JP2019062813A - Cultivation equipment - Google Patents

Abstract

To provide a cultivation device capable of properly managing a health condition of a crop, and being excellent in crop admiration property.SOLUTION: A cultivation device comprises: a casing 1 comprising a transparent cylindrical peripheral wall 11, a lid part 12 for sealing an upper opening 7a of the peripheral wall 11, and a bottom part 13 for sealing a lower opening of the peripheral wall 11 and on which a cultivation unit to which a crop is adhered, is mounted; a cultivation solution supply mechanism 2 for supplying a cultivation solution Z to the cultivation unit Y; a light source 3 arranged in a casing 1 and radiates a light to the crop X; a liquid absorption speed calculation part for calculating liquid absorption speed of the cultivation solution Z to the crop X; and a display part for displaying data of the liquid absorption speed calculated by the liquid absorption speed calculation part.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a growing device.

  A cultivation apparatus for cultivating crops by artificially setting cultivation environment is widely adopted. This cultivation apparatus can grow a crop appropriately, for example, by adjusting the amount of water supplied to the crop and the light applied to the crop.

  Also, today, the crop is also an ornamental object, and a cultivation apparatus having a display capable of ornamentally viewing the crop has also been proposed. As a cultivation apparatus provided with such a display, the "plant cultivation method" (refer Unexamined-Japanese-Patent No. 2012-231729) is proposed, for example.

JP 2012-231729 A

  When cultivating a crop in a state where it can be admired, it is important to control the health condition of this crop in terms of improving the appearance of the crop. However, the conventional cultivation apparatus as described in the above-mentioned publication visually confirms the health condition of the crop. Therefore, according to the conventional cultivation apparatus, the health condition of the crop can not but be treated after being visibly deteriorated, and it is difficult to keep the appearance of the crop good.

  This invention is made based on such a situation, and while it is excellent in the ornamental property of a crop, it makes it a subject to provide the cultivation apparatus which can manage the health condition of a crop appropriately.

  A cultivation apparatus according to an aspect of the present invention made to solve the above problems comprises: a transparent cylindrical peripheral wall, a lid for sealing the upper opening of the peripheral wall, and a lower opening of the peripheral wall And a cultivation liquid supply mechanism for supplying cultivation liquid to the cultivation unit, and a casing having a bottom portion on which the cultivation unit on which the crop has been deposited is disposed in the casing, and the crop is irradiated with light. It has a light source, a liquid absorption speed calculation unit that calculates the liquid absorption speed of the cultivation liquid with respect to the crop, and a display unit that displays data of the liquid absorption speed calculated by the liquid absorption speed calculation unit.

  The cultivation apparatus according to the present invention is excellent in the ornamental property of the crop and can appropriately manage the health condition of the crop.

It is a typical perspective view showing a cultivation device concerning one embodiment of the present invention. It is a schematic cross section which shows the internal structure of the cultivation apparatus of FIG. It is a schematic diagram which shows the cultivation liquid supply mechanism of the cultivation apparatus of FIG. 1, and calculation and display mechanism of liquid absorption speed. It is the sectional view on the AA line of the cultivation apparatus of FIG. It is a BB line end view of the cultivation apparatus of FIG.

Description of the embodiment of the present invention
First, the embodiments of the present invention will be listed and described.

  A cultivation apparatus according to one aspect of the present invention includes a transparent cylindrical peripheral wall, a lid for sealing an upper opening of the peripheral wall, and a lower opening of the peripheral wall, and a cultivation unit having a crop deposited thereon A casing having a bottom to be placed, a cultivation liquid supply mechanism for supplying cultivation liquid to the cultivation unit, a light source disposed in the casing and irradiating the crop with light, and the cultivation liquid for the crop And a display unit for displaying data of the liquid absorption velocity calculated by the liquid absorption velocity calculation unit.

  Since the cultivation apparatus includes a cultivation liquid supply mechanism for supplying cultivation liquid to the cultivation unit on which the crop has grown, and a light source for irradiating the crop disposed in the casing, the crop housed in the casing This crop can be grown by supplying culture fluid and light to the Since the said surrounding apparatus which comprises the said casing is a transparent cylindrical shape, the said cultivation apparatus can enjoy a crop from the outside over 360 degrees on the basis of the central axis of this surrounding wall via this surrounding wall. Therefore, the said cultivation apparatus is excellent in the ornamental property of a crop. Moreover, since the said cultivation apparatus can display the data of the liquid absorption speed of the cultivation liquid with respect to the crop calculated by the liquid absorption speed calculation part on a display part, the health condition of a crop is appropriately monitored by monitoring this data. It can be managed.

  The cultivation liquid supply mechanism comprises: a cultivation liquid tank for storing the cultivation liquid; one or more storage tanks for temporarily storing the cultivation liquid supplied from the culture liquid tank; and the cultivation from the one or more storage tanks. A sensor including a liquid transfer unit that distributes the culture solution by capillary action in a unit, and the liquid absorption speed calculation unit detecting the water level of the culture solution in the one or more storage tanks with time; It is good to have the calculating part which calculates the liquid absorption speed of the said crop from the change of the water level of the cultivation liquid detected by this. Thus, the sensor detects the water level of the culture solution in the one or more storage tanks with time, and the calculation unit calculates the liquid absorption speed of the crop from the change in the water level of the culture solution detected by the sensor. By doing this, it is possible to display the temporal change of the liquid absorption speed of the crop by the display unit. Thereby, the health condition of the said crop can be managed more appropriately.

  The cultivation liquid supply mechanism includes a pair of the storage tanks, and the pair of storage tanks is a first storage tank in communication with the cultivation liquid tank and a second storage tank in communication with the first storage tank, The sensor may detect the water level of the second storage tank. Thus, the above-mentioned cultivation liquid supply mechanism has a pair of the above-mentioned storage tanks, and the above-mentioned pair of storage tanks are the 1st storage tank which communicates with the above-mentioned cultivation liquid tank, and the 2nd storage that communicates with this 1st storage tank. Since it is a tank and the said sensor detects the water level of the said 2nd storage tank, the liquid absorption speed of the said crop can be calculated | required easily and reliably.

  The light source includes one or more discharge lamps disposed in the lid portion and a plurality of LEDs disposed in the peripheral wall, a heat dissipation fan is disposed in the lid portion, and the light source is connected to the bottom portion It is preferable that pores be formed. When the light source includes one or more discharge lamps and a plurality of LEDs, the amount of light supplied to the crop can be sufficiently increased. In addition, the light source includes one or more discharge lamps disposed in the lid portion and a plurality of LEDs disposed in the peripheral wall, a heat dissipation fan is disposed in the lid portion, and the bottom portion By forming the vent holes, it is possible to form a flow of air from the lower side to the upper side in the casing. Thereby, this crop can be grown more appropriately by appropriately supplying air to the crop.

  The light source may include an ultraviolet lamp disposed in the lid. Thus, when the light source includes the ultraviolet lamp disposed in the lid, the occurrence of the damage to the crop can be suppressed.

Details of the Embodiment of the Present Invention
Preferred embodiments of the present invention will be described below with reference to the drawings.

<Cropping equipment>
The said cultivation apparatus seals the lower opening of the transparent cylindrical surrounding wall 11, the cover part 12 which seals the upper opening of the surrounding wall 11, and the surrounding wall 11, as shown in FIGS. It is disposed in the casing 1 having the bottom portion 13 on which the cultivation unit Y on which the crop is deposited, the cultivation liquid supply mechanism 2 for supplying the cultivation liquid Z to the cultivation unit Y, and the casing 1 A liquid supply speed calculation unit 4 that calculates the liquid absorption speed of the cultivation liquid Z with respect to the crop X, and a display unit 5 that displays data of liquid absorption speed calculated by the liquid absorption speed calculation unit 4 Equipped with Moreover, while the said cultivation apparatus covers the cultivation unit Y, it has the protective cover 7 which has the opening 7a which the crop X penetrates. In addition, placing the cultivation unit on the bottom is a concept including both the case where the cultivation unit is directly placed on the bottom and the case where the cultivation unit is placed on the bottom through other members.

  Since the cultivation apparatus includes the cultivation liquid supply mechanism 2 for supplying the cultivation liquid Z to the cultivation unit Y in which the crop X has grown, and the light source 3 for irradiating the crops contained in the casing 1 with light, the casing 1 The crop X can be grown by supplying the cultivation solution Z and light to the crop X contained therein. In the cultivation apparatus, the peripheral wall 11 constituting the casing 1 has a transparent tubular shape, so that the crop X can be viewed from the outside over 360 ° with respect to the central axis of the peripheral wall 11 via the peripheral wall 11 Can. Therefore, the cultivation apparatus is excellent in the ornamental property of the crop X. Moreover, since the said cultivation apparatus can display the data of the liquid absorption speed of the cultivation liquid Z with respect to the crop X calculated by the liquid absorption speed calculation part 4 on the display part 5, monitoring of this data can be used for the crop X. You can manage your health properly.

<produce>
The crop X is not particularly limited, and examples thereof include fruit vegetables, root vegetables, leaf vegetables, gramineous plants, flower vegetables and the like, with preference given to fruit vegetables that are easily grown appropriately while controlling their health condition, Among them, tomato is particularly preferred.

(casing)
The peripheral wall 11 is transparent so that the crop X can be viewed from the outside, and is preferably colorless and transparent. Specific shapes of the peripheral wall 11 include a cylindrical shape, an elliptic cylindrical shape, a polygonal cylindrical shape and the like, and among them, a cylindrical shape which easily supplies light etc. to the crop X uniformly from all directions in the left and right direction Is preferred. As a material of the peripheral wall 11, a synthetic resin, glass, etc. may be mentioned, and a synthetic resin relatively light in weight and excellent in handleability is preferable. As said synthetic resin, an acrylic resin, a polycarbonate, a polyvinyl chloride etc. are mentioned, for example, Especially, the acrylic resin which is excellent in transparency is preferable.

  As a minimum of the mean outside diameter of peripheral wall 11, 300 mm is preferred and 600 mm is more preferred. On the other hand, as an upper limit of the mean outside diameter of peripheral wall 11, 1200 mm is preferred and 900 mm is more preferred. If the average outer diameter of the peripheral wall 11 is smaller than the above lower limit, there is a possibility that the growable crop X may be limited, or the crop X may not be grown sufficiently in the casing 1. Conversely, when the average outer diameter of the peripheral wall 11 exceeds the above upper limit, the volume in the casing 1 becomes unnecessarily large, which may make it difficult to sufficiently irradiate the crop X with light, and the handleability of the entire apparatus It may decrease. The thickness of the peripheral wall 11 can be, for example, about 1 mm or more and 10 mm or less.

  As a minimum of height (axial direction length) of peripheral wall 11, 1.0 m is preferred and 1.5 m is more preferred. On the other hand, as a maximum of height of peripheral wall 11, 3.5 m is preferred and 3.0 m is more preferred. If the height of the peripheral wall 11 is smaller than the above lower limit, there is a possibility that the growable crop X may be limited, or the crop X may not be grown sufficiently in the casing 1. Conversely, if the height of the peripheral wall 11 exceeds the above upper limit, the volume in the casing 1 becomes unnecessarily large, which may make it difficult to sufficiently irradiate the crop X with light, and the handleability of the entire apparatus decreases. There is a risk of

  In addition, the door part may be formed in the surrounding wall 11 so that the crop X can be taken in and out or maintenance of the inside can be performed. In this case, the peripheral wall 11 may have a non-transparent portion in a part or all of the door portion, a portion in contact with the door portion, or the like. Further, for example, an antiglare film or the like for suppressing transmission of light emitted from the light source 3 to the outside may be attached to the upper portion of the peripheral wall 11 or the like.

  The lid 12 has a lid plate 12 a disposed vertically to the central axis of the peripheral wall 11. The lid 12, more specifically, the lid 12 a, is provided with one or more heat radiation fans 6. In the present embodiment, as shown in FIG. 4, four heat radiation fans 6 are disposed on the inner surface of the cover plate 12a. The cover plate 12a is formed with an opening 12b for discharging the air sent from the heat radiation fan 6 to the outside. The openings 12 b are provided at positions overlapping with the heat dissipation fan 6 in a one-to-one correspondence with the heat dissipation fan 6, and in the present embodiment, four openings 12 b are provided.

  The bottom portion 13 is disposed perpendicularly to the central axis of the peripheral wall 11, and a bottom plate 13a for sealing the lower opening of the peripheral wall 11, and a table 13b disposed on the upper surface side of the bottom plate 13a on which the cultivation unit Y is mounted Have. The bottom plate 13a is formed with one or more vent holes 13c. It is preferable that the vent holes 13c be formed at least in a portion not overlapping with the table 13b in plan view (that is, a portion not covered by the table 13b). Thus, the air holes 13c are formed in a portion not overlapping with the table 13b in plan view, so that the air introduced into the casing 1 from the air holes 13c can be easily sent to the heat dissipation fan 6 side. It is easy to form the air flow from the top to the top. The vent holes 13c may be formed in a portion overlapping the table 13b in a plan view of the bottom plate 13a. In this case, it is preferable that one or more vent holes be formed in the table 13b.

  In the cultivation apparatus, the first support 20 is placed on the table 13 b, and the second support 21 is placed on the first support 20. That is, in the cultivation apparatus, the cultivation unit Y is indirectly mounted on the bottom portion 13 via the first support 20 and the second support 21. In addition, the said cultivation apparatus may arrange | position a drain pan between the table 13b and the 1st support stand 20, in order to prevent a water leak.

(Culture liquid supply mechanism)
As shown in FIGS. 2 and 3, the culture solution supply mechanism 2 includes a culture solution tank 14 for storing the culture solution Z, and a pair of storage tanks 15 for temporarily storing the culture solution Z supplied from the culture solution tank 14 ( It has the 1st storage tank 15a and the 2nd storage tank 15b, and the liquid sending part 16 which distributes cultivation liquid Z to a cultivation unit Y from a pair of storage tanks 15 by capillarity. In addition, the culture solution supply mechanism 2 is capable of pumping the culture solution Z stored in the culture solution tank 14 to the pair of storage tanks 15, and the water level of the culture solution Z in the pair of storage tanks 15 is below a certain level In this case, the pump 17 is driven to supply the culture solution Z from the culture solution tank 14 to the pair of storage tanks 15, and the pump 17 is driven when the water level of the culture solution Z in the pair of storage tanks 15 reaches a certain level. And a control unit 18 for stopping the The control unit 18 drives and controls the pump 17 based on the water level of the pair of storage tanks 15 detected by a sensor 22 described later.

<Cultivated liquid tank>
The cultivation liquid tank 14 is a container having, for example, a synthetic resin such as polyethylene as a main component. Although it does not specifically limit as capacity of cultivation liquid tank 14, For example, it can be about 15 L or more and 30 L or less. In addition, a "main component" means the component with most content, for example, the component whose content is 50 mass% or more.

Reservoir
The first storage tank 15 a is in communication with the culture liquid tank 14. The second storage tank 15b is in communication with the first storage tank 15a. Specifically, the first storage tank 15 a and the second storage tank 15 b communicate with each other by the connection pipe 19 provided below the liquid level of the culture solution Z. Thereby, the liquid level of the 1st storage tank 15a and the 2nd storage tank 15b is comprised so that it may be maintained at the same height. Furthermore, the second storage tank 15b directly communicates only with the first storage tank 15a and does not directly communicate with the culture liquid tank 14 (that is, the second storage tank 15b is the first storage tank). It is in communication with the culture broth 14 only via 15a). The first storage tank 15a and the second storage tank 15b are disposed at positions facing each other across the cultivation unit Y in plan view. Moreover, in the said cultivation apparatus, a pair of through-hole penetrated to a height direction is formed in the 1st support stand 20, and the 1st storage tank 15a and the 2nd storage tank 15b are fitted by this pair of through-hole. It is held in the

  The first storage tank 15a and the second storage tank 15b contain, for example, a synthetic resin as a main component. An acrylic resin, a polycarbonate, a polyvinyl chloride etc. are mentioned as said synthetic resin, Especially the acrylic resin or polycarbonate which is excellent in transparency is preferable.

The first storage tank 15a and the second storage tank 15b have a rectangular parallelepiped shape having a large depth (horizontal length perpendicular to the width) with respect to the width (length in the direction in which the first storage tank 15a and the second storage tank 15b face each other) Is formed. As each of the volume of the first reservoir 15a and the second reservoir 15b, it may be of the order for example 200 cm ³ or more 500 cm ³ or less.

  In addition, in the said cultivation apparatus, in order to suppress the reproduction of the algae in a tank, it is preferable to coat | cover the 1st storage tank 15a and the 2nd storage tank 15b with a light shielding cover.

<Liquid transfer section>
The liquid delivery unit 16 is a sheet. Although the specific planar shape of the liquid feeding portion 16 is not particularly limited, it is, for example, a rectangular shape, preferably a rectangular shape. The liquid transfer unit 16 is immersed in the culture solution Z whose both ends are stored in the first storage tank 15a and the second storage tank 15b. In addition, a part between both ends of the liquid transfer unit 16 is in contact with the bottom of the cultivation unit Y. Specifically, a portion between both ends of the liquid transfer unit 16 is disposed on the second support 21, and the cultivation unit Y is placed thereon. Thus, the culture solution Z stored in the first storage tank 15a and the second storage tank 15b is pumped by capillary action, and can be supplied to the bottom of the culture unit Y.

  The material of the liquid transfer unit 16 is not particularly limited as long as it can pump the culture solution Z by capillary action and supply the culture solution Z to the bottom of the culture unit Y, for example, non-woven fabric, rock wool sheet, felt sheet And synthetic resin sheets such as polyurethane. Among them, non-woven fabrics are preferable in that they can exhibit appropriate capillary phenomenon and appropriate water absorption.

  As a minimum of water permeability of sending part 16, 0.01% is preferred and 1.00% is more preferred. On the other hand, as a maximum of water permeability of sending part 16, 40% is preferred and 30% is more preferred. If the above-mentioned water permeability does not reach the above-mentioned lower limit, there is a possibility that the quantity of cultivation liquid Z supplied to the bottom of cultivation unit Y may become insufficient. On the contrary, when the above-mentioned water permeability exceeds the above-mentioned upper limit, there is a possibility that the cost which liquid sending part 16 requires may become high unnecessarily. In addition, "water permeability" means the ratio of the water which passed to the back surface of a liquid feeding part, when water was sprayed from the surface of a flat liquid feeding part.

  As a lower limit of the thickness of liquid sending section 16, 0.5 mm is preferred and 0.7 mm is more preferred. On the other hand, as an upper limit of the thickness of liquid sending section 16, 2.0 mm is preferred and 1.5 mm is more preferred. If the thickness of the liquid sending portion 16 is smaller than the above lower limit, the strength of the liquid sending portion 16 is insufficient and there is a possibility of breakage. Conversely, if the thickness of the liquid transfer portion 16 exceeds the upper limit, the cost required for the liquid transfer portion 16 may be unnecessarily high.

  As a lower limit of the pumping height of liquid sending section 16, 3 cm is preferred, 10 cm is more preferred, and 20 cm is more preferred. On the other hand, as an upper limit of the pumping height of liquid sending section 16, 300 cm is preferred, 200 cm is more preferred, and 40 cm is more preferred. If the pumping height of the liquid transfer unit 16 is smaller than the above-described lower limit, the amount of the culture solution Z supplied to the bottom of the culture unit Y may be insufficient. On the contrary, if the pumping height of the liquid transfer unit 16 exceeds the upper limit, the cost required for the liquid transfer unit 16 may be unnecessarily high. In addition, "pumping height" means the value measured by the following methods. First, a sheet obtained by cutting the liquid-feeding portion to a width of 4 cm and a length of 120 cm is covered with a polyethylene film having an average thickness of 0.03 mm (a sheet is inserted into a bag-like film by thermocompression bonding to cover the periphery) Set as a measurement sample, and set it on a rack where the measurement sample can be suspended vertically. At this time, the upper and lower portions are opened 5 cm to be in contact with the liquid surface. And the height pumped up from the liquid level in 24 hours is measured 5 times, and let the average value of these be the pumped height.

(light source)
As shown in FIG. 4, the light source 3 includes one or more discharge lamps 3 a disposed on the lid 12, more specifically, the lid 12 a. In the present embodiment, four discharge lamps 3a are disposed at equal intervals from the center on a pair of straight lines passing through the center of the inner surface of the lid plate 12a. Further, as shown in FIG. 4, the light source 3 includes an ultraviolet lamp 3 b disposed on the lid 12, more specifically, the lid 12 a. In the present embodiment, one ultraviolet lamp 3b is disposed at the center of the inner surface of the lid plate 12a. Furthermore, as shown in FIG. 5, the light source 3 includes a plurality of LEDs 3 c disposed on the peripheral wall 11. The plurality of LEDs 3 c are linearly arranged on the inner surface of the peripheral wall 11 in parallel with the central axis of the peripheral wall 11. More specifically, the plurality of LEDs 3 c are linearly arranged on the inner surface of the peripheral wall 11 at intervals of 90 ° with respect to the central axis of the peripheral wall 11. The said cultivation apparatus can fully enlarge the light quantity supplied to the crop X by having 1 or several discharge lamp 3a and several LED 3c. Moreover, since the said cultivation apparatus is arrange | positioned by one or several discharge lamp 3a in the cover part 12, and several LED3c is arrange | positioned by the surrounding wall 11, it is easy to supply uniform light to the whole crop X.

  The cultivation apparatus includes one or more discharge lamps 3a in which the light source 3 is disposed in the lid 12 and a plurality of LEDs 3c disposed in the peripheral wall 11, and the calorific value of the discharge lamps 3a is relatively large. Because of the large size, the temperature in the casing 1 tends to be higher toward the upper side. Moreover, as for the said cultivation apparatus, as above-mentioned, the fan 6 for thermal radiation is arrange | positioned by the cover part 12, and the ventilation hole 13c is formed in the bottom part 13. As shown in FIG. Therefore, in the cultivation apparatus, the air introduced into the casing 1 from the vent 13 c is sucked by the heat dissipation fan 6 and easily released to the outside. Thereby, the said cultivation apparatus tends to form the flow of air from the lower part to the upper part. As a result, the cultivation apparatus can promote photosynthesis of the crop X by appropriately supplying air to the crop X, and can grow the crop X more appropriately.

  The one or more discharge lamps 3a have the property of being relatively close to sunlight, and effectively promote the growth of the crop X. The lower limit of the illuminance of the one or more discharge lamps 3a is preferably 4000 lx, more preferably 10000 lx. On the other hand, the upper limit of the illuminance of the one or more discharge lamps 3a is preferably 100,000 lx, and more preferably 800000 lx. If the above-mentioned illumination intensity does not reach the above-mentioned minimum, there is a possibility that crop X can not fully be grown. On the contrary, when the above-mentioned illumination intensity exceeds the above-mentioned upper limit, there is a possibility that fault may be easily generated in crop X. In addition, "illuminance" means the average value of the measured value in the leaf of the crop in five places divided equally into 5 to the center axis direction of a surrounding wall.

  As a kind of discharge lamp 3a, a mercury lamp, a high pressure mercury lamp, a metal halide lamp, a high pressure sodium lamp etc. are mentioned, for example. Among them, metal halide lamps which have a light emission spectrum relatively close to that of sunlight, high luminance, power saving and long life are preferable.

  The ultraviolet lamp 3b suppresses the occurrence of the disorder of the crop X. The cultivation apparatus uses a plurality of LEDs 3c, and the light from the plurality of LEDs 3c has a larger proportion of light with a wavelength of 400 nm to 700 nm and a small proportion of light with a wavelength of 280 nm to less than 400 nm compared to sunlight. . Therefore, it is possible that the said cultivation apparatus will produce disorder in crop X resulting from the ratio of the light of wavelength 280nm-400nm becoming inadequate. In this regard, in the cultivation apparatus, the light source 3 includes the ultraviolet lamp 3b, and the ultraviolet lamp 3b can emit light having a spectrum in which a peak is present in a wavelength range of 280 nm to less than 400 nm. , The occurrence of the disorder of crop X can be suppressed.

  For example, black light is suitably used as the ultraviolet lamp 3b. The ultraviolet ray lamp 3b only needs to be always on at all times as long as it can sufficiently suppress the failure of the crop X as described above. The ultraviolet lamp 3b may be controlled to repeat a cycle of, for example, continuously turning on for about 12 hours to about 20 hours and turning off for about 4 hours to about 12 hours.

  As the plurality of LEDs 3c, for example, a red LED which easily promotes the photosynthesis of the crop X and a blue LED which easily grows the stems of the crop X can be used in an appropriate ratio. The arrangement ratio of the blue LED and the red LED can be, for example, about 4: 6 to 6: 4.

(Liquid absorption speed calculation unit)
From the change of the water level of the culture fluid Z detected by the sensor 22 which detects the water level of the culture fluid Z in a pair of storage tanks 15 temporally, and the sensor 22 as shown in FIG. And a calculation unit 23 for calculating the liquid absorption speed of the crop X.

  In the cultivation apparatus, the sensor 22 detects the water level of the culture solution Z in the pair of storage tanks 15 over time, and the calculation unit 23 detects the liquid absorption speed of the crop X based on the change in the water level of the culture solution Z The temporal change of the liquid absorption speed of the crop X can be displayed by the display unit 5 by calculating. Thereby, the said cultivation apparatus can manage the health condition of the crop X more appropriately.

<Sensor>
The sensor 22 detects the water level of the second storage tank 15b. The said cultivation apparatus has only the sensor 22 which detects the water level of the 2nd storage tank 15b. In the cultivation apparatus, the first storage tank 15a and the second storage tank 15b communicate with each other below the liquid surface of the culture solution Z by the connection pipe 19, so the liquid in the first storage tank 15a and the second storage tank 15b The faces are kept at the same height. Therefore, based on the change of the water level of the 2nd storage tank 15b, the amount of supply of cultivation liquid Z to the bottom of cultivation unit Y and by extension, the fluid absorption of crop X can be measured. Therefore, the liquid absorption speed of the crop X can be easily and reliably determined by the sensor 22 detecting the water level of the second storage tank 15b with time. Moreover, the said cultivation apparatus measures the liquid absorption amount of the crop X from the change of the water level of a pair of storage tank 15 detected by the sensor 22, For example, the liquid absorption of the crop X is about 0.05 cc. The quantity can be measured.

  The type of the sensor 22 is not particularly limited as long as the water level of the pair of storage tanks 15 can be detected with time, and a level sensor such as an optical type, a float type, an electrostatic capacity type, or an ultrasonic type Can be used.

  The interval at which the water level of the pair of storage tanks 15 is detected by the sensor 22 is not particularly limited, but may be, for example, a fixed interval of 1 second or more and 60 seconds or less.

<Operation unit>
Arithmetic unit 23 is configured to include a CPU (Central Processing Unit). The calculation unit 23 converts the change in water level of the pair of storage tanks 15 detected by the sensor 22 into a volume, and divides the change by the time required for the change in water level to calculate the liquid absorption speed of the crop X.

(Display section)
The display unit 5 is, for example, a liquid crystal monitor. The display unit 5 graphically displays, for example, the liquid absorption speed of the crop X. Specifically, the display unit 5 displays a graph in which the horizontal axis represents time, and the vertical axis represents the absorbed amount of the crop X (decreased amount of the culture solution Z stored in the pair of storage tanks 15). Thereby, the viewer can easily confirm the temporal change of the liquid absorption speed of the crop X by visually recognizing this graph, and can grasp the health condition of the crop X from the change of the liquid supply speed. it can.

(Cultivation unit)
The cultivation unit Y has the frame 101 and the particle 102 with which the frame 101 is filled, as shown in FIG. In the cultivation unit Y, for example, soil etc. is filled in the particles 102 (particle layer) filled in the frame 101, and the nursery pot 103 in which the crop X is deposited is placed on the soil etc. . In addition, the cultivation unit Y may have a configuration in which the crop X is planted on the particles 102 (particle layer) filled in the frame 101.

<Frame body>
The frame body 101 is configured in a bottomed cylindrical shape. The frame body 101 has, at the bottom, a plurality of minute through holes through which the culture solution Z passes and the particles 102 do not pass. It does not specifically limit as a raw material of the frame 101, For example, paper, woven fabric, a nonwoven fabric etc. are mentioned.

<particle>
The particles 102 are filled in the frame 101 to form a particle layer. The particles 102 are not particularly limited as long as they are filled in the frame 101 and exhibit capillary action, but, for example, soil, fine pumice such as pumice sand, crushed particles of porous volcanic rock, granular rock wool, coral Sand, coral, charcoal etc. are mentioned. Two or more of these may be mixed and used. Above all, soil is preferable from the viewpoint of ensuring good capillary action and returning to natural soil when it becomes unnecessary.

  Examples of the soil include commercially available horticultural soils for horticulture, vermiculite, bentonite, zeolite, sand, Kanuma soil, Akadama soil, true sand soil and the like. Among these, sand having a low content of organic matter and a small number of living microorganisms as compared with a general culture soil is preferable in that it is difficult to cause root diseases of the crop X.

Other Embodiments
It should be understood that the embodiments disclosed herein are illustrative and non-restrictive in every respect. The scope of the present invention is not limited to the configurations of the above embodiments, but is indicated by the claims, and is intended to include all modifications within the meaning and scope equivalent to the claims. Ru.

  The specific structure of the said cultivation liquid supply mechanism is not limited to the structure of the said embodiment. For example, the above-mentioned cultivation liquid supply mechanism does not necessarily need to be the composition which supplies cultivation liquid to the bottom of a cultivation unit by capillary phenomenon, and it is also possible to adopt the composition which immerses the root part of a crop directly in cultivation liquid. . However, from the viewpoint of suppressing excessive supply of cultivation liquid and the like and cultivating crops appropriately, it is preferable to use a configuration utilizing capillary action. In addition, even in the case of adopting a configuration using capillary action as the above-mentioned culture liquid supply mechanism, the above-mentioned culture liquid supply mechanism may have only one storage tank, and has three or more storage tanks. It may be done.

  The liquid absorption speed calculation unit detects the liquid absorption amount of the crop finely, and detects the water level of the cultivation liquid in one or a plurality of storage tanks with a sensor over time from the point of precisely performing the health management of the crop. It is preferable to do. However, the liquid absorption speed calculation unit may not necessarily measure the liquid absorption amount of the crop by detecting the water level of the cultivation liquid in one or a plurality of storage tanks using a sensor.

  The specific type and specific arrangement of the light source are not limited to the configuration of the above embodiment. For example, the cultivation apparatus need not have all of the discharge lamp, the plurality of LEDs and the ultraviolet lamp, and may have other lamps such as an incandescent lamp, a halogen lamp and a fluorescent lamp.

The cultivation apparatus may further include other sensors that can detect the growth environment of the crop X, such as a temperature sensor, a humidity sensor, and a CO ₂ gas sensor.

  As described above, the cultivation apparatus according to the present invention is suitable as a cultivation apparatus for fruits and vegetables such as tomato, because the cultivation condition of the crop can be appropriately managed while being excellent in the ornamental property of the crop.

Reference Signs List 1 casing 2 culture solution supply mechanism 3 light source 3a discharge lamp 3b ultraviolet lamp 3c LED
4 liquid absorption speed calculation unit 5 display unit 6 heat radiation fan 7 protective cover 7a opening 11 peripheral wall 12 lid 12a lid 12b opening 13 bottom 13a bottom plate 13b table 13c air hole 14 cultivation liquid tank 15 storage tank 15a first storage tank 15b Second storage tank 16 Liquid transfer unit 17 Pump 18 Control unit 19 Connection tube 20 First support 21 Second support 22 Sensor 23 Calculation unit 101 Frame 102 Particles 103 Seedling pot X Crop Y Cultivation unit Z Cultivation liquid

Claims (5)

A casing having a transparent cylindrical peripheral wall, a lid for sealing the upper opening of the peripheral wall, and a bottom for sealing the lower opening of the peripheral wall and on which a cultivation unit on which a crop is deposited is placed;
A culture solution supply mechanism for supplying a culture solution to the culture unit;
A light source disposed in the casing for irradiating the crop with light;
A liquid absorption speed calculation unit that calculates a liquid absorption speed of the cultivation liquid with respect to the crop;
And a display unit for displaying data of liquid absorption speed calculated by the liquid absorption speed calculation unit. The cultivation liquid supply mechanism comprises: a cultivation liquid tank for storing the cultivation liquid; one or more storage tanks for temporarily storing the cultivation liquid supplied from the culture liquid tank; and the cultivation from the one or more storage tanks. The unit has a liquid transfer section for circulating the above culture liquid by capillary action,
The liquid absorption speed calculation unit calculates the liquid absorption speed of the crop from the change in water level of the culture liquid detected by the sensor and the sensor that detects the water level of the culture liquid in the one or more storage tanks with time. The cultivation apparatus according to claim 1, further comprising: The above-mentioned cultivation liquid supply mechanism has a pair of above-mentioned storage tanks,
The pair of storage tanks are a first storage tank in communication with the cultivation liquid tank and a second storage tank in communication with the first storage tank,
The cultivation apparatus according to claim 2, wherein the sensor detects a water level of the second storage tank. The light source includes one or more discharge lamps disposed in the lid, and a plurality of LEDs disposed in the peripheral wall;
A heat dissipation fan is disposed in the lid portion,
The cultivation apparatus according to claim 1, 2 or 3, wherein a vent is formed in the bottom.   The cultivation apparatus according to any one of claims 1 to 4, wherein the light source includes an ultraviolet lamp disposed in the lid.

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