KR102765115B1 - plants cultivation apparatus - Google Patents

Abstract

The plant cultivation device of the present invention can be cleaned by removing the bed from the cultivation room or by rotating the bed cover within the cultivation room so that the upper surface of the bed is open without removing the bed from the cultivation room, thereby enabling cleaning of the bed without separating the pad.

Description

{plants cultivation apparatus}

The present invention relates to a plant cultivation device that enables plants to be cultivated while automatically performing air circulation, light supply, and water supply.

In general, a plant cultivation device is a device for cultivating plants in seed state.

Recently, various types of plant cultivation devices have been provided to allow easy cultivation of plants indoors.

These indoor plant cultivation devices can be divided into hydroponic cultivation devices and soil-based cultivation devices.

Here, the soil-type cultivation device is a device that cultivates plants by planting plants (or seeds) in soil in a flowerpot and continuously supplying moisture to the flowerpot, as disclosed in Registered Patent No. 10-1400375 (prior art 1), Registered Utility Model No. 20-0467246 (prior art 2), and Registered Utility Model No. 20-0465385 (prior art 3).

These soil-type cultivation devices have the advantage of faster plant growth than hydroponic cultivation devices using nutrient solutions, and the various nutrients in the soil can further enhance plant development.

However, in the case of the above-mentioned prior art 1, since the medium and the water storage are installed apart from each other and the water in the water storage is supplied to the soil in the medium by the absorbent member, the cultivation space is bound to be small, and there is a high risk that the water stored in the water storage is easily deteriorated and contaminated due to the nutrient solution.

Furthermore, the above-described prior art 5 had a problem in that it was difficult to take out the water storage unit or take out the medium outside the case due to the connection structure of the absorbent member, and thus continuous maintenance (cleaning, etc.) of the water storage unit could not be performed, and there was a high risk of deterioration and contamination.

In addition, in the case of prior art 2 and prior art 3, since the water is supplied by periodically spraying it onto the soil (plug tray, cultivation container), there is a problem that the nutrient solution splashes around (inside the cultivation room or door) and contaminates the walls, etc., and there is a high risk that the water stored in the tank (nutrient solution container, receiving tank) can easily deteriorate and become contaminated due to the nutrient solution.

Moreover, in the case of the above-mentioned prior art 2, since the bottom-filled bed is not removed, maintenance such as cleaning is difficult, and thus serious contamination is bound to occur.

Of course, in the case of prior art 3, maintenance is possible as needed because the cultivation shelf is configured to be taken out, but since this cultivation shelf is designed to be taken out together with the receiving container, there was an inconvenience in that the receiving container had to be separated after taking it out and then washed.

In particular, the longer the extraction time of the above-mentioned container, the longer the exposure of the plants grown on the cultivation shelf to the external environment, which may have a negative effect on their growth, and there is a disadvantage in that their storage is inconvenient.

That is, in the above prior art 7, when the cultivation of plants is completed and the plants are harvested, the cultivation shelf and the receiving container are simultaneously removed and then the cultivation shelf can be cleaned, but it was difficult to clean it periodically or perform other maintenance.

Registered Patent No. 10-1400375 Registered Utility Model No. 20-0467246 Registered Utility Model No. 20-0465385

The present invention has been made to solve various problems of the above-mentioned conventional technology, and the purpose of the present invention is to provide a plant cultivation device of a new type that can prevent contamination or occurrence of bad odors in a cultivation room that may be caused by residual water by preventing the supply water from remaining in the bed.

In addition, another object of the present invention is to provide a plant cultivation device of a new type in which the bed cover on which the pads are placed can be easily separated from the bed to which the water supply is supplied, thereby enabling easy washing or maintenance of the bed without removing the pads.

In addition, another object of the present invention is to provide a plant cultivation device according to a new form in which, when supply water is supplied into a water supply groove of a bed, the supply water does not overflow around the bed but is accurately supplied to the water supply groove.

In order to achieve the above-described purpose, the plant cultivation device of the present invention comprises a bed having a water receiving portion, and a bed cover installed so as to block the upper surface of the bed while being placed on the upper surface of the bed, and operably installed so that the upper surface of the bed can be opened as needed, thereby enabling cleaning of the bed without separating the pad.

In addition, the plant cultivation device of the present invention is configured such that the bed cover rotates from the bed to open the upper surface of the bed, thereby allowing the user to open the upper surface of the bed for cleaning when necessary.

In addition, the plant cultivation device of the present invention proposes that the bed is installed so that it can be pulled out by sliding back and forth from the cultivation room within the cabinet, thereby allowing the bed to be taken out from the cultivation room together with the bed cover and pad.

In addition, the plant cultivation device of the present invention proposes that a water supply path is formed in the bed, thereby allowing the supply water supplied from the water receiving unit to be stored in the water supply groove.

In addition, the plant cultivation device of the present invention proposes that a water supply channel is formed on the upper surface of the bed, thereby enabling the water supply channel to be formed integrally with the bed.

In addition, the plant cultivation device of the present invention proposes that the water supply path is formed to slope downward from the water receiving portion to the surface height of the water supply groove, thereby enabling smooth supply of water to the water supply groove.

In addition, the plant cultivation device of the present invention proposes that embankments are formed on both sides of the water supply channel among the upper surfaces of the bed, thereby preventing the supply water flowing along the water supply channel from overflowing into the bed.

In addition, the plant cultivation device of the present invention is formed as a body with an open upper surface and a water receiving portion protruding outward from the rear wall surface of the bed, thereby enabling a stable supply of water.

In addition, the plant cultivation device of the present invention proposes that a first support groove is formed at a connection portion between a bed and a water receiving portion, thereby allowing the center of rotation of the bed cover to be provided on the outside of the bed, thereby allowing the upper surface of the bed to be completely opened.

In addition, the plant cultivation device of the present invention provides that the first mounting groove is formed by including a straight portion and a bottom portion, thereby preventing the first mounting projection that is mounted on the first mounting groove and rotated from moving out of its original position during the rotation.

In addition, the plant cultivation device of the present invention proposes that the bottom of the first loading groove is formed to be round, thereby enabling the first loading projection to be supported so that it can rotate smoothly from the first loading groove when the bed cover is rotated.

In addition, the plant cultivation device of the present invention proposes that the bottom of the first loading groove is formed as a semicircular groove, thereby supporting the first loading projection to rotate more smoothly from the first loading groove when the bed cover rotates.

In addition, the plant cultivation device of the present invention proposes that the straight section of the first mounting groove is formed higher than the height of the bottom section, thereby preventing the first mounting projection from being detached from the first mounting groove when the bed cover is rotated.

In addition, the plant cultivation device of the present invention proposes that the first lifting protrusion is formed in a round shape, thereby enabling the first lifting protrusion to rotate smoothly from the first lifting groove when the bed cover rotates.

In addition, the plant cultivation device of the present invention proposes that the end of the first lifting protrusion is formed in a round shape by being rolled up, thereby facilitating the creation of the first lifting protrusion.

In addition, the plant cultivation device of the present invention provides that a second support projection is formed to protrude downward on the front edge of the bed cover, thereby allowing the bed cover to remain stably placed on the bed.

In addition, the plant cultivation device of the present invention proposes that a second support groove is formed in a concave shape on the front periphery of the bed, thereby preventing the bed cover from moving back and forth across the bed.

The plant cultivation device of the present invention as described above has the following various effects.

First, the plant cultivation device of the present invention has a structure for supplying only the required amount of water, so that no water remains in the bed, thereby preventing contamination or unpleasant odors inside the cultivation room that may be caused by residual water.

In addition, since the plant cultivation device of the present invention is configured to be able to rotate the bed cover on which the pads are placed from the bed to which the supply water is supplied, the upper surface of the bed can be opened without taking the bed out of the cultivation room or separating the bed cover and the pads from the bed, thereby having the effect of making it easy to wash or maintain the bed.

In addition, the plant cultivation device of the present invention has a water supply channel formed on the surface of the bed, and embankments formed protruding on both sides thereof, so that when water is supplied into the water supply groove of the bed, the water does not overflow around the bed and is accurately supplied to the water supply groove.

Figure 1 is an exploded perspective view illustrating a plant cultivation device according to an embodiment of the present invention.
Figure 2 is an external perspective view showing the opening/closing door in a closed state to explain a plant cultivation device according to an embodiment of the present invention.
Figure 3 is an external perspective view showing the opening/closing door in an open state to explain a plant cultivation device according to an embodiment of the present invention.
Figure 4 is a cross-sectional view illustrating a pad of a plant cultivation device according to an embodiment of the present invention.
Figure 5 is a cross-sectional view illustrating a pad of a plant cultivation device according to an embodiment of the present invention.
Figure 6 is a cross-sectional view illustrating a plant cultivation device according to an embodiment of the present invention.
Figure 7 is a cutaway perspective view illustrating the internal structure of a plant cultivation device according to an embodiment of the present invention.
Figure 8 is a perspective view illustrating the internal structure of a machine room in a plant cultivation device according to an embodiment of the present invention.
Figure 9 is a plan view illustrating the internal structure of a machine room in a plant cultivation device according to an embodiment of the present invention.
Figures 10 and 11 are perspective views showing the state when viewed from different directions to explain the state in which water is supplied to the bed in the plant cultivation device according to an embodiment of the present invention.
Figure 12 is a plan view illustrating the structure of a bed in a plant cultivation device according to an embodiment of the present invention.
Figure 13 is a perspective cutaway view illustrating the structure of a bed in a plant cultivation device according to an embodiment of the present invention.
Figure 14 is a cross-sectional view illustrating the structure of a bed in a plant cultivation device according to an embodiment of the present invention.
Figure 15 is a perspective view illustrating the structure of a bed cover among plant cultivation devices according to an embodiment of the present invention.
Figure 16 is a perspective cutaway view illustrating the structure of a plant cultivation device according to an embodiment of the present invention in which a bed cover is secured to a bed.
Figure 17 is a plan view illustrating the structure of a bed cover among plant cultivation devices according to an embodiment of the present invention.
Figure 18 is a cross-sectional view illustrating the structure of a bed cover in a plant cultivation device according to an embodiment of the present invention.
Figure 19 is a cross-sectional side view illustrating the structure of a plant cultivation device according to an embodiment of the present invention in which a bed cover is placed on a bed.
Figure 20 is a cross-sectional side view illustrating the structure of a plant cultivation device according to an embodiment of the present invention in which the bed cover is rotated to open the bed.
Figure 21 is a cross-sectional view of a main part of a plant cultivation device according to an embodiment of the present invention to explain a state for detecting residual water by a residual water detection sensor.
Figure 22 is an enlarged view of the “A” section of Figure 7.
Figure 23 is a perspective view showing a state when viewed from a plane to explain the structure of a lighting module among plant cultivation devices according to an embodiment of the present invention.
Figure 24 is a cutaway perspective view illustrating the structure of a lighting module in a plant cultivation device according to an embodiment of the present invention.
Figure 25 is a perspective view showing a state viewed from the bottom to explain the structure of a lighting module among plant cultivation devices according to an embodiment of the present invention.
Figure 26 is a cross-sectional view showing the state to explain the structure of a lighting module among plant cultivation devices according to an embodiment of the present invention.
FIG. 27 is an enlarged view of the “B” portion of FIG. 7 to explain the circulation fan assembly among the plant cultivation devices according to an embodiment of the present invention.
Figure 28 is a cross-sectional view illustrating the internal structure of a watering module among plant cultivation devices according to an embodiment of the present invention.
Figure 29 is a perspective view illustrating the external structure of a watering module among plant cultivation devices according to an embodiment of the present invention.
Figure 30 is a side view illustrating a state in which the opening/closing cover of the water supply module in the plant cultivation device according to an embodiment of the present invention is open.
Figure 31 is a rear view illustrating a state in which a water pump is coupled to an installation frame of a water supply module among plant cultivation devices according to an embodiment of the present invention.
Figure 32 is a plan view illustrating the air flow into the machine room of a plant cultivation device according to an embodiment of the present invention.
Figure 33 is a plan view illustrating the air flow into the cultivation room of a plant cultivation device according to an embodiment of the present invention.
Figure 34 is a plan view illustrating the state of supplying water into a bed in a plant cultivation device according to an embodiment of the present invention.
Figures 35 and 36 are cross-sectional views illustrating the state of rotation of the bed cover for washing the bed in the plant cultivation device according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the plant cultivation device of the present invention will be described with reference to the attached FIGS. 1 to 36.

The attached drawing 1 is an exploded perspective view illustrating a plant cultivation device according to an embodiment of the present invention, drawing 2 is a perspective view illustrating a plant cultivation device according to an embodiment of the present invention, and drawing 3 is a perspective view illustrating a state in which an opening/closing door of the plant cultivation device according to an embodiment of the present invention is opened.

As illustrated in these drawings, the plant cultivation device according to an embodiment of the present invention is largely composed of a cabinet (100), a machine room frame (200), a bed (300), a bed cover (350) on which pads (10) are placed, a lighting module (401,042), a circulation fan assembly (500), a temperature control module (600), and a water supply module (700). In particular, the plant cultivation device of the present invention is configured such that the bed cover (350) rotates away from the bed (300) to open the upper surface of the bed (300), thereby allowing the user to clean the upper surface of the bed (300) without having to take the bed cover (350) and pads (10) out of the cultivation room when necessary.

Let's explain each component of this plant cultivation device.

First, the above pad (10) will be described with reference to the attached drawings 4 and 5.

The above pad (10) is made of a container that is open at the top.

The above pad (10) is filled with topsoil (11) containing nutrient solution (city is omitted).

The above nutrient solution is a substance containing nutrients that are supplied to help plants grow better. This nutrient solution can be provided in a water-soluble capsule form that gradually dissolves in water, so that it is dissolved little by little each time the supply water is supplied and is contained in the supply water.

In addition, seed paper (12) is provided on the upper surface of the topsoil (11). The seed paper (12) is a portion where seeds are planted so that they have a certain arrangement, and when water is supplied while the seed paper (12) is settled on the upper surface of the topsoil (11), the seed paper (12) melts and disappears, and the seeds remain in the topsoil (11).

Additionally, a brick (13) is provided on the upper surface of the seed paper (12).

These bricks (13) are configured to control moisture and humidity in the soil and prevent the growth of mold, and are made by pressing inorganic ores such as vermiculite or stalactite into a powder state.

And, the upper surface of the pad (10) is covered with a protective film (15) to protect its interior.

In particular, a packing member (14) is further provided between the upper surface of the brick (13) and the protective film (15) to protect the brick (13) from the external environment.

The type of plant to be grown can be printed and provided on the surface of the above protective sheet (15).

Meanwhile, a protrusion (16) protruding downward is formed on the bottom surface of the pad (10), and the protrusion (16) is formed as a body with a water passage (16a) formed on the bottom surface. Of course, the protrusion (16) may be formed as a pipe structure that is open upward and downward and has an empty interior.

In addition, a first absorption member (17) that absorbs the supply water supplied to the bed (300a, 300b) is provided within the protrusion (16), and a second absorption member (18) in the shape of a flat plate is provided between the first absorption member (17) and the topsoil. The second absorption member (18) has the function of evenly supplying the supply water absorbed by the first absorption member (17) to the entire area of the topsoil (11).

The following describes the cabinet (100) with reference to the attached drawings 1 to 3.

The above cabinet (100) is a part that forms the exterior of the plant cultivation device.

A cabinet (100) like this is formed as a body that is open to the front and includes an outer case (110) forming an outer wall surface and an inner case (120) forming an inner wall surface.

Here, the outer case (110) is formed as a body with the upper surface closed and the lower surface and front surface open.

In addition, the inner case (120) is installed within the outer case (110) and spaced apart from the outer case (110). At this time, a foam insulation material (omitted in the drawing) may be filled between the inner case (120) and the outer case (110).

In addition, a cultivation room (121, 122) is provided inside the inner case (120). The cultivation room (121, 122) is a space provided for cultivating plants.

These cultivation rooms (121, 122) are composed of an upper cultivation room (121) and a lower cultivation room (122), and these two cultivation rooms (121, 122) are configured to have independent cultivation spaces.

Additionally, an opening door (130) is provided on the front of the cabinet (100).

This opening/closing door (130) is configured to open and close the cultivation room (121, 122) of the cabinet (100).

That is, by providing the above-described opening/closing door (130), the plant cultivation device according to the embodiment of the present invention becomes a closed cultivation device. In particular, as the closed cultivation device, it is possible to cultivate plants while maintaining a constant temperature and providing sufficient light by the lighting module (401, 402) and circulation fan assembly (500) and temperature control module (600) described below.

Meanwhile, the above-mentioned opening/closing door (130) may be configured to block the front of the cabinet (100) with either a rotary opening/closing structure or a sliding opening/closing structure.

In an embodiment of the present invention, the above-mentioned opening/closing door (130) is formed as a rotary opening/closing structure as an example.

In addition, the above-mentioned opening/closing door (130) is presented as an example, comprising a door frame (131) of a square frame structure with an open inner side and a viewing window (132) blocking the open inner side of the door frame (131).

At this time, it is preferable that the viewing window (132) be formed of a material that allows internal visibility, and for example, may be formed of glass.

When the above viewing window (132) is formed of glass, a protective film (not shown) may be attached to the glass. At this time, the protective film is preferably made of a light blocking (partial blocking) film that minimizes the penetration of light from inside the cultivation room into the room.

Of course, instead of the protective film, the viewing window (132) itself can be configured to have a dark color to minimize indoor light penetration.

Additionally, the above-mentioned opening door (130) may be composed of only a viewing window (132) without a door frame (131).

The following describes the machine room frame (200) with reference to the attached drawings 1 and 6 to 9.

The above machine room frame (200) is a configuration provided to form the bottom portion of a plant cultivation device according to an embodiment of the present invention.

As shown in the attached drawing 1, the machine room frame (200) is extended and installed at the bottom of the outer case (110) and is configured to include a bottom plate (211) forming a bottom, side plates (212) forming both side walls, a back plate (213) forming a back surface, and an upper plate (214) forming an upper surface. That is, the machine room frame (200) is formed in a box-shaped structure with an open front. At this time, the upper plate (214) is provided as the floor of the cultivation room (121, 122) within the cabinet (100).

In addition, the machine room frame (200) described above is formed so that the open bottom surface of the outer case (110) is placed and combined.

The machine room frame (200) and the inner case (120) are arranged to be spaced apart from each other, and the side plate (212) and the back plate (213) of the machine room frame (200) are configured to be connected to both sides and the back of the outer case (110).

In addition, the internal space of the machine room frame (200) is provided as a machine room (201) (see attached Figure 6).

That is, the machine room (201) and the cultivation room (121, 122) are formed by dividing the space within the inner case (120) and the space within the machine room frame (200), thereby providing independent spaces.

Some components of the temperature control module (600) to be described later are installed inside the machine room (201).

Of course, although not shown, the inner case (120) and the machine room frame (200) may be formed as a single body, and in this case, a separate partition wall may be provided between the cultivation room (121, 122) and the machine room (201) to divide the two spaces, thereby allowing the cultivation room (121, 122) and the machine room (201) to have independent spaces.

In addition, an intake/exhaust grille (220) is provided on the open front of the machine room frame (200) in front of the machine room (201). That is, the intake/exhaust grille (220) serves to block the open front of the machine room (201) while guiding the flow of air sucked into the machine room (201) from inside the room or air discharged from inside the machine room (201) to inside the room.

In addition, the suction/discharge grille (220) described above is formed with a suction port (221) and a discharge port (222). At this time, the suction port (221) and the discharge port (222) are provided separately at positions that are distinguished from each other by a separation partition (230) described later, and in the embodiment of the present invention, it is presented as an example that they are distinguished as a suction port (221) on the left side and a discharge port (222) on the right side when viewed from the front. This is as illustrated in the attached FIGS. 2 and 3.

In addition, a partition wall (230) is further provided within the machine room frame (200) to divide the space within the machine room (201) into left and right sides. That is, the path through which air is sucked into the machine room (201) and the path through which air is discharged can be distinguished by the partition wall (230).

At this time, the path through which air is sucked into the machine room (201) is the space on the side where the intake port (221) of the intake/exhaust grill (220) is located, and the path through which air is discharged from the machine room (201) is the space on the side where the discharge port (222) of the intake/exhaust grill (220) is located.

In addition, the spaces on both sides within the machine room (201) separated by the separation bulkhead (230) are formed to be connected to each other at the rear end of the space. That is, the rear end of the separation bulkhead (230) is formed to be separated to an extent that it does not reach the rear end wall surface within the machine room (201), thereby allowing the spaces on both sides that are separated to be connected to each other.

Of course, although not shown, the spaces on both sides within the machine room (201) may be configured to be connected to each other by forming an opening (not shown) at the rear end of the separation bulkhead (230).

In addition, the separation partition (230) may be formed in a straight line, but may also be formed in an inclined or folded structure. In the embodiment of the present invention, the separation partition (230) is proposed to be formed in a folded structure. That is, by forming a part of the separation partition (230) in a folded form, a sufficiently large space can be secured in the installation area of the condenser (620) and compressor (610) described later compared to other areas.

In addition, a condensate receiver (240) is provided in the machine room (201) of the machine room frame (200). At this time, the condensate receiver (240) is located on the floor of the machine room (201) on the side where air is introduced through the intake port (221), and serves to receive condensate flowing down from the condenser (620) described later, and also serves to fix the condensate (620) within the machine room.

In addition, a heat dissipation hole (202) is formed through the back plate (213) of the machine room frame (200). This heat dissipation hole (202) is a hole formed to discharge (or inhale) air that has dissipated heat from the compressor (610) to be described later. In other words, the additional formation of the heat dissipation hole (202) enables the air to be discharged more smoothly.

Of course, a discharge hole (203) for discharging air that has dissipated heat from the compressor (610) may also be formed in the floor plate (211) of the machine room frame (200).

Meanwhile, the rear portion of the upper surface plate (214) forming the upper surface of the machine room frame (200) is formed to protrude upward from other portions, so that the rear portion inside the machine room (201) has a higher space than other portions. That is, the rear portion is formed higher than other portions in consideration of the protrusion height of the compressor (610) installed in the machine room (201).

In addition, a control unit (20) (see attached Fig. 6) for controlling the operation of each component of the plant cultivation device is provided in the front space between the upper surface of the upper surface plate (214) and the lower surface of the inner case (120) facing it. This control unit (20) is made of a circuit board having various control circuits.

The following describes the bed (300) with reference to the attached drawings 10 to 14.

The above bed (300) is a portion provided for the pad (10) to be settled.

These beds (300) are formed as a flat plate or a tray structure having a peripheral wall, and are configured so that the supply water can be stored on the upper surface thereof.

In particular, a first guide rail (101) is provided on both sides of the walls (both sides of the inner case) within the cultivation room (121, 122), and the bed (300) is configured to be pulled out from the cultivation room (121, 122) in a drawer-like manner while moving back and forth under the guidance of the first guide rail (101).

At this time, guide members (301) are provided on both sides of the wall of the bed (300), and the guide members (301) are configured to be supported by the first guide rail (101), so that the bed (300) can be taken out from the cultivation room (121, 122) in a drawer-like manner. Of course, the bed (300) can be taken out in a drawer-like manner in various structures not shown.

In addition, a water receiving portion (310) is provided at the rear of the bed (300). The water receiving portion (310) is a portion configured to receive water from outside the bed (300) and provide it into the bed (300).

This water receiving portion (310) is formed to protrude rearward from one side of the rear of the bed (300) and has a bottom surface formed to be concave downward, thereby guiding the supply water to flow to a portion communicating with a water supply path (330) to be described later.

In addition, a water supply groove (320) that is further sunken from the inner bottom of the bed (300) is formed in the central portion within the bed (300), and the supply water supplied to the water receiving portion (310) is configured to be supplied to the water supply groove (320) under the guidance of the water supply path (330).

Here, the water supply path (330) is a path that guides the flow of supply water from the bottom within the water receiving portion (310) to the surface within the water supply groove (320).

At this time, the water supply path (330) is formed along the surface of the bed (300), and in particular, bank parts (331) are formed protrudingly on both sides of the water supply path (330) among the surface of the bed (300) so that the supply water flowing along the water supply path (330) can flow accurately to the water supply groove (320) without overflowing to the surroundings by the two bank parts (331).

Of course, although not shown, the water supply path (330) may be formed as a recessed groove from the upper surface of the bed (300), and the water supply path (330) may be composed of a pipe or hose, etc., separate from the bed (300).

In particular, the above-mentioned water supply path (330) may be formed with a slope or round structure that gradually (or sequentially) lowers from the water receiving portion (310) to the water supply groove (320). That is, the above-mentioned slope or round structure enables rapid supply of water while preventing the water supplied to the water supply groove (320) from flowing back to the water receiving portion (310).

In addition, a dam part (340) protruding upward from the surface of the water supply groove (320) is formed in the central portion within the water supply groove (320). At this time, the dam part (340) is formed to form a long protruding portion in the left and right directions of the bed (300), and the water supply groove (320) is divided into a front water supply groove (321) and a rear water supply groove (322) based on the dam part (340).

That is, when a plurality of pads (10) are placed in rows on the front and rear sides of the bed (300), the pads (10) in the front row are arranged so that the absorption pipe (12) is located on the rear side and touches the front water supply groove (321), and the pads (10) in the rear row are arranged so that the absorption pipe (12) is located on the front side and touches the rear water supply groove (322).

In particular, since the dam section (340) is formed to protrude compared to the bottom of the water supply groove (320), no supply water remains, and it serves to guide the supply water to be accurately supplied only to the area where the absorption pipe (12) of each pad (10) is located.

In addition, a flow guide groove (302) is formed in a portion of the bottom surface of the water supply groove (320) that is connected to the water supply path (330).

That is, the supply water flowing along the above-mentioned water supply path (330) is guided by the above-mentioned flow guide groove (302) during the process of flowing into the water supply groove (320) so that it can flow from one side of the water supply groove (320) to the other side.

In addition, a sensing projection (323) is formed protruding on the bottom surface of the water supply groove (320). At this time, the upper surface of the sensing projection (323) is formed to be positioned higher than the bottom surface of the water supply groove (320) and lower than the bottom surface of the bed (300).

Additionally, a mounting groove (303, 304) is formed on the bed (300).

The above-mentioned mounting groove (303, 304) is a part provided for mounting the bed cover (350) to be described later.

The above-mentioned mounting groove (303, 304) includes a first mounting groove (303) formed to be inserted into the connection portion between the bed (300) and the water receiving portion (310).

The above first support groove (303) is a groove that supports the rotation of the bed cover (350). That is, the center of rotation of the bed cover (350) can be provided on the outside of the bed (300), so that the upper surface of the bed (300) can be completely opened.

The above first loading groove (303) is composed of a straight portion (303a) and a bottom portion (303b).

The above straight portion (303a) is a portion formed vertically in the up-down direction while forming the upper open portion of the first mounting groove (303). That is, due to the structure of the above straight portion (303a), the first mounting projection (353) that is mounted on the first mounting groove (303) and rotated can be prevented from moving out of its original position during rotation.

At this time, it is preferable that the straight portion (303a) of the first mounting groove (303) be formed higher than the height of the bottom portion (303b), thereby preventing the first mounting projection (353) from being detached from the first mounting groove (303) when the bed cover (350) rotates.

In addition, the bottom portion (303b) is formed as a portion forming the bottom within the first loading groove (303) and extends downward from the straight portion (303a).

In particular, the bottom part (303b) is formed to be round. That is, since the bottom part (303b) of the first mounting groove (303) is formed to be round, the first mounting projection (353) mounted thereon can rotate smoothly. In particular, the bottom part (303b) is formed as a semicircular groove, thereby supporting the first mounting projection (353) to rotate more smoothly from the first mounting groove (303) when the bed cover (350) rotates.

In addition, the above-mentioned mounting groove (303, 304) includes a second mounting groove (304) formed in a front peripheral portion of the upper surface of the bed (300).

The above second mounting groove (304) is a groove that prevents forward and backward movement of the bed cover (350) together with the above first mounting groove (303).

Meanwhile, the beds (300) may be provided in multiples, in which case each bed (300) is installed vertically spaced apart from each other within the cultivation room (121, 122). Of course, although not shown, each bed (300) may be installed horizontally spaced apart from each other.

The vertical distance between each bed (300) can be set differently depending on the size of the cultivation room (121, 122) or the type of plant to be cultivated. For example, by configuring the first guide rail (101) provided on both sides of the cultivation room (121, 122) to be height-adjustable, the vertical distance between each bed (300) can be adjusted as needed.

In addition, a handle (361) is provided on the front of the bed (300), and the user can use the handle (361) to pull out or insert the bed (300) in a drawer-like manner.

At this time, the front of the handle (361) is configured so as not to touch the inner surface of the opening/closing door (130), thereby allowing a gap to exist between the front of the handle (361) and the opening/closing door (130). That is, air can flow between the upper cultivation room (121) and the lower cultivation room (122) through the gap, and air flowing through the lower cultivation room (122) can be discharged to the outside through the gap.

Of course, moisture can be prevented from forming on the surface of the opening/closing door (130) by the flow of air through the above-mentioned gap.

The following describes the bed cover (350) with reference to the attached drawings 15 to 20.

The above bed cover (350) is a part that supports each pad (10) so that it is placed in the correct position.

A plurality of fixing grooves (351, 352) are formed on the upper surface of the bed cover (350) for fixing each pad (10).

The above-mentioned settling groove (351, 352) has approximately the same width as the pad (10) and is formed to a depth that allows the pad (10) to be partially inserted. It is preferable that the bed cover (350) be formed of a metal material, and it is more preferable that the bed cover (350) be formed of stainless steel to prevent corrosion. The bed (300) may be formed of ABS resin.

In addition, a through hole (351a, 352a) is formed in the fixing groove (351, 352) so that the absorption tube (12) of the pad (10) passes through it. That is, the user can fix the pad (10) in the correct position by checking the position of the through hole (351a, 352a) and the position of the absorption tube (12). At this time, the through hole (351a, 352a) may be formed as a simple hole, or as illustrated in the example, the inner portion of the through hole (351a, 352a) may be formed to be bent through a lancing process. This bending structure is a structure for preventing the absorption tube (12) from being scratched when the pad (10) is mounted and removed, while also guiding the absorption tube (12) to be accurately mounted in the correct position.

In particular, the above-described settling grooves (351, 352) are divided into a front-row settling groove (351) in which the pads (10) of the front row are settling, and a rear-row settling groove (352) in which the pads (10) of the rear row are settling. At this time, the through-hole (351a) of the front-row settling groove (351) and the through-hole (352a) of the rear-row settling groove (352) are arranged to be adjacent to each other. That is, when the bed cover (350) is placed on the bed (300), each through-hole (351a, 352a) is configured to be positioned in the front-side water supply groove (321) and the rear-side water supply groove (322) of the bed (300), respectively.

Additionally, the bed cover (350) includes a perimeter (355, 356).

The above-mentioned perimeters (355, 356) form the rear edge portion and the front edge portion of the bed cover (350), respectively, and are formed on the rear edge portion and the front edge portion of the portion where each of the above-mentioned fixing grooves (351, 352) is formed, respectively.

In addition, among the above circumferences (355, 356), a first loading projection (353) is formed to protrude downwardly on the rear circumference (355), and a second loading projection (354) is formed to protrude downwardly on the front circumference (356).

The above first mounting projection (353) is mounted on the first mounting groove (303) of the bed (300), and the above second mounting projection (354) is mounted on the second mounting groove (304) of the bed (300).

In particular, the first lifting projection (353) becomes the center of rotation of the bed cover (350). That is, the bed cover (350) rotates with the first lifting projection (353) as the center of rotation.

The above-mentioned first lifting projection (353) is formed with a rounded bottom end. This round structure allows the first lifting projection (353) to rotate smoothly in the first lifting groove (303).

At this time, the above round structure is formed by rolling the end of the first lifting projection (353) inward. Of course, the end surface of the first lifting projection (353) can be formed into a semicircle to form a round shape, but considering that the bed cover (350) is formed of a metal plate, it is advantageous in terms of manufacturing to roll it into a round shape.

The following describes the lighting module (401, 402) with reference to the attached drawings 21 to 26.

The above lighting modules (401, 402) are parts that irradiate light to each pad (10) placed on a bed (300) within a cultivation room (121, 122). That is, by providing the lighting modules (401, 402), it is possible to continuously provide light to plants despite the cultivation device being a closed type.

As an example, these lighting modules (401, 402) are configured to irradiate light using LEDs (421).

To this end, the lighting module (401, 402) is configured to include a lighting case (410) forming an exterior, a circuit board (420) on which an LED (421) is mounted, and a lighting cover (430) covering the lighting case (410).

Here, the lighting case (410) is the part where the circuit board (420) is installed.

In addition, a plurality of irradiation holes (411) are formed in the lighting case (410).

And, the circuit board (420) is fixedly installed on the upper surface of each of the lighting cases (410).

At this time, each LED (421) mounted on the circuit board (420) is arranged to irradiate light through each irradiation hole (411) of the lighting case (410).

In addition, the above lighting cover (430) is a part that is combined to block the bottom surface of the lighting case (410) and is exposed into the cultivation room (121, 122) and protects each circuit board (420) from moisture within the cultivation room (121, 122).

It is preferable that the surface of the above lighting cover (430) be coated or surface-treated to diffuse light. This allows the light source irradiated from each LED (421) to be evenly distributed to all areas within the cultivation room (121, 122) without being concentrated in one place.

In addition, the upper surface of the lighting case (410) is installed to be covered with a top cover (460).

Meanwhile, in case it is desired to provide the cultivation room (121, 122) within the inner case (120) by dividing it into two cultivation spaces, upper and lower, the lighting modules (401, 402) are provided by dividing them into a first lighting module (401) provided on the upper wall surface within the inner case (100) and a second lighting module (402) installed so as to cross between the upper cultivation room (121) and the lower cultivation room (122) and irradiating a light source into the lower cultivation room (122).

That is, since the second lighting module (402) serves as a partition wall that divides the two cultivation rooms (121, 122) vertically, a separate partition wall does not need to be provided, and thus the size of each cultivation room (121, 122) can be secured to the maximum extent possible.

At this time, the second lighting module (402) is configured so that the rear end is fixed to the shroud (520) of the circulation fan assembly (500) to be described later.

In addition, a residual water detection sensor (440) is provided on the upper surface of the second lighting module (402). The residual water detection sensor (440) detects residual water remaining in the water supply groove (320) of the bed (300) stored in the upper cultivation space.

In particular, the residual water detection sensor (440) is positioned on the inner side of the part where the sensing protrusion (323) is formed in the lower part of the bed (300) and is configured to determine the residual water in the water supply groove (320) by sensing whether residual water remains on the upper surface of the sensing protrusion (323).

At this time, the residual water detection sensor (440) is configured as a capacitive sensor so as to accurately detect residual water in the water supply groove (320).

Of course, the above residual water detection sensor (440) may be configured in other ways not shown. For example, it may be configured as a mechanical sensor such as a floating type, or an electronic sensor using two electrodes.

A temperature sensor (450) is further provided on the upper surface of the second lighting module (402). The temperature sensor (450) detects the temperature inside the cultivation room (121, 122) and enables the air temperature to be controlled by the temperature control module (600).

The following describes the circulation fan assembly (500) with reference to the attached drawings 1, 6 to 7, and 27.

The above circulation fan assembly (500) is configured to circulate air within the cultivation room (121, 122).

This circulation fan assembly (500) is provided in the rear space of the cultivation room (121, 122) among the spaces within the cabinet (100), and is configured to suck in air from the lower space within the cultivation room (121, 122) and then discharge the air to the upper space within the cultivation room (121, 122).

Meanwhile, the circulation fan assembly (500) may be provided one for each cultivation room (121, 122), or may be configured to control air circulation for all cultivation rooms (121, 122) with one circulation fan assembly (500).

In an embodiment of the present invention, as an example, one circulation fan assembly (500) is provided for each cultivation room (121, 122). That is, air circulation for each cultivation room (121, 122) can be controlled to be the same or different by each circulation fan assembly (500).

Of course, if the air circulation is controlled differently for each cultivation room (121, 122), it is also possible to simultaneously cultivate plants that require different types of cultivation environments in each cultivation room (121, 122).

The above circulation fan assembly (500) is composed of a circulation fan (510), a shroud (520), and a partition wall (530).

Here, the circulation fan (510) is a fan driven to blow air. The circulation fan (510) is composed of a centrifugal fan that sucks in air in an axial direction and blows it in a radial direction.

In addition, the shroud (520) is a part that guides the flow of air blown by the circulation fan (510) when the circulation fan (510) is installed.

An installation hole (521) for installing a circulation fan (510) is formed through the shroud (520), and an air guide (522) is formed on the front of the shroud (520) to guide air sucked from the rear space within the cabinet (100) through the circulation fan (510) to flow into the cultivation room (121, 122). At this time, the air guide (522) is formed to guide air blown in the radial direction of the circulation fan (510) to flow into the upper space within the cultivation room (121, 122).

In addition, the partition wall (530) is located in front of the shroud (520) and is installed to block the shroud (520) from the cultivation room (121, 122).

That is, the circulation fan (510) can be protected from inside the cultivation room (121, 122) by the partition wall (530).

At this time, the lower portion of the partition wall (530) is formed to be open to the inside of the cultivation room (121, 122), and thus, the air flowing inside the cultivation room (121, 122) flows to the rear space inside the cabinet (100) through the lower portion of the open partition wall (530), and then exchanges heat with the evaporator (630) located in the space, and is continuously supplied to the upper space inside the cultivation room (121, 122) by the blowing force of the circulation fan (510) and the flow guidance of the shroud (522), thereby repeating the circulation.

In particular, both sides of the partition wall (530) are configured to be fixed to the both sides of the inner case (120) or the back side, and the shroud (520) is configured to be installed on the partition wall (530).

The following describes the temperature control module (600) with reference to the attached drawings 7 to 9.

The above temperature control module (600) is configured to control the temperature of air circulating within the cultivation room (121, 122) of the inner case (120).

It is proposed that this temperature control module (600) comprises a refrigeration system including a compressor (610), a condenser (620), and an evaporator (630). That is, the temperature of the air circulating within the cultivation room (121, 122) can be controlled by the above-mentioned refrigeration system.

The above compressor (610) and condenser (620) are installed in the machine room (201) within the machine room frame (200).

Here, the condenser (620) is positioned in a space on the side where air flows in among the two spaces divided into two sides by the separation partition (230) within the machine room frame (200), and the compressor is positioned in a section where air passing through the condenser (620) passes. In particular, the compressor (610) is positioned in a space on the side where air flows out among the two spaces divided by the separation partition (230).

This structure allows air introduced into the machine room (201) of the machine room frame (200) to preferentially pass through the condenser (620). That is, considering that the compressor (610) is configured to generate a large amount of heat, if the air is configured to exchange heat with the condenser (620) after passing through the compressor (610), the heat exchange efficiency may be reduced. Accordingly, it is preferable to configure the air to pass through the condenser (620) before the compressor (610).

In addition, the condenser (620) is located in the front space within the machine room (201), and the compressor (610) is located in the rear space within the machine room (201).

This structure is intended to reduce the influence of high temperature heat of the compressor (610) on the condenser (620) by separating the positions of the compressor (610) and the condenser (620) as much as possible.

In addition, a heat dissipation fan (611) is provided on the air inlet side of the compressor (610), which is the rear side of the separation partition (230), so as to allow air to be sucked in and discharged into the machine room (201) and to dissipate heat from the compressor (610). This heat dissipation fan (611) performs the function of actually blocking the space on the air inlet side where the condenser (620) is located and the space where the compressor (610) is located at the rear side of the separation partition (230), thereby further reducing the high temperature heat of the compressor (610) from affecting the condenser (620).

In addition, the evaporator (630) is placed in the rear space of the circulation fan assembly (500) among each part in the inner case (120). That is, when the circulation operation of sucking air from the lower space in the cultivation room and then discharging the air to the upper space in the cultivation room (121, 122) is performed by the operation of the circulation fan assembly (500), the air can be heat exchanged while passing through the evaporator (630).

This evaporator (630) is configured as a plate-type evaporator so that it can be stably installed in the rear space within the inner case (120) while improving heat exchange performance in a narrow space.

Meanwhile, the temperature control module (600) may be further equipped with an electric heater. That is, the electric heater can be used when growing plants that live in an environment with a higher temperature than a normal indoor environment.

The following describes the water supply module (700) with reference to the attached drawings 28 to 31.

The above water supply module (700) is configured to supply water to the bed (300).

In an embodiment of the present invention, it is proposed that the above-mentioned water supply module (700) stores the supply water in advance and, when water supply is required, pumps only the required amount to the bed (300) to supply water.

That is, rather than supplying the required amount of supply water, the conventional method is to store sufficient supply water in a water storage tank and supply the stored supply water to the soil using an absorbent material. In this case, since the supply water is mixed with a nutrient solution, there is a problem with contamination of the supply water.

However, in the embodiment of the present invention, nutrients are included in the medium (11) of the pad (10), and the supply water is supplied only in the required amount while no residual water exists in areas other than the water tank (710), thereby fundamentally preventing the occurrence of odor due to contamination of the supply water.

This water supply module (700) is composed of a water tank (710), a water pump (720), and a supply hose (730).

Here, the water tank (710) is a location where the supply water is stored.

This water tank (710) is formed as a square box-shaped structure open to the top and is positioned between the bottom surface of the inner case (120) and the bed (300). That is, considering that a gap is formed between the bottom surface of the inner case (120) and the bed (300) in which a part of the upper plate (214) of the machine room frame (200) protrudes upward due to the height of the compressor (610) in the machine room (201), by positioning the water tank (710) in this gap, sufficient space for the cultivation space in the cultivation room (121, 122) can be secured.

In particular, the water tank (710) is installed in the front space within the cabinet (100) so as to be retractable to the front of the cabinet (100). That is, considering that the rear side of the machine room (201) is formed higher due to the height of the compressor (610), the water tank (710) is installed in the front space among the bottom side spaces within the inner case (120) provided due to the upward protruding portion of the machine room (201). At this time, a second guide rail (102) (see attached FIG. 1) for guiding the forward and backward movement of the water tank (710) is provided on both sides of the walls within the cabinet (100).

In addition, the water tank (710) is configured to be exposed to the interior by opening the opening door (130). That is, the opening door (130) is formed to block not only the cultivation room (121, 122) but also the water tank (710), so that the water tank (710) can be exposed when the opening door (130) is opened. As a result, the user can easily take out the water tank (710) and replenish the supply water.

At this time, a handle (711) is provided on the front of the water tank (710), and the user can use the handle (711) to take out or insert the water tank (710) in a drawer-like manner.

In particular, the handle (711) of the water tank (710) is configured so as not to touch the opening/closing door (130) like the handle (361) of the bed (300), thereby ensuring that a gap exists between the front of the handle (711) and the opening/closing door (130).

Next, the water pump (720) is a pump that pumps the supply water in the water tank (710).

This water pump (720) is located in the rear space of the lower space within the inner case (120) where the water tank (710) is installed.

In particular, an installation frame (740) is provided between the water tank (710) and the water pump (720), and the water pump (720) is fixedly installed on the back surface of the installation frame (740). That is, the water pump (720) is prevented from being exposed to the outside when the water tank (710) is taken out by the installation frame (740), and the water pump (720) can always be fixed in the correct position.

In addition, a detection unit (741) that detects whether the water tank (710) is taken out is provided on the front of the installation frame (740). At this time, the detection unit (741) is configured as a proximity sensor and determines that the water tank (710) is installed when the water tank (710) is adjacent. Of course, the detection unit (741) may be configured as a contact switch and various detection devices may be applied.

In addition, a residual water detection sensor (742) is installed on the upper surface of the installation frame (740) to detect residual water remaining in the water supply groove (320) of the drum (300) located on the upper side thereof.

In particular, the residual water detection sensor (742) is positioned on the inner side of the part where the sensing protrusion (323) is formed in the lower part of the bed (300) and is configured to determine the residual water in the water supply groove (320) by sensing whether residual water remains on the upper surface of the sensing protrusion (323).

At this time, the residual water detection sensor (742) is configured as a capacitive sensor so as to accurately detect residual water in the water supply groove (320).

Of course, the above residual water detection sensor (742) may be configured in other ways not shown. For example, it may be configured in various structures such as a mechanical sensor such as a floating type, or an electronic sensor using two electrodes.

In addition, a residual water detection sensor (743) may be additionally installed on the front of the installation frame (740). The residual water detection sensor (743) installed on the front of the installation frame (740) serves to check whether there is supply water in the water tank (710).

Next, the supply hose (730) is a connecting hose that supplies the supply water pumped by the water pump (720) to each bed (300).

This supply hose (730) is installed so that one end is connected to the water pump (720) and the other end is positioned directly above the water receiving portion (310) of each bed (300) (see attached FIG. 10 and FIG. 11).

Meanwhile, the open upper surface of the water tank (710) forming the water supply module (700) is configured to be opened and closed by an opening/closing cover (750).

In addition, the opening/closing cover (750) is provided with a water supply connection pipe (760) connected to a water pump (720) to transfer the supply water stored in the water tank (710) to the water pump (720). That is, the water pump (720) is not directly connected to the water tank (710), but is selectively connected by the water supply connection pipe (760), thereby allowing only the water tank (710) to be taken out of the cabinet (100).

At this time, the water supply connection pipe (760) is configured to include a water supply pipe (761) that protrudes from the rear bottom surface of the opening/closing cover (750) into the water tank (710), and a connection pipe (762) that is formed to extend to the upper rear surface of the water supply pipe (761) and is connected to a water pump (720). That is, when the water tank (710) is stored, the connection pipe (762) is connected to the water pump (720), and the supply water inside the water tank (710) can be pumped to the supply hose (730) by the pumping operation of the water pump (720), and when the water tank (710) is taken out, the connection pipe (762) can be separated from the water pump (720).

In particular, it is preferable that the water supply pipe (761) be formed to protrude all the way to the bottom of the water tank (710) so as to delay the supply water replenishment cycle within the water tank (710) as much as possible.

Meanwhile, the unexplained symbol 745 of Fig. 31 is a water level detection sensor that detects the water level of the supply water in the water tank (710).

A plant cultivation device according to an embodiment of the present invention is further provided with a display module (800).

The above display module (800) is configured to display each status of the plant cultivation device and perform various controls.

At this time, each status displayed through the display module (800) may be an indication of temperature, cultivation time, operation status, etc. within the cultivation room (121, 122).

In addition, the above-mentioned display module (800) may be configured to enable touch operation, or may be configured to enable button or switch operation.

In particular, the display module (800) may be provided in a cabinet (100) or may be provided in an opening/closing door (130).

However, if the above display module (800) is installed in the opening/closing door (130), the connection structure of various signal lines and power lines cannot help but be complicated.

Considering this, it is more preferable that the display module (800) be provided in the cabinet (100).

Furthermore, considering that the viewing window (132) forming the inner portion of the above-mentioned opening/closing door (130) is made of glass that allows for internal visibility, it is most preferable that the display module (800) be installed in front of the second lighting module (402) among each of the lighting modules (401, 402).

Below, the operation of the plant cultivation device according to the embodiment of the present invention described above will be described in more detail for each process.

First, the process of providing pads (10) is explained.

When a new pad (10) is to be provided, the opening door (130) is opened to open the cultivation room (121, 122) inside the inner case (120) and the bed (300) located in the cultivation room (121, 122) is taken out.

At this time, the bed (300) is taken out from the cultivation room (121, 122) within the inner case (120) while sliding along the first guide rail (101). Of course, the bed (300) may not be taken out completely, but may be taken out only to the extent that the settling of the pad (10) can be easily performed without inconvenience.

After removing the protective film (illustrated) of the prepared pad (10) in this state, the pad (10) is placed on each of the fixing grooves (351, 352) of the bed cover (350).

At this time, the pad (10) is installed so that the absorption tube (12) formed on its lower surface is aligned with the through hole (351a, 352a) formed in the mounting groove (351, 352), and thus the pad (10) is mounted with a portion of it stored within the mounting groove (351, 352).

If there is a pod (10) in which plant cultivation is completed in the fixing groove (351, 352) of the bed cover (350), the pod (10) is taken out from the bed cover (350) and a new pod (10) is fixed in the fixing groove (351, 352) of the bed cover (350).

And, when the settling of the pad (10) is completed, the bed (300) is pushed and stored into the cultivation room (121, 122).

The above-described work is performed sequentially or selectively on either one or both of the bed (300) of the upper cultivation room (121) and the bed (300) of the lower cultivation room (122).

The following explains the cultivation process.

As described above, when pads (10) are provided in each bed (300) in the cultivation room (121, 122), a temperature suitable for germination of seeds planted in the pads (10) or cultivation of germinated seeds must be maintained, light must be provided, and water must be supplied.

This control can be carried out as a program set by default in the control unit (20), or can be individually specified by the user.

In an embodiment of the present invention, the above control is automatically performed according to a basically set program. Of course, the above program may vary depending on the type or cultivation method of each plant.

And, the above-mentioned control is performed by operation of the display module (800).

That is, when the display module (800) is operated to perform cultivation operation while the bed (300) with the pad (10) installed in the cultivation room (121, 122) is provided, the control unit (20) automatically cultivates the corresponding plant while controlling the temperature control module (600), the circulation fan assembly (500), the lighting module (401, 402), and the water supply module (700).

Here, when the operation of the temperature control module (600) is controlled, the refrigeration system including the compressor (610), the condenser (620), and the evaporator (630) and the heat dissipation fan (611) operate to perform refrigeration operation.

In particular, when such refrigeration operation is performed, indoor air is sucked into the machine room through the intake port (221) of the intake/exhaust grill (220) installed on the open front of the machine room (201), and air passing through the machine room is discharged through the exhaust port (222) of the intake/exhaust grill (220). At this time, indoor air sucked into the intake port (221) sequentially passes through the condenser (620), the heat dissipation fan (611), and the compressor (610) to exchange heat and dissipate heat, and then is discharged into the room through the exhaust port (222). This is as illustrated in the attached Fig. 32.

In addition, during the above-described freezing operation, the circulation fan (510) forming the circulation fan assembly (500) is operated.

Accordingly, the air existing in the rear space within the inner case (120) passes through the circulation fan (510) and is supplied into the cultivation room (121, 122), and after flowing within the cultivation room (121, 122), flows into the rear space within the inner case (120) through the lower open portion of the partition wall (530) located at the rear of the cultivation room (121, 122), and continues to exchange heat with the evaporator (630) located in the space, and then is supplied into the cultivation room (121, 122) by the air blown by the circulation fan (510), thereby controlling the temperature within the cultivation room (121, 122). This is as illustrated in the attached Fig. 33.

In particular, while the air circulation within the cultivation room (121, 122) is repeated by the operation of the circulation fan (510), the air flows along the rear space of the cultivation room (121, 122) and passes through the evaporator (630) located within the space, undergoes heat exchange, and is then supplied to the upper space within each cultivation room (121, 122) through each circulation fan assembly (500).

Accordingly, the air introduced into the cultivation room (121, 122) flows inside the cultivation room (121, 122) and maintains a constant temperature, thereby allowing the cultivated plants to be grown under optimal temperature conditions.

Meanwhile, some of the air circulating in the upper cultivation room (121) flows into the lower cultivation room (122) while passing through the gap between the front of the upper bed (300) and the opening/closing door (130), and some of the air circulating in the lower cultivation room (121) passes through the gap between the front of the lower bed (300) and the opening/closing door (130). Accordingly, moisture is prevented from forming on the surface of the opening/closing door (130) by the flow of air passing through each of the above-mentioned gaps.

Additionally, when the cultivation operation is performed, the operation of the lighting module (401, 402) is also controlled.

By controlling the operation of these lighting modules (401, 402), the LED (421) is periodically turned on (or continuously turned on) to provide a light source to the plants in the cultivation room (121, 122).

Of course, even if the LED (421) is illuminated by the control of the above lighting module (401, 402), the light inside the cultivation room (121, 122) is transmitted into the room by the protective film (or dark colored viewing window) (illustrated) of the viewing window (132) forming the opening/closing door (130), minimizing glare and minimizing discomfort to indoor users.

In addition, when the above cultivation operation is performed, the operation control of the water supply module (700) is also performed periodically (or, when necessary).

That is, when the cultivation plants are determined and the watering cycle is determined, the operation of the water pump (720) is controlled for each watering cycle. At this time, when the operation of the water pump (720) is controlled, if it is confirmed that the water tank (710) does not exist through detection by the detection unit (741), the water pump (720) is controlled not to operate.

On the other hand, if the detection unit (741) confirms the existence of a water tank (710), the water pump (720) operates to supply the supply water stored in the water tank (710) to each bed (300).

At this time, the supply water is pumped to the water pump (720) through the water supply connection pipe (760) and supplied to the water receiving part (310) of each bed (300) through the supply hose (730).

And, the supply water supplied to the water receiving part (310) is provided to the water supply groove (320) in the bed (300) under the guidance of the water supply path (330) connected to the water receiving part (310). At this time, the water supply path (330) is formed sunken from the surface of the bed (300), and embankments (331) are formed protruding on both sides of the water supply path (300), so that the supply water can flow smoothly into the water supply groove (320) along the water supply path (330).

In particular, a flow guide groove (302) is formed in the connecting portion between the water supply path (330) and the water supply groove (320), and considering that the water supply groove (320) has a track-shaped structure, the supply water guided to the water supply path (330) and flowing to one portion of the water supply groove (320) is guided by the flow guide groove (302) and flows from one portion of the water supply groove (320) toward the other portion, thereby sequentially filling the front-side water supply groove (321) and the rear-side water supply groove (322). This is as illustrated in the attached FIG. 34.

In addition, the supply water filled in the water supply groove (320) is absorbed into the medium (11) of each pad (10) through the absorption pipe (12) installed to reach the supply water in the water supply groove (320) and supplied to the plants.

Meanwhile, while the aforementioned water supply is in progress, the water supply level in the water supply groove (320) is detected by the residual water detection sensor (440, 742).

That is, the residual water detection sensor (440, 742) checks whether there is supply water on the surface of the sensing protrusion (323) of the water supply home (320), and if it is confirmed that there is supply water, the operation of the water pump (720) is stopped so that the supply water is no longer supplied.

The water supply method using the residual water detection sensor (440, 742) is intended to prevent residual water from remaining in the bed (300). In other words, by supplying only the required amount of water, the occurrence of residual water due to excessive water supply and the occurrence of contamination of the residual water thus generated can be prevented.

In particular, considering that plants require increasingly more water as they grow, the method according to the embodiment of the present invention can supply more water as the plant absorbs more water, so that even if the amount of water required by the plant changes during the process of growing, an appropriate amount of water can always be supplied.

The following describes the cleaning process of the bed (300).

It is desirable to wash (or clean) the water supply groove (320) of the bed (300) periodically.

That is, the plant cultivation device according to the embodiment of the present invention cultivates plants in a manner that does not leave residual water in the water supply groove (320) by supplying water to the pad (10) in a required amount, but it is desirable to periodically wash the bed (300) in case some of the medium existing in the pad (10) falls and remains in the water supply groove (320), or some of the water supplied into the water supply groove (320) remains due to an unexpected cause (e.g., a water supply error, etc.), or for other reasons.

To wash the bed (300), the bed (300) is moved by sliding and taken out from the cultivation room (121, 122), and then washed.

Of course, when the bed (300) is removed, the bed cover (350) placed on the bed (300) and each pad (10) placed on the bed cover (350) are also removed together, and thereafter, the bed (300) is washed while the bed cover (350) and pad (10) are separated from the bed (300).

Meanwhile, as described above, the cleaning performed with the entire bed (300) removed has the inconvenience of having to be performed with the bed cover (350) and pad (10) removed together and then separated from the bed (300). Accordingly, if the bed cover (350) is to be cleaned together, it is preferable to remove the entire bed (300).

If you want to simply wash only the bed (300) without cleaning the bed cover (350), open the bed (300) by rotating the bed cover (350) as shown in the attached FIG. 20 and FIG. 35.

That is, by lifting the front of the bed cover (350), the bed cover (350) tilts while rotating away from the bed (300) with the first lifting projection (353) as the center of rotation, thereby opening the upper surface of the bed (300).

Afterwards, when cleaning of the upper surface of the open bed (300) is completed, the bed cover (350) is returned to its original position, thereby completing cleaning of only the bed (300).

Of course, as shown in the attached drawing 36, it is also possible to lift the bed cover (350) with the bed (300) partially removed from the cultivation room (121, 122) and clean the upper surface of the bed (300).

Accordingly, when washing the surface of the bed (300), instead of removing the entire bed (300), bed cover (350), and pad (10) from the cultivation room (121, 122), only the bed cover (350) is folded down so that the upper surface of the bed (330) is open, thereby eliminating inconveniences (e.g., separation of each pad and separation of the bed cover) caused by removing the entire bed (300).

Ultimately, since the plant cultivation device of the present invention is configured with a water supply structure that supplies only the required amount of water, no water remains in the bed (300), thereby preventing contamination or unpleasant odors in the cultivation room (121, 122) that may be caused by residual water.

In addition, since the plant cultivation device of the present invention is configured to be able to rotate the bed cover (350) on which the pad (10) is placed from the bed (300) to which the supply water is supplied, the upper surface of the bed (300) can be opened without taking the bed (300) out of the cultivation room (121, 122) or separating the bed cover (350) and the pad (10) from the bed (300), thereby making it possible to easily perform washing or maintenance of the bed (300).

In addition, the plant cultivation device of the present invention has a water supply path (330) formed on the surface of the bed (300) and embankments (331) formed protrudingly on both sides thereof, so that when water is supplied into the water supply groove (320) of the bed (300), the water does not overflow around the bed (300) and is accurately supplied to the water supply groove (320).

Meanwhile, the plant cultivation device according to the embodiment of the present invention is not limited to being implemented only with the structure of the embodiment described above.

That is, the plant cultivation device according to the embodiment of the present invention can be used as a built-in product while securing the cultivation room (121, 122) to the maximum extent possible simply by providing a structure in which the water tank (710) of the water supply module (700) is positioned between the bed (300) and the floor surface within the inner case (120), regardless of the structure within the machine room (201).

Of course, the water tank (710) is exposed to the interior by opening the opening/closing door (130) and can be taken out forward, thereby allowing the user to easily perform maintenance of the supply water, thereby preventing contamination or corruption of the supply water.

Additionally, the bed cover (350) may be configured to be elastically rotated from the bed (300).

For example, an elastic member (not shown) that provides elastic force (or restoring force) in the direction of rotation is installed on the first support projection (353) forming the center of rotation of the bed cover (350), so that the bed cover (350) can automatically rotate and be maintained in a rotated state by the elastic force of the elastic member when the user needs it.

Of course, in this case, it is desirable to additionally provide a restraining means (not shown) that maintains the bed cover (350) in the state in which it covers the upper surface of the bed (300).

10. Pad 11. Topsoil
12. Seed Paper 13. Brick
14. Packing material 15. Protective paper
16. Protrusion 17. First absorbent member
18. Second absorbent member 100. Cabinet
101,102. Guide rail 110. Out case
120. Inner case 121,122. Cultivation room
130. Opening door 131. Door frame
132. Viewing window 200. Frame for machine room
201. Machine room 202. Heat sink
211. Bottom plate 212. Side plate
213. Back plate 214. Top plate
220. Intake and discharge grille 221. Intake
222. Discharge port 230. Separating bulkhead
240. Condensate catcher 300. Bed
301. Guide Group 302. Mobile Guide Home
303. 1st overlay home 304. 2nd overlay home
310. Water receiving part 320. Water supply home
321. Front side water supply groove 322. Rear side water supply groove
323. Sensing cradle 330. Water supply path
331. Embankment 340. Dam
350. Bed cover 351. Heat-side mounting groove
352. Rear side anchoring groove 351a, 352a. Through hole
353. First overlay projection 354. Second overlay projection
355. Rear circumference 356. Front circumference
361. Handle 401,402. Lighting module
410. Lighting Case 411. Investigator
420. Circuit board 421. LED
430. Lighting cover 440,742. Residual water detection sensor
450. Temperature sensor 500. Circulation fan assembly
510. Circulation fan 520. Shroud
521. Installer 522. Air Guide
530. Compartment bulkhead 600. Temperature control module
610. Compressor 620. Condenser
630. Evaporator 700. Feedwater module
710. Water tank 720. Water pump
730. Supply hose 740. Installation frame
741. Detection unit 745. Water level detection sensor
750. Opening cover 760. Water supply connection pipe
761. Water pipe 762. Connecting pipe
800. Display module

Claims (17)

Cabinet with cultivation room;
A water supply module located on the floor within the cabinet;
A bed positioned above the water supply module, having a water receiving portion formed on one peripheral wall surface to receive water from the water supply module, and having a water supply groove sunken into the inner surface;
A bed cover that is placed on the upper surface of the bed;
A pad having a topsoil containing nutrient solution and a suction pipe formed on the bottom surface to be accommodated in the water supply groove, which is placed on the upper surface of the bed cover;
A lighting module positioned on the upper side of the bed and providing lighting for plant cultivation;
A plant cultivation device characterized in that the bed cover is rotatably installed on the upper surface of the bed, a recessed groove is formed on the inside for placing the pad, and a through hole is formed in the recess for passing the suction tube of the pad. In paragraph 1,
A plant cultivation device characterized in that the above bed is installed so as to be able to be pulled out by sliding back and forth from the cultivation room within the above cabinet. In paragraph 1,
A plant cultivation device characterized in that the bed has a water supply path that guides the supply water supplied from the water receiving unit to be stored in the water supply groove. In the third paragraph,
A plant cultivation device characterized in that the above water supply channel is formed on the upper surface of the bed. In paragraph 4,
A plant cultivation device characterized in that the above water supply channel is formed to slope downward from the water receiving portion to the surface height of the water supply groove formed in the bed. In paragraph 4,
A plant cultivation device characterized in that an embankment portion protruding upward from the upper surface of the bed is formed on both sides of the water supply channel among the upper surfaces of the bed. In paragraph 1,
The above bed cover has a first support protrusion formed to protrude downward,
The above bed has a first mounting groove formed on which the first mounting projection is mounted,
A plant cultivation device characterized in that the bed cover is configured to open the upper surface of the bed by rotating from the bed based on the first loading projection placed on the first loading groove. In paragraph 7,
A plant cultivation device characterized in that the water receiving portion is formed as a body with an open upper surface and protrudes outward from the rear wall surface of the bed. In Article 8,
The above first loading groove is formed to be inserted into the connection portion between the bed and the water receiving portion,
A plant cultivation device characterized in that the first lifting projection is formed to protrude downward from the rear end of the bed cover. In Article 9,
The above first loading home
A straight line formed vertically in the up-down direction while forming an upper open area,
A plant cultivation device characterized by including a bottom portion that extends from the straight portion and forms a floor. In Article 10,
A plant cultivation device characterized in that the bottom of the first mounting groove is formed in a round shape. In Article 11,
A plant cultivation device characterized in that the bottom of the first mounting groove is formed as a semicircular groove. In Article 12,
A plant cultivation device characterized in that the straight section of the first support groove is formed higher than the height of the bottom section. In Article 8,
A plant cultivation device characterized in that the first overlay protrusion is formed in a round shape. In Article 10,
A plant cultivation device characterized in that the first overlay projection is formed to be rounded by rolling inward. In paragraph 1,
A second lifting projection is formed to protrude downward on the front edge of the above bed cover,
A plant cultivation device characterized in that a second support groove is formed in the above bed into which the second support protrusion is inserted. In Article 16,
A plant cultivation device characterized in that the second support groove is formed so as to be recessed into the upper surface of the front peripheral portion of the bed.

Images