JPH0437947Y2 - - Google Patents

Description

[Detailed description of the invention] [Field of industrial application] The present invention relates to a float type flap gate.
In particular, the present invention relates to a waterway opening/closing gate that automatically supplies water to a waterway, reservoir, or other water tank, and maintains a constant water level inside the water tank.

[Prior Art] Conventionally, automatic opening/closing flap gates installed in waterways have been known to swing due to the water level difference between the front and rear portions of the gate and the gate's own weight.
It opens and closes automatically.

However, in conventional flap gates,
When introducing water to the side that receives water supply such as a reservoir, that is, when opening the gate, a rotational moment due to the gate's own weight acts, creating a situation where the gate will not open unless there is a considerable water level difference. Therefore, the manager is usually responsible for opening the gate, and having to do such work is not only inconvenient for management, but also forces the manager to take extra effort. It had the disadvantage of being

Therefore, in order to eliminate the above-mentioned drawbacks, we installed a balance weight on the top of the flap gate to reduce the rotational moment due to the gate's own weight to a practical range. It is conceivable to use a flap type gate that can be opened and closed automatically depending on the difference in water level.

However, when configuring a flap gate in this way, it is extremely difficult to balance the balance weight and the gate's own weight.
Furthermore, there are many problems that need to be solved in the structure of the gate for automatic opening and closing, the structure of the balance weight, etc., depending on whether the gate is partially underwater or in other cases.

[Problem that the invention attempts to solve]

The present invention solves the drawbacks of the conventional automatic opening/closing flap type gate as described above.The float is integrally formed at the bottom of the gate, and when the gate closes the waterway, the buoyancy of the float is applied to the gate. To provide a float-type flap gate that can act in the closing direction to ensure the closing operation, and can automatically perform the opening operation when water pressure acts on the gate in the opening direction. It is an object.

[Means for solving problems]

The floating flap gate of the present invention is installed at the end of a waterway that connects a river or the like with a reservoir or the like where the water level needs to be maintained constant.

That is, it opens and closes the opening of the waterway, and is pivoted to a pivot part so as to maintain the gate vertically by its own weight, and automatically swings due to the difference in water level between the front and rear of the waterway. In the flap gate configured as above, a float is integrally formed at the lower part of the gate, a support arm is provided at the upper end of the gate, the support arm is bendably connected to the arm by a pivot, and the arm is further connected to the arm by a pivot. The upper end of the waterway is attached to a bracket that protrudes upward from the lower end of the waterway in the gate opening direction using a support shaft, and the gate is made to swing freely in the lowered state, so that the center of the buoyancy of the float is lower than the center of gravity of the gate. The structure is such that the gate is pushed against the end of the waterway by being shifted in the closing direction of the gate.

The float-type flap gate of the present invention can be swung in the direction of discharging water from a waterway, and when the opening of the waterway is closed,
The buoyant force caused by the float acts on the communication port of the waterway in the direction of pressing the gate, so that the closing operation can be performed reliably.
Furthermore, when the water level in one side of the reservoir, etc. drops, the float type flap gate of the present invention is automatically opened or closed by the water pressure from the other side, making these operations extremely easy. Moreover, it will be done automatically.

〔Example〕

The structure of the floating flap gate of the present invention will be explained according to the illustrated example. As shown in FIG.
The waterway 1 is provided at the end of the waterway 1 that connects the waterway B and the waterway B. The relationship between water world A and water world B is, for example, the relationship between a reservoir and a river, where the water level must be maintained constant, or the case where there is a large difference in water level between high tide and low tide. When the water level outside (water area B) is high as shown by water level c, the flap gate 10 is securely closed to prevent water from flowing back, and the water area B When the water level of water area A becomes lower than water level a, the flap gate 10 is opened to ensure drainage from water area A, and the water level of water area B becomes lower than water level b. When is slightly unbalanced with respect to the water level of water world A,
It is designed to ensure that the opening and closing operations are performed according to the state.

In the illustrated example, a buffer member 3 is formed as an outlet member at the end of a communication port 2 of a waterway 1 with a water world B, and a bracket 5 and a pivot shaft 6 are connected to the upper part of the buffer member 3. An arm 7 is provided on the arm 7, and a support arm 9 is further swingably provided on the arm 7 via a pivot 8, and a gate 10 is supported by the support arm 9 so as to be swingable in a hanging manner.

Further, in the lower part of the gate 10, a back plate is attached to the back side of the gate front plate, and a watertight hollow part is formed between the two members, and this hollow part allows the gate 10 to be
A float 11 is formed integrally with the gate, and the buoyancy of the float 11 acts against the gate's own weight to assist the swinging motion of the gate when closing and opening the gate 10. I'm starting to get it.

That is, the float 11 is integrally formed at the lower part of the gate 10, and the center F of the buoyancy of the float 11 is shifted in the gate closing direction from the center of gravity G of the gate 10 in the suspended state, and the gate 10 is connected to the communication opening of the waterway 1. It is configured to be pressed against the end portion 2 of 2.

Furthermore, the float 11 of the present invention has a gate 10
If the float is integrally formed by welding a steel plate to the back side of the float, depending on the structure of the float,
As a reinforcing member for the main body of the gate 10, it also serves to resist water pressure applied from the gate surface.

The flap gate of the present invention is stabilized by maintaining the gate in a vertical state by its own weight and positioning its center of gravity G on the vertical line of the pivot 8. 2 is left slightly open. And the float 11 installed at the bottom of the flap gate
is positioned closer to the waterway than its center of gravity, and its buoyancy pushes the flap gate 10 toward the communication port 2 of the waterway 1.

As shown in FIG. 2, when the cross section of the waterway is approximately square, the gate 10 of the present invention is constructed to match the shape and to be slightly larger than that. If the water channel has a circular cross section, the gate 10 will naturally also have a circular shape. In addition, a water leak prevention member made of watertight rubber 12 or the like is provided in the area around the gate 10 of the present invention, that is, in the area that contacts the buffer member 3 at the end of the water channel 1. When closed, water is prevented from flowing back from water area B to water area A.

The operating principle of the float type flap gate of the present invention constructed as described above will be explained with reference to FIGS. 3, 4, and 5. As shown in FIG. 3, the center of gravity G of the flap gate 10 is located at a position slightly shifted from the center F of buoyancy of the float 11.

In Figure 3, W _G : Self-weight of the gate, F _G : Buoyant force of the float, F _F : Displaced weight of the float, ₁ , ₂ , ₃ : Length of each moment arm, where ₁ is the center of gravity G of the gate 10 ₂ is the distance in the X-axis direction from the center of buoyancy F of the float 11, and ₃ is the Y distance between the center of rotation D of the gate 10 and the center of gravity G of the gate. Axial distance, water level difference between water area A and water area B under the above conditions
Considering the case of Dm, the center of gravity G of gate 10 is
When the center D of the pivot 8 is on the Y axis, a moment M _F =F _F・₂ due to the float 11 acts, and a buoyant force acts in the direction of pressing the gate 10 against the communication port 2 of the waterway 1. Therefore, the gate 10 will be automatically closed.

Next, when the gate 10 is completely closed,
As shown in FIG. 4, two opposing moments act around the rotation center D of the gate 10.

In other words, the moment in the positive direction due to the float 11 M _F = F _F・₂ The moment in the negative direction due to the weight of the gate 10 M _G = (W _G − F _G ) ₁ If the sum of these two moments is positive, the gate is Force is always applied in the closing direction.

That is, it is necessary to satisfy the condition M _F > M _G. Furthermore, if this relational expression is reversed, a moment acts in the direction of opening the gate, and the gate can be easily opened and closed due to a slight imbalance in water pressure.

From the above, if the water level difference between water world A and water world B is in the relationship of water world B > water world A, and
When a flow occurs from water field B to water field A, the water pressure P acts on the gate 10 as an external force, and as shown in Fig. 5, the flow acts as a dynamic water pressure P _d on the gate 10. 10 in the direction of closing. The dynamic water pressure P _d in this case is P _d =CA(V ² /2g)r.

In this case, the moment M _s acting in the direction of closing the gate 10 is M _s = P ₃ +F _F・₂ , and the moment M _p in the direction of opening the gate is (if the gate is on the vertical line of the center of rotation D) ) M _p = (W _G − F _G )・₁ = 0 ( ₁ = 0); that is,
Since the center of gravity G of the gate 10 coincides with the vertical line of the center of rotation D, no force acts in the opening direction opposite to the water pressure of the gate 10, and only the pushing action by the float 11 toward the water channel 1 side is applied. I will be working. In the case of the above-described embodiment of the present invention, the gate 10 can be stably fixed when the angle θ between the gate and the vertical line of the rotation center D of the gate 10 is 7°. found.

Therefore, the mounting angle of the buffer member 3 provided at the end of the communication port 2 of the waterway 1 of the present invention is set to 7° corresponding to the above-mentioned inclination angle θ of the flap gate 10.
, the watertight rubber 12 of the flap gate 10 accurately contacts the buffer member 3, and water leakage from the contact portion can be prevented.

As described above, in the flap gate of the present invention, when the water level on the water field B side is high, it is possible to reliably prevent water in the channel from flowing backward.

Further, in the embodiment of the present invention described above, the float 11 is provided in the lower half of the inner surface of the flap gate 10;
The shape of the flap gate 10 can be set arbitrarily, but its size needs to correspond to the weight of the flap gate 10. Further, the link mechanism for swingably supporting the flap gate 10 of the present invention is not limited to the configuration of the above-described embodiments, and it is of course possible to apply other conventionally known support mechanisms. It is possible.

[Effect of idea]

Since the float type flap gate of the present invention has the above-mentioned configuration, once it is installed, there is no need to make any adjustments at all, and the gate can be opened and closed automatically. Since this is carried out accurately using a small difference in water pressure, there is no need for human labor.

In addition, the gate closes at a lower backflow water level, making it possible to prevent backflow extremely sensitively.The timing of pressing the gate against the edge of the waterway opening is also good, making it easier to come into close contact with the waterway opening, making the opening and closing operation of the gate smoother. useful for.

In addition, in the float-type flap gate of the present invention, the float integrally formed on the back side of the gate also serves as a reinforcing member for the gate, making it possible to construct the iron plate of the gate body with a thin material. , thereby making it possible to reduce the weight of the gate.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing the structure of the float type flap gate of the present invention, FIG. 2 is a front view thereof, and FIGS. 3 to 5 are explanatory views showing the operating principle of the gate of the present invention. 1... Waterway, 2... Communication port, 3... Buffer member,
5...Bracket, 6...Pivot shaft, 7...Arm, 8...Pivot part, 9...Support arm, 10...
Flap gate, 11...Float, 12...Watertight rubber.

Claims (1)

[Scope of utility model registration request] In addition to opening and closing the opening 2 of the waterway 1, the gate 1
The gate 10 is pivotally connected to the pivot part 6 so as to maintain the gate 10 in a vertical state by its own weight of 0, and is configured to automatically swing due to the water level difference between the front and rear of the water channel 1. In this flap gate, a float 11 is integrally formed at the lower part of the gate 10, a support arm 9 is provided at the upper end of the gate, the support arm is bendably connected to the arm 7 by a pivot 8, and the arm 7 is The center of the buoyancy of the float 11 is attached to the bracket 5, which is protruded upright from the waterway end with the waterway end protruding in the gate opening direction from the waterway lower end, by means of a pivot shaft 6, so that the gate 1 can be freely swung in a suspended state. is shifted from the center of gravity of the gate 10 in the gate closing direction, and the gate 10
A float-type blup gate characterized by having a configuration in which the is pressed against the end of the waterway.