KR101130132B1 - System for treating total phosphorus from effluent water of sewage treatment plant during the dry season and treating combined sewer overflow selectively during rainy day - Google Patents

Abstract

PURPOSE: A system for treating the total phosphorus of effluent from a sewage treating plant in dry season and selectively treating rainwater combined effluent in rainy season is provided to stabilize the rotating current of mixed liquid of treating water and a coagulating agent based on a plurality of zigzag-shaped slanted baffles. CONSTITUTION: A storm overflow chamber(1) includes a 1Q collecting pipe(1a), a 2Q collecting pipe(1b), and a 3Q collecting pipe(1c). A sewage treating plant(2) is in connection with the 1Q collecting pipe. A combining type effluent storing bath(3) is in connection with the 2Q collecting pipe. Total phosphorus is eliminated from drained water from the sewage treating plant. Combined effluent is introduced into a complex type coagulating treating unit(100), and the effluent is rapidly coagulated.

Description

System for treating total phosphorus from effluent water of sewage treatment plant during the dry season and treating combined sewer overflow 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 confluent effluent during rainfall, and more specifically, to a sewage treatment plant discharged from a sewage treatment plant during dry season by linking a sewage treatment plant with an ultra-high speed and high efficiency coagulation treatment apparatus. It removes total phosphorus from effluent and meets effluent water quality standard which is gradually strengthening effluent quality by super fast flocculation treatment of combined effluent during rainfall. Recycling with weighted coagulant minimizes the use of weighted coagulant to reduce the cost of weighted coagulant and minimizes the amount of sludge to reduce the sludge disposal cost. It relates.

From 1993 to 2005, the water management policy invested 26 trillion won in sewage treatment facilities, representing 91% of the budget spent during the same period. As a result, the pollutant load of organic materials in the four major rivers and rivers has decreased, mainly due to BOD, but the total phosphorus (TP) has increased due to nutrient related vegetable holes. Eutrophication of streams causes rapid fluctuations in dissolved oxygen. During the day, the concentration of dissolved oxygen increases significantly due to photosynthesis of attached algae, whereas at night, the concentration of dissolved oxygen decreases because the attached algae use oxygen from the water hand. This phenomenon adversely affects living things such as fish. The proliferation of algae makes it difficult to treat purified water and causes deterioration of taste and smell of drinking water. In 2007, the total phosphorus concentration of Soyang Dam, the most upstream of the Han River, was 0.032 ㎎ / ℓ and Paldang Dam was 0.058 ㎎ / ℓ. The cause of eutrophication of rivers in Korea can be pointed out in terms of phosphorus concentration in the sewage treatment plant discharged higher than in foreign countries.

Although eutrophication usually occurs in water purification areas, such as lakes, eutrophication is severe in rivers, but due to the decrease in dry season flow rate and increased residence time, the cause of sewage treatment plants with high phosphorus concentrations cannot be ignored. The concentration of phosphorus in Korea is 2 mg / l, which is quite different from that of major countries such as the United States, Germany and Japan. The total phosphorus concentration of effluent in Korea is 2 mg / ℓ, which is 100 times higher than that of eutrophication, 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 357 public sewage treatment plants in operation nationwide. Of these, 245 advanced nitrogen removal processes (A2O, SBR, etc.) accounted for 69% of the total, while traditional methods for removing BOD (standard activated sludge method, long-term aeration method, etc.) were 112% (31%). There is a trend towards a treatment process (Oh Jae-il, drought response sewerage construction, April 2009). In 2006 and 2007, the average inflow and discharged water quality of Korean sewage treatment plant showed that the removal rate of each item is gradually increasing, but the removal rate of BOD, COD, and SS (94.3%, 85.3%, 96.0% as of 2007) This is different from TN and TP removal rates (67.6% and 75.3% in 2007). The average discharge water quality of T-P was 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, 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. Occupy the rules. Nonpoint 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 plant is introduced with a flow rate corresponding to three times the design flow rate (3Q), to make a first precipitation at the primary sedimentation pond, and then discharge 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 sludge treatment system of the sewage treatment plant flows into the inflow 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, in the past, a sewage treatment plant coagulation treatment apparatus has been developed. Examples thereof include an ultra rapid coagulation (URC) method, an actiflo (TM) method, an upflow type method using floating media, a non-powered coagulation precipitation method, and an integrated high efficiency coagulation precipitation method. There is a way.

Conventional URC sewage treatment type coagulation treatment apparatus includes a rapid reaction tank, agglomeration tank, a slow aggregation tank and a high-speed gradient plate settling tank. URC sewage treatment type flocculation apparatus is characterized by using a gradient plate sedimentation tank by administering a flocculent aid together with a flocculant.

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, it is possible to think of a method of steaming the amount of flocculant (drug), but in this case, the amount of sludge is increased, which lowers the economic efficiency of the process, and the solution regarding the disposal of the drug and the sludge is revealed as an additional problem. .

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

Conventional Actiflo (TM) 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 by introducing sand (micro-sand) as weighted coagulant in addition to polymer as coagulant aid, and circulating 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 is provided with an upper screen and a flotation filter in a reaction tank, and has a flocculation collection tank and a collection pump for collecting the agglomeration material on one side of the reaction tank.

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.

Conventional non-cohesive sedimentation type sewage treatment type coagulation treatment device is characterized in that the whole of the hydraulic arrangement by connecting the quantitative drug supply unit, misclumping unit, sedimentation unit and filtration unit in series.

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 system sewage treatment type coagulation treatment unit is 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.

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.

Therefore, the object of the present invention is to maximize the mixing efficiency and the flocculation sedimentation efficiency, to minimize the hydraulic residence time of the combined water flow water to be treated water and to increase the surface load rate, in the case of rainfall in a large amount of water being combined water flow In addition, it can remove over 90% of total phosphorus (TP) in case of dryness, so that it can replace the advanced treatment facilities of existing sewage treatment plants, and the highly efficient ultra-high-speed coagulation sedimentation treatment equipment can make the facility compact. Is to provide.

Another object of the present invention is to provide a high-efficiency ultra-high speed flocculation sedimentation treatment apparatus capable of rapid mixing of the combined flow water and the flocculant as the water to be treated.

It is yet another object of the present invention to provide a highly efficient ultra-fast coagulation sedimentation treatment apparatus that enables a compact construction of a facility.

Another object of the present invention is to stabilize the rotational flow generated in the stirring process to mix the combined water flow to be treated water and to prevent the flocculated giant floc is broken to maximize the settling efficiency, high-efficiency ultra-fast coagulation sedimentation treatment To provide a device.

Another object of the present invention is to use the collected sludge as a weighted coagulant to reduce the use of weighted coagulant compared to the treatment efficiency and to reduce the cost of weighted coagulant, thereby reducing the amount of sludge, minimize the facilities according to the sludge disposal and reduce the cost of sludge disposal It is to provide a highly efficient ultra-fast coagulation sedimentation treatment device that can be saved.

Another object of the present invention is to remove the total phosphorus from the sewage treatment effluent discharged from the sewage treatment plant during the dry season, and to meet the discharge water quality standards that are gradually strengthening the discharge water quality by ultra-fast flocculation treatment of the combined effluent during rainfall. It is intended to provide a total treatment of municipal wastewater treatment plant effluent and an optional treatment system for combined runoff during rainfall.

Another object of the present invention is to recycle the sludge agglomerated in the ultrafast high-efficiency flocculation apparatus as a weighted flocculant in the ultrafast high-efficiency flocculation apparatus, thereby minimizing the use of the weighted flocculant and reducing the cost of the flocculating flocculant and minimizing the amount of sludge. It is to provide a selective treatment system for total discharge of sewage treatment plant effluents during dry season and combined effluents during rainfall.

The present invention, in order to achieve the above object, the settling tank; A sludge collection unit provided below the settling tank and to which the sludge discharge transport pipe is connected; A mixing tank installed in the settling tank and connected to the treatment object water inlet pipe at a lower end thereof; A downward flow path formed between one side wall of the settling tank and one side wall of the mixing tank and connected to the mixing tank through an internal overflow hole formed in one side wall of the mixing tank; A plurality of zigzag inclined baffles installed in the downward flow path; A chemical flocculant inlet pipe connected to the middle of the treatment object water inlet pipe; It provides an ultra-high-speed, high-efficiency coagulation processing apparatus comprising a weighted coagulant inlet tube connected to the upper portion of the mixing tank.

In addition, the present invention, in order to achieve the above object, the settling tank; A sludge collection unit provided below the settling tank and to which the sludge transport pipe is connected; A mixing tank 23 installed at an upstream side of the settling tank and connected to the treatment object water inlet pipe at an upper end of the upstream side; A downward flow path provided on an upstream side of the mixing tank to allow the treatment object water flowing in from the treatment object water inflow pipe to flow downward into the upstream side of the mixing tank; It is provided on the downstream side of the mixing tank and the upstream side of the settling tank provides a high-speed, high-efficiency coagulation processing apparatus comprising a downflow passage for flowing the treated object mixed in the mixing tank down into the settling tank.

In addition, the present invention, to achieve the above-mentioned object, 1Q rain pipe, and 2Q rain pipe and rain storms equipped with 3Q rain pipe; A sewage treatment plant connected to the 1Q collecting pipe and having a sewage treatment discharge pipe; A confluent effluent storage tank connected to the 2Q collecting pipe and having a confluent effluent transport pipe; The water inlet pipe to be treated is connected in parallel to the sewage treatment effluent pipe of the sewage treatment plant and the combined effluent transport pipe of the combined effluent storage tank to remove the total phosphorus from the sewage treatment effluent of the sewage treatment plant during the dry season, A hybrid ultra-high-speed, high-efficiency coagulation processing apparatus for ultra-high-speed coagulation treatment of the combined-type effluent delivered from the combined-type effluent transfer pipe of the combined-type effluent storage tank; Sludge generated in the complex ultra-high-speed high-efficiency flocculation treatment device is stored, and during the dry season, the sludge storage tank for storing the sludge into the complex ultra-high-efficiency high-efficiency flocculation device as a weighted flocculant; dry season sewage treatment plant effluent Provides an optional treatment system for combined effluent from the total phosphorus treatment and rainfall.

In addition, the present invention, to achieve the above-mentioned object, 1Q rain pipe, and 2Q rain pipe and rain storms equipped with 3Q rain pipe; A sewage treatment plant connected to the 1Q collecting pipe and having a sewage treatment discharge pipe; A confluent effluent storage tank connected to the 2Q collecting pipe and having a confluent effluent transport pipe; A high-speed, high-efficiency agglomeration treatment apparatus for sewage treatment that is connected to a sewage treatment effluent discharge pipe of the sewage treatment plant and removes phosphorus from the sewage treatment effluent of the sewage treatment plant during dry season and rainfall; An ultra-high-speed, high-efficiency agglomeration treatment apparatus for confluent effluent treatment, wherein the object water inlet pipe is connected to the confluent effluent transport pipe of the confluent effluent storage tank to coagulate the confluent effluent during rainfall; It is connected to the lower end of the ultra-high-efficiency agglomeration treatment device for the combined effluent treatment, the sludge generated in the ultra-high-efficiency agglomeration treatment apparatus for the combined effluent treatment is stored during rainfall, and the sludge is stored during the dry season, the ultra-high efficiency agglomeration treatment for the sewage treatment. Sludge storage tank to be added to the device as a weighted flocculant; provides a selective treatment system of dry effluent sewage treatment plant effluent and the combined effluent during rainfall.

According to the high-efficiency ultrafast flocculation sedimentation treatment apparatus of the present invention, the mixed liquid of the treated water and the flocculant in which the rotary flow is generated in the process of mixing while stirring in the mixing tank flows downward through the sludge collection tank in the downflow passage. The rotational flow is stabilized by a plurality of zigzag inclined baffles installed, and then flows downward into the sludge collection tank, thereby maximizing the sedimentation and sludge collection in the sludge collection unit.

In addition, according to the high-efficiency ultrafast flocculation sedimentation treatment apparatus of the present invention, by mixing the combined overflow water and the flocculant, which is the water to be treated by an in-line mixer, in a mixing tank having a stirrer, the mixing efficiency and the flocculation precipitation efficiency are maximized, Minimize the hydraulic retention time and increase the surface load rate of the confluenced overflowed water, and in case of rainfall, it can treat a large amount of condensed overflowed water, which is a short time, and 90% of the total phosphorus (TP) in the dry season. By eliminating abnormality, it is possible to replace the advanced treatment facility of existing sewage treatment plant, and to compact the facility.

According to the high-efficiency ultrafast flocculation sedimentation treatment apparatus of the present invention, by providing a mixing tank at the upper side of the settling tank and a sludge collection unit at the bottom of the settling tank, the facility can be compactly configured.

According to the high-efficiency ultrafast flocculation sedimentation treatment apparatus of the present invention, the combined flow of upstream water and flocculant, which are mixed by stirring with a stirrer in a mixing tank, are flowed downward into a sludge collection tank through a downward flow path equipped with a plurality of zigzag inclined baffles. By doing so, it is possible to maximize the settling efficiency by stabilizing the rotational flow generated in the stirring process by the stirrer in the mixing tank and preventing the flocculated giant floc from breaking.

According to the high-efficiency ultrafast flocculation sedimentation treatment apparatus of the present invention, the sludge collected in the sludge collecting unit is conveyed to the mixing tank to utilize the particulate matter such as sand contained in the sludge as a weighted coagulant, thereby reducing the use of weighted coagulant compared to the treatment efficiency and weighted coagulant cost. This reduces the amount of sludge produced, minimizes the facilities for sludge disposal, and reduces the cost of sludge disposal.

According to the present invention, the total phosphorus treatment of the dry sewage treatment plant effluent and the selective treatment system of the combined effluent during rainfall, in connection with the sewage treatment plant and the ultra-high-speed high-efficiency coagulation treatment device, treat the total phosphorus from the sewage treatment plant effluent during dry season and Ultra-fast agglomeration of the combined effluent can meet the effluent water quality standard, which is gradually strengthening the effluent quality.

According to the present invention, the total phosphorus treatment of the effluent from the dry and sewage treatment plant and the selective treatment system of the combined effluent during the rainfall, the aggregated sludge is stored in the ultra-high-efficiency coagulation treatment device, and the sludge is recycled to the ultra-high-speed, high-efficiency coagulation treatment device as a weighted coagulant. By minimizing the use of weighted coagulant, it is possible to reduce the cost of weighted coagulant and minimize the amount of sludge generated to reduce the sludge disposal cost.

1 and 2 show a first preferred embodiment of the total treatment of dry effluent sewage treatment plant effluent and selective treatment system of combined effluent during rainfall according to the present invention,
1 is a flow chart showing the total phosphorus treatment state of the sewage treatment plant effluent during the dry season,
Figure 2 is a system diagram showing a state of ultra-fast agglomeration treatment of confluent effluent during rainfall,
3 and 4 shows a second preferred embodiment of the total treatment of dry effluent sewage treatment plant effluent and selective treatment system of combined effluent during rainfall according to the present invention,
3 is a flow chart showing the total phosphorus treatment state of the sewage treatment plant discharged during dry season,
4 is a system diagram showing the ultrafast flocculation treatment state of the combined effluent during rainfall;
5 is a schematic diagram showing a first preferred embodiment of the ultrafast high efficiency agglomeration processing apparatus according to the present invention;
Figure 6 is a schematic diagram showing a second preferred embodiment of the ultra-high speed and high efficiency coagulation processing apparatus according to the present invention,
7 is a schematic diagram showing a third preferred embodiment of the ultrafast high efficiency agglomeration processing apparatus according to the present invention;
8 is a system diagram showing a fourth preferred embodiment of the ultrafast high efficiency agglomeration processing apparatus according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 show a first preferred embodiment of the total treatment of dry water sewage treatment plant effluent and the selective treatment system of combined effluent during rainfall according to the present invention.

The total treatment of dry season sewage treatment plant effluent and the selective treatment system of the combined effluent during rainfall includes a sewage treatment plant 2 and a combined effluent storage tank 3 respectively connected to the stormwater chamber 1.

The sewage treatment plant 2 is connected to the storm drain chamber 1 through the 1Q collecting pipe 1a, and the combined effluent storage tank 3 is connected to the storm drain chamber 1 through the 2Q collecting pipe 1b. . The rainwater chamber 1 is connected to the filter pollutant removal facility 4 through the 3Q collecting pipe 1c.

The filter pollutant removal facility 4 is provided with a treated water discharge pipe 4a as a conventional device pollutant removal facility.

The sewage treatment discharge pipe 2a of the sewage treatment plant 2 during dry season is connected in parallel to the sewage treatment effluent discharge pipe 2a of the sewage treatment plant 2 and the combined effluent delivery pipe 3a of the combined effluent storage tank 3. Ultra-high-efficiency high-density coagulation treatment apparatus 100 for removing the phosphorus from the sewage treatment effluent discharged from the wastewater discharge, and during the rainfall, the super-high-density coagulation treatment of the combined effluent transported from the combined effluent transfer pipe (3a) of the combined effluent storage tank (3). Include.

The ultra-high-speed, high-efficiency coagulation treatment device 100 has a treatment water inlet pipe connected to the sewage treatment effluent discharge pipe 2a of the sewage treatment plant 2 and the combined effluent water transfer pipe 3a of the combined effluent storage tank 3. 101), and a treated water discharge pipe 102 for discharging the treated water and a sludge discharge transport pipe 103 for discharging and transporting the settled sludge.

The treated water inflow pipe 101 is connected to the sewage treatment effluent discharge pipe 2a and the combined effluent transport pipe 3a by connecting pipes 2b and 3b, respectively.

A treatment object water inflow pump 101p is provided in the middle of the treatment object water inflow pipe 101, and a sludge discharge transport pump 103p is provided in the middle of the sludge discharge transport pipe 103.

The ultra-high speed and high efficiency flocculation apparatus 100 is provided with a chemical flocculant inlet tube 104 and a weighted coagulant inlet tube 105. The chemical flocculant inlet tube 104 is connected in the middle of the treatment object water inlet tube 101, and the weighted coagulant inlet tube 105 is connected to the upper portion of the ultra-high efficiency coagulation treatment apparatus 100.

In the middle of the chemical coagulant inlet tube 104 and the weighted coagulant inlet tube 105, a chemical coagulant inlet pump 104p and a weighted coagulant inlet pump 105p are provided.

The sludge storage tank 5 is connected to the sludge discharge transport pipe 103 by a sludge storage pipe 5a and to the sludge discharge transport pipe 103 by a sludge discharge connection pipe 5b.

The sludge storage tank 5 and the treated water inlet pipe 101 are connected by a sludge conveying pipe 106. A sludge conveying pump 106p is provided in the middle of the sludge conveying pipe 106.

Hereinafter, the operation of the total phosphorus treatment of the dry season sewage treatment plant effluent and the selective treatment system of the combined effluent during rainfall will be described.

In the dry season, as shown in FIG. 1, sewage water of 1Q or less corresponding to the treatment capacity of the sewage treatment plant 2 is introduced into the stormwater chamber 1, and 1Q or less flows into the stormwater chamber 1. All of the sewage flows into the sewage treatment plant 2 through the 1Q collecting pipe 1a and is treated by a conventional sewage treatment method.

That is, during the dry season, as shown in FIG. 1, the sewage treatment effluent treated in the sewage treatment plant 2 and discharged through the sewage treatment effluent outlet pipe 2a is discharged through the treated water inflow pipe 101. It is introduced into the ultrafast high efficiency agglomeration apparatus 100 and coagulated at a high speed with high efficiency. At this time, in the ultra-high-speed, high-efficiency flocculation apparatus 100, the total phosphorus in the sewage treatment effluent discharged from the sewage treatment plant 2 is treated.

Therefore, during the dry season, the total phosphorus contained in the sewage treatment effluent treated and discharged in the sewage treatment plant 2 can be reliably removed, and then discharged into the effluent, etc., so that the water quality of the water system is gradually strengthened. Will be.

The sewage treatment effluent flowing into the ultra-high-speed, high-efficiency flocculation apparatus 100 is polymer or micro sand introduced through the chemical flocculant inlet tube 104 and the weighted flocculant inlet tube 105 and the chemical flocculant. Pollutants such as suspended solids contained in the sewage treatment effluent are mixed and mixed with a weighted flocculant such as a flocculant and precipitated.

The sludge settled in the ultra-high-speed, high-efficiency coagulation processing apparatus 100 is discharged through the sludge discharge transport pipe 103 is transferred to the sludge disposal facility (not shown).

The reason for transferring the sludge precipitated in the ultra-high-efficiency high-efficiency flocculation apparatus 100 during the dry season to the sludge disposal facility immediately without storing it in the sludge storage tank 5 is in the sewage treatment effluent discharged from the sewage treatment plant 2 during the dry season. This is because there are few granular materials that can be used as the weighted coagulant, and their utility as the coagulant is poor.

During rainfall, as shown in FIG. 2, confluent effluent including 1 S or more sewage and rainfall effluent flows into the rainwater sesame chamber 1, and the confluent effluent of 1 Q is discharged through the 1Q collecting pipe 1a to the sewage treatment plant ( 2) is introduced into and treated, the combined effluent of 1Q or more flows into and stored in the effluent storage tank (3) through the 2Q collecting pipe (1b), the confluent effluent stored in the effluent storage tank (3) is connected to the connection pipe ( 3b) and the treatment object water inflow pipe 101 are introduced into the ultra-high-efficiency high-efficiency flocculation apparatus 100 and are processed. In addition, when the rainfall-type confluent effluent flows more than 3Q into the rainwater chamber 1, it is introduced into the filtration-type pollutant removal facility 4 through the 3Q collecting pipe 1c and processed.

That is, during rainfall, as shown in FIG. 2, the combined effluent flowing into the sewage treatment plant 2 during the rainfall is treated with the conventional sewage treatment in the sewage treatment plant 2 and then the sewage treatment effluent discharge pipe 2a. Discharged through the discharge system.

The combined effluent flowing into the ultra-high-speed, high-efficiency coagulation processing apparatus 100 is a chemical coagulant such as alum, which is introduced through the coagulant chemical coagulant inlet tube 104, and a polymer or micro sand injected through the weighted coagulant inlet tube 105. Pollutants, such as suspended solids, which are mixed and mixed with weighted coagulants such as, and contained in the combined effluent, are flocculated and precipitated.

The treated water treated in the ultra-high-speed, high-efficiency flocculation apparatus 100 is discharged to the discharge water system through the treated water discharge pipe 102.

The sludge precipitated in the ultra-high-speed, high-efficiency coagulation processing device 100 is discharged through the sludge discharge transport pipe 103 and transferred to the sludge disposal facility or the sludge discharged through the sludge discharge transport pipe 103 is the sludge storage pipe. It accumulates in the said sludge storage tank 5 through 5a.

The reason for storing the sludge deposited in the ultra-high-speed, high-efficiency coagulation treatment device 100 in the sludge storage tank 5 during the rainfall is that the sewage treatment effluent of the sewage treatment plant 2 during the dry season is the ultra-high-speed, high-efficiency coagulation treatment device 100 Compared to the sludge precipitated by the ultra-high-speed high-efficiency flocculation treatment in the rain, the sludge precipitated by the ultra-high-efficiency high-efficiency flocculation treatment apparatus 100 at the time of rainfall contains a large amount of particulate matter that can be used as a weighted coagulant.

The sludge precipitated in the ultra-high-efficiency high-efficiency flocculation apparatus 100 during the rainfall shown in FIG. 2 and stored in the sludge storage tank 5 is the ultra-high-speed high-efficiency flocculation through the sludge conveying pipe 106 during the dry season shown in FIG. 1. It is put into the processing apparatus 100. The sludge injected into the ultra-high-speed high-efficiency flocculation apparatus 100 acts as a weighted coagulant to increase the flocculation and precipitation efficiency.

In addition, when the sludge stored in the sludge storage tank 5 is introduced into the ultra-high-speed, high-efficiency coagulation processing apparatus 100 as a weighted coagulant, the amount of weighted coagulant introduced through the weighted coagulant inlet tube 105 can be minimized. In addition, the amount of chemical flocculant such as alum added through the chemical flocculant inlet tube 104 may be minimized. Therefore, the use cost of the chemical flocculant and the weighted flocculant can be reduced.

In addition, as the amount of the chemical flocculant and the weighted flocculant is minimized, the amount of sludge precipitated in the ultra-high efficiency coagulation treatment apparatus 100 is minimized. Therefore, the cost of sludge disposal can be reduced.

3 and 4 show a second preferred embodiment of the total treatment of dry effluent sewage treatment plant effluent and selective treatment system of combined effluent during rainfall according to the present invention.

In the dry season sewage treatment plant effluent according to the present embodiment and the selective treatment system of the combined effluent during rainfall,

It is connected to the sewage treatment plant (2) and connected to the effluent storage tank (3) and the effluent storage tank (3) for the ultra-high efficiency and high efficiency coagulation treatment facility (200) for treating phosphorus from sewage treatment effluent discharged from the sewage treatment plant (2). And a super high-efficiency high-efficiency flocculation apparatus (300) for combined effluent treatment for flocculating contaminants such as suspended solids.

The ultra-high-speed, high-efficiency flocculation apparatus 200 for sewage treatment has its treatment water inflow pipe 201 connected to the sewage treatment effluent discharge pipe 2a of the sewage treatment plant 2, and the ultra-high-efficiency high-efficiency aggregation for the combined effluent treatment. The treatment apparatus 300 has a treatment object water inlet pipe 301 connected to the combined effluent transport pipe 3a of the effluent storage tank 3.

The treatment target water inlet pipe 201 is connected to the sewage treatment effluent outlet pipe 2a of the sewage treatment plant 2 by a connecting pipe 2b, and the treatment target water inlet pipe 301 is the combined effluent storage tank. It is connected by the connecting pipe | tube 3b to the combined type | mold outflow conveying pipe 3a of (3).

The treatment object water inflow pipes 201p and 301p are provided in the middle of the treatment water inflow pipes 201 and 301, respectively, and the treated water discharge pipes 202 and 302 and the settled sludge are discharged and discharged into the ultra-high-efficiency high-efficiency flocculation apparatus 200 and 300, respectively. And sludge discharge conveying pipes 203 and 303 for conveying.

The ultra-high-speed, high-efficiency flocculation apparatus (200, 300) is provided with chemical flocculant inlet tube (204, 304) and weighted coagulant inlet tube (205, 305), respectively. The chemical flocculant inlet pipes 204 and 304 are connected to the middle of the treated water inlet pipe 201 and 301, respectively, and the weighted coagulant inlet pipes 205 and 305 are respectively connected to the upper portions of the ultra-high efficiency coagulation treatment devices 200 and 300.

In the middle of the chemical flocculant inlet pipes 204 and 304 and the weighted coagulant inlet pipes 205 and 305, chemical coagulant inlet pumps 204p and 304p and weighted coagulant inlet pumps 205p and 305p are provided.

The sludge storage tank 5 is connected to the sludge discharge transport pipe 303 of the ultra-high-efficiency high-efficiency flocculation apparatus 300 for the combined effluent treatment by the sludge storage pipe 5a and by the sludge discharge connection pipe 5b. It is connected to the sludge discharge transport pipe (303).

The sludge storage tank 5 and the treatment object water inlet pipe 201 of the ultra-high-efficiency high-efficiency flocculation apparatus 200 for sewage treatment are connected by a sludge conveying pipe 306. A sludge conveying pump 306p is provided in the middle of the sludge conveying pipe 306.

In the middle of the sludge conveying pipe 306, a sludge branch conveying pipe 307 for conveying the sludge of the sludge storage tank 5 to the ultra-high-efficiency cohesive processing apparatus 300 for the combined effluent treatment is connected. The sludge branch conveying pipe 307 is connected to the treatment object water inlet pipe 301 of the ultra-high-efficiency high-efficiency flocculation treatment device 300 for the combined effluent treatment.

Hereinafter, the operation of the total phosphorus treatment of the dry season sewage treatment plant effluent and the selective treatment system of the combined effluent during rainfall will be described.

In the dry season, as shown in FIG. 3, sewage water of 1Q or less corresponding to the treatment capacity of the sewage treatment plant 2 is introduced into the stormwater chamber 1, and of 1Q or less flowed into the stormwater chamber 1. All of the sewage flows into the sewage treatment plant 2 through the 1Q collecting pipe 1a and is treated by a conventional sewage treatment method.

That is, during the dry season, as shown in FIG. 3, the sewage treatment effluent treated in the sewage treatment plant 2 and discharged through the sewage treatment effluent discharge pipe 2a is ultra-high efficiency coagulation treatment apparatus 200 for the sewage treatment. It is introduced into the ultra-high-efficiency high-efficiency flocculation apparatus 200 for sewage treatment through the treated water inlet pipe 201 of the coalesced and treated with ultra-high efficiency. At this time, in the ultra-high-speed, high-efficiency coagulation treatment apparatus 200 for sewage treatment, the total phosphorus in the sewage treatment effluent discharged from the sewage treatment plant 2 is treated.

Therefore, during the dry season, the total phosphorus contained in the sewage treatment effluent treated and discharged in the sewage treatment plant 2 can be reliably removed, and then discharged into the effluent, etc., so that the water quality of the water system is gradually strengthened. Will be. According to the experiment, when the sewage treatment effluent discharged from the sewage treatment plant 2 was treated by the ultra-high-efficiency high-efficiency flocculation apparatus 200 for sewage treatment, it was found that 90% or more of the total phosphorus in the sewage treatment effluent was removed. .

The sewage treatment effluent flowing into the ultra-high-efficiency high-efficiency flocculation apparatus 200 for sewage treatment is a chemical flocculant such as alum input through the chemical flocculant inlet pipe 204 and a polymer injected through the weighted flocculant inlet pipe 205. Or contaminants, such as suspended solids, mixed and mixed with a weighted flocculant such as micro sand and contained in sewage treatment effluent, are flocculated and precipitated.

The sludge precipitated in the ultra-high efficiency coagulation treatment apparatus 200 for sewage treatment is discharged through the sludge discharge transport pipe 203 and is transferred to a sludge disposal facility (not shown).

The reason for transporting the sludge deposited in the ultra-high-efficiency high-efficiency flocculation apparatus 200 for sewage treatment in the dry season to the sludge disposal facility without storing it in the sludge storage tank 5 is the sewage discharged from the sewage treatment plant 2 during the dry season. This is because the treated effluent not only has a small amount of particulate matter that can be used as a weighted coagulant but also has poor utility as an agglomerate.

However, if necessary, the sludge discharge pipe 203 is connected to the sludge storage tank 5 so that the sludge deposited in the ultra-high efficiency coagulation treatment apparatus 200 for sewage treatment is also stored in the sludge storage tank 5 during dry season. I have to.

At the time of rainfall, as shown in FIG. 4, confluent effluent including 1 S or more sewage and rainfall effluent flows into the storm drain chamber 1, and the confluent effluent of 1Q is discharged through the 1Q collecting pipe 1a. 2) is introduced into and treated, the combined effluent of 1Q or more flows into and stored in the effluent storage tank (3) through the 2Q collecting pipe (1b), the confluent effluent stored in the effluent storage tank (3) is connected to the connection pipe ( 3b) and the treated water inflow pipe 301 are introduced into and treated with the ultra-high-efficiency high-efficiency flocculation apparatus 300 for the combined effluent treatment. In addition, when the rainfall-type confluent effluent flows more than 3Q into the rainwater chamber 1, it is introduced into the filtration-type pollutant removal facility 4 through the 3Q collecting pipe 1c and processed.

The water to be treated introduced into the sewage treatment plant 2 is a conventional sewage treatment in the sewage treatment plant 2, and is again treated by the ultra-high-efficiency high-efficiency coagulation treatment apparatus 200 for sewage treatment and then the sewage treatment effluent discharge pipe. Through 2a, it is discharged to the discharge water system.

The water to be treated introduced into the sewage treatment ultrafast high efficiency agglomeration processing apparatus 200 is treated through a process equivalent to that of the ultrafast high efficiency agglomeration processing apparatus 100 according to the first embodiment to remove total phosphorus from the sewage treatment effluent. .

A chemical flocculant is introduced into the sewage treatment ultra-high-efficiency high-efficiency flocculation apparatus 200 through the chemical flocculant inlet pipe 204 and the treated water inlet pipe 201, and a weighted flocculant is introduced into the weighted coagulant inlet pipe 205. It is injected into the ultrafast high efficiency agglomeration apparatus 200 for sewage treatment.

The combined effluent flowing into the combined high-efficiency high-efficiency flocculation treatment apparatus 300 for treatment of the combined effluent is introduced through the chemical flocculant such as alum and the weighted coagulant inlet tube 305 introduced through the coagulant chemical flocculant inlet tube 304. Pollutants, such as suspended solids, which are mixed and mixed with a weighted flocculant such as a polymer or micro sand, and contained in the combined effluent, are flocculated and precipitated.

The treated water treated in the combined high-efficiency high-efficiency flocculation treatment apparatus 300 for treatment is discharged to the discharge water system through the treated water discharge pipe 302.

The sludge precipitated in the combined high-efficiency high-efficiency flocculation treatment apparatus 300 for treatment of the combined effluent is discharged through the sludge discharge transport pipe 303 and is transferred to a sludge disposal facility or discharged through the sludge discharge transport pipe 303. It is stored in the sludge storage tank 5 through the sludge storage pipe 5a.

The reason for storing the sludge deposited in the ultra-high-efficiency high-efficiency flocculation apparatus 300 for the combined effluent treatment during rainfall in the sludge storage tank 5 is that the sewage treatment effluent of the sewage treatment plant 2 during the dry season is treated with the combined effluent. Compared to the sludge precipitated by the ultra-high-efficiency coagulation treatment in the high-speed high-efficiency coagulation treatment unit 300 for the rainwater can be utilized as a weighted coagulant to the sludge precipitated by the ultra-high-efficiency high-efficiency coagulation treatment for the combined effluent treatment ultra-high efficiency coagulation treatment in the rain 300 This is because it contains a large amount of particulate matter.

As shown in FIG. 3 (dry time) and FIG. 4 (rain time), the sludge precipitated in the ultra-high-efficiency high-efficiency flocculation apparatus 100 and stored in the sludge storage tank 5 during the rainfall shown in FIG. Through the sludge conveying pipe 306 is injected into the ultra-high speed and high efficiency flocculation apparatus 200 for sewage treatment. The sludge injected into the ultra-high-efficiency high-efficiency flocculation apparatus 200 for sewage treatment acts as a weighted coagulant to increase the flocculation and precipitation efficiency.

In addition, when the sludge stored in the sludge storage tank 5 is introduced into the sewage treatment ultra-high-efficiency high-efficiency flocculation apparatus 200 as a weighted coagulant, the amount of the weighted coagulant injected through the weighted coagulant inlet tube 205 is minimized. Not only can be used, but also the amount of chemical flocculant such as alum added through the chemical flocculant inlet pipe 204 can be minimized. Therefore, the use cost of the chemical flocculant and the weighted flocculant can be reduced.

As the amount of the chemical flocculant and the weighted flocculant is minimized, the amount of sludge precipitated in the ultra-high efficiency coagulation treatment apparatus 200 for sewage treatment and the ultra-high efficiency coagulation treatment apparatus 300 for combined effluent treatment is also minimized. Therefore, the cost of sludge disposal can be reduced.

In addition, sludge may be added to the ultra-high-efficiency high-efficiency flocculation apparatus 300 for the combined effluent treatment through the sludge branch conveying pipe 307 connected to the sludge conveying pipe 306 as necessary.

Figure 5 shows a specific first embodiment of the ultra-high-efficiency, high-efficiency flocculation apparatus suitable for the total treatment of the dry water sewage treatment plant effluent in the dry season and the selective treatment system of the combined effluent during rainfall.

This embodiment is commonly applied to the ultra-high-efficiency, high-efficiency flocculation apparatus (100, 200, 300) used for the total phosphorus treatment of the dry sewage treatment plant effluent and the selective treatment system of the combined effluent during the rain according to the first to second embodiments.

The ultra-high speed high efficiency flocculation apparatus (100, 200, 300), the settling tank (11); A sludge collection unit 12 provided below the settling tank 11; It includes a mixing tank 13 installed in the settling tank (11).

The treatment object water inlet pipe (101,201,301) is connected to the lower end of the mixing tank (13).

The sludge discharge transport pipe (103,203,303) is connected to the lower end of the sludge collection unit (12).

It is formed between the one side wall (11a) of the sedimentation tank 11 and one side wall (13a) of the mixing tank 13 and through the inner overflow hole (13c) formed in one side wall (13a) of the mixing tank 13 It further includes a downward flow path 14 connected to the mixing tank (13).

It further includes a plurality of zig-zag-shaped inclined baffle 15 installed in the downward flow path (14).

Inside the mixing tank 13, a stirrer 13d is provided. In the figure, 13e is a motor for driving the stirrer 13d.

It further includes a plurality of precipitation induction inclined plate 16 provided between the other side wall (11b) of the sedimentation tank 11 and the other side wall (13b) of the mixing tank (13).

The settling tank 11 is provided on the outside of the other side wall (11b) of the settling tank 11 and the inside of the settling tank (11) through the outflow overflow hole (11c) formed in the other side wall (11b) of the settling tank (11) It is further provided with an outflow passage 17 connected to the treated water discharge pipe (102, 202, 302).

It may further include an in-line mixer (19) which is installed on the treated water inlet pipe (101,201,301) downstream from the connection of the chemical flocculant input pipe (104,204,304).

One side wall 12a of the mixing tank 13 side of the side walls of the sludge collection part 12 extends from the lower end of the upper vertical part 12a1 and the upper vertical wall 12a1 to face the other side wall 12b. The lower inclined portion 12a2 is inclined downward, and the other side wall 12b is perpendicular from the lower end of the upper inclined portion 12b1 and the upper inclined portion 12b1 inclined downward toward the one side wall 12a. It can be configured as an extended lower vertical portion 12b2.

The sludge discharge transport pipe (103, 203, 303) is connected to the screw type sludge collection hoop 18 is installed at the lower end of the sludge collection unit (12).

The sludge conveying pipes (106, 201, 301) and sludge discharge transport pipes (103, 203, 303) are sludge conveying pipes (106, 206, 306) for injecting sludge collected in the sludge collection unit (12) into the mixing tank (13) as a weighted coagulant. Is connected. The sludge conveying pumps 106p, 206p, and 306p are provided in the middle of the sludge conveying pipes 106,206,306. The sludge storage tank 5 may be provided between the sludge discharge transport pipes 103, 203, 303 and the sludge transport pipes 106, 206, 306.

The sludge storage tank 5 is connected to the sludge discharge transport pipe (103,203,303) by the sludge storage pipe (5a) and the sludge discharge connection pipe (5b).

The in-line mixer 19 is for rapidly stirring the treated water introduced into the treated water inlet pipes 101, 201, 301 and the coagulant introduced through the chemical coagulant inlet pipes 104, 204, 304 as rapid stirring means.

In the present embodiment, the other components are the same as those in the first and second embodiments of the above-described total treatment of the dry season sewage treatment plant effluent and the selective treatment system of the combined effluent during rainfall. Only the operation of the flocculation treatment facility (100, 200, 300) will be described.

The treated water flowing into the mixing tank 13 introduced through the treated water inflow pipes 101, 201, and 301 may include the chemical flocculant introduced through the chemical flocculant input pipes 104, 204, 304 and the weighted coagulant inlet pipe 105, 205, 305. Along with the weighted coagulant flowing through is filled from the bottom of the mixing tank 13, it is stirred by the stirrer (13d) to achieve sufficient mixing.

In this case, when the in-line mixer 19 is provided, the treated water flowing through the treated water inflow pipes 101, 201, 301 is introduced through the chemical flocculant input pipes 104, 204, 304 before the mixed water 13 flows into the mixing tank 13. Rapid mixing with the chemical flocculant is then introduced into the mixing tank 13 and once again mixed to achieve sufficient mixing.

When the water level of the object water flowing into the mixing tank 13 rises to reach the internal overflow hole 13c, the object water is lowered through the downward flow path 14 through the internal overflow hole 13c. Inflow to the lower portion of the sludge collection unit 12.

The number of objects to be passed through the downward flow path 14 is changed in the flow direction repeatedly by a plurality of zigzag inclined baffles 15 provided in the downward flow path 14, in the process The flow is stabilized.

That is, the number of treatment objects introduced into the mixing tank 13 is caused to rotate as the agitator 13d is stirred, and this rotational flow is subject to treatment even in the process of passing through the downward flow passage 14. It will affect the flow of water. The number of treatment objects descending along the downward flow path 14, that is, downwardly flowing, is rotated while the flow direction thereof is controlled in the left downward inclination direction and the right downward inclination direction by the plurality of zigzag inclined baffles 15. The damping and stable downward, i.e., downward flow, maximizes the sedimentation and sludge collecting action in the sludge collecting unit 12 later.

The water to be treated introduced into the sludge collection unit 12 is filled from the lower portion of the sludge collection unit 12.

In this process, contaminants such as suspended solids contained in the water to be treated are aggregated by a flocculant and precipitated by massive flocculation, and the precipitated suspended solids are collected at the bottom of the sludge collecting unit 12. Collected in the hoop 18.

At this time, one side wall 12a of the mixing tank 13 side of both side walls of the sludge collection unit 12 extends from the lower end of the upper vertical part 12a1 and the upper vertical wall 12a1 to provide the other side wall 12b. It consists of a lower inclined portion 12a2 inclined downward toward the other side, the other side wall 12b is perpendicular to the lower end of the upper inclined portion 12b1 and the upper inclined portion 12b1 inclined downward toward the one side wall 12a. It is composed of a lower vertical portion (12b2) extending to the flow through the downward flow path 14, the number of treatment objects flowing down to the sludge collection unit 12 is primarily of the one side wall (12a) It flows down along the vertical portion 12a1 and flows down along the lower inclined portion 12a2 to reach the lower end of the sludge collecting portion 12, where the lower vertical portion 12b2 of the other side wall 12b and The sludge collection because it flows along the path going up the upper inclined portion (12b1) 12 becomes the processing flow of the number of targets in the place as soon as stable as well as increases the efficiency of precipitation.

When the water level of the water to be treated in the sedimentation tank 11 rises above the sedimentation inclination plate 16, a large floating material in the water to be treated is attached to the sedimentation inclination plate 16, and then gradually, the sedimentation induction slope 16 ) And settles to the lower portion of the sludge collection unit 12 to be collected in the screw-type sludge collection hoop 18.

When the water level of the water to be treated in the sedimentation tank 11 rises above the precipitation induction ramp 16, the treated water forming the upper layer of the water to be treated in the sedimentation tank 11 is the other side wall 11b of the sedimentation tank 11. It flows through the outflow overflow hole 11c formed in the outflow to the outflow channel 17. The treated water flowing into the outflow passage 7 is discharged to the discharge water system through the treated water discharge pipes 102, 202, 302.

Other dry and rain selective treatment processes and the storage and recycling of the precipitated sludge are the same as in the above-described embodiment, so the same reference numerals are assigned to the same parts, and detailed description thereof will be omitted.

Figure 6 shows a specific second embodiment of the ultra-high-efficiency high-efficiency coagulation treatment apparatus suitable for the total treatment of the dry water sewage treatment plant effluent in the dry season and the selective treatment system of the combined effluent during rainfall.

This embodiment is commonly applied to the ultra-high-efficiency, high-efficiency flocculation apparatus (100, 200, 300) used for the total phosphorus treatment of the dry sewage treatment plant effluent and the selective treatment system of the combined effluent during the rain according to the first to second embodiments.

In the ultra-high-speed, high-efficiency coagulation processing apparatus according to the present embodiment, one side wall of the mixing tank 13 side of both side walls of the sludge collection unit 12 is formed at the lower end of the upper vertical portion 12a1 and the upper vertical wall 12a1. The lower inclined portion 12a2 is extended and inclined downward toward the other side wall 12b, and the other side wall 12b is inclined downward toward the one side wall 12a and the upper inclined portion 12b1 and the upper side inclined. The lower inclination portion 2b3 is formed at the lower end of the portion 12b1 and the upper end thereof is closer to the one side wall 12a side than the lower end thereof.

In the present embodiment, since the lower inclined portion 2b3 of the other side wall 12b is formed closer to the one side wall 12a than the lower end thereof, the lower inclined portion 2b3 flows downward through the downward flow path 14 so that the sludge The water to be treated and the flocculant which flows down to the collecting part 12 and flows down along the vertical wall 12a1 and the lower inclined part 12a2 of the one side wall 12a to the lower end of the sludge collecting part 12. In the course of the mixed liquid of the inclined portion 12b3 and the upper inclined portion 12b1, the path that goes up along the lower inclined portion 12b3 retreats to the one side wall 12a side to form a path that goes up. In the sludge collection unit 12, the flow of the mixed liquid of the water to be treated and the flocculant is made to be stable, and the precipitation efficiency is further increased.

In particular, since the lower inclined portion 12c of the other side wall 12b is formed closer to the one side wall 12a than the lower end thereof, the lower inclined portion 12c flows downward through the downward flow path 14 to collect the sludge. The mixed liquid of the water to be treated and the flocculant which flowed to the lower end of the sludge collection part 12 by flowing down to 12 and falling first along the vertical wall 12a and the lower inclined part 12b of the one side wall 12a. In the process of ascending the lower inclined portion 12c and the upper inclined portion 12a, a path that goes up along the lower inclined portion 12c retreats toward the one side wall 11 to form a path to be raised. The flow of the mixed liquid of the water to be treated and the flocculant in the precipitation section 12 is made stable, and the precipitation efficiency is further increased.

When the ultra-high-speed, high-efficiency coagulation treatment apparatus according to the present embodiment is applied to the above-mentioned total phosphorus treatment of the dry sewage treatment plant effluent and the selective treatment system of the combined effluent during rainfall, the total phosphorus treatment of the sewage treatment plant effluent during the dry season and the combined effluent during the rainfall The selective treatment is the same as the first and second embodiments of the above-described treatment of the total treatment of the dry season sewage treatment plant effluent and the combined treatment of rainwater combined effluent. Therefore, description thereof will be omitted.

Figure 7 shows a specific third embodiment of the ultra-high-efficiency high-efficiency flocculation apparatus suitable for the total treatment of the dry water sewage treatment plant effluent in the dry season and the selective treatment system of combined effluent during rainfall.

The ultra-high-speed, high-efficiency flocculation apparatus (100, 200, 300), the ultra-high-efficiency, high-efficiency flocculation apparatus (100, 200, 300) used for the total treatment of the dry sewage treatment plant discharge water according to the first to second embodiments and the selective treatment system of the combined effluent during rainfall. Commonly applied.

The ultra-high speed and high efficiency flocculation apparatus according to the present embodiment,

A settling tank 21 and a sludge collection unit 22 provided below the settling tank 21; And a mixing tank 23 provided upstream of the settling tank 21.

The treatment object water inlet pipe (101,201,301) is connected to the upper portion of the mixing tank (23). An agitator 23a is provided inside the mixing tank 23.

A downstream flow path 24 provided at an upstream side of the mixing tank 23 to allow the treatment object water flowing from the treatment object water inflow pipes 101, 201, and 301 to flow downward into the upstream side of the mixing tank 23; A downward flow path 25 provided between a downstream side of the mixing tank 23 and an upstream side of the settling tank 21 to allow the treated water mixed in the mixing tank 23 to flow downward into the settling tank 21. It includes more.

The downward flow path 24 is formed by a partition wall 24a spaced apart from the upstream wall of the mixing tank 23 to the downstream side, and the downward flow path 25 is provided downstream of the mixing tank 23. It is formed by the overflow wall 25a and the partition 25b.

At the position spaced upstream from the downstream wall of the sedimentation tank 21, the overflow wall (21a) for allowing the treated water precipitated in the sedimentation tank 21 to be discharged to the treated water discharge pipe (102, 202, 302).

The sludge discharge transport pipe (103,203,303) is connected to the lower end of the sludge collection unit (22).

The sludge discharge transport pipe (103,203,303) is connected to the lower end of the sludge collection unit (22).

The sludge discharge transport pipes (103,203,303) are connected to the sludge conveying pipes (106,206,306) for introducing the sludge collected in the sludge collection unit (22) into the mixing tank (23) as a weighted coagulant. The sludge conveying pumps 106p, 206p, and 306p are provided in the middle of the sludge conveying pipes 106,206,306.

The sludge conveying pipe (106, 206, 306) may return the sludge collected in the sludge collection unit 22 to the mixing tank 23 as it is to utilize the sludge as a weighted coagulant, but as described above the sludge discharge transport pipe The sludge storage tank (5) for storing the sludge discharged and discharged from (103,203,303) is stored in the sludge storage tank (5) when the sludge collected in the sludge collection unit (23) and the mixing tank (23) when necessary Can be returned.

The sludge storage tank 5 is the sludge storage pipe 5a and the sludge as shown in Figs. 1 to 4 showing the first and second embodiments of the total treatment of the effluent from the dry sewage treatment plant during the dry season and the selective treatment system of the combined effluent during the rainfall. It can be connected to the discharge connector (5b).

In addition, the ultra-high-speed, high-efficiency coagulation treatment apparatus according to the present embodiment further includes a weighted coagulant input means 27 for injecting the weighted coagulant into the mixing tank (23).

The weighted coagulant input means 27 includes a weighted coagulant supply source 27a and a weighted coagulant input pipe 27b for introducing the weighted coagulant stored in the weighted coagulant supply source 27a into the mixing tank 23. The weighted coagulant source 27a may be configured in the form of a box or hopper for storing the weighted coagulant.

The weighted coagulant introduced into the mixing tank 23 from the weighted coagulant input means 27 is precipitated together with the sludge in the settling tank 21. The sludge weighted to separate, recover and reuse the precipitated weighted coagulant from the sludge. A flocculant separating means 28 is further included.

The sludge-weighted coagulant separating means 28 is connected to the end of the sludge conveying pipe (106, 206, 306) is installed, the hydro cyclone (28a) for separating the sludge and the weighted coagulant, and is connected to the lower end of the hydro cyclone (28a) A weighted coagulant re-entry pipe 28b for introducing the separated weighted coagulant to the mixing tank 23 and a sludge separated and connected to an upper end of the hydrocyclone 28 to a sludge treatment facility (not shown). A sludge conveying pipe 28c for conveying.

The weighted coagulant re-injection pipe 28b may be independently installed on the mixing tank 23, but may be connected to and installed in the weighted coagulant inlet pipe 27b of the weighted coagulant injecting means 27 as shown in the example. .

In the ultra-high-speed, high-efficiency flocculation apparatus according to the present embodiment, the chemicals introduced through the target water inflow pipe (101,201,301) and the chemical flocculant input pipe (104,204,304) in the middle of the treated water inflow pipe (101,201,301) It may further include an in-line mixer 29 as a high speed mixing means for admixing the flocculant at high speed.

Hereinafter, a coagulation process by the ultra-high speed and high efficiency coagulation processing apparatus according to the present embodiment will be described.

The treated water flowing into the mixing tank 23 through the treated water inflow pipes 101, 201, and 301 is weighted through the chemical flocculant introduced through the chemical flocculant inlet pipes 104, 204, 304 and the weighted coagulant inlet pipe 27b. The flocculant is mixed with the flocculant to form a large floc, and the treated object water in which the large floc is formed is precipitated in the settling tank 21 and the sludge is collected in the sludge collection unit 22.

In the mixing tank 23, the chemical flocculant introduced through the chemical flocculant inlet pipes 104, 204, 304 connected to the treatment object water inflow pipes 101, 201, and 301 is introduced into the mixing tank 23, so that the flocculation occurs by the action of the chemical flocculant. As a result, a large floc is formed.

When FeCl ₃ is used as the chemical flocculant, phosphorus (PO 4 ^3- ) in the water to be treated is insoluble phosphate (FePO ₄ ) to obtain a phosphorus (P) removal effect.

On the other hand, the weighted coagulant introduced into the mixing tank 23 from the weighted coagulant input means 27 increases the specific gravity of the large floc so that the precipitation in the settling tank 21 is made more quickly.

In this case, when the in-line mixer 29 is installed in the treated water inflow pipes 101, 201 and 301, the treated water and the chemical flocculant are mixed at high speed by the in-line mixer 29, thereby maximizing the mixing efficiency. The mixing and flocculation efficiency in the tank 23 is maximized.

The water to be treated mixed with the chemical flocculant and introduced into the mixing tank 23 flows downward through the downward flow path 24 formed by the partition wall 24a upstream of the mixing tank 23. No current is generated and sufficient mixing is achieved to form a large floe.

The treated water mixed and agglomerated in the mixing tank 23 to form a large floc is a downward flow path formed by the overflow wall 25a and the partition 25b between the mixing tank 23 and the settling tank 21. Since it flows downward into the settling tank 21 along 24, the large floc formed in the mixing tank 23 is not broken, and the settling efficiency in the settling tank 21 is maximized.

The treated water precipitated in the settling tank 23 flows through the overflow wall 21a and is discharged through the treated water discharge pipes 102, 202, 302.

On the other hand, the sludge collected in the sludge collection unit 22 is put into the mixing tank 23 through the sludge conveying pipe (106,206,306) to act as a weighted coagulant, or by the sludge-weighted coagulant separating means (28) The weighted coagulant may be separated into sludge and the weighted coagulant and may be introduced into the mixing tank 23 through the weighted coagulant re-entry pipe 28b.

As such, when the sludge collected in the sludge collection unit 22 is recycled as a weighted coagulant, the amount of the weighted coagulant and the amount of sludge generated can be reduced, thereby reducing the weighted coagulant cost and the sludge disposal cost.

When the ultra-high-speed, high-efficiency coagulation treatment apparatus according to the present embodiment is applied to the above-mentioned total phosphorus treatment of the dry sewage treatment plant effluent and the selective treatment system of the combined effluent during rainfall, the total phosphorus treatment of the sewage treatment plant effluent during the dry season and the combined effluent during the rainfall The selective treatment is the same as the first and second embodiments of the above-described treatment of the total treatment of the dry season sewage treatment plant effluent and the combined treatment of rainwater combined effluent. Therefore, description thereof will be omitted.

8 shows a fourth specific embodiment of the ultra-high-efficiency high-efficiency flocculation apparatus suitable for the total phosphorus treatment of the dry sewage treatment plant effluent and the selective treatment system of the combined effluent during rainfall according to the present invention.

This embodiment is provided with the primary settling basin 30 on the upstream side of the water inlet pipes 101, 201, 301 of the third preferred embodiment of the ultra-high-speed, high-efficiency flocculation apparatus described above.

In addition, the lower end of the primary sedimentation basin 30 may further include a sludge conveying pipe 31 for conveying the sludge settled in the primary sedimentation basin 30.

The sludge conveying pipe 31 may be configured to inject the sludge conveyed into the mixing tank 23 as it is, as shown in the hydrocyclone (28a) of the sludge-weighted coagulant separating means 28 By separating the sludge and the weighted coagulant may be such that only the weighted coagulant is added to the mixing tank (23).

Since other configurations are the same as those of the third embodiment of the ultra-high-speed, high-efficiency coagulation processing apparatus described above, the same parts will be denoted by the same reference numerals and detailed description thereof will be omitted.

The present invention has been described above with reference to the illustrated drawings as a preferred embodiment, but the present invention is not limited by the embodiments and drawings presented in the present specification, and those skilled in the art within the scope of the technical features of the present invention. Of course, various modifications may be made.

1: Excellent soil room 2: Sewage treatment plant
3: combined effluent storage tank 4: filtration-type pollutant removal facility
5: sludge storage tank 11, 21: sedimentation tank
12, 22: sludge collection unit 13, 23: mixing tank
100, 200, 300: Ultra-high efficiency coagulation processing device
101, 201, 301: treatment object inflow pipe
102, 202, 302: treated water discharge pipe 103, 203, 303: sludge discharge transport pipe
104, 204, 304: chemical flocculant input tube
105, 205, 305: weighted coagulant input pipe
106, 206, 306: sludge conveying pipe

Claims (23)

delete delete delete delete delete delete delete delete delete delete delete delete delete delete Rainwater soil chamber 1 having 1Q collecting pipe 1a, 2Q collecting pipe 1b, and 3Q collecting pipe 1c;
A sewage treatment plant 2 connected to the 1Q collecting pipe 1a and having a sewage treatment discharge water discharge pipe 2a;
A confluent effluent storage tank 3 connected to the 2Q collecting pipe 1b and having a confluent effluent transport pipe 3a;
It is provided with the treatment object water inflow pipe (101) connected in parallel to the sewage treatment effluent discharge pipe (2a) of the sewage treatment plant (2) and the combined effluent transport pipe (3a) of the combined effluent storage tank (3), The sewage treatment effluent discharged from the sewage treatment effluent discharge pipe (2a) of the sewage treatment plant (2) is introduced to the inflow through the treated water inlet pipe (101) to remove the total phosphorus from the sewage treatment effluent introduced, and during rainfall There is a combined ultra-high-speed high-efficiency coagulation for the superfluous flocculation of the confluent effluent flows by allowing the confluent effluent flowing from the confluent effluent transport pipe (3a) of the confluent effluent storage tank (3) to flow through the treated water inlet pipe (101) A processing apparatus 100;
Sludge storage pipe (5a) to the sludge discharge transport pipe 103 of the hybrid ultra-high-speed high-efficiency coagulation processing apparatus 100, and the treatment object water inlet pipe (101) of the hybrid ultra-high-speed high-efficiency coagulation processing apparatus (100) Sludge generated in the process of the super fast flocculation treatment of the combined effluent in the complex ultra-high-efficiency coagulation treatment device 100 is stored in the rainfall during rain, and the sludge stored in the dry season is stored in the sludge Dry gas municipal sewage treatment plant effluent water comprising a; sludge storage tank (5) to be introduced as a weighted flocculant to the complex ultra-high-efficiency high-efficiency flocculation apparatus 100 through the conveying pipe 106 and the treatment object water inflow pipe 101 Treatment system for combined effluent during total rainfall and rainfall.
The method of claim 15,
Selective treatment of the total phosphorus treatment of the effluent from the dry season sewage treatment plant and the combined effluent during the rain, characterized in that it further comprises a chemical flocculant inlet tube 104 is connected to the treated water inlet pipe 101 for injecting a chemical flocculant system.
The method of claim 15,
Dryer is characterized in that it further comprises a weighted coagulant inlet tube 105 which is provided on the complex ultra-high speed high-efficiency coagulation processing apparatus 100 to inject a weighted coagulant to the complex ultra-high speed high efficiency coagulation processing apparatus 100 Total treatment of effluent from the municipal sewage treatment plant and selective treatment system of combined effluent during rainfall.
The method of claim 15,
The total water treatment of the dry season sewage treatment plant effluent and selective treatment of the confluent effluent during the dry season, characterized in that it further comprises a sludge conveying pipe 106 connecting the treated water inlet pipe 101 and the sludge storage tank (5). system.
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