can be connected to the other end of the connecting bracket 9. With such a configuration, a plurality of wave-eliminating devices 1 and 1'can be connected in series, depending on the length of the wave-eliminating region. The number of connections is set arbitrarily. Therefore, the connecting brackets 9 are not provided on the float members 3 outside the wave breaking device located at both ends of the plurality of wave breaking devices 1 and 1 ′ connected to each other, and are located at both ends of the other wave breaking devices. The floating members 3 and 3 are provided with a connecting bracket 9 so that they can be connected to each other.

When setting the floating position of the wave-eliminating device 1 with respect to the water surface, the cap 4a arranged at the end of the pipe member 4 is removed, and a predetermined amount of water is put inside the pipe member 4. By injecting water, the amount of air in the pipe can be adjusted to adjust the buoyancy of the whole wave-eliminating device 1. The water level of the wave-eliminating device 1 can be adjusted by the amount of water injected into the pipe member 4. The floating position with respect to can be set to an arbitrary position.

Next, the wave breaking operation by the wave breaking device 1 configured as described above will be described. As described above, when the wave is propagated from the direction orthogonal to the extension direction to the wave-eliminating device 1 installed on the water surface and fixed in position by the anchor 8, this wave is emitted by the wave-eliminating device. It passes between the meshes of the outer shell 2 of No. 1 and is slightly attenuated when passing between the meshes. Further, the waves that have passed through the meshes and entered the inside of the outer shell 2 may come into contact with the float member 3 or the connecting plate 5, or may pass through the meshes again without contacting them. 2 propagates from the inside to the outside. In other words, the waves that come into contact with the float member 3 and the connecting plate 5 are inverted, propagate toward the center of the course, pass through between the meshes again, and are attenuated, while waves that do not come into contact with them are at the side edges of the course. It propagates toward the wall surface, passes through between the meshes again, and is attenuated. In this way, as the waves are dispersed, attenuation is performed by each mesh,
Waves are effectively damped and the propagation of waves to the center of the course is greatly reduced. Specifically, the wave amplitude is reduced to about 1/5. Further, the pipe member 4 also suppresses the "waviness" of the wave and attenuates the wave.

Thus, according to the wave canceling device 1 of this example,
Compared to the conventional one, it can significantly reduce the wave,
The wave breaking can be surely performed.

Next, a design example of the wave canceling device having such a configuration will be described. In this example, in the installed state as shown in FIG. 4, the radius r of the float member 3 is 225 mm, the height dimension h of the portion of the float member 3 located below the water surface is 130 mm, and the portion located above the water surface. Height dimension H of 32
It is set to 0mm. Further, the number of the float members 3 arranged in one wave breaking device 1 is 20, the total length of the wave breaking device 1 is 19 m, and the number of anchors arranged is 4. Therefore, the weight of each member is as follows. Weight of pipe member: 5.31 (kg / m) × 19 (m) = 10
0.89 (kg) Anchor weight: 0.5 (kg) x 4 (pieces) = 2.0 (kg) Chain weight: 1.3 (kg / m) x 5 (m) x 4 (pieces) =
26.0 (kg) The sum of these is the weight added to the float member 3, and is 100.89 + 2.0 + 26.0 = 128.89 (kg). The buoyancy of one float member 3 in this example is 33.4 (kg), and the volume V of the portion located below the water surface is V = π × 130 ² {225- (130/3 )} = 992
3300 (mm ³ ) The total volume V 0 of the spherical portion of the float member 3 is V 0 = (4π / 3) × 225 ³ = 4768870 (mm
³ ) And the ratio of the volume of V0 to V is: V0 / V = 47687750/9923300 = 4.8 As described above, the buoyancy of one float member 3 is 33.4.
Since it is (kg), the actual buoyancy per unit in the floating state as shown in FIG. 4 is 33.4 / 4.8 = 6.95 (kg), and 20 float members are provided. Therefore, the buoyancy of 6.95 × 20 = 139 (kg) will be obtained. Also, as mentioned above,
Since the weight added to the float member 3 is 128.89 (kg), the weight and the buoyancy are substantially balanced, and a stable floating state can be obtained in such a design state. In this way, the wave canceller 1 is designed.

In the present example, the wave-eliminating device 1 is installed at a position close to the wall surface of the course side edge of the boat racetrack, but the present invention is not limited to this, and is installed in front of the pit. The waves generated around the pits before the start of the race may be eliminated. Further, the wave canceling device of the present invention may be installed in a portion other than the boat racetrack where wave breaking is required, such as a swimming pool.

[0026]

As described above, according to the present invention, the following effects are exhibited. According to the first aspect of the present invention, the wave breaking device is provided with an outer shell formed in a tubular shape by a net material formed of meshes with predetermined intervals, and a plurality of float members are housed inside the outer shell. Therefore, when the wave reaches the wave breaker, the wave is attenuated when the wave passes between the meshes of the outer shell of the wave breaker, and the wave is suppressed while suppressing the inversion of the wave. The waves can be effectively damped, and when the waves are installed on the course side edge of the boat racecourse, the waves can be sufficiently suppressed on the course.

According to the second aspect of the present invention, since the plurality of float members are arranged at regular intervals in the extending direction of the outer shell, uniform buoyancy is obtained and stable in the entire apparatus. The installed state can be obtained. Further, below the float member, an anchor for fixing the position of the entire apparatus is connected, and a pipe member extending in the extension direction of the outer shell is disposed, and the float member and the pipe member are connected via a connecting plate. Since the structure is such that they are connected, the floating state of the float member can be stably obtained.

According to the third aspect of the present invention, both ends of the pipe member in the longitudinal direction are closed by caps to make the inside of the pipe member a closed space, and water is injected into the closed space, and the injection is performed. Since the buoyancy can be adjusted by adjusting the amount, the floating state of this device can be set arbitrarily, and thereby the wave-removing performance can be changed arbitrarily.

[Brief description of drawings]

FIG. 1 is a diagram in which a part of an installation state of a wave breaking device is omitted.

FIG. 2 is a partial enlarged view showing the vicinity of an anchor connecting portion of the wave breaking device.

FIG. 3 is a partially enlarged view showing a pipe member joint portion of the wave breaking device.

[Fig. 4] IV-IV in Fig. 1 showing the installation state of the wave canceller
It is sectional drawing along the position corresponding to a line.

[Explanation of symbols]

 1, 1'wave-eliminating device 2 outer shell 3 float member 4 pipe member 5 connecting plate 8 anchor

Claims (3)

[Claims] 1. A wave-dissipating device installed on the water surface so as to attenuate and dissipate a wave generated and propagating on the water surface, which is formed into a tubular shape by a net material formed of meshes at predetermined intervals. And a plurality of float members housed inside the outer shell. 2. A plurality of float members are arranged at regular intervals in the extension direction of the outer shell, and an anchor for fixing the position of the entire device is connected to the lower side of the float members. 2. The wave breaking device according to claim 1, wherein a pipe member extending in the extension direction of the outer shell is provided, and the float member and the pipe member are connected via a connecting plate. 3. The pipe member has both ends in the longitudinal direction closed by caps to form a sealed space inside, and water is injected into the sealed space and the injection amount is adjusted. The wave breaking device according to claim 2, wherein the buoyancy is adjustable.