KR102103793B1 - 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 flowing water distribution device and a rainwater storage pipe device using a floating bell siphon that can actively control when storing and distributing running water, such as rain water, the storage pipe 1010 in which water bodies are introduced and stored. , Bell having a partition wall portion 2301 disposed to penetrate the lower side of the storage pipe up and down, and an upper member 2220 formed in a form to cover the upper side of the partition wall portion and a lower member 2210 that moves up and down along the outer surface of the partition wall portion Siphon 2200, the bell siphon discharges the water body through the inlet 2230 formed on the side as the water level rises inside the storage pipe to the partition wall, while descending together as the water level decreases, but the air between the water surface and the inlet Provides a non-powered running water distribution device using a floating bell siphon that rises as it flows in and widens the gap with the water surface.

Description

WATER DISTRIBUTION APPARATUS USING FLOATING TYPE BELL SIPHON AND RAIN WATER STORAGE TUBE WITH THE SAME}

The present invention relates to a control device for the level and distribution of running water, and more particularly, to a non-powered running water distribution device and a rainwater storage pipe device that can actively control the storage and distribution of running water such as rain water.

The average annual precipitation in Korea is 1,274 mm, 1.4 times higher than the world average of 973 mm, but the population density is high, and the annual precipitation per person is 2,75 m ³ , which is only 12% of the annual precipitation per person in the world. Therefore, in order to solve such water shortage, it is urgent to develop a nationwide water shortage improvement system, but due to the result of a so-called desert type water management system that focuses only on rapid drainage of rainwater, the drainage capacity decreases in the city center and flows backward from the drain. Due to the occurrence of large-scale flooding, and in rural areas, the enormous damage caused by flooding of rivers continues.

In particular, Korea is one of the most difficult countries to manage water due to the nature of disasters that suffer from floods and droughts every year, and there is not enough facilities to store rainwater that is concentrated in the summer and utilize the rainwater through reduction of spillage through storage facilities. It is true.

Therefore, recently, in order to minimize the damage caused by rainwater, it receives rainwater without draining it to the ground, filters sediment and floating matter, and stores the rainwater in a storage tank having a constant volume, so that it can be used for garden water and general semi-living water. Various technical means have been developed.

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

Looking at this in detail, the rainwater storage tank 100 collects rainwater and purifies / stores it, so that it can use the stored rainwater as needed, and when the user uses the stored rainwater, the rainwater storage tank 100 is provided in the rainwater storage tank 100. The driving motor 110 can be driven or discharged to the outside under natural flow to be used.

The rainwater storage tank 100 has a storage space enclosed therein, and the capacity of the storage space is limited so that when excessive rainwater flows, rainwater having a storage capacity higher than that of the rainwater storage tank is provided through a wall flow port formed on one side of the rainwater storage tank 100. It is allowed to be released naturally.

However, these prior art storage tanks need to be installed on the ground or on the ground, so they have not only spatial problems and limited volume, but also use external power sources in the driving motor when used for vegetation, etc. It is also uneconomical in maintenance.

On the other hand, in constructing such a rainwater storage tank, a siphon pipe may be used as a device for controlling the water level, and the prior art also controls the overflow using the principle of the siphon pipe.

Specifically, the overflow pipe coupled to the overflow port of the rainwater storage tank 100 is a U-shaped overflow device 120, into which the discharge water discharge unit 123 is inserted / combined, and the overflow water inside the rainwater storage tank 100. The inlet part 121 is positioned.

Thereby, the function of adjusting the water level by the head difference in a state in which a predetermined fluid is stored is performed. However, since it is merely controlling the current flow, its effectiveness is low.

In recent years, there has been an attempt to efficiently distribute and manage the flowing water such as stored rainwater from simple storage. To this end, the storage pipe is provided with a distribution means such as a predetermined valve, and the number of cases used to grow plants or animals is increasing.

However, even in this case, there is a problem of inefficiency in that a control panel and an operation system for operation of the valve must be provided.

In addition, like the storage tank of the prior art described above, a technique has been developed to manage the water level of the stored fluid using the principle of a siphon tube and to properly distribute it to a number of places, but there are limitations in the uniform distribution of water flow. It is difficult to maintain the head difference between the siphon pipe and the pressure inside, so it is difficult to apply.

The present invention has been devised to solve the above-mentioned problems, while maintaining the water level by storing a fluid such as rainwater, while actively controlling the flow of air and fluid, the floating bell to maintain performance at all times. An object of the present invention is to provide a non-powered running water distribution device using a siphon.

In addition, the present invention minimizes the consumption of cost and effort according to the facility by allowing rainwater or running water to be stored inside the pipeline without having a separate storage facility, and a rainwater storage pipe device that can be operated without power consumption for supply of water. It aims to provide.

In the present invention, the storage member (1010), the water body is introduced and stored, the upper side member (2220) and the partition wall portion formed in a form that covers the upper side of the partition wall portion (2301) and the partition wall portion disposed to penetrate the lower side of the storage pipe up and down. It includes a bell siphon 2200 having a lower member 2210 that elevates and descends along the outer surface, and the bell siphon discharges the water body to the partition wall through an inlet 2230 formed on the side surface as the water level rises inside the storage pipe. It provides a non-powered running water distribution device using a floating bell siphon that descends together as the water level falls, but rises as air flows between the water surface and the inlet to widen the gap with the water surface. Therefore, the operation reliability is improved by guaranteeing the air-containing performance while operating in an environmentally friendly manner without an external power source.

It is preferable that the partition wall portion has a stopper portion 2320 protruding outward to limit the height of the bell siphon.

In addition, a trap portion 2410 connected to the partition wall portion at the lower side of the storage pipe to discharge water bodies and a discharge portion 2420 to discharge air by bypassing the trap portion may be further provided.

In addition, it is further connected to the trap portion further comprises a distribution portion (2440) for storing the water supplied from the storage pipe, the trap portion is connected to the partition wall portion and the other end is connected to the distribution portion trap portion disposed on the lower side The height of the bottom portion is formed lower than the partition portion and the distribution portion to store the water body therein.

The head difference due to the water level inside the storage pipe and the air level filled in the bell siphon may correspond to a head difference due to a difference between the water level at one side and the water level at the other side.

It is preferable that the distribution part includes a gas discharge part 2422 that allows air inside the storage pipe, the discharge part, the trap part, and the air inside the distribution part to be discharged to the outside.

It may further include one or more branch lines 2450 connected to the lower portion of the distribution unit to supply water to each location.

A storage pipe apparatus including a non-powered running water distribution device using the floating bell siphon, which is disposed on the upper side of the storage pipe to flow in rainwater (1001), stores and filters initial rainwater from the inlet, and supplies it to the storage pipe Storage pipe apparatus including an initial excellent storage pipe (1020), a distribution storage pipe (1030) for storing water bodies branched from the storage pipe, and a vegetation unit (3000) disposed in the soil disposed in the space between the distribution storage pipes to provide.

According to the present invention, it is possible to automatically adjust the water level by controlling the amount of air and water without providing an external power source, and effectively distribute water bodies during rain, so it is economical as well as supplying constant water in an environment such as irregular rainfall or dry season. There is an advantage that irrigation is possible without, and it is eco-friendly and can save energy.

In addition, by overcoming the limitations of the water supply system using the siphon principle of the prior art, it is possible not only to automatically perform the process of filling and discharging the air inside the siphon pipe, but also to ensure the reliability of its operation.

1 is a configuration diagram showing a rainwater storage tank of the prior art.
Figure 2 is a front cross-sectional view for explaining a non-powered water flow distribution device using a floating bell siphon according to the present invention.
3A to 3B are views for explaining the operation of the non-powered running water distribution device using a floating bell siphon according to the present invention.
Figure 4 is a cross-sectional front view for explaining a further embodiment of the non-powered running water distribution device using the floating bell siphon of the present invention.
5 is a view for explaining the operation of the non-powered water flow distribution device using the floating bell siphon shown in FIG.
6 to 7 are diagrams for explaining a modification of the non-powered running water distribution device using the floating bell siphon of the present invention.
8 is a view showing a state in which the rainwater storage pipe device to which the non-powered running water distribution device using the floating bell siphon of the present invention is applied has a vegetation unit.

Hereinafter, a non-powered running water distribution device using the floating bell siphon according to the present invention and a rainwater storage pipe device having the same will be described in more detail with reference to the accompanying drawings.

However, the embodiments described below are only for explaining in detail that the person skilled in the art to which the present invention pertains can easily implement the invention, thereby limiting the protection scope of the present invention. Does not mean

In the following description, when a part is said to be 'connected' to another part, this includes not only the case of being directly connected, but also the case of connecting another element or device in between. Also, when a part is said to 'include' a certain component, this means that other components may be further included rather than excluding other components, unless otherwise stated.

In the concept of the present invention, in order to maintain the performance as a siphon pipe at all times so that the water level of the stored water body and the amount of water discharged can be regulated in discharging water bodies such as rainwater stored in a storage pipe or a water tank, basically. By applying a siphon, a non-powered running water distribution device is constructed.

In the present invention, a description will be given of providing a distribution function to classify the running water stored in the storage pipe into each location as will be described later. However, even when the water level is adjusted in a single storage pipe in the distribution device, water is distributed inside and outside the storage pipe. It should be noted that it is included in the concept.

The distribution device described in the present invention functions to control the water level of a water body, such as rainwater, which is attached to a wall surface or stored in a storage tube in the form of a conduit constituting a predetermined wall surface. It does not work.

Figure 2 is a front cross-sectional view for explaining a non-powered water flow distribution device using a floating bell siphon according to the present invention.

The storage pipe 1010 is disposed substantially horizontal to the horizontal surface and may be connected by one or more storage pipes and a non-powered flowing water distribution device using a floating bell siphon, as will be described later. At this time, the storage pipes may be arranged parallel to each other up and down and function to store rainwater in the interior space as shown. Due to this, as described below, in constructing the wall watering device, it is possible to store rainwater inside the pipeline itself without a separate storage space, thereby improving the management efficiency and spatial advantage of rainwater.

As in the basic concept of the present invention, the distribution device is coupled to the storage pipe 1010 to perform the function of adjusting the water level of the storage pipe 1010 and at the same time to control the amount of water discharged to the bottom. Looking at this in detail, a predetermined opening that penetrates in the vertical direction is formed on the lower side of the storage tube 1010 and the partition wall portion 2301 in the form of a vertical tube is coupled by the fastening member 2300.

The partition wall 2301 is formed of a hollow cylindrical shape and is disposed to protrude upward from the bottom surface of the storage pipe 1010, and the siphon 2000 is coupled from the upper side to the siphon due to the difference in the amount of air flowed and the water level. It helps to maintain its function while inducing the phenomenon.

The bell siphon 2200 is spaced apart from the upper side of the vertical member 2220 and the upper side member 2220 in the form of a bell arranged to cover the upper end of the partition wall 2301 while buoyancy while forming an inlet port 2230 on the lower side. The lower member 2210 is disposed and formed to be floated by.

The position of the partition wall portion 2301 is varied by the bell siphon 2200 to enable the function of discharging water using the siphon principle. The bell siphon is disposed at a fixed position in the height direction with respect to the partition wall portion 2301 You may also want to consider the case. The Bell Syphon refers to a device that is drained by water pressure when it reaches a certain level by installing a bell-shaped cover on the upper part of a predetermined vertical management. However, in the case of simply applying the bell siphon of the prior art, there may be a case in which sufficient air does not flow into the siphon tube after discharge due to the initial siphon phenomenon. Accordingly, it was confirmed that there is a problem of blocking air inflow. Particularly, when the amount of water needs to be precisely adjusted and the relatively small diameter partition wall portion 2301 is applied, this phenomenon is further exacerbated, and there is a problem that the function of water level control by the siphon phenomenon is lost.

In the present invention, in order to solve this problem, the position of the bell siphon 2200 with respect to the partition wall portion 2301 is varied according to the water level, thereby ensuring the function of introducing air into the partition wall part as the water level decreases after discharge of water. This is to ensure that smooth discharge performance is continuously guaranteed. Descriptions related to the discharge of the water body and the inflow of air by the vertical movement of the bell siphon 2200 will be described later.

During the vertical movement of the bell siphon 2200, the outer surface of the partition wall portion 2301 functions to guide it, and the lower position of the bell siphon 2200 is determined below the fastening member 2300 or the partition wall portion 2301. A seating portion 2310 to be provided is donated, and a stopper portion 2320 may be provided at an upper side of the partition portion 2301 to limit the height at which the upper end of the lower member 2210 is locked. However, it is needless to say that the seating portion 2310 may be replaced by an inner wall of the storage pipe 1010 in some cases. The stopper portion 2320 may be formed in a ring shape protruding in the upper outer circumferential direction of the partition portion 2301.

On the other hand, a lower portion of the fastening member 2300 may be provided with a trap portion 2410 through which the water body can be discharged by communicating with the partition wall portion 2301, which is a simple water passage connecting passage. Although it may function, it is preferable that it is formed in a 'U' shape in order to secure the control function of the water level. A detailed description in this regard will be described later.

In addition, an outlet portion 2420 may be additionally provided to bypass the trap portion 2410, and the outlet portion 2420 may communicate with a gas outlet in the distribution portion (2440 in FIG. 4) as described below. It can function to exhaust the air.

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

3A to 3B are diagrams for explaining the operation of the non-powered flowing water distribution device using the floating bell siphon according to the present invention. Specifically, FIG. 3A is for explaining a change in air pressure according to an increase in the internal water level due to the introduction of rainwater into the storage pipe 1010, and FIG. 3B is a bell siphon (in the process of discharging water to the trap portion 2410) 2200) and the process of restoring the amount of air.

As shown in (a) of FIG. 3A, when the lowest water level is formed inside the storage pipe 1010, the lower member 2210, which is the lower side of the bell siphon 2200, floats according to the water level and is attached to the stopper portion 2320. It will maintain the jammed state. Accordingly, the inlet 2230 is open, and air is secured inside the bell siphon 2200 and inside the partition 2230. At this time, the trap portion 2410 is formed in a 'U' or 'J' shape to secure a predetermined water level therein.

As shown in (a) of Figure 3a (b), when the water level rises with the inflow of rainwater, the internal pressure of the bell siphon 2200 increases by water pressure, which acts to lower the air inside the partition wall 2301. Accordingly, it can be seen that the water level is lowered at one side of the trap portion 2410 and the water body is pushed to the other side, while the pressure is also increased at the discharge portion 2420 side.

In FIG. 3A (c), the water level in the storage tube 1010 is close to the full water level, and water flows into the bell siphon 2200, indicating that the overflow is initiated to the top of the partition wall 2301.

FIG. 3B (d) shows a state in which the water flow inside the reservoir 1010 is discharged through the trap portion 2410 by starting the current flow according to the change in the pressure inside the bell siphon 2200. At this time, the trap portion 2410 and the discharge portion 2420 can confirm that the water bodies are discharged together, and the water bodies discharged in this way are temporarily stored in the distribution portion (2440 in FIG. 4) as described below, where necessary or a basin. It can be distributed over lines.

3B (e) shows a state in which the water level inside the storage pipe 1010 falls while the water body is full inside the bell siphon 2200. When the water level in the storage pipe 1010 is lower than the upper side of the bell siphon 2200, continuous discharge of water is made, the bell siphon 2200 descends. The seating portion 2310 descends the bell siphon 2200. It is as described above to determine the position.

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

In FIG. 3B (f), the water level is gradually lowered with respect to the bell siphon 2200, indicating a state in which air is introduced into the inlet 2230 side. Accordingly, the air enters the bell siphon 2200 and the partition wall 2301 and restores buoyancy, so that the bell siphon 2200 is raised again. The rise of the bell siphon 2200 removes water film formation due to the surface tension of the water, thereby promoting the inflow of air into the siphon tube and maintaining the function of the siphon tube at all times.

Figure 4 is a cross-sectional front view for explaining a further embodiment of the non-powered running water distribution device using the floating bell siphon of the present invention.

The above-described bell siphon functions as a kind of water level control valve in the storage pipe 1010, and in addition, the trap portion 2410 functions as an 'U' shape and functions as an outlet of the water body.

Specifically, the water level according to the inflow of rainwater can be controlled by the bell siphon 2200 disposed inside the storage pipe 1010, and the distribution portion 2440 disposed adjacent to the storage pipe 1010 In the function to temporarily store the water discharged from the trap portion 2410.

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

Accordingly, the trap portion 2410 stores air and water bodies together to contain a certain amount of air between the bell siphon 2200, and the water body is smoothly discharged using the siphon principle in the process of changing the amount of gas. You can function to do it. The specific operation related to this will be described later.

On the other hand, it is as described above that the discharge portion 2420 can be formed by bypassing the trap portion 2410, and the discharge portion 2420 is a part of the water body in the process of lowering the water level inside the storage pipe 1010. Bypass to deliver to the distribution unit (2440), it mainly performs a function of bypassing the air inside.

In addition, the distribution part 2440 is connected to one or more branch lines 2450 connected downward, and the branch lines 2450 perform a function of delivering water bodies stored in the storage pipe 1010 to a desired location. In order to control the operation of the branch line 2450, a control valve 2460 may be provided at a connection portion of each branch line 2450 and the distribution unit 2440.

In addition, the upper side of the distribution unit 2440 may be provided with a gas discharge unit 2422 capable of discharging the gas inside the distribution unit 2440, and the arrangement of the gas discharge unit 2422 is optional, but the distribution unit It is efficient to adjust the water body to be disposed at a position distant from the discharge portion 2420 of the 2440.

According to this concept, the distribution part 2440 also has a 'U' shape or a 'J' shape, like the trap portion 2410, so that the storage pipe 1010 contains some water therein while maintaining the water level. desirable.

5 is a view for explaining the operation of the non-powered water flow distribution device using the floating bell siphon shown in FIG.

In the basic concept of the present invention, by providing a floating bell siphon inside the storage pipe 1010, the discharge amount and the water level of the incoming water body are controlled. According to an additional concept, the trap portion 2410 of the lower part according to a constant head pressure. To make it work.

Referring specifically to (a) of FIG. 5, in the reservoir 1010, the bell siphon 2200 maintains a predetermined water pressure so that the water level can be filled to a certain extent, and is stored in the bell siphon 2200. The head difference inside the storage pipe 1010 is determined by the air to be used. That is, the water surface inside the reservoir 1010 and the inner water surface created by the air inside the bell siphon 2200 form a predetermined head difference d1.

In addition, the trap portion 2410 is formed in a substantially 'U' shape to store water bodies at the bottom of the trap portion 2430, and one side to form a head difference corresponding to the head difference of the storage pipe 1010. A predetermined height balance is formed on the other side. That is, until discharged from the storage pipe 1010, the head difference d2 is formed on one side and the other side of the distribution portion 2440, and the head differences d1 and d2 correspond to each other. Note that the meanings corresponding here are not only substantially the same, but also include cases in which they differ depending on the amount of water stored in the discharge portion 2420 or the amount of water or air in the distribution portion 2440.

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

Referring to (b) of FIG. 5, as the water level rises in the storage pipe 1010 as described above, a force that pushes air from inside the bell siphon 2200 toward the trap portion 2410 occurs, and accordingly the trap The water level on one side of the portion 2410 is lowered and the internal water body is pushed to the other side, that is, the distribution portion 2440 side. Air is also pushed from the discharge part 2420 side to the distribution part 2440 side by the moving process by the pressure of the gas.

When all the water bodies are pushed out in the distribution part 2440, the air discharge can function by the discharge part 2420.

The discharge part 2420 may be connected to the distribution part 2440 side by the bypass line 2421. The difference between the diameter of the trap part 2410 and the diameter of the bypass line 2421 depends on the function as a siphon tube. It can have a major impact. From the perspective of discharging the water body, it would be advantageous that the diameter of the trap portion 2410 is large, but in the process of discharging the water body containing air, a space between the ceiling and the water surface can be formed at the bottom of the trap portion 2430. As air enters the space, the function as a siphon tube may be lost. Accordingly, the bypass line 2421 is capable of constantly maintaining the discharge capacity of the water body by bypassing and circulating air. Therefore, the diameter of the bypass line 2421 is preferably smaller than the diameter of the trap portion 2420 and at least the bottom portion of the trap portion 2430.

FIG. 5 (c) shows a state in which the 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 the branch line 2450. Through this, the water body can be distributed to a desired location. At this time, the control of each branch line 2450 can be achieved by individual control valves 2460, as described above.

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

As the water level gradually decreases in the storage pipe 1010 and the bell siphon 2200 descends, the air is contained again inside the bell siphon 2200 and the trap portion 2410 in the process of rising again according to the inflow of air. The head difference (d1) of the storage pipe and the head difference (d2) of the trap portion 2410 is to be balanced again.

Duplicate description of the operation of the bell siphon 2200 will be omitted.

6 to 7 are diagrams for explaining a modification of the non-powered running water distribution device using the floating bell siphon of the present invention.

In a further embodiment of the present invention, a case in which the distribution part 2440 is eccentrically positioned to the other side of the partition part 2301 is shown. However, in the case of dispensing the water body to more places, if it becomes longer to the other side, there may be a problem in the balanced distribution of the water body. In this case, it is possible to distribute the water body around the side where the bell siphon 2200 is disposed. It may be appropriate.

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

In addition, when the distribution unit 2440 is relatively long and there are many branch lines 2450, air outlets 2433 may be additionally formed in each branch line 2450 or a selected part of the branches in consideration of the efficiency of air discharge. have.

On the other hand, in consideration of assembly and maintainability, the trap portion 2410 may be formed as a separate conduit to be fastened on both sides.

8 is a view showing a state in which the storage pipe device to which the non-powered flowing water distribution device using the floating bell siphon of the present invention includes the vegetation part of the present invention.

The rainwater storage pipe apparatus of the present invention is provided with an inflow portion 1001 through which an oily water flows from an upper side, and a storage pipe 1010 may be disposed on the lower side thereof. The storage pipe 1010 for storing and discharging water bodies from the inlet 1001 may be directly connected, but the initial excellent storage pipe 1020 may be interposed therebetween in consideration of the buffer and filtering of the initial rainwater. The initial excellent storage pipe 1020 may have a reverse flow filter 1011 therein.

The storage pipe 1010 is coupled to a distribution 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 distribution storage pipe 1030. You can.

The rainwater storage device or the water storage device mainly describes an example of a water storage device installed in a height direction on a wall in which a vegetation part is formed on one surface, but is not limited thereto, and a retaining wall, a fence, an outer wall of a building, or an inclined slope or It can be applied to areas that require various water supply, such as walls. Hereinafter, a portion where the storage pipe 1010 is disposed as described above is defined as a wall to be used. The vegetation part 3000 is disposed on at least one surface of the wall, and water necessary for the growth of plants of the vegetation part can be supplied.

Rainwater storage device of the present invention can be installed in a manner that is fixedly installed on one side of the wall or embedded in the wall, as shown in the drawing, to continuously or intermittently supply moisture to the vegetation unit 3000 disposed on the front of the wall do.

The vegetation unit 3000 may be formed in an extended form to a soil capable of supplying moisture and nutrients that are fixed and stored at a root portion of a plant. The soil is disposed in a manner filled between each distribution reservoir 1030, and water is supplied by a bottom surface water wick (not shown) communicating between the soil inside and the distribution reservoir. For example, the bottom surface water wick is disposed partially extended to the outside as being inserted into the distribution reservoir 1030, and may be formed long along the horizontal direction of the soil in the space between the distribution reservoirs 1030.

The rainwater flowing into the upper storage pipe 1010 is sequentially discharged to the lower side while the water level is adjusted through the distribution device, and the water body supplied to each distribution storage pipe 1030 is a vegetation unit (3000) ) Will supply water even when there is no rain in the soil.

The non-powered running water distribution device using the floating bell siphon according to the above-described concept of the present invention is economical because it can automatically adjust the water level and effectively distribute the water during rainfall by adjusting the amount of air and water without providing an external power source. In addition to this, even in environments such as irregular rainfall or dry season, irrigation is possible without supply of water.

In addition, by overcoming the limitations of the water supply system using the siphon principle of the prior art, it is possible not only to automatically perform the process of filling and discharging the air inside the siphon pipe, but also to ensure the reliability of its operation.

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

In the above, 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 contents described in the claims below.

1001 ... Inlet 1010 ... Storage pipe
1011 ... Reverse flow filter 1020 ... Initial excellent storage pipe
1030 ... Distribution Reservoir 2000 ... Bel Siphon
2210 ... Lower member 2220 ... Upper member
2230 ... inlet 2300 ... fastening member
2301 ... Bulkhead 2310 ... Seat
2320 ... Stopper part 2410 ... Trap part
2420 ... Exhaust section 2421 ... Bypass line
2422 ... gas outlet 2423 ... line outlet
2430 ... trap part bottom 2440 ... distribution part
2450 ... branch line 2460 ... regulating valve
3000 ... Vegetation Department

Claims (8)

A reservoir 1010 through which water bodies are introduced and stored;
A partition portion 2301 disposed to penetrate the lower side of the storage pipe up and down; And
A bell having an upper member (2220) formed in a form covering the upper side of the partition wall portion, a lower member (2210) that is raised and lowered along an outer surface of the partition wall portion, and an inlet port (2230) formed at spaced apart sides of the upper member and lower member Siphon (2200); includes,
The bell siphon,
When the water level in the storage pipe falls while the water inside the storage space is full while the water flows into the inside through the inlet on the side and discharges it through the inlet on the side at the elevated position as the water level rises inside the storage pipe. When the water level inside the storage pipe starts to correspond to the inlet in the lower position, it is a non-powered flowing water distribution device using a floating bell siphon that induces air into the interior space, restores buoyancy, and rises again to promote the inflow of air.
According to claim 1,
The partition wall portion,
Non-powered running water distribution device using a floating bell siphon having a stopper portion (2320) protruding outward to limit the rising height of the bell siphon.
According to claim 1,
A trap portion 2410 connected to a partition wall portion to discharge the water body from the lower side of the storage pipe; And
Discharge unit (2420) to bypass the trap portion to discharge the air; Non-powered running water distribution device using a floating bell siphon.
According to claim 3,
It is further provided with a distribution unit (2440) connected to the trap portion to store the water body supplied from the storage pipe,
The trap portion,
One end is connected to the partition portion and the other end is connected to the distribution portion, the height of the bottom of the trap portion disposed on the lower side is formed lower than the partition portion and the distribution portion non-powered flowing water distribution device using a floating bell siphon to store water inside.
According to claim 4,
The head difference due to the water level inside the storage pipe and the air level filled in the bell siphon, the floating bell siphon corresponding to the head difference due to the difference between the water level on one side and the water level on the other side with the trap portion at the bottom. Non-powered running water distribution system.
The method of claim 5,
The distribution unit,
Non-powered flowing water distribution device using a floating bell siphon having a gas discharge unit (2422) that allows the air inside the storage pipe and the discharge unit, the trap unit and the distribution unit to be discharged to the outside.
According to claim 4,
One or more branch lines (2450) connected to the lower portion of the distribution unit to supply water to each location; further comprising a floating power siphon distribution device using a floating bell siphon.
A storage pipe apparatus comprising a non-powered running water distribution device using the floating bell siphon according to any one of claims 1 to 7,
An inflow portion 1001 disposed on an upper side of the storage pipe to flow rainwater;
An initial excellent storage pipe (1020) for storing and filtering initial rainwater from the inlet and supplying it to the storage pipe;
A distribution storage pipe 1030 for storing the water body branched from the storage pipe;
Storage vessel device comprising a; vegetation unit (3000) disposed in the soil disposed in the space between the distribution reservoir.

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