KR100992829B1 - System phosphorus treatment - Google Patents

Abstract

PURPOSE: A high efficiency phosphorus processing system is provided to maximize the phosphorus removing efficient and satisfying the water quality standard stability by high processing efficiency of BOD, COD, SS. CONSTITUTION: A high efficiency phosphorus processing system includes a effluent inflow pump(110), a phosphorus concentration detecting sensor(120), a jet mixer(130), a phosphorus processing agent introduction means(140), a control controller(150), and a jet filter(160). The phosphorus concentration detecting sensor detects the phosphoric concentration contained in the effluent inflow water. The jet mixers constitutes the annular flow when being at high speed inserting the inflow water. By inserting the inflow water to the center part of the inflow water which is inserted in high sped inside the jet mixer, the phosphorus processing agent introduction means inserts the phosphorus processing agent which forms floc through absorb reaction with phosphorus component including in the inflow water inside the jet mixer when the inflow water with the annular water. The control controllerr controls the phosphorus processing agent introduction means by determining the insertion amount of phosphorus processing agent according to the phosphorus concentration of the inflow water through the detection value detected by the concentration detecting sensor. The jet filter discharges the filtered final discharge water after filtering the floc by phosphorus reaction including in the phosphorus processing agent and inflow water as flowing in the reaction water comprising reaction by being mixed by a jet mixer.

Description

High Efficiency Phosphorus Treatment System

The present invention relates to a high-efficiency phosphorus treatment system, and more particularly, to the inflow of sewage treated effluents, in which a phosphorus treatment agent and a phosphorus treatment agent are introduced into the influent according to the concentration of phosphorus in the influent. The present invention relates to a high-efficiency phosphorus treatment system capable of improving phosphorus removal efficiency through the configuration of a jet mixer for forming flocs and a jet filter for filtering reaction water reacted by the jet mixer.

In general, industrial wastewater contains a large amount of high concentrations of organic matter such as chemical oxygen demand (COD), biochemical oxygen demand (BOD), solid suspended solids (TSS), nitrogen, and phosphorus. As it flows into rivers and rivers, it causes pollution of water resources such as eutrophication and destruction of ecosystems due to toxicity, which adversely affects the environment. Therefore, industrial wastewater is set to a certain standard, and is purified to drain below a predetermined standard value.

For the reasons described above, the pollution state of public waters such as appeals, inner bays and inland seas, and small and medium urban streams is very prominent. Therefore, the achievement rate of total nitrogen (TN), total phosphorus (TP), COD and BOD which are environmental standards related to appeal, internal bay and inland sea is very low. In addition, rivers, lakes and dams are often sources of drinking water, so mold odors, filter disturbances and abnormal growth of toxic algae have become a major environmental problem.

On the other hand, in relation to eutrophication, Korea also strongly regulates the emission of total nitrogen (TN) and total phosphorus (TP) from wastewater. At this time, if any one of the prior to the management of nitrogen and phosphorus related to eutrophication should be selected to manage rather than nitrogen. This is because most of the major stream-type appeals in our country use phosphorus as a limiting factor because the ratio of TN / TP exceeds the theoretical ratio of 16.

In addition, phosphorus is introduced into the body of water from the outside and accumulates in the appeal, but there is a problem that the nitrogen can be introduced from the atmosphere is more difficult to remove. In other words, if the phosphorus can be completely removed from most of the major river-type appeals in our country, it is estimated that the green algae of the appeal can be prevented. Therefore, due to the tendency of strengthening regulations on environmental protection and the peculiarity of our country's appeal, there is a need for a treatment apparatus capable of efficiently removing phosphate ions present in sewage and wastewater.

On the other hand, as a method of removing phosphorus in water, biological treatment and agglomeration-precipitation treatment are widely used. Among these phosphorus removal methods, biological treatment is a method of treating sewage or sewage using microorganisms having phosphorus removal ability or photosynthetic bacteria having excellent removal ability against nitrogen and phosphorus, and these biological methods include A ₂ / O (Anaerobic, Anoxic , Oxic), 5-Stage Bardenpo, University of Cape Town (UCT), and Vericia Initiative Plant (VIP).

In addition, the coagulation-precipitation treatment method removes phosphorus by converting phosphate ions contained in the wastewater into almost insoluble phosphates using chemical substances containing metal ions, such as iron salt-based inorganic coagulants or aluminum-based inorganic coagulants. In this way, there is an advantage that the phosphorus can be removed to a low concentration when the phosphorus is treated through such a coagulation-precipitation treatment method.

However, among the phosphorus treatment methods for removing phosphorus from sewage or sewage as described above, the biological treatment method has a problem in that phosphorus is not effectively removed from the water quality after treatment of phosphorus and of course, the change in treatment efficiency is severe. In the case of the treatment method, a large amount of chemicals are required to achieve a stable treatment efficiency, such as an increase in operating costs.

In addition, both the biological treatment method and the treatment method by flocculation-precipitation as described above require a large installation area for the installation of the device for phosphorus removal, and a large amount of sludge may be generated to cause additional problems. It is pointed out. In addition, there is a problem that the recovery of the filter medium is not only weak when the backwashing of the filter, but also residual chemicals present in the treated water.

On the other hand, phosphorus treatment methods using titanium oxide, zirconium oxide, tin oxide, etc., which are ion anion exchangers having ion exchange characteristics and ion adsorption capacity in acidic solutions, or zeolites have been proposed in recent years. It is pointed out that a substantial cost is generated for regenerating titanium oxide, zirconium oxide, and tin oxide, which are used components, as well as a large cost in need of an additional reactor or treatment of precipitated precipitate.

The present invention has been made in order to solve the above-mentioned problems of the prior art, the high-efficiency phosphorus treatment agent is introduced into the influent flowed into the effluent discharged by being treated through the sewage treatment device and mixed through the jet mixer and the jet filter It is an object of the present invention to provide a high efficiency phosphorus treatment system capable of maximizing phosphorus removal efficiency through a phosphorus treatment system having a filtering structure.

Another object of the technology according to the present invention is to introduce the effluent discharged through the sewage treatment device to introduce a high efficiency phosphorus treatment agent into the influent, while mixing and filtering through a jet mixer and a jet filter. Phosphorus removal, as well as the high treatment efficiency of BOD, COD, SS to achieve a stable water quality standards.

Still another object of the technology according to the present invention is to introduce a effluent treated through a sewage treatment device, and to construct a phosphorous treatment system for mixing and filtering a jet mixer and a jet filter while injecting a high efficiency phosphorous agent into the influent. Not only to facilitate the maintenance of the system but also to reduce the maintenance cost of the system.

In addition, the technology according to the present invention by installing a effluent treatment system for mixing and filtering through a jet mixer and a jet filter while injecting the effluent discharged through the sewage treatment system into the discharged effluent. The aim is to minimize the need for and to improve the reaction rate.

In addition, the technology according to the present invention is to enter the effluent discharged through the sewage treatment device to input the high efficiency phosphorus treatment agent to the influent, while constructing the phosphorus treatment system to mix and filter through the jet mixer and jet filter The goal is to minimize the drug.

The present invention configured to achieve the above object is as follows. That is, the high-efficiency phosphorus treatment system according to the present invention is a phosphorus treatment system for removing phosphorus contained in the influent water by introducing the discharged water discharged by sewage treatment through the wastewater treatment apparatus. A effluent inflow pump for introducing effluent discharged by sewage treatment through driving by application of power; A phosphorus concentration sensor for detecting a concentration of phosphorus in the effluent flowing into the effluent inflow pump; A jet mixer which allows an annular flow to be formed while injecting the inflow water introduced by the discharge water inflow pump at a high speed; Phosphorus (Floc) is formed through adsorption reaction with phosphorus contained in the inflow water inside the jet mixer while being mixed at the high speed into the center of the inflow water injected in the jet mixer at high speed to mix with the inflow water by the annular flow. Phosphorus treatment means for injecting treatment agent; A control controller for controlling the phosphorus input means by determining an input amount of the phosphorus treatment agent according to the phosphorus concentration of the phosphorus component contained in the inflow water through the detection value detected by the phosphorus concentration detection sensor; And a jet filter in which a reaction mixture mixed with a jet mixer is introduced to filter the floc due to the reaction of the phosphorus treatment agent and the phosphorus contained in the influent, and then discharge the filtered final discharged water.

In the configuration according to the present invention as described above, the jet mixer is a reaction tank in which the reaction of the phosphorus component and the phosphorus agent contained in the inflow water introduced into the inside is made, the discharge pipe for discharging the reaction water made reaction on one side; An inflow water injection nozzle installed in the reactor to allow the inflow water introduced by the effluent inflow pump to be injected into the reactor at a high speed; A phosphorus treatment tube installed at a central portion of the inflow water injection nozzle in a longitudinal direction so that the phosphorus agent injected through the phosphorus agent injection means is introduced at a high speed into the center of the injection water injected at a high speed by the influent water injection nozzle; And an inflow water injection nozzle and a phosphorus injection tube are positioned at a center of the upper end of the tubular shape which is vertically penetrated from the inner circumferential surface of the reaction tank so as to be positioned at a high speed by the inflow water injection nozzle. It may be made of a configuration of the annular flow guide tube to form an annular flow rising upward through the lower outer wall in the middle injected downward through.

In addition to the above-described configuration of the present invention, an injection water injected and injected at a high speed from the inflow water injection nozzle and the processing agent injection tube is formed in a conical shape at a predetermined distance from the lower center of the processing agent inlet tube of the inner center of the annular flow induction tube. Diffusion means may be further configured to diffuse the phosphorus treatment agent to be uniformly mixed.

Diffusion means constituting the present invention includes a support plate supported inside the annular flow guide tube; A rotating shaft configured at the center of the support plate; A diffusion member rotatably supported on a rotating shaft to form a cone and diffuse and mix the infusion water and the phosphorus agent injected and injected at a high speed from the inflow water injection nozzle and the phosphorus injection tube through a conical surface; And a spiral groove formed on the outer surface of the cone of the diffusion member at a predetermined interval so that the diffusion member can be rotated by the injection water and the phosphorus agent injected and injected at high speed from the inflow water injection nozzle and the phosphorus treatment tube on the cone surface. Is done.

In addition, the inner circumferential surface of the annular flow guide tube may be configured to protrude in a ring shape to further induce partial vortices around the vortex forming member to accelerate the mixing of the injection water and the phosphorous treatment agent.

On the other hand, in the configuration of the present invention as described above, the treatment agent input means is a treatment agent tank in which the storage of the treatment agent is made; And it is driven by the control of the control controller can be made of a configuration of a phosphate treatment pump for the injection is made at a high speed by the input amount of the phosphate treatment agent according to the phosphorus concentration of the influent.

In the composition according to the present invention, the phosphorus treatment agent is polyaluminum chloride (PAC), polyaluminum chloride (PACS), polyaluminum chloride hydrochloride (PACSS), and polyaluminum chloride. Polyaluminum Hydroxy Chloro Sulfate (PAHCS), Poly Sulfate Silicate (PASS), Aluminum Sulfate (AS), Ferric Aluminum (FA), Aluminum Chloride (Aluminum Chloride) : AC), at least one inorganic agglomerate selected from the group consisting of Aluminum Ferric Sulfate (AFS) and Aluminum Ferric Chloride (AFC), or an inorganic coagulant containing a polyamine-based compound in these inorganic coagulants. At least one inorganic coagulant and zirconium oxychloride (ZrOCl ₂ ) may be selected from 80 to 99: The composition is mixed at a ratio of 1 to 20% by weight. At this time, zirconium oxychloride (ZrOCl ₂ ) may be composed of a hydrate form ZrOCl ₂ · 8H ₂ O.

The jet filter constituting the present invention is mixed with a jet mixer, the reaction water grown into floc by the adsorption reaction of the phosphorus component and the phosphorus agent contained in the injection water is made, but the inflow of the reaction water on the upper side A reaction tank having a reaction water inlet and a lower one formed with a filtered water outlet through which filtered water is discharged; A support plate having a plurality of outlets installed at a predetermined height from an inner lower portion of the filtration tank to allow the filtered treated water to flow out to the lower portion; A filtration layer loaded on the upper surface of the support plate as a predetermined thickness layer to filter flocs and foreign substances contained in the reaction water introduced into the filtration tank; And back washing means for washing the fine particles and contaminants accumulated in the filtration layer.

In the configuration of the jet filter as described above, the reaction water inlet for introducing the reaction water into the interior of the filtration tank is configured to be inclined to form a vortex while allowing the reaction water to be inclined to the inner circumferential surface of the filtration tank. Can be.

In addition, in the configuration of the jet filter, the filtration layer may be formed of a plurality of layers on the upper surface of the support plate, but may have a structure in which sand or activated carbon having a smaller diameter is stacked from the lowermost layer to the upper layer.

On the other hand, the back washing means in the configuration of the jet filter is installed on the upper side of the filtration tank is driven by the application of the power reduction motor; A rotating shaft extending from the driving shaft of the reduction motor to an inner center of the filtration tank and being rotated by a predetermined length; An impeller installed at a lower end of the rotating shaft to stir sand or activated carbon of the filtration layer through rotation to float fine particles or contaminants accumulated in the filtration layer; A backwash water supply pipe detachably connected to a lower portion of the filtered water outlet formed at the lower side of the filtration tank to supply the backwash water; A backwashing supply pump installed at one side of the backwashing water supply pipe to supply backwashing water at a constant pressure through a drive; And a backwash water outlet formed at an upper side of the filtration tank to discharge backwash water containing fine particles or contaminants.

In addition, the above-mentioned backwashing means further includes a lifting cylinder which lowers the reduction motor and the rotating shaft to position the impeller inside the filtration layer or raises the reduction motor and the rotating shaft so that the impeller can be positioned outside the upper part of the filtration layer. Can be.

According to the high-efficiency phosphorus treatment system of the present invention, through the sewage treatment apparatus, a high-efficiency phosphorus treatment agent is introduced into the influent by introducing the discharged water discharged through the sewage treatment device, and the mixture is filtered through a jet mixer and a jet filter. Phosphorus removal efficiency can be maximized.

Another effect of the technique according to the present invention is a phosphorous treatment system having a structure in which a high efficiency phosphorus treatment agent is introduced into the influent by introducing effluent discharged through the sewage treatment device and mixed filtration through a jet mixer and a jet filter. Through this, it is possible to stably meet water quality standards by achieving high treatment efficiency of BOD, COD, and SS as well as phosphorus removal.

Another effect of the technology according to the present invention is to introduce a effluent treated by the sewage treatment device to configure the phosphate treatment system to mix and filter through a jet mixer and a jet filter while introducing a high efficiency phosphate treatment agent into the influent effluent By doing so, the system can be easily maintained, and the maintenance cost of the system can be reduced.

In addition, the technology according to the present invention by installing a effluent treatment system for mixing and filtering through a jet mixer and a jet filter while injecting the effluent discharged through the sewage treatment system into the discharged effluent. Can minimize the reaction time and improve the reaction rate.

In addition, the technology according to the present invention is to enter the effluent discharged through the sewage treatment device to input the high efficiency phosphorus treatment agent to the influent, while constructing the phosphorus treatment system to mix and filter through the jet mixer and jet filter Drugs can be minimized.

1 is a block diagram showing a high efficiency phosphorus treatment system according to the present invention.
Figure 2 is a perspective view showing a jet mixer constituting a high efficiency phosphorus treatment system according to the present invention.
Figure 3 is a cross-sectional view showing the action of the jet mixer constituting the high efficiency phosphorus treatment system according to the present invention.
Figure 4 is a cross-sectional view showing a jet filter constituting a high efficiency phosphorus treatment system according to the present invention.
Figure 5 is a cross-sectional view showing in detail the impeller of the jet filter constituting the high efficiency phosphorus treatment system according to the present invention.

Hereinafter, a high efficiency phosphorus treatment system according to a preferred embodiment of the present invention will be described in detail.

1 is a block diagram showing a high efficiency phosphorus treatment system according to the present invention, Figure 2 is a perspective view showing a jet mixer constituting a high efficiency phosphorus treatment system according to the present invention, Figure 3 is a high efficiency phosphorus treatment system according to the present invention 4 is a cross-sectional view showing a jet mixer constituting the high efficiency phosphorus treatment system according to the present invention, Figure 5 is a cross-sectional view showing a jet filter constituting the high efficiency phosphorus treatment system according to the present invention, FIG. It is a cross-sectional block diagram which shows the impeller in detail.

1 to 5, the high efficiency phosphorus treatment system 100 according to the present invention is introduced into the effluent inflow pump 110, the effluent inflow pump 110 to introduce the effluent through the drive by the application of power. Phosphorus concentration detection sensor 120 for detecting the concentration of phosphorus contained in the effluent water, jet mixer 130 to form an annular flow to inject the inflow water introduced by the effluent inflow pump 110 at high speed, jet mixer ( The floc (Floc) is introduced through the adsorption reaction with the phosphorus component contained in the inflow water inside the jet mixer 130 while being mixed at high speed in the center of the inflow water injected at a high speed into the inside of the inflow water. Phosphorus treatment means according to the phosphorus concentration of the phosphorus component contained in the inflow water through the detection value detected by the phosphorus treatment agent input means 140, the phosphorus concentration detection sensor 120 to inject the phosphorus agent to be formed Flock mixed by the control controller 150 and the jet mixer 130 controlling the phosphorus treatment agent input means 140 to inject the reacted water reacted with the phosphorus contained in the influent water Floc) is filtered and then composed of a jet filter 160 for discharging the filtered final discharged water.

The high-efficiency phosphorus treatment system 100 according to the present invention configured as described above has a constant pressure into the inside of the jet mixer 130 through the effluent water inflow pump 110 through the effluent water discharged by sewage treatment through a wastewater treatment device. The amount of phosphorus treatment agent is determined according to the phosphorus concentration of phosphorus component contained in the influent water through the detection value detected by the phosphorus concentration detection sensor 120, and the phosphorus treatment agent is introduced into the jet mixer 130.

On the other hand, as described above, if the inflow of inflow water and the injection of the phosphorus treatment agent into the inside of the jet mixer 130, the phosphorus component and the phosphorus treatment agent contained in the inflow water through the adsorption reaction inside the jet mixer 130 (Floc) Will grow. As such, the reaction water in which floc is formed through the adsorption reaction of the phosphorus component and the phosphorous agent contained in the inflow water is introduced into the jet filter 160, filtered through the jet filter 160, and finally discharged into the discharge water system. It is done.

Referring to the high efficiency phosphorus treatment system 100 according to the present invention in more detail as follows. First, the effluent inflow pump 110 is to inject the effluent discharged by being processed through the sewage treatment device at a predetermined pressure, and the effluent inflow pump 110 is disposed through the wastewater treatment device as shown in FIG. 1. The discharged water discharged by sewage treatment is introduced through a drive by application of power.

As described above, the effluent inflow pump 110 which introduces effluent water discharged by sewage treatment through a wastewater treatment device through driving by application of power is controlled by a control controller 150 to be described later. As such, the discharge water inflow pump 110 driven by the control of the control controller 150 allows the discharge water to flow into the jet mixer 130 at a predetermined pressure.

Phosphorus concentration detection sensor 120 constituting the present invention is to detect the concentration of the phosphorus component contained in the influent water flowing through the effluent inflow pump 110, this phosphorus concentration detection sensor 120 is shown in FIG. As described above, it is installed on one side of the effluent inflow line 112 for introducing the effluent discharged by the sewage treatment through the effluent inflow pump 110 to detect the phosphorus concentration contained in the influent.

As described above, detecting the phosphorus concentration of the inflow water introduced by the effluent inflow pump 110 through the phosphorus concentration detection sensor 120 detects the phosphorus concentration contained in the inflow water and thereby internalizes the jet mixer 130. This is to determine the amount of phosphorus agent to be added. At this time, the detection value detected by the phosphorus concentration detection sensor 120 is transmitted to the control controller 150 to be described later.

Jet mixer 130 constituting the present invention is a floc (Floc through the adsorption reaction of the phosphorus component in the influent and the phosphorus treatment agent by mixing the inflow water and the phosphorus treatment agent into the effluent inflow pump 110 and the phosphorus treatment agent means 140 to be described later) In order to form a), such a jet mixer 130 is a circular flow is formed in the middle of the inlet water introduced by the discharge water inlet pump 110 as shown in Figures 1 to 3 at high speed to be formed It is configured to uniformly mix the influent with the phosphorus treatment agent.

Looking at the configuration of the jet mixer 130 is configured so that the mixing of the influent and the in-process treatment agent is made to be uniform by forming an annular flow in the inlet is injected at a high speed as described above contained in the influent introduced into the interior The reaction of the phosphorus component and the phosphorus treatment agent is made, but one side of the inflow water introduced by the discharge water inflow pump 110 is installed in the reaction tank 131 and the reaction tank 131 in which the discharge pipe 131a for discharging the reaction water is reacted. Is installed in the longitudinal center of the inflow water injection nozzle 132, the inflow water injection nozzle 132 to be injected into the reaction tank 131 at a high speed into the inflow water injection nozzle 132 and the inner peripheral surface of the treatment agent injection tube 133 and the reaction tank 131 to be introduced at a high speed to the center of the injection water injected at high speed It is installed on the center so as to be spaced apart at regular intervals, the inlet water injection nozzle 132 and the treatment agent injection tube 133 is positioned in the upper center of the upper and lower tube shape is injected at high speed by the inlet water injection nozzle 132 The injection water is injected downward through the interior of the annular flow induction pipe 134 to form an upward flow through the lower outer wall is formed.

Referring to the operation of the jet mixer 130 configured as described above, first, the effluent supplied by a constant pressure by the discharge water inlet pump 110 described above is the upper center of the reaction tank 131 through the inlet water injection nozzle 132 It is injected at high speed in the form of spraying from the inside. At this time, the phosphorus treatment agent is injected at high speed through the phosphorus treatment tube 133 formed at the center of the inflow water injection nozzle 132 and is sprayed onto the inflow water injected by the inflow water injection nozzle 132 at high speed.

Meanwhile, as described above, the phosphorous agent is injected at high speed through the phosphorous agent inlet tube 133 formed at the center of the influent water injection nozzle 132 and is sprayed on the inlet water injected by the influent water injection nozzle 132 at high speed. The influent is guided downward through the inside of the annular flow guide pipe 134, and then is led upward through the bottom outside of the annular flow guide pipe 134 to form an annular flow.

As described above, the high-speed injection of the inflow water injection nozzle 132 and the high-speed injection of the inflow water by the annular flow induction pipe 134 form an annular flow, so that the mixing of the phosphorous agent introduced through the ingestion agent injection tube 133 is rapid. Make it happen in time. As such, when the influent is mixed with the phosphorus treatment agent, the phosphorus component contained in the influent is adsorbed through the adsorption reaction of the phosphorus treatment agent and grows into a larger floc. That is, the mixing of the inflow water and the phosphorus treatment agent by the jet mixer 130 allows the adsorption reaction of the phosphorus component by the phosphorus treatment agent to proceed quickly.

In addition, in the configuration of the jet mixer 130 configured as described above, the inflow water and the phosphorus treatment agent are diffused through the inflow water injection nozzle 132 and the phosphorus treatment tube 133 and the inflow water and the phosphorus treatment agent are quickly mixed. Diffusion means 135 is further configured to be made uniform. At this time, the diffusion means 135 is a support plate 135a supported inside the annular flow guide tube 134, the rotating shaft 135b configured in the center of the support plate 135a, as shown in Figs. It is rotatably supported on the rotating shaft (135b), but is formed in a cone shape to diffuse and mix the injection water and the phosphorus agent injected and injected at high speed from the inflow water injection nozzle 132 and the phosphorous agent injection tube 133 through the conical surface. The injection member is formed at a predetermined interval on the outer peripheral surface of the diffusion member 135c and the diffusion member 135c to be made is injected and injected at high speed from the inflow water injection nozzle 132 and the processing agent injection tube 133 on the conical surface It consists of a configuration of the spiral groove (135d) to allow the rotation of the diffusion member (135c) by the water and the treatment agent.

The diffusion means 135 configured as described above is injected and introduced at high speed by the inflow water injection nozzle 132 and the treating agent injection tube 133 through the diffusion member 135c rotatably supported on the rotation shaft 135b. Diffuse influent and phosphate treatment. That is, the inflow water and the phosphorus agent injected and injected at high speed by the inflow water injection nozzle 132 and the phosphorous agent injection tube 133 collide with each other on the conical surface of the diffusion member 135c. Influent and Phosphorus Diffusion

In addition, when the inflow water and the phosphorus treatment agent injected and injected at high speed are hit on the conical surface of the diffusion member 135c, the inflow water and phosphorus impingement on the cone surface are formed at a predetermined interval on the conical surface of the diffusion member 135c ( As the diffusion member 135c is rotated by the 135d), the inflow water injected and introduced and the phosphorus treatment agent are diffused. Therefore, the mixing of the influent with the phosphorus agent is quick and uniform.

In addition, in the configuration of the jet mixer 130 as described above, the inner circumferential surface of the annular flow guide tube 134 is configured to protrude in a ring shape to induce partial vortices around the vortex to accelerate the mixing of the injection water and the phosphorous agent. Ash 136 is further configured. As shown in FIG. 3, in the vortex forming material 136, an inflow water injected and injected at a high speed by the inflow water injection nozzle 132 and the phosphorus injection tube 133 collides with the inflow water, and a vortex is formed to inject the injection water. Accelerates the mixing of the phosphorus agent.

Phosphorous agent input means 140 constituting the present invention is to inject the input amount of the phosphorous agent according to the concentration of the phosphorus component contained in the influent water introduced by the effluent inflow pump 110, such a phosphorus agent input means 140 As shown in FIG. 1, a high velocity is introduced into a central portion of the inflow water injected into the reactor 131 of the jet mixer 130 at high speed to be mixed with the inflow water by an annular flow. Phosphorus treatment to form floc is introduced through adsorption reaction with phosphorus in the influent.

On the other hand, the phosphorus treatment agent input unit 140 as described above is driven by the control of the phosphorus treatment tank 142 and the control controller 150 in which the phosphorus treatment is stored, the input amount of the phosphorus treatment agent according to the phosphorus concentration of the influent It may be made of a configuration of the processing agent injection pump 144 to be made at this high speed. The phosphorus treatment agent input unit 140 configured as described above is driven by the phosphorus agent input pump 144 so that only the input amount according to the phosphorus concentration value detected by the phosphorus concentration detection sensor 120 can be input.

Examples of the phosphorus treatment agent stored in the phosphorus treatment tank 142 in the above-described composition of the phosphorus treatment agent 140 include polyaluminum chloride (PAC), polyaluminum chloride (PACS), and polyhydroxide. Polyaluminum Hydroxy Chloro Sulfate Silicate (PAHCSS), Polyaluminum Hydroxy Chloro Sulfate (PAHCS), Poly Sulfate Silicate (PASS), Aluminum Sulfate (AS), Aluminum At least one inorganic coagulant selected from the group consisting of Ferric Aluminum (FA), Aluminum Chloride (AC), Aluminum Ferric Sulfate (AFS) and Aluminum Ferric Chloride (AFC); or At least one inorganic coagulant and zirco selected from inorganic coagulants containing a polyamine compound in these inorganic coagulants The oxychloride (ZrOCl ₂₎ consists of a mixed composition composed of a percentage.

The composition ratio of the inorganic coagulant and zirconium oxychloride (ZrOCl ₂ ) as described above is 80 to 99: 1 to 20% by weight. At this time, zirconium oxychloride (ZrOCl ₂ ) is composed of ZrOCl ₂ · 8H ₂ O in hydrate form. The following Table 1 and Table 2 compares the case where Alum, PAC and JETchem 200 were added to the influent with the phosphorus treatment agent (JETchem 100) and the inorganic coagulant applied in the present invention.

Phosphorus
density Alum PAC JETchem 100 JETchem 200 0 ppm 1.35 1.35 1.35 1.35 30 ppm 1.03 0.83 0.27 0.32 50 ppm 0.89 0.59 0.15 0.23 80 ppm 0.63 0.41 0.08 0.16 100 ppm 0.45 0.32 0.05 0.07 150 ppm 0.34 0.23 200 ppm 0.21 0.15

As described above, it can be seen that the phosphorus treatment agent (JETchem 100) as the inorganic coagulant applied in the present invention is superior to the other inorganic coagulants. Table 2 shows the input of inorganic coagulant to phosphorus concentration.

The control controller 150 constituting the present invention detects the concentration of the phosphorus component contained in the influent water flowing through the phosphorus concentration detection sensor 120, thereby determining the amount of phosphorus agent input and controlling the phosphorus agent input means 140. For this purpose, the control controller 150 determines the input amount of the phosphorus treatment agent according to the phosphorus concentration of the phosphorus component contained in the influent through the detection value detected by the phosphorus concentration detection sensor 120 as shown in FIG. By controlling the phosphorus treatment means 140.

In other words, the control controller 150 constituting the present invention determines the input amount of the phosphorus treatment agent according to the phosphorus concentration value in the influent water detected by the phosphorus concentration detection sensor 120 to configure the phosphorus treatment agent input means 140. Through the operation of the phosphorus treatment pump 144, as much phosphorus agent as the concentration value of the phosphorus component is introduced. At this time, the input ratio of the phosphorus treatment agent according to the concentration value of the phosphorus component is added at a ratio of 5 to 100 ppm relative to the concentration of 0.2 to 1.5 ppm of the phosphorus component.

The jet filter 160 constituting the present invention is introduced into the reaction water mixed and mixed by the jet mixer 130 to filter the floc (Floc) and foreign substances by the reaction of the phosphorus agent and the phosphorus contained in the influent water and then filtered In order to discharge the final discharged water, the jet filter 160 is adsorbed by the phosphorus component and the phosphorus treatment agent contained in the injection water while being mixed by the jet mixer 130 as shown in Fig. 1, 4 and 5 Reaction water inflow to the floc (Floc) by the reaction is made, but the reaction tank inlet (162a) is formed on the upper side and the reaction water inlet and the filtered water outlet 162b is formed in the filtered treated water discharged on the lower side ( 162, the support plate 164, the support plate 164, which is installed at a predetermined height from the inner lower portion of the filtration tank 162, is provided with a plurality of outlets 164a for allowing filtered water to flow out to the lower portion. The fine particles and contaminants accumulated on the filtration layer 166 and the filtration layer 166 which are loaded into a certain thickness layer and are included in the reaction water flowing into the inside of the filtration tank 162 to filter the foreign matters It consists of a backwashing means for cleaning.

The filtration action of the jet filter 160 configured as described above is such that the reaction water introduced into the filtration tank 162 passes through the filtration layer 166 stacked on the support plate 164 to the bottom of the support plate 164. In the process, flocs and foreign substances included in the reaction water are filtered by the filter layer 166. At this time, the filtered water filtered by the filtration layer 166 and passed to the lower portion of the support plate 164 is discharged to the discharge system through the filtered water outlet 162b in the lower portion of the filtration tank 162.

On the other hand, in the configuration of the jet filter 160 as described above, the reaction water inlet 162a for introducing the reaction water into the interior of the filtration tank 162 is configured to have a predetermined slope so as to obliquely react to the inner circumferential surface of the filtration tank 162. It is configured to form a vortex while allowing the inflow to take place. In addition, the filtration layer 166 is composed of a plurality of layers on the upper surface of the support plate 164, but has a structure in which sand or activated carbon having a smaller diameter is stacked from the lowermost layer to the upper layer.

In addition, the backwashing unit constituting the aforementioned jet filter 160 separates floc or foreign matter filtered by the filtration layer 166 from the sand or activated carbon constituting the filtration layer 166. The back washing means 168 is installed on the upper side of the filtration tank 162 and is driven by application of power, and the inner side of the filtration tank 162 from the drive shaft of the reduction motor 168a and the reduction motor 168a. It is installed at the lower end of the rotating shaft 168b and the rotating shaft 168a which extends a predetermined length in the center and agitates the sand or activated carbon of the filtration layer 166 through rotation to remove fine particles or contaminants accumulated in the filtration layer 166. A backwash water supply pipe 168d and a backwash water supply pipe 168d which are detachably connected to a lower portion of the filtered water outlet 162b formed on the lower side of the impeller 168c and the filtration tank 162 to allow the backwash water to be supplied. Being installed on one side of Constitution of a backwash feed pump 168e for supplying backwash water at a constant pressure through a drive and a backwash water outlet 168f formed at an upper side of the filtration tank 162 to discharge backwash water containing fine particles or contaminants Is done.

The backwashing means 168 configured as described above is backwashed under the control of the control controller 150 in a state in which the backwashing water supply pipe 168d is connected to the lower portion of the filtered water outlet 162b formed at the lower side of the filtration tank 162. The filtration layer 166 is driven by driving the feed pump 168e and the reduction motor 168a to supply backwash water through the filtered water outlet 162b so that the backwash water passes through the support plate 164 and the filtration layer 166. Floating fine particles or contaminants accumulated inside. At this time, the impeller 168c is rotated according to the driving of the reduction motor 168e to stir sand or activated carbon constituting the filtration layer 166 to smoothly float fine particles or contaminants in the filtration layer 166. To help. At this time, the backwash water in the state where the fine particles or contaminants are suspended inside the filter layer 166 is discharged through the backwash water outlet 168f.

In addition, in the configuration of the back washing means 168 as described above, the reduction motor 168a and the rotating shaft 168b are lowered to place the impeller 168c inside the filtration layer 166 or with the reduction motor 168a. A lifting cylinder 168g is further configured to raise and lower the rotating shaft 168b so that the impeller 168c can be positioned outside the upper part of the filtration layer 166.

The present invention is not limited to the above embodiments, and various modifications can be made within the scope of the technical idea of the present invention.

100. In-process system 110. Effluent inflow pump
120. Phosphorus concentration sensor 130. Jet mixer
131. Reactor 132. Influent injection nozzle
133. Phosphorus input tube 134. Cyclic induction tube
140. Phosphorus treatment means 142. Phosphorus tank
144. Phosphate Input Pump 150. Control Controller
160. Jet filter 162. Filtration tank
164. Supporting Plates 166. Filtration Layer
168. Backwashing means 168a. Reduction motor
168b. Axis of rotation 168c. Impeller
168d. Backwash water supply line 168e. Backwash feed pump
168 g. Lifting cylinder

Claims (14)

In the phosphorus treatment system for removing the phosphorus contained in the influent by introducing the discharged water discharged by sewage treatment through the waste water treatment device,
A discharge water inflow pump for introducing the discharged water discharged by sewage treatment through the waste and waste water treatment device through driving by applying power;
A phosphorus concentration sensor for detecting a concentration of phosphorus in the effluent flowing into the effluent inflow pump;
A jet mixer which allows an annular flow to be formed while injecting the inflow water introduced by the discharge water inflow pump at a high speed;
A floc is formed through adsorption reaction with phosphorus contained in the inflow water inside the jet mixer while being mixed at the high speed into the center of the inflow water injected into the jet mixer at high speed to mix with the inflow water by the annular flow. Phosphorus treatment means for injecting a phosphorus treatment to make;
A control controller for controlling the phosphorus input means by determining an input amount of the phosphorus treatment agent according to the phosphorus concentration of the phosphorus component contained in the inflow water through the detection value detected by the phosphorus concentration detection sensor; And
It is composed of a jet filter that is mixed by the jet mixer and reacted with the reaction water flows in the floc (Floc) by the reaction of the phosphorus treatment agent and the phosphorus in the influent water and then discharge the filtered final effluent water High efficiency phosphorus treatment system. According to claim 1, wherein the jet mixer is a reaction tank in which the reaction of the phosphorus component and the phosphorus agent contained in the inflow water introduced into the reaction is formed on one side is formed with a discharge pipe for discharging the reaction water;
An inflow water injection nozzle installed in the reactor to allow high speed injection into the discharge water inflow pump;
A phosphorus treatment inlet tube installed at a central portion of the inflow water injection nozzle in a longitudinal direction to inject a phosphorus agent injected through the phosphorus agent injection means at a high speed into a center of the infusion water injected by the inflow water injection nozzle at high speed; And
It is installed on the center so as to be spaced apart from the inner circumferential surface of the reactor by a predetermined interval, the inlet water injection nozzle and the injecting agent injection tube is installed in the upper center of the upper and lower tube shape is injected at high speed by the inlet water injection nozzle A highly efficient in-treatment system, characterized in that it consists of an annular flow induction pipe to form an annular flow rising upward through the lower outer wall while the water is injected downward through the interior. According to claim 2, wherein the center of the annular flow induction pipe is installed in the center of the lower portion of the processing agent inlet tube spaced apart a predetermined distance is formed in a conical shape injecting and injecting at high speed from the inflow water injection nozzle and the processing agent inlet tube A high efficiency phosphorus treatment system, characterized in that the diffusion means is further configured to diffuse the water and phosphorus treatment agent to be uniformly mixed. 4. The apparatus of claim 3, wherein the diffusion means comprises: a support plate supported inside the annular flow guide tube;
A rotating shaft configured at the center of the support plate;
The diffusion member is rotatably supported on the rotating shaft and is formed in a conical shape to diffuse and mix the injection water and the phosphorus agent injected and injected at high speed from the inflow water injection nozzle and the phosphorus injection tube through the conical surface. ; And
Spiral grooves are formed on the outer peripheral surface of the cone of the diffusion member at a predetermined interval so that the diffusion member can be rotated by the injection water and phosphorus agent injected and injected from the inflow water injection nozzle and the phosphorus treatment tube at high speed on the cone surface. High efficiency phosphorus treatment system, characterized in that consisting of. 5. The high efficiency phosphorous treatment according to claim 4, wherein the inner circumferential surface of the annular flow guide tube is formed to protrude in a ring shape to induce partial vortices to accelerate mixing of the injected water with the phosphorous treatment agent. system. According to claim 1, wherein the processing agent input means is a processing agent tank in which the storage of the processing agent is made; And
A high efficiency phosphorus treatment system comprising a composition of a phosphorus treatment pump which is driven by the control of the control controller so that the addition of the phosphorus treatment agent according to the phosphorus concentration of the influent is made at a high speed. The method of claim 6, wherein the phosphorus treatment agent is polyaluminum chloride (PAC), polyaluminum chloride (PAC), polyaluminum hydrochloride Chloro Sulfate Silicate (PAHCSS), Polyaluminum Hydroxy Chloro Sulfate (PAHCS), Poly Sulfate Silicate (PASS), Aluminum Sulfate (AS), Ferric Aluminum (FA), Aluminum Chloride (Aluminum Chloride) AC), at least one inorganic coagulant selected from the group consisting of Aluminum Ferric Sulfate (AFS) and Aluminum Ferric Chloride (AFC) or an inorganic coagulant containing a polyamine-based compound in these inorganic coagulants. 80 to 99: 1 to 20 weights of one or more inorganic coagulants and zirconium oxychloride (ZrOCl ₂ ) A high efficiency phosphorous treatment system, characterized in that the composition is mixed in the ratio of%. 8. The high efficiency phosphorous treatment system of claim 7, wherein the zirconium oxychloride (ZrOCl ₂ ) is ZrOCl ₂ .8H ₂ O in hydrate form. The method of claim 1, wherein the jet filter is mixed by the jet mixer, the reaction water grown in the floc (Floc) by the adsorption reaction of the phosphorus component and the phosphorus agent contained in the injection water is made to the reaction water at the upper side A filter tank in which a filtered water outlet for discharging the filtered water is formed at one side of the reaction water inlet and the lower side through which the inflow is made;
A support plate provided at a predetermined height from an inner lower portion of the filtration tank, the support plate having a plurality of outlets allowing the filtered treated water to flow out to the lower portion;
A filtration layer loaded on the upper surface of the support plate as a layer to filter flocs and foreign substances included in the reaction water flowing into the filtration tank; And
High efficiency phosphorus treatment system consisting of a back washing means for cleaning the fine particles and contaminants accumulated in the filter layer. 10. The method of claim 9, wherein the reaction water inlet for introducing the reaction water into the filtration tank is configured to be inclined to form a vortex while allowing the inflow of the reaction water obliquely to the inner circumferential surface of the filtration tank. High efficiency phosphorus treatment system, characterized in that. The high efficiency phosphorous treatment system according to claim 10, wherein the filtration layer is formed of a plurality of layers on the upper surface of the support plate, and has a structure in which sand or activated carbon having a smaller diameter is laminated from the lowermost layer to the upper layer. 12. The method of claim 11, wherein the backwashing means is installed on the upper side of the filtration tank is a reduction motor driven by the application of power;
A rotating shaft extending from the driving shaft of the deceleration motor to the inner center of the filtration tank by a predetermined length and rotating;
An impeller installed at the lower end of the rotating shaft to stir sand or activated carbon of the filtration layer through rotation to float fine particles or contaminants accumulated in the filtration layer;
A backwash water supply pipe detachably connected to a lower portion of the filtered water outlet formed at the lower side of the filtration tank to supply the backwash water;
A backwashing supply pump installed at one side of the backwashing water supply pipe to supply backwashing water at a predetermined pressure through a drive; And
The high efficiency phosphorus treatment system is formed on the upper side of the filtration tank is composed of a backwash water outlet for discharging the backwash water containing fine particles or pollutants. The method of claim 12, wherein the backwashing means is to lower the reduction motor and the rotating shaft to position the impeller inside the filter layer or to raise and lower the reduction motor and the rotating shaft to position the impeller on the upper outside of the filter layer. Efficient in-process system, characterized in that the lifting cylinder further configured to enable. The amount of the phosphorus treatment agent according to any one of claims 1 to 13 according to the phosphorus concentration of the phosphorus component contained in the inflow water introduced by the effluent inflow pump is 5 to 100 ppm with respect to the concentration of 0.2 to 1.5 ppm High efficiency phosphorous treatment system, characterized in that the input ratio.

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