JP2014030377A - Cultivation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cultivation device for plants with only a small installation space.SOLUTION: A cultivation device 1 includes: an illumination unit 3 for irradiating a plant P with light for cultivation, the illumination unit 3 includes: a light source 5 for light irradiation; a post 6 supporting the light source 5; and a liquid supply tank 7 filled with a liquid to be supplied to the plant P, and the liquid supply tank 7 is also used as the post 6 or integrated therewith.

Description

  The present invention relates to an indoor illuminated plant cultivation apparatus capable of automatically supplying a culture solution.

  In recent years, there have been proposed a plurality of methods for household cultivation devices using hydroponics that can be easily cultivated without using soil. For example, MRT's Living Vesta (see Patent Document 1) that has an illumination and cultivation section inside is sold. This can be grown indoors without the need for sunlight, by appropriately pouring the culture solution into the dish of the cultivation section and by photosynthesis of the plant planted in the cultivation section by lighting directly above the cultivation section. Is. In this method, when the culture medium in the cultivation part is reduced, it is necessary to visually confirm and add as appropriate.

  On the other hand, it does not require such work, and it is called submerged hydroponics, a method of hydroponics by immersing plant roots in a storage tank that stores a sufficient amount of culture solution, and its application. There is a culture medium circulation type that circulates the culture liquid in the tank to the cultivation part by pump, or a method called thin film hydroponics, in which the culture liquid is made to flow little by little on an inclined plane, and the root of the plant is immersed there. is there.

  In the submerged hydroponics, Aero Garden International Aero Garden (see Non-Patent Document 1 and Patent Document 2 for details), as a culture-circulating cultivation device, Kyowa Co., Ltd. Home Hyponika 303 type and 501 type are on the market.

  In such a system, a certain amount of culture solution is stored in the culture solution tank or storage tank, and cultivation is possible even if the culture solution is reduced to some extent, and the additional time interval of the culture solution is increased by one week or more. In addition, since the culture tank is also provided with a water level float, it is easy to determine when a liquid supply is necessary.

  On the other hand, since these methods have a culture solution tank and a storage tank that are not sealed under the cultivation section, there is a concern about leakage due to falling, which has been a problem for indoor use.

  On the other hand, in the automatic liquid supply apparatus as seen in Patent Documents 3, 4, 5, and 6, the culture liquid is stored in the liquid supply tank, and the necessary amount is sequentially supplied from the liquid supply tank to the cultivation tank. Since this liquid supply tank has a valve and is configured to close the valve except when communicating with the cultivation tank, it is possible to minimize the leakage of the culture liquid even in the event of a fall.

  Therefore, if the structure of Non-Patent Document 1 or 2 and any one of Patent Documents 3, 4, 5, and 6 is combined to form a cultivation apparatus that illuminates the automatic liquid supply apparatus, the culture liquid can be automatically supplied. Since water supply for a period is unnecessary and there is little concern about the leakage of the culture solution, there is a possibility that it can be an indoor cultivation apparatus that can be used safely with illumination indoors.

JP 2012-55170 A (published March 22, 2012) US 2006/0272210 A1 (released on December 7, 2006) Japanese Unexamined Patent Application Publication No. 2004-81167 (published March 18, 2004) JP 2010-68735 A (released on April 2, 2010) JP 2010-17097 A (released January 28, 2010) Patent No. 4646708 Patent Publication (Registered on December 17, 2010) JP 10-136793 A (published May 26, 1998) Japanese Patent No. 2873959 Patent Publication (Registered on January 14, 1999)

aerogrowinternational, Inc. “Home Of The AeroGarden From AeroGrow International”, [Online], [Search June 21, 2012], Internet <URL: http://www.aerogrow.com/> Kyowa Co., Ltd., Home Hyponica [Online], [Search June 21, 2012], Internet <URL: http://www.kyowajpn.co.jp/hyponica/hhp/index.html> Shoichi Nakamura, "Study on lodging resistance of cabbage cell seedlings by Cellular Automaton", [Online], [Searched on June 1, 2012], Internet <URL: http: //sysseipc2.mach.bio.mie-u .ac.jp / labHP /? page_id = 10>

  However, as described above, when an illuminating device is added to the automatic liquid supply apparatus, it is necessary to arrange a liquid supply tank and a support column that supports the illuminating apparatus itself on the side wall of the plant.

  Here, in order to cultivate a plant, it is necessary to observe daily growth, and to perform management operations such as sowing, transplanting, leaf cutting, pollination of flowers, and harvesting on the plant to be cultivated. Thus, since it is necessary for an operator to touch a plant when cultivating a plant, it is an essential requirement that the plant is easily accessible.

  However, in the structure of the cultivation apparatus with illumination on the automatic liquid supply apparatus, which is obtained by combining the configurations of Non-Patent Document 1 or 2 and Patent Documents 3, 4, 5, and 6, a support or a liquid supply tank Since a plurality of such structures are arranged in the vicinity of the plant, the more these structures are, the more obstructed the access to the plant is.

  The present invention has been made to solve the above-described problems of the conventional products. The purpose of the present invention is to provide an apparatus for cultivating a plant by artificial lighting while taking a liquid supply mechanism using a liquid supply tank. Plant cultivation equipment that provides users with great benefits by facilitating the management of daily growth observation, sowing, transplanting, leaf cutting, pollination of flowers, harvesting, etc. Can be provided.

  In order to solve the above problems, the cultivation apparatus of the present invention is a cultivation apparatus having an illumination unit for irradiating a plant with light for cultivation, and the illumination unit is a light source for irradiating the light. And a support column that supports the light source and a liquid supply tank filled with a liquid to be supplied to the plant, wherein the liquid supply tank and the support column are integrated.

  Here, when the liquid supply tank and the lighting are not integrated, the two structures of the liquid supply tank itself and the pillars necessary for the illumination exist on the cultivation surface, and the obstacles increase and the management work is performed. It becomes difficult and the burden of time and labor increases.

  Therefore, according to the above configuration, since the liquid supply tank and the support are integrated, there is only one structure on the cultivation surface, there are few obstacles during operations such as leaf shoveling, pollination, harvesting, and There are few obstacles when observing the growth situation from multiple directions, and the above management work is easy. That is, access to the plant being cultivated can be facilitated.

  As described above, in the cultivation of plants, the management work is an indispensable work that is frequently performed, and reducing the work burden is a significant effect on cultivation and provides a great benefit to the user.

  That is, according to the above configuration, in a device for cultivating plants by artificial lighting while taking a liquid supply mechanism using a liquid supply tank, it can be used by facilitating access to plants and facilitating management work. It can provide a great benefit to the person.

  Moreover, it is preferable that the said support | pillar stores the said liquid supply tank. According to the said structure, the said liquid supply tank is supported by the inner wall of the said support | pillar, stability of the said liquid supply tank becomes high, and it becomes difficult to fall down.

  Moreover, it is preferable that a part or all of the side wall of the support column for storing the liquid supply tank is made of a light shielding member.

  According to the said structure, the light which injects into the said liquid supply tank from the said illumination part can be light-shielded by part or all of the side wall of the said support | pillar.

  Here, according to the structure of the liquid supply tank as described in Patent Documents 3, 4, and 5, the light for cultivating the plant is from above the liquid supply tank or from the side wall into the liquid supply tank in the same manner as the plant. Incident. For this reason, when the liquid supply tank is a permeable member, there is a possibility that algae are generated inside the liquid supply tank due to this light, and the liquid supply tank is contaminated. For this reason, the liquid supply tank itself needs to have a light-shielding property, or a component for shielding the liquid supply tank separately is necessary.

  On the other hand, according to the above configuration, since at least the peripheral portion for storing the liquid supply tank is made of a light shielding member, a transparent tank that is not shielded from light may be used as the liquid supply tank for storing in the support column. Algae are unlikely to be generated inside the liquid supply tank. For this reason, a transparent tank can be used as the liquid supply tank.

  For example, a part of general PET bottles used for beverages and the like is transparent, but since these can be used as the liquid supply tank, it leads to a reduction in member costs.

  Moreover, it is preferable that the cultivation apparatus of this invention is provided with the cultivation container in which the said plant is grown, and the said support | pillar and the said cultivation container are being fixed.

  According to the said structure, since the support | pillar of the said lighting unit and the said cultivation container are being fixed, the cultivation apparatus which has integrity and a sense of stability can be obtained. Thereby, the cultivation apparatus with a small installation space and a more stable feeling can be obtained.

  Moreover, it is preferable that the said support | pillar is distribute | arranged to the center position of the said cultivation container by planar view.

  In the structure of the liquid supply apparatus described in Patent Documents 3, 4, and 5, a liquid supply tank is arranged at one end of the cultivation section.

  For this reason, when considering the center of gravity of the entire apparatus including the liquid supply tank, if the culture liquid is sufficiently stored in the liquid supply tank, the center of gravity is near the tank, and the culture liquid in the liquid supply tank decreases. The center of gravity moves from the vicinity of the tank to the far side. In this way, the position of the center of gravity on the plane changes depending on the remaining amount of the liquid supply tank, and the moment generated in each state changes. Therefore, it can be said that the structure is unstable and easily falls.

  In addition, between the concentration when the culture solution reaches the plant planted in the vicinity of the culture solution tank and the concentration of the culture solution that passes under the plant near the tank and reaches the plant far from the culture solution tank The difference in concentration occurs because the plant absorbs the culture solution, and the cultivation speed may vary depending on the planting location of the plant.

  On the other hand, according to the above configuration, these problems can be solved. That is, according to the above configuration, since the support column is arranged at the center position of the cultivation container in a plan view, even if the liquid in the liquid supply tank stored in the support column decreases, the position of the center of gravity is maintained. It is possible to prevent movement in the plane direction. Thereby, the cultivation apparatus with a stable feeling can be obtained.

  Furthermore, the nutrient of the culture solution supplied from the liquid supply tank can be uniformly applied to surrounding plants, and the cultivation speed can be unified.

  In addition, the support column has an opening for storing the liquid supply tank inside the side wall, and includes a lid for covering the opening, and at least a part of the lid is formed on the support column. The window whose inside is visible is formed of a transparent member, and the transparent member preferably transmits light having a wavelength peak in the range of 500 nm to 600 nm. With the above-described configuration, it is possible to check the remaining amount of the liquid supply tank in the support column, and more reliably prevent the generation of algae and photosynthesis in the liquid supply tank.

  Further, the cultivation container includes a skeleton part and a breathable waterproof material, the skeleton part is made of a non-breathable waterproof material, a plurality of holes are formed, and a plurality of convex parts are arranged on the bottom surface. The breathable waterproof material is formed in a bag shape inside the skeleton, and the installation surface of the cultivation device and the bottom surface of the breathable waterproof material are preferably separated from each other.

  By the said structure, the unsaturated gas in the liquid stored in the said cultivation container is supplied to the liquid in the said cultivation container through the said cultivation container from the outside. Thereby, the fall of the density | concentration of gas required for the growth of plants, such as oxygen in the liquid in the said cultivation container, can be prevented.

  Preferably, the light guide plate includes a light guide plate disposed on a side wall of the support column, and the light guide plate guides light from the light source and irradiates light in a direction intersecting with a longitudinal direction of the support column.

  According to the said structure, light can be irradiated from the side with respect to the plant to grow through the said light-guide plate. As a result, it is not necessary to place a light source at a height higher than the height of the plant being cultivated, compared to the case of irradiating from above the plant being cultivated. A cultivation device that requires less space can be obtained.

  The cultivation apparatus of the present invention is a cultivation apparatus having an illumination unit for irradiating a plant with light for cultivation, and the illumination unit includes a light source for irradiating the light, and a support supporting the light source. A liquid supply tank filled with a liquid for supplying to the plant, and the liquid supply tank and the support column are integrated.

  As a result, while taking the liquid supply mechanism using the liquid supply tank, in the device for cultivating the plant by artificial lighting, it is easy for the user to access the plant and facilitate the management work. It has the effect of providing great benefits.

(A) is a figure which represents typically the structure of the cultivation apparatus which concerns on 1st Embodiment, (b) is a perspective view of the illumination unit shown to (a). (A) is a side view showing the structure of the cap of the liquid supply tank of the cultivation apparatus of FIG. 1, (b) is the figure which expanded the front-end | tip part of the cap of (a). (A) is a figure showing the mode of the sink vicinity of the kitchen of a general household, (b) is a figure showing the side wall of the refrigerator installed in the general household. (A) is a figure showing an example which distributes the above-mentioned cultivation device on the side wall of a refrigerator using a rack with a magnet, and (b) represents a rack with a sucker for distributing the above-mentioned cultivation device on the side wall of a refrigerator. It is a perspective view. (A) is a front view of the rack pinned by the side wall, (b) is a side view at the time of storing the said cultivation apparatus in the rack of (a). (A) is a figure explaining the connection part of the illumination part and support | pillar of the said cultivation apparatus, (b) is a side view of the illumination part of (a), (c) is the side surface of the support | pillar of (a). FIG. (A) is sectional drawing showing the structure of the cultivation apparatus of the plant which concerns on 2nd Embodiment, (b) is a perspective view of the cultivation apparatus of (a), (c) is cultivation of (a) It is a figure showing the front-end | tip part vicinity of the liquid supply tank of an apparatus. (A) is a top view showing the cultivation tank whose planar shape is a rectangle, (b) is a top view showing the cultivation tank whose planar shape is a positive direction shape, and (c) is a planar shape of a circle. It is a top view showing a cultivation tank. It is a perspective view explaining the 1st example which fixes the support | pillar of the said cultivation apparatus and a cultivation tank. (A)-(c) is a figure explaining the 2nd example which fixes the support | pillar of the said cultivation apparatus, and a cultivation tank, (a) is a figure showing the front of the catch clip distribute | arranged to the support | pillar. And (b) is a view showing the side surface of the catch clip of (a), and (c) is a perspective view showing a cultivation tank in which a catch member for the catch clip is arranged. (A) is a side view of the catch clip showing another example, (b) is a front view of the catch clip of (a). It is a perspective view explaining the 3rd example which fixes the support | pillar of the said cultivation apparatus and a cultivation tank. (A) is a figure showing a mode that a liquid supply adapter of the above-mentioned cultivation device is equipped, (b) is a figure showing a mode that a valve of a liquid supply adapter is closed, and (c) is cultivated from a tank main part. It is a figure showing a mode that the culture solution is supplied to the tank, (d) is a figure showing the state which the supply of the culture solution from the tank main body to the cultivation tank stopped. It is sectional drawing showing the structure of a general slag type apparatus. (A) and (b) schematically represent a cultivation apparatus in which a liquid supply tank is present at one end, (a) is a diagram illustrating a cultivation apparatus when the liquid level in the liquid supply tank is high, (b ) Is a diagram showing a case where the liquid level in the liquid supply tank is low. (A) is a figure showing the mode of the culture solution density | concentration of the cultivation apparatus in which a liquid supply tank exists in one side edge part, (b) is the figure showing the mode of the culture solution concentration of the cultivation apparatus of 2nd Embodiment. It is. (A) is a figure which assumes the case where it attaches centering on the support | pillar which supports an illumination part to the cultivation apparatus by which the liquid supply tank is arranged around the cultivation plant, (b) is liquid supply around the cultivation plant. It is a figure which assumes the case where the support | pillar which supports an illumination part is attached to the circumference | surroundings of a cultivation plant to the cultivation apparatus by which the tank is distribute | arranged. It is sectional drawing showing the structure of the cultivation apparatus of the plant which concerns on 3rd Embodiment. (A) is a front view showing the structure of the support | pillar and illumination part of the said cultivation apparatus, (b) is a side view of the support | pillar and illumination part shown to (a). It is sectional drawing showing the structure of the cultivation apparatus of the plant which concerns on 4th Embodiment. (A) is a front view showing the structure of the support | pillar and illumination part of the said cultivation apparatus, (b) is a side view of the support | pillar shown to (a). It is a figure showing a mode that the support | pillar of the said cultivation apparatus and the illumination part are being fixed. It is sectional drawing showing the structure of the cultivation apparatus of the plant which concerns on 5th Embodiment. It is a figure showing a mode that a cover is attached to the opening part of the support | pillar of the said cultivation apparatus. It is sectional drawing showing the structure of the cultivation apparatus of the plant which concerns on 6th Embodiment. (A) is a figure showing a mode that a cover is attached to the opening part of the support | pillar of the said cultivation apparatus, (b) is an enlarged view of the cover of (a). It is a figure showing the graph of the absorption wavelength of chlorophyll. It is a figure showing the structure of the liquid supply tank of the cultivation apparatus which concerns on 7th Embodiment. It is a figure showing the structure of the liquid supply tank of the cultivation apparatus which concerns on 8th Embodiment. It is a figure showing the structure of the liquid supply tank of the cultivation apparatus which concerns on 9th Embodiment. It is a figure showing the structure of the cultivation apparatus which concerns on 10th Embodiment. It is a perspective view showing the structure of the cultivation apparatus which concerns on 11th Embodiment. (A) is a perspective view showing the structure of the frame | skeleton part which concerns on 11th Embodiment, (b) is an enlarged view of the convex part vicinity of a skeleton part. It is a perspective view showing the structure of the cultivation apparatus which concerns on 12th Embodiment.

[Embodiment 1]
A first embodiment of the present invention will be described with reference to FIGS. 1 (a), 1 (b) to 6 (a) to 6 (c).

(Configuration of cultivation apparatus 1 and installation example)
First, the structure of the cultivation apparatus 1 and the installation example of the cultivation apparatus 1 are demonstrated using FIG. 1 (a) (b)-FIG. 5 (a) (b).

  Fig.1 (a) is a figure which represents typically the structure of the cultivation apparatus 1 of the plant of this invention, (b) is a perspective view of the illumination unit shown to (a).

  The cultivation apparatus 1 includes a planter (cultivation container) 2 and a lighting unit 3.

  The planter 2 has soil disposed therein, and the plant P is cultivated in the soil. The planter 2 is not particularly limited, and a commercially available product that is generally used can be used. Moreover, the culture medium arrange | positioned in the planter 2 is not limited to soil, What is necessary is just to function as a culture medium, such as a pebble and a zeolite, for example.

  The type of plant P to be cultivated is not particularly limited, but leaf vegetables and herbs that can be easily grown at home are preferred.

  The lighting unit 3 includes a light source for irradiating the plant P cultivated with the planter 2 with light for cultivation, and is supplied with a culture solution (liquid) for supplying the plant P with the light source. The tank can be stored inside. The lighting unit 3 can be attached to or detached from the planter 2.

  The lighting unit 3 includes a lighting unit 4, one or more light sources 5 arranged in the lighting unit 4, a column 6 that supports the lighting unit 4 and can store a liquid supply tank 7 therein, and a plant P And a liquid supply tank 7 filled with a culture solution for supply.

  The illumination unit 3 is provided with one or a plurality of light sources 5. The light source 5 is a light source for irradiating the plant P with light for cultivation.

  The column 6 is connected to the illumination unit 4. The support 6 supports the illumination unit 4 when the illumination unit 3 is attached to the planter 2. Furthermore, an opening 6a is formed in a part of the side surface and the inside of the column 6, and the liquid supply tank 7 can be stored in the column 6 by storing the liquid supply tank 7 in the opening 6a. It has a configuration.

  The illumination unit 4 is attached to the planter 2 by the illumination unit 3. An opening 4a is formed in the illumination unit 4 at a position that becomes the center of gravity. In the present embodiment, the illumination unit 4 has a center of gravity in the vicinity of the center when viewed in plan, and an opening 4a is formed at that position. The illumination unit 4 is connected to the column 6 by inserting the column 6 into the opening 4a. Thereby, the illumination part 4 is supported by the support | pillar 6. FIG. The illumination unit 4 is connected to the support column 6 so as to be movable up and down along the longitudinal direction of the support column 6. In addition, the specific example of the structure which connects the illumination part 4 and the support | pillar 6 is mentioned later.

  The illumination part 4 should just have the area which covers all or one part of the planter 2 when the illumination unit 3 is attached with the planter 2. As shown in FIG. The shape of the illuminating unit 4 is not particularly limited, and as shown in FIGS. 1 (a) and 1 (b), the shape may be a convex shape upward, or may be a planar shape.

  The illumination unit 4 can be made of, for example, glass, acrylic, metal, plastic, or the like. In particular, the illumination unit 3 can be reduced in weight by configuring the illumination unit 4 from plastic or lightweight plastic.

  One or a plurality of light sources 5 are arranged in the illumination unit 4 or on the lower surface (a surface that faces the planter 2). When the illumination unit 3 is attached to the planter 2, the light source 5 irradiates the plant P cultivated with the planter 2 from the inside or the lower surface of the illumination unit 4 with light for cultivation.

  The light source 5 is constituted by a fluorescent lamp, an LED, a semiconductor laser, or the like. The wavelength of the light of the light source 5 is not particularly limited, and the wavelength used in artificial plant cultivation can be used.

  The column 6 has a columnar shape. The support column 6 and the illumination unit 4 are fixed by the upper end of the support column 6 being inserted into the opening 4 a of the illumination unit 4. The lower end of the support 6 is placed in contact with the planter 2 when the lighting unit 3 is attached to the planter 2 or in the vicinity of the planter 2.

  As an example, the column 6 has a cylindrical shape in the present embodiment. The shape of the column 6 is not limited to a cylindrical shape, and may be a prismatic shape such as a triangular prism or a quadrangular prism, or may be a pyramid shape such as a cone, a triangular pyramid, or a quadrangular pyramid.

  The opening 6 a provided in a part of the side surface and the inside of the support column 6 has a shape that allows the liquid supply tank 7 to be taken in and out of the support column 6 and that the liquid supply tank 7 can be stored and held in the support column 6. ing.

  Although the support | pillar 6 may be transparent, it is preferable to be comprised from the light-shielding member. In addition, it is preferable that one surface of the upper end surface 6u of the column 6 is formed of a light shielding member.

  The light from the light source 5 is prevented from being applied to the liquid supply tank 7 arranged inside the support column 6, and thereby algae are generated in the liquid supply tank 7 arranged inside the support column 6. It is because it can prevent.

  The support 6 can be made of, for example, glass, acrylic, metal, plastic, or the like. In particular, the illumination unit 3 can be reduced in weight by configuring the support column 6 from plastic or lightweight plastic.

  The liquid supply tank 7 includes a tank main body 7a and a cap (liquid supply adapter) 7b attached to a single opening of the tank main body 7a.

  When the lighting unit 3 is attached to the planter 2, the liquid supply tank 7 is loaded inside the column 6 so that the cap 7 b attached to the sole opening of the tank body 7 a faces downward.

  The tank body 7a is filled with a culture solution to be supplied to the plant P. As a culture solution filled in the tank body 7a, an optimal type of fertilizer culture solution may be appropriately selected depending on the type of the plant P, or water may be used.

  Here, when the tank body 7a is filled with the fertilizer culture solution, not only the growth of the plant P but also an environment in which algae are easily generated in the tank body 7a. For this reason, when light from the light source 5 or external light is irradiated on the tank body 7a, algae grows in the tank body 7a, consumes fertilizer, and contaminates the inside of the liquid supply tank 7. .

  For this reason, it is preferable that the support | pillar 6 is comprised from the light shielding material. In the illumination unit 3, since the liquid supply tank 7 is stored inside the support column 6, the light irradiated to the liquid supply tank 7 can be shielded by configuring the support column 6 from a light shielding member. It is possible to prevent algae from being generated in the tank 7.

  As for the support | pillar 6, it is preferable that all the side walls 6h which store the liquid supply tank 7 are comprised from the light-shielding member. Thereby, the light incident on the liquid supply tank 7 in the column 6 from the light source 5 can be reliably shielded by the side wall 6 h of the column 6.

  Here, according to the structure of the liquid supply tank as described in Patent Documents 3, 4, and 5, the light for cultivating the plant is from above the liquid supply tank or from the side wall into the liquid supply tank in the same manner as the plant. Incident.

  For this reason, when the liquid supply tank is a permeable member, there is a possibility that algae are generated inside the liquid supply tank due to this light, and the liquid supply tank is contaminated. For this reason, the liquid supply tank itself needs to have a light-shielding property, or a component for shielding the liquid supply tank separately is necessary.

  On the other hand, according to the support column 6 according to the present embodiment, at least the side wall 6h of the support column 6 for storing the liquid supply tank 7 is made of a light shielding member, so that a transparent tank that is not shielded from light (for example, a general PET bottle). Even if it is used as a liquid supply tank 7 for storing in the support column 6, algae hardly occur in the liquid supply tank 7. For this reason, a transparent tank can be used as the liquid supply tank 7.

  Note that at least a part of the side wall 6h of the column 6 may be formed of a light shielding member. Also by this, the light incident on the liquid supply tank 7 in the column 6 from the light source 5 can be shielded.

  For example, a part of general PET bottles used for beverages is transparent, but since these can be used as the liquid supply tank 7, it also leads to a reduction in member costs.

  Furthermore, the upper end of the column 6 may be covered with a light-shielding member. Thereby, since it can prevent that external light is irradiated to 7 from the upper end side of the support | pillar 6, generation | occurrence | production of the algae in the liquid supply tank 7 can be prevented reliably.

  The tank body 7a uses a configuration of a general liquid supply tank used for a humidifier or the like.

  The tank body 7a has only one opening and is a container to which a cap 7b can be attached. The tank body 7a may have a capacity that can supply the culture solution to the planter 2 for about one week.

  The only opening of the tank body 7a is a cap that matches the diameter of a general PET bottle so that a general-purpose 500ml, 330ml, or 475ml bottle used for drinking water can be used as the tank body 7a. Is preferably a size that can be mounted. And the cap 7b attached to the only opening part of this tank main body 7a is a cap suitable for the diameter of a general PET bottle. The cap 7b is preferably compatible with, for example, any of φ28 mm diameter PCO-1810, PCO-1881-MED, PCO-1881-ISBT, or Alcoa-1716.

  Moreover, it is desirable that the opening 6a of the column 6 has an opening area into which a 600 ml plastic bottle can be inserted at the maximum.

  As the tank body 7a, by using a general-purpose plastic bottle that is generally used, the illumination unit 3 can be obtained at a low cost and the versatility can be improved.

  Here, at least a part of a general plastic bottle is often transparent, and it is difficult to shield the light from the plastic bottle itself.

  For this reason, as described above, the liquid supply tank 7 is stored in the support column 6, and the support column 6 is made of a light shielding member, so that a liquid supply tank can be used while using a general PET bottle as the liquid supply tank 7. The generation of algae in 7 can be prevented.

  The cap 7b is a liquid supply adapter for adjusting the flow rate of the culture solution in the tank body 7a. A general-purpose plastic bottle can be used as the tank body 7a by attaching the cap 7b to the opening at the tip of the tank body 7a.

  The cap 7b is configured to be able to supply the culture solution in the tank body 7a to the soil of the planter 2 for a certain period of time, and supports the liquid supply tank 7 by being inserted into a medium such as soil. As a result, the illumination unit 3 is supported. That is, the cap 7 b functions as a support portion for the planter 2 of the lighting unit 3.

  An example of the cap 7b will be described with reference to FIGS. FIG. 2A is a side view showing the configuration of the cap 7b of the liquid supply tank 7, and FIG. 2B is an enlarged view of the tip of the cap 7b of FIG.

  The cap 7b has a conical shape and has a small hole near the tip. And it attaches to the front-end | tip part of the tank main body 7a, covering the only opening part of the tank main body 7a. And it inserts in the soil in the planter 2 from the pointed front-end | tip part of the cap 7b. Thereby, the culture solution in the tank main body 7a gradually oozes out from the small hole provided in the culture medium such as soil near the tip of the cap 7b. When a sufficient amount of the culture solution is sucked into the soil, the pressure is balanced and the supply of the culture solution is stopped.

  As the cap 7b, a commonly used cap can be used, and as an example, a product “Omakase Water Supply Cap” manufactured by Seiei Co., Ltd. can be used.

  Thus, since the illumination unit 3 is supported by the cap 7b being inserted into a culture medium such as soil in the planter 2, a fixing member or the like for fixing to the planter 2 is unnecessary. And it is possible to install the lighting unit 3 in the arbitrary places in the planter 2 according to the cultivation location, growth speed, etc. of the plant P cultivated with the planter 2 of a commercial item. For this reason, the cultivation apparatus 1 with high versatility can be obtained.

  In addition to the cap 7b, the lower end portion of the support column 6 may be inserted into a medium such as soil of the planter 2 so that the lower end portion of the support column 6 may function as a support unit for the planter 2 of the illumination unit 3. Thereby, the illumination unit 3 can be stably arranged on the planter 2.

  Furthermore, the column 6 and the planter 2 may be fixed by attaching a member for fixing the column 6 and the planter 2 to the column 6 or the planter 2. Thereby, the lighting unit 3 can be further stably arranged on the planter 2.

  Thus, the illumination unit 3 is a liquid supply filled with a light source 5 for irradiating the plant P with light for cultivation, a support 6 for supporting the light source 5, and a culture solution for supplying the plant P. And a tank 7. And the liquid supply tank 7 and the support | pillar 6 are united.

  Here, when the liquid supply tank and the lighting are not integrated, the two structures of the liquid supply tank itself and the pillars necessary for the illumination will be present on the cultivation surface, increasing the number of obstacles and managing work. This increases the burden of time and labor. Note that the management work includes daily observation of the growth of the plant P, sowing, transplanting, leaf cutting, pollination of flowers, harvesting, and the like.

  On the other hand, in the cultivation apparatus 1, by storing the liquid supply tank 7 inside the support column 6 and integrating the support column 6 and the liquid supply tank 7, there is one on the cultivation surface of the planter 2 to which the lighting unit 3 is attached. There are only structures (that is, the integrated liquid supply tank 7 and support column 6), there are few obstacles when working such as leaf shoveling, pollination, harvesting, and obstacles when observing the growth status of the plant P from multiple directions. There are few things.

  For this reason, it is easy to observe daily growth of the plant P cultivated in the planter 2, and to perform management work such as sowing, transplanting, leaf cutting, pollination to flowers, and harvesting. In the cultivation of the plant P, this management work is an essential work that is frequently performed. For this reason, according to the cultivation apparatus 1, since a work burden can be reduced, the remarkable effect can be acquired on cultivation and a big benefit can be given to a user.

  Further, according to the illumination unit 3, the illumination unit 4 is supported by the support column 6, whereby one or a plurality of light sources 5 arranged in the illumination unit 4 are supported by the support column 6. Thus, by providing the light source 5 supported by the support 6, it is possible to uniformly irradiate the plant P with light for cultivation while maintaining an appropriate distance from the plant P cultivated on the planter 2. it can.

  By connecting such a lighting unit 3 to the planter 2, the plant P can be cultivated not only outdoors but also indoors.

  The lighting unit 3 includes a liquid supply tank 7, and the liquid supply tank 7 is stored in the illumination unit 4, that is, the support 6 that supports one or more light sources 5. Thus, the column 6 not only functions as a column that supports the light source 5 but also functions as a storage unit that stores the liquid supply tank 7 therein. That is, it can also be expressed that the support column 6 and the liquid supply tank 7 are arranged as a unit.

  For this reason, according to the lighting unit 3, as compared with the case where a support column for supporting the light source for cultivation appropriately separated from the plant being cultivated and a supply tank for supplying water or nutrients to the plant are provided separately, Even if the area of the planter 2 to which the lighting unit 3 is connected is small, an area for cultivating the plant P can be secured sufficiently.

  For this reason, according to the illuminating unit 3, the installation space may be small and the cultivation apparatus 1 which is space-saving and easy to work can be obtained.

  As described above, the liquid supply tank 7 and the column 6 that are integrated with each other have a configuration in which the liquid supply tank 7 is stored in the column 6, so that the liquid supply tank 7 is supported by the inner wall of the column 6. As a result, the stability of the liquid supply tank 7 is increased, and it is difficult for the liquid supply tank 7 to fall.

  Moreover, the illumination unit 3 has the liquid supply tank 7, and a culture solution is supplied to the soil of the planter 2 from the liquid supply tank 7 as needed.

  For this reason, unlike the cultivation tank of the structure which has the above-mentioned liquid-type hydroponics method, the space which accumulates a lot of culture solutions in the planter 2 beforehand is unnecessary. Also from this point, the area of the planter 2 to which the lighting unit 3 is connected can be reduced, and the installation space of the cultivation apparatus 1 can be saved.

  In this way, by configuring the cultivation device 1 using the lighting unit 3, the cultivation device 1 has the light source 5 for cultivation and, in addition, a small installation area, so that it is particularly a small space in a general household. It is possible to easily cultivate plants at home.

  An example of installation of the cultivation apparatus 1 in a general household will be described with reference to FIGS. 3 (a), (b), (c) to FIGS. 5 (a), (b).

  FIG. 3A is a diagram illustrating a state in the vicinity of the sink of a kitchen in a general household, and FIG. 3B is a diagram illustrating a side wall of a refrigerator installed in the general household.

  According to the cultivation apparatus 1, since an installation area may be small, as shown to Fig.3 (a), it distributes to the space near the sink of the kitchen about 10 cm-20 cm in depth, or it shows to Fig.3 (b). Thus, for example, it can be arranged on the side wall R of the refrigerator, where a memo or the like is often attached, or can be arranged on the side wall of a general indoor passage.

  Fig.4 (a) is a figure showing an example which distributes the cultivation apparatus 1 to the side wall of a refrigerator using the rack with a magnet, (b) is a rack with a suction cup for arranging the cultivation apparatus 1 on the side wall of a refrigerator. FIG.

  Fig.5 (a) is a front view of the rack pinned by the side wall, (b) is a side view at the time of storing the cultivation apparatus 1 in the rack of (a).

  When the cultivation apparatus 1 is arranged on the side wall of the refrigerator, a magnet is usually often attached to the side wall of the refrigerator.

  For this reason, as shown to Fig.4 (a), by storing the cultivation apparatus 1 in the rack by which the magnet was distribute | arranged to the back surface, for example, and sticking the magnet distribute | arranged to the back surface of the rack on the side wall of a refrigerator. The cultivation apparatus 1 may be arranged on the side wall of the refrigerator.

  Moreover, as shown in FIG.4 (b), by attaching a several suction cup to the side wall of a refrigerator, hanging a mesh-shaped rack with the suction cup, and storing the cultivation apparatus 1 in the suspended rack The cultivation apparatus 1 may be arranged on the side wall of the refrigerator.

  In addition, when the cultivation apparatus 1 is arranged on a wall made of a material softer than the side wall of the refrigerator, which is not attached to a magnet or a suction cup, which is seen on the side wall of a general indoor passage mentioned above, FIG. (A) As shown in (b), a net-like rack is fixed to the side wall of the passage with a plurality of pins, and the cultivation device 1 is stored in the rack so that the cultivation device 1 is arranged on the side wall of the passage. It may be.

(Connection between the illumination unit 4 and the column 6)
Next, the connection part of the illumination part 4 and the support | pillar 6 is demonstrated using Fig.6 (a) (b) (c).

  FIG. 6A is a diagram for explaining a connection portion between the illumination unit 4 and the support column 6, FIG. 6B is a side view of the illumination unit 4 of FIG. 6A, and FIG. 6C is a support column 6 of FIG. FIG.

  The illumination unit 4 is connected to the support column 6 so that the distance (height position) to the planter 2 to which the illumination unit 3 is connected can be changed.

  On the side surface 4c in the opening 4a of the illuminating unit 4, convex portions 4b and 4b that face each other and protrude toward each other are arranged.

  A switch 4d is disposed in the vicinity of the opening 4a of the illumination unit 4. The place where this switch 4d is arranged is not particularly limited. For example, the switch 4d may be arranged on the side surface of the illuminating unit 4, or the upper surface of the illuminating unit 4 (the lower surface facing the planter 2) It may be arranged on the reverse side.

  The switch 4d is interlocked with the convex portions 4b and 4b. Then, when the operator or the like depresses the switch 4d, the convex portions 4b and 4b protrude into the opening 4a from the side surface 4c or are stored in the side surface 4c.

  On the side surface of the support column 6, concave portions 6b and 6b into which the convex portions 4b and 4b can be inserted are arranged so as to face each other, and the concave portions 6b and 6b facing each other form a plurality of rows. It is arranged. In other words, a plurality of concave portions 6b are arranged in a row along the longitudinal direction (vertical direction) of the support column 6 on the side surface of the support column 6, and the two columns are arranged.

  By inserting the convex portions 4b and 4b into the concave portions 6b and 6b on the side surface of the support column 6, the illumination unit 4 and the support column 6 are fixed.

  When changing the height position of the illuminating unit 4, the switch 4d is pressed down so that the convex portions 4b and 4b protruding from the opening 4a are on the inner side of the side surface 4c (the side opposite to the side where the opening 4a is located). Store. And the distance of the illumination part 4 and the planter 2 is changed by sliding the illumination part 4 along the longitudinal direction (extension direction) of the support | pillar 6 inserted in the opening part 4a of the illumination part 4. FIG. be able to. Then, the operator presses the switch 4d when the distance between the illumination unit 4 and the planter 2 is adjusted to the optimum distance. Accordingly, the convex portions 4b and 4b protrude from the side surface 4c into the opening 4a and are inserted into the corresponding concave portions 6 and 6b. Thereby, the illumination part 4 and the support | pillar 6 are fixed.

  As described above, the height of the light source 5 arranged in the illumination unit 4 is variable along the column 6. That is, the distance between the light source 5 and the plant P cultivated in the cultivation tank 12 can be adjusted.

  Usually, if the height of the plant being grown is small, less light is required. On the other hand, the required light intensity increases as the height of the plant increases.

  Therefore, the height of the light source 5 is variable along the support column 6, so that the plant P can be irradiated from the light source 5 with an optimal amount of light according to the growth of the plant P.

  Further, the distance between the illumination unit 4 and the planter 2 can be changed by simply pressing the switch 4d and sliding the illumination unit 4 along the support column 6. Thus, since the distance can be changed by a simple operation, the cultivation apparatus 1 can be preferably used particularly for home use.

  Further, the opening 4 a of the illumination unit 4 for inserting the support column 6 is provided at the center of gravity of the illumination unit 4. And the illumination part 4 is supported by the support | pillar 6 by the support | pillar 6 being inserted in the opening part 4a provided in this gravity center part.

  For this reason, the lighting unit 3 has a good balance. In particular, by arranging the lighting unit 3 at the center of gravity of the planter 2, the cultivation apparatus 1 having a good balance as a whole can be configured. Thus, even if the area of the cultivation apparatus 1 becomes small by comprising the cultivation apparatus 1 using the illumination unit 3, it is stably, for example, FIG. 3 (a) (b)-FIG. 5 (a). It can be installed in a narrow space of a general household as described using (b). And the stability as the cultivation apparatus 1 whole can be improved by arranging the illumination unit 3 in the gravity center part of the planter 2. FIG.

  Moreover, since the opening part 4a of the illumination part 4 is provided in the gravity center position of the illumination part 4, even if it moves up and down along the support | pillar 6, as a cultivation apparatus 1, a gravity center does not move in a plane direction. Also from this point, by using the illumination unit 3, even if the installation area is reduced, the balance is not deteriorated, and the cultivation apparatus 1 that can be stably installed in a narrow space can be obtained.

[Embodiment 2]
Next, a second embodiment of the present invention will be described with reference to FIGS. 7 (a), (b), and (c) to FIGS. 17 (a) and 17 (b). For convenience of explanation, members having the same functions as those in the drawings described in the first embodiment are given the same reference numerals, and descriptions thereof are omitted.

(Configuration of cultivation apparatus 11)
First, the whole structure of the cultivation apparatus 11 is demonstrated using FIG. 7 (a)-(c) and FIG. Fig.7 (a) is sectional drawing showing the structure of the plant cultivation apparatus 11 which concerns on this Embodiment, (b) is a perspective view of the cultivation apparatus 11 of (a), (c) is (a). It is a figure showing the front-end | tip part vicinity of the liquid supply tank 17 of the cultivation apparatus 11 of.

  As illustrated in FIGS. 7A and 7B, the cultivation device 11 includes a cultivation tank (cultivation container) 12 and an illumination unit 13.

  The cultivation tank 12 includes a planting panel 12a and a cultivation tank body 12b. The lighting unit 13 includes a lighting unit 4, one or more light sources 5 arranged in the lighting unit 4, a column 16 that supports the lighting unit 4 and can store a liquid supply tank 17 therein, and a plant P. And a liquid supply tank 17 filled with a culture liquid L for supply.

  The cultivation tank 12 is a cultivation tank for hydroponics.

  The cultivation tank main body 12b is a concave container, and the entire upper surface is an opening. A culture solution L made of water or a fertilizer culture solution is stored in the cultivation tank body 12b.

  The cultivation tank main body 12b can be comprised from glass, an acryl, a metal, or a plastics, for example. In particular, the cultivation apparatus 11 can be reduced in weight by configuring the cultivation tank main body 12b from plastic or lightweight plastic.

  The planting panel 12a is arranged so as to cover the opening at the upper end of the cultivation tank main body 12b. The planting panel 12a is a holding part for holding the plant P being cultivated. A plurality of planting holes are formed in the planting panel 12a, and a plant P is arranged in each of the holes.

  The planting panel 12a is made of a waterproof and moisture permeable material. The planting panel 12a has a light shielding property. Thereby, the light from light source 5 grade | etc., Can be light-shielded, and it can prevent algae breeding with the culture solution L in the cultivation tank main body 12b. Moreover, since the planting panel 12a consists of moisture-permeable materials, oxygen supply into the cultivation tank main body 12b is possible.

  As an example of a waterproof moisture-permeable material that can be used for the planting panel 12a, Gore-Tex Fabrics manufactured by Gore-Tex Corporation, Super Hydro Breeze manufactured by Montbell Co., Ltd., and the like can be given.

  By using a waterproof moisture-permeable material for the planting panel 12a, it is possible to prevent the culture solution L from seeping out on the planting panel 12a. Moreover, oxygen can be supplied to the cultivation tank main body 12b through the planting panel 12a which is a waterproof moisture-permeable material.

  Here, when the planting panel is formed of a hydrophilic material, the culture solution that has been submerged under the planting panel oozes out on the planting panel due to its hydrophilicity, and then the panel is irradiated with light from the illumination unit. Algae can form on top.

  Such a situation can be prevented by using a waterproof and moisture permeable material for the planting panel 12a.

  The planting panel 12 a is provided with an opening for passing the liquid supply tank 17 at a position serving as the center of gravity of the cultivation tank 12. And the some plant P is mutually spaced apart and arrange | positioned around the opening part of this planting panel 12a.

  FIG. 8A is a plan view showing a cultivation tank whose planar shape is rectangular, FIG. 8B is a plan view showing a cultivation tank whose planar shape is a positive direction, and FIG. 8C is a circular planar shape. It is a top view showing the cultivation tank which is.

  The planar shape of the cultivation tank 12 is not particularly limited. For example, the cultivation tank 12 may have a rectangular shape in plan view as shown in FIG. 8 (a), or may have a square shape in plan view as shown in FIG. 8 (b). As shown in c), it may have a circular shape in plan view, or may have another shape. However, when it is assumed that the cultivation apparatus 11 is arranged in the vicinity of a sink in a narrow kitchen in the home, a rectangular shape or an elliptical shape in which the long diameter (longitudinal direction) is parallel to the opening 16a on the side surface of the support column 16 is preferable.

  Moreover, as shown to Fig.8 (a)-(c), the support | pillar 16 in which the liquid supply tank 17 was stored in the inside of the cultivation tank 12 by planar view, regardless of the shape of the cultivation tank 12 It is preferable to be arranged at the center position. Thereby, it is because the cultivation apparatus 11 with which the gravity center position was stabilized can be obtained.

  As shown in FIGS. 7A and 7B, the illumination unit 4 and the one or more light sources 5 of the cultivation apparatus 11 are the same as those described in the first embodiment.

  The support column 16 is different from the support column 6 in that the support column 16 can be fixed to the cultivation tank 12 and the bottom of the support column 16 has a cylindrical shape with the entire surface being an opening. The other structure of the column 16 is the same as that of the column 6.

  That is, in the column 16, like the column 6, the entire side wall 16h is preferably made of a light shielding member, and the upper end surface 16u of the column 16 is preferably made of a light shielding member. Note that at least a part of the side wall 16h of the support column 16 may be formed of a light shielding member.

  Similarly to the opening 6 a of the support column 6, the support column 16 has an opening 16 a formed in a part and inside of the side wall 16 h of the support column 16. The support column 16 supports the illuminating unit 4 to support the light source 5 disposed in the illuminating unit 4, and stores the liquid supply tank 17 in the opening 16 a, thereby supplying the liquid to the inside of the support column 16. The liquid tank 17 can be stored. By storing the liquid supply tank 17 inside the column 16, the column 16 and the liquid supply tank 17 are configured integrally.

  The support column 16 is connected to the illumination unit 4 in the same manner as the support column 6 described in the first embodiment. That is, a plurality of a pair of recesses into which the projections 4 b and 4 b formed in the opening 4 a of the illumination unit 4 can be inserted are arranged outside the side wall 16 h of the column 16 along the longitudinal direction of the column 16. Thereby, also in the cultivation apparatus 11, the change of the distance of the illumination part 4 and the cultivation tank 12 is possible.

  The support | pillar 16 can be fixed to the cultivation tank 12, and the fixing member which fixes each other to the at least one of the support | pillar 16 or the cultivation tank 12 is distribute | arranged. A specific configuration will be described later.

  The support column 16 is arranged at the center of gravity of the cultivation tank 12. In this Embodiment, it connects with the cultivation tank 12 in the center position of the cultivation tank 12 by planar view. Thereby, the cultivation apparatus 1 with a good balance as the cultivation apparatus 1 whole is comprised.

  As shown in FIGS. 7A to 7C, the liquid supply tank 17 includes a tank body 18 and a liquid supply adapter 19.

  The tank body 18 is the same as the tank body 7a.

  In other words, the tank main body 18 is a container that has only one opening and to which the liquid supply adapter 19 can be attached. The tank body 18 may have a capacity that can supply the culture solution L to the cultivation tank 12 for about one week.

  The only opening of the tank body 18 is a cap that matches the diameter of a general PET bottle so that a general-purpose 500 ml, 330 ml, or 475 ml bottle used for drinking water can be used as the tank body 18. Is preferably a size that can be mounted. And the liquid supply adapter 19 attached to the only opening part of this tank main body 18 is a cap which suits the diameter of a general PET bottle. The liquid supply adapter 19 is preferably compatible with, for example, one of φ28 mm diameter PCO-1810, PCO-1881-MED, PCO-1881-ISBT, or Alcoa-1716.

  Further, it is desirable that the opening 16a of the support column 16 has an opening area into which a 600 ml plastic bottle can be inserted at the maximum.

  By using a general-purpose plastic bottle that is generally used as the tank body 18, the lighting unit 13 can be obtained at a low cost and the versatility can be improved.

  The inside of the tank body 18 is filled with a culture solution L.

  The liquid supply adapter 19 is for adjusting the flow rate of the culture solution L in the tank body 18. By attaching the liquid supply adapter 19 to the opening at the tip of the tank body 18, a general-purpose PET bottle can be used as the tank body 18.

  Moreover, the liquid supply adapter 19 is arranged in the cultivation tank 12, and is also for keeping the liquid level or the amount of the liquid solution of the culture liquid L stored in the cultivation tank 12 constant. This will be described in detail later.

  The liquid supply adapter 19 includes, as an example, a rubber valve disposed in the tank main body 18, a resilient member such as a metal spring, and a valve opening body that penetrates them. The valve opening body is preferably made of a plastic rod.

  The liquid supply tank 17 is loaded inside the column 16 so that the liquid supply adapter 19 attached to the sole opening of the tank body 18 faces downward.

  Since the liquid supply tank 17 is stored in the support column 16, the side wall 16 h of the support column 16 is made of a light shielding member, so that light incident on the supply tank 17 from the light source 5 can be transmitted by the side wall 16 h of the support column 16. Can be shielded from light. For this reason, generation | occurrence | production of the algae in the liquid supply tank 17 can be prevented, using a general PET bottle as the tank main body 18. FIG.

  In the present embodiment, the liquid supply tank 17 is not supported at the lower end of the support column 16, and the vicinity of the tip portion, which is the vicinity where the liquid supply adapter 19 of the liquid supply tank 17 is loaded, is arranged in the cultivation tank 12. ing. And the upper surface (tip surface) of the liquid supply adapter 19 is in direct or indirect contact with the bottom surface in the cultivation tank 12. Thereby, the liquid supply tank 17 is supported from the lower side. The side surface of the liquid supply tank 17 is supported from the side by the side surface in the opening 16 a of the support column 16.

  Thus, the periphery of the liquid supply tank 17 is covered with the support column 16 and the cultivation tank 12. For this reason, in addition to the support | pillar 16, the cultivation tank 12 can also prevent generation | occurrence | production of algae in the liquid supply tank 17 or the cultivation tank 12 by comprising from a light-shielding material.

(Connection between support column 16 and cultivation tank 12)
Next, the structure which connects and fixes the support | pillar 16 and the cultivation tank 12 is demonstrated using FIGS. 9-12. The fixing method of the support | pillar 16 and the cultivation tank 12 can be fixed by various methods.

  FIG. 9 is a perspective view illustrating a first example in which the support column 16 and the cultivation tank 12 are fixed.

  In FIG. 9, the column 16 includes a side wall 16 h (not shown in FIG. 9) and a column body 16 b in which an opening 16 a (not shown in FIG. 9) is formed, and a lower end (cultivation tank 12) of the column body 16 b. And the insertion members 16c and 16c having protrusions, which are arranged on the end portion on the side in contact with the projection. The insertion members 16c and 16c are arranged to face each other. And the protrusion part distribute | arranged to each of insertion member 16c * 16c is distribute | arranged so that it may protrude on the opposite side mutually.

  On the other hand, as for the cultivation tank 12 to which the support | pillar 16 with which insertion member 16c * 16c was arrange | positioned is connected, the handle 12c * 12c which is a member to be inserted is arranged on the upper surface of the cultivation tank main body 12b. Each of the handles 12c and 12c is formed with an opening having a size capable of inserting the protrusions of the insertion members 16c and 16c. And the handle 12c12c is mutually opposed and is distribute | arranged to the center part of the long side of the cultivation tank 12, respectively.

  As described above, in FIG. 9, the fixing member includes the insertion members 16 c and 16 c and the handles 12 c and 12 c.

  And while the lower end of the support | pillar 16 contact | abuts the upper surface of the cultivation tank main body 12b, each projection part of insertion member 16c * 16c is inserted in each opening part of the handle 12c * 12c.

  In this way, the support column 16 and the cultivation tank 12 can be fixed.

  FIGS. 10A to 10C are diagrams illustrating a second example of fixing the support column 16 and the cultivation tank 12, and FIG. 10A is a diagram illustrating the front of the catch clip arranged on the support column. And (b) is a view showing the side surface of the catch clip of (a), and (c) is a perspective view showing the cultivation tank 12 in which a catch member for the catch clip is arranged.

  10 (a) and 10 (b), the column 16 includes a column main body 16b having an opening 16a formed on the side surface and inside, and catch clips 16d and 16d disposed on the side surface near the lower end of the column main body 16b. Have. The catch clips 16d and 16d are arranged to face each other.

  On the other hand, as shown in FIG. 10 (c), in the cultivation tank 12 to which the support column 16 on which the catch clips 16d and 16d are arranged is connected, the receiver members 12d and 12d are arranged on the outer side surface in the vicinity of the upper surface of the cultivation tank body 12b. Has been. Each of the receiver members 12c and 12c is arranged opposite to each other at the central portion of the long side of the cultivation tank 12.

  As described above, in FIGS. 10A to 10C, the fixing member includes the catch clips 16d and 16d and the receiver members 12c and 12c.

  Thereby, while the lower end of the support | pillar 16 contact | abuts with the upper surface of the cultivation tank main body 12b, each catch clip 16d * 16d is hooked by each receiver member 12c * 12c.

  In this way, the support column 16 and the cultivation tank 12 can be fixed.

  Fig.11 (a) is a side view of the catch clip showing another example, (b) is a front view of the catch clip of (a).

  The catch clip is not limited to the configuration shown in FIGS. 10A and 10B, and various configurations can be used. Another example is a catch clip 16e as shown in FIGS. 11 (a) and 11 (b).

  FIG. 12 is a perspective view for explaining a third example for fixing the support column 16 and the cultivation tank 12.

  The support column 16 shown in FIG. 12 is different from the support column 16 shown in FIGS. 9, 10 (a) and 10 (b), and no other fixing member is arranged on the support column 16 (support column body). However, the column 16 in FIG. 12 is configured such that the diameter of the column 16 is longer than the length in the short direction in the direction intersecting the longitudinal direction of the cultivation tank 12.

  On the other hand, in the cultivation tank 12 to which the support column 16 is connected, a slit made of four recesses 12f, 12f, 12f, and 12f is formed on the upper surface of the cultivation tank body 12b.

  Concave portions 12f and 12f are formed on the upper surface of one long side so as to be a target with respect to the center of the long side of the cultivation tank main body 12b. The recesses 12f and 12f are also formed on the upper surface of the other long side so as to be opposed to the recesses 12f and 12 with respect to the center.

  The support column 16 and the cultivation tank 12 are fixed by inserting the lower end of the support column 16 into the slit formed by the four recesses 12f, 12f, 12f, and 12f.

  In FIG. 12, it can be expressed that the vicinity of the lower end portion of the support column 16 and the slit formed of the four recesses 12f, 12f, 12f, and 12f are fixing members.

  In addition, the structure of the fixing member for fixing the support | pillar 16 demonstrated using FIGS. 9-12 and the cultivation tank 12 is an example, and may be other than the structure quoted above.

(Operation of liquid supply adapter 19)
Next, as shown to Fig.13 (a)-(d), operation | movement of the liquid supply adapter 19 for keeping the liquid level in the cultivation tank 12 constant is demonstrated.

  FIG. 13A is a diagram illustrating a state in which the liquid supply adapter 19 is mounted, FIG. 13B is a diagram illustrating a state in which the valve of the liquid supply adapter 19 is closed, and FIG. It is a figure showing a mode that the culture solution L is supplied to the cultivation tank 12, (d) is a figure showing the state which the supply of the culture solution L from the tank main body 18 to the cultivation tank 12 stopped.

  As shown in FIGS. 13 (a) and 13 (b), the liquid supply adapter 19 includes a cap 19a having an opening for attachment to the cultivation tank 12, a valve 19b made of rubber, etc., and a spring made of a metal spring or the like. A member 19c and a valve opening body 19d penetrating the valve 10b and the resilient member 19c are provided.

  The cap 19 a is for attaching the liquid supply adapter 19 to the tank body 18 by engaging with the tip of the tank body 18.

  The valve 19b, the resilient member 19c, and the valve opening body 19d are disposed in the cap 19a. The valve 19b, the resilient member 19c, and the valve opening body 19d are arranged in the opening of the front end of the tank main body 18 when the cap 19a is attached to the front end of the tank main body 18. The valve 19b is arranged on the inner side of the tank body 18 from the resilient member 19c.

  When the valve opening 19d is not pushed from the outside, the opening of the tank body 18 is closed and the inside of the tank body 18 is sealed by the valve 19b as shown in FIG. 13 (b). Thereby, the culture solution L in the tank main body 18 does not leak outside.

  And as shown in FIG.13 (c), the valve opening body 19d is pushed by the projection part 15 because the projection part 15 provided in the bottom face in the cultivation tank 12, for example is inserted in the opening part of the cap 19a. Then, the valve 19b is opened and the external atmosphere flows into the tank body 18. As long as this external air flows into the tank body 18, the culture solution L in the tank body 18 leaks out to the cultivation tank 12.

  Next, when a certain culture solution L accumulates in the cultivation tank 12 and the liquid level of the culture solution L in the cultivation tank 12 rises until the cap 19a is immersed, as shown in FIG. The height of the opening is also lower than the liquid level of the culture solution L in the cultivation tank 12, and the inflow of air into the tank body 18 stops even when the valve 10b is open. Thereby, leakage of the culture solution L from the tank main body 18 to the cultivation tank 12 stops.

  If the liquid level in the cultivation tank 12 falls and the opening part of the front end surface of the cap 19a becomes higher, as shown in FIG.13 (c) (d), the liquid level in the cultivation tank 12 will be the cap 19a. The culture liquid L from the tank body 18 to the cultivation tank 12 leaks out until it becomes higher than the height of the opening on the tip surface.

  Thus, the liquid supply tank 17 includes the liquid supply adapter 19 for keeping the liquid level of the culture liquid L in the cultivation tank 12 constant. Thereby, since the liquid level of the culture solution L in the cultivation tank 12 can be kept constant, the plant P can be cultivated stably.

  In addition, the structure of the liquid supply tank 17 for keeping the liquid level in the cultivation tank 12 constant is not limited to this, and any liquid supply tank that can supply the cultivation tank 12 with a constant interval or a constant amount of the culture liquid L can be used. Good.

(Main advantages of cultivation device 11)
Next, the main advantages of the cultivation apparatus 11 will be described with reference to FIGS. 7A to 7C and FIGS. 14 to 17A and 17B.

  As described with reference to FIGS. 7A to 7C and the like, the cultivation apparatus 11 is mainly divided into (i) a supply tank 17 stored in a column 16 that supports the light source 5. And (ii) a structure in which the support column 16 in which the liquid supply tank 17 is stored is arranged at the center of gravity of the cultivation tank 12. Hereinafter, the advantages of these configurations will be described in particular.

  As described above, according to the cultivation device 11, the liquid supply tank 17 is provided, and the liquid supply tank 17 is stored in the illumination unit 4, that is, the support column 16 that supports one or a plurality of light sources 5. That is, the column 16 functions as a column that supports the light source 5 and also functions as a storage unit that stores the liquid supply tank 7 therein. In other words, it can be expressed that the support column 16 and the liquid supply tank 17 are arranged as a single unit.

  For this reason, according to the cultivation apparatus 11, the light source 5 is supported by the support | pillar 6 by the illumination part 4 being supported by the support | pillar 6. FIG. Thereby, the light for cultivation can be irradiated to the plant P from the light source 5. FIG.

  And according to the cultivation apparatus 11, since the liquid supply tank 17 is stored inside the support | pillar 16, compared with the case where the support | pillar which supports the light source and the liquid supply tank filled with the liquid supplied to a plant are provided separately. And even if the area of the cultivation tank 12 is small, the area for cultivating the plant P is fully securable.

  That is, according to the cultivation apparatus 11, an installation space may be small and can also be installed especially in the narrow space of a general household.

  Specifically, as described with reference to FIGS. 3A, 3B, 5A, and 5B, a narrow space having a depth of about 10 cm to 20 cm in the vicinity of a sink of a general household kitchen, a refrigerator, and the like It can be hung on a wall such as a side wall of a passage or a side wall of a passage.

  Furthermore, when it is difficult to overturn such a narrow space and the cultivation apparatus is arranged, in addition to reducing the installation area, it is necessary to reduce the width of the apparatus and at the same time have high stability. In addition, when the cultivation apparatus is stably placed on the wall, it is necessary to have high stability and light weight in addition to reducing the installation area.

  In addition, the ease of management of the cultivation device is also an important issue for easily growing plants at home.

  The cultivation apparatus 11 according to the present embodiment can sufficiently solve these problems. Hereinafter, it will be described in order.

  FIG. 14 is a cross-sectional view showing a configuration of a general liquid-type device.

  For example, it is necessary to store a sufficient culture solution 400L in the cultivation tank 412 in a general drenched device 401 including an aero garden (trade name) and the like. For this reason, when it distributes to a general household, a problem arises in the point of lightweight.

  Moreover, it is necessary to determine the position of the liquid level in the cultivation tank 412 indirectly using a float or the like to prevent drought.

  And if the liquid level falls, the submerged range of the roots of the plant 400P will change, so the cultivation conditions will change little by little.

  On the other hand, the cultivation apparatus 11 includes a replaceable liquid supply tank 17. For this reason, it is not necessary to always store a large amount of the culture solution 400L as in the case of the dripping type apparatus 401, and the volume of the culture solution L stored in the cultivation tank 12 can be reduced. For this reason, it can be reduced in weight.

  In the cultivation apparatus 11, a general plastic bottle can be used as the tank body 18 by attaching the liquid supply adapter 19 to the opening of the tank body 18.

  Here, since the liquid supply tank 17, particularly the tank body 18, is contaminated by the culture solution L, it is necessary to prepare a replacement tank in order to use the cultivation apparatus 11 for a long period of time. That is, the tank body 18 is a consumable item. Establishing such a supply system for consumables is costly for the manufacturer of the cultivation apparatus 11. Moreover, a running cost will be applied also to the user who uses the cultivation apparatus 11.

  However, since the cultivation apparatus 11 can use a general-purpose plastic bottle as the tank body 18, there is no need to supply the tank body 18 as a member from the manufacture and distributor side of the cultivation apparatus 11, and the member cost is reduced. Can be reduced. On the other hand, since the user who uses the cultivation apparatus 11 can use a PET bottle which is a general-purpose product as the tank body 18, the tank body 18 can be obtained at a low cost. For this reason, versatility is high and the tank body 18 can be easily replaced.

  In particular, by using a general 500 ml PET bottle as the tank main body 18, it is possible to configure the light cultivation device 11.

  In addition, generally, commercially available PET bottles are at least partially transparent, and many of them can visually recognize the amount of liquid filled therein.

  For this reason, the use of a plastic bottle that is at least partially transparent, which is generally commercially available, as the tank body 18 is not only highly versatile, but also leaves the culture medium L in the tank body 18. Since the amount can be confirmed, the supply timing of the culture solution L to the tank body 18 can also be easily and directly determined.

  In the cultivation apparatus 11, the liquid level of the culture liquid L in the cultivation tank 12 can be kept constant at a position lower than the liquid level in the cultivation tank 412 by the liquid supply adapter 19 provided in the liquid supply tank 17. it can.

  For this reason, the relationship between the root of the plant P and the liquid level of the culture solution L hardly changes, and the plant P can be cultivated with a certain quality.

  As described above, the cultivation apparatus 11 has an advantage at least in terms of lightness and simplicity as compared with the dripping apparatus 401.

  Next, some advantages of the structure in which the support column 16 in which the liquid supply tank 17 is stored are arranged at the center of gravity of the cultivation tank 12 will be described.

  As shown to Fig.15 (a) (b), the subject in case the gravity center is biased as the whole apparatus is assumed by arrange | positioning the liquid supply tank in the position shifted | deviated from the gravity center position of the cultivation tank.

  15 (a) and 15 (b) schematically represent a cultivation apparatus in which a liquid supply tank is present at one end, (a) is a diagram illustrating a cultivation apparatus when the liquid level in the liquid supply tank is high, (B) is a figure showing the case where the liquid level in a liquid supply tank is low.

  So far, for example, as in Patent Documents 3 and 4 disclosing the above-described automatic water supply planter, a technique for supplying liquid to the cultivation tank by making the liquid level constant while using the liquid supply tank is disclosed. The application was seen. However, many of the cultivation apparatuses disclosed in such an application have a configuration in which a liquid supply tank is disposed in the vicinity of one end of the cultivation tank.

  Since the cultivation apparatus disclosed in these applications is assumed to be installed outdoors, it is not assumed that the lighting apparatus is attached. In addition, problems such as the concentration of the culture solution are not considered. Concerning the concentration of the culture solution, the configuration described in Patent Document 5 can also solve the problem, but it is necessary to form an annular tank with a special shape, or to create a separate support column when illuminated. Issues such as not becoming necessary remain. In addition to the liquid supply tank, if a cultivation device with a lighting device is assumed, at least one column for mounting the lighting device is necessarily required. When a plurality of facilities such as tanks and support columns exist in the vicinity of the plant cultivation section, the difficulty of accessing plants, which has not been a problem until now, arises as a new problem.

  Therefore, in the present application, in the configuration of the cultivation apparatus having a tank and a lighting device, these facilities that are present so as to surround the cultivation unit are arranged in the center, and these problems newly emerged. Can be solved. That is, it can be created with a small number of parts, access to the plants around the liquid supply tank is easy, and the concentration of the culture solution is hardly generated.

  The cultivation apparatus 501 shown to Fig.15 (a) (b) is also the structure by which the liquid supply tank was distribute | arranged to such one side.

  As shown to Fig.15 (a) (b), as for the cultivation apparatus 501, the culture solution 500L is stored in the cultivation tank 512, and the some plant 500P is cultivated by hydroponics. An illumination unit 504 provided with a light source for illuminating the plant 500P with light for cultivation is supported by the support column 516 and disposed in the cultivation tank 512.

  In the cultivation tank 512, a liquid supply tank 517 filled with a culture solution 500 L to be supplied into the cultivation tank 512 is disposed at a position different from the column 516. The liquid supply tank 517 is disposed on the upper surface of the cultivation tank 512 and in the vicinity of one end (the left end on the paper surface).

  And the support | pillar 516 which supports the illumination part 504, and the cultivation area | region for cultivating the plant 500P are centered when the cultivation apparatus 501 is seen from the front, in order to avoid the liquid supply tank 517 put into this left end part vicinity. Further, the liquid supply tank 517 is arranged so as to be shifted to the opposite side (that is, the right side of the drawing).

  Thus, in the cultivation apparatus 501, since the liquid supply tank 517 is arranged in the vicinity of the end on the left side of the paper, when the amount of the culture solution 500L filled in the liquid supply tank 517 is large, FIG. As shown in the center of gravity position A1 in (a), the center of gravity position A1 of the entire cultivation apparatus 501 is inclined to the left side of the drawing surface, which is the vicinity of the liquid supply tank 517. For this reason, as shown by the arrow B, when the cultivation apparatus 501 is viewed from the front side, a moment is generated counterclockwise, and it is easy to fall.

  On the other hand, when the liquid volume of the culture liquid 500L filled in the liquid supply tank 517 decreases, the cultivation apparatus corresponds to the decrease in the liquid volume, as shown at the center of gravity position A2 in FIG. The center of gravity position A2 of the whole 501 moves to the right side of the drawing, which is the opposite side (distant side) of the liquid supply tank 517. For this reason, as shown by the arrow C, when the cultivation apparatus 501 is viewed from the front side, a moment is generated in the clockwise direction, and in this case, it is easy to fall.

  In either case, if the center of gravity is not in the center, a moment is generated, and it is easy to fall over.

  Further, the cultivation apparatus 501 can be said to be an unstable and easy to fall structure because the center of gravity position A1 and A2 on the plane changes depending on the remaining amount of the liquid supply tank 517 and the moment generated in each state changes.

  On the other hand, in the cultivation apparatus 11 according to the present embodiment, the support column 16 in which the liquid supply tank 17 is stored is arranged at the center position of the cultivation tank 12 in plan view.

  It can be said that the liquid supply tank 17 is a member whose weight is easily changed depending on the amount of the culture liquid L filled therein. Such a liquid supply tank 17 is stored in the inside of the support | pillar 16, Furthermore, the center position where the support | pillar 16 is distribute | arranged is arranged by arranging the support | pillar 16 in the center position of the cultivation tank 12 by planar view. The center of gravity of the cultivation tank 12 can be set. For this reason, even if the amount of the culture liquid L in the liquid supply tank 17 changes, the position of the center of gravity of the cultivation apparatus 11 with little movement in the plane direction (the plane direction perpendicular to the extending direction of the support column 16) is small. Can be configured.

  As a result, since the generation of moment can be prevented, the cultivation apparatus 11 that is stable and hardly falls can be obtained. Thereby, the cultivation apparatus 11 can be stably mounted in a small space, or can be arranged by wall hanging. That is, it is possible to obtain the cultivation device 11 that does not easily fall even when the installation space is reduced.

  In addition, since the cultivation apparatus 11 has fixed the support | pillar 16 and the cultivation tank 12 as demonstrated using FIGS. 9-12, it has integrity and uses the cultivation apparatus 11 more stably. It can be placed in a narrow space or placed by wall hanging.

  And since the liquid supply tank 17 is stored in the inside of the support | pillar 16 fixed to the cultivation tank 12, it is supported by the inner wall of the support | pillar 16, and stability of the liquid supply tank 17 increases. As a result, it is possible to obtain the cultivation device 11 that does not easily fall over.

  And the liquid supply tank 17 is stored in the inside of the support | pillar 16 currently fixed with the cultivation tank 12. FIG. For this reason, in addition to being able to save the space for installing both the support column 16 and the liquid supply tank 17 in the cultivation tank 12, the liquid supply tank 17 is supported by the inner wall of the support column 16, thereby supplying water. The stability of the liquid tank 17 can be improved and the liquid supply tank 17 alone can be prevented from falling. For this reason, as described with reference to FIGS. 3A, 3B, 5A, and 5B, a narrow space in the vicinity of a sink of a general household kitchen having a depth of about 10 cm to 20 cm, or a side wall of the refrigerator Or, it can be installed stably on a wall such as a side wall of a passage.

  Since the center of gravity of the cultivation apparatus 11 is stable, the side wall of the refrigerator as described with reference to FIGS. 3B, 4A, 4B, and 5A, 5B in particular. It is suitable when cultivating the plant P over the wall.

  Moreover, according to the cultivation apparatus 11, since the gravity center is stable and the support | pillar 16 and the cultivation tank 12 are being fixed, it is not limited to the structure to mount, For example, a string etc. are attached to the illumination part 4. It is good also as a structure suspended from a ceiling or the like. Thereby, the choice of the installation place in a general household can be expanded.

  FIG. 16A is a diagram illustrating the state of the culture solution concentration of the cultivation apparatus in which the liquid supply tank exists at one end, and FIG. 16B illustrates the state of the culture solution concentration of the cultivation apparatus according to the second embodiment. FIG.

  Here, in the configuration in which the culture solution is supplied from the supply tank to the cultivation tank, the concentration of the culture solution in the cultivation tank is usually increased in the vicinity where the supply tank is connected, and the culture solution is separated from the supply tank. As the concentration decreases.

  Moreover, as shown to Fig.16 (a), since the liquid supply tank 517 is attached to the paper surface left end part of the cultivation tank 512, the culture solution 500L in the cultivation tank 512 is the left end of the paper surface. The portion becomes darker and becomes thinner at the right side edge of the paper, which is the opposite edge. And in this way, in the cultivation apparatus 501, since the liquid supply tank 517 is arranged near one end part, the culture solution 500L in the cultivation tank 512 is on the side where the liquid supply tank 517 is arranged. The distance between the end and the opposite end is long, and the density difference becomes large.

  On the other hand, in the cultivation apparatus 11, the support | pillar 16 in which the liquid supply tank 17 is stored is distribute | arranged to the center position when the cultivation tank 12 is planarly viewed. For this reason, the liquid supply tank 17 is also arranged at the central position when the cultivation tank 12 is viewed in plan, and the culture liquid L is supplied into the cultivation tank 12 radially from this central position.

  Thus, according to the cultivation apparatus 11, as shown in FIG.16 (b), the position where the liquid supply tank 17 which is the center part of the cultivation tank 12 is distribute | arranged in the cultivation tank 12, and the cultivation tank 12 Since the distance from the position farthest from the position where the liquid supply tank 17 that is the end of the plant is disposed is shorter than that of the cultivation apparatus 501, the difference in the concentration of the culture liquid L in the cultivation tank 12 is small. The culture solution L can be supplied to the plant P with a uniform concentration. For this reason, it is possible to cultivate the plant P while suppressing a certain quality variation. That is, the nutrient of the culture solution L supplied from the liquid supply tank 17 can be uniformly applied to the surrounding plants P, and the cultivation speed of the plants P can be unified.

  Furthermore, according to the structure of the cultivation apparatus 11, since the support | pillar 16 in which the liquid supply tank 17 is stored has the structure distribute | arranged to the center position when the cultivation tank 12 is planarly viewed, it is growing. It is also possible to obtain an effect of preventing an adverse effect due to the close distance between plants and an allelopath (an allergic effect) caused by the plant species to be cultivated.

  As described in Non-Patent Document 3, for example, cabbage seedlings, etc., depending on the plant species, when densely planted, leaves between strains overlap, and each photosynthesis is inhibited or falls by interaction Has been reported.

  For example, in the cultivation apparatus 501 shown in FIGS. 15A and 15B, since the liquid supply tank 517 is arranged near one end of the cultivation tank 512, a plurality of arrangements are performed in the cultivation tank 512. The plant 500P is arranged adjacent to a region where the liquid supply tank 517 is not arranged. For this reason, in the cultivation apparatus 501, each leaf of the some plant 500P currently grown is overlapped, and the irradiation area of the light from the illumination part 504 to each leaf is inhibited. Moreover, since the distance between the plants 500P is short, the roots of each other are entangled with each other.

  Furthermore, when the leaves of each of the plurality of plants 500P come into contact with each other, depending on the plant species, allelopathy may occur, which may adversely affect each other's growth.

  On the other hand, according to the cultivation apparatus 11, since the support | pillar 16 in which the liquid supply tank 17 was stored is distribute | arranged to the center part of the cultivation tank 12 by planar view, in width | variety of the support | pillar 16 at least in the cultivation tank 12, The cultivation area | region which isolate | separates and cultivates the plant P can be ensured.

  Thus, when the cultivation density with respect to the same floor area of a cultivation apparatus is considered, the direction of the cultivation apparatus 11 is cultivated compared with the cultivation apparatus which distributes a liquid supply tank and a support | pillar in the vicinity of the side surface of a cultivation tank, or its circumference | surroundings. The plant P strains that are in contact with each other can be separated from each other to increase the spacing between the plant P strains.

  As a result, according to the cultivation apparatus 11, since the distance between the plurality of cultivated plants P can be separated, the harmful effects due to the close distance between the cultivated plants are prevented, and the plurality of plants P is cultivated. can do.

  In addition, it is not essential that the distance between the plurality of plants P cultivated by the cultivating apparatus 11 is separated. Depending on the plant species, there are also plants in which allelopathy does not occur and the harmful effects caused by the short distance of cultivation are not a problem. When cultivating such a plant P with the cultivation apparatus 11, you may make it cultivate several plants P in the cultivation tank 12 adjacent to each other so that leaves may overlap.

  15A and 15B and FIGS. 16A and 16B, the illumination unit 504 is supported by the support column 516, and the liquid supply tank is located on one end side. The problem of the approaching cultivation apparatus 501 has been described.

  Next, using FIG. 17A and FIG. 17B, similarly to the configuration described in Patent Document 6, the lighting unit is supported by the cultivation apparatus in which the liquid supply tank is provided around the plant being cultivated. The problem in attaching a support | pillar is demonstrated.

  Fig. 17 (a) is a diagram assuming a case where a column supporting a lighting unit is attached to a cultivation apparatus in which a liquid supply tank is arranged around the cultivation plant, and Fig. 17 (b) is a diagram of the cultivation plant. It is a figure which assumes the case where the support | pillar which supports an illumination part is attached to the circumference | surroundings of a cultivation plant to the cultivation apparatus by which the liquid supply tank is distribute | arranged around.

  As shown to Fig.17 (a), in the structure by which the liquid supply tank 612 filled with the culture solution for supplying to a cultivation tank is arranged so that the circumference | surroundings of the flowerpot 600P where the plant is grown may be enclosed, A case is assumed where the lower end of the column 616 that supports the illumination unit 604 provided with the light source 605 at the upper end is arranged. Since the center of gravity of this configuration is the center, when the lower end of the support column 616 is arranged in the area surrounded by the liquid supply tank 612, that is, near the center of the flower pot 600P, a problem that becomes an obstacle to cultivation occurs. That is, the subject that the cultivation area of a plant will reduce arises.

  Or as shown in FIG.17 (b), the light source has the structure where the liquid supply tank 612 filled with the culture solution for supplying to the cultivation tank is arranged around the flower pot 600P where the plant is cultivated. When the lower ends of each of the support columns 616a and 616b that support the illumination unit 604 with the plurality of control units 605 are arranged, the access is made such that the plurality of support columns 616a and 616b are obstructing and the central pot 600P is difficult to take out. There arises a problem that it is difficult to remove.

  Further, the liquid supply tank 612 having a special shape surrounding the flower pot 600P is difficult to clean inside, and there is a problem that the device management is not easy.

  On the other hand, in the cultivation apparatus 11 according to the present embodiment, a liquid supply tank 17 is stored inside a support column 16, and this support column 16 is arranged at the center of the cultivation tank 12 in a plan view. Thereby, centering on the support | pillar 16, several plants P can be distribute | arranged to the circumference | surroundings and can be cultivated.

  For this reason, the center of gravity position is set as the center position of the cultivation apparatus 11, the cultivation apparatus 11 can be stabilized, and the plant P being cultivated can be easily accessed and management can be facilitated.

  Moreover, since the plant P should just be distribute | arranged to the circumference | surroundings of the support | pillar 16, even when cultivating several plants P, sufficient area for cultivation can be ensured. For this reason, according to the cultivation apparatus 11, since the cultivation area of the plant P can fully be ensured even if thinness (depth) is made thin, the thin (small depth) cultivation apparatus 11 can be obtained.

  Furthermore, the cultivation apparatus 11 should just use the container of the magnitude | size which can be stored in the inside of the support | pillar 16 as the liquid supply tank 17, for example, by using the plastic bottle which is a general purpose product for the liquid supply tank 17, it is cheap. Therefore, it has an advantage that the device management is easy.

[Embodiment 3]
Next, a third embodiment of the present invention will be described with reference to FIGS. 18, 19A and 19B. For convenience of explanation, members having the same functions as those in the drawings described in the first and second embodiments are denoted by the same reference numerals and description thereof is omitted.

  FIG. 18: is sectional drawing showing the structure of the plant cultivation apparatus 21 which concerns on this Embodiment. Fig.19 (a) is a front view showing the structure of the support | pillar 26 and the illumination part of the cultivation apparatus 21 which concerns on this Embodiment, (b) is a side view of the support | pillar 26 and illumination part shown to (a).

  The cultivating apparatus 21 is different from the cultivating apparatus 11 in that it includes a support 26 instead of the support 16. Other configurations of the cultivation device 21 are the same as those of the cultivation device 11.

  The column 26 includes an external pipe 27, an internal pipe 28, a joint 24, and a pipe length control unit 25. The support column 26 is configured to have a variable length in the longitudinal direction.

  In the external pipe 27, the upper end side of the internal pipe 28 is inserted into the external pipe 27 from the lower end side. The lower end of the internal pipe 28 is connected to the cultivation tank 12.

  The upper end side of the external pipe 27 is connected to the illumination unit 4 by being inserted into the opening 4 a of the illumination unit 4 in the same manner as the support column 16.

  Although not shown, a pair of recesses into which the projections 4b and 4b formed in the opening 4a of the illuminating unit 4 can be inserted are formed on the outside of the side surface of the external pipe 27, like the support columns 6 and 16. A plurality of lamps are arranged along the longitudinal direction of the lamp 27, whereby the illumination unit 4 can move up and down along the external pipe 27.

  On the front side surface and inside of the external pipe 27 and the internal pipe 28, an opening 26a having a size that can store the liquid supply tank 17 in the column 26 is formed.

  Thereby, the support | pillar 26 becomes a structure which can store the liquid supply tank 17 inside while supporting the illumination part 4. FIG.

  The joint 24 is an outer side surface on the back surface side of the internal pipe 28, and is fixed and arranged in parallel with the internal pipe 28. In the joint 24, a plurality of holes are formed in a row in the longitudinal direction. The joint 24 is inserted into the external pipe 27 together with the internal pipe 28.

  The pipe length control unit 25 is urged by a resilient member or the like so as to protrude from the outer side surface on the back side of the external pipe 27 and engage with any of the holes of the joint 24 inside the external pipe 27. .

  In the normal state, the pipe length control unit 25 is fixed inside the external pipe 27 by engaging with the hole of the joint 24. Thereby, the external pipe 27 and the internal pipe 28 are fixed.

  When the projecting portion of the pipe length control unit 25 from the external pipe 27 is pressed by an operator or the like, the engagement between the pipe length control unit 25 and the hole of the joint 24 in the external pipe 27 is released. The As a result, the internal pipe 28 can slide inside the external pipe 27, and the length of the column 26 can be arbitrarily changed.

  When the column 26 is set to an arbitrary length by the operator and the pressing of the pipe length control unit 25 is released, the pipe length control unit 25 and the corresponding position of the joint 24 are located inside the external pipe 27. The holes engage with each other, and the external pipe 27 and the internal pipe 28 are fixed again.

  Thus, according to the cultivation apparatus 21, the length of the support | pillar 26 is variable and can be fixed to arbitrary positions. As a result, the height of the light source 5 is variable along the column 26.

  Thereby, the distance between the light source 5 and the plant P cultivated in the cultivation tank 12 can be adjusted, and the plant P can be illuminated from the light source 5 with an optimal amount of light according to the growth of the plant P.

  As a mechanism for adjusting the length of the column 26 by sliding the external pipe 27 and the internal pipe 28 as described above, for example, a vacuum cleaner such as EC-AX100 (product name: manufactured by Sharp Corporation) is used. You may implement | achieve by applying the mechanism currently used.

  Further, the internal pipe 28 and the joint 24 may be configured so that the height position of the illumination unit 4 can be arbitrarily changed and fixed. The structure which provided the some hole of the joint 24 in 28 itself may be sufficient.

[Embodiment 4]
Next, a fourth embodiment of the present invention will be described with reference to FIGS. For convenience of explanation, members having the same functions as those in the drawings described in the first to third embodiments are denoted by the same reference numerals and description thereof is omitted.

  FIG. 20 is a cross-sectional view illustrating a configuration of a plant cultivation apparatus 31 according to the present embodiment. Fig.21 (a) is a front view showing the structure of the support | pillar 36 and the illumination part 34 of the cultivation apparatus 31 which concerns on this Embodiment, (b) is a side view of the support | pillar 36 shown to (a). FIG. 22 is a diagram illustrating a state where the support column 36 and the illumination unit 34 of the cultivation apparatus 31 according to the present embodiment are fixed.

  As shown in FIG. 20, the cultivation apparatus 31 is different from the cultivation apparatus 11 in that it includes a column 36 instead of the column 16 and includes an illumination unit 34 instead of the illumination unit 4. Other configurations of the cultivation device 31 are the same as those of the cultivation device 11.

  An opening 36 a in which the liquid supply tank 17 can be stored is formed in the front and inside of the column 36. The column 36 supports the illumination unit 34 in the vicinity of the upper end, and the liquid supply tank 17 is stored in the opening 36a.

  Here, in the cultivation apparatus 11, the illumination unit 4 is provided with the switch 4 d and the projections 4 b and 4 b arranged in the illumination unit 4 and the plurality of depressions 6 b and 6 b arranged in the column 6. It was the structure which can be slid along 6 and fixed.

  On the other hand, in the cultivation apparatus 31, as shown in FIGS. 21A and 21B, the outer side surface of the support column 36 has a screw shape, and is provided at the center position of the illumination unit 34, that is, at the center of gravity of the illumination unit 34. The opening 34 a has a screw hole shape corresponding to the screw shape of the column 36.

  The illumination unit 34 is not provided with the switch 4d. Although not shown in FIG. 21A, the point that one or a plurality of light sources 5 are arranged in the illumination unit 34 is the same as that of the illumination unit 4.

  And in the cultivation apparatus 31, the illumination part 34 can be moved along the support | pillar 36 by rotating the illumination part 34 and the support | pillar 36 inserted in the opening part 34a relatively. Thereby, the height of the light source 5 is variable along the column 36.

  For this reason, the distance between the light source 5 and the plant P cultivated in the cultivation tank 12 can be adjusted, and the plant P can be illuminated from the light source 5 with an optimal amount of light according to the growth of the plant P.

  In addition, according to the cultivation apparatus 31, since the switch 4d, the member which operates the convex part 4b * 4b, etc. are unnecessary compared with the cultivation apparatus 11, a number of parts can be decreased and it becomes difficult to damage. it can.

  Further, as shown in FIG. 22, the illumination unit 34 and the support column 36 may be sandwiched and stopped by a clip 37. Thereby, the illumination part 34 and the support | pillar 36 can be fixed reliably.

  Although not shown, it is preferable that the upper end surface of the support column 36 is covered and covered with a light shielding member, like the upper end surface 16u. This is to prevent the generation of algae in the liquid supply tank 17.

[Embodiment 5]
Next, a fifth embodiment of the present invention will be described with reference to FIGS. For convenience of explanation, members having the same functions as those in the drawings described in the first to fourth embodiments are denoted by the same reference numerals and description thereof is omitted.

  FIG. 23 is a cross-sectional view illustrating a configuration of a plant cultivation apparatus 41 according to the present embodiment. FIG. 24 is a diagram illustrating a state where the lid 46 is attached to the opening 16 a of the support column 16.

  The cultivation device 41 has a configuration including the cultivation device 11 described in the second embodiment and a lid 46.

  The lid 46 has a configuration that can be attached to and detached from the opening 16 a of the support column 16. The lid 46 is fixed to the support column 16 by being attached to the opening 16 a of the support column 16. The method for fixing the lid 46 and the opening 16a of the support column 16 is not particularly limited. For example, a configuration in which a peripheral portion surrounding the opening 16a on the side wall of the support column 16 has a shape that allows the cover 46 to be fitted therein. Can be mentioned.

  The lid 46 can be made of, for example, glass, acrylic, metal, plastic, or the like, like the support columns 6 and 16. In particular, the entire cultivation apparatus 41 can be reduced in weight by configuring the lid 46 from plastic or lightweight plastic.

  Moreover, it is preferable to comprise both the support | pillar 16 and the lid | cover 46 from the light shielding member.

  By attaching the lid 46 to the opening 16 a of the support column 16, the liquid supply tank 17 stored in the support column 16 is completely shielded from light by being completely surrounded by the side wall of the support column 16 and the cover 46. The For this reason, the deterioration of the culture solution L in the liquid supply tank and the generation of algae in the liquid supply tank 17 due to the external light and the light from the light source 5 being irradiated to the liquid supply tank 17 are more reliably performed. Can be prevented.

[Embodiment 6]
Next, a sixth embodiment of the present invention will be described with reference to FIGS. For convenience of explanation, members having the same functions as those in the drawings described in the first to fifth embodiments are denoted by the same reference numerals and description thereof is omitted.

  FIG. 25 is a cross-sectional view illustrating a configuration of a plant cultivation apparatus 51 according to the present embodiment. Fig.26 (a) is a figure showing a mode that the cover 56 is attached to the opening part 16a of the support | pillar 16 of the cultivation apparatus 51 of FIG. 25, (b) is an enlarged view of the cover 56 of (a).

  The cultivation apparatus 51 is different from the cultivation apparatus 41 described in the fifth embodiment in that the cultivation apparatus 51 includes a lid 56 instead of the lid 46. Other configurations of the cultivation device 51 are the same as those of the cultivation device 41.

  That is, the cultivation apparatus 51 includes the cultivation apparatus 11 described in the second embodiment and the lid 56.

  The lid | cover 56 has the structure which can be attached to the opening part 16a of the support | pillar 16, and can be removed. The lid 56 is fixed to the column 16 by being attached to the opening 16 a of the column 16. A method for fixing the lid 56 and the opening 16a of the support column 16 is not particularly limited. For example, a configuration in which a peripheral portion surrounding the opening 16a on the side wall of the support column 16 has a shape that allows the cover 56 to be fitted, or the like. Can be mentioned.

  The lid 56 has a slit-shaped transmission window 56 a formed in the vicinity of the center portion of the lid 56. The transmission window 56a is configured by forming a slit-like opening in the lid 56 and arranging a transparent member made of a translucent material in the opening.

  The material other than the transmission window 56a of the lid 56 can be made of, for example, glass, acrylic, metal, plastic, or the like, like the support columns 6 and 16. In particular, the entire cultivation device 51 can be reduced in weight by configuring the material other than the transmission window 56a of the lid 56 from plastic or lightweight plastic.

  The material other than the column 16 and the transmission window 56a of the lid 56 is made of a light shielding member. Thus, the lid 56 is attached to the opening 16 a of the support column 16, so that the liquid supply tank 17 stored in the support column 16 is completely surrounded by the side wall of the support column 16 and the cover 56. As a result, the liquid supply tank 17 stored in the column 16 is shielded from light by the column 16 and the lid 56. For this reason, generation | occurrence | production of the algae in the liquid supply tank 17 can be prevented more reliably.

  Further, the remaining liquid amount in the liquid supply tank 17 stored inside the column 16 can be visually recognized from the outside by the transmission window 56 a provided in the lid 56. The shape of the transmission window 56a is not particularly limited, and may be provided in at least a part of the support column 16.

  The transmissive member constituting the transmissive window 56a is preferably made of a material having as high a light shielding property as possible, and more preferably a member having a high light shielding property for light in a wavelength band mainly used in photosynthesis of algae. In particular, it is preferable to use a transmission filter that mainly transmits light in the green wavelength band having a peak wavelength in the wavelength range of 500 nm or more and 600 nm or less as the transmission member constituting the transmission window 56a.

  Thereby, photosynthesis of algae due to the incidence of light from the transmission window 56a into the support column 16 can be prevented while ensuring the visibility inside the support column 16.

This will be specifically described with reference to FIG. FIG. 27 is a diagram illustrating a graph of the absorption wavelength of chlorophyll.
<< Source: "Absorption spectra of chlorophyll a (green) and chlorophyll b (red)", Wikipedia, [online], [searched on June 1, 2012], Internet <URL: http://en.wikipedia.org/ wiki /% E3% 83% 95% E3% 82% A1% E3% 82% A4% E3% 83% AB: Chlorophyll_spectrum.png〉
FIG. 27 shows a graph relating to absorption wavelength bands of chlorophyll a and chlorophyll b that absorb light during photosynthesis.

  As shown in FIG. 27, both chlorophyll a and chlorophyll b have absorption bands where the absorption rate is sharply high at 400 nm to 500 nm and 600 nm to 700 nm, and the absorption rate is relatively high in the wavelength band of 500 nm to 600 nm. Is decreasing.

  And it is known that these chlorophylls a and b are mainly used for photosynthesis of algae.

  If the transmission member of the transmission window 56a is composed of a transmission filter that transmits green light having a wavelength peak in the range of 500 nm to 600 nm, a blue wavelength of around 450 nm that is mainly used in the photosynthesis reaction. The wavelength band and the red wavelength band near 660 nm can be shielded.

  As a result, it is difficult for the algae to synthesize with the light transmitted into the support column 16 through the transmission window 56a, while the remaining amount of the culture solution L in the liquid supply tank 17 stored in the support column 16 is It becomes possible to confirm from the outside of the column 16.

  That is, by using a transmission filter that mainly transmits a wavelength band of 500 nm or more and 600 nm or less as the transmission member of the transmission window 56a, it is possible to prevent the generation of algae and photosynthesis while ensuring the visibility inside the support column 16. Can prevent breeding. Further, alteration of the culture solution L can be suppressed.

[Embodiment 7]
Next, a seventh embodiment of the present invention will be described with reference to FIG. For convenience of explanation, members having the same functions as those in the drawings described in the first to sixth embodiments are given the same reference numerals, and descriptions thereof are omitted.

  FIG. 28 is a diagram illustrating a configuration of a liquid supply tank 61 according to the present embodiment.

  The liquid supply tank 61 includes a tank body 18 and liquid supply adapters 62 and 63. The liquid supply tank 61 is different from the liquid supply tank 17 in that a liquid supply adapter 62 and a liquid supply adapter 63 are provided instead of the liquid supply adapter 19 of the liquid supply tank 17. Other configurations of the liquid supply tank 61 are the same as those of the liquid supply tank 17.

  The liquid supply tank 61 includes a plurality of liquid supply adapters 62 and 63 having different valve opening lengths.

  The liquid supply adapter 62 includes a cap 62a, a valve 62b, a resilient member 62c, and a valve opening 62d. The liquid supply adapter 63 includes a cap 63a, a valve 63b, a resilient member 63c, and a valve opening body 63d.

  The caps 62a and 63a, the valves 62b and 63b, and the resilient members 62c and 63c have the same configuration and material as the cap 19a, the valve 19b, and the resilient member 19c, respectively.

  The valve opening body 62d penetrates the valve 62b and the resilient member 62c, and the valve opening body 63d penetrates the valve 63b and the resilient member 63c. The valve opening body 62d is shorter in length than the valve opening body 63d, while the valve opening body 63d is longer in length than the valve opening body 62d. The material and the like of the valve opening bodies 62d and 63d are the same as those of the valve opening body 19d.

  Thus, by changing the length of the valve opening body, when the liquid supply tank 61 is installed in the cultivation tank 12, the heights of the valves 62b and 63b in the tank body 18 are different.

  Thus, the liquid level of the culture solution L in the cultivation tank 12 can be changed by varying the height of the valve in the tank main body 18.

  When the liquid supply tank 61 to which the liquid supply adapter 63 having the valve open body 63d having a long length is attached is attached to the cultivation tank 12, the position of the valve 63b supported by the valve open body 63d in the tank body 18 is , Relatively high. Thereby, the liquid level of the culture solution L in the cultivation tank 12 becomes constant at a relatively high position.

  On the other hand, when the liquid supply tank 61 to which the liquid supply adapter 62 having the short valve open body 62d is attached is attached to the cultivation tank 12, the valve 62b supported by the valve open body 62d is in the tank body 18. The position is relatively low. Thereby, the liquid level of the culture solution L in the cultivation tank 12 becomes constant at a relatively low position.

  Thus, it is possible to change the height of the liquid level made constant in the cultivation tank 12 by varying the length of the valve opening body.

  According to the liquid supply adapter 62, the position at which the liquid level of the culture liquid L in the cultivation tank 12 is constant is variable, so that the liquid level in the cultivation tank 12 is adjusted according to the type and growing time of the plant P to be cultivated. It can be adjusted to the optimum position.

  In addition, the length of the valve opening body of the liquid supply adapter included in the liquid supply tank 61 is not limited to two types like the valve opening bodies 62d and 63d of the liquid supply adapters 62 and 63, but three or more different lengths. You may have the liquid supply adapter which has this valve open body.

[Embodiment 8]
Next, an eighth embodiment of the present invention will be described with reference to FIG. For convenience of explanation, members having the same functions as those in the drawings described in the first to seventh embodiments are denoted by the same reference numerals and description thereof is omitted.

  FIG. 29 is a diagram illustrating a configuration of liquid supply tank 64 according to the present embodiment.

  The liquid supply tank 64 includes a tank body 18, a liquid supply adapter 19, and one or a plurality of receiving members 65. The liquid supply tank 64 includes the liquid supply tank 17 and one or more receiving members 65.

  The receiving member 65 is disposed on the bottom surface of the cultivation tank 12 so as to be positioned below the tank body 18 and the liquid supply adapter 19 attached to the cultivation tank 12.

  The receiving member 65 has a convex portion 65a in the vicinity of the center thereof. The top part (upper end surface) of this convex part 65a and the top part (end part on the opposite side to the side where the valve 19b is located) located in the downward side of the valve opening body 19d of the liquid supply adapter 19 contact. And the convex part 65a supports the said top part of the valve opening body 19d from the downward side. Thereby, the liquid level of the culture solution L in the cultivation tank 12 becomes constant.

  Also, a plurality of receiving members 65 are prepared, and one or a plurality of receiving members 65 are laminated in a block shape below the receiving member 65 that is in contact with the liquid supply adapter 19, thereby providing the liquid supply adapter 19 and the tank body By instructing 18 from below, the height positions of the liquid supply adapter 19 and the tank body 18 may be adjusted, and thereby the liquid level of the culture liquid L in the cultivation tank 12 may be prepared.

  Thus, by providing the receiving member 65, the position where the liquid supply adapter 19 makes the liquid level of the culture liquid L in the cultivation tank 12 constant can be made variable. Thereby, according to the kind and cultivation time of the plant P to grow, the liquid level in the cultivation tank 12 can be matched with an optimal position.

[Embodiment 9]
Next, a ninth embodiment of the present invention will be described with reference to FIG. For convenience of explanation, members having the same functions as those in the drawings described in the first to eighth embodiments are denoted by the same reference numerals and description thereof is omitted.

  FIG. 30 is a diagram illustrating the configuration of the liquid supply tank 66 according to the present embodiment.

  The liquid supply tank 66 includes a tank body 18, a liquid supply adapter 19, and a plurality of receiving members 67. The liquid supply tank 64 includes a liquid supply tank 17 and a plurality of receiving members 67.

  The receiving member 67 is disposed on the bottom surface of the cultivation tank 12 so as to be positioned below the tank body 18 and the liquid supply adapter 19 attached to the cultivation tank 12. A plurality of receiving members 67 are arranged in a stacked manner.

  The receiving member 67 has a convex portion 67a on the upper surface (front surface) near the center thereof, and has a concave portion 67b on the lower surface (back surface) at a position facing the convex portion 67a.

  The top of the convex portion 67a (upper end surface) and the top of the liquid supply adapter 19 located on the lower side of the valve opening 19d (the end opposite to the side where the valve 19b is located) are in contact with each other. The convex portion 67a supports the top of the valve opening 19d from below. Thereby, the liquid level of the culture solution L in the cultivation tank 12 becomes constant.

  The recess 67 b has a shape that protrudes from the lower surface side to the upper surface side inside the receiving member 67. The concave portion 67b is different from the receiving member 67 in which the concave portion 67b is formed, and has a shape in which the convex portion 67a of the receiving member 67 disposed below can be fitted.

  In this way, the plurality of receiving members 67 can be stacked in a block shape by fitting the convex portions 67a of the receiving member 67 arranged below the concave portions 67b formed on the respective back surfaces. It has become. Thereby, it becomes possible to instruct | indicate the liquid supply adapter 19 and the tank main body 18 from the downward side, adjust the height position of the liquid supply adapter 19 and the tank main body 18, and, thereby, the culture solution L in the cultivation tank 12 The liquid level can be prepared.

  Further, not only the convex portion 67a but also a plurality of convex portions are provided on the upper surface of the receiving member 67, and the lower surface is formed not only on the concave portion 67b but also on the upper surface of the receiving member 67 disposed in the lower layer. By providing a plurality of concave portions into which a plurality of convex portions can be fitted, and fitting the plurality of convex portions and the plurality of concave portions, the plurality of receiving members 67 can be stacked more stably.

  Thus, by providing the plurality of receiving members 67, the position where the liquid supply adapter 19 makes the liquid level of the culture liquid L in the cultivation tank 12 constant can be made variable. Thereby, according to the kind and cultivation time of the plant P to grow, the liquid level in the cultivation tank 12 can be matched with an optimal position.

[Embodiment 10]
Next, a tenth embodiment of the present invention will be described with reference to FIG. For convenience of explanation, members having the same functions as those in the drawings described in the first to ninth embodiments are given the same reference numerals, and descriptions thereof are omitted.

  FIG. 31 is a diagram illustrating the configuration of the cultivation apparatus 11 ′ according to the present embodiment.

  The cultivation device 11 ′ includes a receiving member 68 and a plurality of convex slit members 69 in addition to the cultivation device 11. In addition, in FIG. 31, illustration of structures other than the structure of the liquid supply tank 17, the cultivation tank 12, the receiving member 68, and the some convex slit member 69 is abbreviate | omitted for the simplification. Moreover, in FIG. 31, the liquid supply tank 17 is expanded and represented.

  The receiving member 68 is arranged in the cultivation tank 12, and both end portions are supported by the convex slit member 69. The receiving member 68 has a convex portion 68a on the upper surface (surface) in the vicinity of the center thereof.

  A plurality of the convex slit members 69 are arranged on the side surface in the cultivation tank 12 so as to be convex toward the inside.

  The plurality of convex slit members 69 are arranged such that a pair of convex slit members 69 arranged at height positions facing each other on the side surface in the cultivation tank 12 and the pair of convex slit members 69 are arranged in the vertical direction. It is composed of that. Both ends of the receiving member 68 are supported by the pair of convex slit members 69.

  The top (upper end surface) of the convex portion 68a of the receiving member 68 supported in this manner is opposite to the top (the side on which the valve 19b is located) located below the valve opening 19d of the liquid supply adapter 19. (The end on the side) comes into contact with each other, so that the convex portion 68a supports the top of the valve opening 19d from below. Thereby, the liquid level of the culture solution L in the cultivation tank 12 becomes constant.

  Of the pair of convex slit members 69 arranged side by side in the vertical direction, by changing the pair of convex slit members 69 that support both side ends of the receiving member 68, the receiving member 68 can be set to an arbitrary height. The position can be changed and fixed.

  Thereby, the height position of the liquid supply adapter 19 and the tank main body 18 can be adjusted, and as a result, the liquid level of the culture solution L in the cultivation tank 12 can be prepared.

  That is, by providing a plurality of pairs of convex slit members 69 and receiving members 68, the position where the liquid supply adapter 19 makes the liquid level of the culture liquid L in the cultivation tank 12 constant can be made variable. Thereby, according to the kind and cultivation time of the plant P to grow, the liquid level in the cultivation tank 12 can be matched with an optimal position.

[Embodiment 11]
Next, an eleventh embodiment of the present invention will be described with reference to FIGS. 32 (a) and 32 (b) and FIGS. 33 (a) and 33 (b). For convenience of explanation, members having the same functions as those in the drawings described in the first to tenth embodiments are denoted by the same reference numerals and description thereof is omitted.

  FIG. 32A is a perspective view illustrating the configuration of the plant cultivation apparatus 70 according to the present embodiment, and FIG. 32B is a diagram illustrating the configuration of the cultivation tank main body 72b.

  FIG. 33A is a perspective view showing the configuration of the skeleton part 72d, and FIG. 33B is an enlarged view of the vicinity of the convex part of the skeleton part 72d.

  The cultivation apparatus 70 is different from the cultivation apparatus 11 in that a cultivation tank 72 is provided instead of the cultivation tank 12 of the cultivation apparatus 11. Other configurations of the cultivation device 70 are the same as those of the cultivation device 11.

  The cultivation tank 72 includes a planting panel 72a and a cultivation tank main body 72b. The planting panel 72a has the same structure and material as the planting panel 12a.

  The cultivation tank main body 72b is different from the cultivation tank main body 12b in that a storage part 72c and a skeleton part 72d are provided. Other configurations and the like of the cultivation tank main body 72b are the same as those of the cultivation tank main body 12b, including being connected to the lower end portion of the support column 16.

  The skeleton part 72d is made of a non-breathable waterproof material, and the side wall is a mesh-like frame on one side, thereby forming a large number of holes. The skeleton part 72d has a concave shape constituted by a bottom surface and side walls. The storage part 72c is arranged in the concave shape of the skeleton part 72d. The bottom surface of the skeleton part 72d has a clog shape due to the arrangement of a plurality of convex parts 72e.

  The convex portions 72e are arranged in the vicinity of the four corners of the outer bottom surface of the skeleton portion 72d. When this convex part 72e contacts the installation surface of the cultivation apparatus 70, the said installation surface and the bottom face (namely, bottom face of the cultivation apparatus 70) of the frame | skeleton part 72d are spaced apart and distribute | arranged.

  The non-breathable waterproof material constituting the skeleton part 72d can be formed of glass, acrylic, metal, or plastic. In particular, the cultivation tank main body 72b can be reduced in weight by comprising from a plastic or a lightweight plastic.

  The storage part 72c is arranged inside a concave skeleton part 72d constituted by a bottom surface and side walls. The storage part 72c is bag-shaped and is made of a breathable waterproof material.

  The breathable waterproof material constituting the storage portion 72c is not particularly limited as long as it has a waterproof and breathable structure. For example, a continuous porous structure film obtained by drawing polytetrafluoroethylene (trade name) : Gore-Tex (registered trademark)) or the like can be used.

In addition, as a breathable waterproofing material, among water-resistant waterproof breathable materials such as Montbell's Super Hydro Breeze, water resistance that does not penetrate the culture solution in general use (water pressure resistance of rainwear) About 2000mm)
<< Reference: Sun Ride website, [Search June 1, 2012], [online], Internet <http://www.sunride.jp/com/caution_rain.html >>>
It is preferable to use one having

  Here, as for a cultivation tank, the structure which does not let liquid and gas pass along the side and the bottom is common.

  Usually, the oxygen inside the cultivation tank is reduced because it is consumed by the respiration of the plant to be cultivated. The oxygen in the liquid is supplied from the atmosphere in an unsaturated state. However, the oxygen mobility at that time is proportional to the contact surface area of the gas-liquid.

  Then, the storage part 72c of the cultivation tank main body 72b is comprised with the air permeable waterproof material formed in the bag shape. By comprising this breathable member, the cultivation tank main body 72b does not leak the culture medium L inside, but the gas can pass through the cultivation tank main body 72b.

For this reason, it becomes possible to increase the contact surface area of the gas-liquid of the culture liquid L in the cultivation tank main body 72b and external gas, and, thereby, plant P, such as oxygen, into the culture liquid L in the cultivation tank main body 72b. It is possible to promote the gas supply necessary for the growth of the plant in comparison with a configuration in which normal liquid and gas are not passed.
Furthermore, the bottom surface of the skeleton part 72d is formed in a clog shape. That is, the convex portion 72e is disposed on the bottom surface of the skeleton portion 72d. For this reason, even if the cultivation apparatus 70 is installed on the ground surface, a concrete surface, or the like, the bottom surface of the storage unit 72c arranged in the concave shape of the skeleton part 72d is separated from the installation surface of the cultivation apparatus 70.

  Here, when the installation surface of the cultivation apparatus 70 and the bottom surface of the storage part 72c are in contact, the permeation of oxygen from the bottom surface of the storage part 72c is inhibited by the installation surface.

  On the other hand, in the cultivation apparatus 70, the storage part 72c is separated from the installation surface of the cultivation apparatus 70, and a space is formed below the storage part 72c, so that oxygen can be transmitted from the bottom surface of the storage part 72c. This further increases the contact area of the culture solution in the reservoir 72c with the gas-liquid, and facilitates the exchange of oxygen when the dissolved oxygen in the culture solution is unsaturated.

  That is, in the cultivation tank main body 72b, when the oxygen concentration of the culture solution L in the vicinity of part or all of the cultivation tank main body 72b is unsaturated, the cultivation tank main body 72b passes through the outside of the cultivation tank main body 72b. Oxygen can be supplied to the culture solution L inside the cultivation tank main body 72b. In this way, it is possible to prevent a decrease in the concentration of gas such as oxygen necessary for the growth of the plant P in the culture solution L in the cultivation tank main body 72b.

  In particular, the effect of preventing the above-described decrease in density can be obtained more reliably by separating the installation surface of the cultivation device 70 and the bottom surface of the storage portion 72c by 5 mm or more.

  In addition, in the cultivation apparatus 70, since the culture liquid L can always be supplied to the cultivation tank 72 from the liquid supply tank 17 stored in the support | pillar 16, it is compared with the dripping type apparatus 401 etc. which were shown in FIG. Thus, the volume of the liquid smoke portion (the culture liquid L in the cultivation tank 72) can be reduced.

  Thus, according to the cultivation apparatus 70, while providing the liquid supply tank 17, the volume in the cultivation tank 72 can be made small, and the side wall of the cultivation tank main body 72b, a part or all of the bottom face is breathable waterproof material. By comprising, since the surface area which enables oxygen supply through the cultivation tank main body 72b is high, the synergistic effect of the fall prevention of the oxygen concentration of the culture solution L in the cultivation tank 72 can be acquired. For this reason, the oxygen concentration fall of the culture solution L in the cultivation tank 72 can fully be prevented.

  Here, in Patent Document 7, a ventilation hole penetrating through at least a part of a side surface or a bottom surface of the container body having an open top is provided on the side surface so as to block the ventilation hole. A plant cultivation container comprising a breathable waterproof material is disclosed.

  On the other hand, since the cultivation tank main body 72b includes a skeleton portion 72d formed of a non-breathable waterproof material and a storage portion 72c formed of a breathable waterproof material formed in a bag shape therein, It is not the structure which the air permeable waterproof material was provided in the side part so that the ventilation | gas_flowing hole penetrated in part and the said ventilation | gas_flowing hole might be blocked | closed like patent document 7, but both differ. Another difference is that the storage portion 72c can be set apart from the installation surface by forming the skeleton portion 72d in a clog shape.

  Patent Document 8 discloses that a water repellent surface modifier (water repellent) is infiltrated over the entire surface of a container for dissolving a nutrient solution, thereby increasing the dissolved oxygen concentration of the nutrient solution and supplying oxygen to the roots of the crop. Thus, a hydroponic cultivation apparatus using a water repellent that promotes the growth of crops is disclosed.

  On the other hand, the cultivation tank main body 72b is not configured by infiltrating a water repellent into the container, and the cultivation tank main body 72b is prepared by including in advance at least part of a material having a breathable waterproof function. Is. For this reason, both are different.

[Embodiment 12]
Next, a twelfth embodiment of the present invention will be described with reference to FIG. For convenience of explanation, members having the same functions as those in the drawings described in the first to eleventh embodiments are denoted by the same reference numerals and description thereof is omitted.

  FIG. 34 is a perspective view illustrating a configuration of a plant cultivation apparatus 80 according to the present embodiment. The cultivation apparatus 80 is different from the cultivation apparatus 11 in that it includes light guide plates 85 and 86 and light sources 87 and 88 instead of the illumination unit 4 and the light source 5 of the cultivation apparatus 11. Other configurations of the cultivation device 80 are the same as those of the cultivation device 11.

  The light guide plates 85 and 86 are arranged on the outer side walls of the columns 16 so that the longitudinal direction (extending direction) is substantially parallel to the longitudinal direction (extending direction) of the columns 16.

  The light source 87 is disposed on the upper end portion of the light guide plate 85, and the light source 88 is disposed on the upper end portion of the light guide plate 86. Thereby, the support | pillar 16 is supporting the light source plates 85 and 86, and is supporting the light sources 87 and 88 indirectly or directly. A liquid supply tank 17 is stored in the opening 16 a of the support column 16.

  The light guide plate 85 causes the light emitted from the light source 87 to enter the light guide plate 85 from the upper end portion, guide the inside of the light guide plate 85, and from an irradiation surface that is a surface facing the surface in contact with the support column 16. Irradiate light toward the outside of itself. Thereby, the plant P arranged in the vicinity of the irradiation surface of the light guide plate 85 is illuminated.

  The light guide plate 86 causes light emitted from the light source 88 to enter the light guide plate 86 from the upper end portion, guide the inside of the light guide plate 86, and from an irradiation surface that is a surface facing the surface in contact with the support column 16. Irradiate light toward the outside of itself. Thereby, the plant P arranged in the vicinity of the irradiation surface of the light guide plate 86 is illuminated.

  Thus, the cultivation apparatus 80 includes the light guide plates 85 and 86 that guide the light from the light sources 87 and 88 to the side wall 16h of the support column 16 and irradiate the light in the direction intersecting the longitudinal direction of the support column 16. ing.

  Thereby, it can illuminate from the side with respect to the plant P to grow with the light irradiated from the light-guide plates 85 * 86. For this reason, compared with the case where it illuminates from the upper direction of the plant P to grow, it is not necessary to arrange | position the light sources 87 and 88 to the height more than the height of the plant P to grow. Thereby, the cultivation apparatus 80 can be reduced in size, and the cultivation apparatus 80 which requires a smaller installation space can be obtained.

  In addition, although the cultivation apparatus 80 demonstrated as what distribute | arranges light guide plate 85 * 86 to a part of support | pillar 16, it is not limited to this, The light guide plate covers the whole surface of the support | pillar 16 so that the circumference | surroundings of the support | pillar 16 may be covered. You may make it cover with. Thereby, it becomes possible to irradiate light from the entire surface of the support column 16.

  Moreover, since the support | pillar 16 is distribute | arranged to the center of the cultivation tank 12 by planar view, the distance of the support | pillar 16 and the some plant P is substantially equal.

  Therefore, the cultivation device 80 is configured to have a light guide plate on a part or the entire surface of the support column 16. Thereby, light will be irradiated from the side wall of the support | pillar 16, and it will irradiate to each plant P with high irradiation efficiency, since it is illuminated near by each plant P and equally.

  Furthermore, since the support column 16 for storing the liquid supply tank 17 is erected in the vertical direction, the light guide plates 85 and 86 are attached to the side walls of the support column 16, thereby eliminating the need for the shade-shaped illumination unit 4. Thereby, the reduction effect of a number of parts can also be acquired and also stability can be improved.

  The present invention is not limited to the above-described embodiments, and various modifications are possible within the scope shown in the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is also included in the technical scope of the present invention.

  The present invention can be used for a cultivation apparatus for cultivating plants.

1.11 'Cultivation equipment 2 Planter (cultivation container)
3 Illumination unit 4 Illumination part 4a Opening part 4b Convex part 4c Side surface 5 Light source 6/16 Post 6a Opening part 6b Concave part 6h Side wall 7 Liquid supply tank 7a Tank body 7b Caps 11, 21, 31, 41, 51, 70, 80 Cultivation Device 12 Cultivation tank (cultivation container)
12a Planting panel 12b Cultivation tank body 12c Handle 12d Receiving member 12f Recess 13 Illumination unit 15 Protruding part 16, 26, 36 Post 16a, 26a, 36a Opening part 16c Inserting member 16d, 16e Catch clip 16h Side wall 17 Supply tank 18 Tank Main body 19 Liquid supply adapter 24 Joint 27 External pipe 28 Internal pipe 34 Illumination part 34a Opening part 56a Transmission window 61/64/66 Liquid supply tank 62/63 Liquid supply adapter 62a / 63a Cap 62c / 63c Elastic member 62d / 63d Valve Open body 65, 67, 68 Receiving member 65a, 67a, 68a Convex part 67b Concave part 69 Convex slit member 72 Cultivation tank (cultivation container)
72a Planting panel 72b Cultivation tank main body 72c Storage part 72d Skeletal part 72e Convex part 85 * 86 Light guide plate 87 * 88 Light source L Culture solution P Plant

Claims (8)

A cultivation apparatus having an illumination unit for irradiating a plant with light for cultivation,
The lighting unit is
A light source for irradiating the light;
A column supporting the light source;
A liquid supply tank filled with a liquid for supplying to the plant,
The cultivation apparatus, wherein the liquid supply tank is integrated with the support column.   The cultivation apparatus according to claim 1, wherein the strut stores the liquid supply tank.   The cultivation apparatus according to claim 2, wherein a part or all of a side wall of the support column that stores the liquid supply tank is made of a light shielding member. Comprising a cultivation container in which the plant is grown,
The cultivation apparatus according to claim 2, wherein the support column and the cultivation container are fixed.   The cultivation apparatus according to claim 4, wherein the support column is arranged at a center position of the cultivation container in a plan view. The support column is formed with an opening for storing the liquid supply tank in the side wall, and includes a lid for covering the opening.
At least a part of the lid is formed of a transparent member with a window through which the inside of the column can be visually recognized,
The cultivation apparatus according to claim 5, wherein the transparent member transmits light having a wavelength peak in a range of 500 nm to 600 nm. The cultivation container includes a skeleton part and a breathable waterproof material,
The skeleton part is made of a non-breathable waterproof material, a large number of holes are formed, and a plurality of convex parts are arranged on the bottom surface,
The breathable waterproof material is formed in a bag shape inside the skeleton part, and the installation surface of the cultivation device and the bottom surface of the breathable waterproof material are separated from each other. The cultivation apparatus of any one of -6. Comprising a light guide plate arranged on the side wall of the column;
The said light guide plate guides the light from the said light source, and irradiates light in the direction which cross | intersects the longitudinal direction of the said support | pillar, The cultivation apparatus of any one of Claims 1-7 characterized by the above-mentioned. .

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