JP2013021980A - Plant cultivation apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a plant cultivation apparatus that has few limitations as to the place of installation.SOLUTION: The plant cultivation apparatus 1 includes a cultivation liquid container 3 for retaining a cultivation liquid, openings 30, 33 for allowing the cultivation liquid to flow into the cultivation liquid container 3, and an opening 24 for allowing the cultivation liquid retained in the cultivation liquid container 3 to flow out of the cultivation liquid container 3. The amount of the cultivation liquid that is allowed to flow into the cultivation liquid container 3 through the openings 30, 33 and the amount of the liquid allowed to flow out of the opening 24 are set to be equal when a predetermined amount of cultivation liquid is retained in the cultivation liquid container 3. The plant cultivation apparatus 1 also includes a cultivation liquid tank 5 for retaining the cultivation liquid, a liquid pump 6 for sending the cultivation liquid out from the cultivation liquid tank 5 to the cultivation liquid container 3, and a rack on which the cultivation liquid container 3, the cultivation liquid tank 5 and the liquid pump 6 are mounted. The openings 30, 33 allow the cultivation liquid to flow into a portion of the cultivation liquid container 3. The opening 24 allows the cultivation liquid to flow out of a portion of the cultivation liquid container 3. The openings 30, 33 and the opening 24 are arranged in positions crossing the inside of the cultivation liquid container 3.

Description

  The present invention relates to a plant cultivation apparatus.

  DESCRIPTION OF RELATED ART Conventionally, as disclosed by patent document 1, 2, the plant cultivation apparatus which grows plants, such as vegetables, using the cultivation liquid tank in which the cultivation liquid was stored is known.

JP 2009-34055 A JP 2010-88425 A

  However, when installing the plant cultivation apparatus described above, a large installation space for providing a water supply / drainage system is required. Therefore, there is a great limitation on the installation location where the plant cultivation apparatus is installed.

  Then, this invention makes it a subject to provide the plant cultivation apparatus with few restrictions of an installation place.

  In order to solve the above-mentioned problem, the cultivation liquid tank in which the cultivation liquid is stored, the inflow part that allows the cultivation liquid to flow into the cultivation liquid tank, and the cultivation liquid stored in the cultivation liquid tank are caused to flow out of the cultivation liquid tank. A state in which a predetermined amount of the cultivation liquid is accumulated in the cultivation liquid tank, the inflowing amount of the cultivation liquid flowing into the cultivation liquid tank from the inflow part and the outflow amount flowing out from the outflow part. In the plant cultivation apparatus set to be equal to each other, a cultivation liquid tank in which the cultivation liquid is stored, a liquid pump that sends the cultivation liquid from the cultivation liquid tank to the cultivation liquid tank, a cultivation liquid tank, a cultivation liquid tank, and A mounting body to which the liquid pump is attached, the inflow part allows the cultivation liquid to flow into one place in the cultivation liquid tank, and the outflow part causes the cultivation liquid to flow out from one place in the cultivation liquid tank. And the outflow part should be arranged at a position that crosses the inside of the cultivation liquid tank. To.

  In the plant cultivation apparatus described above, the depth of the cultivation liquid stored in the cultivation liquid tank is Q, the distance between the inflow part and the outflow part is P, the distance between the inflow part and the side of the cultivation liquid tank is L, the inflow of the cultivation liquid When the amount and the outflow amount are M, it is preferable that 0.5 cm ≦ Q ≦ 7 cm, 20 cm ≦ P ≦ 150 cm, L ≦ 150 cm, 500 cc / min ≦ M ≦ 25000 cc / min.

  Moreover, as for the cultivation liquid tank of the above-mentioned plant cultivation apparatus, it is preferable that the shape of a horizontal direction exhibits an elongate shape, and the inflow part and the outflow part are arrange | positioned in the longitudinal direction.

  The elongated shape of the plant cultivation device described above is rectangular, and the inflow portion and the outflow portion are preferably arranged diagonally to each other.

  Moreover, it is preferable that the inflow part of the above-mentioned plant cultivation apparatus flows culture liquid into the horizontal direction to the side by which an outflow part is arrange | positioned.

  A part of the inflow part of the above-mentioned plant cultivation device is located above the liquid level of the cultivation liquid stored in the cultivation liquid tank, and the inflow part is between the cultivation liquid flowing into the cultivation liquid tank. It is preferable that a space is formed.

  In order to solve the above-mentioned problem, the cultivation liquid tank in which the cultivation liquid is stored, the inflow part that allows the cultivation liquid to flow into the cultivation liquid tank, and the cultivation liquid stored in the cultivation liquid tank are caused to flow out of the cultivation liquid tank. A state in which a predetermined amount of the cultivation liquid has accumulated in the cultivation liquid tank, the amount of the cultivation liquid flowing into the cultivation liquid tank from the outflow part and the outflow amount flowing out from the outflow part. In the plant cultivation apparatus set to be equal to each other, a cultivation liquid tank in which the cultivation liquid is stored, a liquid pump that sends the cultivation liquid from the cultivation liquid tank to the cultivation liquid tank, a cultivation liquid tank, a cultivation liquid tank, and A liquid pump is attached, and the inflow part causes the cultivation liquid to flow horizontally to the side where the outflow part is disposed, and a part of the inflow part is stored in the cultivation liquid tank. It is located above the liquid level of the plant, and the inflow part has a tree that flows into the cultivation liquid tank. And that a space is formed between the liquid.

It is a perspective view which shows the whole structure of the plant cultivation apparatus which concerns on embodiment of this invention. It is a perspective view which shows the structure of the plant cultivation apparatus of the state which removed the cultivation liquid tank, the planting panel, the side panel, and the door from the plant cultivation apparatus shown in FIG. It is a perspective view which shows the structure of a cultivation liquid tank and a planting panel. It is a figure which shows the circulation path of the cultivation liquid of the plant cultivation apparatus shown in FIG. It is a figure which shows the attachment state of an illumination lamp. It is a figure which shows the internal size etc. of a cultivation liquid tank. It is a figure which shows the internal size etc. of a cultivation liquid tank. It is a figure for demonstrating the positional relationship of the opening part used as an inflow part, and the opening part used as an outflow part. It is a figure which shows the modification of the plant cultivation apparatus which concerns on embodiment of this invention. It is a figure which shows roughly the flow which generate | occur | produces in the cultivation liquid stored by a cultivation liquid tank. It is a figure which shows roughly the flow which generate | occur | produces in the cultivation liquid stored by a cultivation liquid tank. It is a figure which shows roughly the flow which generate | occur | produces in the cultivation liquid stored by a cultivation liquid tank. It is a figure which shows roughly the flow which generate | occur | produces in the cultivation liquid stored by a cultivation liquid tank. It is a figure which shows roughly the flow which generate | occur | produces in the cultivation liquid stored by a cultivation liquid tank. It is a figure which shows the modification of the plant cultivation apparatus which concerns on embodiment of this invention. It is a figure which shows the modification of the plant cultivation apparatus which concerns on embodiment of this invention. It is a figure which shows the modification of the plant cultivation apparatus which concerns on embodiment of this invention. It is a figure which shows the modification of the plant cultivation apparatus which concerns on embodiment of this invention. It is a figure which shows the modification of the plant cultivation apparatus which concerns on embodiment of this invention. It is a figure which shows the modification of the plant cultivation apparatus which concerns on embodiment of this invention.

(Embodiment)
Hereinafter, the structure of the plant cultivation apparatus 1 which concerns on embodiment of this invention is demonstrated, referring drawings. FIG. 1 is a perspective view showing an overall configuration of a plant cultivation apparatus 1 according to an embodiment of the present invention. FIG. 2 is a perspective view showing a configuration of the plant cultivation apparatus 1 in a state where the cultivation liquid tank 3, the planting panel 4, the side panel 21, and the door 22 are removed from the plant cultivation apparatus 1 shown in FIG. FIG. 3 is a perspective view showing the configuration of the cultivation liquid tank 3 and the planting panel 4. FIG. 4 is a diagram illustrating the circulation path 35 of the cultivation liquid of the plant cultivation apparatus 1. In the following description, the configuration of the plant cultivation apparatus 1 will be described with the X direction shown in FIG. 1 as the upper side (upper side), the Y direction as the left side (left side), and the Z direction as the front side (front side).

(Whole structure of the plant cultivation apparatus 1)
The plant cultivation apparatus 1 is an apparatus for performing hydroponics cultivation of plants such as vegetables indoors. As shown in FIG. 1, a shelf 2 as an attachment body, a cultivation liquid tank 3, a planting panel 4, and the like. The cultivation liquid tank 5 (see FIG. 2), the liquid pump 6 (see FIG. 2), the illumination lamp 7 (see FIG. 5) and the like are included. The plant cultivation apparatus 1 exhibits a rectangular parallelepiped that is long in the vertical direction as a whole (for example, a height of 190 cm, a horizontal width of 75 cm, and a front and rear depth of 40 cm), and has a size that can be installed in a kitchen or the like of a general household.

  As shown in FIG. 2, the shelf body 2 includes four support columns 8 arranged on the front, rear, left, and right sides, five housings 9 arranged on the front and rear, and five housings 10 arranged on the left and right, respectively. have. The housing 9 arranged on the front side connects the two support columns 8 arranged on the left and right sides of the front side at five locations in the vertical direction. Similarly, the housing 9 arranged on the rear side connects the two support columns 8 arranged on the left and right sides of the rear side at five locations in the vertical direction. The casing 10 connects two casings 9 arranged at the front and rear at each of the five locations in the vertical direction at the left and right ends.

  In the shelf 2, four shelf parts 11, 12, 13, and 14 divided in the vertical direction are formed by a housing 9 and a housing 10. A shelf plate 15 is placed on the upper surfaces of the front and rear housings 9 and 9 and the left and right housings 10 and 10 disposed on the lowest side of the shelf 2. That is, the shelf plate 11 forms the shelf portion of the shelf portion 11. A shelf plate 16 is placed on the upper surfaces of the front and rear housings 9 and 9 and the left and right housings 10 and 10 that are disposed second from the bottom of the shelf 2. That is, the shelf of the shelf 12 is formed by the shelf board 16.

  As shown in FIG. 2, an illuminating lamp mounting rod 17 to which the illuminating lamp 7 is attached is supported on the left and right casings 10, 10 arranged on the upper side of the shelf portion 12. The illuminating lamp 7 is attached to the lower side of the illuminating lamp mounting rod 17 (see FIG. 5). Moreover, the illuminating lamp mounting rod 17 to which the illuminating lamp 7 is attached is also supported by the left and right casings 10 and 10 arranged on the upper side of the shelf portion 13 and the shelf portion 14, respectively. The illuminating lamp mounting rods 17 are provided in three rows in the front-rear direction, and the illuminating lamps 7 are mounted on the illuminating lamp mounting rods 17. Therefore, the inside of the shelf parts 12, 13, and 14 is illuminated by the illuminating lamp 7 provided on the upper side of each shelf part.

  As shown in FIG. 2, a cultivation liquid tank 5 and a liquid pump 6 are installed on the shelf board 15. That is, the cultivation liquid tank 5 and the liquid pump 6 are accommodated in the shelf portion 11. Further, as shown in FIG. 1, the cultivation liquid tank 3 is placed on the shelf board 16. Furthermore, the cultivation liquid tank 3 is placed on the casings 9 and 9 and the casings 10 and 10 arranged below the shelf portion 13. The cultivation liquid tank 3 is also placed on the casings 9 and 9 and the casings 10 and 10 arranged below the shelf portion 14. That is, the cultivation liquid tank 3 is stored in each of the shelf 12 to the shelf 14. The housings 9 and 9 and the housings 10 and 10 disposed on the lower sides of the shelf portions 13 and 14 function as shelf stages of the shelf portions 13 and 14, respectively.

  A control circuit (not shown) and a power source (not shown) for controlling the driving of the liquid pump 6 and the lighting of the illumination lamp 7 are provided above the casings 9 and 9 and the casings 10 and 10 disposed on the shelf 14. Etc. are arranged and covered with a cover 18 (see FIG. 1). An operation panel 19 is disposed on the front surface of the cover 18. The operation panel 19 is provided with a power switch, an operation switch for adjusting the delivery amount of the liquid pump 6 and the like.

  As shown in FIG. 1, the rear side of the plant cultivation apparatus 1 is shielded by a back panel 20. The step portions 12, 13, and 14 are open in the left-right direction and the front. About the step part 11, the left-right direction is shielded by the side panel 21, and the front is shielded by the door 22. The door 22 has a structure that can be opened in the center. Therefore, by setting the door 22 in an open state, various operations such as maintenance of the cultivating liquid tank 5 and the liquid pump 6 and replenishment of the cultivating liquid to the cultivating liquid tank 5 can be performed. In addition, about the back panel 20, it is good also as a structure which does not provide about the back of the step part 11. FIG. By adopting such a configuration, it is possible to prompt the heat generated from the liquid pump 6 and the like to be released to the outside of the step portion 11.

(Cultivation tank 3)
The cultivation liquid tank 3 is a rectangular parallelepiped container having an opening 23 (FIG. 3) above. The planting panel 4 can be placed in the opening 23. By placing the planting panel 4 on the opening 23, the opening 23 can be covered with the planting panel 4. As shown in FIGS. 6 and 7, the inner dimensions of the cultivation liquid tank 3 shown in the present embodiment are configured such that the left-right width W is 62 cm, the front-rear width T is 35 cm, and the depth D is 4.5 cm. It has a flat shape in the direction. Of the four corners of the cultivation liquid tank 3, one corner is provided with an opening 24 as an outflow part for allowing the cultivation liquid in the cultivation liquid tank 3 to flow out. A pipe 26 extending downward from the bottom plate 25 of the tank 3 is connected. The opening 24 is an opening at the upper end of the pipe 26. In addition, between the pipe 26 and the baseplate 25, it is comprised watertight using packing etc., and becomes a structure which the cultivation liquid in the cultivation liquid tank 3 does not leak.

(Planting panel 4)
The planting panel 4 presents a rectangular plate that is slightly larger than the left and right and front and rear widths of the opening 23. Therefore, the entire surface of the opening 23 can be covered with the planting panel 4 in a state where the planting panel 4 is placed on the peripheral edge 27 of the opening 23. Of the four corners of the planting panel 4, a hole 28 through which the pipe 26 or the cultivation liquid supply pipe 32 can be inserted is formed in a corner disposed diagonally to the opening 24. Yes. The planting panel 4 is formed with a plurality of pot holes 29 for inserting seedling pots (not shown) on which plants are vegetated. In the present embodiment, a total of twelve pot holes 29 in three rows in the front-rear direction and four rows in the left-right direction are formed at regular intervals.

  As shown in FIGS. 1 and 4, the cultivation liquid tanks 3 placed on the shelves 12, 13, and 14 have the openings 24 of the cultivation liquid tanks 3 alternately in the diagonal direction of the cultivation liquid tank 3. It is placed to become. That is, it is set as the arrangement | positioning which the opening parts 24 of the cultivation liquid tank 3 arrange | positioned up and down do not overlap with an up-down direction. Moreover, the planting panel 4 mounted in each cultivation liquid tank 3 is arrange | positioned so that the hole part 28 may be located above the position diagonally with the opening part 24 of the cultivation liquid tank 3. FIG. In the present embodiment, the cultivation liquid tank 3 placed on the shelf 14 is provided with the opening 24 on the left front, and the hole 28 of the planting panel 4 placed on the cultivation liquid tank 3 is arranged on the right rear. ing. The cultivation liquid tank 3 placed on the shelf 13 is provided with an opening 24 on the right rear, and the hole 28 of the planting panel 4 placed on the cultivation liquid tank 3 is arranged on the left front. And the opening part 24 is arrange | positioned at the front left, and the hole 28 of the planting panel 4 mounted in this cultivation liquid tank 3 is arrange | positioned at the right rear.

  Each cultivation liquid tank 3 is connected by a pipe 26. Specifically, the pipe 26 connected to the cultivation liquid tank 3 placed on the shelf 14 is a hole of the planting panel 4 that covers the opening 23 of the cultivation liquid tank 3 placed on the shelf 13. 28, an opening 30 at the lower end of the pipe 26 is disposed in the cultivation liquid tank 3 placed on the shelf 13. Similarly, the pipe 26 connected to the cultivation liquid tank 3 placed on the shelf 13 also has a hole 28 in the planting panel 4 that covers the opening 23 of the cultivation liquid tank 3 placed on the shelf 12. The opening 30 at the lower end of the pipe 26 is disposed in the cultivation liquid tank 3 placed on the shelf 12.

  The pipe 26 connected to the cultivation liquid tank 3 placed on the shelf 12 is passed through a hole 31 formed in the shelf 16, and the lower end portion of the pipe 26 is cultivated arranged on the shelf 11. It is arranged in the liquid tank 5. A cultivation liquid supply pipe 32 connected to the liquid pump 6 is passed through the hole 28 of the planting panel 4 that covers the opening 23 of the cultivation liquid tank 3 placed on the shelf 14. An upper opening 33 is arranged in the cultivation liquid tank 3.

  The liquid pump 6 and the cultivation liquid tank 5 are connected through a pipe 34. The liquid pump 6 can pump up the cultivation liquid to the cultivation liquid tank 3 accommodated in the shelf portion 14 via the cultivation liquid supply pipe 32. Therefore, in order from the cultivation liquid tank 5, the pipe 34, the liquid pump 6, the cultivation liquid supply pipe 32, the cultivation liquid tank 3 stored in the shelf 14, the pipe 26, the cultivation liquid tank 3 accommodated in the shelf 13, and the pipe 26, the cultivation liquid can be circulated to the cultivation liquid tank 3, the pipe 26, and the cultivation liquid tank 5 which are stored in the shelf 12. That is, the cultivation liquid tank 5, the pipe 34, the liquid pump 6, the cultivation liquid supply pipe 32, the cultivation liquid tank 3 accommodated in the shelf 14, the pipe 26, the cultivation liquid tank 3 accommodated in the shelf 13, the pipe 26, The cultivating liquid tank 3, the pipe 26, and the cultivating liquid tank 5 stored in the shelf 12 are configured as a circulation path 35 through which the cultivating liquid circulates.

  In the circulation path 35, the inflow amount and the outflow amount of the cultivation liquid into each cultivation liquid tank 3 are equal, and the opening 24 of each cultivation liquid tank 3 is above the bottom plate 25 of the cultivation liquid tank 3. (See FIG. 6). Therefore, a constant amount of cultivation liquid can be always stored in each cultivation liquid tank 3. A plant is planted on the planting panel 4 through a seedling pot (not shown), and its root extends into the cultivation liquid tank 3. Therefore, the roots of the plant planted in the planting panel 4 can be immersed in the culture solution stored in the culture solution tank 3. The length of the root, the distance from the liquid level of the planting panel 4, and the like are set so that the roots of the plant planted on the planting panel 4 can be immersed in the culture solution stored in the culture solution tank 3.

(Detailed configuration of the plant cultivation apparatus 1)
Below, the structure of the plant cultivation apparatus 1 is demonstrated in more detail.

  As shown in FIG. 6, the opening 24 of each cultivation liquid tank 3 is disposed above the bottom plate 25 of the cultivation liquid tank 3. Further, the amount of the liquid pump 6 is set so that the amount of the cultivation liquid flowing into each of the cultivation liquid tanks 3 is within the amount that can be discharged from the opening 24. Therefore, the cultivation liquid that has flowed into the cultivation liquid tank 3 from the opening 30 and the opening 33 as an inflow part for allowing the cultivation liquid to flow into the cultivation liquid tank 3 is accumulated until the height (depth) of the opening 24 is exceeded. The cultivation liquid that has flowed in after flowing out flows out from the opening 24. That is, a certain amount of the cultivation liquid is stored in the cultivation liquid tank 3. In addition, in the following description, when it is not necessary to distinguish between the opening 30 and the opening 33 in the description of the configuration of the plant cultivation device 1, the opening 30 (33) is described. .

  Each cultivation liquid tank 3 presents a rectangular parallelepiped flattened in the vertical direction, and the opening 30 (33) and the opening 24 are arranged so as to cross the inside of the cultivation liquid tank 3 and the cultivation liquid tank 3. They are arranged diagonally. That is, as shown in FIG. 7, the cultivation liquid which flowed in from the opening part 30 (33) arrange | positioned in one corner of the four corners of the cultivation liquid tank 3 is in a position diagonal to this corner. It flows out from the opening part 24 arrange | positioned. In addition, arrangement | positioning crossing the inside of the tank of the cultivation liquid tank 3 means that the opening part 30 (33) and the opening part 24 are arrange | positioned so that one side and other side of the cultivation liquid tank 3 may be crossed. say.

  The positional relationship between the opening 30 (33) and the opening 24 is, for example, adjacent to each other as shown in the upper part (A) of FIG. 8 or the same as shown in the lower part (B) of FIG. It can also be considered that the arrangement is made along the side surface and does not cross the inside of the cultivation liquid tank 3. However, as shown in FIG. 7, by arranging the opening 30 (33) and the opening 24 at a position crossing the inside of the tank, the virtual line R connecting the opening 30 (33) and the opening 24 is formed. It becomes easy to generate a flow in the water area on both sides. That is, the flow is likely to occur over a wide range in the tank. As a result, the generation | occurrence | production of the residence part which the flow of the cultivation liquid in a tank stagnates can be suppressed. Moreover, by arrange | positioning the opening part 30 (33) and the opening part 24 in the position which becomes the diagonal of the cultivation liquid tank 3, in the tank, the opening part 30 (33) and the opening part 24 are the longest distance. Can be arranged. By increasing the distance (distance) between the opening 30 (33) and the opening 24, it becomes easy to generate a flow over a wide range in the tank.

  Further, the opening 30 (33) and the opening 24 are each provided at one place. A certain amount of the cultivation liquid flows into the cultivation liquid tank 3. Moreover, the quantity of the cultivation liquid which flows out from the cultivation liquid tank 3 is also constant. Therefore, when the opening 30 (33) is provided at a plurality of locations, that is, when the opening 30 (33) is a plurality of openings, the flow rate of the cultivation liquid flowing from each opening is reduced. Moreover, if it comprises also the opening part 24 with a some opening part, the flow volume of the cultivation liquid which flows out out of each opening part will decrease. Therefore, the flow from the opening 30 (33) to the opening 24 is easily finely dispersed, and the flow is less likely to occur in the cultivation liquid in the tank. As a result, the retention portion is likely to be generated.

  On the other hand, when the opening 30 (33) is provided at one place and the opening 24 is provided at one place, a large flow rate can be created from the opening 30 (33) to the opening 24. . Thereby, it becomes easy to generate | occur | produce a flow in the cultivation liquid in a tank, and a retention part becomes difficult to generate | occur | produce. In addition, "one place" said about the opening part 30 (33) and the opening part 24 does not mean one opening part for inflow or outflow, for example, even if there are a plurality of openings for inflow, When the openings are close enough to form a single flow in the tank, there is one opening 30 (33). Similarly, even if there are a plurality of outflow openings, if the openings are close to each other so that there is only one flow flowing into the opening, there is only one opening 24.

  In addition, it is preferable to form the opening 30 (33) from 1 to 3, preferably 2 or less openings. When the opening 30 (33) is formed by a plurality of openings, the size of each opening is reduced. When the size of the opening is reduced, wastes, root waste, etc. from the roots of the plant are likely to be clogged in the opening. Therefore, each of the openings 30 (33) can be formed larger by forming one to three, preferably two or less openings. Thereby, it is possible to prevent clogging of the plant wastes and root wastes in the opening.

  The opening 30 (33) is disposed at a position away from the liquid surface upward. That is, the cultivation liquid which flowed into the cultivation liquid tank 3 from the opening 30 (33) falls to the liquid level through the space between the opening 30 (33) and the liquid level. Thereby, cultivation liquid can contact air until it reaches a liquid level from opening 30 (33). Moreover, when a cultivation liquid falls on the liquid level, a cultivation liquid can be aerated by stirring a cultivation liquid and air.

  The height H (see FIG. 6) of the opening 24 of each cultivation liquid tank 3 from the bottom plate 25 is arranged at a height of 3 cm, and in each cultivation liquid tank 3, the water depth Q is slightly deeper than 3 cm. The culture solution is stored at a water depth Q of 3.2 cm. As described above, the inner dimensions of the cultivation liquid tank 3 are such that the left-right width W is 62 cm and the front-rear width T is 35 cm. Further, the longest distance L between the opening 30 (33) and the side surface of the cultivation liquid tank 3 is about 69 cm, and the distance P between the opening 30 (33) and the opening 24 is 67 cm. And the sending amount of the liquid pump 6 is set so that the inflow amount and outflow amount M of the cultivation liquid into the cultivation liquid tank 3 may be 6000 cc per minute.

  The size of the front and rear, left and right of the cultivation liquid tank 3, the depth Q of the cultivation liquid stored in the cultivation liquid tank 3, the longest distance L between the opening 30 (33) and the side surface of the cultivation liquid tank 3, and the opening 30 (33 ) And the opening 24 and the inflow amount and outflow amount M of the cultivating liquid are set as described above, so that the stagnation of the cultivating liquid in the cultivating liquid tank 3 can be suppressed. By suppressing the occurrence of retention, it is possible to prevent mold from being generated in the cultivation liquid, and it is possible to make the liquid quality (nutrient concentration, water temperature, etc.) of the cultivation liquid in the tank uniform. Therefore, since the liquid quality of the cultivation liquid becomes uniform, the growth of the plants planted in the planting panel 4 can be made uniform regardless of the position of the pot hole 29.

  Moreover, a flow is generated in the cultivation liquid when 6000 cc of the cultivation liquid flows into and out of the tank. The plant planted in the planting panel 4 is stimulated by the water flow of the roots immersed in the culture solution, so that the absorption of moisture and nutrients of the root is promoted, so that the growth of the plant is promoted.

  Although the water depth Q is described as 3.2 cm in the present embodiment, it is preferably set in the range of 0.5 cm to 7 cm. When the water depth Q is less than 0.5 cm, it becomes difficult for the roots of the plant to be immersed in the cultivation liquid, and the absorption efficiency of moisture and nutrients is lowered. In addition, when an accident occurs in which the circulation of the cultivation liquid stops due to a power failure, disconnection of the power outlet, etc., if the water depth Q is less than 0.5 cm, the cultivation liquid evaporates while the cultivation liquid circulation is stopped. There is a high risk that the plant will damage the plant in a short time until it becomes deep enough to absorb the cultivation liquid. On the other hand, when the water depth Q exceeds 7 cm, it is difficult to cause a flow in the cultivating liquid at a portion close to the bottom plate 25 of the cultivating liquid tank 3, and it is not preferable because stagnation is likely.

  By setting the water depth Q to 0.5 cm or more, the roots of the plant can be easily immersed in the culture solution, and the absorption efficiency of moisture and nutrients is such that there is no problem with the growth of the plant. Moreover, even if it is a case where the state where the circulation of the cultivation liquid has continued, the water depth at which the plant can suck up the cultivation liquid can be maintained for about at least 12 hours. Further, by setting the water depth Q to 7 cm or less, stagnation hardly occurs in a portion close to the bottom plate 25.

  Note that the above 12 hours is a general time from going to work to returning home, for example, in a home away from work, and in business places such as a cafeteria kitchen after business hours. It is the time when the staff (employee) is absent until the start. Therefore, when the plant cultivation apparatus 1 is installed in a home or canteen, even if the circulation of the cultivation liquid is stopped due to a power failure or the like while a person is absent, the plant can suck up the cultivation liquid for about 12 hours. If the water depth can be maintained, the person who goes home or goes to the kitchen notices that the circulation of the cultivation liquid has stopped, before the plant becomes unable to suck up the cultivation liquid, etc. It is easy to take measures such as recovering the above, or replenishing the cultivation liquid tank 3 with the cultivation liquid.

  When the water depth Q is 1 cm or more, the root of the plant is more easily immersed in the cultivation liquid, and the water depth at which the plant can suck up the cultivation liquid is maintained even when the circulation of the cultivation liquid continues. Can be maintained longer. Moreover, by setting the water depth Q to 6 cm or less, the flow of the cultivation liquid is easily generated also on the bottom plate 25 side, and the occurrence of the stay can be effectively suppressed.

  Furthermore, when the water depth Q is 2 cm or more, the roots of the plant can be more surely immersed in the cultivation liquid, and the plant can suck up the cultivation liquid even if the circulation of the cultivation liquid continues. The possible water depth can be maintained even longer. In addition, by setting the water depth Q to 5 cm or less, the flow of the cultivation liquid on the bottom plate 25 side is more likely to occur, and the occurrence of stagnation can be more reliably suppressed. For example, even if the inflow amount and outflow amount M of the cultivation liquid are set to about 500 cc / min, the occurrence of stagnation can be suppressed.

  In the plant cultivation device 1 of the present embodiment, the longest distance L between the opening 30 (33) and the side surface of the cultivation liquid tank 3 is 69 cm, and the distance P between the opening 30 (33) and the opening 24 is. Although it is 67 cm, the distance L is preferably 150 cm or less, and the distance P can be set in the range of 20 cm to 150 cm. When the distance L exceeds 150 cm, when the inflow of the cultivation liquid is about 500 cc / min, the flow does not reach the part where the distance L between the opening 30 (33) and the side surface of the cultivation liquid tank 3 exceeds 150 cm. , The retention portion is likely to occur. Similarly, with respect to the distance P between the opening 30 (33) and the opening 24, when the distance P exceeds 150 cm, when the inflow of the cultivation liquid is about 500 cc / min, from the opening 30 (33). Since the flow does not reach the opening 24, a stagnant portion is likely to occur. On the other hand, when the distance P between the opening 30 (33) and the opening 24 is less than 20 cm, the cultivation liquid flowing from the opening 30 (33) almost flows out from the opening 24 as it is, A stagnant part tends to occur in the tank.

  The inflow amount and outflow amount M of the cultivation liquid are described as 6000 cc / min in the present embodiment, but are preferably set in the range of 500 cc / min to 25000 cc / min. When it becomes less than 500 cc / min, the distance L (the longest distance between the opening 30 (33) and the side surface of the cultivation liquid tank 3) and the distance P (the distance between the opening 30 (33) and the opening 24) are obtained. In the case of 150 cm, a stay part tends to occur in the cultivation liquid in the tank. On the other hand, if it exceeds 25000 cc / min, when the distance P is 20 cm, the flow rate is too high, and there is a high risk of damaging the roots of the plant. The problem is likely to occur. In particular, when the distance L is 150 cm or less, if it exceeds 25000 cc / min, a problem that the cultivating liquid is likely to be scattered from the cultivating liquid tank 3 is likely to occur.

  When the distance L≈69 cm and the distance P≈67 cm as in the plant cultivation apparatus 1 of the present embodiment, the occurrence of stagnant portions can be suppressed by setting 4000 cc / min ≦ M ≦ 90000 cc / min. The flow rate is suitable for plant cultivation. Moreover, in the range of 4000 cc / min ≦ M ≦ 9000 cc / min, the distance L is 120 cm or less, and if the distance P is in the range of 45 cm to 120 cm, generation of stagnant portions can be suppressed and the plant A flow rate suitable for cultivation can be obtained.

  The cultivation liquid tank 3 of the plant cultivation apparatus 1 of the present embodiment has a rectangular shape in which the left-right direction is longer than the front-rear direction, and the opening 30 (33) and the opening 24 are arranged diagonally to each other. ing. The diagonal direction of the cultivation liquid tank 3 is a direction in which the distance P between the opening 30 (33) and the opening 24 can be taken longest in the cultivation liquid tank 3. By making the distance P as long as possible, the flow generated by being induced by the flow from the opening 30 (33) toward the opening 24 can be increased. That is, it becomes easy to generate a flow (a movement of the cultivation liquid) in the cultivation liquid stored in the tank, and it is possible to suppress the occurrence of a retention portion in the cultivation liquid.

  The left and right and front three sides of the shelf parts 12, 13, and 14 of the plant cultivation apparatus 1 are open. Therefore, a hand can be put into the shelf from three sides. Therefore, for example, compared to a configuration in which three sides are surrounded by a glass plate or the like, an operation of planting a plant in the pot hole 29, an operation of collecting a plant from the planting panel 4, or cleaning the inside of the cultivation liquid tank 3 The work efficiency of various work such as work to be performed can be improved.

  Further, since the three sides are released, air can be distributed to the shelves 12, 13, and 14. A configuration is also conceivable in which the left and right sides and the front side of the shelves 12, 13, and 14 are surrounded by glass plates or the like, and the air circulation in the shelves 12, 13, and 14 is forced by an electric fan or the like. However, as in the present embodiment, when the size of the plant cultivation apparatus 1 is, for example, a height of 190 cm, a horizontal width of 75 cm, and a front and rear depth of about 40 cm, the environment is set in a room of a general house. Compared with the case where the air circulation is forcibly made by an electric fan or the like, the natural air circulation is more suitable for the healthy cultivation of plants.

  In addition, the depth P of the cultivation liquid stored in the cultivation liquid tank 3 is 0.5 cm or more and 6 cm or less, the distance P between the opening 30 (33) and the opening 24 is 20 cm or more and 150 or less, and the opening 30 (33). As long as the plant cultivation apparatus 1 is configured to have a size in which the longest distance L to the side of the cultivation liquid tank 3 satisfies 150 cm or less, ventilation to the plant is natural compared to forced means such as an electric fan. It is suitable for the healthy cultivation of plants to circulate fresh air.

(Modification 1)
As shown in FIG. 9, the distal end portion 26 </ b> A of the pipe 26 and the distal end portion 32 </ b> A of the cultivation liquid supply pipe 32 are bent into an L shape, and the cultivation liquid is allowed to flow horizontally into the tank from the opening 30 (33). It is good. Thereby, compared with the case where it is set as the structure which drops the cultivation liquid mentioned above to the liquid level from a top, it becomes easy to generate | occur | produce a flow in a cultivation liquid. In this case, it is preferable that the inflow direction, that is, the direction in which the cultivation liquid flows into the tank from the opening 30 (33) is closer to the opening 24 than the opening 30 (33). Specifically, the opening 24 side of the opening 30 (33) is orthogonal to the direction passing through the opening 30 (33) and the opening 24 and passes through the opening 30 (33). It means the side of the opening 24 rather than the direction. By setting the direction in which the cultivation liquid flows into the tank from the opening 30 (33) to the opening 24 side of the opening 30 (33), a flow from the opening 30 (33) toward the opening 24 occurs. It becomes easy and stagnation does not occur easily in the cultivation liquid in the tank.

  The direction in which the cultivation liquid flows into the tank from the opening 30 (33) can be set, for example, as shown in FIGS. 10 to 14 schematically show the results when the flow generated in the cultivation liquid stored in the cultivation liquid tank 3 is observed. The distal end portion 26A of the pipe 26 and the distal end portion 32A of the cultivation liquid supply pipe 32 are bent into an L shape. The flow was observed by hanging a paint on the opening 30 (33) and observing the locus of the paint. The flow shown in FIG. 10 to FIG. 14 is the cultivation liquid tank 3 having a lateral width W of 62 cm and a longitudinal width T of 32 cm. The cultivation liquid is stored at a water depth Q of 3 cm. 24 are arranged diagonally to each other, and the inflow and outflow M are 2500 cc / min.

  FIG. 10 shows a flow state when the inflow direction of the cultivation liquid is directed to the opening 24. In the cultivation liquid, there is a tendency that a flow A1 from the opening 30 (33) toward the opening 24 and flows A2 and A3 flowing in a direction away from the opening 24 are mainly generated. The flow A2 merges with the flow A1 along the side surface 3A from the side surface 3A, and the flow A3 merges with the flow A1 along the side surface 3D from the side surface 3B. The flow from the flow A1 to the flow A2 becomes a recirculation flow, and there is a tendency that the stay portion A4 is generated inside the recirculation flow. In addition, the flow from the flow A1 to the flow A3 is also a recirculation flow, and there is a tendency that a stay part A5 is generated inside the recirculation flow. Moreover, there exists a tendency for stay part A6, A7 to generate | occur | produce in the diagonal parts 3E and 3F in which the opening part 30 (33) and the opening part 24 of the cultivation liquid tank 3 are not arrange | positioned.

  FIG. 11 shows a flow state when the inflow direction of the cultivation liquid is 45 degrees from the side surface 3C. The cultivation liquid mainly travels straight from the opening 30 (33) and reaches the side surface 3A, and then flows B1 toward the opening 24 along the side surface 3A and a flow B2 that forms a circulation on both sides of the flow B1. , B3 tend to occur. A large stay portion is not generated from the flow B1 to the inside of the flow B2, but a large stay portion B4 is generated between the flow B2 and the corner portion 3E, and is also large inside the flow from the flow B1 to the flow B3. There exists a tendency for the retention part B5 to occur. Further, there is a tendency that a staying part B6 is generated between the flow B3 and the corner part 3F.

  FIG. 12 shows the state of the flow when the inflow direction of the cultivation liquid is 20 degrees from the side surface 3C on the short side. The cultivation liquid tends to generate a flow C1 that travels straight from the opening 30 (33) and reaches the side surface 3A and then toward the opening 24 along the side surface 3A. And the cultivation liquid which was not flowed out by the opening part 24 among flow C1 generate | occur | produces the flow C2 which flows along the side surfaces 3B and 3D, the flow of the flow C2 turns into a recirculation from the flow C1, and a big residence inside this recirculation | circulation Part C3 tends to occur. In the diagonal parts 3E and 3F of the cultivation liquid tank 3, there is a tendency that the stay parts C4 and C5 are generated.

  FIG. 13 shows a flow state in the case where the inflow direction of the cultivation liquid is set along the side surface 3D on the long side. In the cultivation liquid, there is a tendency that a flow D1 mainly proceeds straight from the opening 30 (33) along the side surface 3D and toward the opening 24 in front of the corner 3F. And among the flow D1, the cultivation liquid which was not flowed out by the opening part 24 produces | generates the flow D2 which flows along the side surface 3A, the flow of the flow D2 becomes a recirculation from the flow D1, and the big residence part D3 inside this recirculation | circulation Tend to occur. In the diagonal parts 3E and 3F of the cultivation liquid tank 3, the stay parts D4 and D5 are generated. The staying part D4 tends to be larger than the staying part D5.

  FIG. 14 shows a flow state when the inflow direction of the cultivation liquid is parallel to the side surfaces 3A and 3D from the center of the side surface 3C on the short side. In the cultivating liquid, a flow E1 mainly from the opening 30 (33) toward the opening 24 is generated, and among the flow E1, the cultivating liquid that has not flowed out through the opening 24 flows along the side surface 3A. And there exists a tendency to generate the flow E3 which flows along the side surfaces 3B and 3D. And the flow of the flow E1 to the flow E3 turns into a recirculation | flow, and there exists a tendency for the big retention part E4 to generate | occur | produce inside this recirculation | flow. On both sides of the opening 30 (33) of the cultivating liquid tank 3, the stay portions E5 and E6 tend to occur, and the stay portion E7 tends to occur on the diagonal portion 3F.

  Of the staying parts shown in FIGS. 10 to 14, except for the staying parts E5 and E6 of FIG. 14, while continuing the inflow and outflow of the cultivation liquid, within ten to several tens of seconds, Although the cultivation liquid around the staying part flows into the staying part and the staying is eliminated, it has been observed that it takes several minutes for the staying parts E5 and E6 to flow into the surrounding cultivation liquid.

  From the results of the observation shown in FIG. 10 to FIG. 14, as shown in FIG. 10, when the inflow direction of the cultivation liquid from the opening 30 (33) is directed to the opening 24, the size of the staying portion generated is Compared to other cases (the case shown in FIGS. 11 to 14), the overall size is small, and an extremely large stay portion is unlikely to occur. Furthermore, the time until the surrounding cultivation liquid flows into the staying part and the staying is eliminated is shorter than in other cases. Therefore, about the rectangular cultivation liquid tank 3, the opening part 30 (33) and the opening part 24 are arrange | positioned diagonally, and the inflow direction of the cultivation liquid from the opening part 30 (33) is made into the opening part 24 It is preferable to point.

  In addition, as shown in FIG. 15, it can suppress that a residence part generate | occur | produces in the vicinity of corner | angular part 3E, 3F by attaching a round to corner | angular part 3E, 3F of the cultivation liquid tank 3. FIG.

(Modification 2)
As shown in FIG. 16, the distal end portion 26A of the pipe 26 is bent into an L shape, and a part of the opening 30 is positioned above the liquid level 37 of the cultivation liquid stored in the cultivation liquid tank 3, It is good also as a structure which forms the space 36 in the pipe 26 through which culture solution flows. A part of the opening 30 is disposed above the liquid level 37 of the cultivation liquid, and the flow rate of the cultivation liquid flowing in the pipe 26 is made smaller than the volume in the pipe 26, so that the pipe 26 A space 36 is formed at both ends. By forming the space 36, the cultivation liquid flowing down from the upper cultivation liquid tank 3 to the lower cultivation liquid tank 3 in the pipe 26 can be exposed to the air. Thereby, a cultivation liquid can be aerated. The cultivation liquid is also aerated when the cultivation liquid flowing down in the pipe 26 falls into the L-shaped portion of the pipe 26 and flows into the opening 30 and the flow is disturbed and the cultivation liquid and air are stirred. The As described above, the amount of dissolved oxygen in the cultivation liquid can be increased by aeration of the cultivation liquid.

  Further, as shown in FIG. 17, the tip 32A of the cultivating liquid supply pipe 32 is bent into an L shape, and a branching portion 39 is provided in the cultivating liquid supply pipe 32 so that one of the branches communicates with the opening 33 to branch. The other is communicated with the opening 38 that opens at a position away from the flow path from the liquid pump 6 to the opening 33, and a space 40 is formed in the cultivating liquid supply pipe 32 through the opening 38 to the opening 33. It is good. A part of the opening 33 is positioned above the liquid level 37 of the cultivation liquid stored in the cultivation liquid tank 3, and the flow rate of the cultivation liquid flowing in the section from the branch part 39 to the opening 33 is set in the section. The space 40 can be formed by making it smaller than the volume of.

  By forming the space 40, the cultivation liquid flowing into the cultivation liquid tank 3 from the liquid pump 6 can be exposed to the air. Thereby, a cultivation liquid can be aerated. Further, the cultivation liquid is aerated when the cultivation liquid and the air are agitated while the cultivation liquid flows down from the branch portion 39 to the bent portion of the cultivation liquid supply pipe 32 and flows into the opening 33 and the flow is disturbed. Is done. As described above, the amount of dissolved oxygen in the cultivation liquid can be increased by aeration of the cultivation liquid.

(Modification 3)
As shown in FIG. 18, the plant cultivation apparatus 1 may be provided with a transparent curtain 41 that covers the left and right and the front three sides of the shelf 2 in a configuration that can be opened and closed. The curtain 41 is attached to a curtain rail 42 and can be opened and closed left and right at the center of the front surface. When the temperature around the plant cultivation apparatus 1 is high, it is preferable to encourage the ventilation to the shelves 12, 13, and 14 by opening the curtain 41. By covering the open portions of the shelves 12, 13, and 14 with the curtain 41 at a time when the temperature is low, the plants in the plant cultivation apparatus 1 can be protected from low-temperature damage.

  The curtain 41 is preferably provided with pleats 43. By providing the pleats 43, even when the curtains 41 cover the open portions of the shelves 12, 13, and 14, a gap 44 as shown in FIG. 18 is formed between the pleats 43 and the shelves 2. . By forming the gap 44, an air flow can be formed between the shelf 2 and the curtain 41. For this reason, ventilation can be performed between the inside of the shelf parts 12, 13, and 14 covered with the curtain 41 and the outside air. The gap 44 is not formed by the pleats 43, but a hole is formed in the curtain 41, or a gap is formed between the curtain rail 42 and the shelf 2 so that the curtain 41 and the shelf 2 are separated. It is good also as a structure by which a clearance gap is formed between them.

  The curtain 41 is preferably formed of a resin such as polyvinyl chloride or polyethylene. Resins have lower thermal conductivity than glass. Therefore, the adhesion of water droplets to the curtain 41 can be suppressed as compared with the case where the shelves 12, 13, and 14 are covered with glass. By suppressing the adhesion of water droplets, the occurrence of mold in the shelves 12, 13, and 14 can be suppressed. Moreover, compared with the case where glass is used, the inside of the shelf parts 12, 13, and 14 can be kept warm.

  In addition, by covering the shelves 12, 13, and 14 with the curtain 41, children and pets can prevent accidents such as tampering with plants accepted by the planting panel 4 or accidentally drinking the cultivation liquid. be able to.

(Main effects of this embodiment)
The plant cultivation apparatus 1 is stored in the cultivation liquid tank 3 in which the cultivation liquid is stored, the opening 30 (33) as an inflow part for allowing the cultivation liquid to flow into the cultivation liquid tank 3, and the cultivation liquid tank 3. And an opening 24 as an outflow part for allowing the cultivation liquid to flow out from the cultivation liquid tank, and an inflow amount of the cultivation liquid flowing into the cultivation liquid tank 3 from the opening 30 (33) and outflow from the opening 24. The outflow amount is set to be equal in a state where a predetermined amount of the cultivation liquid is accumulated in the cultivation liquid tank 3. The plant cultivation apparatus 1 includes a cultivation liquid tank 5 in which the cultivation liquid is stored, and a liquid pump 6 that sends the cultivation liquid from the cultivation liquid tank 5 to the cultivation liquid tank 3. The tank 5 and the liquid pump 6 are held by a shelf 2 as an attachment body.

  Thus, the plant cultivation apparatus 1 is integrated by making the shelf 2 hold the cultivation liquid tank 3, the cultivation liquid tank 5, and the liquid pump 6. Thereby, the freedom degree of the installation place of the plant cultivation apparatus 1 becomes large, and the restriction | limiting of an installation place decreases.

  In addition, the opening 30 (33) allows the cultivation liquid to flow into one place in the cultivation liquid tank 3, and the opening 24 causes the cultivation liquid to flow out from one place in the cultivation liquid tank 3, and the opening 30 (33). ) And the opening 24 are arranged at positions that cross the inside of the cultivation liquid tank 3. By arrange | positioning the opening part 30 (33) and the opening part 24 in the position which crosses the inside of the tank of the cultivation liquid tank 3, it becomes easy to generate | occur | produce a flow over the wide range in a tank, As a result, cultivation in a tank Generation | occurrence | production of a retention part in a liquid can be suppressed. Moreover, by making each of the opening 30 (33) and the opening 24 one place, a large flow can be made from the opening 30 (33) to the opening 24, and the cultivation liquid in the tank It becomes easy to generate a flow. As a result, it becomes difficult to generate a staying portion.

  In above-mentioned embodiment, although the opening part 30 (33) and the opening part 24 showed the example arrange | positioned in the diagonal direction of the cultivation liquid tank 3 which exhibits a rectangle, as shown to FIG. 19 (A), The opening part 30 (33) and the opening part 24 can also be set as the structure arrange | positioned in the longitudinal direction of the cultivation liquid tank 3. FIG. Further, as shown in FIG. 19B, the opening 30 (33) and the opening 24 may be arranged in the short direction. Furthermore, as shown in FIG. 19 (C), various ones such as arranging one of the opening 30 (33) or the opening 24 at the corner of the cultivation liquid tank 3 and arranging the other on the side surface 3C side. It can be configured.

  In the above-mentioned embodiment, although the attachment body showed the example made into the structure of the frame comprised by the support | pillar 8, the housing | casing 9, and the housing 10, the shelf was comprised with the panel and it was as a case body or a cabinet body. Also good. Moreover, about the shelf part in which the cultivation liquid tank 3 is stored, it may be configured to be transparent or covered with a transparent glass plate or resin so that light from the outside can enter, but it is covered with a light shielding plate, It is good also as a structure which performs a photosynthesis using the light of the illuminating lamp 7 with which the shelf part was equipped. As the illumination lamp 7, various light sources, such as a fluorescent lamp and LED, can be used, for example.

  In addition, about the back panel 20, it is preferable to make a front surface into a mirror surface. By making the front surface of the back panel 20 a mirror surface, it becomes easy to allow light to reach the plants arranged on the rear side. The front surface of the back panel 20 can be configured as a light reflecting surface by using a mirror surface, white or light color, or a light retroreflecting surface.

  The shelf 2 described above is configured in four stages, but may be configured in two stages, three stages, or five stages or more. In this case, the cultivation liquid tank 5 and the liquid pump 6 are arrange | positioned at the lowest stage.

The plant cultivation apparatus 1 has a depth Q of the cultivation liquid stored in the cultivation liquid tank 3, a distance P between the opening 30 (33) and the opening 24, and an opening 30 (33) and the side surface of the cultivation liquid tank 3. When L is the longest distance to and M is the inflow and outflow of the cultivation liquid,
0.5cm ≦ Q ≦ 7cm
20cm ≦ P ≦ 150cm
L ≦ 150cm
It is preferable that 500 cc / min ≦ M ≦ 25000 cc / min.

  By setting it as this structure, it can suppress effectively staying in the cultivation liquid in the cultivation liquid tank 3, and the extent which does not damage a plant root to the cultivation liquid in the cultivation liquid tank 3 A water stream can be generated.

  The cultivation liquid tank 3 has an elongated shape in the horizontal direction, and the opening 30 (33) and the opening 24 are arranged in the longitudinal direction.

  By disposing the opening 30 (33) and the opening 24 in the longitudinal direction of the cultivation liquid tank 3, the distance P between the opening 30 (33) and the opening 24 can be increased. By making the distance P between the opening 30 (33) and the opening 24 as long as possible, the flow generated by being induced by the flow from the opening 30 (33) toward the opening 24 can be increased. It can suppress that a retention part generate | occur | produces in a cultivation liquid because a flow (movement of a cultivation liquid) increases to the cultivation liquid stored in a tank. On the other hand, it is difficult for a flow to occur in the short direction, which is a direction orthogonal to the direction in which the opening 30 (33) and the opening 24 are arranged. However, by narrowing the width of the cultivating solution tank 3 in the short direction, it is possible to prevent the staying portion from being generated in the region in the short direction.

  The shape of the cultivation liquid tank 3 in the horizontal plane and the arrangement of the opening 30 (33) and the opening 24 are such that the cultivation liquid tank 3 is elliptical and opens in the long axis direction, as shown in the upper part (A) of FIG. The portion 30 (33) and the opening 24 are arranged, or, as shown in the lower part (B) of FIG. 20, the cultivation liquid tank 3 is rhombused, and the opening 30 (33) and the opening are formed in an acute diagonal direction. 24 can be arranged.

  In the cultivation liquid tank 3 of the plant cultivation apparatus 1, the shape in the horizontal plane of the cultivation liquid tank 3 is an elongated rectangle, and the opening 30 (33) and the opening 24 are arranged diagonally to each other.

  By making the shape in the horizontal surface of the cultivation liquid tank 3 into a rectangle, it becomes easy to make the whole shape of the plant cultivation apparatus 1 into a rectangular parallelepiped. Generally, the interior of a building is a rectangular parallelepiped. Therefore, by setting the overall shape of the plant cultivation device 1 to be a rectangular parallelepiped, the plant cultivation device 1 can be installed so as to reduce the dead space when installed in the room. Further, the rectangular shape is elongated, and the opening 30 (33) and the opening 24 are arranged diagonally to each other, thereby making the distance P between the opening 30 (33) and the opening 24 as long as possible. It is possible to increase the flow generated by being induced by the flow from the opening 30 (33) toward the opening 24, and to prevent the staying portion from being generated in the cultivation liquid.

  As shown in FIG. 9, the tip 26A of the pipe 26 and the tip 32A of the cultivation liquid supply pipe 32 are bent into an L shape, and the cultivation liquid flowing into the tank from the opening 30 (33) It is preferable to adopt a configuration in which the fluid is allowed to flow in the horizontal direction toward the side where 24 is disposed.

  With this configuration, it becomes easier to generate a flow in the cultivation liquid as compared with the case where the cultivation liquid is dropped from above onto the liquid surface. And the flow which goes to the opening part 24 from the opening part 33 is easy to generate | occur | produce by making the inflow direction, ie, the direction into which a culture solution flows into the tank from the opening part 33 into the opening part 24 side rather than the opening part 30 (33). It becomes difficult to stay in the cultivation liquid in the tank. Moreover, by allowing the cultivation liquid to flow in the horizontal direction, it becomes easy to generate a flow in the cultivation liquid and to stimulate the roots of the plant.

  As shown in FIGS. 16 and 17, a part of the opening 30 (33) is disposed above the liquid level 37 of the cultivation liquid stored in the cultivation liquid tank 3, and the opening 30 (33) is cultivated. It is preferable to form a space 36 (FIG. 16) and a space 40 (FIG. 17) between the cultivation liquid flowing into the liquid tank 3. By forming the spaces 36 and 40, the cultivation liquid can be introduced into the cultivation liquid tank 3 from the opening 30 (33) in a state where the cultivation liquid is aerated. Thereby, the dissolved oxygen amount of a cultivation liquid can be increased.

DESCRIPTION OF SYMBOLS 1 ... Plant cultivation apparatus 2 ... Shelf (attachment body)
DESCRIPTION OF SYMBOLS 3 ... Cultivation liquid tank 5 ... Cultivation liquid tank 6 ... Liquid pump 24 ... Opening part (outflow part)
30, 33 ... opening (inflow part)
37 ... Liquid level 36, 40 ... Space Q ... Depth of cultivation liquid stored in cultivation liquid tank P ... Distance between inflow part and outflow part L ... Longest distance between inflow part and side surface of cultivation liquid tank M ... Cultivation Inflow and outflow of liquid

Claims (7)

A cultivation liquid tank in which the cultivation liquid is stored;
An inflow portion for allowing the cultivation liquid to flow into the cultivation liquid tank;
An outflow part for causing the cultivation liquid stored in the cultivation liquid tank to flow out of the cultivation liquid tank;
With
The inflow amount of the cultivation liquid flowing into the cultivation liquid tank from the inflow part and the outflow amount flowing out from the outflow part are in a state where a predetermined amount of the cultivation liquid is accumulated in the cultivation liquid tank. In plant cultivation equipment set to be equal,
A cultivation liquid tank in which the cultivation liquid is stored;
A liquid pump for delivering the cultivation liquid from the cultivation liquid tank to the cultivation liquid tank;
An attachment body to which the cultivation liquid tank, the cultivation liquid tank and the liquid pump are attached;
Have
The inflow part causes the cultivation liquid to flow into one place in the cultivation liquid tank,
The outflow part causes the cultivation liquid to flow out from one place in the cultivation liquid tank,
The inflow portion and the outflow portion are arranged at positions that cross the inside of the cultivation liquid tank,
A plant cultivation apparatus characterized by that. In the plant cultivation device according to claim 1,
Q, the depth of the cultivation liquid stored in the cultivation liquid tank
The distance between the inflow portion and the outflow portion is P,
L is the longest distance between the inflow part and the side of the cultivation liquid tank,
The inflow and outflow amount of the cultivation liquid is M,
And when
0.5cm ≦ Q ≦ 7cm
20cm ≦ P ≦ 150cm
L ≦ 150cm
500 cc / min ≦ M ≦ 25000 cc / min In the plant cultivation device according to claim 1 or 2,
The cultivation liquid tank has an elongated shape in the horizontal direction,
The inflow portion and the outflow portion are arranged in the longitudinal direction.
A plant cultivation apparatus characterized by that. In the plant cultivation device according to claim 3,
The elongated shape is a rectangle;
The inflow portion and the outflow portion are arranged diagonally to each other,
A plant cultivation apparatus characterized by that. In the plant cultivation device according to any one of claims 1 to 4,
The inflow portion causes the cultivation liquid to flow in the horizontal direction on the side where the outflow portion is disposed.
A plant cultivation apparatus characterized by that. In the plant cultivation device according to claim 5,
A part of the inflow part is located above the liquid level of the cultivation liquid stored in the cultivation liquid tank,
In the inflow part, a space is formed between the cultivation liquid flowing into the cultivation liquid tank,
A plant cultivation apparatus characterized by that. A cultivation liquid tank in which the cultivation liquid is stored;
An inflow portion for allowing the cultivation liquid to flow into the cultivation liquid tank;
An outflow part for causing the cultivation liquid stored in the cultivation liquid tank to flow out of the cultivation liquid tank;
With
The inflow amount of the cultivation liquid flowing into the cultivation liquid tank from the outflow part and the outflow amount flowing out from the outflow part are in a state where a predetermined amount of the cultivation liquid is accumulated in the cultivation liquid tank. In plant cultivation equipment set to be equal,
A cultivation liquid tank in which the cultivation liquid is stored;
A liquid pump for delivering the cultivation liquid from the cultivation liquid tank to the cultivation liquid tank;
An attachment body to which the cultivation liquid tank, the cultivation liquid tank and the liquid pump are attached;
Have
The inflow portion causes the cultivation liquid to flow in the horizontal direction on the side where the outflow portion is disposed,
A part of the inflow part is located above the liquid level of the cultivation liquid stored in the cultivation liquid tank,
In the inflow part, a space is formed between the cultivation liquid flowing into the cultivation liquid tank,
A plant cultivation apparatus characterized by that.

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