KR20140095783A - Equipment and method for decrease non-point pollution sources using separating vegetation waterway - Google Patents

Abstract

The present invention relates to a nonpoint pollution reducing facility having a separate grassed waterway, a separate grassed waterway structure for the nonpoint pollution reducing facility, and a nonpoint pollution reducing method using the nonpoint pollution reducing facility. More specifically, the said invention relates to a nonpoint pollution reducing facility having a separate grassed waterway including: a collecting well where leaked rainwater flowing on a road surface is collected; a guiding waterway guiding the leaked rainwater to the collecting well; the grassed waterway connected to the first end of one side of the collecting well, and receiving the initial leaked rainwater of the collected leaked rainwater; and an existing waterway connected to the second end of one side of the collecting well, and receiving the leaked rainwater of the leaked rainwater collected in the collecting well not received in the grassed waterway. The initially leaked rainwater is filtered by the grassed waterway and received in one side of the existing waterway.

Description

TECHNICAL FIELD [0001] The present invention relates to a non-point pollution abatement facility having a separation-type fresh water channel, a separation type super-water pollution reduction facility for non-point pollution abatement facilities,

The present invention relates to a non-point pollution abatement facility having a detached-type canalized water channel, a detached super-clean water structure for nonpoint pollution abatement facilities, and a nonpoint pollution abatement method using the abatement facilities. In more detail, since it is installed on the existing site close to the existing waterway in parallel with the longitudinal direction of the existing waterway, it is possible to minimize the required site and to maintain the existing water- The present invention relates to a non-point pollution abatement facility having a detachable fresh water channel that can improve the non-point pollution abatement function of the non-point pollution abatement facility.

Water pollution sources are divided into point pollution sources and non-point pollution sources. Point pollution sources are mainly used for monitoring the occurrence area and generation amount such as domestic sewage generated in general households or business areas, industrial wastewater discharged from factories, animal wastewater generated in large- This is a relatively easy subject and is the main object of sewage disposal.

On the other hand, non-point pollution source refers to drainage from agricultural drainage, mine waste water, livestock wastewater from small-scale livestock facilities, living sewage or forest in rural areas without sewerage, and these pollutants are relatively dependent on natural treatment due to less contribution of pollution.

Emphasis is placed on non-point sources, non-specific pollutants, surface pollutants, mobile pollutants, and other pollutants. Unlike point pollutants having specific discharge routes, non-point pollutants are unspecified, such as urban road drains or agricultural drainage. Refers to a location or area that generates nonpoint pollutants through an exhaust path.

Aquaculture facilities, transportation facilities, maintenance or disposal facilities, simplified processing facilities for enriched fisheries products, photo processing facilities, etc., which have been renamed as 'other water pollution sources' in the 'Specified Facility' under the Water Quality Protection Law, , Product yard, land change area, and other facilities.

Non-point pollutants are mainly pollutants that run out along with surface rainfall runoff when they are exposed to rain. These include fertilizers, pesticides, soil sprinkling plants, housing spills, traffic pollutants, dust and garbage in urban areas, Residues, and air pollutants that have fallen on the surface of the earth.

Therefore, rainwater (rainwater runoff) containing all pollutants is actually the main nonpoint source. Since non-point pollutants usually flow out with a lot of rainfall, there is a large difference between daily and seasonal emissions, and it is difficult to forecast and quantify, and it is affected by weather conditions, geology, and topography which are difficult to manure.

The point pollution sources such as domestic sewage are steadily decreasing due to the establishment of basic environmental facilities, but the nonpoint pollution sources are continuously increasing due to the improvement of land use. In particular, the impact of non-viscous salts on water quality is predicted to reach 65 ~ 70% by water sector in 2015, and active management of non-point pollution sources is required.

In 2007, the government revised and amended the 'Law on Water Quality and Aquatic Ecosystem Correction' to select and expand objects to be installed in nonpoint pollution abatement facilities.

As of the end of 1999, as a result of the "Non-point Source Pollution Research Service" (conducted in June 2000) on the upper stream of the Paldang Dam in the Han River, the main water source of the metropolitan area residents, The pollutant loads generated from point sources such as industrial wastewater and livestock wastewater were 804.4%, 130,650t / year, and the pollution load from nonpoint pollution sources was 19,3193t / year, which was 19.6%.

In addition, the non-point source pollution source was estimated to be 44.5% of the total discharge load (BOD standard), and nonpoint source pollution was found to have a significant influence on water pollution. The Geum River, Nakdong River and Youngsan River . Therefore, as the regulations for point sources with regulatory standards are continuously strengthened and environmental facilities are expanded, the impact of non - point pollution sources on water quality will gradually increase.

Point pollution sources such as domestic sewage are steadily decreasing due to steady establishment of infrastructure facilities, but non-point pollution sources are continuously increasing due to the improvement of land use. In particular, the impact of nonpoint pollution sources on water quality is expected to reach 65 ~ 70% by water sector in 2015, and active management of nonpoint pollution sources is needed.

The government revised the related law in 2007 and imposed a nonpoint pollution abatement facility at the time of construction of a new road. Currently, the law is being revised to require the abatement facility to be installed on the road constructed before 2007, It is forecast.

As a countermeasure for reducing pollution, conventionally, in order to reduce pollution, the road surface drainage in an urban area is provided with a storage tank to allow the pollutants generated due to the initial rainfall to be settled and discharged, · Agricultural drainage, which contains a large amount of agricultural chemicals, was installed in a reservoir, a wetland purification facility, and aquatic plants to prevent direct influx into the river.

However, such a countermeasure would be to treat only the initial rainfall, which is the actual nonpoint source pollutant discharged with all the pollutants, by continuously treating the rainwater after a certain period of time when the concentration of the pollutant decreases, There is a problem that the maintenance cost rises. Therefore, a nonpoint pollution abatement facility with proper efficiency and economical efficiency was required for the initial runoff containing the majority of nonpoint pollutants.

In addition, non-point pollution abatement facilities such as infiltration ditches or sand filtration facilities should be installed off-line (separation of abatement facilities from existing waterways) in order to improve the stability of the abatement facilities and the water treatment efficiency. The separation facility corresponds to a flow splitter.

In the United States, it is designed to be made into a corrugated form. However, it is not suitable for the domestic repair system, it is disadvantageous to the construction and maintenance, and the abatement facility can not exert its function because there is no installation standard in Korea.

In order to remove the non-point pollution from the initial effluent by distributing the initial effluent, a water channel for inducing the initial effluent is separately installed in the existing water channel, and a separate abatement facility is separately installed in the flow channel, And the effluent with reduced non-point pollution was reintroduced into the existing waterway.

FIG. 1 is a perspective view of a conventional non-point pollution abatement facility. FIG. 2 is a perspective view of a conventional non-point-of-smoke reduction facility viewed from the front, and FIG. 3 is a perspective view of a conventional non-point pollution reduction facility.

As shown in FIGS. 1 to 3, rainfall runoff on roads and other road surfaces is introduced into an existing waterway through an induction waterway, and a separate flow distribution structure, a pretreatment tank, and various abatement facilities are installed in the existing waterway , It can be seen that the initial effluent is introduced into the abatement facility and the rainwater effluent from which the non-point pollutant is removed through the abatement facility is reintroduced into the existing canal, thereby removing the nonpoint contamination of the initial effluent.

However, in such a method, it is not easy to install the abatement facility within the limited paper width of the existing water channel, and there is a problem that the installation of the separate flow rate distribution tank, the pretreatment tank, the abatement facilities, etc., .

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a method and apparatus for separating an off-channel waterway from an existing waterway, It is an object of the present invention to provide a non-point pollution abatement facility having a detachable fresh water channel that can minimize the required site and improve the function of reducing the non-point pollution of the initial effluent while maintaining the existing water flow function.

Other objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments with reference to the accompanying drawings.

SUMMARY OF THE INVENTION A first object of the present invention is to provide an air conditioning system, which is capable of collecting rainwater runoff on a road surface, An induction waterway leading to rainfall runoff by collecting water; A fresh water stream which is connected to the first end of the one side of the house collection and into which the initial effluent flows from the rainwater runoff collected in the house collection; And an existing water line connected to the second side of the one side of the house correction and into which the effluent not introduced into the freshwater channel flows into the stormwater collected in the fresh water channel is filtered by the freshwater channel, The present invention can be achieved as a non-point pollution abatement facility having a detached caisson channel.

The offshore waterway can be characterized in that the vegetation water is planted on the existing site located close to the longitudinal direction of the existing waterway.

And a wall provided between the grazing water channel and the existing water channel.

The initial effluent flowing into the caustic canal is joined to the existing channel from the end of the wall located at the end of the flow direction.

One side of the collecting surface is formed with an inlet hole at the first end thereof, and the initial effluent is introduced into the caustic effluent channel through the inlet hole.

And an orifice is provided in the inflow hole.

The height of the second side of the one side of the collecting crystal is higher than the length between the inflow hole and the bottom of the collecting crystal by a specific length.

And a specific length is 20 to 30 cm.

And the induction channel may be inclined toward the collecting side.

The second object of the present invention is to provide a super structure for reducing the non-point pollutants of the initial effluent by being installed close to the flow distribution structure for introducing the runoff water flowing on the road surface into the existing water channel by the induction water channel, Modifying houses to collect rainfall runoff; And the first runway connected to the first end of the house fixation to receive the initial runoff from the rainwater runoff collected in the house fixation, the existing waterway is connected to the second end of the one side of the house fix, The effluent which has not flowed into the freshwater channel flows in the runoff of the collected rainfall, and the initial runoff is filtered by the freshwater channel and merged to one side of the existing water channel. .

The initial effluent from the freshwater channel can be characterized by filtration, fresh water, sedimentation by the vegetation water, and infiltration and evaporation into the lower soil.

A third object of the present invention is to provide a method of reducing non-point pollution, comprising: inducing a runoff runoff on a road surface to an induction channel; Collecting the rainfall runoff induced in the induction channel by a house correction connected to the induction channel; The initial effluent of the rainwater runoff collected at the house collection is introduced into the first runway connected to the first end of the runway; The initial effluent flowing into the freshwater channel is filtered and merged into the existing channel; And a step of introducing the rainfall run-off water not flowing into the runoff channel into an existing waterway connected to the second end of the windrow.

The abatement method may further include a wall provided between the grazing water channel and the existing water channel in which the vegetation water is planted in the existing site located adjacent to the existing water channel along the longitudinal direction of the existing water channel.

In addition, in the step of merging into the existing waterway, the initial effluent flowing into the caustic water channel is joined to the existing waterway from the end of the wall located at the end of the flow direction.

In the step of introducing into the caustic water channel, an inlet hole is formed at the first end of one side of the collector, and an orifice is provided in the inlet hole, so that the initial effluent is introduced into the caustic water channel through the orifice.

The height of the second side of the collecting surface is higher than the length between the inflow hole and the lower surface of the collecting surface, and the step of introducing the water into the existing water channel includes the steps of: And flows into the existing water channel.

This reduction method can be characterized in that the initial effluent flowing into the fresh water channel is infiltrated and evaporated into the filtration, fresh water, sedimentation and lower soil by the vegetation water.

Therefore, according to the embodiment of the present invention, since the off-line is separated from the existing water channel and installed in the existing site close to the existing water channel in parallel with the longitudinal direction of the existing water channel, It has an effect of improving the function of reducing the non-point pollution of the initial effluent while maintaining the existing water flow function.

In addition, it is possible to install easily and quickly in existing members, to maintain the existing drainage system, to secure the water supply stability, to meet the installation standards of the Ministry of Environment and Korea Highway Corporation, and to install the nonpoint pollution abatement facilities economically There are advantages to be able to.

1 is a perspective view of a conventional non-point pollution abatement facility,
2 is a partial perspective view of a conventional non-viscous surface reduction facility viewed from the front,
3 is a perspective view of a conventional non-point pollution abatement facility,
FIG. 4 is a perspective view of a non-point pollution abatement facility having a detached-type fresh water channel according to an embodiment of the present invention;
FIG. 5 is a plan view of a nonpoint pollution abatement facility having a detached-type fresh water channel according to an embodiment of the present invention;
FIG. 6A is a cross-sectional view of a non-point pollution abatement facility on the collecting side in a state where an initial effluent is introduced into an aquifer through an orifice according to an embodiment of the present invention,
FIG. 6B is a cross-sectional view of a non-point pollution abatement facility on the collecting side in a state in which the ferro-effluent flows into the existing water channel in excess of the discharge port according to an embodiment of the present invention;
7 is a cross-sectional view of a non-point pollution abatement facility at a conventional waterway side, according to an embodiment of the present invention;
FIG. 8 is a flowchart illustrating a method of reducing non-point pollution with a detachable corn line according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the detailed description of known functions and configurations incorporated herein will be omitted when it may unnecessarily obscure the subject matter of the present invention.

The same reference numerals are used for portions having similar functions and functions throughout the drawings. Throughout the specification, when a part is connected to another part, it includes not only a case where it is directly connected but also a case where the other part is indirectly connected with another part in between. In addition, the inclusion of an element does not exclude other elements, but may include other elements, unless specifically stated otherwise.

Hereinafter, the configuration and function of the non-point pollution abatement facility 100 having the separated super-fresh water channel 130 according to an embodiment of the present invention will be described. 4 is a perspective view of a non-point pollution abatement facility 100 having a detached super-heated waterway 130 according to an embodiment of the present invention. FIG. 5 is a plan view of a non-point pollution abatement facility 100 having a detached super-heated waterway 130 according to an embodiment of the present invention.

4 and 5, the non-point pollution abatement facility 100 having the detachable supernatant waterway 130 according to an embodiment of the present invention is adapted to retrofit the existing collecting pool 120, It can be seen that the non-point pollutants in the initial effluent can be removed only by quickly installing the filter 130 in a site close to the existing waterway 1.

The nonpoint pollution abatement facility 100 having the separate superheated waterway 130 according to an embodiment of the present invention includes a rainwater collecting unit 120 for collecting rainwater runoff on a road surface, And a first water channel 130 connected to the first end 124 of one side of the water collecting unit 120 to receive the initial effluent out of the rainwater runoff collected in the water collecting unit 120, The existing waterway 1 or the like connected to the second end 125 of the one side of the crystal 120 and flowing out from the rainwater runoff collected in the water collector 120 into the ultra- As shown in FIG. Therefore, the initial effluent is filtered by the super-fresh water passage 130 and merged to one side of the existing water channel 1. [

Concretely, the rainwater runoff flowing on a road surface such as a road or the like is collected by the collection collector 120 through the induction waterway 110. As shown in FIGS. 4 and 5, it can be seen that the induction channel 110 has a predetermined inclination from the road surface to the collecting surface 120 side. Therefore, the rainwater effluent flowing on the road surface through the induction waterway 110 flows into the collector 120.

In addition, the initial effluent of the rainwater flowing into the collection tank 120 is collected and stored in the collection tank 120, and the non-point pollutants are settled. 4 and 5, the collecting unit 120 has a rectangular cross-section, such as a conventional collecting tank, and has a first end 124 connected to the supernatant passage 130, And the second end 125 connected to the first passage 1 is provided.

The height of the first end 124 of the collecting corrugation 120 is the same as the height of the collecting cores 120 and the discharge port 123 is formed in the second end 125 connected to the existing water channel 1 And is formed to be lower than the height of the first end 124.

6A is a cross-sectional view of a non-point pollution abatement facility 100 on a collecting surface 120 side where an initial effluent flows into an ultra-fresh water path 130 through an orifice 122 according to an embodiment of the present invention . 6B is a cross-sectional view of the non-point pollution abatement facility 100 on the side of the wind turbine 120 in a state where the ferro-effluent water flows into the existing water channel 1 in excess of the discharge port 123 according to an embodiment of the present invention. Respectively.

6A and 6B, it can be seen that an inlet hole 121 having a shooting cross-section is formed at the first end 124 at one side of the collector 120 according to an embodiment of the present invention. have. The orifice 122 is installed in the inflow hole 121. The initial effluent outflow of the rainwater flowing into the refinement 120 flows into the ultra-fresh water path 130 through the orifice 122 .

That is, when the rainfall runoff is continuously introduced, the water surface of the rainwater flowing into the wind tunnel 120 reaches the height at which the inlet hole 121 is formed. When the water level rises up to the point where the inlet hole 121 is located, So that the initial effluent is introduced into the supernatant water passage 130 through the second passage 122.

6A and 6B, the height of the second end 125 of one side of the collecting crystal 120 is higher than the distance between the lower surface of the collecting crystal 120 and the inflow hole 121 The initial effluent flowing in at the beginning does not flow into the existing waterway 1 but flows through the orifice 122 into the superheated waterway 130 .

6B, when the rainwater effluent is continuously introduced and the water level of the rainwater collected in the water collecting unit 120 reaches the height of the second end 125, The rainwater effluent starts to flow into the existing waterway 1 through the outlet 123 of the waterway. Accordingly, only the initial number of outflows can be introduced into the ultra-fresh water passage 130 by the structure of the collecting cores 120.

The initial effluent that has flowed into the supernatant passage 130 through the orifice 122 is filtered by filtration, fresh water, sedimentation by the vegetation water planted in the supernatant passage 130, infiltration into the lower soil, Is removed. 7 shows a cross-sectional view of a non-point pollution abatement facility 100 on an existing waterway 1 side according to an embodiment of the present invention.

As shown in FIGS. 4 and 7, it can be seen that the supernatant passage 130 is installed in an existing member located close to the longitudinal direction of the existing waterway 1. Also, a wall 131 having a specific height is installed between the supernatant waterway 130 and the existing waterway 1. Therefore, the initial effluent flowing into the supernatant passage 130 is merged into the existing canal 1 at the end of the wall 131 after the non-point contaminants are removed from the supernatant passage 130. In addition, the flooded waterway 130 can be installed by selecting the bottom surface of the existing site and planting the vegetation water on the bottom surface. Through the flooded waterway 130, the initial effluent water is filtered by the vegetation water, , Precipitation and penetration into the lower soil and evaporation remove non-point contaminants.

Hereinafter, a method of reducing non-point pollution with a detachable supernatant passage 130 according to an embodiment of the present invention will be described. FIG. 8 shows a flow chart of a method for reducing non-point pollution with a detached superheated waterway 130 according to an embodiment of the present invention.

First, a rainfall runoff on a road surface such as a road is led to the induction waterway 110 (S10). Then, the rainwater effluent led to the induction waterway 110 is collected by the dust collector 120 connected to the induction waterway 110 (S20). The contaminants of the rainwater runoff collected by the collection unit 120 are settled by the collection unit 120.

The initial effluent of the stormwater collected in the stormwater collecting compartment 120 is discharged through the orifice 122 provided in the inlet hole 121 formed in the first end 124 of the collecting compartment 120, (S30). The initial effluent flowing into the supernatant passage 130 is removed from the supernatant passage 130 and merged into the existing water passage 1 at step S40. In addition, the flooded waterway 130 can be installed by selecting the bottom surface of the existing site and planting the vegetation water on the bottom surface. Through the flooded waterway 130, the initial effluent water is filtered by the vegetation water, , Precipitation and penetration into the lower soil and evaporation remove non-point contaminants.

When the rainwater effluent continuously flows into the collection tank 120 and the water level of the rainwater runoff exceeds the height of the second end 125 of the collection tank 120, (S50). ≪ / RTI > That is, as described above, the height of one second side end 125 of one side of the collecting crystal 120 is set to be higher than the length between the inlet hole 121 and the bottom side of the collecting crystal 120 by a specific length, The rainwater effluent flowing in excess of the height of the one end (125) flows into the existing waterway (1) through the discharge port (123).

1: existing waterway
2: Flow distribution structure
3: Pretreatment tank
4: Mitigation facilities
10: Non-point pollution abatement facilities
100: Non-point pollution abatement facilities with detached caustic channels
110: Induced waterway
120: Edit the house
121: inlet hole
122: Orifice
123: Outlet
124: First Stage
125: 2nd stage
130: with fresh water
131: Wall
W: Outlet width
H: Correction height
H ₁ : Fence height
D: Depth of compaction, distance between inflow hole and compaction bottom
H ₂ + D: Height of second edge

Claims (19)

Correction of stormwater runoff;
An induction water path for leading the rainwater runoff by the collection of the collected water;
An ultra-fresh water which is connected to a first end of the one side of the collecting and into which the initial effluent of the rainwater collected in the collecting compartment flows; And
And an existing water channel connected to a second end of the one side of the water collecting and through which the rainwater effluent not flowing into the fresh water channel flows,
Wherein the initial effluent is filtered by the grazing water channel and merged to one side of the existing water channel.
The method according to claim 1,
Wherein the vegetation water is planted in the existing site adjacent to the existing water channel along the longitudinal direction of the existing water channel.
The method according to claim 1,
Further comprising a wall provided between the grazing water channel and the existing water channel.
The method of claim 3,
Wherein the initial effluent flowing into the grazing water channel is merged from the end of the wall positioned at the end of the flow direction into the existing water channel.
The method according to claim 1,
Wherein an inlet hole is formed at a first end of the collecting hole so that the initial effluent is introduced into the grazing water channel through the inlet hole.
6. The method of claim 5,
Characterized in that an orifice is provided in the inflow hole.
6. The method of claim 5,
Wherein the height of the second side of the one side of the corrugation is higher than the length between the inlet hole and the bottom side of the corrugation by a specific length.
8. The method of claim 7,
Wherein the specific length is 20 to 30 cm.
The method according to claim 1,
And the induction channel is inclined toward the collecting side.
The present invention relates to a structure in which superfluous water is installed in close proximity to a flow distribution structure for introducing rainwater runoff on a road surface into an existing waterway by an induction waterway,
Collecting the rainwater runoff by the induction waterway; And
And a brine flow passage connected to a first end of the one side of the brine to introduce the initial brine from the brine collected in the brine collection,
Wherein the existing water channel is connected to a second end of the one side of the water collecting compartment so that effluent water not flowing into the fresh water channel among the storm water collected in the water collecting compartment flows,
Wherein the initial effluent is filtered by the fresh water channel and merged into one side of the existing water channel.
11. The method of claim 10,
Wherein the vegetation water is planted in an existing site adjacent to the existing water channel along the longitudinal direction of the existing water channel.
11. The method of claim 10,
Further comprising a wall provided between the grazing water channel and the existing water channel, wherein the initial effluent water flowing into the grazing water channel merges from the end of the wall positioned at the end in the flow direction to the existing water channel. Separate super - water structure installed in facilities.
11. The method of claim 10,
Wherein the initial effluent flowing into the fresh water channel is permeated and evaporated into filtration, fresh water, sedimentation, and lower soil by vegetation water, and is installed in a non-point pollution abatement facility.
In the nonpoint pollution abatement method,
A step of introducing the runoff water flowing on the road surface to the induction waterway;
Collecting the rainfall runoff induced in the induction channel by a house correction connected to the induction channel;
Wherein the initial effluent of the rainwater runoff collected in the collection is introduced into the first generation channel connected to the first end of the collecting channel;
The initial effluent flowing into the grazing channel is filtered and merged into an existing channel; And
Wherein the rainfall effluent that has not flowed into the grazing water channel flows into the existing channel connected to the second end of the collecting channel.
15. The method of claim 14,
Wherein the grazing water channel further comprises a wall provided between the grazing water channel and the existing water channel in which vegetation water is planted in an existing site located close to a longitudinal direction of the existing water channel, A method for reducing nonpoint pollution.
16. The method of claim 15,
The method of claim 1,
Wherein the initial effluent flowing into the grazing water channel is joined from the end of the wall located at the end of the flow direction to the existing water channel.
15. The method of claim 14,
The method of claim 1,
Characterized in that an inlet hole is formed in a first end of the collecting hole and an orifice is provided in the inlet hole so that the initial effluent is introduced into the nacelle through the orifice. Way.
18. The method of claim 17,
Wherein a height of a second one end of the one side of the collector is higher than a length between the inlet hole and the bottom of the collector,
The method of claim 1,
Wherein the rainwater effluent flowing into the existing channel exceeds the height of the second end of the channel.
15. The method of claim 14,
Wherein the initial effluent flowing into the freshwater channel is permeated and evaporated into filtration, fresh water, sedimentation, and lower soil by vegetation water.

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