KR102870818B1 - House modular smart farm system - Google Patents

Abstract

The present invention relates to an indoor modular smart farm system, and more specifically, to an indoor modular smart farm system that is formed in a modular manner to enable cultivation of crops indoors, such as in an apartment or building, and thus enables interior decoration and smart farm functions.
An indoor modular smart farm system capable of growing crops indoors is provided, comprising one or more unit modules, wherein the unit modules comprise a hexagonal support frame formed by connecting support rods to each other, a hexagonal rear support frame formed by connecting support rods to each other, and a hexagonal connection support frame connecting the hexagonal front support frame and the hexagonal rear support frame with support rods of a predetermined length; an upper plate installed on the upper side of the support frame, a nutrient solution supply pipe installed on the lower surface of the upper plate, and an upper plate portion including growth LEDs installed on one or both sides of the nutrient solution pipe portion; a medium box portion disposed below the upper plate portion into which a medium for growing crops is introduced and into which the nutrient solution is sprayed; and a waste nutrient solution discharge pipe portion installed on the lower surface of the medium box portion to discharge waste nutrient solution discharged from the medium box portion.

Description

Indoor modular smart farm system {HOUSE MODULAR SMART FARM SYSTEM}

The present invention relates to an indoor modular smart farm system, and more specifically, to an indoor modular smart farm system that is formed in a modular form so that crops can be grown indoors, such as in an apartment or building, thereby enabling interior decoration and smart farm functions.

Smart farms, which incorporate IT, are currently the mainstream. By integrating IT into crop cultivation, crop yields can be increased. Consequently, the development of systems and devices that can be applied to smart farms is urgently needed. Because crops typically require regular watering and fertilizer application and sufficient sunlight during certain periods, various forms of smart farms are being proposed. Furthermore, smart farms require extensive space and various facilities, resulting in excessive facility costs.

Previous smart farm systems that could be installed indoors were primarily constructed in a square shape, stacked or arranged in rows to grow plants. Consequently, these systems were limited to simply cultivating crops, lacking the decorative function of indoor spaces.

Additionally, conventional smart farm systems have had many difficulties in being built in narrow indoor spaces or in narrow spaces within cities.

Patent Publication No. 10-1901418 (registered on September 17, 2018) Patent Publication No. 10-2022-0109933 (published on August 5, 2022) Patent Publication No. 10-2023-0032708 (published on March 7, 2023)

The present invention has been devised to solve the above problems, and its purpose is to provide an indoor modular smart farm system that can grow crops indoors in buildings such as apartments or buildings while also functioning as an interior decoration.

In addition, the present invention aims to provide an indoor modular smart farm system that is not subject to limitations on indoor space and location by modularizing the configurations so that installation is possible in a narrow indoor space.

In addition, the present invention aims to provide an indoor modular smart farm system that can create a comfortable indoor environment by reducing carbon emissions and increasing the amount of negative ions generated by enabling the cultivation of crops indoors.

In order to achieve the above object, the present invention provides an indoor modular smart farm system capable of growing crops indoors, which is composed of one or more unit modules, wherein the unit modules include a hexagonal support frame formed by connecting support rods to each other, a hexagonal rear support frame formed by connecting support rods to each other, and a hexagonal connection support frame connecting the hexagonal front support frame and the hexagonal rear support frame with support rods of a predetermined length; an upper plate installed on the upper side of the support frame, a nutrient solution supply pipe installed on the lower surface of the upper plate, and a growth LED installed on one or both sides of the nutrient solution supply pipe; a medium box section disposed below the upper plate section into which a medium for growing crops is introduced and into which the nutrient solution is sprayed; and a waste nutrient solution discharge pipe section installed on the lower surface of the medium box section to discharge waste nutrient solution discharged from the medium box section.

In the present invention, the badge box portion is characterized by comprising: a box body formed in a certain shape so as to be mounted on a hexagonal support frame; and a plurality of waste nutrient solution discharge holes formed on the bottom plate of the box body and connected to the waste nutrient solution discharge pipe portion.

In the present invention, the badge box portion is characterized by comprising: a box body formed in a predetermined shape so as to be mounted on a hexagonal support frame, in which badges are filled inside and an upper waste nutrient solution discharge hole is formed through which waste nutrient solution is discharged; and a water receiver connected to the lower portion of the box body, in which the waste nutrient solution discharged through the upper waste nutrient solution discharge hole is temporarily stored, and in which a lower waste nutrient solution discharge hole is formed through which the waste nutrient solution is discharged by being connected to the waste nutrient solution discharge pipe portion.

In the present invention, the support frame is characterized in that it is provided with a three-way connecting joint that connects the support rods at a certain angle in three directions at the vertex of the support frame.

In the present invention, the nutrient solution supply pipe section is characterized by comprising a supply pipe of a certain length mounted on the lower surface of the upper plate, and a spray nozzle connected to the center of the supply pipe and configured to supply the nutrient solution to the culture box section disposed on the lower side.

In the present invention, the waste nutrient solution discharge pipe section is characterized by comprising a branch pipe connected to a waste nutrient solution discharge hole formed in the box body, and a discharge pipe of a certain length connected to the branch pipe and mounted on the bottom surface of the box body.

In the present invention, the waste nutrient solution discharge pipe section is characterized by comprising a branch pipe connected to a lower waste nutrient solution discharge hole formed in a water receiver, and a discharge pipe of a certain length connected to the branch pipe and mounted on the bottom surface of the box body.

In the present invention, the unit modules are characterized in that a plurality of them are connected to each other to form a honeycomb structure.

In the present invention, the unit modules forming the honeycomb structure are characterized in that a nutrient solution connection pipe section connecting the nutrient solution supply pipe section of each unit module in a zigzag shape from the top to the bottom is further connected.

In the present invention, the unit modules forming the honeycomb structure are characterized in that the waste nutrient solution connecting pipes connecting the waste nutrient solution discharge pipes of each unit module in a zigzag shape from the top to the bottom are further connected.

In the present invention, the nutrient solution supply pipe section and the nutrient solution connection pipe section are characterized in that they are connected to each other by a flexible hose.

In the present invention, the waste nutrient solution discharge pipe section and the waste nutrient solution connection pipe section are characterized in that they are connected to each other by a flexible hose.

The present invention has the advantage of being able to grow crops indoors in buildings such as apartments or buildings while also serving as an interior decoration.

In addition, the present invention has the advantage of being able to be installed without any restrictions on indoor space and location by modularizing the configurations so that installation is possible in narrow indoor spaces.

In addition, the present invention has the advantage of creating a pleasant indoor environment by reducing carbon emissions and increasing the amount of negative ions generated by enabling the cultivation of crops indoors.

In addition, the present invention has the advantage of having few restrictions on installation space, as it only requires space for installation in the form of a unit module.

Figure 1 is a perspective view of a unit module of an indoor modular smart farm system according to the present invention.
Figure 2 is a perspective view of a support frame in a unit module of an indoor modular smart farm system according to the present invention.
Figure 3 is a perspective view of the upper part of a unit module of an indoor modular smart farm system according to the present invention.
Figure 4 is a perspective view of a nutrient solution supply pipe in a unit module of an indoor modular smart farm system according to the present invention.
Figure 5 is a perspective view of a badge box portion of one embodiment of a unit module of an indoor modular smart farm system according to the present invention.
Figure 6 is a perspective view of a badge box section of another embodiment of a unit module of an indoor modular smart farm system according to the present invention.
Figure 7 is a perspective view of a system in which unit modules of an indoor modular smart farm system according to the present invention are connected in a honeycomb structure.
Figure 8 is a perspective view of a unit module of an indoor modular smart farm system according to the present invention, in which a nutrient solution supply pipe section and a nutrient solution connection pipe section are connected with a flexible hose.
Figure 9 is a perspective view of a unit module of an indoor modular smart farm system according to the present invention, in which a waste nutrient solution discharge pipe and a waste nutrient solution connection pipe are connected with a flexible hose.
Figure 10 is a perspective view of a clamp used in a unit module of an indoor modular smart farm system according to the present invention.
Figure 11 is a diagram showing the installation status of the connecting pipes for the nutrient solution and waste nutrient solution of the unit module of the indoor modular smart farm system according to the present invention.
Figure 12 is a perspective view of an indoor modular smart farm system according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, this description is intended to be sufficiently detailed to enable those skilled in the art to easily practice the invention, and is not intended to limit the technical spirit or scope of the present invention.

An indoor modular smart farm system according to the present invention is composed of one or more unit modules (1). Fig. 1 is a perspective view of a unit module, and Figs. 2 to 6 are drawings of each component forming the configuration of the unit module (1). Hereinafter, the configuration of the unit module (1) will be described in detail with reference to each drawing. The unit module (1) is composed of a hexagonal support frame (10), an upper plate (20) mounted on the upper part of the support frame (10), a medium box section (30) in which medium is introduced and crops are grown, and a waste nutrient solution discharge pipe section (40) in which waste nutrient solution is discharged from the lower part of the medium box section (30). First, the support frame (10) is composed of a hexagonal front support frame (11a) formed by connecting support rods (111) to each other, a hexagonal rear support frame (11b) formed by connecting support rods (111) to each other, and a hexagonal connection support frame (11c) connecting the hexagonal front support frame (11a) and the hexagonal rear support frame (11b) with support rods (111) of a certain length. The upper plate (20) is composed of a top plate (21) installed on the upper side of the support frame (10), a nutrient solution supply pipe section (23) installed on the bottom surface of the upper plate (21), and growth LEDs (22) installed on one or both sides of the nutrient solution supply pipe section (23). The medium box section (30) is placed below the upper plate section (20) so that medium for cultivating crops is introduced and nutrient solution is sprayed. A waste nutrient solution discharge pipe section (40) is installed on the bottom surface of the medium box section.

Fig. 2 is a perspective view of a support frame (10). As shown in the drawing, the support frame (10) forms a hexagonal front support frame (11a) by connecting support rods (111) with three-way connecting joints (112), forms a hexagonal rear support frame (11b) by connecting the support rods (111) with upper connecting joints (112), and forms a hexagonal column shape by connecting a hexagonal connecting support frame (11c) made of support rods (111) to the three-way connecting joints (112) connected to the hexagonal front support frame (11a) and the hexagonal rear support frame (11b). The hexagonal front support frame (11a), the hexagonal rear support frame (11b), and the hexagonal connecting support frame (11c) are each made of six support rods (111).

Fig. 3 is a perspective view of the upper plate (20). The upper plate (20) is composed of a rectangular upper plate (21), a nutrient solution supply pipe (23) installed on the bottom surface of the upper plate (21), and growth LEDs (22) installed on one or both sides of the nutrient solution supply pipe (23). The upper plate (21) can be installed on a support bar (111) by welding or other methods. The growth LEDs (22) installed on the bottom surface of the upper plate (21) irradiate light so that crops can grow in the culture box (31). One or two sets of growth LEDs (22) can be installed on the bottom surface of the upper plate. The nutrient solution supply pipe (23) is installed in the center of the upper plate (21). The nutrient solution supply pipe (23) is fixed to a support plate (211: 211a, 211b) installed in the center of the upper plate (21). As shown in Fig. 4, the nutrient solution supply pipe section (23) is composed of a supply pipe (231) of a certain length mounted on the lower surface of the upper plate (21), a spray nozzle (232) connected to the center of the supply pipe (231) to supply the nutrient solution to the culture box section (30) placed on the lower side, and a T-shaped connecting pipe (233) for mounting the spray nozzle (232) on the supply pipe (231).

Fig. 5 illustrates an embodiment of a badge box unit (30). The badge box unit (30) is composed of a box body (31) formed in a predetermined shape so as to be mounted on a hexagonal support frame (10), and a plurality of waste nutrient solution discharge holes (32) formed on a bottom plate (312) of the box body (31) and connected to a waste nutrient solution discharge pipe unit (40). Specifically, the box body (31) has side plates (311) formed in an inclined shape on both sides so as to be mounted on the inside of the support frame (10) and having front and rear sides formed vertically, a bottom plate (312) formed at the lower end of the side plate (311), and a groove (313) formed on the bottom surface of the bottom plate (312) such that the front and rear sides of the side plates are formed to extend further than the bottom plate (312). A waste nutrient solution discharge pipe unit (40) is installed in the groove (313). The waste nutrient solution discharge pipe (40) is composed of a branch pipe (41) connected to a waste nutrient solution discharge hole (32) formed in the box body (31), and a discharge pipe (42) of a certain length that is connected to the branch pipe (41) and is mounted on the bottom surface of the box body (31). In addition, a mounting groove (33) is formed on the front and rear lower sides of the side plate (311) for mounting on a support bar (111).

Fig. 6 illustrates another embodiment of a badge box unit (30'). The badge box unit (30') is formed in a certain shape so as to be mounted on a hexagonal support frame (10), and is composed of a box body (31') in which badge is filled inside and an upper waste nutrient solution discharge hole (312') is formed through which waste nutrient solution is discharged, and a water receiver (32') which is connected to the lower part of the box body (31') and in which the waste nutrient solution discharged through the upper waste nutrient solution discharge hole (312') is temporarily stored and is connected to a waste nutrient solution discharge pipe unit (40) and in which a lower waste nutrient solution discharge hole (33') is formed through which waste nutrient solution is discharged. Specifically, the box body (31') is composed of an upper side plate (311') formed with both sides inclined and the front and rear sides formed in a vertical shape, an upper bottom plate (312') connected to the lower end of the upper side plate (311'), and an upper waste nutrient solution discharge hole (312') formed in the upper bottom plate (312'). The water receiver (32') is composed of a lower side plate (321'), a lower bottom plate (322'), and a lower waste nutrient solution discharge hole (33') formed in the lower bottom plate (322') through which the waste nutrient solution is discharged, a mounting groove (34') formed at the lower end of the front and rear sides of the side plate so that it can be mounted on a support bar (111), and a groove (324') formed on the lower surface of the lower bottom plate (322') such that the front and rear sides of the lower side plate (321') extend further than the lower bottom plate (322'). A waste nutrient solution discharge pipe (40) is connected to the home (324'). The waste nutrient solution discharge pipe (40) is composed of a branch pipe (41) connected to a lower waste nutrient solution discharge hole (33') formed in a water receiver (32'), and a discharge pipe (42) of a certain length, to which the branch pipe (41) is connected and which is mounted on the bottom surface of the water receiver (32').

Figure 7 illustrates a state of use in which multiple unit modules (1) are connected to each other. The unit modules (1) can be fixed to each other by welding or the like, or by using clamps.

Fig. 8(a) illustrates the connection of the nutrient solution supply pipe (23). The nutrient solution supply pipe (23) is connected to the nutrient solution connection pipe (25) using a flexible hose (24), and is also connected to another nutrient solution supply pipe (23) using the flexible hose (24). The flexible hose (24) is fixed using a fastener (441). Fig. 8(b) illustrates the connection of the waste nutrient solution discharge pipe (40). The waste nutrient solution supply pipe (40) is also connected to the waste nutrient solution connection pipe (43) using a flexible hose (44), and the waste nutrient solution connection pipe (43) is connected to another waste nutrient solution discharge pipe (40) using the flexible hose (44). Similarly, the flexible hose (44) is fixed using a fastener (441).

Fig. 9(a) illustrates the installation of a nutrient solution supply pipe (23), and Fig. 9(b) illustrates the installation of a waste nutrient solution supply pipe (40). In Fig. 9(a), a nutrient solution connection pipe (25) connected to a nutrient solution supply pipe (23) using a flexible hose (24) is shown being fixed using a clamp (50). In addition, Fig. 9(b) illustrates a waste nutrient solution connection pipe (43) connected to a waste nutrient solution discharge pipe (40) using a flexible hose (44) is fixed using a clamp (50).

Fig. 10 illustrates a clamp (50). The clamp (50) is composed of a main clamping part (51) that is fitted to a support bar (111), a target clamping part (52) into which a nutrient solution connection pipe (25) or a waste nutrient solution connection pipe (43) is fitted, and a joint hole (53) into which a bolt is mounted to fix the clamp (50). The main clamping part (51) and the target clamping part (52) are formed to be spaced apart from each other by a certain distance.

Figure 11(a) shows a zigzag route in which a nutrient solution supply pipe (23) and a nutrient solution connection pipe (25) are installed, and Figure 11(b) shows a zigzag route in which a waste nutrient solution discharge pipe (40) and a waste nutrient solution connection pipe (43) are installed.

Fig. 12 illustrates an indoor modular smart farm system (100). The system (100) comprises one or more unit modules (1) connected to each other, a control panel (2) equipped with a control unit and a power supply for controlling the supply of nutrient solution flowing to the unit modules (1) and the lighting of a growth LED (22), and a storage unit (3) for storing the discharged waste nutrient solution. The storage unit (3) may be equipped with a water level sensor and a pH sensor. In addition, the storage unit (3) may be equipped with a sensor for measuring the electrical conductivity (EC: Electrical Conductivity) of the soil. In addition, a pump for circulating the waste nutrient solution may be equipped.

Although the above examples have been described as illustrative, it will be apparent to those skilled in the art that the present invention can be embodied in many other forms without departing from the spirit and scope thereof. Therefore, the above-described examples should be considered illustrative rather than restrictive, and all implementations within the scope of the appended claims and their equivalents are intended to be included within the scope of the present invention.

1: Unit module
10: Support frame 11a: Hexagonal front support frame
11b: Hexagonal rear support frame 11c: Hexagonal connection support frame
20: Top 21: Top
22: Growth LED 23: Nutrient supply pipe
24: Nutrient solution connection pipe 25: Flexible hose
30: Badge box section 31: Box body
32: Waste fluid discharge hole 33: Settling groove
40: Waste water discharge pipe 41: Branch pipe
42: Discharge pipe 43: Waste nutrient solution connection pipe
44: Flexible hose
50: Clamp 51: Main clamping part
52: Target clamping part 53: Joint hole
Q ₁ : Nutrient solution flow rate Q ₂ : Spent nutrient solution flow rate

Claims (12)

In an indoor modular smart farm system that consists of one or more unit modules and can grow crops indoors,
The above unit module is,
A hexagonal support frame comprising a hexagonal front support frame formed by connecting support rods to each other, a hexagonal rear support frame formed by connecting support rods to each other, and a hexagonal connection support frame connecting the hexagonal front support frame and the hexagonal rear support frame with support rods of a certain length;
An upper plate comprising a top plate installed on the upper side of the support frame, a nutrient solution supply pipe installed on the lower surface of the top plate, and a growth LED installed on one or both sides of the nutrient solution supply pipe;
A box body formed in a certain shape so that the medium for cultivating crops is placed under the upper part and into which nutrient solution is sprayed and the box body is formed so that the box body can be placed on the hexagonal support frame; and a medium box part formed in a number of manners on the bottom plate of the box body and connected to a nutrient solution discharge pipe part; and
It is composed of a waste nutrient solution discharge pipe installed on the bottom surface of the above-mentioned badge box section and through which the waste nutrient solution discharged from the above-mentioned badge box section is discharged;
The above support frame is provided with a three-way connecting joint that connects the support rods at a certain angle in three directions at the vertex of the support frame.
The above nutrient solution supply pipe section is composed of a supply pipe of a certain length mounted on the bottom surface of the upper plate, and a spray nozzle connected to the center of the supply pipe and configured to supply nutrient solution to the culture box section disposed on the lower side.
The above waste nutrient solution discharge pipe section is composed of a branch pipe connected to a waste nutrient solution discharge hole formed in the box body, and a discharge pipe of a certain length connected to the branch pipe and mounted on the bottom surface of the box body.
The above unit modules are connected in large numbers to form a honeycomb structure,
The unit modules forming the above honeycomb structure are further connected by a nutrient solution connection pipe section that connects the nutrient solution supply pipe section of each unit module in a zigzag shape from the top to the bottom.
An indoor modular smart farm system characterized in that the unit modules forming the above honeycomb structure are further connected to form a waste nutrient solution connection pipe that connects the waste nutrient solution discharge pipe of each unit module in a zigzag shape from the top to the bottom. In an indoor modular smart farm system that consists of one or more unit modules and can grow crops indoors,
The above unit module is,
A hexagonal support frame comprising a hexagonal front support frame formed by connecting support rods to each other, a hexagonal rear support frame formed by connecting support rods to each other, and a hexagonal connection support frame connecting the hexagonal front support frame and the hexagonal rear support frame with support rods of a certain length;
An upper plate comprising a top plate installed on the upper side of the support frame, a nutrient solution supply pipe installed on the lower surface of the top plate, and a growth LED installed on one or both sides of the nutrient solution supply pipe;
A box body, which is formed in a certain shape so that a medium for cultivating crops is placed under the upper part and into which a nutrient solution is sprayed, and which can be settled on the hexagonal support frame, and in which a medium is filled inside and an upper waste nutrient solution discharge hole is formed through which waste nutrient solution is discharged; and a water receiver, which is connected to the lower part of the box body and in which the waste nutrient solution discharged through the upper waste nutrient solution discharge hole is temporarily stored and is connected to a waste nutrient solution discharge pipe and in which a lower waste nutrient solution discharge hole is formed through which the waste nutrient solution is discharged; and
It is composed of a waste nutrient solution discharge pipe installed on the bottom surface of the above-mentioned badge box section and through which the waste nutrient solution discharged from the above-mentioned badge box section is discharged;
The above support frame is provided with a three-way connecting joint that connects the support rods at a certain angle in three directions at the vertex of the support frame.
The above nutrient solution supply pipe section is composed of a supply pipe of a certain length mounted on the bottom surface of the upper plate, and a spray nozzle connected to the center of the supply pipe and configured to supply nutrient solution to the culture box section disposed on the lower side.
The above waste water discharge pipe section is composed of a branch pipe connected to a lower waste water discharge hole formed in the water receiver, and a discharge pipe of a certain length connected to the branch pipe and mounted on the bottom surface of the box body.
The above unit modules are connected in large numbers to form a honeycomb structure,
The unit modules forming the above honeycomb structure are further connected by a nutrient solution connection pipe section that connects the nutrient solution supply pipe section of each unit module in a zigzag shape from the top to the bottom.
An indoor modular smart farm system characterized in that the unit modules forming the above honeycomb structure are further connected to form a waste nutrient solution connection pipe that connects the waste nutrient solution discharge pipe of each unit module in a zigzag shape from the top to the bottom. delete delete delete delete delete delete delete delete In claim 1 or 2,
An indoor modular smart farm system characterized in that the nutrient solution supply pipe section and the nutrient solution connection pipe section are connected to each other by a flexible hose. In Article 11,
An indoor modular smart farm system characterized in that the waste nutrient solution discharge pipe section and the waste nutrient solution connection pipe section are connected to each other by a flexible hose.