JP6894609B2 - Floating and sinking fences and floating and sinking fence systems - Google Patents

Description

The present invention relates to a floating and sinking fence and a floating and sinking fence system.

Conventionally, floating and sinking fences may be installed in rivers, dam lakes, etc. for the purpose of suppressing the downstream outflow of floating garbage. As such a floating / sinking fence, for example, a floating / sinking fence as disclosed in Patent Document 1 is known. The floating / sinking fence disclosed in Patent Document 1 includes an upper fence, a lower fence, and a bag body (float) whose buoyancy can be adjusted by air at the lower ends of the upper fence and the lower fence, and a bag body. It is equipped with a bag body and a weight body arranged in parallel to each other on the outside, and by supplying air to one or both of the bag body arranged on the upper fence and the bag body arranged on the lower fence. , One or both of the upper fence and the lower fence can be levitated. As a result, for example, in the flood season or when muddy water flows in, the lower part of the fence can be floated to allow water to flow as needed.

Japanese Patent No. 3632000

However, in the floating / sinking fence as in Patent Document 1, since the weight body is arranged on the outer side of the bag body separately from the bag body, the bag body and the weight body become bulky, and the bag body and the weight are used. Each of the bodies becomes a resistance to water. Therefore, in the normal state where the weight body and the bag body arranged at the lower end of the fence are submerged in water, it becomes difficult for water to flow smoothly. It is also possible that the resistance of water hinders the smooth raising and lowering of the lower end of the fence. Furthermore, when raising and lowering the lower end of the fence, it is conceivable that the fence will be damaged by the weight and foreign matter caught on the weight.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a floating / sinking fence in which a weight body and a bag body for raising the lower end of the impermeable fence are compact and less susceptible to water resistance. .. More preferably, it is an object of the present invention to provide a floating / sinking fence that is less likely to be damaged by a weight body or a foreign matter caught on the weight when raising or lowering the fence.

In order to solve the above problems, the present invention uses a float floating on a water surface, a water-blocking fence hanging from the float into water, a weight for sinking the lower end of the water-blocking fence, and an air buoyancy. It is provided with a bag body formed so that air can be supplied and discharged so that the lower end of the impermeable fence can be floated, and one of the weight body and the bag body is housed in the other. It provides a floating and sinking fence characterized by being present.

According to this configuration, the lower end of the impermeable fence can be raised (floated) by supplying air to the bag body to generate a buoyancy larger than the weight of the weight body. Moreover, since the bag body is housed in the weight body, it can be made compact and the resistance of water can be reduced. Therefore, in the normal state where the weight body and the bag body arranged at the lower end of the impermeable fence are submerged in water, water can flow smoothly. Further, when raising and lowering the lower end of the impermeable fence, the resistance of water can be reduced and the operation can be performed smoothly.
In this case, it is preferable that the bag body extends in the longitudinal direction of the tubular body, and the plurality of through holes are formed in the longitudinal direction of the tubular body.

In the floating / sinking fence, the tubular body preferably has a circular or elliptical cross-sectional outer peripheral shape.

According to this configuration, the resistance of water when raising and lowering the lower end of the impermeable fence can be reduced, and even if the weight body directly rubs against the impermeable fence when raising the lower end of the impermeable fence, the weight body The contact resistance of the water shield is small, and the impermeable fence is less likely to be damaged.

On the other hand, in the floating / sinking fence system of the present invention, the floating / sinking fence described above, a detection unit that detects an external force acting on the impermeable fence by a water flow or a physical quantity proportional to the external force, and a detection value by the detection unit are set. When the value is equal to or higher than the value, a control unit for controlling the supply of air to the bag body is provided so as to raise the lower end of the impermeable fence.

According to this floating / sinking fence system, it is possible to automatically raise the lower end of the impermeable fence to promote water flow when a situation occurs in which the external force acting on the impermeable fence becomes large, such as when the water level rises. It becomes. Therefore, it is possible to protect the impermeable fence from damage caused by flooding or the like.

As described above, according to the floating / sinking fence of the present invention, it is possible to provide a floating / sinking fence in which the weight body and the bag body that raises the lower end of the impermeable fence are compact and are less susceptible to water resistance. ..

It is a top view of the floating / sinking fence of the 1st Embodiment of this invention installed in a dam lake. It is a front view of the floating / sinking fence of FIG. 1 seen from the upstream side. It is a circuit diagram which shows the whole structure of the floating and sinking fence system. It is a schematic cross-sectional view of the floating and sinking type fence of FIG. FIG. 5 is a schematic cross-sectional view of a state in which air is supplied to a bag body provided in the floating / sinking fence of FIG. 1 and the lower end of the impermeable fence is raised. It is a front view of the floating / sinking fence of the 2nd embodiment. FIG. 6 is a schematic cross-sectional view of the floating / sinking fence of FIG. FIG. 6 is a schematic cross-sectional view of a state in which air is supplied to a bag body provided in the floating / sinking fence of FIG. 6 and the lower end of the impermeable fence is raised.

Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings. FIG. 1 is a plan view of the floating / sinking fence of the first embodiment of the present invention installed on a dam lake, FIG. 2 is a front view of the floating / sinking fence seen from the upstream side, and FIG. 3 is a floating / sinking fence. It is a circuit diagram which shows the whole structure of a fence system.

The floating / sinking fence 1 of the first embodiment includes a float 18 (A, B) floating on the water surface of the dam lake 10, an impermeable fence 17, and a weight 4 for sinking the lower end of the impermeable fence 17. It is provided with a bag body 5 that raises the lower end of the impermeable fence 17. A floating / sinking fence system is configured by the floating / sinking fence 1 and a supply / discharge device 60 for supplying / discharging air to / from the bag body 5. In FIG. 2, for convenience, the float 18 (A) is shown by a line.

Both ends of the float 18 (A, B) are connected to the wires of the anchor blocks 16 and 16 installed on the left bank and the right bank (the left and right are the directions when the upstream side is viewed from the downstream side. The same applies hereinafter). Has been done. The total length of the floating / sinking fence 1 of this embodiment is, for example, about 302 m, and the maximum deflection D is, for example, about 65 m. The total length L1 of the float 18 (A, B) is also substantially the same as the total length of the floating / sinking fence 1.

The float 18 (A, B) is composed of a fixed float 18 (A) that constantly floats on the water surface of the dam lake 10 and a float 18 (B) that floats and sinks due to the supply and discharge of air.

The fixed float 18 (A) is arranged on the right bank side and the left bank side, respectively, and the floating and sinking float 18 (B) is provided between the fixed float 18 (A) on the right bank side and the fixed float 18 (A) on the left bank side. ) Is placed.

The floating / sinking float 18 (B) is a floating / sinking float 18 (B-1) having a width L5 (for example, about 6 m) through which a small boat for management can pass and a length capable of sinking to a depth H2 (for example, about 2 m). ), And the floating / sinking float 18 (B-1) for both water passage and ship passage, and the floating / sinking float 18 (B-2) for exclusive use of water passage for ensuring a desired amount of water flow. In this embodiment, the total length (L2 + L3) of these floats 18 (B-1) and (B-2) is about 40 m.

The floating / sinking float 18 (B-1) for water passage and ship passage is provided with a length L2 from the substantially central portion of the floating / sinking fence 1 to the left bank side, and the floating / sinking float 18 (B-2) dedicated to water passage is provided at the central portion thereof. It is provided with a length of L3 on the right bank side.

The floating / sinking float 18 (B-1) for water passage and ship passage is made of synthetic rubber, and expands into a cylindrical shape (for example, an outer diameter of about 400 mm) when air is supplied.

Auxiliary floats (not shown) are connected to both ends of the upper part of the floating / sinking float 18 (B-1) for both water flow and ship passage by a chain or the like. By ascending to the water surface when the float 18 (B-1) sinks, the sinking position of the float 18 (B-1) for both water passage and ship passage is regulated.

In addition, a ship passage display buoy (not shown) is connected to both sides of the upper part of the floating / sink float 18 (B-1) for water passage and ship passage near the center by a chain or the like, and a pair of left and right passages are connected. Ship display The buoy floats on the water surface when the float 18 (B-1) for both water and ship is submerged (see the alternate long and short dash line), so that the available width of the ship (for example, about 6 m) L5 is displayed. There is.

The floating / sinking float 18 (B-2) for exclusive use of water flow is made of synthetic rubber like the floating / sinking float 18 (B-1) for water passage and ship passage, and is cylindrical (for example, outer diameter) in the air supply state. Is expanded to about 400 mm).

In this embodiment, auxiliary floats (not shown) are connected to appropriate positions (4 locations in this example) above the floating / sinking float 18 (B-2) dedicated to water flow by a chain or the like, and the auxiliary floats (not shown) are connected to each other. When the float floats on the water surface when the float 18 (B-2) dedicated to water flow sinks, the sinking position of the float 18 (B-2) dedicated to water flow is regulated.

The right end of the floating / sinking float 18 (B-1) for water flow and ship and the left end of the floating / sinking float 18 (B-2) for water flow are connected to each other via a communication valve 28 and a connection fitting, which will be described later, so that air can communicate with each other. Has been done. On the other hand, the left end of the floating / sinking float 18 (B-1) for water passage and the floating / sinking float 18 (B-1) and the right end of the fixed float 18 (A) on the left bank side are connected only by the connecting metal fittings. The right end of B-2) and the left end of the fixed float 18 (A) on the right bank side are connected only by the connecting metal fittings. That is, the floats 18 (B-1) and (B-2) and the fixed float 18 (A) are simply connected in a state where air communication is not possible.

The upper end of the impermeable fence 17 is connected to the float 18 (A, B), and the lower end side is arranged so as to hang from the float 18 (A, B) into the water due to the weight of the weight body 4 described later. In this embodiment, the impermeable fence 17 is made of a synthetic resin sheet, the length thereof is substantially the same as that of the float 18 (A, B), and the height H of the impermeable fence 17 is H. Is, for example, about 15 m. As the impermeable fence 17, one having a water-cutting property and one having a certain degree of water permeability are used depending on the place and use. In this embodiment, a water-cutting one is used.

The bag body 5 includes a first bag body 51 supported by the lower end of the impermeable fence 17 and a second bag body 52 housed in the first bag body 51.

As shown in FIG. 4, the first bag body 51 is composed of a tubular body having a second bag body accommodating portion 51a for accommodating the second bag body 52 inside. In this embodiment, the first bag body 51 is provided by folding back the lower end of the sheet constituting the impermeable fence 17 to form a tubular shape. Therefore, as shown in FIG. 2, the first bag body has substantially the same length as the total length of the impermeable fence 17, and is arranged over the entire area at the lower end of the impermeable fence 17. Even if the first bag 51 is separate from the impermeable fence 17, a tubular body formed of a synthetic resin sheet or the like is connected to the lower end of the impermeable fence 17. Good.

In this embodiment, the second bag body 52 is composed of a synthetic rubber tubular body having a weight body accommodating portion 52a for accommodating the weight body 4 inside, as shown in FIG. Further, the second bag body 52 is formed so that air can be supplied and discharged to the weight body accommodating portion 52a so that the lower end of the impermeable fence 17 can be lifted by the buoyancy of the air.

The second bag body 52 has substantially the same length as the first bag body 51, and the entire second bag body 52 is housed in the second bag body accommodating portion 51a of the first bag body 51.

In this embodiment, the weight body 4 is composed of a chain in which a plurality of chain elements are sequentially connected, and has substantially the same length as the length of the impermeable fence 17. The weight body 4 is housed in the weight body accommodating portion 52a of the second bag body 52, and the whole is covered by the second bag body 52. The weight body 4 is fixed to the second bag body 52 at a plurality of places including both ends in the longitudinal direction thereof. In FIG. 2, only a part of the weight body 4 is shown.

As shown in FIG. 3, the water supply / discharge device 60 communicates with an air supply machine (compressor) 6, an air supply hose extending from the air supply machine 6, and a floating / sinking float 18 (B-1) for water passage and ship passage. It is provided with a communication valve 28 for connecting the floating / sinking float 18 (B-2) dedicated to water and an exhaust valve 30 provided on the floating / sinking float 18 (B-1) for both water passage and ship passage. In FIG. 3, the first bag body 51 and the weight body 4 are omitted.

The air supply hose includes a float air supply hose 29 extending from the air supply machine 6 to the floating / sinking float 18 (B-1) for water flow and ship passage, and a bag body supply extending from the air supply machine 6 to the second bag body 52. An air hose 54, a communication valve air supply hose 32a extending from the air supply machine 6 to the communication valve 28, and an exhaust valve air supply hose 33a extending from the air supply machine 6 to the exhaust valve 30 are provided.

The float air supply hose 29 is provided with a float air supply valve 31, and the bag air supply hose 54 is provided with a bag air supply / exhaust valve 71. Further, the air supply hose 32a for the communication valve and the air supply hose 33a for the exhaust valve are provided with air drive valves 32b and 33b for controlling the opening and closing of the communication valve 28 and the exhaust valve 30, respectively. Further, the bag body air supply hose 54 is provided with a bag body air supply / exhaust valve 71 such as a three-way valve.

In this embodiment, the control unit 7 automatically controls the air supply to the second bag body 52 via the bag body air supply / exhaust valve 71.

Specifically, the impermeable fence 17 is provided with a detection sensor 72 (corresponding to the detection unit of the present invention) that detects the tension applied to the impermeable fence 17 by the water flow. The control unit 7 is communicably connected to each of the bag air supply / exhaust valve 71 and the detection sensor 72. Then, when the detection sensor 72 detects that a tension equal to or higher than the set tension (corresponding to the set value of the present invention) is applied to the impermeable fence 17, the control unit 7 controls the bag air supply / exhaust valve 71. Air is sent from the air supply machine 6 to the second bag body 52.

The air supply valve 31 and the air drive valves 32b and 33b can be manually operated by workers on land, but can also be remotely controlled by a crew member of a small boat for management or the like using a remote controller or the like.

Further, the air supply / exhaust valve 71 for the bag body is not limited to the one that is automatically controlled by the control unit 7, and may be one that can be manually operated, and can be changed as appropriate. Further, the detection sensor 72 is not limited to the one that detects the tension applied to the impermeable fence 17, and may be, for example, the one that detects the flow rate or the flow velocity of the water flow. In short, the impermeable fence 17 is provided by the water flow. Any external force that works or a physical quantity that is proportional to the external force may be detected.

Next, the operation of the floating / sinking fence 1 of the first embodiment configured as described above will be described. First, the operation of the floating / sinking float 18 (B-1) for water passage and the floating / sinking float 18 (B-2) for exclusive use of water passage will be described.

Normally, by closing the exhaust valve 30 and opening the communication valve 28, air is supplied from the air supply machine 6 to the floating / sinking float 18 (B-1) for water passage and ship passage via the air supply hose 29, and communication is performed. Air is also supplied to the floating / sinking float 18 (B-2) dedicated to water flow through the valve 28. As a result, the floating / sinking float 18 (B-1) for water passage and the floating / sinking float 18 (B-2) for water passage are kept floating on the water surface. Therefore, the water on the upstream side flows to the downstream side only through the lower part of the impermeable fence 17.

At this time, since the weight body 4 arranged at the lower end of the impermeable fence 17 is housed in the bag bodies 51 and 52, the resistance of water is higher than when the weight body and the bag body are separately arranged. It becomes smaller. Therefore, water can flow smoothly from the lower side of the impermeable fence 17 to the downstream side.

Then, when the exhaust valve 30 and the communication valve 28 are opened as needed, the air of the floating / sinking float 18 (B-1) for water passage and the floating / sinking float 18 (B-2) for exclusive use of water is exhausted. The floating / sinking float 18 (B-1) for water passage and ship passage and the floating / sinking float 18 (B-2) for exclusive use of water passage will be submerged in water. As a result, the water on the upstream side also passes through the subsided floating / sinking float 18 (B-1) for water passage and the floating / sinking float 18 (B-2) for exclusive use of water flow in the upper end of the impermeable fence 17. It will flow to the downstream side.

In order to allow the small boat for management to pass through while the floating / sinking float 18 (B-1) for water passage and the floating / sinking float 18 (B-2) for water passage are floating on the water surface, the communication valve 28 If you close and open the exhaust valve 30, only the air of the floating / sinking float 18 (B-1) for water passage and ship passage will be exhausted. Only the floating / sinking float 18 (B-1) for water passage and ship passage can be submerged in water to a depth H2 over a width L5. As a result, the small boat can be freely passed to the upstream side and the downstream side of the floating / sinking float 18 (B-1) for both water passage and passage.

Next, the operation of the bag body 5 will be described. For example, when the detection sensor 72 detects that a large amount of turbid water flows in from the upstream side at a high speed and a tension equal to or higher than the set tension is applied to the impermeable fence 17, the control unit 7 controls the air supply / exhaust valve for the bag body. The 71 is controlled, and air is sent from the air supply machine 6 to the second bag body 52 via the bag body air supply / exhaust valve 71. As a result, as shown in FIGS. 4 and 5, when air is accumulated in the second bag body 52 in which the weight body 4 is housed and a buoyancy larger than the weight of the weight body 4 acts on the second bag body 52, the second bag body 52 becomes the first. The two-bag body 52 rises to the water surface together with the weight body 4. Along with this, as a result of the lower portion of the impermeable fence 17 rising to the water surface, the impermeable state by the impermeable fence 17 is released. Therefore, the impermeable fence 17 is prevented from being damaged by being continuously subjected to the water pressure of a large amount of muddy water.

At this time, since the weight body 4 arranged at the lower end of the impermeable fence 17 is housed in the bag bodies 51 and 52, the weight body and the bag body are separately separated when raising the lower end of the impermeable fence 17. The resistance of water can be reduced as compared with the case where it is arranged in, and the lower end of the impermeable fence 17 can be smoothly levitated.

Further, when the weight body 4 is exposed to the outside, foreign matter is easily caught on the weight body 4 made of a chain, and the foreign matter rubs against the water blocking fence 17 when the lower end of the water blocking fence 17 rises. The impermeable fence 17 may be damaged. Further, even when a foreign object is not caught on the weight body 4, the weight body 4 itself may rub against the water-impervious fence 17 when the water-impervious fence 17 floats, and the water-impervious fence 17 may be damaged.

However, according to the impermeable fence 17 of the above embodiment, since the weight body 4 is housed in the bag bodies 51 and 52, there is no possibility that foreign matter is caught in the weight body 4 formed of the chain, and the impermeable fence 17 The impermeable fence 17 is not damaged by the foreign matter when raising the lower end of the. Further, when raising the lower end of the impermeable fence 17, the weight body 4 does not directly rub against the impermeable fence 17, and therefore the impermeable fence 17 is not damaged by the weight body 4.

Further, since the second bag body 52 containing the weight body 4 is further housed in the first bag body 51, the second bag body 52 does not rub against the impermeable fence 17, and the second bag body 52 It is prevented from being damaged by being rubbed against the impermeable fence 17. Therefore, even in long-term use, it is possible to prevent the bag body from being torn, hindering the raising and lowering of the lower end of the fence, and exposing the weight body.

In order to return the impermeable fence 17 to the original state (the state shown in FIG. 1), the worker manually or remotely controls the bag body by operating the air supply / exhaust valve 71 for the bag body. The air in the second bag body 52 is exhausted from the air supply / exhaust valve 71. As a result, the lower part of the impermeable fence 17 is submerged by the weight of the weight body 4.

In this case as well, since the weight body 4 arranged at the lower end of the impermeable fence 17 is housed in the bag bodies 51 and 52, the resistance of water is reduced as in the case of raising the lower end of the impermeable fence 17. Therefore, the lower end of the impermeable fence 17 can be smoothly lowered. Further, since the weight body 4 is housed in the bag bodies 51 and 52, there is no possibility that foreign matter is caught in the weight body 4 made of a chain, and when the lower end of the water-impervious fence 17 is lowered, the water-impervious fence is caused by the foreign matter. 17 is not damaged. Further, when the lower end of the impermeable fence 17 is lowered, the weight body 4 does not directly rub against the impermeable fence 17, and therefore the impermeable fence 17 is not damaged by the weight body 4.

In the first embodiment, the bag body 5 is composed of the first bag body 51 and the second bag body 52, but is not limited to this form, and is composed of, for example, only the second bag body 52. It may be changed as appropriate. However, according to the configuration including the first bag body 51 and the second bag body 52, it is possible to prevent the second bag body 52 (the bag body to which air is supplied) from being damaged by contact with foreign matter such as driftwood. Will be done. Therefore, there is an advantage that the durability of the floating / sinking fence 1 can be improved.

Next, the floating / sinking fence 100 of the second embodiment will be described with reference to FIGS. 6 to 8. The floating / sinking fence 100 of the second embodiment includes a float 18 (A, B), an impermeable fence 17, a weight body 104, and a bag body 152, as in the case of the first embodiment. .. The floating / sinking fence 100 and the water supply / discharge device 60 (see FIG. 3) constitute a floating / sinking fence system. The float 18 (A, B), the impermeable fence 17, and the water supply / discharge device 60 have the same configurations as those of the first embodiment.

The weight body 104 of the second embodiment is composed of a tubular body having a bag body accommodating portion 142 inside. The weight body 104 is, for example, a flexible tube made of synthetic resin (rubber) having an elliptical cross-sectional outer peripheral shape, has substantially the same length as the impermeable fence 17, and has a lower end of the impermeable fence 17. Has a weight that can be submerged. The weight body 104 is not limited to having an elliptical cross-sectional outer peripheral shape, and may have, for example, a circular cross-sectional outer peripheral shape, and can be appropriately changed.

A plurality of through holes 141 penetrating the bag body accommodating portion 142 from the outside are formed on the peripheral surface of the weight body 104. These through holes 141 are for allowing water to enter the bag body accommodating portion 142 and discharging the air inside, and are formed over the longitudinal direction of the weight body 104. In FIG. 6, only a part of the through holes 141 are shown.

The bag body 152 is made of a tubular body made of synthetic rubber. The bag body 152 is housed in the bag body accommodating portion 142 of the weight body 104. Further, the bag body 152 is connected to the bag body air supply / exhaust valve 71 via a bag body air supply hose 54.

In the floating / sinking fence 100 of the second embodiment configured as described above, air is not normally supplied to the bag body 152, and the lower end of the impermeable fence 17 is in a state of being sunk by the weight of the weight body 104. It has become.

In this state, when the detection sensor 72 detects that the impermeable fence 17 is under tension equal to or higher than the set tension, the control unit 7 controls the bag air supply / exhaust valve 71 from the air supply machine 6. Air is sent to the second bag body 52. As a result, as shown in FIGS. 7 and 8, when air is accumulated in the bag body 152 housed in the weight body 104 and a buoyancy larger than the weight of the weight body 104 acts on the bag body 152, the weight is applied together with the bag body 152. The body 104 will rise to the surface of the water. Along with this, as a result of the lower portion of the impermeable fence 17 rising to the water surface, the impermeable state by the impermeable fence 17 is released. Therefore, it is possible to prevent the impermeable fence 17 from being damaged by receiving a large amount of turbid water pressure.

At that time, since the bag body 152 arranged at the lower end of the impermeable fence 17 is housed in the weight body 104, the weight body and the bag body are separately arranged when raising the lower end of the impermeable fence 17. The resistance of water can be reduced as compared with the case where the water is shielded, and the lower end of the impermeable fence 17 can be smoothly levitated.

Further, since the weight body 104 has an elliptical cross-sectional outer peripheral shape, it is difficult for foreign matter to get caught in the weight body 104, and when raising the lower end of the impermeable fence 17, the foreign matter is less likely to rub against the impermeable fence 17. Will be done. Further, even if the weight body 104 directly rubs against the water blocking fence 17 when raising the lower end of the water blocking fence 17, the contact resistance of the weight body 104 is small and the water blocking fence 17 is not easily damaged. Therefore, the impermeable fence 17 can be protected from damage caused by rubbing against the weight body 104 and foreign matter caught on the weight body 104.

In order to return the impermeable fence 17 to the original state (the state shown in FIG. 6), the worker manually or remotely controls the bag body by operating the air supply / exhaust valve 71 for the bag body. The air in the bag 152 is exhausted from the air supply / exhaust valve 71. As a result, the lower part of the impermeable fence 17 is submerged by the weight of the weight body 104.

In this case as well, since the weight body 104 has an elliptical cross-sectional outer peripheral shape, the resistance of water can be reduced and the lower end of the impermeable fence 17 can be smoothly performed, as in the case of raising the lower end of the impermeable fence 17. Can be lowered. Further, even if the weight body 104 directly rubs against the water blocking fence 17 when lowering the lower end of the water blocking fence 17, the contact resistance of the weight body 104 is small and the water blocking fence 17 is not easily damaged. Therefore, the impermeable fence 17 can be protected from damage caused by rubbing against the weight body 104 and foreign matter caught on the weight body 104.

Further, since the bag body 152 is housed in the weight body 104 arranged at the lower end of the water-impervious fence 17 in a state where the lower end of the water-impervious fence 17 is sunk, the weight body 104 and the bag body 152 are separately separated. The resistance of water can be reduced as compared with the case where it is arranged. Therefore, water can flow smoothly from the lower side of the impermeable fence 17 to the downstream side.

Further, since the bag body 152 is housed in the weight body 104 in this way, it is possible to prevent the bag body 152 from being damaged by contact with foreign matter such as driftwood. Therefore, there is an advantage that the durability of the floating / sinking fence 100 can be improved.

In the above embodiment, the float 18 (A, B) is composed of the fixed float 18 (A) and the floating / sinking float 18 (B), but the float 18 (A, B) is not limited to this form, for example, the fixed float 18 ( It may be composed of only A) and can be changed as appropriate.

1,100 Floating and sinking fence 4,104 Weight 5 Bag body 6 Air supply machine 17 Impermeable fence 18 Float 18 (A) Fixed float 18 (B) Floating and sinking float 18 (B-1) Floating and sinking float for both water and ship 18 (B-2) Float for water flow 51 First bag 52 Second bag

Claims (4)

A float that floats on the surface of the water, a fence that hangs down from the float into the water, a weight that sinks the lower end of the fence, and an air buoyancy that allows the lower end of the fence to rise. Equipped with a bag body formed to allow air supply and discharge,
The weight body includes a tubular body having a bag body accommodating portion inside, and having a plurality of through holes formed on the peripheral surface for communicating the inside and outside.
The bag body is a floating / sinking fence characterized in that the bag body is housed in the bag body accommodating portion. The tubular body extends in the longitudinal direction of the impermeable fence.
The bag body extends in the longitudinal direction of the tubular body.
The floating / sinking fence according to claim 1, wherein the plurality of through holes are formed in the longitudinal direction of the tubular body. The floating / sinking fence according to claim 1, wherein the tubular body has a circular or elliptical cross-sectional outer peripheral shape. The floating / sinking fence according to any one of claims 1 to 3 and
A detection unit that detects an external force acting on the impermeable fence by a water flow or a physical quantity proportional to the external force,
A floating / sinking fence system including a control unit that controls the supply of air to the bag body in order to raise the lower end of the impermeable fence when the value detected by the detection unit becomes equal to or higher than a set value.

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