JP2016010388A - Cultivation bed, plant cultivation device using cultivation bed, and method for using plant cultivation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cultivation bed which promotes growth of plants.SOLUTION: A cultivation bed 100 comprises a first surface 1, a second surface 2, lateral faces 3 connecting a periphery of the first surface 1 and a periphery of the second surface 2, one or more cutout parts 13 provided to the lateral faces 3 penetrating through the first surface 1 and the second surface 2 for inserting seedlings, and one or more aeration parts 14, 15 penetrating from the first surface 1 to the second surface 2.

Description

  The present invention relates to a cultivation bed, a plant cultivation apparatus that uses the cultivation bed, and a method that uses the plant cultivation apparatus.

  In recent years, plant factories have attracted attention as environmentally friendly production systems for the purpose of supplying safe food and the yearly supply of ingredients. In plant factories, generally, hydroponics is used to grow plants using artificial light or natural light (sunlight) as a light source. In addition, temperature, humidity, and carbon dioxide are controlled. These technologies enable the planned production of plants regardless of the season.

Patent Literature 1 discloses a cultivation bed for growing transplanted seedlings. Patent Literature 1 discloses a cultivated floor formed from a pair of long divided polystyrene foam blocks. It is possible to arrange a number of the cultivation beds themselves and float them on the liquid surface. A seedling collected from another nursery bed is sandwiched between a pair of both divided blocks, suspended on the surface of the water tank (water or water containing nutrients), pumped by capillary action, or directly fed by the root Hydroponic cultivation is performed by absorbing the liquid.
In addition, when the width of one pair of divided blocks is reduced and the crop grows greatly, both divided blocks are arranged so that the outer surface of the one divided block does not protrude from the outer surface of the other pair of blocks. A cultivation bed is disclosed in which the two sliding blocks can slide relative to each other due to the growth of crops by fitting. By arranging a large number of cultivation floors in close contact with each other and covering the entire surface of the liquid surface, it is possible to block light and suppress the generation of a large amount of algae in the solution.

Japanese Utility Model Publication No. 50-153139

  In the cultivation floor of patent document 1 mentioned above, since there is a gap between the two divided blocks fitted, there is a problem that light to the liquid surface cannot be completely blocked and a large amount of algae is still generated. It was happening. Furthermore, since the roots of the seedlings are sandwiched between the two divided blocks, the roots of the seedlings were damaged.

  An object of the present invention is to solve the conventional problems described above, provide a cultivation floor for promoting the growth of plants, provide a plant cultivation apparatus including the cultivation bed, and use the plant cultivation apparatus And providing a method for cultivating plants.

According to a first aspect of the present invention, there is a cultivated floor having a first surface, a second surface, and a side surface connecting the periphery of the first surface and the periphery of the second surface, provided on the side surface, A cultivated floor is provided that includes one or more notches for inserting seedlings leading from one surface to the second surface and one or more vents leading from the first surface to the second surface.
Here, one or more ventilation parts may be a through-hole provided inside the cultivation floor.
One or more vents may be provided near each of the one or more notches.
The side surface may include a protrusion that overlaps with a protrusion of another adjacent cultivation bed.
The shape of the first surface and the second surface is substantially rectangular, and the side surface has a first side surface portion and a second side surface portion located opposite to the first side surface portion, and one or more cutout portions. However, it may be provided on at least one of the first side surface portion and the second side surface portion.
The one or more ventilation portions are in the vicinity of the side portion located opposite to the side portion having one or more cutout portions, and each of the one or more cutout portions has one or more cutout portions. You may provide in a substantially perpendicular direction with respect to the side part which has.
The projecting portion may have a first projecting portion provided on the first side surface portion and / or a second projecting portion provided on the second side surface portion.
At least one side surface portion of the first side surface portion and the second side surface portion may have a shape including one or more concave portions and one or more convex portions.
The first side surface portion and the second side surface portion have a shape including one or more concave portions and one or more convex portions, and one or more concave portions and one or more convex portions of the first side surface portion. Each of the one or more convex portions and the one or more concave portions of the second side surface portion may be arranged in a direction substantially perpendicular to the first side surface portion from each of the portions.

According to the 2nd viewpoint of this invention, it is a plant cultivation apparatus provided with the cultivation bed group containing the said cultivation bed, and a nutrient solution pool, Comprising: A nutrient solution pool is a nutrient solution supply for supplying a nutrient solution The cultivation bed group is placed so as to cover at least a part of the concave portion of the nutrient solution pool, the nutrient solution discharge unit for discharging the nutrient solution, the carbon dioxide supply unit for supplying carbon dioxide, and the nutrient solution pool There is provided a plant cultivation apparatus provided with a cultivation bed group mounting table for doing.
Here, the nutrient solution pool is a substantially rectangular parallelepiped, and has a first side portion and a second side portion located opposite to the first side portion on the side surface of the substantially rectangular parallelepiped, and supplies the nutrient solution to the first side portion. A nutrient solution discharge part may be provided on the second side part.
The carbon dioxide supply unit may be provided on the first side and above the nutrient solution supply unit.

According to a third aspect of the present invention, there is provided a method for cultivating a plant using the plant cultivating apparatus, wherein carbon dioxide gas is ventilated from a ventilation portion provided in the vicinity of each of the one or more cutout portions. The plant cultivation method which supplies a carbon dioxide gas from a carbon dioxide supply part is given so that the total amount may become 1.2-1.6 m < ³ > / h.

  ADVANTAGE OF THE INVENTION According to this invention, the cultivation floor, plant cultivation apparatus, and plant cultivation method which are excellent in the cultivation efficiency of a plant are given.

According to the present invention, it is easy to insert a seedling into the cultivation floor by providing a cut-out portion on the side of the cultivation floor, making the seedling difficult to hurt, and providing a ventilation portion on the cultivation floor allows carbon dioxide gas to It has the effect of facilitating absorption from the back side and promoting photosynthesis.
By providing the ventilation part as a through hole inside the cultivation floor, it has the effect that the ventilation part can be arranged in the part where the carbon dioxide gas is easily absorbed effectively in the leaves of the seedlings inserted into the notch part. .
By providing the ventilation part in the vicinity of the notch part, there is an effect that the ventilation part can be arranged in a portion where the carbon dioxide gas is more effectively absorbed into the leaves of the seedlings inserted into the notch part. . Here, the vicinity of the notch is a part of the cultivation floor located below the leaves of the seedling.
The effect of suppressing the mass generation of algae by blocking the light to the nutrient solution soaked in the nutrient solution pool from between the adjacent cultivation beds by providing a projection portion that overlaps the projection portion of another adjacent cultivation bed on the side surface Have
By making the surface shape of the cultivation floor into a substantially rectangular shape, it becomes easy to arrange a plurality of cultivation floors continuously in length and breadth, and the cultivation floors can be arranged and arranged so as to be suitable for plant cultivation devices of all sizes. .
By providing a concave portion and a convex portion on the side surface of the cultivation floor, each of the concave portion and the convex portion is fitted to each of the convex portion and the concave portion on the side surface of another adjacent cultivation floor, so that a plurality of cultivation beds are continuously provided. Therefore, it is easy to arrange them side by side, and the cultivation floor does not slide relative to the adjacent cultivation floor, so that the work efficiency of fixed planting is improved.
The plant cultivation apparatus includes a cultivation bed group including one cultivation floor, one of the above cultivation beds, a concave portion for soaking a nutrient solution, a nutrient solution supply unit and a nutrient solution for supplying the nutrient solution. By providing a nutrient solution discharge unit for discharging, a carbon dioxide supply unit for supplying carbon dioxide, and a nutrient solution pool provided with a cultivation bed group mounting table for placing the cultivation bed group, seedlings Makes it easier to insert into the cultivation floor and makes it difficult for the seedling to hurt. It has the effect of blocking the light on the nutrient solution surface and suppressing the mass generation of algae.
The nutrient solution is provided in the first side portion of the nutrient solution pool that is a substantially rectangular parallelepiped, and the nutrient solution discharge portion is provided on the second side located on the opposite side of the first side portion, so that the nutrient solution is the nutrient solution. It flows uniformly in the pool and has the effect that the nutrients of the nutrient solution are uniformly absorbed by the roots of each seedling.
The carbon dioxide gas is supplied from the carbon dioxide supply section so that the total amount of carbon dioxide gas vented from the ventilation section provided in the vicinity of each of the one or more notches is 1.2 to 1.6 rubbe / hour. Is effective in efficiently absorbing carbon dioxide from the back side of the leaves of the seedling, promoting photosynthesis of the seedling and shortening the period from planting to shipping.

It is the partial perspective view seen from the upper surface of the structure of the cultivation floor of this invention. It is the side view seen from the A direction of Drawing 1 of the structure of the cultivation floor of the present invention. It is the side view seen from the B direction of Drawing 1 of the structure of the cultivation floor of the present invention. It is the partial perspective view seen from the upper surface of the structure of another cultivation floor of this invention. It is the side view seen from the A direction of Drawing 3 of the structure of another cultivation floor of the present invention. It is the partial perspective view seen from the upper surface of the structure of the plant cultivation apparatus which uses the cultivation floor of FIG. 1 of this invention. It is the partial perspective view seen from the upper surface of the structure of the plant cultivation apparatus which uses the cultivation floor of FIG. 3 of this invention. It is sectional drawing along the AA line of FIG. 5 of the structure of the plant cultivation apparatus of this invention. It is the partial perspective view seen from the B direction of Drawing 5 of the structure of the plant cultivation device of the present invention. It is the side view seen from the C direction of Drawing 5 of the structure of the plant cultivation device of the present invention.

  EXAMPLES The present invention will be described below with reference to examples, but the present invention is not limited to these examples. Moreover, common reference symbols are assigned to corresponding components throughout the drawings.

1 to 3 show a first embodiment of the present invention. The cultivation floor 100 has a first surface 1, a second surface 2, and a side surface 3 that connects the periphery of the first surface 1 and the periphery of the second surface 2. The cultivation floor 100 has one or more notches for inserting seedlings into the cultivation floor 100 that leads from the first surface 1 to the second surface 2 in the first side surface portion 4 and the second side surface portion 5 of the side surface 3. The unit 13 is provided. In FIG. 1, the notch portion 13 is provided on both side surfaces of the first side surface portion 4 and the second side surface portion 5, but may be provided only on one side surface. The cutout portion 13 may have any shape as long as it is a shape suitable for inserting a seedling. Moreover, the cultivation bed 100, the first side portion 4 and the second side surface portion 5 of the side 3, carbonate (CO, CO ₂₎ for venting the gas from the first surface 1 to the second surface 2 One or more ventilation parts 14 and 15 are provided. Such a configuration of the cultivation floor facilitates insertion of the seedling into the cultivation floor 100 and makes it difficult to damage the seedling, facilitates absorption of carbon dioxide from the back side of the seedling leaf, and promotes photosynthesis of the seedling. .
In addition, as the cultivation floor 100, any material can be used as long as it is a material capable of cultivating plants. For example, polystyrene foam can be used. In addition, the cultivated floor is preferably flat and has a thickness of, for example, about 15 mm. In FIG. 1, the shapes of the first surface 1 and the second surface 2 of the cultivation floor are substantially rectangular, but may be any shape as long as they can be used as the cultivation floor.

The ventilation parts 14 and 15 may be provided inside the cultivation bed as through-holes, or may be provided on the side surface 3 as notches. As shown in FIG. 1, if the ventilation parts 14 and 15 are provided as a through-hole inside the cultivation bed 100, carbon dioxide gas can be ventilated from a desired position. And as shown in FIG. 1, it is preferable to provide the ventilation | gas_flowing part 14 in the part of each notch part 13, ie, the part of the cultivation bed located under the leaf of a seedling. As a result, carbon dioxide gas discharged from the ventilation part 14 is made to be absorbed more easily by the back side of the leaves of the seedlings inserted into the notch parts 13 to promote seedling photosynthesis and grow faster than the plant. Can do. For example, it is preferable to provide the ventilation part 14 within 1 cm from the notch part 12.
In FIG. 1, one ventilation portion 14 is arranged for each of the cutout portions 13 and the shape is circular, but a plurality of ventilation portions 14 may be arranged, and the leaves of the seedlings inserted into the cutout portions 12 Any shape can be used as long as it makes it easier to absorb carbon dioxide on the back side of the substrate. Moreover, it is preferable that the magnitude | size of the shape of the ventilation | gas_flowing part 14 is a magnitude | size that the length of the longest part is 1 cm or less.

In addition, as shown in FIG. 1, in the vicinity of the side surface portion (for example, the second side surface portion 5) located opposite to the side surface portion (for example, the first side surface portion 4) having the cutout portion 13, that is, adjacent to the side surface portion. The side portion of the cultivation floor located below the leaves of the seedlings inserted into the cutout portion 13 of the cultivation floor 100, and having the cutout portion 13 from the cutout portion 13 (for example, the first side portion 4 It is preferable to provide the ventilation part 15 in a substantially vertical direction. This facilitates absorption of carbon dioxide gas vented from the vent 15 by the back side of the seedling leaf inserted into the notch 13 in another adjacent cultivation bed 100, thereby promoting photosynthesis of the seedling. And let the plant grow faster. For example, the ventilation portion 15 is within 1 cm from the second side surface portion 5 positioned opposite to the first side surface portion 4 and is substantially perpendicular to the first side surface portion 4 from the cutout portion 13 of the first side surface portion 4. Is preferably provided.
In FIG. 1, one ventilation portion 15 is arranged for each of the cutout portions 13 of the adjacent cultivation floor 100, and the shape is circular. However, a plurality of ventilation portions 15 may be arranged, and the cutout portions 13 may be arranged. Any shape may be used as long as the carbon dioxide gas can be absorbed more easily on the back side of the inserted seedling leaf. Further, the size of the shape of the ventilation portion 15 is preferably such that the length of the longest portion is 1 cm or less.

  The cultivation floor 100 is provided with the protrusion part 8 which overlaps with the protrusion part 8 of another adjacent cultivation floor 100 in the side surface 3. As the protrusion 8, for example, in FIGS. 1 to 3, the first protrusion 9 provided on the first side 4, the second protrusion 10 provided on the second side 5, and the third side 6 The 3rd protrusion part 11 provided and the 4th protrusion part 12 provided in the 4th side part 7 are shown. The overlapping part by the 1st protrusion part 9 provided in the 1st side part 4 of one cultivation floor 100 and the 2nd protrusion part 10 provided in the 2nd side part 5 of another cultivation floor 100 overlapping. The generation of a large amount of algae can be suppressed by blocking the light to the nutrient solution immersed in the solution pool below. Moreover, when the 3rd protrusion part 11 provided in the 3rd side surface part 6 of one cultivation floor 100 and the 4th protrusion part 12 provided in the 4th side surface part 7 of another culture medium 100 overlap. By blocking light to the nutrient solution immersed in the solution pool below the overlapping portion, a large amount of algae can be suppressed. By providing the protrusions in this way, even when a plurality of cultivation beds are arranged side by side, light from between the side surfaces of the adjacent cultivation beds can be blocked.

  Moreover, as shown in FIG. 2, the first protruding portion 9 of the cultivation floor 100 has a first thickness 16 from the first surface 1 to the thickness of the cultivation floor 100, and the second of the cultivation floor 100. The protruding portion 10 has a second thickness 17 excluding the first thickness 16 from the second surface 2 to the thickness of the cultivation floor 100. Thereby, when arranging one cultivation floor 100 and another cultivation floor 100 side by side continuously, the 1st protrusion part 9 of the 1st side part 4 of one cultivation floor 100, and another cultivation bed 100 adjacent. When the 2nd protrusion part 10 of the 2nd side part 5 of this overlaps, thickness 17 of the 2nd protrusion part 11 of another cultivation floor 100 adjacent to the thickness 16 of the 1st protrusion part 10 of one cultivation floor 100 is overlapped. Is the same as the thickness of the cultivation floor 100, and it is easy to arrange a plurality of cultivation floors side by side.

  4 and 5 show a second embodiment of the present invention. In FIGS. 4 and 5, the same reference numerals as those in FIGS. 1 to 3 are the same as the corresponding elements in FIGS. 1 to 3. Description of is omitted.

  According to the 2nd Example, the side surface (for example, 1st side surface part 4) which has the 1 or more notch part 13 of the cultivation floor 200 has one or more recessed parts 18, and one or more convex parts 19. It has. As shown in FIG. 4, the first side surface portion 4 and the second side surface portion 5 of the cultivation floor 200 include one or more concave portions 18 and one or more convex portions 19. One or more concave portions 18 and one or more convex portions 19 may be provided only on one of the second side surface portions 5. Further, as shown in FIG. 4, the second side surface portion 5 is provided in a direction substantially perpendicular to the first side surface portion 4 from each of the concave portion 18 and the convex portion 19 provided in the first side surface portion 4. Each of the convex part 19 and the recessed part 18 is each arrange | positioned. Thereby, when arranging one cultivation bed 200 and another cultivation floor 200 side by side continuously, the recessed part 18 and the convex part 19 of the 1st side surface part 4 of one cultivation bed 200 are another cultivation bed which adjoins. Since it fits respectively in the convex part 19 and the recessed part 18 of the 2nd side surface part 200 of 200, it becomes easy to arrange a some cultivation bed side by side continuously, and the work efficiency of fixed planting improves.

  Further, in order to securely hold the seedling in the notch 13, the notch 13 is provided in the recess 18 as shown in FIG. 4. In order to make it more reliable, the notch 13 is preferably provided at the bottom of the recess 18.

6 to 10 show a third embodiment of the present invention. 6 to 10, the same reference numerals as those in FIGS. 1 to 5 are the same as the corresponding elements in FIGS. 1 to 5. Description is omitted.
The plant cultivation apparatus 500 includes a cultivation bed group 300 or 400 including at least one cultivation floor among the cultivation beds 100 and 200. In FIG. 6, the cultivation floor group 300 uses the cultivation floor 100, the 1st side surface part 4 (3) of one cultivation floor 100, and the 2nd side surface part 5 (3) of another cultivation bed 100 adjacent. The plant cultivation apparatus 500 is shown, which is configured to overlap with each other via the first protruding portion 9 (8) and the second protruding portion 10 (8), respectively.
In FIG. 7, the cultivation floor group 400 uses the cultivation floor 200, and the first first side face portion 4 of one cultivation floor 200 and the second side face portion 5 of another adjacent cultivation bed 200 are A plant cultivation device 500 is shown which is configured to overlap with each other via a first protruding portion 9 (8) and a second protruding portion 10 (8).
Furthermore, when using the cultivation floor 200, as shown in FIG. 4, in the 1st side surface part 4 and the 2nd side surface part 5 of the cultivation floor 200, one or more recessed parts 18 and one or more convex parts. 19, each of the concave portion 18 and the convex portion 19 provided in the first side surface portion 4 is substantially perpendicular to the first side surface portion 4, and the convex portion 19 provided in the second side surface portion 5 and Since each of the recesses 18 is arranged, as shown in FIG. 7, one cultivation bed 200 and another cultivation bed 200 are continuously arranged along the first side surface portion 4 and the second side surface portion 5. When arrange | positioning, the recessed part 18 and the convex part 19 of the 1st side surface part 4 of one cultivation floor 200 are fitted in the convex part 19 and the recessed part 18 of the 2nd side surface part 5 of another adjacent cultivation bed 200, respectively. Moreover, the cultivation floor group 400 is comprised.

Moreover, the plant cultivation apparatus 500 includes a nutrient solution pool 20. The nutrient solution pool 20 has a concave portion 22 for immersing the nutrient solution 21 on the upper surface, and the nutrient solution supply unit 23 for supplying the nutrient solution 21 to the concave portion 22 and the concave portion 22 A nutrient solution discharge part 24 for discharging the nutrient solution 21, a carbon dioxide supply part 26 for supplying the carbon dioxide gas 25 to the concave part 22, and a cultivation bed group so as to cover at least a part of the concave part 22 And a cultivation floor group mounting table 27 for mounting 300 or 400. In addition, it is comprised so that oxygen can be inject | poured from the carbon dioxide supply part 26 as needed.
Any material can be used as the nutrient solution pool 20 as long as it is a material capable of cultivating plants. For example, polystyrene foam can be used. The size of the nutrient solution pool 20 is, for example, about 80 cm in the width direction, about 5 to 10 m in the length direction, and about 9 cm in the height direction.

Plant seedlings are inserted into the cutout portions 13 of the cultivation floor 100 or 200, supplied to the concave portion 22 of the nutrient solution pool 20 from the nutrient solution supply unit 23, and fed from the nutrient solution discharge unit 24. It is immersed in the liquid 21. The standard of the depth of the nutrient solution 21 is about 5 cm. Examples of plants include lettuce, mizuna and komatsuna.
The carbon dioxide gas 25 is supplied from the carbon dioxide supply unit 26 to the concave shape portion 22 of the nutrient solution pool 20, and the nutrient solution 21 immersed in the concave shape portion 22 of the nutrient solution pool 20 and cultivation of the nutrient solution pool 20 The air is ventilated from the ventilation portions 14 and 15 of the cultivation floor 100 or 200 through a space between the cultivation floor group 400 or 500 placed on the floor group placement table 27. In addition, providing a space between the nutrient solution 21 and the cultivation bed group 300 or 400 placed on the cultivation bed group mounting table 27 means that the cultivation bed group 300 or 400 does not contact the nutrient solution 21. Therefore, it has the effect that plant growth is not hindered. The carbon dioxide gas aerated from the ventilation parts 14 and 15 is absorbed by the leaves of the seedlings inserted into the notch parts 13, thereby promoting photosynthesis of the seedlings. In order to make the carbon dioxide gas 25 easy to be absorbed by the leaves of the seedling, it is preferable to provide a ventilation part 14 in the vicinity of the notch 13 of the cultivation bed 100 or 200 located below the leaves of the seedling. For example, it is good to provide the ventilation part 14 in the part of the cultivation floor 100 or 200 within 1 cm from the notch part 13.
Moreover, in order to make the carbon dioxide gas 25 more easily absorbed by the leaves of the seedlings inserted into the notch 13 of the adjacent cultivation floor 100 or 200, the side surface having the notch 13 (for example, the first side surface). Part 4) in the vicinity of a side part (for example, second side part 5) opposite to the side part (for example, first side part 4) having notch part 13 to notch part 13 The ventilation portion 15 may be provided in a substantially vertical direction. For example, it is within 1 cm from the second side surface portion 5 positioned opposite to the first side surface portion 4 having the notch portion 13, and is substantially from the notch portion 13 of the first side surface portion 4 to the first side surface portion 4. The ventilation part 15 is preferably provided in the vertical direction.

As the supply of the carbon dioxide gas 25 from the gas supply unit 26, the total amount of the carbon dioxide gas 25 ventilated from the ventilation portions 14 and 15 provided in the vicinity of each of the cutout portions 13 of the cultivation bed 100 or 200 is 1. It is good to set it as 2-1.6m < ³ > / h. This means that the total amount of carbon dioxide gas 25 vented from the vents 14 and 15 provided for the seedlings inserted into the notches 13 is 1.2 to 1.6 m ³ / h. means. For example, the total amount of carbon dioxide gas 25 vented from the vents 14 and 15 within 1 cm from each notch 13 is 1.2 to 1.6 m ³ / h.
By supplying carbon dioxide 25 in this way, lettuce can be shipped in about two weeks if it does not supply carbon dioxide from planting of seedlings to shipment. .

As shown in FIG. 10, the nutrient solution supply unit 23 is on the first side portion 28 of a substantially rectangular parallelepiped, and the nutrient solution discharge unit 24 is on the second side portion 29 located on the opposite surface of the first side portion 28. Is provided. The carbon dioxide supply part 26 is provided on the first side part 28 and above the nutrient solution supply part 23. If all the seedlings uniformly absorb nutrients from the nutrient solution 21, the nutrient solution supply unit 23 and the nutrient solution discharge unit 24 may be on any surface of the substantially rectangular parallelepiped. Or if all the seedlings supply the carbon dioxide gas 25 uniformly, the carbon dioxide supply part 26 may exist in any surface of a substantially rectangular parallelepiped.
In addition, in FIG. 10, although the nutrient solution pool 20 is a substantially rectangular parallelepiped, in the case where a plurality of plant cultivation apparatuses 500 are arranged and a plant is cultivated, any shape can be used as long as the plurality of plant cultivation apparatuses 500 are easily arranged. It may be a simple shape. A plurality of nutrient solution supply units 23, nutrient solution discharge units 24, and carbon dioxide supply units 26 may be provided.

  Moreover, the cultivation floor group not only arranges the cultivation floor 100 or 200 continuously in the vertical direction as described above, but also the third side surface portion 6 of the first cultivation floor 100 or 200 and the second cultivation bed. It can also arrange | position so that the 4th side surface part 7 of 100 or 200 may overlap, and the cultivation bed 100 or 200 can also be arranged side by side continuously in the horizontal direction. In this case, the 3rd protrusion part 11 of the 3rd side surface part 6 of the 1st cultivation floor 100 or 200 and the 4th protrusion part 12 of the 4th side surface part 7 of the 2nd cultivation bed 100 or 200 seem to overlap. Is arranged. By providing the 3rd protrusion part 11 in the 1st side surface part 7 of the cultivation floor 100 or 200, and the 4th protrusion part 12 in the 2nd side surface part 8, the 3rd side surface part 6 and the 4th side surface of the cultivation floor 100 or 200 are provided. Even when the cultivation beds 100 or 200 are arranged along the section 7, light from between the side surfaces of the adjacent cultivation floors to the nutrient solution surface can also be blocked to suppress a large amount of algae.

  As described above, according to the present invention, the seedling can be easily inserted into the cultivation floor and the seedling is less likely to be damaged, and carbon dioxide is easily absorbed from the back side of the seedling to promote the photosynthesis of the seedling. Since light on the liquid surface can be blocked to prevent a large amount of algae, it can greatly contribute to the improvement of plant cultivation efficiency.

1 first surface 2 second surface 3 side surface 4 first side surface portion 5 second side surface portion 6 third side surface portion 7 fourth side surface portion 8 projecting portion 9 first projecting portion 10 second projecting portion 11 third projecting portion 12 first Four projecting portions 13 Notch portion 14 Ventilation portion 15 Ventilation portion 16 First thickness 17 Second thickness 18 At least one concave portion 19 At least one convex portion 20 Nutrient solution pool 21 Nutrient solution 22 Concave portion 23 Nutrient solution Supply section 24 Nutrient solution discharge section 25 Carbon dioxide 26 Carbon dioxide supply section 27 Cultivated floor group mounting table 28 First side section 29 Second side section 100 Cultivated floor 200 Cultivated floor 300 Cultivated bed group 400 Cultivated bed group

Claims (13)

A cultivation bed having a first surface, a second surface, and a side surface connecting the periphery of the first surface and the periphery of the second surface,
One or more cutouts for inserting seedlings provided from the first surface to the second surface provided on the side surface;
A cultivation bed comprising: one or more ventilation portions communicating from the first surface to the second surface.   The cultivation bed according to claim 1, wherein the one or more ventilation portions are through holes provided inside the cultivation floor.   The cultivation bed according to claim 1, wherein the one or more ventilation portions are provided in the vicinity of each of the one or more cutout portions.   The said side is provided with the protrusion part which overlaps with the protrusion part of another adjacent cultivation bed, The cultivation bed as described in any one of Claim 1- Claim 3 characterized by the above-mentioned.   The first surface and the second surface have a substantially rectangular shape, and the side surface includes a first side surface portion and a second side surface portion positioned opposite to the first side surface portion, The cultivated floor according to claim 4, wherein the cutout portion is provided on at least one of the first side surface portion and the second side surface portion.   The one or more ventilation portions are in the vicinity of a side surface portion opposite to the side surface portion having the one or more cutout portions, and each of the one or more cutout portions includes the one or more ventilation portions. The cultivation bed according to claim 5, wherein the cultivation bed is provided in a substantially vertical direction with respect to the side surface portion having the cutout portion.   The said protrusion part has the 1st protrusion part provided in the said 1st side part, and / or the 2nd protrusion part provided in the said 2nd side part, The Claim 5 or Claim 6 characterized by the above-mentioned. The cultivated floor described in 1.   The at least one side surface part of said 1st side surface part and said 2nd side surface part is a shape provided with one or more recessed parts and one or more convex parts, The Claims 5-7 characterized by the above-mentioned. The cultivation bed as described in any one of until.   The first side surface portion and the second side surface portion have a shape including one or more concave portions and one or more convex portions, and the one or more concave portions of the first side surface portion, and the Each of the one or more convex portions of the second side surface portion and each of the one or more concave portions is arranged in a direction substantially perpendicular to the first side surface portion from each of the one or more convex portions. The cultivated floor according to any one of claims 5 to 7, wherein the cultivated floor is provided. A cultivation bed group including the cultivation floor according to any one of claims 1 to 9,
A plant cultivation apparatus comprising a nutrient solution pool,
The nutrient solution pool is
A nutrient solution supply unit for supplying nutrient solution;
A nutrient solution discharger for discharging the nutrient solution;
A carbon dioxide supply section for supplying carbon dioxide;
A plant cultivation apparatus comprising: a cultivation bed group mounting table for placing the cultivation bed group so as to cover at least a part of the concave portion of the nutrient solution pool.   The nutrient solution pool is a substantially rectangular parallelepiped, and has a first side part on a side surface of the substantially rectangular parallelepiped and a second side part located on the opposite side of the first side part, and the nutrient solution pool is provided on the first side part. The plant cultivation apparatus according to claim 10, further comprising a liquid supply unit, and the second side portion including the nutrient solution discharge unit.   12. The plant cultivation apparatus according to claim 11, wherein the carbon dioxide supply unit is provided on the first side and above the nutrient solution supply unit. A method for cultivating a plant using the plant cultivation apparatus according to any one of claims 10 to 12, wherein the ventilation portion is provided in the vicinity of each of the one or more cutout portions. The carbon dioxide gas is supplied from the carbon dioxide gas supply unit so that the total amount of carbon dioxide gas vented from the air is 1.2 to 1.6 m ³ / h.