KR102209112B1 - Mushroom cultivation Apparatus - Google Patents

Abstract

The present invention relates to a mushroom cultivation apparatus capable of increasing a success rate of cultivating various kinds of mushrooms. Provided is a mushroom cultivation apparatus. According to the present invention, the mushroom cultivation apparatus comprises: a cultivation room having one or more medium trays; an air conditioner which is disposed outside the cultivation room and which supplies cooling air into the cultivation room; a first supply duct disposed on a first surface of the cultivation room to supply and distribute cooling air that has passed through the air conditioner; and an intake duct which is provided on one side surface of a lower portion of the cultivation room, and which has an intake hole to draw in air in the cultivation room and transfer the air to the air conditioner, wherein air supplied to the cultivation room through the first supply duct is evenly distributed to the medium trays.

Description

Mushroom cultivation apparatus {Mushroom cultivation Apparatus}

The present invention relates to a mushroom cultivation apparatus capable of increasing the success rate of various mushroom cultivation.

In general, in mushroom cultivation technology, temperature, humidity, CO2 concentration, pollution prevention, light irradiation, etc. are important management factors.

Among these mushrooms, especially the mushroom cultivation technology, mushroom cultivation farmers are experiencing considerable difficulties as they cannot efficiently manage these factors, and many failures have been made.

Korean Patent Application Publication No. 10-2016-0132613 (Publication date: November 21, 2016)

In the cultivation of champignon mushrooms, heat insulation is maintained by covering the outside of the plastic house with a heat insulation cover, but it is difficult to efficiently manage heat due to a large amount of heat loss.

In addition, the internal temperature of the mushroom cultivation company should be kept constant anywhere inside the cultivation company as the optimum temperature required by the mushroom cultivation company, but there is a problem in that proper management is impossible due to insufficient air conditioning facilities.

In addition, in order to control the internal humidity, the operator is supplying water through the watering can, but this is difficult to accurately manage the humidity due to humidity control by the operator's senses.

In addition, in the case of controlling the concentration of CO2, one of the important environmental factors of the mushrooms, a large amount occurs during the growth of the mushrooms, and when the concentration of CO2 reaches a certain level, the mushrooms stop growing and die when they reach a certain level. Has a problem.

Therefore, such CO2 concentration control was also made uneven in the prior art, and was difficult to manage.

In addition, air supplied to the cultivation company must be uniformly distributed, but it is difficult to achieve uniform air distribution, and a device for uniform air distribution has not been provided.

The present invention provides a mushroom cultivation apparatus capable of increasing cultivation productivity during mushroom cultivation by supplying heat-exchanged air in a state uniformly distributed to the cultivation room.

The solution means of the present invention includes a cultivation room equipped with one or more discharge trays; An air conditioner disposed outside the cultivation room to supply cooling air into the cultivation room; A first supply duct disposed on the first surface of the cultivation room to supply and distribute the cooling air passing through the air conditioner; And a suction duct provided on a lower side of the cultivation room and having an intake hole to suck air in the cultivation room and send it to the air conditioner,

A mushroom cultivation apparatus may be provided in which air supplied to the cultivation room through the first supply duct is evenly distributed toward the discharge tray and supplied.

As described above, the present invention allows air to be evenly distributed and supplied to the discharge tray for each mode, thereby enabling good mushroom cultivation during mushroom cultivation.

In the present invention, since the ceiling surface of the cultivation room is formed to be inclined in one direction, the air supplied from the air conditioner collides and descends vertically, so that it can be evenly distributed to the discharge tray.

Depending on the mode, some air is bypassed and supplied to the first supply duct, so that the amount of air directly supplied to the discharge tray can be adjusted.

When the concentration of carbon dioxide generated in the cultivation room exceeds the reference value, the carbon dioxide concentration can be detected so that the air supply fan and the exhaust fan are operated to introduce outside air and discharge the air in the cultivation room to the outside so that the carbon dioxide concentration does not exceed the reference value.

The air supply duct connected to the supply fan is arranged on one side of the ceiling of the cultivation room, and the exhaust duct connected to the exhaust fan is arranged at the lower one side of the cultivation room to supply outside air from the top, and the air in the cultivation room is sucked and discharged from the lower side Therefore, when the cooling air supplied from the ceiling surface moves to the bottom, it can more smoothly move through the discharge tray, so that air supply in the mushroom cultivation process can be provided more reliably.

1 is a schematic side view of the interior of the mushroom cultivation apparatus of the present invention.
2 is a cross-sectional view taken along line AA of FIG. 1.
3 is an enlarged side cross-sectional view of a suction duct installed in a cultivation room of the present invention.
4 is a plan view of FIG. 3.
5 is a plan sectional view of the supply pipe and the exhaust pipe installed in the cultivation room of the present invention.
6 is a block diagram for explaining a control state of the air conditioner of the present invention.

Hereinafter, specific details for carrying out the present invention will be described in detail based on the accompanying exemplary drawings.

1 is a schematic side view of the inside of the mushroom cultivation apparatus of the present invention, and FIG. 2 is a cross-sectional view taken along line A-A of FIG. 1.

1 and 2, the mushroom cultivation apparatus 10 of the present invention is a cultivation room 100 providing a space for cultivating mushrooms, and a cultivation to supply heat exchanged air in the cultivation room 100. It may include an air conditioner 200 provided outside the room 100.

In the cultivation room 100, a suction duct 110 in communication with the air conditioner 200, a first supply duct 120 for re-supplying and distributing heat exchanged while passing through the air conditioner 200, the It may include a second supply duct 130 for supplying part of the heat exchanged air while passing through the air conditioner 200.

In addition, an air supply fan 140 and an exhaust fan 150 may be provided in the cultivation room 100.

The air supply fan 140 and the exhaust fan 150 may be operated according to the amount of carbon dioxide (CO2) generated in the cultivation room 100.

The air conditioner 200 is a heat exchanger 220 provided inside the main body 210, a suction fan that sucks air from the air intake duct 110 and performs heat exchange through the heat exchanger 220 The heat-exchanged air that has passed through 230 and the suction fan 230 may be supplied into the cultivation room 100 again.

The air conditioner 200 may include a first transfer pipe 240 in communication with the first supply duct 120 and a second transfer pipe 250 in communication with the second supply unit 130.

A first damper actuator 241 and a second damper actuator 251 capable of adjusting the amount of supplied air may be installed inside the first transfer pipe 240 and the second transfer pipe 250, respectively.

When the air in the cultivation room 100 is sucked, the suction duct 110 may be uniformly sucked.

3 is an enlarged side cross-sectional view of a suction duct installed in a cultivation room of the present invention, and FIG. 4 is a plan view of FIG. 3.

"형으로 형성될 수 있다. 3 and 4, the intake duct 110 may be connected to be in communication with the air conditioner 200 and the connection pipe 212, and the intake duct 110 is "

"Can be formed into a mold.

In addition, the connection pipe 212 may be connected to one side of the suction duct 110, and preferably may be connected to be located at the center of the entire length of the suction duct 110.

A plurality of suction holes 112 may be formed on the first surface 111 of the suction duct 110 to suck air in the cultivation room 100 and send it to the air conditioner 200.

The first surface 111 of the suction duct 110 may be a bottom surface (lower surface), and the suction hole 112 is the suction hole 112 as it moves away from the center C of the connection pipe 212 The number of) can be increased.

Referring to FIG. 2, the first surface 101 of the cultivation room 100 may be formed to be inclined downward at a predetermined angle as it moves away from the first supply duct 120 through which air is introduced.

The first surface 101 may be a ceiling surface of the cultivation room 100.

In addition, referring to FIG. 1, the first supply duct 120 may be formed along the length of the second surface 102, which is one side of the cultivation room 100, and slopes upward toward the first surface 101. The inclined portion 121 is formed, and the end 122 of the inclined portion 121 is bent, and the bent end 122 is formed with an outlet 124 through which air introduced from the first surface 101 is discharged. They can be arranged at intervals as much as possible.

Accordingly, the outlet 124 may be formed along the length direction of the first supply duct 120 (the direction of one side of the cultivation room 100 ).

The second supply duct 130 is bent in a vertical direction at both sides of the first supply unit 131 and the first supply unit 131 formed in a straight line so that air is introduced through the second transfer pipe 250 to be filled first As a result, the air conveyed from the first supply unit 131 may be provided with a second supply unit 132 to be supplied into the cultivation room 100.

5 is a plan cross-sectional view of the supply pipe and the exhaust pipe installed in the cultivation room of the present invention. 5, the air supply fan 140 is connected to the air supply duct 142 that supplies air into the cultivation room 100 by inhaling external air, and the exhaust fan 150 is the air in the cultivation room 100. It may be connected to the exhaust duct 152 for discharging to the outside.

The air supply duct 142 may be provided on the first surface 101 side of the cultivation room 100, and the exhaust duct 152 may be provided on the bottom side of the cultivation room 100.

In addition, a plurality of air supply holes 142a and exhaust holes 152a may be formed in the air supply duct 142 and the exhaust duct 152 along a length direction, respectively.

The air supply hole 142a and the exhaust hole 152a may be formed such that the distance between the air supply fan 140 and the exhaust fan 150 becomes narrower as the distance from the air supply fan 140 and the exhaust fan 150 increases. Accordingly, as the distance from the air supply fan 140 and the exhaust fan 150 increases, the air supply holes 142a and the exhaust holes 152a may be arranged to increase.

Referring to FIG. 2, in the cultivation room 100, one or more medium trays 300 for cultivating mushrooms may be provided.

6 is a block diagram for explaining a control state of the air conditioner of the present invention.

Referring to FIG. 6, in the present invention, a control unit 400 for controlling the supply of air through the air conditioner 200 may be provided, and the control unit 400 may be provided in the air conditioner 200. The amount of air supplied can be adjusted by controlling the 1 damper actuator 241 and the second damper actuator 251.

The present invention is provided with a discharge tray 300 in the cultivation room 100, and in the process of cultivating mushrooms in the discharge tray 300, the mushroom cultivation by supplying and distributing appropriate air by the air conditioner 200 You can increase your success rate.

Among the mushrooms, for example, if the mushroom is a mushroom, the air conditioning conditions in the cultivation room 100 must be different according to the four modes.

[In case of whitening mode]

In the white side mode, it is maintained for 15 days, the appropriate room temperature is set to be 20±2℃ and the appropriate humidity is 90±5%, and the water supply can be supplied by running the water pump for 10 minutes at 3 hour intervals. Supply and exhaust operations may be performed by the air supply fan 140 and the exhaust fan 150 according to a state in which carbon dioxide generated in the cultivation room 100 is sensed by a carbon dioxide sensor installed in the cultivation room 100.

When the concentration of carbon dioxide in the cultivation room 100 is 700 to 1000 ppm, the air supply fan 140 and the exhaust fan 150 may be operated.

[In case of browning mode]

In the browning mode, it is maintained for 15 to 20 days, and the appropriate indoor temperature is set to be 20±2℃ and the humidity is 90±5%, and the water supply can be supplied by running the water pump for 10 minutes every 3 hours. . Supply and exhaust operations may be performed by the air supply fan 140 and the exhaust fan 150 according to a state in which carbon dioxide generated in the cultivation room 100 is sensed by a carbon dioxide sensor installed in the cultivation room 100.

When the concentration of carbon dioxide in the cultivation room 100 is 700 to 1000 ppm, the air supply fan 140 and the exhaust fan 150 may be operated.

[In case of stitch mode]

In the needle-stick mode, it is maintained for 1 day, and the appropriate room temperature is set to 13±2℃ and the appropriate humidity is 70±5%, and water supply can be eliminated. Supply and exhaust operations may be performed by the air supply fan 140 and the exhaust fan 150 according to a state in which carbon dioxide generated in the cultivation room 100 is sensed by a carbon dioxide sensor installed in the cultivation room 100.

When the concentration of carbon dioxide in the cultivation room 100 is 700 to 1000 ppm, the air supply fan 140 and the exhaust fan 150 may be operated.

[In the case of cultivation mode]

In the cultivation mode, it is maintained for 15 days, and the room temperature is set to 15±2℃ and the humidity is 70±5%, and water supply can be eliminated. Supply and exhaust operations may be performed by the air supply fan 140 and the exhaust fan 150 according to a state in which carbon dioxide generated in the cultivation room 100 is sensed by a carbon dioxide sensor installed in the cultivation room 100.

When the concentration of carbon dioxide in the cultivation room 100 is 700 to 1000 ppm, the air supply fan 140 and the exhaust fan 150 may be operated.

In the above four modes, the second damper actuator 251 is not opened in the whitening mode, the browning mode, and the stitching mode, and the first damper actuator 241 and the second damper actuator 251 are only in the cultivation mode. Each can be opened by 50%.

The present invention can ensure that appropriate air is supplied and distributed according to these four modes.

In other words, referring to FIGS. 1 and 2, when the suction fan 230 is first operated by the operation of the air conditioner 200, the cultivation room 100 through the intake hole 112 of the suction duct 110 The air inside may be sucked and moved upward while passing through the connection pipe 212 and passing through the heat exchanger 220 inside the main body 210 of the air conditioner 200.

Air cooled by heat exchange through the first transfer pipe 240 formed on the air conditioner 200 may be introduced into the cultivation room 100 again.

The inner ceiling surface of the cultivation room 100 is provided with a first supply duct 120 communicating with the first transfer pipe 240, so that the cooling air passing through the first transfer pipe 240 is provided with a first supply duct ( It may be supplied into the cultivation room 100 by passing through 120.

Since the first supply duct 120 has an inclined portion 121 and an end portion 122 bent from the inclined portion 121, cooling air passes through the inclined portion 121 and the end 122 It may be supplied while colliding with the first surface 101 which is the ceiling surface.

Since the first surface 101 has a structure inclined in one direction, the cooling air that has passed through the first supply duct 120 collides with the first surface 101 and is turned downward, so that the discharge tray ( 300).

Accordingly, the cooling air collides along the inclined first surface 101 and is turned toward the discharge tray 300, so that uniform air can be distributed to the discharge tray 300.

If the first surface 101 is not inclined and has a flat surface, the air passing through the first supply duct 120 collides with the first surface 101 at the discharged initial portion, but the direction is changed. It is not possible to continue to advance along the first surface 101 and then descend while changing direction along the opposite wall, so it may not be possible to distribute and provide uniform air to the discharge tray 300.

If uniform air cannot be communicated to the discharge tray 300, the condition of the champignon mushrooms provided in the discharge tray 300 becomes poor, and eventually mushroom cultivation may not succeed.

In addition, in the present invention, since the intake duct 110 is disposed on the lower surface of the cultivation room 100, air can be sucked in from the lower portion and air can be evenly distributed from the upper portion.

Therefore, since the air supplied from the upper part of the cultivation room 100 must pass through the discharge tray 300 and be sucked again through the suction duct 110 at the lower part, the even air supply and distribution state to the discharge tray 300 is maintained. This can be achieved, and accordingly, the growth state of the mushrooms can be improved.

In addition, depending on the mode, cooling air is not supplied only through the first supply duct 120, and some air is bypassed through the first supply duct 130 to adjust the amount of air supplied to the discharge tray 300.

That is, in the case of the stitching mode and the exhaust mode, the amount of air supplied and distributed should be smaller than that of the back surface mode and the browning mode, so that part of the supplied air is directly distributed to the discharge tray 300 through the second supply duct 130. It is not to be.

In this case, the control unit 400 may determine this and adjust the opening degree of the first damper actuator 241 and the second damper actuator 251 differently.

In other words, in the case of the whitening mode and the browning mode, the first damper actuator 241 is completely open and the second damper actuator 251 is closed so that the cooling air passes through the second damper actuator 251 and the second supply duct ( 130), and may be supplied only through the opened first damper actuator 241.

However, in the case of the stitching mode and the cultivation mode, the opening degree of the first damper actuator 241 and the second damper actuator 251 is opened by 50%, so that the cooling air is halved by the first damper actuator 241 and the second. It may be supplied through the first supply duct 120 and the second supply duct 130 respectively through the damper actuator 251.

The second supply duct 130 through which a part of the cooling air is supplied by bypassing is composed of a first supply unit 131 in a horizontal state and a second supply unit 132 in a vertical state, so that the bypassed cooling air is transferred for the second time. When flowing into the second supply duct 130 through the pipe 250, it may be discharged toward the lower side of the cultivation room 100 through the second supply unit 132 through the first supply unit 131.

Accordingly, since air is not directly supplied to the discharge tray 300, an appropriate amount of air may be provided to the discharge tray 300 in the needle-stick mode and the cultivation mode.

In addition, since carbon dioxide is generated during cultivation of champignon mushrooms and needs to be discharged, when the carbon dioxide sensor detects this, the air supply fan 140 and the exhaust fan 150 are operated to cultivate outdoor air through the supply fan 140 ( 100) can be supplied to the inside, and carbon dioxide can be discharged to the outside through the exhaust fan 150.

Since the supply fan 140 and the exhaust fan 150 are provided with an air supply duct 142 and an exhaust duct 152, respectively, air may be sucked in.

The air supply duct 142 is disposed on one side of the first surface 101 that is the ceiling surface of the cultivation room 100, the exhaust duct 152 is disposed on one side of the floor surface of the cultivation room 100, and the air supply duct ( Since a plurality of air supply holes 142a and exhaust holes 152a are formed in the 142 and exhaust ducts 152 along the longitudinal direction, the outside air introduced through the air supply holes 142a into the inside of the cultivation room 100 It is supplied, and the air in the cultivation room 100 may be sucked through the exhaust hole 152a and discharged to the outside through the exhaust fan 150.

The air supply hole 142a and the exhaust hole 152a formed along the longitudinal direction of the air supply duct 142 and the exhaust duct 152 have a narrower gap as the distance from the air supply fan 140 and the exhaust fan 150, respectively. Since it is arranged and formed, when the inhaled outdoor air is supplied or indoor air is sucked and exhausted, it may be possible to evenly supply air or intake for exhaust in the cultivation room 100.

In a position close to the air supply fan 140 and the exhaust fan 150, the air flow is fast, so that the supply hole 142a and the exhaust hole 152a formed in the supply duct 142 and the exhaust duct 152 are less formed. As the air flow becomes slower as the distance from the supply fan 140 and the exhaust fan 150 increases, the number of supply holes 142a and exhaust holes 152a is increased and compensated for even air supply and discharge. This can be done.

10: mushroom cultivation device
100: cultivation room 101: first side
102: second side 110: suction duct
112: suction hole 120: first supply duct
121: inclined portion 122: end
124: outlet 130: second supply duct
131: first supply unit 132: second supply unit
140: air supply fan 142: air supply duct
142a: supply hole 150: exhaust fan
152: exhaust duct 152a: exhaust hole
200: air conditioner 210: main body
212: connector 220: heat exchanger
230: suction fan 240: first transfer pipe
241: first damper actuator 250: second transfer pipe
251: second damper actuator
300: output tray 400: control unit
C: center

Claims (6)

A cultivation room equipped with one or more discharge trays;
An air conditioner disposed outside the cultivation room to supply cooling air into the cultivation room;
A first supply duct disposed on the first surface of the cultivation room to supply and distribute the cooling air passing through the air conditioner;
A suction duct provided on a lower side of the cultivation room and having an intake hole to suck air in the cultivation room and send it to the air conditioner;
Including,
The first surface of the cultivation room is formed to be inclined in one direction, and the air introduced through the first supply duct collides with the inclined first surface and descends downward to be evenly distributed to the discharge tray,
The suction duct is connected to the air conditioner in communication with a connection pipe, and the mushroom cultivation apparatus is formed with a narrow gap so that the number of suction holes for inhaling air increases as the distance from the connection pipe increases to both sides.
The method of claim 1,
The first supply duct comprises an inclined portion facing the first surface of the cultivation room and an end formed by being bent from the inclined portion, and the end portion and the first surface are formed with an outlet at intervals.
delete The method of claim 1,
A second supply duct is provided on the second surface of the cultivation room to allow a part of the air supplied through the air conditioner to be bypassed and supplied,
The second supply duct is composed of a first supply unit in a horizontal state to allow the incoming air to move to both sides, and a second supply unit formed vertically downward at both ends of the first supply unit,
A mushroom cultivation apparatus configured to move a portion of the air supplied to the first supply duct to the second supply duct so that the air is not directly distributed to the discharge tray and is moved to a lower portion of the discharge tray.
The method of claim 1,
An air supply fan for supplying outside air is provided on one side of the second surface of the cultivation room, and an exhaust fan for discharging the air in the cultivation room to the outside is provided at a position separated from the air supply fan and crossing the discharge tray. ,
The air supply fan and the exhaust fan each have an air supply duct and an exhaust duct each having a predetermined length,
Mushroom cultivation apparatus in which the air supply hole and the exhaust hole formed in the air supply duct and the exhaust duct have a narrower gap as the distance from the air supply fan and the exhaust fan increases.
The method of claim 4,
Each of the first and second transfer pipes connected to the first and second supply ducts is provided with a first damper actuator and a second damper actuator. Mushroom cultivation device in which the degree of opening is controlled according to.

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