KR100728614B1 - Siphon spillway - Google Patents

Abstract

A siphon spillway is provided to discharge the water stored in a water tank of a dam or a reservoir to the lower reaches smoothly by preventing vortex phenomenon using a vortex prevention unit, controlling the flow of water effectively using an air regulator and maximizing the discharge of water using a water head regulating pipe. The invention relates to a siphon spillway for discharging the water stored in a water tank(1) of a dam or a reservoir to the lower reaches(3), which includes an inflow pipe(10) installed to the water tank to make the water stored in the water tank flow in, an inlet pipe(11) connected to the front of the inflow pipe and provided with a vortex prevention unit(12) to prevent vortex phenomenon while the water stored in the water tank flows in the inflow pipe, an inclined pipe(14) connected to the rear end of the inflow pipe and installed upward along the inside of a barrier(2) formed on the edge of the water tank to convey the water of the water tank flew in the inflow pipe, an air regulator(30) fixed longitudinally on the inclined pipe and a connecting pipe to inhale the air or to exhaust the air remaining in the inclined pipe to regulate the flow of water according to the water level of the water tank, a connecting pipe(20) fixed with the air regulator and connected to an inclined pipe by a primary extension pipe(16) and a downstream inclined pipe(21) by a secondary extension pipe(17) to be installed on the top of the barrier, a water level regulating pipe(22) connected to the downstream inclined pipe by a third extension pipe(18) and installed at the appointed angle to regulate the discharge of water according to the water level of the water tank, and a water head regulating pipe(23) connected to the water level regulating pipe by a fourth extension pipe(19) to discharge the water stored in the water tank to the lower reaches.

Description

Siphon Yeosu-ro {siphon spillway}

1 is an installation state diagram showing an embodiment of the present invention.

Figure 2 is an enlarged view showing that the inlet pipe formed with the vortex breakdown portion at the tip of the present invention communicated.

Figure 3 is a partially enlarged cross-sectional view showing that the air controller for controlling the flow of water through the intake of air at the top of the present invention.

Figure 4 is an installation state diagram showing another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

1-reservoir 2-inlet pipe

3-downstream 10-inlet pipe

11-Entrance Hall 12-Vortex Release

14-Inclined pipe 15-Air inlet

16, 17, 18, 19-Extension 20-Connector

21-Downhill Sergeant 22-Water Level Control

23-Head Control Tube A-Threshold

B-Proper Level C-Level Control Angle

The present invention relates to a siphon channel, and more particularly, to invent water stored in a dam, a reservoir, or the like rapidly downstream.

In general, if the water flows into the dam or reservoir, or more than the appropriate water level is installed in order to exclude it downstream.

Most of the dams and reservoirs that are installed to facilitate water supply are formed in flat and gentle places, and the water flowing through them is generally moving at a slow speed.

If more water flows into a dam or reservoir where water moves at a slower rate than the pre-designed and planned water inflow, and the water level rises rapidly, the water flow will not be processed quickly and will be delayed so that the water level will quickly reach the critical level. do.

If the water level exceeds the limit level, which is a safe water storage level, the water overflows to the dams or reservoirs, resulting in the loss of facilities and permits or crops.

In order to solve this problem, the yeast channel to be installed is mainly used by installing the siphon channel.

In other words, if the water level reached the critical level by installing a siphon channel in the dam or reservoir, the siphon was opened to exclude the stored water downstream to control the limit level.

However, in the conventional Yeosu channel, there is a problem that the stored water is not smoothly removed downstream by simply installing the siphon in the dam or the reservoir.

This is due to the vortex of the water, because water distributed in a wide area such as a dam or a reservoir flows in a swirl before entering a relatively narrow siphon inlet.

Therefore, the water flow is not made smoothly by the vortex of the water, there is a problem that the conventional Yeosu can not properly perform its function.

In addition, in the case of Yeosu-ro using a siphon, the outlet should be lowered than the inlet of the siphon to induce the exclusion of water due to the water head difference. However, in the case of the conventional Yeosu-ro, the difference is insignificant. There was a problem that was very difficult.

Therefore, the present invention solves the above problems and eliminates the vortex that may occur in the process of removing the water stored in the reservoir, such as dams or reservoirs downstream, and induces the easy exclusion of water by the water head car. Its purpose is to help.

An object of the present invention is to provide a siphon channel to solve the vortex of the water to smoothly enter the water stored in the reservoir into the inlet of the waterway, and to maximize the exclusion of water using the water head difference.

SUMMARY OF THE INVENTION An object of the present invention is to provide a siphon filtration channel capable of quickly adjusting the threshold level of water stored in a low casting to an appropriate level.

The present invention for achieving the above object and the inlet pipe installed in the reservoir;

An inlet pipe communicating with the tip of the inlet pipe and having a vortex releasing portion for solving the vortex of water entering the inlet pipe;

An inclined tube installed on an inclined inner surface of the barrier in communication with a rear end of the inflow tube;

An air controller mounted on an upper portion of the inclined tube and controlling water flow according to the water level of the reservoir;

A connecting tube connected to the inclined tube through a first extension tube and installed on an upper surface of the barrier;

A downstream inclined tube installed on the inclined outer surface of the barrier in communication with the connecting tube through a second extension tube;

A level control pipe communicating with a rear end of the downstream inclined pipe through a third extension pipe and having a water level control angle to control the exclusion of water according to the water level of the reservoir;

It is achieved by consisting of a head control tube communicating with the water level control tube through the fourth extension tube to exclude water downstream.

Therefore, it is possible to smooth the inflow of water stored in the reservoir by eliminating the vortex phenomenon of the water through the vortex releasing portion formed in the inlet pipe, and efficiently control the flow of water by using the air intaked by the air controller. It is possible to maximize the exclusion of water through the water head difference by the pipe.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 shows an embodiment of the present invention as an installation state diagram, showing the overall configuration and installation state of the present invention for excluding the water stored in the reservoir downstream.

Figure 2 is a partially enlarged view showing that the inlet pipe formed with the vortex breakdown portion at the tip of the present invention, showing a state in which the inlet pipe with a plurality of absorption holes in the tip of the inlet pipe installed in the water reservoir in the vortex breakdown portion is in communication have.

Figure 3 is a partially enlarged cross-sectional view showing that the air controller for controlling the flow of water through the intake of air at the top of the present invention. It is shown that a valve tube having a plurality of intake holes drilled in an upper portion of a connection pipe in which an air inlet hole is drilled in communication with the air inlet hole.

Figure 4 shows another embodiment of the present invention a state in which the yeast channel is stacked.

That is, as shown in Figs. 1 to 3, the present invention is a configuration for quickly excluding water stored in a reservoir 1 such as a dam or a reservoir downstream.

To this end, the present invention is largely inlet pipe 10, inlet pipe 11, inclined pipe 14, air controller 30, connecting pipe 20, downstream inclined pipe 21, water level control pipe 22, The head control tube 23, and the extension tube (16) (17) (18) (19) connecting them to the basic features of the technical configuration.

The inlet pipe 10 is installed in the reservoir 1 serves to introduce the water stored in the reservoir (1).

Although the inlet pipe 10 is formed and provided in a circular shape, it is noted that the shape thereof may be changed according to the shape of the water storage tank 1 and the storage amount of water, construction convenience, and the like.

The inlet pipe 11 communicates with the tip of the inlet pipe 10 and serves to solve the swirling vortex phenomenon in the process of entering the inlet pipe 10 with water stored in the reservoir 1. On the outer circumferential surface of the inlet pipe 11, the vortex releasing portion 12 is formed.

There are various types of the vortex releasing portion 12, but in the embodiment of the present invention by forming a plurality of absorption holes 13 on the outer circumferential surface of the inlet pipe 11 at regular intervals to form the vortex phenomenon generated in the inflow process It is solved.

That is, the inlet pipe (a plurality of absorption holes 13 formed on the outer circumferential surface of the vortex phenomenon, which is a phenomenon in which water distributed in a large area of the reservoir 1 enters into a relatively narrow inflow pipe 10 and swirls and rotates) 11) is communicated to the tip of the inlet pipe 10 to be introduced into the water of the reservoir tank 1 together with the inlet pipe 10, thereby to be eliminated.

The inclined tube 14 installed upward along the inner surface of the barrier 2 formed at the edge of the reservoir 1 while being in communication with the rear end of the inlet tube 10 is a reservoir 1 introduced into the inlet tube 10. ) To transport water.

Here, even though the inclined tube 14 is installed along the inner surface of the barrier 2, the water flows into the inclined tube 14 when the water reaches the limit level A of the water in the reservoir tank. The siphon phenomenon using the energy conservation law of Bernoulli's equation causes the water in the reservoir 1 to flow downstream.

The inclined tube 14 may be molded into a single size and installed on the inclined inner surface of the barrier 2. However, the inclined tube 14 is connected to a plurality of inclined tubes 14 for the convenience of the movement and construction to the construction site. It is good to use, and in the present invention has been shown to use the three inclined tubes (14) in communication.

The air controller 30 is mounted over the upper portion of the inclined tube 14 and the connecting tube 20 having such a configuration to intake air in the air according to the water level of the reservoir 1 or the inside of the inclined tube 14. By controlling the flow of water by exhausting the air remaining in the.

That is, when the water stored in the reservoir 1 is excluded below the proper water level (B), the air controller 30 serves to block the flow of water by inhaling air in the atmosphere, and conversely, the proper water level ( When the water level is increased to the limit level (A) in B), the internal air of the inclined pipe is exhausted to induce the exclusion of water more actively.

To this end, in the present invention, as shown in FIG. 3 as an embodiment of the air controller 30, the air inlet 15 is drilled in the upper portion of the connecting pipe 20, the valve in the upper portion of the air inlet 15 The pipe 31 is mounted in communication, and the valve pipe 31 shows that a plurality of intake holes 32 for intake of air in the atmosphere to be supplied to the air inlet hole 15 are drilled.

Therefore, when the water stored in the reservoir 1 is lowered from the threshold level (A) to the proper level (B), the air intake hole 32, which is immersed in the water at the threshold level (A), is exposed to the outside to release the air in the atmosphere. It will intake.

The air taken in through the intake hole 32 is supplied to the air inlet hole 15 drilled in the upper portion of the connecting pipe 20 via the valve pipe 31, and the supplied air is inclined to the connecting pipe 20 and inclined. By forming the air pressure inside the tube 14 is to block the water so that no more flow.

On the contrary, when the water in the reservoir 1 rises from the proper water level B to the limit water level B, the air remaining in the inclined pipe 14 is exhausted to the air inlet 21 drilled through the connecting pipe 20. The exhausted air is finally exhausted into the atmosphere through the intake hole 32 formed in the valve tube 31, so that the water is more actively removed.

The connection pipe 20 to which the air controller 30 that performs this role is mounted is installed on the top surface of the barrier 2 in a state of being communicated through the first extension pipe 16 to the rear end of the inclined pipe 14.

In addition, the connecting pipe 20 is installed on the inclined outer surface of the barrier 2 in a state in which the downstream inclined pipe 21 communicates through the second extension pipe 17.

Here, the third and fourth extension pipes 18 and 19 to be described below, including the first and second extension pipes 16 and 17, are used to connect the channel, and the inclined barrier 2 due to the characteristics of the channel Due to being installed over and downstream (3), it is not possible to directly connect each pipe, it is to be indirectly connected using the first, second, third, fourth extension pipe (16) (17) (18) (19).

The water level control pipe 22 communicating with the downstream inclined pipe 21 through the third extension pipe 18 is installed with a water level control angle C to control the exclusion of water according to the water level of the reservoir 1.

That is, the water level control pipe 22 is installed to be inclined upward in the downstream direction so that the rear end has a water level control angle (C) to serve to control the exclusion of water according to the water level of the reservoir (1). .

That is, when the water flows along the inside of the water level control pipe 22 and is no longer excluded in the process of being excluded to the downstream 3, the water level control pipe 22 has a water level control angle C. The water which flowed by will remain.

This remaining water forms a kind of water pressure inside the water level control pipe 22 to prevent the water, which has been lowered from the limit water level (A) to the proper water level (B), from being attempted to be excluded downstream by the siphon phenomenon (3). The role of the control is to ensure that no more water is excluded.

Therefore, it is possible to prevent the lack of unexpected water and the like by controlling the water in the reservoir 1 to fall below the appropriate level (B) through the water level control pipe 22 of such a configuration.

The head control tube (23) communicates with the water level control tube (22) through the fourth extension tube (19) serves to finally remove the water stored in the reservoir (1) to the downstream (3).

The head control tube 23 is in communication with the water level control tube 22 to further extend the length of the present invention is to increase the amount of exclusion of water, the present invention is to communicate the head control tube 23 to the present channel. If the length is further extended, the exclusion amount of about 120% may be increased in comparison to the exclusion amount of water through the water level control tube 22 only.

The reason for the increase in the amount of exclusion is due to the head difference between the water level control pipe 22 and the head control pipe 23, and the head control pipe 23 is downwardly along the downstream 3, as shown in the drawing. As it is installed to be inclined at an angle between 10 ° to 45 °, the installation position of the head control tube 23 is relatively lower than the installation position of the water level control pipe 22 occurs, the head head difference occurs, The exclusion amount will increase.

Here, when the exclusion process of the water stored in the reservoir 1 through the present invention as described above in detail.

That is, when the inlet pipe 10 rises by the limit water level A from the proper water level B of the water storage tank 1 by the increase of the inflow volume, the inflow pipe 10 will introduce the water of the water storage tank 1.

The vortex phenomena generated in the inflow process is the vortex releasing portion 12 of the inlet pipe 11 communicated with the tip of the inlet pipe 10 simultaneously with the inlet pipe 10 and the water in the reservoir (1) at the same time It is eliminated by the water flowing smoothly into the inlet 10.

Water introduced into the inlet pipe 10 is slowly risen along the inside of the inclined pipe 14 by the siphon phenomenon using the energy conservation law of Bernoulli's equation and is transferred to the connecting pipe 20.

Residual air inside the inclined tube 14 during the transfer of this water is exhausted into the atmosphere through the intake hole 32 of the air controller 30 by the water gradually rising inside the inclined tube 14. As a result, the siphon phenomenon is promoted so that the water flow becomes more active.

On the contrary, when the water level of the reservoir 1 is lowered from the critical level (A) to the proper level (B) by the continuous exclusion of water, the air intake air 32 of the air controller 30 is exposed to the outside to intake air from the atmosphere. The air supplied to the inside of the inclined tube 14, the air supplied to the inside of the inclined tube 14 forms an air pressure in the inside of the inclined tube 14 to block the flow of water down to the appropriate water level (B) will be.

That is, the water flowing in the interior of the inclined tube 14 is to be flowed more smoothly or blocked by the air controller 30 that controls the flow of water using the air in the atmosphere as described above.

The water transferred to the connecting pipe 20 via the inclined pipe 14 drops rapidly through the downstream inclined pipe 21, and the water falling through the downstream inclined pipe 21 is the third extension pipe 18. ) Flows into the water level control pipe (22), and the water flowing along the inside of the water level control pipe (22) is transferred to the head control pipe (23) through the fourth extension pipe (19) and finally downstream. It is excluded by (3).

At this time, when the water flows through the inside of the waterway through the series of processes such that the water level of the reservoir 1 is lowered by the appropriate level B, the water is not flowed any more by the water pressure formed in the water level control tube 22. It is controlled to maintain the level of the reservoir (1).

On the other hand, the present invention that performs the role as described above, as shown in Figure 4, can be installed by stacking in multiple stages over the reservoir (1) and downstream (3), through which a large amount of water more quickly downstream (3 ) Can be excluded.

That is, the inlet pipe 10, the inclined tube 14, the first extension tube 16, the connecting tube 20, the second extension tube 17, the downstream inclined tube 21, which are in communication with each other to constitute the present invention. , The third extension pipe (18), the water level control pipe (22), the fourth extension pipe (19), the head control pipe (23) by stacking in multiple stages, the water reaching the limit level of the reservoir (1) to the downstream (3) It will be excluded quickly.

According to the configuration of the present invention as described above, the vortex phenomenon of the water is solved through the vortex releasing portion formed in the inlet pipe, the water stored in the reservoir can smoothly flow into the inlet pipe.

In addition, by inhaling air in the atmosphere through the air control unit or by evacuating the internal air of the inclined tube, it is possible to efficiently control the flow of water by the air pressure, and to maximize the exclusion of water by using the head difference by the head control tube. It becomes possible.

Therefore, when the water stored in the reservoir such as a dam or a reservoir reaches the limit level through the configuration of the present invention as described above, it is a very useful invention such that it can be quickly adjusted to the appropriate level.

Claims (4)

An inlet pipe 10 installed in the reservoir 1; An inlet pipe 11 communicating with a tip of the inlet pipe 10 and having a vortex releasing part 12 for solving a vortex phenomenon of water entering the inlet pipe 10; An inclined tube 14 installed on an inclined inner surface of the barrier 2 in a state in communication with a rear end of the inflow tube 10; An air controller (30) mounted on an upper portion of the inclined tube (14) to control the flow of water in accordance with the water level of the reservoir (1); A connecting tube 20 connected to the inclined tube 14 through a first extension tube 16 and installed on an upper surface of the barrier 2; A downstream inclined tube 21 installed on the inclined outer surface of the barrier 2 in a state in communication with the connecting tube 20 through the second extension tube 17; The water level control pipe 22 is communicated through the third extension pipe 18 to the rear end of the downstream inclined pipe 21 and installed with a water level control angle C to control the exclusion of water according to the water level of the reservoir 1. and; Said water level control pipe (22) is a siphon effluent, characterized in that the communication through the fourth extension pipe (19) consisting of a head control pipe (23) for excluding water to the downstream (3). The siphon drainage channel according to claim 1, wherein the vortex breaker (12) is a plurality of absorption holes (13) arranged at regular intervals on the outer circumferential surface of the inlet pipe (11). According to claim 1, The air controller 30 is the valve tube 31 is mounted in communication with the upper portion of the connection pipe 20 through which the air inlet hole 15 is drilled, the valve tube 31 to the air in the atmosphere The siphon filter channel, characterized in that a plurality of intake holes 32 for intake to supply air to the air inlet hole (15). delete

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