JP6292700B1 - Yield prediction system in vertical hydroponics - Google Patents

Abstract

[PROBLEMS] To provide a yield prediction system in vertical hydroponics capable of accurately predicting the yield and harvest time of a plant by numerical values. SOLUTION: A plurality of vertical hydroponics tubes suspended in a suspended portion provided on the ceiling side in a plant cultivation house 13 that receives sunlight or artificial light, a culture medium, a nutrient solution storage tank, and a nutrient solution It is provided with a nutrient solution supply means and a nutrient solution recovery means, and is provided with a vertical slit for planting plant seedlings in the culture medium on one side surface of the vertical hydroponic cultivation cylinder. A culture medium for a vertical hydroponic cultivation cylinder, comprising a weight sensor 9 that outputs a detection signal corresponding to the weight of the vertical hydroponic cultivation pipe between the cultivation cylinder and weight calculation means 14 that calculates the weight based on the detection signal. A yield prediction system comprising a yield prediction calculation means 15 that predicts the yield of a plant based on the weight increased from the reference value, with the weight in a state where a plant seedling is implanted and the nutrient solution is supplied as a reference value. [Selection] Figure 1

Description

  The present invention relates to a yield prediction system in vertical hydroponics.

As an agricultural issue, it is very difficult to make a profit and loss forecast, especially in plant factories that require a large amount of capital investment, predicting plant yield and harvest time is indispensable for maintaining the overall business potential. Element.
Conventionally, as a system for predicting the harvest time of plants, the average temperature for the same day of the same month is used for the effective temperature, which is the temperature that exceeds the growth limit temperature of the crop for which the harvest time is predicted, among the average temperatures of each day of the past multiple years. By using the first storage unit that stores the value, the average value is integrated with the effective integrated temperature based on the actual measurement value of the average temperature of each day from the start of cultivation of the crop to the day before the forecast implementation date. A computer in which processing for calculating a predicted value of harvest time is executed by a computer is disclosed (Cited document 1).
Further, as a plant yield prediction system, a system that predicts a rough yield from an image of a camera that captures a plant can be considered.

JP 2013-191107 A

As described above, the conventional system predicts the harvest time of crops based on the relationship between the average temperature in the past several years and the harvest time, so there are many uncertainties and it is only possible to roughly predict the harvest time. There is a problem that you can not.
In addition, there is a problem that the yield prediction is not useful at all, and the yield prediction has to be roughly predicted by visual observation or video from a camera.

  The problem to be solved by the present invention is that in vertical hydroponics that can accurately predict the yield and harvest time of a plant by numerical values regardless of the visual or camera image and regardless of the cultivation environment. It is to provide a yield prediction system.

In order to solve the above-mentioned problem, the yield prediction system in vertical hydroponics according to claim 1,
A plurality of vertical hydroponics cylinders 1 suspended in a suspended portion 10 provided on the ceiling side in a plant cultivation house 13 that receives sunlight or artificial light, and accommodated in the vertical hydroponics cylinder 1 in a removable manner. The culture medium 2, the nutrient solution storage tank 3, the nutrient solution supply means 4 for supplying the nutrient solution 7 from the nutrient solution storage tank 3 to the culture medium 2, and the nutrient solution 7 dropped from the lower part of the vertical hydroponics cylinder 1 are collected. A nutrient solution collecting means 5 for
The vertical hydroponics cylinder 1 is provided with an opening 11 for planting a plant seedling 6 in the medium 2 on one side surface thereof,
The culture medium 2 is composed of a water-retaining sheet 21 and breathable materials 22 and 23 sandwiching both sides thereof,
The upper part of the water retaining sheet protruding from the upper ends of the breathable materials 22 and 23 is bent and placed on the upper surface of at least one of the breathable materials 23,
It is configured to drop the nutrient solution 7 from the nutrient solution supply means onto the water-retaining sheet 21a that is bent and placed,
A weight sensor 9 for outputting a detection signal corresponding to the weight of each vertical hydroponic cultivation cylinder 1 is provided between the suspended portion 10 and each vertical hydroponic cultivation cylinder 1.
Weight calculating means 14 for calculating the weight of each vertical hydroponics cylinder 1 based on the detection signal from the weight sensor 9,
The weight calculated by the weight calculating means 14 in a state where the plant seedling 6 is planted in the medium 2 of the vertical hydroponics cylinder 1 and the nutrient solution 7 is supplied from the nutrient solution storage tank 3 to the medium 2 is used as a reference value. Thereafter, it is provided with a yield prediction calculating means 15 for predicting the yield of the plant by the weight increasing from the reference value.

Moreover, the yield prediction system in the vertical hydroponics according to claim 2 is a plurality of vertical hydroponic cultures hung on the suspended portion 10 provided on the ceiling side in the plant cultivation house 13 that receives sunlight or artificial light. A tube 1, a medium 2 accommodated in the vertical hydroponics tube 1 so as to be removable, a nutrient solution storage tank 3, and a nutrient solution supply means 4 for supplying the nutrient solution 7 from the nutrient solution storage tank 3 to the medium 2 A nutrient solution collecting means 5 for collecting the nutrient solution 7 dripped from the lower part of the vertical hydroponics cylinder 1, and
The vertical hydroponics cylinder 1 is provided with an opening 11 for planting a plant seedling 6 in the medium 2 on one side surface thereof,
The culture medium 2 is composed of a water-retaining sheet 21 and breathable materials 22 and 23 sandwiching both sides thereof,
The water retaining sheet upper end protruding from the upper ends of the breathable materials 22, 23 is bent and placed on the upper surface of one of the breathable materials 23,
A separate water-retaining sheet 24 is placed on the upper surface of the air-permeable material 22 opposite to the air-permeable material 23 on which the water-retaining sheet is folded and placed, and its lower end is brought into contact with the water-retaining sheet 21. And
The nutrient solution 7 is folded from the nutrient solution supply means 4 to the water-retaining sheet 21a that is folded and placed, or a separate water-retaining sheet 24.
A weight sensor 9 for outputting a detection signal corresponding to the weight of each vertical hydroponic cultivation cylinder 1 is provided between the suspended portion 10 and each vertical hydroponic cultivation cylinder 1.
Weight calculating means 14 for calculating the weight of each vertical hydroponics cylinder 1 based on the detection signal from the weight sensor 9,
The weight calculated by the weight calculating means 14 in a state where the plant seedling 6 is planted in the medium 2 of the vertical hydroponics cylinder 1 and the nutrient solution 7 is supplied from the nutrient solution storage tank 3 to the medium 2 is used as a reference value. Thereafter, it is provided with a yield prediction calculating means 15 for predicting the yield of the plant by the weight increasing from the reference value .

Moreover, the yield prediction system in the vertical hydroponics according to claim 3 is a plurality of vertical hydroponics suspended in a suspended portion 10 provided on the ceiling side in the plant cultivation house 13 that receives sunlight or artificial light. A tube 1, a medium 2 accommodated in the vertical hydroponics tube 1 so as to be removable, a nutrient solution storage tank 3, and a nutrient solution supply means 4 for supplying the nutrient solution 7 from the nutrient solution storage tank 3 to the medium 2 A nutrient solution collecting means 5 for collecting the nutrient solution 7 dripped from the lower part of the vertical hydroponics cylinder 1, and
The vertical hydroponics cylinder 1 is provided with an opening 11 for planting a plant seedling 6 in the medium 2 on one side surface thereof,
The culture medium 2 is composed of a water-retaining sheet 21 and breathable materials 22 and 23 sandwiching both sides thereof,
The upper end portion of the water retaining sheet protruding from the upper ends of the breathable materials 22 and 23 is folded and placed on the upper surface of one breathable material 23, and the tip is folded and placed on the upper surface side of the other breathable material 22. And
It is configured to drop the nutrient solution 7 from the nutrient solution supply means 4 onto the water-retaining sheet 21b that is folded and placed,
A weight sensor 9 for outputting a detection signal corresponding to the weight of each vertical hydroponic cultivation cylinder 1 is provided between the suspended portion 10 and each vertical hydroponic cultivation cylinder 1.
Weight calculating means 14 for calculating the weight of each vertical hydroponics cylinder 1 based on the detection signal from the weight sensor 9,
The weight calculated by the weight calculating means 14 in a state where the plant seedling 6 is planted in the medium 2 of the vertical hydroponics cylinder 1 and the nutrient solution 7 is supplied from the nutrient solution storage tank 3 to the medium 2 is used as a reference value. Thereafter, it is provided with a yield prediction calculating means 15 for predicting the yield of the plant by the weight increasing from the reference value.

Moreover, the yield prediction system in the vertical hydroponics according to claim 4 is the yield prediction system in the vertical hydroponics according to claim 1 ,
The weight of each vertical hydroponics cylinder 1 calculated by the weight calculation means 14 and / or the plant yield predicted by the yield prediction calculation means 15 is transmitted to the data server 16 via the Internet N. It is characterized by being.

Moreover, the yield prediction system in the vertical hydroponics of Claim 5 is a yield prediction system in the vertical hydroponics of any one of Claims 1-4 ,
It is characterized by comprising a notification means 17 for notifying by lighting of light when the yield of the plant of each vertical hydroponic cultivation cylinder 1 predicted by the yield prediction calculation means 15 reaches a preset planned harvest amount .

Moreover, the yield prediction system in the vertical hydroponics of Claim 6 is the yield prediction system in the vertical hydroponics of any one of Claims 1-5 ,
The bent or folded water-retaining sheet is formed in an inclined shape that increases as it goes outward .

Moreover, the yield prediction system in the vertical hydroponics of Claim 7 is a yield prediction system in the vertical hydroponics of any one of Claims 1-6,
Characterized in that it comprises a tilting member 8 having a higher becomes inclined upper surface taken to go to either side wall of the vertical hydroponics tube around the water retaining sheet 21 at least on an upper surface of said breathable material on one side .

Moreover, the yield prediction system in the vertical hydroponics of Claim 8 is a yield prediction system in the vertical hydroponics of any one of Claims 1-6 ,
The upper surface of at least one side of the breathable material is formed in an inclined shape that increases as it goes outward with the water-retaining sheet as a center .

Moreover, the yield prediction system in the vertical hydroponics of Claim 9 is a yield prediction system in the vertical hydroponics of any one of Claims 1-8 ,
The nutrient solution collecting means 5 includes a drain pan 51 that collects the nutrient solution 7 dripped from the lower part of the vertical hydroponic cultivation cylinder 1, and circulates the nutrient solution 7 collected in the drain pan 51 to the nutrient solution storage tank 3. It is comprised as follows.

In the yield prediction system in the vertical hydroponics according to any one of claims 1 to 3, as described above, plant seedlings 6 are planted in the medium 2 of the vertical hydroponics cylinder 1, and the nutrient solution storage tank 3 transfers the medium 2 to the medium 2. By providing the weight calculation means 15 with the weight calculated by the weight calculation means 14 in the state in which the nutrient solution 7 is supplied as a reference value, and thereafter with the yield prediction calculation means 15 for predicting the yield of the plant by the weight that increases from the reference value, Regardless of the image and regardless of the cultivation environment, it is possible to accurately predict the yield and harvest time of the plant by numerical values.
Further, if the water-retaining sheet 21 is simply sandwiched between the breathable materials 22 and 23, only a part of the supplied nutrient solution reaches the water-retaining sheet 21, and a large amount is lost from the gaps of the breathable materials 22 and 23. Therefore, if a large amount of nutrient solution 7 is not supplied, it was insufficient for growing plants. On the other hand, in the present invention, the end of the water-retaining sheet 21 is disposed on the upper surfaces of the breathable materials 22 and 23. Since the nutrient solution 7 can be effectively collected on the water retention sheet 21, the plant can be cultivated with the supply of the nutrient solution 7 even when the nutrient solution supply means 4 having a large variation in the dropping position of the nutrient solution 7 is used. can do. Accordingly, it is possible to use a pump having a small capacity as a pump used for supplying or circulating the nutrient solution 7, thereby reducing facility costs and running costs.

In the yield prediction system in the vertical hydroponics according to claim 4, as described above, the weight and / or yield prediction calculation means 15 of each vertical hydroponics cylinder 1 calculated by the weight calculation means 14 is used for prediction. Since the yield of the plant thus obtained is transmitted to the data server 16 via the Internet N, the cultivation manager can manage it remotely.
Therefore, the effect that it becomes possible to centrally manage the plant cultivation houses 13 scattered in various places by remote control is obtained.

In the yield prediction system for vertical hydroponic cultivation according to claim 5, as described above, the yield of each vertical hydroponic cylinder 1 predicted by the yield prediction calculation means 15 is set in advance. By providing the notification means 17 that notifies when the amount reaches the light level, the harvest time of the plants of each vertical hydroponic cylinder 1 can be known by visual observation, so that the harvest time is not missed.

In the yield prediction system in the vertical hydroponic cultivation according to claim 6, as described above, the notification unit 17 lights the LED lamp 18 provided in each vertical hydroponic cylinder 1. It is possible to easily and surely identify which plant among the plurality of vertical hydroponics cylinders 1 is the harvest time.

In the yield prediction system in the vertical hydroponics according to claim 7, as described above , both side walls of the vertical hydroponics cylinder 1 centering on the water retaining sheet 21 with the upper surfaces of the water retaining sheets 21 a and 21 b folded or folded. By forming it in an inclined shape that becomes higher as it goes to the side , it is possible to prevent the nutrient solution 7 dropped on the folded or folded water-retaining sheets 21a and 21b or the separate water-retaining sheet 24 from jumping to the outside. In addition, the nutrient solution 7 dropped on the water retention sheet 21 can be prevented from leaking to the breathable materials 22 and 23 and evaporation, and the nutrient solution can be used more efficiently.

In the yield prediction system in vertical hydroponics according to claim 8, as described above, the upper surfaces of the both water-permeable materials 22 and 23 have an inclined upper surface that becomes higher toward the outside with the water-retaining sheet 21 as the center. By providing the inclined member 8, the nutrient solution 7 can be intensively supplied to the water retention sheet 21.

In the yield prediction system in the vertical hydroponics according to claim 9, as described above, the upper surface of at least one side of the breathable materials 22, 23 becomes higher as it goes outward with the water retention sheet 21 as the center. By forming it in an inclined shape, the nutrient solution 7 can be intensively supplied to the water retention sheet 21.

It is a block diagram which shows the yield prediction system in the vertical hydroponics of Example 1. FIG. It is a perspective view which shows the principal part of the yield prediction system in the vertical hydroponics of Example 1. It is explanatory drawing which shows the nutrient solution circulation to the culture medium of a vertical hydroponic cultivation cylinder. FIG. 4 is an enlarged cross-sectional view taken along line AA in FIG. 3. FIG. 3 is an enlarged front view showing a main part of the culture medium of Example 1. FIG. 4 is an enlarged front view of a main part showing the culture medium of Example 2. FIG. 4 is an enlarged front view of a main part showing the culture medium of Example 3. (A), (b), (c) 3 type principal part enlarged front views showing the culture medium of Example 4. FIG. FIG. 10 is a perspective view showing an inclined member of Example 5.

  Embodiments of the present invention will be described below with reference to the drawings.

First, the yield prediction system in the vertical hydroponics of Example 1 will be described with reference to FIGS.
The yield prediction system in the vertical hydroponics of the first embodiment is a plurality of vertical types that are hung on a hanging portion 10 constituted by bars provided on the ceiling side in the plant cultivation house 13 that receives sunlight or artificial light. Hydroponic culture cylinder 1, culture medium 2 accommodated in vertical hydroponic culture cylinder 1 so as to be removable, nutrient solution storage tank 3, and nutrient solution supply for supplying nutrient solution 7 from nutrient solution storage tank 3 to culture medium 2 Means 4, nutrient solution recovery means 5 for collecting nutrient solution 7 dropped from the lower part of the vertical hydroponic cultivation cylinder 1, weight sensor 9, weight calculation means 14, yield prediction calculation means 15, and data server 16 And the alerting | reporting means 17 and the LED lamp 18 are provided as main structures.

  More specifically, as shown in FIGS. 2 and 3, the vertical hydroponic cultivation cylinder 1 is a cylinder having a square cross section, and is vertically used as an opening 11 for planting a plant seedling 6 on one side surface thereof. The slit 11a is provided, and is provided in a state of being hung on a bar constituting the suspended portion 10 on the ceiling of the house 67.

  As shown in FIGS. 4 and 5, the culture medium 2 is composed of a water-retaining sheet 21 and breathable materials 22 and 23 sandwiching both sides thereof, so that the medium 2 can be inserted into and removed from the vertical hydroponics cylinder 1. Contained.

  Further, the upper end portion of the water retaining sheet 21 is projected from the upper ends of the air permeable materials 22 and 23, and is placed on the upper surface of one of the air permeable materials 23, and the nutrient solution 7 is folded and placed from the nutrient solution supply means 4. It is comprised so that it may be dripped at the water-retaining sheet 21a.

  As shown in FIG. 3, the nutrient solution supply means 4 includes a nutrient solution supply pump 41, and drops the nutrient solution 7 from the nutrient solution storage tank 3 onto the upper end of the water retention sheet 21 a that is bent and placed in the culture medium 2. Let The dripping amount of the nutrient solution 7 may be such that the water content at the lower end of the water retaining sheet 21 is maintained in a saturated state.

  The nutrient solution recovery means 5 includes a drain pan 51 that receives the nutrient solution 7 dripped from the lower end of the water retention sheet 21 and a nutrient solution recovery pump 52, and the nutrient solution 7 collected in the drain pan 51 is supplied to the nutrient solution circulation pump At 52, the nutrient solution storage tank 3 is recovered and circulated.

  As shown in FIG. 2, the weight sensor 9 outputs a detection signal corresponding to the weight of each vertical hydroponics cylinder 1, and between the suspended portion 10 and each vertical hydroponics cylinder 1. Is provided.

  As shown in FIG. 2, the weight calculating means 14 calculates the weight of each vertical hydroponics cylinder 1 based on the detection signal from the weight sensor 9, and is built in the microcomputer 19.

  The yield prediction calculation means 15 is calculated by the weight calculation means 14 in a state where the plant seedling 6 is planted in the medium 2 of the vertical hydroponic cultivation cylinder 1 and the nutrient solution 7 is supplied from the nutrient solution storage tank 3 to the medium 2. The yield of the plant is predicted based on the weight obtained as a reference value and then increased from the reference value, and is built in the microcomputer 19.

  The microcomputer 19 is connected to the Internet N via a line terminating device 20.

  As shown in FIG. 1, the data server 16 is provided on the cultivation manager side, and the manager side includes a terminal device 25 with a monitor. The data server 16 and the terminal device 25 with a monitor include the Internet. The weight data of each vertical hydroponic cylinder 1 calculated by the weight calculation means 14 and / or the yield prediction calculation means 15 through the line termination device 26 and the broadband router 27 connected to N Yield data is sent.

The informing means 17 is provided in each vertical hydroponics cylinder 1 when the yield of the plants of each vertical hydroponics cylinder 1 predicted by the yield prediction calculation means 15 reaches a preset harvest amount. By turning on the LED lamp 18, the harvest time of the plant is notified by light.
The notification means 17 is also built in the microcomputer 19.

  Next, the operation of the first embodiment will be described.

  Since the yield prediction system in the vertical hydroponics of Example 1 is configured as described above, a plurality of spaces are provided between the water retention sheet 21 and the breathable material 22 or 23 as shown in FIGS. An upper end of a water-retaining sheet 21a in which the culture medium 2 is inserted into the vertical hydroponics cylinder 1 with the plant seedling 6 sandwiched between them and the nutrient solution 7 is folded and placed by the nutrient solution supply pump 41 Then, the seedling 6 grows by absorbing the nutrient solution 7 from the water-holding sheet 21.

Next, the cultivation comparison experiment example of a conventional example and a present Example is demonstrated.
1. This example: A breathable material (polyethylene) having a thickness of 4.8 cm, a width of 10 cm, and a length of 150 cm is folded into two pieces in half, and a polyester felt having a thickness of 1 mm, a width of 9 cm, and a length of 70 cm in between. (Water retentive sheet) is sandwiched, the upper end 5cm of the felt is protruded from the upper end of the polyethylene, and the protruding part is bent and placed on the upper surface of the polyethylene. The state inserted in the vertical hydroponic cultivation cylinder.
2. Comparative Example 1: A state in which the upper end of the felt is not projected above the upper end of the polyethylene.
3. Comparative Example 2: A state in which the medium is only polyethylene without felt.
Basil seedlings were planted on these three types of vertical hydroponic cultivation cylinders.
The seedlings are planted in a 9 cm pot, 7 to 10 cm tall, and after washing the soil from the roots with tap water, basil is placed between the polyethylene and the felt (in the case of Comparative Example 2 between the two polyethylenes). The basement of the seedling was sandwiched and attached to a vertical hydroponics cylinder.
Cultivation was carried out under sunlight for 3 days while dropping a fertilizer nutrient solution (an aqueous solution in which OAT House No. 1 was dissolved to a concentration of 0.8 g / L) at a rate of 20 g per minute.

Results of Comparative Experiments Example: All 6 seedlings out of 6 grew successfully.
Comparative Example 1: 2 of 6 seedlings continued to grow, but 4 seedlings withered.
Comparative Example 2: 1 of 6 seedlings continued to grow, but 5 seedlings withered.

Next, plant yield and harvest time prediction will be described.
Since the yield prediction system in vertical hydroponics of Example 1 is configured as described above, the yield of plants in each vertical hydroponics cylinder 1 is first determined by the weight sensor 9. The weight calculation means 14 calculates the detection signal according to the weight of the type hydroponic cultivation cylinder 1 and then the yield prediction calculation means 15 applies the plant seedling 6 to the medium 2 of each vertical hydroponic cultivation cylinder 1. The weight calculated by the weight calculation means 14 in a state where the nutrient solution 7 is supplied from the nutrient solution storage tank 3 to the culture medium 2 is used as a reference value, and then the plant yield is predicted by the weight that increases from the reference value.
Moreover, the harvest time of the plant in each vertical hydroponic cultivation cylinder 1 can be estimated when the yield of the plant of each vertical hydroponic cultivation cylinder 1 reaches the preset harvest amount (weight).

Next, the effect of the first embodiment will be described.
Since the yield prediction system in the vertical hydroponics of Example 1 is configured as described above, the following effects can be obtained.

  In the yield prediction system in vertical hydroponics of Example 1, a state where the seedling 6 of a plant is planted in the medium 2 of the vertical hydroponics cylinder 1 and the nutrient solution 7 is supplied from the nutrient solution storage tank 3 to the medium 2 The weight calculation means 14 in the above is used as a reference value, and the yield prediction calculation means 15 for predicting the yield of the plant by the weight that increases from the reference value thereafter is provided, regardless of the visual or camera image, Regardless of the cultivation environment, it is possible to accurately predict the yield and harvest time of plants by using numerical values.

Further, the weight of each vertical hydroponic cylinder 1 calculated by the weight calculation means 14 and / or the plant yield predicted by the yield prediction calculation means 15 is transmitted to the data server 16 via the Internet N. The cultivation manager can manage remotely.
In addition, a plurality of plant cultivation houses 13 scattered in various places can be centrally managed by remote operation.

  Moreover, by providing the notification means 17 which notifies by light lighting when the yield of the plant of each vertical hydroponic cultivation cylinder 1 estimated by the yield prediction calculation means 15 reaches a preset expected harvest amount, it is visually confirmed. Since the harvest time of the plants of each vertical hydroponic cultivation cylinder 1 can be known, the harvest time is not missed.

  Moreover, the said alerting | reporting means 17 was made to light up the LED lamp 18 with which each vertical-type hydroponic cultivation cylinder 1 was lighted, and any plant of the multiple vertical-type hydroponic cultivation cylinders 1 is a harvest time. Can be identified easily and reliably by visual inspection.

  Moreover, the culture medium 2 accommodated in the vertical hydroponics cylinder 1 so as to be detachable is composed of a water-holding sheet 21 for planting plant seedlings 6 and breathable materials 22 and 23 sandwiching both sides thereof. Is dripped onto the upper end of the water-holding sheet 21, so that oxygen is reliably supplied to the roots of the plant seedlings 6 sandwiched between the water-holding sheet 21 and the breathable materials 22, 23. Plant root rot can be prevented.

In addition, the medium 2 has a water retention sheet 21 and a breathable material 22, 23, and by sharing the roles, the water retention is low but the breathability is excellent and inexpensive, and the easy to supply / breathability is If it is low but excellent in water retention, inexpensive and easy to supply, it can be widely used and the range of materials can be selected.
In addition, by selecting a material that is light in weight or hard to break, performance such as ease of use can be improved.

  Further, if the water-retaining sheet 21 is simply sandwiched between the breathable materials 22 and 23, only a part of the supplied nutrient solution reaches the water-retaining sheet 21, and a large amount is lost from the gaps of the breathable materials 22 and 23. Therefore, if a large amount of nutrient solution 7 is not supplied, it was insufficient for growing plants. On the other hand, in the present invention, the end of the water-retaining sheet 21 is disposed on the upper surfaces of the breathable materials 22 and 23. Since the nutrient solution 7 can be effectively collected on the water retention sheet 21, the plant can be cultivated with the supply of the nutrient solution 7 even when the nutrient solution supply means 4 having a large variation in the dropping position of the nutrient solution 7 is used. can do. Accordingly, it is possible to use a pump having a small capacity as a pump used for supplying or circulating the nutrient solution 7, thereby reducing facility costs and running costs.

  Next, another embodiment will be described. In the description of the other embodiments, the same components as those of the first embodiment are not shown, or the same reference numerals are given and the description thereof is omitted, and only the differences are described.

As shown in FIG. 6, the yield prediction system for vertical hydroponics in Example 2 is a breathable material on the opposite side to the breathable material 23 in which the water retention sheet 2 in Example 1 is folded and placed. A separate water-retaining sheet 24 is placed on the upper surface of 22, and the lower end portion is sandwiched between the water-retaining sheet 21 and the breathable material 22 so as to be in contact with the water-retaining sheet 21. This is different from the first embodiment in that the nutrient solution 7 is folded from the solution supply means 4 onto the water retention sheet 21a that is folded and placed or the separate water retention sheet 24.
Therefore, according to the second embodiment, the nutrient solution 7 is dropped from the nutrient solution supply means 4 onto the water retention sheet 21a that is folded and placed, or a separate water retention sheet 24, so that the nutrient solution 7 is added to the water retention sheet. 21 can be supplied intensively.
Further, by forming the upper surfaces of the air permeable materials 22 and 23 in an inclined shape that becomes higher with the water retentive sheet 21 as the center, the water retentive sheet 21a that is bent and placed or a separate water retentive substance is formed. In addition to preventing the nutrient solution 7 dropped on the porous sheet 24 from jumping to the outside, the nutrient solution 7 dropped on the water-holding sheet 21 is prevented from leaking to the breathable materials 22 and 23 and evaporating more efficiently. The nutrient solution 7 can be utilized.

As shown in FIG. 7, the yield prediction system in vertical hydroponics of Example 3 has a water retention property in which the upper end portion of the water retention sheet 21 in Example 1 is folded and placed on the upper surface of one breathable material 23. The tip of the sheet 21a is folded and placed on the upper surface side of the other breathable material 22, and the nutrient solution 7 is dropped from the nutrient solution supply means 4 onto the folded water retaining sheet 21b. This is different from the first embodiment.
Therefore, according to the third embodiment, the nutrient solution 7 is concentratedly supplied to the water retention sheet 21 by dripping the nutrient solution 7 from the nutrient solution supply means 4 onto the water retention sheet 21b that is folded and placed. Will be able to.
Further, by forming the upper surfaces of the air-permeable materials 22 and 23 in an inclined shape that becomes higher with the water-retaining sheet 21 as the center, the nutrient solution 7 dripped on the water-retaining sheet 21b that is placed in a folded state. In addition, the nutrient solution 7 can be used more efficiently by preventing the nutrient solution 7 dripped on the water retention sheet 21b from leaking to the breathable materials 22 and 23 and evaporation. It becomes like this.

As shown in FIGS. 8A, 8B, 7C, and 7, the yield prediction system for vertical hydroponics in Example 4 is provided on the top surfaces of the water-permeable materials 22, 23. The embodiment is different from the first to third embodiments in that it includes an inclined member 8 having a substantially right-angled triangular cross section having an inclined upper surface that becomes higher as it goes outward with the water-retaining sheet 21 as the center.
Therefore, according to this Example 4, the nutrient solution 7 dropped from the nutrient solution supply means 4 onto the folded water retention sheet 21a (separate water retention sheet 24, folded water retention sheet 21b) is splashed to the outside. Can be concentrated and supplied to the water retention sheet 21, whereby the nutrient solution 7 dropped onto the folded water retention sheet 21 a (separate water retention sheet 24, folded water retention sheet 21 b). Leaking to the breathable materials 22 and 23 and evaporation can be prevented and the nutrient solution 7 can be used more efficiently.
In addition, although the raw material of the inclination member 8 is arbitrary, it is desirable that at least the upper surface of the inclination is made of a material having no water permeability.
Further, the shape of the inclined member 8 is not limited to a substantially right triangle as long as an inclined upper surface is formed, and is arbitrary. Further, the inclined upper surface of the inclined member 8 is not limited to a straight line, but may be a concave curved surface, for example.

  As shown in FIG. 9, the yield prediction system in vertical hydroponics of Example 5 has an inclined upper surface that becomes higher as it goes outward with the water retaining sheet 21 as the center on the upper surface of at least one breathable material. In this configuration, the nutrient solution 7 can be intensively supplied to the water-retaining sheet 21.

  Although the present embodiment has been described above, the present invention is not limited to the above-described embodiment, and design changes and the like within a scope not departing from the gist of the present invention are included in the present invention.

  For example, in the first embodiment, the vertical hydroponic cultivation cylinder 1 has a substantially square cross section, but a cylinder other than a square may be used.

  Moreover, in Example 1, although the culture medium 2 was made into 2 part structure of the water retention sheet | seat 21 and the water-permeable materials 22 and 23, one type may be sufficient.

  Moreover, in Example 1, although the vertical slit 11a was formed as the opening part 11 for planting the seedling 6 of a plant in one side of the vertical hydroponic cultivation cylinder 1, it is made to form a some opening part in a perpendicular direction. May be.

  In the first embodiment, the LED lamp 18 provided in each vertical hydroponic cylinder 1 is turned on as the notification unit 17. However, the lamp may be displayed on one display panel or display device. ,

1 Vertical Hydroponic Cultivation Tube 11 Opening 11a Slit (Opening)
2 Medium 21 Water retentive sheet 21a Folded water retentive sheet 21b Folded water retentive sheet 22 Breathable material 23 Breathable material 24 Separate water retentive sheet 3 Nutrient solution storage tank 4 Nutrient solution supply means 41 Nutrient solution supply pump 5 Nutrient Liquid recovery means 51 Drain pan 52 Nutrient liquid recovery circulation pump 6 Plant seedling 7 Nutrient liquid 8 Tilting member 9 Weight sensor 10 Suspension 13 Plant cultivation house 14 Weight calculation means 15 Yield prediction calculation means 16 Data server 17 Notification means 18 LED lamp 19 Microcomputer 20 Line terminator 25 Terminator with monitor 26 Line terminator 27 Broadband router N Internet

Claims (10)

A plurality of vertical hydroponics cylinders 1 suspended in a suspended portion 10 provided on the ceiling side in a plant cultivation house 13 that receives sunlight or artificial light, and accommodated in the vertical hydroponics cylinder 1 in a removable manner. The culture medium 2, the nutrient solution storage tank 3, the nutrient solution supply means 4 for supplying the nutrient solution 7 from the nutrient solution storage tank 3 to the culture medium 2, and the nutrient solution 7 dropped from the lower part of the vertical hydroponics cylinder 1 are collected. A nutrient solution collecting means 5 for
The vertical hydroponics cylinder 1 is provided with an opening 11 for planting a plant seedling 6 in the medium 2 on one side surface thereof,
The culture medium 2 is composed of a water-retaining sheet 21 and breathable materials 22 and 23 sandwiching both sides thereof,
The upper part of the water retaining sheet protruding from the upper ends of the breathable materials 22 and 23 is bent and placed on the upper surface of at least one of the breathable materials 23,
It is configured to drop the nutrient solution 7 from the nutrient solution supply means onto the water-retaining sheet 21a that is bent and placed,
A weight sensor 9 for outputting a detection signal corresponding to the weight of each vertical hydroponic cultivation cylinder 1 is provided between the suspended portion 10 and each vertical hydroponic cultivation cylinder 1.
Weight calculating means 14 for calculating the weight of each vertical hydroponics cylinder 1 based on the detection signal from the weight sensor 9,
The weight calculated by the weight calculating means 14 in a state where the plant seedling 6 is planted in the medium 2 of the vertical hydroponics cylinder 1 and the nutrient solution 7 is supplied from the nutrient solution storage tank 3 to the medium 2 is used as a reference value. A yield prediction system in vertical hydroponics, comprising a yield prediction calculation means 15 for predicting the yield of plants based on a weight that increases from the reference value thereafter. A plurality of vertical hydroponics cylinders 1 suspended in a suspended portion 10 provided on the ceiling side in a plant cultivation house 13 that receives sunlight or artificial light, and accommodated in the vertical hydroponics cylinder 1 in a removable manner. The culture medium 2, the nutrient solution storage tank 3, the nutrient solution supply means 4 for supplying the nutrient solution 7 from the nutrient solution storage tank 3 to the culture medium 2, and the nutrient solution 7 dropped from the lower part of the vertical hydroponics cylinder 1 are collected. A nutrient solution collecting means 5 for
The vertical hydroponics cylinder 1 is provided with an opening 11 for planting a plant seedling 6 in the medium 2 on one side surface thereof,
The culture medium 2 is composed of a water-retaining sheet 21 and breathable materials 22 and 23 sandwiching both sides thereof,
The water retaining sheet upper end protruding from the upper ends of the breathable materials 22, 23 is bent and placed on the upper surface of one of the breathable materials 23,
A separate water-retaining sheet 24 is placed on the upper surface of the air-permeable material 22 opposite to the air-permeable material 23 on which the water-retaining sheet is folded and placed, and its lower end is brought into contact with the water-retaining sheet 21. And
The nutrient solution 7 is folded from the nutrient solution supply means 4 to the water-retaining sheet 21a that is folded and placed, or a separate water-retaining sheet 24.
A weight sensor 9 for outputting a detection signal corresponding to the weight of each vertical hydroponic cultivation cylinder 1 is provided between the suspended portion 10 and each vertical hydroponic cultivation cylinder 1.
Weight calculating means 14 for calculating the weight of each vertical hydroponics cylinder 1 based on the detection signal from the weight sensor 9,
The weight calculated by the weight calculating means 14 in a state where the plant seedling 6 is planted in the medium 2 of the vertical hydroponics cylinder 1 and the nutrient solution 7 is supplied from the nutrient solution storage tank 3 to the medium 2 is used as a reference value. A yield prediction system in vertical hydroponics, comprising a yield prediction calculation means 15 for predicting the yield of plants based on a weight that increases from the reference value thereafter. A plurality of vertical hydroponics cylinders 1 suspended in a suspended portion 10 provided on the ceiling side in a plant cultivation house 13 that receives sunlight or artificial light, and accommodated in the vertical hydroponics cylinder 1 in a removable manner. The culture medium 2, the nutrient solution storage tank 3, the nutrient solution supply means 4 for supplying the nutrient solution 7 from the nutrient solution storage tank 3 to the culture medium 2, and the nutrient solution 7 dropped from the lower part of the vertical hydroponics cylinder 1 are collected. A nutrient solution collecting means 5 for
The vertical hydroponics cylinder 1 is provided with an opening 11 for planting a plant seedling 6 in the medium 2 on one side surface thereof,
The culture medium 2 is composed of a water-retaining sheet 21 and breathable materials 22 and 23 sandwiching both sides thereof,
The upper end portion of the water retaining sheet protruding from the upper ends of the breathable materials 22 and 23 is folded and placed on the upper surface of one breathable material 23, and the tip is folded and placed on the upper surface side of the other breathable material 22. And
It is configured to drop the nutrient solution 7 from the nutrient solution supply means 4 onto the water-retaining sheet 21b that is folded and placed,
A weight sensor 9 for outputting a detection signal corresponding to the weight of each vertical hydroponic cultivation cylinder 1 is provided between the suspended portion 10 and each vertical hydroponic cultivation cylinder 1.
Weight calculating means 14 for calculating the weight of each vertical hydroponics cylinder 1 based on the detection signal from the weight sensor 9,
The weight calculated by the weight calculating means 14 in a state where the plant seedling 6 is planted in the medium 2 of the vertical hydroponics cylinder 1 and the nutrient solution 7 is supplied from the nutrient solution storage tank 3 to the medium 2 is used as a reference value. A yield prediction system in vertical hydroponics, comprising a yield prediction calculation means 15 for predicting the yield of plants based on a weight that increases from the reference value thereafter. In the yield prediction system in the vertical hydroponics according to any one of claims 1 to 3,
The weight of each vertical hydroponics cylinder 1 calculated by the weight calculation means 14 and / or the plant yield predicted by the yield prediction calculation means 15 is transmitted to the data server 16 via the Internet N. Yield prediction system in vertical hydroponics, characterized by In the yield prediction system in the vertical hydroponics according to any one of claims 1 to 4, the yield of the plant of each vertical hydroponics cylinder 1 predicted by the yield prediction calculation means 15 is preset. A yield prediction system in vertical hydroponics, comprising notification means 17 that informs by light of light when a planned harvest amount is reached. In the yield prediction system in the vertical hydroponics according to claim 5,
The said notification means 17 lights the LED lamp 18 with which each vertical hydroponic cultivation cylinder 1 was equipped, The yield prediction system in the vertical hydroponic cultivation characterized by the above-mentioned. In the yield prediction system in the vertical hydroponics according to any one of claims 1 to 6,
The vertical hydroponic culture is characterized in that the folded or folded water-retaining sheet is formed in an inclined shape that increases as it goes to both side walls of the vertical hydroponic cylinder with the water retentive sheet as the center. Yield prediction system. In the yield prediction system in the vertical hydroponics according to any one of claims 1 to 6,
Yield prediction system in vertical hydroponics characterized by comprising an inclined member 8 having an inclined upper surface that becomes higher as it goes outward with the water-retaining sheet 21 as the center on the upper surface of the breathable material on at least one side . In the yield prediction system in the vertical hydroponics according to any one of claims 1 to 7 ,
A yield prediction system in vertical hydroponics, wherein an upper surface of at least one side of the breathable material is formed in an inclined shape that increases as it goes outward with a water-retaining sheet as a center. In the yield prediction system in the vertical hydroponics according to any one of claims 1 to 9,
The nutrient solution collecting means 5 includes a drain pan 51 that collects the nutrient solution 7 dripped from the lower part of the vertical hydroponic cultivation cylinder 1, and circulates the nutrient solution 7 collected in the drain pan 51 to the nutrient solution storage tank 3. The yield prediction system in the vertical hydroponics characterized by being comprised as follows.

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