KR101828029B1 - Device for producing liquid fertilizer using multinozzle - Google Patents

Abstract

[0001] The present invention relates to an apparatus for producing a slurry using a multi-stage nozzle, and more particularly, to a slurry producing apparatus using a multi-stage nozzle, which comprises a receiving tank containing therein organic wastes, a feeding pump for pumping organic wastes contained in the receiving tank, An aeration unit having an aeration nozzle unit for injecting pumped organic waste, an accommodating container provided with an installation space in which an aeration nozzle unit is installed to accommodate the organic waste injected through the aeration nozzle unit, An air supply unit provided in the aeration nozzle unit to supply oxygen to the supplied organic waste, a gas supply unit connected to the storage tank for supplying gas generated from the organic waste contained in the storage tank to the aeration nozzle unit, Collecting the organic waste sprayed by the aeration nozzle unit, Number and a unit for injecting a.
The apparatus for producing a liquid slurry using the multi-stage nozzle according to the present invention has an advantage of saving time and manpower required for liquefying the fluid because gas generated from organic waste as well as oxygen is supplied to the fluid by the gas supply unit.

Description

Technical Field [0001] The present invention relates to a device for producing liquid fertilizer using multinozzle,

The present invention relates to an apparatus for producing a liquid using a multi-stage nozzle, and more particularly to a liquid making apparatus using a multi-stage nozzle for producing a liquid by supplying oxygen and a fermentation gas to a fluid including organic waste such as livestock manure.

Since livestock wastewater contains high concentrations of pollutants in excess of hundreds of times that of general household wastewater, it is difficult to treat the livestock wastewater with certainty and economically as a general wastewater treatment facility. The concentration of solids, organic matter and nitrogen contained in livestock wastewater not only deteriorates the efficiency of the water treatment process but also makes maintenance of the facility difficult.

The livestock wastewater pollutes groundwater, causes lethal health, sanitation and environmental disturbances to humans and animals, propagates odor and pests, inhibits animal growth, increases livestock mortality, It is becoming more and more social because of the increasing cost.

Livestock wastewater generally contains thousands of ppm of high ammonia nitrogen. Such high concentration of ammonia nitrogen has limitations in biological treatment and high ammonia nitrogen concentration has been reported to inhibit the activity of the nitrogen-removing microorganism itself. As a solution to this problem, a method of lowering the concentration by diluting wastewater and a physico-chemical denitrification method are used. There are various physico-chemical denitrification methods, but in the case of air stripping, the key mechanism is the mass transfer triggered by the principle of material concentration equilibrium. Therefore, the higher the concentration of ammonia-containing wastewater, the better the application and the faster the treatment . Despite its advantages, however, there is a problem due to the secondary treatment of deaerated ammonia gas, which makes it difficult to apply in the field.

Korean Patent Laid-Open No. 10-2004-0045707 discloses an apparatus for treating animal wastewater. The livestock wastewater treatment apparatus includes a line type mixer provided with a mixing device between the wastewater storage tank and the dewatering device and having a plurality of diaphragms spaced apart at regular intervals so as to form a zigzag water channel therein, And the flocculant impinges on the diaphragm of the mixer and is transported in zigzag so that the flocculant and the livestock wastewater are mixed.

However, since the livestock wastewater treatment apparatus treats only livestock wastewater into which livestock wastewater is injected by simply supplying oxygen, it takes a long time to ferment the livestock wastewater during the production of the livestock wastewater.

The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a liquid production apparatus using a multi-stage nozzle for producing liquid fertilizer by injecting oxygen and a fermentation gas generated from the organic waste into a fluid having organic wastes such as livestock wastewater, And the like.

In order to accomplish the above object, the present invention provides an apparatus for producing a liquid fertilizer using a multi-stage nozzle, comprising: a storage tank containing therein organic wastes; a supply pump for pumping the organic waste contained in the storage tank; An aeration nozzle unit for spraying the organic waste pumped through the supply pump so as to allow the aeration nozzle unit to be installed in the aeration nozzle unit, An air supply unit provided in the aeration nozzle unit so as to supply oxygen to the organic waste supplied to the aeration nozzle unit, and an air supply unit connected to the aeration tank and generated from the organic waste accommodated in the storage tank, A gas supply unit for supplying gas to the aeration nozzle unit, It is connected to the group receiving cells by collecting the organic waste injected by the aeration nozzle units and comprising a number of injecting into the receiving tank.

The aeration nozzle unit is provided with a receiving space therein so that the high-pressure organic waste pumped by the feed pump can be received therein, and the exhaust gas discharged into the receiving space is discharged to the outside And a plurality of unit nozzles provided on the coaxial line of the discharge nozzle, the plurality of unit nozzles being disposed on the coaxial line of the discharge nozzle.

The unit nozzle is formed with an inflow path by which the outside air or the organic waste in the receiving container can be introduced into the inside by the flow rate of the organic waste passing through the unit nozzle.

Wherein the air supply unit includes at least one air supply pipe having one end connected to the main body and having an inflow hole for allowing external air to flow into the other end, the gas supply unit having one end connected to the accommodation tank, And the other end is provided with at least one gas supply pipe connected to the air supply pipe so that the gas in the gas supply pipe can flow into the main body through the air supply pipe.

Wherein the accommodating container is provided with the installation space such that water or the organic waste injected from the aeration nozzle unit is accommodated therein and an exhaust port through which the organic waste is discharged is formed in the accommodating container, The bottom portion of the outer nozzle portion is located below the outlet so that the portion of the outer nozzle can be partially immersed in the water or the organic waste contained in the receiving container, and the collecting portion receives the organic waste discharged through the outlet, And a return pipe connected to the collecting container and the receiving tank, respectively, at both ends of the collecting container.

The apparatus for producing a liquid slurry using the multi-stage nozzle according to the present invention has an advantage of saving time and manpower required for liquefying the fluid because gas generated from organic waste as well as oxygen is supplied to the fluid by the gas supply unit.

FIG. 1 is a conceptual view of a liquid making device using a multi-stage nozzle according to the present invention,
FIG. 2 is a cross-sectional view of the aeration nozzle unit of the liquid production apparatus using the multi-stage nozzle of FIG. 1,
FIG. 3 is a partially cutaway perspective view of the aeration nozzle unit of the liquid production apparatus using the multi-stage nozzle of FIG. 1;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the present invention are shown.

1 to 3 show an apparatus 100 for producing a liquid fertilizer using a multi-stage nozzle according to the present invention.

Referring to the drawings, an apparatus 100 for producing a liquid slurry using a multi-stage nozzle includes a receiving tank 200 containing organic wastes therein, an aeration unit 300 for pumping and discharging the organic waste contained in the receiving tank 200, An air supply unit 400 installed in the aeration unit 300 to supply oxygen to the organic waste supplied to the aeration unit 300 and an air supply unit 400 connected to the storage tank 200, A gas supply unit 500 connected to the aeration unit 300 to supply the generated organic wastes to the aeration unit 300, (600) for injecting the water into the storage tank (200).

The storage tank 200 is provided with a space for storing organic wastes such as livestock wastewater therein and is provided with a space for preventing corrosion or defects caused by fermentation gas such as nitrogen generated by organic wastes It is preferably formed of a high-strength synthetic resin material.

The aeration unit 300 includes a supply pump for pumping the organic waste contained in the storage tank 200 and an aeration nozzle unit for spraying the organic waste pumped through the supply pump to allow the organic waste to contact oxygen, And an installation space 331 in which the aeration nozzle unit 320 is installed so as to receive the organic waste sprayed through the aeration nozzle unit 320 do.

The supply pump is installed at a fluid supply pipe 311 connected at one end to the accommodation tank 200 and at the other end connected to the aeration nozzle unit 320 to pump the organic waste contained in the accommodation tank 200, 320).

The aeration nozzle unit 320 is provided with an accommodation space 323 therein so that the organic waste pumped by the supply pump can be received therein and the organic waste introduced into the accommodation space 323 is supplied to the outside A main body 321 provided with a discharge nozzle 324 formed on the bottom surface of the main body 321 so as to be discharged and an outer nozzle part 322 provided on the main body 321.

The main body 321 has a circular cross-section, extends in the vertical direction, and the accommodation space 323 is provided therein so that the organic waste flows and flows. One end of a fluid supply pipe 311 provided with a supply pump is connected to the outer circumferential surface of the main body 321.

The main body 321 is supported by the supporting frame (not shown) so as to be spaced upward relative to the receiving container 330. The support frame extends vertically and has an upper end fixed to the outer circumferential surface of the main body 321 and a lower end fixed to the accommodation container 330. A plurality of the support frames are spaced apart from each other along the circumferential direction on the outer circumferential surface of the main body 321 .

The discharge nozzle 324 protrudes downward from a lower surface of the main body 321 and a discharge hole is formed on the lower surface of the discharge nozzle 324 to discharge the organic waste introduced into the main body 321. In addition, the discharge nozzle 324 may be formed so that the inner diameter becomes narrower toward the downward direction so that the flow rate of the organic waste discharged to the outside of the main body 321 may increase.

The outer nozzle part 322 is provided on the main body 321 by a support member 326 and has a plurality of unit nozzles 325 spaced apart from each other on a coaxial line of the discharge nozzle 324.

A flow path is formed in the unit nozzle 325 to allow the organic waste to flow therein, and a drainage hole is formed in the bottom surface of the unit nozzle 325 so that the organic waste can be discharged downward. Further, the unit nozzle 325 is formed so that the inner diameter becomes narrower toward the downward direction so that the flow rate of the organic waste passing through the flow path may increase.

The unit nozzle 325 is formed such that the upper surface thereof is opened so that the lower end of the discharge nozzle 324 or the lower end of the unit nozzle 325 adjacent to the upper side can be drawn. At this time,

The unit nozzle 325 has an upper end portion of the unit nozzle 325 so that an inflow path can be provided between the inner wall surface and the outer surface of the discharge nozzle 324 drawn through the opened upper surface or the outer surface of the unit nozzle 325. [ The outer diameter of the lower end of the discharge nozzle 324 or the unit nozzle 325 drawn through the opened upper surface of the inner diameter is preferably larger.

A negative pressure is generated according to the flow rate of the organic waste passing through the discharge nozzle 324 and the unit nozzle 325. The negative pressure causes the outside air or the organic waste in the receiving container 330 to flow through the inflow path Flows into the nozzles 325 and is stirred with each other.

The support member 326 includes a plurality of first connection plates 327 for interconnecting the unit nozzle 325 located at the uppermost position and the main body 321 and a plurality of second connection plates 327 for interconnecting the unit nozzles 325. [ (328).

The first connecting plate 327 extends along the vertical direction, the upper end is fixed to the outer peripheral surface of the main body 321, and the lower end is fixed to the outer peripheral surface of the uppermost unit nozzle 325. A plurality of first connection plates 327 are provided on the outer peripheral surface of the unit nozzle 325 so as to be spaced apart from each other along the circumferential direction.

The upper end of the second connection plate 328 is fixed to the outer circumferential surface of the unit nozzle 325 located at the upper side and the lower end of the second connection plate 328 is fixed to the outer circumferential surface of the lower unit nozzle 325. A plurality of second connection plates 328 are installed on the outer peripheral surface of the unit nozzle 325 so as to be spaced apart from each other along the circumferential direction.

The accommodating container 330 is provided with an installation space 331 for accommodating the organic waste discharged through the external nozzle part 322 and is formed so as to be provided with an outlet for discharging the organic waste on the upper surface thereof . At this time, water is contained in the installation space 331 before the organic waste is injected from the aeration nozzle unit 320, and the organic waste is injected through the aeration nozzle unit 320 into the accommodation container 330 ) Dilutes the organic waste.

The lower end of the outer nozzle unit 322 is connected to the upper surface of the receiving container 330 so that a part of the unit nozzles 325 can be locked with the water or organic waste contained in the receiving container 330. [ And the upper end of the outer nozzle portion 322 is positioned above the outlet of the receiving container 330 so that the outside air can flow into the unit nozzles 325. [ As shown in Fig.

The air supply unit 400 includes an air supply pipe 401 having one end connected to the main body 321 and formed with an inflow hole 402 for allowing outside air to flow into the other end. In the illustrated example, one air supply pipe 401 is installed in the main body 321. However, the number of the air supply pipes 401 is not limited to the illustrated example but may be two or more.

The organic waste of the storage tank 200 is pumped into the main body 321 by the supply pump and the external air is discharged from the air supply pipe 401 by the negative pressure generated by the flow rate of the organic waste flowing inside the main body 321 To the inside of the main body 321 and stirred with the organic waste.

One end of the gas supply part 500 is connected to the accommodation tank 200 so that the gas in the accommodation tank 200 can be introduced into the main body 321 through the air supply pipe 401, And a gas supply pipe 501 connected to the air supply pipe 401. In the illustrated example, one gas supply pipe 501 is provided in the air supply pipe 401. However, the number of the gas supply pipes 501 is not limited to the illustrated example, but may be two or more.

The gas is sucked from the holding tank 200 by the negative pressure generated by the flow rate of the organic waste flowing in the main body 321 and flows into the main body 321 through the air supply pipe 401. The gas is introduced into the main body 321 and mixed with the organic waste, thereby improving the fermentation efficiency of the organic waste.

The collecting unit 600 includes a collecting container 601 in which the receiving container 330 is installed so that the organic waste discharged through the discharging port can be introduced into the collecting container 601 and both ends of the collecting container 601 and the receiving tank 200, respectively. The upper surface of the collecting container 601 is opened and the receiving container 330 is installed therein. The organic waste discharged through the outlet of the storage container 330 flows into the storage tank 200 through the return pipe 602 again.

The operation of the liquid production apparatus 100 using the multi-stage nozzle according to the present invention constructed as described above will be described in detail as follows.

First, when the supply pump is operated, the organic sulfur waste contained in the storage tank 200 is supplied into the main body 321 at a high pressure by the supply pump. At this time, a negative pressure is generated by the organic waste flowing into the main body 321, and the outside air and the fermentation gas in the holding tank 200 are sucked through the air supply pipe 401. The external air and the fermentation gas introduced into the main body 321 are mixed with the organic wastes to improve the fermentation efficiency of the organic wastes.

The organic waste in the main body 321 passes through the discharge nozzle 324 and the plurality of unit nozzles 325 at a high speed and is discharged into the receiving vessel 330 and diluted by the water contained in the receiving vessel 330. At this time, a negative pressure is generated between the unit nozzles 325 due to the flow rate of the organic waste, so that the diluted organic waste accommodated in the outside air or the storage container 330 flows between the unit nozzles 325 and agitates, And enhances the mixing ratio with the gas and gas.

The organic waste discharged into the storage container 330 flows into the collection hopper through the discharge port of the storage container 330 and flows into the storage tank 200 through the recovery pipe 602. The organic waste contained in the holding tank 200 is again pumped back into the main body 321 by the feed pump.

Since the gas generated from the organic waste as well as oxygen is supplied to the fluid by the gas supply unit 500 using the multi-stage nozzle according to the present invention constructed as described above, the time and attraction There is an advantage in that the user can save money.

 While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

100: Liquor production device using multi-stage nozzle
200: Storage tank
300:
310: Feed pump
320: Aeration nozzle unit
321:
322: outer nozzle part
325: Unit nozzle
330: receptacle container
400: air supply unit
401: Air supply pipe
500: gas supply part
501: gas supply pipe
600:
601: Collection container
602: Collection pipe

Claims (5)

A storage tank 200 containing organic wastes therein,
A supply pump 30 for pumping the organic waste contained in the storage tank 200 and an aeration nozzle unit 320 for spraying the organic waste pumped through the supply pump to contact the organic waste with oxygen, An aeration unit 300 provided with a storage container 330 having an installation space in which the aeration nozzle unit 320 is installed so as to receive the organic waste sprayed through the aeration nozzle unit 320, ,
An air supply unit 400 installed in the aeration nozzle unit 320 to supply oxygen to the organic waste supplied to the aeration nozzle unit 320 and an air supply unit 400 connected to the storage tank 200, A gas supply unit 500 for supplying a gas generated from the organic waste contained in the aeration nozzle unit 320 to the aeration nozzle unit 320,
(600) for collecting the organic waste sprayed by the aeration nozzle unit (320) and injecting the collected organic waste into the storage tank (200)
The aeration nozzle unit is provided with an accommodation space 323 therein so that the organic waste pumped by the supply pump 30 can be received therein and the organic waste introduced into the accommodation space 323 is supplied to the outside A main body 321 provided with a discharge nozzle 324 formed on the bottom surface of the discharge nozzle 324 so as to be discharged to the main body 321 by a supporting member, The unit nozzle 325 is provided with an outer nozzle part,
The unit nozzle 325 is formed with an inflow path through which external air or the organic waste in the container can be introduced into the unit nozzle 325 by the flow rate of the organic waste passing through the unit nozzle 325. The air supply unit 400 has one end And at least one air supply pipe (401) connected to the main body (321) and formed with an inflow hole for allowing outside air to flow into the other end, wherein the gas supply unit (500) And the other end is connected to at least one gas supply pipe 501 connected to the air supply pipe 401 so that the gas in the accommodation tank 200 can be introduced into the main body 321 through the air supply pipe 401. [ And,
The accommodating container 330 is provided with the installation space for accommodating water or the organic waste injected from the aeration nozzle unit 320. An outlet for discharging the organic waste is formed in the upper part of the accommodating container 330, The unit 320 is installed in the receiving container 330 such that the lower end of the external nozzle unit is positioned below the discharging port so that a part of the unit nozzles 325 can be locked in the water or the organic waste contained in the receiving container 330 Installed,
The collecting unit 600 includes a collecting container 601 in which the receiving container 330 is installed so that the organic waste discharged through the discharging port can be introduced into the collecting container 601, And a return pipe (602) connected to the tank (200), respectively.




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