KR20190021651A - Water distribution apparatus using floating type bell siphon and rain water storage tube with the same - Google Patents

Abstract

The present invention relates to a non-powered flow distribution apparatus and a rainwater storage tube apparatus using a floating bell siphon that can actively control water storage and distribution such as rainwater, including a storage pipe (1010) for water body inflow and storage and a bell siphon (2200) provided with a partition wall (2301) disposed to vertically pass through the lower side of the storage pipe, an upper member (2220) covering the upper side of the partition wall, and a lower member (2210) raised and lowered along the outer surface of the partition wall. The bell siphon is lowered along with a decrease in water level while discharging the water body to the partition wall through an inlet port (2230) formed on the side surface in accordance with the rise of the water level in the storage pipe and ascends together with air inflow between the water surface and the inlet port so that the gap with the water surface can be widened in the non-powered flow distribution apparatus using a floating bell siphon.

Description

TECHNICAL FIELD [0001] The present invention relates to a non-dynamic water distribution apparatus using an invisible bell siphon, and a rainwater storage system having the same. [0002]

The present invention relates to an apparatus for controlling water level and distribution, and more particularly, to a non-powered water distribution apparatus and a rainwater storage system that can actively control reservoirs such as rainwater and distribution thereof.

Annual precipitation of Korea is 1.4 times higher than the world average 973㎜ to 1,274㎜ high population density per capita annual precipitation to 2,75m ^3, only 12% of the world's per capita annual precipitation. Therefore, in order to solve the water shortage, it is necessary to develop a system to improve the water deficit. However, due to the desert water management system that focuses on the rapid drainage of rainwater, And the flooding of the rivers caused by the flooding of the rivers has caused enormous damage to the crops.

In particular, Korea is one of the most difficult countries to manage water due to the disaster that causes floods and droughts at the same time, and there are not enough facilities to store rainwater in summer and to utilize the rainwater through reduction of runoff through reservoir facilities It is true.

Therefore, recently, in order to minimize damages caused by stormwater, stormwater is not drained to the ground but stormwater is filtered, and the stormwater and floodwater are filtered, and the stormwater is stored in a reservoir having a constant volume. And a variety of technical means have been developed.

Korean Patent Laid-Open Publication No. 10-2009-0039342 discloses a rainwater storage tank of the prior art, and Fig. 1 is a configuration diagram thereof.

Specifically, the rainwater storage tank 100 collects rainwater, purifies / stores the rainwater, and then uses the stored rainwater as needed. When the user uses the stored rainwater, the rainwater storage tank 100 is installed in the rainwater storage tank 100 The driving motor 110 can be driven or discharged under a natural flow to the outside.

The rainwater storage tank 100 has a closed storage space. The capacity of the storage space is limited. When excess rainwater is introduced, the rainwater having a storage capacity or more is stored in the rainwater storage tank 100 So that it can be discharged to nature.

However, since such prior art storage tanks are required to be installed in the ground or on the ground, they are not only limited in terms of spatial problems and volume, but also require external power sources to be used in driving motors for vegetation purposes. It is also uneconomical in terms of maintenance.

On the other hand, a siphon tube is used as a device for controlling the water level in constructing such a rainwater storage tank, and the overflow is controlled using the principle of the siphon tube even in the above-mentioned prior art.

The U-shaped overflow device 120 is connected to the overflow port of the rainwater storage tank 100. The U-shaped overflow device 120 includes a overflow discharge port 123 inserted into the overflow port, The inlet 121 is positioned.

Thus, the water level is controlled by the water head difference in the state where the predetermined fluid is stored, but the efficiency is low because it controls the overflow simply.

In recent years, there has been an attempt to efficiently manage the distribution of such reservoirs, as well as simple storage of reservoirs such as storm surplus. For this purpose, there is an increasing number of cases where a storage tube such as a predetermined valve is provided in a storage tube and used for growing plants or animals.

However, even in such a case, there is a problem of non-economy in that a control panel and a control system for operating the valve must be provided.

Also, as in the above-mentioned conventional storage tank, there has been developed a technique for managing the level of the stored fluid by using the principle of the siphon tube and appropriately distributing it to a plurality of locations, but there is also a limit to the even distribution of the water flow It is difficult to maintain the pressure difference between the siphon tube and the siphon tube.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a floating type air conditioner capable of constantly maintaining performance by actively controlling the flow of air and fluid, And it is an object of the present invention to provide a non-powered hydraulic distribution apparatus using a siphon.

In addition, the present invention can store stormwater or runoff in a pipeline without having a separate storeroom, thereby minimizing the cost and effort required for the facility, and can provide a rainwater storage system that can be operated without power consumption for supplying water The purpose is to provide.

The present invention is characterized by comprising a storage tube (1010) through which a water body is introduced and stored, a partition wall (2301) arranged so as to pass through the lower side of the storage tube, an upper member (2220) covering the upper side of the partition wall, And a bell siphon 2200 having a lower member 2210 raised and lowered along an outer surface thereof. The bell siphon discharges the water body to the partition wall through an inlet port 2230 formed on the side surface in accordance with an increase in the water level in the storage tube The present invention provides a non-powered water distribution apparatus using an invisible bell siphon which is lowered together with a descent of a water level and is raised as air flows in between a water surface and an inlet to widen the gap with the water surface. Therefore, operation reliability can be improved by operating environmentally without an external power source, while ensuring air-containing performance.

Preferably, the partition portion includes a stopper portion 2320 protruding circumferentially to limit the elevation height of the bell siphon.

Further, it may further include a trap portion 2410 connected to the partition wall portion from the lower side of the storage tube to discharge the water body, and a discharge portion 2420 for bypassing the trap portion to discharge air.

The trap unit may further include a distribution unit 2440 connected to the trap unit and storing a water body supplied from the storage pipe. The trap unit may include a trap part having one end connected to the partition wall part and the other end connected to the distribution part, The height of the bottom portion is lower than that of the partition wall portion and the distribution portion, and the water body can be stored therein.

The water head difference due to the water level inside the storage tube and the water level due to the air charged in the bell siphon may correspond to the water head difference due to the difference between the water level on one side and the water level on the other side with the bottom part of the trap part therebetween.

Preferably, the distributing unit includes a gas discharging unit 2422 for discharging the inside of the storage tube, the discharging unit, the trap unit, and the inside of the distributing unit to the outside.

And one or more branch lines (2450) connected to the lower side of the distribution unit to supply the water bodies to the respective locations.

And a non-dynamic flow distribution device using the floating bell-siphon. The storage device includes an inflow section (1001) disposed above the storage tube and introducing rainwater, an initial stormwater is stored from the inflow section, filtered and supplied to a storage tube A storage reservoir 1030 for storing water bodies branched from the reservoir tube, and a vegetation part 3000 disposed in the soil disposed in the space between the storage reservoir tube to provide.

According to the present invention, since the water level can be automatically adjusted by adjusting the amount of air and the water body without providing an external power source, and the water body can be effectively distributed during the rainfall, it is economical and it is possible to supply water constantly even in an environment such as irregular rainfall or dry season There is an advantage that irrigation can be performed without being environmentally friendly, but energy can be saved.

In addition, it is possible to overcome the limitations of the water supply system using the siphon principle of the prior art, so that the process of charging and discharging air into the siphon tube can be performed automatically and reliability of the operation can be ensured.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram showing a conventional rainwater storage tank. FIG.
2 is a front cross-sectional view illustrating a non-powered fluid distribution apparatus using an invisible bell siphon according to the present invention.
FIGS. 3A to 3B are views for explaining the operation of a non-powered fluid distribution apparatus using an inverse bell siphon according to the present invention.
4 is a front cross-sectional view for explaining a further embodiment of a non-powered fluid distribution apparatus using an invisible bell siphon of the present invention.
Fig. 5 is a view for explaining the operation of the non-powered fluid distribution apparatus using the floating bell siphon shown in Fig.
6 to 7 are views for explaining a modification of the non-powered fluid distribution apparatus using the invisible bell siphon of the present invention.
FIG. 8 is a view showing a state in which a rainwater storage system to which a non-powered water distribution apparatus using an invisible bell siphon of the present invention is applied includes a vegetation part.

Hereinafter, a non-powered water distribution apparatus using an invisible bell siphon according to the present invention and a rainwater storage system having the same will be described in detail with reference to the accompanying drawings.

It is to be understood, however, that the embodiments described below are only for explanation of the embodiments of the present invention so that those skilled in the art can easily carry out the invention, It does not mean anything.

In the following description, when a part is referred to as being 'connected' to another part, it includes not only a direct connection but also a case where another part or device is connected in between. In addition, when a part is referred to as including an element, it is to be understood that the element may include other elements, not the exclusion of any other element, unless specifically stated otherwise.

In the concept of the present invention, in order to maintain the performance of the siphon tube so that the water level of the stored water body and the amount of the discharged water body can be controlled at the time of discharging the water body such as rainwater stored in the storage tube or the water tank, By applying a siphon, a non-powered flow distribution device is constructed.

In the present invention, as described later, the distribution function of dividing the water stored in the storage tube into the respective parts is explained. However, in the case of adjusting the water level in a single storage tube in the distribution device, It should be noted that this concept is included in the concept of

The distribution apparatus described in the present invention functions to regulate the water level of a water body such as storm, which is attached to a wall surface or stored in a reservoir-like reservoir tube constituting a predetermined wall surface. It is not.

2 is a front cross-sectional view illustrating a non-powered fluid distribution apparatus using an invisible bell siphon according to the present invention.

The reservoir tube 1010 may be connected horizontally with respect to a substantially horizontal plane and may be connected by a non-powered hydrodistribution device using an additional bell siphon and at least one other reservoir as described below. At this time, the storage tubes may be arranged in parallel to each other on the upper and lower sides and function to store storms in an inner space as shown in the figure. Therefore, as described later, in the construction of the wall watering apparatus, the stormwater can be stored inside the channel without a separate storage space, thereby improving the management efficiency and spatial advantage.

The distribution device is coupled to the storage tube 1010 to control the water level of the storage tube 1010 and to control the amount of the water body discharged downward. Specifically, a predetermined opening penetrating in the up and down direction is formed on the lower side of the storage tube 1010, and a partition wall portion 2301 of a straight tube shape is coupled by the fastening member 2300.

The partition wall 2301 has a hollow cylindrical shape and is protruded upward from the bottom surface of the storage tube 1010. The bell siphon 2000 is coupled from the upper end thereof to the siphon 2000, So that the function can be maintained while inducing the phenomenon.

The bell siphon 2200 includes a vertical member 2220 arranged to cover the upper end of the partition 2301 and an inlet 2230 formed at a lower side of the upper member 2220, The lower member 2210 is disposed so as to be floatable.

The position of the bell siphon 2200 is changed with respect to the partition 2301 so that the function of the water discharge using the siphon principle is enabled. The bell siphon is disposed at a position fixed to the partition 2301 in the height direction You can also consider the case. Bell siphon refers to a device that has a bell-shaped lid installed on a predetermined vertical upper part of the vessel and is discharged by water pressure when the vessel reaches a certain level. However, when the prior art bell siphon is simply applied, air may not sufficiently flow into the siphon tube after the discharge due to the first siphon phenomenon. The water film is formed due to water tension at the water surface and the lower end of the lid It is confirmed that there is a problem of blocking air inflow. Particularly, when the water content is precisely controlled and the partition wall 2301 having a relatively small diameter is used, this phenomenon is further exacerbated, and the water level control function due to the siphon phenomenon is lost.

In order to solve this problem, in order to solve such a problem, the position of the bell siphon 2200 with respect to the partition wall 2301 is changed according to the water level, thereby ensuring the function of introducing air into the partition wall as the water level becomes lower after the water is discharged So that a smooth exhaust performance can be continuously ensured. The discharge of the water body due to the upward and downward movement of the bell siphon 2200 and the inflow of air will be described later.

When the bell siphon 2200 moves up and down, the outer surface of the partition wall 2301 functions to guide the bell siphon 2200. When the bell siphon 2200 descends, a lower position is determined on the lower side of the fastening member 2300 or the partition wall 2301 A stopper portion 2320 may be provided on the upper portion of the partition wall 2301 so as to restrict a height at which the upper end of the lower member 2210 is hooked. However, it is needless to say that the seat portion 2310 may be replaced by the inner wall of the storage tube 1010 according to circumstances. The stopper portion 2320 may have a ring shape protruding in the outer circumferential direction of the partition wall 2301.

The trap unit 2410 may be provided at a lower side of the coupling member 2300 to communicate with the partition 2301 to discharge the water body. But it is preferable that it is formed in the U-shape in order to secure the control function of the water level. A detailed description related to this will be given later.

The discharge portion 2420 may further include a discharge portion 2420 to bypass the trap portion 2410. The discharge portion 2420 may communicate with the gas discharge port of the distribution portion 2440 So that the air can be discharged.

In the structure of the storage pipe 1010 and the distribution apparatus of this type, when the water level such as rainwater flows into the storage pipe 1010 side and the water level rises, the water is discharged to the trap portion 2410 side through the operation of the bell siphon 2200 This operation will be described below.

FIGS. 3A and 3B are views for explaining the operation of the non-powered fluid distribution apparatus using the invisible bell siphon according to the present invention. 3A is a view for explaining a change in the air pressure due to the inflow of stormwater into the storage pipe 1010 and an increase in the internal water level. FIG. 3B is a view for explaining the change of the air pressure in the bell siphon 2200) and the process of recovering the amount of air.

3A, when the lowest level is formed inside the storage tube 1010, the lower member 2210, which is the lower side of the bell siphon 2200, floats according to the water level, and the stopper 2320 Thereby maintaining the engagement state. The inlet 2230 is open and air is secured inside the bell siphon 2200 and inside the partition 2301. [ At this time, the trap portion 2410 is formed in the shape of 'U' or 'J' so that a predetermined water level is secured inside.

As shown in FIG. 3A, when the water level rises due to the inflow of rainwater, the internal pressure of the bell siphon 2200 is increased by the water pressure, which acts to lower the air inside the partition wall 2301. As a result, the water level is lowered from one side of the trap portion 2410 to push the water body to the other side, and the pressure is also elevated on the discharge portion 2420 side.

In FIG. 3A, the water level in the storage tube 1010 is close to the high water level, and water flows into the bell siphon 2200 to indicate that the overflow is started at the upper end of the partition 2301.

FIG. 3 (d) shows a state in which the water in the storage tube 1010 is discharged through the trap part 2410, starting with the change in the pressure inside the bell siphon 2200. At this time, it can be confirmed that the water bodies are discharged together in the trap portion 2410 and the discharge portion 2420. The discharged water body is temporarily stored in a distribution portion (2440 in FIG. 4) Line. ≪ / RTI >

FIG. 3 (e) shows a state in which the water level inside the storage tube 1010 is lowered in a state where the water body is filled in the bell siphon 2200. The bell siphon 2200 is lowered when the water level in the storage tube 1010 is lower than the upper side of the bell siphon 2200. The bell siphon 2200 is lowered. As described above.

The lowering state of the bell siphon 2200 may continue until the gas inside the storage tube 1010 flows into the bell siphon 2200 and more precisely until the water level corresponds to the inlet 2230 .

In (f) of FIG. 3B, the water level is gradually lowered with respect to the bell siphon 2200, and the air is introduced into the inlet 2230 side. As a result, air is introduced into the bell siphon 2200 and the partition wall 2301, and the bellows 2200 is lifted again. The rising of the bell siphon 2200 removes the water film formation due to the surface tension of the water, thereby promoting the inflow of air into the siphon tube and keeping the function of the siphon tube constant at all times.

4 is a front cross-sectional view for explaining a further embodiment of a non-powered fluid distribution apparatus using an invisible bell siphon of the present invention.

The above-described bell siphon functions as a kind of level control valve in the storage tube 1010, and in addition, the trap portion 2410 functions as a U-shaped discharge port of the water body.

The water level can be adjusted by the bell siphon 2200 disposed inside the storage tube 1010 and the distribution portion 2440 disposed adjacent to the storage tube 1010. [ A function of temporarily storing a water body discharged from the trap part 2410 is performed.

The distribution unit 2440 may be placed substantially horizontally with respect to the ground like the storage pipe 1010, but the arrangement relationship with the storage pipe 1010 is not necessarily limited to the illustrated state. However, the dispenser 2440 should be disposed at a lower position than the storage tube 1010 for controlling the head, but higher than the bottom 2430 of the trap.

Accordingly, the trap portion 2410 stores the air and the water body together to contain a certain amount of air with the bell siphon 2200. In the process of changing the amount of the gas, the water body is smoothly discharged Can be used. Specific operations related to this will be described later.

The discharging part 2420 can be formed in a part of the water body in the process of lowering the water level in the storage tube 1010. [ And transfers the air to the distribution unit 2440. The air distribution unit 2440 mainly performs the function of bypassing the inside air.

The distribution unit 2440 is connected to one or more branch lines 2450 connected to the downward direction and the branch lines 2450 deliver the water bodies stored in the storage tube 1010 to a desired location. A control valve 2460 may be provided at the connection between each branch line 2450 and the distribution portion 2440 to control the operation of the branch line 2450.

The gas discharge unit 2422 may be disposed above the distribution unit 2440 to discharge gas inside the distribution unit 2440. The arrangement of the gas discharge unit 2422 may be optional, It is efficient for the water level control to be disposed at a position far from the discharge portion 2420 of the water supply pipe 2440.

According to this concept, the distributor 2440 is also formed in a U-shape or a J-shape like the trap 2410 to contain some water in the reservoir 1010 desirable.

Fig. 5 is a view for explaining the operation of the non-powered fluid distribution apparatus using the floating bell siphon shown in Fig.

In the basic concept of the present invention, the discharge volume and the water level of the inflowing water body are controlled by providing the floating siphon siphon inside the storage tube 1010. According to a further concept, .

5 (a), the bell siphon 2200 maintains a predetermined water pressure in the storage tube 1010 so that the water level can be reduced to some extent. In the bell siphon 2200, The water head difference inside the storage tube 1010 is determined. That is, the water surface inside the storage tube 1010 and the internal water surface created by the air inside the bell siphon 2200 form a predetermined water head difference d1.

The trap portion 2410 is formed in a substantially U shape so as to store the water body on the trap portion bottom portion 2430. In order to form the water head difference corresponding to the water head difference of the storage tube 1010, And a predetermined height balance is formed on the other side. That is, the water head difference d2 is formed on one side from the one side and the other side on the side of the distributor 2440 before being discharged from the storage tube 1010, and the water head differences d1 and d2 correspond to each other. Note that the meaning of correspondence here is not only the same but also includes the case where the amount of water stored in the discharge portion 2420 or the amount of water or air in the distribution portion 2440 are different from each other.

When the water level in the trap portion 2410 becomes lower than the ceiling of the trap portion bottom portion 2430, air is discharged and a siphon phenomenon occurs.

Referring to FIG. 5B, as the water level rises in the storage tube 1010, a force is generated to push air into the bell siphon 2200 toward the trap portion 2410, The water level of one side of the portion 2410 is lowered, and the internal water body is pushed to the other side, that is, toward the distribution portion 2440. The air is also pushed to the distribution portion 2440 side by the movement process by the pressure of the gas.

When the water body is entirely pushed out of the distribution portion 2440, the air discharge can be performed by the discharge portion 2420.

The discharge portion 2420 may be connected to the distribution portion 2440 by a bypass line 2421. The difference between the diameter of the trap portion 2410 and the diameter of the bypass line 2421 is a function of the siphon tube It can have a significant impact. In view of discharging the water body, it is advantageous that the diameter of the trap portion 2410 is large. However, in the process of discharging the water body including air, a space can be formed between the ceiling and the water surface in the trap portion bottom portion 2430, Air may be introduced into the space and the function of the siphon tube may be lost. The bypass line 2421 bypasses the air and circulates the air so that the discharge ability of the water body can be maintained at all times. Therefore, it is preferable that the diameter of the bypass line 2421 is smaller than the diameter of the trap portion 2420, at least the trap bottom portion 2430.

5C shows a state in which a water body flows from the storage pipe 1010 to the partition part 2301 and flows into the trap part 2410 and continuously flows to the distribution part 2440 and flows through the branch line 2450 So that the water body can be distributed to a desired position. At this time, the control of each branch line 2450 can be performed by the individual control valve 2460 as described above.

The air contained in the distribution portion 2440 and the air stored in the bell siphon 2200, the discharge portion 2420, and / or the trap portion 2410 may be discharged to the gas discharge portion 2422.

In the process of raising the bell siphon (2200) in the storage pipe (1010) and lowering the bell siphon (2200) and then rising again according to the inflow of air, air is again contained in the inside of the bell siphon (2200) The water head difference d1 of the storage pipe and the water head difference d2 of the trap portion 2410 are balanced again.

Duplicate descriptions regarding the operation of the bell siphon 2200 will be omitted.

6 to 7 are views for explaining a modification of the non-powered fluid distribution apparatus using the invisible bell siphon of the present invention.

In a further embodiment of the present invention, the distribution portion 2440 is positioned eccentrically to the other side of the partition 2301. However, in the case of distributing the water body to more places, if the water body is elongated only to the other side, there is a problem in the balanced distribution of the water body, and in such a case, it is possible to distribute the water around the side where the Bell Siphon It may be appropriate.

Therefore, the connection member (not shown) of the distribution unit 2440 connecting the other end of the trap unit 2410 is connected to the distribution unit 2440 on both sides, and the water body introduced by the siphon principle is connected to the distribution unit (2440). At this time, the gas discharging portion 2422 may be provided on either selected side or both sides of both sides.

Further, in the case where the distribution portion 2440 is relatively long and the branch line 2450 is large, an air discharge port 2433 may be additionally formed in each branch line 2450 or any selected portion thereof in consideration of the efficiency of air discharge have.

Meanwhile, in consideration of assembly and maintenance, the trap portion 2410 may be formed as a separate channel so as to be fastened at both sides.

FIG. 8 is a view showing a state in which a storage pipe to which a non-powered water distribution apparatus using an auxiliary bell siphon of the present invention is applied includes a vegetation part.

The rainwater storage system according to the present invention may include an inlet portion 1001 through which water flows from above, and a storage tube 1010 below the inlet portion 1001. The storage tube 1010 for storing and discharging the water body from the inlet portion 1001 may be directly connected to each other, but an initial excellent storage tube 1020 may be interposed therebetween in consideration of initial buffering and filtering of the stormwater, The initial best stor- age tube 1020 may have a backflow filter 1011 therein.

The reservoir tube 1010 is coupled to a dispensing device having a bell siphon 2200 and a trap portion 2410 as described above and a branch line 2450 branched therefrom is connected to each of the distribution storage tubes 1030 .

The rainwater storage system or water storage system will be mainly described as an example of a water storage system installed in a height direction on a wall on which a vegetation part is formed on one side, but the present invention is not limited thereto. It can be applied to a part where various water supply such as a wall is required. Hereinafter, the portion where the storage tube 1010 is disposed is defined as a wall. A vegetation part (3000) is disposed on at least one surface of the wall, and water necessary for growing vegetation of the vegetation part can be supplied.

The rainwater storage pipe system of the present invention may be installed on one side of a wall as shown in the figure or may be installed in a manner that it is embedded in a wall and continuously or intermittently supplies water to the vegetation part 3000 disposed on the front side of the wall do.

The vegetation part 3000 may be formed in an extended form in the soil that can supply the fixed and stored moisture and nutrients of the root part of the plant. The soil is disposed in such a manner as to be filled between the respective distribution storage tubes 1030, and water is supplied by a bottom water supply core (not shown) communicating the inside of the soil with the inside of the distribution storage tube. For example, the bottom water pipe core may be formed extending along the horizontal direction of the soil in a space between the distribution storage tubes 1030, while a part of the bottom water pipe core is inserted into the distribution storage tube 1030 and extended outwardly.

The stormwater introduced into the upper storage pipe 1010 is discharged to the lower side while the water level is adjusted through the distribution device in order. The water body supplied to each of the distribution storage pipes 1030 is connected to the vegetation part 3000 ) Even when there is no rain on the soil.

The non-powered water distribution apparatus using the invisible bell siphon according to the above-described concept of the present invention can automatically adjust the water level by controlling the amount of air and the water body without providing an external power source and effectively distribute the water body during the rainfall, As well as irrigation or irrigation in the environment of the dry season without the supply of water can have the advantage of irrigation.

In addition, it is possible to overcome the limitations of the water supply system using the siphon principle of the prior art, so that the process of charging and discharging air into the siphon tube can be performed automatically and reliability of the operation can be ensured.

Therefore, there is an advantage that it is possible to save energy while being environmentally friendly.

In the foregoing, the present invention has been described in detail based on the embodiments and the accompanying drawings. However, the scope of the present invention is not limited by the above embodiments and drawings, and the scope of the present invention will be limited only by the content of the following claims.

1001 ... inlet 1010 ... storage tube
1011 ... Reverse flow filter 1020 ... Early superior storage tube
1030 ... Distribution storage tube 2000 ... Bell siphon
2210 ... lower member 2220 ... upper member
2230 ... inlet 2300 ... fastening member
2301 ... partition wall portion 2310 ... seat portion
2320 ... stopper portion 2410 ... trap portion
2420 ... discharge part 2421 ... bypass line
2422 ... gas discharge portion 2423 ... line discharge portion
2430 ... trap bottom part 2440 ... distribution part
2450 ... branch line 2460 ... control valve
3000 ... Vegetation Department

Claims (8)

A storage tube 1010 through which a water body is introduced and stored;
A partition wall portion 2301 arranged to pass through the lower side of the storage tube vertically; And
And a bell siphon (2200) having an upper member (2220) configured to cover the upper side of the partition wall portion and a lower member (2210) raised and lowered along an outer surface of the partition wall portion,
The bell-
As the water level inside the storage tube rises, the water body is discharged to the partition wall through the inlet port 2230 formed on the side surface, and the water level is lowered along with the lowering of the water level. The air is raised between the water surface and the inlet, A non-powered hydrodistribution device using an invisible bell siphon.
The method according to claim 1,
Wherein,
And a stopper portion (2320) projecting outwardly to limit the raised height of the bell siphon.
The method according to claim 1,
A trap portion 2410 connected to the partition wall portion from the lower side of the storage tube to discharge the water body; And
And a discharge portion (2420) for discharging air by bypassing the trap portion.
The method of claim 3,
And a distribution unit (2440) connected to the trap unit and storing a water body supplied from the storage pipe,
The trap portion
Wherein the height of the bottom part of the trap part, which is connected to the partition part at one end and is connected to the distribution part at the other end, is lower than the height of the partition part and the distribution part so as to store the water body therein.
5. The method of claim 4,
The water head difference due to the water level inside the storage tube and the air filled in the bell siphon is determined by the difference between the water level at one side and the water level difference at the other side with the bottom of the trap portion interposed therebetween, A non-powered hydrodistribution device used.
6. The method of claim 5,
Wherein the distributor comprises:
And a gas discharging portion (2422) for discharging the inside of the storage tube, the discharging portion, the trap portion, and the air inside the distributing portion to the outside.
The method according to claim 1,
And at least one branch line (2450) connected to the lower portion of the distribution unit to supply the water body to each point.
8. A retentive piping system comprising a non-powered flow distribution apparatus using an inverse bell siphin of any one of claims 1 to 7,
An inlet 1001 disposed above the storage tube for introducing the storm;
An initial superior stor- age tube (1020) for storing and filtering the initial storm from the inlet and supplying it to the stor- age tube;
A distribution storage tube 1030 for storing the water body branched from the storage tube;
And a vegetation part (3000) arranged in the soil disposed in the space between the distribution storage tubes.

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