KR102119221B1 - Oxygen dissolver for composting livestock sludge - Google Patents

Abstract

According to an embodiment of the present invention, disclosed is an oxygen dissolver for composting livestock excretion. The oxygen dissolver for composting livestock excretion comprises: a first circular plate; a second circular plate; a third circular plate; a first cylindrical pipe part; a pillar part; and a shielding part. According to the present invention, oxygen is easily dissolved in liquid livestock excretion, and thus an aerobic fermentation process of livestock excretion can be promoted.

Description

Oxygen dissolver for composting of livestock manure {OXYGEN DISSOLVER FOR COMPOSTING LIVESTOCK SLUDGE}

The present invention relates to an oxygen dissolver for composting of livestock manure, and more particularly, to an oxygen dissolving machine for composting of livestock manure so that oxygen is readily dissolved in livestock manure.

Tailored technologies for composting of livestock manure are being developed according to the nature and breeding conditions of livestock manure. For example, solid fermentation is suitable in the case of manure or manure because it is discharged as a solid. In the case of pig manure, liquid fermentation is suitable because it is often discharged as a liquid because the pig wash water is often mixed.

Because pig manure accounts for 50 to 80% of the total amount of livestock manure, the development of treatment technology for pig manure is becoming more important. As an example of a method for treating pig manure, first, the manure is separated into a sludge and a liquid through a solid-liquid separation process. Here, the liquid is liquidized, and the sludge is composted by mixing a moisture control agent such as sawdust or composting through a long-term drying process (usually more than 6 months) using a simple vinyl house facility. Recently, the SCB (compost filtration) method and the purification treatment method have been widely used, but the interest in the odor reduction technology is increasing because odor is continuously generated during composting, liquid fertilization, and purification treatment.

As an example of the technology that is the background of the present invention, the Republic of Korea Patent Publication No. 10-2017-0105950 (2017.9.20.) is for a high-temperature digestion liquid fertilizer manufacturing apparatus through an internal circulation and intermittent aeration, and a manufacturing method thereof, in a closed type Construct a reaction tank and circulate the internal air using an injector to prevent the odor from occurring as far as possible.

As another example of the technology that is the background of the present invention, Republic of Korea Patent Publication No. 10-0951307 (2010.4.5.) is for a livestock facility odor treatment system, in a liquid fertilizing facility that produces livestock manure generated from livestock as liquid fertilizer The odor removal efficiency is increased by circulating the microbial active liquid activated by aerobic microorganisms into circulating water of the odor prevention facility (bio filter) to remove odors from the house and cleaning water from the house.

An object of the present invention is to facilitate the aerobic fermentation process of livestock manure by easily dissolving oxygen in liquid livestock manure.

An object of the present invention is to remove the malodor of livestock manure by maintaining the activity of the active odor removal active species by continuously supplying oxygen to the livestock manure.

초과로 회전이동하는 것을 차단하는 차폐부를 포함할 수 있다. 여기서, 상기 제1 원형 플레이트 및 상기 제2 원형 플레이트는, 상기 기둥부에 의해 결합되어 서로 평행하게 배치되고, 상기 제1 원형 플레이트의 상기 일면 및 상기 제2 원형 플레이트의 타면은, 상기 산소용존분뇨체의 상기 와류를 분산시켜 산소용해를 촉진하는 돌출부가 배치될 수 있다.Oxygen dissolver for the composting of livestock manure according to an embodiment of the present invention, an agent for moving oxygen dissolved manure containing oxygen and the livestock manure from one side of the first circular plate to the other side of the first circular plate 1 The first circular plate on which the through portion is formed, the second circular plate on which the second through portion is formed to move the oxygen-soluble manure body from the other side of the first circular plate to one side of the second circular plate, and the first side is the first It is coupled to the first through portion of the circular plate, the other side is coupled to one surface of the second circular plate, the outer periphery of the first circular plate so that the oxygen-soluble manure body forms a vortex at the other side of the first circular plate A cylindrical first tube portion having a first outlet hole disposed in a tangential direction of, a pillar portion penetrating through a through hole formed in a center of the first circular plate and a center of the second circular plate, and a side surface of the first pipe portion, the It is formed so as to be connected to one surface of the first circular plate, the side surface of the pillar portion, and the one surface of the second circular plate, and flows through the first outlet hole disposed in the first tube to rotate around the pillar portion. The vortex of the oxygen-soluble manure body is 360 based on the position of the first outlet hole.

It may include a shield that blocks the rotational movement in excess. Here, the first circular plate and the second circular plate are coupled by the pillar portion to be disposed parallel to each other, the one surface of the first circular plate and the other surface of the second circular plate, the oxygen dissolved manure A protrusion for dispersing the vortex of the sieve to promote oxygen dissolution may be disposed.

According to various embodiments of the present invention, the aerobic fermentation process of livestock manure can be promoted by easily dissolving oxygen in liquid livestock manure.

According to various embodiments of the present invention, by continuously supplying oxygen to livestock manure, it is possible to remove the odor of livestock manure by maintaining the activity of active odor removal active species.

1 shows a liquid fermentation system of livestock manure according to an embodiment of the present invention.
2 is a cross-sectional view of an oxygen dissolver according to an embodiment of the present invention.
3 is an internal configuration diagram of an oxygen dissolver according to an embodiment of the present invention.
4 is an enlarged internal configuration diagram of an oxygen dissolver according to an embodiment of the present invention.
5 is a rear view and a side view of one cell of an oxygen dissolver according to an embodiment of the present invention.
6 is a rear view and a side view of one cell of an oxygen dissolver according to another embodiment of the present invention.
7 is a rear view and a side view of one cell of an oxygen dissolver according to another embodiment of the present invention.
8 is a rear view and a side view of one cell of an oxygen dissolver according to another embodiment of the present invention.

Hereinafter, the operation principle of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In addition, in describing embodiments of the present invention, when it is determined that detailed descriptions of related known functions or configurations may obscure the subject matter of the present disclosure, detailed descriptions thereof will be omitted. In addition, terms used in the following are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or practice. Therefore, the definitions of terms used should be interpreted based on the contents throughout the specification and corresponding functions.

1 shows a liquid fermentation system of livestock manure according to an embodiment of the present invention.

Referring to Figure 1, the liquid fermentation system 1 is a storage tank 10, livestock manure inlet 20, pump 30, oxygen dissolver 40, oxygen generator 50, compost outlet 60 and drain (70) may be included.

The storage tank 10 may store livestock manure. Here, the livestock manure may be, for example, liquid manure.

The livestock manure inlet 20 is a passage through which the livestock manure is introduced into the storage tank 10. For example, a pig bottom is provided with a plurality of gaps formed in the longitudinal direction of the pig house. Money manure is discharged through the gap bottom can be collected in the livestock manure input (20).

The pump 30 may pump livestock manure stored in the storage tank 10 to the outside of the storage tank 10. Livestock manure may be circulated according to the pumping of the pump 30.

The oxygen dissolver 40 can dissolve oxygen in livestock manure. For example, the oxygen dissolver 40 may dissolve oxygen in the liquid livestock manure in the process of stirring the liquid livestock manure. Through this, the liquid livestock manure can be dissolved in oxygen to become a high concentration of oxygen dissolved water.

The oxygen generator 50 supplies oxygen to the oxygen dissolver 40. The oxygen generator 50 is coupled to or connected to the oxygen dissolver 40, whereby livestock manure and oxygen can be simultaneously input to the oxygen dissolver 40.

The compost outlet 60 is an outlet of compost fermented with livestock manure. Here, the fermentation state of the discharged compost may be different depending on the presence or absence of an additional process and the application of the compost.

The drain 70 is a discharge port of water generated in the fermentation process of livestock manure.

1, the liquid fermentation system of livestock manure according to an embodiment of the present invention has been described in detail. Hereinafter, an embodiment of the oxygen dissolver 40 will be described in detail.

2 is a cross-sectional view of an oxygen dissolver according to an embodiment of the present invention.

Referring to FIG. 2, the oxygen dissolver 200 may include a plurality of chambers 201 to 210. Here, livestock manure (or liquid livestock manure) may flow out from the first chamber 201 to the tenth chamber 210.

For example, livestock manure may be introduced into the first chamber 201 through the outlet hole 201-1 formed in the pipe 212. In this case, the livestock manure is moved to the second chamber 202 through the pipe portion 202-1 by pumping the pump 30 described above. In the second chamber 202, livestock manure is discharged through the outlet hole formed in the cylindrical tube portion 202-1 and rotates around the pillar portion 211. This process is also repeated in the third chamber 203 to the ninth chamber 209.

Specifically, in the third chamber 203, the livestock manure flows out through the outlet hole formed in the cylindrical tube portion 203-1, and rotates around the pillar portion 211. In the fourth chamber 204, livestock manure is discharged through an outlet hole formed in the cylindrical tube portion 204-1 and rotates around the pillar portion 211. In the fifth chamber 205, livestock manure is discharged through an outlet hole formed in the cylindrical tube portion 205-1 to rotate and move around the pillar portion 211. In the sixth chamber 206, livestock manure is discharged through an outlet hole formed in the cylindrical tube portion 206-1 and rotates around the pillar portion 211. In the seventh chamber 207, livestock manure is discharged through the outlet hole formed in the cylindrical tube portion 207-1 and rotates around the pillar portion 211. In the eighth chamber 208, livestock manure is discharged through the outlet hole formed in the cylindrical tube portion 208-1 and rotates around the pillar portion 211. In the ninth chamber 209, livestock manure is discharged through the outlet hole formed in the cylindrical tube portion 209-1 to rotate about the pillar portion 211.

Oxygen can be dissolved in the livestock manure by easily contacting the particles of the livestock manure and oxygen during the rotation movement process of the livestock manure.

Livestock manure moved from the ninth chamber 209 to the tenth chamber 210 flows into the inlet hole 201-1 formed in the pipe 213 and moves to the outside of the oxygen dissolver 200.

3 is an internal configuration diagram of an oxygen dissolver according to an embodiment of the present invention.

Referring to FIG. 3, the oxygen dissolver 300 may have a structure in which a plurality of cells having the same structure are stacked. For example, one of the plurality of cells 310 may include a circular plate 301, a tube portion 302, and a protrusion 303 as one set. In addition, the plurality of cells may be stacked with the center connected to the pillar portion 320.

Hereinafter, various embodiments of the structure of the plurality of cells described above will be described in detail.

4 is an enlarged internal configuration diagram of an oxygen dissolver according to an embodiment of the present invention. 5 is a rear view and a side view of one cell of an oxygen dissolver according to an embodiment of the present invention.

4 and 5, the oxygen dissolver 300 includes a first circular plate 330, a second circular plate 340, a first tube portion 331, a pillar portion 320, and a protruding portion 332. It can contain.

The first circular plate 330 may be defined as a partition that divides at least two of the plurality of chambers described above. In this case, the first circular plate 330 may support the first tube portion 331 and the pillar portion 320 and the protrusion 332 to be described later.

The first circular plate 330 may form a first through portion 3301. Here, the first through portion 3301 may move the oxygen-dissolved manure body including oxygen and livestock manure from one side of the first circular plate 330 to the other side of the first circular plate 330.

The second circular plate 340 may also be defined as a partition that divides at least two of the plurality of chambers described above.

The second circular plate 340 may form a second through portion 3401. Here, the second through portion 3401 may move the oxygen-dissolving manure body from the other side of the first circular plate 330 to one side of the second circular plate.

The first pipe portion 331 is a pipe that moves the oxygen-dissolving manure. One side of the first tube portion 331 may be coupled to the first through portion 3301 of the first circular plate 330. In addition, the other side of the first tube portion 331 may be coupled to one surface of the second circular plate 340. In this case, the first tube portion 331 is a first outlet hole 3311 arranged in the tangential direction of the outer periphery of the first circular plate 330 so that the oxygen-dissolving manure forms a vortex on the other side of the first circular plate 330 It can be formed.

The pillar portion 320 may penetrate a through hole formed in the center of the first circular plate 330 and the center of the second circular plate 340. The first circular plate 330 and the second circular plate 340 may be combined by the pillar portion 320 and disposed parallel to each other.

The protrusion 332 may promote oxygen dissolution by dispersing the vortex of the oxygen-dissolving manure on one surface of the first circular plate 330 and the other surface of the second circular plate 340.

Meanwhile, the oxygen dissolver 300 may further include a third circular plate 350. In this case, the third circular plate 350 may be disposed with a third through portion 3501 for moving the oxygen-dissolving manure from the one side of the second circular plate 340 to one side of the third circular plate 350. You can.

In addition, the oxygen dissolver 300 described above may further include a second pipe part 351. One side of the second pipe portion 351 may be coupled to the second through portion 3401 of the second circular plate 340. In addition, the other side of the second pipe portion 351 may be coupled to one surface of the third circular plate 350. In this case, the second pipe portion 351 may be formed with a second outlet hole disposed in a tangential direction of the outer periphery of the second circular plate 340 so that the oxygen-dissolving manure forms a vortex at one side of the second circular plate 340. have.

In one embodiment of the present invention described above, the pillar portion 320 may penetrate a through hole formed in the center of the third circular plate 350. Accordingly, the first circular plate 330, the second circular plate 340, and the third circular plate 350 may be disposed parallel to each other.

In addition, in one embodiment of the present invention described above, the distance between the centers of the first through plate 3301 and the first circle plate 330 formed in the first circle plate 330 is formed in the second circle plate 340. It is the same as the distance between the centers of the second through portion 3401 and the second circular plate 340.

In addition, in FIG. 5 described above, one side 331-1 of the first tube portion 331 may protrude a predetermined length in one direction of the first circular plate 330. Likewise, the one side of the second pipe portion 351 may protrude a predetermined length in the other direction of the second circular plate 340.

Meanwhile, the oxygen dissolver 300 may further include a case portion. For example, the case portion may be disposed to surround the side surface of the first circular plate 330, the side surface of the second circular plate 340, and the side surface 350 of the third circular plate.

Hereinafter, various embodiments of one cell of the oxygen dissolver 300 will be described in detail. However, in order to avoid duplication of the description, detailed description of the configuration overlapping with the above-described configuration will be omitted.

6 is a rear view and a side view of one cell of an oxygen dissolver according to another embodiment of the present invention.

Referring to FIG. 6, the through portion 6101 formed on the circular plate 610 of the oxygen dissolver 600 may be disposed in contact with the outer circumference of the circular plate 610. In this case, one side of the pipe portion 611 coupled to the through portion 610 may also be disposed in contact with the outer circumference of the circular plate 610. In this case, the oxygen-dissolved manure discharged through the outlet hole 6111 formed in the tube portion 611 may rotate in a larger circle around the pillar portion 620. Here, the protrusion 612 may contact the outer circumference of the circular plate 610 or may be disposed close to the outer circumference of the circular plate 610 according to the larger radius of the rotational movement of the oxygen-dissolving manure.

7 is a rear view and a side view of one cell of an oxygen dissolver according to another embodiment of the present invention.

FIG. 7 shows a structure in which a shield 612 is added to the same structure as one cell of the oxygen dissolver 600 of FIG. 6 described above.

초과로 회전이동하는 것이 차폐부(613)에 의해 차단될 수 있다. 차폐부(612)는 산소용존분뇨체의 불필요한 회전을 차단하고, 산소용존분뇨체를 다른 챔버로 용이하게 이동시킬 수 있다.Here, the shield 613 is on the side of the tube portion 611, one surface of the first circular plate 610, the side surface of the pillar portion 620 and the second circular plate (for example, 340 in FIG. 4) It may be formed to be connected. In this case, the vortex of the oxygen-dissolving manure that flows out through the outlet hole 6111 disposed in the tube portion 611 and rotates around the pillar portion 620 is 360 based on the location of the outlet hole 6111

Excessive rotational movement may be blocked by the shield 613. The shielding portion 612 blocks unnecessary rotation of the oxygen-dissolving manure, and can easily move the oxygen-dissolving manure to another chamber.

8 is a rear view and a side view of one cell of an oxygen dissolver according to another embodiment of the present invention.

8 illustrates a structure in which the first shielding part 333 and the second shielding part 334 are added to the same structure as one cell of the oxygen dissolver 300 of FIG. 5 described above.

Here, the first shielding portion 333 is one side surface of the first tube portion 331, one surface of the first circular plate 330, the side surface of the pillar portion 320 and the second circular plate (for example, in FIG. It may be formed to be connected to one surface of 340).

The second shielding part 334 includes the other side surface of the first tube part 331, one surface of the first circular plate 330, the side surface 335 of the case part, and the second circular plate (for example, 340 of FIG. 4 ). It may be formed to be connected to one surface.

초과로 회전이동하는 것이 제1 차폐부(333) 및 제2 차폐부(334)에 의해 차단될 수 있다. 제1 차폐부(333) 및 제2 차폐부(334)는 산소용존분뇨체의 불필요한 회전을 차단하고, 산소용존분뇨체를 다른 챔버로 용이하게 이동시킬 수 있다.In this case, the vortex of the oxygen-dissolved manure that flows out through the first outlet hole 3311 disposed in the first pipe part 331 and rotates around the pillar part 320 is positioned at the first outlet hole 3311. Based on 360

Excessive rotational movement may be blocked by the first shield 333 and the second shield 334. The first shielding part 333 and the second shielding part 334 block unnecessary rotation of the oxygen-dissolving manure, and can easily move the oxygen-dissolving manure to another chamber.

In various embodiments of the present invention described above, the pillar portions 211 and 320 may be provided with a backflow prevention plate. Here, the backflow prevention plate is disposed in the direction of rotational movement of the oxygen-dissolving manure to prevent the oxygen-dissolving manure body from flowing backward in the opposite direction of the rotational movement direction after reaching the shield. For example, the backflow prevention plate may be concave in the rotational movement direction and may be formed in a convex curved shape in the opposite direction of the rotational movement direction.

According to various embodiments of the present invention described above, the aerobic fermentation process of livestock manure can be promoted by easily dissolving oxygen in liquid livestock manure. In addition, by continuously supplying oxygen to the livestock manure, it is possible to remove the odor of the livestock manure by maintaining the activity of the active odor removal active species.

While the embodiments of the present invention have been shown and described above, various changes in form and details may be made by those skilled in the art without departing from the spirit and scope of the present embodiment as defined by the appended claims and equivalents thereof. You will understand that you can.

Liquid fermentation system: 1
Reservoir: 10
Livestock manure input: 20
Pump: 30
Oxygen Dissolver: 40, 200, 300, 600
Oxygen generator: 50
Compost outlet: 60
Drain: 70
First round plate: 330, 610
Second round plate: 340, 620
First Presidency: 331
Second government department: 351
First penetration: 3301
Second penetration: 3401
Third penetration: 3501
Protrusions: 332, 612

Claims (7)

In the oxygen dissolver for composting of livestock manure,
The first circular plate formed with a first through portion for moving an oxygen-soluble manure body including oxygen and the livestock manure from one side of the first circular plate to the other side of the first circular plate;
The second circular plate formed with a second through portion for moving the oxygen-soluble manure body from the other side of the first circular plate to one side of the second circular plate;
The third circular plate having a third through portion for moving the oxygen-soluble manure body from the one side of the second circular plate to one side of the third circular plate;
One side is coupled to the first through portion of the first circular plate, the other side is coupled to one surface of the second circular plate, and the oxygen-soluble manure body is formed on the other side of the first circular plate to form the vortex. A cylindrical first tube portion having a first outlet hole disposed in a tangential direction of the outer periphery of the circular plate;
A pillar portion penetrating through the through hole formed in the center of the first circular plate and the center of the second circular plate; And
It is formed to be connected to the side surface of the first tube portion, one surface of the first circular plate, the side surface of the pillar portion, and the one surface of the second circular plate, and is discharged through the first outlet hole disposed in the first tube portion The vortex of the oxygen-soluble manure that rotates and moves around the pillar portion is 360 based on the position of the first outlet hole.

Includes; shielding to prevent the rotational movement exceeded;
The first circular plate and the second circular plate are coupled by the pillar portion and are disposed parallel to each other,
The one surface of the first circular plate and the other surface of the second circular plate are dispersing the vortices of the oxygen-dissolving manure, and protruding portions for promoting oxygen dissolution are disposed.
According to claim 1,
One side is coupled to the second through portion of the second circular plate, the other side is coupled to one surface of the third circular plate, and the oxygen-dissolving manure body is formed on the one side of the second circular plate to form the vortex. 2, a second cylindrical tube portion formed with a second outlet hole disposed in a tangential direction of the outer periphery of the circular plate; further comprising, oxygen dissolver.
According to claim 2,
The pillar portion penetrates a through hole formed in the center of the third circular plate,
The first circular plate, the second circular plate and the third circular plate, are arranged in parallel to each other, oxygen dissolver.
According to claim 3,
The distance between the first through-plate formed in the first circular plate and the center of the first circular plate is the same as the distance between the second through-plate formed in the second circular plate and the center of the second circular plate, Oxygen dissolver.
The method of claim 4,
The one side of the first tube portion,
The first circular plate protrudes a predetermined length in the direction of the one side,
The one side of the second pipe portion,
The oxygen dissolver, which protrudes a predetermined length in the other direction of the second circular plate.
The method of claim 5,
A case portion disposed to surround a side surface of the first circular plate, a side surface of the second circular plate, and a side surface of the third circular plate; further comprising a oxygen dissolver. delete

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