KR101107734B1 - A Siphon Type Rainwater Tank - Google Patents

Abstract

The present invention relates to a water storage device for receiving rainwater, and more particularly, a double discharge pipe using the principle of siphon is disposed in the water storage device so that the rainwater received and stored in the water storage device is organically reacted to a natural climate. A siphonic rainwater reservoir configured to be automatically discharged without power.

Description

Siphon Type Rainwater Storage System

The present invention relates to a water storage device for receiving rainwater, and more particularly, a double discharge pipe using the principle of siphon is disposed in the water storage device so that the rainwater received and stored in the water storage device is organically reacted to a natural climate. A siphonic rainwater reservoir configured to be automatically discharged without power.

Rainwater, which falls all over Korea, is at least 754 mm to 1792 mm, which is concentrated in the rainy season during June-July. Some of them flow to the ground and others evaporate away. Among the rainwater that flows to the ground, it can be used as agricultural and living water for human use through rainwater, dams, rivers, and groundwater that flows to the sea.

Acid rain resulting from air pollution contains a lot of acid, but when it meets the earth's material, it becomes weakly alkaline.

In particular, rainwater has the property of not decaying no matter how long it is stored. This is because the water vapor evaporated from the sea or land repeats the cycle of falling into the clouds and then back to the ground, thereby preventing the decay, which is the process of decomposing organic matter.

Such rainwater flows into the dam along the stream. The dam is a structure made to prevent the storage of water, sediment outflow, intake, water level rise or collapse along mountain valleys or rivers, which has a problem of damaging the vast site, the old site and the natural landscape.

Accordingly, it is urgent to develop structures that can replace dams that damage natural landscapes.

On the other hand, the conventional water tank merely serves as a container for receiving rainwater, etc., and had to discharge the water received through power or manpower, if necessary. Therefore, it would be more reasonable to install a reservoir of adequate capacity with the ability to discharge itself during a drought than to build a dam.

Therefore, the present invention is devised to supplement the above-mentioned disadvantages or problems of the dam or reservoir, and it is a siphonic rainwater reservoir that can be automatically discharged with no power by receiving and storing rainwater and allowing the rainwater to react organically in a natural climate. The object is to provide a device.

Siphon-type rain water storage device according to the problem to be solved of the present invention is provided with a storage space therein and the upper portion is opened body portion for receiving rain water; A first weight weight disposed proximate to the outside of the body portion and including a water absorbent absorbing rainwater and a porous cover receiving the water absorbent, the upper opening being coupled to the open upper portion of the housing; It is arranged to be able to move up and down inside the body portion and has an inlet tube having a first tube diameter contacting the bottom surface of the body portion and a second tube diameter relatively smaller than the inlet tube, and is inserted into the inlet tube and one side of the inlet tube. A double outlet pipe extending from the exposed side of the body through the lower side of the body and having an outlet pipe disposed at a lower position than the top of the inlet pipe; And a connection member coupled to an outer surface of the body portion and penetrating the body portion to connect the upper portion of the first weight weight and the double water outlet pipe so that the double water outlet pipe is relatively moved by gravity of the first weight weight. It is characterized by including a support for raising and lowering action.

According to a preferred embodiment of the present invention, coupled to the upper portion of the body portion, the bottom of each side in the shape of a square pyramid coupled to the rain gutter roof made of porous material and the bottom surface of each side of the rain gutter roof The eave gutter portion and one side to receive rainwater flowing from the rain gutter roof and one side communicate with each eave gutter portion and the other side penetrates the outer surface of the body portion so as to communicate with the internal storage space of the body portion to introduce the rainwater of the eave gutter portion It is reasonable to further comprise a plurality of rainwater inlet pipe for.

At this time, the eave gutter portion is plate-like, the upper surface is coupled to the bottom surface of the rain gutter roof, the central portion of the outer surface is coupled to the hinge pin formed to protrude outwards on both sides of the channel at a relatively lower position than the hinge pin A waterway is formed along the longitudinal direction so that rainwater flows and a channel support plate having a seating groove formed thereon so that one side or the other side of the groove is flown, and a central portion is hinged to the hinge pin so that both sides can be moved upward or downward from the central axis. However, one side or the other side is prevented from being separated by both seating grooves of the channel support plate, and the water absorbent is coupled to one side and the bottom surface of the waterway groove and the discharge hole of the waterway groove so that the rain water is discharged to the opposite side The inlet hole is coupled to one side of the receiving groove side of the channel support plate and opened so that one surface is opened. Air can comprise the rainwater inflow pipe and the inlet plate communicating.

In addition, the cornice is formed in the channel along the longitudinal direction so that the rain water flows and is coupled to the upper portion of the waterway groove is disposed from the portion formed by the hinge hole to the hinge coupled portion, facing the discharge hole of the waterway groove The waterway is formed so that the second waterway groove and the rain water is formed on the bottom surface and the rainwater flows and is coupled to the upper portion of the second waterway groove further comprises a third waterway groove disposed in the portion where the second discharge hole is formed. Therefore, it is possible to remove foreign substances such as fine dust based on the waterfall effect composed of three stages.

On the other hand, the present invention is characterized in that it further comprises a rain water discharge portion consisting of a discharge pipe and a valve for controlling the opening and closing of the discharge pipe and the communication through the lower outer surface of the body portion of the body portion.

Here, according to a preferred embodiment of the present invention, the rain water discharge portion is fixed to the body coupled to the outer surface of the body portion and the spring and one side connected to the lower side of the body from the fixing member is connected to the spring and the other side is It is coupled to the valve and rotates the valve in accordance with the absorption state of the rain is characterized in that it is configured to be easily applicable to the existing well-known one-touch faucet further comprises a water absorbent for organically opening and closing the discharge pipe according to the climate. .

As described in detail above, the siphonic rainwater storage device of the present invention has a simple structure, and thus, the construction cost of the water storage device is relatively lower than that of the conventional water storage device, and the siphonic power is used to organically react the stored rainwater to the natural climate. As it is automatically withdrawn, there is an effect that can reduce the maintenance costs, such as maintenance.

1 is a view showing a siphonic rainwater storage device according to the present invention.
2 is a view showing the storage space of the siphonic rainwater storage device according to the present invention.
Figure 3 is a view showing a double outlet pipe of one configuration of the present invention.
4 is a view showing a support that is one configuration of the present invention.
5 is a view showing a rainwater discharge unit that is one configuration of the present invention.
6 is a view showing a purification pipe of one configuration of the present invention.
7 shows a siphonic rainwater storage device according to a first embodiment of the present invention.
8 is a view showing a siphonic rainwater storage device according to a second embodiment of the present invention.
9 is a view for explaining the cornice portion of FIG.
10a to 10b is a view showing the operating state of the cornice portion of FIG.
11 is a view showing a siphonic rainwater storage device according to a third embodiment of the present invention.

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

1 is a view showing a siphonic rainwater storage device according to the present invention, Figure 2 is a view showing a storage space of the siphonic rainwater storage device according to the present invention, Figure 3 is a double discharge pipe which is one configuration of the present invention It is a figure which shows.

4 is a figure which shows the support which is one structure of this invention, FIG. 5 is a figure which shows the rainwater discharge part which is one structure of this invention, and FIG. 6 is a figure which shows the purification pipe which is one structure of this invention.

The siphonic rainwater storage device according to the present invention has a double outlet pipe 30 using the principle of siphon is disposed inside the body portion 10 so that the received and stored rainwater can be organically reacted according to the natural climate to be discharged with no power. It is a rainwater reservoir.

Looking at the siphonic rainwater storage device according to the present invention with reference to Figures 1 to 3 body portion 10 for receiving rain water, the double water discharge pipe 30 disposed in the body portion 10 and the double water discharge pipe The first weight 20 and the support weight 50, which is an operation means of the double weight pipe 30 and the first weight 20 is configured to act relative to the gravity 30.

Specifically, the body portion 10 is configured in the shape of a container such as a cylinder or a polygon having a storage space (R) therein, the capacity of the storage space (R) is to be produced in a suitable standard according to the trend of yearly precipitation As can be seen, the invention is not limited to the shape of the body portion 10.

The body portion 10 is configured so that rain water flows into the water storage space (R) inside the upper portion is opened, the material is composed of a heat insulating material 11, as shown in Figure 1, or the heat insulating material 11 It is reasonable to prevent the rain water stored in the storage space (R) from freezing in winter due to the warming effect, because the structure is embedded in the structure or any one of the vacuum structure 12 can be applied.

In addition, the body portion 10 is provided with a ventilation window 13 to allow the outside air to smoothly flow into the storage space (R) to supply oxygen to the stored and stored rain water for a long time to prevent the corruption of the rain water do. As shown in FIG. 1, the ventilation window 13 is formed to open at least one or more at predetermined intervals along the outer surface of the top of the body portion 10. At this time, preferably, the air inlet net 14 of the porous material is coupled to prevent the foreign substances, etc. from being introduced into the ventilation window 13.

On the other hand, the first weight 20 of the present invention is disposed close to the outside of the body portion 10, the upper or second weight 40 of the double outlet pipe 30 by the support 50 to be described later It is connected to and acts relatively by gravity. As shown in FIG. 1, the first weight 20 receives a water absorbent 21 for absorbing rainwater and the water absorbent 21, and a housing 22 having an upper portion thereof and an upper portion of the housing 22. It consists of a porous cover 23 which is bonded to. In this case, the porous cover 23 may be manufactured in various ways, but preferably, foreign matter such as fallen leaves is configured in a conical shape so that the cover 23 may naturally fall to the lower side without sealing the cover 23.

The double outlet pipe 30 is disposed along the longitudinal direction of the body portion 10 in the storage space (R) of the body portion 10, the lower end of the double outlet pipe 30 as shown in FIG. It is located on the bottom surface in the storage space (R) of the body portion 10 and the top is disposed in the upper side in the storage space (R) of the body portion 10. At this time, the double outlet pipe 30 is moved upward or downward in the storage space (R) according to the climate by the first weight 20 having a predetermined length disposed outside the body portion 10, and the like. It is configured to move up and down.

As shown in FIG. 3, the double outlet pipe 30 is configured in the form of a double pipe including an outlet pipe 31 and an inlet pipe 32 having different diameters.

First, the water inlet pipe 32 has a first diameter and one side thereof is in contact with the bottom surface of the body portion 10, the water outlet pipe 31 is relatively smaller than the water inlet pipe 32 Is inserted into the first tube diameter of the inlet pipe 32 having a two-diameter, one side is extended from the inlet pipe 32 is configured to penetrate through the lower side of the body portion 10 to be exposed to the outside, The upper end of the other side is disposed at a position lower than the water inlet pipe (32). At this time, one side of the water outlet pipe 31 is fixed to the portion penetrating through the body portion 10 is not separated from the lower side of the body portion 10 when lifting the double water outlet pipe (30).

The double outlet pipe 30 having such a configuration is obtained through the aperture formed in the lower end of the inlet pipe 32 and the rainwater received in the body portion 10 by the principle of siphon is applied to the top aperture of the outlet pipe 31. The fluid is finally discharged to the outside of the body portion 10.

In this case, a second weight 40 may be coupled to the upper portion of the double discharge pipe 30 so as to surround the outer diameter of the double discharge pipe 30. The second weight 40 is connected to the first weight 20 through a connecting member 51 including a connecting line to operate relatively to the first weight 20 by gravity, the second weight The double water discharge pipe 30 coupled with the weight 40 is moved upward or downward in the inner reservoir space R of the body portion 10.

Here, since the first weight 20 can be lifted by the gravity action even by the weight of the double outlet pipe 30, it is natural that the configuration of the second weight 40 can be deleted as necessary Do.

Again, the second weight 40 should be selected in consideration of the weight of the first weight 20 described above. That is, when the water absorbent 21 of the first weight weight 20 absorbs water and when the water evaporates, the double water discharge pipe 30 may be moved upward or downward in consideration of the weight according to each situation. It is reasonable that the weight should be selected, and as described above, it may be selectively included since the double water discharge pipe 30 may serve as a weight as the flexibility and its own weight.

Hereinafter, the present invention will be described according to the embodiment to which the second weight 40 is applied.

On the other hand, the first weight 20 and the second weight 40 is to interact through the support 50 is coupled to the outer surface of the body portion 10.

Specifically, the support 50 includes a connecting member 51 penetrating the side of the body portion 10 to connect the first weight 20 and the second weight 40. The connecting member 51 may be a wire, a rope, a rubber band, etc., but preferably by using a fishing line to be quickly cut in the fire by the rainwater in the storage space (R) is discharged to extinguish the surrounding fire at the time of fire. Help.

The support 50 is according to the known art can be configured in a variety of structures, to describe an example of the support 50 according to the present invention with reference to Figure 4, the outer surface of the body portion 10 A first frame 52 coupled along a longitudinal direction and a second frame 53 coupled to be orthogonal on an upper portion of the first frame 52, and coupled to one end of the second frame 53, 1 as long as the first roller 54 to which the connecting member 51 to which the weight 20 is connected is seated, and side by side opposite to the end of the second frame 53 on the inner surface of the body portion 10. A second roller fixed by a pair of fixed frames 55 and the pair of fixed frames 55 and on which the connection member 51 penetrating the body portion 10 from the first roller 54 is seated ( 56).

The connecting member 51 of the support 50 is seated on the first roller 54 and the second roller 56 so that one side of the support member 50 and the second weight of the second weight 40 are on the other side. Each is connected.

As a result, the first weight 20 and the second weight 40 are interacted by gravity due to the change in weight due to the climate of the first weight 20, and consequently the second weight 40 The double outlet pipe 30 is connected to the elevating.

On the other hand, the support 50 may be coupled to the guide portion 60 to prevent the departure of the first weight (20) and provide a stable lift. As illustrated in FIG. 4, the guide part 60 has a ring shape having a diameter corresponding to that of the first weight 20, and an upper portion 61-1 and a lower portion 61 of the side surface of the first frame 52. A pair of guide rings 61-1 and 61-2 coupled to -2) to be spaced apart from each other are provided.

In addition, a plurality of guide rods 62 are vertically connected between both guide rings 61-1 and 61-2 to maintain parallelity with the first frame 52. In addition, a seating plate 63 on which the first weight 20 is seated is coupled to the center side of the lower guide ring 61-2.

In this case, a magnet 200 is formed on an upper surface of the seating plate 63, and the magnet 210 is also formed on the lower surface of the first weight 20 to correspond to the first weight ( 20 is able to maintain the home position by the magnet 200 and the magnetic force of the seating plate 63 of the guide portion 60.

In addition, the plurality of guide rods 62 may also be formed with a magnet 200 on one surface, it is preferable that the first weight 20 is formed in a range that can be moved upward, the guide rods The magnet 210 is formed on the side surface of the first weight 20 so as to correspond to the magnet 200 formed on the side surface (62).

The above-described configuration of the magnets 200 and 210 is elastic at the moment of falling from the magnets 200 and 210 when the first weight 20 moves up, so that the upper end of the double outlet pipe 30 is easy in the storage space R. This is to let the submerged water out so that the water can be submerged.

Hereinafter, referring to the operating principle of the siphonic rainwater storage device according to the present invention, first, the second weight weight 40 disposed in the storage space R of the body portion 10 and the first weight weight disposed outside 20 is designed to have gravity corresponding to each other. Rainwater is received and stored in the storage space (R) of the body portion 10 in the rain, and at the same time the water absorbent 21 of the first weight 20 also absorbs rain water to the second weight 40 The weight is relatively larger than). Accordingly, the first weight 20 moves downward, and the second weight 40 connected through the connecting member 51 moves upward in the storage space R of the body portion 10.

At this time, the double water discharge pipe 30 coupled with the second weight 40 is also moved upwardly in conjunction with the second weight 40, the water inlet pipe that is in contact with the bottom surface of the body portion 10 ( 32 and the double outlet pipe 30 is fixed to the lower side of the body portion 10 by the outlet pipe 31 fixed to the side of the body portion 10, so only the double outlet pipe 30 of the upper side It moves upward with the second weight 40 and can be located above the water level stored and stored in the storage space (R) of the body portion 10.

Then, the moisture absorbent 21 of the first weight 20 according to the natural environment, such as wind and temperature is dried and gradually lighter, from the time when the weight is relatively lighter than the weight of the second weight (40) The first weight 20 is subjected to the upward traction force and is quickly moved upward by the moment the elasticity falls from the magnet so that the upper end of the double outlet pipe 3 is submerged in the reservoir and at the same time the upper end of the outlet pipe 31 The exit is made through the caliber. In this way, once the water is discharged, the rainwater in the storage space R is in contact with the bottom surface of the body part 10 due to the pressure difference between the water outlet pipe 31 and the water inlet pipe 32 based on the principle of the siphon according to the known technique. One side of the water inlet pipe 32, that is, continuously flows through the lower diameter of the water inlet pipe 32, and flows back upward in the other direction of the water outlet pipe 31. Accordingly, even the rainwater contained in the bottom surface of the body part 10 flows upward through one side of the water inlet pipe 32 and finally flows back into the upper diameter of the water outlet pipe 31 and the bottom diameter of the water outlet pipe 31. Through the rainwater received in the storage space (R) are all discharged. The siphonic rainwater storage device according to the present invention is to repeat the acquisition and withdrawal according to the natural climate by this operating principle.

On the other hand, the siphonic rainwater storage device according to the present invention is configured to drain the rainwater in the storage space (R) by configuring the rainwater discharge portion 70 in the body portion 10 as shown in FIG. .

The rain water discharge portion 70 is coupled to the discharge pipe 71 and the discharge pipe 71 which communicates with the storage space (R) of the body portion 10 through the lower outer surface of the body portion 10 from the outside is The valve 72 is configured to control the opening and closing of the discharge pipe 71.

At this time, the valve 72 is used to control the flow rate discharged through the discharge pipe 71 may be a stop valve, a slew valve, and the like, which is opened and closed by a manager's arbitrary operation and is stored in the storage space R. Rainwater can be discharged.

Such rainwater discharge unit 70 may be configured to respond to the natural climate, such as the above-described dual discharge pipe 30, not the manager's arbitrary operation. For example, as shown in FIG. 5, the rainwater discharge portion 70 is a lower side of the body portion 10 from the fixing member 73 and the fixing member 73 coupled to the outer surface of the body portion 10. Spring 74 and one side is connected in the direction and the other side is connected to the spring 74 and the other side is coupled to the valve 72 further comprises a water absorbent 75 that can operate the opening and closing of the valve 72 Can be.

The rainwater discharge unit 70 having the above-described structure rotates the valve 72 according to the absorption state of the rainwater by the water absorbent 75 disposed below the body portion 10 to open or discharge the discharge pipe 71. Will be closed. That is, by absorbing rain water, the moisture absorbent 75 moves downward as the weight increases, thereby rotating the valve 72 connected thereto to close the discharge pipe 71.

On the contrary, in the non-raining state, the rain water absorbed by the water absorbent 75 is evaporated, and thus the water absorbent 75 gradually lightened is moved upward by the restoring force of the spring 74 and the rotational direction of the valve 72. This change is to open the discharge pipe 71 is to be able to discharge the rainwater in the storage space (R).

At this time, although not shown in the figure on the outer diameter portion of the discharge pipe 71, it is reasonable to prevent the valve 72 rotated by the water absorbent 75 from rotating over a predetermined range by mounting a stopper such as a latch. .

As described above, in the present invention, the rainwater discharge unit 70 together with the double discharge pipe 30 disposed in the storage space R may discharge rainwater organically stored and stored in the natural climate.

Meanwhile, the siphonic rainwater storage device according to the preferred embodiment of the present invention further includes a plurality of purification pipes 80 disposed inside the body 10 and made of earthenware as shown in FIG. 6. Can be configured.

The plurality of purification pipes 80 is composed of earthenware with excellent purification function to prevent the rainwater from decaying as it performs a purification action on the rainwater stored and stored for a long time.

7 is a view showing a siphonic rainwater storage device according to a first embodiment of the present invention, Figure 8 is a view showing a siphonic rainwater storage device according to a second embodiment of the present invention. In addition, Figure 9 is a view for explaining the cornice portion of Figure 8, Figure 10a to Figure 10b is a view showing the operating state of the cornice portion of FIG.

In the siphonic rainwater storage device according to the first embodiment of the present invention, a rain gutter cover 90 may be coupled to an opened upper portion of the body portion 10. For example, as shown in FIG. 7, the rain gutter cover 90 is made of a porous material to prevent foreign substances or insects from being introduced into the storage space R of the body part 10.

The rain gutter cover 90 may be manufactured in various shapes, such as a triangular pyramid and a square pyramid, but is preferably configured in a conical shape without sealing an upper portion of the body portion 10 in which a large particle such as fallen leaves is opened. It is supposed to fall naturally.

At this time, preferably the upper portion and the rain gutter cover 90 of the body portion 10 is coupled to and separated by the coupling flange 91 is provided with a plurality of coupling holes 910 along the circumference is screwed together It is reasonable to make this easy.

On the other hand, the siphonic rainwater storage device according to the second embodiment of the present invention is coupled to the rain gutter roof 100 and the like in the open upper portion of the body portion rainwater flows into the storage space (R) inside the body portion (10) It is configured to be. Specifically, referring to FIGS. 8 to 10B, in the present embodiment, the porous material may be coupled to the opened upper portion of the body portion 10 so that a predetermined portion of the lower portion of each surface may be introduced into the rectangular pyramid. Rain gutter roof 100 consisting of 101, the eave gutter section 110 and one side is coupled to the bottom surface of each side of the rain gutter roof 100 to receive rainwater flowing from the rain gutter roof 100 Further comprising a plurality of rainwater inlet pipe 120 is in communication with the eaves groove portion 110 and the other side penetrates the outer surface of the body portion 100 so as to communicate with the internal reservoir space (R) of the body portion (10) Can be configured.

That is, in the present embodiment, the rainwater flowing through the porous net 101 at the bottom of each surface of the rain gutter roof 100 is received by the cornice 110 and the body portion along the rainwater inlet pipe 120. It is introduced into the reservoir space (R) through the side of (10).

At this time, the cornice 110 is configured to include the channel receiving plate 111, the channel groove 114 and the inlet plate 117 as shown in FIG.

The channel receiving plate 111 is plate-shaped, the upper surface is coupled to the bottom of the rain gutter roof 100, the central portion of the outer surface is formed with a hinge pin 112 is formed to protrude outward to the center of gravity. .

In addition, seating grooves 113 and 113-1 are formed at both sides of the channel receiving plate 111 so that one side or the other side of the channel groove 114 may be seated.

The waterway groove 114 is a pipe through which the rainwater flowing through the porous net 101 of the rainwater gutter roof 100 flows, and a waterway is formed along its longitudinal direction, and the hinge pin ( 112 is hinged so that one side or the other side can be moved upward or downward from its central portion. At this time, the waterway groove 114 is prevented from being separated from one side by the two mounting grooves 113, 113-1 of the channel receiving plate 111 when one side or the other side is moved up or down. .

In addition, the water absorbent 115 for absorbing the rainwater to the side of the channel groove 114, one side is coupled to the discharge surface 116 is formed so that the rain water is discharged along the channel on the bottom surface.

The waterway groove 114 is configured to be relatively heavy on the opposite side of the water absorbent 115 is inclined toward the opposite side of the water absorbent 115 in normal rain does not fall.

On the other hand, the inflow plate 117 is coupled to the side of the one side mounting groove 111 of the channel receiving plate 111, is disposed on the bottom surface of the waterway groove 114 and the discharge hole 116 of the waterway groove 114 Inflow hole 118 is formed so that one surface facing the) is opened to communicate with the rainwater inflow pipe (120).

Referring to the operating state, the rainwater flowing from the rain gutter roof 100 falls into the channel of the waterway groove 114, the initial rain water including fine dust falls to the opposite side to the water absorbent 115, the water absorbent 115 ) Absorbs rain water and becomes heavier and more inclined downward toward the water absorbent 115.

Accordingly, the waterway groove 114 is seated in the seating groove 113 formed on one side and no longer flows, and the discharge hole 116 is in contact with the inlet hole 118 facing the other.

At this time, the rain water flowing through the water channel flows in one direction of the waterway groove 114 and passes through the discharge hole 116 and the inlet hole 118 which are in contact with each other finally through the rain water inlet pipe 120 through the body portion ( Rainwater flows into the internal reservoir space R of 10).

Thereafter, in the drying period in which the rain does not fall, the water of the moisture absorbent 115 is evaporated, and the channel groove 114 is inclined again to the opposite side of the moisture absorbent 115.

Meanwhile, in the present embodiment, the second channel groove 114-1 and the third channel groove 114-2 are provided to provide a small waterfall effect in order to remove foreign substances such as fine dust generated during a drying period in which rain does not fall. It may be configured to include more.

The second channel groove 114-1 has a channel formed so that rainwater can flow in the same manner as the channel groove 114 described above, and is coupled to an upper portion of the channel groove 114 to form a channel groove 114. Configured to close the upper portion. For example, the second channel groove 114-1 is disposed from a portion in which the discharge hole 116 of the channel groove 114 is formed to a central portion of the channel groove 114 hinged and the channel groove 114. The second discharge hole (116-1) is formed on the bottom surface facing the discharge hole 116 of the).

The third channel groove 114-2 has a channel formed to allow rainwater to flow in the same manner as the channel channel 114 described above, and is coupled to an upper portion of the second channel groove 114-1, wherein the second channel is formed in the second channel groove 114-2. The discharge hole 116-1 is coupled to be disposed in the formed portion.

As such, the channel groove 114, the second channel groove 114-1, and the third channel groove 114-2 are coupled in multiple stages to form a plurality of layers.

Accordingly, when one side of the waterway groove 114 absorbs rainwater and moves downward by the water absorbent 115, that is, when the waterway groove 114 maintains a parallel state, the second waterway groove 114-1 is formed. And the other side of the waterway groove 114 only for a predetermined time by using a force in which rainwater received in the third waterway groove 114-2 is sequentially dropped. As a result, the foreign matter present in the waterway groove 114 is discharged to the other side of the waterway groove 114 while the waterway groove 114 is moved to the other side and sweeps through the rainwater, and the water absorbent 115 gradually absorbs the rainwater again. Moved downward to one side of the waterway groove 114 has a characteristic that can be introduced into the reservoir space (R) of the body portion 10 only relatively clear rain water.

11 is a view showing a siphonic rainwater storage device according to a third embodiment of the present invention, the siphonic rainwater storage device according to the present embodiment may further include a disconnection extraction pipe 130. The disconnected water extraction pipe 130 has a different structure from the above-described double water discharge pipe 30 and the rainwater discharge unit 70, and does not discharge the received and stored rainwater in the storage space R at a time according to the natural climate. It is configured to discharge rainwater sequentially according to the natural climate.

Specifically, the disconnected water extraction pipe 130 has a predetermined diameter as shown in FIG. 11, and is capable of being elevated in the storage space R of the body portion 10 as in the above-described double water extraction pipe 30. It is arranged. The disconnected water extraction pipe 130 has one side in contact with the bottom surface of the body portion 10 and penetrates through the lower side of the body portion 10 and is exposed to the outside, and the other side is directed to the upper side of the reservoir R. It is arranged.

At this time, the disconnection water extraction pipe 130 may be made in the same manner as the operation structure of the above-described double water extraction pipe 30 so as to be able to move up and down in the storage space (R) of the body portion 10 according to the natural climate.

In other words, the above-described first weight 20, 20-1 and the second weight 40, 40-1 and the support 50, 50-1 for connecting them are each composed of a pair of predetermined intervals Is disposed spaced apart, one first weight 20 and the second weight 40 and the support 50 is configured to act the double outlet pipe 30, the other first weight 20-1, the second weight 40-1 and the support 50-1 are configured to act on the disconnection outlet pipe 130. Accordingly, the other second weight 40-1 is coupled to surround the other side of the disconnection extraction pipe 130, that is, the upper side of the disconnection extraction pipe 130, and the other first weight Will interact with the weight (20-1).

Here, the connection relationship and the interaction state of the other first weight 20-1, the second weight 40-1 and the support 50-1 is made the same as described above, so Detailed description thereof will be omitted.

As a result, the disconnection water extraction pipe 130 is gradually moved downward in the storage space R of the body part 10 according to the natural climate, and the rainwater received and stored in the storage space R is sequentially discharged. As the rainwater received and stored in the storage space (R) is sequentially discharged according to the height at which one side of the disconnection extraction pipe 130 is located, the water level is adjusted.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

10: body portion 20: first weight
30: double outlet pipe 40: second weight
50: support 60: guide portion
70: rain water discharge portion 80: purification pipe
90: rain gutter cover 100: rain gutter roof
110: eave gutter 120: rainwater inlet pipe
130: disconnection pipe 200, 210: magnet

Claims (6)

A body portion having a storage space therein and having an upper portion opened to receive rainwater;
A first weight weight disposed proximate to the outside of the body portion and including a water absorbent absorbing rainwater and a porous cover receiving the water absorbent, the upper opening being coupled to the open upper portion of the housing;
It is arranged to be able to move up and down inside the body portion and has an inlet tube having a first tube diameter contacting the bottom surface of the body portion and a second tube diameter relatively smaller than the inlet tube, and is inserted into the inlet tube and one side of the inlet tube. A double outlet pipe extending from the exposed side of the body through the lower side of the body and having an outlet pipe disposed at a lower position than the top of the inlet pipe; And
It is coupled to the outer surface of the body portion, and through the body portion is provided with a connecting member for connecting the upper portion of the first weight and the double outlet pipe is relatively lifted by the double weight pipe by the weight of the first weight Siphonic rainwater storage device, characterized in that it comprises a support to act. The method of claim 1,
It is coupled to the upper portion of the body portion, and the rain gutter roof made of a porous material so that rain water is introduced into the lower portion of each surface in the shape of a square pyramid
Eave gutter portion coupled to the bottom surface of each side of the rain gutter roof for receiving rainwater flowing from the rain gutter roof and
One side is in communication with each of the eaves and the other side is characterized in that it further comprises a plurality of rainwater inflow pipe for introducing the rainwater of the eaves through the outer surface of the body to communicate with the internal reservoir space of the body portion Siphon rainwater reservoir. According to claim 2, wherein the cornice portion
The upper surface is coupled to the bottom portion of the rain gutter roof in a plate shape, the hinge pin is formed in the center portion of the outer surface protrudes outward, and one side or the other side of the channel groove in the lower side relative to the hinge pin A channel support plate having a seating groove formed thereon so as to be seated;
A waterway is formed along the longitudinal direction so that rainwater flows, and a central portion is hinged to the hinge pin so that both sides can move upward or downward from a central axis, but one side or the other side is separated by both seating grooves of the channel support plate. And a water absorbent is coupled to the side of one side, and a waterway groove formed with a discharge hole to discharge rainwater from the bottom of one side;
Siphon rainwater storage device characterized in that it comprises an inlet plate is coupled to the side of the seating groove side of the channel receiving plate to face the discharge hole of the waterway groove, the inlet hole is open on one surface and in communication with the rainwater inlet pipe . According to claim 3, wherein the cornice portion
A water channel is formed along the longitudinal direction to allow rain water to flow, and is coupled to an upper portion of the waterway groove, and is disposed from a portion where the discharge hole is formed to a hinged portion, and a second discharge on a bottom surface facing the discharge hole of the waterway groove. A second channel groove formed with a ball and
A siphonic rainwater storage device, characterized in that the water channel is formed so that the rain water can flow, and further comprises a third channel groove coupled to the upper portion of the second channel groove, the third channel groove is disposed in the portion formed with the second discharge hole. The method of claim 1,
Siphonic rainwater storage device further comprises a rainwater discharge portion consisting of a discharge pipe which passes through the lower outer surface of the body portion and communicates with the storage space of the body portion and a valve for controlling the opening and closing of the discharge pipe. The method of claim 5, wherein the rain water discharge portion
Fixed member coupled to the outer surface of the body portion
A spring connected to the lower portion of the body from the fixing member;
One side is connected to the spring and the other side is coupled to the valve and the siphonic rainwater characterized in that it further comprises a moisture absorbent for rotating the valve in accordance with the absorption state of the rain organically open and close the discharge pipe according to the climate. Water storage device.

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