KR101728130B1 - Flocculant injecting apparatus for wastewater treatment - Google Patents

Abstract

The present invention relates to an apparatus for injecting coagulant for treating sewage and wastewater which can uniformly mix a coagulant for coagulation treatment of phosphorus in sewage and wastewater within a short time in multiple points and can smoothly inject the coagulant for coagulation treatment of phosphorus in sewage and wastewater without clogging a portion of an injection nozzle caused by scum. According to an embodiment of the present invention, the apparatus for injecting coagulant for treating sewage and wastewater comprises: a compressed air supply line which supplies compressed air; multiple coagulant injection lines comprising a horizontal extension pipe which is branched and connected to the compressed air supply line, a coagulant injection pipe which is horizontally extended while immersed in sewage and wastewater and has multiple injection nozzles arranged at intervals, and a connection pipe connecting the horizontal extension pipe to the coagulant injection pipe; multiple coagulant supply lines which are coaxially arranged in the horizontal extension pipe among the coagulant injection lines and then are extended downwards only to a certain height of the joining pipe; a coagulant equal division supply device which has one side connected to a coagulant supply source, the other side connected to the coagulant supply lines in parallel, equally supplies the coagulant supplied by the coagulant supply source to the coagulant supply lines; and a coagulant injection amount controller which is connected to the coagulant equal division supply device which measures the concentration of phosphorous in each n sample, obtained by sampling the sewage and wastewater for each section, before a coagulation test and the concentration of phosphorous after the coagulation test and controls the amount of coagulant to be supplied to the coagulant equal division supply device.

Description

Technical Field [0001] The present invention relates to a flocculant injecting apparatus for treating wastewater,

The contents disclosed in this specification are used to coagulate and remove phosphorus contained in wastewater or sewage (hereinafter referred to as "wastewater") by introducing coagulant into a wastewater treatment facility water channel, ≪ / RTI >

Unless otherwise indicated herein, the contents of this identification are not prior art to the claims of this application and are not to be construed as being prior art to the extent that they are included in this identification.

Generally, a considerable amount of phosphorus (P) is contained in the wastewater. Phosphorus (P), for example, corresponds to a pollutant promoting the eutrophication of water quality, such as plant Francon breeding. Therefore, in a wastewater treatment facility, phosphorus concentration in wastewater is usually lowered to a certain level and discharged to rivers or the sea.

In the wastewater treatment facility, phosphorus is removed by biologically treating the wastewater. However, since the removal efficiency of phosphorus (P) is not constant due to environmental changes of influent water or changes in activity of microorganisms during biological treatment, Concentration constant

It can not be lowered below the level.

Therefore, in the wastewater treatment facility, the concentration of phosphorus (P) contained in the sampled wastewater is measured and then a predetermined amount of coagulant is injected (injected) to lower the concentration of phosphorus contained in the wastewater.

As a coagulant for coagulating and removing phosphorus in wastewater, polyaluminum chloride (PAC) or polyhydroxy aluminum chloride sulfate (PAHCS) containing aluminum cations as a main component is often used, and a chlorinating agent containing iron cations as a main component Ferric Chloride) are widely used.

The coagulant is injected by a method of adding a coagulant and forcibly stirring using a stirrer, a method of introducing a coagulant into a position where a drop in a water channel occurs, a method of introducing a coagulant by a line mixer, A method of adding a coagulant to a water chamber, a method of mixing the coagulant with water, and the like.

The coagulant injection methods described above require considerable time for the coagulant to diffuse and mix into the wastewater by mixing the wastewater with the chemicals while stirring the wastewater or forming a vortex. Therefore, it is difficult for the coagulant to uniformly mix the wastewater to cause the chemical reaction for coagulating the phosphorus (P) to occur within a short time (about 1-2 seconds), and as a result, the chemical reaction between the coagulant and the wastewater is delayed, There is a problem that the removal efficiency is lowered.

In order to estimate the input amount of the coagulant, a method of performing sampling after putting the coagulant into the wastewater is used. When the coagulant can not be uniformly mixed in the wastewater, the amount of the coagulant is excessively or underestimated due to sampling error And there is a problem that the medicine is injected excessively or excessively more than necessary.

When the coagulant and water are mixed in the mixer, the coagulant reacts with water in a short period of time and coagulates like a gel in the coagulant feeder, so that the coagulant is not normally injected .

In order to solve such a problem, Korean Patent Registration No. 10-1187824 (Oct. 10, 2012) filed by the applicant of the present application has a distributor in which a coagulant flow path and a fluid flow path are formed, Wherein the coagulant discharge channels are branched in the coagulant flow channels, the fluid discharge channels are branched in the fluid channels, and the coagulant discharge channels and the fluid discharge channels are connected to the respective injection nozzles to perform a wastewater treatment A coagulant injection device for a coagulant is disclosed.

However, in the case of the coagulant injector for wastewater treatment as described above, since the coagulant discharging flow paths and the fluid discharging flow paths are connected to the respective spray nozzles, scum is generated due to the aggregation of phosphorus immediately above the spray nozzles, There was a problem.

Also, the input of coagulant for the coagulation treatment of phosphorus usually takes place in a channel connecting the plurality of aeration tanks to the final settling tank or in a separate tank treatment facility connected to the rear end of the final settling tank.

In particular, the waterway connecting the plurality of aeration tanks to the final settling basin is usually formed in a multi-layered structure, and the water depth is as large as 1.3 to 1.5 m, the drop between the aeration tank and the waterway is as small as 20 cm or less, Can not be installed. Therefore, it is difficult for the coagulant to be rapidly stirred, and it is difficult to mix the coagulant at a uniform ratio at multiple points.

In addition, since the coagulation reaction by the coagulant has various influence factors and the mechanism is complicated, a proper amount of the coagulant is injected directly into the wastewater sample and reacted, (Jar-test) experiment (generally, the sample to be flocculated is placed in 6 jars and the optimum amount of coagulant is injected by varying the amount of flocculant injected).

However, it takes time to measure the phosphorus concentration (usually about 85% of the total phosphorus, which is a soluble phosphate, which is known to be PO ₄ -P), which is the contaminant on the site where the coagulant is injected, It takes time to calculate the flocculant efficiency of influent water according to influential factors such as suspended solids.

Therefore, since the inflow water quality at the site where the inflow water quality changes over time is not immediately known, the coagulant is injected using past inflow water quality (phosphate concentration, self test test result, etc.) Have no choice but to.

However, it is difficult to perform the field test in more than 2 times a day because skilled personnel take more than one hour. Therefore, the actual field depends on the past experience, measurement, safety factor, Tests are conducted to try to reduce the difference between the predicted value and the actual demand value (actual inflow water quality), but there are many cases where the experiment can not be performed. Even when the concentration of the phosphorus in the solution is measured, the concentration of the phosphorus in situ and the field test are ineffective when the factors affecting the flocculation reaction of the flocculant such as phosphorus concentration, flocculant efficiency and pH are influential over time.

Therefore, in order to cope with the situation in which the phosphorus concentration of the influent changes temporally or the factors (floating substances, pH, etc.) affecting the flocculation reaction of the flocculent change in time, inevitably, The flocculation agent is over-injected because the coagulant is injected into the site in consideration of the self test test value and the safety factor.

In order to solve this problem, it is necessary to predict the concentration of the phosphorus at the injection site among the influent water quality at the time of the coagulant injection at the time of injecting the flocculant by using the measured values of phosphate for the past inflow water already passing through the site, There has been an attempt to improve the efficiency (efficiency) of coagulants by influence factors or influence factors of the site pollution at the time by predicting and using coagulant test data for past inflows already passed through the site.

However, since the concentration of the past phosphorous was used a long time ago, the concentration of phosphorous in the field could not be predicted in time, or the coagulant efficiency was used according to the self-test experiment conducted long time ago. There was a limit.

Therefore, up to now, the phosphorus concentration and the influencing factor of the influent water can be changed at the same time in any section, even if one of them mainly fluctuates according to the passage of time, so that a solution capable of coping with such an environment has not been properly prepared. In addition, a solution to cope with a sudden change in phosphorus concentration or influencing factor of the influent water was not properly prepared.

Since the phosphorus concentration and the flocculant efficiency included in the wastewater can vary from time to time and it takes a certain time to measure the phosphorus concentration, the wastewater measured after passing through the site where the coagulant is introduced has already been measured. The concentration may be different from the phosphorus concentration of the wastewater passing through the site where the coagulant is input. Since the amount of the flocculant to be added is determined by the actual phosphorus concentration (actual value) and the phosphorus concentration (approximate value) of the field, problems arise due to the phosphorus concentration difference (error).

That is, when the measured value of phosphorus is applied to the field using the approximate value, when the phosphorus concentration is larger than the actual concentration in the field (positive error), the phosphorus concentration is excessively used. But the flocculant is wasted.

In addition, when the measured concentration of phosphorus becomes smaller than the actual concentration in the field (negative error), the coagulant is injected too little, so that the amount of the coagulant is reduced but the phosphorus concentration of the water quality may be lowered below the target value . Also, the greater the time interval between the measurement of the wastewater and the input to the site, the greater the likelihood of such a problem occurring.

Further, when the actual amount of the coagulant is determined on the basis of the actual coagulant (drug) efficiency in the field and the efficiency of the coagulant, there arises a problem due to the difference in coagulant efficiency (error). In other words, if the applied (or measured) flocculant efficiency is greater than the actual flocculant efficiency of the site, the coagulant is used in an excessively small amount, so that the amount of flocculant used is reduced but the concentration of phosphorous in the water is lowered below the target value. Lt; / RTI >

And a coagulant for coagulating the phosphorus in the wastewater can be uniformly mixed in a short time within a short time.

The present invention also provides a coagulant injecting apparatus for treating wastewater, which is capable of smoothly injecting a coagulant for coagulating the phosphorus in wastewater into the wastewater without clogging the spray nozzle due to scum.

It is another object of the present invention to provide a coagulant injector for treating wastewater by minimizing an error between the actual concentration of phosphorus in the wastewater and the measured concentration so that an optimum amount of coagulant can be injected.

It is obvious that the present invention is not limited to the above-described technical problems, and another technical problem may be derived from the following description.

According to one embodiment of the disclosure disclosed herein, a compressed air supply line to which compressed air is supplied; A horizontal extension pipe branched to the compressed air supply line; an agglomerated granular inlet extended horizontally so as to be immersed in the wastewater and spaced apart from a plurality of injection nozzles; A coagulant injection line having a connector; A coagulant supply line coaxially arranged in the horizontal extension pipe of the coagulant injection line and extending downward only to a certain height of the connection pipe; A flocculant equalizer feeder connected in parallel to one of the flocculant supply lines, one side of which is connected to a flocculant supply source and the other side of which is connected in parallel to the plurality of flocculant supply lines, and which supplies the flocculant supplied from the flocculant supply source equally to the plurality of flocculant supply lines; And a coagulant injection amount controller for controlling the amount of coagulant to be supplied to the coagulant equal split feeder by measuring the concentration of the coagulation experiment and the concentration of the coagulant after the coagulation experiment of each of the n samples sampled in each section of the wastewater.

The flocculus equally divided supply unit includes a container body, a first partition wall that divides both sides across the inside of the container body, and a second partition wall that is connected to a coagulant supply source at one end, And a plurality of the flocculant supply lines, which are arranged in the other direction of the container body divided by the first bank, are arranged in the vertical direction to the first bank and the ends of the flocculant supply line are connected to the inside of the other side of the container body And a second partition wall forming an equal partitioning section.

In addition, a V-shaped notch groove may be formed in the upper end of the first partition wall for each of the plurality of uniform partitioning sections formed by the second partition walls.

Further, the coagulant injection amount controller measures the concentration {P (n)} before the coagulation experiment of each n sample, and calculates the concentration n (n) of each n sample in accordance with the coagulant injection rate {Cj A pretreatment unit for measuring the phosphorus concentration {P '(n)} after the coagulation agent is injected and the coagulation experiment of each n sample is carried out before the concentration of the sample {P (n)} is measured. (N) and the coagulant efficiency {C (n)} of each n sample are calculated, and the concentration {P (n)} before the coagulation experiment of each n sample and the coagulant efficiency {C (n)}, which is the concentration {P (n)} of the coagulation experiment of each of the n samples, is controlled according to the concentration of the coagulating agent {n (n-1) P (n)} of each n sample is calculated using the phosphorus concentration {P '(n)} after the coagulation experiment of the chair tester, and the coagulation efficiency {P And a second coagulant injection rate {O '(n)} injected into the coagulant-uniformly divided feeder according to the coagulant efficiency {Cp (n)} of each n sample.

According to an embodiment of the present disclosure, the coagulant for coagulating the phosphorus in the wastewater can be uniformly mixed in a short time within a short time, and the coagulant for coagulating the phosphorus in the wastewater can be prevented from clogging It can be injected into the wastewater smoothly.

According to one embodiment of the present disclosure, the phosphorus concentration of the sample is measured, the concentration of phosphorus in the flocculated sample is measured after flocculating the sample, and the time (one cycle interval time) So that the error between the actual concentration of phosphorus in the wastewater and the measured concentration is reduced to the maximum, and the error between the actual flocculant efficiency of the field and the calculated flocculant efficiency is reduced, so that the flocculant can be supplied in an optimum amount without excessive or insufficient.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall schematic structural view of a coagulant injection apparatus for wastewater treatment according to an embodiment of the disclosure disclosed herein; FIG.
FIG. 2 is a detailed structural view of a main portion of a coagulant injecting apparatus for wastewater treatment according to an embodiment of the present disclosure; FIG.
3 is a detailed structural view of a coagulant-even-division feeder in a coagulant feeder for wastewater treatment according to an embodiment of the present disclosure.
FIG. 4 is an explanatory view illustrating the operation of coagulant injection by the coagulant injection device for wastewater treatment according to an embodiment of the present disclosure; FIG.
5 is a schematic structural view of an embodiment of a pretreatment section of a flocculant feed rate controller in a flocculant injection device for wastewater treatment according to an embodiment of the disclosure disclosed herein.
6 is an operational explanatory view of an embodiment of a flocculant feed rate controller including a preprocessor and an arithmetic control unit in a flocculant injection apparatus for wastewater treatment according to an embodiment of the disclosure disclosed herein.

Hereinafter, the structure, operation, and effects of the coagulant injecting apparatus for wastewater treatment according to a preferred embodiment will be described with reference to the accompanying drawings. For reference, in the following drawings, each component is omitted or schematically shown for convenience and clarity, and the size of each component does not reflect the actual size, and the same reference numerals denote the same components throughout the specification. And reference numerals for the same components in individual drawings are omitted.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an overall schematic structural view of a coagulant injecting apparatus for wastewater treatment according to an embodiment of the present disclosure, and Fig. 2 is a cross-sectional view of a coagulant injecting apparatus for wastewater treatment according to an embodiment of the present invention A detailed structural view is shown.

1 and 2, the coagulant injecting apparatus 1 for wastewater treatment according to an embodiment of the present disclosure includes a compressed air supply line 10 to which compressed air is supplied, A plurality of coagulant feed lines (20) immersed in the coagulant feed line (20) for injecting the coagulant into the coagulant feed line (20) A flocculation agent uniformly divided feeder 40 for uniformly dividing and supplying the same amount of flocculant to a plurality of flocculant feed lines 30 and a line 30 are supplied to the flocculant uniformly divided feeder 40 to be finally injected into wastewater And a flocculant injection volume controller 50 for controlling the amount of flocculant.

The coagulant injecting apparatus 1 for wastewater treatment according to an embodiment of the present disclosure is installed in a waterway connecting a plurality of aeration tanks and a final settling tank among sewage treatment facilities, The flocculant for treatment enables the flocculant to be uniformly dispersed and mixed at the same time.

Here, the compressed air supply line 10 is a line for supplying compressed air into the plurality of coagulant injection lines 20 and supplying the compressed air to the bubble ejector 15 at the same time.

 1 and 2, the compressed air supply line 10 includes a compressed air supply pipe 11 connected to a compressed air supply source (not shown) and one end branch connected to the coagulant injection line 20, And a connection pipe 17 connecting the compressed air supply pipe 11 and the bubble generating pipe 13 so as to communicate with each other. The bubble generator 13 includes a bubble generator 15, do.

The compressed air supply source connected to the compressed air supply line 10 may be formed as a separate air pump, but is preferably a ventilation pipe of the aeration tank of the wastewater treatment facility. Since the air supply pipe of the aeration tank is connected to the air pump of a large capacity, when the air supply pipe of the aeration tank is used as the compressed air supply source, it is possible to supply the compressed air without using the additional air pump.

It is also preferable that the bubble generating tube 13 is branched horizontally on both sides with respect to the lower end of the connection tube 17.

The bubble injector 15 is configured to inject the upward flow from the lower portion of the injection nozzle 25 so that the coagulant injected together with the compressed air from the injection nozzle 25 can diffuse into the upper portion of the wastewater in a short time, . The bubble injector 15 is positioned in correspondence with the lower portion of the injection nozzle 25 of the coagulant injection line 20 as shown in detail in Fig. 2, and is provided with a jar Is preferably formed in a shape.

The coagulant injection line 20 is connected to the compressed air supply line 10 described above. The coagulant injection line 20 is a line for pushing down the coagulant supplied to the inside by using the compressed air provided from the compressed air supply line 10 to be injected into the wastewater.

The coagulant injection line 20 includes a horizontal extension pipe 21 branched to the compressed air supply line 10 as shown in Figs. 1 and 2, and a horizontal extension pipe 21 extending horizontally so as to be immersed in the wastewater and having a plurality of injection nozzles 25 And a connecting pipe 27 for connecting the horizontal extending pipe 21 and the flocculating inlet 23 in a communicating manner with each other.

The horizontal extension pipe 21 is connected to the compressed air supply line 10 by the branched connection pipe 21a and is supplied with compressed air for pushing out the flocculant.

It is preferable that the coalescing gravity inlet 23 is branched horizontally on both sides with respect to the lower end of the connecting pipe 27.

The injection nozzle 25 is formed by an angle tube which is protruded to the front face of the coagulating vessel inlet pipe 23 and then bent upward, and is protruded one by one at regular intervals in the longitudinal direction of the coagulating vessel inlet pipe 23. The coagulant supplied through the coagulant supply line 30 is pushed out by the compressed air supplied by the compressed air supply line 10 from the injection nozzle 25 and is discharged together.

The coagulant supply line 30 is coaxially arranged in a predetermined length in the coagulant injection line 20 described above. The coagulant supply line 30 supplies the coagulant to the inside of the coagulant injection line 20 connected to the compressed air supply line 10 so that the coagulant is pushed by the compressed air in the coagulant injection line 20, 25).

The flocculant supply line 30 is coaxially arranged into the horizontal extension pipe 21 of the flocculant injection line 20 as shown in FIGS. 1 and 2, and then extends downward only to a certain height of the connection pipe 27.

Particularly, the lower end of the flocculant supply line 30 is preferably located below the center height of the connection pipe 27 of the flocculant injection line 20. This arrangement allows the coagulant discharged from the coagulant feed line 30 into the coagulant feed line 20 to readily flow downward in spite of the pressure in the vessel.

The above-described plurality of flocculant supply lines 30 are connected in parallel to the flocculant equal-split feeder 40. The flocculant-equal-split feeder 40 divides the flocculant supplied from the flocculant supply source (not shown) equally into the same amount of the flocculant supply line 30 and supplies the flocculant to the flocculant supply line 30, (Not shown), and the other side is connected in parallel to a plurality of flocculant supply lines 30.

Fig. 3 shows a detailed structural diagram of such a flocculant even division feeder.

4, the flocculant-equal-split feeder 40 includes a container body 41 for forming a kind of a water tank in which the flocculant is contained, a first pipe 42 for partitioning both sides in the longitudinal direction of the container body 41, A flocculant supply pipe 45 connected to one side of the container body 41 partitioned by the first partition wall 43 and the other end connected to a flocculant supply source (not shown) including a flocculant tank and a pump And a flocculant supply line 30 is arranged inside the other side of the container body 41 partitioned by the first partition wall 43 and vertically spaced from the first partition wall 43 and inside the other side of the container body 41, And a second partition wall 47 forming a plurality of uniform partition dividing portions 41a to which end portions of the first partition wall 41a are connected.

Therefore, when the flocculant is supplied into the one side of the container body 41 partitioned by the first partition wall 43 through the flocculant supply pipe 45 and reaches the water level corresponding to the upper end of the second partition wall, The same amount of the flocculant is evenly divided into the plurality of equally divided partitioning portions 41a while the flocculant rushes into the plurality of equally divided partitioning portions 41a partitioned by the first and second partition walls 47a and 47b.

In order to evenly divide the flocculant, one second partition wall 47 is preferably provided for each of the same intervals, and a plurality of equal division compartments 47 formed by the second partition wall 47 are formed at the upper end of the first partition wall 43, It is preferable that the V-shaped notch grooves 43a forming the flow passage of the flocculant are formed to have the same size for each of the V-shaped notch grooves 43a.

FIG. 4 shows an explanatory view of the flocculant injection operation by the flocculant injection apparatus for wastewater treatment according to an embodiment of the disclosure disclosed herein.

The coagulant injector 1 for wastewater treatment according to an embodiment of the present disclosure is configured such that the compressed air is supplied from the compressed air supply line 10 into the coagulant injection line 20 and the coagulant is supplied from the coagulant supply source And is continuously supplied through the supply pipe 45 to one side of the flocculant equal-split feeder 40.

The flocculant supplied to one side of the container main body 41 of the flocculant uniformly divided feeder 40 partitioned by the first partition wall 43 is discharged through the V-shaped notch grooves 43a to the flocculent equal split feeder 40 And then supplied to the coagulant supply line 30. The coagulant supply line 30 is provided with a plurality of uniform division dividing sections 41a.

The coagulant is fed into the coagulant feed line 20 through the coagulant feed line 30 coaxially arranged into the coagulant feed line 20 and then pushed down by the compressed air to feed the coagulant feed through the feed nozzle 25, And is ejected together with compressed air.

The flocculant supply line 30 does not extend from the flocculant injection line 20 to the injection nozzle 25 but extends only to a certain height of the connection pipe 25 of the flocculant injection line 20, Is injected through the injection nozzle (25) having a relatively large diameter while being mixed with the compressed air in the injection line (20). Therefore, not only the coagulant can be dispersed in the wastewater at a more uniform concentration but also the phenomenon that the injection nozzle 25 is closed by the scum due to the agglomeration phenomenon of the phosphorus (P) is prevented in advance.

4, when the coagulant is injected through the injection nozzle 25, the compressed air in the compressed air supply line 10 is supplied to the bubble injector 15 in the shape of a jar located below the injection nozzle 21 The flocculant sprayed from the injection nozzle 25 can be further spread in the upward direction.

According to the structure and operation of the coagulant injecting apparatus 1 for wastewater treatment according to an embodiment of the present invention described above, the flocculant for coagulating the phosphorus (P) in the wastewater can be uniformly Mixed.

In addition, the flocculant equal split feeder (40) described above is connected to a flocculant injection volume controller (50). FIG. 5 shows a schematic structural view of one embodiment of the pretreatment section of such a flocculant feed rate controller, and FIG. 6 shows an operational explanatory view of one embodiment of a flocculant feed rate controller comprising a preprocessing section and an arithmetic control section.

The coagulant injection amount controller 50 optimally controls the amount of coagulant to be supplied to the coagulant-equal-split feeder by measuring the concentration of the coagulation test before the experiment and the concentration of the coagulant after the coagulation test, A measurement preprocessing unit 50a for measuring the phosphorus concentration {P '(n)} after the coagulation test of each n sample, and a calculation control unit 50b for calculating and controlling the coagulant injection rate to be injected into the coagulant- (50b).

The pretreatment unit 50a of the coagulant feed rate controller 50 measures the concentration P (n) before the coagulation experiment of each of the n samples and calculates the concentration {P (n)} according to the coagulant feed rate {Cj P (n)} is measured before the coagulation experiment concentration of each n sample is measured in the self-tester tank and the coagulation agent is injected and the concentration {P '(n)} after each coagulation experiment of each n sample is measured.

As shown in Fig. 5, the pretreatment unit 50a includes a self-tester tank 51 for holding a sample of influent wastewater and performing a coagulation test on the sample, and a sample of the wastewater flowing into the tank and a sample of the self- An inlet filtration tank 52 in which the filter 52a is installed and a transfer pipe 53 for transferring the sample subjected to the coagulation test of the self tester tank 51 to the inflow filtration tank 52 for filtering the sample, A washing unit 55 for washing the self-tester tank 51 and the inflow filtration tank 52 and a washing unit 55 for washing the self-tester tank 51 and the inflow filtration tank 52, And a discharge pipe 56 for discharging the gas.

The stirrer 51a is rotatably driven by the stirring motor 51a 'in the self-tester tank 51. The sample conveyed to the inflow filtration tank 52 by the transfer pipe 53 is introduced into the inflow filtration tank 52 underneath the inclined filter 52a and filtered.

The structure of the pretreatment unit 50a is only an example and can be partially changed depending on the type of the inflow filtration tank 52, the shape of the filter 52a, or the addition of a separate filtrate storage unit. Other embodiments of the preprocessing unit 50a may be found in Korean Patent Registration No. 10-1567539 (published on November 5, 2015) and Korean Patent Registration No. 10-1567541 11), the detailed description will be omitted here for the sake of simplification of the description.

The operation control unit 50b of the coagulant supply controller 50 calculates the self-tester coagulant injection rate {Cj (n)} for each of the n samples and calculates the concentration {P (n) And the primary coagulant injection rate {O (n)} injected into the flocculant uniformly divided feeder 40 according to the flocculant efficiency {Cp (n-1)} of each (n-1) The coagulant efficiency {Cp (n)} of each n sample is calculated using the concentration {P (n)} before the coagulation experiment and the concentration {P '(n)} after the coagulation experiment of the self- The second coagulant injection rate {O '(n)} injected into the coagulant-equal split feeder 40 according to the coagulation concentration {P (n)} of each n sample and the coagulant efficiency { )}.

The injection rate {Cj (n)} of the self-tester coagulant for each n sample is calculated by multiplying the second coagulant injection rate {O '(n-1)} or each (n-1) sample interval Can be calculated according to the primary coagulant injection rate {O (n-1)} of the coagulant.

The coagulant efficiency {Cp (n)} of each n sample was calculated from the following equation: [concentration before the coagulation experiment {P (n)} - concentration after the coagulation experiment {P ' Can be calculated by a relational expression of the injection rate {Cj (n)}.

In addition, the primary coagulant injection rate {O (n)} of each n sample section is calculated by the following equation: [concentration of P (n)} - target value (Pt)] / Can be calculated by a relational expression of the flocculant efficiency {Cp (n-1)}.

Also, the second coagulant injection rate {O '(n)} of the n sample sections is calculated by the following formula [{P (n)} - target value (Pt) (n)}. < / RTI >

5 and 6, the overall operation of the coagulant injection amount controller 50 will be described as follows:

When the wastewater sample for sampling is filled with the inlet 52b of the inlet filtration tank 52 of the pre-treatment unit 50a, the filtration of the sample is performed by the filter 52 of the filter type, It starts.

At this time, the wastewater supply valve 52c of the inflow filtration tank 52 is opened, while the drain valves 52d and 52d 'are opened for a few seconds and then closed. A wastewater supply pump (not shown) is operated and the wastewater is sampled and wastewater is supplied to the inflow filtration tank 52. In the case where the washing water remains in the inflow filtration tank 52, the drainage valves 52d and 52d 'are opened for a few seconds after the wastewater supply pump is operated to push out the washing water remaining in the inflow filtration tank 52 with the wastewater Is closed.

When the drain valves 52d and 52d 'are closed and supply of the wastewater for a predetermined time is completed, the wastewater supply pump is stopped and then the wastewater supply valve 52c is closed. The amount of sample contained in the inflow filtration tank 52 is determined by the opening time of the wastewater supply valve 52c (for example, about 4 seconds to complete opening, about 26 seconds to sample wastewater, 4 seconds). Further, a water level sensor may be installed in the inflow filtration tank 52 to maintain the inflow amount of the wastewater at a predetermined water level, or an overflow pipe may be separately installed.

When the wastewater is supplied to the inflow filtration tank 52, the filtration of the sample is started through the filter 52a, and the filtered sample is collected in the filtration unit 52e. A filtered water storage unit (not shown) may be provided in the filtration unit 52e at a position lower than the lower end of the inflow filtration tank 52 to store the filtered sample (filtered water).

The sampling tanks are filled with the sample tester 51 at the same time as the sample is supplied to the inflow filtration tank 52 or sequentially. At this time, the wastewater supply valve 51c of the self-tester tank 51 is opened, and the drain valve 52d in the closed state is opened for a few seconds and can be closed. In order to push out the washing water remaining in the self-tester tank 51 by the wastewater tank, that is, when the self-tester tank 51 is washed with the wastewater, The drain valve 51d is opened for a few seconds and is closed.

In the illustrated embodiment, the wastewater supply valve 51c of the self-tester tank 51 and the wastewater supply valve 52c of the inflow filtration tank 52 are constituted by separate valves. However, according to the embodiment, have. When the supply of the wastewater is completed, the wastewater supply pump is stopped and the wastewater supply valve 51c of the tester tank 51 is immediately closed.

The amount of the sample to be filled in the self-tester tank 51 is determined by adjusting the ON / OFF times of the valves. The closing time of the drain valve 129 of the self-tester tank 51 may be adjusted in order to finely adjust the amount of the wastewater supplied to the self-tester tank 51 after the supply of the wastewater is completed. The wastewater supply valve 51c of the self tester tank 51 is opened simultaneously with the wastewater supply valve 52c of the inflow filtration tank 51 or the wastewater supply valve 52c of the inflow filtration tank 52 is opened, Or may be opened to the inflow filtration tub 52 after the wastewater is supplied. Only the wastewater supply valve 52c of the inflow filtration tank 52 is opened to supply the wastewater to shorten the time for filling wastewater into the inflow filtration tank 52. [

In addition, since the self-tester tank 52 must maintain an accurate sample amount, the wastewater supply pump can be controlled by the water level sensor, and an overflow pipe may be provided if necessary in case of malfunction.

When the wastewater sample 51 is filled in the self-tester tank 51, the coagulant is injected into the self-tester tank 51 from the coagulant storage tank 60, and a Jar test coagulation test is started. After the wastewater is supplied to the self-tester tank 51 so that the wastewater is filled in the predetermined amount, the coagulant supply pump 61 injects the calculated amount of coagulant. A metering pump is used as the coagulant supply pump 61 so that the coagulant injection can be made in one unit of micro.

When the coagulant {Cj (n)} is injected, agitation by the agitator 51a starts in the self-tester tank 52. [ When the coagulant is injected, the stirring motor 51a 'is rotated and stirred at high speed for T ₁ second (for example, 1 minute). When the high-speed stirring is completed, lower the stirring intensity and stir at low speed for T ₂ seconds (for example, 3 minutes). It is also possible to set stirring at a high speed stirring T ₁ second, a medium speed stirring T ₂ , and a low speed stirring T ₃ seconds. Depending on the site, the stirring strength and stirring time are adjusted and stirred.

The filtered sample is collected in the filtration section 52e of the inflow filtration tank 52 during the coagulation test in the self-tester tank 51 as described above. When the filtered sample is collected to some degree in the filtration section 52e, the phosphorus concentration measuring device 54 sucks a small amount to start the phosphorus concentration measurement. During the low-speed stirring in the chair, the tester tank 51. When using a concentration meter 54 for measuring the filtration portion (52e), the filtered samples by the suction (PO ₄ -P, phosphate) concentration gathered on Since sufficient filtered water can be stored in the filtration section 52e, measurement of the phosphorus concentration for the filtered sample (sample before the flocculation experiment) is started at that point. The time required to measure the phosphorus concentration may vary depending on the instrument type. A measurement period of at least about 5 minutes, a measurement period of at least about 15 minutes, etc. are known.

When a 5-minute period phosphorus concentration meter (54) is used, the time to inhale the wastewater sample is 30 seconds and the analysis result is 4 minutes later (phosphorus concentration measured at n_cycle, P (n)). When the result is obtained, the phosphorus concentration measuring device 54 performs a constant cleaning by itself for 25 seconds. For the first 25 seconds of the 30-second time to inhale the sample, clean the inside of the aspirator and the instrument with the sample.

Using the concentration {P (n)} obtained from the coagulation experiment obtained here, the calculation control part of the optimal control system is used to calculate the first and second coagulant injection rates and the flocculant efficiency {Cp (n)} do.

As shown in FIG. 6, when the concentration {P (5)} before the coagulation test for five samples is obtained in the fifth cycle, the first field injection rate {O (5)} is {P 5) -Pt} / Cp (4) where Cp (4) is the previously calculated coagulant efficiency at the time of injection, the primary site injection rate is determined and injected into the site.

When the phosphorus concentration measuring device 54 completes the suction of the wastewater sample before the flocculation experiment, the primary washing of the inflow filtration bath 52 is started. That is, when the phosphorus concentration measuring device 54 finishes sucking the wastewater sample, the drain valves 52d and 52d 'of the inflow filtration tank 52 are opened and the sample is discharged. The washing water (constant water) is injected in the lower direction from the upper part of the inflow filtration bath 52 as the washing water supply valve 55a of the washing unit 55 for the inflow filtration bath 52 is opened together with the discharge of the sample, ) And the filter are cleaned. After the washing, the drain valves 52d and 52d 'of the inflow filtration tank 52 are closed after a period of time until the remaining washing water is discharged. At this time, the drain valve 52d on the side of the filtration unit or the drain valve 52d on the inlet side can be kept open when it is opened at the beginning of the next cycle.

When the primary washing of the inflow filtration bath 52 is completed, the coagulated sample is transferred to the inflow portion 52b of the inflow filtration bath 52. That is, the transfer valve 53a of the transfer pipe 53 for transferring the flocculation sample after the first washing of the inflow filtration tank 52 is completed and the drain valve 52d 'of the inflow side of the inflow filtration tank 52 is closed, The coagulated sample is transported from the self-tester tank 51 to the filter 52a of the inflow filtration tank 52 for a certain period of time. When the transfer is completed, the transfer valve 52a is closed. The connection position of the transfer tube 53 with respect to the self-tester tank 51 and the inflow filtration tank 52 is determined in consideration of the selected position of the sample to be transferred and the smooth transfer of the sample. It is preferable that the connection portion of the transfer tube 53 with respect to the self-tester tank 51 is higher than the connection portion of the transfer tube 53 with respect to the inflow filtration tank 52 in order to smoothly transfer the sample.

When the coagulated sample is transferred, the self-tester tank (51) is cleaned. That is, when the conveyance of the coagulated sample (about 1 minute and 20 seconds) is completed and the conveying valve 53a is closed, the drain valve 52d of the self-tester tank 51 is opened to convey the remaining coagulated sample. The discharge of the washing water supply valve 55b of the washing section 55 to the self-tester tank 51 is started and the inside of the tester tank 51 is cleaned (about 30 seconds) ). After the cleaning of the self-tester tank 51, the drain valve 51d of the self-tester tank 51 is closed after the washing water supply valve 55b is closed and the remaining washing water is discharged (about 50 seconds) And is maintained until the next wastewater is supplied. The drain valve 51d may be opened in advance to adjust the amount of the next sample of the self-tester tank 51d.

The concentration of the sample subjected to coagulation and filtration (the sample after the coagulation test) is measured through the phosphorus concentration meter 54. That is, when the coagulated sample is transported to the inflow filtration tank 52 for a certain period of time, and the phosphorus concentration of the coagulated and filtered sample (coagulation experiment sample) collected in the filtration section 52e a few minutes later (P ' (n)) < / RTI >

As shown in FIG. 6, when the phosphorus concentration {P '(5)} is obtained after the coagulation test on five samples, the coagulant efficiency (per unit volume) (5) = {P (5) -P '(5)} / Cj (5) and the coagulant efficiency Cp 5) -Pt} / Cp (5), the amount of the second field coagulant injected is determined and injected into the site.

After the phosphorus concentration measuring device 54 completes the suction of the filtered sample after the coagulation test, the secondary washing of the inflow filtration tank is started. That is, after the measurement of the phosphorus concentration of the sample is started after the coagulation test, the washing water (constant water) is sprayed downward from the upper part of the inflow filtration bath 52 to clean the inside of the inflow filtration bath 52 and the filter 52a. When the washing water collects in the filtered water storage portion, the filtered water storage portion is also cleaned. After the inflow filtration bath 52 has been cleaned, the drain valve 52d 'and the filtrate-side drain valve 52d of the inflow-side filtration tank 52 are closed after a predetermined time elapses until the cleaning residual water is discharged. At this time, the drain valves 52d and 52d 'can be kept open when the valve is opened at the start of the next cycle.

The overall operation of the preprocessing unit 50a and the operation control unit 50b is described in Korean Patent Registration No. 10-1567539 (published on Feb. 11, 2015), in which one of the applicants of the present invention is registered, 10-1567541 (November 11, 2015), detailed description will be omitted here for the sake of simplification of the specification.

The coagulant injection amount controller 50 described above can not only shorten the time of one cycle such that the recent measured value of the phosphorus concentration becomes an approximate value with little error from the actual value of the site, The concentration of phosphorus can be measured after the coagulation test necessary for the calculation of the concentration. Also, by using the preprocessing unit 50a, the coagulant injection amount can be optimized by controlling the coagulant injection rate twice in one cycle. That is, it is possible to determine the coagulant injection rate to be firstly injected into the site according to the phosphorus concentration measured in one cycle section, and to determine the coagulant injection rate to be injected in the second site according to the calculated efficiency of the coagulant, It is possible to optimize the amount of coagulant injected in real time.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken in conjunction with the present invention. It is to be understood that various equivalents and modifications may be substituted for those at the time of the present application. It is to be understood, therefore, that the above description is intended to be illustrative, and not restrictive, and that the scope of the present invention will be defined by the appended claims rather than by the foregoing description, All changes or modifications that come within the scope of the equivalent concept are to be construed as being included within the scope of the present invention.

1: Coagulant injection device for wastewater treatment
10: Compressed air supply line
11: Compressed air supply pipe
13: Bubble generation pipe
15: Bubble generator
17: Connector
20: Coagulant injection line
21: Horizontal tube
23: Congratulatory Jeju Admission
25: injection nozzle
27: Connector
30: Coagulant supply line
40: Flocculant homogenizer
41:
41a: Equal dividing partition
43: first partition
43a: V-shaped notch groove
45: Coagulant feed pipe
47: second partition
50: coagulant injection amount control unit
50a:
50b:
51: Self test group
51a: stirrer
51a ': stirring motor
51c: Wastewater supply valve
51d: drain valve
52: Inflow filtration tank
52a: filter
52b:
52c: Wastewater supply valve
52d, 52d ': drain valve
52e:
53: Transfer pipe
53a: Feed valve
54: Phosphorus concentration meter
55: Cleaning section
56: discharge pipe
60: coagulant storage tank
61: coagulant feed pump

Claims (10)

A flocculant injector for wastewater treatment for injecting a flocculant for coagulating and removing phosphorus contained in wastewater,
A compressed air supply line to which compressed air is supplied;
A horizontal extension pipe branched to the compressed air supply line; an agglomerated grain inlet extending horizontally so as to be immersed in the wastewater and having a plurality of injection nozzles spaced apart from each other; A plurality of coagulant injection lines having a connector;
A plurality of coagulant supply lines coaxially arranged in the horizontal extension pipe of the coagulant injection lines and extending downward only to a certain height of the connection pipe;
A flocculant equalizer feeder connected in parallel to one of the flocculant supply lines, one side of which is connected to a flocculant supply source and the other side of which is connected in parallel to the plurality of flocculant supply lines, and which supplies the flocculant supplied from the flocculant supply source equally to the plurality of flocculant supply lines; And
A coagulant injection amount controller connected to the coagulant equal split feeder and measuring the concentration of phosphorus before the coagulation test and the concentration of phosphorus after the coagulation test of each of the n samples sampled by intervals of the wastewater is controlled to control the amount of the coagulant to be supplied to the coagulant- Including,
The compressed air supply line includes a compressed air supply line connected to a source of compressed air and having one end branch connected to the coagulant injection line, a bubble injector horizontally extended so as to be immersed in the wastewater and positioned correspondingly below the injection nozzle And a connection pipe connecting the compressed air supply pipe and the bubble generation pipe so as to communicate with each other. delete The method according to claim 1,
Wherein the compressed air supply source is a blowing pipe of an aeration tank of a wastewater treatment facility. The method according to claim 1,
Wherein the lower end of the coagulant supply line is located below a center height of the connection pipe of the coagulant injection line. The method according to claim 1,
The flocculant uniformly divided feeder comprises a container body, a first partition wall which divides both sides across the inside of the container body, and a second partition wall which is connected at one end to the coagulant supply source and at the other end to one side of the container body A plurality of first and second partition walls which are vertically arranged in the first partition and which are connected to ends of the coagulant supply line inside the other side of the container body, respectively; And a second partition wall which forms an even partition dividing section. The method of claim 5,
Wherein a V-shaped notch groove is formed in an upper end of the first partition wall for each of the plurality of uniform partitioning sections formed by the second partition wall. The method according to claim 1,
Wherein the coagulant injection amount controller comprises:
The concentration (P (n)) before the agglomeration experiment of each n sample was measured, and according to the injection rate {Cj (n)} of the self-tester coagulant for each n sample, A preprocessing unit for injecting the coagulant before the measurement of {P (n)} and measuring the phosphorus concentration {P '(n)} after the coagulation experiment of each n sample; And
(N) and the coagulant efficiency {Cp (n)} of each n sample are calculated, and the concentration {P (n)} before the coagulation experiment of each n sample and the coagulant efficiency {Cp (n)} of each n sample and controlling the concentration {P (n)} of each n sample to control the injection rate of primary coagulant {O (n)} injected into the coagulant- The coagulant efficiency {Cp (n)} of each n sample is calculated using the phosphorus concentration {P '(n)} after the coagulation experiment of the self-tester tank, (N)} injected into the coagulant-uniformly divided feeder in accordance with the coagulant efficiency {Cp (n)} of each n sample, characterized in that the coagulant injecting rate Device. The method of claim 7,
The pretreatment unit includes a self-tester tank containing a sample of wastewater to be inflowed, a sample of wastewater to be inflowed and a sample of the self-tester tank, an inflow filtration tank in which a filter is installed, A transfer tube for transferring the filtered sample to the inflow filtration tank for filtration, a phosphorus concentration meter for measuring the quality of the filtered sample, a washing section for washing the self-tester tank and the inflow filtration tank, And a discharge pipe for discharging the sample and the washing water contained in the sample,
Wherein the sample transported to the inflow filtration tank by the transfer pipe is provided under the filter of the inflow filtration tank and is filtered. The method of claim 7,
The injection rate {Cj (n)} of the self-tester coagulant for each n sample is calculated by multiplying the second coagulant injection rate {O '(n-1)} or each (n-1) sample interval Is calculated according to the primary coagulant injection rate {O (n-1)} of the coagulant. The method of claim 7,
The coagulant efficiency {Cp (n)} of each n sample is calculated by the following equation: [concentration before the coagulation test {P (n)} - concentration after the coagulation test {P ' Rate {Cj (n)},
The first coagulant injection rate {O (n)} of each n sample section was calculated from the following equation: [concentration of P (n)} - target value (Pt) Is calculated by a relational expression of the efficiency {Cp (n-1)},
The second coagulant injection rate {O '(n)} in the n sample section is calculated by the following equation: [concentration (P (n)} - target value (Pt) before coagulation experiment of each n sample] / coagulant efficiency {Cp n)}. < / RTI >

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