KR20130010971A - Plant factory system - Google Patents

Abstract

PURPOSE: A plant factory system is provided to increase the crop productivity per unit cell part according to efficiently use space to raise crop inside of cell part. CONSTITUTION: A building unit consists of horizontally or vertically connecting cell part(100) which is composed as a side part of connecting the top and bottom. A building unit mutually connects the side of cell parts in case of connecting horizontality, and mutually connects top and bottom of cell parts in case of connecting verticality. A cell part is cant column shape. A main supporter(110) is vertically arranged in the center. A exterior cover material(115) is formed with multiple plastic sheets that is passed well by lights, and a gap is formed between plastic sheets. A vertical material is arranged parallel to the main supporter. A horizontal material(130) is arranged to connect the interval between top and bottom of adjoining vertical materials. A step(140) is arranged to connect top of main supporter, top of vertical material, bottom of main supporter, and bottom of vertical material. A plane which is surrounded by a main supporter, a vertical material, a step is formed with concrete. A polygonal shape which connects top of vertical material, and a polygonal shape which connects bottom of vertical material are the same polygonal shape formed in the top or bottom of main supporter. A polygonal shape which connects top of the vertical material and bottom of vertical material is a hexagon shape. A vertical material is arranged at a same interval, which has same distance from the center of main supporter on the same plate.

Description

Plant factory system

The present invention relates to a plant factory system.

Plant factory means a plant that can produce a large amount of plants by artificially creating environmental conditions for plant growth in a closed space and controlling the growth rate of plants. In relation to plant plants, Joseph W. Campbell et al. Proposed the concept of "automatic food plant production" in US Patent Publication No. 4,068,405 in 1978. They built tray-type plant cultivation on a continuous conveyor belt, installed artificial light, and periodically moved the conveyor. In addition, the nutrient solution supply network was installed so that the nutrient solution can be supplied centrally, and the temperature, humidity, and carbon dioxide concentration can be controlled for plant growth indoors.

This invention was a technically important development in that it proposed a mass production technology of a plant factory. However, due to the low precision of environmental control, high heating and cooling costs, and high installation and operating costs of artificial light sources, the commercialization was very low.

In recent years, an invention related to a plant factory using LED having excellent efficiency as compared to a conventional fluorescent lamp as an artificial light source has been reported. Korean Patent Laid-Open Publication No. 10-2004-0010426 (Dye plant with LED light source and its device) in the cultivation of pigment plants in the closed space to increase the production efficiency in a short space and to be grown in a short time ( LED, Light Emitting Diode) As a plant factory, LED lamps with far infrared light 730 nm, red light 660 nm, and blue light 450 nm are used as light sources. In addition, an ultraviolet sterilizer and an ozone sterilizer of the culture medium were configured, and the dissolved oxygen supply device was used to supply the dissolved oxygen of the culture solution. Cultivation uses NFT (Nutrient Film Technique) and spray hydroponic systems.

In addition, in order to maximize the space for plant cultivation by minimizing the space occupancy in the plant factory, a plant cultivation lighting apparatus for inserting a plurality of LED modules into the floodlight panel, and manufacturing in a slim panel form is disclosed in Korea Patent Publication No. It was reported in 10-2011-0013164. This reduces the space of the lighting device, and features a simple configuration. In recent years, many technologies are mainly focused on LEDs and diversifying light sources to promote plant growth. However, these technologies can be viewed as a high cost structure because the installation of a lot of expensive LED. The closed plant factory is a method that induces the growth of plants with only artificial light without sunlight in the existing closed reinforced concrete or steel structured building, so it is easy to control the environment of the building, but it has the disadvantage of expensive facility cost. It is developing into a building plant factory using

The solar combined type is a fusion of the technical concept of the existing glass greenhouse and the plant factory, and has the technical characteristics of lighting using artificial lighting and sunlight at the same time. Conventional glass greenhouses are made of transparent glass, so the solar transmittance is about 90%. The disadvantages of glass greenhouses are that they do not have good thermal insulation, so they have high indoor and heating energy costs in summer or winter. In addition, there is a problem that can not use the space efficiently because it is difficult to multilayer. The advantage is that daylight mainly uses sunlight and artificial lighting as a supplement, and at night only artificial light can reduce the installation cost of the light source. Conventional solar photovoltaic panels are mostly single-story buildings, and thus the space is not effectively utilized, and heating costs are high in winter and cooling costs are high in summer, resulting in high energy costs.

US Patent Publication No. 4,068,405 (Registration date: January 17, 1978) Republic of Korea Patent Publication No. 10-2004-0010426 (Published: January 31, 2004) Republic of Korea Patent Publication No. 10-2011-0013164 (published: February 9, 2011)

The present invention is a high-efficiency photovoltaic structure consisting of a multi-layered solar combined building structure with excellent light efficiency, a shell structure with low heat energy loss, smart lighting in the cultivation cell unit, automatic transfer of arable land of the cultivation cell, nutrient solution supply and management system per plant unit It is an object to provide a combined plant plant system.

The plant factory system according to claim 1 includes a building portion configured by horizontally or vertically connecting a cell portion composed of an upper surface and a lower surface of a polygonal shape and a side surface connecting the upper surface and the lower surface, wherein the building portion is horizontal One side surface of the cell portion is in contact with each other when connected to each other, and the upper and lower surfaces of the cell portion are in contact with each other when connected vertically, the cell portion is a polygonal column shape.

Therefore, according to the plant factory system which is invention of Claim 1, a crop can be efficiently cultivated in a fixed space by making a cell part polygonal shape.

The plant factory system according to claim 2 is the plant factory system according to claim 1, wherein the cell unit includes: a support zone vertically disposed at the center; A plurality of vertical members disposed in parallel with the support zone; A plurality of horizontal members arranged to connect between upper ends and lower ends of the vertical members adjacent to each other; And a plurality of beams arranged to connect an upper end of the support and an upper end of the vertical member, and a lower end of the vertical support to the lower end of the vertical member. Is formed of concrete.

Therefore, according to the plant plant system of the present invention according to claim 2, the honeycomb structural elements can be structurally stabilized by being combined with each honeycomb structural element centered on a centrally located land area. Light weight, quality uniformity and construction time can be shortened. In addition, it is possible to reduce the cost of construction work by minimizing the number of support zones and beams by arranging the support zones in the center.

The plant factory system according to claim 3 is the plant factory system according to claim 2, wherein the shape of the polygon connecting the upper end of the vertical member and the shape of the polygon connecting the lower end of the vertical member are the upper end of the supporting zone. Or the shape of the polygon formed at the bottom.

Therefore, according to the plant factory system which is invention of Claim 3, the cell part which has an integrated shape can be comprised by making the shape of the polygon which connects the upper end or the lower end of a support zone and a vertical member the same.

In the plant factory system according to claim 4, in the plant factory system according to claim 3, the shape of the polygon connecting the upper end of the vertical member, and the shape of the polygon connecting the lower end of the vertical member is the shape of a regular hexagon.

Therefore, according to the plant factory system which is invention of Claim 4, the cell part which has a cube shape can be comprised by making the shape of the polygon which connects the upper end or the lower end of a vertical member into a regular hexagon shape.

The plant factory system according to claim 5 is the plant factory system according to claim 3, wherein the vertical members are arranged at equal intervals from each other, and the distances from the center of the support zone are the same on the same plane.

Therefore, according to the plant factory system of the invention according to claim 5, it is possible to form a balanced and stable cell part in the vertical direction by having the same spacing at the time of vertical member arrangement and the same distance from the center of the support zone.

The plant factory system of the invention according to claim 6 is the plant factory system according to the invention according to claim 2, wherein the horizontal member has the same distance from the center to the both ends thereof on the same plane.

Therefore, according to the plant factory system of the invention according to claim 6, it is possible to form a balanced and stable cell part in the horizontal direction by making the distance from the center of the support zone to both ends thereof equal when the horizontal member is arranged.

The plant factory system of the invention according to claim 7 is the plant factory system according to the invention according to claim 2, wherein the beam forms the same angle as the horizontal member on the same plane.

Therefore, according to the plant factory system of the invention according to claim 7, the beams make the same angle with the horizontal member on the same plane to balance the magnitude of the force applied to both ends of the horizontal member in the horizontal direction.

According to the present invention, crops can be cultivated within the cell part, and thus the crop yield per unit cell part can be increased by using space efficiently.

1 is a perspective view showing the appearance of the plant factory system according to an embodiment of the present invention.
2 is a perspective view of a cell unit connected horizontally and vertically according to an embodiment of the present invention.
Figure 3 is a perspective view showing a cross section of the outer skin according to an embodiment of the present invention.
4 is a plan view geometrically illustrating an upper surface of the cell unit of FIG. 2.
5 is a perspective view of a cell unit of a crop cultivation unit having a crop planting unit according to an embodiment of the present invention.
6 is a perspective view of a lighting unit according to an embodiment of the present invention.
7 is a perspective view illustrating a bottom surface of the lighting unit of FIG. 6.
8A to 8B are perspective views of the moved crop planting of the planting line group according to an embodiment of the present invention.
9 is an enlarged perspective view of the third quadrant of FIG. 8A.
FIG. 10 is a perspective view illustrating the underside of the crop planting part of FIG. 8A. FIG.
11 is a perspective view of the nutrient solution supply unit according to an embodiment of the present invention.
12 is a perspective view of the lower crop planting portion according to an embodiment of the present invention.
13 is a cross-sectional view of the lower crop planting portion according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention may be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. The shape and the size of the elements in the drawings may be exaggerated for clarity and the same elements are denoted by the same reference numerals in the drawings.

1 is a perspective view showing the appearance of the plant factory system according to an embodiment of the present invention. Referring to FIG. 1, the plant factory system includes a building part 10, an outer skin part 115, a cell part 100, an illumination part 200, a crop planting part 300, and a nutrient solution supply part 400.

The building unit 10 is configured by connecting the cell unit 100 horizontally or vertically. When the building unit 10 is connected horizontally, one side surfaces of the cell unit 100 are in contact with each other, and when connected vertically, the upper and lower surfaces of the cell unit 100 are in contact with each other.

The outer skin 115 constitutes a side surface of the cell unit 100. The outer skin 115 is formed by arranging a plurality of outer skin members 115 formed of a plastic sheet having excellent transparency and elasticity such as PMMA (acrylic) and polycarbonate at predetermined intervals. The outer shell member 115 is attached to the side of the cell portion 100 in a lattice shape and used as the outer shell portion 115. In the present embodiment, the plastic sheet is used as the shell member 115, but glass may be used as the shell member 115 in addition to the plastic sheet.

The cell unit 100 includes a top surface and a bottom surface of a polygonal shape, and side surfaces connecting the top surface and the bottom surface. The upper and lower surfaces of the cell portion 100 are hexagonal, and the cell portion 100 is hexagonal. In the present embodiment, the shape of the cell part 100 is a hexagonal column, but the shape of the cell part 100 is not limited to the hexagonal column, and other polygonal column shapes are possible. The cell portion has a polygonal column shape, so that crops can be efficiently grown in a certain space.

The lighting unit 200 may be disposed in the interior space of the cell unit 100, irradiate light while rotating, and may be implemented by the lighting lamp 221. In the center of the cell portion 100, a support zone is disposed, and the lighting unit 200 is fitted with a rotation zone, the center of which is supported by the support zone, and has a lighting lamp 221 for irradiating light to the crop. Including the whole.

The crop planting unit 300 is disposed in two or more layers in the inner space of the cell unit 100, crops are planted and grown, and light from the lighting unit 200 is irradiated. The crop planting unit 300 may include a planting line group in which unit planting lines of a linear rectangular shape are arranged in parallel, and may be implemented as a crop planting plate.

The nutrient solution supply unit 400 is disposed in the inner space of the cell unit 100, and supplies the nutrient solution to the nutrient solution flow passage 340 provided in the crop planting unit 300. The nutrient solution supply unit 400 will be described in detail later with reference to FIG. 10.

In addition, it may further include a remote control means for remotely controlling the rotation operation and the light irradiation operation of the lighting unit 200, and the nutrient solution supply operation of the nutrient solution supply unit 400.

On the other hand, instead of the above-described lighting unit 200, cutting means for cutting the upper portion of the crop while rotating in the crop planting unit 300, or irradiated with light and irradiating light to the crop while rotating in the crop planting unit 300 When rotating without irradiation, it may include an illumination unit 200 for cutting the upper part of the crop, a sensor 222 that can observe the growth state of the crop while rotating. The lighting unit 200 may selectively perform a function of irradiating light to the crop while rotating on the crop planting unit 300 and a function of cutting an upper portion of the crop while rotating without irradiating light. At this time, the lighting lamp 221 is turned on when the light is irradiated according to the constant amount of light required for the crop while being installed in the lighting unit 200, and is turned off when the light is not irradiated. The lighting or turning off the lighting lamp 221 can be implemented using an automatic system using a switch or a light amount sensor (a kind of sensor).

Hereinafter, the building part 10, the outer skin part 115, the cell part 100, the lighting part 200, the crop planting part 300, and the nutrient solution supply part 400 will be described in detail with reference to FIGS. 2 to 13. Shall be.

2 is a perspective view of the cell unit in a horizontal and vertical connection state according to an embodiment of the present invention, Figure 3 is a perspective view showing a cross-section of the outer skin 115 according to an embodiment of the present invention. 4 is a plan view geometrically illustrating an upper surface of the cell unit of FIG. 2. Referring to FIG. 2, the cell portion 100 has a polyhedron shape and a hexagonal column shape. A plurality of cell units 100 may be connected horizontally or vertically. The plurality of cell portions 100 are horizontally connected to one side surfaces of the cell portions 100 in contact with each other, and the plurality of cell portions 100 are vertically connected to the upper and lower surfaces of the cell portions 100 in contact with each other. .

The solar cell unit 100 that receives sunlight directly has a high amount of insolation, but the remaining cell unit 100 that does not receive sunlight directly has a lower amount of solar radiation than the cell unit 100 of a crop cultivation unit that receives sunlight directly. This may be complemented by the lighting unit 200 as shown in FIGS. 6 and 7 to be described later.

2 and 4, the cell unit 100 includes a support zone 110, a plurality of vertical members 120, a plurality of horizontal members 130, and a plurality of beams 140.

The support zone 110 is disposed vertically in the center, and serves to support the load of the entire cell unit 100. As shown in FIG. 4, when the upper surface of the cell unit 100 has a regular hexagonal shape, the cell unit 100 is horizontally connected to each other by six regular hexagons contacting each side of the central regular hexagon. When the support zone 110 of the cell unit 100 is connected, another regular hexagonal shape is formed.

The plurality of vertical members 120 are disposed in parallel with the support zone 110. The vertical members 120 are arranged at equal intervals from each other, and the distances from the center of the support zone 110 are the same on the same plane. As such, when the vertical member 120 is disposed, the cell unit 100 may be balanced and stable in the vertical direction by having the same interval and the same distance from the center of the support zone 110.

The plurality of horizontal members 130 are arranged to connect between upper ends and lower ends of the vertical members 120 adjacent to each other. The horizontal member 130 has the same distance from the center of the support zone 110 to both ends thereof on the same plane. As such, when the horizontal member 130 is disposed, the distance from the center of the support base 110 to the opposite ends thereof may be equal to form a balanced and stable cell unit 100 in the horizontal direction.

The plurality of beams 140 are arranged to connect the upper end of the support 110 and the upper end of the vertical member 120, and the lower end of the support 110 and the lower end of the vertical member 120. Angle of the beam 140 and the horizontal member 130 on the same plane is the same. As shown in FIG. 4, when the top surface of the cell unit 100 has a regular hexagonal shape, the angle formed with the horizontal member 130 on the same plane is 60 degrees, and the beams 140 are formed around the support zone 110. The angle is also 60 degrees. In this way, the beam 140 is equal to the angle formed by the horizontal member 130 on the same plane to balance the magnitude of the force received at both ends of the horizontal member 130 in the horizontal direction.

In addition, such a cell unit 100 is structurally stabilized by combining each honeycomb structural element with a dry-based beam 140 centered on the support zone 110 disposed in the center. Cell portion 100 made of a multi-layer is made of a precast prestressed concrete (PCaPC) structure type to reduce the weight and quality uniformity, shorten the construction period. In addition, by placing the support zone 110 in the center can minimize the number of the support zone 110 and the beam 140 to reduce the construction cost.

The cell unit 100 described above is a structure having a minimum of structural elements, the support zone 110, a plurality of vertical members 120, a plurality of horizontal members 130, and a plurality of beams 140. It has a ring structure connected with). This structure is different from the conventional structure having a simple cubic structure, despite the movement of the sun during the day, it facilitates the inflow of sunlight to maintain a high amount of solar radiation inside the cell portion (100). To this end, in the case of rural areas, the cell unit 100 is installed high, and in the case of the city, the cell 100 unit is installed wide.

In addition, the plane surrounded by the support zone 110, the horizontal member 130, the beam 140 is formed of concrete, the beam 140 is applied to the concrete so that the tensile stress is not applied to the concrete. In this way, tension is applied to the cell portion 100 to form an integrated structure.

On the other hand, the outer skin portion 115 constituting the side of the cell portion 100, the plane formed by the vertical member 120 and the horizontal member 130 adjacent to each other, the plane formed by the polygon connecting the upper end of the vertical member 120, and It is provided in the plane formed by the polygons connecting the lower end of the vertical member (120). The shape of the polygons connecting the top of the vertical member 120, and the shape of the polygons connecting the bottom of the vertical member 120 is the same as the shape of the polygon formed on the top or bottom of the support zone 110, and may be a regular hexagonal shape. have. That is, if the shape of the polygon connecting the upper end of the support 110 is a regular hexagonal shape, the shape of the polygon connecting the upper end of the vertical member 120 is also a regular hexagonal shape, the shape of the polygon connecting the lower end of the support 110 is a regular hexagon. If the shape, the shape of the polygon connecting the lower end of the vertical member 120 is also a regular hexagonal shape. As such, the cell unit having the integrated shape may be configured by making the shape of the polygon connecting the upper end or the lower end of the support 110 and the vertical member 120 the same. In addition, the cell portion 100 having a hexagonal pillar shape may be configured by using a polygonal shape connecting a top or bottom of the vertical member 120 to a regular hexagon.

The envelope member 115 is formed of multiple plastic sheets (or glass) through which light passes well, and a space is formed between the plastic sheets. For example, the outer shell member 115 may be formed of a double window (or double skin, 115a, 115b) formed of a plastic sheet, as shown in Figure 3, the air 155 to the outer shell member 115 By circulating) to maintain a constant temperature in the cell unit 100, and provides an optimal environment for crop growth. In addition, the shell member 115 may optimize the temperature environment in the cell unit 100 by using the difference in the thermal environment for each season. That is, if the wind directly applied to the crop is a barrier to crop growth due to the dry environment, double windows (115a, 115b) can prevent such a barrier. In other words, by circulating air in the outer shell formed of a plastic sheet of a double structure it can block the outflow and inflow of thermal energy in the plant factory. That is, in winter, circulating air or waste heat introduced into the interior can reduce heat energy flowing out to the outside, and in summer, circulate cold air supplied through the air conditioning facility in the same way to heat transfer through the plastic skin from the outside. By reducing the cooling energy of the room can be reduced. In summary, circulating the air flowing from the air conditioning facility between the plastic casing of the dual structure to properly control the flow of heat energy into the indoor and outdoor, thereby greatly reducing the heating and cooling costs in the plant factory.

Natural light is possible through such an outer shell member 115, and the light insufficient by natural light can be supplemented with an illumination lamp 221 (fluorescent lamp or LED).

It may further include a water supply means for supplying water to the upper end of the outer skin 115 to flow water down to the lower end of the outer skin 115 along the outer surface of the outer skin 115. In this case, it may further include a drip tray receiving water flowing down and installed at the lower end of the outer skin part 115. The drip tray is for recovering water flowing through the outer skin 115 when the outer skin 115 overheated in the summer with water. As such, the temperature of the shell member 115 may be reduced by flowing water in the summer portion of the outer shell member 115 having a double structure. In addition to the direct contact with water on the surface of the outer shell member 115 in the summer, there is an effect that can directly take heat from the heated outer shell member 115, as well as the water generated in the process of evaporating water from the surface of the outer shell member 115 The heat of evaporation (endothermic) has the effect of taking heat away from the shell member 115.

2 to 4, the present embodiment relates to the construction of a dry-based PCaPC structure design for plant factories and the development of a structural system using the same, in particular, the design and joining method of the frame design and element members used in the structural frame of the plant factory It is about. In addition, the present embodiment relates to a dry structural system, and to a method of assembling by introducing post-tension to the PS steel in the sage by constructing the structural member in the factory and transported to the construction site.

In general, the tensile strength of concrete is very small, about 1/10 to 1/13 of the compressive strength. In addition, the flexural tensile strength of the concrete is as small as 1/5 to 1/8 of the compressive strength. Therefore, when manufacturing the concrete structure, the reinforcement is reinforced by putting the reinforcement on the tensile side so that the compressive force is received by the concrete and the tensile force is received by the reinforcement, but cracks occurring on the tensile side cannot be prevented. However, in order to offset the tensile stress occurring in the concrete so that the tensile force does not occur in the structure, the type of structure that controls the cracks in the concrete structure by applying compressive stress in advance is called prestressed concrete.

In relation to the fabrication of structural elements, the steel wires are laid so that compressive stress can be applied to concrete using PS steel so that tensile stress does not occur in concrete structures. The fabricated structural element introduces the compressive stress by tensioning the steel in the field and introduces the tension force to the structural element to complete the structure through integration. Structural elements are designed through structural calculation, and the element members are manufactured in the factory to produce formwork with the same quality and performance, brought into the site, and the PS steel can be tensioned at the site to complete the structure. .

An example of a structure is a cantilever structure that includes a hexagonal column coupled to a PS steel rod due to a honeycomb-shaped structure, and a PCaPC floor slab system with two or more girders in the column.

5 is a perspective view of a cell unit of a crop cultivation unit having a crop planting unit according to an embodiment of the present invention. Referring to FIG. 5, the cell plant 100 includes a crop planting unit 300 having a multilayer structure. That is, as shown in Figure 5, the inside of the cell unit 100 has a support zone 110 in the center, crop planting unit 300, lighting unit 200, crop from below on the basis of the support zone 110 The planting unit 300 and the lighting unit 200 are respectively disposed. In the case of FIG. 5, the crop planting unit 300 is composed of two layers. The crop planting unit 300 is not limited to only two layers but may be configured to three or more layers by different design methods.

6 is a perspective view of a lighting unit according to an embodiment of the present invention. 5 and 6, the support zone 110 is disposed at the center of the cell unit 100, and the lighting unit 200 is fitted to the support zone 110 to rotate, and the center of the cell unit 100 is rotated. And a supported rotating body.

The rotating body has a rotary frame 210 fitted to the support base 110, and a rotary blade 220 inserted and fixed in a groove formed in the rotary frame 210 and detachable. Rotating blade 220 is composed of three, but is not limited thereto.

In addition, by rotating the rotating body, it is possible to lower the installation cost of the lighting unit 200, it is possible to obtain a flashing effect even when the lighting lamp 221 is not used. That is, the light can be irradiated when the light is needed according to the constant amount of light required for the crop, and the light is not irradiated when the light is not required for the crop, thereby increasing the efficiency of energy consumption by light irradiation.

In addition, the rotational speed is controlled to adjust the amount of light irradiated to the crop. When the rotational speed of the rotating body is adjusted, the blinking time of the lighting unit 200 is also adjusted, and the light intensity and the amount of light can be controlled by adjusting the number of lighting lamps 221 provided in the lighting unit 200.

In addition, the size of the rotating body and the number of the lighting lamps 221 are also variables of the lighting conditions. As the speed of the rotor is faster, the driving energy consumption of the rotor is greater. Therefore, if the lighting cost is optimized by dividing the lighting cost into the lighting facility cost and the lighting operation cost, the economical efficiency of the lighting cost can be increased.

In addition, the distance from the crop planting unit 300 of the rotating body can also be adjusted. At this time, the rotating body may move up or down with the support zone 110 as an axis. When the rotating body moves upward, the distance from the crop planting part 300 becomes long, and when the rotating body moves downward, the distance from the crop planting part 300 becomes short.

The rotating frame 210 is the center of the rotating body and has a hollow shape. The rotating frame 210 rotates while being fitted to the support base 110 even when rotating.

In addition, a fan 230 for circulating the heat generated from the lighting lamp 221 to the outside of the rotary blade 220 may be further installed on the rotary blade 220. Due to the installation of the fan 230, it serves to release the heat due to the illumination lamp 221.

In addition, the rotary blade 220 has a fan-shaped end of the opposite side of the rotary frame 210.

On the other hand, the lighting unit 200 may enable the rotation operation and the light irradiation operation through the remote control means. That is, the crop cultivator may operate the push button through a remote control means such as a remote controller to rotate the lighting unit 200 to irradiate light. In this way, by allowing the crop cultivator to operate by remotely controlling without operating the lighting unit 200, it is possible to pursue the convenience and speed of crop cultivation.

As illustrated in FIG. 1, instead of the lighting unit 200, cutting means for cutting the upper portion of the crop while rotating above the crop planting unit 300, or light on the crop while rotating above the crop planting unit 300. When rotating without irradiating and irradiating light may include cutting means for cutting the upper portion of the crop. However, when the cutting means is included instead of the lighting unit 200, the components related to light irradiation are not included.

The above-described lighting unit 200 or the cutting means may be configured by inserting the rotating blade 220 into the rotating frame 210 in a different structure. At this time, the upper part of the crop can be more easily cut due to the cutting means.

7 is a perspective view illustrating a bottom surface of the lighting unit of FIG. 6. Referring to FIG. 7, a motor is installed in the support zone 110 to generate a driving force to rotate the rotary blade 220. The rotary blade 220 includes an illumination lamp 221 for irradiating light to crops, A reflection plate mounted on the illumination lamp 221 and reflecting the light emitted from the illumination lamp 221 in the direction of the crop may be installed.

The lighting lamp 221 may be composed of a fluorescent lamp or an LED, or may be composed of a combination of a fluorescent lamp and an LED. When the LED is configured, a variety of combinations of blue LEDs and red LEDs may be used. Can be investigated.

When the combination of the fluorescent lamp and the LED, it is possible to compensate for the problem of using only a fluorescent lamp that is rapidly reduced in life and increase the use of electricity when flashing, or using only expensive LED installation.

The reflector collects the light irradiated from the lighting lamp 221 to the place where the crop is located.

That is, the reflective plate may be provided with a light-organic reflector in order to ensure the incident angle of the sunlight according to the altitude and movement of the sun to 60 degrees or more. The mineral organic reflector may effectively introduce sunlight into the building part 10.

As a result, more light can be efficiently distributed to the crop. The reflector may be formed of a material having high reflectance such as aluminum, stainless steel, or plastic.

The rotary blade 220 may be further provided with a camera for photographing the crop image when the rotary blade 220 is rotated, and a sensor 222 (see FIG. 7) for detecting temperature, humidity, and quantity of light suitable for crop growth. have. The camera and the sensor 222 may be installed only on one rotary blade 220, and because the crop to monitor the state of the crop when the rotary blade 220 rotates, the crop grower is the crop is grown through the camera and sensor 222 You can monitor the process or the condition of the crop. By installing the camera and sensor 222, the crop grower does not have to check the condition of the crops one by one.

On the other hand, the rotation operation and the light irradiation operation of the lighting unit 200 can be controlled by a remote control means.

8A to 8B are perspective views of a moved crop planting unit of the planting line group according to an embodiment of the present invention, and FIG. 9 is an enlarged perspective view of the third quadrant of FIG. 8A.

The crop planting unit 300 includes a planting line group in which linearly-shaped unit planting lines are arranged in parallel, and are divided into first and fourth quadrants 310a to 4th. In other words, the crop planting unit 300 can be modularized. The planting line group is disposed one by one in the first quadrant 310a to the fourth quadrant, and the spacing between the unit planting lines l is adjustable.

The crop planting part 300 passes through the unit planting line l perpendicularly to the longitudinal direction of the unit planting line l, and one end thereof is inserted into a groove g formed in the guide devices 320a and 320b. A semicircular guide rod 350 is disposed. Thus, when the guide devices 320a and 320b move, the planting line group can move along the guide devices 320a and 320b.

The crop planting part 300 is provided with a groove g into which a container c (shown in FIG. 13) into which a crop can be planted can be inserted. The grooves g are arranged along the unit planting line l at equal intervals.

The crop planting part 300 has a square shape, and outside the crop planting part 300 having a square shape, guide devices 320a and 320b having the same length direction as the unit planting line l are disposed. Roller-shaped belts 330 (see FIG. 11) are disposed on both sides of the planting line group.

The planting line group may move to the adjacent quadrants among the first quadrant 310a to the fourth quadrant with respect to the center of the crop planting unit 300. The planting line group disposed in the first quadrant 310a is movable to the fourth quadrant by the guide devices 320a and 320b, and the planting line group disposed in the third quadrant is formed by the guide devices 320a and 320b. It is movable to two quadrants 310b. In addition, the planting line group disposed in the second quadrant 310b is movable to the first quadrant 310a by the roller-type belt 330, and the planting line group disposed in the fourth quadrant is the roller-type belt 330. Move to the third quadrant. That is, the planting line group arranged in each quadrant can move clockwise. 8A to 8B show positions (1) moved to the original position and (2) clockwise, respectively, and as a result, the positions moved four times in the clockwise direction in FIG. 3A are the same as the original positions. In addition, in the embodiment of the present invention, the planting line group is designed to move in the clockwise direction, it is also possible to design to move in the counterclockwise direction.

Due to the movement of the planting line group, crop growers can grow the crops without moving one by one, and can carry out seedling work and collection work in one place. In addition, since the planting line group is spaced apart from each other by a minimum distance, there is no need to separately adjust the light according to each planting line group.

FIG. 10 is a perspective view illustrating the underside of the crop planting part of FIG. 8A. FIG. Referring to FIG. 10, two plant nutrient drainage units 360a and 360b are symmetrically installed in the crop planting unit 300 based on the center in one direction. That is, the inclined surfaces of the symmetrical nutrient solution drainage parts 360a and 360b are V-shaped, and the nutrient solution is collected at the bottom of the inclined surface. The nutrient solution collected at the bottom is pumped by a pump and sent to the nutrient solution tanks 410a and 410b through the nutrient solution recovery line.

11 is a perspective view of the nutrient solution supply unit according to an embodiment of the present invention. Referring to FIG. 11, the nutrient solution supply unit 400 includes a nutrient solution tank 410a, 410b, FIGS. 8A and 8B), a pipe 420, a first nutrient solution supply nozzle 430, and a second nutrient solution supply nozzle. .

The nutrient solution tanks 410a and 410b store the nutrient solution, and the pipe 420 is connected to the nutrient solution tanks 410a and 410b so that the nutrient solution passes. The first nutrient solution supply nozzle 430 and the second nutrient solution supply nozzle are detachable to the nutrient solution flow passage 340 in the form of the plug is inserted. The first nutrient solution supply nozzle 430 is connected between the pipe 420 and the nutrient solution flow passage 340 to supply the nutrient solution that passes through the pipe 420 to the nutrient solution flow passage 340. The nutrient solution supplied to the plant is discharged to the lower part of the groove (g), whereby the nutrient solution is collected. To be discharged.

When the first nutrient supply nozzle 430 and the second nutrient supply nozzle are separated from the crop planting unit 300, the crop planting unit 300 may move to an adjacent quadrant as shown in FIGS. 8A to 8B.

The nutrient solution flow passage 340 is formed in the upper part of the planting line (1), and supplies the nutrient solution to the sponge installed in the container (c) that can plant the crop inside the unit planting line (l). Sponge to which the nutrient solution is supplied is located below the nutrient solution flow passage 340, it is possible to supply the nutrient solution by using the inclination due to the height difference.

On the other hand, the nutrient solution supply unit 400 may further include a pump, the pump is discharged from the second nutrient solution supply nozzle pumps the nutrient solution collected at the bottom of the inclined surface shown in FIG. 10 and sent to the nutrient solution recovery tank.

On the other hand, the nutrient solution supply unit 400 may enable the nutrient solution supply operation through a remote control means. That is, the crop grower may be operated through a remote control means such as a remote controller so that the nutrient solution may be supplied to the nutrient solution flow passage 340 from the nutrient solution tanks 410a and 410b of the nutrient solution supply unit 400 through the first nutrient solution supply nozzle. . In this way, by allowing the crop grower to operate by controlling and operating the nutrient solution supply unit 400 remotely, it is possible to seek convenience and speed of crop cultivation.

12 and 13 are a perspective view and a cross-sectional view of the lower crop planting according to an embodiment of the present invention, respectively. 12 and 13, it can be seen that the crops planted in the sponge m may be located through the grooves g formed in the planting line group of the crop planting unit 300. The nutrient solution flow passage 340 is formed above the unit planting line l, and supplies the nutrient solution to the sponge m installed in the container c capable of planting the crop inside the unit planting line l. The inner wall of the container (c) inserted into the groove (g) is provided with a sponge can effectively suck the supplied nutrient solution, and can be attached and detached when the sponge is not necessary because the sponge is detachable. At this time, the nutrient solution flow passage 340 supplies the nutrient solution to its own weight by using the inclination due to the height difference of the sponge.

In this way, since the nutrient solution is poured into the sponge (m) located at the root of the crop, unnecessary nutrient solution may not be supplied in the process of supplying the nutrient solution, thereby minimizing the amount of nutrient solution supplied to the crop, and reducing the nutrient supply cost. This can be reduced to a minimum.

The present invention is not limited by the above-described embodiment and the accompanying drawings. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims, .

10: building part
100: cell part
110: Governor Zone
115: outer skin
115a, 115b: Double Window
155: air
120: vertical member
130: horizontal member
140: Bo
200: lighting unit
210: rotating frame
220: rotating blade
221: lighting lamp
222: sensor
230: fan
300: crop planting
310a: first quadrant
310b: second quadrant
320a, 320b: guide device
330: Roller type belt
340: nutrient solution flow passage
350: guide rod
360a, 360b: Nutrient Drainage
370: nutrient return passage
400: nutrient solution supply unit
410a, 410b: nutrient solution tank
420: piping
430: first nutrient solution supply nozzle

Claims (7)

Building part configured by connecting the cell part consisting of the upper and lower surfaces of the polygonal shape and the side surface connecting the upper and lower surfaces horizontally or vertically
Including,
When the building unit is connected horizontally, one side surfaces of the cell unit are connected to each other, and the upper and lower surfaces of the cell unit are connected to each other when connected vertically.
The cell portion has a polygonal column shape,
Plant factory system. The method of claim 1,
The cell unit,
A centrally located vertical zone;
A plurality of vertical members disposed in parallel with the support zone;
A plurality of horizontal members arranged to connect between upper ends and lower ends of the vertical members adjacent to each other; And
A plurality of beams arranged to connect an upper end of the support and an upper end of the vertical member, and a lower end of the support and the lower end of the vertical member;
Including,
The plane is surrounded by the support, the horizontal member, the beam is formed of concrete,
Plant factory system. The method of claim 2,
The shape of the polygon connecting the upper end of the vertical member, and the shape of the polygon connecting the lower end of the vertical member is the same as the shape of the polygon formed on the upper or lower end of the support,
Plant factory system. The method of claim 3,
The shape of the polygon connecting the upper end of the vertical member, and the shape of the polygon connecting the lower end of the vertical member is the shape of a regular hexagon,
Plant factory system. The method of claim 3,
The vertical members are arranged at equal intervals from each other, the same distance from the center of the support zone on the same plane,
Plant factory system. The method of claim 2,
The horizontal member is the same distance from the center of the support zone to both ends on the same plane,
Plant factory system. The method of claim 2,
The beams make the same angle as the horizontal member on the same plane,
Plant factory system.

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