KR101585754B1 - Hydroponic flowerpot - Google Patents

Abstract

The present invention relates to a hydroponically cultivated flower pot which is capable of supplying a nutrient solution to a plant by repeatedly performing the operation of filling the nutrient solution completely so that the root is completely immersed and discharging it, A cultivating water tank in which a storage space is formed, a cultivation water tank provided on an upper portion of the nutrient solution tank and having an accommodation space for temporarily storing nutrient solution supplied from the nutrient solution tank, and at least one perforation hole At least one cultivating port for receiving the nutrient solution in the storage tank, at least one cultivation port to be fitted in correspondence with the perforation hole of the cultivation bed, and electrically operated to supply the nutrient solution contained in the storage space to the receiving space of the cultivation tank, An underwater pump, and a cultivation water tank, And a water supply pipe for discharging the nutrient solution from the cultivation water tank to the nutrient solution tank. Thus, the underwater pump is operated to supply the nutrient solution to the cultivation water tank through the water supply pipe, and the water is pumped until the roots of the plant are sufficiently locked. The water is returned to the nutrient solution tank through repetition of the operation and drainage operation. Thus, even though the water is used in a small amount, the nutrient solution is sufficiently supplied to the plant, Helping to stimulate the growth of plants.

Description

{Hydroponic flowerpot}

The present invention relates to a hydroponic cultivated flowerpot, wherein the nutrient solution is fully filled with the root of the plant, and then discharged repeatedly, thereby supplying sufficient nutrition to the plant at the time of watering, And to facilitate water management.

Generally, hydroponic cultivation can be largely classified into pale liquid type, thin film type, and spray type depending on the method of supplying nutrient solution (a mixture of water and water soluble fertilizer).

The pear liquid method is a traditional hydroponic cultivation method in which plants are planted on a cultivation box filled with a nutrient solution. The thin film method is a method in which nutrients are supplied to the root by flowing nutrients to the bottom of the cultivation box. , It has a disadvantage in that it has a long overall growth period since it can be formulated after the roots are sufficiently grown and causes serious environmental pollution due to excessive nutrient discharge especially during the growing process.

On the other hand, spray hardening is a method in which the nutrient solution is injected in the form of mist directly into the roots using a nozzle. Unlike the parenteral solution or the thin film type, since the amount of the nutrient solution is small, environmental pollution can be reduced. By repeating the operation, root respiration efficiency can be increased.

However, in order to finely spray the nutrient solution in such spraying hardness, an initial investment cost such as a plurality of nozzles, piping, a filter, and a high-pressure pump for connecting the nozzles is excessively high.

Particularly, in the spraying type, a gear pump is used because a high pressure is required to atomize the nutrient solution finely in the roots using a nozzle. Therefore, the gear pump is not only expensive but also has a high noise, short motor life, There are various problems such as a structural problem for accommodating the size of the pump.

On the other hand, in hydroponic cultivation, the nutrient solution is formed by sequentially dissolving and mixing essential elements such as nitrogen, phosphoric acid, galli, and essential trace elements such as iron, zinc, magnesium, boron, calcium, and manganese and amino acid sequentially. They can not bind to each other or settled on the floor and can not be supplied smoothly to the plants, thereby causing yellowing or premature growth of leaves.

Therefore, there is a problem that the nutrient solution must be replaced frequently and therefore the environment is contaminated, and the stored nutrient solution must be stirred at all times.

Korean Patent No. 10-0798142 (2008.01.18) Korean Patent No. 10-0824272 (Apr. 16, 2008) Korean Registered Utility Model No. 20-0416500 (2006.05.10) Korean Registered Utility Model No. 20-0389646 (July 7, 2005)

Therefore, the present invention can provide a balanced nutrition to plants even when water is used in a small amount until the root of the plant is fully submerged, and then repeats the operation of performing the complete drainage, and helps the root respiration The present invention aims at providing a hydroponically grown flower pot which can promote growth and simplify the parts required for production and can be manufactured at low cost.

To this end, the present invention provides a nutrient solution tank, comprising: a nutrient solution tank having a storage space for receiving a nutrient solution; a cultivation water tank provided at an upper portion of the nutrient solution tank and having an accommodation space for temporarily storing nutrient solution supplied from the nutrient solution tank; And at least one regeneration port which is fitted to the perforation hole of the re-feeding bed and at least one regeneration port which is installed at a lower portion of the nutrient solution tank and is contained in the storage space, An underwater pump which is electrically operated to supply the nutrient solution to the cultivation tank or the drainage pipe for discharging the nutrient solution from the nutrient solution tank to the nutrient solution tank while connecting the underwater pump and the cultivation tank to each other, Lt; / RTI >

In addition, the submersible pump has a built-in impeller in the channel of the casing, and the nutrient solution is supplied by rotation of the impeller. When the operation of the submerged pump is stopped, the submergence pump of the submersible pump itself becomes the discharge channel. Or can be recovered to the nutrient solution tank.

In addition, a drain may be provided to mount the tubular body on the bottom surface of the cultivation water tank to keep the water level of the nutrient solution constant.

Therefore, the present invention is a method of growing plants so that the roots of the plants can be respiration by repeating the process of discharging the roots after taking out the roots of the plant by utilizing the advantages of each of the leek solution type, the thin film type and the spray type, And it is possible to prevent environmental pollution by using less water in this process.

In addition, since the additives contained in the nutrient solution are naturally agitated during the drainage by the level difference, the nutrient solution can be supplied to the plants continuously and uniformly.

In addition, it is possible to operate only with a small AC submersible pump for an aquarium which is very cheap in price, and because it does not require additional parts such as SMPS, it can greatly reduce the manufacturing cost and the energy consumption for operation is very small. Can be used.

Especially, since AC motor has no commutator and brush structure, it has excellent durability, so it can reduce the occurrence rate of failure in long-term use, easy maintenance and management, easy to use at home, and easy to supply.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a sectional view showing one embodiment of the hydroponic pot of the present invention
Fig. 2 is an exploded perspective view of the hydroponically grown pollen of Fig. 1
Fig. 3 is an explanatory drawing showing the operating structure of the hydroponically grown flower pot of Fig. 1
Fig. 4 is a perspective view showing a mounting structure of the repositioning port of the present invention
5 is an exploded perspective view showing an assembling structure of the cultivation port of the present invention.
6 is a sectional view of the water level adjusting structure of the cultivating water tank using the drain of the present invention,
Figs. 7 and 8 are cross-sectional views showing another embodiment of the hydroponic pot of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 and 2, the present invention includes a nutrient solution tank 100 containing a nutrient solution, a cultivation water tank 200 mounted on an upper portion of the nutrient solution tank 100, (500) for supplying the nutrient solution contained in the nutrient solution tank (100) to the cultivation bath (200), and a water supply pipe (500) for supplying the nutrient solution contained in the nutrient solution tank (100) to the cultivation bath (300) (600).

A storage space 110 is formed in the nutrient solution tank 100 so that the nutrient solution tank 100 is formed in the shape of an enclosure having an open top, so that the nutrient solution can be received.

The cultivation water tank 200 is installed on the upper part of the nutrient solution tank 100, and the accommodation space 210 is formed so that the upper part of the nutrient solution tank 200 is formed in a shape of a hollow body.

It is preferable that the nutrient solution tank 100 and the cultivation water tank 200 are installed so that the cultivation water tank 200 is placed on the upper portion of the nutrient solution tank 100 by forming the flanges 120 and 220 on the upper rim of the nutrient solution tank 100 And the shape of each flange formed in the cultivation water tank 200 can be formed in such a manner that the cultivation water tank 200 is fastened and fixed while being inserted into the storage space 110 of the nutrient solution tank 100.

The water storage tank 200 is relatively smaller than the nutrient solution tank 100 so that the upper and lower depths of the cultivation water tank 200 are relatively lower than the depth of the nutrient solution tank 100 .

The cultivation bed 300 is mounted on the upper part of the cultivation bath 200. The cultivation bed 300 is provided with a perforation hole 310 penetrating upward and downward so that the regrowth port 400 is inserted into the perforation hole 310 do.

Preferably, the cultivation bed 300 has a step to be inserted into the upper surface of the cultivation bath 200 so that the rim of the cultivation bed 300 is seated.

The perforation hole 310 formed in the cultivation bed 300 and the cultivation port 400 inserted into the perforation hole 310 may be formed of one or more than two or more, Depending on the type of plant to be cultivated or the type of plant to be cultivated, it is possible to grow plants using one cultivation port 400 or arrange a plurality of cultivation ports 400 to cultivate a large amount of plants at the same time can do.

An electrically operated underwater pump 500 is installed in the lower portion of the nutrient solution tank 100 to supply the nutrient solution contained in the storage space 110 to the accommodation space 210 of the cultivation water tank 200, The pump 500 is equipped with a water supply pipe 600 connected to the cultivation water tank 200.

The underwater pump 500 is preferably installed on the bottom surface 130 of the nutrient solution tank 100. One end of the water supply pipe 600 is connected to the underwater pump 500 and the other end is connected to the cultivation water tank 200 And the nutrient solution supplied from the underwater pump 500 is supplied to the accommodation space 210 of the cultivation water tank 200.

The submerged pump 500 has a channel 520 formed in a casing 510 and an impeller 530 is embedded in the channel 520 to receive kinetic energy by rotation of the impeller 530, The nutrient solution contained in the storage space 110 is supplied to the cultivation water tank 200.

That is, when the underwater pump 500 is driven as shown in FIG. 3 in a state where the nutrient solution is contained in the storage space 110 of the nutrient solution tank 100, the impeller 530 of the underwater pump 500 is rotated, The nutrient solution passing through the water supply pipe 600 is continuously filled into the receiving space 210 of the cultivation water tank 200 while pushing the water on the channel 520 to the water supply pipe 600 by centrifugal force, ) Of the nutrient solution gradually increases.

When the nutrient solution to be filled in the cultivation water tank 200 reaches a necessary water level (preferably, the lower end of the pot can be slightly clipped), the nutrient solution is inserted into the roots or the cultivation port 400 planted in the cultivation port 400 The nutrient solution is absorbed by a culture sponge or the like inhung to the nutrient solution.

When the driving of the submersible pump 500 is stopped while the nutrient solution reaches the necessary water level, the nutrient solution is no longer supplied to the cultivation water tank 200 and the water supply pipe 600 is discharged from the nutrient solution tank 100 to the cultivation water tank 200 When the operation of the submersible pump 500 is stopped, the cultivation water tank 200 serves as a discharge channel for discharging the nutrient solution to the nutrient solution tank 100, 100), the nutrient solution is slowly drained.

At this time, when the nutrient solution is discharged to the nutrient solution tank 100 through the water supply pipe 600, the nutrient solution is discharged from the storage space of the nutrient solution tank 100 through the channel 520 in which the rotation of the impeller 530 is stopped Since the rotation of the impeller 530 is stopped as compared with the case where the nutrient solution is supplied by the underwater pump 500, the flow path is relatively narrow and the nutrient solution contained in the cultivation water tank 200 is slowly drained.

The upper end of the water supply pipe 600 may be connected to the bottom surface 230 of the cultivation water tank 200 by forming a through hole 235. The end of the water supply pipe 600 may be mounted So that the drainage of the nutrient solution contained in the cultivation water tank 200 can be performed.

In the process of recovering the nutrient solution through the water supply pipe 600 to the nutrient solution tank 100, the aeration phenomenon occurs and the amount of dissolved oxygen in the nutrient solution is increased.

Therefore, when the nutrient solution is supplied to the roots of the plant, the water is drained, and the roots of the plant are moistly moistened with the nutrient solution, and the ideal root respiration is actively performed. Ventilation promotes plant growth.

Also, in the case of a plant which is not able to grow hydroponics, if the nutrient solution is attached to the roots for a long time, root rot disease or melanosis will occur. It is possible to dry the roots by completely draining it. Therefore, it is possible to cultivate the plants which have not been able to grow hydroponics conventionally. Also, the plants that have already been hydroponically cultivated, including these plants, It is possible to increase the growth efficiency by assisting the oxygen breathing of the plant.

The submersible pump 500 can be a submerged pump having a small output. If a small AC pump is used, a separate electrical part (for example, an adapter) is not required. The submersible pump 500 can be purchased at a low cost, Lt; / RTI >

In addition, two or more cultivation tanks 200 may be installed in one nutrient solution tank 100. At this time, each underwater pump 500 is installed in a plurality of cultivation tanks 200, Alternatively, each of the cultivation tanks 200 may be provided with the positive water and the drain water sequentially.

The submersible pump 500 may further comprise a timer 800 for controlling the electrical operation.

The timer 800 adjusts the time in consideration of the capacity of the submersible pump 500 so that the nutrient solution is supplied to the required level of the cultivation tank 200. After a predetermined time has elapsed, The nutrient solution contained in the cultivation water tank 200 is flowed backward through the water supply pipe 600 and the underwater pump 500 to be slowly discharged to the nutrient solution tank 100 and the nutrient solution in the cultivation water tank 200 is completely drained .

The reed port 400 may be circular or polygonal. The reed port 400 may be formed in a shape of a narrow upper portion and a lower portion. The reed port 400 is inserted into the perforation hole 310 of the reed bed 300.

In the lower part of the cultivation port 400, a mounting space 410 is provided so that a culture sponge that is cultivated in a state in which plants are grown to some extent, A hole 420 is formed in the lower part of the tub 410 to allow the nutrient solution to be supplied to the culturing sponge while the roots of the plant are drawn through the hole 420 so that the root can be locked in the nutrient solution.

The hole 420 may be formed on the bottom surface or side surface of the reaping port 400, or may be formed on both the bottom surface and the side surface.

The cultivation port 400 may be formed by assembling the longitudinally divided part 430. The culturing sponge and the plant cultivated in the culturing sponge may be attached to the cultivation port 400 while assembling the divided part 430, The reapplication port 400 can be assembled and inserted into the reaming bed 300 so as not to damage the roots of the plant.

The divided divided bodies 430 can be easily assembled with the simple fitting structure by forming the fitting elements 435 to correspond to each other and can be easily assembled to the perforated holes 310 of the reed bed 300, .

At this time, the fitting element 435 does not need to be tightly fitted, and is merely sufficient for fixing the position. This is because the inner peripheral edge of the perforation hole 310 is formed in a state in which the regrowth port 400 is inserted into the perforation hole 310 It is held in close contact with the outer periphery of the re-cultivation port 400, so that the re-cultivation port 400 is not separated.

When the divided body 430 is assembled so as to have a folded structure in a hinge manner or when the divided body divided into two parts is integrally formed during molding, the divided body 430 can be opened and closed. So that the incubation sponge can be easily inserted or removed.

The cultivation water tank 200 may further include a drain 700 to maintain the level of the nutrient solution contained in the accommodation space 210 at a constant level.

The drain 700 is mounted on the tubular body 710 in the through hole 235 formed so as to penetrate the bottom surface 230 of the cultivation bath 200 upward and downward. When the nutrient solution reaches the required level, The water level of the nutrient solution tank 200 can be kept constant until the operation of the underwater pump 500 is stopped by the timer 800 by discharging the nutrient solution from the nutrient solution tank 710 to the nutrient solution tank 100.

The upper end of the tubular body 710 may be formed to have a height enough to come in close contact with the lower end of the reed port 400 or may have a height enough to partially lock the lower end of the reed port 400, It is preferable that the culture sponge stored in the cultivation port 400 is formed at a height enough to immerse the seed in order to seed the seed directly.

6, the height of the tubular body 710 is adjusted so that the level of the nutrient solution contained in the accommodating space 210 of the cultivation water tank 200 can be adjusted. At this time, the height of the tubular body 710 can be adjusted The upper and lower heights of the tube 710 can be adjusted by mounting the element 720.

As shown in the drawing, the height adjusting element 720 may be provided with an elastic material packing on the outer surface of the tube 710 to adjust the height of the packing to set the depth of insertion of the tube 710, It can be manufactured by applying various structures for adjusting the height of the tube, which are already known.

The upper end of the tubular body 710 may be curved in a shape of an ∩ shape and if the boundary water surface of the nutrient solution remaining in the accommodation space 210 of the cultivation water tank 200 is exceeded, 210 may be discharged into the storage space 110 of the nutrient solution tank 100.

That is, as shown in FIG. 7, the nutrient solution is not discharged until the nutrient solution filled in the storage space 210 of the cultivation water tank 200 reaches the boundary water surface near the upper end of the tube 710, The nutrient solution is discharged to the nutrient solution tank 100 through the tubular body 710 at atmospheric pressure and the entire amount is discharged by the siphon phenomenon. At the same time, the nutrient solution is discharged to the bottom of the cultivation water tank 200 All the remaining dirt and sediment is discharged.

Therefore, it is not necessary to separately manage the nutrient solution, foreign matter, etc. remaining in the cultivation water tank 200, which is easy to maintain and manage, and is convenient to wash and use.

In addition, as the water is sucked in, a pressure difference is generated and air is sucked into the cultivation water tank 200. In this process, air supply for root respiration of the plant is more actively performed, and the amount of dissolved oxygen .

At this time, when the lower end of the tubular body 710 is formed close to the bottom surface of the cultivation water tank 200, the amount of dissolved oxygen can be increased by increasing contact with air when the nutrient solution is discharged into the nutrient solution tank 100.

In addition, the swash plate 730 is attached to the lower end of the tube 710 so that the nutrient solution is unfolded while reducing the noise when discharging the nutrient solution, thereby further increasing the contact area with air.

The nutrient solution tank 100 may further include a water level sensing unit 900.

The water level sensing means 900 is mounted on the outside of the nutrient solution tank 100 with an exposure tube 910 which is made of a transparent or translucent material and is capable of measuring the water level and the upper and lower ends of the exposure tube 910 are connected to the nutrient solution tank 100 Through the penetrating member 920 so as to communicate with the storage space 110 of the storage space 110 so that the nutrient solution level in the storage space 110 can be confirmed from the outside.

100: Nutrient solution tank 110: Storage space
120: flange 130: bottom surface
200: Cultivation tank 210: Capacity space
220: flange 230: bottom surface
235: Through hole
300: Cultivation bed 310: Perforation hole
400: Cultivation port 410: Mounting space
420: hole 430:
435: Fitting element
500: Submersible pump 510: Casing
520: conduit 530: impeller
600: Water supply pipe
700: drain 710: tubular body
720: height adjustment element 730: swash plate
800: timer
900: Water level sensing means 910: Exposed tube
920:

Claims (10)

A nutrient solution tank (100) in which a storage space (110) is formed to receive a nutrient solution;
A cultivation water tank 200 provided at an upper part of the nutrient solution tank 100 and having a receiving space 210 for temporarily storing the nutrient solution supplied from the nutrient solution tank;
A cultivation bed (300) which is seated on the cultivation water tank (200) and in which at least one perforation hole (310) is formed;
At least one reaping port (400) corresponding to the perforation hole of the reaming bed (300);
An electrically operated underwater pump 500 installed at a lower portion of the nutrient solution tank 100 to supply the nutrient solution stored in the storage space 110 to the storage space 210 of the cultivation water tank 200;
The underwater pump 500 and the cultivation water tank 200 are connected to each other so that the nutrient solution in the nutrient solution tank 100 is used as a flow path for supplying the nutrient solution to the cultivation water tank 200 or the nutrient solution in the cultivation water tank 200 100), a water supply pipe (600) for selectively using the water supply pipe (600);
And,
The impeller 530 is installed in the channel 520 of the casing 510. When the power is applied, the impeller rotates to supply the nutrient solution of the nutrient solution tank 100 to the cultivation water tank 200, The nutrient solution contained in the cultivation water tank 200 is recovered into the nutrient solution tank 100 through the open water pipe and the casing,
The underwater pump 500 is provided with a timer 800 for periodically controlling the operation of the underwater pump 500 according to the set time so that the nutrient solution is supplied to the cultivation water tank 200, (100), the plants are pumped until the roots are fully submerged, and then drainage is repeated. delete The culture tank (200) according to claim 1, wherein a plurality of cultivation tanks (200) are mounted in one nutrient solution tank (200), and a cultivation bed (300) and a cultivation port And a plurality of cultivation water tanks (200) are caused to be pumped and drained at once or sequentially. [2] The method of claim 1, wherein the cultivation port (400) is formed with a mounting space (410) so that a culture sponge can be received therein, and a plurality And the reapplication port 400 is composed of a divided body 430 divided into two sides so that the plant and the culturing sponge can be easily inserted without damaging the roots of the plant. Cultivated flower pots. The cultivation apparatus according to claim 1, further comprising: a drain (700) mounted at a lower portion of the cultivation water tank (200) to maintain a constant level of the nutrient solution contained in the cultivation water tank (200) . 6. The water drainage system according to claim 5, wherein the drain (700) is installed so as to pass through the bottom surface (230) of the cultivation water tank (200) . [7] The method as claimed in claim 6, wherein the upper end of the tubular body (710) is curved in an inverted U-shape so that when the level of the nutrient solution sucked into the accommodating space (210) And the remaining nutrient solution is discharged into the storage space (110) of the nutrient solution tank (100). The tubular body (710) according to claim 6 or 7, wherein height of the tubular body (710) is adjustable up and down so that the level of the nutrient solution contained in the accommodation space (210) of the cultivation bath (200) A hydroponically grown flowerpot. delete 2. The hydroponics plant of claim 1, wherein the nutrient solution tank (100) further comprises a water level sensing means (900).

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