KR20180118032A - Purification device for livestock waste water - Google Patents

Abstract

The present invention relates to a livestock wastewater purification apparatus which comprises: a storage tank for storing livestock wastewater; a first stirring tank for receiving livestock wastewater from the storage tank, injecting compressed heating air, stirring the same, and primarily fermenting the same; a second stirring tank installed at one side of the first stirring tank to be adjacent thereto, receiving the primarily fermented livestock wastewater, injecting and stirring compressed heating air and a coagulant to perform re-fermentation, and primarily coagulating solids; a first coagulation tank installed adjacent to one side of the second stirring tank, receiving the re-fermented and primarily coagulated livestock wastewater, injecting and stirring a coagulant and compressed heating air, and re-aggregating the solids; a second coagulation tank installed at one side of the first coagulation tank, and additionally coagulating the solids in the livestock wastewater including the re-coagulated solids; a dehydration device installed at one side of the second coagulation tank, receiving wastewater and coagulated materials from the second coagulation tank, and separating the coagulated materials and moisture; a wastewater storage tank installed at the lower side of the dehydration device, and storing dehydrated moisture; a dilution tank installed at one side of the wastewater storage tank, receiving moisture transferred from the wastewater storage tank, and injecting and stirring a diluent and compressed heating air to perform dilution; and a discharge tank installed at one side of the dilution tank, receiving the diluted moisture from the dilution tank, injecting and stirring compressed heating air, and discharging purified water.

Description

[0001] Purification device for livestock waste water [0002]

The present invention relates to an apparatus for treating livestock wastewater, comprising livestock wastewater transferred to a plurality of tanks in stages to coagulate the solid matter by fermentation, separating and purifying solids and water through a dewatering device, It is a purification treatment device.

Generally, livestock wastewater contains a large amount of water and solids, and it takes a great deal of time to treat the wastewater. Also, since organic matter in livestock wastewater is decomposed, a bad odor is generated and pathogenic bacteria harmful to the human body are naturally produced. Serious water pollution and air pollution.

The general technique for preventing such contamination is to feed chemicals such as coagulant and activated charcoal to livestock wastewater and filtrate and purify them. However, the filtration and purification devices are easily clogged by many solids contained in livestock wastewater, There is a problem that the cost of the drug required for the drug is excessive.

In order to solve this problem, Korean Patent Laid-Open Publication No. 10-2013-0083147 filed by the applicant of the present invention is known in the prior art of an apparatus for treating livestock wastewater. This is because, as shown in Fig. 1, (A) containing solid and liquid stored in a coagulating float tank and containing a coagulant in a coagulating float tank (A) for separating solid matter and wastewater into a primary liquid by feeding a coagulant into a stock tank (W) (C) for transferring the wastewater filtered from the filtration treatment tank (B) and the filtration treatment tank (B) by transferring the wastewater and filtering the wastewater, (D) a final water treatment tank (D) in which the coagulant is added to the wastewater and the solid matter is re-separated to produce purified water, and a flocculant is mixed with the effluent water tank (E) Is a technique obtained by over flocculation include injury tank (A) and Jong - su coagulant to be supplied to the treatment tank (D) mixing (F) and a dehydrator (G) for transferring received dewatering the solids generated in the aggregation portion tank (A).

However, the above-mentioned prior art has a problem that it takes a long time to agitate the wastewater by using a rotating propeller that agitates the livestock wastewater only in the flocculating float tank. Also, since only the diluting water and the flocculant are used as the purifying agent, Water is not sufficiently separated from the livestock wastewater. Further, there is a problem in that the dehydrated water from the housing wastewater containing the aggregate is dehydrated through the dehydrator (G) to the effluent water tank (E) There is a problem that the water pollution is not reduced as it is discharged without being subjected to the final purification process.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to simplify the apparatus for livestock wastewater purification, improve the cohesion force of sludge distributed in livestock wastewater, completely dehydrate water from coagulated sludge, And an object of the present invention is to provide a livestock wastewater purification treatment apparatus that prevents environmental pollution.

In order to accomplish the above object, the present invention provides an apparatus for purifying livestock wastewater, comprising: a storage tank (100) for storing a stock solution of livestock wastewater; A first agitation tank 200 that receives the raw stock of livestock wastewater from the storage tank 100 and puts the compressed heating air into the tank and stirs them to perform primary fermentation; A second agitation tank 300 provided adjacent to one side of the first agitation tank 200 to receive the primary fermented livestock wastewater and pressurize the heated air and the coagulant to agitate and re-ferment the solids; A first agglomeration tank 400 disposed adjacent to one side of the second agitation tank 300 to receive re-fermentation and primary agglomerated livestock wastewater, and agitating the agglomerated and pressurized heated air to re-agglomerate the solids; A second agglomeration tank (500) installed at one side of the first agglomeration tank for further agglomerating solids from the livestock wastewater containing the agglomerated solids; A dewatering device 600 installed at one side of the second flocculation tank and transferring wastewater and flocculant from the second flocculation tank to separate the flocculant and water; A dehydrating solution storage tank 700 installed at a lower portion of the dehydrating apparatus and storing moisture to be dehydrated; A dilution tank 800 installed at one side of the wastewater storage tank for transferring water from the wastewater storage tank to dilute the dilution water and the compressed heating air, And an outlet tank (900) installed at one side of the dilution tank and supplied with diluted water from the dilution tank, for introducing the compressed heating air and stirring and discharging the purified water, is provided .

The first agitation tank 200, the second agitation tank 300 and the first agglomeration tank 400 are formed so that the heights of the tanks are sequentially lowered. The raw stock of the livestock wastewater to be supplied to the first agitation tank 200 Is forced from the storage tank 100 through the first stirring tank inflow pipe 220 provided with a pump and discharged from the bottom of the first stirring tank 200 to be supplied to the first stirring tank 200. In the first stirring tank 200, The livestock wastewater to be supplied to the second agitation tank 300 is supplied through the water tray 230 provided in the upper portion of the first agitation tank 200. The livestock wastewater is supplied to one side of the second agitation tank 300, The livestock wastewater to be supplied to the first agglomeration tank 400 from the second agitation tank 300 is supplied to the second agitation tank 300 through the second agitation tank inflow pipe 310, Is supplied through the water film port (330) provided on the upper part of the stirring tank (300), and is supplied to one side of the first flocculation tank Form to be supplied into an upper portion and from the bottom portion of the first flocculation tank 400 via the first agglomeration tank inlet pipe 410 is connected to form a floor.

The livestock wastewater containing the agglomerated agglomerates in the first agglomeration tank 400 is supplied from the upper part of the first agglomeration tank 400 through the fixed line provided with the pump to the second agglomeration tank 500 connected to the lower part of the second agglomeration tank 500 The second flocculation tank 500 is forced to be fed to the tank inlet 510 to be supplied to the second flocculation tank 500. The second flocculation tank 500 flocculates and discharges the wastewater mixed with the flocculent flocculated on the water surface, The waste water is discharged to the hopper 601 provided at the upper side of the dewatering apparatus 600. The hopper 601 is provided at the upper side of the dewatering apparatus 600,

The agglomerate and the wastewater flowing into the hopper 601 of the dewatering device 600 are separated from the wastewater and the sludge cake while being discharged through the dewatering device 600. The separated wastewater is stored in the dewatering liquid storage tank 700 And the wastewater stored in the dehydrating solution storage tank 700 is supplied to the dilution tank 800 through the dehydrating solution transfer pipe 609 provided with the pump and the wastewater diluted in the dilution tank is supplied to the discharge tank 900, So that the purified water is discharged.

The compressed heating air supplied to the first stirring tank 200, the second stirring tank 300, the first flocculation tank 400, the dilution tank 800 and the discharge tank 900 is supplied to the air compressor The heated compressed air is heated to a predetermined temperature through a heating tank provided with a plurality of infrared heating lamps and supplied through an air supply pipe 241. The heated compressed air is injected into the lower four sides of each of the tanks through rotary blades 243 And the air injector 240 are spaced apart from each other at regular intervals.

The water tray 230 installed at the upper part of the first stirring tank 200 and the second stirring tank 300 is provided so that the gaseous livestock wastewater floating over the upper part of each tank is overflowed and supplied to the inflow pipe of the adjacent tank. The tank is inclined at an upper portion of the tank at an angle and the one end is protruded outside the tank for a predetermined length.

The dewatering device 600 includes a transfer part 602 for forcibly transferring wastewater and agglomerates supplied through the hopper 601; A compression dewatering unit (603) for compressing wastewater and agglomerates supplied from the transfer unit to separate moisture and sludge; And a sludge cake outlet 604 for discharging the sludge cake generated by dewatering the agglomerate. The transfer portion 602 is formed in the inside of the cylinder The compression dewatering unit 603 forms a conveying screw 605 that receives the driving force of the compression dewatering unit driving motor 608 and rotates to receive the driving force of the compression dewatering unit driving motor 607. The cylindrical dewatering unit 607 ) And a compression screw (606) inside the cylindrical perforated network.

The livestock wastewater treatment apparatus according to the present invention agitates livestock wastewater through a plurality of stages and feeds heated compressed air to ferment the livestock wastewater. As the livestock wastewater is agglomerated and dehydrated, the livestock wastewater has a total content of 8 mg / L or less, a total nitrogen content of 60 mg / / L or less and BOD 30 mg / L or less, thereby discharging water in accordance with the livestock wastewater discharge standard, and removing the moisture from the solid matter contained in the livestock wastewater.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram showing a conventional technology of an agricultural wastewater purification treatment apparatus.
2 is a view schematically showing an apparatus for treating livestock wastewater according to the present invention.
3 is a view showing a first agitating tank of the present invention.
4 is a view showing a second stirring tank of the present invention.
5 is a view showing a first flocculation tank of the present invention.
6 is a view schematically showing a second flocculation tank and a dewatering device of the present invention.
7 is a view showing a dilution tank and a discharge tank according to the present invention.
8 is a view showing a water tray provided on the upper part of the first and second stirring tanks of the present invention.
9 is a view showing the dehydrating apparatus of the present invention.

It should be noted that the embodiments described in the specification of the present invention and the configurations shown in the drawings describe the most preferred embodiments of the present invention and thus all of the equivalents of the inventions described in the claims of the present invention are included in the scope of right .

As shown in FIG. 2, the apparatus for treating livestock wastewater according to the present invention comprises: a storage tank 100 for storing raw stock of livestock wastewater; A first agitation tank 200 that receives the raw stock of livestock wastewater from the storage tank 100 and puts the compressed heating air into the tank and stirs them to perform primary fermentation; A second agitation tank 300 provided adjacent to one side of the first agitation tank 200 to receive the primary fermented livestock wastewater and pressurize the heated air and the coagulant to agitate and re-ferment the solids; A first agglomeration tank 400 disposed adjacent to one side of the second agitation tank 300 to receive re-fermentation and primary agglomerated livestock wastewater, and agitating the agglomerated and pressurized heated air to re-agglomerate the solids; A second agglomeration tank (500) installed at one side of the first agglomeration tank for further agglomerating solids from the livestock wastewater containing the agglomerated solids; A dewatering device 600 installed at one side of the second flocculation tank and transferring wastewater and flocculant from the second flocculation tank to separate the flocculant and water; A dehydrating solution storage tank 700 installed at a lower portion of the dehydrating apparatus and storing moisture to be dehydrated; A dilution tank 800 installed at one side of the wastewater storage tank for transferring water from the wastewater storage tank to dilute the dilution water and the compressed heating air, And a discharge tank (900) which is installed at one side of the dilution tank and receives the diluted water from the dilution tank, receives the compressed heating air, stirs the purified air, and discharges the purified water after purification treatment.

As shown in FIGS. 2 and 3, the first stirring tank 200, the second stirring tank 300, and the first flocculating tank 400 are formed so that the height of the tank is sequentially lowered, and the first stirring tank 200 is forced from the storage tank 100 through a first stirring tank inflow pipe 220 provided with a pump and discharged from the bottom of the first stirring tank 200 to be supplied.

The livestock wastewater to be supplied from the first stirring tank 200 to the second stirring tank 300 is supplied to a water tank (not shown) provided in the upper portion of the first tank 200, as shown in FIGS. 230 to the upper portion of the second agitating tank through the second agitating tank inflow pipe 310 formed by connecting the upper portion and the bottom portion to one side of the second agitating tank.

2, 4 and 5, the livestock wastewater supplied from the second agitation tank 300 to the first agglomeration tank 400 is supplied to a water tank (not shown) The first flocculation tank 400 is supplied from the bottom of the first flocculation tank 400 through the first flocculation tank inflow pipe 410 which is formed by connecting the upper part and the bottom part to one side of the first flocculation tank 330 .

The livestock wastewater supplied to the second agitation tank 300 and the first agglomeration tank 400 is supplied through the water tray 230 of the first agitation tank and the water tray 330 of the second agitation tank as described above The second agitation tank 300 and the first agglomeration tank 400 are connected to each other through a transfer pipe provided with pumps of the first agitation tank 200 and the second agitation tank 300, Or may be forcedly supplied to the bottom of the apparatus.

As shown in FIGS. 2 and 6, the livestock wastewater containing agglomerated agglomerates in the first agglomeration tank 400 is introduced into the first agglomeration tank 400 through the first agglomeration tank discharge pipe 420 equipped with the pump, To the second flocculation tank inlet (510) connected to the lower part of the second flocculation tank (500) and fed to the second flocculation tank (500).

As shown in FIG. 6, the second flocculation tank 500 has an outlet 530 formed at one side thereof so that wastewater, which is aggregated from wastewater and floated on the water surface, is flowed out, And a flocculant inlet port 520 for discharging the flocculant to the lower part of the hopper 601 is formed on the lower part of the dewatering unit 600.

As shown in FIG. 6, the agglomerate and the wastewater flowing into the hopper 601 of the dewatering device 600 are separated from the wastewater and the sludge cake while being squeezed through the dewatering device 600, And stored in the liquid storage tank 700.

As shown in FIG. 7, the wastewater stored in the dehydrating solution storage tank 700 is supplied to the dilution tank 800 through a delivery pipe 609 provided with a pump, is diluted by adding a diluent, Is supplied to the discharge tank (900) and discharged after purification treatment.

Compressed heating air to be supplied to the first stirring tank 200, the second stirring tank 300, the first flocculation tank 400, the dilution tank 800, and the discharge tank 900 is shown in FIGS. 2, 3, 4, As shown in FIGS. 5 and 7, a plurality of air injectors 240 connected to an air supply pipe 241 at the bottom of each tank are installed at equal intervals so that the heated compressed air can be discharged. Is heated to a predetermined temperature through a heating tank provided with a plurality of infrared heating lamps, and is preferably supplied.

The livestock wastewater is filled into the first and second stirring tanks 200 and 300 and the first flocculation tank 400, the dilution tank 800 and the discharge tank 900 from the lower portion of each tank, The livestock wastewater supplied to each tank is dewatered from the bottom by stirring and pressurized heating air and the fermentation progresses naturally and rapidly and the fermented wastewater and suspended matter are transferred to the tank and the dewatering device The effect is obtained that the purification treatment is performed and the water is separated, whereby the purification treatment operation is efficiently and completely performed.

The construction of each tank and dewatering device described above will be described in more detail. 3, the first stirring tank 200 is formed as an octagonal cylinder and is formed by narrowing a lower portion thereof. The livestock wastewater is supplied to one side of the octagonal cylinder through a pump to the lower portion of the tank, An agitator 210 for stirring the livestock wastewater is provided by a motor 211 installed at the center of the upper part of the octagonal tubular body, And an air injector 240 for injecting compressed air to the livestock wastewater and injecting the compressed heated air through the air supply pipe 241 is installed.

The stirrer 210 is formed in the shape of a rectangular frame having a rectangular shape and engages with the rotary shaft 212 of the drive motor 211 rotatably supported by the lower end of the first stirring tank, So that the livestock wastewater can be smoothly stirred through the rotary blades.

As shown in FIG. 3, the air injector 240 has a long rectangular parallelepiped shape, and an air supply pipe 241 is connected to one side of the air injector 240, a jetting portion 242 and a rotary blade 243 are formed therein, When the heating pressure air is introduced through the pipe, air is injected through the injection part, and the heating pressure air, which is rotated and rotated, is injected while rotating like a whirlwind.

Compressed heating air injected from the first stirring tank 200 is supplied to a heating tank provided with a plurality of infrared lamps by air compressed to 6 kg / cm 2 by an air compressor and heated to a temperature of 50 to 100 ° C.

As shown in FIGS. 2, 3, and 8, the water tray 230 installed on the upper portion of the first stirring tank 200 is mixed with the gaseous livestock wastewater which is stirred and heated to float above the first stirring tank The first stirring tank is installed at an upper portion of the first stirring tank so as to be supplied to the second stirring tank 300 provided adjacent to the first stirring tank. The other end of the first stirring tank is protruded outside the first stirring tank by a predetermined length Is formed close to the upper portion of the second stirring tank inflow pipe (310).

As shown in FIGS. 2 and 4, the second stirring tank 300 is formed in the same manner as the first stirring tank 200 by forming an octagonal tubular body and by narrowing the lower portion thereof. A motor (not shown) 211 for feeding livestock wastewater to the livestock wastewater by means of an agitator 210 for agitating the livestock wastewater and feeding the compressed heated air through the air supply pipe 241 to the four sides of the bottom of the second agitating tank, The second stirring tank inflow pipe 310 into which the gaseous livestock wastewater flows from the first stirring tank 200 is formed at one side of the second stirring tank, As shown in the figure, the water tray 330 is installed on the upper part of the second stirring tank 300 at a predetermined angle, and one end of the water tray 330 is protruded to the outside of the second stirring tank by a predetermined length, Is formed close to the upper portion of the first flocculation tank inflow pipe (410).

As shown in FIGS. 2 and 5, the first agglomeration tank 400 is installed adjacent to one side of the second agitation tank 300, and the first agglomeration tank inflow pipe 410 is connected to one side of the first agglomeration tank 300, And the livestock wastewater which has been subjected to the secondary agitation and fermentation to be fed from the water tray 330 of the second agitating tank may be introduced into the lower portion of the first agglomeration tank through the first agglomeration tank inflow pipe 410 .

5, the first aggregating tank 400 is provided with a stirrer 210 that stirs the livestock wastewater while rotating in the same state as the second stirring tank 300 at the center, And an air injector 240 for injecting compressed air to the livestock wastewater through the air supply pipe 241 and injecting the coagulant into the upper portion of the first flocculation tank (not shown) 6, the first flocculating tank 500 is provided with a first flocculating tank 500 for forcedly conveying the flocculated flocculated flocculant and wastewater to the second flocculating tank 500 on the upper side of the first flocculating tank 500, A flocculation tank discharge pipe 420 is installed.

The flocculant in the first flocculation tank 400 is fed from the second flocculation tank 300 so that the flocculant (polymer) can be fed into the first flocculation tank when the livestock wastewater flows into the first flocculation tank. , And the agitator 210 was rotated at a rate of 40 to 60 rpm while supplying compressed compressed air at a pressure of 6 kg / cm 2 and 50 to 100 ° C., and the agitator 210 was operated until the agglomeration rate of the solids contained in the livestock wastewater reached 50% .

As shown in FIG. 6, the second agglomerating tank 500 is formed into a conical shape by inclining the lower end portion thereof, as shown in FIG. 6, and has a total volume smaller than that of the first agglomeration tank. And a small-sized door-type stirrer 540 is rotated.

At the bottom of the second flocculation tank 500, two air injectors 240 are disposed at a predetermined interval and an inlet 510 for receiving the flocculation and wastewater by the first flocculation tank discharge pipe 430 And a flocculant inlet port 520 for introducing the flocculant into the second flocculation tank is connected to one side of the inflow pipe.

An outlet 530 is formed at an upper portion of one side of the second flocculation tank 500 so as to flocculate and discharge the flocculated and flocculated flocculated flocculated material from the wastewater. The end of the discharge port is positioned above the hopper 601, So that it can be discharged to the dewatering apparatus 600.

The second flocculation tank 500 is forcibly introduced together with the flocculant made of polymer at the flocculant inlet 520 when the livestock wastewater flows from the first flocculation tank through the inlet 510. The polymer flocculant is one ton of livestock wastewater It is preferable to add 20 to 30 g per one unit.

Compressed heating air supplied to the second agglomerating tank 500 is supplied to the first and second agitation tanks 200 and 400 at a pressure of 6 kg / cm 2 at a temperature of 50 to 100 ° C , And the second flocculation tank agitator 210 is rotated at 30 rpm to agitate and flocculate the solids distributed in the wastewater so that the flocculated flocculates float over the water surface.

The agglomerates and the wastewater flowing into the hopper 601 of the dewatering device 600 through the discharge port 530 of the second agglomeration tank 500 are compressed through the dewatering device 600 as shown in FIGS. Thereby separating moisture and sludge, and recovering the separated wastewater and sludge cake.

As shown in FIG. 6, the dewatering unit 600 includes a transfer unit 602 for forcibly transferring wastewater and aggregates supplied through the hopper 601; A compression dewatering unit (603) for compressing wastewater and agglomerates supplied from the transfer unit to separate moisture and sludge; A dewatering liquid storage tank 700 for storing wastewater generated in the compression dewatering unit, and a sludge cake outlet 604 for draining the sludge cake generated by dewatering the aggregate.

The conveying unit 602 forms a conveying screw 605 that rotates in response to the driving force of the compression dewatering unit driving motor 608 and the compression dewatering unit 603 drives the compression dewatering unit driving motor And a compression screw 606 is formed in the interior of the cylindrical perforated network.

6 and 9, the conveying unit 602 and the compressing and dewatering unit 603 are rotated by receiving the driving force of the compression dewatering unit driving motor 608 at the central portion to rotate the cylindrical perforating network 607 And rotates the compression screw rotary shaft 611 in a rotatable manner while rotating the rotary shaft 610 to rotate the discharge impeller 614 fixed to the one end of the cylindrical perforated network 607 by the perforated network fixing nut 615 .

The compression screw rotary shaft 611 is installed on the outside of the perforated rotating shaft 610 so as to be rotatable in the form of a concentric hollow shaft so as to receive the driving force of the compression dehydrating part driving motor 608, The screw 606 is rotated.

A driving screw rotating shaft (611) is installed on the outer side of the compression screw rotary shaft (611) so as to be rotatably extruded in the form of a concentric hollow shaft to receive the power of the compression dewatering unit driving motor (608) 612).

A gear or a pulley for receiving the driving force of the compression dewatering drive motor 608 is installed at one end of the perforation network rotary shaft 610, the compression screw rotary shaft 611 and the feed screw rotary shaft 612, The rotary screw shaft 610 and the screw shaft 611 and the feed screw rotary shaft 612 are provided with bearings on the rotary shaft housing 613 and the rotary shaft 612 of the rotary screw is rotatably mounted, And the other side is formed by installing the center bearing 616 on the sludge cake outlet 604 and by joining the ends of the perforated pellet rotary shaft 610.

The wastewater and agglomerates supplied through the hopper 601 in the second agglomerating tank 500 through the construction of the conveying unit 602 and the compression dewatering unit 603 are supplied to the compression dewatering unit driving motor 608 in a state where the rotation of the compression dewatering unit driving motor 608 is reduced And the wastewater and the sludge are conveyed and compressed while being rotated at different rotational speeds, respectively, and the dewatering operation for separating the water is performed, The wastewater is stored in the dewatering liquid storage tank 700, and the sludge is separated and discharged through the sludge cake outlet 604.

As shown in FIG. 6, the wastewater stored in the dehydrating solution storage tank 700 is forcibly transferred to the dilution tank 800 through the dehydrating solution transfer pipe 609 provided with the pump, 7, an agitator 210 rotatably driven by a motor 211, and an air supply unit 210 for discharging heated compressed air are provided. And a diluent inlet port to supply a diluent to the wastewater flowing into the upper portion of the dilution tank from the dehydration liquid storage tank 700. The wastewater is diluted and purified. It is preferable that the diluent is put into 40 L / ton of water flowing in.

7, the wastewater diluted and purified from the dilution tank 800 is transferred to a discharge tank 900 through a dilution wastewater transport pipe 810 equipped with a pump, and the discharge tank 900 is connected to a dilution tank And the diluted wastewater is supplied to the dilution tank, and the heated compressed air is supplied through the air injector 240 while rotating the stirrer 210 to perform stirring treatment.

Through the above-described structure, the livestock wastewater is purified and treated to a total of 8 mg / L of total nitrogen, 60 mg / L of total nitrogen, 30 mg / L of suspended solids, and 30 mg / L of BOD, So that the purified water can be discharged through the purified water discharge pipe 910.

100: storage tank 200: first stirring tank
210: stirrer 211: motor
212: rotating shaft 220: first stirring tank inlet pipe
230, 330: water film chamber 240: air injector
241: air supply pipe 242:
243: rotating blade 300: second stirring tank
310: second stirring tank inlet pipe 400: first aggregation tank
410: first flocculation tank inflow pipe 420: first flocculation tank inflow pipe
500: second agglomeration tank 510: inlet
520: coagulant inlet port 530: outlet port
540: Small-sized door type stirrer 600: Dewatering device
601: Hopper 602:
603: Compression dehydration unit 604: Sludge cake outlet
605: Feed screw 606: Compression screw
607: Cylindrical perforated mesh network 608: Compression dewatering drive motor
609: Dewatering liquid transfer pipe 610: Perforated pipe rotating shaft
611: Compression screw rotating shaft 612: Feed screw rotating shaft
613: Rotation shaft housing 614: Discharge impeller
615: Perforated nuts fixing nut 616: Center bearing
700: Dewatering liquid storage tank 800: Dilution tank
810: diluting waste water conveying pipe 900: discharge tank
910: purified water discharge pipe

Claims (8)

An apparatus for purifying livestock wastewater, comprising:
A storage tank (100) for storing stock livestock waste water; A first agitation tank 200 that receives the raw stock of livestock wastewater from the storage tank 100 and puts the compressed heating air into the tank and stirs them to perform primary fermentation; A second agitation tank 300 provided adjacent to one side of the first agitation tank 200 to receive the primary fermented livestock wastewater and pressurize the heated air and the coagulant to agitate and re-ferment the solids; A first agglomeration tank 400 disposed adjacent to one side of the second agitation tank 300 to receive re-fermentation and primary agglomerated livestock wastewater, and agitating the agglomerated and pressurized heated air to re-agglomerate the solids; A second agglomeration tank (500) installed at one side of the first agglomeration tank for further agglomerating solids from the livestock wastewater containing the agglomerated solids; A dewatering device 600 installed at one side of the second flocculation tank and transferring wastewater and flocculant from the second flocculation tank to separate the flocculant and water; A wastewater storage tank 700 installed at a lower portion of the dewatering apparatus and storing moisture to be dewatered; A dilution tank 800 installed at one side of the wastewater storage tank for transferring water from the wastewater storage tank to dilute the dilution water and the compressed heating air, And a discharge tank (900) installed at one side of the dilution tank for receiving the diluted water from the dilution tank and feeding the compressed heating air and stirring to discharge the purified water. . The method according to claim 1,
The first agitation tank 200, the second agitation tank 300, and the first agglomeration tank 400 are formed so that the height of the tank is sequentially lowered,
The raw stock wastewater from the first stirring tank 200 is forced to flow from the storage tank 100 through the first stirring tank inflow pipe 220 provided with a pump and discharged from the bottom of the first stirring tank 200 Therefore,
The livestock wastewater to be supplied to the second stirring tank 300 from the first stirring tank 200 is supplied through the water tray 230 provided in the upper portion of the first stirring tank 200, And is supplied from the bottom of the second agitating tank to the upper part through the second agitating tank inflow pipe 310 formed by connecting the upper part and the bottom part to one side,
The livestock wastewater to be supplied to the first agglomeration tank 400 from the second agitation tank 300 is supplied through the water tray 330 installed in the upper portion of the second agitation tank 300, Is formed to be supplied from the bottom of the first flocculation tank (400) to the upper part through a first flocculation tank inflow pipe (410) formed by connecting an upper part and a bottom part to one side. 3. The method of claim 2,
The livestock wastewater containing the agglomerated agglomerates in the first agglomeration tank 400 is supplied from the upper part of the first agglomeration tank 400 through the fixed line provided with the pump to the second agglomeration tank 500 connected to the lower part of the second agglomeration tank 500 To be supplied to the second flocculation tank 500 by forced transfer to the tank inlet 510,
The second flocculation tank 500 has an outlet 530 formed at one side thereof so that wastewater mixed with aggregates floating on the water surface flocculates from the wastewater overflowing and discharged. Is discharged to the hopper (601) provided on the upper side of the livestock wastewater treatment facility (600). The method of claim 3,
The agglomerate and the wastewater flowing into the hopper 601 of the dewatering device 600 are separated and discharged from the wastewater and the sludge cake while being compressed through the dewatering device 600 so that the separated wastewater is stored in the wastewater storage tank 700 and,
The wastewater stored in the wastewater storage tank 700 is supplied to the dilution tank 800 through a dehydrating solution transfer pipe 609 provided with a pump,
And diluted wastewater in the dilution tank is supplied to the discharge tank (900) so that the purified water is discharged. 5. The method according to any one of claims 1 to 4,
The compressed heating air supplied to the first stirring tank 200, the second stirring tank 300, the first flocculation tank 400, the dilution tank 800 and the discharge tank 900 is supplied to the air compressor And is heated to a predetermined temperature through a heating tank provided with a plurality of infrared heat lamps and supplied through the air supply pipe 241,
And an air injector (240) for spraying the heated compressed air through rotary blades (243) to the lower four sides of the respective tanks is spaced apart at regular intervals. 5. The method according to any one of claims 1 to 4,
The water tray 230 installed at the upper part of the first stirring tank 200 and the second stirring tank 300 is provided so that the gaseous livestock wastewater floating over the upper part of each tank is overflowed and supplied to the inflow pipe of the adjacent tank. Wherein the tank is formed by being inclined at an upper portion of the tank at a predetermined angle and having one end protruding outside of each tank by a predetermined length. 5. The method according to any one of claims 1 to 4,
The dewatering device 600 includes a transfer part 602 for forcibly transferring wastewater and agglomerates supplied through the hopper 601; A compression dewatering unit (603) for compressing wastewater and agglomerates supplied from the transfer unit to separate moisture and sludge; And a sludge cake outlet (604) for discharging the sludge cake generated by dewatering the agglomerate, wherein the sludge cake discharging port (604) is formed by discharging the sludge cake. 8. The method of claim 7,
The conveying unit 602 is formed with a conveying screw 605 which receives the driving force of the compression dewatering unit driving motor 608 and rotates,
Wherein the compression dewatering unit (603) forms a cylindrical perforated network (607) that receives and rotates the driving force of the compression dewatering unit drive motor and a compression screw (606) in the interior of the cylindrical perforated network .

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