KR20160001429U - Flowerpot for water culture - Google Patents

Abstract

The present invention relates to a pollen for hydroponic cultivation, comprising: a container part in which a plant is placed; A first receiving unit for receiving water supplied to a root of the plant; And a second receiving part extending from the first receiving part to communicate with the first receiving part and having an end opened to install the container part and a through hole formed in the outer surface so that the water is discharged to the outside, .
Thereby, there is provided a pot for hydroponics which can efficiently clean the whole space of the inner bottom of the first hydrangea receiving the water supplied to plants efficiently and easily.

Description

{FLOWERPOT FOR WATER CULTURE}

The present invention relates to a pollen for hydroponic cultivation, and more particularly, to a method of cleaning, maintaining, and maintaining the inside of a first hydraulic vessel using a through hole formed in a second hydraulic vessel so that water contained in the first hydrocarbons is discharged to the outside. The present invention relates to a pot for hydroponic cultivation that can facilitate management.

Hydroponic cultivation means a method of growing plants in a culture medium made of water and water-soluble nutrients without using soil.

Such hydroponic cultivation has an advantage that it can be utilized for ornamental use because it can directly observe the roots and the growth state of the above-mentioned plants and can be easily cultivated indoors. The hydroponic cultivation described above is used to cultivate an extracellular plant or an extinct plant such as Peppermia, Ivy, or Lucky Tree, which is provided with a hairy root.

Hydroponic cultivation is generally carried out by placing the plant in a net-like container and then placing the vessel on the top of the water tank or pot containing the water to allow the root of the plant to come into contact with the water.

After the hydroponic cultivation has been carried out, as time elapses, the water contained in the water tank or the flowerpot becomes turbid due to the foreign matter produced or separated in the plant or the like, whereby the float or the like floats on the bottom surface of the flowerpot or the water tank.

When these floats are left untouched, fungi are generated in the pollen or water tank, and the fungi that are generated are parasitic on the roots of the plants and inhibit the growth of the plants. In addition, since pollen or a water tank is made of a transparent glass material or the like, impurities and floating matters are not well-formed. Therefore, there is a need to remove foreign matters and suspended matters from the pots or water tanks.

In addition, in the case of the water tank or the flowerpot described above, the tubular goldfish or the like is put into the interior of the water tank or the flowerpot in many cases. In such a case, the generation of floating matters or foreign matter in the water tank or the flowerpot is accelerated by goldfish or the like, so that it is necessary to carry out washing and maintenance more frequently in the water tank or the flowerpot.

The cleaning and maintenance described above are generally carried out as follows. First, the user separates the network in which the plant is accommodated from the tank or the flowerpot. Thereafter, the user directly removes the water contained in the water tank or pot by moving the water tank or pot to the drainable area. Thereafter, the user cleans the inside of the water tank or pot, and then injects water again. That is, in the case of such general washing and repairing, the user must directly move the water tank or the flowerpot. When the size of the plant is relatively small, the mesh type container and the water tank or the flowerpot are also provided in a small size, so that it is relatively easy for the user to move the water tank or the flowerpot.

However, when the size of the plant is large, the net-shaped container and the water tank or the flowerpot are also provided in a large size, and accordingly, the amount of the water contained in the water tank or the flowerpot is proportionally increased. Therefore, when hydroponic cultivation of such a large plant is carried out, not only a lot of labor is applied to remove the water contained in the water tank or the flowerpot, to wash the inside and then to inject the water again, Problems can arise.

The object of the present invention is to solve the above-mentioned problems, and it is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to provide a water- And a pollen for hydroponic cultivation that can facilitate management.

According to the present invention, the above object can be achieved by a container unit in which plants are seated; A first receiving unit for receiving water supplied to a root of the plant; And a second receiving part extending from the first receiving part to communicate with the first receiving part and having an end opened to install the container part and a through hole formed in the outer surface so that the water is discharged to the outside, The present invention relates to a hydroponics planting pot.

The through holes may be formed in a plurality of holes.

The through holes may be formed on an outer surface of the second receiving portion so that imaginary straight lines perpendicular to the central axis of the second receiving portion are spaced 120 degrees from each other.

The apparatus may further include a pump unit inserted into the through-hole to allow the water contained in the first receiving unit to flow out to the outside.

The pump unit may include a first hose inserted into the through hole and a second hose connected to the first hose and configured to contract and relax due to an external pressure so that the water accommodated in the first hose receiving unit is introduced into the first hose unit, And a second hose connected to the pressure module for receiving the water from the pressure module and discharging the water to the outside.

According to the present invention, it is possible to facilitate the cleaning, maintenance and management of the interior of the first receiving portion by using the through holes formed in the second receiving portion so that the water contained in the first receiving portion is discharged to the outside.

Further, by using the through holes, the fertilizer to be supplied to the roots of the plants can be easily injected into the first receiving portion.

In addition, in the case of culturing a coral goldfish or the like inside the first water receiving portion, it is possible to easily feed food such as a goldfish ornamental fish into the first water receiving portion by using the through holes.

Further, by using a plurality of through holes formed in the second receiving portion, the entire space inside the first receiving portion can be cleaned without any gaps.

Further, by using three through holes formed in the outer surface of the second receiving portion so that imaginary straight lines perpendicular to the central axis of the second receiving portion passing through the center of the through hole are spaced apart from each other by 120 degrees, Thereby efficiently cleaning the entire space.

Further, the space inside the first receiving portion can be easily cleaned by using the pump portion which is inserted into the through hole and allows the water contained in the first receiving portion to flow out.

1 is a perspective view of a pollen for hydroponics according to an embodiment of the present invention,
Fig. 2 is an exploded perspective view of the pollen for hydroponic cultivation of Fig. 1,
Fig. 3 is a side view of the pot for hydroponic cultivation of Fig. 1,
Fig. 4 is a plan view of the portion A-A 'shown in the side view of the flowerpot of Fig. 1,
Fig. 5 shows the pump section of the pot for hydroponic cultivation of Fig. 1,
Fig. 6 is a view showing the pump section of the pot for hydroponic cultivation shown in Fig. 1 inserted into the through hole,
FIG. 7 is a view showing a state in which foreign matters and floating matters settled on the bottom of the first water receiving portion of the pot for hydroponic cultivation of FIG. 1 are removed.

The pollen for hydroponics according to one embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Fig. 1 is a perspective view of a pollen for hydroponics according to an embodiment of the present invention, Fig. 2 is an exploded perspective view of the pollen for hydroponic cultivation of Fig. 1, Fig. 3 is a side view of the pollen for hydroponic cultivation of Fig. FIG. 5 is a plan view of a portion of the hydroponics pot shown in FIG. 1 taken along the line A-A 'in FIG. 5, and FIG. 6 is a plan view of the pump portion of the hydroponic cultivation pot, FIG. 7 is a view showing a state in which foreign substances and floating matters settled on the bottom of the first water receiving portion of the pot for hydroponic cultivation of FIG. 1 are removed.

1 to 7, the pollen 100 for hydroponics according to one embodiment of the present invention includes a container 110, a first water receiving unit 120, a second water receiving unit 130, (140).

The container portion 110 is inserted into the open end of the second receiving portion 130 to be described later by placing the plant p thereon.

The container unit 110 forms a plurality of exposure holes on the outer surface so that the roots of the plant p may be exposed to the outside of the lower side. When the plant p is placed inside the container 110, the roots of the plant p are exposed to the outside through the above-described exposure holes. In addition, a plurality of gravel or the like may be accommodated in the container 110 so that the plant p can be supported.

The first receiving part 120 receives the water supplied to the root of the plant p and is integrally extended from the second receiving part 130 to be described later and is connected to the second receiving part 130 .

It is necessary that the water is filled in the first receiving unit 120 until it comes into contact with the bottom surface of the container unit 110 described above. In order to supply water to the plant p, water must be in contact with the roots of the plant p. The roots of the plant p are exposed to the outside through the exposure holes, Because it extends to the lower side.

In addition, the first receiving part 120 may be formed of a transparent glass material. Since the tubular goldfish or the like can be accommodated in the first receiving unit 120, the first receiving unit 120 is preferably made of a transparent glass material so that the tubular goldfish or the like can be observed from the outside . However, the material of the first receiving part 120 is not limited thereto, and any material and form may be used as long as it can receive water supplied to the root of the plant (p).

The second receiving part 130 is extended from the first receiving part 120 so as to communicate with the first receiving part 120. The end of the second receiving part 130 is opened so that the container 110 is installed. A through hole (v) through which water contained in the trough (120) can be discharged to the outside is formed on the outer surface.

The container portion 110 is provided at the open end of the second receiving portion 130 so that the water contained in the second receiving portion 130 can be supplied to the root of the plant p accommodated in the container portion 110 When the container portion 110 is removed from the open end, water can be supplied to the second receiving portion 130 through the open end.

On the other hand, a pump unit 140 to be described later is inserted into the through hole v. At this time, it is preferable that the end of the first hose 141 is inserted deeply so as to be close to the bottom surface of the first hosing portion 120. Then, when the user presses the pressure module 142 of the pump unit 140, water, foreign matter, floating matters, etc. close to the bottom surface of the first receiving unit 120 are introduced into the first hose 141, (142) and the second hose (143).

As the volume of the first receiving portion 120 increases, the area of the bottom surface of the first receiving portion 120 also widens. The end portion of the first hose 141 is limited in the range of movement of the end portion of the first hose 141 adjacent to the bottom surface of the first hose coupling portion 120 through the through hole v, It can not be close to the entire bottom surface of the bottom surface of the substrate. Therefore, it is preferable that a plurality of through-holes v are formed on the outer surface of the second receiving unit 130.

The through holes v are formed on the outer surface of the second receiving unit 130 so that imaginary straight lines perpendicular to the central axis of the second receiving unit 130 are spaced apart from each other by 120 degrees, More preferably, it is formed. When the two through holes v are spaced at an angle of less than 120 degrees, the first hose 141 inserted in the other through hole v is in contact with the bottom surface of the first receiving portion 120, Is relatively inefficient because it has to be relatively wide.)

As shown in FIG. 4, when the three through holes v are respectively formed at a distance of 120 degrees from the center of the second hose 130, the first hose 141 The end portion of the first hose 141 can be easily brought closer to the entire bottom surface of the second receiving portion 130. [

7, when the first hose 141 is inserted into the through hole v formed on the right side, it is possible to remove the foreign matter and suspended matter deposited on the first surface s1, When the first hose 141 is inserted into the hole v, it is possible to remove the foreign matter and suspended matter deposited on the second surface s2, and the first hose 141 with the through hole v formed at the center In the case of inserting, the foreign substances and suspended matters precipitated on the third surface s3 can be removed.

Therefore, according to the three through holes (v) spaced 120 degrees from the center of the second receiving portion 130, the entire bottom surface (first surface s1, second surface s1) of the second receiving portion 130, (s2), the third surface (s3), and the like) can effectively be removed.

When the first hose 141 is not inserted into the above-described through hole v, that is, when there is no need for cleaning and maintenance, a finishing portion (not shown) is inserted into the above- . By this closing portion, the water contained in the first receiving portion 120 can be easily prevented from flowing out to the outside through the through hole (v) by an external impact.

In addition, the second receiving unit 130 may be made of a transparent glass material. Since the tubular goldfish or the like can be accommodated in the first receiving unit 120, the second receiving unit 130 can be transparent (transparent) like the first receiving unit 120 so that the tubular goldfish or the like can be observed from the outside. As shown in FIG. The finishing portion (not shown) is also made of a transparent material as in the case of the second receiving portion 130, which is aesthetically pleasing.

Therefore, according to the second receiving portion 130 forming the through hole v, the inside of the first receiving portion 120 can be easily cleaned, maintained, and managed. It is also possible to easily feed the fertilizer to be supplied to the root of the plant p into the first receiving part 120 by using the through hole v and to insert the tubular goldfish or the like into the first receiving part 120 It is possible to easily feed the food such as the ornamental goldfish into the first receiving portion 120 by using the through holes v.

The pump 140 is inserted into the through hole v and allows water contained in the first receiving part 120 to flow out to the outside so that the first hose 141, the pressure module 142, 143).

The first hose 141 is inserted into the above-described through hole (v), and is connected to a pressure module (142) described later. The pressure module 142 is contracted and relaxed by external pressure so that the water contained in the first receiving portion 120 is introduced into the first hose 141 so that one end of the pressure module 142 is connected to the first hose 141 And the other end is connected to the second hose 143, which will be described later. The second hose 143 receives water from the pressure module 142 and discharges the water to the outside. One end of the water is connected to the pressure module 142, and the other end of the water is disposed in a drainable area.

When the user pressurizes the pressure module 142 to generate pressure, water, foreign matter, floating matters, and the like contained in the first receiving portion 120 are absorbed to the end portion of the first hose 141 by the generated pressure. Thereafter, the inflowed water, foreign matter, floating matters, etc. are flowed to the pressure module 142 by the generated generated pressure, and then discharged to the outside (drainable area) through the second hose 143.

In addition, the pressure module 142 may be connected to a motor (not shown) driven by an electric force to generate a pressure, so that the first hose 141 may introduce water, foreign matter, suspen- sion, or the like.

According to the pump unit 140 including the first hose 141 and the pressure module 142 and the second hose 143, it is possible to prevent the user from moving the water tank to the drainable area, The space inside the first receiving part 120 can be easily cleaned by inserting the pump part 140 into the first receiving part 120 and pressing the pressure module 142. [

Therefore, according to the hydroponic potting pot 100 according to one embodiment of the present invention including the container 110, the first hydropower part 120, the second hydropower part 130 and the pump part 140, , The whole space of the inner bottom of the first water receiving part 120, which receives the water supplied to the plant p, can be efficiently cleaned efficiently and easily.

The scope of the present invention is not limited to the above-described embodiments, but may be embodied in various forms of embodiments within the scope of the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as claimed in the appended claims.

100: Pollen for hydroponics according to one embodiment of the present invention
110: container part 120: first receiving part
130: second receiving portion 140: pump portion
141: first hose 142: pressure module
143: 2nd hose
p: Plant v: Through hole
s1: first side s2: second side
s3: Third side

Claims (5)

A container portion on which the plant is seated;
A first receiving unit for receiving water supplied to a root of the plant;
And a second receiving part extending from the first receiving part to communicate with the first receiving part and having an end opened to install the container part and a through hole formed in the outer surface so that the water is discharged to the outside, Wherein the plant is cultivated in a pot. The method according to claim 1,
Wherein the through-holes are formed in a plurality of holes. 3. The method of claim 2,
Wherein the through holes are formed on an outer surface of the second receiving portion so that imaginary straight lines perpendicular to the central axis of the second receiving portion are spaced apart from each other by 120 degrees, passing through the center of the through hole, . 4. The method according to any one of claims 1 to 3,
And a pump unit inserted into the through hole to allow the water contained in the first receiving unit to flow out to the outside. 5. The method of claim 4,
The pump unit includes:
A pressure module connected to the first hose and configured to cause the water accommodated in the first hosepiece section to flow into the first hose section by being contracted and relaxed by an external pressure; And a second hose connected to the pressure module for receiving the water from the pressure module and discharging the water to the outside.

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