KR101323367B1 - Rainwater storage system for reduction of nonpoint source pollution - Google Patents

Abstract

PURPOSE: A rainwater storage device for reducing nonpoint pollution sources is provided to separate a precipitate by generating vortex in rainwater and to filter foreign materials from the rainwater with a filter unit, thereby storing clear rainwater. CONSTITUTION: A rainwater storage device for reducing nonpoint pollution sources comprises a rainwater supply part (200), a vortex unit (300), and a filter unit (400). The rainwater supply part supplies rainwater to be treated. The vortex unit generates vortex by guiding the flow of the rainwater supplied by the rainwater supply part. The vortex unit comprises a first vortex generating unit with a first passage; and a screen part installed in the first passage. The filter unit filters foreign materials from the rainwater passing the vortex unit. The filter unit comprises a second vortex generating unit with a second passage; and multiple filter members charged in the second passage.

Description

Rainwater storage system for reduction of nonpoint source pollution

The present invention relates to a non-point source reduced rainwater storage device, and more particularly, to a non-point source reduced rainwater storage device that collects and stores rainwater filtered through a nonpoint source.

Rainwater storage tanks are installed to collect rainwater during rainy weather as an alternative to solve problems caused by water shortages. To this end, the storm storage tank is formed in the form of a cylinder having a predetermined volume, and one side of the storm storage tank is provided with a discharge port for discharging the stored rainwater.

Conventional rainwater storage tanks may be of a type that collects rainwater that has fallen to the bottom of a road, etc., depending on the form thereof, to form a reservoir, and a type of rainwater that falls directly into the air.

Among them, rainwater storage tanks having a type of rainwater collected on the bottom are stored in the rainwater, and since rainwater contains a large amount of non-point pollutants, the water can be used only after a separate treatment process. That is, in the case of the conventional rainwater storage tank, a variety of filtration devices for filtering the non-point pollutants contained in the rainwater according to the type of rainwater is introduced.

On the other hand, in the case of rainwater storage tank of the type to receive the rainwater coming directly from the air is made of a structure in which the upper portion is open so that rainwater can be introduced. Therefore, there are problems such as falling leaves, etc. in the excellent storage tank, the drainage is clogged due to the fallen leaves.

The present invention was devised to improve the above problems, and generates a vortex in the inflow rainwater to separate the sediment, the non-point pollution source to filter and store the foreign matter suspended in the rainwater through the filtering means installed in the flow path of rainwater The purpose is to provide a mitigation reservoir.

The non-point source reducing rainwater storage device according to the present invention for achieving the above object is a spiral so as to generate a vortex by inducing the flow of rainwater supplied by the rainwater supply unit and the rainwater supply unit for processing the rainwater; A vortex unit having a first vortex generating portion having a first flow path, and a screen portion provided on the first flow path of the first vortex generating portion to filter foreign matter into the rainwater flowing by the first vortex generating portion; A second passage having a spiral second passage so as to be in communication with the first vortex generating unit so that the rainwater having passed through the first vortex generating unit can flow, and allow the rainwater passing through the first vortex generating unit to flow; A filtration unit provided with a vortex generating unit and a plurality of filter media filled in the second channel and adsorbing foreign matter contained in the rainwater flowing through the second channel; It is connected to a filtration unit, and a storage tank provided with a storage space to accommodate the solid has passed through the filtration unit therein.

The first vortex generating unit is formed with a first accommodating space for accommodating rainwater therein, a first outer passage provided with a first inlet communicating with the rainwater supply unit to allow the rainwater to flow into the first accommodating space; It is installed inside the first outer cylinder to be spaced apart from the inner circumferential surface of the first outer cylinder, the first opening is formed in the lower portion so that the rainwater received in the first accommodation space is introduced, the rainwater to the second vortex generating portion in the upper portion A first inner cylinder provided with a first discharge port for discharging gas, and is provided between the first outer cylinder and the first inner cylinder so that the spiral first channel is formed from the first inlet to the first opening. Preferably, the first guide member extends helically along the outer circumferential surface of the inner cylinder.

The screen unit is formed on the first guide member at positions spaced apart from each other along the flow direction of the rainwater passing through the first flow path, respectively, the rainwater is passed through the upper and lower so that the foreign matter contained in the rainwater can be filtered out A plurality of filter portions provided with a plurality of first through holes penetrated in the direction, and the first guide member behind the filter portion based on the flow direction of the rainwater passing through the first flow path, respectively; And a plurality of blocking plates protruding upward from the first guide member to guide the rainwater to pass through the manure portion.

The blocking plate has one end adjacent to the inner circumferential surface of the first outer cylinder based on the flow direction of the rainwater passing through the first flow path so that vortices can be generated in the flow of rainwater near the filter part. It is formed to be curved to be located in front of the other end adjacent to the outer peripheral surface of the.

At this time, the screen portion is installed inside the first inner cylinder between the first opening and the first outlet, the rainwater flowing into the first inner cylinder passes, but a plurality of the foreign matter contained in the rain to filter It may be further provided with a foreign matter removal net formed with a second through-hole.

The second vortex generator is provided with a second inlet, one end of which communicates with the other end of the communication tube connected to the first vortex generator so that the first vortex generator can communicate with the first vortex generator through the communication tube. The second outer passage formed with a second accommodation space to accommodate the rainwater introduced through the, is installed in the second outer cylinder spaced from the inner peripheral surface of the second outer cylinder, rainwater accommodated in the second accommodation space can be introduced The second opening is formed in the lower portion so that the second inlet is formed so that the rainwater introduced through the second opening on one side is discharged to the storage tank, from the second inlet to the second opening A second guide member installed between the second outer cylinder and the second inner cylinder so that the second flow path filled with the filter medium is formed and spirally extending along the outer circumferential surface of the second inner cylinder; .

The second vortex generator is formed on the second guide member at positions spaced apart from each other along the flow direction of the rainwater passing through the second flow path, and the rainwater passes through the foreign matter contained in the rainwater. It further comprises a plurality of mesh portion provided with a plurality of third through holes penetrated in the vertical direction.

Preferably, the mesh portion is formed in the second guide member at a position spaced apart along the flow direction of the rainwater from an opposite portion of the second guide member facing the adjacent mesh portion.

The second vortex generating unit is provided with the second rear portion of the mesh unit based on the flow direction of the rainwater passing through the second passage to prevent the filter medium filled in the second passage from flowing into the second inner cylinder. Each of the two guide members may further include a plurality of prevention plates protruding upward from the second guide member.

The rainwater supply unit communicates with the inflow pipe into which the rainwater collected from the outside flows into the inflow pipe, and when the flow rate of the rainwater flowing through the inflow pipe is smaller than a predetermined value, the rainwater flows through the outflow pipe. When discharged to the outside, the flow rate of the rainwater flowing through the inlet pipe is more than a predetermined value, it is preferable to have an initial excellent exhaust unit for supplying the rainwater to the first vortex generating unit.

The initial excellent drainage unit has one end connected to communicate with the inflow pipe, and a first flow path through which the rainwater flowing from the inflow pipe flows is provided therein, and at the other end, the outflow to communicate with the first flow path. The pipe is connected, but the lower outer peripheral surface is connected to the main tube formed with an outlet port so that the rainwater can be discharged to the first vortex generating unit, the upper end is in communication with the outlet, extending a predetermined length downward, the outlet inside A second flow path is formed to allow the rainwater discharged through the inlet to flow in, and a lower end thereof is connected to the first flow path of the first vortex generating unit through a connecting pipe, and is installed in the sub pipe. A closing plate formed so that the inflow hole penetrates in the vertical direction so that the rainwater introduced into the sub pipe flows into the connection pipe, and opens and closes the inflow hole of the closing plate. It is installed in the sub-pipe, and has a buoy floating in the rainwater flowing into the main pipe, and connected to the buckle, opening and closing plate for opening and closing the inlet hole by lifting up and down by buoyancy generated by the buckle The opening and closing part is provided.

The opening and closing portion is opposed to the sliding groove so that the opening and closing portion can be inserted into a sliding groove extending on the inner circumferential surface of the sub pipe so as to correspond to the movement trajectory of the opening and closing plate which is lifted and lowered by the buoy to guide the lifting and lowering of the opening and closing plate. It is preferable to further include an insertion bar protruding in the direction on the inner circumferential surface of the sub-pipe on the outer circumferential surface of the opening and closing plate in the position.

The opening and closing portion may further include an elastic member installed between the inner circumferential surface or the closing plate of the sub pipe and the opening and closing plate to elastically bias the opening and closing plate in a direction adjacent to the inflow hole.

The initial excellent drainage unit further includes a water level control unit to increase the water level near the outlet, inside the main pipe, and the water level control unit is based on the flow direction of the rainwater flowing through the flow path. The first control plate is installed in the main pipe in front of the front, and the rainwater introduced through the inlet pipe is formed with a first drain port so that the rainwater and the outlet pipe flows, and the rainwater flowing through the flow path A second drainage port is installed inside the main pipe rearward with respect to the outlet port based on a flow direction, and a second drain hole is formed so that the rainwater introduced through the first drain hole is discharged to the outlet pipe. The second drain is provided with a second control plate formed in a smaller size than the first drain so that the water level in the interior can be increased .

Non-point source reducing rainwater storage device according to the present invention can generate a vortex in the collected rainwater to separate the sediment, and by filtering the foreign matter suspended in the rainwater through the filtering means installed in the flow path of rainwater can be stored more clean rainwater There is an advantage.

1 is a cross-sectional view of the non-point source reduced rainwater storage device according to an embodiment of the present invention,
2 is a cross-sectional view of the non-point source reduction storm storage device of FIG.
3 is a plan view of the non-point source reduction excellent storage device of FIG.
4 is a perspective view of the vortex unit of the non-point source reduction storm storage device of FIG.
5 is a perspective view of the filtration unit of the non-point source reduction storm storage device of FIG.
FIG. 6 is a perspective view of the rainwater supply unit of the non-point source reducing rainwater storage device of FIG. 1;
7 is a perspective view of the rainwater supply unit of the non-point source reduction rainwater storage device according to another embodiment of the present invention,
8 is a cross-sectional view of the rainwater supply unit of the non-point source reduction stormwater storage device according to another embodiment of the present invention,
9 is a cross-sectional view of the rainwater supply unit of the rainwater source reduced rainwater storage device according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in more detail non-point source reduction excellent storage device according to a preferred embodiment of the present invention.

1 to 6 shows a non-point source reduction excellent storage device 100 according to the present invention.

Referring to the drawings, non-point source reduction rainwater storage device 100 is a storm supply unit 200 for supplying the rainwater to be treated, and the vortex unit to induce the flow of rainwater supplied by the stormwater supply unit 200 to generate a vortex 300 and a filtering unit 400 for collecting rainwater that has passed through the vortex unit 300 to filter foreign matter contained in the rainwater.

The rainwater supply unit 200 communicates with the inflow pipe into which the rainwater collected from the outside flows into the inflow pipe, and when the flow rate of the rainwater introduced through the inflow pipe is smaller than a predetermined value, the rainwater discharge pipe ( Discharge to the outside through the 224, and if the flow rate of the rainwater introduced through the inlet pipe is more than a predetermined value is provided with an initial excellent drainage unit 220 for supplying rainwater to the vortex unit 300.

The initial excellent excretion unit 220 includes a main pipe 221, a sub pipe 222, and a pipe determination unit 230.

One end of the main pipe 221 is connected to the inlet pipe, extends horizontally with respect to the ground in the left and right directions, and is formed to have a rectangular cross section. The main pipe 221 is provided with a first flow path 239a through which rainwater flowing from the inlet pipe flows, and the outlet pipe 224 is connected to the other end so as to communicate with the first flow path 239a. . In addition, the main pipe 221 has an outlet 238 formed on the lower outer circumferential surface so that the rainwater can be discharged to the first generator. Meanwhile, in the illustrated example, the main tube 221 has been described to have a rectangular cross section, but the main tube 221 is not limited to the illustrated example but may have a circular or elliptical cross section.

The upper end is installed in the main pipe 221 so as to communicate with the outlet 238, the predetermined length is extended downward, and the second flow path (239b) so that the rainwater discharged through the outlet 238 is introduced therein. Is formed. The lower end is connected to the first outer cylinder 311 of the first vortex generating unit 310 to be described later through a connecting pipe.

The pipe determining tube is configured to selectively introduce rainwater into one of the outlet 238 and the inlet, according to the flow rate of the rainwater flowing through the inlet pipe, and the first and second gates 231 and 232 and the water level sensor 233. And a gate driver 234 and a controller 235.

The first gate 231 opens and closes the outlet 238 and is rotatably installed on the bottom surface of the main tube 221 at a position adjacent to the outlet 238. The first gate 231 is larger than the outlet 238 so as to cover the outlet 238, and is formed in a fan shape.

The second gate 232 is rotatably installed at the rear of the outlet port 238 based on the rain flow direction in the main pipe 221, and the first flow path 239a of the main pipe 221 is rotated. It is formed to have a cross section corresponding to the cross section of the first flow path (239a) to close the.

The water level detection sensor 233 measures the water level in the main pipe 221 and is installed on the inner wall surface of the main pipe 221 at a position spaced upwards from the bottom surface of the main pipe 221 by a predetermined length of the main pipe 221. ) When the water level is higher than the installation position of the water level sensor 233, and transmits a detection signal to the controller 235 to be described later.

The gate driver 234 includes a first motor 236 installed on a rotation shaft of the first gate 231, and a second motor 237 provided on a rotation shaft of the second gate 232. The gate driver 234 drives the first and second gates 231 and 232 by the signal of the controller 235.

The control unit 235 detects the detection signal through the water level sensing sensor so that the second gate 232 closes the first flow path 239a so as to block the inflow of rainwater into the outlet pipe 224. In operation 237, the outlet 238 rotates the first gate 231 by operating the first motor 236 to open. If the detection signal is not detected through the water level sensor 233, the first gate 238 may be operated to close the outlet 238 by operating the first motor 236 to block the inflow of rainwater into the outlet 238. The second gate 232 is rotated by rotating the 231 and operating the second motor 237 to open the first flow path 239a to allow the rainwater to flow into the outlet pipe 224.

When the water level of the rainwater flowing into the main pipe 221 is lower than the preset value, the pipe determining unit 230 configured as mentioned above is determined to be the initial rainwater to the outside or the sewage treatment facility through the outflow pipe 224. When the water level of rainwater flowing into the main pipe 221 is greater than or equal to a predetermined value, the water flows into the vortex unit 300 through the outlet 238. Therefore, the initial rainwater containing a relatively large number of pollutants is introduced into the outside or sewage treatment facility through the outlet pipe 224, the remaining rainwater is stored in the storage tank 500 through the vortex unit 300 and the filtration unit 400. do.

The vortex unit 300 includes a first vortex generating unit 310 having a spiral first channel 318 and a first channel so as to induce a flow of rainwater supplied by the storm supply unit 200 to generate a vortex. And a screen portion 320 provided at 318.

The first vortex generator 310 includes a first outer cylinder 311, a first inner cylinder 312, and a first guide member 313.

The first outer cylinder 311 is formed in a cylindrical shape provided with a first accommodation space 314 to accommodate rainwater therein, the connection pipe so that the rainwater flows into the first accommodation space 314 from the rainwater supply unit 200 A first inlet 315 is formed to communicate with each other. At this time, the first inlet 315 is preferably formed on the upper outer peripheral surface of the first outer cylinder (311).

The first inner cylinder 312 is installed inside the first outer cylinder 311, and is formed in a cylindrical shape having an inner space therein. The first inner cylinder 312 is installed to be spaced apart from the inner circumferential surface of the first outer cylinder 311, it is preferably installed to be located in the central portion of the first outer cylinder 311.

The first inner cylinder 312 is formed so that the lower surface is opened so that the first opening 316 is provided in the lower portion so that the rainwater contained in the first outer cylinder 311 can be introduced into the inside, the first opening 316 It is preferable that the lower end portion extends to a length shorter than the vertical length of the first outer cylinder 311 so that the lower end portion is spaced upwardly from the bottom surface of the first outer cylinder 311 so as to easily flow into the rainwater.

In addition, the first inner cylinder 312 is provided with a first discharge port 317 for discharging rainwater to the second vortex generator 410 of the filtration unit 400 described later on the upper outer peripheral surface.

The first guide member 313 is disposed between the first outer cylinder 311 and the first inner cylinder 312 so that a spiral first passage 318 can be formed from the first inlet 315 to the first opening 316. It is installed, and extends helically along the outer circumferential surface of the first inner cylinder 312. At this time, the first guide member 313 is preferably formed to have a width as much as half the difference in the outer diameter of the first outer cylinder 311 and the second inner cylinder 412. Rainwater flows through the first flow path 318 formed by the first guide member 313, and the sediment contained in the rainwater is separated by the centrifugal force generated by the helical flow to separate the first outer cylinder 311. Precipitates to the inner circumferential surface and the bottom surface.

The screen part 320 is installed on the first flow path 318 and filters foreign matter in the rainwater flowing by the first vortex generating part 310, and includes a plurality of filtering parts 321 and a plurality of blocking plates ( 322).

The filtering part 321 is formed in each of the first guide members 313 spaced apart from each other along the flow direction of the rainwater passing through the first flow passage 318. The filter part 321 is formed in a mesh form in which a plurality of first through holes 324 are formed to pass through the upper and lower directions so that the rainwater passes downward, and the foreign matter contained in the rainwater is filtered. In addition, the filtering portion 321 is located at a position spaced apart along the direction of flow of the rain relative to the opposing portion of the first guide member 313 opposite to the adjacent filtering portion 321 so as to prevent the sequential arrangement in the vertical direction It is preferably formed.

The blocking plates 322 are respectively installed on the first guide member 313 behind the filter part 321 based on the flow direction of the rainwater passing through the first flow passage 318, and the rainwater is disposed on the filter part 321. It is formed to protrude upward from the first guide member 313 to guide the rainwater to pass. At this time, the blocking plate 322 is formed so as to close the first passage 318, one end adjacent to the inner peripheral surface of the first outer cylinder 311 is superior to the other end adjacent to the outer peripheral surface of the first inner cylinder 312. It is formed to be curved to be located forward with respect to the flow direction. Vortex is generated near the filter part 321 by the blocking plate 322 to improve the separation efficiency of foreign matter in the rainwater.

Preferably, the first guide member 313 is formed to correspond to a cross section of the first flow path 318.

On the other hand, the screen 320 is installed in the first inner cylinder 312 between the first opening 316 and the first discharge port 317 is passed through the rain, but the plurality of foreign matter contained in the rain to filter It is further provided with a foreign matter removal net 323, the second through-hole is formed. The foreign material removal net 323 is the upper surface is opened, the lower surface is closed, is formed in a cylindrical shape extending in the vertical direction, the upper end of the fixing projections to be fixed to the inner peripheral surface of the first inner cylinder 312 in the circumferential direction It is formed to protrude. The foreign material removal net 323 configured as mentioned above is preferably formed of a mesh structure provided with a plurality of second through holes.

Rainwater flowing into the first outer cylinder 311 through the connecting pipe flows helically along the first flow path 318 formed by the first guide member 313. Centrifugal force is generated by the spiral flow of rainwater, and the precipitate contained in the rainwater is separated and settled to the bottom surface of the first outer cylinder 311. Rainwater that passed through the first flow passage 318 is introduced into the first inner cylinder 312 through the first opening 316, the rainwater introduced into the first inner cylinder 312 is filtered unit through the first outlet 317 Discharged to 400. At this time, the rainwater introduced into the first inner cylinder 312 is filtered out of the foreign matter removal network 323 is again discharged through the first outlet 317.

The filtration unit 400 communicates with the first vortex generator 310 so that the rainwater that has passed through the first vortex generator 310 flows into the first vortex generator 310, and the rainwater that has passed through the first vortex generator 310 is doldol. The second vortex generator 410 having a spiral second passage 416 and the foreign matter contained in the rainwater that is filled on the second passage 416 and flows through the second passage 416 may be adsorbed. It is provided with a plurality of filter media (420).

The second vortex generator 410 includes a second outer cylinder 411, a second inner cylinder 412, a second guide member 413, a plurality of mesh portions 414, and a plurality of prevention plates 415.

The second outer cylinder 411 is formed in a cylindrical shape provided with a second accommodation space (411a) for receiving rainwater therein, so that the rainwater can flow from the second receiving space (411a) from the first inner cylinder 312 The second inlet 411b through which the communication tube 401 communicates is formed. At this time, one end of the communication tube 401 communicates with the first outlet 317 of the first inner cylinder 312, and the other end is installed to communicate with the second inlet 411b of the first outer cylinder 311. In addition, it is preferable that the second inlet 411b is formed on the upper outer peripheral surface of the second outer cylinder 411.

The second inner cylinder 412 is installed inside the second outer cylinder 411, and is formed in a cylindrical shape having an inner space therein. The second inner cylinder 412 is installed to be spaced apart from the inner circumferential surface of the second outer cylinder 411, it is preferable to be installed to be located in the central portion of the second outer cylinder 411.

The second inner cylinder 412 is formed so that the lower surface is opened so that the second opening 412a can be provided at the lower portion so that the rainwater contained in the second outer cylinder 411 flows into the inside, and the second opening 412a is formed. The lower end portion is preferably extended to a length shorter than the vertical length of the second outer cylinder 411 so as to be spaced upwardly from the bottom surface of the second outer cylinder 411 so that rainwater can be easily introduced.

In addition, the second inner cylinder 412 is formed with a second discharge port 412b to discharge the rainwater to the storage tank 500 on the upper outer peripheral surface. At this time, the discharge pipe 412c is installed in communication with the second discharge port 412b of the second inner cylinder 412, the discharge pipe 412c is formed to extend through the second outer cylinder 411 so that the end is exposed to the outside. .

The second guide member 413 is disposed between the second outer cylinder 411 and the second inner cylinder 412 so that a spiral second passage 416 can be formed from the second inlet 411b to the second opening 412a. It is installed, and extends helically along the outer circumferential surface of the second inner cylinder (412). At this time, the second guide member 413 is preferably formed to have a width as much as half the difference in the outer diameter of the second outer cylinder 411 and the second inner cylinder 412. Rainwater flows through the second flow path 416 formed by the second guide member 413, and the sediment contained in the rainwater is separated by the centrifugal force generated due to the helical flow to separate the second outer cylinder 411. Precipitates to the inner circumferential surface and the bottom surface.

The mesh part 414 is formed in each of the second guide members 413 spaced apart from each other along the flow direction of the rainwater passing through the second flow passage 416, and the rainwater passes through the foreign matter contained in the rainwater. It has a mesh structure provided with a plurality of third through holes 417 penetrating in the vertical direction to be filtered. The mesh portion 414 extends a predetermined length along the extending direction of the second flow passage 416. At this time, the mesh portion 414 is spaced apart along the flow direction of rain with respect to the opposing portion of the second guide member 413 opposite to the adjacent mesh portion 414 so as to be prevented from being sequentially arranged in the vertical direction It is preferably formed in.

The prevention plates 415 are respectively installed on the second guide member 413 behind the mesh part 414 on the basis of the flow direction of the rainwater passing through the second flow passage 416, and the rainwater prevents the mesh part 414. The rainwater may be guided to pass therethrough, and the filter medium 420 filled in the second flow passage 416 may protrude upward from the second guide member 413 to prevent the filter medium 420 from being separated from the second flow passage 416. In this case, the prevention plate 415 is preferably formed to correspond to the cross section of the second passage 416 formed by the second guide member 413 so as to close the second passage 416.

Rainwater flowing into the second outer cylinder 411 through the communication tube 401 flows helically along the second flow path 416 formed by the second guide member 413. Centrifugal force is generated by the spiral flow of rainwater, and the precipitate contained in the rainwater is separated again and settles on the bottom surface of the second outer cylinder 411. Rainwater passing through the second flow passage 416 flows into the second inner cylinder 412 through the first opening 316, the rainwater introduced into the second inner cylinder 412 is the storage tank (2) through the second outlet (412b) 500). At this time, the foreign matter contained in the rainwater is filtered again through the mesh portion 414 formed on the second guide member 413.

The filter medium 420 is filled in the second passage 416, and includes a cylindrical body 421 and a plurality of protruding members 422 protruding upward and downward on the upper and lower surfaces of the main body 421, respectively. The main body 421 is formed with a plurality of contact protrusions along the circumferential direction on the outer circumferential surface of the main body 421 so that foreign matter contained in the rainwater passing through the second passage 416 can be adsorbed, and a plurality of through holes penetrated in the vertical direction are formed. It is.

The protruding member 422 is formed in a cylindrical shape having an outer diameter smaller than the outer diameter of the main body 421, a plurality of contact protrusions are formed along the circumferential direction on the outer circumferential surface so that foreign matter contained in the rainwater can be easily adsorbed, A plurality of through holes penetrated in the vertical direction are formed. The filter media 420 configured as described above are suspended in the second flow passage 416 to adsorb and separate foreign matter contained in the rainwater.

The storage tank 500 is installed to communicate with the second inner cylinder 412 through the discharge pipe 412c communicated with the second discharge port 412b, the rainwater passing through the second inner cylinder 412 therein can be stored. The storage space 501 is provided so as to. At this time, the storage tank 500 is preferably installed so that the vortex unit 300 and the filtration unit 400 is introduced into the storage space 501 therein.

The non-point source reducing rainwater storage device 100 according to the present invention configured as described above generates vortices in the collected rainwater to separate sediment and separates the screen portion 320 and the filter medium 420 installed in the rainwater flow path. Through filtering the foreign matter floating in the rainwater is stored in the storage tank 500, there is an advantage that can be stored more clean rainwater.

On the other hand, Figure 7 is a pipeline determination unit 600 according to another embodiment of the present invention.

Elements having the same functions as those in the previous drawings are denoted by the same reference numerals.

Referring to the drawings, the pipe line determining unit 600 includes a closing plate 610 and the opening and closing portion 620.

The closing plate 610 is installed inside the sub pipe 222 above the connection portion with the connection pipe, the inlet hole 611 in the central portion so that rainwater introduced into the sub pipe 222 flows into the connection pipe. It is formed to penetrate in the vertical direction. The closing plate 610 is preferably formed of a disc having an outer diameter corresponding to the inner diameter of the sub pipe 222.

The opening and closing part 620 is installed in the sub-pipe 222 to open and close the inlet hole 611 of the closing plate 610, and includes a buckle 621, a rod 622 and the opening and closing plate 623.

Buoy 621 is installed in the sub-pipe 222, the buoyancy space is provided therein to be floating in the rainwater flowing from the main pipe 221. The float 621 moves up and down when the level of rainwater in the main pipe 221 rises, and falls down when it falls. The rod 622 is formed to extend a predetermined length in the vertical direction, the upper end is fixed to the lower surface of the buckle 621, the lower end is fixed to the opening and closing plate 623.

The opening and closing plate 623 is lowered by the buoyancy generated in the buoy 621 is fixed to the lower end of the rod 622 on the upper surface. The opening and closing plate 623 is formed in a disc shape having an outer diameter larger than the inner diameter of the inlet hole 611 to close the inlet hole 611 of the closing plate 610. In addition, a plurality of insertion bars 624 are formed on the outer circumferential surface of the opening and closing plate 623 to guide the lifting and lowering movement of the opening and closing plate 623. The insertion bars 624 are formed to protrude in the radial direction on the outer circumferential surface of the opening and closing plate 623 at positions opposite to each other based on the center of the opening and closing plate 623.

The insertion bars 624 are respectively inserted into the sliding grooves 625 formed on the inner circumferential surface of the sub pipe 222, and the sliding grooves 625 are respectively opposed to each other with respect to the center of the sub pipe 222. It is preferably formed to extend a predetermined length upward from the upper surface of the opening and closing plate 623.

When the initial rainwater is introduced, since the flow rate flowing into the main pipe 221 is not much, buoyancy enough to elevate the opening and closing plate 623 is not generated, so that the inlet hole 611 of the closing plate 610 is the opening and closing plate 623. ) To prevent rainwater from entering the connector. After the initial stage, a relatively large amount of rainwater flows in. At this time, the water level in the main pipe 221 rises, and the buoy 621 rises due to buoyancy. The opening and closing plate 623 is raised by the rising buoy 621 to open the inlet hole 611 of the closing plate 610 and is supplied to the vortex unit 300 through the rainwater pipe.

The pipe determination unit 600 configured as mentioned above opens and closes the inlet hole 611 according to the level of rainwater flowing into the main pipe 221, so that no additional power is required, thereby saving facility maintenance costs. have.

Meanwhile, FIG. 9 illustrates a pipe determination unit 700 according to another embodiment of the present invention.

Referring to the drawings, the pipe line determining unit 700 further includes a water level control unit 710 inside the main pipe 221 to increase the water level near the outlet 238. The water level control unit 710 includes first and second control plates 711 and 712.

The first control plate 711 is installed inside the main pipe 221 in front of the outlet 238 based on the flow direction of rainwater flowing through the first flow path (239a) in the main pipe 221, The first drain 713 is formed such that the rainwater introduced through the inlet pipe flows into the outlet 238 and the outlet pipe 224. The first control plate 711 is formed in a plate shape having a cross section corresponding to the cross section inside the main pipe 221, the first drain 713 is formed in the lower end of the first control plate 711.

The second control plate 712 is installed inside the main pipe 221 rearward with respect to the outlet 238, the second drain 714 so that the rainwater introduced through the first drain 713 is discharged to the outlet pipe 224. ) Is formed. The second control plate 712 is formed in a plate shape having a cross section corresponding to the cross section inside the main pipe 221, the second drain 714 is formed at the lower end of the second control plate 712. At this time, it is preferable that the second drain 714 is formed to have a smaller cross section than the first drain 713 so that the water level between the first and second control plates 711 and 712 can rise.

Since the water level near the outlet 238 is higher than the water level in the surrounding area by the water level control unit 710 configured as described above, a greater buoyancy acts on the buoy 621 to easily lift the opening and closing plate 623. There are advantages to it.

Meanwhile, FIG. 8 illustrates a pipe determination unit 800 according to another embodiment of the present invention.

Referring to the drawings, the pipe line determination unit 800 further includes an elastic member 801 which elastically biases the opening and closing plate 623 in a direction adjacent to the inflow hole 611. A plurality of fixing bars 802 are installed on the inner circumferential surface of the sub pipe 222 below the closing plate 610 to fix the elastic member 801. The fixing bars 802 are formed to protrude in the center direction of the sub pipe 222 on the inner circumferential surface of the sub pipe 222 at positions opposite to each other with respect to the center of the sub pipe 222.

A plurality of elastic members 801 is provided, the lower end is fixed to the end of the fixing bar 802, the upper end is penetrated through the inlet hole 611 is fixed to the lower surface of the opening and closing plate 623, the coil spring desirable. When the water level in the main pipe 221 is lowered, the opening and closing plate 623 is easily lowered by the elastic force of the elastic member 801 to close the inlet hole 611 of the closing plate 610.

Although the present invention has been described with reference to the embodiments illustrated in the drawings, these are merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments thereof are possible.

Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

100: excellent storage device for reducing non-point source
200: excellent supply
210: inlet pipe
220: initial excellent exclusion unit
300: Vortex Unit
310: first vortex generating unit
311: first external cylinder
312: first inner tube
313: first guide member
318: first euro
320: screen portion
321: filter
322: blocking plate
323: debris removal network
400: filtration unit
410: second vortex generator
411: second outer cylinder
412: second inner tube
413: second guide member
414: mesh portion
415: preventive plate
420: filter medium
500: reservoir

Claims (14)

A rainwater supply unit for supplying rainwater to be treated;
A first vortex generator having a spiral first flow path and a first flow path provided in the first vortex generating part so as to generate a vortex by inducing the flow of the rainwater supplied by the rainwater supply unit; A vortex unit having a screen portion for filtering foreign matter into the rainwater flowing by the vortex generator;
A second passage having a spiral second passage so as to be in communication with the first vortex generating unit so that the rainwater having passed through the first vortex generating unit can flow, and allow the rainwater passing through the first vortex generating unit to flow; A filtration unit provided with a vortex generating unit and a plurality of filter media filled in the second channel and adsorbing foreign matter contained in the rainwater flowing through the second channel;
And a storage tank connected to the filtration unit, and having a storage space provided therein to accommodate the rainwater passing through the filtration unit.
The first vortex generating unit
A first receiving space having a rainwater received therein and having a first inlet communicating with the rainwater supply unit so that the rainwater may flow into the first receiving space;
It is installed inside the first outer cylinder to be spaced apart from the inner circumferential surface of the first outer cylinder, a first opening is formed in the lower portion so that rainwater contained in the first accommodation space is introduced, the second vortex generating portion in the upper A first internal passage provided with a first outlet for rainwater to be discharged;
A first guide member disposed between the first outer cylinder and the first inner cylinder so as to form the spiral first channel from the first inlet to the first opening, and spirally extending along the outer circumferential surface of the first inner cylinder And
The screen unit
It is formed in the first guide member of each position spaced apart from each other along the flow direction of the rainwater passing through the first flow path, the rainwater passes through the upper and lower directions so that foreign matter contained in the rainwater can be filtered. A plurality of filter portions provided with a plurality of first through holes,
The first guide is installed on the first guide member behind the filter part based on the flow direction of the rainwater passing through the first flow path, and the first guide to guide the rainwater to pass the rainwater through the filter part. Non-point source reduction excellent storage device, characterized in that it comprises a plurality of blocking plates protruding upward from the member.
delete delete The method of claim 1,
The blocking plate has one end adjacent to the inner circumferential surface of the first outer cylinder based on the flow direction of the rainwater passing through the first flow path so that vortices can be generated in the flow of rainwater near the filter part. Excellent storage device for reducing non-point source pollution, characterized in that formed to be bent in front of the other end adjacent to the outer peripheral surface of the.
The method of claim 1,
The screen unit
The rainwater flowing into the first inner cylinder between the first opening and the first outlet is installed inside the first inner cylinder, but passes through the plurality of second through holes to filter foreign matter contained in the rainwater. Excellent storage device for reducing non-point source pollution, characterized in that it further comprises a foreign matter removal network is formed.
The method of claim 1,
The second vortex generating unit
A second inlet port is provided to communicate with the other end of the communication pipe connected to the first vortex generating unit so that the first vortex generating unit communicates with the first vortex generating unit, and the rainwater introduced through the second inlet inside A second outer passage having a second accommodation space accommodated therein;
It is installed inside the second outer cylinder to be spaced apart from the inner circumferential surface of the second outer cylinder, a second opening is formed in the lower portion so that rainwater contained in the second accommodation space is introduced, the inflow through the second opening portion A second inner passage in which a second discharge port is formed to discharge the rainwater to the storage tank;
A second passage formed between the second outer cylinder and the second inner cylinder to form the second passage through which the filter medium is filled from the second inlet to the second opening, and spirally extending along the outer circumferential surface of the second inner cylinder; Excellent storage device for reducing non-point source pollution, characterized in that it comprises two guide members.
The method according to claim 6,
The second vortex generating unit
Respectively formed in the second guide member at positions spaced apart from each other along the flow direction of the rainwater passing through the second flow path, and the rainwater passes through the upper and lower directions so that foreign matter contained in the rainwater can be filtered out. Non-point source reduction excellent storage device, characterized in that it further comprises a plurality of mesh portion provided with a plurality of third through holes.
The method of claim 7, wherein
The mesh part
Non-point source reduced rainwater storage device, characterized in that formed on the second guide member at a position spaced along the flow direction of the rainwater from the opposite portion of the second guide member facing the adjacent mesh portion.
The method of claim 7, wherein
The second vortex generating unit
In order to prevent the filter medium filled in the second channel from flowing into the second inner cylinder, the filter member is installed in the second guide member behind the mesh unit based on the flow direction of the rainwater passing through the second channel. The non-point source reduction excellent storage device further comprises a plurality of preventive plates protruding upward from the second guide member.
The method of claim 1,
The excellent supply unit
An inlet pipe into which the rainwater collected from the outside is introduced;
When the flow rate of the rainwater flowing through the inlet pipe is less than a predetermined value, the rainwater is discharged to the outside through the outlet pipe, the flow rate of the rainwater flowing through the inlet pipe Non-point source reduced rainwater storage device, characterized in that it comprises an initial excellent drainage unit for supplying the rainwater to the first vortex generating unit when the predetermined value or more.
The method of claim 10,
The initial excellent exclusion unit
One end is connected in communication with the inlet pipe, a first flow path through which the rainwater flowing from the inlet pipe flows is provided, and the other end is connected to the outlet pipe to communicate with the first flow path, An outer circumferential surface of the main pipe formed with an outlet so that the rainwater can be discharged to the first vortex generating unit;
An upper end is connected in communication with the outlet, and a predetermined length extends downward, and a second flow path is formed to allow the rainwater discharged through the outlet to enter therein, and a lower end of the first vortex through a connecting pipe. A sub pipe connected in communication with the first channel of the generating unit;
A closing plate installed inside the sub pipe, the inlet hole penetrating in the vertical direction such that the rainwater introduced into the sub pipe flows into the connection pipe;
Opening and closing the inlet hole of the closing plate, is installed in the sub-pipe, connected to the buoy floating in the rainwater flowing into the main pipe, and connected to the buckle, the elevating by the buoyancy generated by the buckle Excellent storage device for reducing non-point source pollution, characterized in that it comprises an opening and closing portion having an opening and closing plate for opening and closing the inlet hole.
12. The method of claim 11,
The opening /
A position opposite to the sliding groove so that the sliding groove may be inserted into a sliding groove extending to the inner circumferential surface of the sub pipe to correspond to the movement trajectory of the opening and closing plate which is lifted and lowered by the buoy to guide the lifting and lowering of the opening and closing plate. Non-point source reduction excellent storage device, characterized in that further comprising an insertion bar protruding in the direction on the inner peripheral surface of the sub-pipe on the outer peripheral surface of the opening and closing plate.
12. The method of claim 11,
The opening /
The non-point source reduction excellent storage device further comprises an elastic member installed between the inner circumferential surface or the closing plate of the sub pipe and the opening and closing plate to elastically bias the opening and closing plate in a direction adjacent to the inflow hole.
12. The method of claim 11,
The initial excellent drainage unit is further provided with a water level control unit in the main pipe to increase the water level near the outlet,
The water level control unit
The rainwater flowing through the first flow path is installed inside the main pipe in front of the outlet, and the rainwater introduced through the inlet pipe is introduced into the outlet and the outlet pipe. A first throttle plate formed with a drainage port,
It is installed inside the main pipe to the rear with respect to the outlet port based on the flow direction of the rainwater flowing through the first flow path, the second rain so that the rainwater introduced through the first drain is discharged to the outlet pipe. The non-point source reduction excellent storage device, characterized in that the drain is formed, the second drain is provided with a second control plate having a smaller size than the first drain so that the water level in the main pipe near the outlet can be increased.

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