KR101923707B1 - Apparatus for nonpoint pollutants treatment and stormwater detention - Google Patents

Abstract

The present invention relates to a road surface boundary stover having an opening through which a rainwater flowing on an upper surface of a road flows, a branching valve for guiding the rainwater introduced through the opening to any one of a sewage pipe, The control unit directs the rainwater to the sewage pipe when the rainfall is good, and after the lapse of the first time, the branching valve guides the rainwater to the planting soil, and after the lapse of the second time, the branching valve controls the rainwater to be led to the rainwater pipe Lt; RTI ID = 0.0 > non-point < / RTI >

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a non-point pollution reducing apparatus,

The present invention relates to a non-point pollution abatement and stormwater storage apparatus, and more particularly, to a method of treating rainwater discharged from a road during rainfall and a non-point pollution abatement will be.

As the urbanization progresses rapidly, the area of impervious surface where the surface of the earth is covered with asphalt or concrete is rapidly increasing. This increase in the impervious area leads to the depletion of groundwater and consequent distortion of the water circulation system by blocking the inflow of rainwater into the underground, while increasing the inundation of the urban center in conjunction with sudden heavy rainfall due to the recent climate change . In addition, pollutants that are mixed with rainwater during rainfall are discharged into rivers along with rainwater, and thus the problem of environmental pollution is also serious.

In order to solve this problem, Korean Patent Registration No. 1639379 (hereinafter referred to as "Prior Patent 1"), Korean Patent Publication No. 2012-0006715 (hereinafter referred to as "Prior Patent 2"), 1322622 (hereinafter referred to as "Prior Patent 3") and the like.

The prior patent 1 is proposed to overcome the inefficiency problem of installation of road structures and the inefficiency problem of pollutant removal in existing prior patents 2 and 3, The efficiency of removing pollutants is not high because the filter is installed in the structure and the pollutant is removed by using it. Also, since the structure according to the above-mentioned Patent 1 is stored in the infiltration storage section and penetrates into the underground, there is a problem that sinkholes are generated due to the subsidence of the ground on the road side.

Accordingly, there is a need for a solution to the problem of the above-mentioned prior patent.

An object of the present invention is to provide a non-point pollution reduction device and an excellent storage device capable of treating initial non-point pollutants in an early stage without installing a filter material in a road structure, and capable of preventing settlement of roadside sediments.

The present invention also provides a device for continuously removing foreign matter flowing into a drainage channel together with rainwater, thereby preventing a flooding caused by blocking the drainage port with foreign matter.

In order to solve the above-described problems, the present invention provides a road surface boundary stover comprising: a road boundary stone having an opening through which a rainwater flowing on an upper surface of a road flows, the rainwater flowing through the opening is branched into one of a sewage pipe, Wherein the branch valve directs the rainwater to the sewer pipe when the valve and the branch valve are in an initial good state, and after the lapse of the first time, the branch valve guides the rainwater to the plant material trough, And a controller for controlling the non-point pollution reduction and the excellent storage apparatus.

According to one embodiment, the diverging valve includes an inlet connected to the inlet pipe at an upper portion thereof, a first oil connector connected to the first induction pipe, the second induction pipe and the third induction pipe along the side periphery, Wherein the first induction pipe is a pipe for forming a flow path from the first induction port to the drain pipe, and the second induction pipe is a pipe for forming a flow path from the first induction port to the drain pipe, Wherein the second induction pipe is a conduit for forming the flow path from the second induction port to the planting soil path and the third induction pipe is a conduit for forming a flow path from the third induction port to the gutter tube. And the branching valve may further include blocking means for blocking two of the first to third oil film tools by the driving device.

According to one embodiment, the apparatus further comprises a drain pipe connected to communicate with the inlet pipe, wherein the drain pipe is provided with the branch valve at an upper portion thereof, and the rainwater leaking from the inlet pipe and / And an aggregate is laminated inside the lower portion of the drain pipe.

According to one embodiment, the blocking means may be a blocking plate that rotates along the side inner circumferential surface of the branch valve by the driving device.

According to one embodiment, the blocking means is a blocking block rotated by the driving device while being in contact with the inner circumferential surface of the branching valve, and the blocking block has an upper through hole and a side through hole at the upper portion and the side portion, The upper through-hole and the side through-hole may have a valve flow path so as to communicate with the inside of the blocking port.

In addition, the present invention is directed to a road barrier stool having an opening through which a rainwater flowing on an upper surface of a road flows, and rainwater flowing through the opening, to guide the rainwater into any one of a sewage pipe, And a branch housing for guiding rainwater to the sewer pipe and for guiding the rainwater to the planting soil and the gutter in sequence, wherein the branch housing has a first oil tool connected to the first induction pipe at the bottom face, And a third oil guide having a second oil guide connected to the second guide pipe on one side and connected to the third guide pipe on the other side of the second guide pipe, Wherein the second induction pipe is a conduit for forming the flow path from the second induction port to the plant material path, Wherein the conduit is a conduit for forming a flow path from the third induction port to the gutter tube, wherein the branch housing comprises: an excellent passage for storing the rainwater flowing through the opening; And a wire for connecting one end of the cover to the one end of the cover, wherein the barrel is biased toward the wire side by the center shaft, and the tension of the wire generated by the weight of the stored rainwater Wherein the cover opens the first oil reservoir.

According to an embodiment, the height from the bottom of the branch housing to the second oil reservoir may be higher than the height from the bottom of the branch housing to the third oil reservoir.

According to one embodiment, the branch housing includes a switch projecting toward an upper portion of one end of the barrel, the switch operating according to the tilting of the barrel, the toothed wheel rotating according to the pressing operation of the switch, A cam member for switching the rotational motion of the wheel to the up-and-down linear motion, and a support rod for pulling out toward the outer cylinder by up-and-down linear motion of the cam member to prevent the outer cylinder from tilting .

According to an embodiment of the present invention, there is further provided a sieve belt disposed in the opening and adapted to filter foreign matter other than the rainwater, wherein the sieve belt has a sieve belt pulley and a sieve belt guide roller And the squeeze belt pulley can be rotated by receiving the rotational force of the aberrator installed to rotate by the fall of the inflowing rainwater.

According to an embodiment, a filtering plate for filtering foreign matter other than the rainwater may be inserted or drawn along the groove to block or open the opening, the groove including grooves formed on at least one side of the opening.

The non-point pollution abatement and abso- lute storage apparatus according to the present invention is capable of treating pollutants by introducing non-point pollutants in an initial pollutant into a sewage treatment plant without the above-mentioned non- The ground subsidence on the road side can be prevented.

In addition, it is possible to prevent flooding caused by foreign matter flowing into a drainage channel together with rainwater, by blocking the drainage port.

1 is a view showing a non-point pollution reduction and an installed appearance of an excellent storage apparatus according to an embodiment of the present invention.
FIG. 2 is a view showing the overall configuration of a non-point pollution abatement and stormwater storage apparatus according to an embodiment of the present invention.
3A is a side cross-sectional view of a branch housing according to an embodiment of the present invention.
FIG. 3B is a view for explaining the operation of the branch enclosure of FIG. 3A.
4 is a side view of a branch valve according to an embodiment of the present invention.
5A is a view of a branch valve according to an embodiment of the present invention.
5B is a view of a branch valve according to another embodiment of the present invention.
5c is a view of a branch valve according to another embodiment of the present invention.
6A is a view illustrating a state in which a sieve belt is installed according to an embodiment of the present invention.
Figure 6b is a schematic view of the sieve belt drive of Figure 6a.
FIG. 7 is a view illustrating an example of setting a sieve plate according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like reference numerals are used to designate identical or similar elements, and redundant description thereof will be omitted. The suffix "module" and " part "for the components used in the following description are given or mixed in consideration of ease of specification, and do not have their own meaning or role. In the following description of the embodiments of the present invention, a detailed description of related arts will be omitted when it is determined that the gist of the embodiments disclosed herein may be blurred. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. , ≪ / RTI > equivalents, and alternatives.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The singular expressions include plural expressions unless the context clearly dictates otherwise.

In this specification, the terms "comprises" or "having ", and the like, are intended to specify the presence of stated features, integers, steps, operations, elements, parts, or combinations thereof, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

FIG. 1 is a view showing a non-point pollution reduction device according to an embodiment of the present invention, and an installed external appearance of the excellent storage device, and FIG. 2 is a diagram showing the overall configuration of a non-point pollution reduction device and an excellent storage device according to an embodiment of the present invention. to be.

1 and 2, the nonpoint pollution abatement and stormwater storage device 100 according to an embodiment of the present invention has the same appearance as the road boundary stone 3, and is provided between the road 1 and the sidewalk 2 And can be installed adjacent to the road boundary stones 3 to be installed.

The non-point pollution abatement and stormwater storage device 100 includes a road barrier 120 having an opening through which rainwater flowing on the upper surface of the road flows, and rainwater flowing through the opening to the sewage pipe 171, And a control unit (not shown) for controlling the operation of the branch valve.

However, it is needless to say that the components shown in FIGS. 1 and 2 are not essential, so that the non-point pollution abatement and stor- age storage apparatus 100 having more or fewer components can be implemented. Hereinafter, each component will be described.

The road boundary seat 120 is a means for separating the road 1 and the sidewalk 2 from the road 1 and located between the road 1 and the sidewalk 2, The road boundary stones 120 may have a rectangular column shape with rounded corners, but the present invention is not limited thereto.

In the road barrier 120 according to the present invention, an opening through which rainwater flowing on the upper surface of the road 1 flows may be formed on one side, more specifically, on the lower side.

A slope is provided in front of the road boundary 1 in the direction of the road 1 so as to be inclined downward in the direction of the sidewalk 2 from the road 1 in the case where the road 1 is inclined downward in the direction of the sidewalk 2 from the road 1 So that the rainwater flows into the opening w formed on one side of the road boundary stake 120 and the opening w communicates with another opening formed on the bottom or opposite side of the road boundary stake 120, It is preferable that the rainwater flowing into the opening portion w flows into the inflow pipe 140a to be described later. That is, one end of the inflow pipe 140a may be connected to the opening w to be communicable therewith.

The branch valve 150 is provided with a means for guiding the rainwater flowing through the opening w formed in the road boundary stones 120 to any one of the sewage pipe 171, the planting soil 172 of the drinking water table, , And the other end of the inflow pipe 140a (one end of which is connected to be able to communicate with the opening w).

That is, the control unit (not shown) controls the operation of the branch valve 150 so that the branch valve 150 guides the rainwater to the sewage pipe or the planting soil 172, Lt; / RTI >

Although the branch valve 150 is not particularly limited, the branch valve 150 may include an inlet 154 connected to the inlet pipe 140a at an upper portion thereof, as shown in FIGS. 4 and 5, A second oil tool 152, and a third oil tool 153 along the side outer circumferential surface.

The first to third induction tubes 161 to 163 may be connected to the first to third induction tubes 151 to 153 so that the first to third induction tubes 161 to 163 can communicate with each other. The rainwater flowing through the inflow opening 154 by the operation of the branch valve 150 is communicated with the sewage pipe 171, the planting soil 172, A flow path is formed so as to flow to any one of the soil 172 and the gutter tube 173.

The control unit (not shown) controls the diverter valve 150 to make the flow path through the water pipe 171 when the initial state is good.

In the case of an early storm including conventional non-point pollutants, the pollutants discharged from an automobile are discharged to the river through the storm duct 173 together with rainwater as it is. Therefore, environmental pollution occurs. However, The stormwater storage apparatus 100 guides the rainwater to the sewage pipe 173 at the initial stage of the storm, thereby guiding rainwater to the sewage treatment plant located at the distal end of the sewage pipe 173, The conventional environmental pollution problem can be solved.

Further, there is no need to provide a filter medium for treating contaminants between the road 1 and the sidewalk 2 as in the prior art 1 (Korean Patent Registration No. 1639379), and maintenance such as continuous replacement of the filter medium The problem of the prior art 1 can be solved.

The control unit may control the amount of flow or flow rate sensor (for example, it may be installed in the inflow pipe 140a) disposed on the flow path formed starting from the opening w of the road boundary stake 120, (The term "rainfall time point" in the present specification is used in combination with the terms "initial good weather" or "initial good time point") using a signal output from a sensor or the like, The control unit may determine an initial good point of view based on rainfall time information extracted from the current weather information transmitted from a weather station server (not shown). As used herein, the term "initial good time" may indicate an interval from a time of the rainfall to a point of time that has elapsed by a predetermined first time (e.g., about 20 to 30 minutes).

After the first time elapses, the control unit may control the branch valve 150 so that the introduced rainwater can form a flow path to the planting soil 172. Only the initial fresh water including the nonpoint pollutants is allowed to flow into the basin sewage treatment plant through the sewage pipe 171 and thereafter infiltrated into the basement as in the conventional case. At this time, the downstream side of the effluent is not the lower part of the road 1, Of the planting soil (172).

When a large amount of rainwater flows into the apparatus disclosed in the prior art patent 1, there is a problem that a large amount of rainwater infiltrates into the ground, thereby causing ground settlement of the road 1. However, According to the storm reservoir 100, the rainwater after the elapsed time of the initial storm is led to the planting soil 172, so there is no possibility that the ground subsidence of the road 1 will occur. Even if a large amount of rainwater flows into the planting soil (172), there is less fear of subsidence in the sidewalk (2) because the roots of the planting water hold the soil.

At this time, according to one embodiment, aggregate such as crushed stone or gravel is contained in the downstream end of the second induction pipe 162, and the flow rate of the rainwater flowing into the plantation soil 172 through the second induction pipe 162 is It is preferable that the rainwater is gradually permeated into the planting soil 172 by buffering.

The control unit may control the branch valve 150 to guide the incoming rainwater to the planting soil 172 for a second time and thereafter the branching valve 150 to guide the incoming rainwater to the effluent tube 173 .

Since the ground subsidence of the sidewalk 2 may also occur when an excessive amount of rainwater is finally introduced, the control unit may allow the inflow rainwater to form the effluent with the existing excellent pipe 173 after the second time have.

In this case, the third induction pipe 163 may be directly connected to the reflux pipe 173, but according to an embodiment, as shown in FIG. 2, the third induction pipe 163 may be installed in the lower part of the grating 4 May be connected to the rainwater receiver (10) and indirectly connected to the rainwater pipe (173). Of course, a channel for forming a flow path to the gutter tube 173 may be provided at a predetermined height of one side of the rainwater receiver 10. Here, the grating 4 may be opened to allow the rainwater to flow into the grating 4, but it is preferable that the grating 4 is provided at the upper portion of the grating 4 And a water catching film 180 that can block the inflow of rainwater can be installed in the lower part.

Alternatively, the control unit may control the flow rate of the flow rate sensor or the flow rate sensor (not shown) disposed on the flow passage formed from the opening of the road boundary stall 120 (for example, about 1 to 2 hours) (For example, it may be installed in the inflow pipe 140a), and calculates a precipitation amount after the rainfall time point, and when the rainfall amount exceeds the predetermined rainfall amount based on the estimated rainfall amount from the first time May be the second time.

The branch valve 150 is operated by the drive unit 155 to perform the above-described operation by the control unit, and the branch valve 150 is operated by the operation of the drive unit 155, And blocking means for blocking two of the tools 151-153.

The branching valve 150 suffices to block the two oil tools by the blocking means, and the specific configuration is not particularly limited.

For example, the branch valve 150 may be configured as shown in Figures 4 and 5a. As shown in FIGS. 4 and 5A, the branch valve 150 may have an inlet 154 formed at an upper portion thereof, and first through third oil reservoirs 151 through 153 may be formed along a side peripheral surface thereof And a drive unit 155 for rotationally driving the blocking plate 156 may be attached to the lower portion.

The blocking means may be a blocking plate 156 which is movable in the lateral direction while being in contact with the inner circumferential surface of the branch valve 150 by the driving device 155. At this time, the blocking plate 156 is rotated by the driving force generated by the driving device 155. The blocking plate 156 has a size enough to close two oil tools of the first to third oil-rich tools 151 to 153, so that the rainwater introduced through the upper inlet 154 is discharged to the outside 1 to the third oil tools 151 to 153, respectively.

As another example, the branch valve 150 may be configured as shown in Figs. 4 and 5B. 4 and 5B, the branch valve 150 may have an inlet 154 formed at an upper portion thereof, and first through third oil-like tools 151 through 153 may be formed along a side peripheral surface thereof And a driving unit 155 for driving the blocking member 157 to rotate.

The blocking means may be a blocking member 157 provided so as to be rotatable sideways while being in contact with the inner circumferential surface of the branch valve 150 by the driving device 155. At this time, the blocking member 157 is rotated in the lateral direction by the driving force generated by the driving device 155. The blocking port 156 has one through hole 1571 and one through hole 1572 on the upper side and the side wall of the blocking hole 156 so as to communicate between the upper through hole 1571 and the side through hole 1572, Lt; RTI ID = 0.0 > 1573 < / RTI >

The rainwater flowing into the branch valve 150 through the upper inlet 154 flows into the side through hole 1572 as the blocking member 156 rotates by a predetermined angle in the lateral direction in accordance with the control signal of the controller. Through the first to third oil guides 151 to 153, the oil is formed through the open induction port.

As another example, the branch valve 150 may be configured as shown in FIG. 5C. As shown in FIG. 5C, first to third open / close valves 1511 and 1511 capable of controlling the opening and closing of the pipeline are provided at the distal end portions of the first to third oil spring tools 151 to 153 provided in the branch valve 150, respectively. , 1521, and 1531, respectively. The first to third open / close valves 1511, 1521 and 1531 may be, for example, butterfly valves. Open / close valve driving devices 1512 and 1522 , 1532).

Accordingly, the control unit controls the opening / closing valve driving devices 1512, 1522, 1532 individually to open only one of the opening / closing valve driving devices 1512, 1522, 1532 in accordance with the control signal, The rainwater flowing into the branch valve 150 through the open / close valves 1511, 1521, and 1531 opens the corresponding induction port.

The inflow pipe 140a is a pipe for guiding the rainwater introduced through the opening formed in the road barrier 120 to the branch valve 150 and the distal end of the inflow pipe 140a is communicated with the drain pipe 140c (See FIG. 4).

The branch valve 150 may be disposed at an upper end of the drain pipe 140c. For example, the branch valve 150 may be inserted into the upper end of the drain pipe 140c so that the rainwater leaking from the inlet pipe 140a and / or the branch valve 150 may flow into the drain pipe 140c But it is more preferable to modularize the branch valve 150 provided with the at least one driving device for efficient maintenance and repair. That is, the branch valve 150 is inserted into the connection pipe 140b, and the connection pipe 140b is formed so that one end of the connection pipe 140 can be engaged with / separated from the inflow pipe 140a (reference numeral b1) And can be formed so that an end thereof can be engaged with / separated from the drain pipe 140c (reference numeral b2).

4, the lower inner end portion may be configured to be coupled to the inlet port of the branch valve 150, and the lower outer end portion of the inlet pipe 140a may be connected to the drain pipe 140c To be coupled to one end of the second housing (not shown).

As described above, the rainwater leaking through the drain pipe 140c flows out downward, but aggregates such as crushed stone and gravel are stacked on the inner lower part of the drain pipe 140c, and the leaking rainwater passes through the aggregate It is good to be able to penetrate.

According to an embodiment of the present invention, a solar cell panel (not shown) for collecting solar light and generating electric power is provided on the upper surface of the road boundary stake 120, The driving device 155 can receive power generated by the solar cell panel.

The solar cell panel may include a plurality of solar cell modules for converting solar light into electricity, and may be installed on the upper surface of the road boundary stones 120 so as to condense the solar light by being exposed to the outside.

Accordingly, the power consuming control unit and / or the driving unit 155, 1512, 1522, 1532 can be used as the main power and / or the auxiliary power to directly use the power generated by using the solar cell panel, The control unit and / or the driving unit 155, 1512, 1522, 1532 may use a commercial power source as a main power source for stable driving, ) Can be supplemented if the power generated by using solar light is above a certain level.

Meanwhile, according to one embodiment of the present invention, the non-point pollution reduction and storage apparatus 100 according to an embodiment of the present invention can be implemented in a mechanical manner. That is, as shown in FIG. 3A, the non-point pollution abatement and stormwater storage apparatus 100 according to an embodiment of the present invention includes a road barrier 120 having an opening through which rainwater flows, And a branch enclosure 101 capable of guiding the sewage to the sewage pipe 171, the planting soil 172 of the drinking water table, and the gutter tube 173.

The branch enclosure 101 is for guiding the rainwater flowing through the opening to any one of the sewage pipe 171, the planting soil 172 of the drinking water table, and the gutter tube 173. That is, the rainwater can be guided to the sewage pipe 171 at the time of the initial storm, and the introduced rainwater can be sequentially introduced into the planting soil and the guttering pipe.

3A, the branch housing 101 has a first oil guide 102a connected to the first guide pipe 102b on the bottom surface thereof, and a second guide pipe 102b connected to one side of the branch housing 101, And a third oil tool 104a connected to the third induction pipe 104b on one side of the second oil compartment 103b.

Here, the first induction pipe 102b is a conduit for forming a flow path from the first fluid tool 102a to the sewage pipe 171, and the second induction pipe 103b is connected to the second fluid tool 103a And the third induction pipe 104b is a conduit for forming a flow path from the third fluid tool 104a to the relief pipe 173. [

That is, the initial rainwater flowing into the branched enclosure 101 through the opening of the road boundary stones 120 passes through the first induction pipe 102b and the water pipe 171 through the first oil tool 102a formed on the bottom surface The first oil tool 102a is closed and the storage amount of the rainwater in the branch housing 101 gradually increases and the second induction pipe 103b and the vegetable soil 172, respectively. When the rainwater flowing into the planting soil 172 is overflowed, the rainwater gradually accumulates in the branching housing 101 and flows through the third induction pipe (not shown) through the third oil tool 104a at a higher position than the second oil tool 103a 104b and the bellows pipe 173, respectively.

3A, the branch enclosure 101 includes, besides the first to third oil reservoirs 102a to 104a, a reservoir 105a for storing the rainwater flowing through the opening, A cover 108a for opening and closing a first oil tool 102a formed on the bottom surface of the branch housing 101 and a wire 107 for connecting one end of the barrel 105a to one end of the cover 108a ).

The outer cylinder 105a is in the form of a bowl having an opened upper surface, and the rainwater flowing through the opening of the road boundary seat 120 can be temporarily stored. The outer cylinder 105a is provided at its bottom surface with a central shaft 105b for supporting the outer cylinder 105a and the center shaft 105b is positioned at a position which does not coincide with the center of gravity of the outer cylinder 105a, So that the cylinder 105a can be supported.

3A, the center shaft 105b is disposed so as to support the upper end of the outer tube 105a and is positioned so as to support the upper end of the outer tube 105a. It is preferable that the opposite side of the wire 107 is inclined downward.

The cover 108a is for opening and closing the first oil tool 102a formed on the bottom surface of the branch housing 101. The cover 108a is connected to the center of the rotating shaft 108b So that the first oil tool 102a can be opened and closed. That is, when a force acts upward on one end of the cover 108a through the wire 107, the cover 108a rotates in the clockwise direction about the rotary shaft 108b located at the other end, When the oil tool 102a is opened and no external force acts on the cover 108a, the cover 108a rotates counterclockwise about the rotation shaft 108b by its own weight, 102a are closed.

At this time, one end of the cover 108a is connected to the outer tube 105a so that the opening / closing operation of the cover 108a with respect to the first oil tool 102a can be interlocked with the tilting of the outer tube 105a. (Not shown). In order to increase the amount of rotation of the cover 108a, a lever 106 may be extended at one outer end of the vat 105a, and the wire 107 may be provided at the tip of the lever 106, Lt; / RTI >

When the initial storm flows into the branching enclosure 101 in the initial state (the state shown in FIG. 3A), the initial stormwater is stored in the stormwater tank 105a, and the initial stormwater exceeding a predetermined amount is stored in the stormwater tank 105a. The vat 105a rotates clockwise about the central axis 105b so that the end of the vat 105a on the side of the wire 107 is moved upward, The cover 108a is rotated around the rotation shaft 108b by tension to open the first oil tool 102a.

As a result, the initial clearance is stored at the bottom of the branched enclosure 101 beyond the outer cylinder 105a in accordance with the inclination of the outer cylinder 105a, and the initial clearance is closed by the opened oil cover 105a, 102a. To this end, the bottom surface of the branch housing 101 may have a slope b along at least a portion of the inner circumferential surface or at least a portion of the inner circumferential surface to guide the initial storm to the first hydraulic tool 102a.

As described above, the initial storm is led to the first oil reservoir 102a, but after a certain period of time has elapsed, to introduce the storm introduced into the branch enclosure 101 to the second oil reservoir 102b, The branch housing 101 may include an obstruction device 109 capable of preventing rotation of the gastight barrel 105a.

3B, the blocking device 109 includes push switches 1091 to 1093 operated in accordance with the rotation of the gastight barrel 105a, a rotation shaft 1095 in accordance with the pushing action of the push switch 1091, A cam member (not shown) for switching the rotational motion of the toothed wheel 1094 to up and down linear motion, and a cam member (not shown) So as to prevent rotation of the outer cylinder 105a.

The push switches 1091 to 1093 are provided with a pushing portion 1091 which protrudes toward the upper end of one side of the vat 105a and which performs linear elastic movement by a spring 1092 disposed in the tangential direction of the toothed wheel 1094 1091). That is, the pressing portion 1091 is pushed upward every time when the vat 105a is pivoted by the initial good weight, so that every time the pressing portion 1091 is pushed, the other- The teeth of the gear 1094 can be pushed one by one to rotate the gear 1094.

The cam member is a means for switching the rotational motion of the toothed wheel 1094 to the linear motion of the support rod 1096. [ The cam member may include, for example, a plate cam that is connected to the center shaft of the toothed wheel 1094 and eccentrically rotates, and the support rod 1096 is engaged with the eccentric rotation of the plate cam on the outer circumferential surface of the plate cam (Disc cam, tangential cam, circular cam, etc.).

As a result, a series of processes in which the initial storm is stored in the stor- age tank 105a and the stor- age tank 105a is tilted by the stored storm and the push switches 1091 to 1093 are operated is repeated, The support cylinder 1096 is drawn down toward the outer cylinder 105a and the support rod 1096 drawn down is in contact with the upper surface of the outer cylinder 105a to support the outer cylinder 105a, Do not turn any more due to stormwater in the reservoir.

It is a matter of course that the number of teeth of the cogs 1094 or the gear members interlocking with the cogs 1094 may be designed for the initial good times in order to set the initial excellent time to about 20 to 30 minutes.

The additional storm overflows the stor- age tank 105a and the overflow storm is gradually accumulated in the branch housing 101 At this time, the cover 108a closes the first oil tool 102a), and flows into the second oil tool 103a having the height h1 lower than the height h2 of the third oil tool 104a do.

The rainwater flowing into the second oil tool 103a is led to the planting soil 172 through the second induction pipe 103b. At this time, the second induction pipe 103b may be arranged to be inclined downward toward the other end, and a predetermined space may be formed at the other end of the second induction pipe 103b, and a wire mesh 103c So that the soil can not flow into the second induction pipe 103b. The upper surface of the wire mesh 103c may be opened to dredge the soil, and the upper surface of the wire mesh 103c may be open to allow the wire mesh 103c to communicate with the ground surface A check pipe 103d may be further provided.

As described above, the height h1 of the branch housing 101 from the bottom face to the second oil reservoir 104a is greater than the height h1 of the branch housing 101 from the bottom face of the branch housing 101 to the third oil tool 104a By making the height h2 higher, the extra rainwater is induced to the third oil tool 104a when the stormwater soil is induced and the rainwater overflows with no further rainwater flowing into the plant material.

Thus, according to the present invention, it is possible to treat non-point pollutants in the initial sewage to a sewage treatment plant, to treat the pollutants first, and then to induce excellence in planting soil and gutters sequentially.

Meanwhile, according to an embodiment of the present invention, a sieve belt may be installed at a side opening of the road boundary stake 120.

The sieve belt 110 may be installed across the opening so that foreign matter other than the rainwater can be filtered during the course of the rainwater on the road being discharged together with the non-point pollutant through the opening.

When the rainwater of the road is drained by the apparatus disclosed in the prior art 1, the leaves and garbage that have been washed down together with the rainwater are filtered by the screen of the opening, and the filtered leaves and garbage are prevented from draining the rainwater And cause road flooding.

The sieve belt 110 according to the present invention continuously moves in one direction so that foreign substances other than rainwater move together in one direction so that the sieve belt 110 can continuously maintain the drainage function .

FIG. 6A is a view showing a state where a sieve belt is installed according to an embodiment of the present invention, and FIG. 6B is a schematic view of a sieve belt driving unit of FIG. 6A.

As shown in FIGS. 6A and 6B, the sieve belt 110 is disposed in the opening and has a predetermined mesh, so that foreign matter flowing along with the rainwater other than the rainwater can be removed.

The material of the squeezing belt 110 is not particularly limited, but it is preferable that the squeezing belt 110 is made of a fabric that can be wound on a squeezing belt pulley 111 and a squeezing belt guide roller 112, which will be described later.

The sieve belt 110 may be supported by a sieve belt pulley 111 and a sieve belt guide roller 112 so as to be able to rotate while being tightened by a tension greater than a predetermined size.

At this time, the squeezing belt pulley 111 may be rotated using a commercial power source or the power using the sunlight described above, but according to an embodiment, the squeezing belt pulley 111 and the squeezing belt guide roller 112 The sieving belt 110 is configured such that the rotational force generated by the rotation of the aberration 115 is transmitted to the sieve belt pulley 111 through the driving force transmitting means 113 via the rotating shaft 114 and the rotation of the sieve belt pulley 111 The squeezing belt 110 is rotated about the squeezing belt pulley 111 and the squeezing belt guide roller 112. [

However, the sieve belt 110 moves in one direction as described above, so that the sieve belt 110 can collect the foreign matter at the end of the sieve belt 110 in the moving direction. And it is preferable that it is installed by being drawn by a predetermined depth in the inner direction from the outer side surface. At this time, in order to prevent the inflow of running water to the gap between the squeezing belt 110 and the opening (w) of the road block seat 120 and to prevent the movement of the foreign matter due to the movement of the squeezing belt 110, At least one side surface of the opening w may include diaphragms 121 and 122 attached to the inside direction (see Fig. 6A).

The aberration 115 which is axially coupled to the rotating shaft 114 is provided on the dropping point of the rainwater transmitted through the sieve belt 110. The number of the aberrations 115, the number of the blades, the length of the blades, Etc. are not particularly limited so long as the rainwater passing through the sieving belt 110 falls and the aberration 115 can be rotated and the sieving belt 110 can be rotated by the rotation of the aberration 115 .

The aberration 115 may be installed inside the inflow pipe 140a when one end of the inflow pipe 140a is connected to the opening of the road boundary stake 120 as described above.

Reference numeral 130 in FIG. 2 denotes a sieve belt driving means. The sieve belt driving means 130 includes drive force transmission means (not shown) for rotating the sieve belt pulley 111 with an electric force according to an embodiment, Or may include a rotating shaft 114, aberration 115, and driving force transmitting means 113 according to another embodiment.

When a small amount of rainwater flows in through the opening of the road barrier 120, the aberration 115 is not rotated, and when a large amount of rainwater flows in through the opening, Since the aberration 115 caused by the aberration belt 115 rotates the sieve belt 110, the foreign matter that has been separated along with the large amount of rainwater is moved to one side of the sieve belt 110 to prevent the sieve belt 110 from being blocked, The problem of the flooding of the road due to the drainage of the rainwater can be solved.

FIG. 7 is a view illustrating an example of setting a sieve plate according to another embodiment of the present invention. 7, grooves 1241 and 1242 may be formed on at least one side of the opening w of the road boundary stones 120 according to another embodiment of the present invention. Specifically, grooves 1241 and 1242 may be formed at a predetermined depth from the outer side surface of the road boundary stones 120 by a predetermined depth, and the sieve belt 110 may have a mesh corresponding to the sieve belt 110, The opening 110 'is inserted or drawn along the grooves 1241 and 1242 so that the filtering plate 110' blocks or opens the opening w.

According to this embodiment, since the operator can easily install and remove the sieve plate 110 'by grasping the handle 110'-1 located at one end of the sieve plate 110' Even if the opening w is blocked by the operator, the operator can easily remove it.

The preferred embodiments of the present invention have been described in detail with reference to the drawings. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims.

Accordingly, the scope of the present invention is defined by the appended claims rather than the foregoing detailed description, and all changes or modifications derived from the meaning, range, and equivalence of the claims are included in the scope of the present invention Should be interpreted.

1: Road 2: Press
3: Road border 4: Grating
10: Rainwater catcher 100: Reduction of non-point pollution and excellent storage device
101: branch enclosure 102a: first type tool
102b: first induction tube 103a:
103b: second induction tube 104a: third type tool
104b: third induction pipe 105a:
105b: center shaft 106: lever
107: wire 108a: cover
108b: cover rotating shaft 109: blocking device
1091: pressing portion 1092: spring
1093: projection 1094: gear wheel
1095: rotating shaft 1096: supporting rod
110: Filter belt 110 ': Filter plate
110'-1: Handle 111: Screw belt pulley
112: Filter belt guide roller 113: Driving force transmitting means
114: rotating shaft 115: aberration
120: road barrier seats 121, 122: barrier film
1241, 1242: groove 130: sieve belt driving means
140a: inlet pipe 140b: connecting pipe
140c: Drain pipe 150: Branch valve
151: first type tool 152: second type tool
153: Oil type tool 154: Inlet
1511: first opening / closing valve 1521: second opening / closing valve
1531: Third open / close valve 1512: First open / close valve drive device
1522: second opening / closing valve driving device 1532: third opening / closing valve driving device
155: drive device 156: breaking plate
157: blocking portion 1571: upper through hole
1572: side through hole 161: first induction pipe
162: second induction tube 163: third induction tube
171: sewage pipe 172: vegetable soil
173: Excellent pipe 180:

Claims (10)

A road barrier seat having an opening through which an inflow of rainwater flowing on an upper surface of the road is formed;
A branching valve for guiding the rainwater flowing through the opening to any one of a sewage pipe, planting soil in the drinking water table and a gutter; And
Wherein the branch valve leads the rainwater to the sewage pipe when the branch valve is in an initial good state, the branch valve directs the rainwater to the planting soil after a lapse of a first time, And a control unit
Lt; / RTI >
The branch valve includes an inlet connected to the inlet pipe at an upper portion thereof, a first oil tool, a second oil tool and a third oil fluid connected to the first induction pipe, the second induction pipe and the third induction pipe, Having a tool,
Wherein the inlet pipe is a conduit for forming the flow path from the rainwater to the branch valve and the first induction pipe is a conduit for forming a flow path from the first induction port to the drain pipe, And the third induction pipe is a conduit for forming a flow path from the third induction port to the excellent pipe,
Wherein the branching valve further comprises a blocking means for blocking two of the first to third oil-well tools by a driving device,
The drain pipe connected to the inlet pipe communicates with the drain pipe through which the rainwater leaking from the inlet pipe and / or the branch valve flows downward, and aggregates are stacked inside the lower portion of the drain pipe Wherein the non-point pollution reducing apparatus comprises: delete delete The method according to claim 1,
Wherein the shutoff means is a shutoff plate that rotates along the inner circumferential surface of the side portion of the branch valve by the drive device. The method according to claim 1,
The shutoff means is a shutoff valve that rotates while being in contact with the inner circumferential surface of the branch valve by the drive device,
Wherein the blocking port has an upper through hole and a side through hole at each of an upper portion and a side portion, wherein the upper through hole and the side through hole have a valve flow path so as to communicate with the inside of the blocking hole. Storage device. A road barrier seat having an opening through which an inflow of rainwater flowing on an upper surface of the road is formed; And
The rainwater introduced through the opening is guided to one of the sewer pipe, the planting soil in the drinking water table, and the gutter tube. In the initial stage, the rainwater is guided to the sewer pipe, and the rainwater is guided to the planting soil and the gutter Branch enclosure;
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Wherein the branch housing has a first oil guide connected to the first guide pipe on the bottom face, a second oil guide connected to the second guide pipe on one side, and a third oil guide connected to the third guide groove on the other side, Wherein the first induction pipe is a conduit for forming a flow path from the first induction port to the sewage pipe and the second induction pipe is connected to the vegetable soil from the second induction port, Wherein the third induction pipe is a conduit for forming a flow path from the third induction port to the gutter tube,
The branching housing includes a cover for opening and closing the first oil tool, a wire for connecting one end of the barrel and one end of the cover, , The cover opens the first oil tool with the tensile force of the wire caused by the weight of the stored rainwater, the center tube being biased toward the wire side,
Wherein the branch housing includes a switch projecting toward an upper portion of one end of the barrel and operated in accordance with an inclination of the barrel, a gear wheel rotating in accordance with a pressing operation of the switch, Further comprising a support rod for withdrawing the support member from the upper end of the support member to the upper end of the support member and moving the upper end of the support member toward the upper end of the support member, Pollution abatement and stormwater storage. The method according to claim 6,
And the height from the bottom of the branch housing to the second oil reservoir is higher than the height from the bottom of the branch housing to the second oil reservoir. delete A road barrier seat having an opening through which an inflow of rainwater flowing on an upper surface of the road is formed;
A branching valve for guiding the rainwater flowing through the opening to any one of a sewage pipe, planting soil in the drinking water table and a gutter;
Wherein the branch valve leads the rainwater to the sewage pipe when the branch valve is in an initial good state, the branch valve directs the rainwater to the planting soil after a lapse of a first time, And a control unit And
A squeezing belt disposed at the opening to filter foreign matter other than the rainwater;
, ≪ / RTI &
Wherein the squeezing belt is supported by a squeeze belt pulley and a squeeze belt guide roller so as to be rotatable while maintaining a predetermined tension,
Wherein the squeeze belt pulley rotates by receiving the rotational force of the aberrator installed to rotate by falling of the inflowing rainwater. delete

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