KR101494296B1 - A Non-power Automatic Back-washing Type Equipment for Decreasing Non-point Pollution of First Flush - Google Patents

Abstract

The present invention relates to an initial rain nonpoint pollution reducing facility comprising a precipitation tank and a filtration tank. More specifically, the present invention relates to a nonpowered automatic backwash-type initial rain nonpoint pollution reducing facility comprising a backwash unit which allows foreign substances collected on a filtration unit filtering contaminants to flow backwards with water when the filtration unit is clogged and thus allows the filtration unit to be automatically washed, thereby dispensing with a separate replacement or washing process of the filtration unit; and allowing the filtration unit to be automatically washed without a separate power to allow the convenient management and continuous use of the initial rain nonpoint pollution reducing facility. The backwash unit comprises a siphon connected to the filtration tank; and a backwash start unit discharging compressed air from the siphon to allow the discharge of foreign substances collected on the filtration unit to be started, thereby allowing foreign substances collected on the filtration unit to flow backwards with water by the discharge of compressed air; and allowing water and foreign substances to be continuously discharged by siphon principle. The backwash unit comprises a backwash stop unit comprising an air inlet pipe which has one side end connected to a bent pipe part of the siphon and the other side end connected to the filtration tank, thereby allowing air to flow in according to the level of filtered water stored in the filtration tank. Accordingly, when the water in the filtration tank flows backwards according to a backwash process and the water level is lowered, the backwash process is stopped at a certain water level and a normal filtration process is allowed to be automatically performed again.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a non-powered automatic back-

The present invention relates to an initial excellent non-point pollution abatement facility including a settling tank and a filtration tank. More particularly, the present invention relates to a retrofit This makes it possible to perform convenient management and continuous use of the initial excellent non-point pollution abatement facility by allowing the filtration unit to be automatically cleaned without any additional power, And a backwash initiation part for discharging the compressed air from the siphon tube and starting the discharge of the foreign matter accumulated in the filtration part so that the foreign matter accumulated in the filtration part flows back together with the water through the discharge of the compressed air, In order to ensure continuous discharge of water and foreign matter, And a backwash stopper including an air inlet pipe connected to the bending portion of the tube and having an other end connected to the filtration tank so as to allow air to flow in accordance with the level of the filtration water stored in the filtration tank, And a non-powered automatic backwashing type initial non-point pollution abatement facility for automatically back-washing the water at a certain level when the water level is lowered.

In general, water pollution sources can be divided into point pollution sources and nonpoint pollution sources. Point pollution sources are mainly generated from domestic sewage, industrial wastewater generated from general households and business areas, industrial wastewater generated from factories, and animal wastewater generated from large- Non-point sources are sometimes called non-specific pollutants, surface pollutants, mobile pollutants, or other pollutants. Unlike point pollutants having specific discharge paths, non-point pollutants can be classified as urban drainage or farmland drainage. Refers to a place or area that generates non-point pollutants through an unspecified discharge path.

In the past, most countries have been focusing on the treatment of point pollutants. However, due to the increase of non-point pollution sources due to the increase in the ratio of impervious piles to residential land and roads due to the improvement of land use since the mid-20th century, It was recognized that there was difficulty in achieving the goal. As a result of examining the ratio of loads between the four major rivers and nonpoint sources in the Ministry of the Environment, the ratio of nonpoint sources among the total pollutants is 40 ~ 60% (2009 Environmental White Paper). As a result, And the necessity of nonpoint pollution source reduction management has been increased.

The initial storm means the storm that the storm in early rainfall flows through the surface of the ground and the sewer and cleans the sediments deposited on the impervious surface and the sediments of the sewer pipe to contain relatively high concentrations of pollutants. And polluting rivers and the like, thereby deteriorating the quality of water.

Therefore, as a countermeasure to reduce non-point pollution in the past, in order to reduce the pollution of non-point pollution, a drainage tank is installed in an urban area to allow pollutants generated due to the initial rainfall to be discharged and discharged, In recent years, as shown in the following Patent Document, a device for treating non-point pollutants contained in rainwater by precipitation and filtration method is installed so as to prevent boiling water from entering into the boiling point Efforts are being made to reduce pollution. However, in the non-point pollution abatement apparatus using the filtration system as in the following Patent Document, when the filter medium for filtration is clogged by foreign substances such as pollutants, the abdomen introduced into the abatement apparatus can not be filtered, In order to solve this problem, the filter medium must be replaced or cleaned. In reality, the abatement apparatus is not properly managed and non-point pollutants are discharged to the river as it is.

(Patent Literature)

Patent Registration No. 10-1249179. "Non-point pollution abatement equipment that can be installed in a limited space"

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems,

The present invention relates to an initial excellent non-point pollution abatement facility including a settling tank and a filtration tank, including a backwashing unit for allowing foreign matter accumulated in the filtration unit to flow back together with water when the filtration unit for filtering pollutants is blocked, This system eliminates the necessity of replacing or washing the filtration part of the filtration system and automatically cleans the filtration part without any additional power so as to enable convenient management and continuous use of the initial excellent nonpoint pollution reduction facility. The purpose is to provide.

The backwashing unit includes a backwashing unit for discharging compressed air from a siphon tube and a siphon tube connected to the filtration tank to start discharge of foreign matter accumulated in the filtration unit. The present invention provides a non-powered, automatic backwash-type initial excellent non-point pollution abatement facility that allows accumulated substances to flow back together with water, and ensures that water and foreign matter are continuously discharged by the siphon principle.

The present invention relates to a filtration apparatus, comprising: a backflow water inflow section connected to a settling tank and having a water flow back from a filtration tank; And an opening / closing part for opening and closing the siphon tube according to the water level of the backwash water, wherein the backwashing start part includes a backwashing start part which receives the backwash water from the backwash water inflow part, When the water level reaches a certain level, compressed air in the siphon tube is discharged to start backwashing, thereby automatically starting backwashing and also preventing non-reciprocal damage due to backwash water. It is aimed to provide a pollution abatement facility.

The present invention relates to a backflow water storage tank for storing backwash water transmitted from a backwash water inflow section, a float formed on the water surface of the backwash water stored in the backwash water reservoir and rising and falling together with the rising and falling of the water surface, And a valve for opening and closing the siphon tube according to the opening degree of the siphon tube. The non-powered automatic backwashing type initial high boiling point pollution It is aimed to provide abatement facilities.

The present invention relates to a siphon tube having one end connected to a filtration tank and having an inclination rising upward from one end to a curved portion and the other end being formed at a lower position than one end, And the back side of the siphon tube is discharged to the other end of the siphon tube by the siphon principle, so that the backwashing can be continuously performed.

The present invention includes a backwashing section including a backwash stop section for stopping backwash by allowing air to flow into a siphon tube so that backwashing can be stopped and a normal filtration process can be performed again. It is aimed to provide abatement facilities.

The present invention includes a backwash stop section including an air inlet pipe having one end connected to a bending portion of a siphon tube and the other end connected to a filtration tank so as to allow air to flow in accordance with the level of the filtration water stored in the filtration tank, The present invention also provides a non-motorized automatic backwashing type initial non-point pollution abatement facility for allowing the backwashing to stop at a certain level when the water level of the filtration tank is lowered due to the backwash of the filtration tank.

The present invention relates to a washing machine comprising a backwash stop part including a backwash time adjusting part for adjusting a water level of filtered water into which air is introduced into an air inlet pipe, It is aimed to provide a pollution abatement facility.

The present invention relates to a siphon tube, comprising: a housing surrounding one end of a siphon tube and protruding downward; And a height adjusting means for adjusting the height of the housing, so that air can be introduced into the air inlet pipe only when the water level of the filtration tank falls below the lower end of the housing, Which is a non-powered automatic backwash type initial non-point non-point pollution abatement facility.

The present invention relates to a filtration unit in which water from which a contaminant is primarily removed is introduced from a settling tank; A water collection tank formed below the filtration unit and collecting the filtered water filtered by the filtration unit; And a filtration tank which is formed on the upper side of the filtration unit and is connected to the collection tank to store the filtration water. By allowing the filtration water to be stored in the filtration water storage tank, the filtration water stored in the filtration water storage tank, The present invention also provides a non-powered automatic backwashing type initial non-point pollution abatement facility that can be used as negative wash water.

In the present invention, a plurality of filtration units are formed in parallel, and a pyramidal separation membrane is formed on the upper side of the plurality of filtration units to separate the filtration water from the filtration water storage tank. One end of the siphon pipe is connected to the upper vertex of the separation membrane, And an object of the present invention is to provide a non-powered, automatic backwashing type initial non-point pollution abatement facility capable of smoothly discharging foreign matter discharged from a filtration unit through a siphon tube.

The present invention includes a filtration unit including an inlet unit for introducing water from the settling tank and a filtration module for filtering contaminants of water formed downward from the inlet unit and falling downward from the inlet unit. The inlet unit includes an inlet hole communicating with the settling tank, And an inflow pipe communicating with the inflow hole to allow water to flow therethrough. The inflow pipe is formed into a cylindrical shape with an open top, so that water flowing through the inflow pipe is overflowed to naturally fall into the filtration module and the water is uniformly distributed to the end of the filtration module The present invention provides a non-powered, automatic backwashing type initial non-point pollution abatement facility capable of increasing filtration efficiency.

The present invention includes a settling tank including a plurality of initial storm inflow tubes into which initial stormwater is introduced, the initial storm inflow tube including a plurality of initials including an inlet through which initial stormwater flows and an outlet formed by being split from the inlet to both sides, The present invention aims to provide a non-powered, automatic backwash-type initial excellent non-point pollution abatement facility capable of enhancing sedimentation efficiency of a sedimentation tank by causing collision of initial outpour from each outlet of each stormwater inflow pipe to form lumps.

The present invention includes an initial stormwater inflow tube in which a plurality of outflow ports are formed to increase the velocity of the initial storm that is ejected from the outflow port and increase the collision frequency of the initial storm that is ejected from the outflow port, And a non-powered automatic backwashing type initial non-point pollution abatement facility.

The present invention includes an outlet including a guide plate projecting on both sides along the outer perimeter so that the initial storm jetted from the outlet of each initial storm inlet pipe collides with the initial storm jetted from the opposite outlet without deviating up and down The present invention aims at providing a non-powered automatic backwashing type initial non-point pollution abatement facility that makes the formation of lumps more efficient.

The present invention includes a sedimentation tank including an inclined wall which is fixed on the upper side of the sedimentation tank and is inclined to the side from which the initial sediment flows from the upper side to the lower side, so that the initial storm introduced into the sedimentation tank is lowered downward by the inclined wall Purpose non-point pollution abatement facility that can improve the sedimentation efficiency of the sedimentation tank because the contaminants contained in the initial rainfall are more closely adhered and the traveling speed to the lower side is increased and lumps are more easily generated. have.

In order to achieve the above object, the present invention is implemented by the following embodiments.

According to one embodiment of the present invention, there is provided a non-powered automatic backwash-type initial excellent non-point pollution abatement facility, comprising: a sedimentation tank in which an initial storm flows and pollutants are deposited; A filtration tank into which the polluted matter is removed by the sedimentation tank, and a pollutant is filtered by the filtration unit; And a backwashing unit connected to the filtration unit and configured to backwash foreign substances accumulated in the filtration unit together with water flowing backward when foreign substances are accumulated in the filtration unit and water flows backward, Thereby causing additional washing.

According to another embodiment of the present invention, in the non-motorized automatic backwash-type early excellent nonpoint pollution abatement facility according to the present invention, the backwashing portion is connected to the filtration tank and discharges water and foreign substances flowing backward, A siphon tube having a portion; And a backwash initiation part for discharging compressed air from the siphon tube to start discharging the foreign substances accumulated in the filtration part.

According to another embodiment of the present invention, in the non-powered automatic backwash-type initial excellent nonpoint pollution abatement facility according to the present invention, the backwash initiation part is connected to the sedimentation tank, Wealth; And an opening / closing unit for opening / closing the siphon tube according to the water level of the backwash water by receiving and storing the backwash water from the backwash water inflow unit.

According to another embodiment of the present invention, there is provided a non-powered automatic backwash-type initial excellent non-point pollution abatement facility according to the present invention, wherein the opening / closing unit includes a backwash water storage tank for storing the backwash water transferred from the backwash water inflow unit, A float formed on the water surface of the counter current water stored in the counter current water storage tank and rising and falling together with the rising and falling of the water surface, and a valve for opening and closing the siphon pipe according to the rising and falling of the float.

According to another embodiment of the present invention, there is provided a non-motorized automatic backwash-type initial excellent nonpoint pollution abatement facility according to the present invention, wherein the backwashing unit includes a backwash stopper stopping backwash by allowing air to flow into the siphon tube .

According to another embodiment of the present invention, there is provided a non-motorized automatic backwash-type initial excellent nonpoint pollution abatement facility according to the present invention, wherein the backwash stopper has one end connected to the bending portion of the siphon tube, And an air inlet pipe connected to the filtration tank so that air flows in accordance with the level of the filtration water stored in the filtration tank.

According to another embodiment of the present invention, there is provided a non-motorized automatic backwash-type initial excellent nonpoint pollution abatement facility according to the present invention, wherein the backwash stoppage includes a backwash station for controlling the water level of the filtered water, And a cleaning time adjusting unit to adjust a time point at which the backwashing ends.

According to another embodiment of the present invention, in the non-powered automatic backwash-type initial excellent nonpoint pollution abatement facility according to the present invention, the backwash time regulating unit surrounds the other end periphery of the air inflow pipe, A housing formed therein; And height adjusting means for adjusting the height of the housing.

According to another embodiment of the present invention, in the non-powered automatic backwash-type initial excellent non-point pollution abatement facility according to the present invention, the filtration unit includes a filtration unit, ; A water collection tank formed below the filtration unit and collecting the filtered water filtered by the filtration unit; And a filtering water reservoir formed above the filtering unit and connected to the water collecting tank to store the filtered water.

According to another embodiment of the present invention, there is provided a non-motorized automatic backwash-type initial excellent non-point pollution abatement facility according to the present invention, wherein the filtration tank has a plurality of filtration units formed in parallel, and on the upper side of the plurality of filtration units, And a sidewall of the siphon tube is connected to an upper vertex of the separation membrane.

According to another embodiment of the present invention, there is provided a non-motorized automatic backwash-type initial excellent non-point pollution abatement facility according to the present invention, wherein the filtration unit includes an inflow portion into which water is introduced from the settling tank, And a filtration module for filtering contaminants of water falling down from the inflow section, wherein the inflow section includes an inflow hole communicating with the settling tank and an inflow pipe communicating with the inflow hole to allow water to flow therethrough, And the filter module is formed in a cylindrical shape with its upper side opened so that water flowing through the inflow pipe can be naturally dropped to the filtration module.

According to another embodiment of the present invention, there is provided a non-motorized automatic backwash-type initial high boiling point pollution abatement facility according to the present invention, wherein the settling tank includes a plurality of initial storm inflow pipes into which initial stormwater flows, Wherein the tube comprises an inlet through which the initial storm flows and an outlet formed by being split from the inlet to both sides so that the initial storm jetted from an outlet of each of the plurality of initial storm inlet tubes collides to form a lump, Thereby improving the efficiency.

According to another embodiment of the present invention, there is provided a non-motorized automatic backwash-type initial excellent non-point pollution abatement facility according to the present invention, in which a plurality of the outlets are formed so as to increase the velocity of the initial exholiation from the outlet, Thereby further increasing the efficiency.

According to another embodiment of the present invention, there is provided a non-motorized automatic backwash-type initial excellent non-point pollution abatement facility according to the present invention, wherein the outlet comprises a guide plate projecting on both sides along an outer circumference, So that the collision of the initial storm jetted from the outlet of the pipe is made more efficient.

According to another embodiment of the present invention, in the non-powered automatic backwash-type initial excellent non-point pollution abatement facility, the sedimentation tank is fixed on the upper side of the sedimentation tank, And an inclined wall formed so as to be inclined, thereby enhancing the sedimentation efficiency of the sedimentation tank.

The present invention can obtain the following effects by the above-described embodiment, the constitution described below, the combination, and the use relationship.

The present invention relates to an initial excellent non-point pollution abatement facility including a settling tank and a filtration tank, including a backwashing unit for allowing foreign matter accumulated in the filtration unit to flow back together with water when the filtration unit for filtering pollutants is blocked, It is unnecessary to replace the filtration part of the filtration part or to clean the filtration part, and the filtration part is automatically cleaned without any additional power, thereby making it possible to conveniently manage and continuously use the initial excellent nonpoint pollution reduction facility.

The backwashing unit includes a backwashing unit for discharging compressed air from a siphon tube and a siphon tube connected to the filtration tank to start discharge of foreign matter accumulated in the filtration unit. So that the accumulated foreign matter can flow back together with the water, and the discharge of water and foreign matter can be continuously performed by the Siphon principle.

The present invention relates to a filtration apparatus, comprising: a backflow water inflow section connected to a settling tank and having a water flow back from a filtration tank; And an opening / closing part for opening and closing the siphon tube according to the water level of the backwash water, wherein the backwashing start part includes a backwashing start part which receives the backwash water from the backwash water inflow part, When the water level reaches a certain level, the compressed air in the siphon tube is discharged to start the backwashing, so that the backwashing is automatically started and the secondary damage due to the backwash water can be prevented.

The present invention relates to a backflow water storage tank for storing backwash water transmitted from a backwash water inflow section, a float formed on the water surface of the backwash water stored in the backwash water reservoir and rising and falling together with the rising and falling of the water surface, And a valve for opening and closing the siphon tube according to the flow rate of the siphon tube.

The present invention relates to a siphon tube having one end connected to a filtration tank and having an inclination rising upward from one end to a curved portion and the other end being formed at a lower position than one end, Thereafter, the water in the filtration tank is backwashed by the siphon principle to be discharged to the other end of the siphon tube, so that backwashing can be continuously performed.

The present invention includes a backwashing unit including a backwash stopper stopping backwashing by allowing air to flow into the siphon tube, thereby stopping backwashing and allowing a normal filtration process to proceed again.

The present invention includes a backwash stop section including an air inlet pipe having one end connected to a bending portion of a siphon tube and the other end connected to a filtration tank so as to allow air to flow in accordance with the level of the filtration water stored in the filtration tank, When the water in the filtration tank is backwashed by the washing and the water level is lowered, the backwashing is stopped at a certain level and the normal filtration process is performed.

The present invention includes a backwash stop section including a backwash time adjusting section that adjusts the level of filtered water to which air is introduced into the air inlet pipe, so that the time point at which the backwash is finished can be adjusted.

The present invention relates to a siphon tube, comprising: a housing surrounding one end of a siphon tube and protruding downward; And a height adjusting means for adjusting the height of the housing, so that air can be introduced into the air inlet pipe only when the water level of the filtration tank falls below the lower end of the housing, So that the termination of the operation can be accurately performed.

The present invention relates to a filtration unit in which water from which a contaminant is primarily removed is introduced from a settling tank; A water collection tank formed below the filtration unit and collecting the filtered water filtered by the filtration unit; And a filtration tank which is formed on the upper side of the filtration unit and is connected to the collection tank to store the filtration water. By allowing the filtration water to be stored in the filtration water storage tank, the filtration water stored in the filtration water storage tank, So that it can be used as negative washing water.

In the present invention, a plurality of filtration units are formed in parallel, and a pyramidal separation membrane is formed on the upper side of the plurality of filtration units to separate the filtration water from the filtration water storage tank. One end of the siphon pipe is connected to the upper vertex of the separation membrane, So that the foreign matter discharged from the filtration unit can be smoothly discharged through the siphon tube.

The present invention includes a filtration unit including an inlet unit for introducing water from the settling tank and a filtration module for filtering contaminants of water formed downward from the inlet unit and falling downward from the inlet unit. The inlet unit includes an inlet hole communicating with the settling tank, And an inflow pipe communicating with the inflow hole to allow water to flow therethrough. The inflow pipe is formed into a cylindrical shape with an open top, so that water flowing through the inflow pipe is overflowed to naturally fall into the filtration module and the water is uniformly distributed to the end of the filtration module So that the filtration efficiency can be increased.

The present invention includes a settling tank including a plurality of initial storm inflow tubes into which initial stormwater is introduced, the initial storm inflow tube including a plurality of initials including an inlet through which initial stormwater flows and an outlet formed by being split from the inlet to both sides, It is possible to increase the sedimentation efficiency of the sedimentation tank by allowing the initial storm jetted from the outflow port of each of the storm inflow pipes to collide with each other to form lumps.

The present invention includes an initial stormwater inflow tube in which a plurality of outflow ports are formed to increase the velocity of the initial storm that is ejected from the outflow port and increase the collision frequency of the initial storm that is ejected from the outflow port, There is an effect that can be increased.

The present invention includes an outlet including a guide plate projecting on both sides along the outer perimeter so that the initial storm jetted from the outlet of each initial storm inlet pipe collides with the initial storm jetted from the opposite outlet without deviating up and down There is an effect that the formation of the lumps can be performed more efficiently.

The present invention includes a sedimentation tank including an inclined wall which is fixed on the upper side of the sedimentation tank and is inclined to the side from which the initial sediment flows from the upper side to the lower side, so that the initial storm introduced into the sedimentation tank is lowered downward by the inclined wall The contaminants contained in the initial storm are more closely adhered to each other and the moving speed to the lower side is increased, so that lumps are more easily generated, and the sedimentation efficiency of the sedimentation tank can be increased.

1 is a view showing a configuration of a non-powered automatic backwash-type initial excellent non-point pollution abatement facility according to an embodiment of the present invention;
FIG. 2 is a plan view of a non-powered automatic backwash type initial excellent nonpoint pollution abatement facility according to an embodiment of the present invention.
FIG. 3 is a reference view showing the flow of water during normal operation of the non-powered automatic backwashing type initial excellent non-point pollution abatement facility according to an embodiment of the present invention.
4 is a cross-sectional view taken along line AA in Fig. 1
Fig. 5 is a perspective view of the initial storm inflow pipe of Fig.
Fig. 6 is a cross-sectional view of the inflow pipe as viewed in Fig. 1
FIG. 7 is a view for explaining the flow of water when the filtration module is contaminated;
8 is a view for explaining the operation of the backwash start portion
9 is a reference view for explaining the flow of water when the backwash is in progress
10 is a view for explaining the operation of the backwashing section when backwashing is in progress.
11 is a reference diagram for explaining the flow of water when the backwashing is stopped
12 is a view for explaining the operation of the backwashing section when the backwashing is stopped;
Fig. 13 is an enlarged view of a portion C in Fig. 1
14 is a reference diagram for explaining a method of adjusting the backwash time adjusting unit

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a non-powered automatic backwash-type initial excellent non-point pollution abatement facility according to the present invention will be described in detail with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements, rather than excluding other elements, unless specifically stated otherwise.

Referring to FIGS. 1 to 14, the initial non-point pollution abatement facility according to an embodiment of the present invention includes a non-motive automatic backwash-type initial non-point pollution abatement facility, A sedimentation tank 1 installed for purifying, in which initial storms are introduced and contaminants are deposited; A filtration tank 3 into which the polluted matter is removed by the sedimentation tank 1 and the polluted matter is filtered by the filtration unit 31; A backwashing unit 5 connected to the filtration unit 3 and configured to backwash the foreign material accumulated in the filtration unit 31 together with the water flowing backward when the foreign material is accumulated in the filtration unit 31 and water flows backward, , Allowing the filtration unit to be cleaned automatically without using any additional power. As described in the Background Art, the initial storm means that the storm in the early stage of rainfall cleans the contaminants deposited on the impervious surface and the sediments of the sewer pipe while flowing through the surface and the sewer, The non-point pollutants are included in the initial pollutants to pollute rivers and the like, thereby deteriorating the quality of the water. Before the initial pollutants are introduced into the river, the pollutants are settled and filtered by installing the initial non- The filtration unit 31 is automatically cleaned without the need of replacing the separate filtration unit 31 and the cleaning operation, thereby facilitating the management of the facility and preventing secondary damage caused by reverse flow or the like.

As shown in FIG. 1, the sedimentation tank 1 has a structure in which an initial stormwater is introduced and contaminants are precipitated. The sedimentation tank 1 is formed at a front end of the initial stormwater non-point pollution reduction facility and includes a plurality of initial stormwater inflows A slope wall 13 formed inside the settling tank 1 for increasing the sedimentation efficiency and water that has been settled by the settling tank 1 and has been removed by the overflow, (Not shown). The reverse flow of the reverse flow by the clogging of the filtration unit 31 can be supplied to one side of the upper part of the settling tank 1 to be supplied to the reverse flow water inflow unit 531 of the backwashing unit 5 531a are formed, and a detailed description thereof will be described later.

As shown in FIG. 4, a plurality of the initial storm inflow pipe 11 may be connected in parallel to each other, and the initial storm inflow pipe 11 may be formed as a T-shaped pipe . However, it may also be formed into tubes of various shapes. As shown in FIG. 5, the initial storm inflow pipe 11 includes an inflow port 111 through which the initial storm flows and an outflow port 113 through which the initial storm inflow from the inflow port 111 is discharged.

The inlet 111 may be connected to a gut pipe or the like and may be connected to the inlet 111 of each of the plurality of initial storm inlet pipes 11, So that the initial outflow can be injected into the outflow opening 113 of the ink tank.

The outlet 113 is branched from the inlet 111 to both sides to discharge an initial storm that has flowed into the inlet 111 into the settling tank 1, As shown in FIG. 4, the outflow openings 113 are formed to face each other, so that initial outflows discharged from the respective outflow openings 113 collide with each other to form a flocculated floc. Therefore, the contaminants contained in the initial storm collide with each other to be agglomerated masses, thereby increasing the specific gravity thereof and increasing the amount of the contaminants to be precipitated, thereby increasing the sedimentation efficiency of the sedimentation tank 1. In addition, a plurality of the outlets 113 may be formed in the upper and lower portions to increase the velocity of the initial outflow from the outflow opening 113, thereby increasing the collision strength, collision frequency, etc. between the contaminants included in the initial outflow, So that it can be formed better. In addition, the outlet 113 includes a guide plate 113a extending to protrude along the outer circumference, so that the initial outlet injected from the outlet 113 does not deviate vertically, So that it can collide with superiority more efficiently.

As shown in FIG. 3, the inclined wall 13 is fixed to the upper side of the sedimentation tank 1 and is inclined to the side where the initial storm flows from the upper side to the lower side, that is, toward the initial storm inflow pipe 11 side In the plate-like configuration, a space through which water can pass is formed in the lower part of the inclined wall 13. [ The slope wall 13 passes through a narrow space where the initial storm flows through the initial storm inflow pipe 11 toward the lower part of the sedimentation tank 1 so that the contaminants contained in the initial storm are more closely adhered So that the sedimentation is facilitated by allowing the sediment to coagulate with each other. The space that becomes narrower and narrower toward the lower side accelerates the downward initial velocity and the velocity of the contaminant contained in the initial velocity, so that the sedimentation action becomes more active. In addition, as compared with the side of the initial storm inflow pipe 11 which gradually becomes smaller toward the lower side, the speed of the initial storm rising due to the increase of the area of the opposite storm hole 151 side is slowed down, Is more active. Therefore, the agglomerates of contaminants formed by the plurality of initial storm inflow pipes 11 are further agglomerated by the inclined walls 13, and the speed of the downward flow is increased, so that the sedimentation efficiency of the sedimentation tank 1 is increased And more clean water is directed from the settling tank 1 to the filtration tank 3.

The inflow water tank 15 is a space for temporarily storing water so that purified water after the pollutants are primarily removed by the settling tank 1 can be introduced into the filtration tank 3, And a through hole 151 communicating with the through hole 3. As shown in FIG. 1, the inflow water tank 15 is formed between the settling tank 1 and the filtration tank 3, and water from which contaminants have been removed by sedimentation by the settling tank 1 can be introduced It is preferable that the overflow hole 151 is formed on the upper side of the settling tank 1. A plurality of inflow pipes 311b of the filtration tank 3 are connected to the inflow water tank 15 on the opposite side to the overflow hole 151. Therefore, the water flowing into the throughflow hole 151 is supplied to the filtration tank 3 along the inflow pipe 311b. Further, a siphon tube 51 to be described later passes through the inflow water tank 15.

The overflow hole 151 is a path connecting the settling tank 1 and the inflow water tank 15. The position where the overflow hole 151 is formed is located above the filtered water discharge pipe 39 of the filtration tank 3 So that the water of the inflow water tank 15 can be continuously supplied to the filtration tank 3 by the difference of the head.

As shown in FIG. 3, the filtration tank 3 has a structure in which the water introduced from the inflow water tank 15 is filtered to remove contaminants and then the purified water is discharged. A plurality of filtration units (31) through which filtered water is introduced and filtered; A separation membrane (33) formed on the upper side of the plurality of filtration units (31) and separated from the filtration water storage tank (37); A collecting tank 35 formed below the filtration unit 31 and collecting the filtered water filtered by the filtration unit 31; A filtered water storage tank 37 formed above the filtration unit 31 and connected to the water collection tank 35 to store the filtered water; And a filtered water discharge pipe (39) for discharging the purified water from the filtered water storage tank (37). The backwashing section 5 is connected to the filtration tank 3. The filtration section 31 of the filtration tank 3 is blocked by a foreign substance or the like so that the water is automatically returned to the filtration section 31 So that it is possible to continuously remove contaminants without washing or replacing the separate filtration unit 31, and it is possible to prevent the damage due to backwash of water.

The filtration unit 31 is configured to filter and purify water introduced from the inflow water tank 15 and includes an inflow unit 311 connected to the inflow water tank 15 to receive the water from which the sediment is removed, And a filtration module 313 formed below the inflow section 311 to filter pollutants when water falling downward from the inflow section 311 passes. A plurality of the filtration units 31 are formed in parallel, and the filtration process can be performed simultaneously by the plurality of filtration units 31, thereby shortening the filtration time and increasing the filtration efficiency. A pyramid-shaped separation membrane 33 is formed on the filtration unit 31 and is separated from the filtration water storage tank 37. A siphon tube 51 to be described later is connected to an upper vertex of the separation membrane 33 So that water and contaminants can flow back from the filtration unit 31. A detailed description thereof will be described later.

The inflow section 311 is configured to allow water to flow into the filtration section 31 from the inflow water tank 15 and includes a plurality of inflow holes 311a communicating with the inflow water tank 15, And a plurality of inlet pipes 311b connected to the inlet pipes 311a.

The inflow hole 311a connects the inflow water tank 15 and the inflow pipe 311b to supply water to the filtration tank 3. [

The inflow pipe 311b is configured to be supplied to a plurality of filtration modules 313 formed on the lower side of the water that has passed through the inflow hole 311a. The inflow pipe 311b is formed as a cylindrical pipe having an open top side as shown in FIG. So that water flowing through the inflow pipe 311b flows over the inflow pipe 311b so that it can be supplied to the filtration module 313 naturally. Therefore, water is supplied to the filtration module 313 in a state where water flowing through the inflow pipe 311b reaches the end of the inflow pipe 311b, so that water is uniformly supplied to the entire filtration module 313 Accordingly, the filtration module 313 can be used evenly, and the service life of the filtration module 313 can be further increased.

The filtration module 313 is formed below the inflow pipe 311b to filter contaminants of water flowing from the inflow pipe 311b and includes a filter medium 313a for filtering contaminants, (Not shown). When the filter module 313 is continuously used, the filter module 313 is clogged by foreign substances generated by filtering the contaminants. When the foreign matter trapped in the filtration module 313 increases to increase the filtration load, the filter module 313 is supplied through the inflow pipe 311b Water does not pass through the siphon tube 1 or the siphon tube 51 which will be described later, so that the initial excellent nonpoint pollution abatement facility can not be used. The non-point pollution source due to the initial rainfall is discharged to the river as it is due to the frequent clogging of the filtration module 313 and the inconvenience of management due to backward flow. Therefore, the foreign substances caught in the filtration module 313 are removed through backwashing through the backwashing unit 5, thereby enabling the continuous use of the initial excellent nonpoint pollution abatement facility.

The filter medium 313a is configured to filter the water flowing down from the inflow pipe 311b and is composed of a porous medium such as sand, gravel, activated carbon, etc., so that contaminants can be caught. Therefore, the contaminants are primarily removed while the contaminated water is primarily removed by the settling tank 1 while passing through the filter media 313a and collected in the water collecting tank 35 via the supporting member 313b. do.

The support member 313b is configured to prevent the filter medium 313a from flowing down, and is preferably formed of a metal net such as a strainer so as to prevent fine pollutants from passing therethrough. However, the present invention is not limited thereto, and may be constituted by a block or the like capable of passing water.

The separation membrane 33 is formed in a pyramid shape on the upper side of the filtration unit 31 and precisely on the upper side of the plurality of inflow pipes 311b so that the filtration water storage tank 37 is formed on the upper side of the filtration unit 31 . Therefore, the water stored in the filtered water storage tank 37 can be used as washing water in backwashing, which will be described later, and the siphon tube 51, which will be described later, is connected to the upper vertex of the separation membrane 33, So that it can be discharged together with the water along the siphon tube (51). A detailed description thereof will be described later.

The water collecting tank 35 is formed on the lower side of the support member 313b with a structure in which water filtered by a plurality of the filtration modules 313 is gathered, The collected water is conveyed along the conveying line 351 to the upper side of the filtered water storage vessel 37 as shown in FIG.

The filtered water storage tank 37 is a space in which filtered water transferred from the lower collecting tank 35 is temporarily stored through the transfer pipe 351 and a filtered water discharge pipe 39 is formed on the upper side of the filtered water storing tank 37 So that filtered water can be discharged to rivers and the like. The filtration water storage tank 37 may be formed on the upper side of the filtration unit 31 by the separation membrane 33 and a space through which the filtration water can be stored by forming the filtration water discharge pipe 39 on the upper side So that the filtered water stored in the filtered water storage tank 37 can be used as washing water when backwashing is performed by the backwashing unit 5 to be described later. In other words, the filtered water stored in the filtered water storage tank 37 is lifted through the filter module 313 through the water collection tank 35 by the pressure of the compressed air discharged from the siphon tube 51 to be described later, Foreign matter trapped in the filtration module 313 is floated together and discharged along the siphon tube 51. In addition, a backwash stopper 55, which will be described later, is formed in the filtered water storage tank 37 to stop backwashing according to the level of the filtered water in the filtered water storage tank 37. This will be described later.

The filtered water discharge pipe 39 is formed on the upper side of the filtered water storage tank 37 so that purified water can be discharged from the initial excellent nonpoint pollution abatement facility and is connected to a river to discharge clean water do. The filtrate discharge pipe 39 is formed at a position lower than the overflow hole 151 of the inflow water tank 15 and is continuously supplied from the sedimentation tank 1 to the filtration tank 3 by the difference in head between the settling tank 1 and the filtration tank 3. [ (3) so that the filtration can continue.

Therefore, as shown in FIG. 3, during the normal operation of the initial excellent non-point pollution abatement facility, the pollutants of the initial pollutants introduced through the early storm inflow pipe 11 of the sedimentation tank 1 are separated Collides with the slope wall 113 to form agglomerated agglomerates, which are further agglomerated as they descend down the settling tank 1 along the inclined wall 13, and as a result of the accelerating speed, do. The remaining water flows into the inflow water tank 15 through the rim 151 and flows through the inflow pipe 311b through the inflow hole 311a, The water flowing in the inflow pipe 311b overflows and is supplied to the lower filtration module 313. The water supplied to the filtration module 313 is filtered by the filter medium 313a and the filtered water purified by the filtration module 313 is collected in the water collecting tank 35 to be collected in the filtration water storage tank 351 along the transfer pipe 351, When the level of the filtered water is increased up to the filtered water discharge pipe 39, the filtered water is discharged along the filtered water discharge pipe 39.

If the filtration module 313 accumulates foreign matter in the filtration module 313 due to continuous use and the filtration load of the filtration module 313 increases, the speed at which the water supplied to the filtration tank 3 passes through the filtration module 313 becomes slow, When the flow rate is slower than the flow rate of the initial inflow, the water starts to flow back into the siphon tube 51 and the settling tank 1 to be described later. Accordingly, when the water flowing backward becomes a certain level or more, the backwashing unit 5 starts to operate, and the backwashing of the filtration module 313 is automatically started. Hereinafter, the backwashing unit 5 will be described in detail.

As described above, the backwashing unit 5 is backwashed according to the water level of the backwashing water when the filtration module 313 is blocked, so that the foreign matter trapped in the filtration module 313 is separated The siphon tube 51 and the siphon tube 51, which are connected to the filtration tank 3 to discharge water and foreign substances flowing backward, and the siphon tube 51, And a backwash initiation part (53) for starting the discharge of the foreign matter accumulated in the backwashing part (313). The backwashing section 5 includes a backwash stop section 55 capable of stopping backwash by allowing air to flow into the siphon tube 51 and water flowing through the siphon tube 51 And a backwash water reservoir 57 in which the foreign matter is temporarily stored and then discharged.

1, one end of the siphon tube 51 is connected to the upper vertex of the separation membrane 33 and the other end of the siphon tube 51 is connected to the lower side of the backwash water storage tank 57 As shown in Fig. The siphon tube 51 rises from one end and forms a peak at the bending portion 511 and has a curved tube shape in which the bending portion of the bending portion 511 is straightened down to the other end. 4, the opening / closing part 533 of the backwashing start part 53 is connected to the siphon tube 51 so as to open / close the other side of the siphon tube 51, Water and foreign substances having passed through the siphon tube 51 are temporarily stored in the backwash water storage tank 57 and stored in the backwash water storage tank 57 And is discharged through the backwashing / refluxing path 571 formed in the backwashing /

4, the bending portion 511 indicates the highest point of the siphon tube 51 in which the siphon tube 51 is bent. The position of the bending portion 511 is determined by a backward cleaning start portion The water flowing backward through the siphon tube 51 until the backwashing water starts to flow back to the backflow hole 531a is formed at a position higher than the backflow hole 531a of the siphon tube 531a, When the compressed air in the siphon tube 51 is discharged by the opening and closing part 533 of the backwashing start part 53 described later, the compressed air is discharged from the filtered water storage tank 37, The foreign substances and water impregnated in the filtration module 313 are lifted together with the foreign matter and water passing through the bending portion 511 and the reverse And flows into the washing water storage tank 57, To water and foreign matter in the filter unit 31 is to be continuously backwash water is discharged to flow into the reservoir 57, the back washing is completed by the backwash negative portion 55.

The backwashing start unit 53 is configured to start backwashing in accordance with the level of water flowing backward when the filtration module 313 is blocked and water flows backward. As shown in FIG. 4, A backflow water inflow section 531 connected to the filtration tank 3 and flowing backward from the filtration tank 3; And an opening / closing part 533 for receiving and storing the backwash water from the backwash water inflow part 531 and opening / closing the siphon tube 51 according to the water level of the backwash water. 7, the water flowing into the filtration tank 1 may not pass through the filtration module 313, and the water may flow between the sedimentation tank 1 and the sedimentation tank 31. In this case, The water flowing backward through the siphon tube 51 compresses the air in the siphon tube 51 and the water in the siphon tube 51 is discharged to the outside of the siphon tube 51, When the water level reaches a certain level, the backwashing is automatically started by using the compressed air, thereby preventing the secondary damage by the backwashing and performing the backwashing automatically without any additional control device or operation.

The backwash water inflow section 531 allows backwash water to flow from the settling passage 1 when the water level of the settling tank 1 reaches a certain level and backwashing is performed according to the water level of the settling tank 1 A backflow hole 531a communicating with the settling tank 1, a backflow milking sub-tank 531b in which the amount of reverse flow introduced through the backflow hole 531a is temporarily stored, the backflow milking sub-tank 531b, And a backflow water conveyance pipe 531c connected to the backwash water storage tank 57 and communicated to the opening / closing unit 533. The backwash water having passed through the backflow hole 531a is transferred to the backwash water storage tank 533a of the opening and closing unit 533 through the backwash water transfer pipe 531c, The siphon tube 51 can be opened according to the water level of the water and the backwash water flowing through the backflow hole 531a is temporarily stored in the backwashing milk feeding trough 531b and the backwash water transfer tube 531c The water level of the backwash water storage tank 533a can be gradually increased so that the opening of the valve 533c can be smoothly performed according to the water level of the backwash water storage tank 533a . A detailed description thereof will be described later.

The opening / closing part 533 is configured to open and close the siphon tube 51 according to the water level of the backwash water received from the backwash water transfer tube 531c of the backwash water inflow section 531, A reverse-flow water storage tank 533a for storing the reverse-flow water conveyed from the reverse-flow water pipe 531c; and a reverse-flow water storage tank 533b formed at the water surface of the reverse-flow water stored in the reverse-flow water storage tank 533a, A float 533b and a valve 533c for opening and closing the siphon tube 51 in accordance with the rising and falling of the float 533b. As shown in FIG. 8, the float 533b rises together with the water level of the countercurrent water stored in the countercurrent water storage tank 533a, and the float 533b The valve 533c is opened and the compressed air in the siphon tube 51 is discharged in the direction @ and the inside of the siphon tube 51 is instantaneously evacuated. As a result, The stored filtered water passes through the water collecting tank 35 and flows through the filtration module 313 to float the filter module 313 together with the foreign substances stuck to the filtration module 313 and to collect the foreign substances in the back wash water storage tank 57 And is discharged to the backwashing / discharging path 571 to be described later. A drainage hole 533a-1 is formed in the backwash water storage tank 533a to discharge the backwash water stored in the backwash water storage tank 533a. At the end of backwashing, The water level of the backwash water storage tank 533a is lowered by gradually flowing the water through the drain hole 533a-1 so that the valve 533c is closed. Details of the end of the backwash will be described later.

As shown in FIG. 3, the process of starting and advancing backwashing by the backwashing unit 5 in the abatement facility where the purification process normally proceeds through the settling tank 1 and the filtration tank 3 is shown in FIGS. 10, foreign matter is accumulated in the filtration module 313, and water flowing into the filtration module 313 through the inflow pipe 311b flows smoothly through the filtration module 313, as described above. The water that can not pass through the filtration module 313 flows back to the sedimentation tank 1 and the siphon tube 51 as shown in FIG. 7, and the water level gradually increases. At this time, the water flowing back to the siphon tube (51) compresses the air in the siphon tube (51) to increase the density. A reverse flow hole 531a formed at one side of the sedimentation tank 1 lower than the bending portion 511 of the siphon tube 51 is formed and the water level of the sedimentation tank 1 is connected to the reverse flow hole 531a 8, the backwash water flowing backward through the backflow hole 531a passes through the backwashing milk feeding trough 531b and the backwash water transfer pipe 531c to the backwash water storage tank 533b of the opening / And the float 533b is raised as the water level of the backwash water storage tank 533a becomes higher. As shown in FIG. 10, when the float 533b rises to a certain level, the valve 533c is opened and the compressed air in the siphon tube 51 opens in the direction of the arrow 533c As shown in FIG. 9, the filtered water stored in the filtered water storage tank 37 passes through the transfer tube 351 and the water collecting tank 35, passes through the filtration module 313, So that the foreign substances accumulated in the filtration module 313 are lifted together. The water and the foreign substances passing over the bending portion 511 of the siphon tube 51 pass through the siphon tube 51 when the water and foreign matter flowing backward to the siphon tube 51 cross the bending portion 511, The water level of the backwash water storage tank 57 is always kept at the same level as that of the filtration water storage tank 37 because the water level of the backwash water storage tank 57 is continuously discharged from the filtration tank 3 to the backwash water storage tank 57, Washing water storage tank 57 by the backwash water storage tank 57 and the water and the foreign matter discharged to the backwash water storage tank 57 are discharged to the outside along the backwashing water discharge path 571) And is discharged to the sewage pipe along the backwashing / discharging path 571 and continues until the backwashing is stopped by the backwash stopper 55. [

11, air is introduced into the siphon tube 51 to stop backwashing, and the backwashing stopper 55 stops the backwashing in the siphon tube 51, The backwash water flowing from the side of the filtration tank 3 is supplied to the siphon tube 51 by the air supplied to the siphon tube 51 while the backwash water is flowing through the backwash water storage tank 57, So that the backwashing can be stopped without exceeding the bending portion 511 and the normal filtration process is performed again. The inductively coupled device 55 includes an air inlet pipe 551 having one end connected to the siphon tube 51 and the other end connected to the filtration tank 3, And a backwash time adjusting unit 553 for adjusting the backwashing time by adjusting the time of the inflow of air. When the backwashing is completed by the backwash stopper 55, the water stored in the backwash water storage tank 533a is drained through the drain 533a-1 as shown in FIG. 12, The valve 533c closes the siphon tube 51 again as the level of the backwash water storage tank 533a becomes lower and the float 533b descends. Accordingly, backwashing can be performed when backwashing occurs again, thereby enabling continuous backwashing.

The air inlet pipe 551 is connected to the siphon tube 51 and supplies air so that one end of the air inlet pipe 551 is connected to the bending portion 511 of the siphon tube 51 The backwash water passing through the bending portion 511 is discharged through the backwashing water storage tank 57 and the backwash water which has not passed the bending portion 511 is directed to the filtration tank 3 again The backwash can be terminated at the correct time by the air inlet pipe 551. The other end of the air inlet pipe 551 is formed in the filtering water storage tank 37 so that the backwashing can be terminated by the water level of the filtering water storage tank 37. As described above, when backwashing is performed, the filtered water in the filtered water storage tank 37 flows backward and the filter module 313 is cleaned. As a result, the filtered water level in the filtered water storage tank 37 is lowered. When the other end of the air inlet pipe 551 is released from the filtered water and is exposed to the air, air is introduced through the other end of the air inlet pipe 551, and the introduced air flows into the bending portion of the siphon tube 51 511 to stop backwashing.

The backwashing time adjusting unit 553 is configured to adjust the time point at which air is introduced into the air inflow pipe 551 to control the end point of backwashing. As shown in FIG. 13, A housing 553a which surrounds the other end periphery of the first housing 551 and protrudes downward; And height adjusting means 553b for adjusting the height of the housing 553a.

The housing 553a surrounds the other end of the air inlet pipe 551 and is formed to protrude downward. The housing 553a can be raised and lowered by the height adjusting means 553b, 551 of the first embodiment. In other words, when the housing 553a descends downward as shown in FIG. 14 (b), the water level of the filtered water storage tank 37 The end point of the backwash is delayed. When the housing 553b is lifted upward as shown in FIG. 14 (c) Even if the water level of the storage tank 37 is lowered, the air is introduced into the air inlet pipe 551, so that the end point of backwashing is accelerated. Accordingly, the end point of the backwashing can be adjusted by adjusting the vertical position of the housing 553a.

As shown in FIG. 1, the height adjusting unit 553b may adjust the height of the housing 553a. The height adjusting unit 553b may be connected to the housing 553a to adjust the height of the housing 553a. A steering wheel, and the like, and various other configurations such as a remote control device may be applied.

The backwash water storage tank 57 is constructed such that the backwash water flowing through the siphon tube 51 is temporarily stored, and the backwash water discharge path 571 is connected to one side to discharge the backwash water. As described above, the water level of the backwash water temporarily stored in the backwash water storage tank 57 is maintained below the water surface of the filtration water storage tank 37, so that the water of the filtration tank 3, together with foreign matter, It is possible to flow over the bending portion 511 of the siphon tube 51 to the backwashing water storage tank 57. While the backwashing is proceeding as shown in Figure 10, So that the water surface is not raised.

The backwash water discharging path 571 is connected to the lower side of the backwashing water storage tank 57 to discharge backwash water (water and foreign matter) discharged into the backwashing water storage tank 57 by backwashing, And the backwashing and discharging passage 571 may be connected to a sewer pipe (not shown) so that the backwashing and discharging pipe 571 can flow to a sewage disposal plant or the like.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Should be interpreted as falling within the scope of.

1: settling tank
11: initial storm inflow pipe 111: inlet 113: outlet
13: inclined wall
15: Inflow water tank 151:
3: Filtration tank
31: Filtration section 311: Inflow section 313: Filtration module
33: Membrane
35: Water collecting tank 351: Transfer pipe
37: Filtered water storage tank
39: Filtration water discharge pipe
5:
51: Siphon tube 511:
53: backwash start part 531: backwash water inlet part
531a: Reverse flow 531b: Reverse flow breast feed 531c: Reverse flow
533:
533a: backflow water storage tank 533b: float 533c: valve
55: backwash stop 551: air inlet pipe
553: backwashing time adjusting unit 553a: housing 553b: height adjusting means
57: Backwash water storage tank 571: Backwash water storage tank

Claims (15)

In an initial excellent non-point pollution abatement facility installed to purify contaminants of early storm generated from a nonpoint pollution source,
A sedimentation tank into which initial storms are introduced and contaminants are deposited;
A filtration tank into which the polluted matter is removed by the sedimentation tank, and a pollutant is filtered by the filtration unit;
And a backwashing unit connected to the filtration unit and configured to backwash foreign substances accumulated in the filtration unit together with water flowing backward when foreign substances are accumulated in the filtration unit and water flows backward, To be partially washed,
Wherein the backwashing unit comprises: a siphon tube having a curved portion bent at an apex, the siphon tube being connected to the filtration tank and discharging backwash water and foreign matter; A backwash initiation part for discharging compressed air from the siphon tube to start discharging foreign matter accumulated in the filtration part; And a backwash stopper stopping the backwash by allowing air to flow into the siphon tube,
The backwash stopper includes an air inlet pipe having one end connected to the bending portion of the siphon tube and the other end connected to the filtration tank and a backwashing time adjusting unit for adjusting the time for the air to flow into the air inlet pipe So that the time point at which the backwashing is completed can be adjusted. delete 2. The washing machine as claimed in claim 1,
A backflow water inflow part connected to the settling tank and through which water flowing backward from the filtration tank flows; And an opening / closing part for opening and closing the siphon tube according to the level of the backwash water, and an opening / closing part for receiving and storing the backwash water from the backwash water inflow part. 4. The apparatus according to claim 3, wherein the opening /
A float formed on a water surface of the backwash water stored in the backwash water storage tank and rising and falling together with the rising and falling of the water surface; And a valve that opens and closes the siphon tube according to the operation state of the siphon tube. delete delete delete The apparatus of claim 1, wherein the backwash time adjustment unit
A housing surrounding the other end of the air inlet tube and protruding downward; And a height adjusting means for adjusting a height of the housing. The non-powered automatic backwash type initial excellent non-point pollution abatement facility. The filtration system according to any one of claims 1, 3, 4 and 8,
A filtration unit in which water from which the contaminants are primarily removed from the settling tank flows and is filtered; A water collection tank formed below the filtration unit and collecting the filtered water filtered by the filtration unit; And a filtering water reservoir formed on the filtering unit and connected to the water collecting tank to store the filtered water. 10. The method of claim 9,
The filtration tank has a plurality of filtration sections formed in parallel,
A pyramid-shaped separation membrane for separating the filtration water from the filtration water storage tank is formed on the plurality of filtration units,
Wherein the one end of the siphon tube is connected to the upper vertex of the separation membrane. 10. The apparatus of claim 9, wherein the filtering unit
And a filtration module for filtering contaminants of water formed downward from the inflow section and descending downward from the inflow section,
Wherein the inflow section includes an inflow hole communicating with the settling tank and an inflow pipe communicating with the inflow hole to allow water to flow therethrough,
Wherein the inflow pipe is formed in a cylindrical shape having an open upper side so that water flowing through the inflow pipe can be naturally dropped to the filtration module. The method according to any one of claims 1, 3, 4 and 8,
The settling tank includes a plurality of initial storm inflow pipes into which initial storms are introduced,
Wherein the initial storm inlet tube includes an inlet through which the initial stormwater flows and an outlet formed by being split from the inlet to both sides so that the initial storm jetted from the outlet of each of the plurality of initial stormwater tubes collides to form a lump Wherein the sedimentation efficiency of the sedimentation tank is increased. 13. The method of claim 12,
Wherein a plurality of the outlets are formed so as to increase the velocity of the initial outflow from the outlets to further increase the precipitation efficiency. 14. The method of claim 13,
Wherein said outlet comprises a guide plate projecting on both sides along an outer perimeter so as to more efficiently cause an impact of an initial storm sprayed from an outlet of each said initial storm inlet pipe, Nonpoint pollution abatement facility. The method according to any one of claims 1, 3, 4 and 8, wherein the settling tank
And an inclined wall which is fixed to the upper side of the settling tank and is inclined toward the side where the initial strike is introduced from the upper side to the lower side, thereby increasing the sedimentation efficiency of the sedimentation tank. .

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