KR102655085B1 - Plant cultivating apparatus - Google Patents

Abstract

The present invention relates to a plant cultivation device.
A plant cultivation device according to one aspect includes a main body portion having a cultivation space therein and an intake port and an exhaust port on one side; a cultivation bed disposed below the cultivation space; a light source unit disposed above the cultivation bed unit and irradiating light; and an air circulation unit that causes external air flowing into the intake port to flow toward the exhaust port, wherein the air circulation unit includes a cooling passage that causes a portion of the external air to flow to the light source unit to cool the light source unit. a ventilation passage that flows the remaining part of the outside air into the cultivation space to ventilate the cultivation space; and an opening/closing control unit installed in the ventilation passage and controlling whether the external air flows into the cultivation space.

Description

Plant cultivation device {PLANT CULTIVATING APPARATUS}

The present invention relates to a plant cultivation device.

A general plant cultivation device forms a storage room with an environment suitable for plant growth, and grows the plants stored in the storage room.

For example, related technology is disclosed in Korean Patent No. 10-1342141, “Light source separated LED plant cabinet for home vegetable cultivation.”

According to the prior art, a cooling passage through which air flows to cool the heat generated from the light source and a ventilation passage through which air flows for ventilation of the cultivation room must be separately formed, thereby complicating the structure of the plant cultivation device, and manufacturing There is a problem with the unit price increasing.

The purpose of the present invention is to provide a plant cultivation device that simplifies the outdoor air flow path for cooling the light source and the outdoor air flow path for ventilating the cultivation room, and can easily control whether outdoor air flows into the cultivation room.

The plant cultivation device according to the present invention forms an intake port through which outdoor air flows in from the outside, and an exhaust port through which outdoor air is discharged, and causes the outdoor air flowing into the intake port to flow toward the exhaust port, and cools the light source unit with a portion of the flowing outdoor air, By including an air circulation unit that ventilates the cultivation space with the remaining part of the flowing outdoor air, cooling and ventilation of the light source can be performed together with outdoor air flowing in from the outside.

In addition, the outdoor air flowing into the intake port is divided into a cold air flow path for cooling the light source and a ventilation flow path for ventilation of the cultivation space, and an open/close control unit is installed in the ventilation flow path so that it can be supplied to the ventilation flow path when ventilation of the cultivation space is not needed. The cooling efficiency of the light source can be increased by flowing outside air into the cold air passage.

According to the present invention, the outdoor air sucked through the intake port is branched into a cooling passage for cooling the light source and a ventilation passage for ventilation to form an air passage that can cool the light source and ventilate the cultivation space, thereby forming a plant cultivation device. There is an advantage in that the structure is simplified.

According to the present invention, the inflow of external air through the ventilation passage can be controlled through the opening/closing control unit, which has the advantage of simplifying the operation of the plant cultivation device.

1 is a perspective view of a plant cultivation device according to the present invention.
Figure 2 is a diagram showing an air circulation unit and a light source unit according to the present invention.
Figure 3 is a cross-sectional view showing a portion of the air circulation unit and the light source unit according to the present invention.
Figure 4 is a diagram showing a cooling passage according to the present invention.
Figure 5 is a perspective view showing an opening and closing control unit according to the present invention.
Figure 6 is a view showing the open/close control unit according to the present invention in an open state.
Figure 7 is a view showing a closed state of the opening/closing control unit according to the present invention.

Hereinafter, the plant cultivation device according to the present invention will be described based on the drawings.

1 is a perspective view of a plant cultivation device according to the present invention.

Referring to FIG. 1, the plant cultivation device 1 according to the present invention may include a main body 10. The main body 10 may include an inner frame 11 and an outer frame 12. The main body 10 may be formed by combining the inner frame 11 and the outer frame 12. A space may be formed between the inner frame 11 and the outer frame 12. Alternatively, the inner frame 11 and the outer frame 12 may be formed as one piece.

The internal frame 11 may form the inner surface of the main body 10, and the external frame 12 may form the outer surface of the main body 10. A cultivation room 21 and a battlefield room 15 may be placed inside the main body 10. The cultivation room 21 and the battlefield room 15 may be distinguished from each other. The cultivation room 21 can be understood as a space where plants grow. The electrical equipment room 15 may be equipped with devices for driving the plant cultivation device 1 .

The main body 10 may be configured to have one side open. A door (not shown) may be placed on one open side of the main body 10. The door may be rotatably provided on one side of the main body 10. The door can selectively shield one open side of the main body. When one side of the main body 10 is opened, the cultivation room 21 and the electrical equipment room 15 disposed inside the main body 10 are exposed to the outside, and when one side of the main body 10 is closed, The cultivation room 21 and the battlefield room 15 may be closed.

The interior of the main body 10 may include a cultivation bed 20, a light source 30, and an air circulation unit 40.

Plants may be sown in the cultivation bed portion 20. The cultivation bed units 20 may be arranged inside the main body unit 10 to be spaced apart from each other in the vertical direction. A plurality of cultivation rooms 21 may be distinguished from each other by the cultivation bed portion 20. Plants sown in the cultivation bed unit 20 can grow by absorbing the nutrient solution contained within the cultivation bed unit 20. The cultivation bed unit 20 may be configured to accommodate a nutrient solution therein. The cultivation bed unit 20 may include a bed unit 201 in which the nutrient solution is accommodated, and a bed cover 202 that covers the bed unit 201. In addition, a plurality of portholes 203 for sowing plants may be formed in the bed cover 202.

A bed moving unit 25 may be provided below the cultivation bed unit 20. The bed moving unit 25 may support the cultivation bed unit 20. Additionally, the bed moving unit 25 can slide and move the supported cultivation bed unit 20. One side of the bed moving part 25 may be fixed to the internal frame 11, and the other side of the bed moving part 25 may be fixed to the bed part 201 of the cultivation bed part 20. The bed unit 201 may be slidably moved in the front-back direction with respect to the internal frame 11 by the bed moving unit 25 .

The light source unit 30 may be disposed above the cultivation bed unit 20. The light source unit 30 may be arranged to be spaced upward from the cultivation bed unit 20. The light source unit 30 may generate light and supply it to the cultivation bed unit 20. Plants sown in the cultivation bed unit 20 can grow by the light supplied from the light source unit 30.

In addition, when the light source unit 30 generates light, high-temperature heat is generated in the light source unit 30, so an air circulation unit 40 may be included to dissipate the heat generated from the light source unit 30. . The air circulation unit 40 according to this embodiment may dissipate heat from the light source unit 30 and introduce external air into the cultivation chamber 21 to circulate the air in the cultivation chamber 21 .

The air circulation unit 40 has an intake port 41 through which air outside the main body 10 flows into the inside of the main body 10, and an exhaust port 42 through which the air introduced inside is discharged to the outside. ) may be included. In this embodiment, the exhaust port 42 may include a first exhaust port 421 and a second exhaust port 422. The first exhaust port 421 can be understood as a passage through which air that has cooled the light source unit 30 is discharged. The second exhaust port 422 can be understood as a passage for the air inside the cultivation chamber 21 to be discharged to the outside.

The air circulation unit 40 may be located above the light source unit 30. In addition, a cultivation bed unit 20 may be located above the air circulation unit 40. The main body 10 according to this embodiment may include two cultivation rooms 21 and one battlefield room 15. Among the two cultivation chambers 21, one cultivation chamber 21 may be placed upward, and the other cultivation chamber 21 may be disposed downward. The cultivation chamber 21 has the light source unit 30 and the intake port 41 disposed on the upper side, the cultivation bed portion 20 and the bed moving unit 25 disposed on the lower side, and a space to be formed in the space between them. You can. The battlefield room 15 may be placed below the cultivation room 21, which is located below one of the two cultivation rooms 21. The battlefield room 15 may have the cultivation bed unit 20 and the bed moving unit 25 disposed on the upper side, the internal frame 11 disposed on the lower side, and may be formed in the space between them.

Figure 2 is a diagram showing an air circulation unit and a light source unit according to the present invention, Figure 3 is a cross-sectional view showing a portion of the air circulation unit and a light source unit according to the present invention, and Figure 4 is a diagram showing a cooling passage according to the present invention. .

Referring to FIGS. 2 to 4, an air circulation unit 40 may be disposed on one side of the light source unit 30 according to the present invention. The air circulation unit 40 may generate a flow of air for cooling the light source unit 30 on one side of the light source unit 30 . In addition, the air that has cooled the light source unit 30 can be discharged to the outside through the air circulation unit 40. A fixing part 32 may be disposed on the other side of the light source unit 30. The fixing part 32 can be understood as a structure for fixing the other side of the light source part 30 to the inside of the main body part 10. In addition, the air circulation unit 40 may fix one side of the light source unit 30 to the inside of the main body unit 10.

The light source unit 30 may include a lighting frame 301 and a circuit board 302.

The lighting frame 301 may form the body of the light source unit 30. A portion of the lighting frame 301 may be depressed to form a depressed space, and the circuit board 302 may be placed in the depressed space. For example, a portion of the lower surface of the lighting frame 301 is recessed in a direction toward the upper surface, and the circuit board 302 is inserted from the bottom to the top of the lighting frame 301 to form the lighting frame 301. It can be placed in a caved-in space.

One side of the lighting frame 301 may be opened so that one side of the depressed space may be opened. Additionally, an air circulation unit 40, which will be described later, may be disposed on one side of the opening. When the air circulation unit 40 is disposed on one side of the opening, air flows into the inside of the lighting frame 301 through the air circulation unit 40, or the air inside the lighting frame 301 flows into the outside. can be discharged as

The circuit board 302 may be placed in a recessed space of the lighting frame 301. The circuit board 302 may be provided with components for generating light. In this embodiment, a plurality of light sources (not shown) are provided on one side of the circuit board 302, and one side of the circuit board 302 may be arranged in a direction toward the cultivation chamber 21. Light generated from the plurality of light sources may pass through a transparent member 31, which will be described later, and then be irradiated to plants placed in the cultivation chamber 21. The circuit board 302 may divide the interior of the lighting frame 301 into an upper space and a lower space. The air introduced into the air circulation unit 40 may circulate through the upper and lower spaces of the circuit board 302 and then be discharged through the air circulation unit 40 . The air circulating between the upper space and the lower space may be discharged after cooling the heat generated in the circuit board 302.

The light source unit 30 may further include a transparent member 31.

The transparent member 31 may be mounted on the lighting frame 301. In detail, the transparent member 31 may be placed on one side of the recessed space of the lighting frame 301. A transparent member mounting groove into which the transparent member 31 can be mounted may be formed in the lighting frame 301. The transparent member 31 may be inserted into the transparent member mounting groove and fixed to the lighting frame 301. The transparent member 31 can be understood as a “partition plate” that divides the space where the circuit board 302 is placed and the cultivation room 21. The space above the transparent member 31 may be defined as a space where the circuit board 302 is disposed. The space below the transparent member 31 may be defined as a space where the cultivation chamber 21 is located when the light source unit 30 is mounted on the main body unit 10. The upper space of the transparent member 31 is a cooling passage 414 through which air flowing in from the air circulation unit 40 flows, cools the heat generated from the light source, and then is discharged to the air circulation unit 40. It can be understood as

The light source unit 30 may further include a flow path guide 35.

The flow guide 35 may be provided inside the lighting frame 301. The flow guide 35 may guide the flow direction of air flowing into the air circulation unit 40. The flow guide 35 divides the air area sucked into the internal space through the air circulation unit 40 and the air area discharged to the external space through the air circulation unit 40 to define the interior of the lighting frame 301. The flow direction of circulating air can be guided. That is, the circuit board 302 can be efficiently cooled by the flow path guide 35. Additionally, the flow guide 35 may support the circuit board 302 disposed inside the lighting frame 301.

The air circulation unit 40 may be fixed to one side of the light source unit 30.

The air circulation unit 40 can be understood as a configuration for supplying external air to the inside of the light source unit 30. In detail, the air circulation unit 40 is disposed on one open side of the lighting frame 301 and can cool the circuit board 302 disposed inside the lighting frame 301. In addition, the air circulation unit 40 can supply external air to the cultivation chamber 21 of the main body 10. Air introduced into the light source unit 30 by the air circulation unit 40 may flow along the space formed between the lighting frame 301 and the transparent member 31. Whether or not external air is supplied to the cultivation room 21 can be controlled by the opening/closing control unit 45, which will be described later.

Hereinafter, the air circulation unit 40 will be described in detail.

The air circulation unit 40 may include a circulation body 401 that forms a body.

The circulation body 401 may be fixed to one side of the lighting frame 301. The circulation body 401 may be configured to be detachable from one side of the lighting frame 301. In this embodiment, the lighting frame 301 may be inserted into and fixed to the circulation body 401.

The air circulation unit 40 may include an intake port 41 and an exhaust port 42.

The intake port 41 and the exhaust port 42 may be formed in the circulation body 401. The intake port 41 and the exhaust port 42 may be arranged to be spaced apart from each other. The exhaust port 42 may include a first exhaust port 421 and a second exhaust port 422. The first exhaust port 421 may be disposed above the second exhaust port 422. The intake port 41 and the first exhaust port 421 may communicate with a cooling passage 414 formed inside the light source unit 30. That is, the air introduced through the intake port 41 cools the circuit board 302 when passing through the cooling passage 414, and the air whose temperature increases after cooling the circuit board 302 is transferred to the first It may be discharged to the external space through the exhaust port 421. Additionally, the second exhaust port 422 may be in communication with a ventilation passage 413, which will be described later.

A blowing fan 411 may be disposed in the intake port 41.

The blowing fan 411 can rotate by receiving power from a motor (not shown). When the blowing fan 411 rotates, air in the external space may flow in a direction toward the cooling passage 414. The air introduced into the cooling passage 414 may be discharged through the first exhaust port 421 after cooling the light source unit 30.

The circulation body 401 may further include a ventilation hole 412 and a ventilation passage 413.

The ventilation hole 412 and the ventilation passage 413 may be formed inside the circulation body 401. The ventilation passage 413 can be understood as a passage for supplying external air flowing in through the intake port 41 to the cultivation room 21. The ventilation hole 412 can be understood as an opening that communicates the ventilation passage 413 and the ventilation hole 412. The ventilation passage 413 may communicate with the intake port 41 and the second exhaust port 422. In this embodiment, the ventilation passage 413 may be disposed below the cooling passage 414. Additionally, a portion of the air flowing in through the intake port 41 may flow through the ventilation passage 413 . Additionally, the remainder of the air flowing in through the intake port 41 can flow through the cooling passage 414 .

An opening/closing control unit 45 may be provided in the ventilation passage 413.

The opening/closing control unit 45 may control the flow of air flowing through the ventilation passage 413. For example, when the opening/closing control unit 45 is opened, external air may flow into the cultivation room 21. Also, when the opening/closing control unit 45 is closed, the inflow of external air into the cultivation room 21 may be restricted.

Figure 5 is a perspective view showing the opening and closing control unit according to the present invention.

Referring to Figure 5, the opening/closing control unit 45 according to the present invention may be rotatably mounted on the circulation unit body 401. The opening/closing control unit 45 is disposed on the ventilation passage 413 and can control whether the ventilation passage 413 is opened or closed.

The opening/closing control unit 45 may include an upper surface portion 451 forming a top surface, a side surface portion 453 forming a side surface, and a bottom surface portion 452 forming a lower surface. The body of the opening/closing control unit 45 can be formed by combining the top portion 451, the side portion 453, and the bottom portion 452. For example, the opening/closing control unit 45 may be formed in a cylindrical shape. And the interior of the cylinder may be formed as hollow.

A partition 454 is provided inside the opening/closing control unit 45, so that the internal space of the opening/closing control unit 45 can be divided into a plurality of spaces. In this embodiment, the interior of the opening/closing control unit 45 may be divided into two spaces by the partition 454. The two spaces partitioned inside the opening/closing control unit 45 are a passage through which air introduced through the ventilation passage 413 flows into the cultivation room 21, and an interior of the cultivation room 21. It can be understood as a passage through which the air is discharged to external space.

A rotating part 455 may be formed in the opening/closing control unit 45 to rotate the opening/closing control unit 45. The rotating part 455 is connected to a motor (not shown) and can rotate by receiving power from the motor. The rotating portion 455 extends from the upper surface portion 451 toward the lower surface portion 452 and may be configured to insert the motor shaft of the motor.

The opening/closing control unit 45 may include a first opening (456a), a second opening (456b), a third opening (456c), and a fourth opening (456d). The first opening 456a and the second opening 456b may be formed in the side portion 453. The third opening 456c and the fourth opening 456d may be formed in the bottom portion 452. In addition, the first opening 456a and the third opening 456c are disposed on one side of the partition 454, and the second opening 456b and the fourth opening 456d are located on the partition 456. Unit 454 may be placed on the other side of the reference. That is, a first flow path 457 and a second flow path 458 formed by the plurality of openings may be formed on one side and the other side of the partition 454. In this embodiment, the first passage 457 is disposed on the right side of the partition 454, and is inside one side of the first opening 456a, the third opening 456c, and the opening/closing control unit 45. It can be defined by space. The second passage 458 is disposed on the left side of the partition 454 and is defined by the second opening 456b, the fourth opening 456d, and the inner space on the other side of the opening/closing control unit 45. It can be.

In this embodiment, the first flow path 457 may selectively communicate with the ventilation flow path 413 through which air flows in from the intake port 41 and the cultivation chamber 21. The second flow path 458 may selectively communicate with the ventilation flow path 413 through which air is discharged to the cultivation chamber 21 and the second exhaust port 422.

Figure 6 is a diagram showing the opening and closing control unit according to the present invention in an open state, and Figure 7 is a diagram showing the opening and closing control unit according to the present invention in a closed state.

Referring to FIGS. 6 and 7 , when the blowing fan 411 of the intake port 41 operates, external air may flow into the cooling passage 414 and the ventilation passage 413. The air flowing into the cooling passage 414 may be discharged through the first exhaust port 421 after cooling the light source unit 30.

The flow of air supplied to the ventilation passage 413 can be controlled by whether the opening/closing control unit 45 is opened or closed.

When the opening/closing control unit 45 is opened, the outside air flowing in through the intake port 41 passes through the ventilation flow path 413 in communication with the intake opening 41 and then is controlled by the opening/closing control unit 45. It can be imported for 1 euro (457). External air supplied through the first flow path 457 may flow into the interior of the cultivation chamber 21 to supply external air to the interior of the cultivation chamber 21 . When external air flows into the cultivation room 21, fresh air can be supplied to the inside of the cultivation room 21 to promote plant growth.

And, when external air flows into the cultivation chamber 21 through the first passage 457, the air existing inside the cultivation chamber 21 is discharged through the second exhaust port 458. It flows into the ventilation passage 413 in communication with 422 and can be discharged to the outside through the second exhaust port 422.

The opening/closing control unit 45 may be rotated and closed by the rotating unit 455. When the opening/closing control unit 45 is closed, external air flowing in through the intake port 41 passes through the ventilation passage 413 in communication with the intake opening 41 and flows in the direction of the first passage 457. , the inflow into the cultivation room 21 may be restricted by the side portion 453 of the opening/closing control unit 45. That is, when the opening/closing control unit 45 is rotated, the first opening (456a) and the second opening (456b) of the opening/closing control unit 45 rotate toward the cultivation chamber 21, and the side portion 453 ) can be rotated toward the ventilation passage 413. At this time, the cultivation chamber 21 and the ventilation passage 413 may be partitioned from each other by the side portion 453. When the ventilation passage 413 and the cultivation room 21 are partitioned, the inflow of air from an external space into the cultivation room 21 may be blocked. In addition, the partition 454 of the opening/closing control unit 45 is formed in a size corresponding to the ventilation passage 413, and forms a ventilation passage communicating with the intake port 41 when the opening/closing control unit 45 is closed. The ventilation passage 413 communicating with 413 and the second exhaust port 422 is partitioned by the partition 454, thereby preventing air from flowing.

According to the present invention, a part of the external air flowing in through the air circulation unit 40 can circulate inside the light source unit 30 to cool the heat generated in the light source unit 30. In addition, the remaining part of the external air flowing in through the air circulation unit 40 is supplied to the inside of the cultivation room 21 depending on whether the opening/closing control unit 45 is opened or closed, thereby providing fresh air to the cultivation room 21. Air can be introduced. In addition, when ventilation of the cultivation room 21 is completed, the opening/closing control unit 45 may be closed to limit the flow of external air supplied to the cultivation room 21. Additionally, when the opening/closing control unit 45 is closed, the flow rate of air flowing into the cooling passage 414 increases, thereby increasing the heat dissipation efficiency of the light source unit 30.

1: plant cultivation device 10: main body
20: Cultivation bed 21: Cultivation room
25: bed moving part 30: light source part
40: air circulation unit 41: intake port
42: exhaust port 45: opening/closing control unit

Claims (10)

A main body portion having a cultivation space formed therein and provided with an intake port and an exhaust port including a first exhaust port and a second exhaust port;
a cultivation bed disposed below the cultivation space;
a light source unit disposed above the cultivation bed unit and irradiating light; and
It includes an air circulation unit that causes external air flowing into the intake port to flow toward the first exhaust port and the second exhaust port,
In the air circulation unit,
a cooling passage that allows a portion of the external air introduced into the intake port to cool the light source unit and then be discharged through the first exhaust port;
a ventilation passage that allows the remaining part of the external air flowing into the intake port to flow into the cultivation space, and allows the air discharged from the cultivation space to be discharged to the second exhaust port; and
It includes an opening/closing control unit that controls whether the ventilation passage is opened or closed,
The intake port and the exhaust port are open in the same direction in the main body,
The opening/closing control unit is a plant cultivation device disposed between the intake port and the exhaust port. delete According to claim 1,
A plant cultivation device wherein the intake port is provided with a blowing fan for forcing the outside air to flow. According to claim 1,
In the air circulation unit,
A plant cultivation device including a ventilation port that allows external air flowing into the intake port to flow into the ventilation passage. According to claim 1,
The air circulation unit is mounted on one side of the light source unit and fixes one side of the light source unit inside the main body unit,
A plant cultivation device in which a fixing part for fixing the other side of the light source unit to the inside of the main body is provided on the other side of the light source unit. According to claim 1,
A plant cultivation device wherein the opening/closing control unit is rotatably provided in the ventilation passage. According to claim 6,
The opening/closing control unit,
an upper surface portion forming the upper surface;
A bottom portion forming the lower surface;
A side portion forming a side surface; and
A plant cultivation device comprising a partition part disposed inside the top part, the bottom part, and the side part, and dividing an internal space to form a first flow path and a second flow path. According to claim 7,
In the opening/closing control unit,
a first opening that communicates with the intake port and the first flow path and is open at one side of the partition;
a second opening that communicates with the cultivation space and the first flow path, and through which a bottom portion of one side of the partition is opened;
a third opening that communicates with the cultivation space and the second flow passage, and through which a bottom portion of the other side of the partition is opened; and
A plant cultivation device comprising a fourth opening that communicates with the second exhaust port and the second flow passage, and through which the other side surface of the partition is opened. According to claim 8,
When the opening/closing control unit rotates to close the ventilation passage, a side portion of the opening/closing control unit shields the ventilation passage, thereby restricting the inflow of external air passing through the ventilation passage. According to claim 1,
The light source unit further includes a flow guide that changes the flow direction of external air introduced in one direction through the intake port and flows in another direction toward the exhaust port.

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