KR101095323B1 - System for treating total phosphorus from effluent water of sewage treatmentplant during the dry season and treating storm water runoff selectively during rainy day - Google Patents

Abstract

The present invention relates to a total phosphorus treatment of effluent from dry season sewage treatment plant and a selective treatment system of rainfall effluent during rainfall. In the present invention, the total phosphorus treatment of effluent from the dry season sewage treatment plant and the selective treatment system of rainfall effluent during rainfall are provided with an in-line mixer for ultra-high speed mixing of the treated water and the flocculant with high mixing efficiency to maximize the mixing efficiency of the treated water and the flocculant. The final flocculation treatment efficiency is greatly improved, and the compactness of the facility can be minimized, and high efficiency flocculation treatment is possible, and the rotational flow is not generated in the slow stirring tank, so that the flocculation treatment efficiency can be maximized, and the surface area of the final precipitation tank is increased. By installing the inclined plate to improve the sedimentation efficiency can be further maximized the flocculation efficiency. The sewage and rainwater selective treatment device of the present invention can reliably prevent the water pollution of the discharged water system by treating the treated water treated in the sewage treatment facility again by an ultra-high-speed, high-efficiency flocculation treatment device, and joining in the case of pyeong-su and rainfall. Depending on the flow rate of sewage and / or rainwater flowing through conduits, treatment by sewage treatment facilities, flocculation by ultra-high-efficiency high-efficiency flocculation equipment, and filtration by filtration-type pollutant treatment facilities can be carried out selectively or in combination. It is possible to cope with the best possible situation and to remove TP from the treated water from which the TP was first removed from the sewage treatment facility, so that the TP can be removed reliably to prevent water pollution in the discharge water system. If the flow rate of sewage and rainwater increases rapidly, It will be able to maximize the treatment efficiency of sewage and rainwater by dispersing and collecting them into ultra-high-efficiency high-efficiency flocculation equipment and filtering pollutant treatment facilities.

Description

System for treating total phosphorus from effluent water of sewage treatmentplant during the dry season and treating storm water runoff selectively during rainy day}

The present invention relates to a selective treatment system for total phosphorus treatment of effluent from dry season sewage treatment plant and rainfall effluent during rainfall, and more particularly, to an in-line mixer that maximizes the efficiency of flocculation treatment by minimizing head loss. Ultra-high-efficiency high-efficiency flocculation unit and separation device to separate the weighted coagulant from the primary sedimentation basin to minimize the number of flocculation treatments and maximize the efficiency of flocculation, and the total treatment of effluent from the dry season sewage treatment plant and the selective treatment system of rainfall effluent during rainfall It is about.

The water management policy from 1993 to 2005 amounted to 26 trillion won, representing 91% of the budget spent during the same period. As a result, the pollutant loads of organic materials in the four major rivers and rivers decreased, but total phosphorus (TP) increased due to lack of countermeasures related to nutrients. Eutrophication of streams causes rapid fluctuations in dissolved oxygen. During the day, the concentration of dissolved oxygen increases greatly due to photosynthesis of the attached algae, whereas at night, the dissolved oxygen varies greatly because the attached algae use oxygen in the water. This phenomenon adversely affects living things such as fish. The prosperity of algae makes it difficult to treat purified water and causes taste and smell in drinking water. In 2007, the total phosphorus concentration of Soyang Dam, the most upstream of the Han River, was 0.032mg / l and Paldang Dam was 0.056mg / l. As the cause of eutrophication of rivers in Korea, we can point out the high standard of discharged sewage treatment plant compared to foreign countries.

Although eutrophication usually occurs in water purification areas, such as lakes, eutrophication is severe in rivers, but due to the decrease in the dry season flow rate and the increased residence time, the cause of effluent with high phosphorus concentration can not be ignored. Korea's effluent phosphorus concentration standard is 2 mg / L, which is quite different from that of major countries such as the US, Germany, and Japan. The total phosphorus concentration of 2 mg / L of Korean effluent is 100 times that of eutrophication standard, and should be strengthened to 0.1 mg / L or less in the water where eutrophication occurs.

As of the end of 2007, there are a total of 357 public sewage treatment facilities in operation nationwide. Among them, 245 advanced nitrogen removal advanced treatment methods (A2O, SBR, etc.) accounted for 69% of the total, and the traditional methods for removing BOD (standard activated sludge, long-term aeration, etc.) are 112 locations (31%). The trend is shifting (Oh Jae-il, drought response sewerage system, April 2009). Table 10 shows the average inflow and discharged water quality of sewage treatment plants in Korea in 2006 and 2007. The removal rate of each item is gradually increasing, but it is different from the removal rate of BOD, COD, and SS (94.3%, 85.3%, 96.0% in 2007) and TN, TP removal rate (67.6%, 75.3% in 2007). . The average discharge water quality of T-P is 1.2 mg / L in 2007, which is within the discharge water quality standard (2 mg / L) but more than 50 times the eutrophication standard. Considering that 69% of the nation's public sewage treatment plants have advanced treatment methods, it is inferred that the current advanced treatment facilities have no significant effect on the removal of total phosphorus (TP) to prevent eutrophication.

In addition, pollutants included in influent water flowing into rivers or lakes are from point sources and non-point sources, of which 60 to 70% of the contaminants come from non-point sources. Occupies. Non-point pollutants are discharged by rainfall and flow into rivers or lakes, which are more difficult to treat than point pollutants.

Most of the country employs confluent sewer pipes, and the outflow of pollutants occurs during the initial rainfall. This is called CSO (Combined Sewer Overflow), and due to the initial rainfall, the pollutants on the surface and the contaminants settled in the consolidation sewers flow out at the same time, resulting in a very high concentration and load of the pollutants.

In case of rainfall, the amount of sewage flowing into the sewage treatment plant is increased. At this time, the sewage treatment facility introduces a flow rate equal to three times the design flow rate (3Q) to make the first precipitation at the primary sedimentation basin and then discharges 2Q as it is. Only 1Q is processed in biological treatment facilities.

In this case, as the flow rate to the primary settler increases, the efficiency of the first settler decreases, and the high concentration of return water returned from the sewage treatment plant sludge treatment system flows into the inlet sewage, so that the primary treated water has a higher concentration than the influent. In many cases, the amount of pollutants introduced into the water system such as rivers or lakes is not reduced, but rather increases.

Therefore, a sewage treatment type flocculation apparatus has been developed in the past, and examples thereof include the URC (Ultra Rapid Coagulation) method, the Actiflo (TM) method, the upflow type method using the flotation media, the non-powered flocculation precipitation method, and the integrated high efficiency flocculation method. There is a precipitation method.

The conventional URC sewage treatment type flocculation apparatus includes a rapid reaction tank, a flocculation tank, a slow flocculation tank, and a high-speed gradient plate settling tank, as shown in FIG. URC sewage treatment type flocculation apparatus is characterized by administering the flocculent aid with the flocculant and using the inclined plate settling tank.

URC sewage treatment type coagulation treatment device has an advantage that can reduce the reaction and precipitation time more than 10 times compared to the existing coagulation precipitation system.

However, the rapid reaction tank is a rapid agitation by mixing the treated water and the flocculant with a stirrer to rotate at high speed, the mixing of the treated water and the flocculant in the rapid reaction tank should be made within 1 minute, but in the case of large facilities, rapid mixing There is a problem that is not made sufficiently, and also in the rapid reaction tank, flocculation tank and slow flocculation tank by mixing the treated water and the flocculant by using a stirrer, the dead space is formed in the corner of each tank There is a problem that the rotational flow is generated, whereby the stirring and miscibility decreases.

In order to solve this problem, a method of increasing the amount of flocculant (drug) can be considered, but in this case, the amount of sludge generated increases, thereby reducing the economic feasibility of the process, and a solution for disposing of the drug and sludge reveals additional problems. .

In addition, depending on the intermittent operation, there is an economic and maintenance problem, excellent in flocculation of suspension, but dissolved organic materials and in particular, T-N has a problem that the removal effect is inferior.

As shown in FIG. 30, a conventional Actiflo (TM) type sewage treatment type coagulation treatment apparatus includes a rapid stirring tank, a slow stirring tank, a floculation reactor (slow stirring tank), and a precipitation tank. Actiflo type sewage treatment type coagulation treatment device has the same principle as URC method, but it is characterized in that sand (micro-sand) is added as a coagulant as a coagulant aid and recycled sand using cyclone.

Actiflo type sewage treatment system is used for treating CSOs in rainy weather in many parts of Europe because it has the advantage of economical and quick operation due to low facility area requirements.

However, Actiflo-type sewage treatment type coagulation treatment device has a problem of requiring a solution for disposal of chemicals, as in the URC method, and has a problem of complicated and expensive facilities due to the installation of a cyclone. .

The conventional sewage treatment type flocculation apparatus using a conventional flotation filter has an upper screen and a flotation filter in a reaction tank, and has a flocculation tank and a collection pump for collecting the agglomerates on one side of the reaction tank. Characterized in that provided.

The upflow sewage treatment type flocculation apparatus using flotation media can flexibly cope with rapid flow fluctuations in sewage during rainy weather, and has the advantage that the flocculation treatment can be performed without a separate flocculant by using a suitable media for rainwater treatment.

However, the upflow sewage treatment type flocculation apparatus using the flotation media has a problem in that the size of the facility is increased, such that the reactor must be installed in multiple stages.

As shown in FIG. 32, the conventional non-cohesive sedimentation type sewage treatment type coagulation treatment device is characterized in that the entirety is hydraulically arranged by connecting a quantitative drug supply unit, a mixed flocculation unit, a precipitation unit, and a filtration unit in series.

The non-cohesive sedimentation type sewage treatment type coagulation treatment device has the advantage that the treatment efficiency can be maintained more than 90% even if the flow rate is changed.

However, the non-cohesive sedimentation type sewage treatment type coagulation treatment apparatus has a problem in that the size of the facility is increased, such that the reactor must be installed in multiple stages.

Conventional integrated high efficiency coagulation sedimentation method sewage treatment type coagulation treatment apparatus as shown in Fig. 33, characterized in that the coagulation tank and the sedimentation basin is integrated, adopts the precipitation method using the inclined plate and is a non-powered coagulation treatment facility without a mechanical stirring device do.

Integrated high efficiency coagulation sedimentation method Sewage treatment type coagulation treatment device has the advantage of high sedimentation efficiency and greatly reduces the required site area.

However, the integrated high efficiency coagulation sedimentation type sewage treatment type coagulation treatment device has a problem that the water quality may be temporarily deteriorated when the residence time is short, impact, but sludge injuries due to long-term operation.

Recently, in order to solve the problems in the URC method and the Actiflo method, efforts to replace the rapid reactor with an inline mixer have been continued to increase the mixing effect and reduce the number of reactors.

Conventional in-line mixers are provided with a plurality of diaphragms or screws inside the cylindrical casing to form a treated water passage extending longer than the length of the cylindrical casing, so that two or more kinds of treated water are mixed while passing through the extended treated water passage. It is widely used.

However, the conventional in-line mixer simply forms a flow path in a zigzag or spiral form, or forms a distribution hole having a phase difference in a plurality of diaphragms, thereby extending the flow distance of the water to be treated. Has a problem that is not so high.

Therefore, even if the in-line mixer is replaced by a rapid reactor, a problem of reducing the coagulation treatment efficiency of the ultrafast coagulation treatment facility occurs due to large head loss and low mixing efficiency, and does not solve the above problems in the URC method or the Actiflo method. It is true.

Accordingly, an object of the present invention is to provide a treatment system for total discharge of effluent from a dry season sewage treatment plant and a selective treatment system of rainfall effluent during rainfall.

Accordingly, an object of the present invention is to use the in-line mixer to quickly mix the treated water and the flocculant with high mixing efficiency to increase the flocculation treatment efficiency. To provide a system.

Another object of the present invention is to install a baffle on the inner wall of the slow stirring tank to maximize the flocculation efficiency, so as to maximize the flocculation efficiency of dry season sewage treatment plant to provide the total phosphorus treatment and rainwater outflow water selective treatment system I will.

Still another object of the present invention is to maximize the mixing efficiency of the treated water and the flocculant such as the treated water and the flocculant, and to use the in-line mixer that can be mixed at a very high speed so that rapid stirring or rapid coagulation bath can be omitted. It is to provide a selective treatment system of total discharge of effluent from dry season sewage treatment plant and rainfall runoff during rainfall, which enables miniaturization and high efficiency of flocculation treatment.

Another object of the present invention is to install the inclined plate to increase the surface area in the final sedimentation tank to improve the sedimentation efficiency to further maximize the flocculation treatment efficiency. We want to provide an optional processing system.

Another object of the present invention is to separate the fine particulate matter from the sediment precipitated in the primary sedimentation basin of the pretreatment tank and put it into a slow stirring tank to utilize as a weighted coagulant to reduce the cost of using the weighted coagulant, dry sewage treatment plant It is intended to provide a system for the treatment of total discharge of effluent and selective treatment of rainfall effluent during rainfall.

It is another object of the present invention to filter the flocculation treatment and the filtration pollutant treatment facility by the sewage treatment facility and the ultra-high-speed high-efficiency coagulation treatment device according to the flow rate of the sewage and / or rainwater flowing through the conduit of the PyeongSu and the rainfall. The treatment is optional or combined, so that it can cope optimally with the situation that may occur, and as a result, it is possible to improve the water quality of the discharged water system. To provide a processing system.

Another object of the present invention is to remove the TP from the treated water from which the TP was first removed in the sewage treatment facility to remove the TP more reliably, thereby improving the water quality of the discharged water system. It is intended to provide an optional treatment system for the total phosphorus treatment and rainfall runoff during rainfall.

Another object of the present invention is to treat the sewage and rainwater by discharging the inflow flow rate into sewage treatment facilities, ultra-high-efficiency high-efficiency flocculation equipment, and filtration-type pollutant treatment facilities, respectively, if the flow rate of sewage and rainwater increases rapidly. In order to maximize the efficiency, it is to provide a treatment system for total discharge of effluent from the dry season sewage treatment plant and selective treatment system of rainfall effluent during rainfall.

In order to achieve the above object, the present invention provides a high-speed stirring means for quickly admixing the flocculant to the treated water discharged from the biological sewage treatment device, and a slow stirring of the treated water mixed with the flocculant in the high speed stirring means. A coagulation treatment device having a slow stirring means for forming a giant floc, and a settling tank for precipitation treatment of the water to be treated by the slow stirring means; A primary sedimentation basin for precipitating the water to be treated and introducing the supernatant into the biological sewage treatment apparatus; Sludge-weighted coagulant separating means for supplying the weighted coagulant separated by separating the sediment settled in the primary sedimentation with sludge and weighted coagulant to the slow stirring means; and discharged from the biological sewage treatment device during the dry season Provides a treatment system for treating the water to be treated and when the rainfall, the total sewage treatment of the sewage treatment plant effluent that does not flow into the sewage treatment plant in the primary sedimentation basin, and the overflow water flowing overflow, and a selective treatment system of rainfall effluent during rainfall.

It is preferable that an inline mixer is used for the said high speed stirring means.

The in-line mixer may include a cylindrical casing having an inflow pipe and an outflow pipe; A stem inserted concentrically into the cylindrical casing to form a water flow space to be treated between the outer circumferential surface and the inner circumferential surface of the cylindrical casing; And a plurality of streams of water flow control and a mixture of projection projections concentrically installed in the treatment water flow space to form the treatment water flow space.

The stream control and mixing projection rows include a plurality of projections in each row, and the projections constituting the flow control and mixing projection sequences adjacent in the circumferential direction are alternately disposed along the length direction on the cylindrical kay to be treated. It is preferable to configure the object water flow space to be formed in the form of repeating the branching zone and the confluence zone.

The cross-sectional shape and the cross-sectional area of the outer circumferential side end portion and the inner circumferential side end portion of the protrusions constituting the water flow control and the mixing protrusion sequence can be configured in the same manner.

The cross-sectional area of the outer circumferential side end portion of the protrusion constituting the water flow control and the mixing protrusion sequence can be configured to be larger than the cross-sectional area of the inner circumferential side end portion.

The protrusions constituting the water flow control and the mixing protrusion streams are formed in a rhombic cross-sectional shape, and the edges facing each other may be disposed upstream and downstream.

The slow stirring means may comprise a slow stirring tank, an agitator installed inside the slow stirring tank, and at least one baffle installed on four inner walls of the slow stirring tank.

The baffle may be composed of an upper baffle leading to a stop at the upper end of the upstream and downstream walls of the slow stirring tank, and a lower baffle reaching a stop at the bottom of the left and right walls of the slow stirring bath.

The settling tank may include a plurality of inclined plates, and the inclined plate preferably forms a pipe or round bar-shaped member in the settling tank in a lattice shape.

The sludge-weighted coagulant separating means is connected to the sediment conveying tube of the primary sedimentation basin hydrocyclone to separate the returned sediment into sludge and weighted coagulant, and is connected to the lower end of the hydrocyclone and separated from the hydrocyclone It is preferable to include a weighted coagulant inlet tube for introducing the weighted coagulant to the slow stirring means, and a sludge conveying pipe connected to the upper end of the hydrocyclone.

The hydrocyclone of the sludge-weighted coagulant separating means may be connected to the precipitate return pipe connected to the bottom of the settling tank.

It is preferable to further include a weighted coagulant input means for injecting the weighted coagulant to the slow stirring means.

The weighted coagulant injecting means may include a weighted coagulant supply source and a weighted coagulant inlet tube for injecting the weighted coagulant stored in the weighted coagulant supply source into the slow stirring means.

The weighted coagulant inlet tube of the sludge-weighted coagulant separating means and the weighted coagulant inlet tube of the weighted coagulant injecting means may be configured to individually add the weighted coagulant to the slow stirring means.

The weighted coagulant inlet tube of the sludge-weighted coagulant separating means and the weighted coagulant inlet tube of the weighted coagulant injecting means may be connected to each other and may be configured to add the weighted coagulant to the slow stirring means.

The treatment system for the total phosphorus treatment of effluent from the dry season sewage treatment plant and the rainfall effluent during the rainy season according to the present invention comprises an inline mixer for quickly mixing the treated water and the flocculant at high speed, and the treated water and the flocculant mixed by the inline mixer. A slow stirring tank which forms a large floc by stirring and a final settling tank which sediments the treated object in which the large floc is formed by slow stirring in the slow stirring tank, and the in-line mixer flows along the flow space of the treated water The flocculant and the flocculant are branched by the protrusions constituting the flow control and the mixing projection stream, and the mixing is actively performed while repeating the process, and the flow of water to be treated flows through the outer and inner circumferences of the flow control and the mixing projection stream. As the flow rate is different, the stream of treated water forms a turbulent flow, and the mixture of treated water and flocculant Is made more active, and the width of the inclined surface formed on both sides of the upstream edge has a wider outer circumferential side and a narrower inner circumferential side, which are treated by the upstream edges of the projections constituting the water flow control and the mixing projection stream. Since the flow resistance acting on the treated water flowing in contact with the outer circumferential surface and the flowing water in contact with the inner circumferential surface is different, the mixing efficiency of the treated water and the flocculant is further maximized. Therefore, the final flocculation treatment efficiency is greatly improved.

In addition, the selective treatment system of total discharge of effluent from dry season sewage treatment plant and rainfall effluent during rainfall can maximize the mixing efficiency of treated water and flocculant, and also by using an inline mixer that can be mixed at a very high speed. Stirring tanks or rapid agglomeration tanks can be omitted, enabling a compact and highly efficient flocculation treatment.

In addition, in the dry treatment sewage treatment plant during the dry process and the selective treatment system of rainfall runoff during rainfall, the baffle is installed in a slow stirring tank so that a rotational flow does not occur in the process of stirring the water and the flocculant in the slow stirring tank. There is an effect that can maximize the flocculation treatment efficiency.

In addition, the ultra-high-speed, high-efficiency flocculation apparatus according to the present invention improves the precipitation efficiency by installing an inclined plate that can increase the surface area in the final settling tank to further maximize the flocculation efficiency.

Selective treatment system for total phosphorus treatment of effluent from dry season sewage treatment plant according to the present invention and rainfall effluent during rainfall is used as weighted coagulant by separating fine particulate matter from sediment precipitated in primary sedimentation basin of pretreatment tank and using it as weighted coagulant in slow stirring. The cost can be reduced.

In addition, the selective treatment system of total discharge of effluent from the dry season sewage treatment plant and rainfall effluent during the rainy season is to treat the treated water treated in the sewage treatment facility again by an ultra-high-speed, high-efficiency coagulation treatment system. Pollution can be prevented.

In addition, the selective treatment system of the total phosphorus treatment of effluent from the dry season sewage treatment plant according to the present invention and the rainfall runoff during rainfall is treated by the sewage treatment facility according to the flow rate of sewage and / or rainwater flowing through the conduit pipe during pyeongsu and rainfall. Coagulation treatment by ultra-high-efficiency coagulation treatment device and filtration treatment by filtration-type pollutant treatment facility can be performed selectively or in combination, so that it is possible to cope optimally with the situation that may occur, and consequently It can be prevented.

In addition, the selective treatment system of total discharge of effluent from the dry season sewage treatment plant and rainfall effluent during the rainy season according to the present invention is to remove TP from the treated water from which the TP is first removed from the sewage treatment plant, so that the TP can be reliably removed. It is possible to reliably prevent water contamination of the discharge water system.

In addition, the present invention can maximize the treatment efficiency of sewage and rainwater by discharging the inflow capacity exceeding the sewage treatment facility capacity quickly and discharged by the ultra-high-speed high-efficiency coagulation treatment device when the flow rate of sewage and rainwater rapidly increases during rainfall. Will be.

1 to 16 shows a preferred example of the ultra-high speed and high efficiency coagulation treatment apparatus applied to the present invention,
1 is an overall schematic diagram,
2 to 6 show a first example of an inline mixer,
2 is a perspective view,
3 is an exploded perspective view,
4 is a longitudinal side view,
5 is a cross-sectional view taken along the line AA of FIG.
6 is an exploded view for explaining the principle of water flow control and mixing;
7 to 11 show a second example of an inline mixer,
7 is a perspective view,
8 is an exploded perspective view,
9 is a longitudinal side view,
10 is a cross-sectional view taken along line BB of FIG.
11 is an exploded view for explaining the principle of water flow control and mixing;
12 and 13 are partial perspective views showing another example of the inline mixer,
14 is a perspective view of a slow stirring;
15 is a partial cutaway perspective view of a slow stirring;
16 is a partial cutaway perspective view of a slow stirring;
17 to 19 is an analysis diagram showing a stirring process of the conventional slow stirring bath,
20 to 22 is an analysis diagram showing a stirring process of the slow stirring tank according to the present invention,
23 and 24 are perspective views of the inclined plate installed in the final settling tank of the present invention,
25 is a schematic diagram showing another preferred example of the ultrafast high efficiency agglomeration processing apparatus applied to the present invention;
26 and 27 shows a preferred embodiment of the total phosphorus treatment of the dry sewage treatment plant effluent and the selective treatment system of rainfall effluent during the rain according to the present invention,
Fig. 26 is a flow diagram showing a process of treating sewage in normal water;
27 is a system diagram showing a process of treating sewage and rainwater during rainfall;
28 and 29 are schematic diagrams showing a second preferred embodiment of the total phosphorus treatment of the dry sewage treatment plant effluent and the selective treatment system of rainfall effluent during rainfall according to the present invention;
28 is a flow chart showing a process of treating sewage in plain water;
29 is a flow chart showing a selective treatment process of sewage and rainwater during rainfall;
30 to 34 is a view showing a conventional flocculation apparatus.

Hereinafter, with reference to the accompanying drawings, a preferred example of the ultra-high efficiency and high efficiency coagulation treatment apparatus applied to the present invention will be described in detail.

One preferred ultra-high-speed, high-efficiency coagulation treatment apparatus applied to the present invention, as shown in Figure 1, a high speed stirring means for mixing the treated water and the flocculant; Slow stirring means for stirring the treated water and the flocculant mixed by the high speed stirring means; And a final settling tank 3 for sedimenting the water to be treated stirred by the slow stirring means.

As the high speed stirring means, an in-line mixer 1 is used, and the slow stirring means is a slow stirring tank 2.

An in-line mixer (1) for mixing the water to be treated and the flocculant, a slow stirring tank (2) for stirring the treated water and the flocculant mixed in the in-line mixer (1), and agitation in the slow stirring (2) It includes a final settling tank (3) for sedimentation treatment water.

The inline mixer 1 may use a conventional inline mixer such as a system having a partition wall and a water hole, a screw system, but it is preferable to use an inline mixer as described below.

The inline mixer 1 is connected to the slow stirring tank 2 whose inlet end is connected to the treatment object inlet pipe 1a and the outlet end thereof through the outlet pipe 1b. A coagulant inlet pipe 1c is connected in the middle of the water inlet pipe 1a to allow the coagulant to flow into the inline mixer 1 together with the water to be treated.

As a preferable example of the inline mixer 1, as shown in Figs. 2 to 6, the cylindrical casing 10 and the cylindrical casing 10 are concentrically inserted into the outer peripheral surface and the cylindrical casing ( A stem 20 forming an object water flow space 21 between the inner circumferential surfaces of 10); And a plurality of rows of water flow control and mixing projection rows 30 installed concentrically in the treatment water flow space 21 to form the treatment water flow space 21.

The cylindrical casing 10 is open at both ends thereof, and both ends of the cylindrical casing 10 and 14 are coupled thereto. The water passage caps 11 and 14 are configured such that a plurality of inlets 13 and outlets 16 are formed by the spoke ribs 12 and 15 as shown in the example. It can be, but can also be configured to allow the inflow and outflow of water to be treated using the net.

The stem 20 has an outer diameter smaller than the inner diameter of the cylindrical casing 10 because the stem 20 forms a water flow space 21 to be treated with the cylindrical casing 10.

As shown in FIGS. 2 to 5, the water flow control and the mixing protrusion string 30 includes a plurality of protrusions 31 for each column, and the water flow control and the mixing protrusion strings 30 adjacent to each other in the circumferential direction. The protrusions 31 constituting the alternating protrusions 31 are alternately disposed along the longitudinal direction of the cylindrical casing 10 so that the treatment water flow space 21 is formed to repeat the branching zone and the joining zone.

In the present embodiment, the water flow control and the mixing projection lines 30 have the same cross-sectional shape and cross-sectional area of the outer circumferential side end portion 32 and the inner circumferential side end portion 33.

In addition, the projections 31 constituting the water flow control and the mixing projection lines 30 are formed in a rhombic cross-sectional shape, and it is preferable to arrange the edges 34 and 35 facing each other upstream and downstream.

This is because the projections 31 of the water flow control and the mixing projection streams 30 are formed in a square shape, and when the two surfaces facing each other face upstream and downstream, the surface located upstream is a resistance factor to the flow of water to be treated. In order to solve the problem that the surface located on the downstream side acts as a factor for generating negative pressure, which causes both head loss.

The water flow control and mixing projection strings 30 are in close contact with the inner circumferential surface of the cylindrical casing 10 at the outer circumferential side end 32 of each projection 31 constituting them.

The stem 20 having an outer diameter smaller than the inner diameter of the cylindrical casing 10 to fix the inner circumferential end of each of the protrusions 31 constituting the water flow control and the mixing projection string 30 is inside the cylindrical casing 10. The inner peripheral side end 33 of each of the protrusions 31 is in close contact with the outer peripheral surface of the stem 20.

The flow control and the mixing projection stream 30 may be configured such that the inner circumferential side end 33 is integrally formed on the outer circumferential surface of the stem 20.

In the illustrated example, the water flow control and mixing projection lines 30 are configured in six rows, but are not necessarily limited thereto, and may be configured in three, five, or seven rows.

The inlet cap 11 and the outlet cap 13 may also be configured to also serve to secure both ends of the stem 20.

The in-line mixer may be treated with two substances introduced from one end of the cylindrical casing 10, for example, treated water such as rainwater or wastewater, and a flocculant, such as a treated water flow space formed between the cylindrical casing 10 and the stem 20. 21 is discharged from the other end of the cylindrical casing 10.

Two or more treated objects such as the treated water and the flocculant flowing along the treated water flow space 21 are branched by the projections 31 constituting the water flow control and the mixing projection stream 30 and then again. You join, and you repeat this process.

In particular, the projections 31 constituting the water flow control and the mixing projection stream 30 are arranged so that the edges 34 and 35 facing each other are directed upstream and downstream, and thus flow along the water flow space 21 to be treated. The object to be treated is branched by the upstream edge 34 of the projection 31, and the branched object to be processed is guided by the inclined surfaces formed on both sides of the upstream edge 34, so that the branch of the object can be smoothly branched. Will be done.

The number of objects to be passed through the inclined surfaces formed on both sides of the upstream edge 34 flows along the inclined surfaces formed on both sides of the downstream edge 35, which continues, and the factor causing negative pressure in this portion is excluded. Therefore, no negative pressure occurs, so there is no head loss.

In addition, the number of treatment subjects branched by the projections 31 located on the upstream side is joined by an upstream side of the projections 31 located on the downstream side and then branched by the projections 31 located on the downstream side. This process is repeated to maximize the mixing efficiency of the water to be treated and the flocculant, such as the water to be treated and the flocculant.

As another preferable example of the in-line mixer 1, as shown in FIGS. 7 to 11, the cross-sectional area of the outer circumferential side end 32 of the projection 31 constituting the water flow control and the mixing projection string 30 is circumscribed. It is formed to be larger than the cross-sectional area of the side end 33 to enhance the adhesion of the outer peripheral end 32 to the inner peripheral surface of the cylindrical casing 10, the other configuration is the same as the in-line mixer shown in Figs. Therefore, the same reference numerals are assigned to the same parts, and detailed description thereof will be omitted.

In addition, the in-line mixer according to the present embodiment forms a cross-sectional area of the outer peripheral end 32 of the projection 31 constituting the water flow control and the mixing projection stream 30 to be larger than the cross-sectional area of the inner peripheral end 33 and the upstream side thereof. Since the width of the inclined surface formed by the edge 34 on both sides of the upstream edge 34 is configured so that the outer peripheral side is wide and the inner peripheral side is narrow, the treatment object water flowing while contacting the outer peripheral side oblique surface is in the inner peripheral side. As the flow resistance acting on the treated water flowing in contact with the inclined surface is different, the mixing efficiency of the treated water and the flocculant is further maximized.

That is, in the in-line mixer according to the present embodiment, the mixing efficiency is further maximized by three factors, such as branching and merging of the water to be treated, generation of turbulence, and difference in flow resistance.

2 to 11, the cross-sections of the outer circumferential side end portion 32 and the inner circumferential side end portion 33 of the protrusions 31 constituting the water flow control and the mixing projection line 30 are formed in a rhombus. 12 and 13 may be formed in a circular cross section, or may be formed in an elliptical cross section (not shown).

The slow stirring tank 2 is provided with a conventional stirrer 2a.

The slow stirring tank (2) has an induction wall (2b) for guiding the material to be treated which is a mixture of the treated water and the flocculant mixed in the inline mixer (1) toward the bottom of the slow stirring tank (2) upstream. It is provided, and the material to be processed that flowed through the overflow wall (2c) and the overflow wall (2c) for the supply of the stirred material in the slow stirring tank (2) to the final settling tank (3) of the final settling tank (3) The guide wall 2d for downstream side supply is provided.

On the inner surface of the wall of the slow stirring tank (2), a baffle (B) is provided to increase the stirring efficiency by preventing rotational flow of the water to be treated.

The baffle (B) can be obtained even if only installed on the inner surface of any one of the four walls of the slow stirring tank (2).

In the illustrated example, the baffle B includes a guide baffle B1 located above and downstream of the slow stirring tank 2 and an upper baffle B1 extending from the upper end of the overflow wall 2c to the middle of the slow stirring tank. It is preferable to comprise with the lower baffle B2 which leads to an interruption from the lower end of the left and right wall 2e of (2). In addition, the lower baffle B2 may be provided on the guide wall 2b and the overflow wall 2c, and the upper baffle B1 may be provided on the left and right side walls 2e.

The final settling tank 3 may employ any one of the settling tanks in the prior art described above, but it is preferable to employ a settling tank having the inclined plate 3a as shown in the illustrated example.

An upper end of the final settling tank (3) is provided with a discharge pipe (3c) for discharging the treated water.

The lower end of the final settling tank (3) is connected to the precipitate transport pipe (3d), the transport pump (3e) is provided in the middle of the precipitate transport material (3d). The sludge discharged by the settling material conveying pipe 3d and the conveying pump 3e may be sent to a conventional sludge treatment facility or a sewage treatment facility.

In addition, in the present invention, in order to increase the settling efficiency in the final settling tank (3) it is further provided with a weighted coagulant injecting means (4) for injecting a weighted coagulant such as micro-sand into the slow stirring tank (2) desirable.

The weighted coagulant injecting means 4 includes a weighted coagulant source 4a and a weighted coagulant inlet tube 4b for injecting the weighted coagulant stored in the weighted coagulant source 4a into the slow stirring tank 2. .

The weighted coagulant source 4a may be configured in the form of a box or hopper for storing the weighted coagulant.

The weighted coagulant introduced into the slow stirring tank (2) in the weighted coagulant input means (4) is precipitated together with the sludge in the final settling tank (3), the precipitated weighted coagulant is separated from the sludge and recovered to reuse the sludge- Weighted coagulant separating means 5 is further provided.

The sludge-weighted coagulant separating means (5) is connected to the end of the sediment conveying pipe (3d), the hydrocyclone (5a) for separating the sludge and the weighted coagulant, and is connected to the lower end of the hydrocyclone (5a) Sludge sludge treatment facility (not shown) connected to and installed at the top of the weighted coagulant re-entry tube (5b) and the hydrocyclone (5a) to re-introduce the separated weighted coagulant to the slow stirring tank (2) Sludge feed pipe (5c) for conveying to the.

The weighted coagulant re-entry pipe (5b) may be independently installed on the slow stirring tank (2), as shown in Figure 1, to the weighted coagulant inlet pipe (4b) of the weighted coagulant injecting means (4) Can be connected and installed.

The sludge conveying pipe (5c) is to transport the sludge to a conventional sewage treatment facility or sludge treatment facility, sludge transferred to the sewage treatment facility is recycled in the sewage treatment process, the sludge transferred to the sludge treatment facility is finally It is treated and disposed of.

Hereinafter, the coagulation process by the ultra-high efficiency coagulation apparatus applied to the present embodiment will be described.

The raw water, which is the treated water introduced through the treated water inlet pipe 1a, and the coagulant introduced through the coagulant inlet pipe 1c are mixed by the in-line mixer 1.

In this case, the treated water and the flocculant introduced into the in-line mixer 1 flow along the flow space 21 formed between the cylindrical casing 10 and the stem 20, and as described above, the flow space ( 21 is sufficiently mixed at high speed by the flow control and mixing projection lines 30 provided in the plurality of rows due to repetition of branching and confluence, generation of turbulence and difference in flow resistance.

The in-line mixer 1 is sufficiently mixed with the treated water and the flocculant within 1 minute, thereby minimizing the amount of flocculant (drug) and the amount of sludge generated can increase the economics of the process, and for the disposal of drugs and sludge The burden can be minimized.

Here, the principle of maximizing the mixing efficiency of the water to be treated and the flocculant is the same as described above, and a detailed description thereof will be omitted.

As the coagulant introduced through the coagulant inlet tube 1c, a polymer coagulant and / or an inorganic coagulant may be used.

When FeCl ₃ is used as the flocculant, phosphorus (PO43-) in the water to be treated becomes insoluble phosphate (FePO ₄ ), thereby obtaining a phosphorus (P) removal effect.

The treated water and the coagulant mixed in the in-line mixer 1 flow into the slow stirring tank 2 and are agitated slowly by the agitator 2a, whereby coagulation is performed by the action of the coagulant.

In the flocculation tank 2, a large floc is formed by aggregation. In this case, in the in-line mixer 1, since the mixing efficiency of the water to be treated and the flocculant is maximized, the flocculation efficiency in the flocculation tank 2 is maximized.

In addition, since the baffle (B; B1, B2) is provided on the upstream side guide wall (2b), the overflow wall (2c), and the left and right side walls (2d) of the slow stirring tank (2), rotational flow does not occur, and sufficient As a result of the mixing, a large floc can be formed.

In addition, the baffle (B) is composed of the upper baffle (B1) and the lower baffle (B2), so that the mixing of the water to be treated in the slow stirring tank (2) and the flocculant is made uniform throughout.

17 and 18 show the results of water flow experiments in the slow stirring tank without baffle and the slow stirring tank with baffle, respectively.

In a slow stirring tank without baffles, dead space (dead space) is present in the corners (see FIG. 17), so that a rotational flow occurs due to the rotation of the stirrer 2a (see FIG. 18), and the solid floating material It is deposited on the bottom of the slow stirring tank (2) (see FIG. 19), which not only lowers the mixing efficiency but also causes the large flocs to not be sufficiently generated, thereby further reducing the settling efficiency in the final settling tank 3 later. It was confirmed.

On the other hand, in the slow stirring tank with a baffle as in the present invention, there is no dead space at the corners (see FIG. 20), and no rotation flow occurs due to rotation in the agitator 2a (FIG. 21). The material is not deposited on the bottom of the slow stirring tank (2) (see FIG. 22) to maximize the miscibility and to generate a large floc sufficiently, thereby greatly improving the precipitation efficiency in the final settling tank 3 later. It was confirmed.

Water to be treated having a large flocculated flocculation in the flocculation tank 2 is introduced into the final precipitation tank 3 and subjected to precipitation treatment.

At this time, due to the action of the baffle (B; B1, B2) in the slow stirring tank (2) is sufficiently mixed with the target water and the flocculant, and a large floc has been generated enough, the precipitation efficiency in the final settling tank (3) is Is maximized.

In addition, the inclined plate 3a may be constituted by a simple plate member, but as shown in FIGS. 23 and 24, it is preferable to form a circular pipe or a round member 3a 'in a lattice form. .

That is, as a method of increasing the precipitation efficiency in the final settling tank (3), there is a method of increasing the depth and the surface area, and when the water depth is the same condition, the larger the surface area, the more the precipitation efficiency increases. When the pipe or the round member 3a 'is formed in a lattice form, the water surface area is increased to increase the settling efficiency.

The treated water precipitated in the final settling tank 3 is discharged through the discharge pipe (3c).

The treated water discharged through the discharge pipe 3c is discharged to the discharge water system.

On the other hand, the sludge settled in the final settling tank (3) is a mixed flocculant having a specific gravity greater than that of the sludge in the slow stirring tank (2), so that a large floc is formed in the final settling tank (3). This is maximized.

The sludge deposited in the lower part of the final settling tank 3 during the settling process in the final settling tank 3 is returned to the sewage treatment facility or the sludge treatment facility by the settling material return pipe 3d and the return pump 3e.

In this case, when the weighted coagulant is added to the slow stirring tank 2 to increase the sedimentation efficiency of the sludge, the weighted coagulant is precipitated together with the sludge in the lower part of the final settling tank 3.

The sludge and weighted flocculant settled in the lower part of the sedimentation tank 3 are conveyed by the sediment return pipe 3d and the conveying pump 3e, and the sludge-weighted flocculant is connected to the end of the sediment return pipe 3d. It is separated by the hydrocyclones 5a constituting the means 5.

At this time, the weighted coagulant having a relatively high specific gravity is collected in the lower portion of the hydrocyclone (5a), where the weighted coagulant is re-introduced into the slow stirring tank (2) through the weighted coagulant re-entry pipe (5b), and the relatively low specific gravity sludge is hydrocyclone. Collected at the top of 5a and concentrated, the concentrated sludge is transferred to the sludge treatment facility through the sludge conveying pipe 5c.

Ultra-high-speed, high-efficiency coagulation treatment apparatus according to another embodiment applied to the present invention, as shown in FIG. 25, by connecting the primary settling basin (6) to the treated water inlet pipe (1a) of the in-line mixer (1) After subjecting the water to the first precipitation, the supernatant is introduced into the in-line mixer (1), and the fine particulate matter in the sediment deposited on the primary sedimentation basin (6) is separated and weighted in a slow stirring tank (2). It is to be used as a flocculant.

The primary sedimentation basin (6) is installed on the downstream side of the sedimentation basin, which is a pretreatment tank in a conventional sewage treatment facility. A supernatant feed pipe 6a for supplying the pipe 1a and a precipitate material conveying pipe 6b for conveying the precipitated material are provided.

The sediment return pipe (6b) of the primary sedimentation basin (6) is connected to the sludge-weighted coagulant separating means (5).

The sludge-weighted coagulant separating means 5 is the same as in the first embodiment described above, and the sediment conveying tube 3d of the final settling tank 3 and the sediment conveying tube 6b of the primary sedimentation basin 6. This common connection allows the sediment of the final settling tank 3 and the sediment of the primary sedimentation basin 6 to be selectively or simultaneously separated into sludge and weighted coagulant.

The weighted coagulant inlet tube 5b is configured to independently inject the weighted coagulant into the slow stirring tank 2 or is connected to the weighted coagulant inlet tube 4b of the weighted coagulant inlet means 4 to add the weighted coagulant injector ( The weighted coagulant of 4) can be added to the slow stirring tank (2).

The weighted coagulant inlet tube 5b may be connected to the weighted coagulant inlet tube 4b of the weighted coagulant injector 4 or the weighted coagulant may be independently added to the slow stirring tank 2 as shown in FIG. It may be stored and connected to a recovery device (not shown) and then introduced into the weighted coagulant supply source 4a of the caustic coagulant input means 4.

The sludge conveying pipe 5c may transfer the separated sludge to the sludge treatment facility, and a part of the sludge conveying pipe may be returned to the slow stirring tank 2 to aggregate and settle in the final settling tank 3.

In addition, although the sludge-weighted coagulant separating means 5 is configured as a hydrocyclone 5a in FIG. 25, the sludge-weighted coagulant separating means 5 may be configured in a sieve manner.

The sludge-weighted coagulant separating means (5) is connected to the settling material conveying pipe (3d) of the final settling tank (3) to separate the sediment settled in the final settling tank (3) with a sludge and a weighted coagulant, slow stirring ( May be re-injected in 2).

That is, the sludge-weighted coagulant separating means 5 may selectively separate or simultaneously separate the precipitate of the primary sedimentation basin 6 and the precipitate of the final sedimentation tank 3.

Hereinafter, the sewage and rainwater selective treatment apparatus according to the present invention will be described according to the first preferred embodiment shown in FIGS. 26 and 27.

The sewage and rainwater selective treatment device according to the present embodiment combines the ultra-high-efficiency high-efficiency flocculation treatment device as described above with the sewage treatment facility and the rainwater treatment facility, and selectively treats the water according to the smooth water and rainfall and the flow rate of the sewage and rainwater. It is configured to do so.

Selective treatment apparatus for sewage and rainwater according to the present embodiment, as shown in Figs. 26 and 27, by connecting the ultra-high-efficiency high-efficiency flocculation treatment apparatus 100 to a conventional sewage treatment facility 200 selectively It is to be handled.

The ultra-high-speed, high-efficiency flocculation apparatus 100 and the sewage treatment facility 200 are treated water inlet of the treated water discharge pipe 201 of the sewage treatment facility 200 and the in-line mixer (1) of the ultra-high-speed, high-efficiency flocculation apparatus (100). The tubes 1a are connected to each other by connecting the connecting tubes 202.

Since the ultra-high-speed, high-efficiency coagulation processing apparatus 100 is the same as the preferred embodiment of the ultra-high-speed, high-efficiency coagulation processing apparatus described above with reference to FIGS. 1 to 24, the same reference numerals are given to each component, and detailed description thereof will be omitted.

The sewage treatment facility 200 may select any one of the existing sewage treatment facilities, which is not described in detail in this embodiment.

In addition, in order to selectively treat the sewage and rainwater is connected to the conventional stormwater toil 300 and the conventional filter pollutant removal facility 400.

In other words, the conduit (L) is connected to the stormwater chamber 300, the stormwater chamber 300 is connected to the sewage treatment facility 200, ultra-high-speed high-efficiency coagulation treatment device 100 and filtration pollutant treatment facility 400 do.

The storm drain chamber 300 may be a conventional one having a 1Q collecting pipe 301, a 2Q collecting pipe 302, and an overcapacity discharge pipe 303. The capacity excess discharge pipe 303 is for discharging a flow rate of 3Q or more.

The 1Q collecting pipe 301 of the rainwater chamber 300 is connected to the sewage treatment facility 200, the 2Q collecting pipe 302 is connected to the ultra-high-efficiency high-efficiency coagulation treatment device 100, the excess capacity discharge pipe 303 Is connected to the filter pollutant removal facility 400.

The filter contaminant removing facility 400 may be any filter filtering contaminant removing facility having a filter medium, and may use the one disclosed in Korean Patent No. 10-0952998 by the present applicant.

It is preferable to provide a storage tank 500 in the middle of the 2Q collecting pipe 302 so as to control the flow rate flowing into the ultra-high-speed, high-efficiency coagulation processing apparatus 100.

In addition, a three-way valve (not shown) may be installed between the treated water discharge pipe 201 and the connection pipe 202 and between the connection pipe 202 and the 2Q collecting pipe 302 to control the flow direction. It is composed.

Hereinafter, the sewage and rainwater treatment processes by the sewage and rainwater selective treatment apparatus according to the present invention will be described.

In normal water, that is, when there is no rainfall, when the sewage flows into the storm drain 300, the sewage treatment facility 200 is introduced into the sewage treatment facility 200 through the 1Q collecting pipe 301, and the treated water is treated in the sewage treatment facility 200. Through the water discharge pipe 201 and the connection pipe 202 is introduced through the treated water inlet pipe (1a) of the in-line mixer (1) constituting the ultra-high-speed high efficiency coagulation treatment apparatus (100).

The treated water introduced through the treated water inlet pipe 1a of the inline mixer 1 is treated by the action of the ultra-high-efficiency high-efficiency coagulation treatment apparatus as described above with reference to FIGS. Is discharged through the discharge pipe (3c).

In this case, the treated water first treated by the sewage treatment facility 200 is secondly treated by the ultra-high-speed, high-efficiency flocculation apparatus 100, and the ultra-high-efficiency, high-efficiency flocculation apparatus 100, as described above, is mixed with the mixing efficiency and aggregation. Since the efficiency and sedimentation efficiency are maximized, the quality of the final treated water is greatly improved.

In the rainfall, when the sewage and rainwater enter the storm sediment (300), the sewage and rainwater collected in 1Q through the 1Q collecting pipe (301) flows into the sewage treatment facility (200) and is treated through a conventional sewage treatment process. The sewage and rainwater of 2Q collected through the 2Q collecting pipe 302 is introduced into the ultra-high-efficiency high-efficiency flocculation apparatus 100 and coagulated, and when the sewage and rainwater of 3Q or more flow into the rainwater toil 300, an excess discharge pipe ( 303 is introduced into the filter pollutant removal facility 400 is filtered. The treated water treated in the filtering pollutant removal facility 400 is discharged to the discharge water system through the treated water discharge pipe 401.

As described above, the selective treatment device for sewage and rainwater according to the present invention is a sewage treatment facility 200 and ultra-high-speed and high-efficiency coagulation treatment according to the flow rate of sewage and / or rainwater flowing through the conduit (L) during pyeongsu and rainfall. Since the coagulation treatment by the apparatus 100 and the filtration treatment by the filtration-type pollutant treatment facility 400 are selectively or combinedly treated, it is possible to cope with an optimal situation in a possible situation, and consequently the water quality of the discharge water system. It will be possible to improve.

In addition, the sewage treatment water biologically treated in the sewage treatment facility 200 may be treated again by the ultra-high-speed, high-efficiency coagulation treatment apparatus 100 to more reliably remove T-P, thereby improving the water quality of the discharge water system.

Hereinafter, the sewage and rainwater selective treatment apparatus according to the present invention will be described according to the second preferred embodiment shown in Figs.

In the selective treatment apparatus for sewage and rainwater according to the present embodiment, as shown in FIG. 28 and FIG. 29, a primary sedimentation basin 6 is connected to an inlet of the stormwater chamber 300 so that the water to be treated is primary. After the sedimentation treatment, the supernatant is introduced into the stormwater chamber 300, and the weighted coagulant in the sediment deposited on the primary sedimentation basin (6) is separated and used as a weighted coagulant in the slow stirring tank (2). .

The primary sedimentation basin (6) is to be installed in the sedimentation basin downstream of the pretreatment tank in a conventional sewage treatment facility, by sedimentation of the solid suspended solids of the water to be treated, the supernatant water for supplying the supernatant water to the storm water chamber (300) The transfer pipe 6a and the precipitate material conveying tube 6b for conveying a precipitate substance are provided. A conveying pump 6c is installed in the precipitate conveyance pipe 6b.

Sludge-weighted coagulant separating means 5 for separating the sediment deposited on the primary sedimentation basin 6 with sludge and weighted coagulant are provided.

Since the sludge-weighted coagulant separating means 5 is the same as in the second embodiment (see FIG. 25) of the ultra-high-efficiency high-efficiency flocculation apparatus described above, the same parts are given the same reference numerals, and detailed description thereof will be omitted.

In addition, the sewage and rainwater selective treatment process of the sewage, rainwater selective treatment device according to the present embodiment is separated by the sludge-weighted coagulant separating means (5) as a weighted coagulant sediment precipitated in the primary sedimentation basin (6) Except for utilizing, since it is the same as in the above-described first embodiment, a detailed description thereof will be omitted.

In the above described the present invention as a preferred embodiment, with reference to the illustrated drawings, but the present invention is not limited by the embodiments and drawings presented in the present specification, the corresponding companies within the scope of the technical spirit of the present invention Of course, various modifications may be made.

1: inline mixer 2: slow stirring
3: final sedimentation tank 4. weighted coagulant input means
5: sludge-weighted coagulant separation means
10: cylindrical casing 20: stem
30: water flow control and mixing projection sequence 31: projection
100: high speed high efficiency coagulation treatment device 200: sewage treatment facility
300: rainwater soil 400: filter pollutant removal device

Claims (11)

Stirred slow as to form big flocs by stirring the flocculating agent and the process can target miscible with slow in a high-speed agitation means for mixing the flocculating agent at a high speed in the treated subject to be discharged and the high-speed stirring means in the biological wastewater treatment apparatus tank and A slow stirring means consisting of a stirrer provided inside the slow stirring tank and at least one baffle provided on four inner walls of the slow stirring tank, and a settling tank for sedimenting the water to be treated in the slow stirring means; A flocculation apparatus;
A primary sedimentation basin for precipitating the water to be treated and introducing the supernatant into the biological sewage treatment apparatus;
Sludge-weighted coagulant separating means for supplying the weighted coagulant separated by separating the sediment settled in the primary sedimentation with sludge and weighted coagulant to the slow stirring means; and discharged from the biological sewage treatment device during the dry season Treatment of the water to be treated and when the rainfall is not flowing into the sewage treatment plant in the primary sedimentation basin, the total treatment of effluent from dry sewage treatment plant during dry season and selective treatment system of rainfall effluent during rainfall.
delete The method of claim 1,
The baffle is composed of an upper baffle extending from the top of the upstream and downstream walls of the slow stirrer to the middle and a lower baffle extending from the bottom of the left and right walls of the slow stirring to the middle. Selective treatment system of rainfall runoff during rainfall.
The method of claim 1,
The sedimentation tank is characterized in that it comprises a plurality of inclined plate in the dry season sewage treatment plant total phosphorus treatment and rainwater outflow water selective treatment system.
The method of claim 4, wherein
The inclined plate is a pipe or round rod-shaped member in the settling tank is characterized in that the gross treatment of the discharge of the sewage treatment plant during dry season and selective treatment system of rainfall runoff during rainfall.
The method of claim 1,
The sludge-weighted coagulant separating means is connected to the sediment conveying pipe of the primary sedimentation basin hydrocyclone to separate the returned sediment into sludge and weighted coagulant,
A weighted coagulant inlet tube connected to a lower end of the hydro cyclone to inject the weighted coagulant separated from the hydro cyclone into the slow stirring means;
Selective treatment system for total phosphorus treatment and rainfall during runoff during the dry season sewage treatment plant characterized in that it comprises a sludge conveying pipe connected to the top of the hydro cyclone.
The method according to claim 6,
The hydrocyclone of the sludge-weighted coagulant separating means is connected to the sediment return pipe connected to the bottom of the sedimentation tank, characterized in that the total treatment of effluent from dry sewage treatment plant and selective treatment system of rainfall effluent during rainfall.
The method of claim 1,
And a weighted coagulant injecting means for injecting the weighted coagulant into the slow stirring means, wherein the total phosphorus treatment in the dry sewage treatment plant effluent and the selective treatment system of rainfall effluent during rainfall.
The method of claim 8,
The weighted coagulant input means comprises a weighted coagulant supply source and a weighted coagulant input pipe for inputting the weighted coagulant stored in the weighted coagulant supply source into the slow stirring means, the total phosphorus treatment of dry sewage treatment plant effluent. Selective treatment system of rainfall runoff during rainfall.
The method of claim 6 or 8,
The weighted coagulant inlet tube of the sludge-weighted coagulant separating means and the weighted coagulant inlet tube of the weighted coagulant injecting means are configured to individually add the weighted coagulant to the slow stirring means. Selective treatment system of rainfall runoff during rainfall.
The method according to claim 5 or 8,
Drying sewage treatment plant characterized in that the weighted coagulant inlet tube of the sludge-weighted coagulant separating means and the weighted coagulant inlet tube of the weighted coagulant injecting means are connected to each other and to add the weighted coagulant to the slow stirring means Total phosphorus treatment of effluent and selective treatment system of rainfall effluent during rainfall.

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