JP2019047732A - System for cultivating plant - Google Patents

Abstract

To provide a system for cultivating plant whose installation location is not restricted.SOLUTION: A system 101 for cultivating plant comprises: an outer housing 102 having pillars 115, outer walls 103, and a roof 104; and an inner housing 109 having inner walls 110 and a ceiling 111 inside the outer housing 102, in which a cultivation chamber 114 for arranging a cultivation bed 301 mounting seeds of a plant thereon is provided inside the inner housing 109. An air layer 108 is provided between the outer housing 102 and the inner housing 109, the outer walls 103, the roof 104, the inner walls 110, and the ceiling 111 are formed of a three-layer plate 118 in which a heat insulation material layer 120 is arranged between two fiber-reinforced plastic layers 119, and the pillar 115 is formed of the fiber-reinforced plastic.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a system for cultivating plants, wherein the installation location is not restricted.

  Soil cultivation tends to be influenced by the weather, and there are restrictions such as the time of cultivation being limited and the selection of varieties suitable for the climate and soil of the area to be cultivated. Various hydroponic cultivation methods have been attempted to solve these limitations.

  Patent Document 1 describes shelter tunnel houses utilizing tunnels to avoid the effects of natural evil environment, human evil environment, natural disaster, human disaster, insect damage, bird damage, animal damage and the like. There is disclosed a plant factory which can grow by controlling the growth environment of the plant and can provide safe food and food products for the year.

  In Patent Document 2, a water tank including a culture necessary for growing a plant, a plant holding plate which holds a plant and is disposed over the water tank, a drainage portion for discharging a culture solution from the water tank, a water tank There is disclosed a hydroponic cultivation system comprising a water supply unit for supplying a culture solution, and a foamed resin house accommodating the hydroponic cultivation system.

JP, 2016-21879, A WO 2015/02282

  In the plant factory of Patent Document 1, a flat ground tunnel, a mountain tunnel, an underwater tunnel, etc. are constructed in an isolated place which is not easily affected by natural evil environment etc., and plants are cultivated in the tunnel. There is a problem that it can be set only by a specific operator, such as being able to dig a tunnel, and can not be easily set by anyone.

  The hydroponic cultivation system of Patent Document 2 has a problem that an apparatus for circulating the culture solution is required because the system is a system for supplying and discharging the culture solution to the water tank. Moreover, although the foamed resin house of Patent Document 2 can obtain a certain degree of heat insulation effect by using the foamed resin, it can not be said that it is sufficient, and since it is a foamed resin, it maintains high strength. There is a problem that you can not

  Therefore, an object of the present invention is to solve the above-mentioned problems and to provide a system for cultivating a plant whose installation location is not limited.

  According to one aspect of the invention, a system for cultivating a plant comprises a first housing having a pillar, an outer wall and a roof, and a second housing having an inner wall and a ceiling inside the first housing. And a second housing provided inside the second housing, wherein a cultivation room for placing a cultivation bed on which plant seeds are placed, a first housing and a second An air layer can be provided between the housings of the outer wall, the outer wall, the roof, the inner wall and the ceiling by means of a three-layer plate in which a heat insulating material layer is arranged between two fiber reinforced plastic layers The columns are formed of fiber reinforced plastic.

  According to one embodiment of the invention, in the system for cultivating a plant, one end of the post is in the form of a screw so that the first housing can be fixed relative to the installation surface.

  According to one embodiment of the present invention, in the system for cultivating a plant, the first housing comprises a ventilator.

  According to an embodiment of the present invention, in a system for cultivating a plant, a cultivation rack for arranging a cultivation bed may be installed in a cultivation room, and a pillar and a shelf of the cultivation rack are fibers. It is made of reinforced plastic.

  According to one embodiment of the present invention, in a system for cultivating a plant, a cultivation tank installable on a shelf plate includes a growing water for cultivating a plant and a culture bed floatable on the growing water. Can be housed, and the culture bed is provided with holes for placing seeds.

  According to one embodiment of the present invention, in a system for cultivating a plant, no growing water is injected into the cultivation tank when the plant is cultivated.

  According to one embodiment of the present invention, in a system for cultivating a plant, LED lighting arranged on a rack formed by a heat transfer material can be installed under a shelf board, and the LED lighting At least a portion is arranged to be embedded in the gantry.

  According to one embodiment of the present invention, in the system for cultivating a plant, a water temperature control heater for maintaining the temperature of the cultivating water at a constant level can be disposed in the cultivating water of the cultivation tank.

  According to one embodiment of the present invention, the system for cultivating a plant comprises a growing water generator containing a sintered body containing aluminum oxide and a Cretaceous deposit in a container, the growing water The water is generated by extracting the water injected from the input pipe of the growth water generator from the output pipe of the growth water generator through the container.

  According to one embodiment of the present invention, the system for cultivating the above plant can be configured by an assembly kit.

  According to the present invention, a system for cultivating plants can form a plant and crop breeding environment without restriction of installation location, and planned production and planned shipment of plants and crops throughout the year It can be performed.

  Other objects, features and advantages of the present invention will become apparent from the following description of embodiments of the present invention with reference to the attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view from above of a system for cultivating a plant according to an embodiment of the present invention. Figure 2 is a side view of the system of Figure 1; FIG. 3 is a cross-sectional view of the system of FIG. 1 as viewed in the direction of the arrow at line A-A of FIG. 2; 3 is a cross-sectional view of the system of FIG. 1 as viewed in the direction of the arrow at line B-B of FIG. 2; Figure 2 is a cross-sectional view of a three-layer plate used in the system of Figure 1; Figure 2 is a schematic view of one end of a post used in the system of Figure 1; It is the perspective view seen from the upper surface side of the cultivation shelf as one embodiment of the present invention. It is a side view at the time of installing a cultivation tank and illumination in the cultivation shelf of FIG. It is sectional drawing seen from the direction of the arrow in the CC line | wire of FIG. 8 of the cultivation shelf of FIG. It is a side view of a water temperature control heater which can be installed in a cultivation tank. It is sectional drawing seen from the direction of the arrow in the DD line of FIG. 10 of the water temperature management heater of FIG. It is the perspective view seen from the upper surface side of the cultivation bed as one embodiment of the present invention. It is a top view of the cultivation bed of FIG. It is sectional drawing seen from the direction of the arrow in the EE line of FIG. 13 of the cultivation bed of FIG. It is sectional drawing at the time of making the cultivation bed of FIG. 12 float on growth water, and setting a seed in the hole of a cultivation bed. It is a side view of a breeding water generator as one embodiment of the present invention.

  Examples of the present invention will be described below with reference to the drawings, but the present invention is not limited to these examples.

  One embodiment of a system for cultivating a plant of the present invention will be described with reference to FIGS. 1 to 15.

  1 to 4 show a system 101 for cultivating plants according to an embodiment of the present invention. The system 101 comprises an outer housing (first housing) 102 having a column 115, an outer wall 103 and a roof 104. The outer housing 102 may be provided with an eaves beam 106, a purlin 107 and a rafter 117 in order to strengthen its structure. If the width is less than 7.5 m, the beam 116 may not necessarily be provided, but if the width is 7.5 m or more or the structure is to be reinforced, the beam 116 may be provided. It may be Further, when the depth is 3 m or more, a rafter may be further provided between rafters 117 at both ends.

  The system 101 for cultivating plants comprises an inner housing (second housing) 109 having an inner wall 110 and a ceiling 111 inside the outer housing 102. Inside the inner housing 109, there is provided a cultivation room 114 for placing a cultivation bed on which plant seeds are placed. Similarly to the outer housing 102, the inner housing 109 may also include an eaves beam 112, a purlin 113, a pillar, a rafter, and the like. An air layer 108 can be provided between the outer housing 102 and the inner housing 109. The width of the air layer 108 (the distance between the outer housing 102 and the inner housing 109) depends on the size of the outer housing 102 and the inner housing 109, but is preferably 20 to 30 cm. Also, the outer housing 102 may include a ventilator 105 to facilitate ventilation between the air layer 108 and the outside, and the outer housing 102 may include an air inlet. The inner housing 109 may have an inlet and an outlet.

  FIG. 5 shows a three-layer plate 118 for forming the outer wall 103, the roof 104, the inner wall 110, and the ceiling 111. The three-layer plate 118 is structured such that the heat insulating material layer 120 is disposed between two plastic layers 119. Here, for the plastic layer 119, fiber-reinforced plastic (FRP) is used, and as FRP, carbon-fiber-reinforced plastics (CRP), glass There are fiber reinforced plastics (Glass-Fiber-Reinforced-Plastics: hereinafter, GFRP) and the like. FRP is lightweight as compared with iron, aluminum alloy, wood, etc., and is excellent in strength, corrosion resistance, thermal conductivity, heat resistance, thermal expansion, chemical stability, and as plastic layer 119 If FRP is used as the material, and the three-layer plate 118 has a three-layer structure of FRP layer 119-heat insulating material layer 120-FRP layer 119, it is covered by the outside air, outer wall 103, roof 104, inner wall 110, and ceiling 111. The heat insulation between the growing room 114 and the growing room 114 can be enhanced, and the temperature of the growing room 114 can be kept constant regardless of the outside air temperature. As a heat insulating material used for the heat insulating material layer 120, although there is a foam material, for example, it is not limited to this. The thickness of the FRP layer 119 may be, for example, 3 mm, but may be changed according to the use conditions of the three-layer plate 118, for example, the size of the outer wall 103, the roof 104, the inner wall 110, the ceiling 111, etc. it can. The thickness of the heat insulating material layer 120 may be, for example, 10 to 20 mm, depending on the use conditions of the three-layer plate 118, for example, the environment where the outer wall 103, the roof 104, the inner wall 110, the ceiling 111, etc. are disposed. It can be changed. Although the three-layer plate 118 is flat in FIG. 5, it may be corrugated. Furthermore, if the width of the air layer 108 between the outer housing 102 and the inner housing 109 is 20 to 30 cm, the heat insulation can be further enhanced. For example, even if the outside air temperature is as high as 40 ° C., the temperature of the cultivation room 114 can be maintained at 23 ° C. Further, FRP has a working temperature range of -40 to 150 ° C., and thus is sufficiently resistant to ordinary outside air temperatures.

  A post 115 for supporting the outer housing 102 is shown in FIG. The pillars 115 may be formed of FRP. By forming the columns 115 by FRP, the high strength of the outer housing 102 can be maintained. One end of the post 115 may be screw shaped 121 to allow the outer housing 102 to be fixed relative to the mounting surface. By forming the screw shape 121, the end of the screw shape 121 of the column 115 can be screwed into the installation surface, and the column 115 can be easily fixed to the installation surface. Further, by forming the columns 115 by FRP, it is possible to suppress heat conduction from the installation surface (for example, conduction of geothermal heat when the installation surface is the ground). When the pillars 115 are formed of a material having high thermal conductivity, heat is conducted from the installation surface to the cultivation room 114 via the pillars 115, and the temperature of the cultivation room 114 changes, and cultivation is carried out in the cultivation room 114 Although it affects plants, if the columns 115 are formed of FRP having low thermal conductivity, it is possible to suppress the temperature change of the cultivation room 114 due to the installation surface. As a pillar for supporting the inner housing 109, one having a structure similar to that of the pillar 115 of the outer housing 102 may be used. In addition, the eaves beams 106 and 112, the purlins 107 and 113, the beams 116, the rafters 117, and the like may be formed of FRP.

FIGS. 7 to 9 show schematic diagrams in the case of cultivating plants using the cultivation shelf 201 according to an embodiment of the present invention and the cultivation shelf 201. FIG. The cultivation shelf 201 is installed in the cultivation room 114, and includes a support column 202, a bottom plate 203, a shelf plate 204, and a top plate 205. The support column 202, the bottom plate 203, the shelf plate 204, and the top plate 205 may be made of plastic, in particular, FRP. By forming the pillars 202, the bottom plate 203, the shelf plate 204, and the top plate 205 with FRP, high strength of the cultivation shelf 201 can be maintained, and heat conduction from the installation surface of the cultivation shelf 201 can be suppressed. Can. In addition, although the cultivation shelf 201 of FIGS. 7-9 is a multistage type provided with the one baseplate 203 and the one shelf board 204, the cultivation shelf 201 is a multistage type further equipped with the at least 1 or more shelf board 204. It may be. By a multistage cultivation rack 201, to improve the productivity of the plant cultivation per 1 m ^2, and more, in plant cultivation, work safety, efficiency of the work is suitable for continuity of work, The cultivation rack 201 can be installed even in a narrow place. In addition, the number of stages of the cultivation shelf 204 may be set according to the plant to be cultivated, and when the plant to be cultivated is large, the cultivation shelf 201 may be a single-stage type (in the case of a single-stage type, the bottom plate 203). Is the shelf board 204). Moreover, the size of the cultivation shelf 201 may also be set according to the plant to be cultivated.

  The bottom plate 203 and the shelf 204 of the cultivation shelf 201 can install the cultivation tank 206 thereon. In the cultivation tank 206 installed on the bottom plate 203 and the shelf plate 204, cultivation water 209 for cultivating a plant can be accommodated, and a cultivation bed 301 capable of floating on the cultivation water 209 can be accommodated. The cultivation bed 301 is provided with holes for placing seeds of plants to be cultivated. When the plants are hydroponically grown, the growing water 209 is injected into the culture tank 206, the injected growth water 209 is discharged through the culture tank 206, and the discharged culture water 209 is further cultured. It may be a circulating hydroponic culture in which it is injected into 206, but even if it is an anhydrous flow type in which the growing water 209 is not injected into the culture tank 209 when the plant is hydroponically grown. Good. In the case of using an anhydrous flow method, when setting the seeds of the plant to be grown in the pores of the culture bed 301, the growing water 209 is accommodated in the culture tank 206. By using an anhydrous flow system, hydroponic culture can be easily and inexpensively performed.

  Under the shelf plate 204 and the top plate 205, the illumination 208 disposed on the gantry 207 may be installed. By providing the light 208, the amount of light necessary for the plant to be grown can be artificially applied to promote plant growth. In addition, since the plant to be grown will burn if the distance between the light 208 and the culture floor 301 is too short and the illuminance of the light 208 is too large, depending on the plant to be grown, the light 208 and the culture floor 301 The distance between them and the illuminance of the light 208 are set as appropriate. In order to suppress the temperature rise due to the heat generation in the cultivation room 114, it is preferable that the illumination 208 be capable of illuminating a plant with low power consumption, for example, LED illumination is desirable. The color of the light emitted by the illumination 208 is not particularly limited, but may be determined according to the plant to be grown. For example, it may be white. The illumination 208 may be arranged such that at least a portion thereof is embedded in the gantry 207. By embedding at least a part of the illumination 208 in the pedestal 207, the contact area between the pedestal 207 and the illumination 208 is increased, and if the pedestal 207 is made of a material having high thermal conductivity, the heat generated by the illumination 208 is generated. Can be efficiently dissipated, the illuminance of the illumination 208 can be held constant, and the life of the illumination 208 can be extended. As a material which comprises the mount frame 207, there exists aluminum, for example. If the mount 207 is made of aluminum, the weight of the mount 207 can be reduced.

  The water temperature control heater 210 is shown in FIG. 10 and FIG. In winter and the like, the outside air temperature is lowered, and accordingly, the temperature of the breeding water 209 is lowered to affect the growth of a plant that absorbs the breeding water 209 from the roots. Therefore, in order to keep the temperature of the growth water 209 constant, the water temperature control heater 210 may be disposed in the growth water 209 of the cultivation tank 206. The water temperature control heater 210 includes a heater main body 211 and a cover 212 surrounding the heater main body 211. The cover 212 is formed in a mesh shape and may be formed of plastic. By surrounding the heater main body 211 by the cover 212, even if a plant grower accidentally touches the water temperature control heater 210, the plant grower can be protected from burns and the like. Also, although a thermostat is usually attached to the heater main body 211, a person who grows plants takes out the water temperature management heater 210 from the culture tank 206 and leaves the water temperature management heater 210 in a state where the heater main body 211 is turned on. In order to prevent a fire by continuing the operation, the heater main body 211 may be controlled without using a thermostat. If the temperature of the heater main body 211 continues to rise by not using the thermostat, the heater main body 211 is broken, but if it is broken, a fire can be prevented.

  FIG. 12 shows a cultivation bed 301, which can be used in the system 101 for cultivating a plant of the present invention, viewed obliquely from above. The cultivation bed 301 is composed of a flat main body 302. The main body 302 is made of a material capable of floating in the growing water 209 in which the culture bed 301 is disposed, in order to simplify the working process of hydroponic culture. For example, body 302 is manufactured from wood, plastic, foam, and the like. The main body 302 has a first surface 303 on the upper surface side on which seeds are placed, and a second surface 304 on the lower surface side in contact with the growing water 209. Further, the main body 302 is provided with a hole 305 penetrating from the first surface 303 which is the upper surface side to the second surface 304 which is the lower surface side so that the seeds can be set. The body 302 can also be provided with a plurality of holes 305 so that a plurality of seeds can be set and cultivated, whereby many seeds can be planted simultaneously in a small space. In addition, although the shape of the hole 305 is set as circular in FIG. 12, it is not restricted to this, It may be set as another polygon, an ellipse, etc., It is set so that the shape of a seed may be fitted May be

  The cultivation bed 301 seen from the upper surface side is shown in FIG. A plurality of holes 305 are provided in the main body 302 of the cultivation bed 301, and seeds for hydroponic cultivation are set in a first region 306 in contact with the first surface 303 of each hole 305. Examples of seeds to be placed include seeds of the genus Allium such as garlic flakes, bamboo flakes, onion seedlings, and the like.

  The cultivation bed 301 of the cross section seen from FIG. 14 from the direction of the arrow in the EE line of FIG. 13 is shown. Further, FIG. 15 shows a culture bed 301 which is floated on growth water 209 and seeds 309 are set in holes 305. The holes 305 pass from a first area 306 in contact with the first surface 303 to a second area 308 in contact with the second surface 304 via the intermediate area 307. The radius of the hole 305 decreases from the first surface 303 toward the intermediate region 307 in the first region 306. If the radius of the hole 305 is constant from the first surface 303 to the second surface 304, if the radius and size of the hole 305 are not the same seed 309 (especially the seed 309 larger than the radius of the hole 305) in the hole 305 Although it can not be accommodated, by reducing the radius of the hole 305 in the first area 306 from the first surface 303 toward the intermediate area 307, the seed 309 differs in the radius and size of the hole 305, Also, it is possible to accommodate in the first area 306 of the hole 305 (in particular even the seeds 309 which are larger than the radius in the middle area 307 with the smallest radius). The radius of the hole 305 may be linearly reduced from the first surface 303 towards the intermediate region 307 in the first region 306 to facilitate the drilling process for the body 302. Also, the shape of the hole 305 may be a substantially truncated cone such as a mortar shape in the first region 306.

  The dimensions of the first area 306 of the hole 305 may be set according to the type of seed 309. When large seeds 309 are placed in the first area 306 and cultivated, large perforations are made in the first area 306 to match the large dimensions of the seeds 309 in the main body 302, and the small seeds 309 are When growing in the area 306 of 1, the main body 302 may be small and perforated in the first area 306 to match the small dimensions of the seed 309.

  The radius of the hole 305 may be constant in the middle region 307. The radius of the intermediate region 307 may be set to allow the seeds 309 to be sorted by their size. Seeds 309 having a size smaller than the radius of the set middle area 307 can not pass through the middle area 307 and fall into the growing water 209 and can not be cultivated. The dimensions of the seeds 309 can be sorted.

  The radius of the hole 305 increases from the middle area 307 to the second surface 304 in the second area 308. When the radius of the hole 305 is constant in the middle area 307 and the second area 308, the root 310 of the seed 309 can only grow downward from the lower end of the seed 309 and absorbs water sufficiently from the growth water 309 Because of the inability to grow, the growth of seeds 309 is delayed. Therefore, by making the radius of the hole 305 in the second region 308 larger than the radius of the hole 305 in the intermediate region 307 and further increasing from the intermediate region 307 toward the second surface 304, the root 310 of the seed 309 is obtained. The seed 309 can be grown not only downward but also obliquely downward from the lower end of the seed 309, and water can be sufficiently absorbed from the growth water 209, so that the growth of the seed 309 can be accelerated. The radius of the hole 305 may be made to increase linearly in the second region 308 from the intermediate region 307 towards the second surface 304 to facilitate the drilling process for the body 302. Also, the shape of the hole 305 may be a substantially truncated cone such as a mortar shape in the second region 308.

  When the culture bed 301 is placed on the growth water 209 and the seeds 309 are placed in the holes 305 of the culture bed 301, the weight of the culture bed 301 and the seeds 309 sinks the lower part of the culture bed 301 into the growth water 209, At least a part of the second area 308 of the hole 305 is flooded with the growing water 209, and the water surface of the growing water 209 rises in the second area 308. In addition, the surface of the growing water 209 also rises in the second region 308 due to the surface tension of the growing water 209. When the height of the second region 308 is large, the water surface of the growing water 209 does not reach the lower end of the seed 309, so the seed 309 can not sufficiently absorb water from the growing water 209. In addition, when the height of the second region 308 is small, the water surface of the growing water 209 reaches the intermediate region 307 and further to the first region 306, and the contact surface between the seed 309 and the growing water 209 becomes wide. 309 may be corrupted. Therefore, the height of the second region 308 of the hole 305 is such that at least a part of the second region 308 is submerged by the growing water 209 and the growing water 209 reaches the lower end of the seed 309 and only the lower end of the seed 309 is grown It may be set to be able to contact the water 209.

When hydroponically cultivating garlic flakes as seeds 309 in the first region 306 of the hole 305 of the cultivation bed 301, the main body 302 of the cultivation bed 301 may be manufactured from a foam material; The body 302 may be provided with a plurality of holes 305 by a drilling process, and garlic clove pieces may be placed in the first region 306 of each hole 305. In this case, the size of the hole 305, with reference to FIG. 14, the upper end diameter phi ₁ of the first region 306 is 29 mm, (the diameter of the intermediate region 307) a lower end diameter of the first region 306 phi ₂ is 20mm , the upper end diameter phi ₃ of the second region 308 is 26 mm, bottom diameter phi ₄ is 28mm in the second region 308, the height _{h 1} of the first region 306 is 16 mm, the height _{h 2} of the intermediate region 307 is 5mm , the height _{h 3} of the second region 308 is set to be 9 mm, the thickness of the body 302 may be 30 mm. By setting the size of the hole 305 in the main body 302 of the culture bed 301 in this manner, garlic flakes can be placed on the first region 306 in a short time and easily, and the radius of the hole 305 in the intermediate region 307 As smaller garlic flakes pass through the middle region 307, only garlic flakes larger than the radius of the hole 305 in the middle region 307 can be selected and cultivated, and further, the second region 308 is grown by the growing water 209. Since the bottom of the garlic flakes reaches the lower end of the garlic flakes and only the lower ends of the garlic flakes can be brought into contact with the growing water 209, the cultivation bed 301 can be used to hydroponically grow garlic.

  FIG. 16 shows a growing water generator 401 for generating the growing water 209 stored in the growing tank 206 as an embodiment of the present invention. The growth water generator 401 is provided with a container 402. In the container 402, a sintered body 406 containing aluminum oxide (alumina) and deposits such as Cretaceous shell layers is accommodated. The sintered body 406 is sintered using hydrogen in the range of 1200 to 1400 ° C. Water 405 such as tap water, drinking water, etc. is injected into the container 402 from the input pipe 403 of the growth water generator 401 and passed through the container 402 containing the sintered body 406, and the output pipe 404 of the growth water generator 402 The breeding water 209 is produced | generated by extracting from. The breeding water 209 generated in this manner is weakly alkaline, has antifungal activity, and can maintain the water quality. Therefore, by using the growing water 209 generated in this manner, hydroponic culture can be performed by an anhydrous flow method without adopting a water flow type in which the growth water 209 is injected into the culture tank 206 and discharged. it can.

  Also, the outer housing 102, the inner housing 109, and the growing shelf 201 of the system 101 for cultivating a plant may be manufactured and sold as a kit that can be assembled by a planter. By making the system 101 into an assembly kit, a plant grower can assemble the system 101 easily and inexpensively at the installation site.

  Although the above description has been made for a specific embodiment, it will be apparent to those skilled in the art that the present invention is not limited thereto and that various changes and modifications can be made within the principles of the present invention and the appended claims. is there.

DESCRIPTION OF SYMBOLS 101 System for growing a plant 102 Outer housing 103 Outer wall 104 Roof 105 Ventilator 106 Eaves 107 Vulture 108 Air layer 109 Inner housing 110 Inner wall 110 Ceiling 112 Eaves 113 Vulture 114 Cultivation room 115 Column 116 Beam 117 Rafter 118 119 plastic layer 120 heat insulating material layer 121 screw shape 201 cultivation shelf 202 support 203 bottom plate 204 shelf plate 205 top plate 206 cultivation tank 207 gantry 208 illumination 209 growing water 210 water temperature control heater 211 heater main body 212 cover 301 cultivation floor 302 main body 303 first 1 Surface 304 Second surface 305 Hole 306 First region 307 Intermediate region 308 Second region 309 Seeds 310 Roots 401 Breeder for water production 402 Container 403 Input tube 40 Output tube 405 of water 406 sintered

Claims (10)

A system for cultivating plants,
A first housing having a column, an outer wall, and a roof;
A second housing having an inner wall and a ceiling inside the first housing, wherein a cultivation room for arranging a culture bed on which the seeds of the plant are placed is provided inside the second housing And a second housing,
An air layer can be provided between the first housing and the second housing,
The outer wall, the roof, the inner wall, and the ceiling are formed by a three-layer plate in which a heat insulating material layer is disposed between two fiber reinforced plastic layers, and the pillars are formed of fiber reinforced plastic. system.   The system according to claim 1, wherein one end of the post is screw shaped to allow the first housing to be fixed relative to the mounting surface.   The system of claim 1, wherein the first housing comprises a ventilator.   The cultivation shelf for arrange | positioning the said cultivation bed can be installed in the said cultivation room, The support | pillar and shelf board of the said cultivation shelf are formed of fiber reinforced plastic. The system according to one item.   A cultivating water for cultivating the plant and the cultivating bed capable of floating on the cultivating water can be accommodated in the cultivating tank which can be installed on the shelf plate, and the cultivating bed can contain the cultivating floor. 5. The system according to claim 4, wherein a hole is provided to set the seed.   The system according to claim 5, wherein the growing water is not injected into the culture tank when the plant is grown.   LED lighting disposed on a pedestal formed of a heat conductive material may be disposed under the shelf, wherein at least a portion of the LED lighting is disposed to be embedded in the pedestal. A system according to claim 5 or 6.   The system according to any one of claims 5 to 7, wherein a water temperature control heater for maintaining the temperature of the growing water constant may be disposed in the growing water of the cultivation tank.   A growing water generator containing a sintered body containing aluminum oxide and a Cretaceous deposit in a container, the growing water containing water injected from the input pipe of the growing water generator being the container 9. A system according to any of the claims 5-8, which is produced by extracting from the output pipe of the growth water generator through.   The system according to any one of the preceding claims, which can be constituted by an assembly kit.