KR20220108979A - Continuous nutrient and oxigen supply type flowerpot for both soil and nutrient solution growing - Google Patents

Abstract

As a disclosed pot for continuous nutrient and oxygen supply and soil nutrient solution cultivation comprises a heat supply pipe, by a heat supply fluid flowing along the heat supply pipe, there is an advantage that cooling and heating can be supplied to the inside of a case member. The pot for continuous nutrient and oxygen supply and soil nutrient solution cultivation according to one aspect of the present invention comprises: the case member; and the heat supply pipe.

Description

Continuous nutrient and oxigen supply type flowerpot for both soil and nutrient solution growing

The present invention relates to a potted plant for continuous nutrient and oxygen supply-type soil nutrient solution cultivation.

Sunlight, water, and air are essential requirements for potted crops to grow.

It is that of the patent literature presented below that can be presented as an example of a flowerpot for cultivating such crops.

However, according to the conventional potted plants including the above patent documents, nutrients in the soil for planting crops in pots are gradually depleted over time. Therefore, there is a problem that not only the supply of nutrients is cumbersome, but also stresses the crops and causes the crops to die.

In addition, there is a problem in that the water in the pot to be supplied to the crops is not properly supplied with oxygen, so the water rots, and such rotten water adversely affects the crops.

In addition, there was a problem in that the level of water or nutrient solution in the pot is not easily recognized from the outside and in real time.

In addition, there was a difficult problem to supply heating and cooling for the inside of the pot.

Public Utility Model No. 20-2011-0002377, Release Date: 2011.03.09., Name of Design: A planter set in which a decorative flowerpot and a drip tray are integrally provided on a flowerpot stand

An object of the present invention is to provide a pot for continuous nutrient and oxygen supply in which the level of water or nutrient solution in the pot can be easily recognized from the outside in real time.

It is another object of the present invention to provide a continuous nutrient and oxygen supply-capable soil nutrient solution cultivation combined pot that can continuously and stably supply nutrients and oxygen to potted crops without replanting.

Another object of the present invention is to provide a continuous nutrient and oxygen-supplyable soil nutrient solution that can provide heating and cooling to the inside of the pot.

A pot for continuous nutrient and oxygen supply-able soil nutrient solution cultivation according to an aspect of the present invention includes a case body and a digestible food assembly protruding from each corner of the case body in an arc-shaped cross section of a certain curvature, the case a case member in which at least one of water and nutrient solution is accommodated in a lower portion of the main body and the digestive meal assembly; and

and a heat supply pipe disposed to wind the outer portion of the case member, and through which a heat supply fluid flowing from the outside flows along the inside to cool and cool the inside of the case member.

According to the continuous nutrient and oxygen supply type soil nutrient solution cultivation combined pot according to an aspect of the present invention, as the continuous nutrient and oxygen supply type soil nutrient solution cultivation combined pot includes a heat supply pipe, along the heat supply pipe Heating and cooling can be supplied to the inside of the case member by the flowing heat supply fluid, so that cooling in summer and heating in winter can be provided using the cold and hot heat of groundwater, which is the heat supply fluid, and circulation of groundwater Accordingly, it can absorb the daytime heat of the facility house, which is a place where the potted plant for continuous nutrient and oxygen supply is installed, and release it at night. has the effect of being cheaper.

1 is a perspective view showing an exploded state of a pot for continuous nutrient and oxygen supply-type soil nutrient solution cultivation combined use according to a first embodiment of the present invention.
2 is a cross-sectional view of a pot for continuous nutrient and oxygen supply-type soil nutrient solution cultivation according to the first embodiment of the present invention.
3 is another cross-sectional view of a pot for continuous nutrient and oxygen supply-type soil nutrient solution cultivation according to the first embodiment of the present invention.
Figure 4 is a perspective view showing a combined state of the potted plant for continuous nutrient and oxygen supply type soil nutrient solution according to the first embodiment of the present invention.
5 is a perspective view of a partition member applied to a pot for continuous nutrient and oxygen supply capable soil nutrient solution cultivation according to the first embodiment of the present invention, obliquely looking down from above.
6 is a perspective view of a partition member applied to a pot for continuous nutrient and oxygen supply capable soil nutrient solution cultivation according to a first embodiment of the present invention, as viewed obliquely from below.
7 is a perspective view showing an exploded state of a digestive component constituting a pot for continuous nutrient and oxygen supply-able soil nutrient solution cultivation according to a second embodiment of the present invention;
8 is a cross-sectional view showing a combined state of the digestive elements constituting the pot for continuous nutrient and oxygen supply-able soil nutrient solution cultivation according to the second embodiment of the present invention.
9 is a perspective view showing an exploded state of a pot for continuous nutrient and oxygen supply-type soil nutrient solution cultivation according to a third embodiment of the present invention.
10 is a perspective view showing a case member constituting a pot for continuous nutrient and oxygen supply-type soil nutrient solution cultivation combined use according to a third embodiment of the present invention.
11 is a cross-sectional view of a pot for continuous nutrient and oxygen supply-type soil nutrient solution cultivation according to a third embodiment of the present invention.
12 is another cross-sectional view of a pot for continuous nutrient and oxygen supply-type soil nutrient solution cultivation according to a third embodiment of the present invention.
13 is a perspective view showing a combined state of a potted plant for continuous nutrient and oxygen supply-capable soil nutrient solution cultivation according to a fourth embodiment of the present invention.
14 is a perspective view showing an exploded state of a potted plant that can continuously supply nutrients and oxygen according to a fourth embodiment of the present invention;
15 is a perspective view showing a state of a partition member constituting a pot for continuous nutrient and oxygen supply-type soil nutrient solution cultivation combined use according to a fourth embodiment of the present invention.
16 is a perspective view showing an upper spacer member constituting a pot for continuous nutrient and oxygen supply-capable soil nutrient solution cultivation according to a fourth embodiment of the present invention;
17 is a cross-sectional view showing a combined state of a pot for continuous nutrient and oxygen supply-able soil nutrient solution cultivation according to a fourth embodiment of the present invention.
18 is a perspective view of a potted plant for continuous nutrient and oxygen supply-type soil nutrient solution cultivation according to a fifth embodiment of the present invention.
19 is a view showing a pipe hanging member applied to a pot for continuous nutrient and oxygen supply-able soil nutrient solution cultivation according to a fifth embodiment of the present invention.
20 is a perspective view showing a state in which a plurality of pots for continuous nutrient and oxygen supply-capable soil nutrient solution cultivation are connected according to a sixth embodiment of the present invention;
21 is a perspective view showing an exploded state of a potted plant that can continuously supply nutrients and oxygen according to a sixth embodiment of the present invention;
22 is a perspective view showing a potted plant for continuous nutrient and oxygen supply-type soil nutrient solution cultivation according to a seventh embodiment of the present invention.

Hereinafter, with reference to the drawings, it will be described with respect to the continuous nutrient and oxygen supply type soil nutrient solution combined pots according to embodiments of the present invention.

1 is a perspective view showing an exploded state of a pot for continuous nutrient and oxygen supply-capable soil nutrient solution cultivation according to a first embodiment of the present invention, and FIG. 2 is a continuous nutrient and oxygen supply according to a first embodiment of the present invention. It is a cross-sectional view of a potted plant that can be cultivated with a soil nutrient solution, and FIG. 3 is another cross-sectional view of a pot for continuous nutrient and oxygen supply according to the first embodiment of the present invention, and FIG. 4 is a first embodiment of the present invention. A perspective view showing a combined form of a pot for cultivation of a continuous nutrient and oxygen supply type soil nutrient solution according to an embodiment, and FIG. 5 is a potted plant for cultivation of a continuous nutrient and oxygen supply type soil nutrient solution according to the first embodiment of the present invention 6 is a perspective view of the applied partition member obliquely looking down from above, and FIG. 6 is a perspective view of the partition member applied to the continuous nutrient and oxygen supply-capable soil nutrient solution cultivation combined pot according to the first embodiment of the present invention, as viewed obliquely from below.

Referring to FIGS. 1 to 6 together, the pot 100 for cultivating a continuous nutrient and oxygen supply type soil nutrient solution according to the present embodiment includes a case member 110 , a partition member 120 , and a digestive component member 130 . ) is included.

The case member 110 includes a case body 111 and a digester assembly 112 protruding from each corner of the case body 111 in an arc-shaped cross-section of a certain curvature, and the case body 111 . And in the lower portion of the digested food assembly 112, at least one of water and nutrient solution is accommodated.

The case body 111 is exemplarily formed in a form in which two pairs of flat plates facing each other form four sides, and long-term trees such as fruit trees and ornamental trees are planted in the soil of the main pot part of the case body 111 .

The digester assembly 112 is formed to be gradually narrower (tapered shape) downward toward each edge of the case body 111, and is formed to protrude more outward than each edge of the case body 111.

In this embodiment, the ratio of the portion at which the digestive component member 130 is caught on the digestive component assembly 112 is relatively compared to the portion at which the digestive component assembly 112 communicates with the case body 111 and is opened. formed larger. For example, when an imaginary circle is drawn by extending the curved surface of the digestive tract assembly 112, the portion where the digestive tract member 130 is caught is the actual wall portion of the digestive tract assembly 112. 112), which is formed to be relatively larger than the portion opened toward the inside of the case body 111 as a virtual circle portion. Then, the digester member 130 can be stably supported by the digester assembly 112 .

The upper end of the case body 111 and the digester assembly 112 is opened, and the lower end thereof is closed by the base plate. Then, soil in which crops can be planted may be contained in the case member 110 by the case body 111 and the digestive meal assembly 112 .

The case body 111 and the digester assembly 112 are further formed with a locking jaw 113 protruding in an inward direction, so that the partition member 120 can be caught on the locking jaw 113 .

The partition member 120 includes a partition body 121 hung on a predetermined height inside the case body 111 and a partition body 121 connected to the partition body 121 and hung on a predetermined height inside the digestive system assembly 112 . The compartment extended body 122, the body-side recessed protrusion 124 that is formed to be depressed to a predetermined depth downward from the compartment body 121 and is immersed in the liquid accommodated in the case member 110, and in the compartment extended body 122 It includes an extended body-side recessed protrusion 125 that is recessed downward to a certain depth and is immersed in the liquid accommodated in the case member 110, and hangs at a certain height of the liquid accommodated in the lower portion of the case member 110, and the upper portion thereof The soil is supported on the , and a part of the soil is drawn into the body-side recessed protrusion 124 and the extended body-side recessed protrusion 125 to come into contact with the liquid accommodated in the lower portion of the case member 110 .

The compartment body 121 is formed in the form of a square plate, and the compartment extension body 122 is formed to protrude in the form of an arc of a certain curvature at each corner of the compartment body 121 , so that the compartment member 120 is caught. When caught on the chin 113 and installed inside the case member 110 , the partition member 120 divides the inside of the case member 110 into upper and lower spaces. Water and air layers are formed in the lower space inside the case member 110 partitioned by the partition member 120 , and soil in the upper space inside the case member 110 partitioned by the partition member 120 . this will be acceptable.

The partition body 121 and the partition extension body 122 are formed in a form capable of air flow, such as being formed in a net shape, so that the air under the partition member 120 passes through the partition member 120 . (120) It can be supplied to the soil above.

Each lower portion of the body-side recessed protrusion 124 and the extended body-side recessed protrusion 125 is immersed in the liquid accommodated in the lower portion of the case member 110, and the body-side recessed protrusion 124 and the A plurality of through holes are also formed on each surface of the extended body-side recessed projection 125 . Then, part of the soil on the upper part of the partition member 120 is introduced into the body-side recessed protrusion 124 and the extended body-side recessed protrusion 125, so the body-side recessed protrusion 124 and Air and liquid inside the case member 110 may be supplied to the soil through each through hole of the extended body-side recessed protrusion 125 .

An upper protrusion 114 protruding upward from the center of the bottom surface 115 of the case member 110 is formed at a lower portion of the case member 110 , and the upper protrusion 114 is formed on the partition member 120 . A locking body 123 that can be caught in the upper portion is formed to protrude upward. In addition, a protrusion-side pore is formed on the upper portion of the upper protrusion 114 to allow external air raised through the upper protrusion 114 to flow into the case member 110 , and the locking body ( 123) is formed with a locking body-side pore 126 through which the air in the space below the partition member 120 can communicate with the soil on the upper side of the partition member 120 .

When formed as described above, the upper protrusion 114 is caught by the locking body 123 so that the partition member 120 is stably coupled to the inside of the case member 110 , and the upper protrusion 114 is closed. As a result, the external air rises and can be supplied to the air layer between the liquid chamber inside the case member 110 and the lower side of the partition member 120 through the pores on the protrusion side, so that the soil inside the case member 110 is fresh. It is possible to continuously supply oxygen as well as prevent the liquid contained in the lower portion of the case member 110 from rotting.

The digester member 130 is detachably coupled to the digester assembly 112, and a crop 10 planted in the soil above the partition member 120 and a separate crop 20 can be planted. will be.

In detail, the digester member 130 includes a digester body 131 formed in a cylindrical shape so as to be inserted into the digester assembly 112, and the digester body 131 is the digester assembly 112. A fire extinguisher catcher 132 formed in a band shape at the center or lower portion of the digester body 131 so as to be caught on the upper portion of the digester body 131, and a soil support 133 for supporting the soil contained in the digester body 131. includes

The soil support 133 is formed in the form of a net to allow air flow.

The lower surface of the digester body 131 is opened or a hole is formed to allow air flow, and the soil support 133 has a support so as to be positioned at a predetermined height from the lower surface of the digester body 131 . Then, an air layer is formed between the soil support 133 and the soil in contact with the bottom surface of the digester body 131 , so that oxygen can be continuously supplied to the soil on the soil support 133 , and the soil The compost fermented gas generated from within can be removed by flowing to the outside.

In this embodiment, the fire extinguisher hooking body 132 is formed to be recessed to a certain depth inside the fire extinguisher body 131 , and thus protrudes to the inside of the fire extinguisher body 131 . Then, while the digestive tract catcher 132 can be caught on the upper end of the digestive tract assembly 112 , the soil support 133 can be caught on the inner protruding portion of the digestive tract catcher 132 . .

Annual fruits and vegetables may be planted in the digestion member 130 .

When water is supplied for the growth of crops planted in the digestion member 130 , the nutrients contained in the digestion member 130 are naturally introduced into the soil inside the case member 110 , which is the main pot part. When this process is repeated and all the nutrients in the soil contained in the digester member 130 are exhausted, the digester member 130 is removed to put the nutrient-rich soil back in, and then placed in the digester hook 132 again. can be combined. Then, it is possible to continuously supply nutrients to the soil in the case member 110 without dividing the soil in the case member 110 , which is a part of the main pot.

Reference numeral 101 denotes a liquid supply pipe for supplying a liquid into the case member 110 , and reference numeral 102 denotes an overflow pipe that overflows when the liquid is excessively supplied into the case member 110 .

On the other hand, the continuous nutrient and oxygen supply type soil nutrient solution cultivation combined pot 100 further includes a liquid supply member 140 capable of supplying a liquid to the inside of the case member 110 .

The liquid supply member 140 includes a liquid container 141 containing a liquid supplied to the inside of the case member 110 , a cover 142 operably covering an upper portion of the liquid container 141 , and the liquid container. When the liquid level sensor 143 for detecting the level of the liquid contained in 141 and the liquid level sensed by the liquid level sensor 143 is relatively lower than a preset water level, an external water source ) and the like, including a liquid supply body 144 capable of supplying a liquid to the liquid container 141.

The liquid may be supplied manually by opening the cover 142 .

When formed as described above, the liquid supply member 140 can automatically supply the liquid to the inside of the case member 110 , thereby enabling stable and continuous liquid supply.

As described above, the case member ( Since liquid (or water), nutrients and oxygen can be continuously supplied to the crops planted in the main pot part of 110), long-term water such as fruit trees and ornamental water can be grown in the main pot part of the case member 110 without replanting. While possible, annual fruits and vegetables can be simultaneously grown in the digestion member 130 .

Hereinafter, with reference to the drawings, a potted plant for cultivating a soil nutrient solution capable of supplying continuous nutrients and oxygen according to a second embodiment of the present invention will be described. In carrying out such a description, the description overlapping with the content already described in the first embodiment of the present invention described above will be substituted for it, and will be omitted herein.

7 is a perspective view showing an exploded state of a digestive component constituting a pot for cultivation of a continuous nutrient and oxygen supply type soil nutrient solution according to a second embodiment of the present invention, and FIG. 8 is a second embodiment of the present invention. It is a cross-sectional view showing the combined appearance of the digestive elements constituting the pot for continuous nutrient and oxygen supply-capable soil nutrient solution cultivation.

7 and 8 together, in this embodiment, the fire extinguishing member 230 is composed of a fire extinguisher body 231, a fire extinguisher catcher 232, and a soil support 233, the fire extinguishing Minute stopper 232 is made in the form of a band protruding to the outside of the digestive meal body (231).

Hereinafter, with reference to the drawings, a continuous nutrient and oxygen supply type soil nutrient solution combined potted plant according to a third embodiment of the present invention will be described. In carrying out such a description, the description overlapping with the content already described in the first and second embodiments of the present invention described above will be omitted instead of it.

9 is a perspective view showing an exploded state of a pot for cultivation of a soil nutrient solution capable of continuous nutrient and oxygen supply according to a third embodiment of the present invention, and FIG. 10 is a continuous nutrient and oxygen supply according to another embodiment of the present invention. It is a perspective view showing a case member constituting a potable soil nutrient solution for cultivation combined use, and FIG. 11 is a cross-sectional view of a pot for continuous nutrient and oxygen supply according to a third embodiment of the present invention, and FIG. 12 is this Another cross-sectional view of a pot for continuous nutrient and oxygen supply-type soil nutrient solution cultivation according to a third embodiment of the present invention.

9 to 12 together, in this embodiment, a mesh member 350 that can prevent the intrusion of external pests is further installed.

The mesh member 350 includes a mesh 353 formed in a mesh shape to allow air flow while preventing the intrusion of external pests, an expanding part 352 that holds the mesh 353 to be spread out, and a partition member. The lower part of the locking body 323 protruding upward is inserted and erected, and the spreading part 352 includes a post 351 formed at the upper end thereof.

The mesh member 350 is detachably installed.

When formed as described above, while preventing the intrusion of external pests, air flow can be enabled.

In addition, the pot 300 for cultivating a continuous nutrient and oxygen supply type soil nutrient solution according to this embodiment includes a water level display member 360 that displays the level of at least one of the water and the nutrient solution accommodated in the case member 310 . include more

In detail, the water level indication member 360 includes a water level indication buoy 365 and a buoy guide 361 .

The buoy guide 361 protrudes from the inner wall of the case member 310, for example, one inner wall of the inner wall of the case body 111, and inside the buoy guide 361, the water level display buoy in the vertical direction ( 365) is formed so that it can be raised and lowered for water level indication. Then, the water level indicator buoy 365 by the buoy guide 361 can be lifted while being guided according to the water level in the case member 310 without arbitrarily falling over.

The water level indicator buoy 365 is formed in the form of a long rod with a predetermined length and is guided along the through hole in the buoy guide 361 and the buoy rod 366 that can be raised and lowered, and the lower part of the buoy rod 366 . Floating body 367 that is formed in and floats on at least one of water and nutrient solution in the case member 310 and is linked to the water level in the case member 310 while applying a load so that the buoy rod 366 does not fall over ) is included.

When the water level in the case member 310 is changed, the position of the buoy body 367 floating in the case member 310 is changed in conjunction with the fluctuating water level, at this time the buoy rod 366 is the It is possible to stably elevate along the buoy guide 361.

The water level in the case member 310 may be displayed according to the height at which the buoy rod 366 is exposed to the outside, in this case, a mark capable of displaying the water level on the buoy rod 366, for example, a rainbow color By forming the mark, the water level in the case member 310 can be easily recognized from the outside even by looking at the buoy rod 366 .

For example, since rainbow colors are sequentially displayed on the surface of the buoy rod 366, the water level can be recognized by looking at the exposed color of the buoy rod 366.

As described above, as the pot 300 for cultivating the continuous nutrient and oxygen supply type soil nutrient solution includes the water level display member 360 , at least one of water and nutrient solution accommodated in the case member 310 . The water level can be easily and real-time recognized from the outside.

In addition, in this embodiment, the continuous nutrient and oxygen supply type soil nutrient solution cultivation combined pot 300 further includes a mesh installation flange 316 .

The mesh installation flange 316 protrudes outwardly from the case member 310 so that at least a portion of the distal end of the mesh 353 is coupled, so that the mesh 353 is fixed to the case member 310 . , so that the mesh 353 is expanded in a relatively more extended form in the outer direction of the case member 310 .

The mesh installation flange 316 is formed in the form of a flange protruding a certain length to the outside from the outer wall between each fire extinguisher assembly 312 in the case body 311, and a fixing means (not shown) such as a bolt passes through. A coupling hole 317 is formed. As the fixing means passing through the mesh 353 passes through the coupling hole 317 , the mesh 353 can be fixed to the mesh installation flange 316 .

Hereinafter, with reference to the drawings, a potted plant for cultivation of a continuous nutrient and oxygen supply type soil nutrient solution according to a fourth embodiment of the present invention will be described. In carrying out such a description, the description overlapping with the content already described in the first to third embodiments of the present invention described above will be substituted for it, and will be omitted herein.

13 is a perspective view showing a combined appearance of a pot for cultivation of a continuous nutrient and oxygen supply type soil nutrient solution according to a fourth embodiment of the present invention, and FIG. 14 is a continuous nutrient and oxygen supply according to a fourth embodiment of the present invention. It is a perspective view showing the disassembled state of the potable soil nutrient solution cultivation combined use, and FIG. 15 is a perspective view showing the appearance of the partition members constituting the continuous nutrient and oxygen supply type soil nutrient solution combined flowerpot according to the fourth embodiment of the present invention 16 is a perspective view showing an upper spacer member constituting a pot for cultivation of a continuous nutrient and oxygen supply type soil nutrient solution according to a fourth embodiment of the present invention, and FIG. 17 is a fourth embodiment of the present invention It is a cross-sectional view showing the combined appearance of a pot for cultivation of a soil nutrient solution capable of continuous nutrient and oxygen supply.

13 to 17 , the pot 400 for continuous nutrient and oxygen supply capable soil nutrient solution cultivation according to the present embodiment includes a case member 410 , a partition member 420 and a digestive component member 430 and Together, it further includes an upper spacer member 470 and an upper input member 480 .

In this embodiment, the partition member 420 includes a partition body 421 , a partition extension 422 , a body-side recessed protrusion 424 , and an extended body-side recessed protrusion 425 , together with a partition-side fixing protrusion 427 . ) is further included.

A plurality of the partition-side fixing protrusions 427 protrude from the partition body 421 and the partition extension 422 to be spaced apart from each other, and a portion of the upper spacer member 470, in detail, an upper and lower extension body (to be described later) ( 475) is caught and fixed.

The upper spacer member 470 includes an upper spacer body 471 hung on a predetermined height from the partition member 420 above the partition member 420 in the case member 410, and the upper spacer body ( 471), the upper spaced extension body 472 extending outward, and the upper spaced body 471 and the upper spaced extension body 472 are respectively extended by a predetermined length downward to each of the compartment-side fixing protrusions 427. The plurality of upper and lower extensions 475 to which the lower ends are fixed, and the upper spaced body 471 and the upper spaced extension 472 each extend a certain length upward, so that the digestive component 430 is spread over the upper portion. A plurality of upper upper extensions 478 and the upper ends of the upper upper extension body 471 and the upper upper extension body 472 are spaced apart from each other so that the lower ends of the upper upper extension bodies 478 are fixed. and a fixing protrusion 477 .

When the upper spacer member 470 is inserted into the case member 410 in a state in which the partition member 420 is installed inside the case member 410 , the respective partition-side fixing protrusions 427 are attached to each other. The upper and lower extension body 475 is fixed, so that the upper spaced body 471 and the upper spaced extension body 472 are above the partition member 420 and spaced apart from the partition member 420 at a height spaced apart from each other. can be fixed.

In a state in which the partition member 420 and the upper spacer 470 are installed inside the case member 410 , when the fire extinguisher member 430 is raised, the fire extinguisher member 430 moves upward and downward. It is hooked on the upper portion of the extension body 478 so that the fire extinguishing member 430 is hooked and fixed at a predetermined height from the upper spaced body 471 and the upper spaced apart extension body 472 .

One side of the fire division member 430 is caught inside the case member 410 , and the other side of the fire division member 430 is caught on the upper portion of the upper upper extension 478 .

Mesh-shaped holes are formed in the upper spaced body 471, the upper spaced extension body 472, the upper lower extension body 475, and the upper upper extension body 478, so that air and water can freely penetrate have.

The upper input member 480 is coupled to the upper portion of the upper upper extension 478 in a state in which the digester member 430 is caught, and fixes the digester member 430, while also providing fertilizer and It becomes a passage through which at least one of the water is introduced, and becomes a passage through which oxygen is supplied from the upper side.

The upper input member 480 is in communication with the upper upper extension body 478, so that at least one of fertilizer and water input through the upper input member 480, and oxygen supplied through the upper input member 480 can spread into the soil through the upper upper extension 478 . Therefore, fertilizer, water, and oxygen can be supplied not only through the lower side of the pot 400 for continuous nutrient and oxygen supply-capable soil nutrient solution, but also through the upper side on the same day.

As described above, as the upper spacer member 470 is further installed together with the partition member 420 , a phenomenon in which the soil accommodated in the case member 410 is compacted by its own weight can be prevented, and accordingly Fertilizer, water, and oxygen may be more smoothly supplied into the soil through the partition member 420 as well as the upper spacer 470 , and the gas formed in the soil may be more smoothly discharged.

In this embodiment, the case member 410 has a leaf that is relatively tall, such as a water loss in the soil, and can form a shade over the pot 400 for continuous nutrient and oxygen supply. Perennial plants are planted, and accordingly, a shade is formed on the digestive member 430 by the leaves of the perennial plant, so that the digestive member 430 is cultivated in a semi-shade environment such as ginseng, lettuce, etc. Plants can be planted.

It is inserted into the styrofoam in the digestion member 430, so it is possible to cut and plant the stem of a plant to form a root and grow it.

Reference numeral 485 denotes a solar member, which receives solar heat from the solar member 485 to form hot water and then supplies it to the inside of the case member 410, and receives sunlight from the solar member 485 to generate electricity Then, electricity may be supplied for the operation of the continuous nutrient and oxygen supply type soil nutrient solution combined pot 400 .

Hereinafter, with reference to the drawings, a potted plant for cultivating a continuous nutrient and oxygen supply type soil nutrient solution according to a fifth embodiment of the present invention will be described. In carrying out such a description, the description overlapping with the content already described in the first to fourth embodiments of the present invention described above will be replaced with it, and will be omitted here.

18 is a perspective view of a pot for cultivation of a continuous nutrient and oxygen supply type soil nutrient solution according to a fifth embodiment of the present invention, and FIG. 19 is a continuous nutrient and oxygen supply type soil nutrient solution according to a fifth embodiment of the present invention. It is a drawing showing a pipe hanging member applied to a planter for cultivation combined use.

18 and 19 together, the pot 500 for continuous nutrient and oxygen supply type soil nutrient solution according to the present embodiment further includes a heat supply pipe 590 .

The heat supply pipe 590 is disposed to wind the outer 510 of the case member, and a heat supply fluid flowing from the outside flows along the inside to cool and cool the inside of the case member 510 .

The heat supply pipe 590 is disposed to wind at least one turn around the central portion of the case member 510 , so that the heat supply fluid flowing from the outside flows along the heat supply pipe 590 and the case member Through 510, the inside of the case member 510 is cooled and cooled.

That is, in a hot environment in which the ambient temperature is relatively high compared to the inside of the pot 500 for cultivation of the continuous nutrient and oxygen supply type soil nutrient solution 500, such as in summer, the heat supply fluid flows along the heat supply pipe 590 By obtaining the heat inside the case member 510, the inside of the case member 510 can be cooled, and compared to the inside of the continuous nutrient and oxygen supply type soil nutrient solution culture pot 500, such as in winter. In a cold environment where the ambient temperature is relatively low, the heat supply fluid flows along the heat supply pipe 590 and transfers heat to the inside of the case member 510 , thereby increasing the temperature inside the case member 510 . can become

Here, when the inside of the case member 510 is cooled by the heat supply fluid, moisture in the air around the case member 510 is condensed on the outer surface of the case member 510 to form condensed water, A place where the continuous nutrient and oxygen supply type soil nutrient solution cultivation pot 500 is installed, for example, the humidity inside the facility house can also be controlled.

The heat supply fluid may be groundwater supplied from the ground.

A plurality of the continuous nutrient and oxygen supply type soil nutrient solution cultivation combined pot 500 is arranged side by side, and the heat supply pipe 590 continuously applies the continuous nutrient and oxygen supply type soil nutrient solution cultivation combined pot 500 By being formed in a winding form, the plurality of continuous nutrient and oxygen supply-capable soil nutrient solution cultivation pots 500 can be heated and cooled together.

In addition, the continuous nutrient and oxygen supply type soil nutrient solution culture pot 500 according to the present embodiment may further include a pipe hanging member 595 .

The pipe hanging member 595 supports the heat supply pipe 590 wound on the outer surface of the case member 510 so that the heat supply pipe 590 is preset on the outer surface of the case member 510 . It is to maintain a position on a predetermined height.

In detail, the pipe hanging member 595 is connected to the case member 510 so that the heat supply pipe 590 can be positioned on the predetermined height on the outer surface of the case member 510 , and the It supports the heat supply pipe (590).

In detail, the pipe hanging member 595 includes an upper hanger 597 caught in a predetermined portion of the case member 510, for example, a coupling hole 517 of the mesh installation flange 516, and the upper hanger 597. A pipe hanger body 596 that extends by a predetermined length from the case member 510 and is arranged in a lowered form along the outer surface of the case member 510, and an outward pipe hanger body that protrudes outward from the lower portion of the pipe hanger body 596 ( 598), and a pipe seating groove 599 in which the heat supply pipe 590 is placed because the upper surface of the pipe hanger outward body 598 is recessed.

A plurality of the pipe hanging members 595 are applied to be spaced apart from each other along the periphery of the case member 510 , thereby supporting the heat supply pipe 590 at various parts of the case member 510 .

As described above, as the pot 500 for cultivating the continuous nutrient and oxygen supply type soil nutrient solution includes the heat supply pipe 590, by the heat supply fluid flowing along the heat supply pipe 590 , heating and cooling can be supplied to the inside of the case member 510, so that cooling in summer and heating in winter can be provided using the cold and hot heat of groundwater, which is the heat supply fluid, and according to the circulation of groundwater, It can absorb the daytime heat of the facility house, which is the place where the soil nutrient solution for continuous supply of nutrients and oxygen is installed, and release it at night. can become cheaper.

Hereinafter, with reference to the drawings, a potted plant for cultivating a soil nutrient solution capable of supplying continuous nutrients and oxygen according to a sixth embodiment of the present invention will be described. In carrying out such a description, the description overlapping with the content already described in the first to fifth embodiments of the present invention described above will be replaced with it, and will be omitted here.

20 is a perspective view showing a state in which a plurality of pots for cultivation of a continuous nutrient and oxygen supply-capable soil nutrient solution are connected according to a sixth embodiment of the present invention, and FIG. It is a perspective view showing the disassembled form of a potable soil nutrient solution that can be grown.

20 and 21 together, in the present embodiment, a heat supply pipe 690 is arranged along a plurality of continuous nutrient and oxygen supply-capable soil nutrient solution cultivation pots 600, and the heat supply pipe 690 ) branched pipe 691 for cooling and heating passes through the inside of the potable plant 600 for continuous nutrient and oxygen supply type soil nutrient solution.

In detail, the branch pipe 691 for heating and cooling, which extends from a part of the heat supply pipe 690, is connected to the inside of the continuous nutrient and oxygen supply type soil nutrient solution cultivation combined pot 600, for example, a partition member ( The upper part of the partition body 621 constituting the 620) and the upper part of the upper spacer body 671 constituting the upper spacer member 670 are respectively bent and unfolded a plurality of times, and the branch pipe for heating and cooling (691). The end is connected to the other part of the heat supply pipe (690).

When configured as described above, some of the heat supply fluid, such as groundwater, which has flowed along the heat supply pipe 690 flows through the branch pipe 691 for heating and cooling, and the continuous nutrient and oxygen supply type soil nutrient solution can be cultivated. It is possible to provide hot and cold heat directly to the root of a plant planted in the pot 600, so that energy can be saved, and the stem of the plant can be attracted along the heat supply pipe 690, so that humidity occurs in the plant disease can be prevented.

Hereinafter, with reference to the drawings, a pot for continuous nutrient and oxygen supply-capable soil nutrient solution cultivation according to a seventh embodiment of the present invention will be described. In carrying out such a description, the description overlapping with the content already described in the first to sixth embodiments of the present invention described above will be replaced with it, and will be omitted here.

22 is a perspective view showing a pot for continuous nutrient and oxygen supply-type soil nutrient solution cultivation according to a seventh embodiment of the present invention.

Referring to FIG. 22 , in this embodiment, the water supply branch pipe 792 is branched from the heat supply pipe 790 separately from the branch pipe 791 for heating and cooling, and the water supply branch pipe 792 is continuously connected through the pipe 792 . It is possible to directly supply water to the inside of the nutrient and oxygen supply-type soil nutrient solution combined pot 700 .

In detail, the water supply branch pipe 792 is branched from the heat supply pipe 790 , and at the end of the water supply branch pipe 792 , a plurality of water discharge nozzle pipes 793 are branched, and each water discharge A discharge nozzle tip 794 is formed at the end of the nozzle pipe 793, and the discharge nozzle tip 794 is the continuous nutrient and oxygen supply type soil nutrient solution combined pot (700). Heading.

The discharge nozzle tip 794 may be opened only at a predetermined pressure or higher, so that groundwater, which is a heat supply fluid flowing through the water discharge nozzle pipe 793 , may be supplied to the root of the plant.

Normally, when water supply is not required, since the water discharge nozzle pipe 793 is closed, water supply through the discharge nozzle tip 794 is not made, but when water supply is required, the heat supply fluid is pumped. By increasing the flow pressure of the heat supply fluid flowing through the heat supply pipe 790 in a manner such as increasing the pressure of the pump, the discharge nozzle tip 794 is opened, and thus the heat supply A portion of the heat supply fluid that has flowed through the pipe 790 flows through the water supply branch pipe 792 and each water discharge nozzle pipe 793 , and then through the discharge nozzle tip 794 , the root of the plant can be supplied directly to the

By being configured as described above, it is possible to solve the problem that the conventional water supply line and the heating line are separately configured so that the structure is complicated and the installation cost is excessive, and it is possible to provide the water supply line and the heating/cooling line in an integrated manner.

In the above, the present invention has been shown and described with respect to specific embodiments, but those of ordinary skill in the art can variously modify the present invention within the scope without departing from the spirit and scope of the present invention as set forth in the claims below. and can be changed. However, it is intended to clearly state that all such modifications and variations are included within the scope of the present invention.

According to the continuous nutrient and oxygen supply type soil nutrient solution cultivation combined pot according to an aspect of the present invention, the level of water or nutrient solution in the pot can be easily recognized in real time from the outside, and nutrients are continuously supplied to the potted crops without replanting. And oxygen can be stably supplied, and since it can supply heating and cooling to the inside of the pot, its industrial applicability is high.

100: Pot for continuous nutrient and oxygen supply type soil nutrient solution cultivation combined use
110: case member
120: partition member
130: absence of digestion
140: liquid supply member
316: mesh mounting flange
360: No water level indication
361 : Buoy Guide
365 : water level indicator buoy
590: heat supply piping
595: pipe hanger member

Claims (5)

It includes a case body and a digestive meal assembly protruding from each corner of the case body in an arc-shaped cross section of a certain curvature, wherein at least one of water and nutrient solution is accommodated in the lower portion of the case body and the digestive component assembly case absent; and
A continuous nutrient and oxygen supply type soil comprising a; is disposed in a shape that winds the outer portion of the case member, and a heat supply pipe through which a heat supply fluid flowing from the outside flows along the inside to cool and cool the inside of the case member A potted plant for nutrient solution cultivation. The method of claim 1,
In an environment where the ambient temperature is relatively high compared to the inside of the continuous nutrient and oxygen supply type soil nutrient solution combined pot, the heat supply fluid flows along the heat supply pipe to obtain heat inside the case member, The inside of the case member may be cooled,
In an environment where the ambient temperature is relatively low compared to the inside of the pot for continuous nutrient and oxygen supply type soil nutrient solution, the heat is transferred to the inside of the case member while the heat supply fluid flows along the heat supply pipe, A pot for continuous nutrient and oxygen supply-type soil nutrient solution cultivation, characterized in that the inside of the case member can be heated. 3. The method of claim 2,
The heat supply fluid is a continuous nutrient and oxygen supply type soil nutrient solution cultivation combined pot, characterized in that the groundwater supplied from the ground (underground). The method of claim 1,
The continuous nutrient and oxygen supply type soil nutrient solution combined potted plant
By supporting the heat supply pipe wound on the outer surface of the case member, the heat supply pipe can maintain a position at a predetermined height on the outer surface of the case member; A continuous nutrient and oxygen supply-type soil nutrient solution that can be grown as a combined pot. 5. The method of claim 4,
The pipe hanging member is
an upper hook caught on a predetermined portion of the case member;
a pipe hanger body extending by a predetermined length from the upper hanger and arranged in a lowered form along the outer surface of the case member;
A pipe hanger outward body that protrudes outward from the lower part of the pipe hanger body;
The continuous nutrient and oxygen supply type soil nutrient solution cultivation combined pottery, characterized in that it comprises a pipe seating groove in which the heat supply pipe is placed because the upper surface of the external pipe hanging body is recessed.

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