KR101402610B1 - Odorless composting processor of livestock wastewater - Google Patents

Abstract

The present invention relates to a livestock wastewater odorless composing processor comprises: an oxygen dissolution device connected to an oxygen supplier and a wastewater inserting line and dissolves oxygen in the wastewater in the inner side; a wastewater processing bath connected to an oxygen dissolver and inserts the wastewater in which the oxygen is dissolved; and a dehydration pulverizer connected to the wastewater processing bath and dehydrates and pulverizes and composts the processing water.

Description

{Odorless composting processor of livestock wastewater}

The present invention relates to an apparatus for composting livestock wastewater having a high solids content and generating odor. More specifically, the present invention relates to an apparatus for composting livestock wastewater, To a processing apparatus which can be used as a processing apparatus.

Livestock wastewater is generated by the excretion of livestock such as pigs and cows raised in money and housing. These livestock wastewater contains a large amount of solid matter and organic matter such as manure, and is generally treated by supplying oxygen gas to the inside of the treatment tank. When the oxygen gas is sufficiently supplied to the inside of the livestock wastewater, the growth of the anaerobic microorganisms causing the odor is suppressed and the growth of the aerobic microorganisms is activated, so that the volatile sulfur compounds such as hydrogen sulfide which is the main odor inducing substance contained in the livestock wastewater And volatile nitrogen compounds such as ammonia are decomposed. This can reduce the odor from the livestock wastewater and reduce the sediment.

However, conventionally, as disclosed in Korean Patent Registration No. 0983094, the oxygen gas is supplied to the treatment tank in which the livestock wastewater is stored through the oxygen generating device. Since oxygen gas is formed in a relatively large air bubble form, It does not diffuse well inside the wastewater. As a result, the oxygen gas is not dissolved smoothly in the livestock wastewater, so that it takes a considerable time to treat the livestock wastewater. In addition, since the oxygen is not sufficiently dissolved in the livestock wastewater, the odor is not sufficiently removed, and the process for removing the odor must be performed separately as the treated water is composted.

Korean Patent Registration No. 0983094

Therefore, in order to solve the above-mentioned problems, the present invention provides a livestock wastewater treatment apparatus for removing odors and composting treated water by directly dissolving oxygen in livestock wastewater to activate the growth of aerobic microorganisms, To provide.

The present invention relates to an apparatus for composting livestock wastewater-free odor compost, comprising: an oxygen dissolver connected to an oxygen feeder and a wastewater inflow line so that oxygen is dissolved in livestock wastewater; A wastewater treatment tank connected to the oxygen dissolver and into which the livestock wastewater in which oxygen is dissolved flows; And a dehydrating mill connected to the wastewater treatment tank for dehydrating, pulverizing and composting the treated water.

For example, the oxygen dissolver may include a casing through which livestock wastewater and oxygen are introduced from one side and oxygen dissolved water is discharged from the other side; A plate formed at least one above and below the casing to partition the vortex chamber, respectively; A flow hole formed at a rim of the plate to allow the upper and lower swirl chambers to communicate with each other; A lower tube portion mounted to communicate with the flow hole, and a correlation portion bent integrally at the lower tube portion, wherein the fluid introduced from the lower vortex chamber is bent in the circumferential direction of the plate so as to flow in the upper vortex chamber through the inner periphery of the casing And an induction tube.

In addition, in the upper and lower plates, the flow holes of the lower plate and the upper plate are arranged such that the fluid discharged from the induction pipe of the lower plate flows into the flow holes of the upper plate at less than 360 degrees in the direction of fluid rotation, As shown in FIG.

In addition, it is appropriate that the lower end of the outer periphery of the upper tube is in contact with the plate.

In addition, for example, in the casing, the livestock wastewater and oxygen are introduced into the lowermost vortex chamber and oxygen dissolved water is discharged from the uppermost vortex chamber, and each vortex chamber has a diameter larger than the diameter of the upper vortex chamber .

In addition, the vortex chamber may be configured such that the diameter of the lower end portion is larger than the diameter of the upper end portion.

The apparatus for anaerobic composting treatment of livestock wastewater according to the present invention sufficiently dissolves oxygen in livestock wastewater from pigs, houses, houses and the like, whereby the growth of anaerobic microorganisms is suppressed and the growth of aerobic microorganisms is activated, It is possible to produce the odorless compost without any additional treatment by composting the treated water by dehydration and pulverization.

1 is a schematic diagram showing a basic example of a processing apparatus of the present invention,
Fig. 2 is a schematic view showing an oxygen dissolver which is an embodiment of the present invention,
3 is a perspective view showing a structure in which an induction tube is formed on a plate in an oxygen dissolver,
FIG. 4 is a plan view showing an operating state of the oxygen dissolver shown in FIG. 2,
5A and 5B are schematic diagrams showing an embodiment of an oxygen solubilizer.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

Hereinafter, the structure and operation of the present invention will be described in more detail with reference to the accompanying drawings. In describing the present invention, terms and words used in the present specification and claims are to be construed in accordance with the principles of the present invention, on the basis that the inventor can properly define the concept of a term in order to best explain his invention It should be construed as meaning and concept consistent with the technical idea of.

Fig. 1 is a schematic view showing a basic example of the treatment apparatus of the present invention, Fig. 2 is a schematic view showing an oxygen dissolver which is one constitution of the present invention, Fig. 3 is a perspective view showing a structure in which an induction tube is formed in a plate in an oxygen dissolver Fig. 4 is a plan view showing the operating state of the oxygen dissolver shown in Fig. 2, and Figs. 5a and 5b are schematic views showing an embodiment of the oxygen dissolver.

First, as shown in FIG. 1, an apparatus for treating odorless compost livestock wastewater according to the present invention comprises an oxygen dissolver 1 connected to an oxygen supplier 6 and a wastewater inflow line 11 so that oxygen is dissolved in livestock wastewater therein; A wastewater treatment tank (8) connected to the oxygen dissolver (1) into which the livestock wastewater in which oxygen is dissolved flows; And a dehydrator (9) connected to the wastewater treatment tank (8) for dehydrating, pulverizing and composting the treated water.

The term "livestock wastewater" refers to wastewater containing a large amount of solids and organic matter, such as livestock manure, which has a large amount of solids and organic matter, which causes odor generation and cost disadvantages of filtration.

Accordingly, the present invention is intended to enable the use of compost without any additional treatment by removing the odor and decomposing organic matter by raising the oxygen dissolution rate in the livestock wastewater and composting the treated water treated with no-smell.

As shown in FIG. 1, the oxygen dissolver 1 includes a casing 2 through which livestock wastewater and oxygen are introduced from one side and oxygen dissolved water is discharged from the other side. A plate (3) formed at least one above and below the casing (2) to define vortex chambers (7); A flow hole 4 formed at a rim portion of the plate 3 so as to allow the upper and lower swirl chambers 7 to communicate with each other; A lower tube portion 51 which is mounted so as to communicate with the flow hole 4 and a fluid which is integrally bent at the lower tube portion 51 and flows in the lower vortex chamber 7 flows from the upper vortex chamber 7 into the casing 2 And a guiding pipe (5) composed of a correlation part (52) bent in the circumferential direction of the plate (3) to flow on the inner periphery of the plate (3).

1, a wastewater inflow line 11 is formed at the lower end of the casing 2 to introduce wastewater, and an oxygen supply unit 6 is formed in the wastewater inflow line 11, So that the wastewater and the oxygen supplied from the oxygen feeder 6 are introduced into the inside. The inflow line 11 is disposed at the center of the lower end of the casing 2 in the figure but is formed at the edge of the lower end of the casing 2 in order to form a vortex even in the lowermost vortex chamber 7 It is reasonable.

In the casing 2, an oxygen dissolved water discharge line 12 is formed at an upper end so that dissolved oxygen is discharged to the outside by the vortex flow of the raw water in each swirl chamber 7. The oxygen-dissolved water discharge line (12) is disposed at the center in the figure, but it is preferable that the fluid discharged from the induction pipe (5) formed on the uppermost plate (3) It is proper to form the oxygen-dissolved water discharge line 12 so as to prevent the deterioration of the dissolution rate due to the flushing of the foreign matter or the occurrence of micro-bubbles due to the collision between vortexes.

The shape of the casing 2 is not limited, but it is proper that the casing 2 is formed in a cylindrical shape for smooth vortex formation.

One or more plates (3) are formed on the inside of the casing (2) so that a plurality of vortex chambers (7) are formed in the casing (2) by the plate (3).

The flow hole 4 is formed at a rim portion of the plate 3 so that the upper and lower vortex chambers 7 communicate with each other so that the induction pipe 5 to be described below is mounted. The number of the flow holes 4 is not limited, but it is proper to form one flow hole 4 in the plate 3 as shown in the figure.

This is because, in the conventional oxygen dissolving apparatus, the vortices induced in the induction pipe mounted on the respective flow holes are caused to collide with each other due to the formation of the plurality of flow holes, so that there is a problem that foreign substances are scattered or deposited by hair or the like in the flow holes , And one flow hole (4) is formed as in the present invention to prevent the problem of such deposition. In addition, in the conventional oxygen dissolving apparatus, a vortex is formed in a plurality of induction pipes in a plurality of induction tubes, and a collision between vortexes occurs. Such a collision increases pressure at the collision portion to increase the dissolution rate, There is a problem in that the dissolution rate is lowered due to the generation of minute bubbles. Accordingly, in the present invention, one guide hole 4 is formed at the edge of each plate 3. [

2 and 4, the flow hole 4 of the lower plate 3 and the flow hole 4 of the upper plate 3 in the upper and lower plates 3, It is proper to form a constant clearance d on the basis of the vertical and vertical lines. That is, the upper and lower plates (3, 4) are vertically and horizontally arranged so that the fluid discharged from the induction pipe (5) of the lower plate (3) flows into the flow hole (4) of the upper plate Each of the flow holes 4 formed in the flow path 3 is formed to have a constant clearance d.

By this, it is possible to minimize the collision between vortexes in one vortex chamber 7. By this function, it is possible to control the problem of the flow obstruction due to the flushing of the foreign matter and double the oxygen dissolution rate.

The induction pipe 5 has a lower pipe portion 51 mounted so as to communicate with the flow hole 4 in such a manner that one end thereof is mounted on the flow hole 4 and the other end is opened in the circumferential direction of the plate 3, And the lower vortex chamber 7 is integrally bent in the lower vortex chamber 51 and flows in the upper vortex chamber 7 in the circumferential direction of the plate 3 so as to flow along the inner circumference of the casing 2 And a folded correlation portion 52.

In other words, the induction pipe 5 is bent so that the fluid swirling in the lower vortex chamber 7 flows in the rim of the plate 3 and rides on the inner circumference of the casing 2 in the upper vortex chamber 7 So that the vortex in the circular direction is induced. In this way, the corrugated portion 52 bent in the circumferential direction of the plate 3 is formed in the induction pipe 5, so that the fluid introduced in the vortex chamber 7 forms a vast circular vortex as much as possible, It is possible to increase the dissolution rate by the vortex formed in the course of the reaction.

As shown in Fig. 4, the vortex flow w1 formed by the induction pipe 5-1 in the lower vortex chamber 7-1 is connected to the lower vortex chamber 7-1, -1), the dissolution rate is increased by a vortex formed while the residence time is made long so that a vortex in the counterclockwise direction in the drawing is formed. The vortex (w1) And flows into the induction pipe 5-2 of the upper vortex chamber 7-2 in which the tube 5-1 and the constant clearance d are formed so that the vortex w2 in the counterclockwise direction also flows in the upper vortex chamber 7-2. Is formed.

That is, the vortex formed in each vortex chamber 7 is guided to the upper vortex chamber 7 before rotating 360 degrees to minimize the vortex collision in the vortex chamber 7. In addition, it is possible to simplify the line through which the fluid flows in the vortex chamber 7, thereby preventing foreign substances such as hair from being deposited on the induction pipe 5.

  Preferably, the lower end of the outer periphery of the upper pipe 52 is brought into contact with the plate 3 so as to minimize the space in which the vortexed water is used. That is, when the induction tube is spaced apart from the upper surface of the plate as in the prior art, foreign matter may be deposited between the induction tube and the upper surface of the plate, thereby causing secondary contamination. So that the lower end of the outer periphery is in contact with the plate (3).

1, the wastewater inflow line 11 and the oxygen-dissolved water discharge line 12 are connected to each other by the circulation line 14, and the oxygen-dissolved water discharged through the oxygen- And is introduced into the dissolver 1 to increase the oxygen dissolution rate.

The present invention, as shown in Figs. 5A and 5B, shows oxygen dissolvers 1a and 1b of another embodiment.

4A, in the oxygen dissolving apparatus 1a, the wastewater inflow line 11 is connected to the lowermost vortex chamber 71 of the casing 2 so that wastewater and oxygen flow into the uppermost vortex chamber 74, The discharge line 12 is connected to discharge oxygen dissolved water, and each of the vortex chambers 71, 72, 73. 74 is configured such that the diameter of the lower vortex chamber is larger than the diameter of the upper vortex chamber. For example, the diameter d1 of the lowermost vortex chamber 71 is made larger than the diameter d2 of the upper vortex chamber 72 just above. Therefore, the diameter of each vortex chamber 71 is such that d1> d2> d3> d4.

This is because the wastewater inflow line 11 is connected to the lowermost vortex chamber 71 and the oxygen dissolved water discharge line 12 is connected to the uppermost vortex chamber 74. As a result, So that the diameter of the vortex chamber becomes smaller as it goes to the upper part, and the pressing force is increased to the wastewater and oxygen introduced into the inside of the vortex chamber to increase the oxygen dissolution rate in the wastewater.

This is because the wastewater flows from the lower part to the upper part of the oxygen dissolver 1 depending on the amount of the wastewater flowing into the wastewater inflow line 11, It is assumed that the pressure of the wastewater flows in the upward direction of the wastewater (1), so that the wastewater flows into the narrow space in the upward direction to increase the pressure acting on the wastewater to double the dissolved rate of oxygen will be.

In the case of the embodiment 1b shown in FIG. 4B, the casing 2 is formed in such a shape as to form a gentle curved surface and to be narrowed in the upward direction. In the embodiment 1b shown in FIG. 4A, The diameter of the lower end portion of each vortex chamber is made larger than the diameter of the upper end portion.

4b, the average diameters d1, d2, d3 and d4 between the vortex chambers 71, 72, 73 and 74 are made smaller toward the upper vortex chamber, (71, 72, 73, 74), the diameter of the lower end portion is larger than the diameter of the upper end portion. The diameter d1-1 of the lower end portion is set to be larger than the diameter d1-2 of the upper end portion by taking the lowermost vortex chamber 71 as an example.

The reason why the diameter of the upper end portion and the lower end portion are different from each other also in the vortex chamber is that the wastewater flowing into the vortex chamber 7 flows upward in the vortex chamber 7 and flows into the upper vortex chamber 7, So that the dissolution rate of oxygen in the wastewater is increased.

Oxygen dissolved water flows into the wastewater treatment tank 8 through the oxygen dissolved water discharge line 12 while the wastewater flows through the oxygen dissolver 1 as described above and is stored. In the wastewater treatment tank (8), oxygen dissolved water sufficiently dissolved in oxygen is introduced into the livestock wastewater so that an aerobic decomposition process is performed by the action of aerobic microorganisms. Through this process, hydrogen sulfide, ammonia and volatile organic compounds are decomposed, The odor is removed.

Although not shown in the drawing, the wastewater treatment tank 8 may be equipped with a temperature control device or a filter medium to further enhance the activity of the aerobic microorganisms.

After the sufficient aerobic process has been completed in the wastewater treatment tank 8, the treated water flows to the dehydrating and crushing device 9. In the dehydrating and crushing device 9, moisture is removed from the treated water by drying and pressurization, And so on, so that the cake-like solids are crushed to form a granular compost.

Such a compost can be used as a product directly without further treatment in a state in which the odor has been sufficiently removed from the front end. The dehydrating mill 9 may be any of various well known techniques, so that its explanation is omitted.

1: Oxygen dissolver 2: casing
3: Plate 4: Floating ball
5: induction tube 6: oxygen supplier
7: Vortex chamber 8: Wastewater treatment tank
9: Dehydrating mill 11: Waste water inflow line
12: Oxygen-dissolved water discharge line

Claims (6)

An oxygen dissolver connected to the oxygen supplier and the wastewater inflow line so that oxygen is dissolved in the wastewater;
A wastewater treatment tank connected to the oxygen dissolver and into which wastewater containing oxygen is introduced;
And a dehydrating mill connected to the wastewater treatment tank for dehydrating, pulverizing and composting the treated water,
The oxygen-
A casing for introducing wastewater and oxygen from one side and discharging oxygen dissolved water from the other side; A plate formed at least one above and below the casing to partition the vortex chamber, respectively; A flow hole formed at a rim of the plate so that the upper and lower swirl chambers communicate with each other; A lower tube portion mounted to communicate with the flow hole, and a correlation portion bent integrally at the lower tube portion, wherein the fluid introduced from the lower vortex chamber is bent in the circumferential direction of the plate so as to flow in the upper vortex chamber through the inner periphery of the casing Guide tube,
In the upper and lower plates, the flow holes of the lower plate and the flow holes of the upper plate are spaced apart from each other such that the fluid discharged from the induction pipe of the lower plate flows into the flow holes of the upper plate at less than 360 degrees in the fluid rotation direction Wherein the composting unit is formed at a predetermined position.
delete delete delete The method according to claim 1,
Wherein the casing is configured such that wastewater and oxygen are introduced into the lowermost vortex chamber and oxygen dissolved water is discharged from the uppermost vortex chamber, and each vortex chamber has a diameter of the lower vortex chamber larger than that of the upper vortex chamber Livestock wastewater - free odor composting system.
6. The method of claim 5,
Wherein the vortex chamber has a diameter at the lower end thereof larger than a diameter of the upper end thereof.

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