JP2010510806A - Assembled flowerpot - Google Patents

Abstract

The assembling type flowerpot according to the present invention includes a cylindrical water tank in which a nutrient solution is placed, a rotating plate disposed on the upper part of the water tank and rotating, and a rotating means for rotating the rotating plate. The rotating plate has a hole for a cage structure member into which a plant can be inserted. In the upper part of the rotating plate, a pot insertion port for receiving insertion of a hydroponics pot is provided, and on the outer periphery of the rotating plate, a rotating plate gear for receiving transmission of rotational force from the rotating means is formed. The assembly-type flower pot further includes a hydroponics pot that is inserted into the pot insertion opening and stacked, and a pot lid that covers the top of the hydroponics pot. The pot lid has a hole for a ridge structure member into which a plant can be inserted into a hydroponics pot.

Description

  The present invention relates to an assembly type flower pot, and more particularly to an assembly type flower pot in which a plurality of hydroponics pots are stacked to increase the available space.

Conventionally, when a large number of plants are grown indoors, a method of planting and arranging plants in a plurality of flower pots or hanging a flower pot on a tree branch or wall has been employed.
However, the above method has a problem in that it is not suitable for cultivation of a large number of plants in a narrow space because the available space is reduced.

An object of the present invention is to provide a prefabricated type flower pot in which a plurality of hydroponic pots are stacked and a large number of plants can be grown even in a narrow space.
Another object of the present invention is to assemble a plant pot that can uniformly irradiate light from all directions to all plants by pumping the nutrient solution in the lower part with small power and rotating the flower pot using its weight. Is to provide.

  In order to achieve these objects, an assembling type flowerpot according to the present invention includes a cylindrical water tank for storing nutrient solution, a rotating plate disposed on the upper part of the water tank and rotating, and a rotating means for rotating the rotating plate. Is provided. Here, the rotating plate has holes for structural members (upper) into which plants can be inserted. In the upper part of the rotating plate, a pot insertion port for receiving insertion of a hydroponics pot is provided, and on the outer periphery of the rotating plate, a rotating plate gear for receiving transmission of rotational force from the rotating means is formed. The assembly-type flower pot further includes a hydroponics pot that is inserted into the pot insertion opening and stacked, and a pot lid that covers the top of the hydroponics pot. Here, a pot lid has a hole for a cocoon structure member which can insert a plant in a hydroponics pot.

Since the assembly type flower pot according to the present invention is configured such that a plurality of hydroponics pots capable of plant cultivation are stacked, a large number of plants can be cultivated even in a narrow space.
Moreover, the assembly-type flowerpot which concerns on this invention is comprised so that a nutrient solution of a lower part may be pumped up by small power to the upper part, and a flowerpot may be rotated using the weight. Thereby, light can be uniformly irradiated to all plants from all directions.

It is a whole perspective view of the assembly-type flowerpot which concerns on one Example of this invention. It is a perspective view of the hydroponics pot concerning one example of the present invention. It is a top view of the hydroponics pot of FIG. It is a perspective view of the rotation means which concerns on one Example of this invention. It is a partial cross section figure of the rotation means and hydroponics pot concerning one Example of this invention. FIG. 6 is a partial cross-sectional view showing a wider part than FIG. 5 of the rotating means and the hydroponics pot. It is a perspective view of the eaves structural member concerning one example of the present invention. It is a cross-sectional view of the eaves structural member of FIG. It is a perspective view of the hydroponics pot in which the cage | basket structure member based on another Example of this invention was inserted. It is a perspective view of the eaves structural member based on another Example of this invention. It is a perspective view of the hydroponics pot of the state from which the cocoon structural member which concerns on another Example of this invention was removed. It is the whole disassembled perspective view of the assembly-type flowerpot which concerns on another Example of this invention. FIG. 6 is a rear perspective view of a rotating plate according to still another embodiment of the present invention. It is a perspective view of the assembled state of the assembly-type flower pot of FIG. It is a vertical sectional view of the assembly-type flower pot of FIG.

FIG. 1 is an overall perspective view of an assembly-type flower pot according to an embodiment of the present invention.
As shown in FIG. 1, the assembly type flower pot according to the present invention includes a hydroponics pot 10 and a rotation holding member 20. There are a plurality of hydroponics pots 10, and they are sequentially stacked. The rotation holding member 20 has a rotating means 21 that is arranged at the lower part of the hydroponics pot 10 and rotates the hydroponic pot 10.

The hydroponics pot 10 is formed with a plurality of holes 11 for cocoon structural members. A plurality of eaves structural members 30 (see FIG. 7) in which plants are planted are inserted into the respective eaves structural member holes 11. Since a plurality of hydroponics pots 10 are stacked, the available space increases.
The hydroponics pot 10 is rotated at a constant speed by the rotating means 21. Thereby, light can be uniformly supplied from all directions to plants in all directions.

FIG. 2 shows a hydroponics pot 10 of an assembly type flower pot according to the present invention.
As shown in FIG. 2, the hydroponics pot 10 of the present invention includes a pot insertion port 12 and a plurality of ridge structure member holes 11 formed around the pot insertion port 12. Another upper water culture pot 10 is inserted into the pot insertion opening 12. The eaves structural member 30 is inserted into the eaves structural member hole 11.

An insertion portion 14 and a locking projection 13 are formed at the lower portion of the hydroponics pot 10. The insertion part 14 is inserted into the pot insertion opening 12 of another hydroponics pot 10. The locking projection 13 has a predetermined height for limiting the insertion depth of the insertion portion 14 into the bowl insertion port 12.
The diameter A of the bowl insertion port 12 is slightly larger than the diameter B of the insertion portion 14, but smaller than the diameter of the locking protrusion 13. For this reason, although the insertion part 14 is inserted in the bowl insertion port 12, it is restrict | limited by the latching protrusion 13 and cannot be inserted deeper.
An insertion portion gear 15 is formed on the outer periphery of the lower part of the hydroponics pot 10. The insertion portion gear 15 is adapted to receive a rotational force from the rotating means 21.

FIG. 3 is a plan view of the hydroponics pot 10 of FIG.
As shown in FIG. 3, at least two openings 16 a and 16 b (water supply opening 16 a and nutrient solution discharge opening 16 b) are formed in the lower part of the hydroponics pot 10 of the assembly-type flower pot according to the present invention. A water supply hose 18 (see FIG. 5) for supplying the lower layer nutrient solution to the upper layer is inserted into the water supply opening 16a. A nutrient solution discharge hose 19 (see FIG. 5) for supplying the nutrient solution in the upper layer to the lower layer immediately below is inserted into the nutrient solution discharge opening 16b.

FIG. 4 shows the rotation holding member 20 of the assembly type flower pot according to the present invention.
As shown in FIG. 4, a rotary table 22 is formed at the center of the rotary holding member 20. The hydroponics pot 10 is placed on the rotary table 22.
A plurality of rollers 23 are provided radially on the rotary table 22. These rollers 23 make the rotation of the hydroponics pot 10 smooth.
A rotation means 21 is disposed on one side of the rotation holding member 20. The rotating means 21 meshes with the insertion portion gear 15 of the hydroponics pot 10 to rotate the hydroponics pot 10.

FIG. 5 is a vertical sectional view of the rotation holding member 20 and a part of the hydroponics pot 10 arranged on the rotation holding member 20.
As shown in FIG. 5, the openings 16 a and 16 b of the hydroponics pot 10 disposed just above the rotation holding member 20 are closed by a lid 16-1. A pumping means 17 capable of pumping the nutrient solution upward is arranged inside the hydroponics pot 10.
The pumping means 17 is connected to a water supply hose 18 for supplying nutrient solution to the upper part.

FIG. 6 is a cross-sectional view illustrating a portion wider than FIG.
With reference to FIG. 6, in the assembly type flower pot according to the present invention, the rotation holding member 20 is disposed in the lowermost layer, and a large number of hydroponics pots 10 are stacked thereon.
The openings 16a and 16b of the lowermost hydroponics pot 10 among the stacked hydroponic pots 10 are closed by a lid 16-1. Thereby, the nutrient solution is stored in the lowermost hydroponics pot 10.

A pump 17 that can pump the nutrient solution upward is housed in the lowermost hydroponics pot 10.
One end of the water supply hose 18 is connected to the pump 17. The other end of the water supply hose 18 is connected to the uppermost hydroponics pot 10 through the water supply opening 16a of the upper hydroponic pot 10.
By operating the pump 17, the nutrient solution of the lowermost hydroponics pot 10 passes through the water supply hose 18 and is supplied to the uppermost hydroponics pot 10.

  The nutrient solution supplied to the uppermost hydroponics pot 10 passes through the nutrient solution discharge hose 19 and is discharged to the lower-layer hydroponic pot 10. At this time, only the nutrient solution higher than the height of the nutrient solution discharge hose 19 passes through the nutrient solution discharge hose 19 and is discharged to the lower hydroponics pot 10. The remaining nutrient solution is stored in the uppermost hydroponics pot 10. Therefore, a nutrient solution can be supplied to the plant cultivated with the cocoon structural member 30 for a long period of time.

Even in the hydroponics pot 10 of each layer, the nutrient solution is stored at a certain height in the same manner.
The nutrient solution discharge hose 19 may be formed so as to protrude upward by a predetermined height inside the hydroponics pot 10 and bend at an arbitrary height.

FIG. 7 shows a schematic form of the eaves structural member 30 according to the present invention.
As shown in FIG. 7, the rod structure member 30 has a shape similar to a rod that captures fish. The eaves structural member 30 is preferably formed so that its width becomes narrower toward the lower portion in order to facilitate insertion into the eaves structural member hole 11.

FIG. 8 is a cross-sectional view of the eaves structural member 30 of FIG.
As shown in FIG. 8, the cut surface of the frame 31 of the eaves structural member 30 has a triangular shape. Thereby, the root of the plant cultivated in the cocoon structural member 30 becomes easy to extend outward from the gap between the frames 31.

9-11 is the figure which showed the assembly-type flower pot which concerns on another Example of this invention.
9 to 11 include a hydroponics pot 110 in which a unit block hole 111 is formed. The size of the unit block hole 111 is larger than that of the persimmon structure member hole 11 of the hydroponics pot 10 shown in FIG. As shown in FIG. 10, the unit block 132 corresponds to the size of the unit block hole 111 and surrounds the flange structural member hole 131.
The unit block 132 and the unit block hole 111 are preferably formed in a square shape, but the shape is not limited at all.

As shown in FIG. 11, in the hydroponics pot 110, the unit block 132 and the unit block hole 111 have a quadrangular shape. Since the unit block 132 can be removed from the unit block hole 111, the inside of the hydroponics pot 110 can be easily maintained. Furthermore, it is possible to grow plants even with the unit block 132 removed.
A partition wall (wall column) is formed between the unit block holes 111. These partition walls can withstand the weight of the hydroponics pot 110 stacked on the top.

12 to 15 illustrate an assembly type flower pot according to still another embodiment of the present invention.
FIG. 12 is an exploded perspective view of the assembly type flower pot.
As shown in FIG. 12, this assembling type flower pot includes a water tank 250, a rotating plate 260, a rotating means 270, a large number of hydroponics pots 210, and a pot lid 240.
The water tank 250 is disposed in the lowermost layer and has a cylindrical shape so that a nutrient solution can be placed therein. The rotating plate 260 is disposed on the upper part of the water tank 250 and rotates. The rotating means 270 rotates the rotating plate 260. A large number of hydroponics pots 210 are sequentially stacked on the top of the rotating plate 260. The pot lid 240 is for covering the upper part of the hydroponics pot.

The water tank 250 contains nutrient solution to be supplied to the plant.
The nutrient solution contained in the water tank 250 is supplied to the rotating means 270 through a passage 252 connected to the rotating means 270. Then, the nutrient solution is supplied to the uppermost hydroponics pot 210 through the hose 274 by the rotating means 270.
A part of the nutrient solution in the uppermost hydroponics pot 210 flows into the lowermost hydroponics pot 210. And it flows to the water culture pot 210 of the next lower layer by the same system, and finally returns to the water tank 250.
The water tank 250 is preferably cylindrical so that the rotating plate 260 disposed on the upper part of the water tank 250 can rotate, but the shape is not limited at all.

The assembly type flower pot according to still another embodiment of the present invention may further include a plurality of ball bearings 251. These ball bearings 251 are intended to reduce the frictional force at the outer peripheral edge portion where the water tank 250 and the rotating plate 260 are in contact with each other and to make the rotating plate 260 rotate smoothly.
A portion where the water tank 250 and the rotating plate 260 are in contact with each other is preferably formed in a groove shape so that the ball bearing 251 is not detached.

A gear-shaped rotary plate gear 263 is formed on the edge portion of the outer peripheral side surface of the rotary plate 260. The rotating force from the rotating means 270 is transmitted to the rotating plate gear 263.
A bowl insertion port 262 is preferably formed on the upper surface of the rotating plate 260. The pot insertion port 262 has a size corresponding to the size of the insertion portion 214 of the hydroponic pot 210 so that the hydroponic pot 210 can be inserted.
In addition, a large number of eaves structural member holes 261 are formed in the upper surface of the rotating plate 260. A large number of hole 261 for the bowl structure member is formed around the bowl insertion port 262. A plant is planted in the hole 261 for the eaves structural member.
Here, a downward partition is formed around the perforated structure member hole 261. By this partition wall, the supporting force of the rotating plate is increased, and plant cultivation becomes easy.

FIG. 13 is a rear view of the rotating plate 260.
As shown in FIG. 13, a partition wall is formed around the perforated structure member hole 261 and the bowl insertion port 262. These partition walls are formed to be connected to each other so as to partition the bowl structural member hole 261 and the bowl insertion port 262. Further, the partition wall can withstand the load of the rotating plate 260.

In addition, as shown in FIG. 12, a hydroponics pot 210 is disposed on the upper layer of the rotating plate 260. The insertion part 214 of the hydroponics pot 210 is inserted into the pot insertion port 262 of the rotating plate 260.
The hydroponic pot 210 is preferably formed with a locking projection 213. The locking projection 213 is for preventing the insertion portion 214 from being inserted into the bowl insertion port 262 to a predetermined depth but being further inserted.

By covering the upper part of the hydroponics pot 210 with the pot lid 240, the other hydroponic pots 210 are not stacked. As in the case of the rotating plate 260, a downward partition is formed around the bowl insertion port 242 of the bowl lid 240. In addition, around the pot insertion opening 242 of the pot lid 240, a large number of persimmon structure member holes 241 capable of plant cultivation are formed. A downward partition is formed around each of the flange structural member holes 241.
These partition walls are formed by connecting the partition walls to each other so as to partition the bowl insertion port 242 and the bowl structural member hole 241 as in the case of the bowl insertion slot 262 and the bowl structural member hole 261 of the rotating plate 260. Is done. Thereby, the partition can support the hydroponics pot 210 firmly.
According to the assembly type flower pot of the present embodiment, since the partition wall is formed around the holes 241 and 261 for the cage structure member, the cage structure member becomes unnecessary.

  On the other hand, at least one opening 216 is formed in the lower surface of the hydroponics pot 210 so as to vertically penetrate this surface. The opening 216 may be formed so as to protrude upward from the lower surface by a predetermined height.

Further, the discharge hose 215 is arranged so as to protrude from the lower surface by a predetermined height through the opening 216 of the hydroponics pot 210. Thereby, the nutrient solution in the height lower than the height of the opening of the discharge hose 215 is accumulated in the hydroponics pot 210 without flowing into the lower layer.
In addition, the number of hydroponics pots 210 on which the assembly type flower pots according to the present invention are stacked is not limited at all.

The rotating means 270 according to this embodiment includes a pump 271, a water wheel 273, and a bevel gear 272.
The pump 271 pumps the nutrient solution in the water tank 250 to the uppermost hydroponics pot 210. The water turbine 273 is configured to rotate vertically by using the fall of the nutrient solution pumped up by the pump 271. The bevel gear 272 is meshed with the rotating plate gear 263, converts the vertical rotation of the water wheel 273 into horizontal rotation, and rotates the rotating plate 260 horizontally.
The rotating means 270 preferably further includes a hose 274 that can transport the nutrient solution from the water tank 250 to the uppermost hydroponics pot 210.

  The hose 274 is separated in two directions near the upper portion of the water wheel 273. Thereby, a part of nutrient solution is supplied to the water wheel 273 and the water wheel 273 is rotated. The remaining nutrient solution is supplied to the uppermost hydroponics pot 210.

The rotating means 270 preferably further includes an adjustment lever 275 and a flow path 276.
The adjustment lever 275 adjusts the amount of nutrient solution supplied from the hose 274 to the water wheel 273.
The flow path 276 is for allowing the nutrient solution supplied from the hose 274 to the water turbine 273 to flow in a constant direction at a stable speed, and has a structure like a rain gutter.

The ratio of the rotational speed of the rotating plate 260 to the rotational speed of the water wheel 273 is adjusted by the ratio of the gear ratio of the rotating plate gear 263 and the bevel gear 272. It goes without saying that this is obvious to those skilled in the art.
The rotating means 270 preferably further includes a housing 277. The housing 277 is for containing the nutrient solution supplied from the water tank 250 and the nutrient solution falling from the water wheel 273.

The housing 277 is configured to cover the entire rotation means 270 and protect the rotation means. Alternatively, the housing 277 may be configured to cover only a part of the rotating means 270 to protect the rotating means.
The housing 277 may be formed of a transparent material. Thereby, the rotation of the water wheel 273 and the flow of the nutrient solution can be visually recognized from the outside, so that the aesthetics are improved.

FIG. 14 is a combined perspective view of the assembly type flower pot of FIG.
FIG. 14 illustrates two hydroponic pots 210 stacked on the rotating plate 260, but the number of hydroponic pots 210 is not limited at all.
As shown in FIG. 14, in this assembling type flower pot, the rotating plate 260 is rotated by the rotating means 270 in a state where plants are planted in the hole 241 and 261 for the ridge structure members. Therefore, all plants can receive light uniformly from all directions.
The nutrient solution contained in the water tank 250 is supplied to the uppermost hydroponics pot 210 by the rotating means 270.

Hereinafter, the operation process of the assembly type flower pot according to the present invention will be described with reference to FIG.
First, the nutrient solution in the water tank 250 is supplied into the housing 277 of the rotating means 270 through the passage 252 and is pumped up through the hose 274 by the pump 271 of the rotating means 270.
A part of the pumped nutrient solution is supplied to the uppermost hydroponics pot 210, and the rest is supplied to the water turbine 273.
The nutrient solution supplied to the uppermost hydroponics pot 210 is put up to the height of the opening of the discharge hose 215. The nutrient solution further supplied beyond the height of the opening of the discharge hose 215 passes through the discharge hose 215 and is discharged into the lower hydroponics pot 210.

In the above process, the nutrient solution discharged from the lowermost hydroponics pot 210 is put to the height of the opening of the discharge hose 215. The nutrient solution further supplied beyond the height of the opening of the discharge hose 215 passes through the discharge hose 215 and is finally supplied to the water tank 250.
On the other hand, the nutrient solution supplied to the water turbine 273 side flows at a constant speed and in a constant amount on the flow path 276 and is supplied to the water turbine 273.
The water wheel 273 rotates vertically when the supplied nutrient solution falls. As a result, the bevel gear 272 rotates.
The bevel gear 272 converts vertical rotation into horizontal rotation. The bevel gear 272 rotates the rotating plate 260 when the horizontal gear rotates horizontally and meshes with the rotating plate gear 263 of the rotating plate 260.
A large number of hydroponics pots 210 stacked on top of the rotating plate 260 rotate together with the rotation of the rotating plate 260.
Therefore, plants in all directions planted in the persimmon structure member holes 241 and 261 can receive light uniformly from any direction by the rotation of the hydroponics pot 210 and the rotating plate 260.

  The preferred embodiments of the present invention described above are disclosed for illustrative purposes only, and various modifications, changes and variations within the spirit and scope of the present invention will occur to those skilled in the art having ordinary knowledge of the present invention. Addition is possible. Such modifications, changes and additions do not limit the scope of the present invention.

Claims (11)

In the assembly type flower pot,
With at least one hydroponics pot,
The hydroponics pot is composed of a pot insertion opening and an insertion part,
The pot insertion opening is provided at the top of the hydroponics pot,
The insertion portion has a locking projection that engages with the bowl insertion port, and an upward first opening and a second opening, respectively.
The assembly type flower pot further comprises:
A plurality of opening / closing unit blocks having holes for structural members,
The plurality of openable unit blocks are respectively inserted into a plurality of openable unit block holes formed around the pot insertion opening,
The assembly type flower pot further comprises:
A first hose passing through the first opening;
A second hose for passing through the second opening and adjusting the nutrient solution content;
And a pumping means for transferring the nutrient solution through the first hose by power.   The assembly type flowerpot according to claim 1, wherein a terminal end of the insertion portion has a gear structure. The assembly type flowerpot further includes a rotation holding member,
The rotation holding member is
A plurality of rollers arranged radially and a rotating gear meshing with the end of the insertion portion;
The assembly-type flower pot according to claim 2, further comprising a rotating means for applying power for rotating the rotating gear. A partition is provided between the opening and closing unit block holes,
2. The assembly type flower pot according to claim 1, wherein the partition wall is disposed between the openable unit blocks so as to support a left surface and a right surface of the openable unit block. In the assembly type flower pot,
A cylindrical aquarium containing nutrient solution,
A rotating plate disposed at the top of the aquarium and rotating;
Rotating means for rotating the rotating plate,
The rotating plate has a hole for a cage structure member into which a plant can be inserted,
The upper part of the rotating plate is provided with a pot insertion opening for receiving insertion of a hydroponics pot,
On the outer periphery of the rotating plate, a rotating plate gear for receiving transmission of rotational force from the rotating means is formed,
The assembly type flower pot further comprises:
Hydroponics pots that are inserted into the pot insertion opening and stacked,
A pot lid covering the top of the hydroponics pot,
The said pot lid is a prefabricated type flowerpot characterized by having a hole for a ridge structure member into which a plant can be inserted into a hydroponics pot. The rotating plate has a partition wall formed downward in the periphery of the pot insertion port that receives the insertion of the hydroponics pot,
The height of the said partition corresponds to the height of the said rotation board, The assembly-type flower pot of Claim 5 characterized by the above-mentioned. The pot lid has a partition wall formed downward in the periphery of the pot insertion port that receives the insertion of the hydroponics pot,
The height of the said partition corresponds to the said pot lid height, The assembly-type flower pot of Claim 5 characterized by the above-mentioned. The bowl lid has a hole for a bowl structure member provided in an upper part of the bowl lid, and a partition wall formed downward around the hole for the bowl structure member,
The assembly-type flower pot according to claim 5, wherein a plant can be inserted from the outside of the pot insertion port into the hole for the eaves structural member. The hydroponic pot has a locking projection formed on the outer peripheral surface of the lower part of the hydroponic pot,
The assembly type flower pot according to claim 5, wherein the locking protrusion limits an insertion depth of the rotating plate and the pot lid with respect to the pot insertion opening. The rotating means comprises a pump, a water wheel and a bevel gear,
The pump is for pumping nutrient solution from the aquarium to the uppermost hydroponics pot,
The water wheel rotates when a part of the nutrient solution pumped by the pump falls,
6. The assembly-type flower pot according to claim 5, wherein the bevel gear meshes with the rotating plate gear to convert vertical rotation of the water wheel into horizontal rotation to rotate the rotating plate. The assembly type flowerpot further includes a ball bearing,
6. The assembly type flower pot according to claim 5, wherein the ball bearing facilitates rotation of the rotating plate on a contact surface between the water tank and the rotating plate.

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