KR102330899B1 - Compost fermentation apparatus - Google Patents

Abstract

The present invention relates to a compost decomposer. According to one embodiment of the present invention, the compost decomposer comprises: a main body; a blower which is installed inside the main body and blows air; a heating unit which is installed inside the main body, receives air from the blower, and heats the received air; a decomposed microbial stirred liquid generating unit which is installed inside the main body, receives the heated air from the heating unit, and stirs water with decomposed microorganisms to generate a decomposed microbial stirred liquid; a mixing unit which receives the heated air from the heating unit, receives the decomposed microbial stirred liquid from the decomposed microbial stirred liquid generating unit, and mixes the received decomposed microbial stirred liquid; and a discharge unit which is connected to the mixing unit, is arranged on a compost shed, and discharges air mixed with the decomposed microbial stirred liquid to the compost shed. According to the present invention, the compost decomposer has the effect of preventing death of microorganisms by injecting air into the compost.

Description

Compost fermentation apparatus

The present invention relates to the compost ripening period.

In general, when the manure of livestock is discharged unilaterally, it becomes a major cause of contamination of soil and rivers. In order to solve these general problems, by converting livestock manure into organic fertilizer and using it in the soil, it is possible to fertilize the soil acidified due to the use of chemical fertilizers, thereby cultivating excellent soil quality.

As a conventional method for composting livestock manure, there is a method of mixing livestock manure with sawdust. When livestock manure is mixed with sawdust, microorganisms grow, and these microorganisms rapidly decompose and change livestock manure and sawdust into organic fertilizer.

In such a conventional composting machine, there is a 'continuous batch-type composting device' in Korean Utility Model No. 20-1995-0006383.

In the case of the conventional composting period, including the prior art, when the mixture of manure and sawhape runs out of oxygen after a certain period of time, the microorganisms die, and the mixture is not organically fertilized, but rots, and can be used as fertilizer. There was a problem that it didn't exist.

In addition, in the case of the conventional composting period including the prior art, there is a problem that the time required for composting is long as the decomposition occurs slowly due to the low temperature of microorganisms in the winter season.

It was devised based on the technical background as described above, and an embodiment of the present invention can prevent the death of microorganisms by supplying air to the compost, and increase the temperature of the compost in the winter so that the decomposition of microorganisms is smoothly performed. Therefore, it is intended to provide a composting machine that can reduce the time required for composting.

In order to achieve the above object, a composting machine according to an embodiment of the present invention includes a main body; a blower installed in the body and blowing air; a heating unit installed in the body and receiving air from the blower to heat the air; a fermented microbial stirring liquid generating unit installed inside the main body and receiving heated air from the heating unit to agitate water and fertilized microorganisms to generate a fermented microbial stirring liquid; a mixing unit that receives heated air from the heating unit and receives and mixes the mature microorganism stirring liquid from the mature microorganism stirring liquid generating unit; It is connected to the mixing unit and disposed in the composting unit and may include a discharge unit for discharging the air mixed with the fermented microorganism stirring liquid from the mixing unit to the composting unit.

In addition, the heating unit, a heating body having one end connected to the blower side; a heating coil installed inside the heating body and dissipating heat to heat the air transferred from the blower; It may include a heating sensor installed on the rear end side of the heating body for measuring the temperature of the air that has passed through the heating coil.

In addition, the immature microorganism stirring liquid generating unit may include: a tank in which an internal space is formed, a fermented microbial undiluted solution is introduced into the inner space through an immature microbial undiluted solution inlet, and water is introduced into the internal space through a water inlet; a first stirring unit having one end connected to the tube connected to the heating unit and disposed in the lower portion of the inner space of the tank to discharge heated air to the mature microbial undiluted solution and water to stir the fermented microbial undiluted solution and water; And one end is connected to the pipe connected to the heating unit and disposed in the upper portion of the inner space of the tank to agitate the heated air, the fermented microorganism stock solution and water, and may include a second stirring unit for discharging to the inner space.

In addition, the discharge unit may include: at least one discharge pipe having one side connected to the conveying pipe connected to the mixing unit and having a plurality of discharge holes formed on an outer circumferential surface; and a protective pipe spaced apart from the discharge pipe at a predetermined distance, surrounding the discharge pipe, and having a plurality of through-holes formed on an outer circumferential surface thereof.

In addition, the discharge unit may include: at least one discharge pipe having one side connected to the conveying pipe connected to the mixing unit and having a plurality of discharge holes formed on an outer circumferential surface; a back tubule having one side connected to the transfer pipe and the other side connected to the other side of the discharge pipe; a first washing pipe connected to one side of the discharge pipe; and a second washing pipe connected to one side of the back pipe, wherein a first valve is provided between the transfer pipe and the discharge pipe, and a second valve is provided between the first washing pipe and the discharge pipe, A third valve is provided between the transfer pipe and the back tubule, and a fourth valve is provided between the second washing pipe and the back tubule. When the discharge part is washed, the first valve, the second valve, The fourth valve may be opened and the third valve may be closed.

In addition, it may include a control unit installed on the main body to control the blower and the heating unit.

The compost steamer according to an embodiment of the present invention has the effect of preventing the death of microorganisms by injecting air into the compost by discharging the air mixed with the fermentation mixture of microorganisms into the compost through the discharge unit.

The composting machine according to an embodiment of the present invention raises the temperature of the air through the heating unit and discharges it to the composting material through the discharge unit, thereby increasing the temperature of the compost in the winter season to facilitate the decomposition of microorganisms. has the effect of reducing

1 is a schematic diagram showing a compost ripening period according to an embodiment of the present invention.
2 is a perspective view showing the main body of the composting machine according to an embodiment of the present invention.
3 is a view showing the inside of the main body of the composting machine according to an embodiment of the present invention.
4 is a view showing a heating unit of the compost ripening period according to an embodiment of the present invention.
5 is a view showing a fermenting microbial stirring liquid generating unit of the compost fermenting period according to an embodiment of the present invention.
6 is a view showing a first embodiment of the discharging unit of the composting machine according to an embodiment of the present invention.
7 is a view showing a first embodiment of the discharging unit of the compost ripening machine according to an embodiment of the present invention.
8 is a view showing a second embodiment of the discharging unit of the compost ripening machine according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. The present invention may be embodied in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and the same reference numerals are assigned to the same or similar components throughout the specification.

In the present specification, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It is to be understood that it does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

In the composting machine according to an embodiment of the present invention, the discharge unit is installed in the composting company, and the air mixed with the fermentation of the composting microorganisms is discharged to the compost to make the compost.

1 to 8 , the composting machine 10 according to an embodiment of the present invention includes a main body 100 , a blower 200 , a heating unit 300 , and a fermentation stirrer generating unit 400 . ), a mixing unit 500 , and a discharging unit 600 may be included.

The body 100 may have an installation space formed therein. In addition, at least one pedestal may be provided at a lower portion of the main body 100 to be spaced apart from the ground by a predetermined distance.

The blower 200 may be installed inside the main body 100 and blow air in one direction by sucking air from the outside. Here, the blower 200 may be provided as a blower distributed in the market.

The heating unit 300 may be installed inside the main body 100 and receive air from the blower 200 to heat the air.

In addition, the heating unit 300 may include a heating body 310 , a heating coil 320 , and a heating sensor 330 .

One end of the heating body 310 is connected to the blower 200 side, and air blown from the blower 200 may be introduced therein.

The heating coil 320 may be installed inside the heating body 310 and radiate heat to heat the air transferred from the blower 200 to the inside of the heating body 310 .

The heating sensor 330 may be installed on the rear end side of the heating body 310 and measure the temperature of the air passing through the heating coil 320 . In addition, the operator may grasp the temperature of the air that has passed through the heating unit 300 through the heating sensor 330 .

Additionally, the heating body 310 may be provided with a heating power supply unit 300a for operating the heating coil 320 . The heating power supply unit 300a is provided with an on/off switch, and the on/off switch may operate the heating coil 320 or stop the operation of the heating coil 320 . In addition, the heating power supply unit 300a may be provided with a heating intensity adjusting unit, and the heating intensity adjusting unit may adjust the intensity of heat emitted from the heating coil 320 .

The immature microorganism stirring liquid generating unit 400 may be installed inside the main body 100 and receive heated air from the heating unit 300 to agitate water and the immature microorganism to generate the immature microorganism stirring solution.

In addition, the immature microorganism stirring liquid generating unit 400 may include a tank 410 , a first stirring unit 420 , and a second stirring unit 430 .

The tank 410 may have an internal space 410s, and an undiluted microorganism stock solution inlet 410a and a water inlet 410b may be formed on the outer surface, respectively. In addition, the tank 410 may have a fermented microbial undiluted solution into the internal space 410s through the fermented microbial undiluted solution inlet 410a, and water may be fed into the internal space 410s through the water inlet 410b. .

Additionally, a water level sensor WS for measuring the water level in the inner space 410s may be installed in the tank 410 . Then, the operator can check the water level through the water level sensor (WS) and inject the fermented microorganism stock solution and water into the inner space (410s).

One end of the first stirring unit 420 is connected to a pipe connected to the heating unit 300 and may be disposed in a lower portion of the inner space 410s of the tank 410 . In addition, the first stirring unit 420 may discharge the heated air to the fermented microbial stock solution and water to agitate the fermented microbial undiluted solution and water. To this end, the first stirring unit 420 may be formed with at least one air outlet, and may eject heated air through the outlet.

The second stirring unit 430 may have one end connected to a pipe connected to the heating unit 300 and be disposed at an upper portion of the inner space 410s of the tank 410 . And, the second stirring unit 430 may be discharged to the inner space (410s) while stirring the heated air, the fermented microorganism stock solution and water.

Referring to FIG. 5 , the unripe microorganism stock solution and water may be discharged from the upper part of the second stirring unit 430 toward the inner space 410s by the heated air. Accordingly, the fermented microbial stock solution and water may be stirred by the heated air.

The mixing unit 500 may receive heated air from the heating unit 300 , and may receive and mix the immature microorganism stirring liquid from the mature microorganism stirring liquid generating unit 400 . Accordingly, the mixing unit 500 may generate air in which the fermented microorganism stirring liquid is mixed.

In more detail, the mature microbial agitation liquid may be sprayed into the mixing unit 500 as fine particles, and the heated air is delivered to the sprayed fertilized microbial agitation liquid side, so that the heated air and the fertilized microbial agitation liquid may be mixed. .

The discharge unit 600 may be connected to the mixing unit 500 and disposed in the composting sand 20 . In addition, the discharge unit 600 may discharge the air mixed with the fermented microorganism stirring liquid from the mixing unit 500 to the composting sand 20 .

6 to 8 , the discharge unit 600 may be implemented through the first embodiment and the second embodiment.

6 and 7 , the discharge unit 600 according to the first embodiment may include a discharge pipe 610 and a protection pipe 620 .

At least one discharge pipe 610 may be provided, and one side may be connected to the transfer pipe ES connected to the mixing unit 500 , and a plurality of discharge holes 610h may be formed on the outer circumferential surface. Here, the discharge hole 610h may be formed to be spaced apart from each other by a predetermined interval by matching rows on the outer circumferential surface of the discharge pipe 610 in the axial direction, and may be formed in each of the four sides of the discharge pipe 610 .

The protective pipe 620 is spaced apart from the discharge pipe 610 by a predetermined distance, surrounds the discharge pipe 610, and a plurality of through-holes 620h may be formed on the outer circumferential surface. In other words, the discharge pipe 610 may be disposed inside the protective pipe 620 . And, the air mixed with the immature microorganism agitation liquid discharged through the discharge hole 610h of the discharge pipe 610 is filled in the protective pipe 620, and can be discharged to the composting sand 20 through the through hole 620h. . Also, the through hole 620h may be formed at a position corresponding to the discharge hole 610h. Additionally, the through-holes 620h may be formed in the same number as the discharge holes 610h. In addition, the protection pipe 620 may protect the discharge pipe 610 from composts flowing into the composting sand 20 .

Referring to FIG. 7 , the discharge part 600 may include a support part 640 to which the discharge pipe 610 is inserted and fixed therein, and is inserted and fixed inside the protective pipe 620 .

The support 640 may include a support pipe 641 and a support 642 .

Referring to FIG. 7A , the support pipe 641 is disposed at the center of the protection pipe 620 , and the discharge pipe 610 may be inserted therein.

Referring to FIG. 7B , the support 642 may be formed to protrude in all directions from the support tube 641 , and may be in close contact with the inner surface of the protective tube 620 . In addition, the supporter 642 may allow the support tube 641 to be disposed in the center of the protective tube 620 .

In addition, the support 642 may have a communication hole YT that penetrates to the inside of the support pipe 641 . Here, the communication hole YT may communicate the discharge hole 610h of the discharge pipe 610 and the through hole 620h of the protection pipe 620 . In more detail, the support part 640 may match the discharge hole 610h of the discharge pipe 610 with the through hole 620h of the protection pipe 620 .

In summary, the air mixed with the fermented microorganism stirring liquid discharged through the discharge hole 610h of the discharge pipe 610 passes through the communication hole YT and can be discharged to the composting sand 20 through the through hole 620h. Therefore, the air mixed with the immature microorganism stirring liquid discharged through the discharge hole 610h of the discharge pipe 610 is not filled in the inside of the protection pipe 620 and can be discharged to the composting sand 20 through the through hole 620h. , the pressure of the air mixed with the fermented microorganism agitation liquid is improved so that it can be smoothly discharged to the composting sand (20).

Referring to FIG. 8 , the discharge unit 600 according to the second embodiment may include a discharge pipe 610 , a back tubule 630 , a first washing pipe ST1 , and a second washing pipe ST2 .

Since the discharge pipe 610 has been described above, a detailed description thereof will be omitted.

The back tubule 630 may have one side connected to the transfer pipe ES and the other side connected to the other side of the discharge pipe 610 .

The first washing pipe ST1 may be connected to one side of the discharge pipe 610 .

The second washing pipe ST2 may be connected to one side of the back pipe 630 .

In addition, foreign substances inside the discharge pipe 610 may be discharged through the first washing pipe ST1 and the second washing pipe ST2 .

In addition, a first valve V1 may be provided between the transfer pipe ES and the discharge pipe 610 , and a second valve V2 may be provided between the first washing pipe ST1 and the discharge pipe 610 . In addition, a third valve V3 may be provided between the transfer pipe ES and the back tubule 630 , and a fourth valve V4 may be provided between the second washing pipe ST2 and the back tubule 630 . have.

And, when discharging the air mixed with the fermented microorganism stirring liquid to the composting sand 20 through the discharge unit 600, the operator closes the second valve V2 and the fourth valve V4, and the first valve V1 ) and/or the third valve V3 may be opened so that the air mixed with the fermented microorganism stirring liquid may be discharged through the discharge hole 610h of the discharge pipe 610 .

In addition, when washing the discharge pipe 610, the operator opens the first valve (V1), the second valve (V2), the fourth valve (V4), and closes the third valve (V3) to the discharge pipe (610) Foreign substances inside may be discharged to the outside through the first washing pipe ST1 or the second washing pipe ST2.

Therefore, when the discharge pipe 610 is clogged, the operator can wash the discharge pipe 610 through the back tubule 630 without having to remove the discharge pipe 610 and re-install it after washing, so that the discharge pipe 610 can be penetrated, The cleaning operation of the discharge pipe 610 can be easily performed.

In addition, the discharge unit 600 may be implemented in a form in which the second embodiment is merged with the first embodiment.

Additionally, the control unit 700 for controlling the blower 200 and the heating unit 300 may be installed in the main body 100 . The control unit 700 may adjust the blowing pressure of the blower 200 . In addition, the control unit 700 may control the heating temperature of the heating unit 300 , and may receive temperature information from the heating sensor 330 of the heating unit 300 and display it. In more detail, the control unit 700 may control the heating power supply unit 300a to operate the heating unit 300 .

In addition, a warning light BR and a speaker SP may be installed in the main body 100 .

When an abnormality occurs in the blower 200 or the heating unit 300, the control unit 700 may notify the operator of the abnormality through the warning light BR and the speaker SP.

As a result, the compost steamer 10 according to an embodiment of the present invention discharges the air mixed with the fermentation microbial stirring liquid through the discharge unit 600 to the composting sand 20, thereby injecting air into the compost to kill microorganisms. can prevent

The composting machine 10 according to an embodiment of the present invention raises the temperature of the air through the heating unit 300 and discharges it to the composting sand 20 through the discharge unit 600, thereby increasing the temperature of the compost in the winter season to increase the temperature of the microorganisms. It is possible to reduce the time required for compost ripening by making the decomposition of the compost smooth.

Although the present invention has been described through preferred embodiments as described above, the present invention is not limited thereto, and various modifications and variations are possible without departing from the concept and scope of the following claims. Those in the technical field to which it belongs will readily understand.

10: compost ripening period
100: body 200: blower
300: heating unit 310: heating body
320: heating coil 330: heating sensor
300a: heating power supply unit 400: ripening microorganism stirring liquid generating unit
410: tank 410a: fermented microorganism stock solution inlet port
410b: water inlet 410s: internal space
420: first stirring unit 430: second stirring unit
WS: water level sensor 500: mixing unit
600: discharge unit 610: discharge pipe
610h: discharge hole 620: protection pipe
620h: through hole 630: reverse tube
ST1: first washing pipe ST2: second washing pipe
V1: first valve V2: second valve
V3: third valve V4: fourth valve
640: support 641: support pipe
642: support YT: communication hole
700: control unit BR: warning light
SP : Speaker ES : Transport pipe
20: compost

Claims (5)

main body;
a blower installed in the body and blowing air;
a heating unit installed in the body and receiving air from the blower to heat the air;
a fermented microbial stirring liquid generating unit installed inside the main body and receiving heated air from the heating unit to agitate water and fertilized microorganisms to generate a fermented microbial stirring liquid;
a mixing unit that receives the heated air from the heating unit and receives and mixes the aged microorganism stirring liquid from the mature microorganism stirring liquid generating unit;
It is connected to the mixing unit and disposed in the composting unit and includes a discharge unit for discharging the air mixed with the fermented microorganism stirring liquid from the mixing unit to the composting unit,
The discharge unit,
at least one discharge pipe having one side connected to the conveying pipe connected to the mixing unit and having a plurality of discharge holes formed on an outer circumferential surface; and
and a protective pipe spaced apart from the discharge pipe at a predetermined distance, surrounding the discharge pipe, and having a plurality of through-holes formed on an outer circumferential surface thereof,
The through holes are formed in the same number as the discharge holes and are formed at positions corresponding to the discharge holes,
The discharge unit is inserted into the protective tube and fixed, and the discharge tube is inserted and fixed therein;
The support part is disposed in the center of the protective tube and includes a support tube into which the discharge tube is inserted, each protruding from the support tube in all directions, is in close contact with the inner surface of the protective tube, and the support tube is disposed in the center of the protective tube A compost composting machine including a support in which a communication hole for communicating the discharge hole and the through hole is formed. According to claim 1,
The heating unit,
a heating body having one end connected to the blower side;
a heating coil installed inside the heating body and dissipating heat to heat the air transferred from the blower;
Composting machine including a heating sensor installed on the rear end side of the heating body and measuring the temperature of the air that has passed through the heating coil. According to claim 1,
The immature microorganism agitation liquid generating unit,
a tank in which an internal space is formed, a fermented microbial undiluted solution is introduced into the internal space through a fermented microbial undiluted solution inlet, and water is introduced into the internal space through a water inlet;
a first stirring unit having one end connected to the tube connected to the heating unit and disposed in the lower portion of the inner space of the tank to discharge heated air to the mature microbial stock solution and water to agitate the mature microbial stock solution and water; and
Composting machine including a second stirring part connected to the pipe connected to the heating part and disposed at the upper part of the internal space of the tank to agitate the heated air, the fermented microorganism stock solution and water, and discharge to the internal space. delete According to claim 1,
The discharge unit,
a back tubule having one side connected to the transfer pipe and the other side connected to the other side of the discharge pipe;
a first washing pipe connected to one side of the discharge pipe; and
a second washing pipe connected to one side of the back pipe;
A first valve is provided between the transfer pipe and the discharge pipe,
A second valve is provided between the first washing pipe and the discharge pipe,
A third valve is provided between the transfer pipe and the back tubule,
A fourth valve is provided between the second washing pipe and the back pipe,
When the discharge part is washed, the composting machine opens the first valve, the second valve, and the fourth valve, and closes the third valve.

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