KR101610599B1 - the watertreatment device to improve the flexibility of submerged membrane system installed with Dissolved air floatation in high turbidity and algae-rich conditions and the method thereof - Google Patents

Abstract

The present invention relates to an advanced water purification technology using a dissolved air floatation apparatus and a membrane and, more specifically, to an advanced water treatment device and an advanced water treatment method using a dissolved air floatation tank and a submerged membrane tank, which improves correspondence to an algae-rich and high turbidity condition by reducing contamination load caused by solids and increase in algae in the membrane tank under algae-rich and high turbidity conditions by using DAF. Provided in the present invention is the advanced water treatment device comprising a raw water inlet (100), a flocculator (200), a first membrane tank (300), a second membrane tank (400), and a dissolved air floatation apparatus (500). Also, provided in the present invention is an advanced water treatment device which treats concentrated water untreated in the first membrane tank (300) by allowing the water to pass through the dissolved air floatation device (500), and reinjects treated water treated by entering the dissolved air floatation apparatus (500) to the first membrane tank by being connected with a return line (542).

Description

Technical Field [0001] The present invention relates to a high-altitude water treatment apparatus and an advanced water treatment method using a submerged membrane separation tank and a dissolved air flotation apparatus for high-altitude and high turbidity, conditions and the method thereof}

The present invention relates to an advanced water purification technology using a dissolved air floating apparatus and a separation membrane, and more particularly, to a purification system using a DAF The present invention relates to an advanced water treatment apparatus and an advanced water treatment method using a dissolved air floating tank and a submerged membrane tank,

In general, a membrane separation tank (or membrane separation tank) for filtering microorganisms or foreign substances contained in raw water using a separation membrane without applying disinfectant is applied. In particular, since the immersion separation membrane is directly immersed in a water tank without using a pressure vessel , There is no need for a separate space for the membrane system and suction is performed only by the amount of processing by the vacuum pressure of the suction pump. Therefore, compared with the external circulation type, the area and the power ratio can be reduced. However, In order to solve this problem, air is injected into the membrane separation tank during operation to reduce the adsorption of contaminants onto the surface of the separation membrane, and at the same time, contaminants adsorbed on the separation membrane surface are desorbed If necessary, backwashing the submerged membrane with water and air, By thus suppressing the contamination film phenomenon.

However, even in the case of such an operation, an excessive load is applied to the submerged membrane separator, and when the suspended solids of the treated water are concentrated, the operation difficulty occurs.

That is, in the conventional immersion type membrane water purification method, since one membrane separation tank is installed and installed, the load on the separation membrane is increased and the operation time is shortened. Further, when the suspended matters are concentrated, The recovery time of the treated water is maintained at 85% to 95%, and the sudden change of the enemy water can not be coped with.

In order to solve the above problems, the applicant of the present invention has proposed a method of supplying an input line of a coagulant to a part of a constant introduction pipe by a registered patent (10-0843656, an advanced water treatment apparatus using a two-stage submerged membrane separation tank, Then, the coagulant and the water are mixed with each other through the inline mixer, and the resulting mixture is transported to the coagulation tank. In the coagulation tank, the coagulation efficiency is increased by adjusting the pH of the coagulation tank and then filtered through the first and second monolithic separation membrane tanks The present invention provides a system for supplying post-treatment water, wherein the separation membrane bath is provided with a step of continuously cleaning the submerged separation membrane, which simultaneously supplies air through the lower diffuser and backwashes intermittently to maximize the efficiency of the separation membrane .

The applicant of the present invention described above has the effect of maximizing the efficiency of removing the suspended substances and the efficiency of the separation membrane. However, in the case of high turbidity and high concentration of suspended solids in the high algae, The performance of the separator is deteriorated drastically.

Accordingly, the present invention provides an advanced water treatment apparatus and a water treatment method capable of maximizing efficiency of removal of suspended substances and algae and efficiency of separation membrane by remarkably alleviating the phenomenon of sudden contamination of the membrane of the separation membrane at high turbidity and high algae I want to.

In the case of a water treatment process using a conventional air flotation device (DAF), the entire raw water is treated as a dissolved air flotation device (DAF) by directly applying a dissolved air flotation device (DAF) (DAF), and the maintenance cost of using a large amount of energy and chemicals is large. The present invention has a disadvantage in that it requires a high water treatment to minimize the site area, installation cost, and maintenance cost Device and a water treatment method.

In addition, it is difficult to recover the membranes by chemical cleaning, especially when the membranes are contaminated by algae in the membrane filtration system, and the membranes become unrecoverable if they are exposed to continuous high currents. Therefore, it is necessary to monitor these algae in real time and to respond appropriately. For this purpose, algae measuring devices are generally used. Algae measuring methods include Plate count method and algae measuring device to measure Chl-a concentration in real time Branches are common. In the case of the plate count method, it is possible to more accurately measure the species and the number of the algae actually distributed. However, it is difficult to respond in real time.

In the case of a tidal meter, it has the advantage of measuring the concentration in real time using the inherent wavelength of the tidal current. However, most of these equipments are expensive in foreign countries, and in case of trouble or malfunction of the equipment, they are sent to overseas headquarters for repair, except for simple repairs, resulting in a lot of operational difficulties in the water treatment system requiring information in real time .

In the present invention, a correlation between algae and pH is derived and a simpler and less costly method is applied. In order to solve the above problem, the pH measurement unit installed in the water treatment apparatus is used to install additional equipment The present invention provides a water treatment apparatus capable of easily and easily controlling the process without any problems.

The present invention also relates to a method for recovering a waste water from a waste water, comprising the steps of: injecting coagulant by turbidity into the tank, operating the dissolved air flotation device, operating the recovering rate of the first separation membrane tank and the second separation membrane tank (1 stage: 2 stages = 90: 9 → 1 stage: 14 or 80: 19), thereby maximizing the membrane treatment efficiency.

In addition, the present invention relates to a method for recovering an organic solvent from an aqueous medium, comprising the steps of injecting coagulant by pH during high algae, operating the dissolved air floating device, and changing the recovery rate of the first membrane separation tank and the second separation membrane separation tank (1 stage: 2 stages = 90: 9 → 1 stage: : 14 or 80: 19). When the flocculation agent and the dissolved air flotation device can not control the operation, it is possible to control the membrane treatment efficiency by controlling the maintenance frequency and maintenance concentration of the cleaning chemical when the chlorine injection and the chlorine injection are not controlled by the operation And to provide a water treatment apparatus that maximizes the amount of water.

The present invention also relates to a process for raising the recovery rate (more than 99%) by discharging only the concentrated sludge of the membrane filtration and non-discharge process in the general process and the SS concentration (example, setting Value: 200 mg / L), it is intended to provide a water treatment apparatus which maximizes membrane treatment efficiency by adjusting the operation rate of the dissolved air floating apparatus.

In order to solve the above problems and needs,

A first separation membrane tank 300, a second separation membrane tank 400, and a dissolved air floating apparatus 500. The first water separator 300 and the second separator tank 400 are connected to each other through the water inlet 500,

Further, the present invention is characterized in that untreated concentrated water in the first separation membrane bath 300 is treated through the dissolved air floating apparatus 500,

And a process of connecting the treated water passed through the sophisticated dissolved air lifting device (500) to the return line (542) and reintroducing the treated water into the first separation membrane bath (300) is performed.

Further, the present invention treats the untreated concentrated water of the second separation membrane bath 400 through the dissolved air floating apparatus 500,

And a process of passing treated water passing through the tidal open air floating apparatus (500) through a return line (542) and reintroducing the treated water into the second separation membrane tank (300).

The present invention also relates to a process for adding coagulant to raw water and mixing and mixing in an inline mixer,

A step of coagulating in an aggregation tank,

After the above-mentioned coagulation step, it flows into the first separation membrane bath and filtrates the membrane,

A step of filtering the membrane in the second separation membrane bath after the membrane filtration step of the first separation membrane bath,

Filtration of concentrated water in the second separation membrane bath to the dissolved air floating device to float and separate the membrane-

And a step of flowing the treated water treated in the flotation separation step back into the second separation membrane bath.

A step of adding coagulant to the raw water and mixing and mixing in an inline mixer,

A step of coagulating in an aggregation tank,

After the above-mentioned coagulation step, it flows into the first separation membrane bath and filtrates the membrane,

A step of filtering the membrane in the second separation membrane bath after the membrane filtration step of the first separation membrane bath,

A step of transferring the membrane-unfiltered concentrated water of the first separation membrane bath to a dissolved air floating apparatus to float and separate,

And a step of flowing the treated water treated in the flotation separation step back into the first separation membrane bath.

Further, the present invention is characterized in that the raw water portion 110-1,

A raw water inflow section 100 for introducing the raw water to be treated in the raw water section into the coagulation tank,

An agglomeration tank 200 having an agitator to cause flocculation reaction between raw water and flocculant to form floc,

A first separation membrane tank 300 for filtering out flocs formed in the flocculation tank,

A second separation membrane tank 400 for filtering and removing flocs from the concentrated unprocessed residual water in the first separation membrane bath,

A dissolved air floating device 500 for removing untreated concentrated water from the second separation membrane bath to remove sludge and algae concentrated by floating separation,

And an integrated control unit (600) for performing overall control of each configuration of the altitude water treatment apparatus,

The raw water portion 110-1 is provided with a PH measuring portion 610 for measuring PH of raw water,

A turbidity measuring unit 620 for measuring the turbidity of the raw water is constituted,

The raw water inflow section 100 includes a raw milk inflow inlet 110, a flocculant inlet pipe 120, an inline mixer 130 for mixing raw water and a flocculant, and a coagulant inflow control section 630 are added,

In the coagulation bath 200, a transferring soju inlet 140 is added, and a chlorine injection control unit 640, which is controlled by an integrated controller,

The second separation membrane tank 400 is provided with a solids measurement unit 650 for measuring the concentration of the solid in the treatment water and a TMP measurement unit 660 for measuring the differential pressure of the membrane filtration.

In the second separation membrane bath 400, a holding and cleaning agent injector 141 is added,

The integrated control unit 600 may be configured such that when the reference value PS of the PH is established and the PH measurement value measured by the PH measurement apparatus is equal to or greater than the reference value, The control unit 630 inputs a coagulant injection command, and the coagulant is input to perform the process control so as to perform the water treatment,

If the measured PH value of the raw water is equal to or greater than the reference value PS of PH in the integrated controller 600, the process control is performed to change the recovery rates of the first and second separation membrane tanks,

The integrated controller 600 controls the dissolved air flotage apparatus 500 to operate in a water treatment mode when the PH measurement value of the raw water is equal to or greater than the reference value PS of PH.

In the present invention, the turbidity reference value ST for the turbidity of raw water is preset in the integrated controller 600. When the turbidity of the raw water measured by the turbidity measurement unit 620 is equal to or greater than the turbidity reference value, A flocculant is injected into the flocculant 630,

If the turbidity measurement value of the raw water is equal to or greater than the turbidity reference value ST, the integrated controller 600 controls the dissolved air flotation device DAF to operate,

Wherein the integrated controller (600) performs the process control to change the recovery rates of the first and second separation membrane baths when the turbidity measurement value of the raw water is equal to or greater than the turbidity reference value (ST).

The present invention also provides an advanced water treatment apparatus characterized in that, when the influent water to be treated flows into a high turbidity or high algae concentration, the process is controlled so as to change the recovery rates of the first separation membrane bath and the second separation membrane bath.

Further, in the present invention, the reference value for the solid concentration of the second separation membrane bank is set in the integrated controller 600,

When the solids concentration measured by the solids measurement unit 650 of the second separation membrane bath 400 is lower than the reference value, the dissolved air floatation apparatus 500 is operated without discharging the concentrated water of the second separation membrane bath, And a process of controlling to discharge only the concentrated sludge through the collection chamber discharge line 551 of the apparatus is performed.

Further, in the present invention, the reference value for the solid concentration of the second separation membrane bank is set in the integrated controller 600,

When the solids concentration measured by the solids measuring unit 650 of the second separation membrane bath 400 is lower than the reference value, the dissolved air floating apparatus 500 is intermittently operated to reduce the required energy of the dissolved air floatation apparatus Thereby providing an advanced water treatment apparatus.

In the high-temperature water treatment apparatus and the water treatment method according to the present invention, the high-temperature water treatment apparatus and the water treatment method are connected such that the process of the dissolved air floating apparatus (DAF) is applied after the first or second separation membrane bath, DAF) is re-introduced into the first or second separation membrane bath to prevent contamination of the separation membrane such as fouling on the surface of the separation membrane.

Accordingly, the present invention removes only high-concentration sludge and algae, and the treated water is sent back to the membrane separation tank. The turbidity and turbidity of the membrane separation membrane at the time of high tide are significantly reduced, The efficiency can be maximized.

Further, the advanced water treatment apparatus and the water treatment method according to the present invention are connected so that the dissolved air floating apparatus (DAF) process is applied to the treated water through the membrane separation tank, so that only sludge and algae of high concentration are removed and the treated water is sent again to the separation membrane tank (DAF) process compared to the process of treating the entire raw water with the dissolved air floating device (DAF), and the maintenance cost such as energy consumption and drug consumption can be reduced accordingly Advantages and high concentrations of sludge and algae are targeted and treated with a dissolved air flotation device, resulting in a remarkably high treatment efficiency.

The high water treatment apparatus according to the present invention analyzes the correlation between the pH and the algae concentration (Chl-a) rather than the existing algae meter (high price, foreign acid) and controls the coagulant injection according to the pH value installed in the field, The effect of maximizing the membrane treatment efficiency in response to algae appears.

Further, the high-temperature water treatment apparatus according to the present invention can perform a membrane filtration-free discharge process, thereby achieving an improvement in recovery rate (99% or more) and minimizing a concentrated water treatment facility compared with the conventional membrane separation and separation system appear.

Further, the high-temperature water treatment apparatus according to the present invention enables stable operation by appropriately distributing the first and second pollutant loads by changing the recovery rate of the separation membrane bath and removing membrane contaminants by the dissolved air floating apparatus even in the case of high algae and high turbidity .

Further, the high-temperature water treatment apparatus according to the present invention has an effect of minimizing an increase in the differential pressure of the separation membrane, thereby reducing the frequency of chemical cleaning due to membrane contamination and prolonging the life of the separation membrane.

1 is a conceptual diagram of an advanced water treatment apparatus using a dissolved air floating apparatus and a submerged membrane separation tank according to the present invention.
2 is a conceptual diagram showing another embodiment of an advanced water treatment apparatus using a dissolved air floating apparatus and a submerged membrane separation tank according to the present invention.
3 is a conceptual diagram of a dissolved air floating apparatus according to the present invention.
FIG. 4 is a conceptual diagram of an advanced water treatment apparatus using the dissolved air floating apparatus and the immersion type membrane tank according to the present invention and controlling the process at high turbidity and at high tide
FIG. 4B is a conceptual view of the process control of an advanced water treatment apparatus using the dissolved air floating apparatus and the immersion type membrane tank according to the present invention and controlling the process at high turbidity and high algae.
FIG. 4B is a conceptual diagram of a dissolved air floating apparatus and a submerged membrane separation tank in the case of a general treatment process of an advanced water treatment apparatus according to the present invention. FIG.
5 is a flowchart of one embodiment of process control at high turbidity and high tide for an advanced water treatment apparatus according to the present invention.
Figure 5b is a flow chart of another embodiment of process control at high turbidity and high algae for an advanced water treatment apparatus according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings.

The present invention provides an advanced water treatment apparatus including a raw water inflow section 100, a flocculation tank 200, a first separation membrane tank 300, a second separation membrane tank 400, and a dissolved air floating apparatus 500.

The present invention also provides an advanced water treatment method comprising the steps of carrying out the above-described construction.

The raw water inflow part 100 of the present invention includes a raw water inflow inlet 110, a coagulant inflow pipe 120, and an inline mixer 130 for mixing the raw water and the flocculant to introduce raw water into the flocculation tank .

The raw milk infusion inlet 110 means an apparatus or means for introducing raw water to be treated.

In the present invention, the raw water introduced into the above-described raw milk infusion means water to be treated such as water, sewage or wastewater, and is preferably more suitable for constants.

In the present invention, a screen may be installed on the upper portion of the raw milk inflow inlet 110 to provide raw water from which contaminants have been removed.

The above-mentioned coagulant inlet pipe 120 means an apparatus or means that performs the function of injecting coagulant into the raw water to be treated using a conventional pump.

The flocculant to be injected into the above flocculant inlet pipe of the present invention is a concept including conventional flocculant and flocculant aid.

The flocculant used in the present invention may be selected from the group consisting of aluminum sulfate, ferrous sulfate, ferric sulfate, ferric chloride, potassium alum, PAC (poly aluminum chloride), sodium aluminate, ammonium alum, Iron salts such as calcium hydroxide, calcium oxide, activated silicic acid and polymer flocculant, and aluminum flocculants, etc.

The above-mentioned coagulation assistant refers to a drug added to increase the performance of the coagulant to increase the effect. In the present invention, calcium sulfate, soda ash, caustic soda, or the like may be used as the pH adjusting alkali as the coagulation assistant. Examples of commonly used inorganic coagulation assistants include bentonite, activated silicic acid, cement dust, and fly ash. As the organic coagulation assistant, cationic polyacrylamines, polyethyleneamines, anionic polyacrylic acids and the like can be used.

The in-line mixer 130 of the present invention means an apparatus or means for mixing the above-mentioned raw water and the flocculant.

The flocculation tank 200 of the present invention means a reaction tank or means for allowing the treated water subjected to the mixing process of the above-mentioned inline mixer to cause an aggregation reaction.

The flocculation tank 200 of the present invention is equipped with a stirrer 210 as a conventional tank-type reaction tank to cause flocculation reaction of raw water and flocculant to form floc.

The flocculation tank 200 may be provided with PH adjusting means 220 such as an apparatus for injecting acid or base chemicals so as to appropriately flocculate the flocculation tank 200 to adjust the pH of the flocculation tank.

In the present invention, a process is performed in which the treated water passed through the coagulation bath is treated as a first separation membrane bath.

The first separation membrane bath 300 of the present invention means a treatment water tank provided with a first membrane filtration device 310 capable of filtering out flocs formed in the flocculation tank.

The membrane of the first separation membrane apparatus may be of various types, and may be a microfiltration membrane (MF) or a hollow fiber type ultrafiltration membrane (UF). Preferably, the separation membrane unit is integrated It is recommended to install in module form.

Further, the present invention can freely select and use an organic film or an inorganic film with a structure that reduces contamination or damage of the film.

If the filtration is made long in a general separation membrane process, there arises a problem of membrane contamination such as clogging of membranes and decomposition of organic matters. Due to these problems, oxidative agents such as NaOCl are often used to control membrane contamination in general membrane processes.

The removal of the membrane fouling of the membrane separation membrane of the present invention can be cleaned by backwash, air, physical movement (impact such as vibration), and the like, but it is preferable to adopt the air cleaning method as described above.

In the present invention, the treated water passed through the first separation membrane device 310 of the first separation membrane bath is discharged to the first treated water discharge line 320.

The present invention is characterized in that the residual raw water that has not been treated in the first separation membrane tanks flows into the second separation membrane tanks and is subjected to separation membrane treatment.

The untreated concentrated water of the first separation membrane bath is introduced into the second separation membrane bath through the concentrated water conveyance line 330.

The second separation membrane bath 400 of the present invention has the same structure as the first separation membrane bath 300.

Therefore, the second separation membrane tank 400 means a treatment water tank provided with a second membrane filtration device 410 capable of filtering out flocs from raw water concentrated in the first separation membrane tank.

In the present invention, the treated water passed through the second separation membrane apparatus 410 of the second separation membrane bath is discharged to the second treated water discharge line 420.

The technical feature of the present invention is that the throughput of the second separation membrane bath is less than that of the first separation membrane treatment, thereby enabling long-term operation.

That is, in the present invention, for example, it is preferable to set the flux of the first separation membrane bath at 30 to 50 L / m 2 · hr and the flux of the second separation membrane bath at a ratio of 15 to 25 L / m 2 · hr.

That is, the ratio of the treated water Q1 treated in the first separation membrane bath to the treated water Q2 treated in the second separation membrane bath is about 3: 1 to 2.

This serves to minimize clogging of the separation membrane by dispersing the impact of the suspended concentration of the raw water flowing in the first separation membrane bath.

The raw water that has been introduced into the second separation membrane is again filtered by the suction pump through the second membrane filtration device by differential pressure to be treated with treated water.

The bottom of the submerged separation membrane in the second separation membrane bath continuously blows air through the air diffuser during operation in the same manner as the first separation membrane membrane, thereby removing suspended matters accumulated in the separation membrane, thereby improving the efficiency of the treated water.

The applicant of the present invention described above can stably maintain the operation of the apparatus by discharging the untreated internal concentrated water of the second separation membrane tank through the discharge pump within a range of 1 to 2 volume% It is possible to reduce the waste disposal cost by minimizing the generation of waste.

However, the prior art has a problem that it is difficult to apply it to raw water of high algae and high turbidity, and the present invention is a technical feature that a structure for solving the problem is added.

In the present invention, untreated concentrated water in the first or second separation membrane bath is treated by passing through the dissolved air floating device 500, the sludge and algae concentrated in the separation membrane bath are treated with a Dissolved Air Floatation device , DAF) to minimize the effect of sludge and algae on the separation membrane.

3, the above-described dissolved air floating apparatus (DAF) of the present invention includes an influent zone 510, a contact zone 520, a separation zone 530, an effluent zone 540, and a collecting chamber 550.

A micro-bubble injector 521 for injecting micro-bubbles is additionally provided below the contact portion 520.

Such a micro-bubble injecting apparatus is usually provided such that a nozzle for generating micro-bubbles is installed in a nozzle header.

The nozzle header serves to uniformly distribute the air saturated liquid through the pressurized nozzle to each of the installed nozzles. As the saturated liquid passes through the nozzle, minute bubbles are generated. Further, the fine bubble injecting apparatus includes a plurality of nozzle heads

May be provided.

The inflow section serves to equalize the inflow flow. Thereafter, fine bubbles injected from the lower portion of the contact portion 520 are attached to the suspended particulates.

The preferably designed contact 520 facilitates the collision between microbubbles and suspended particulates.

The inclination from the lower portion to the upper portion of the baffle of the contact portion 520 as shown in Fig. 3 causes the volume of the contact portion 520 to increase from the lower portion to the upper portion.

This increase in the volume of the contact portion 520 reduces the flow rate of the influent water in the contact portion 520 and causes turbulence.

Therefore, the microbubbles generated by the microbubble injector 521 adhere to the suspended material in the treatment water, and the floating material to which the microbubbles adhere is adhered to the water surface as the inflow water flows to the separation unit 530 It will rise.

Accordingly, the treated water from which various pollutants including suspended substances in the treated water are removed is discharged to the bottom of the separating part 530.

The treated water discharged to the bottom of the separation unit 530 flows into the discharge unit 540 and is discharged to the treated water discharge line 541 of the discharge unit.

In addition, the suspended solids in the treatment water described above are discharged to the collection chamber 550 and discharged to the collection chamber discharge line 551 to be treated.

The technical feature of the present invention is that the untreated concentrated water of the second separation membrane bath 400 is treated through the dissolved air floating device 500 and the treated water that has been treated through the dissolved air floating device is re- (400).

The untreated concentrated water of the second separation membrane bath is introduced into the inlet 510 of the dissolved air floating apparatus 500 through the concentrated water inflow line 430.

That is, as shown in FIG. 1, the present invention connects the treated water discharge line 541 of the discharge portion 540 of the dissolved air floating device 500 to the transfer line 542 connected to the second separation membrane bath, The process of re-flowing the treated water into the second separation membrane bath 400 is performed.

The technical feature of the present invention is that the untreated concentrated water of the first separation membrane bath 300 is treated through the dissolved air floating device 500 and the treated water passed through the dissolved air floating device is re- 1 separator tank 300, as shown in FIG.

The untreated concentrated water of the first separation membrane bath flows into the inlet 510 of the dissolved air floating apparatus 500 through the concentrated water inflow line 430.

That is, as shown in FIG. 2, the present invention connects the treated water discharge line 541 of the discharge portion 540 of the dissolved air floating apparatus 500 to the return line 542, And then flows into the separation membrane bank 300 again.

In addition, the present invention is characterized in that the treated water discharged to the treated water discharge line 541 of the discharge portion 540 of the above-described dissolved air floating apparatus 500 is connected to the return line 542 in the first and second separation membrane tanks It is characterized in that it is possible to perform the process of selectively flowing the treated water of the dissolved air floating device into the first separation membrane bath 300 or the second separation membrane bath 400.

As described above, according to the present invention, when the raw water of high algae flows in the process of transferring and processing the concentrated water treated in the first separation membrane bath to the second separation membrane bath, which is composed of the first separation membrane bath and the second separation membrane bath, (DAF) is applied to the concentrated water in the separation membrane tank or the second separation membrane tank to remove the suspended substances (sludge and algae) in the concentrated water, and then the treated water having been removed from the concentrated water is introduced again into the first separation membrane tank or the second separation membrane tank Sludge and algae can be minimized, thereby maximizing the treatment efficiency.

Further, the present invention is characterized in that the effect on the film of the first or second separation membrane bath can be minimized by flexibly operating the recovery rates of the first and second separation membrane baths.

That is, the conventional separation membrane process is operated with a fixed recovery rate in the first separation membrane and the second separation membrane, and the ability to minimize the effect on the separation membrane due to the property change of the influent water is insufficient. In this case, the dissolved air floating device (DAF) effectively removes the solids from the separation membrane bath, and the recovery rate of the first separation membrane bath or the second separation membrane bath can be changed according to the raw water conditions, thereby enabling the operation of the process.

In the conventional two-stage separation membrane process, the recovered water in the first separation membrane tank is 90% of the total influent water, and in the second separation membrane tank, 9% of the total influent water is recovered as treated water and 1% Structure.

That is, the suspended solid concentration of the influent water flowing into the first separation membrane tanks is 200 to 300 ppm, and the SS concentration of the concentrated influent water flowing into the second separation membrane tanks is about 2000 ppm, so that the solid matter load of the second separation membrane tanks do.

The present invention is characterized in that the solidified material in the second separation membrane bath is significantly reduced as the untreated concentrated water in the second separation membrane bath is introduced into the second separation membrane bath through the dissolved air floating unit (DAF) Action and effect.

This action adjusts the recovery rate of the treated water in the first separation membrane tank to 80 to 85% of the total influent water. In the second separation membrane tank, 14.5 to 19.5% of the total influent water is recovered as treated water and 0.5 of the remaining influent water is discharged as concentrated water To perform the function that can be performed.

Therefore, when the influent to be treated is introduced at a high turbidity and a high concentration of algae, the operation of recovery rates of the first and second separation membrane tanks, that is, the treatment of the first separation membrane tanks in the case of high turbidity and high tide, The recovery rate is adjusted to 80 to 85% of the total influent, and the second separation membrane tank collects 14.5 to 19.5% of the total influent water as treated water, thereby reducing the solid load of the first separation membrane and increasing the recovery rate of the second separation membrane. Efficiency is improved.

In addition, in the case of the conventional separator composed of the first stage and the second stage, the recovery rate can be operated up to 99%, but the process according to the present invention is characterized in that the recovery rate can be increased up to 99.5% or more.

In the case of separation membrane process using dissolved air floating device (DAF), dissolved air floating device (DAF) is applied directly to the influent water to treat the entire raw water as a dissolved air floating device (DAF) A large amount of energy is injected into the reactor, resulting in a significant decrease in efficiency.

However, since the dissolved air floating apparatus (DAF) process according to the present invention is connected to the treated water through the separation membrane bath, only the sludge and algae of high concentration are removed, and the treated water is sent back to the separation membrane tank. (DAF) process compared to the process of treating with air floating device (DAF), it is possible to reduce the energy consumption accordingly, and it is also possible to target the sludge and algae of high concentration to be dissolved And the treatment efficiency is remarkably high due to treatment with an air floating apparatus.

The present invention provides an advanced water treatment apparatus having the above-described structure.

The present invention also provides an advanced water treatment method comprising the steps of carrying out the above-described construction.

The present invention relates to a process for adding coagulant to raw water and mixing and mixing in an inline mixer,

A step of coagulating in an aggregation tank,

After the above-mentioned coagulation step, it flows into the first separation membrane bath and filtrates the membrane,

A step of filtering the membrane in the second separation membrane bath after the membrane filtration step of the first separation membrane bath,

Filtration of concentrated water in the second separation membrane bath to the dissolved air floating device to float and separate the membrane-

And a step of flowing the treated water treated in the flotation separation step back into the second separation membrane bath.

The present invention also relates to a process for adding coagulant to raw water and mixing and mixing in an inline mixer,

A step of coagulating in an aggregation tank,

After the above-mentioned coagulation step, it flows into the first separation membrane bath and filtrates the membrane,

A step of filtering the membrane in the second separation membrane bath after the membrane filtration step of the first separation membrane bath,

A step of transferring the membrane-unfiltered concentrated water of the first separation membrane bath to a dissolved air floating apparatus to float and separate,

And a step of flowing the treated water treated in the flotation separation step back into the first separation membrane bath.

The present invention also relates to a process for adding coagulant to raw water and mixing and mixing in an inline mixer,

A step of coagulating in an aggregation tank,

After the above-mentioned coagulation step, it flows into the first separation membrane bath and filtrates the membrane,

A step of filtering the membrane in the second separation membrane bath after the membrane filtration step of the first separation membrane bath,

A step of selectively floating the unfiltered concentrated water in the first separation membrane bath or the second separation membrane bath to the dissolved air floating apparatus to float and separate,

And a step of selectively introducing the treated water treated in the flotation separation step into the first separation membrane tanks or the second separation membrane tanks again without filtration of the membrane-filtered concentrated water of the first separation membrane tanks or the second separation membrane tanks .

The present invention provides an advanced water treatment method including a process having the above-described constitution.

The technical feature of the present invention is that the above- In high turbidity  Coagulant injection or In high algae  Coagulant injection, Ex Chlorine  A process for controlling the maintenance frequency of the film, a concentration of the cleaning liquid for maintenance, and the like, Water-treated  Altitude Water treatment device  .

Further, it is a technical feature to provide a water treatment apparatus which is highly water-treated according to high turbidity and / or high algae, in addition to a configuration enabling the above-described control configuration of the present invention.

The present invention can be applied to a water treatment system including a raw water portion 110-1, a raw water inflow portion 100, an aggregation tank 200, a first separation membrane tank 300, a second separation membrane tank 400, a dissolved air floating device 500, 600,

A pH measuring unit 610 and a turbidity measuring unit 620 are configured in the raw water unit 110-1,

The raw water inflow part 100 includes a raw milk inflow pipe 110, a coagulant infusion pipe 120, and an inline mixer 130 for mixing the raw water and the coagulant. The coagulant infusion control part 630 is added,

The flocculant tank 200 is provided with an inlet 140 for transferring contaminants, a chlorine injection control unit 640 for introducing contaminants,

In the second separation membrane bath 400, a solids measurement unit 650 and a TMP measurement unit 660 are added,

The second separation membrane bath (400) is provided with a holding and cleaning agent injector (141).

The present invention can be applied to a water treatment system including a raw water portion 110-1, a raw water inflow portion 100, an aggregation tank 200, a first separation membrane tank 300, a second separation membrane tank 400, a dissolved air floating device 500, 600,

A pH measuring unit 610 and a turbidity measuring unit 620 are configured in the raw water unit 110-1,

The raw water inflow part 100 includes a raw milk inflow pipe 110, a coagulant infusion pipe 120, and an inline mixer 130 for mixing the raw water and the coagulant. The coagulant infusion control part 630 is added,

The flocculant tank 200 is provided with an inlet 140 for transferring contaminants, a chlorine injection control unit 640 for introducing contaminants,

In the second separation membrane bath 400, a solids measurement unit 650 and a TMP measurement unit 660 are added,

The second separation membrane tank 400 is provided with a holding cleaning chemical injector 141 to control the process according to the high turbidity and the high tide by the integrated controller 600. [ to provide.

The present invention provides an advanced water treatment apparatus through process control of coagulant injection, raw air flotation (DAF) operation, first separation membrane preparation, and recovery rate change operation of a second separation membrane tank during high turbidity of raw water.

In the present invention, the second separation membrane bath (400) comprises the solids measurement unit (650), so that the concentration of the solid matter in the treated water treated in the second separation membrane bath can be measured.

The solid matter measurement unit 650 refers to a conventional apparatus or means for measuring the concentration of suspended solids (SS) of treated water in the second separation membrane bath, and transmits the measured solid matter concentration information to the integrated controller 600 Function.

Accordingly, the solids measuring unit 650 may include hardware such as a solids concentration measuring sensor, an MCU or CPU, an information processing device such as a CPU, a memory, and a data transmitting / receiving device, and a measurement program or the like may be mounted on the hardware.

The present invention is characterized in that the operation of the first separating membrane tank, the second separating membrane tank, and the dissolved air floating apparatus 500 is controlled by the integrated controller 600 based on the information measured by the solids measuring unit of the second separating membrane tank, .

When the solids concentration (SS concentration) measured by the solids measurement unit of the second separation membrane bath is equal to or lower than the reference value, the dissolved air floating apparatus 500 is set to the integrated controller 600, Thereby lowering the operating rate of the vehicle.

The lowering of the operating rate of the dissolved air floating apparatus 500 means that the amount of the treated water flowing into the dissolved air floating apparatus 500 in the second separation membrane tank is reduced or the dissolved air floating apparatus 500 is intermittently .

The above-described dissolved air floating apparatus 500 discharges the concentrated sludge through the collection chamber discharge line 551.

When the solids concentration (SS concentration) measured by the solids measurement unit of the second separation membrane bath is below the reference value, the integrated controller 600 does not discharge the concentrated water to the concentrated water discharge line 422 of the second separation membrane bath Respectively.

Conventional operation of the separation membrane bath in the water treatment system or system performs a process of discharging the concentrated water through the concentrated water outlet 422. [

However, when the solids concentration (SS concentration) of the second separation membrane bath of the present invention is equal to or lower than the reference value, the dissolved air floating apparatus 500 is operated without discharging the concentrated water to the concentrated water discharge line 422 of the second separation membrane bath The operation rate is lowered to control the operation and the dissolved air floating apparatus 500 has an effect of improving the recovery rate of the treated water by 99% or more through process control for discharging only the concentrated sludge through the collection chamber discharge line 551.

In the present invention, when the solids concentration (SS concentration) measured by the solids measurement unit of the second separation membrane bath is below the reference value, it means that the solid concentration of the second separation membrane treated water is low. Generally, .

However, the reference value of the solid concentration can be freely set by the user according to the quality of the raw water as one embodiment.

In the present invention, when the solids concentration (SS concentration) measured by the solids measurement unit of the second separation membrane bath is below the reference value, it means that the solids concentration is normal.

The present invention performs the step of not discharging the concentrated water of the second separation membrane bath even when the solid concentration is normal.

In the present invention, when the concentration of the solid substance is normal, that is, when the solid substance concentration (SS concentration) measured by the solid substance measurement section is not more than the reference value, the dissolved air floating device 500 So that only the concentrated sludge is discharged through the collection chamber discharge line 551 of the dissolved air floating apparatus.

In this general case, the present invention creates the effect of raising the recovery rate by more than 99% by controlling the process of discharging only the concentrated sludge through the collection chamber discharge line 551 of the dissolved air floating apparatus.

The integrated control unit 600 of the present invention controls the discharge of the concentrated water discharge line 422 of the second separation membrane bath and controls the amount of the treated water flowing into the dissolved air floating apparatus 500, And controls the operation of the air lifter 500.

The turbidity measurement unit 620 of the present invention means an apparatus or means installed in the raw water unit 110-1 and capable of measuring the turbidity of raw water and transmits the turbidity measurement data to the integrated control unit 600 Function.

Therefore, the turbidity measuring unit may be equipped with hardware such as a turbidity measuring probe, an information processing device such as an MCU or a CPU, a memory, and a data transmitting / receiving device, and a measurement program or the like may be mounted on the above hardware.

As shown in FIG. 5, the technical feature of the present invention is that the turbidity reference value ST for the turbidity of raw water is preset in the integrated controller 600, and the turbidity of the present raw water measured by the turbidity measurement unit is equal to or higher than the turbidity reference value The coagulant injection control unit 630 inputs the coagulant injection instruction to the coagulant injection control unit 630 to inject the coagulant into the water treatment unit.

In the present invention, when the turbidity measurement value of the raw water is equal to or greater than the turbidity reference value ST in the integrated controller 600, the dissolved water flotation device DAF is operated to transport the treated water to the second separation membrane bath .

In the present invention, if the turbidity measurement value of the raw water is equal to or greater than the turbidity reference value ST, the integrated controller 600 controls the recovery rate of the first and second separation membrane baths.

That is, the integrated control unit 600 of the present invention controls the operation of the dissolved air floating apparatus (DAF) and the control of whether the treated water is returned or not.

The integrated control unit 600 of the present invention controls the recovery rate changing operation of the first and second separation membrane baths.

The above-described control can be realized by controlling the flow rate of the treated water flowing into the first and second separation membrane tanks, and the valve control method, and various other methods can be adopted.

As described above, the technical feature of the present invention is that if the raw water is not high turbidity in the integrated controller 600, the recovery rate of the first and second separation membrane tanks is set to be 90: 9, 2 membrane is controlled to operate at a recovery rate of 85:14 to 80:19, thereby minimizing membrane contamination and improving the treatment efficiency even in the case of high turbidity.

Whether the above-mentioned raw water has high turbidity can be set to be not turbidity when the turbidity unit is less than 50 NTU (nephelometry turbidity unit), and this criterion can be set differently according to the property of the element and the demand of the user.

As described above, the recovery ratio of the first and second separation membrane baths is 90: 9. The recovery rate of the treated water of the first separation membrane bath of the recovery ratio is adjusted to 90% of the total influent water. In the second separation membrane bath, 9% And to discharge 1% of the remaining influent water to the concentrated water.

In the membrane filtration system of the water treatment apparatus according to the present invention, algae is one of the main causes of membrane contamination. In order to monitor the algae in real time and properly cope with it, the algae measuring apparatus is generally used. However, Is the most technological feature that it is easier and more cost effective.

Two methods are commonly used to measure the Chl-a concentration in real time using the plate count method and the tide measuring device. In the case of the plate count method, it is possible to more accurately measure the species and the number of the algae actually distributed. However, it is difficult to respond in real time.

In the case of a tidal meter, it has the advantage of measuring the concentration in real time using the inherent wavelength of the tidal current. However, most of these equipments are expensive in foreign countries, and in case of trouble or malfunction of the equipment, they are sent to overseas headquarters for repair, except for simple repairs, resulting in a lot of operational difficulties in the water treatment system requiring information in real time .

In order to solve such problems, the present invention provides a water treatment apparatus that can easily and easily control a process without using additional equipment by utilizing a pH measuring unit installed in the water treatment apparatus.

As described above, in the present invention, a PH measuring unit 610 and a turbidity measuring unit 620 are configured in the raw water unit 110-1.

The raw water part 110-1 of the present invention means an apparatus or means in which water (raw water) to be treated as a river or a lake is stored, and raw water is transferred from the raw water part to the raw water inflow part 100. [

As shown in FIG. 4, the PH measuring unit 610 is installed in the raw water unit 110-1 to measure the PH of the raw water and transmit the measured PH data to the integrated controller 600. FIG.

The above-mentioned PH measuring unit means an apparatus or means for measuring a normal PH.

Therefore, the PH measuring unit is provided with hardware such as a PH measurement probe, an information processing device such as an MCU or a CPU, a memory, and a data transmitting / receiving device, and a measurement program or the like can be mounted on the above hardware.

As described above, the integrated control unit 600 of the present invention means an apparatus or means that performs a function of collectively controlling the respective configurations of the advanced water treatment apparatus of the present invention.

Accordingly, the integrated control unit 600 refers to an apparatus or means including hardware such as a central processing unit, a memory, a data transmission / reception device, a control device, and a monitor, and an application program installed on the hardware.

The meaning of the above-mentioned central processing unit is used as a general meaning of a means or a device that is provided with a CPU, a micro controller unit (MCU), a RAM or a ROM, etc. to drive the software.

In the present invention, the PH measuring unit 610 is configured to be interlocked with the integrated controller 600.

In the integrated control unit of the present invention, the initial data of the correlation between the PH measurement data of the raw water and the concentration of the algae of the raw water is inputted.

That is, when the concentration of the algae in the raw water increases, the PH of the raw water generally increases.

Therefore, the PH value measured according to the algae concentration (Algae Concetration) is preset and the correlation data of the algae and the PH are stored in the integrated controller.

5, in the present invention, when the reference value PS of PH is set in the correlation data of the above-mentioned algae and PH and the measured value of PH is more than the reference value, the integrated controller 600 controls the coagulant infusion control unit 630 ), And the coagulant is injected into the water treatment system to perform water treatment.

The above-mentioned coagulant injection control unit 630 refers to an apparatus or means for performing a function of controlling the coagulant dosing device and the amount of the coagulant to be fed, in response to an instruction of whether or not the coagulant is injected in the integrated control unit 600.

In the present invention, when the PH measurement value measured by the PH measuring unit of the raw water unit is equal to or greater than a predetermined reference value PS of the PH set in the integrated controller 600, the integrated controller 600 controls the coagulant load control unit 630 So that the coagulant is injected.

In the present invention, when the PH measurement value of the raw water is equal to or greater than the predetermined reference value PS of the PH set in the integrated controller 600 in the integrated controller 600, the dissolved air floating device (DAF) (DAF) to process the treated water treated in the dissolved air floating device (DAF) to the second separation membrane bath.

In the present invention, if the measured PH value of the raw water is equal to or greater than the reference value PS of PH in the integrated controller 600, the process control is performed to change the recovery rate of the first and second separation membrane baths.

That is, when the integrated control unit 600 determines that the PH measurement value of the raw water is equal to or greater than the reference value PS of PH, the process control is performed so that the recovery rates of the first and second separation membrane baths are 85: 14 to 80:19, The contamination of the resist film is minimized and the film processing efficiency is improved.

If the integrated control unit 600 determines that the PH measurement value of the raw water is equal to or greater than the reference value PS of PH, the dissolved air floating apparatus 500 is operated to control the water treatment.

In the case where it is determined that the operation control is not performed well even when the flocculant is injected by the PH measurement value at the time of the high algae, the operation of the dissolved air floating device (DAF), the operation of changing the recovery rate of the first separation membrane bath and the recovery of the second separation membrane bath A process of injecting total chlorine is added.

In the present invention, the integrated controller 600 determines that the operation control is not performed well.

The TMP measurement unit 660 is interlocked with the integrated control unit 600 to determine whether the operation control is performed using the membrane filtration differential pressure information.

As shown in FIGS. 4 to 4C, the TMP measurement unit 660 is provided in the second separation membrane tank 400 to transmit the membrane filtration differential pressure information of the second separation membrane tank to the integration controller 600.

The TMP measuring unit 660 means an apparatus or means for measuring the differential pressure of normal membrane filtration. The TMP measuring unit 660 may be a device for measuring the difference between the pressure of the inlet portion of the separation membrane bath and the pressure of the outlet portion.

The TMP measuring unit 660 may include hardware such as a membrane filtration differential pressure sensor, an information processing device such as an MCU or a CPU, a memory, and a data transmission / reception device, and a measurement program may be installed in the hardware.

As shown in FIG. 5, the TMP measuring unit 660 of the present invention measures the membrane filtration differential pressure of the second separation membrane bank 400 and transmits the membrane filtration differential pressure information to the integration controller 600.

In the integrated controller 600, the membrane filtering differential pressure reference value SP is set in advance for the membrane filtration differential pressure information of the second separation membrane bath 400.

The TMP measuring unit 660 of the present invention transmits the membrane filtration differential pressure information obtained by measuring the membrane filtration differential pressure during the water treatment operation to the integrated controller 600.

In this case, it is determined that the operation control is not performed in the case where the membrane filtration differential pressure measurement value is equal to or greater than the predetermined membrane filtration differential pressure reference value SP, and the transmitted membrane filtration differential pressure measurement value is preliminarily set (SP), it is judged that the operation control is good.

When the integrated controller 600 determines that the operation control is not performed well at the time of high tide, the control unit 600 controls the introduction of the total chlorine into the flocculation tank through the infiltration tank 140.

In the flocculation tank 200 according to the present invention, an infusion port 140 is added and chlorine is injected into the flocculation tank by a chlorine injection device.

Drugs used as infectious agents can be widely adopted, and NaOCl is mainly used as an infectious agent.

In addition, the chlorine injection control unit 640 is added to the chlorine injection device. The chlorine injection control unit 640 receives the command for the chlorine injection to be transferred from the integration control unit 600, And control the amount of chlorine input.

The present invention continues to measure the membrane filtration differential pressure by the TMP measuring device while injecting the above-mentioned total chlorine to determine whether the operation control is good.

When the operation control is not performed well by the above-described pre-chlorine injection control of the present invention, the maintenance frequency of the first separation membrane bath and the second separation membrane bath and the concentration of the maintenance cleaning chemical are adjusted to perform the maintenance cleaning.

In the present invention, even if the membrane filtration differential pressure is measured by the TMP measuring device while the chlorine is being injected, if the operation control is not satisfactory, the integrated controller 600 performs the maintenance of the first and second separation membrane tanks do.

In the above-described maintenance and cleaning, chemicals used as the above-mentioned infecting unit are used, and the maintenance washing liquid is treated through the membrane filtration.

The above-mentioned maintenance cleaning agent can be adopted variously and NaOCl, which is a commonly used infectious agent, is mainly used.

4, the first cleansing line 321 and the second cleansing line 421 are connected to the treated water tank and the backwash pump (not shown), respectively, in the first separation membrane bank and the second separation membrane bank .

The integrated control unit 600 of the present invention also controls the valve control of the first cleaning line 321 of the first separation membrane bath and the second cleaning line 421 of the second separation membrane bath, .

In addition, the integrated control unit 600 also controls the amount and concentration of the maintenance cleaning chemicals.

As shown in FIG. 4, the present invention includes a maintenance cleaning agent injector 141 for injecting NaOCl, which is an infectious agent, into a maintenance cleaning agent, and commands the integrated controller 600 to supply maintenance cleaning agents to the first and second separation membrane baths So that the film is cleaned and operated.

The present invention is based on the above-mentioned constitution and operation to judge the high algae of raw water by using a simple PH measuring device and to control the flow rate of the raw water by the process control which minimizes the film contamination at the high turbidity or high algae and maximizes the film treatment efficiency Thereby providing an advanced water treatment apparatus.

INDUSTRIAL APPLICABILITY The present invention is very useful for an industry that produces, manufactures, sells, facilities, and distributes an apparatus or system for treating water such as water, sewage, and the like.

Particularly, the present invention is very useful for an industry that produces, manufactures, sells, facilities, and distributes a water treatment apparatus or system that requires advanced treatment for high algae and high turbidity.

100: raw water inflow part 110: raw milk infusion
100-1:
120: coagulant feed pipe 130: inline mixer
140: Transmission Suzhou Entrance 141: Maintenance Cleaning Drug Injector
200: Coagulation tank
210: stirrer 220: PH adjusting means
300: first separation membrane tank 310: first membrane filtration device
320: first treated water discharge line
400: second separation membrane bath 410: second membrane filtration system
420: second treated water discharge line 430: concentrated water inflow line
500: Dissolved air floating device
510: inlet 520:
530: separating part 540: discharging part
542: return line
550: collection chamber 551: collection chamber discharge line
600:
610: PH measuring unit 620: turbidity measuring unit
630: Coagulant loading control unit
650: solids measuring part 660: TMP measuring part

Claims (5)

delete delete A water column 110-1 in which water to be treated is stored,
A raw water inflow section 100 for introducing the raw water to be treated in the raw water section into the coagulation tank,
An agglomeration tank 200 having an agitator to cause flocculation reaction between raw water and flocculant to form floc,
A first separation membrane tank 300 for filtering out flocs formed in the flocculation tank,
A second separation membrane tank 400 for filtering and removing flocs from the concentrated unprocessed residual water in the first separation membrane bath,
A dissolved air floating device 500 for removing untreated concentrated water from the second separation membrane bath to remove sludge and algae concentrated by floating separation,
And an integrated control unit (600) for performing overall control of each configuration of the altitude water treatment apparatus,
When the influent to be treated flows at a high turbidity or a high concentration of algae, the process control is performed to change the recovery rates of the first and second separation membrane tanks,
The reference value for the solid concentration of the second separation membrane bath is set in the integrated controller 600,
When the solids concentration measured by the solids measurement unit 650 of the second separation membrane bath 400 is lower than the reference value, the dissolved air floatation apparatus 500 is operated without discharging the concentrated water of the second separation membrane bath, Wherein the control unit performs a process of controlling to discharge only the concentrated sludge through the collection chamber discharge line (551) of the apparatus.
A water column 110-1 in which water to be treated is stored,
A raw water inflow section 100 for introducing the raw water to be treated in the raw water section into the coagulation tank,
An agglomeration tank 200 having an agitator to cause flocculation reaction between raw water and flocculant to form floc,
A first separation membrane tank 300 for filtering out flocs formed in the flocculation tank,
A second separation membrane tank 400 for filtering and removing flocs from the concentrated unprocessed residual water in the first separation membrane bath,
A dissolved air floating device 500 for removing untreated concentrated water from the second separation membrane bath to remove sludge and algae concentrated by floating separation,
And an integrated control unit (600) for performing overall control of each configuration of the altitude water treatment apparatus,
When the influent to be treated flows at a high turbidity or a high concentration of algae, the process control is performed to change the recovery rates of the first and second separation membrane tanks,
The reference value for the solid concentration of the second separation membrane bath is set in the integrated controller 600,
When the solids concentration measured by the solids measuring unit 650 of the second separation membrane bath 400 is lower than the reference value, the dissolved air floating apparatus 500 is intermittently operated to reduce the required energy of the dissolved air floatation apparatus Features advanced water treatment system.
5. The method according to any one of claims 3 to 4,
The raw water portion 110-1 is provided with a PH measuring portion 610 for measuring PH of raw water,
The integrated control unit 600 may be configured such that when the reference value PS of the PH is established and the PH measurement value measured by the PH measurement unit is greater than the reference value, The control unit 630 inputs a coagulant injection command, and the coagulant is input to perform the process control so as to perform the water treatment,
And the process is controlled so that the dissolved air floating apparatus (500) is operated to perform water treatment.

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