KR20010068850A - The system to treat the sanitary sewage,wastewater by the membrane separator activated sludge process and the advanced oxidation process - Google Patents

Abstract

PURPOSE: Provided is a sewage-wastewater treatment system using membrane activated sludge process and advanced oxidation process. In membrane process, to prevent membrane from being fouled by pollutants, the system separates pollutants due to vibration by contacting the membrane with fine bubbles containing ozone and removes fine pollutants by the oxidizing power of ozone. CONSTITUTION: The sewage-wastewater treatment system consists of the following parts: a tank (1) for removing adulterated things such as solid wastes and suspended solids in influent wastewater; a denitrification tank (2) for removing organic nitrogen compounds in influent wastewater; a membrane separation tank (4) for removing activated sludge generated by the organic matter uptake of aerobes; a sludge equalization tank (3) for returning surplus sludge into the denitrification tank (2); and an advanced oxidation tank (5) for purifying water that passed from the membrane (41) by using the oxidation power and the sterilizing power of ozone.

Description

Wastewater treatment system using membrane separation activated sludge method and advanced oxidation method {the system to treat the sanitary sewage, wastewater by the membrane separator activated sludge process and the advanced oxidation process}

The present invention is applied to a system for treating sewage and wastewater by applying a membrane separation activated sludge method for separating organic sludge by solid aerobic microorganisms and solid-liquid separation of activated sludge (sludge) by a membrane unit and an advanced oxidation method using ozone. In particular, the self-cleaning of the membrane surface to be installed in the membrane separation tank is possible to omit the pretreatment step for damage and maintenance of the membrane to reduce the installation cost of the auxiliary facilities and the cost of the membrane, as well as to maintain and manage.

Conventionally, the general system for wastewater treatment is a complex treatment step such as screen tank 100, sedimentation tank 200, flow adjustment tank 300, aeration tank 400, sedimentation tank 500, discharge tank 600, etc. Although most of the sewage and wastewater are composed of very high concentrations of pollutants, it is difficult to comply with the treatment standards of the effluent due to low treatment efficiency.

Therefore, in recent years, the active sludge generated at the same time as the removal of organic matter by microorganisms is used to separate solid-liquid by using membranes, and the membrane-separated activated sludge process which removes contaminants of polymers almost completely, and the strong oxidizing and sterilizing power of ozone are used. Therefore, a wastewater treatment system has been proposed to obtain an excellent water treatment efficiency by applying an advanced oxidation process that enables high water treatment.

However, in the wastewater treatment system using the membrane separation activated sludge process and the advanced oxidation process, when the polymer contaminants of the wastewater wastewater adhere to the surface of the microporous membrane, the membrane is not only severely damaged. If the membrane is clogged due to overload of the membrane surface, it is not treated. Therefore, a pretreatment step for preventing and maintaining the membrane was necessary.

Therefore, there is a problem in that additional facility costs are required and a separate membrane cleaning is required for the removal of contaminants adhered to the fine pores of the membrane even when the pretreatment facility is installed.

In addition, because the membrane replacement cycle is short, the consumption of the membrane is high, and the condition of the membrane is very difficult to maintain and manage because the high treatment efficiency of the system can be obtained only by smoothly maintaining and managing the condition of the pretreatment facility and the membrane.

The present invention has been made to solve the above-mentioned conventional problems, and the object of the present invention is to omit the pretreatment facility for damaging and maintaining the membrane, and to extend the membrane replacement cycle for a long time, while being economical and easy to maintain and manage. It is to make it possible to expect perfect treatment efficiency of sewage and wastewater.

Therefore, the present invention is a membrane separation tank (4) formed with a debris removal tank (1), a denitrification tank (2), a sludge (sludge) concentration adjusting tank (3), a membrane separation device (41) and an ozone aeration device (42), In the system composed of advanced oxidation tank (5) to treat sewage and wastewater using membrane separation activated sludge method and advanced oxidation method, ozone is included in the membrane surface of membrane separation device installed in the membrane separation tank (4). By contacting the surface of the membrane with a rising air of fine air bubbles, the contaminants were removed by the vibration of the membrane by contact with the bubbles, as well as adhered to the membrane surface due to the strong oxidizing power of ozone. It allows the removal of ultra fine contaminants, enabling complete self-cleaning of membranes.

1 is a flowchart of a waste water and wastewater treatment system showing a configuration according to an example of use of the present invention.

Figure 2 is a schematic diagram showing the configuration of a membrane separation device applied to the system of the present invention.

3 is a schematic diagram showing a self-cleaning state of the film due to the rising airflow of bubbles. 4 is a flowchart of a conventional wastewater treatment system.

Explanation of symbols on the main parts of the drawing

1: debris removal tank 2: denitration tank

3: sludge concentration adjusting tank 4: membrane separation tank

5: high level oxidizing tank

Hereinafter, with reference to the accompanying drawings will be described in detail the most preferred embodiment of the present invention.

As shown in FIG. 1, the wastewater treatment system of the present invention includes an organic nitrogen compound contained in a contaminant removal tank 1 for removing relatively large solids or suspended solids floating in the incoming wastewater and wastewater. De-nitrification tank (2) to remove water and activated sludge (sludge) generated by decomposing organic matter by aerobic microorganisms by oxygen supplied through ozone aeration device 42 to the wastewater and wastewater from which nitrogen was removed. To be removed by a membrane separation device (41) capable of self-cleaning by an updraft of air bubbles containing ozone that is supplied by spraying by an air diffuser (41e) connected to the ozone aeration device (42). Effluent water containing sludge (sludge) that failed to pass through the membrane separation tank 4 for the separation and the membrane separation device 41 mounted in the membrane separation tank 4 is returned to the concentrated sludge (sludge) The sludge (sludge) concentration adjusting tank (3) for carrying out the wastewater and returning the excess sludge to the denitrification tank (2) and the purified water by the strong oxidation and sterilizing power of ozone It is composed of a highly oxidizing tank (5) to be treated.

At this time, the constituents of the waste water to be treated are various wastes such as kitchens, bathrooms, washing water, and toilets in general households, and are composed of high concentrations of pollutants containing a large amount of solids and floating miscellaneous materials. Therefore, the screen 11 is mounted in the contaminant removal tank 1 for the treatment of solid substances and floating miscellaneous substances in the wastewater and wastewater.

In the denitrification tank (2), a stirring blower (21) for promoting the diffusion of the waste and waste water by agitation and enhancing the effect of the denitrification reaction is provided. An air lift pump 22 for discharging into the tank 4 is provided, and the upper portion of the denitrification tank 2 is provided with a flow rate adjusting unit 2a for coping with the water level fluctuation of the inflow and wastewater. have.

In the membrane separation tank 4, the membrane element 41a having the fine porous membrane sheet 41h attached to both sides of the filter plate 41g, and the tube 41b and the tube 41b for extracting the treated water from the inside thereof are extracted. Membrane separation device composed of a collecting tube 41c into which the treated water is collected, a membrane case 41d containing a plurality of membrane elements 41a, and an air diffuser 41e for spraying air containing ozone as fine bubbles. (41) and a suction pump (43) for causing the treated water from the membrane separation device (41) to flow out into the advanced oxidation tank (5) in the next step, and are housed in the membrane case (41d). The membrane element 41a becomes a flat membrane so that it can be lifted one by one so that inspection and replacement are easy.

At this time, the membrane used as an exemplary embodiment of the present invention is a flat membrane of the microporous membrane, but is selected by MF (micro filtration) <UF (ultra filtration) <RO (reverse osmosis), etc. according to the purpose of removal or reuse. Can be used.

The advanced oxidizing tank 5 has ozone supply 51 and ultraviolet lamp 52 in which ozone-containing air generated from an external ozone generator 6 is connected to the ozone supply pipe and is strongly ejected by the porous diffuser 51a. ) Is installed.

At this time, the ozone generator 6 is also connected to the ozone aeration device 42 of the membrane separation tank 4 to supply air containing ozone.

Therefore, the wastewater treatment by the system of the present invention configured as described above is performed as follows.

First, the waste water discharged from the general household flows into the debris removal tank 1, and solids and suspended solids are collected by the screen 11 of the debris removal tank 1, and then flows into the denitrification tank 2. do.

The organic nitrogen compounds in the wastewater flowing into the denitrification tank (2) undergo a nitrification step in which they are oxidized to NO ₃ ⁻ in the aerobic state in which dissolved oxygen is present in water, if nitrogen is NH3, because of a lack of the water oxygen anaerobic (嫌氣性) when the status received the action of anaerobic bacteria NO ₃ ^- is subjected to the denitrification reaction that is released in the water is in a nitrogen gas, and if nitrogen is NO ₃ ^- as already If only nitrogen is removed by a denitrification reaction, it is introduced into the membrane separation tank 4 by the air lift pump 22.

At this time, if a chemical is put into the denitrification tank (2) to remove phosphorus (P), it is possible to remove phosphorus (P) simply, so it is included in various detergents in the inflowing wastewater and wastewater, which causes eutrophication. Nitrogen and phosphorus can be treated.

The waste water flowing into the membrane separation tank 4 passes through the membrane element 41a of the membrane separation device 41 while being decomposed by oxidation of organic matter by aerobic microorganisms by oxygen supplied from the ozone aeration device 42. While the various contaminants 44 including activated sludge (sludge) are separated, the separated activated sludge (sludge) is returned to the sludge concentration adjusting tank 3 so that some concentrated sludge (sludge) is taken out and some activated sludge is removed. Since the sludge is returned to the denitrification tank 2 to be continuously circulated in the system for treatment, the sludge concentration is adjusted, and only the permeate liquid 45 passing through the fine pores on the membrane surface is separated from the membrane separator. Collected by the collection pipe 41c of 41, it flows out to the high oxidation tank 5 by the suction pump 43. As shown in FIG.

At this time, the contaminants adhering to the membrane surface are included in the bubbles as well as desorb the contaminants by vibrating the membrane by contact with the rising air of the bubble 46 generated from the diffuser (41e) of the membrane separation device (41). Because of the strong oxidizing power of ozone, it is possible to remove ultra fine contaminants that could not be detached due to adhesion to the membrane surface. It will be possible.

Therefore, just two injections of chemical solution per year are sufficient to maintain and manage the membrane, which can significantly increase the life of the membrane and significantly increase the replacement cycle.

In addition, in the membrane separation tank 4, gravity filtration by water level is also possible, and thus higher processing efficiency can be obtained.

On the other hand, the permeate flowing into the high oxidation tank (5) is treated water in which superfine particles of contaminants passed through the membrane element (41a) remain, and ozone generated in the high oxidation tank (5) By reacting, almost all pollutants are completely oxidized and even bacteria are completely sterilized and almost completely removed so that they can be discharged with clean treated water.

The above reactions react with organics as ozone generated in water diffuses rapidly at the bottom of the highly oxidizing tank (5), and in particular, since OH ^- radicals, the decomposition by-products of ozone, react very quickly with almost all organic materials. is the safest way to sterilize degradation products by the reaction of the radicals are oxygen and water, with no generation of secondary waste ^- will have a very short time, the effect is the oxidative decomposition and the sterilization excellent, ozone, ultraviolet rays, OH.

Therefore, the sewage and wastewater treatment system using the membrane separation activated sludge method and the advanced oxidation method is configured to perform a complete self-cleaning function of the used membrane, and does not require a pretreatment facility for preventing and maintaining membrane damage. Maintenance and management costs can be reduced, and automation is possible because the whole system is easy to maintain and manage.

In addition, since the membrane consumption is greatly reduced by the self-cleaning effect of the membrane, there is an advantage of saving the expensive membrane purchase cost.

Therefore, the present invention is a system that can expect complete treatment efficiency of wastewater and wastewater while considering economical efficiency and ease of maintenance and management.

Claims (2)

Provides oxygen to the sewage removal tank (1) for removing solids and suspended solids from inflowing sewage and wastewater, denitrification tank (2) for removal of organic nitrogen compounds from incoming sewage and wastewater, and oxygen to the wastewater from which nitrogen has been removed. Membrane separation tank 4, membrane separation tank 4 mounted in the membrane separation tank 4 to remove the activated sludge (sludge) generated by the decomposition of organic matter by aerobic microorganisms by the membrane separation device 41 Effluent containing sludge (sludge) that has not passed through the device 41 is returned to the sludge (sludge) concentration adjusting tank 3 for carrying out the concentrated sludge (sludge) and returning the excess sludge to the denitrification tank 2, The treatment water that has passed through the membrane separation device 41 is composed of a highly oxidizing tank 5 capable of purifying water by strong oxidizing and sterilizing power of ozone. Wastewater treatment sheath The O and the waste water treatment system. The membrane separation device (41) installed in the membrane separation tank (4) of the sewage and wastewater treatment system is self-contained by rising air of air bubbles containing ozone injected from the air discharging device (41e). Wastewater treatment system using membrane separation activated sludge method and advanced oxidation method characterized by being configured for cleaning.