KR100447812B1 - Process and plant of the ubr formation for wastewater treatment - Google Patents

Abstract

Disclosed is a wastewater treatment apparatus having a stirring means. Such waste water treatment apparatus is a waste water is stored, the aeration tank in which the inside is divided up and down by at least one partition, and is integrally mounted to the lower portion of the aeration tank is equipped with a raw water inlet pipe and an air inlet pipe, the raw water inlet pipe A concentration tank for precipitating sludge of wastewater introduced through the wastewater is disposed in the partition to agitate the wastewater introduced from the thickening tank and collide bubbles formed by air introduced through the air inlet pipe to increase dissolved oxygen, and to stay there. Sludge separation to extend the time, the reactor consisting of agitation means for decomposing contaminants by aerobic microorganisms, and the sludge contained in the waste water discharged from the reactor connected integrally with the reactor and return the waste water back to the concentration tank. Includes Joe.

Description

Method and apparatus for constructing bioreactor for integrated wastewater treatment device {PROCESS AND PLANT OF THE UBR FORMATION FOR WASTEWATER TREATMENT}

The present invention relates to a wastewater treatment device, and more particularly, by integrally equipped with a stirring means inside the reaction tank, when biologically treating wastewater, by effectively supplying and stirring oxygen to the wastewater, the wastewater treatment efficiency can be improved. The present invention relates to a wastewater treatment apparatus.

In general, water treatment is a process of converting contaminated substances in water into substances stabilized by microorganisms or chemical oxidation and reduction reactions.

Therefore, the water treatment technology is a technique for stabilizing the characteristics of the wastewater, organic matter and nutrients in various ways. Currently, water treatment techniques are mostly biological treatment methods and relatively inexpensive treatment costs.

However, this biological water treatment method is very slow and unstable because it depends on the organic decomposition rate of microorganisms in the natural state.

Thus, the key to biological wastewater treatment is to supply organic matter more freely as a source of free or combined oxygen as a source of energy, and to maintain the proper conditions of microorganisms, and to contact between microorganisms and organic or nutrients. This is to stir efficiently so that it can be made smoothly.

The basic principle of such biological treatment is through a laboratory, and based on the device, it is installed on site. However, since the device installed in the field is a large scale, fluid movement is different from that of the laboratory, and the accumulation of sludge in the vicinity of the reactor is intensified, which reduces the space where the microorganisms can operate, thereby causing treatment efficiency and deterioration. have. This phenomenon is an essential phenomenon due to the enlargement of the device, and appears to have a limit to substantially improve through structural deformation.

Accordingly, an object of the present invention is to install a slanted blade assembly inside the reaction vessel to solve the above problems, to induce the fluid to have a certain direction by passing the gas or liquid to prevent the accumulation of sludge in the reaction vessel and It is to provide a waste water treatment apparatus for increasing the stirring effect.

In addition, another object of the present invention, in order to solve the above problems, in the process of separating the sludge generated after biological treatment by connecting the sludge separation tank to the reaction tank, by matching the direction of gravity of the fluid movement direction with the sludge and The present invention provides a wastewater treatment apparatus that can effectively separate the supernatant.

In addition, another object of the present invention is to install a wedge-shaped guide blade in the lower portion of the thickening tank, thereby effectively depositing relatively high density and high specific gravity solids due to the difference in relative velocity of the fluid due to air buoyancy around the guide blade. To provide a waste water treatment apparatus that can be.

In addition, another object of the present invention, in order to solve the above-mentioned problems, the sludge is high in specific gravity by inducing circular motion by the rotational force generated by the blade assembly of the upper sludge conveyed and introduced into the reactor, the center of the reactor bottom It is to provide a water treatment process by using a bioreactor to accelerate the concentration of sludge by induction to induce decomposition, precipitation, and concentration of organic matter by a single reactor.

1 is a structural diagram schematically showing the structure of an integrated wastewater treatment apparatus according to an embodiment of the present invention.

FIG. 2 is a sectional view of a reactor of the wastewater treatment apparatus shown in FIG. 1; FIG.

3 is an enlarged partial view of a blade assembly of the wastewater treatment apparatus shown in FIG.

4 is a sectional view of the blade assembly shown in FIG.

FIG. 5 is a sectional view of an "A-A" portion of the wastewater treatment apparatus shown in FIG.

FIG. 6 is an enlarged cross-sectional view of a portion “B-B” of the integrated wastewater treatment apparatus shown in FIG. 1; FIG.

Figure 7 is a schematic structural view showing the structure of the integrated wastewater treatment apparatus according to another preferred embodiment of the present invention.

FIG. 8 is an enlarged view showing a portion of the blade assembly of the integrated wastewater treatment apparatus shown in FIG.

9 is a perspective view showing a blade assembly of the integrated wastewater treatment apparatus shown in FIGS. 3 and 7.

Figure 10 is a schematic cross-sectional view showing the structure of an integrated wastewater treatment apparatus according to another preferred embodiment of the present invention.

FIG. 11 is a sectional view seen from above of the guide blade shown in FIG. 10; FIG.

FIG. 12 is a bottom view of the outlet shown in FIG. 10; FIG.

In order to achieve the above object, the present invention is the waste water is stored, the inside of the aeration tank divided up and down by at least one partition; A concentrating tank mounted integrally with the lower portion of the aeration tank and equipped with a raw water inflow pipe and an air inflow pipe, for settling sludge of wastewater introduced through the raw water inflow pipe; Stir to dissolve contaminants by aerobic microorganisms by increasing the amount of dissolved oxygen by agitating the waste water introduced from the concentration tank and colliding the bubbles formed by the air introduced through the air inlet pipe, and extending the residence time A reactor consisting of means; And it is connected integrally with the reactor provides an integrated wastewater treatment apparatus including a sludge separation tank for sedimentation of sludge contained in the wastewater discharged from the reactor and returning the wastewater to the concentration tank.

In addition, in order to achieve the above object, the present invention is the waste water is stored, the inside of the up and down partitioned by at least one partition, the aeration tank protruding gas inlet and gas collecting port formed in each partition; A reactor comprising stirring means for agitating the wastewater introduced into the partition and colliding bubbles formed by the gas introduced through the gas inlet to extend the residence time to decompose contaminants by anaerobic microorganisms; And it is connected integrally with the reactor provides an integrated wastewater treatment apparatus including a sludge separation tank for sedimentation of sludge contained in the wastewater discharged from the reactor and returning the wastewater to the concentration tank.

Hereinafter, an integrated wastewater treatment apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figures 1 to 4, the integrated wastewater treatment apparatus proposed by the present invention comprises a first reactor (1) for primarily decomposing contaminants contained in the wastewater by aerobic microorganisms by mixing the wastewater and air, A second reactor (2) connected to the first reactor (1) for secondary decomposition of contaminants contained in the wastewater introduced from the first reactor (1), and the wastewater introduced from the second reactor (2) Sludge separation tank 3 for removing the sludge by sedimenting the sludge contained in the natural flow type.

In the integrated wastewater treatment apparatus having such a structure, the first reactor (1) is cylindrical and the aeration tank (4) in which the waste water flows into and stored therein, and the concentration tank integrally mounted to the lower portion of the aeration tank (4). It includes (6).

One side of the concentration tank 6 is connected to the raw water inlet pipe 7 through which waste water is introduced, and the raw water inlet pipe 7 is connected to a pump (not shown) or the like to feed the raw water by a predetermined pressure.

As such, the wastewater introduced into the concentration tank 6 by the predetermined pressure rises and flows into the reactor 1, and in this process, the sludge having a large specific gravity falls downwardly and is precipitated and discharged to the outside. At this time, by adjusting the pressure it is possible to adjust the inflow rate of the introduced waste water, it is possible to adjust the amount and time of the sludge precipitated.

In addition, the raw water inlet pipe is disposed in a tangential direction with respect to the thickening tank 6 as shown in Figure 6, so that the incoming waste water is rotated inside the thickening tank (6). In addition, an air inlet pipe 8 is connected to one upper portion of the concentration tank 6.

Therefore, waste water and air are introduced into the first reactor 1 through the raw water inlet pipe 7 and the air inlet pipe 8. At this time, the waste water is gradually allowed to flow upward from the inside of the first reactor 1 by a predetermined pressure by the pump.

The aeration tank 4 is provided with a plurality of partitions 13 and 20 therein, and the inner space is divided into a plurality of spaces 36 up and down by the plurality of partitions 13 and 20.

Further, circular holes 13a are formed in the plurality of partitions 13 and 20, respectively, and wastewater flows into the upper space through the circular holes 13a.

At this time, in each of the spaces 36, the flow of the wastewater is agitated due to collision with the bottoms of the partitions 13 and 20 in the process of increasing the flow of the introduced wastewater, and mixed with the air bubbles formed by the introduced oxygen to the aerobic microorganisms. As a result, the pollutants contained in the waste water are gradually decomposed.

In more detail, the aeration tank 4 is equipped with first and second partitions 13 and 20 from below, and the first and second partitions 13 and 20 are provided with stirring means, namely, first and second partitions 13 and 20. Second blade assemblies 9 and 19 are mounted respectively. Since the first and second partitions 13 and 20 have the same structure, and the first and second blade assemblies 9 and 19 have the same structure, the first partition 13 and the first blade assembly will be described below. It demonstrates by (9).

A circular hole 13a having a predetermined diameter is formed in the middle of the first partition 13, and waste water flows upward through the circular hole 13a. Parts other than the circular hole 13a are sealed by the partition 13 so that the waste water collides with the bottom surface of the partition 13 and flows downward. In addition, a bubble is formed by the air introduced through the air inlet pipe, and the flow is collided or mixed with the bubble. This air increases the dissolved oxygen of the waste water and can increase the treatment efficiency due to the buoyancy energy of the air.

The wastewater introduced through the circular hole 13a is introduced into the first bladder assembly 9. The first blade assembly 9 consists of a lower assembly 12 having a smaller diameter and an upper assembly 11 having a larger diameter.

The lower assembly 12 has a cylindrical shape having a predetermined diameter D, and is integrally connected to the edge of the circular hole 13a by a welding or the like and protrudes upward. The lower blade 14 is mounted on the upper end thereof.

Therefore, the wastewater introduced through the circular hole 13a moves upward through the cylinder 21 and the lower blade 14 and flows into the upper assembly 11.

The upper assembly 11 consists of a cylinder 22 having a diameter D1 larger than the lower assembly 12 and an upper blade 16 mounted on the upper end of the cylinder 22. The lower assembly 12 is disposed at an inner lower portion of the upper assembly 11. That is, a plurality of connecting rods 15 protrude radially from the upper outer circumferential surface of the lower assembly 12 and are connected to the inner circumferential surface of the upper assembly 11 by welding or the like. Accordingly, the upper and lower assemblies 11 and 12 are integrally connected and the inside thereof communicates with each other to allow waste water to flow.

In addition, the waste water can be stirred more efficiently by the difference in the internal volumes of the upper and lower assemblies 11 and 12.

In addition, the agitation effect is increased due to turbulence and shear force as the moving distance of the introduced waste water is increased up, down, left and right.

Meanwhile, as shown in FIG. 9, the upper and lower blades 16 and 14 have a shape in which a plurality of blades 23 overlap each other and are assembled in the circumferential direction, and the overlapped area ratio is 1/3 or more. . Then, one side portion 24 of the plurality of blades 23 are connected to each other in the middle portion, the other side portion 25 is attached to the inner circumferential surface 21a of the cylinder 21 by welding or the like. In addition, the plurality of blades 23 are inclined at a predetermined angle, preferably 10 degrees to 70 degrees, so that a space t is formed between the plurality of blades 23 so that waste water can flow into the space t.

As a result, the wastewater rising from the bottom rises through the space t of these upper and lower blades 16, 14 and is guided at a predetermined angle by the inclined blade 23 to rotate in a helical direction about the center. do. In addition, the rotary waste water is collided with the bubbles to increase the specific surface area of the bubbles to improve the decomposition effect of the pollutants.

And, the sludge precipitated in this process may be accumulated on the upper surface of each partition (13, 20) is periodically discharged to the outside by a method such as back washing.

The wastewater passing through the first blade assembly 9 flows into the second blade assembly 19 to separate contaminants contained in the wastewater while going through the same process as the first blade assembly 9.

On the other hand, the second reactor 2 is connected by the first reactor 1 and the pipe 26 and its internal structure has the same structure as the first reactor (1). Therefore, the wastewater treated first in the first reactor 1 is introduced into the second reactor 2 through the pipe 26 and treated through the same process as the first reactor 1. The wastewater discharged from the second reactor 2 flows into the sludge separation tank 3.

The sludge separation tank 3 is a tubular shape in which a predetermined space is formed and waste water flows in. This sludge separation tank 3 is connected to the second reactor 2 through the inlet pipe 27, the waste water flows in, and the supernatant from which the sludge is removed is discharged to the outside through the discharge pipe 34.

And, the sludge separation tank 3 is formed to have a "shaped" cross-sectional area gradually reduced from the top to the bottom to activate the bottom movement of the sludge to discharge more than 50% of the waste water. In addition, the bottom line 29 of the sludge separation tank 3 is formed to be inclined at a predetermined angle, preferably 10 degrees, in the direction of the outlet 30. Due to the inclination of the bottom line 29, the lower flow rate is formed faster than the upper flow rate, so that the sludge is more effectively precipitated and drawn out.

Therefore, the sludge conveyed downward by the "shaped" shape flows in the direction coinciding with the direction of gravity by the inclination of the bottom line 29, that is, the outlet 30.

In addition, an inclined plate 31 having a predetermined width is attached to the upper bottom of the sludge separation tank 3 to protrude downward. The inclined plate preferably maintains an angle of 45 degrees or less with the top bottom. Therefore, the wastewater introduced through the inflow pipe 27 is in contact with the inclined plate 31 so that the flow is directed downward, the sludge can be moved to the bottom bottom to the maximum.

In addition, the wear 32 is mounted at a predetermined distance from the inclined plate 31, and the wear 32 is attached to the inner upper surface of the sludge separation tank 3. The weir 32 has a recess 33 formed at an upper portion thereof, and the supernatant water is discharged through the discharge pipe 34 through the recess 32 through the recess 33 of the weir 32.

The waste water containing sludge precipitated in the sludge separation tank 3 is conveyed back to the raw water inlet pipe 7 through the outlet 30 and the conveying pipe 28. Then, the raw water inlet pipe 7 is introduced again into the concentration tank 6 to go through the treatment process again.

On the other hand, the reactor of the integrated wastewater treatment apparatus according to another embodiment of the present invention is shown in Figs. As shown, the integrated wastewater treatment apparatus according to another embodiment relates to a bioreactor for inducing anaerobic digestion, and the structure of the reactor is different from that of the embodiment.

That is, the reactor 100 is connected to the gas inlet pipe 101 that can inject anaerobic gas, such as methane gas, nitrogen gas in place of the air inlet pipe. And the gas collection port 107 for collecting the gas which generate | occur | produced in each division is provided separately.

In addition, the blade assembly 102 is a funnel-shaped partition 103, connected to the rim of the circular hole formed in the middle portion of the partition 103, the cylinder 104 protrudes downward, and mounted in the circular hole Blade 105.

Therefore, the wastewater introduced into the reaction tank 100 rises through the cylinder 104 to pass through the space portion (t; FIG. 7) of the blade 105, and in this process, the wastewater rotates in a spiral direction. You exercise. Then, the wastewater that has passed through the blade 105 rises and collides with the partition bottom surface 106 of the upper portion to form a overflow.

At this time, by injecting anaerobic gas such as methane gas and nitrogen gas through the gas inlet pipe 101, it is possible to improve the stirring effect inside the reactor. In addition, the gas generated in each compartment is collected through the gas collecting port 107. In this process, due to the pressure difference due to the discharge of the gas is discharged to the lower waste water can be expected to the reverse stirring effect.

In the above process, the anaerobic gas may optionally be injected into the reactor. That is, the agitation effect may be induced by simply supplying only waste water without injecting anaerobic gas into the reactor, or may be injected together with waste water as described above.

In addition, since the reactor is an upflow reactor, anaerobic microorganisms are mostly at the bottom, thereby minimizing the loss of microorganisms.

As a result, the wastewater is purified through a process similar to the reactor of one embodiment.

Meanwhile, another embodiment of the present invention is shown in Figs. As shown, another embodiment of the present invention differs in the structure of the thickener as compared to the above embodiments. That is, by adding the guide blade 205 to the concentration tank 201, it is possible to more effectively discharge the solids contained in the waste water.

In more detail, the concentrating tank 201 includes a case 203, a guide blade 205 provided inside the case 203, and an air inlet pipe for supplying air into the case 203. 207, a raw water inlet pipe 209 through which wastewater is introduced, and a discharge pipe 211 through which solids are discharged.

The case 203 is preferably cylindrical in shape, and since wastewater and air are introduced and stored therein, a space is formed therein. The guide blade 205 has a wedge shape and is supported by the inner wall surface 224 of the case 203 by a plurality of support bases 226. In this case, a distance of a predetermined distance D is maintained between the inclined surface 213 of the guide blade 205 and the inner wall surface of the case 203. Therefore, the introduced air moves upward along the inclined surface 213 of the guide blade 205.

In addition, the discharge pipe 211 is formed to protrude in the opposite direction to each other, as shown in Figure 12 and protrudes in a tangential direction with respect to the concentration tank 201. Therefore, the discharge efficiency of the wastewater discharged from the concentration tank 201 can be improved.

In the thickening tank having such a structure, waste water is supplied through the raw water inlet pipe 209 and fills the entire interior of the thickening tank 201 and the reactor 200 by gradually filling the inside of the thickening tank 201 from the bottom. At this time, the waste water maintains a static state in which external energy does not work.

When air is injected through the air inlet pipe 207 in this state, the injected air is supplied to the waste water stored in the concentration tank 201 to generate bubbles. These bubbles are moved upward along the first arrow direction 215 in contact with the inclined surface 213 of the guide blade 205, and in this process, the bubbles are kinetic energy so as to move upward in the static waste water. To make it dynamic. Therefore, it moves upward depending on the weight of the substance contained in the waste water.

At this time, as the bubbles and the dissolved substance rise along the inclined surface 213 of the guide blade 205, the fluid pressure is temporarily lowered around the inclined surface 213. In addition, the relatively heavy wastewater moves to the lower space where the fluid pressure is lowered in the direction opposite to the movement of air, that is, along the second arrow direction 217. At this time, the type of solids having high density or high specific gravity among the waste water preferentially moves to the lower portion. The movement of the wastewater can be improved by appropriately adjusting the distance D between the inclined surface 213 of the guide blade 205 and the inner wall surface of the case 203.

Therefore, foreign matters, such as solids, contained in the waste water can be removed by moving to the lower side opposite to the direction of the air and settle down efficiently.

This process is the same for the first and second blade assemblies 220 and 222. That is, the space between each blade is spaced at regular intervals so that the relative speed of the fluid moving along each surface to the maximum can further increase the precipitation effect of the solids contained in the waste water.

On the other hand, the high concentration wastewater moved downward as described above has a high viscosity and tends to adhere to the inner wall surface 224 of the concentration tank 201. As a result, relatively low concentration is maintained in the center of the concentration tank 201, and high concentration is maintained on the wall surface side 224. Therefore, when the high concentration wastewater is discharged, the low concentration wastewater in the center is preferentially discharged through the discharge port 211. This is contrary to the intention of discharging the high concentration wastewater preferentially, so as to prevent this, two concentration ports 211 are alternately opened to increase the solids concentration of the wastewater discharged.

In addition, as the wastewater treatment device is operated, sludge is attached to the inner wall surface 224 of the concentration tank 201 to reduce the treatment efficiency. Therefore, in order to prevent this, a large amount of concentrated water is injected in a direction opposite to the discharge direction and discharged toward the raw water inlet 209 to separate the sludge attached to the inner wall surface 224 of the concentration tank 201. In particular, the outlet 211 has a tangential structure, as shown in Figure 12 can be accelerated to this departure phenomenon.

Hereinafter, with reference to the accompanying drawings will be described in more detail the operation of the integrated wastewater treatment apparatus according to an embodiment of the present invention.

1 to 9, wastewater is introduced into the concentration tank 6 through the raw water inflow pipe 7, and at this time, the wastewater returned from the sludge settling tank 3 is also joined. In addition, the wastewater introduced into the thickening tank 6 is tangentially rotated so as to rotate in a spiral direction with respect to the center of the thickening tank 6, and is also combined with the rotational force generated by the first blade assembly 9 to maintain a constant rotation. You exercise. In this process, the sludge contained in the waste water has a high specific gravity and the returned sludge is easily precipitated and concentrated by biological adsorption. By continuously discharging a certain amount of sludge from the bottom of the partition, high concentrations of solids can be separated before biological treatment.

The wastewater raised in the thickening tank 6 is introduced into the lower assembly 12 of the first blade assembly 9 through the circular hole 13a of the first partition 13 to pass through the lower blade 14. At this time, the waste water is stirred by rotating in the helical direction while passing through the lower blade (14). In addition, air is introduced through the air inlet pipe 8 and mixed with the waste water to form bubbles, and primary collision is made between these bubbles.

Waste water and bubbles which have risen through the lower assembly 12 are introduced into the upper assembly 11 having a larger volume and more vigorously stirred and secondary collisions between the bubbles occur. In addition, dissolution of the gas is activated by extending the residence time of the bubbles.

Through this process, waste water and bubbles passing through the upper assembly 11 enter the upper space 36 and collide with the bottom surface 20a of the second partition 20. Therefore, the waste water is circulated downward in the upper space 36 to form the overflow.

As the collision between the overflow of the waste water and bubbles in the upper space 36 is activated, the decomposition efficiency of the contaminants is further improved.

In this process, some waste water is introduced into the second blade assembly 19 again. Then, while the same process as the first blade assembly 9, the decomposition of the microorganism proceeds.

Waste water treated in the first reactor 1 through the above process is introduced into the second reactor 2 through the pipe 26. Then, the wastewater is decomposed while going through the same process as in the first reactor (1).

The waste water discharged from the second reactor 2 flows into the sludge separation tank 3. The wastewater introduced into the sludge separation tank 3 is in contact with the inclined plate 31 and the flow is directed downward, and in this process, the sludge is deposited on the bottom 29. The sludge deposited on the bottom 29 is introduced into the outlet along the inclined surface of the bottom 29. In addition, since the sludge separation tank 3 has a “Ｖ” shape, the lower sludge flow rate is formed faster than the upper portion, so that the sludge precipitated flows into the outlet 30 more efficiently. The supernatant from which the sludge is separated is discharged through the discharge pipe 34 by moving through the concave groove 33 of the wear 32.

Through this process, the sludge separation tank 3 inside the sewage sludge contained in the waste water is made, the sludge is precipitated in the sludge separation tank in addition to the reactor as described above to increase the settling speed, to prevent the release of phosphorus Can be.

Then, the wastewater introduced through the outlet 30 is conveyed back to the raw water inlet pipe 7 through the conveying pipe 28 to repeat the above process.

Experimental results for the treatment efficiency of wastewater obtained through the treatment process are as follows.

Reactor Volume (Treatment Temperature) Wastewater Inflow / Outflow Concentration (mg / L) Processing time (h) Etc Aerobic treatment (one embodiment) 20L (20 degrees) Sewage BOD 150/10 3.5 17% oxygen transfer rate when giving up Anaerobic Treatment (Other Embodiments) 20L (35 degrees) Sewage Sludge VS 7,500 / 3,200 120 (5 days) Gas generation rate of each stage% (CH4 / CO2) -1 stage: 65 / 35-2 stage: 75 / 25-3 stage: 83/17

Integrated wastewater treatment apparatus according to a preferred embodiment of the present invention has the following advantages.

First, the stirring effect is increased by turbulent flow and shear force of the fluid by increasing the moving distance of the fluid in the general bioreactor up, down, left and right.

Second, by controlling the accumulation of sludge in the reactor to maintain a high concentration of microorganisms it is possible to ensure a sufficient time for the waste water is removed by the microorganisms.

Third, the introduced air can reduce the cost by increasing the dissolved oxygen and maximizing the stirring effect to fully utilize the buoyancy energy of the air.

Fourth, in the case of anaerobic digestion, the gas can be collected in each compartment, so that the separate collection of the gas composition is possible.

Fifth, since the anaerobic microorganisms are mostly at the bottom because of the upflow reactor, the loss of microorganisms can be minimized.

Sixth, the reactor itself has a concentration tank, so there is no need for a separate concentration facility.

Seventh, by taking out the sludge from the lower sludge separation tank can increase the sludge settling rate can shorten the settling time.

Eighth, by mounting the guide blade in the lower portion of the thickening tank, it is possible to effectively precipitate a high density, high specific gravity sludge due to the difference in the relative velocity of the fluid by the air buoyancy.

Since the present invention can be variously modified by those skilled in the art without departing from the scope of the claims claimed in the claims, the technical protection scope of the present invention is limited to the specific preferred embodiments described above. It is not limited.

Claims (12)

An aeration tank in which waste water is stored, the inside of which is divided up and down by at least one partition; A concentrating tank mounted integrally with the lower portion of the aeration tank and equipped with a raw water inflow pipe and an air inflow pipe, for settling sludge of wastewater introduced through the raw water inflow pipe; Stir to dissolve contaminants by aerobic microorganisms by increasing the amount of dissolved oxygen by agitating the waste water introduced from the concentration tank and colliding the bubbles formed by the air introduced through the air inlet pipe, and extending the residence time A reactor consisting of means; And An integrated wastewater treatment apparatus comprising a sludge separation tank connected to the reactor integrally to precipitate sludge contained in the wastewater discharged from the reactor and return the wastewater to the concentration tank. An aeration tank in which waste water is stored, the inside of which is divided up and down by at least one partition, and a gas inlet and a gas collecting port protrude from each compartment; A reactor comprising stirring means for agitating the wastewater introduced into the partition and colliding bubbles formed by the gas introduced through the gas inlet to extend the residence time to decompose contaminants by anaerobic microorganisms; And An integrated wastewater treatment apparatus comprising a sludge separation tank connected to the reactor integrally to precipitate sludge contained in the wastewater discharged from the reactor and return the wastewater to the concentration tank. The integrated wastewater treatment apparatus according to claim 1 or 2, further comprising at least one reactor having the same structure as the reactor between the reactor and the sludge separation tank. The lower assembly of claim 1, wherein the stirring means is mounted around the hole formed in the partition, and the waste water flowing through the hole is introduced into the lower assembly, and is mounted on the upper portion of the lower assembly to pass through the lower assembly. An integrated wastewater treatment apparatus comprising at least one blade assembly comprising an upper assembly for secondary agitation of one wastewater. The integrated wastewater treatment apparatus of claim 4, wherein the lower assembly includes a cylindrical portion mounted to an edge of a circular hole formed in the partition, and a lower blade mounted to an upper end of the cylindrical portion to stir waste water. 5. The upper assembly of claim 4, wherein the upper assembly has a larger diameter than the cylindrical portion of the lower assembly, and a cylinder in which the upper end of the lower assembly is disposed, and an upper blade mounted on the upper end of the cylinder to stir waste water. Integrated wastewater treatment device further comprising a. According to claim 2, wherein the stirring means is a funnel-shaped partition, connected to the edge of the circular hole formed in the middle portion of the partition connected to the protruding downward and at least one blade consisting of the blade mounted in the circular hole Integrated wastewater treatment apparatus comprising an assembly. According to any one of claims 5 to 7, wherein the blade is formed with a plurality of blades having a fan-shaped inclined at an angle, and the waste water is passed through the space by forming a space between the adjacent blades Integrated wastewater treatment device having a rotational force. According to claim 1 or 2, wherein the sludge separation tank is a body having a shape whose cross-sectional area is reduced from the upper direction to the lower direction, the inclined plate formed on the upper inner bottom of the body to guide the flow of waste water to the bottom, A ware is formed at a predetermined distance away from the inclined plate, and has a recess formed on the upper surface thereof to allow the supernatant water from which sludge is separated through the recess to be discharged to the outside, and formed at the rear corner of the bottom to convey waste water to the raw water inflow pipe. Integrated wastewater treatment device including an outlet. 10. The integrated wastewater treatment apparatus of claim 9, wherein the bottom of the sludge separation tank is inclined toward the outlet so that the sludge deposited therein is movable to the outlet. According to claim 1, wherein the concentration tank is a case, a guide blade provided in the inside of the case, an air inlet pipe for supplying air into the inside of the case, a raw water inlet pipe through which waste water is introduced, solids are discharged Integrated wastewater treatment device including a discharge pipe. The guide blade of claim 11, wherein the guide blade has a wedge shape, and the inclined surface of the guide blade maintains a predetermined distance from the inner wall surface of the case, so that air introduced through the air inlet pipe is along the inclined surface of the guide blade. Integrated wastewater treatment device movable upwards.