KR20160009241A - a system for advanced wastewater treatment using capacitive deionization process as a nitrate concentrating process and the advanced wastewater treatment method - Google Patents

Abstract

The present invention relates to an advanced wastewater treatment technology for removing nutrient salts. More specifically, the present invention provides an advanced wastewater treatment system comprising an anaerobic tank (100), a membrane separation aerobic tank (200), and a capacitive deionization tank (300). In addition, the anaerobic tank (100) of the present invention comprises a carrier; the membrane separation aerobic tank (200) comprises an aerobic tank (210) and a membrane separation tank (220); and the capacitive deionization tank (300) has a transfer device which transfers condensed water by capacitive deionization (CDI) into the anaerobic tank (100).

Description

[0001] The present invention relates to a sewage elevation treatment system and a method thereof, which utilize a storage desalination process as a nitrate concentration process,

The present invention relates to a technology for treating wastewater to remove nutrients, and more specifically, to a method for treating wastewater by nitrifying nitrification by electrically discharging nitrified nitrogen by means of a storage desalination unit (CDI apparatus) at the end of a sewage elevation treatment process composed of anoxic- The present invention relates to a sewage elevation treatment system and a method for treating sewage so as to produce treated water by adsorption and conveying the concentrated nitrate nitrogen to an anoxic tank.

Advanced technology for wastewater treatment to remove nutrients has been developed by many engineers (environmental engineers).

Techniques for treating wastewater to remove nitrogen and phosphoric acid components have been developed in various ways. Recently, wastewater treatment technology using CDI (capacitive deionization) has been developed.

No. 10-0953085 (a wastewater treatment system using a storage deionization method, hereinafter referred to as "Prior Art 1") relates to a membrane separation tank for removing solid matter in treated water treated from a pre-anaerobic tank and an SBR tank, A CDI reaction tank for adsorbing an ion component of the separation membrane treatment water in which the ion component is dissolved and an oxidant generator for communicating with the CDI reaction tank and generating an oxidant and supplying the generated oxidant to the CDI reaction tank to remove organic substances adsorbed on the electrodes of the storage deionization stack And a wastewater treatment system including the wastewater treatment system.

In addition, the present applicant's registered patent No. 10-1273445 (energy-saving type water recovery technology using a storage desalination technology, hereinafter referred to as prior art 2) discloses a method in which "an aerobic membrane separation activated sludge tank for decomposing organic matters from a wastewater treatment inflow section, A water regeneration system including a CDI treatment tank and a power supply device for adsorbing and removing nutrient salts and dissolved salts at the rear end of the activated sludge tank ".

The present invention is a sewage elevation treatment system that further improves the prior art of the present applicant.

The above-mentioned prior art shows a further aspect as a wastewater treatment system for removing nutrients.

However, in the case of the conventional anoxic-aerobic BNR process including the above-described prior art, the internal transportation of 2Q to 5Q is essentially necessary from the nitrification tank to the anoxic tank, and a disadvantage that a large power ratio is consumed for driving the internal return pump there was.

Also, in the conventional art, there is a problem that the high dissolved oxygen (DO) of the oxic tank return water flows into the anoxic tank, the efficiency of the organic matter loss and the denitrification in the anoxic tank are lowered, I want to.

In addition, in the conventional sewage elevation treatment system, when the storage desalting tank is used, the recovery rate of treated water (CDI standard 90%) due to the generation of CDI concentrated water and the separate treatment process for treating the CDI concentrated water However, the present invention is intended to solve this problem.

In addition, the conventional techniques including the above-described prior arts can effectively remove the dissolved salts including nitrogen ions when the desalting process such as R / O, CDI, and ion exchange resins are linked to reuse of the wastewater treatment water, There has been a problem that there is no appropriate treatment option for the concentrated water.

In addition, the conventional process has a problem that the total nitrogen (TN) concentration of the final treated water can not be lowered to 10 mg / l or less. Accordingly, the present invention provides a sewage elevation treatment system and a method thereof.

In order to solve the above problems and needs,

An anoxic tank (100), a membrane separation aquarium (200), and a thermal desalination tank (300).

In the present invention, the anoxic tank (100) comprises a floating oil carrier,

The membrane separation aeration tank 200 is provided with an aerobic tank 210 and a membrane separation tank 220.

In addition, the present invention provides a sewage elevation treatment system characterized in that the storage desalting tank (300) is provided with a conveying device and conveys the CDI-concentrated water to the anoxic tank (100).

The present invention also relates to a process (first process) in which influent water flows into an anoxic tank (100) and is treated with an anoxic tank,

(The second step) in which the treated water passing through the anoxic tank is introduced into the membrane separation aeration tank 200 and treated,

And a process for treating the sewage water containing the deodorizing process (third process) by flowing the treated water through the membrane separation aquarium 200 into the storage desalting tank 300.

In the present invention, the process of treating the anoxic tank is an anoxic tank containing a floating oil carrier,

The treatment process of the membrane separation aquarium 200 includes an aerobic treatment process and a membrane separation treatment process,

The above-described thermal desalination process (third process) includes the step of conveying the CDI-concentrated water to the anoxic tank 100.

The present invention has the effect of solving all the problems of the above-mentioned problems to be solved.

Specifically, the sewage elevation treatment system and the method according to the present invention have an effect of utilizing a storage desalting tank (CDI) as a NO 3 -N filter for treated water treated in a membrane separation tank. In particular, the CDI- A separate process for treating the CDI-concentrated water is unnecessary.

The sewage treatment system and method according to the present invention are only 0.1 to 0.2Q (5% or less compared to the conventional system), while the flow rate of the conventional process is 2 to 3Q, The effect of solving the problem appears.

Further, there is a problem that the organic matter consumption by the dissolved oxygen (DO) of the oxic tank returning water of the conventional process and the denitrification efficiency of the anoxic tank are lowered. The present invention minimizes the influence of the DO in the return water, This effect is particularly well suited for domestic sewage having a low C / N ratio.

Further, the sewage elevation treatment system and method according to the present invention can perform MBBR of an anoxic tank to selectively cultivate denitrifying microorganisms and reduce the amount of sludge generated.

Further, the sewage treatment system and method according to the present invention have a problem that the conventional process can not lower the total nitrogen (TN) concentration of the final treated water to below 10 mg / l, whereas the total treated nitrogen ) Concentration to 10 mg / l or less.

That is, the conventional biological sewage treatment process is very difficult to lower the TN concentration of the effluent to less than 10 mg / L, and therefore, when a large amount of external carbon source is injected into the anoxic tank, the TN concentration can be lowered to 10 mg / L or less, The present invention is advantageous in that the TN concentration can be lowered to 10 mg / L even if only an external carbon source is injected into the anoxic tank or only a minimal amount of the external carbon source is injected into the anoxic tank.

1 is a conceptual diagram of a sewage elevation treatment system according to the present invention;
FIG. 1B is a conceptual diagram showing a case where two electrolytic desalination vessels of a sewage elevation treatment system according to the present invention are constructed. FIG.
FIG. 1C is a conceptual diagram showing a constitutional type membrane separation aerobic tank in the sewage elevation treatment system according to the present invention. FIG.
2 is a conceptual diagram of a conventional sewage elevation treatment system.
Figure 3 shows a change in the concentration of NO3-N in the process in a sewage elevation treatment system and method according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

The present invention provides a sewage elevation treatment system including an anoxic tank (100), a membrane separation aerobic tank (200), and a storage tank (300), and a method thereof.

The anoxic tank 100 of the present invention refers to a reaction tank that mainly performs a denitrification reaction.

Therefore, the main purpose of the anoxic tank is to shut off the supply of oxygen and to convert the nitrate nitrogen (NO ₃ ^- ) into nitrogen to fly into the air.

As described above, the present invention performs a process in which influent water is introduced into an anoxic tank and treated with an anoxic tank (Step 1)

As shown in FIG. 1, the influent water is introduced into the anoxic tank and includes nitrate nitrogen, ammonia nitrogen and total dissolved solids (TDS), and the nitrate nitrogen, ammonia nitrogen and TDS contained therein are treated in an anoxic tank .

Preferably, the present invention can be constituted by an anoxic tank including the carrier 110 in the above-mentioned anoxic tank.

Accordingly, the process of treating the anoxic tank may be performed by an anoxic tank containing the carrier. (Step 1)

The above-described carrier further enhances the activity of the denitrifying microorganism in the anoxic tank.

The carrier may be made of ceramics, polymer compound materials (PVA, PE, PU, etc.), and shapes and shapes thereof may be variously adopted so that microorganisms can grow.

In one embodiment of the present invention, a PVA gel type carrier having a diameter of 3 to 6 mm can be used.

The carrier may be in the form of a moving bed (or floating carrier) or a fixed bed carrier.

As described above, the process of removing nitrogen in the influent water introduced from the anoxic tank is performed.

In the present invention, a process is performed in which the treated water passing through the anoxic tank is introduced into the membrane separation aquarium 200 and treated. (Second Step)

The membrane separation aerobic tank 200 may be a reaction tank or a device having a membrane separation tank for removing suspended solids using an aerobic tank and a membrane that nitrifies the ammonia nitrogen of the influent water using an aerobic microorganism and decomposes organic matter it means.

As shown in FIG. 1, the membrane separation aeration tank 200 includes an aerobic tank 210 and a membrane separation tank 220.

As shown in FIG. 1, it can be seen that the aerobic tank 210 and the membrane separation tank 220 are constructed in the same reaction tank, and this type is referred to as an integrated membrane separation aerobic tank.

Therefore, the integrated membrane-separation aeration tank can be constructed in a form in which a membrane filtration apparatus that functions as a membrane separation tank is installed in the same reaction tank.

As shown in FIG. 1 (c), the aerobic tank 210 and the membrane separation tank 220 can be distinguished from each other.

Therefore, the classifying membrane-separation aquarium is provided with a separating means 230 for separating the aerobic tank 210 and the membrane separating tank 220, so that the treated water passing through the aerobic tank is transferred to the membrane separating tank for treatment.

The division means 230 refers to a membrane, a plate, a wall, and the like separating the aerobic tank and the membrane separation tank into unit processes.

When a fluidized bed carrier is used in the anoxic tank, a device such as a media screen is provided to introduce the treated water into the membrane separation and aeration tank so that the fluidized bed carrier does not enter the membrane separation aeration tank.

In the present invention, the aerobic tank 210 of the above-mentioned membrane separation aquarium 200 performs an aerobic decomposition process in which aerobic microorganisms are supplied with oxygen to decompose nitrification and organic matter (Second Step-1)

The aerobic tank of the membrane-separation aeration tank refers to a tank or a reaction tank. In such an aerobic tank, air (oxygen) supply means such as an aeration device may be provided.

The above-described aerobic tank of the present invention is a concept that includes both a carrier process including a carrier, or a process in which a microorganism suspends growth without a carrier, such as a general activated sludge process.

In the present invention, the treated water passed through the aerobic tank performs a microflora floc formed in the aerobic tank and a membrane separation tank 220 for removing the organic matter. (Second Step-2)

The above membrane separation vessel means a reaction vessel equipped with a membrane filtration apparatus using a membrane.

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

As described above, the membrane separation apparatus used in the present invention may be a membrane filtration apparatus used in a conventional membrane separation tank.

Therefore, an organic film or an inorganic film can be used as the filtration membrane used in the membrane separation tank of the present invention.

The organic film may be a commonly used organic film, and may be formed of a cellulose type (cellulose acetate), a synthetic resin (polysulfone, polyethylene, polypropylene, polyacrylonitryl, PVDF (polyvinylidene fluoride) and the like).

Three methods of air scouring, backwashing or backpulse, and maintenance cleaning can be used to prevent self-fouling of the membrane, Recovery cleaning can be carried out when it becomes impossible to carry out a normal filtration process.

In the above-described air cleaning, a blower (not shown) is installed in the membrane filtration unit, and filtration and backwash modes are continuously performed using the blower. A cassette with combined membrane modules

A pipe for discharging the air supplied by the blower and an air hole are provided in the lower part of the membrane module, and the supplied air flows upward from the lower part of the membrane module to the upper part. By using the generated shear force, Let the solid matter out.

In order to remove surplus sludge immersed in the above-mentioned membrane separation aeration tank, the surplus sludge discharge device 221 is provided to discharge the acclimated sludge. (Second Step-3)

The excess sludge discharging device 221 is constituted by a normal suction pump and a discharge pipe.

The surplus sludge discharge process may be performed simultaneously with the aerobic treatment process and / or the membrane separation treatment process, or sequentially or at different times.

The present invention is characterized in that the treated water passing through the above-mentioned membrane separation aquarium 200 flows into the direct storage type desalination tank 300 to perform the electrolytic desalination process (third process)

The above-mentioned storage type desalination tank means a water treatment tank equipped with a capacitative deionization device (310) using capacitive deionization (CDI).

The present invention relates to a storage demineralizer comprising a stack of CDI stacked with a positive electrode to which a positive electrode is applied, a negative electrode to which a negative electrode is applied, and a spacer provided between the positive electrode and the negative electrode so that the process water can be circulated, A power supply unit for supplying power, and a control unit.

The CDI stack of the storage and desalination apparatus is composed of a support plate, a current supply plate, an electrode, a gasket, and an electrode separator. The current supply plate receives the current from the power supply part and makes a positive electrode or negative electrode to the electrode attached to the current supply plate, and the negative ion and the positive ion adsorb to each electrode according to the electrical attraction.

The ion desorption process and the ion desorption process of the storage dechlorination process of the present invention are alternately operated.

In the case of the ion adsorption process of the above-described capacitative demineralizer, negative ions are attached to the electrode (A) when a positive potential is applied to the electrode and a negative potential is applied to the electrode. nitrate nitrogen (NO ₃ ^-) and to be attached to such belt is materials anions, also in the above (B) electrode strip cations and positively charged such as a cation of ammonium nitrogen (NH ₄ ^+), Mg, Ca, Na A TDS or the like is attached.

As a result, anion and cation are removed, and clean water is processed and produced. This process is also referred to as the purification process of the storage desalination apparatus.

As described above, in the present invention, in the ion desorption process, the anion and the cation of the influent water adhere to the electrolytic desalination apparatus.

The ion desorption process (regeneration process) of the above-described capacitative demineralization apparatus is performed as follows.

The potential of the electrode is temporarily released by the above-described capacitive desalination apparatus to remove the electric attraction force between the electrode and the ion, and then the ion is desorbed. Then, (-) potential is applied to the electrode (+) Potential is applied to the electrode (B) so that the ions adhered to the electrode are desorbed at the same time in the purification process, and are discharged in the form of concentrated water.

Positive ions such as nitrate nitrogen (NO ₃ ^- ), ammonia nitrogen (NH ₄ ⁺ ), Mg, Ca, Na and the like attached to the electrodes (A) and (B) Ions and the like are desorbed to form CDI concentrated water.

Therefore, the process of forming the CDI-concentrated water through the ion adsorption process (purification process) and the ion desorption process (regeneration process) is referred to as a CDI-concentrated water formation process of the storage desalting tank.

The concentration of CDI concentrate thus formed is determined by the following equation: nitrate nitrogen (NO ₃ ^- ) 0.2 (mg / l) and nitrate nitrogen (NO ₃ ^- ) in the case of TDS 370.7 (mg / The concentration is 98.3 (mg / l) and TDS 1723.3 (mg / l).

The present invention is carried out in such a manner that the condensate desalination apparatus is operated to form the CDI concentrated water, and the condensate desalination apparatus is operated or the non-activated process can be performed by forming the CDI concentrated water.

In one embodiment, CDI-enriched water can be produced by a method of ion adsorption process (purification process) for 1 to 5 minutes and an ion desorption process (regeneration process) for 1 to 5 minutes in a storage type desalination device.

As shown in FIG. 1B, it is preferable that the present invention include two or more storage desalting vessels, and it is possible to facilitate the above-described CDI concentrated water forming process by alternately performing the purification process on the one side and the regeneration process on the other side.

When two or more storage type desalination baths are provided, the processing time of the storage desalination bath can be adjusted according to a user's request by a conventional influent distribution device 311 having a control function.

The CDI treated water in which the ammonium nitrate, nitrate nitrogen, TDS, etc. are almost completely removed is discharged to the CDI treated water discharge line 312.

As described above, the present invention creates the effect of lowering the TN concentration of the CDI-treated water to 5 mg / l or less.

The technical feature of the present invention is that a step of conveying the CDI-concentrated water generated in the above-mentioned condensate desalting tank to the above-mentioned anoxic tank 100 is added. (Third Step-2)

The above-described conveying step may be constituted by a conveying device 320 such as a normal pump and a pipe.

In the present invention, the above-described conveying device 320 is referred to as a CDI concentrated water conveying device and is constituted by a normal pump and a pipe.

In the process of conveying the CDI-concentrated water to the anoxic tank, the amount of the carrier to be fed is a small amount of 0.1Q to 0.2Q when the amount of the influent water entering the anoxic tank is Q.

As described above, according to the present invention, since the CDI concentrated water flow amount to be transported to the anoxic tank flows into a small amount of 0.1Q to 0.2Q, the treated water flow rate of the aerobic tank transported to the anoxic tank in the conventional process is 2Q to 3Q There is a merit that is remarkably advantageous.

Fig. 2 shows an advanced treatment system and advanced treatment process (hereinafter referred to as "conventional process") consisting of a conventional anoxic tank, an aerobic tank, a membrane separation tank, and a storage desalination tank.

As shown in FIG. 2, the flow rate of the carrier flowing into the anoxic tank 100 from the oxic tank 210 is about 2Q to 3Q, and a large amount of process water is transported through the inner carrier line 211.

Such a large amount of treated water is a cause of deteriorating the process of the anoxic tank.

Particularly, the above oxic tank includes a large amount of oxygen dissolved in water. However, the anoxic tank is a well-maintained process only when there is no oxygen, and if it contains oxygen that is two to three times as many as the influent water flowing into the anoxic tank, the process is inevitably made worse.

Also, in the conventional process, the amount of the feed water of two to three times the amount of the influent water is introduced into the anoxic tank, so that the power consumption of the pump for conveying is excessively uneconomical.

As shown in FIG. 2, the conventional process includes a process of transporting the treated water through the inner circulation line 222 to the oxic tank 210 in the membrane separation tank 220, And there is a problem of causing complexity of the process.

In addition, the conventional electrothermal desalting apparatus discharges the CDI-concentrated water through the CDI-concentrated water discharge line 321, which causes a secondary processing problem with the CDI-concentrated water.

As described above, the present invention solves all the problems of the conventional process as described above, and the CDI concentrated water produced in the storage desalting tank is directly returned to the anoxic tank 100 as described above.

The present invention provides a sewage elevation treatment system and method for removing nitrogen by using a storage desalination process as a nitrate concentration process.

As described above, the concentration of CDI concentrated water is increased to about 400 to 500 (98.3 / 0.2) times that of nitrate nitrogen (NO ₃ ^- ) of the influent water. Thus, the nitrate nitrogen (NO ₃ ^- ), ), So that the concentration of nitrate nitrogen in the anoxic tank is increased, and the denitrification efficiency is remarkably increased.

In addition, conventionally, the aerobic transporting water having a flow rate that is two to three times higher than that of the anoxic tank inflow has been introduced. In addition, the aerobic transporting water having a high oxygen concentration and high oxygen concentration has flowed in and the efficiency of the anoxic tank has decreased. It is possible to increase the efficiency of the anoxic tank because the amount of oxygen introduced is about 0.1 to 0.2 times as much as the inflow amount.

In addition, the number of conveying rollers is reduced to 1/30 to 1/30 of that of the conventional process, and the economical effect of significantly reducing the consumption of the pump power to convey is remarkable.

The experimental results of the material balance of COD, ammonia nitrogen, nitrate nitrogen and TDS by the sewage elevation treatment system and the method using the storage desalination process according to the present invention as a nitrate concentration process are as follows.

The concentrations of pollutants contained in the influent (or raw water) flowing into the anoxic tank of the present invention are shown in Table 1 below.

Influent COD ((mg / l) 125.7 NH4-N (mg / l) 29.4 NO3-N (mg / l) 0.2 TDS (mg / l) 370.7

The concentrations of pollutants in the anoxic tank are shown in Table 2 below.

Anoxic tank COD ((mg / l) 45.3 NH4-N (mg / l) 22.7 NO3-N (mg / l) 0.2 TDS (mg / l) 623.0

The concentrations of pollutants in the membrane separation aeration tank are shown in Table 3 below.

Membrane separation pump COD ((mg / l) 15.0 NH4-N (mg / l) 0.9 NO3-N (mg / l) 26.9 TDS (mg / l) 605.0

The concentration of CDI and the number of CDI-treated water in the storage type desalting tank are shown in [Table 4] and [Table 5].

CDI concentrate COD ((mg / l) 27.0 NH4-N (mg / l) 2.5 NO3-N (mg / l) 98.3 TDS (mg / l) 1723.3

CDI processed number COD ((mg / l) 15.0 NH4-N (mg / l) 0.4 NO3-N (mg / l) 7.5 TDS (mg / l) 273.0

As shown in the material balance of ammonia nitrogen, nitrate nitrogen and TDS of the above experiment, the final TN of CDI-treated water finally discharged is effective to be treated to 10 mg / l or less.

FIG. 3 also shows the concentration of NO3-N in the process according to the sewage elevation treatment system and the method of the present invention using nitrate concentration process, l. < / RTI >

As described above, the sewage elevation treatment system and the method using the storage desalination process according to the present invention as a nitrate concentration process show an excellent effect for nitrogen removal.

INDUSTRIAL APPLICABILITY The present invention is an extremely useful invention in an industry that performs water treatment, particularly, advanced treatment of sewage effluent.

Further, the present invention is a breakthrough invention for the industry that installs, constructs, manages and operates water treatment, especially wastewater treatment facility or wastewater treatment facility.

The present invention is also closely related to industries that produce, manufacture, process, sell, distribute and use pharmaceuticals for water treatment.

100: anoxic tank 110: carrier
200: Membrane separation and etching tank 210:
211: inner return line 222: inner circulation line
220: membrane separation tank 221: surplus sludge discharging device
230:
300: Storage type desalting tank 301: Storage type desalting tank (second)
310: Storage type desalination device 311: Inflow water distribution device
312: CDI treated water discharge line 320: CDI concentrated water conveyance device
321: CDI concentrated water discharge line

Claims (5)

An anoxic tank (100), a membrane separation aerobic tank (200), and a storage desalination tank (300).
The method according to claim 1,
The anoxic tank 100 includes a carrier,
The membrane separation and treatment tank (200) is characterized in that it comprises an oxic tank (210) and a membrane separation tank (220).
3. The method according to claim 1 or 2,
Characterized in that the storage desalting tank (300) is equipped with a transfer device and conveys CDI-concentrated water to the anoxic tank (100).
(The first step) in which the influent water flows into the anoxic tank 100 and is treated as an anoxic tank,
(The second step) in which the treated water passing through the anoxic tank is introduced into the membrane separation aeration tank 200 and treated,
Wherein the treated water passing through the membrane separation aquarium 200 flows into the electrolytic desalination tank 300 and includes a storage desalination process (third process).
5. The method of claim 4,
The process of treating with the anoxic tank is a process of treating with an anoxic tank containing a carrier,
The treatment process of the membrane separation aquarium 200 includes an aerobic treatment process and a membrane separation treatment process,
Wherein the storage desalination step (third step) includes a step of conveying CDI-concentrated water to the anoxic tank (100).

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