JPH10160623A - Wave suppressor for test water tank - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress wave generated in a test water tank effectively by disposing a plurality of horizontal plates having a water flow-in part and mesh bodies at the end part of the test water tank thereby suppressing the wave over a wide range of wavelength. SOLUTION: A wave suppressor 11 is disposed on the bottom face of a test water tank contiguously to the end wall 6 thereof. The frame 10 of the wave suppressor 11 supports a plurality of horizontal plate 9 arranged at an interval in the vertical direction. Each horizontal plate 9 is provided with a water flow-in part 12 comprising a plurality of holes or slits for passing the water in the vertical direction. Mesh bodies 8 made of a plastic material are provided between respective horizontal plates 9 and a baffle 13 is planted between the water flow-in parts 12. The mesh bodies 8 absorb energy of a wave 3 and the horizontal plates 9 function to block circular movement of water particles. Consequently, energy of the wave 3 is converted into energy of flow between the horizontal plates 9 and thereby the wave 3 is damped. The flow-in parts 12 generates vortexes in the passing water thus suppressing the wave.

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 for a test tank for canceling waves in a test tank.

[0002]

2. Description of the Related Art First, a conventional wave absorber for a test water tank will be described with reference to the drawings. FIG. 8 shows one example of a conventional wave canceling device for a test tank.
FIG. 9 is a side view of an essential part showing an example, and FIG. 9 is a plan view of the wave canceling device of the test water tank shown in FIG.

In the conventional wave absorber for a test tank shown in FIGS. 8 and 9, the bottom wall 5 of the tank is connected to the end wall 6 of the tank.
A large number of channel members 2 are placed on a slope 1 installed over
They are installed along the slope 1 at substantially equal intervals from each other, extending in the transverse direction of the water tank. Then, each channel member 2 disposed on the slope 1 has a wave 3 traveling in a traveling direction indicated by, for example, an arrow 4 in the water tank.
Is broken by the wave breaking action of each channel member 2 to eliminate the wave.

[0004]

However, in the above-described conventional wave-absorbing device, if the wavelength of the wave is long, the wave-absorbing effect becomes worse, and the wave collides with the water tank wall without being wave-absorbed and is reflected. The reflected waves will adversely affect the tank test.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is possible to improve the wave canceling effect even in a region where the wavelength of the wave is long.
So that long wavelength waves can be extinguished, and a wide range of wavelength waves can be extinguished,
Furthermore, in addition to the wave breaking action on the waves, a motion converting action for converting the motion of the waves into vortices is also added, so that the waves generated in the test tank can be effectively eliminated.
It is an object of the present invention to provide a wave absorber for a test tank.

[0006]

Means for Solving the Problems To solve the above-mentioned problems, a wave canceling device for a test water tank according to the present invention comprises a horizontal plate disposed horizontally at an end of the test water tank. At least one water flow portion is formed to allow water to flow from one surface side to the other surface side of the plate body, and a wave-dissipating net is provided at a position adjacent to the plate surface of the horizontal plate body. I have.

[0007] In the wave canceling device for a test water tank according to the present invention, a plurality of horizontal plates are disposed at an end of the test water tank in a substantially horizontal state and are vertically spaced from each other. At least one water flow portion is formed on each of the plate members to allow water to flow in the vertical direction, and a wave-dissipating net is disposed between the horizontal plate members.

Further, in the wave canceling device for a test water tank according to the present invention, the flowing water portion is formed by a through hole having a substantially circular cross section and vertically penetrating therethrough.

Further, in the wave canceling device for a test water tank according to the present invention, the flowing water portion is formed by a slit-like elongated hole having a slit-like elongated cross section and penetrating vertically.

Further, in the wave canceling device for a test water tank according to the present invention, a baffle plate is erected on the horizontal plate vertically to the plate surface of the horizontal plate.

Further, in the wave canceling device for a test water tank according to the present invention, a baffle plate is erected on a horizontal plate disposed in a horizontal state at an end of the test water tank in a direction perpendicular to the plate surface of the horizontal plate. A wave-dissipating net is provided at a position adjacent to the plate surface of the horizontal plate.

Further, the wave canceling device for a test water tank according to the present invention comprises:
At the end of the test tank, a plurality of horizontal plates are disposed at an interval in the vertical direction from each other in a substantially horizontal state,
In each of the horizontal plates, a baffle plate is erected perpendicularly to the plate surface of each of the horizontal plates, and a wave canceling net is disposed between the horizontal plates.

Further, in the wave canceling device for a test water tank according to the present invention, a plurality of the baffle plates are erected in parallel on the horizontal plate at intervals.

Further, in the wave canceling device for a test water tank according to the present invention, the height of the plurality of baffle plates from the plate surface of the horizontal plate is uniform.

Further, in the wave canceling device for a test water tank according to the present invention, the height of the plurality of baffle plates from the plate surface of the horizontal plate is sequentially changed stepwise.

Further, in the wave canceling device for a test water tank according to the present invention, the horizontal plate and the mesh are combined to form a unit structure.

[0017]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a side view of a wave canceler of a test water tank according to one embodiment of the present invention, and FIG. 2 is a cross-sectional plan view of the wave canceler of the test water tank according to the embodiment of FIG.

In FIG. 1 and FIG. 2, a wave absorber 11 is installed on the bottom surface 5 of the test tank adjacent to the end wall 6 of the tank. The wave absorber 11 has, for example, a steel frame 10 whose open surface side is disposed toward the inside of the test water tank. The frame body 10 supports a plurality of horizontal plate bodies 9, and the plurality of horizontal plate bodies 9 supported by the frame body 10 are arranged in a substantially horizontal state with a vertical interval therebetween. I have. Each horizontal plate 9 is formed with a plurality of flowing water portions 14 each having a plurality of holes or slits having various cross-sectional shapes, for example, which allow water to flow in the vertical direction. And
Between the horizontal plates 9, a net 8 made of a water-resistant material such as a plastic material is provided.

As shown in FIG. 1, between the plurality of flowing water portions 12 of each horizontal plate member 9, a baffle plate 13 is provided perpendicular to the plate surface of the horizontal plate member 9.
Can be erected. In addition, only a part of the plurality of horizontal plate bodies 9 has a plurality of flowing water portions 1.
The baffle plate 13 may be provided upright between the two plates vertically to the plate surface of the horizontal plate body 9.

The net 8 absorbs the energy of the waves, and the horizontal plate 9 disposed between the nets 8 acts to block the circular motion of the water particles due to the waves, and transfers the energy of the waves to the horizontal plate. It converts the energy of the flow between the nine to attenuate the waves. Further, the flowing water portion 12 formed on the horizontal plate body 9 generates a vortex in the water passing through the flowing water portion 12, converts the kinetic energy of the wave into the energy of the vortex, and eliminates the wave. Further, the baffle plate 13 erected on the horizontal plate body 9 acts as a breaking wave. The reticulated body 8 absorbs the energy of the short wavelength wave, and the horizontal plate 9 blocks the circular motion of the long wavelength wave. Thus, according to the present invention, a high wave-elimination effect can be obtained for a wide range of waves from short wavelengths to long wavelengths.

Each of the horizontal plates 9 may be securely fixed to the frame 10 so as not to be detachable. However, if the horizontal plates 9 are detachably fixed to the frame 10, they can be used for inspection and repair.
Alternatively, it is convenient to exchange a new horizontal plate of the same type or a horizontal plate of various other types. The vertical intervals between the plurality of horizontal plates 9 may be all constant, and the vertical intervals between the horizontal plates 9 may change depending on the height position of the frame 10. It may be configured so that the user can freely adjust the vertical distance between the horizontal plates 9 with respect to the frame 10.

Further, each horizontal plate 9 can be configured so as to be detachable from the frame 10 individually.
One or more sets of the horizontal plate 9 and the net-like body 8 are combined with each other to form a unit, and each unit can be detachably stored in a storage section formed by the frame 10. The wave canceling device 11 can also be configured.

Next, some of the various forms of the horizontal plate 9 will be described. FIG. 3A is a plan view showing an example of a horizontal plate used in the wave canceling device for a test water tank according to the present invention. FIG. 3B is a side view of the horizontal plate shown in FIG. 4 (1) is a plan view showing another example of the horizontal plate used in the wave canceler of the test water tank of the present invention, FIG. 4 (2) is a side view of the horizontal plate of FIG. 4 (1), FIG. 5 (1) is a plan view showing still another example of the horizontal plate used in the wave canceling device for a test water tank of the present invention, and FIG. 5 (2) is a side view of the horizontal plate of FIG. 5 (1). Fig. 6 (1) is a plan view showing still another example of the horizontal plate used in the wave canceler of the test water tank of the present invention, and Fig. 6 (2) is the horizontal plate of Fig. 6 (1). Side view of the
FIG. 7A is a plan view showing still another example of the horizontal plate used in the wave canceling device for a test water tank according to the present invention.
(2) The figure is a side view of the horizontal plate of FIG. 7 (1).

3 (1) and 3 (2), the flowing water portion 12a of the horizontal plate 9a has a substantially circular cross section and is formed by a through hole vertically penetrating the horizontal plate 9a. Is formed. A vortex is generated so as to reduce the vertical movement of the wave by the flowing water portion 12a formed by the through hole having the substantially circular cross section and penetrating the horizontal plate 9a in the vertical direction. Thereby, the wave energy can be absorbed.

4 (1) and 4 (2), a plurality of baffle plates 13b are arranged on the horizontal plate 9b in parallel with each other at a distance from each other and perpendicular to the plate surface of the horizontal plate 9b. And the horizontal plate 9 of the plurality of baffle plates 13b.
The height b from the plate surface sequentially changes in a stepwise manner. In this way, by providing the step-shaped baffle plate 13b on the horizontal plate body 9b, the wave-breaking effect due to the breaking of the waves can be further improved.

5 (1) and 5 (2), a plurality of baffle plates 13c are arranged on the horizontal plate 9c in parallel with each other at a distance from each other and perpendicular to the plate surface of the horizontal plate 9c. And the horizontal plate 9 of the plurality of baffle plates 13c.
The height c from the plate surface is uniform. In this case, as the wave breaking effect, the same effect as the effect of the stepped baffle plate 13b in FIGS. 4A and 4B can be obtained.
Since the shape and size of each baffle plate 13c can be made uniform, the manufacturing cost is reduced.

In FIG. 6 (1) and FIG. 6 (2), the flowing portion 12d of the horizontal plate 9d has a slit-like shape having a slit-like elongated cross section and vertically passing through the horizontal plate 9d. A plurality of baffle plates 13d are vertically formed on the plate surface of the horizontal plate body 9d between the plurality of flowing water portions 12d. Moreover, the height of the plurality of baffle plates 13d from the plate surface of the horizontal plate 9d is sequentially different in a stepwise manner. In this way, the horizontal plate body 9d has a slit-shaped elongated cross section, and the flowing water portion 12 formed by the slit-shaped elongated holes penetrating the horizontal plate body 9d in the vertical direction.
d and a stepped baffle plate 13d to generate a vortex so as to reduce the up-and-down motion of the wave, thereby improving the energy absorption effect of the wave and further improving the wave-elimination effect by breaking the wave. Can be done.

In FIG. 7 (1) and FIG. 7 (2), the flowing portion 12e of the horizontal plate 9e has a slit-like shape having a slit-like elongated cross section and vertically penetrating the horizontal plate 9e. A plurality of baffle plates 13e are formed between the plurality of flowing water portions 12e, and are formed perpendicularly to the plate surface of the horizontal plate body 9e. Moreover, the height of the plurality of baffle plates 13e from the plate surface of the horizontal plate 9e is uniform. As described above, the horizontal plate 9e has a slit-like elongated cross section, and the flowing water portion 12e formed by the slit-like elongated hole penetrating the horizontal plate 9e in the vertical direction, and the baffle plate 13e having a uniform height. With the above, the vortex is generated so as to reduce the vertical movement of the wave, thereby improving the effect of absorbing the energy of the wave, and further improving the wave canceling effect by breaking the wave. Since the shape and the size of the device can be made uniform, the manufacturing cost is reduced.

[0029]

According to the wave canceling device for a test tank of the present invention,
The following effects can be obtained. (1) At least one running water portion is formed on a horizontal plate body disposed horizontally at an end of the test water tank to allow water to flow from one surface side to the other surface side of the horizontal plate body; Since the wave-dissipating mesh is disposed at a position adjacent to the plate surface of the horizontal plate, the horizontal plate acts to block the circular motion of the water particles due to the waves, and the energy of the waves is transferred to the horizontal plate. Waves are attenuated by converting them to the energy of the flow along the body, and the flowing water generates a vortex in the water passing through the flowing water, converts the kinetic energy of the waves to the energy of the vortex, and performs wave extinction. While the body absorbs the energy of the short wavelength wave, the horizontal plate blocks the circular motion of the long wavelength wave, and the horizontal plate, running water and meshwork cooperate from short wavelength to long wavelength. A high wave-eliminating effect is achieved for a wide range of waves (claim 1). (2) At the end of the test tank, a plurality of horizontal plate members are arranged in a substantially horizontal state and are spaced apart from each other in the vertical direction, and each horizontal plate member allows water to flow in the vertical direction. At least one running water portion is formed, and a wave-dissipating mesh is provided between the horizontal plates, so that the plurality of horizontal plates respectively perform the circular motion of the water particles due to the waves. It acts as a shield, converts the energy of the waves into the energy of the flow along the horizontal plate body and attenuates the waves, and the flowing water generates a vortex in the water passing through the flowing water, The kinetic energy is converted into vortex energy to cancel the wave.The mesh absorbs the energy of the short wavelength wave, while the multiple horizontal plates block the circular motion of the long wavelength wave in a multiple manner. , A plurality of horizontal plates, flowing parts and meshes work together to It can be performed with high wave-dissipating effect on the wave of a wide range up al long wavelength (claim 2). (3) Since the flowing water portion is formed by a through hole having a substantially circular cross section and penetrating in the vertical direction, it is easy to process the flowing water portion on the horizontal plate, and The position of the flowing water and the size of the flowing water can be adjusted by arbitrarily selecting the position of the through hole and the size of the cross section of the through hole. It converts the energy of the waves to the energy of the flow along the horizontal plate and attenuates the waves.The flowing water generates a vortex in the water passing through the flowing water, and the kinetic energy of the waves is reduced. The wave plate absorbs the energy of the short wavelength wave while the horizontal plate blocks the circular motion of the long wavelength wave, and the horizontal plate, the flowing water and the net The body cooperates to achieve a high range of waves from short to long wavelengths. It can exhibit wave-dissipating effect (claim 3). (4) Since the flowing water portion is formed by a slit-shaped elongated hole having a slit-shaped elongated cross-section and penetrating vertically, the direction of the slit-shaped elongated hole is adjusted in accordance with the traveling direction of the wave. By setting it properly, vortices can be effectively generated in the water flowing through the flowing water section, and the kinetic energy of the waves can be efficiently converted to the energy of the vortices to perform wave extinction. The part and the reticulated body cooperate with each other to effectively extinguish a wide range of waves from a short wavelength to a long wavelength (claim 4). (5) Since the baffle plate is erected perpendicularly to the plate surface of the horizontal plate body, the baffle plate breaks waves well, and the horizontal plate body, the baffle plate, the flowing water portion, and the net-like body are provided. Can cooperate with each other to effectively extinguish a wide range of waves from short wavelengths to long wavelengths (claim 5). (6) A baffle plate is erected perpendicularly to the plate surface of the horizontal plate body disposed horizontally at the end of the test water tank, at a position adjacent to the plate surface of the horizontal plate body. Since the wave-dissipating mesh is provided, the horizontal plate acts to block the circular motion of the water particles due to the waves, and converts the energy of the waves into the energy of the flow along the horizontal plate to convert the waves. Attenuate, the baffle breaks the wave well, the mesh absorbs the energy of the short wavelength wave, while the horizontal plate blocks the circular motion of the long wavelength wave, the horizontal plate, the baffle and The meshes cooperate to exhibit a good wave-eliminating effect on a wide range of waves from short wavelengths to long wavelengths. (7) At the end of the test water tank, a plurality of horizontal plate members are arranged in a substantially horizontal state and are spaced apart from each other in the vertical direction, and each horizontal plate member is perpendicular to the plate surface of each horizontal plate member. Since a baffle plate is erected and a wave-dissipating mesh is provided between the horizontal plate members, a plurality of horizontal plate members act to block the circular motion of water particles due to the waves. Then, the wave energy is multiply converted into the energy of the flow along the horizontal plate to attenuate the wave, the baffle on each horizontal plate breaks the wave well and the net is While absorbing the energy of the short wave, the multiple horizontal plates block the circular motion of the long wavelength wave in a multiple way, and the multiple horizontal plates, baffles and nets cooperate to work from the short wavelength to the long wavelength. The wave canceling action can be favorably performed on waves in a wide range up to the wavelength (claim 7). (8) Since the plurality of baffle plates are erected in parallel on the horizontal plate at intervals, the plurality of baffles erected in parallel on the horizontal plate are multi-staged. The horizontal plate, the baffle plate, and the mesh can cooperate with each other to effectively cancel the wave in a wide range from short to long wavelengths. . (9) Since the height of the plurality of baffle plates from the plate surface of the horizontal plate body is uniform, the shape and size of each baffle plate can be made uniform, thereby making and managing members. The baffle plate breaks waves well in multiple stages, and the horizontal plate, baffle plate, and mesh work together to effectively extinguish a wide range of waves from short to long wavelengths. The function can be performed (claim 9). (10) Since the heights of the plurality of baffle plates from the plate surface of the horizontal plate body are sequentially changed in a stepwise manner, the wave-breaking effect due to the breaking of waves is improved, and the horizontal plate body, the baffle plate, and the net-like shape are provided. The bodies cooperate with each other to effectively perform wave canceling on a wide range of waves from short wavelengths to long wavelengths.
0). (11) Since the horizontal plate and the mesh are combined to form a unit structure, operations such as transport, assembly, and replacement can be performed in units of the unit structure.
The efficiency of operations such as transportation, assembly, and replacement can be improved.In use, at least the horizontal plate and mesh work together to cope with a wide range of waves from short to long wavelengths. A high wave-elimination effect is achieved (claim 11).

[Brief description of the drawings]

FIG. 1 is a side view of a test-water tank wave-breaking device according to an embodiment of the present invention.

FIG. 2 is a plan view of the wave absorber of the test tank according to the embodiment of FIG. 1;

FIG. 3 (1) is a plan view showing an example of a horizontal plate used in the wave canceling device for a test tank according to the present invention.
(2) The figure is a side view of the horizontal plate of FIG. 3 (1).

FIG. 4 (1) is a plan view showing another example of the horizontal plate used in the wave canceling device for a test tank according to the present invention;
(2) The figure is a side view of the horizontal plate of FIG. 4 (1).

FIG. 5 (1) is a plan view showing still another example of the horizontal plate used in the wave absorber of the test water tank of the present invention, and FIG. 5 (2) is a horizontal view of FIG. 5 (1). It is a side view of a board.

FIG. 6 (1) is a plan view showing still another example of the horizontal plate used in the wave canceling device for a test tank according to the present invention, and FIG. 6 (2) is a horizontal view of FIG. 6 (1). It is a side view of a board.

FIG. 7 (1) is a plan view showing still another example of the horizontal plate used in the wave canceling device for a test water tank of the present invention, and FIG. 7 (2) is a horizontal view of FIG. 7 (1). It is a side view of a board.

FIG. 8 is a side view of an essential part showing an example of a conventional wave canceler for a test water tank.

FIG. 9 is a plan view of the wave canceling device of the test tank shown in FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Slope 2 Channel material 3 Wave 4 Arrow indicating wave traveling direction 5 Bottom of water tank 6 End wall of water tank 7 Water tank 8 Reticulated body 9, 9a, 9b, 9c, 9d, 9e Flat plate body 10 Frame 11 Wave canceler Reference Signs List 12 running water section 12a through hole 12d as running water section 12d, slit elongate hole as running water section 13, 13b, 13c, 13d, 13e baffle plate

Claims (11)

[Claims] 1. A horizontal plate body disposed horizontally at an end of a test water tank has at least one flowing water portion which allows water to flow from one surface side to the other surface side of the horizontal plate body. A wave absorber for a test water tank, wherein a wave absorber mesh is disposed at a position adjacent to a plate surface of the horizontal plate. 2. A plurality of horizontal plate members are disposed at an end of the test tank in a substantially horizontal state and are spaced apart from each other in a vertical direction, and each horizontal plate member has a flow of water in a vertical direction. At least one flushing section is formed,
In addition, a wave absorber for a test water tank is provided with a wave absorber net between the horizontal plates. 3. The wave canceling device for a test water tank according to claim 1, wherein the flowing water portion is formed by a through hole having a substantially circular cross section and vertically penetrating therethrough. A wave absorber for a test tank. 4. The wave canceling device for a test water tank according to claim 1 or 2, wherein the flowing water portion is formed by a slit-like elongated hole having a slit-like elongated cross-section and vertically penetrating therethrough. A wave attenuator for a test tank. 5. The wave canceling device for a test tank according to claim 1, wherein a baffle plate is erected on the horizontal plate vertically to a plate surface of the horizontal plate. A wave attenuator for a test tank. 6. A horizontal plate disposed in a horizontal state at an end of the test water tank, a baffle plate is erected perpendicularly to the plate surface of the horizontal plate, and is adjacent to the plate surface of the horizontal plate. A wave absorber for a test water tank, wherein a wave absorber net is disposed at a position. 7. A plurality of horizontal plate members are disposed at an end of the test tank in a substantially horizontal state and are spaced apart from each other in a vertical direction, and each horizontal plate member has a plate surface of the horizontal plate member. A wave absorber for a test water tank, characterized in that a baffle plate is erected vertically and a wave-absorbing mesh is disposed between the horizontal plates. 8. The wave canceling device for a test water tank according to claim 5, wherein a plurality of said baffles are erected in parallel on said horizontal plate at intervals. A wave attenuator for a test tank. 9. The wave canceling device for a test tank according to claim 8, wherein the height of the plurality of baffle plates from the plate surface of the horizontal plate is uniform. Wave absorber. 10. The wave canceling device for a test tank according to claim 8, wherein the height of the plurality of baffle plates from the plate surface of the horizontal plate body is sequentially changed in a stepwise manner. , Test water tank wave absorber. 11. The wave canceling device for a test tank according to claim 1, wherein the horizontal plate and the mesh are combined to form a unit structure. Wave absorber.