KR100433469B1 - Wastewater Treatment System - Google Patents

Abstract

The present invention by forcibly supplying air to the closed microbial reaction tank at high pressure to give up the closed microbial reaction tank to suppress the release of air to activate microbial growth, and to analyze the water quality of the treated water to be the highest water supply The present invention relates to a wastewater treatment device that detects and maintains a physical quantity measured in a microbial reaction tank at this time so that the wastewater can be treated at the highest water level at all times. The wastewater treatment device is sealed and grows microorganisms therein. A microbial reaction tank with a built-in filter medium; A pump connected to the microbial reaction tank and a pipe to supply wastewater to the microbial reaction tank; An ejector installed in a pipe between the microbial reaction tank and the pump to supply external air to the microbial reaction tank by a pipe pressure and an atmospheric pressure difference when the pump supplies waste water; Sludge separation means connected to the microbial reaction tank and pipes to collect the first treated water discharged from the microbial reaction tank to collect and remove the injured sludge by the skimmer and to remove the precipitated sediment by the scraper installed on the floor Here, the water quality analyzer analyzes the discharged treated water, and the control determines the highest level, and stores the physical quantity such as temperature and pressure in the microbial reaction tank, quantity of waste water, and numerical information of the concentration of gas. It is characterized by further having a control device for maintaining the physical quantity of the microbial reaction tank according to the information.

Description

Wastewater Treatment System {Wastewater Treatment System}

The present invention relates to an apparatus for treating various wastewater discharged from an industrial site or a home, and more particularly, by forcibly supplying air required for the growth of wastewater and microorganisms to a closed tank by using a pump and an ejector at high pressure. By abandoning, the closed tank suppresses the release of abandoned air, thereby increasing the oxygen dissolution rate, thereby remarkably activating the growth of microorganisms, and in particular, a thermal insulation means is provided to maintain the temperature necessary for the growth of microorganisms even in cold weather. When the water quality reaches the highest water level, it is possible to detect and maintain physical quantities such as tank pressure, temperature, quantity, and gas concentration at this time to treat the waste water as cleanly as possible to prevent environmental pollution.

Wastewater treatment methods are largely divided into physicochemical treatment and biochemical treatment. The physicochemical treatment uses chemicals, and the biochemical treatment uses microorganisms to treat the wastewater.

1 shows a physicochemical treatment method which is most commonly used. This physicochemical treatment method separates raw water storage tank (1) for temporarily storing waste water, agglomeration reaction means (2) for aggregating waste water by adding chemicals, and treated water treated in the flocculation reaction means (2) into sludge and sediment. Sludge separation means 3 are connected to each other by a pipe (4). And a pipe (P) and a pressure tank (5) for forcibly transporting and compressing the waste water is installed on the pipe (4) between the flocculation reaction means (2) and the sludge separation means (3), the pump (P) and Between the pressure tanks 5, an ejector 6 for supplying air is installed.

The agglomeration reaction means (2) is provided with a supply tank (8) for supplying a coagulant to agglomerate wastewater on the reaction tank (7) formed in a multi-stage.

The sludge separation means (3) is provided with a skimmer (11) for collecting the sludge floating in the upper portion of the reservoir (9) to the trench 10, the scraper 12 for treating the precipitates are installed on the bottom of the reservoir. .

In the physicochemical treatment method configured as described above, when the pump P is driven, wastewater stored in the raw water storage tank 1 is transferred to the reaction tank 7 of the flocculation reaction means 2 through the pipe 4. When staying there for a predetermined time, the flocculant stored in the supply tank 8 is supplied to the wastewater, and the organic matter of the wastewater is collected and aggregated in the form of agglomerates to treat the wastewater first.

Thereafter, the treated primary treated water is transferred to the sludge separation means 3 through the pressure tank 5 by the driving of the pump P, and the ejector by the driving of the pump P in this process. Air supplied through 6 is conveyed to the sludge separation means 3 together with the primary treated water in a state of being compressed at high pressure in the pressure tank 5. As such, the compressed air transferred to the sludge separation means 3 flows into the reservoir 9 and at the same time, the pressure is suddenly lowered to increase the microbubble and rise to the small mass or organic matter in the water.

Thereafter, the floated sludge is transferred to the trench 10 by the cummer 11 installed on the sludge separation means 3 and finally disposed or transferred back to the flocculation reaction means 2, and the precipitate precipitated to the bottom. The scraper 12 is processed and removed. The treated water treated in this way is overflowed from the reservoir 9 and finally discharged.

However, the conventional chemical treatment method has to use a flocculant as a chemical to agglomerate the wastewater, the supply tank (8) for supplying the flocculant and the pipes and accessories should be further installed, there was a problem that the facility is complicated and large, the chemical Careful care was required, such as health care of workers according to the use and prevention of incidental environmental pollution due to the use of drugs.

Due to these problems, biochemical treatment using microorganisms has recently been applied. This biochemical treatment method is to multiply the microorganisms in the microbial reaction tank, the microorganisms ingest the organic matter of the wastewater into agglomerate form and transfer the treated primary treatment water to the sludge separation means by using a skimmer and a scraper as in the chemical treatment method. Floating sludge and settled sediments are removed.

In the conventional biochemical treatment method, when the microorganism is an aerobic microorganism requiring oxygen, an aeration means for abandoning air in the microbial reaction tank must be installed in order to propagate the microorganism.

The aeration means may be configured in various forms. In general, a blower is formed to communicate with an acid pipe under the microbial reaction tank, such that the air injected by the blower causes the air to be abandoned through the acid pipe. Alternatively, as described above, a pressurized method using a pressure pump and a pressure tank, that is, when a part of the wastewater in the microbial reactor is forced to return to the microbial reactor using a pump, introduces air through an ejector installed on the pipe. The compressed air was compressed to high pressure in the pressurized tank and then discharged to high pressure in the microbial reactor. This air pressurized aeration method is the air is discharged to the microbial reactor to form a lot of fine particles to supply oxygen to the microorganisms.

The microorganisms propagated by the above-mentioned aeration means decompose the organic matter of the waste water to form a lump, and the first treatment, and the treated water is transferred to the sludge separation means, where the lump-shaped sludge is wound there. It is then removed by the skimmer and the scraper removes the precipitate.

However, in the biological treatment method using the microorganisms as described above, the bioreactor is configured in an open form so that most of the oxygen supplied by the aeration means is released and its dissolution rate is about 5-15%. Since the growth was not smooth, the organic matter decomposition of the wastewater was not satisfactorily achieved, and the wastewater treatment state was not clean.

In addition, the sediment precipitated in the sludge separation means takes a long time to settle because it is a natural sedimentation, and if the sedimentation time is reduced, the secondary treatment water finally treated in the sludge separation tank is not treated cleanly, causing environmental pollution There was this.

The present invention is to solve the conventional problems as described above, the purpose is to seal the microbial reaction tank and at the same time equipped with a heat insulating means to enable microbial growth in the winter and waste water and air for microbial growth pump and It is to provide a wastewater treatment apparatus that can force the microbial proliferation by increasing the oxygen dissolution rate by suppressing the release of the abandoned air by forcibly abandoning the air by forcibly supplying the high pressure using the ejector.

Another object of the present invention is to detect and maintain the physical quantity of the pressure, temperature, quantity, gas concentration, etc. of the microbial reaction tank at this time when the water quality of the second treated water finally treated in the sludge separation means is the highest water supply. It is to provide a wastewater treatment apparatus that can be treated in an optimal state at all times.

Such a wastewater treatment apparatus includes a microbial reaction tank in which a wastewater is sealed and a medium for propagating microorganisms therein; A pump connected to the microbial reaction tank and a pipe to supply wastewater to the microbial reaction tank; An ejector installed in a pipe between the microbial reaction tank and the pump to supply external air to the microbial reaction tank by a pipe pressure and an atmospheric pressure difference when the pump supplies waste water; Sludge separation that the skimmer collects and removes the injured sludge and collects and removes the sediment before the sediment before settling by collecting the first treated water discharged at high pressure by being treated by the microbial reaction tank and pipe connected to the microbial reaction tank. Means;

Here, the ejector is installed on the pipe between the pump and the microbial reaction tank so that external air can be introduced when the pump transports the wastewater, or the air on the pipe between the pump and the microbial reaction tank. The supply pipe may be further installed to install the ejector in this air supply pipe.

Each of the ejector both bypass pipes is provided with a flow rate control valve for controlling the flow rate of the air supplied to the microbial reaction tank through the ejector to selectively control the air inflow amount.

In addition, the microbial reaction tank may be provided with a separate aeration means, the aeration means may be provided with an air compressor in the microbial reaction tank to give up air using this air compressor. Another embodiment of the aeration means is to install a diffuser on the bottom of the microbial reaction tank and connect the blower for supplying air to the diffuser so that the air supplied by the blower is abandoned in the form of fine bubbles in the diffuser.

In addition, the microbial reaction tank is further equipped with a heating means to activate the growth of microorganisms even in cold winter.

The thermal insulation means of the microbial reaction tank may be applied to various embodiments, it may be a heat insulating material is covered on the outer wall of the microbial reaction tank, it may be a heater wound on the outer wall of the microbial reaction tank. In addition, the insulating means will be possible by forming the microbial reaction tank into a double tube to circulate the hot water to the space between the double tube.

The present invention connects the flow storage tank for temporarily storing the waste water and the separation tank of the sludge separation means by a first bypass pipe to transfer the sludge collected and separated from the sludge separation means to the flow storage tank to recycle microorganisms and further waste water. Make sure it's clean.

The fertilizer manufacturing apparatus may be further installed on the first bypass pipe so as to recover some of the sludge transferred to the flow rate storage tank through the first bypass pipe, thereby efficiently making resource use. have.

The fertilizer manufacturing apparatus is preferably connected to the lower sludge separation means and the second bypass pipe so as to manufacture the fertilizer using the precipitate precipitated in the sludge separation means.

In the present invention, in the treatment of wastewater, various water quality analyzers check the water quality of the treated water finally processed by the sludge separation means, and the control determines the water quality information to determine the highest water quality from the inspected water quality information. The control stores and physically stores the physical quantities such as pressure, temperature, quantity, and gas concentration in the microbial reaction tank, which are organically connected to the control and detected by a pressure gauge, thermometer, gas analyzer, and flow meter installed in the microbial reaction tank. It further has a control device for controlling the microbial reaction tank.

The water quality analyzer used in such a control device is a biodegradation (BOD) analyzer for analyzing biological oxygen demand, a Shiodi (COD) analyzer for analyzing chemical oxygen demand, and an SS (SS) analyzer for analyzing the degree of suspended matter, and the control The water quality information of the treated water analyzed by each of these water quality analyzers is determined at any time, and whenever the advanced water quality information is inputted than the previously stored water quality information, the previously stored information is deleted and new advanced information is stored. When the lower water quality information is input than the stored water quality information, the controller maintains the physical quantity and then deletes all the stored water quality information, and repeats the above process whenever the water quality information is input again from that point, and discharges the highest quality treated water at all times. To control it.

1 is a schematic diagram of a conventional wastewater treatment apparatus,

2 is a schematic view of the wastewater treatment apparatus of the present invention,

Figure 3 is a heat insulating means according to the present invention, the front cross-sectional view of the state in which the heat insulating material is covered in the microbial reaction tank,

4 is a front view of a heater wound in a microbial reaction tank as another thermal insulation means according to the present invention;

5 is a further cross-sectional view of the microbial reaction tank having a double pipe as another insulating means according to the present invention,

6 is a front view of a state in which the air compressor is mounted on the microbial reaction tank as the aeration means according to the present invention;

7 is a front view of a state in which a diffuser and a blower are mounted in a microbial reaction tank as another aeration means according to the present invention;

8 is a schematic view of a state in which the control means for controlling the physical quantity is mounted in the microbial reaction tank according to the present invention.

Explanation of symbols on the main parts of the drawings

15: microbial reaction tank 16: sludge separation means

19: ejector 20: flow adjustment tank

21: heat insulating material 22: heater

23: double tube 24: space

25: air compressor 26: diffuser

27: blower 33: the first bypass tube

34: fertilizer manufacturing apparatus 35: the second bypass pipe

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of each embodiment of the present invention. Figure 2 is a schematic view of the wastewater treatment apparatus of the present invention, Figures 3 to 5 is a front sectional view of a microbial reaction tank to which each of the thermal insulation means according to the present invention, Figure 6 to Figure 7 is a microorganism to which each aeration means according to the present invention is applied 8 is a front view of a reaction tank, and FIG. 8 is a schematic view of a state in which a control means for controlling a physical quantity is mounted in a microbial reaction tank.

The present invention will be a revolutionary invention by using a pressure tank used for supplying conventional air as a closed bioreactor.

As shown in FIG. 2, the microbial reaction tank 15 is formed to be sealed, and the pump P and the sludge separation means 16 are connected to the pipe 17 so as to communicate with the microbial reaction tank 15. In addition, the sludge separation means 16 is a storage tank 18 is connected to the microbial reaction tank 15 and the pipe 17. In addition, the pipe 17 between the microbial reaction tank 15 and the pump P supplies external air to the microbial reaction tank 15 by a pipe pressure and an atmospheric pressure difference when the pump P supplies wastewater. An ejector 19 is installed. In addition, the flow rate adjustment tank 20 for temporarily storing the waste water is further installed on one side of the pump (P).

The microbial reaction tank 15 should have a sufficient space area so that microorganisms are multiplied therein and the wastewater supplied by the pump P can be stored sufficiently for storage. Therefore, the microbial reaction tank 15 is selectively determined according to the treatment capacity.

In addition, the microbial reaction tank 15 is preferably embedded with a media (media) to help microbial growth. Here, the filter medium provides a place where various kinds of microorganisms are attached to the anaerobic, aeration, aerobic, and the like.

The microbial reaction tank 15 further has a keeping means as shown in Figures 3 to 5 to maintain the temperature required for the growth of microorganisms even in cold weather, such as winter.

Here, the heat retaining means maintains a temperature suitable for microbial growth, and is organically linked with the control means described later to discharge the treated water discharged from the sludge separation means 16 to the highest water state. Done.

Various embodiments may be applied to the thermal insulation means, one of which will be a heat insulator 21 covering the outer wall of the microbial reaction tank 15 as shown in FIG. The heat insulating material 21 is a sponge or synthetic resin or glass fiber excellent in heat insulating property may be applied in addition to a variety of.

Another embodiment of the thermal insulation means may be a heater 22 that generates heat by supplying power to the outer wall of the microbial reaction tank 15 as shown in FIG. 4. The heater 22 does not need to be wound to the top of the microbial reaction tank 15 in view of the heat rising.

In addition, another embodiment of the insulating means is configured by the microbial reaction tank 15 itself in the form of a double tube 23, as shown in Figure 5 is heated by a heating device to the space 24 to form the double tube (23) The hot water is circulated to control the temperature inside the microbial reaction tank 15. Since the temperature inside the microbial reaction tank 15 is determined according to the temperature of the circulating hot water, the temperature inside the tank is selectively controlled by a control control of a controller to be described later. That is, the heating device for heating the temperature is operated under the control of the control to heat the hot water to adjust the temperature of the microbial reaction tank 15.

The microbial reaction tank 15 is further provided with a separate aeration means therein as shown in Figs.

Here, the aeration means is the air itself is supplied to the high pressure state by the pump (P) and the ejector 19 as described above, but the aeration function, but other than the aeration means provided separately.

Such aeration means is an air compressor 25 installed in the microbial reaction tank 15 as shown in FIG. Air supplied to the microbial reaction tank 15 through the air compressor 25 is also supplied at a high pressure to supply a large amount of oxygen to the microorganisms to the air and the air supplied by the ejector 19 to activate microbial growth. do.

In addition, the aeration means includes a diffuser 26 installed on the bottom surface of the microbial reaction tank 15 and a blower 27 installed on the diffuser 26 as shown in FIG. Since the aeration means composed of the diffuser 26 and the blower 27 is a conventional aeration method, a detailed description thereof will be omitted.

An ejector 19 is further installed between the microbial reaction tank 15 and the pump P. The ejector 19 is a microbial reaction tank for the waste water stored in the flow rate adjusting tank 20. The function of supplying atmospheric air to the microbial reaction tank 15 by using the pressure difference generated when the high pressure is supplied to the (15), it is commonly used in the industrial field, the detailed description thereof will be omitted.

Here, the ejector 19 may be installed on the pipe 17 between the microbial reaction tank 15 and the pump P as described above, or may be separately provided on the pipe 17 as shown in the drawing. The air supply pipe 28 may be further installed to be installed at the center of the air supply pipe 28, and the flow control valve 29 may be further installed at the air supply pipe 28 on both sides of the ejector 19. It is preferable to adjust the pressure of the air introduced and the amount of air introduced.

The sludge separation means 16 is the same as a conventional structure.

In other words, the sludge separation means 16 is a storage tank 18 for storing the primary treatment water treated in the microbial reaction tank 15 is located in the lower portion, the upper portion of the storage tank 18 is decomposed by the microorganisms. The skimmer 31 which collects the sludge of the lump-shaped sludge into the trench 30 is installed, and a scraper 32 is installed on the bottom surface of the reservoir 18 to remove precipitates.

In the present invention, the flow rate adjusting tank 20 for temporarily storing the wastewater is installed to stably supply the wastewater to the microbial reaction tank 15. The flow rate adjusting tank 20 and the storage tank 18 of the sludge separation means 16 are connected to the first bypass pipe 33 to the trench 30 by the skimmer 31 of the sludge separation means 16. The separated sludge is transferred to the flow adjusting tank 20 to recycle the microorganisms contained in the sludge so that the wastewater can be treated more cleanly.

In addition, the present invention is a fertilizer on the first bypass pipe 33 to recover some of the sludge conveyed to the flow rate adjustment tank 20 through the first bypass pipe 33 to produce a fertilizer. The manufacturing apparatus 34 is further installed.

The fertilizer manufacturing apparatus 34 is preferably connected to the lower sludge separation means 16 and the second bypass pipe 35 so as to manufacture the fertilizer using the precipitate precipitated in the sludge separation means 16. .

In addition, the present invention, when treating the wastewater by using the microbial reaction tank 15 and the sludge separation means 16, the water quality of the treated water finally treated in the sludge separation means 16 is examined, The control means for detecting the physical quantity such as pressure and temperature in the microbial reaction tank 15 and to control the physical quantity to maintain the state is further installed.

The control means includes various water quality detectors (not shown) for detecting biological oxygen demand and chemical oxygen demand of the treated water finally discharged from the sludge separation means 16 and the degree of suspended solids in the treated water, and the microbial reaction. A pressure gauge (36) installed in the tank (15) for analyzing the internal pressure, temperature, flow rate of the wastewater, and the concentration of the gas generated in the wastewater treatment process and the concentration of the gas contained in the introduced air in the microbial reaction tank (15). And various gauges including a thermometer 37, a flow meter 38, and a gas analyzer 39, and the information sent by the water quality sensors to determine the best water to be treated. Control to store the information detected by the 37, 38, 39 to maintain a constant physical quantity of the microbial reaction tank 15 detected by the gauges 36, 37, 38, 39 ( 40).

Thus, the water quality sensor, the gauges 36, 37, 38, 39 and the control 40 are organically connected to each other so that the water quality can be treated in the highest water supply condition within the range of the waste water treatment. To be.

Here, the water quality analyzer may be applied in various ways, but preferably, in consideration of simplicity in handling, an analyzer for inspecting a main physical quantity which is a factor for determining a state of water quality, a bio-analytical (BOD) analyzer for examining a biological oxygen demand, It should be limited to a COD analyzer that checks chemical oxygen flow and an SS analyzer that checks the degree of suspended solids in the treated water.

Next, a process of treating wastewater using the present invention configured as described above will be described in detail with reference to the accompanying drawings.

The overall apparatus of the present invention is shown in FIG. The microbial reaction tank 15 may be provided with any one of the aeration means consisting of the air compressor 25 or the diffuser 26 and the blower 27, or both aeration means may be installed.

The microorganism reaction tank 15 is further provided with the insulating means. Therefore, the heat insulating material 21 or the heater 22 is wound around the outer circumference of the microbial reaction tank 15. In addition, the microbial reaction tank 15 may be configured in the form of a double tube 23 having an inlet 23a and an outlet 23b to continuously supply hot water separately heated to the space 24 forming the double tube 23. have.

In addition, the water quality analyzer is installed on the final treated water path discharged from the sludge separation means 16, and various gauges 36, 37, 38, and 39 are installed in the microbial reaction tank 15. The control 40, the analyzer and the gauges are operated organically to each other to install a control device to complete the overall device.

The wastewater is treated by the completed device as described above. First, when the pump P is driven, the wastewater stored in the flow rate adjusting tank 20 is driven by the pump P at a high speed and high pressure. At the same time, the external air is supplied to the microbial reaction tank 15 at a high pressure through the ejector 19 to give up oxygen, and oxygen is supplied to the microorganisms attached to the media of the microbial reaction tank 15. The microorganisms propagated by this high-pressure abandonment take up organic matter from the supplied wastewater and decompose it into a lump.

At this time, when the abandonment is not satisfactorily achieved by the method of giving up the air in a high pressure state by the ejector 19, the separate aeration means is used. That is, by using the air compressor 25 or by driving the blower 27 to discharge the air from the diffuser (26) it is possible to abandon the air sufficiently to activate the microbial growth. Therefore, the microorganism of the microbial reaction tank 15 is proliferated due to sufficient abandonment, so that the wastewater is decomposed to make sludge.

On the other hand, when the waste water is treated in the cold winter weather, the microorganisms in the microbial reaction tank 15 are propagated using the warming means. The insulating means may be in various forms, such as forming the heat insulating material 21 or the heater 22 and the microbial reaction tank 15 as a double tube 23, but they are appropriately selected according to the conditions of use.

Since the warming means in the form of a double tube 23 of the microbial reaction tank 15 of the heat insulating means is set to a temperature most suitable for the growth of microorganisms by controlling the temperature of the hot water because the separately supplied hot water flows into the double tube 23, In conjunction with the control device to control the temperature of the microbial reaction tank (15).

As described above, the primary treatment water treated in the microbial reaction tank 15 is supplied by the microorganisms through the pipe 17 and the gas supplied by the ejector 19 to the high pressure together with the remaining gas. These gases are supplied to the sludge separation means 16, and these gases are various gases discharged by microorganisms, that is, carbon dioxide, ammonia, methane, hydrogen sulfide, and air supplied by the ejector 19, that is, nitrogen.

The various gases are dissolved in the primary treatment water and supplied to the sludge separation means 16 together with the primary treatment water under high pressure, and suddenly flow into the storage tank 18 of the sludge separation means 16. As the pressure is lowered, the state becomes fine bubbles and rises. In this process, the agglomerates mixed in the primary treated water by the surface tension of the rising micro-bubbles are attached to the micro-bubbles to rise to the surface, the heavy gravity material is precipitated at the bottom of the reservoir 18, the skimmer It is removed by the 31 and the scraper 32 and subjected to secondary treatment, and the treated secondary water is discharged from the reservoir 18.

When the discharged secondary treated water is analyzed by each water quality analyzer of the control device from time to time, the control 40 collects the information analyzed by the water quality analyzer and determines that it is the highest water supply. The microbial reaction tank 15 ) Input numerical information of temperature and pressure, quantity of waste water and concentration of gas in order to maintain the physical quantity of the microbial reaction tank 15 according to the inputted information, so that the waste water can be discharged to the highest level within the capability of the device to process. Will be processed as a state.

In the process of treating the waste water as described above, the sludge and the precipitate are supplied to the fertilizer manufacturing apparatus 34 through the first and second bypass pipes 33 and 35 to be manufactured as fertilizer.

In the present invention configured as described above, the microbial reaction tank is configured to be sealed, and air is supplied to the high pressure state through the ejector by the pump, so that the oxygen is not only supplied sufficiently but also the release of the supplied oxygen is remarkably. It is suppressed to smoothly multiply the microorganisms to increase the wastewater treatment effect.

In addition, by controlling the control device to control the various physical quantities of the microbial reaction tank appropriately to treat the waste water to the highest water has the advantage of reducing environmental pollution. In addition, the present invention is provided with a thermal insulation means in the microbial reaction tank. Therefore, in the cold or cold weather is to maintain the temperature required for the growth of microorganisms.

In addition, since the fertilizer manufacturing apparatus can manufacture the fertilizer by raw material of the sludge and sediments as by-products of wastewater treatment, it is possible to prevent secondary environmental pollution by sludge and sediment and to recycle the resources.

Claims (14)

A microbial reaction tank, which is sealed and has a medium for growing microorganisms therein; Thermal insulation means installed in the microbial reaction tank to maintain a temperature necessary for the growth of microorganisms even in winter; A pump connected to the microbial reaction tank and a pipe to supply wastewater to the microbial reaction tank; An air supply pipe is installed on a pipe between the microbial reaction tank and the pump, and the ejector for supplying external air to the microbial reaction tank by a difference between a pipe pressure and an atmospheric pressure when the pump supplies waste water to the air supply pipe; Sludge separation means connected to the microbial reaction tank and pipes to collect and remove the first treated water discharged from the microbial reaction tank by the skimmer to remove the injured sludge and to collect and remove the precipitated sediment by the scraper installed on the floor ; Disposal means consisting of any one of an air compressor or an diffuser directly connected to the microbial reaction tank. delete delete delete The wastewater treatment apparatus according to claim 1, wherein the thermal insulation means is a heat insulator covered on the outer wall of the microbial reaction tank. The wastewater treatment apparatus according to claim 1, wherein the thermal insulation means is a heater that is wound around the outer wall of the microbial reaction tank. The wastewater treatment apparatus according to claim 1, wherein the thermal insulation means forms the microbial reaction tank into a double tube to circulate hot water into the space between the double tubes. delete delete delete The flow rate adjusting tank is installed so that waste water can be stored and supplied to the pump, and a first bypass pipe for bypassing sludge to the flow adjusting tank is connected between the flow adjusting tank and the storage tank of the sludge separating means. And a fertilizer manufacturing device for recovering sludge transported to the first bypass pipe at a predetermined position of the first bypass pipe to produce fertilizer. The wastewater treatment apparatus according to claim 11, wherein the fertilizer production apparatus is connected to a storage tank of the sludge separation means and a second bypass pipe so as to prepare fertilizer using the precipitate precipitated in the sludge separation means. . The method of claim 1, wherein in treating the wastewater by using the microbial reaction tank and the sludge separation means, the water quality state finally processed by the sludge separation means is analyzed and the water quality in the microbial reaction tank at that time is the highest. A wastewater treatment apparatus further comprising a control device for treating the wastewater with the highest grade water by setting various physical quantities such as pressure and temperature in the state. 14. The apparatus of claim 13, wherein the control device comprises: various water quality sensors for sensing the biological oxygen demand, the chemical oxygen demand, and the suspended matter in the treated water treated in the sludge separation means and finally discharged; Pressure gauges, thermometers, flow meters installed in the microbial reaction tank to analyze the internal pressure, temperature, flow rate of the wastewater and the concentration of the gas generated in the wastewater treatment process and the concentration of the gas contained in the air flow; Various gauges including gas analyzers; And analyzing the information sent from the water quality sensors from time to time to determine the highest level, and storing the information detected by the gauges to control the physical quantity of the microbial reaction tanks detected by the gauges to be kept constant. In this case, the control frequently determines the water quality information of the treated water analyzed by each of these water quality analyzers, and deletes the stored information and saves the new advanced information at the same time when the advanced water quality information is input from the previously stored water quality information. It controls to maintain the physical quantity of the microbial reaction tank, and then deletes all the stored water quality information when lower water quality information is input than stored water information, and repeats the above process whenever water quality information is input again from that time point. Wastewater treatment device.