JP4101272B2 - Plant growing system, plant growing plant, and plant growing method - Google Patents

Description

The present invention relates to a plant growing technique for growing plants such as vegetables by hydroponics, and particularly relates to a plant growing system, a plant growing plant, and a plant growing method using sunlight and artificial light in combination.

Conventionally, as a system for hydroponically cultivating plants such as vegetables, a system that uses only artificial light or a system that uses sunlight and artificial light in combination is known.
These are cultivated using one-stage panels, etc., which are arranged in a mountain shape with the growth panel planted with vegetables etc. horizontal to the ground or inclined at about 40 degrees to the ground. There was a problem that the harvesting efficiency per ² was low and the production efficiency was very bad.

On the other hand, the inventor of the present application dramatically increases the cultivation density by vertically configuring the cultivation panels to reduce the cultivation cost ("ultra-high density plant vertical mist hydroponic system"). (Refer to Patent Document 1).

Japanese Patent No. 3320707

The technique described in Patent Document 1 has been actually implemented, and it has been confirmed that the production efficiency can be greatly improved as compared with the conventional system. However, at the production site, the production efficiency can be further improved. It has been desired.

Therefore, the inventor of the present application has further earnestly studied and has come up with the present invention, and the present invention can further improve the production efficiency, particularly in the plant breeding technology using both sunlight and artificial light. An object of the present invention is to provide a plant growing system, a plant growing plant, and a plant growing method that can be achieved.

In order to solve the above-mentioned problems, the plant growing system according to claim 1 is a plant growing system for growing a plant by hydroponics using both sunlight and artificial light, and is hollow cylindrical. A growth tower having a cultivation floor on which plants are planted, which is configured to be rotatable about an axis and is set up substantially vertically so as to be able to irradiate sunlight, and arranged in a ring shape along a predetermined arc; A mist nozzle that sprays liquid fertilizer on the plant root exposed on the inner peripheral surface side of the cultivation floor, and a growth lamp that is arranged in the arc and radiates artificial light radially outward. , While rotating the cultivation floor around the axis and revolving on the arc, toward the plants planted on the cultivation floor, sunlight and artificial light by the growing lamp, respectively, It is necessary to irradiate from the inside. To.

Further, in the plant growing system according to claim 2, in the configuration according to claim 1, the lower end of the growing tower is rotatably supported by a pivot so that the growing tower can be laid down substantially horizontally. The summary is what was done.

The plant growing system according to claim 3 is a plant growing system for growing a plant by hydroponically cultivating a plant using sunlight and artificial light in combination, and rotates around an axis in a hollow cylindrical shape. Liquid fertilizer is sprayed onto a growth tower having a cultivation floor on which plants are planted, which is set up substantially vertically so that sunlight can be irradiated, and a plant root exposed on the inner peripheral surface side of the cultivation floor. A mist nozzle and a growth lamp that sequentially irradiates artificial light from a certain direction toward the plant planted on the cultivation floor as the cultivation floor rotates, and the lower end of the growth tower rotates around the pivot The gist is that the growth tower is supported in such a manner that it can be laid down substantially horizontally.

Moreover, the plant growth system of Claim 4 is a structure in any one of Claims 2 thru | or 3. For growing the seedling of the plant planted in this cultivation floor on the side which lays down this growth tower The gist is that the nursery bed is movably disposed.

Moreover, while the plant growing plant of Claim 5 is provided with the plant growing system of the structure in any one of Claims 1 thru | or 4,
The gist of the invention is that it is covered with a roof and an outer wall that allow sunlight to pass therethrough.

The plant growing method according to claim 6 is a plant growing method for growing a plant by hydroponically cultivating the plant using sunlight and artificial light in combination, and rotates around an axis in a hollow cylindrical shape. The cultivated floor on which the plant is planted is erected substantially vertically so as to be able to irradiate sunlight, and is arranged annularly along a predetermined arc, and the cultivated floor is rotated about the axis, and While revolving on the arc, while spraying liquid fertilizer on the plant root exposed on the inner peripheral surface side of the cultivation floor, toward the plants planted on the cultivation floor, sunlight and artificial light, The gist is that irradiation is performed from the outside and the inside.

According to the present invention, a growth tower having a cultivation floor on which a plant is planted, which is formed in a hollow cylindrical shape and is rotatable about an axis, and is erected substantially vertically so as to be able to irradiate sunlight, A mist nozzle that sprays liquid fertilizer on the plant root exposed on the inner peripheral surface side, and a growth that sequentially irradiates artificial light from a certain direction toward the plant planted on the cultivation floor as the cultivation bed rotates Therefore, it is possible to further improve the production efficiency when plants such as vegetables are cultivated by hydroponics, using both sunlight and artificial light.

  The present invention is for growing plants by hydroponics using both sunlight and artificial light. Plants that can be targeted are mainly vegetables, especially leaf vegetables, but lettuce and salad vegetables are particularly preferred. In addition, fruits and vegetables such as strawberries can be cultivated.

  The plant growing system according to the present invention mainly includes a growing tower, a mist nozzle, and a growing lamp. Moreover, the plant growth plant which concerns on this invention provides this system, and is comprised.

The growing tower has a cultivation floor for planting plant seedlings and growing the seedlings until the crop can be harvested. The cultivation floor has a hollow cylindrical shape that can be rotated around the axis and is erected substantially vertically so that sunlight can be irradiated.
It is suitable that the cultivation floor has a diameter of about 1.2 to 1.5 m and a total length of about 6 to 12 m from the viewpoint of the degree of aggregation and workability. The material for the cultivated floor is not particularly limited, but a material having excellent durability and water resistance and excellent rigidity is preferable. Generally, a galvanized steel sheet or the like is used.

A plant is planted on the cultivation floor so that the plant grows obliquely upward along the outer peripheral surface of the cultivation floor, and the plant root is exposed on the inner circumferential surface side of the cultivation floor. .
Planting is usually carried out through a pot, and the pot is supported on the cultivation floor by an installation interval corresponding to the strain required for the plant to be cultivated.

The mist nozzle is provided inside the cultivation bed having a hollow cylindrical shape, and sprays and supplies the necessary liquid fertilizer to the plant roots exposed along the inner peripheral surface of the cultivation bed. Liquid fertilizer is usually supplied mixed with water.
The mist nozzle may be one in which a large number of nozzles are fixed in a plurality of stages, and for example, one or a plurality of nozzles are arranged so as to be movable in the axial direction in the cultivation bed by motor control. It may be done.

The growth lamp irradiates artificial light effective for plant growth toward the plant planted on the cultivation floor to compensate for the lack of sunlight. The cultivating lamp is arranged and fixed at a position separated from the cultivated floor by a predetermined distance so as to irradiate a certain area of the cultivated floor that is erected. It is configured to irradiate artificial light sequentially toward the plant. The other areas of the cultivation floor that are not irradiated with artificial light are irradiated with sunlight.

Generally, a plurality of rod-shaped lamps are connected and used as the growth lamp, but the connection mode may be either vertical or horizontal. The growing lamp is preferably provided so as to irradiate evenly from the upper end to the lower end of the cultivation floor so that uniform illuminance can be obtained at each irradiation site.
Moreover, it is preferable to provide a cover formed of a transparent acrylic plate or the like so that the fertilizer sprayed from the mist nozzle is not applied to the growth lamp.

As the growth lamp, a fluorescent lamp, a high pressure sodium lamp, a light emitting diode, or the like can be used without limitation. In general, light-emitting diodes are preferable because they have a lower voltage and a lower calorific value than fluorescent lamps, and do not fear that they will die even when they are close to crops.
Growing lamps are long-lasting and use less labor when considering use in large-scale plants, small heat generation to reduce the air conditioning load, and when considering space saving, Even if it installs adjacently, the thing with a small emitted-heat amount and the thing which can perform proximity illumination are preferable.

Plants have chlorophyll (photosynthetic pigment) in their cells, but the absorption spectrum of chlorophyll is visible light blue of 400 to 500 nm and visible light red of 600 to 700 nm. That is, blue light and red light play an important role in plant photosynthesis.
From this point of view, the growth lamp preferably has a wavelength peak in blue light (especially around 440 nm) and red light (especially around 660 nm).

When a fluorescent lamp is used as a growth lamp, a phosphor is applied to the inside of the tube, and external electrodes are provided on both electrodes outside the tube, and plasma discharge is generated inside the tube by applying high frequency and high voltage thereto. Those having a structure in which the fluorescent pigment is caused to emit light are preferable. A normal fluorescent lamp is provided with an electrode inside the tube, and the electrode is consumed every time it emits light, so its life is short and the amount of heat generation is large. It is suitable for use in the present invention because the temperature is about 38 ° C., the amount of heat generation is small, and it is cheaper than a light emitting diode.

A first embodiment of the present invention will be described with reference to FIGS. This example shows one embodiment of a plant growing plant provided with a plant growing system according to the present invention. FIG. 1 is a plan view of the plant growing plant, FIG. 2 is a side sectional view of the plant growing plant, FIG. 3 is a front elevation view of the plant growing plant, and FIG. 4 is an enlarged end view of the main part of the growing tower. FIG. 5 is a partial cross-sectional side view of the growth tower showing another embodiment of the mist nozzle, and FIG. 6 is a cross-sectional view taken along line A to A ′ in FIG. 5.

  As shown in FIG. 1 to FIG. 3, the plant growing plant (1) according to the present embodiment is rectangular in plan view, and a glass roof (40) having an arch shape from the rear upper part toward the front lower part is laid. It is configured to exhibit a substantially quarter circle shape in a side view, and has a relatively large scale having a width of about 11.5 m, a depth of about 13 m, and a height of about 11 m. The plant growing plant (1) mainly includes a growing tower (2), a mist nozzle (3), a growing lamp (4), a seedling bed (5) and the like.

As shown in FIG. 4, the growing tower (2) has a cultivation floor (10) on which a plant (7) can be planted. The cultivation floor (10) has a hollow cylindrical shape having a diameter of about 1.3 m and a total length of 8 m, and is erected upward from about 1.8 m above the ground as shown in FIG. As shown in FIG. 1, in this embodiment, four growth towers (2) are arranged adjacent to one horizontal row with an appropriate interval.
In addition, as shown in FIG. 2, the cultivation bed (10) is connected to the motor (11) via a rotation gear (12) (consisting of a motor direct connection gear, a reduction gear, and a growth tower shaft gear). P) It is configured to rotate slowly around, for example, at a speed of one round in 2.5 minutes. The cultivation floor (10) can be rotated not only in one direction but also in both directions.

As shown in FIG. 4, the cultivation floor (10) has a corrugated pipe shape obtained by processing a steel plate into a corrugated shape, and ribs (13) are formed in multiple stages along the axial direction. In this embodiment, the wave pitch is 150 mm and the wave depth is 60 to 75 mm, but these may be appropriately changed depending on the plant to be cultivated. On both inner and outer peripheral surfaces of the cultivation floor (10), 900 g or more of hot dip galvanizing is applied per 1 m ² for improving corrosion resistance.

As shown in FIG. 4, an obliquely inclined planting surface (14) is formed on each stage of the cultivation floor (10), and a pot receiving hole (15) is formed in the circumferential direction on the planting surface (14). While being drilled at an appropriate interval, the pot (16) is supported by the pot receiving hole (15). The pot (16) is an inverted conical shape whose bottom is open and whose tip is cut, and is a container for accommodating and cultivating plant seedlings together with cultivation soil. As shown in FIG. 4, the plant root (8) penetrates the pot (16) and is exposed on the inner peripheral surface side of the cultivation floor (10).

  The pot receiving hole (15) for receiving the pot (16) should have an angle from the horizontal so that the pot (16) does not fall when the pot (16) is inserted. Specifically, it is preferable that the pot (16) is arranged at an angle of at least 20 to 50 degrees with respect to the horizontal plane. If this angle exceeds 50 degrees, the degree of aggregation does not increase, and if it is less than 20 degrees, the drop of the plant (7) from the pot (16) and the drooping shape of the grown plant (7) become conspicuous. Absent. If it is a cultivation floor (10) of the shape shown in the present embodiment, this angle can be easily maintained.

  As shown in FIG. 2, the growth tower (2) has a lower end supported by a pivot (19) and is configured to be rotatable up and down around the pivot (19). (2) can be tilted forward and substantially horizontally. Thereby, planting and harvesting of the seedling of the plant (7) can be performed easily. And as shown in FIGS. 1-2, the plant growth plant (1) has the space where the growth tower (2) can be laid down forward each.

  As shown in FIG. 2, a growth tower shaft roller (20) is provided at the upper end of the growth tower (2), and the growth tower shaft roller (20) follows a trajectory drawn by the upper end of the growth tower (2). Guided by an arched guide rail (21), the other end of the wire (23) having one end connected to the winch (22) is fixed to the upper end of the growth tower (2). The traction of the wire (23) is controlled by the winch (22). In FIG. 2, the tension roller (24) is used to guide the wire (23).

As shown in FIG. 4, the mist nozzle (3) is located at an appropriate position along the liquid fertilizer supply pipe (30) disposed in line with the axis (P) in the cultivation bed (10). The liquid fertilizer that is formed through the liquid fertilizer supply pipe (30) is sprayed periodically in a necessary amount toward the plant root (8) exposed on the inner peripheral surface side of the cultivation floor (10). To do.
The mist nozzle (3) is arranged so as to spray liquid manure in two to four directions in plan view, and the spray angle of the nozzle is adjusted so that the liquid manure can be sprayed evenly on the plant roots (8) of each stage. ing. Moreover, the mist nozzle (3) is controlled to spray liquid fertilizer intermittently, for example, spraying for 5 minutes at intervals of 20 minutes.
5 to 6 show other forms of the mist nozzle. Thus, if a relatively large mist nozzle (3 ′) is used, the number of nozzles can be reduced.

As shown in FIGS. 1 to 2, the growing lamp (4) is a series of rod-shaped fluorescent lamps stacked in series at an appropriate interval corresponding to the height position of the cultivation floor (10). It is placed along the inner surface of the arcuate wall (32) arranged in a subarc shape so as to form a part of a circular arc concentric with the cultivation floor (10) at the rear of the growth tower (2). . As a result, the growing lamp (4) irradiates a certain area of the cultivated floor (10) which is erected, and is directed toward the plant (7) planted on the cultivated floor (10) rotating around the axis (P). Thus, artificial light can be irradiated sequentially.
The said fixed area | region which a growth lamp (4) irradiates is an area | region part equivalent to 30 to 50% of the total surface area of a cultivation floor (10) from a viewpoint of synergistic utilization of both sunlight and artificial light. Is preferred.

As shown in FIG. 1, the arcuate wall (32) is connected in a horizontal row in the adjacent direction of the growth tower (2), and is connected to the side wall (33) and further to the rear wall (34) at both left and right ends. ing. The arc-shaped wall (32), the side wall (33), and the rear wall (34) are integrally formed by an RC wall. Note that it is preferable to finish the inner surface of the arc-shaped wall (32) with a material having a high reflectivity such as a mirror surface material because the irradiation efficiency can be improved.
The growing lamp (4) is appropriately lit at night or in the daytime from autumn to spring to compensate for the lack of sunlight.
In this embodiment, artificial light irradiation by the growth lamp (4) and spraying of liquid fertilizer by the mist nozzle (3) are automatically controlled by a computer optimally programmed according to the plant (7) to be cultivated. It is made to do.

As shown in FIGS. 1 to 2, the nursery bed (5) is disposed in a space in front of the standing growth tower (2). The seedling raising bed (5) is for growing seedlings that can be planted on the cultivation floor (10) by seeding the plant (7).
As shown in FIG. 1 to FIG. 2, the seedling bed (5) has a shape in which the seedling tray is placed substantially horizontally on the leg, and is parallel to the adjacent direction of the growing tower (2), Each is configured to be movable on the bed rail (37). As shown in FIG. 2, a mist piping hose (38) is connected to the seedling bed (5) so that necessary liquid fertilizer can be sprayed onto the seedlings in the seedling tray.
As the seedling bed (5), for example, a pot in which slits and meshes are appropriately provided on the side surface or the bottom surface can be used, which is arranged and fixed in advance in the tray. It is preferable that a large amount can be grown.

Moreover, as shown in FIGS. 1-3, the plant growing plant (1) is covered with the glass roof (40) and glass wall (41) with an aluminum frame so that sealing is possible, and sunlight is received. It is designed to be able to capture as much as possible. In addition to the glass plate, an acrylic plate or the like may be used as long as it can transmit necessary sunlight.
Needless to say, the plant growing plant (1) can adjust the indoor temperature, humidity, CO ₂ concentration, and the like as necessary.

An example of a usage mode of the plant growing plant (1) configured as described above will be described below.
First, seed the plant (7) on the seedling bed (5) and grow it into a seedling suitable for hydroponics. This growing period is usually about two weeks, although it varies somewhat depending on the type of plant.
Next, the growth tower (2) is laid down, and the seedling of the grown plant (7) is planted on the cultivation floor (10). At this time, since the nursery bed (5) is configured to be freely movable, the nursery bed (5) can be placed immediately next to the lying growth tower (2), and the seedling of the plant (7) Planting is easy.
In addition, each pot receiving hole (15) in the cultivation floor (10) is provided with one or a plurality of spring-loaded pressing metal fittings (not shown) so as to protrude and retract in the hole, and the pot (16 ) Is inserted into the pot receiving hole (15), the press fitting presses the side surface of the pot (16) according to the urging force of the spring so that the pot (16) does not fall from the pot receiving hole (15).

When planting of the seedling of the plant (7) is completed, the growth tower (2) is erected. And as above-mentioned, while rotating a cultivation floor (10) around an axis (P), while spraying liquid manure from a mist nozzle (3), it irradiates sunlight and artificial light by a growth lamp (4) The planted plant (7) is cultivated and grown until the crop can be harvested. This growing period is usually about two weeks, although it varies somewhat depending on the type of plant.
The crop may be harvested by turning the growth tower (2) over again.

According to the present Example, a plant (7) can be cultivated and bred using sunlight and artificial light effectively together. Moreover, since the cultivation floor (10) was made to stand vertically, a plant (7) can be raised efficiently with a fixed land area, and it becomes possible to improve a production efficiency markedly. For example, compared with the case where the vertical panel format (patent 3320707 etc.) which has a width equal to the diameter of the cultivation bed (10) of a present Example is used, a cultivation area can be made about 3 times.
In addition, in the plant growing plant (1) as in this example, vegetables and the like having a certain quality can be supplied in a short period of time and in a stable manner, so that not only ordinary households but also the restaurant industry. It can also be expected to make a great contribution to the demand for

A second embodiment of the present invention will be described with reference to FIGS. This embodiment shows a modification of the previous embodiment.

In the present embodiment, as shown in FIG. 2, a solution tank (50) and a filtration tank (51) are embedded under the floor, and the liquid fertilizer stored in the solution tank (50) is mist pipe (53). , And the mist pipe (54) and the mist pipe hose (38), respectively, are sent to the growing tower (2) and the seedling bed (5), and the surplus liquid fertilizer is passed through the drain pipe (57), It is collected in the filtration tank (51).
The liquid fertilizer collected in the filtration tank (51) is filtered and then transferred to the solution tank (50) so that the surplus liquid fertilizer can be effectively circulated and used.

Furthermore, in this example, as shown in FIGS. 1 to 2, curtain rails (59) and (60) are provided at positions surrounding the growing tower (2), and the cultivation bed is suspended from the insulating curtain. By covering (10), a heat insulating wall can be formed to easily improve the air conditioning efficiency.
As described above, the present invention can be implemented in a mode in which various modifications are made without departing from the gist of the present invention.

A third embodiment of the present invention will be described with reference to FIGS. The present embodiment shows another embodiment of the plant growing plant provided with the plant growing system according to the present invention. 7 is a plan view of the plant growing plant, FIG. 8 is a side sectional view of the plant growing plant, and FIG. 9 is a front view of the plant growing plant.
In addition, description is abbreviate | omitted about the structure which is common in Example 1,2.

As shown in FIGS. 7 to 9, the plant growing plant (70) according to the present embodiment grows a growing space (71) for cultivating and growing plants, plant seedlings, or harvests cultivated crops. And a seedling raising / harvesting space (72) for the purpose, and mainly comprises a growth tower (75), a mist nozzle (76), a growth lamp (77), a seedling bed (78) and the like.

As shown in FIGS. 7 to 9, the growing space (71) is formed by laying a dome roof on a relatively large cylinder having a diameter of about 15 m, and has a height of about 15 m at the top. Further, as shown in FIGS. 7 to 9, the seedling / harvest space (72) extends forward from one side of the growth space (71) and has a substantially convex shape in a sectional view with the lower part widened. The central protruding portion is formed so as to form an arch shape as shown in FIG. 8 in a side view.
As shown in FIGS. 7 to 9, the growing space (71) and the seedling / harvest space (72) have a glass wall (96), a glass roof (97), And the whole is covered with glass walls (98) (99) and glass roofs (100) (101).

The growth tower (75) has a cultivation bed (80) having a diameter of about 1.3 m and a total length of 10 m, and as shown in FIG. 7, in a predetermined arc centered on the center line (Q) in plan view. Along the ring and at an appropriate interval, they are arranged adjacent to each other in an annular shape.
As shown in FIGS. 7 to 8, a donut-shaped drive panel (82) whose center line (Q) coincides with the center position is installed at an appropriate height position below the growth tower (75). The lower end of the growth tower (75) is fixed to the side surface of the drive panel (82). And as shown in FIGS. 7-8, each cultivation bed (80) is comprised by the motor (85) while being comprised around an axis line (R) via a rotation gear (83). It is configured to be rotatable around the center line (Q) according to the rotation of the driving panel (82). That is, the cultivation bed (80) revolves on a predetermined arc centered on the center line (Q) while rotating about the axis (R) as a rotation axis. At this time, since the outer periphery and the upper part are covered with the glass wall (96) and the glass roof (97), they are planted on the cultivation floor (80) regardless of the installation orientation of the plant growing plant (70). The plant can be irradiated with sunlight evenly.
A ring-shaped guide rail (87) is fixed above the growth tower (75) as shown in FIGS. 7 to 8, and the upper end of the growth tower (75) is guided to the guide rail (87). By doing so, the cultivation floor (80) is revolving with keeping substantially vertical.

As shown in FIGS. 8 to 9, the lower end of the growth tower (75) is rotatably supported by the pivot (89), and at a predetermined position, the growth tower (75) is moved to the front for raising seedling and harvesting. It can be laid down substantially horizontally toward the space (72). On the track drawn by the upper end of the growth tower (75), an arch-shaped guide rail (90) is provided. The glass wall (98) of the nursery / harvest space (72) and the glass roof (100) are provided. The shape corresponds to the shape of the guide rail (90).

As shown in FIGS. 7 to 8, a mist nozzle (76) for spraying liquid fertilizer onto the plant root is disposed inside each cultivation bed (80), and a drive panel (82). ) Below, a solution tank (92) and a filtration tank (93) are installed so that the surplus liquid manure can be filtered and recycled.

As shown in FIG. 7, the growth lamps (77) are arranged concentrically with the annularly arranged cultivation floor (80) in the vicinity of the center line (Q) at appropriate intervals, and outward. On the other hand, artificial light is irradiated radially.
As shown in FIG. 7, the growth lamp (77) is surrounded by a surrounding wall (95) made of a material that can transmit artificial light, such as a transparent glass plate, and the upper portion of the surrounding wall (95) is closed. Thus, a sealable space is formed. The air conditioning load can be reduced by dissipating the heat generated by the growth lamp (77) to the outside through a heat exhaust fan or a heat exhaust duct (not shown).

As shown in FIGS. 7 and 9, the nursery bed (78) is arranged along the left and right sides of the cultivation bed (80) of the lying growth tower (75) in the nursery / harvest space (72). Yes. As shown in FIG. 9, in this embodiment, the seedling bed (78) has a structure in which a plurality of seedling trays are vertically stacked.

In this way, the plant growing plant (70) according to the present example rotates each cultivated floor (80) around the axis (R) and revolves around the center line (Q) while revolving around the mist nozzle (76). ) To spray liquid fertilizer and irradiate sunlight and artificial light from the growth lamp (77) from the outside and the inside, respectively, to cultivate and grow plants planted on the cultivation floor (80) Is what you do. Operations such as planting plant seedlings on the cultivation floor (80) and harvesting the grown crops are easily performed by laying the growth tower (75) one after another in the seedling / harvest space (72). be able to.

Even in the plant growing plant (70) according to the present example, the production efficiency of the plant is extremely good. Even if only focusing on the cultivation area, it is about 653 m ² (= cultivation floor diameter 1.3 m × circularity ratio 3.14 × cultivation floor total length 10 m × 16 places), for example, 15 m in diameter ( Compared with the circular planar cultivated land (about 177 m ² ) of the growth space (71), the cultivation area can be increased by about 3.7 times.
Furthermore, if it is a structure like a present Example, it will become possible to grow a plant by irradiating sunlight and the artificial light by the breeding lamp (77) uniformly from all directions.

The present invention provides a plant growing system, a plant growing plant, and a plant growing method capable of further improving production efficiency in plant growing technology using both sunlight and artificial light. With the above applicability.

It is a top view of a plant breeding plant. It is side surface sectional drawing of a plant growth plant. It is a front elevation view of a plant breeding plant. It is a principal part expanded end elevation of a growth tower. It is side surface partial sectional drawing of the growth tower which shows the other form of a mist nozzle. FIG. 6 is a cross-sectional view taken along line A-A ′ in FIG. 5. It is a top view of the plant breeding plant concerning other embodiments. It is side surface sectional drawing of the plant growth plant which concerns on other embodiment. It is a front view of the plant breeding plant concerning other embodiments.

Explanation of symbols

1 Plant growth plant 2 Growth tower
3 Mist nozzle 4 Raising lamp 5 Nursery bed 7 Plant (seed)
8 Plant Root 10 Cultivation Floor 13 Rib 16 Pot 19 Axis 20 Growing Tower Shaft Roller 21 Guide Rail 37 Bed Rail 40 Glass Roof 41 Glass Wall 50 Solution Tank 51 Filtration Tank 70 Plant Growing Plant 71 Growing Space 72 Raising and Harvesting Space 75 Growing Tower 76 Mist nozzle 77 Raising lamp 78 Raising bed 80 Growing bed 89 Axis P Axis Q Center line R Axis

Claims (6)

A plant growing system for growing plants by hydroponics using both sunlight and artificial light,
Growing having a cultivation bed on which a plant can be planted, which is formed in a hollow cylindrical shape, is rotatable about an axis, is erected substantially vertically so as to be able to irradiate sunlight, and is annularly arranged along a predetermined arc. Tower,
A mist nozzle that sprays liquid manure on the plant root exposed on the inner peripheral surface side of the cultivation floor;
A growth lamp that is disposed within the arc and radiates artificial light radially outwardly;
While rotating the cultivated floor around the axis and revolving on the arc, sunlight and artificial light by the growing lamp are respectively directed outward and inward toward the plant planted on the cultivated floor. A plant breeding system designed to irradiate from one side. The plant growing system according to claim 1, wherein a lower end of the growing tower is rotatably supported by a pivot, and the growing tower can be laid down substantially horizontally. A plant growing system for growing plants by hydroponics using both sunlight and artificial light,
A growth tower having a cultivation floor on which plants are planted, which is formed in a hollow cylindrical shape and is rotatable about an axis, and is set up substantially vertically so as to be able to irradiate sunlight.
A mist nozzle that sprays liquid manure on the plant root exposed on the inner peripheral surface side of the cultivation floor;
A growth lamp that sequentially irradiates artificial light from a certain direction toward the plant planted on the cultivation floor as the cultivation floor rotates,
A plant growth system in which a lower end of the growth tower is rotatably supported by a pivot so that the growth tower can be laid down substantially horizontally. The plant growing system according to any one of claims 2 to 3, wherein a seedling bed for growing plant seedlings to be planted on the cultivation floor is movably disposed on the side where the growing tower is laid down. While the plant growing system according to any one of claims 1 to 4 is provided,
A plant breeding plant that is covered with a roof and an outer wall that can transmit sunlight through. A plant growth method for growing plants by hydroponics using sunlight and artificial light,
A hollow cylinder is made rotatable around the axis, and the cultivation floor on which plants are planted is erected substantially vertically so that it can irradiate sunlight, and is arranged annularly along a predetermined arc,
While rotating the cultivation floor around the axis and revolving on the arc,
While spraying liquid fertilizer on the plant root exposed on the inner peripheral surface side of the cultivation floor,
A plant growing method in which sunlight and artificial light are emitted from the outside and the inside, respectively, toward the plant planted on the cultivation floor.

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