JPS61282025A - Hydroponic apparatus - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Field of Application> The present invention relates to a hydroponic cultivation device that can hydroponically cultivate uniform plants systematically, with good workability, and economically.

<Prior Art> As a hydroponic cultivation apparatus according to the prior art, there is one disclosed, for example, in Japanese Patent Application Laid-Open No. 49-91833. As shown in Fig. 7, plants are supported on a chevron-shaped panel 01 having many holes, sunlight is applied through a transparent bow-shaped roof 02, and a nutrient solution spraying mechanism is shown in Fig. 8. 03
The plant is grown by spraying a nutrient solution onto the roots of the plant. Here, the nutrient solution spraying mechanism 03 is fixedly installed inside the chevron panel O], and this nutrient solution spraying mechanism 03 is designed to spray the nutrient solution onto the roots of the plants supported by the chevron panel 01. A large number of spray nozzles are arranged in the direction in which the chevron panel 01 is newly installed.

As shown in FIG. 9, this harvesting was carried out by removing the panel O1a supporting the grown plants from the frame.

<Problems to be solved by the invention> However, the conventional fixed nutrient solution spraying mechanism as described above
3 has the following problems.

(2) Since the entire nutrient solution spraying mechanism is long and has many spray nozzles, it is necessary to circulate a large amount of nutrient solution and to increase the supply pressure.

■ In order to keep the spray pressure constant for each spray nozzle, the piping specifications become complicated and large.

■ Since there is a certain distance between each spray nozzle, the amount of spray applied to the roots of the plants varies depending on the location, causing uneven growth of the plants.

■ If some of the spray nozzle holes become clogged, the spray will be incomplete and there will be a large difference in growth between plants and plants that are treated with normal spray nozzles.

In view of these problems, the present invention is equipped with a nutrient solution spraying mechanism that can uniformly spray nutrient solution, etc. onto the roots of plants supported by angular panels, and that is compact and reduces the amount of nutrient solution circulated. The purpose is to promote hydroponic cultivation equipment.

Means for Solving the Problems〉 The structure of the present invention that achieves the above-mentioned object is that the upper ends of two panels are brought together and a large number of plants are supported by making the roots of the plants protrude inward of the panels. In a hydroponic cultivation device having a chevron-shaped panel having holes, a nutrient solution supply mechanism consisting of a nutrient solution pressure feeding system for supplying nutrient solution etc. to the roots of plants from the inside of the mount-shaped panel, and a nutrient solution spraying mechanism, The present invention is characterized in that the nutrient solution spraying mechanism is movable in the direction in which the panels are extended, and that a nutrient solution spraying mechanism driving means is provided for moving the nutrient solution spraying mechanism.

<Function> In the above configuration, by spraying while moving the spraying mechanism in the extending direction of the chevron panel, the supply of nutrient solution, etc. to the roots of the plants inside the panel is made uniform.

Embodiment Hereinafter, a preferred embodiment of the Kagaro hydroponic cultivation apparatus according to the present invention will be described in detail with reference to the drawings.

FIG. 1 and FIG. 2 are explanatory diagrams conceptually showing the hydroponic cultivation apparatus of this embodiment. As shown in both figures, the chevron panel 1 is provided with a number of holes 2 for supporting plant seedlings so that their roots hang inward, and wheels 3 are attached to the bottom of the chevron panel 1. It is designed so that it can be moved freely. The chevron-shaped panel 1 shown in FIG. 1 is made of a foamable synthetic resin such as styrofoam, a ceramic material such as a ceramic plate, or the like. As shown in FIG. 2, a plurality of the chevron-shaped panels 1 are arranged in series and are movable in the column direction. At this time, in this embodiment, the wheel 3
A support rod 5 is provided through a support member 4 provided at the upper end of the chevron-shaped panel 1 to guide and support the chevron-shaped panel 1 in order to further increase stability.

Such a mechanism for guiding the chevron-shaped panel 1 is not necessarily necessary.

A plurality of rows of the chevron panels 1 as described above are arranged in parallel as shown in FIG.

Next, the nutrient solution supply mechanism and nutrient solution spraying mechanism driving means of this embodiment will be explained. As shown in FIG. 3, the nutrient solution supply mechanism of this embodiment includes a nutrient solution spraying mechanism 7 and a flexible hose 20.
and a nutrient solution pressure feeding system consisting of a nutrient solution feed pump 12. Here, the nutrient solution spraying mechanism 7 in which the four spray nozzles 31 are arranged is located inside the chevron panel 1 and is movable in the direction in which the chevron panel 1 is extended. This nutrient solution spray [17 is connected to a nutrient solution feed pump 2 that is connected to a flexible hose 20]. In addition, the nutrient solution spraying mechanism 7 includes the pace sprays 1 and 32, a stand rod 33 erected on the base plate 32, and two rods 34 fixed at right angles to the stand rod 33. A spray nozzle 31 is arranged on this rod 34. These spray nozzles 31 are arranged symmetrically with respect to the extending direction of the chevron-shaped panel 1, as shown in FIG. 4, which is a partial plan view as viewed from arrow A. To elaborate further,
The spray nozzle 31 is disposed on the rod 34 via a block 35, and has a structure in which the spray angle can be freely adjusted. Furthermore, the spray nozzle 3J has an adjustment screw 31a, and this adjustment screw 31
The amount of spray can be adjusted by rotating by a%.

Further, the nutrient solution spraying mechanism driving means includes an endless drive chino 13,
The nutrient solution spraying mechanism 7 is mounted on two rows of endless drive chains 13 supported by two rolls 15 and an auxiliary roll 16. This endless drive chain 13 is driven reciprocally by a drive motor 14 with variable speed and reversible control via a roll 17, and the reciprocation can be switched by a detection switch 18 provided at both ends. ing.

In addition, the flexible hose 20 and the endless drive chain 13 are housed in a bellows-type holder (not shown) installed in parallel, and can be bent only in a vertical plane parallel to the endless drive chain 13, and can be bent in the lateral direction ( It is designed so that it cannot be bent in a direction perpendicular to the direction in which the chevron-shaped panel 1 is extended, so that it does not get in the way of the reciprocating movement of the nutrient solution spraying mechanism 7.

Here, when spraying a nutrient solution to plants, first drive the nutrient solution feed pump 12 to force-feed the nutrient solution in the nutrient solution tank 19, start spraying from the spray nozzle 31, and drive the drive motor 14. Then, the reciprocating movement of the nutrient solution spraying mechanism 7 is started. This allows the nutrient solution to be sprayed uniformly over the entire roots of the plants inside the panel.

At this time, if the openings at both ends of the chevron panel 1 in the extending direction are closed, a nearly sealed spray chamber will be formed inside the chevron panel 1, and the spray will be filled with a mist of nutrient solution, making it more uniform. Can be sprayed.

Further, in this embodiment, the nutrient solution accumulated on the floor can be recovered by the grooves 6 that guide the wheels 3 of the chevron panel 1, which is described above, so that it is very economical.

Next, a case will be described in which a plurality of chevron panels 1, which are provided with the above-mentioned nutrient solution supply mechanism inside and arranged in parallel in multiple rows, are all installed in the cultivation chamber 11 that blocks sunlight. The wall material of the cultivation room 11, in which the lighting fixture 8 that supplies a certain amount of light to the plants is arranged on the ceiling, is not particularly limited, but if necessary, a heat insulating material may be used. In addition, a sodium lamp, a mercury lamp, etc. are used as lighting equipment. Since plants are grown using only such artificial light, uniform plants can be cultivated in a planned manner. In such equipment, it is necessary to effectively use the light emitted from the lighting fixtures 8 to reduce the number of lighting fixtures 8, and to significantly reduce electricity costs and the like to improve economic efficiency. In this example, the lighting fixture 8h,)
A reflector 9 is installed on the ceiling as a reflective surface to reflect the light irradiated by the plant toward the plants, and a reflector 10 is installed on the surface of the chevron panel l, thereby greatly improving economic efficiency. Reflector 9 used here. IO is not particularly limited as long as it is a material that reflects light, such as a SUS plate or aluminum foil. Also SU
The chevron panel 1 or the like may be made of the reflector itself, such as an S plate.

The operation of the apparatus configured as described above will be explained together with the mode of operation. First, seedlings of plants such as leafy vegetables such as Okayama salad greens, Bibb lettuce, summer green, and red fire are inserted into the holes 2 of the chevron panel 1. Then, a predetermined light is irradiated from the lighting device 8, and a predetermined amount of the nutrient solution is sprayed from the nutrient solution spraying mechanism 7. As mentioned above, this nutrient solution is sprayed while the nutrient solution spraying mechanism 7 is reciprocated in the panel extension direction by the drive motor 14, so that it can be uniformly applied to all the roots of the plants inside the panel. can. This allows seedlings to be grown in a planned manner and harvested as plants of a uniform size. Furthermore, in this embodiment, the chevron panel 1
are lined up in series and are movable and removable.
By introducing the method in which the plants are fed in one direction in order, and the plants that have grown from the other end are taken out together with the chevron panel 1, work efficiency can be greatly improved. In other words, if it takes 20 days to harvest plants, for example, if 20 chevron panels 1 are arranged in one row and moved one panel per day in one direction, chevron panel 1 will enter from one end and the other. Since it takes 20 days to reach the edge, the plants in the chevron panel IL will fully grow during this time. Therefore, this method greatly improves work efficiency and allows regular harvesting. At this time, it is sufficient to move the chevron panel 1 by hand, but
A driving device may be used when the number is large. By moving the chevron panel 1 in this manner, in addition to the effect of improving work efficiency, it is possible to obtain the effect of keeping the irradiation conditions (amount, direction) and nutrient solution supply conditions approximately constant.

FIG. 5 is an explanatory diagram conceptually showing a hydroponic cultivation factory using the above-described apparatus. This factory has a structure that blocks sunlight, and lighting is installed inside the factory. Also, as shown in the drawing, the number of rows of chevron panels 1 is 1.
There are 12 rows from 01 to 112, and these chevron panels 1 can be moved to the left in the drawing by driving force. In addition, in the same factory, there are holes 2 of these chevron panels 1.
A seedling nursery room 120 for growing seedlings is installed, and a nutrient solution sterilization tank 121 and an underground tank 122 are installed side by side. Further, the above-mentioned nutrient solution supply mechanism is connected to a nutrient solution sterilization tank 125, a pressure tank 124, and an underground stock tank 123, which are installed separately. The nutrient solution is periodically sprayed from the spray nozzles 31 of these nutrient solution spraying mechanisms 7, and the nutrient solution accumulated on the floor is collected by the grooves 6. In such factories, seedling nursery room 1
The seedlings grown in step 20 are inserted into the holes 2 of the chevron panel 1 and then attached to the right side of the row of chevron panels 1 in the figure.

These seedlings are periodically sent to the left in the figure along with the chevron panel 1 and grow while absorbing CO2, 02 from the atmosphere and being supplied with a nutrient solution and artificial light. It is then planned to grow fully and uniformly when it reaches the left end of the column. The plants grown in this manner are removed from the row together with the chevron panels 1 and collected in the panel assembly area 128 by the panel moving conveyor 126. There, the plants are harvested, sorted by a sorting conveyor 127, automatically packaged and boxed, and then shipped. Also, the empty chevron panel 1 is sent to the right in the drawing by the return conveyor 113, and new seedlings are arranged again.

As explained above, by installing the apparatus according to the present invention, work can be carried out only on both sides of the factory (left and right sides in the figure), making it very efficient. Furthermore, plants can be shipped regularly and in a planned manner, which is even more effective.

In the embodiment described above, by arranging the chevron panels 1 in series and making them movable and removable, it is possible to greatly improve the work efficiency when inserting and harvesting seedlings. Furthermore, by periodically moving the chevron panel 1 in one direction, the irradiation conditions become almost constant, allowing for more systematic and uniform harvesting. In addition, since artificial light is used, the irradiated light is effectively utilized by providing reflective surfaces on the inner surfaces of the ceiling, walls, floor, etc. of the cultivation room, and on the surface of the chevron panel 1. This greatly improves economic efficiency by reducing the number of electricity bills and other costs.

In the above-described embodiments, the plants were grown using artificial light, but of course sunlight may also be used. In this case as well, since the supply of nutrients is uniform, plants with even growth can be provided.

Moreover, various structures of the nutrient solution spraying mechanism 7 can be considered, but it may be a structure that can uniformly spray the entire plant depending on the size of the chevron panel 1 and the like.

Further, the nutrient solution spraying mechanism driving means, the nutrient solution pressure feeding mechanism, etc. are not limited to the above embodiments, and various configurations are possible. Here, another example is shown in FIG. 6 [al, (
This will be explained with reference to bl. As shown in both figures, in this nutrient solution spraying mechanism driving means, the nutrient solution spraying mechanism 7a having a moving roller 36 has a rope 23 fixed to its front and rear ends in the moving direction, which is a variable speed and reversibly controlled rope winding mechanism. It is reciprocated by being wound up by the device 21. At this time, the flexible hose 20 connecting the nutrient solution feed pump 12 and the nutrient solution spraying mechanism 7a is wound up by the hose winding device 22 so as not to slack, so as not to interfere with the reciprocating movement of the nutrient solution spraying mechanism 7a. It has become. Also, along the reciprocating path of the nutrient solution spraying mechanism 7a, the nutrient solution recovery 711
24 are provided.

<Effects of the Invention> As specifically explained above in conjunction with the embodiments, in the present invention, the nutrient solution spraying mechanism is made movable in the extending direction of the chevron panel, so that nutrients can be uniformly supplied to the entire plant. Furthermore, even if a part of the spray nozzle becomes clogged, the nutrient solution can be supplied in a fairly uniform manner as a whole, so it is possible to provide plants with even growth.

In addition, by making the nutrient solution spraying mechanism mobile, the entire nutrient solution supply mechanism can be downsized, and the number of spray nozzles can be significantly reduced, so the amount of 51 liquid to be circulated can be reduced, and the feeding pressure of the nutrient solution can also be reduced. It's small. Furthermore, a constant spray pressure can be obtained without installing complicated piping, and parts such as the spray nozzle can be easily replaced.

[Brief explanation of drawings]

FIGS. 1 and 2 are explanatory diagrams conceptually showing a hydroponic cultivation apparatus according to an embodiment of the present invention, and FIG. 3 is an explanatory diagram conceptually showing its nutrient solution supply mechanism and nutrient solution jet FJaivt driving means. ,
4 is a sectional view taken along the line A in FIG. 3; FIG. 5 is an explanatory diagram conceptually showing a hydroponic cultivation factory using a hydroponic cultivation apparatus according to an embodiment of the present invention; Figures (al, (bl) are explanatory diagrams conceptually showing the nutrient solution supply mechanism and nutrient solution spraying mechanism driving means in other embodiments, and Figures 7 to 9 are hydroponics according to the prior art. It is an explanatory diagram conceptually showing a cultivation device. In the drawing, 1 is a chevron panel, 2 is a hole, 7 is a nutrient solution spraying mechanism, 7a is a nutrient solution III mist mechanism, 12 is a nutrient solution feed pump, and 13 is an endless drive. 5 is a roller, 19 is a nutrient solution tank, 20 is a flexible hose, and 31 is a spray nozzle. Patent applicant Kewpie Co., Ltd. Agent

Claims (1)

[Scope of Claims] 1) A chevron panel formed by joining the upper ends of two panels and having a large number of holes for supporting plants by allowing plant roots to protrude inward of the panel; In a hydroponic cultivation apparatus having a nutrient solution supply mechanism consisting of a nutrient solution pressure feeding mechanism and a nutrient solution spraying mechanism for supplying nutrient solution etc. to the roots of plants, the nutrient solution spraying mechanism is movable in the extending direction of the panel. A hydroponic cultivation apparatus characterized by further comprising a nutrient solution spraying mechanism driving means for moving the nutrient solution spraying mechanism. 2) The hydroponic cultivation apparatus according to claim 1, wherein an endless drive chain is used as the nutrient solution spraying mechanism driving means. 3) The hydroponic cultivation apparatus according to claim 1 or 2, wherein the nutrient solution pressure feeding mechanism includes a flexible hose for supplying the nutrient solution connected to the nutrient solution spraying mechanism. 4) The hydroponic cultivation apparatus according to claim 1, 2, or 3, wherein the nutrient solution spraying mechanism has spray nozzles arranged symmetrically with respect to the extending direction of the panel. .