KR101566948B1 - Apparatus for managing underground water and stormwater - Google Patents

Abstract

Disclosed is a device to manage underground water and rainwater. The device to manage underground water and rainwater is installed in the ground comprising: an underground water tank capable of storing underground water; a storage tank having a storage space inside to be able to store rainwater by receiving the underground water stored in the underground water tank and rainwater separately; an underground water supply pipe supplying underground water stored in the underground water tank inside the storage tank; and a drain pipe branched from the underground water supply pipe to discharge a part of a fluid in the storage tank to the outside when a fluid level in the storage tank exceeds a preset standard range. According to the present invention, the device to manage the underground water and the rainwater integrally manages the underground water and the rainwater in the storage tank; thus using the rainwater and the underground water by linking the rainwater and the underground water. The device to manage the underground water and the rainwater easily controls a level of fluid in the storage tank in accordance to a change in the level of fluid in the storage tank where the rainwater and the underground water are stored.

Description

[0001] APPARATUS FOR MANAGING UNDERGROUND WATER AND STORMWATER [0002]

The present invention relates to a groundwater and stormwater management apparatus, and more particularly, to a groundwater and stormwater management apparatus that enables stormwater and underground water to be used in conjunction with each other by integrating and managing stormwater and groundwater in a storeroom.

In recent years, due to changes in land use patterns due to urbanization, the number of impervious floors has increased, and damage to flood damage and pollution of non-point pollutants in cities (pollutants discharged from unspecified places such as roads, farmlands, mountainous areas, and construction sites) And the need for a sustainable water cycle system has begun to be emphasized. Low-Impact Development (LID) technology has been proposed as part of land-use planning and urban development techniques. However, the technology for securing water resources using rainwater has been lacking.

Especially, in Korea, there are limitations of rainfall runoff storage capacity due to the characteristics of rainfall concentrated in summer, the size of water surface and the size of reservoir, and there is no multi - purpose facility such as reduction of nonpoint pollution and utilization of rainfall runoff.

Korean Registered Patent No. 10-0869775 (registered on Nov. 14, 2008)

It is an object of the present invention to provide an underground water and stormwater management apparatus which can utilize stormwater and underground water in cooperation by managing stormwater and groundwater in a storage tank in an integrated manner.

It is another object of the present invention to provide a groundwater and stormwater management apparatus that facilitates fluid level control in a storage tank in accordance with fluid level fluctuations in storages where stormwater and groundwater are stored.

The solution to the problem of the present invention is not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided an apparatus for managing groundwater and stormwater installed in the ground, comprising: a groundwater tank capable of storing groundwater; A storage tank having a water storage space provided therein so as to receive and store rainwater separately from groundwater stored in the groundwater tank; A groundwater supply pipe for supplying groundwater stored in the groundwater tank to the inside of the storage tank; And a drain pipe branched from the ground water supply pipe to discharge a part of the fluid in the storage tank to the outside when the fluid level in the storage tank exceeds a set reference range.

Wherein the groundwater supply pipe is composed of a horizontal pipe and a bending pipe bent upward from an end of the horizontal pipe, groundwater in the groundwater tank flows into the storage tank through an opening formed in the horizontal pipe, The fluid in the storage tank may be reversely introduced into the groundwater supply pipe through the upper end of the bending pipe.

A first filtration means and a second filtration means are provided in a part of the groundwater supply pipe disposed in the storage tank and at a discharge end portion of the groundwater supply pipe to filter foreign substances contained in the groundwater, The first and second filtration means may be backwashed during backwash through the groundwater supply pipe and the drain pipe.

The first filtration means may have a structure in which a filter member is filled in the mesh, or a structure in which a plurality of funnel bundles are aggregated.

The first filtering means may include a pipe body and a plurality of flow direction changing walls spaced apart from each other to switch a plurality of flow directions while the ground water passes through the pipe body.

A hinge door that is hinged on a rear side of the first filtering unit of the groundwater supply pipe to open and close the inside of the groundwater supply pipe to the inner space of the storage tank based on a direction in which groundwater is supplied into the storage tank More can be provided.

The hinge door includes: a first door part hingably coupled to an opening of the groundwater supply pipe; And a second door part connected to an end of the first door part and having a relatively thin thickness compared to the first door part.

A first level sensor for detecting a groundwater level stored in the groundwater tank; A second level sensor for detecting a fluid storage level stored in the storage tank; A high pressure spraying part capable of spraying at least one of air and water into the groundwater supply pipe from the outside of the storage tank at a high pressure; And a controller receiving the detection values of the first level sensor and the second level sensor and controlling the driving of the high pressure injector.

A cap may further be provided at the discharge end of the groundwater supply pipe so that the fluid in the storage tank can be reversely introduced into the groundwater supply pipe after the flow direction is switched in the vicinity of the discharge end.

The bottom surface of the storage tank may be sloped downward to one side and a sludge discharge unit may be further provided to discharge the sludge stacked on the bottom surface of the storage tank to the outside.

A pore pipe provided below the groundwater tank for collecting groundwater in the ground; A connection pipe connecting the pore pipe and the groundwater tank to form a path for supplying groundwater in the pore pipe to the inside of the groundwater tank; And a groundwater supply pump provided on the connection pipe.

According to the present invention, the stormwater and groundwater can be integratedly managed in the storage tank, and the stormwater and groundwater can be utilized in conjunction with each other, and the fluid level in the storage tank can be easily controlled have.

Further, by providing a hinge door on the groundwater supply pipe so as to be rotatable with respect to the hinge, it is possible for the operator to smoothly carry out replacement and re-installation work of the first filtration means.

Further, it is possible to more accurately determine occurrence of clogging of the first and second filtration means by detecting the level of water level by providing a level sensor in each of the underground water tank and the storage tank, and it is possible to efficiently solve the clogged state through the high- .

Further, by further providing a cap at the discharge end of the groundwater supply pipe, it is possible to further prevent the foreign matter and the sludge particles from flowing back to the groundwater supply pipe side in the storage tank.

In addition, the bottom surface of the storage tank is inclined to facilitate sludge collection, and the sludge stacked on the bottom of the storage tank can be discharged more efficiently through the sludge discharging means.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the following description.

1 is a view showing a groundwater and stormwater management apparatus according to a first embodiment of the present invention.
FIG. 2 and FIG. 3 are cross-sectional views showing an application example of the first filtering means in the groundwater and well water management apparatus according to the first embodiment of the present invention.
FIG. 4 and FIG. 5 are diagrams showing a state of replacing the hinge rotation structure and the first filtration means of the groundwater supply pipe in the groundwater / well management apparatus according to the first embodiment of the present invention.
FIG. 6 and FIG. 7 are diagrams illustrating changes in the groundwater flow path according to the change of the water level in the storage tank in the groundwater and stormwater management apparatus according to the first embodiment of the present invention.
FIGS. 8 to 10 are views showing the groundwater flow and the fluid discharge state according to the groundwater inflow and the inflow into the groundwater in the groundwater and well water management apparatus according to the first embodiment of the present invention.
11 is a sectional view showing a state in which first filtering means is applied in the groundwater and well water management apparatus according to the second embodiment of the present invention.
12 is a perspective view showing the first filtering means in the groundwater and well water management apparatus according to the second embodiment of the present invention.
13 is a view showing a groundwater and stormwater management apparatus according to a third embodiment of the present invention.
14 is a view showing a groundwater and stormwater management apparatus according to a fourth embodiment of the present invention.
15 is a view showing a groundwater and stormwater management apparatus according to a fifth embodiment of the present invention.
16 is a view showing a groundwater and stormwater management apparatus according to a sixth embodiment of the present invention.
17 is a view showing a groundwater and stormwater management apparatus according to a seventh embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. Wherein like reference numerals refer to like elements throughout.

The groundwater and stormwater management apparatus (hereinafter, referred to as 'management apparatus') according to the preferred embodiment of the present invention is an apparatus for collecting and managing groundwater and stormwater.

Hereinafter, a management apparatus according to a first embodiment of the management apparatus according to various embodiments of the present invention will be described first.

As shown in FIG. 1, the management apparatus according to the first embodiment of the present invention includes a groundwater tank 100 capable of storing groundwater, A groundwater supply pipe 120 for supplying the groundwater stored in the groundwater tank 100 to the inside of the storage tank 110, And a drain pipe 140 branched from the ground water supply pipe 120 so as to discharge a part of the fluid in the storage tank 110 to the outside when the level of the fluid (ground water and excellent water) in the storage tank 110 exceeds the set reference range .

Prior to the description, the term 'fluid' as used herein refers to groundwater stored in the water or the reservoir 110 in a state where rainwater and groundwater are mixed in the reservoir 110.

First, the groundwater tank 100 has an underground water storage space and is installed in the ground. A plurality of groundwater inflow holes (not shown) are provided on the outer surface of the groundwater tank 100 and groundwater can be introduced into the groundwater tank 100 through the groundwater inflow hole. The inflow hole may be formed by a nonwoven fabric or the like, and a gravel layer may be disposed outside the nonwoven fabric. In addition to the structure and method described above, groundwater can be introduced into the groundwater tank 100 through various known structures and methods.

Next, the storage tank 110 is provided with a water storage space in the groundwater tank 100 so as to be able to receive and store stormwater separately from the groundwater stored in the groundwater tank 100, and is installed on the ground in the side of the groundwater tank 100.

In the upper part of the upper part of the upper part of the upper part of the storage tank 110, a part of the stored fluid is discharged to the outside when the fluid storage level in the storage tank 110 is higher than a certain level. A drain pipe 112 is provided. A pretreatment device capable of filtering a foreign matter (sand, leaves, etc.) in the rainwater separately collected in a pipeline (not shown) connected to the storm inflow pipe 111 as a pretreatment device, And the foreign matter from which the foreign matter is removed is introduced into the storage tank 110 through the stormwater inflow pipe 111 through the stormwater foreign matter removing unit. In addition, when the storm water is excessively introduced into the storage tank 110 through the stormwater inflow pipe 111, the rainwater or the stormwater (ground water and stormwater) stored in the storage tank 110 may flow through the storm drain pipe 112 Some can be discharged. That is, the fluid stored in the storage tank 110 in an amount exceeding the proper level is lowered to a position corresponding to the drain pipe 112 due to fluid discharge through the drain pipe 112.

In the embodiment of the present invention, a fluid discharging portion 113 is provided for discharging the fluid stored in the storage tank 110 to the outside and supplying the fluid to a required place. The fluid discharge portion 113 includes a fluid discharge pipe 114 forming a discharge path of the fluid stored in the storage tank 110 and a fluid discharge pump 115 provided on the fluid discharge pipe 114. Here, the end of the fluid discharge pipe 114 is desirably provided at a position spaced apart from the bottom surface of the storage tank 110, so that only the purified fluid can be discharged to the outside. The bottom surface of the storage tank 110 may be filled with rainwater and may be stored in the storage tank 110. The storage tank 110 may be provided at the bottom of the storage tank 110, The foreign matter (the foreign matter having a specific gravity larger than water) is piled up, so that the sludge layer can be formed. In the present invention, since the end of the fluid discharge pipe 114 is provided at a position spaced apart from the bottom surface of the storage tank 110, only the purified fluid can be discharged.

The groundwater supply pipe 120 forms a groundwater supply path so as to supply the groundwater stored in the groundwater tank 100 to the inside of the storage tank 110. The groundwater supply pipe 120 stores the groundwater level stored in the groundwater tank 100 and stored in the storage tank 110 The fluid level difference enables groundwater supply.

1, the groundwater supply pipe 120 includes a horizontal pipe 120b disposed substantially horizontally with respect to the bottom of the storage tank 110 and a vertical pipe 120b extending upwardly from the end of the horizontal pipe 120b. (120c).

One end of the groundwater supply pipe 120 is disposed in the groundwater tank 100 and the other end is disposed in the storage tank 110. A groundwater supply pipe 120 located relatively close to the groundwater tank 100 is provided with a check valve 121 and a gate valve 122 are provided.

The check valve 121 allows the groundwater in the groundwater tank 100 to move toward the storage tank 110 but conversely prevents the fluid in the storage tank 110 from flowing back to the groundwater tank 100. The gate valve 122 is operated to perform an operation such as cleaning the interior of the storage tank 110 and backwashing the filtration means described later to block groundwater supply from the groundwater tank 100 to the storage tank 110.

Meanwhile, in the embodiment of the present invention, the check valve 121 is provided as close as possible to the connection portion between the groundwater supply pipe 120 and a drain pipe 140 described later. As a result, the water level in the storage tank 110 rises and the fluid in the storage tank 110 flows through the upper end of the bending pipe 120c to the groundwater supply pipe 120, that is, the horizontal pipe 100a and the drain pipe 140 The foreign matters adhered to the first and second filtration means 123 and 129 can be discharged to the outside as efficiently as possible. In the case where the check valve 121 is provided at a position spaced from the connection portion between the groundwater supply pipe 120 and the drain pipe 140 by a predetermined distance, foreign matter flowing in the reverse flow as described above flows through the groundwater supply pipe 120 There arises a problem that it can be stacked again in the vicinity of the connection part of the drain pipe 140. [ In the present invention, as described above, the check valve 121 is disposed at an appropriate position, so that the foreign matter flowing like the reverse flow can be prevented from being deposited on the dead space in the groundwater supply pipe 120.

In the embodiment of the present invention, the groundwater supply pipe 120 is provided with a first filtration means 123 and a second filtration means 129.

As shown in FIG. 1, the first and second filtration means 123 and 129 are used to filter foreign substances contained in the groundwater transported from the groundwater tank 100 to the storage tank 110. Specifically, the first and second filtration means 123 are provided in a part of a groundwater supply pipe 120 disposed inside the storage tank 110 to filter out foreign matter. In addition, the second filtration unit 129 not only prevents foreign matter that can be retained in the storage tank 110 from flowing back into the groundwater supply pipe 120 during the backwash described later, but also prevents the water level of the groundwater tank 100 from being excessively increased It is possible to filter the foreign matter in the groundwater discharged to the upper end side of the bending pipe 120c in a special case of ascending.

In the embodiment of the present invention, the first filtration unit 123 may be configured such that the filter member 125 is filled in the mesh 124, for example. 2, the first filtration unit 123 may include a mesh 124 having an approximately hollow cylindrical shape and a filter member 125 disposed inside the mesh 124, It can be made in filled form. At this time, the mesh 124 may be coupled to the groundwater supply pipe 120 so as to be detachable from the groundwater supply pipe 120.

3, the first filtration unit 123 may include a pair of meshes 124 that are fixed on the inner circumferential surface of the groundwater supply pipe 120 and are spaced apart from each other, And a filter member 125 filled in the space between the meshes 124 of the filter member 125. At this time, the pair of meshes 124 may be engaged with the fixing jaws 130 whose edges are fixed to the inner circumferential surface of the groundwater supply pipe 120, and may be fixed to the inner circumferential surface of the groundwater supply pipe 120 So that separation can not be made.

In the embodiment of the present invention, the filter member 125 may be a variety of filters capable of filtering foreign matters such as activated carbon, plastic spheres, ceramic balls, fiber bundles, etc., and if foreign matter contained in ground water can be filtered, Other materials and structures are also applicable.

On the other hand, the life of the filtration member 125 is not semi-permanent, and there is a situation in which it is necessary to replace the filtration member 125 with a new one at a proper time in proportion to a predetermined time period or a foreign matter treatment time of the groundwater.

In the embodiment of the present invention, as shown in FIG. 4 and FIG. 5, an open structure of the groundwater supply pipe 120 is further provided so that the operator can replace the first filtering means 123.

Specifically, the area of the groundwater supply pipe 120 provided with the first filtering unit 123 is connected to the first groundwater supply pipe 131 and the first groundwater supply pipe 131, which are disposed on the lower side, And a second groundwater supply line 132 that is coupled to the first groundwater supply line. 4, when the first filtration means 123 is replaced or repaired, the operator hinges the second groundwater supply pipe 132 upward to rotate the mesh 124 All of the coupling members of the filtration member 125 are taken out and replaced with new ones (corresponding to the former case of the two cases described above), or only the filtration member 125 is taken out and replaced with a new one In the latter case). Here, it is preferable that a separate sealing member (not shown) is additionally provided at a mutual connection portion between the first groundwater supply pipe 131 and the second groundwater supply pipe 132, and the second groundwater supply pipe 132, Can be coupled to the first groundwater supply pipe 131 through a latching and latching coupling structure, a magnet coupling structure, etc., and if necessary, the coupling structure is released and hinged as described above.

Next, the second filtration unit 129 not only prevents the backflow of foreign matter that can be retained in the storage tank 110 into the groundwater supply pipe 120 during backwash described later, but also prevents the water level of the groundwater tank 100 In a special case of excessively rising, foreign matter in the groundwater discharged to the upper end of the bending pipe 120c is filtered. For example, the filter may be applied to a mesh structure. However, the present invention is not limited thereto. And the like.

1, 6 and 7, in the embodiment of the present invention, the direction of the supply of the groundwater to the inside of the storage tank 110 is determined based on the direction of the groundwater supplied to the first filtration means 123 of the groundwater supply pipe 120 And a hinge door 133 is provided at the rear side.

The hinge door 133 is hingably rotatable on an upper area of the groundwater supply pipe 120 so as to open and close the inside of the groundwater supply pipe 120 with respect to the inner space of the storage tank 110. In the embodiment of the present invention, the hinge door 133 may have the same specific gravity as water or may be made of a material similar in level to water.

Specifically, the hinge door 133 includes a first door portion 134 hinged to the opening 120a of the groundwater supply pipe 120, and a second door portion 134 connected to the end of the first door portion 134, And a second door portion 135 provided to have a relatively thin thickness as compared with the first door portion 134.

The groundwater supply pipe 120 is provided with a latching jaw 136 so that the step of the hinge door 133, that is, the connection of the first door portion 134 and the second door portion 135, The upper surface (upper side in the figure) of the first door portion 134 and the second door portion 135 is connected to the groundwater supply pipe 120 without being hingedly rotated by the hinge door 133, And the lower surface (the lower surface in the drawing) of the first door portion 134 is exposed to the inside of the groundwater supply pipe 120. [

6, when the fluid level stored in the storage tank 110 is located below the groundwater supply pipe 120, specifically, the horizontal pipe 120b, the groundwater flowing along the horizontal pipe 120b The hinge door 133 is hinged upward by the flow pressure and then enters the storage tank 110 through the opening 120a of the horizontal pipe 120b.

The supply of the ground water is continued for a predetermined period of time and the fluid level stored in the reservoir 110 is supplied to the groundwater supply pipe 120, that is, the groundwater supply pipe 120 provided above the horizontal pipe 120b, specifically, The groundwater flowing along the groundwater supply pipe 120 is also discharged through the opening 120a, as shown in Fig.

The hydraulic pressure is applied to the hinge door 133 when the fluid level stored in the storage tank 110 is located above the section of the groundwater supply pipe 120 provided with the hinge door 133. However, The area in which the fluid pressure P ₁ stored in the storage tank 110 acts on the hinge door 133 and the fluid pressure P ₂ flowing along the groundwater supply pipe 120 to the hinge door 133 act The hinge door 133 is hinged at an angle relatively smaller than the rotation angle as shown in FIG.

The area of the hinge door 133 in which the fluid pressure stored in the storage tank 110 acts is the sum of the upper surface areas of the first door portion 134 and the second door portion 135, An area where the fluid pressure flowing along the groundwater supply pipe 120 acts is a bottom area of the first hinge door 133. This is possible because the specific gravity of the hinge door 133 is equal to or similar to that of water.

Therefore, when the level of the fluid in the storage tank 110 is lower than a predetermined level, the hinge door 133 is hinged at a relatively large angle to form a flow path of the groundwater supply pipe 120. When the fluid level is above a certain level, It is rotated at a relatively small angle.

1, the management apparatus according to the embodiment of the present invention includes a groundwater supply pipe (not shown) for discharging part of the fluid in the storage tank 110 to the outside when the fluid level in the storage tank 110 exceeds the set reference range And a drain pipe 140 branched from the drain pipe 120.

The drain pipe 140 includes a first drain pipe 141 branched from the ground water supply pipe 120 and extending upward and a second drain pipe 142 bent to communicate with the upper end of the first drain pipe 141 . It is preferable that the second water pipe 142 is provided a certain distance below the water flow pipe 112 so that the fluid level stored in the water storage tank 110 is supplied to the flow pipe 112 and the second water pipe A part of the fluid in the storage tank 110 can be discharged to the outside through the first drain pipe 141 and the second drain pipe 142 sequentially through the ground water supply pipe 120. [

At this time, in the present invention, the first and second filtration means 129 may be backwashed by the fluid flowing back through the groundwater supply pipe 120, and the first and second filtration means The foreign matter attached to the surface of the filtration member 125 is removed from the surface of the filtration member 125 by the flow pressure of the backwash water and then the first and second water pipes 141 and 142 To be discharged to the outside.

Meanwhile, in the embodiment of the present invention, the bending pipe 120c is provided so as to be bent upward with respect to the horizontal pipe 120b, and the backwash water flows into the bending pipe 120c through the upper end of the bending pipe 120c. The upper end portion of the pipe 120c is disposed in the central region on the basis of the height direction in the storage tank 110 so that the foreign matter remaining on the fluid surface stored in the storage tank 110 and the sludge particles, Can be further prevented from being adversely influenced through the upper end portion. That is, the present invention has an advantage that backwashing can be performed through purified water.

Hereinafter, the operating state of the management apparatus according to the first embodiment of the present invention will be described.

8, when the level difference between the groundwater level in the groundwater tank 100 and the fluid level stored in the storage tank 110 occurs, specifically when the groundwater level is greater than the fluid level, The groundwater in the groundwater tank 100 flows into the storage tank 110 along the groundwater supply pipe 120 due to the difference in the level of the water level.

When the fluid level stored in the storage tank 110 is located below the groundwater supply pipe 120, that is, the horizontal pipe 120b during the generation of the groundwater flow, the flow of the fluid along the horizontal pipe 120b The groundwater is hinged upward by the hinge door 133 by flow pressure and then enters the storage tank 110 through the opening 120a of the horizontal pipe 120b.

The supply of the groundwater is continued for a certain period of time and the fluid level stored in the storage tank 110 is lower than the groundwater supply pipe 120, that is, above the horizontal pipe 120b, specifically the groundwater supply pipe 120 provided with the hinge door 133 The groundwater flowing along the groundwater supply pipe 120 rotates at a relatively small angle to form a groundwater supply channel.

As shown in FIGS. 9 and 10, when the groundwater inflow is continued for a certain period of time and the water flows into the reservoir 110 over a predetermined amount, the fluid level in the reservoir 110 continuously rises and flows to the drain pipe 140 The fluid in the storage tank 110 flows into the groundwater supply pipe 120 (or 120) according to the difference between the fluid level stored in the storage tank 110 and the second drain pipe 142. In this case, And the drain pipe 140, and is discharged. At this time, the fluid that flows back into the groundwater supply pipe 120 in the storage tank 110 backwashes the first and second filtration means 129 to discharge the foreign matter remaining on the surface of the filtration member to the drain pipe 140 side . That is, according to the fluid level fluctuation in the storage tank 110, the first and second filtration means 129 are backwashed without additional power to further increase the replacement period of the first and second filtration means 129 .

Meanwhile, the discharge of backwash water into the drain pipe 140 may occur even when a certain amount of stormwater flows into the storage tank 110 through the storm inflow pipe 111 and the water level in the storage tank 110 rises. Of course.

Although the case where the ground water is supplied into the storage tank 110 only through the opening of the horizontal pipe 120b has been described above, the present invention is not limited thereto, and the water level in the groundwater tank 100 may be significantly The groundwater may be simultaneously discharged to the upper discharge end of the opening 120a and the upper discharge end of the bending pipe 120c when the discharge pipe 120a is positioned higher than the upper end of the bending pipe 120c.

If the groundwater level stored in the underground water tank 100 is relatively lower than the upper discharge end of the bending pipe 120c and the hinge door 133 and the opening 120a are not provided in the embodiment of the present invention, The inflow of groundwater into the water tank 110 becomes difficult. Accordingly, in the present invention, by providing the hinge door 133 and the opening 120a in the horizontal pipe 120b, groundwater can be introduced into the storage tank 110 even when the groundwater level in the groundwater tank 100 is relatively low There is an advantage to be able to.

FIG. 11 is a sectional view showing a state in which first filtration means is applied in the groundwater and well water management apparatus according to the second embodiment of the present invention. FIG. 12 is a cross- Fig.

Hereinafter, a description will be given of a management apparatus according to a second embodiment of the present invention, and repetitive description of the same configuration as that of the first embodiment described above will be omitted. In the same drawing, do.

11 and 12, in the management apparatus according to the second embodiment of the present invention, the first filtration unit 223 may have a structure in which a plurality of funnels 226 are bundled.

In the second embodiment of the present invention, the section where the first filtration means 223 of the groundwater supply pipe 220 is disposed is tapered, and a plurality of funnels 226 are provided in the tapered inner region. The plurality of funnels 226 are preferably arranged so as to be in close contact with the inner surface of the tapered groundwater supply pipe 220 without forming gaps therebetween. Therefore, the groundwater supply pipe (s) The groundwater flowing into the storage tank 220 is allowed to flow into the storage tank 110 (see FIG. 1) after passing through a plurality of funnel bundles 226.

Each of the plurality of funnels 226 includes a first opening 227 provided at one end thereof and having a relatively largest opening area and a second opening 228 provided at the other end thereof and having the smallest opening area, The foreign matter may be caught between the first opening 227 and the second opening 228 or the second opening 228 while flowing through the bundle of the funnels 226 to restrict the inflow to the storage tank side. Accordingly, it is preferable that the second openings 228 of the plurality of funnels 226 are formed to have an opening area smaller than a predetermined size so as to filter foreign materials having a predetermined size or smaller.

In the second embodiment of the present invention, a plurality of funnels 226 may be integrally fixed to the groundwater supply pipe 220. Alternatively, as described in the first embodiment, The groundwater supply pipe 220 may be formed as a second groundwater supply piping structure that is hingedly coupled to the first groundwater supply pipe and the first groundwater supply pipe so that the second groundwater supply pipe may be rotated, The bundle 226 may be replaced with a new one.

13 is a view showing a groundwater and stormwater management apparatus according to a third embodiment of the present invention.

Hereinafter, a description will be given of a management apparatus according to a third embodiment of the present invention, and repetitive description of the same configuration as that of the first embodiment described above will be omitted. In the same drawing, do.

13, the management apparatus according to the third embodiment of the present invention includes a first level sensor 350 for detecting a groundwater storage level stored in the groundwater tank 300, A high pressure spraying unit 352 for spraying at least one of air and water into the groundwater supply pipe 320 from the outside of the storage tank 310 at a high pressure, The control unit 355 receives the detection values of the first level sensor 350 and the second level sensor 351 and controls the driving of the high pressure spray unit 352.

The first level sensor 350 detects the groundwater storage level stored in the groundwater tank 300 and the second level sensor 351 detects the fluid storage level stored in the storage tank 310, , An ultrasonic level sensor, a capacitive level sensor, or the like.

Next, the high-pressure spraying section 352 is provided to spray at least one of air and water into the groundwater supply pipe 320 at a high pressure. For example, high-pressure air or water is sprayed to the groundwater supply pipe 320 The clogged state of the first and second filtration means 323 and 329 can be released.

The high-pressure spraying unit 352 is capable of spraying air at a high pressure. The high-pressure spraying unit 352 includes a compressed air tank (not shown), a channel for flowing compressed air in the compressed air tank, A high pressure injection pipe 353 partially inserted into or located in the vicinity of the high pressure injection pipe 353 and a control valve 354 provided on the high pressure injection pipe 353 for adjusting the opening degree.

In addition, as another example, the high-pressure spraying section 352 capable of spraying water at a high pressure is provided with a water tank (not shown) in which water is stored, a flow path that allows water stored in the water tank to flow, A high pressure injection pipe 353 which is partially inserted into or located in the vicinity of the high pressure injection pipe 353 and a high pressure injection pipe 353 which is provided on the high pressure injection pipe 353 to pressurize and discharge water at a high pressure, And a regulating valve 354 provided on the regulating valve 352 to regulate the opening degree.

In the third embodiment of the present invention, the controller 355 receives the detection values of the first level sensor 350 and the second level sensor 351 and controls the driving of the high-pressure sprayer 352.

Meanwhile, when the inflow of groundwater from the groundwater tank 300 to the storage tank 310 is maintained for a predetermined time in a state where there is no inflow to the storage tank 310, the level of the groundwater tank 300 and the storage tank 310 are equal to each other . When the level of each level is the same, the groundwater flow stops because there is no level difference between the groundwater tank 300 and the storage tank 310.

In the third embodiment of the present invention, the control unit 355 receives the detection values of the first level sensor 350 and the second level sensor 351 in the above-described situation, It is determined that at least one of the second filtration means 323 and 329 is clogged to some extent and the high pressure spraying section 352 is driven to spray high pressure water or air toward the first and second filtration means 323 and 329, It is possible to remove the clogged state by removing the foreign substance.

14 is a view showing a groundwater and stormwater management apparatus according to a fourth embodiment of the present invention.

Hereinafter, a description will be given of a management apparatus according to a fourth embodiment of the present invention, and repeated description of the same configuration as that of the first embodiment described above will be omitted. In the same drawing, do.

14, in the management apparatus according to the fourth embodiment of the present invention, the fluid in the storage tank 400 is supplied to the discharge end of the groundwater supply pipe 420 after the flow direction is switched in the vicinity of the discharge end, The cap 437 is further provided to be able to flow back into the supply pipe 420.

As described in the first embodiment of the present invention, micro-foreign substances introduced into the storage tank 400 may float on the surface of the fluid stored in the storage tank 400, So that the sludge layer can be formed by accumulating the foreign matter (foreign matter having a specific gravity larger than water)

In such a situation, when a situation occurs in which the fluid stored in the storage tank 400 flows backward along the groundwater supply pipe 420 and the drain pipe 440 due to the continual influx of the storm, etc., in the fourth embodiment of the present invention, A cap 437 is provided to prevent fine foreign matter floating on a fluid water surface and sludge particles stacked on the bottom from flowing back through the groundwater supply pipe 420.

The cap 437 is provided at the discharge end of the groundwater supply pipe 420 so that the fluid in the reservoir 410 can be reversely introduced into the groundwater supply pipe 420 after the flow direction is switched in the vicinity of the discharge end, Thereby preventing the fluid located on the upper side of the fluid level in the groundwater supply pipe 420 from flowing into the groundwater supply pipe 420. In addition, in the fourth embodiment of the present invention, only the fluid located in the middle area in the height direction of the approximately reservoir 410 through the cap 437 flows back into the groundwater supply pipe 420, Can be used as backwash water.

15 is a view showing a groundwater and stormwater management apparatus according to a fifth embodiment of the present invention.

Hereinafter, a description will be given of a management apparatus according to a fifth embodiment of the present invention, and repetitive description of the same configuration as that of the first embodiment described above will be omitted. In the same drawing, do.

As shown in Fig. 15, in the management apparatus according to the fifth embodiment of the present invention, the bottom surface of the storage tank 510 is formed to be inclined downward to one side.

Meanwhile, even if the foreign matter is filtered through the first and second filtration means 523 and 529 while the groundwater flows along the groundwater supply pipe 520, the foreign matter having relatively small particles, such as fine particles, To some extent. When the groundwater inflow into the storage tank 510 and the inflow of the fine water into the storage tank 510 are stopped for a long time and the discharge of the fluid for use of the fluid is also stopped, .

In the fifth embodiment of the present invention, the bottom surface of the storage tank 510 may be inclined to one side so that the sludge particles are moved to one side along the bottom inclined surface of the storage tank 510 and stacked on the lowest point area. A sludge discharging means 560 for discharging the sludge stacked on the bottom surface to the outside can be provided so that the sludge deposited on the bottom of the storage tank 510 can be discharged more easily.

The sludge discharge means 560 includes a sludge discharge pipe 561 extending from the outside of the storage tank 510 to the bottom side and a sludge discharge pump 562 connected to the sludge discharge pipe 561 and installed on the bottom of the storage tank 510 . ≪ / RTI >

The sludge discharging operation can be performed periodically at predetermined time intervals, and when the degree of stacking of the sludge is detected and it is ascertained that the sludge is stacked above the set reference amount, the sludge discharging operation may be performed.

15, an inner bottom surface of the storage tank 510 is provided with a plurality of optical sensors (not shown) for detecting whether the sludge remaining in the sludge is stacked, 563 may be provided. The control unit (not shown) receives the light sensing value of the optical sensor 563 and determines that the sludge is stacked to some extent when the current sensing value of the optical sensor 563 is less than the set reference range, (562) to discharge the sludge to the outside.

When the sludge is discharged after determining whether or not the sludge is stacked by the optical sensor 563, the sludge is discharged after the degree of stacking of the sludge is more accurately detected than when the sludge is periodically discharged. It is possible to maximize the work efficiency and increase the work efficiency.

16 is a view showing a groundwater and stormwater management apparatus according to a sixth embodiment of the present invention.

Hereinafter, a description will be given of a management apparatus according to a sixth embodiment of the present invention, and repetitive description of the same configuration as that of the first embodiment described above will be omitted, and the same reference numerals beginning with 600 in the related drawings are used do.

As shown in FIG. 16, in the case where sufficient groundwater can not be stored in the groundwater tank 600 installed at a position relatively close to the ground, the management apparatus according to the sixth embodiment of the present invention When the groundwater inflow is not smooth, the groundwater tank 600 is provided to further supplement the groundwater.

The management apparatus according to the sixth embodiment of the present invention includes a piercing pipe 670 provided under the groundwater tank 600 for collecting groundwater in the ground and a piercing pipe 670 connected to the piercing pipe 670 and the groundwater tank 600, And a groundwater supply pump 674 provided on the connection pipe 673. The groundwater supply pump 674 may be connected to the groundwater tank 600 through a connection pipe 673 and a groundwater supply pump 674.

The perforated pipe 670 is provided below the groundwater tank 600 to replenish the groundwater in a deep ground position with the groundwater tank 600 and has a plurality of groundwater inflow holes 671 on the outer surface thereof. The groundwater located in the ground deeper than the groundwater tank 600 through the groundwater inflow hole 671 flows into the oil pipe 670 and flows into the groundwater tank 600 through the connection pipe 673 do. Here, the connection pipe 673 is applicable to a structure in which a plurality of groundwater inflow holes (not shown) are provided on the surface like the oil pipe 670.

In the sixth embodiment of the present invention, a groundwater supply pump 674 is provided on the connection pipe 673 to supply the groundwater introduced into the oil pipe 670 to the groundwater tank 600 more quickly. In addition, a level sensor 672 for sensing the level of the groundwater in the oil pipe 670 may be further provided in the oil pipe 670. The control unit (not shown) receives the sensing value of the level sensor 672, If it is confirmed that the ground water is present in the oil pipe 670, the groundwater supply pump 674 can be driven to supply the groundwater to the groundwater tank 100 more quickly.

17 is a view showing a groundwater and stormwater management apparatus according to a seventh embodiment of the present invention.

Hereinafter, a description will be given of a management apparatus according to a seventh embodiment of the present invention, repetitive description of the same configuration as that of the first embodiment described above will be omitted, and the same reference numerals beginning with 700 in the related drawings are used do.

17, in the management apparatus according to the seventh embodiment of the present invention, the first filtration means 723 may have a pipe structure having flanges at both ends thereof.

The first filtration means 723 also includes a pipe body and a plurality of flow direction change walls 727 spaced apart from one another to switch a plurality of flow directions while the ground water passes through the pipe body.

Not only a plurality of such flow direction changing walls 727 are provided so as to be spaced apart from each other along the longitudinal direction of the pipe body, but also portions in contact with the pipe body are alternately changed. Specifically, as the flow direction changing wall 727 moves from the left side to the right side in the drawing, the contact portions are alternately changed in the upper, lower, upper, and lower portions of the pipe body, and groundwater is supplied to the inside of the first filtering means 723 During the flow, the flow direction is transformable a plurality of times.

In the seventh embodiment of the present invention, foreign matter that may be contained in the groundwater is filtered by converting a direction of the groundwater flow in the first filtration means 723 into pluralities. Specifically, the foreign matter flows into the flow direction conversion wall 727 And can be stacked on the bottom surface side of the pipe body.

The first filtration means 723 is provided at both ends with a flange structure. The groundwater supply pipe 720 can be coupled to and separated from each other through flange coupling using bolts, nuts, and the like. Accordingly, the operator can separate the first filtration means 723, clean the foreign matters deposited on the inside, and then re-install the foreign matter. Here, a separate sealing member (not shown) for preventing water leakage may be further provided at a connection portion between the first filtration unit 723 and the groundwater supply pipe 720.

Although the present invention has been described with reference to the accompanying drawings and the preferred embodiments described above, the present invention is not limited thereto but is limited by the following claims. Accordingly, those skilled in the art will appreciate that various modifications and changes may be made thereto without departing from the spirit of the following claims.

100: Groundwater tank 110: Storage tank
120: groundwater supply piping 123: first filtration means
129: second filtering means 133: hinged door
134: first door part 135: second door part
140: Water pipe 226: Funnel
350: first level sensor 351: second level sensor
352: high pressure spraying part 437: cap
560: Sludge discharging means 563: Light sensor
670: Pore tube 672: Level sensor
674: Groundwater supply pump

Claims (12)

It is installed in the ground to manage groundwater and stormwater.
Groundwater reservoir capable of storing groundwater;
A storage tank having a water storage space provided therein so as to receive and store rainwater separately from groundwater stored in the groundwater tank;
A groundwater supply pipe for supplying groundwater stored in the groundwater tank to the inside of the storage tank; And
And a drain pipe branched from the groundwater supply pipe to discharge a part of the fluid in the storage tank to the outside when the fluid level in the storage tank exceeds a set reference range,
Wherein the groundwater supply pipe is composed of a horizontal pipe and a bending pipe bent upward from an end of the horizontal pipe, groundwater in the groundwater tank flows into the storage tank through an opening formed in the horizontal pipe, The fluid in the storage tank flows back into the groundwater supply pipe through the upper end of the bending pipe,
A first filtration means and a second filtration means are provided in a part of the groundwater supply pipe disposed in the storage tank and at a discharge end portion of the groundwater supply pipe to filter foreign substances contained in the groundwater, The first filtration means or the second filtration means is backwashed while flowing back through the groundwater supply pipe and the drain pipe,
A hinge door that is hinged on a rear side of the first filtering unit of the groundwater supply pipe to open and close the inside of the groundwater supply pipe to the inner space of the storage tank based on a direction in which groundwater is supplied into the storage tank Wherein the hinge door further comprises: a first door part hingably coupled to an opening of the groundwater supply pipe; And a second door part connected to an end of the first door part, the second door part having a relatively thin thickness compared to the first door part. delete delete The method according to claim 1,
Wherein the first filtration means has a structure in which a filtration member is filled in the mesh. The method according to claim 1,
Wherein the first filtration means comprises a structure in which a plurality of funnel bundles are stacked. The method according to claim 1,
Wherein the first filtration means comprises a pipe body and a plurality of flow direction change walls spaced apart from one another to switch a plurality of flow directions while the ground water passes through the pipe body. . delete delete The method according to claim 1,
A first level sensor for detecting a groundwater level stored in the groundwater tank;
A second level sensor for detecting a fluid storage level stored in the storage tank;
A high pressure spraying part capable of spraying at least one of air and water into the groundwater supply pipe from the outside of the storage tank at a high pressure; And
Further comprising a controller receiving the detection values of the first level sensor and the second level sensor and controlling the driving of the high pressure injector. The method according to claim 1,
Wherein a cap is further provided in the discharge end of the groundwater supply pipe so that the fluid in the storage tank can flow back into the groundwater supply pipe after the flow direction is switched in the vicinity of the discharge end. The method according to claim 1,
Wherein the bottom surface of the storage tank is inclined downward to one side,
And a sludge discharging means for discharging the sludge stacked on the bottom surface of the storage tank to the outside. The method according to claim 1,
A pore pipe provided below the groundwater tank for collecting groundwater in the ground;
A connection pipe connecting the pore pipe and the groundwater tank to form a path for supplying groundwater in the pore pipe to the inside of the groundwater tank; And
And a groundwater supply pump provided on the connection pipe.

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