JP3171212U - Water gate - Google Patents

Abstract

[PROBLEMS] To reliably drain water even when the amount of water flowing through a water channel is small, without requiring power, with a simple structure, and reliably when the downstream water level is higher than the upstream water level. Provided is a sluice capable of blocking a drain port and preventing backflow. A sluice 1 includes a support arm 5 provided at an upper portion of a drain outlet 2a, and a connection in which one end is rotatably supported on the support arm 5 by a shaft 4 and the other end is connected to an upper portion of a door body 3. The member 6 and the balance weight 7 provided in the intermediate part of the connection member 6 are provided. The balance weight 7 is constituted by what generates buoyancy in water. The door body 3 opens the drainage port 2a in the standard state, opens the drainage port 2a when pressed by water, and drains by the buoyancy of the balance weight 7 when the water level in the outside water area rises above the drainage port 2a. It is swung so as to close the mouth 2a. [Selection] Figure 1

Description

  The present invention relates to a sluice, and more particularly to a sluice installed in a river, a coast, a dam, or the like.

  Rivers, coasts, dams, etc. are provided with sluices that open and close the doors according to the water levels upstream and downstream of the waterway. As a conventional technique of such a sluice gate, as disclosed in Patent Document 1, for example, one that opens and closes by raising and lowering a door body is known. As shown in FIG. 4, such a sluice raises the door 3 ′ to open the drain port 2 a ′ of the sluice 1 ′ when draining the water in the water channel 2 ′ from the upstream side to the downstream side. Further, when the water level on the downstream side rises, the door body 3 ′ is lowered to close the drain port 2 a ′ of the sluice 1 ′ to prevent water from flowing backward from the downstream side to the upstream side.

  In such a sluice 1 ′, generally, a gate pillar 60 ′ that slidably supports both sides of the door body 3 ′ and guides its up-and-down movement, and a floor board 61 provided so as to straddle the gate pillar 60 ′. And an elevating device 62 'provided on the floor plate 61' for driving the elevating and lowering of the door body 3 '. The elevating device 62' is a power source such as an electric motor when the door body 3 'is relatively large. And those that are manually operated when the door body 3 'is relatively small. In general, the lifting device 62 ′ has an auxiliary mechanism that can manually lift and lower the door body 3 ′ even when the power source is lost, even if power is used. In such a sluice 1 ′, in general, not only in the case of the lifting device 62 ′ that is manually operated, but also in the case where the lifting device 62 ′ that uses power is adopted, a person performs a switch operation or the like. When the door 3 'is raised and lowered to open and close, and when the power source is lost, a person goes from the embankment 64' across the management bridge 63 'to operate the auxiliary mechanism of the lifting device 62'. Become.

  As another conventional technique, a door body is provided on the upper part of the drainage outlet of the waterway so as to be swingable through a hinge. When the downstream water level is lower than the upstream water level, the water flowing through the waterway is If the water pressure swings around the hinge so that the lower part of the door opens the drain, and the water level on the downstream side is higher than the water level on the upstream side, the lower part of the door body is moved by the water pressure on the downstream side. A so-called flap gate is known which swings around a hinge so as to block the drain port and prevent backflow from the downstream side to the upstream side. In the flap gate, the upper part of the flap gate is swingably supported by a hinge so that the door body always closes the drainage port of the water channel.

JP-A-8-85934

  In the above conventional technology, as disclosed in Patent Document 1, in the case where the door body 3 ′ is moved up and down by the lifting device 62 ′ using power, the power source is lost particularly due to power failure. Since it is necessary to manually operate the auxiliary mechanism of the elevating device 62 ′ to raise and lower the relatively large door body 3 ′, the sluice 1 ′ is not delayed according to fluctuations in the upstream and downstream water levels. There is a problem that the drainage port 2a 'cannot be opened and closed. Further, in the sluice 1 ′ having a structure for raising and lowering the door body 3 ′, even if the lifting device 62 ′ uses power, a person must raise and lower the door body 3 ′ by a switch operation or the like. In addition, there is a problem that a safety check must be performed by a person, such as whether dust or the like that hinders the up-and-down movement of the door body 3 ′ is attached to the gate pillar 60 ′. Furthermore, in the sluice 1 'having a structure for raising and lowering the door body 3', it is necessary to provide a gate column 60 'for guiding the raising and lowering movement of the door body 3' and a floor plate 61 'for installing the lifting device 62'. Therefore, since the structure is enlarged, a relatively large installation area is required, and there is a problem that a place where the sluice 1 'is installed is limited or costs are increased.

  Moreover, in what is called a flap gate among the above-mentioned conventional techniques, the upper part is supported by a hinge so that the door body always closes the drain outlet of the water channel, and the amount of water flowing through the water channel is small. If the water level is low (the water level on the upstream side is low) and it is difficult to swing the door body to open depending on the water pressure, drainage will continue until the water level in the water channel rises sufficiently to open the door body. The problem is that the water cannot be drained from the mouth, or dust that flows down accumulates in the water channel, clogs the water channel, or is sandwiched between the water channel drain port when the door is opened, and the downstream water level As a result, it becomes impossible to reliably block the drain port when the flow rate becomes high, and as a result, there is a problem that it is impossible to reliably prevent the backflow upstream. And in order to solve these problems, it is necessary to provide a drive means for opening and closing the door body regardless of the upstream and downstream water levels. There were problems such as the location where the flap gate was installed was limited and the cost was high.

  The present invention has been made in view of the above-described problems, and can be drained reliably even when the amount of water flowing through the water channel is small, without requiring power, with a simple configuration, and When the water level on the downstream side is higher than the water level on the upstream side, the drain outlet can be reliably closed to prevent backflow, and the installation location is not limited and can be installed at low cost. The purpose is to provide a sluice with a structure that can be used.

In order to achieve the above-mentioned object, the sluice according to claim 1 is provided with a door body swingable in a water channel for circulating water from the inner water area to the outer water area, and the door body swings. A sluice that opens and closes a drainage port of the water channel, and a support arm provided at an upper part of the drainage port, one end of which is pivotally supported by the support arm by a shaft, and the other end is an upper part of the door body A connecting member connected to the balance member, and a balance weight provided in an intermediate portion of the connecting member,
The balance weight is configured to generate buoyancy in water, and the balance weight is provided at an intermediate portion of the connecting member, whereby the door body is not pressed by water discharged from the water channel. When the water outlet is opened and pressed by water discharged from a water channel, the water outlet is further swung to open the water outlet, and the balance is increased when the water level in the outer water area rises above the water outlet. The door body is swung so as to close the drain port by buoyancy generated by weight.
In order to achieve the above object, the sluice according to claim 2 is characterized in that, in the device according to claim 1, the balance weight has a space formed therein, and can impart buoyancy in the space. It is characterized in that the substance is enclosed.
In order to achieve the above object, the sluice according to claim 3 is characterized in that, in the devise according to claim 2, the substance enclosed in the space is air at atmospheric pressure at normal temperature. .
In order to achieve the above object, a sluice according to claim 4 is characterized in that, in the devise according to claim 2, the substance enclosed in the space is a foam material.
In order to achieve the above object, the sluice according to claim 5 is the device according to any one of claims 1 to 4, wherein the connecting member includes a first connecting member and a second connecting member. One end of the first connecting member is connected to the upper portion of the door body, the other end is connected to the balance weight, and one end of the second connecting member is connected to the support arm. The other end is connected to the balance weight, and the first connection member and the second connection member are different from the balance weight so as to form a predetermined angle therebetween. It is connected to the place.

According to the first aspect of the present invention, the balance weight is provided at the intermediate portion of the connecting member whose end portions are respectively connected to the upper portion of the support arm and the door body. The balance weight balances with the door body and easily swings, generates buoyancy in the water, and further opens the drain port in a state where the door body is not pressed by the water discharged from the water channel. It functions to maintain. For this reason, the door body is maintained in a state in which the drain outlet is opened without being pressed by the water discharged from the water channel by the balance weight without using power, and as a result, the amount of water flowing through the water channel is small. Even if it drains reliably. Further, when the amount of water discharged from the water channel increases, the door body is pressed by this water and is easily swung by the balance weight so as to open the drain outlet, so that the increased amount of water is surely drained without delay. be able to. Further, when the water level in the outer water area rises above the drainage port, the door body is reliably swung so as to close the drainage port by the buoyancy generated by the balance weight provided in the intermediate portion of the connecting member. When the water level on the downstream side is higher than the water level on the upstream side, the drain outlet can be reliably closed to prevent backflow. The movement of these door bodies does not require power, and the balance weight not only balances the door body but also generates buoyancy in the water, so there is no need to provide a float separately from the balance weight. Therefore, the sluice gate can be installed at low cost without limiting the place where the sluice gate is installed.
In the invention of claim 2, in the invention of claim 1, a space is formed in the balance weight, and a substance capable of imparting buoyancy is enclosed in the space, thereby having a simple configuration. Without using power, the door body is maintained in a state where the drain opening is opened without being pressed by the water discharged from the water channel, and when the amount of water increases, it can be easily swung to open the drain opening. In addition, when the water level in the outer water area rises above the drainage port, the door body is swung so as to close the drainage port due to the buoyancy of the balance weight to prevent backflow from the outer water area to the inner water area. Possible sluice gates can be embodied.
According to the invention of claim 3, in the invention of claim 2, a balance capable of generating buoyancy in water at low cost by enclosing air at atmospheric pressure at room temperature in the balance weight space. A sluice with a weight can be embodied.
According to the invention of claim 4, in the invention of claim 2, even if the balance weight is damaged and the internal space is not sealed by sealing the foam material in the balance weight space, A sluice having a balance weight capable of generating buoyancy can be realized.
According to a fifth aspect of the present invention, in the device according to any one of the first to fourth aspects, the connecting member includes a first connecting member and a second connecting member, and a door is provided at one end of the first connecting member. The upper part of the body is connected, a balance weight is connected to the other end, one end of the second connecting member is pivotally supported on the support arm, the other end is connected to the balance weight, and the first connecting member The second connecting member is connected to a different location with respect to the balance weight so as to form a predetermined angle between each other, so that the door body is not pressed against the water discharged from the water channel. When the water discharged from the drainage port is pressed, it is easily swung to open the drainage port, and when the water level in the outside water area rises above the drainage port, the drainage port So that it can be rocked reliably , It is possible to embody the floodgates having a coupling member capable of easily appropriately adjusted.

According to the first aspect of the present invention, the support arm provided at the upper part of the drainage port and one end of the support arm are rotatably supported by the shaft and the other end is connected to the upper part of the door body. And a balance weight provided at an intermediate portion of the connection member. The balance weight is configured to generate buoyancy in water, and the balance weight is an intermediate portion of the connection member. By providing the door body, the door body opens the drain port without being pressed by the water discharged from the water channel, and further opens the drain port when pressed by the water discharged from the water channel. The door body is swung so as to close the drainage port due to the buoyancy generated by the balance weight when the water level in the outer water area rises above the drainage port. Due to the configuration, it is possible to drain reliably even when the amount of water flowing through the water channel is small without requiring power, and reliably when the downstream water level is higher than the upstream water level. The drain port can be closed to prevent backflow, and the balance weight not only balances with the door body but also generates buoyancy in the water, so there is no need to provide a float separately from the balance weight. Therefore, a sluice gate having a structure that can be installed at low cost can be provided without limiting the installation location.
According to the invention described in claim 2, in the invention described in claim 1, the balance weight has a space formed therein, and a substance capable of providing buoyancy is enclosed in the space. Therefore, even when the amount of water flowing through the water channel is small without requiring power, the water can be reliably drained, and reliably when the downstream water level is higher than the upstream water level. A drainage port can be blocked to prevent backflow, and a sluice gate having a structure that can be installed at low cost can be easily provided without limiting the place of installation.
According to the invention described in claim 3, in the invention described in claim 2, the substance enclosed in the space is air at atmospheric pressure at room temperature, so that no power is required. Even when the amount of water flowing through the water channel is small, it can be drained reliably, and when the downstream water level is higher than the upstream water level, the drain outlet is reliably closed to prevent backflow. In addition, it is possible to provide a sluice gate having a structure that can be installed at low cost without limiting the installation location.
According to the invention described in claim 4, in the invention described in claim 2, the substance enclosed in the space is a foam material, so that the water flowing through the water channel without requiring power is used. Even when the amount is small, the water can be drained reliably, and when the water level on the downstream side is higher than the water level on the upstream side, the balance weight reliably generates buoyancy in the water and reliably blocks the drain port. Thus, backflow can be prevented, and a sluice gate having a structure that can be installed at a low cost can be provided at a low cost without limiting the installation location.
According to the invention described in claim 5, in the device described in any one of claims 1 to 4, the connecting member includes a first connecting member and a second connecting member. One connecting member has one end connected to the upper portion of the door body and the other end connected to the balance weight, and the second connecting member is pivotally supported at one end by the support arm. The other end is connected to the balance weight, and the first connecting member and the second connecting member are connected to different locations with respect to the balance weight so as to form a predetermined angle therebetween. By adjusting the connecting member easily and appropriately, it is possible to reliably drain water even when the amount of water flowing through the water channel is small without requiring power, and the downstream water level is low. When the water level is higher than the upstream water level Reliably drain outlet clogged able to prevent backflow, moreover, without place to place is limited, it is possible to reliably provide a structure which can be installed at low cost sluices.

It is the side view which showed the reference | standard state of the door body in order to demonstrate one Embodiment of the sluice of this invention. It is the side view shown in order to demonstrate the state which the water level rose from the state of FIG. 1, the balance weight was submerged, and the door block | closed the drain outlet by the buoyancy. It is the side view shown in order to demonstrate the modification of the sluice by this invention. It is the side view shown in order to demonstrate the outline of the sluice which moves up and down the conventional door body.

One embodiment of the sluice gate of the present invention will be described mainly based on FIG. 1 and FIG. In the figure, the right side is the upstream side and the left side is the downstream side. Moreover, in the figure, the same code | symbol shall be attached | subjected to the same part or an equivalent part.
In the sluice 1 of the present invention, a door 3 is swingably provided in a water channel 2 through which water is circulated from an inner water area to an outer water area, and when the door body 3 swings, a drain outlet of the water channel 2 is provided. 2a for opening and closing the support arm 5 provided at the top of the drain port 2a, one end of which is rotatably supported by the support arm 5 by the shaft 4, and the other end connected to the top of the door body 3. And a balance weight 7 provided at an intermediate portion of the connection member 6, and the balance weight 7 is configured to generate buoyancy in water, and the balance weight 7 is the connection member. 6, the door body 3 opens the drain port 2 a in a state where it is not pressed by the water discharged from the water channel 2, and further drains when pressed by the water discharged from the water channel 2. Swung to open the mouth 2a Furthermore, the water level of the outer waters are configured so that the door body 3 by buoyancy balance weight 7 is produced is swung to close the drain outlet 2a when higher than the drain outlet 2a.

  The water channel 2 in this embodiment is constituted by a soot tube having a substantially rectangular cross section perpendicular to the water flow. The water channel 2 includes an inner water area (right side in FIG. 4) such as a tributary river inside the embankment (see reference numeral 64 ′ in FIG. 4), and an outer water area (left side in FIG. 4) such as a river, a coast, and a dam. It is provided between. The water channel 2 in this embodiment can be formed in a substantially rectangular cross section, for example, and can be formed in a circular cross section, for example. The end face of the water outlet 2a of the water channel 2 is formed substantially vertically.

  A base portion of the support arm 5 is provided on the upper surface (hereinafter referred to as slab) of the water channel 2 in the vicinity of the drain outlet 2a. As will be described later, the support arm 5 is curved and shaped so that the balance weight 7 does not interfere when the door 3 closes the drain port 2a. And the axis | shaft 4 provided in the front-end | tip of the support arm is located above the drain port 2a, and is offset from the end surface of the drain port 2a to the outside water area side. The door body 3 is formed in a plate shape having a size and a shape that can close the drain port 2a of the water channel 2.

  In this embodiment, the connecting member 6 includes a first connecting member 6A and a second connecting member 6B. One end of the first connecting member 6 </ b> A is connected to the upper portion of the door body 3, and the other end is connected to the balance weight 7. One end of the second connecting member 6 </ b> B is supported by the shaft 4 of the support arm 5, and the other end is connected to the balance weight 7. The first connecting member 6A and the second connecting member 6B are connected to different portions with respect to the balance weight 7 so as to form a predetermined angle therebetween. The first connecting member 6A and the second connecting member 6B have a predetermined length according to the mutual angle, the mass of the door body 3 and the balance weight 7, the buoyancy generated by the balance weight 7, and the like. ing. At least the state in which the door body 3 is not pressed by the water discharged from the drain port 2a of the water channel 2 as shown in FIG. 1 (hereinafter, this state is referred to as a reference state), and the water channel 2 as shown in FIG. In the state where the water level in the outside water area rises higher than the drainage port 2a and the door 3 closes the drainage port 2a (hereinafter, this state is referred to as the closed state), the balance weight 7 is closer to the drainage port 2a side than the shaft 4 ( A balance weight 7 is provided at an intermediate portion of the connecting member 6 so as to be located on the inner water area side). By adjusting the position where the first connecting member 6A and the second connecting member 6B are connected to the balance weight 7 such as the length and the angle of each other, the swinging door body 3 and the balance weight 7 can be easily balanced. In addition, the moment by the balance weight 7 can be arbitrarily adjusted as will be described later so as to adjust the position (opening degree) of the door body 3 with respect to the drain port 2a in the reference state (FIG. 1).

  The balance weight 7 has a mass corresponding to the moment due to the mass of the door body 3 and the length of the connecting member 6, and a sealable space 7 a is formed inside thereof. In the space 7a, for example, air at atmospheric pressure or a foaming material is enclosed as a material capable of generating buoyancy in the balance weight 7 in water. Therefore, the balance weight 7 not only functions so as to be able to swing easily around the shaft 4 in balance with the mass of the door body 3, but also has a function of generating buoyancy in water. By appropriately adjusting the size of the space 7a, the buoyancy generated by the balance weight 7 in water can be easily adjusted. In addition, when air is enclosed in the space 7a of the balance weight 7, the balance weight 7 can be configured at low cost so as to generate buoyancy in water. Further, when the foam material is enclosed in the space 7a of the balance weight 7, even if the balance weight 7 is damaged and the space 7a is not sealed, the buoyancy is surely generated in water. Can do. However, the present invention is not limited to this embodiment, and any material other than air or foam material can be employed as long as it can generate buoyancy in the balance weight 7 in water.

  Further, the present invention is not limited to the above-described embodiment, and as shown in FIG. 3, the water channel 2 is not formed of a soot pipe, and a wall surface is formed around the drain port 2a. In this case, a support arm can be provided on the wall surface, and the second connecting member 6B can be supported by the shaft 4 at the tip of the support arm. In this case, in particular, even when the water channel 2 does not have a slab (see FIGS. 1 and 2) on the upper surface and the installation space is limited, the water gate 1 can be reliably installed.

  Further, the connecting member 6 is formed so as to be bent integrally without being divided into the first connecting member 6A and the second connecting member 6B, and one end thereof is connected to the upper portion of the door body 3, and the others. The end may be connected to the shaft 4 of the support arm 5 and a balance weight 7 may be provided at a predetermined position in the middle portion thereof.

  In the sluice 1 configured as described above, the shaft 4 provided at the tip of the support arm 5 is located above the drain port 2a and on the outer water area side of the end surface of the drain port 2a. The balance weight 7 provided in the intermediate part of the connecting member 6 connected to 4 is located on the drain outlet 2 a side with respect to the shaft 4. Therefore, as shown in FIG. 1 and FIG. 3, in the reference state where there is little water flowing through the water channel and the door body 3 is not pressed, the door body 3 slightly opens the drain port 2 a of the water channel 2 due to the weight of the balance weight 7. It is in a state. Therefore, a small amount of water flowing through the water channel 2 can flow out from the drain port 2a to the downstream outer water area, and dust contained in the flowing water is sandwiched between the door body 3 and the drain port 2a. There is nothing.

  When the amount of water flowing through the water channel 2 increases and the door body 3 is pressed, the door body 3 is further moved from the reference state by the water pressure of the flowing water without using power, and the door is further centered on the shaft 4. The body 3 rotates so as to open the drain port 2a of the water channel 2. At this time, the door body 3 can be easily rotated by the balance weight 7 according to the water pressure of the flowing water. If the amount of water flowing through the water channel 2 decreases and the door body 3 is not pressed by the water pressure, the door body 3 immediately returns to the reference position without using power.

  On the other hand, as shown in FIG. 2, the water level in the outer water area becomes higher than the water level in the inner water area or the water channel 2 (that is, the water level on the downstream side of the drainage port 2a becomes higher than the water level on the upstream side). When the weight 7 is submerged, the door 3 rotates immediately and reliably around the shaft 4 so that the drainage port 2a is closed by the buoyancy of the balance weight 7 provided in the intermediate portion of the connecting member 6 without using power. Thus, it is possible to reliably prevent the reverse flow from the downstream side of the drain port 2a to the upstream side.

  The present invention adjusts the position where the balance weight is provided with respect to the intermediate part of the connecting member, the size of the buoyancy generated by the balance weight, etc., according to the size and weight of the door body, the assumed flow rate of water, etc. be able to.

  1: Sluice, 2: Waterway, 2a: Drainage port, 3: Door body, 4: Shaft, 5: Support arm, 6: Connection member, 6A: First connection member, 6B: Second connection member, 7: Balance weight 7a: Space

Claims (5)

A door body is provided so as to be able to swing in a water channel that circulates water from an inner water area to an outer water area, and is a sluice that opens and closes a drain outlet of the water channel by swinging the door body,
A support arm provided at the top of the drain;
A connecting member, one end of which is rotatably supported by the support arm by a shaft and the other end of which is connected to the upper portion of the door body;
A balance weight provided at an intermediate portion of the connecting member,
The balance weight is composed of a material that generates buoyancy in water,
By providing the balance weight at the intermediate portion of the connecting member, the door body opens the drainage port without being pressed by the water discharged from the water channel, and is pressed by the water discharged from the water channel. Then, the door is further swung so as to open the drain, and further, the door body is swung so as to close the drain due to the buoyancy generated by the balance weight when the water level in the outer water area rises above the drain. A sluice that is moved.   The sluice according to claim 1, wherein a space is formed in the balance weight, and a substance capable of providing buoyancy is enclosed in the space.   The sluice according to claim 2, wherein the substance enclosed in the space is air at atmospheric pressure at normal temperature.   The sluice according to claim 2, wherein the substance enclosed in the space is a foam material. The connecting member is composed of a first connecting member and a second connecting member,
The first connecting member has one end connected to the upper part of the door body and the other end connected to the balance weight.
One end of the second connecting member is pivotally supported by the support arm, and the other end is connected to the balance weight.
The first connection member and the second connection member are connected to different locations with respect to the balance weight so as to form a predetermined angle between each other. The sluice according to item 1.