KR102059988B1 - Membrane water treatment apparatus using micro-bubble - Google Patents

Abstract

The present invention relates to a membrane water treatment apparatus for removing nitrogen and phosphorus, and more specifically, based on the membrane process using A2 / O method, a plurality of sedimentation tanks between an aeration tank into which raw water is introduced and a membrane separation tank equipped with membrane modules. Install the sedimentation tank module consisting of the membrane and inject the microbubble into the membrane separation tank to remove contaminants using the redox action of the microbubble to reduce the microbial concentration (MLSS) inside the membrane separation tank to prevent fouling of the membrane. The present invention relates to a membrane water treatment device using microbubbles that can be easily managed even by an unskilled person by reducing the cost of frequent replacement of the separator and facilitating maintenance by extending the life of the separator.

Description

Membrane Water Treatment Apparatus Using Microbubble {MEMBRANE WATER TREATMENT APPARATUS USING MICRO-BUBBLE}

The present invention relates to a membrane water treatment apparatus for removing nitrogen and phosphorus, and more specifically, based on the membrane process using A2 / O method, a plurality of sedimentation tanks between an aeration tank into which raw water is introduced and a membrane separation tank equipped with membrane modules. Install the sedimentation tank module consisting of the membrane and inject the microbubble into the membrane separation tank to remove contaminants using the redox action of the microbubble to reduce the microbial concentration (MLSS) inside the membrane separation tank to prevent fouling of the membrane. The present invention relates to a membrane water treatment device using microbubbles that can be easily managed even by an unskilled person by reducing the cost of frequent replacement of the separator and facilitating maintenance by extending the life of the separator.

If the pollutants contained in sewage and wastewater are discharged without treatment, they will contaminate rivers and lakes, adversely affecting water resources and ecosystems. Sewage and wastewater treatment methods can be broadly classified into physical, chemical and biological methods.

Physical sewage and wastewater treatment methods include ammonia removal by air removal, filtration, distillation, flotation, foam secretion method, cooling, separation using a gas layer, surface scattering method, reverse osmosis method, and absorption. Chemical sewage and wastewater treatment methods include activated carbon adsorption, flocculation, precipitation, ion exchange, electrochemical treatment, electrodialysis, oxidation and reduction. Biological sewage / wastewater treatment method removes contaminants by the metabolism of microorganisms (contaminants in sewage waste water are used for microbial energy source or cell proliferation). Bacterial assimilation, algae extraction, nitrification and denitrification, etc. There is this.

Nitrogen and phosphorus in sewage and wastewater belong to nutrients, and if it is not properly removed, it causes eutrophication of rivers and lakes, and it causes problems of polluting water supply and industrial water due to abnormal breeding of algae. There is a need to effectively remove the nitrogen and phosphorus contained.

Several methods are known for the treatment of phosphorus and nitrogen, including the A2 / O (Anerobic-Anoxic-Oxic) process, the University of cape town (UCT) process, the Modified UCT (MUCT) process, and the VIP Polytechnic Institue (VIP) process. There is a biological treatment process such as a process.

Dual A2 / O methods are generally widely used. This process is stable in processing, relatively inexpensive and environmentally friendly. As shown in FIG. 1, the treatment step 100 of the A2 / O method includes an anaerobic tank 110, an anaerobic tank 120, an aerobic tank 130, and a precipitation tank 140. In the anaerobic tank 110, microorganisms decompose contaminants in anaerobic conditions and release phosphorus to release phosphorus in the influent. In the oxygen-free tank 120, the nitrogen component is removed by the denitrification reaction. Denitrification refers to the action of reducing the nitrate nitrogen to nitrogen gas (N2) by the microorganism. When the microorganism lacks oxygen, the nitric acid loses oxygen and uses nitrogen because it removes the oxygen contained in the nitric acid (NO3). It is reduced to gas (N2) and released into the atmosphere. In the aerobic tank 130, a dephosphorization process is performed to remove some organic matter, cause nitrification, and excessively absorb phosphorus in raw water in the microbial body. In the settling tank 140, the treated water and the excess sludge are solid-liquid separated. In addition, the phosphorus component is discharged to the outside together with the excess sludge. And the excess sludge of the settling tank 140 is returned to the anaerobic tank (110). However, the A2 / O method has a disadvantage in that the excess sludge has a high phosphorus content, difficult to operate optimally, and it is difficult to expect stable phosphorus treatment.

Accordingly, in recent years, due to the strengthening of the required level for sewage wastewater treatment, a membrane separation water treatment apparatus for installing a separation membrane in an aerobic tank is used. As shown in FIG. 2, the membrane separation water treatment apparatus 200 includes an anaerobic tank 210 for organic matter and phosphorus treatment, an anaerobic tank 220 for denitrification, and a membrane separation tank 230 for nitrification and phosphorus excess intake and solid-liquid separation. ) In addition, a flocculant injection device 236 for injecting a flocculant into the membrane separation tank 235 may be further installed. This separation membrane process, it is possible to maintain a high microbial concentration (MLSS: Mixed Liquor Suspended Solid) up to about 5000 ~ 10,000mg / L has the advantage that the water quality of the treated water is good and stable. In addition, by introducing the immersion type separation membrane 240 into the aerobic tank 230, the sedimentation basin can be omitted by solid-liquid separation of the treated water in place of the sedimentation tank, which not only saves the sedimentation tank site but also deteriorates the treated water quality due to sludge injury of the sedimentation tank. The advantage is that there is no problem.

However, such immersion type membrane fouling occurs when the membrane is contaminated by organic matter and microorganisms during the solid-liquid separation of sludge and treated water from the mixed solution. As fouling progresses, energy consumption increases due to reduced production of filtered water or increased pump operation to ensure a constant output. Periodic cleaning is performed to solve this problem of fouling.

The washing method of the membrane is washing the air bubbles and periodically backwashing with treated water, and maintenance washing with sodium hypochlorite (NaOCl). Maintenance cleaning refers to backwashing in a condensed membrane tank for a certain period of time using a chemical to solve the membrane fouling problem caused by membrane organic matter which occurs during air cleaning and periodic backwashing. In general, maintenance cleaning may be performed once daily with a drug distillation. However, sodium bichlorate, which is used for maintenance cleaning, also eliminates microbial contamination only in separation, but also lowers the activity of microorganisms in the sludge. In addition, the frequent maintenance is to reduce the life of the membrane, there is a problem that often replace the membrane module.

Korea Patent Registration 10-0920176 Republic of Korea Patent Registration 10-1018587 Republic of Korea Patent Registration 10-1281514 Republic of Korea Patent Registration 10-1264310

The present invention has been made to solve the problems of the prior art, the main object of the present invention is to prevent fouling of the membrane and to extend the life of the membrane, so that frequent maintenance and separation membrane replacement is not required to maintain maintenance It is to provide a membrane water treatment device using a micro bubble to facilitate the.

The present invention is to install a sedimentation tank module consisting of a plurality of sedimentation tank for separating excess residue in the front of the membrane separation tank to significantly reduce the microbial concentration of the membrane separation tank to prevent fouling of the membrane and to extend the life of the membrane It is to provide a separator water treatment device using.

In addition, the present invention by injecting micro bubbles into the membrane separation tank to decompose contaminants inside the membrane using the redox effect of the micro bubble to improve the water quality of the treated water and at the same time prevent fouling of the membrane and It is to provide a membrane water treatment device that can extend the life.

In addition, the present invention by introducing a flocculant into the aerobic tank into which the raw water is introduced to remove the phosphorus component contained in the raw water to improve the water quality of the treated water, to prevent fouling of the separator and to simplify the structure of the device micro bubbles It is to provide a separator water treatment device.

Separator water treatment apparatus using a micro bubble according to the present invention as a means for achieving the object of the present invention,

In the membrane water treatment device comprising a flow control tank, an aerobic tank and a membrane separation tank,

A storage tank installed between the flow adjusting tank and the exhalation tank;

A settling tank module installed between the exhalation tank and the membrane separation tank;

A supply line installed between the flow rate adjustment tank and the exhalation tank to supply raw water;

A conveying line installed between the settling tank module and the storage tank to convey excess sludge;

A sludge discharge pipe installed in the storage tank and discharging a part of excess sludge to the outside;

A micro bubbler installed to inject micro bubbles into the membrane separation tank;

A flocculant injection device installed to inject coagulant into the aerobic tank;
And a first T-shaped tube installed inside the aerobic tank and supplying the treated water decomposed by the aerobic microorganisms to the sedimentation tank module adjacent thereto.

The settling tank module, the low oxygen settling tank, the anaerobic settling tank and the anaerobic settling tank in which the treated water flows into the aerobic tank is installed in sequence, the low oxygen settling tank, the anaerobic settling tank and the anaerobic settling tank, the excess sludge Air lifts are respectively provided for returning to the storage tank through a conveying line, and the anaerobic sedimentation tank, anoxic sedimentation tank, and the membrane separation tank adjacent to the solid-liquid separated treatment water are disposed inside the low oxygen settling tank, anaerobic settling tank, and anoxic settling tank. The second to fourth T-shaped pipes for supplying are respectively installed to reduce the microbial concentration (MLSS) introduced into the membrane separation tank through the anoxic settling tank of the settling tank module and to supply the microbubbles supplied from the microbubble group. The membrane by decomposing contaminants in the membrane separation tank Prevent contamination of the membrane immersed in the inside of the separation tank and characterized in that it extends the life of the separation membrane.

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Technical problems of the present invention are not limited to the above-mentioned technical problems, and other technical problems that are not mentioned will be clearly understood by those skilled in the art from the following solutions.

The present invention is based on a membrane process to which the A2 / O method is applied, and simultaneously, a physicochemical process using microbubbles and a chemical process using a flocculant together, firstly, to improve the water quality of the treated water and secondly, to simplify the structure of the apparatus. And third, it is easy to maintain by extending the life of the membrane, when applied to small-scale treatment plant has the effect that can be easily managed even by unskilled people.

1 is a schematic configuration diagram showing an A2 / O method according to the prior art;
Figure 2 is a schematic diagram showing a separator water treatment apparatus according to the prior art,
Figure 3 is a block diagram showing a preferred embodiment of the membrane water treatment device using a microbubble according to the present invention.

Advantages and features of the present invention, and a method for achieving the same will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. However, this embodiment is provided to explain in detail enough to easily implement the technical idea of the present invention to those skilled in the art. In addition, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in describing the embodiments of the present invention, when it is determined that a detailed description of a related well-known configuration or function interferes with the understanding of the embodiments of the present invention, the detailed description thereof will be omitted.

Figure 3 is a block diagram showing an example of a membrane water treatment device using a microbubble according to the present invention.

As shown, the membrane water treatment device 1 (hereinafter referred to as 'water treatment device') using the microbubble according to the present invention is largely the flow rate adjustment tank 10, the storage tank 20, the aeration tank 30, the settling tank module ( 40) and membrane separation tank (50). The membrane module 60 is installed inside the membrane separation tank 50. In addition, a micro bubbler 70 for injecting micro bubbles into the membrane separation tank 50 is provided. In addition, agglomerate dosing device 80 for introducing a coagulant into the exhalation tank 30 is provided.

That is, the water treatment apparatus 1 according to the present invention is a separation membrane water treatment apparatus including a flow regulating tank 10, an aeration tank 30, and a membrane separation tank 50, wherein the flow regulating tank 10 and the aerobic tank are separated by 30. The storage tank 20 is installed. In addition, the settling tank module 40 is installed between the exhalation tank 30 and the membrane separation tank 50. The settling tank module 40 is composed of a plurality of settling tank 41, 42, 43. And a supply line 15 for supplying raw water is installed between the flow rate adjustment tank 10 and the aerobic tank 30, and a conveying line for conveying excess sludge between the settling tank module 40 and the storage tank 20 ( 45) is installed. The storage tank 20 is provided with a sludge discharge pipe 25 for discharging a part of the excess sludge to the outside.

The settling tank module 40 is composed of a low oxygen settling tank 41, an anaerobic settling tank 42 and an oxygen-free settling tank 43 according to the concentration of dissolved oxygen. In other words, the sedimentation tank module 40 not only separates the excess sludge and the treated water into solid-liquid, but also serves to decompose nitrogen and organic matter contained in the sewage. Therefore, the microbial concentration is very low in the treated water discharged from the anoxic precipitation tank 43.

As described above, the present invention is basically based on the A2 / O method, but improves the water quality of the treated water by using a membrane process using a separator, a physicochemical process using a micro bubble, and a chemical process using a flocculant together. It simplifies the structure and extends the life of the membrane to facilitate maintenance.

In order to achieve this effect, the first aspect of the water treatment device 1 according to the present invention, the settling tank module 40 composed of a plurality of settling tank between the aeration tank 30 and the membrane separation tank 50 is supplied with raw water Install it. Preferably, the settling tank module 40 includes a low oxygen settling tank 41, an anaerobic settling tank 42, and an oxygen-free settling tank 43. And a low oxygen settling tank 41, an anaerobic settling tank 42 and an oxygen-free settling tank 43 is provided with a T-shaped pipe (T) for discharging the treated water, respectively, and the air for returning the excess sludge to the storage tank (20) The lift L is installed. The sedimentation tank module 40 is a solid-liquid separation of the excess sludge and the treated water contained in the waste water, the excess sludge is returned to the storage tank 20 and the treated water is finally discharged to the membrane separation tank 50 through the neighboring sedimentation tank. .

Therefore, the microbial concentration (MLSS: Mixed Liquor Suspended Solid) of the membrane separation tank 50 is significantly lower than that of the conventional membrane separation tank. For example, the microbial concentration of the membrane separation tank 50 is lower than about 20 to 50% compared to the microbial concentration of the conventional membrane separation tank. Here, in order to lower the microbial concentration of the membrane separation tank 50 to about 20% or less than the microbial concentration of the conventional membrane separation tank, the capacity of the settling tank module 40 must be increased, which is uneconomical. On the contrary, when the microbial concentration of the membrane separation tank 50 is about 50% or more than that of the conventional membrane separation tank, it becomes difficult to extend the life of the membrane. As such, when the microbial concentration in the membrane separation tank 50 decreases, fouling of the separation membrane contaminated by organic matter and microorganisms can be prevented. In addition, by reducing the number of cleaning cycles life of the membrane can be extended. And when the life of the membrane is extended, it is not necessary to replace the membrane frequently, thereby reducing the cost and easy maintenance.

Next, a second aspect of the water treatment device 1 according to the present invention injects microbubbles into the membrane separation tank 50. To this end, the micro bubbler 70 is installed to inject micro bubbles into the membrane separation tank 50. As such, when the microbubble is injected into the membrane separation tank 50, contaminants may be decomposed by the redox action of the microbubble. That is, the microbubble injected by the microbubble 70 rises to the surface and disappears from the surface. The microbubble that is generated generates various energies. For example, the microbubbles dissipate and produce ultrasonic waves and high sound pressure. In addition, the micro bubble bursts and instantly generates high heat of 4,000 to 6,000 ° C. Microbubbles also produce OH radicals. OH radical is a strong oxidizing agent has excellent sterilizing power and increases the dissolved oxygen in the membrane separation tank 50. In addition, ozone may be injected into the micro bubbler 70. Therefore, ozone is included in the micro bubbles generated by the micro bubbler 70. Ozone oxidizes contaminants in the membrane separation tank 50 because of its strong oxidizing power.

Next, in the third aspect of the water treatment device 1 according to the present invention, a flocculant is introduced into the aerobic tank 30 to which raw water is supplied. To this end, a coagulant injection device 80 including a coagulant tank 81 for storing a coagulant and a coagulant injection pump 82 for supplying a coagulant is provided. That is, the conventional membrane water treatment device is to put the flocculant into the membrane separation tank, this method can not only reduce the efficiency of the flocculant but also affect the blockage of the membrane due to the excessive input of the flocculant. However, the present invention can prevent contamination of the membrane inside the membrane separation tank 50 by introducing a flocculant into the aerobic tank 30 into which the raw water is introduced and removing the aggregate from the settling tank module 40 installed at the rear end thereof.

As described above, in the present invention, a flocculant is directly added to the aerobic tank 30 to remove the phosphorus component, and a membrane separation tank (40) consisting of a plurality of precipitation tanks is installed at the tip of the membrane separation tank 50 ( 50) while reducing the concentration of microorganisms introduced into the membrane separation tank (50) by injecting microbubbles to decompose contaminants to improve the water quality of the treated water and prevent contamination of the membrane to extend the life of the membrane. In addition, the life of the membrane is extended, so that frequent cleaning and replacement of the membrane are not necessary, thereby reducing costs and facilitating maintenance, so that even an inexperienced person can easily manage the membrane.

More specifically, the flow rate adjustment tank 10 is provided with a raw water inlet pipe 11 through which raw water flows. Therefore, the raw water is introduced into the flow rate adjustment tank 10 through the raw water supply pump and the screen not shown. And the inside of the flow regulating tank 10, the stirrer 13 is installed. The stirrer 13 mixes raw water to make the concentration uniform. In addition, a supply line 15 for supplying wastewater is provided between the flow rate adjustment tank 10 and the exhalation tank 30. In addition, a first air lift (L1) for transferring the wastewater through the supply line (15) is installed in the flow rate adjustment tank (10). Therefore, the wastewater in the flow rate adjusting tank 10 may be supplied to the exhalation tank 30 through the air lift L1 and the supply line 15.

A storage tank 20 is installed between the flow rate adjusting tank 10 and the exhalation tank 30. The storage tank 20 is connected to the low oxygen settling tank 41, anaerobic settling tank 42, and anoxic settling tank 43 of the settling tank module 40 through the conveying line 45, respectively. Therefore, the storage tank 20 stores excess sludge conveyed through the conveying line 45. And the agitator 23 is installed in the storage tank 20. The stirrer 23 mixes the excess sludge. In addition, a sludge discharge pipe 25 for discharging a part of the excess sludge to the outside is installed in the storage tank 20. Therefore, a portion of the excess sludge is discharged to the outside through the sludge discharge pipe 25 according to the water level of the storage tank (20). For example, it is possible to discharge the excess sludge periodically to maintain a constant water level of the storage tank (20).

 Subsequently, an diffuser 33 is installed inside the aerobic tank 30. The diffuser 33 supplies bubbles to bring the aerobic tank 30 into aerobic state. Therefore, the aerobic tank 30 decomposes organic matter into carbon dioxide and water by aerobic microorganisms. In addition, a flocculant is injected into the aerobic tank 30. To this end, a coagulant injection device 80 including a coagulant tank 81 and a coagulant injection pump 82 is provided. The flocculant introduced by the flocculant injection device 80 aggregates the phosphorus component and the suspended solids contained in the raw water. In addition, a first T-shaped tube T1 is installed in the exhalation tank 30. The upper end of the first T-shaped tube (T1) is connected to the hypoxic precipitation tank 41 and the lower end is installed to be located in the middle portion of the aerobic tank (30). Therefore, the treated water from which the organic matter is decomposed by the aerobic microorganism is supplied to the low oxygen precipitation tank 41 through the first T-shaped tube T1.

The low oxygen precipitation tank 41 is maintained in a low oxygen state. Therefore, the wastewater inside the hypoxic precipitation tank 41 is organic matter is precipitated and removed. In addition, a second air lift L2 and a second T-shaped pipe T2 are installed in the hypoxic precipitation tank 41. The upper end of the second T-shaped tube (T2) is connected to the anaerobic precipitation tank 42 and the lower end is installed so as to be located in the middle portion of the hypoxic precipitation tank (41). Therefore, the wastewater from which the organic matter is removed from the low oxygen precipitation tank 41 is supplied to the anaerobic precipitation tank 42 through the second T-shaped tube T2. The excess sludge in the low oxygen precipitation tank 41 is conveyed to the storage tank 20 through the second air lift L2 and the conveying line 45.

The anaerobic sedimentation tank 42 is maintained in the anaerobic state. Therefore, organic waste is decomposed by anaerobic microorganisms in the sewage wastewater in the anaerobic sedimentation tank 42. And inside the anaerobic sedimentation tank 42, the 3rd air lift L3 is installed. Therefore, the excess sludge in the anaerobic settling tank 42 is conveyed to the storage tank 20 through the 3rd air lift L3 and the conveying line 45. As shown in FIG. In addition, a third T-shaped tube T3 is provided in the anaerobic settling tank 42. The upper end of the third T-shaped tube (T3) is connected to the anaerobic settling tank 43 and the lower end is installed to be located in the middle portion of the anaerobic settling tank (42). Therefore, the wastewater from which the organic matter is removed from the anaerobic settling tank 42 is supplied to the anoxic settling tank 43 through the third T-shaped tube T3.

The anoxic precipitation tank 43 is maintained in an oxygen free state. Therefore, the wastewater within the anaerobic sedimentation tank 43 is removed by converting dinitic acid and nitric acid into nitrogen gas by the denitrification microorganism. In addition, a fourth air lift L4 is installed inside the anoxic precipitation tank 43. Therefore, the excess sludge inside the anoxic precipitation tank 43 is conveyed to the storage tank 20 through the fourth air lift L4 and the conveying line 45. In addition, a fourth T-shaped tube T4 is provided in the anoxic precipitation tank 43. The upper end of the fourth T-shaped tube (T4) is connected to the membrane separation tank 50 and the lower end is installed to be located in the middle portion of the anoxic precipitation tank (43). Therefore, waste water from which nitrogen is removed from the anoxic precipitation tank 43 is supplied to the membrane separation tank 50 through the fourth T-shaped tube T4.

 The diffuser 53 is installed inside the membrane separation tank 50. Therefore, the membrane separation tank 50 is maintained in aerobic state. In addition, the membrane unit 60 is installed inside the membrane separation tank 50. The membrane unit 60 separates the treated water from the mixed liquid. To this end, the separator unit 60 includes a separator module 61 composed of a plurality of hollow fiber membranes, and a suction pump 62 connected to the separator module 61 to suck treated water. In addition, the separator module 61 is provided with a fifth air lift L5 for injecting backwash water. In addition, an air supply device (not shown) is connected to the diffuser 53 installed at the lower portion of the membrane module 61 to supply air bubbles for washing to the lower portion of the membrane module 61.

And a micro bubbler 70 for supplying micro bubbles into the membrane separation tank 50 is provided. Therefore, the contaminants contained in the mixed solution in the membrane separation tank 50 are decomposed by the redox action of the micro bubble. That is, the microbubble injected by the microbubble 70 is dissipated from the surface while rising to the surface, and the microbubble dissipating generates various energies. For example, microbubbles disappear as they generate ultrasonic waves and high sound pressure. In addition, the micro bubble bursts and instantly generates high heat of 4,000 to 6,000 ° C. Microbubbles also produce OH-radicals with oxidizing power. OH-radicals decompose and sterilize organic matter.

As described above, the present invention adds a flocculant to the aerobic tank 30 into which raw water flows to remove phosphorus and suspended solids, and removes organic matter using aerobic microorganisms. And between the aerobic tank 30 and the membrane separation tank 50 to install a settling tank module 40 consisting of a plurality of settling tank to lower the microbial concentration flowing into the membrane separation tank 50 to the maximum. In addition, the microbubble is injected into the membrane separation tank 50 to physically remove organic substances in the membrane separation tank 50, thereby reducing the number of cleaning cycles of the membrane module 61, thereby extending the life of the membrane. In this way, if the life of the separator is extended, it is possible to reduce the cost due to frequent replacement of the membrane and to facilitate maintenance. In addition, easy maintenance has the effect that even an inexperienced person can easily manage.

Hereinafter, the operation of the membrane water treatment device using the microbubble according to the present invention will be described.

First, the raw water to be treated is introduced into the flow rate adjustment tank 10. The wastewater introduced into the flow rate adjustment tank 10 is supplied to the aeration tank 30 through the first air lift L1 and the supply line 1 by detecting the level of the level switch.

The aerobic tank 30 maintains aerobic conditions by air bubbles supplied from the diffuser 33 to remove organic matter using aerobic microorganisms. In addition, a flocculant is injected into the aerobic tank 30. The flocculant injected from the flocculant injection device 80 aggregates the suspended solids and the phosphorus component. The wastewater from which the organic matter is removed is supplied to the hypoxic precipitation tank 41 through the first T-shaped tube T1.

The low oxygen precipitation tank 41 is formed in a low oxygen state to decompose organic matter. In addition, excess sludge precipitated in the low oxygen precipitation tank 41 is conveyed to the storage tank 20 through the second air lift L2 and the conveying line 45. In addition, the treated water from which the organic matter is removed from the low oxygen precipitation tank 41 is supplied to the anaerobic precipitation tank 42 through the second T-shaped tube T2.

 The anaerobic sedimentation tank 42 is formed in an anaerobic state, and organic matter is decomposed by anaerobic microorganisms, and phosphorus absorbed with excess is released. The excess sludge precipitated in the anaerobic settling tank 42 is conveyed to the storage tank 20 through the third air lift L3 and the conveying line 45. In addition, the treated water from which the organic matter is removed from the anaerobic settling tank 42 is supplied to the anoxic settling tank 43 through the third T-shaped tube T3.

 The anoxic precipitation tank 43 is an anoxic state is formed and denitrification occurs. That is, the nitrate nitrogen is reduced to nitrogen gas (N2) by the microorganisms, and the nitrogen gas (N2) is released into the atmosphere. And the excess sludge precipitated in the anoxic precipitation tank 43 is conveyed to the storage tank 20 through the fourth air lift (L4) and the conveying line (45). In addition, the treated water from which the nitrogen component is removed from the anoxic precipitation tank 43 is supplied to the membrane separation tank 50 through the fourth T-shaped tube T4.

The treated water introduced into the membrane separation tank 50 is solid-liquid separated into solid materials and treated water through the immersion type membrane module 61. Due to the suction pressure generated by the operation of the suction pump 62, the mixture outside the separator flows into the separator through the membrane pores, and solid-liquid separation occurs, and finally, the clean filtered water is discharged to the outside via the suction pump 62. In addition, only the solid matter such as microorganisms is present in the membrane separation tank 50, which is decomposed again by the microbubble injected into the membrane separation tank 50.

Finally, the excess sludge conveyed to the storage tank 20 is discharged to the outside through the sludge discharge pipe (25). At this time, the excess sludge discharged to the outside may be disposed of through a separate sludge treatment process.

In this way, the water treatment device 1 according to the present invention, a coagulant is added to the aerobic tank 30 to remove the phosphorus component and suspended solids, and to remove organic matter using aerobic microorganisms. And between the aerobic tank 30 and the membrane separation tank 50 by installing a settling tank module 40 consisting of a plurality of settling tank to lower the microbial concentration flowing into the membrane separation tank 50 to the maximum while the membrane separation tank (50) The microbubble is injected into the organic material to physically remove the organic material, thereby preventing contamination of the membrane module 61, thereby extending the life of the membrane. In addition, by extending the life of the separator, the cost of frequent replacement of the membrane is reduced, and the maintenance is easy, so that even an inexperienced person can easily manage.

The technical idea described in the embodiments of the present invention as described above may be implemented independently, or may be implemented in combination with each other. In addition, the present invention has been described through the embodiments described in the drawings and detailed description of the invention, which is merely exemplary, and those skilled in the art to which the present invention pertains various modifications and equivalent other embodiments from this It is possible. Therefore, the technical protection scope of the present invention will be defined by the appended claims.

1: separator water treatment device 10: flow rate adjustment tank
11: Raw water inlet pipe 13: Agitator
20: storage tank 23: stirrer
25: sludge discharge pipe 30: aerobic tank
33: diffuser 40: sedimentation tank module
41: low oxygen precipitation tank 42: anaerobic precipitation tank
43: anoxic precipitation tank 45: return line
50: membrane separation tank 61: membrane module
62: suction pump 70: micro bubbler
80: flocculant injection device L1-L4: A lift
T1-T5: T-shaped tube W: Water level sensor

Claims (6)

In the membrane water treatment device comprising a flow rate adjustment tank, an aerobic tank and a membrane separation tank,
A storage tank installed between the flow adjusting tank and the exhalation tank;
A settling tank module installed between the exhalation tank and the membrane separation tank;
A supply line installed between the flow rate adjustment tank and the exhalation tank to supply raw water;
A conveying line installed between the settling tank module and the storage tank to convey excess sludge;
A sludge discharge pipe installed in the storage tank and discharging a part of excess sludge to the outside;
A micro bubbler installed to inject micro bubbles into the membrane separation tank;
A flocculant injection device installed to inject coagulant into the aerobic tank;
And a first T-shaped tube installed inside the aerobic tank and supplying the treated water decomposed by the aerobic microorganisms to the sedimentation tank module adjacent thereto.
The sedimentation tank module is made of a low-oxygen settling tank, anaerobic settling tank and anoxic settling tank in which the treated water flows from the aerobic tank is sequentially installed, the excess oxygen sludge in the interior of the low oxygen settling tank, anaerobic settling tank and the anoxic settling tank An air lift for returning to the storage tank is installed, respectively, and the inside of the hypoxic sedimentation tank, anaerobic sedimentation tank and anoxic sedimentation tank for supplying the solid-liquid separated treated water to a neighboring anaerobic sedimentation tank, anoxic sedimentation tank and the membrane separation tank. Second to fourth T-shaped pipes are respectively installed to reduce the microbial concentration (MLSS) introduced into the membrane separation tank via the settling tank module and contaminants in the membrane separation tank using the micro bubble supplied from the micro bubbler Separation membrane immersed in the membrane separation tank by decomposing Separator water treatment device using a micro bubble, characterized in that to prevent contamination of the membrane to extend the life of the membrane. According to claim 1,
Separation membrane using the micro-bubble is installed in the flow rate adjustment tank is installed raw water inlet pipe, the raw water inlet, the supply line for supplying the raw water to the exhalation tank and the air lift for supplying the raw water to the exhalation tank through the supply line Water treatment device. delete delete delete According to claim 1,
Separator water treatment apparatus using a micro bubble, characterized in that the ozone is contained in the micro bubble by injecting ozone gas into the micro bubble.

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