KR20130068830A - Gardening pot for 3-dimensional greening and 3-dimensional greening system using the same - Google Patents

Abstract

PURPOSE: A liquid crystal display device is provided to easily improve response characteristics without using a manufacturing apparatus of a large scale, and to give a significantly large pre-tilt stability (a high orientation stability) to a liquid crystal molecule. CONSTITUTION: A liquid crystal display device has 'a pair of alignment layers(22,32) provided at an opposite surface side of a pair of substrates(20,30)' and 'a liquid crystal layer(40) including a liquid crystal molecule having a negative dielectric anisotropy provided between the pair of alignment layers'. At least one of the pair of alignment layers includes 'a compound cross-linked with a polymer compound having a cross-linking functional group as a side chain', a pre-tilt is given to the liquid crystal molecule by using the cross-linked compound, and at least one compound represented by Formula 101: CH_(4-n)(R^1)_n or Formula 102: (R^2)_m-A-(X)_p is included in the liquid crystal layer.

Description

Plant cultivation container for stereoscopic recording and stereoscopic recording system using the same {GARDENING POT FOR 3-DIMENSIONAL GREENING AND 3-DIMENSIONAL GREENING SYSTEM USING THE SAME}

The present invention relates to stereoscopic recording technology. Specifically, the present invention relates to a three-dimensional green plant cultivation container and a three-dimensional green plant cultivation system using the same.

Conventional urban greening has been recognized as the concept of planar greening after planing greenery on natural ground or growing soil layer on artificial ground, but in order to secure more green space on natural or artificial ground of narrow area in the city center. The three-dimensional green space is more efficient than the flat green space, and the urban aesthetics can be expanded. Anyone can appreciate the need for a three-dimensional recording system that is an improvement over the conventional planar recording system.

On the other hand, in the conventional technology that can cultivate a large amount of plants such as flowers or vegetables in a limited narrow space has been proposed in the domestic patent No. 032158, Patent No. 0500019 and the like.

The former patent No. 0332158 discloses a stacked plant cultivator 11, as shown in Figs. A spacing holder 12 for maintaining the spacing of the plant cultivation period; Rotating base 13 for rotating the multi-layer plant cultivator; A pipe 14 having a supply hose 15 for supplying the nutrient solution to the top plant cultivator; A water supply unit 16 installed at an upper end of the pipe 14 to eject the nutrient solution; The diffusion pad 17 and the circulation pump 19 are installed at the pipe 14 position below the spacing holder 12 so that the nutrient liquid ejected from the water fountain 16 is sprayed to the plant cultivator 11. It includes a built-in nutrient solution tank (18).

In the above configuration, the nutrient solution is pumped through the supply hose 15 of the pipe 14 by the operation of the circulation pump 19, and is discharged through the water fountain 16. The ejected nutrient solution flows into the gap holding region 12 and flows, and the nutrient solution flows to the lower plant cultivator 11 through the diffusion pad 17, and the nutrient solution flowing out to the lower part of the plant cultivator is located in the lower layer again. Flows into the gap retaining zone 12 and is stored. This operation is repeated so that the nutrient solution is sprayed to the lowest plant cultivator.

The latter patent No. 0500019 technology is, as shown in Figure 3, formed upright in a multi-layer, plant cultivator 31 arranged in a number of rows; A spacing holder 32 for maintaining a spacing between the plant cultivators 31; Rotating base 33 for rotating the multi-layer plant cultivator; A vertical pipe 34 installed between the plurality of planters 31 arranged in a row, and having a plurality of branch pipes formed therein; A water supply pipe 35 for supplying water to the vertical pipe 34; Nozzles 36 connected to branch pipes of the vertical pipes 34 and for supplying water to individual plant cultivators 31; The water discharged through the upper and lower water circulation pipes (37, 38) and the lower water circulation pipe (38) for collecting water discharged to the lower part of the plant cultivator (31) to be introduced into the external water tank again It includes a circulation pump (39).

When the nutrient solution which is a mixture of nutrients and water filled in the water tank is supplied to the vertical pipe 34 through the water supply pipe 35, the nutrient solution to the plant cultivator through the nozzle 36 connected to the branch pipe of the vertical pipe 34 Is supplied.

The nutrient solution discharged from the plant cultivator 31 is collected in the lower water circulation pipe 38, and is supplied to the water supply pipe again from the circulation pump 39.

These structures can be cultivated vertically by cultivating a growing plant to increase the cultivation area and to cultivate crops efficiently, and when used for horticulture, various kinds of flowers can be grown and plant cultivators in the form of columns. Because it is deployed, it provides the advantage that it can be used for ornamental purposes.

In addition, the structure is provided with a separate means for supplying the nutrient solution, and separately installed a cold and hot water supply device capable of supplying water in response to the temperature change according to the season, it is possible to produce year-round regardless of high-temperature obstacles and cold seas, And seedlings are provided.

However, the stacked plant cultivator of the above structure has a simple structure in which the plant cultivator is stacked up, and although the water supply and circulation pipe for irrigation are provided, the structure cannot be arranged in various forms. Since there is no suitable irrigation system, there is a problem that it is not suitable as a landscaping facility for the purpose of improving the aesthetics of the city buildings or for the ornamental use.

In the layered three-dimensional plant cultivation method of the above proposed structure, water flowing along the uppermost plant cultivation vessel flows to the ground through the lower cultivation vessel.

Because of this, the growing soil in the plant cultivation vessel located at the bottom absorbs the water excessively, so that the plant of the plant cultivation vessel located at the bottom may cause severe obstacles. In addition, when the plants planted in the plant cultivation vessel of the upper layer is contaminated by growing soil pollution or pests, the plants of the lower layer are naturally contaminated by water discharged to the plant cultivation vessel of the lower layer after irrigation.

In particular, the three-dimensional plant cultivation method has a problem that can be easily damaged due to all the irrigation facilities exposed to the outside.

In general, flowers or vegetable plants need a constant amount of moisture and nutrients, and the general public who wants to grow these plants is difficult to determine the proper amount and time of supply of water or nutrient solution. There is a problem that the cultivated plant is dead or does not grow smoothly.

The present invention has been proposed in order to solve the above problems, the present invention is equipped with an independent water supply and drainage in each of the three-dimensional planting containers for cultivating each other interfering viruses between plants planted in each plant growing container It is an object of the present invention to provide a stereoscopic recording system capable of preventing infection.

In addition, the present invention provides a water supply function and a drainage function to the plant cultivation container as an independent individual, and the water cultivation and drainage classification by allowing each plant cultivation container to be connected to each other organically up, down, left and right It is another purpose of the user to arrange the plant cultivation container in various forms as needed to create a variety of artistically landscaped three-dimensional green sculptures for the landscape landscape of the city.

In addition, another object of the present invention is to provide a plant cultivation system capable of freshly cultivating a plant and promoting smooth growth by supplying an appropriate amount of nutrient solution at an appropriate time according to the characteristics of the plant.

The present invention relates to a body;

A drain pipe of the body provided inside the body;

A drain provided on a bottom surface of the body and not closed by a drain pipe of the body;

A soil receiving portion detachably provided in the body, the soil receiving portion provided with an opening for accommodating or removing a plant or soil and at least one drainage hole, and separated from the liquid passing through the drain pipe of the body. ; And

It is a plant cultivation container including a water supply means for supplying water or nutrient solution through the opening of the soil receiving portion,

Each unit of the plant cultivation container provides a planting container for stereoscopic greening, characterized in that the water supply and drainage independently.

The present invention also provides a frame in which two or more of the three-dimensional green plant cultivation container is fixed.

In addition, the present invention is two or more plant cultivation containers for three-dimensional greening; And it provides a stereoscopic greening system comprising a frame fixed to the two or more stereoscopic planting containers for planting.

As stated above, according to the present invention, a plant cultivation container provided with a water supply and drainage system is constituted by each individual individual, and the plant cultivation container is arranged in various forms in the upper, lower, left, and right directions, and as a three-dimensional green sculpture in the city. It is possible to install. For example, tower-shaped three-dimensional green sculptures that can be installed in front of parks, rotarys, plazas, and entrances to buildings, wall-solid green sculptures that can be installed on walls outside buildings, and large lobby rooms such as hotels and department stores. Interior wall surface stereoscopic green sculptures that can be installed on walls, Fence-type stereo green sculptures that are used for boundary fences such as school fences or factory fences, and retaining walls stereoscopic green sculptures that are installed on stone retaining walls or concrete retaining walls, viaducts or bridges It can be applied to various ranges such as stereoscopic green sculptures for hanging rails installed on railings and stereoscopic green sculptures for replacing soundproof walls between roads and apartments. As a result, urban heat island phenomena are improved by improving urban aesthetics, absorbing air pollutants such as carbon dioxide and sulfur dioxide, mitigating air pollution by supplying oxygen through green plants, and restoring urban ecosystems by creating biological habitats and green spaces in urban areas. It can exhibit mitigating and controlling earth humidity.

In particular, it is possible to secure more green space by securing three-dimensional green space instead of securing a flat green space on a natural or artificial ground in a narrow area in the city center.

In addition, in the present invention, by separately installing a water supply and drain line (Line) in each plant cultivation container, it is possible to prevent pest virus infection between cultivated plants and to facilitate the smooth growth of cultivated plants. In addition, it is easy to replace the cultivated plants with the topsoil (上 土) simply by replacing the soil receiving portion of the cultivated plant container, there is always an effect that can be observed with a new three-dimensional greening sculptures according to the seasonal change.

In addition, when the stereoscopic greening system according to the present invention includes a drop button or a timer, an appropriate amount of water or nutrient solution (water containing nutrients) can be supplied to each plant cultivation container independently at a proper time according to the characteristics of the cultivated plant. Therefore, the smooth growth of cultivated plants can be promoted.

1 and 2 is a cross-sectional view showing an example of a stacked plant cultivation apparatus according to the prior art.
Figure 3 is a perspective view showing another example of the stacked plant cultivation apparatus according to the prior art.
Figure 4 is an exploded perspective view showing the configuration of the three-dimensional planting container for planting according to the present invention.
5 is an assembled perspective view of FIG.
6 is a side view of Fig.
Figure 7 is a side cross-sectional view showing a coupling configuration of the three-dimensional planting container for planting according to the present invention.
Fig. 8 shows the configuration of the wall stereoscopic recording system as the first embodiment of the present invention.
9 is a side view of FIG. 8.
Fig. 10 is a side cross-sectional view of a soundproof wall stereoscopic recording system as a third embodiment of the present invention.
Fig. 11 is a perspective view showing the structure of a Higgs stereo recording system as a fourth embodiment of the present invention.
12A to 12F show a frame configuration of a tower type stereoscopic recording system as a fifth embodiment of the present invention.
FIG. 13 is a perspective view of a tower type stereoscopic recording system using the frame of FIG. 12E.
Fig. 14 shows the structure of a three-dimensional recording system for a street lamp or a park lamp hanger as a sixth embodiment of the present invention.
Fig. 15 shows the structure of a columnar stereoscopic greening system as a seventh embodiment of the present invention.

The present invention relates to a body;

A drain pipe of the body provided inside the body;

A drain provided on a bottom surface of the body and not closed by a drain pipe of the body;

A soil receiving portion detachably provided in the body, the soil receiving portion provided with an opening for accommodating or removing a plant or soil and at least one drainage hole, and separated from the liquid passing through the drain pipe of the body. ; And

It is a plant cultivation container including a water supply means for supplying water or nutrient solution through the opening of the soil receiving portion,

Each unit of the plant cultivation container provides a planting container for stereoscopic greening, characterized in that the water supply and drainage independently.

The soil receiving portion may be a polygonal tubular shape in which the horizontal cross-sectional shape of the ground surface is any one of a triangle, a square, a pentagon, a hexagon, a hexagon, and an octagon, and specifically, the horizontal cross-sectional shape of the ground surface is a square or a rectangle. It may be a tubular shape of.

With respect to the same volume of plant cultivation container, when the horizontal cross-sectional shape of the bottom surface of the soil receiving portion is rectangular, there is an advantage that the capacity of the soil accommodated in the soil receiving portion is large. Specifically, when the horizontal cross-sectional shape of the bottom surface of the soil receiving portion is rectangular, the capacity of the soil accommodated in the soil receiving portion is more advantageous than the cylindrical soil receiving portion.

This allows many plants to be planted in one soil receptacle and, in some cases, two or more plants together. As described above, when two or more plants are planted together in one soil receiving unit, due to the effect of growing and competing with each other, the plant may grow healthier than when planting only one type of plant.

In the present invention, since the water supply line and the drainage line are separately provided as the independent plant cultivation container for three-dimensional greening, it is possible to prevent contamination of the growing soil and viral infection between cultivated plants due to plant pests.

In the present invention, the drain port serves to drain the liquid drained from the drain pipe of the body and the liquid drained from the soil receiving portion.

In the present invention, the drain pipe and the drain of the body do not necessarily have to be connected. When two or more plant cultivation vessels are disposed in the vertical direction, the liquid drained from the drain pipe and the drain of the plant cultivation vessel located on the upper side may pass through the drain pipe and the drain of the plant cultivation vessel located on the lower side. The shape and location are not particularly limited as long as the liquid passing through the drain pipe does not flow into the soil container.

In one embodiment of the drain pipe of the body, the side of the drain pipe of the body is connected to the inner surface of the body so that the lower end of the drain pipe of the body may be away from the lower surface of the body. That is, the drain pipe of the body is spaced apart from the lower surface of the body, the drain pipe of the body may be supported by connecting to the inner surface of the body.

In this case, it is not connected to the drain provided on the bottom of the body. At this time, by adjusting the center of the drain pipe of the body and the center of the drain so that the drainage passing through the drain pipe of the body can be introduced into the drain.

In addition, another embodiment of the drain pipe of the body, as shown in Figure 4, a portion of one end of the drain pipe of the body is connected to the drainage hole between the lower surface of the body and the drain pipe of the body (62a) This can be formed. That is, a part of one end of the drain pipe of the body is connected to the drain port, a hole 62a may be provided on the side of the drain pipe of the body. In this case, through the hole located on the side of the drain pipe of the body, the liquid flowing from the soil receiving portion can be discharged to the drain.

In the present invention, when the two or more plant cultivation vessels are arranged in the vertical direction, the drain port is located below the drain pipe of the plant cultivation vessel located on the upper side and the liquid drained from the drain port does not flow in the other direction. It is preferable to have a structure projecting downward so that it can be introduced into the drain pipe of the plant cultivation vessel.

In addition, the drain port may be further provided with a drain connection pipe so that the connection with the drain pipe of the plant cultivation vessel located in the lower side more easily, the drain connection pipe may be provided to be detachable to the drain. .

In addition, it is connected to the lower end of the drain connection pipe, it may include a removable drain connection lake. The drain connection lake may be coupled to a drain or drain connection pipe, and may be specifically fitted fitting. In this case, the coupling method may be a method known to those skilled in the art, but is not limited thereto.

In the present invention, the soil receiving portion is preferably formed on the inclined surface so that even when the plant cultivation vessel is disposed two or more vertically, the opening is accommodated and exposed to the plant can be observed from the outside. It is preferable that the inclined surface forms an angle of more than 0 degrees and less than 90 degrees, preferably 15 degrees or more and 75 degrees or less with respect to the lower surface of the plant cultivation container. The soil receiving portion may be provided so that the opening is positioned on the inclined surface as described above by one edge of the opposite side of the opening supported by the drain pipe of the body.

At least one water supply or drainage hole of the soil container may be provided at a wall surrounding the opening. The water supply or drainage hole may include a plurality of holes provided in the bottom surface direction of the soil container from the opening. When the wall surrounding the opening is an inclined surface having an inclination with respect to the horizontal plane, at least one water supply hole may be provided at an upper side of the wall surrounding the opening so that liquid supplied from the upper side may flow. In addition, at least one drain hole may be provided at a lower side of the wall surrounding the opening to allow the water to be drained.

The soil receiving portion may be provided with at least one protrusion on the wall surrounding the opening to allow the liquid supplied from the upper side to stay without flowing down the wall due to the inclination. In this case, the protrusion is installed around the water supply hole to help the liquid supplied from the upper side to flow into the soil receiving portion through the water supply hole.

In the present invention, the plant cultivation container may include a fixing plate provided to cover a part of the opening of the soil receiving portion. Specifically, the fixing plate may cover an opening closer to the bottom surface of the plant cultivation container among the openings of the soil receiving portion. In this way, when the opening of the soil container is formed on the inclined surface with respect to the lower surface of the plant cultivation container, the inclination can prevent the soil in the soil container and the water supplied from flowing into the opening of the soil container.

In the present invention, the plant cultivation container may be provided with a protrusion for supporting the soil receiving portion on the inner lower surface of the body. This may support the bottom surface of the soil container in which the protrusion is inclined when the soil container itself is formed on an inclined surface with respect to the bottom surface of the plant cultivation container.

In the present invention, a drain plate may be further provided between the soil container and the drain port. The drain plate is preferably provided with at least one, preferably a plurality of drain holes. The drain plate may prevent the drain port from being blocked by soil, plants, or other foreign matter that may flow out of the soil receiving portion, and may reduce the degree of contamination of the drained liquid.

The water supply system of one embodiment of the plant cultivation container may be independently supplied with water through the water supply hole of each soil receiving portion.

In addition, the water supply system of another embodiment of the plant cultivation container may include a water supply means for supplying water through the opening of the soil receiving portion, without forming a water supply hole in the soil receiving portion. The water supply means includes a drop spike having a hollow in the longitudinal direction inside, one end of the water supply means may be inserted into the soil receiving portion. That is, it can be used directly plugged into the soil contained in the soil receiving unit.

The plants in each plant cultivation vessel can be supplied with water or nutrient solution directly through a water supply means plugged into the soil receptacle.

This has the advantage of supplying water or nutrient solution to plants efficiently even with a small amount of water or nutrient solution.

The water supply means in which the hollow is formed in the longitudinal direction is not particularly limited as long as the hollow is formed therein so that water or nutrient solution can flow and can be inserted into the soil. Specifically, it may be a drop spike.

The water supply means in which the hollow is formed in the longitudinal direction may include a drop button connected to the water supply pipe, a water supply lake connected to the drip button, and a drop spike connected to the water supply lake to supply water to the individual plant cultivation vessel from the water supply pipe.

In addition, the drainage system of each plant cultivation vessel may be drained from the soil receiving portion through the drain.

At this time, the drain pipe of the body is connected to the inner surface of the body, if away from the bottom of the body, the drainage discharged from the soil receiving portion may be discharged directly to the drain of the body.

When a part of one end of the drain pipe of the body is connected to the drain and has a hole in the side of the drain pipe of the body, the drainage discharged from the soil receiving portion is formed in the side of the drain pipe of the body It can pass through and be discharged to the drain.

The installation method of one embodiment of the plurality of plant cultivation containers can be installed vertically.

When a plurality of plant cultivation vessels are arranged vertically, the drainage liquid introduced into the drain port is moved to the drain pipe of the plant cultivation vessel located below.

The height of the lower end of the drainage port of the upper plant cultivation container, the height of the lower end of the drainage connection pipe of the drainage port of the upper plant cultivation container, It is preferable that the height of the lower end of the drain connection lake connected to the drain connection pipe of the upper plant cultivation vessel is lower than the height of the upper end of the drain pipe of the lower plant cultivation vessel.

At this time, the soil receiving portion may include a drain line connecting groove directed toward the inside of the soil receiving portion from the edge of the lower surface so that the drain, drain connection pipe or drainage connection lake of the upper plant cultivation vessel extends to the drain pipe of the lower plant cultivation vessel. have.

The installation method of another embodiment of the plurality of plant cultivation vessel can be installed horizontally.

When the plurality of plant cultivation vessels are arranged horizontally, it may be provided with a separate drain line for receiving the drainage from the drain, drain connection pipe or drain connection lake of the plant cultivation container. The drainage flowed into the drainage line moves to the drainage storage tank for storing the drainage.

It is preferable that the said three-dimensional green-vegetation plant container is provided with the clip for fixing to the frame mentioned later. The clip is preferably provided on the bottom surface of the three-dimensional green plant cultivation container, it may be provided with at least one side of the container. The clip may be detachably provided to the plant cultivation container. The clip may be fixed to the container by bolts and screws, or may be secured to the container by physical fastening structures.

The present invention also provides a frame capable of fixing at least two or more plant growing containers for stereoscopic greening. In the present invention, by using the above frame can be configured by connecting the plant cultivation container of the independent entity in combination up, down, left, right. In the present invention, since the structure of the frame can be configured in various shapes, it is possible to provide a three-dimensional recording system that can be installed as an artistic three-dimensional recording sculpture of various shapes according to the shape of the frame.

The frame preferably includes a support portion and a fixing portion having a network structure supported by the support portion and capable of fixing the plant cultivation container. The network structure is not particularly limited as long as it can fix the plant cultivation container, it may be a lattice structure.

The frame may be manufactured in various shapes such as tower type, column type, cone type, pyramidal type, quadrangular flat type and the like. The fixing part may be connected to the support part by welding or assembly.

Fixing the plant cultivation container to the network structure may be achieved by adjusting the eye size of the network of the network structure and the circumference of the plant cultivation container to be about the same, or when the plant cultivation container has the clip described above. It may be achieved by fixing the clip to the network structure. The clip may be fixed to the container by welding or assembly.

The material of the frame is not particularly limited, but is preferably iron. Specifically, a-beam (Steel Angle), a flat iron plate and an iron pipe may be used.

The shape of the frame may be determined according to a three-dimensional shape such as a quadrilateral plate, a cylinder, and a cone. The support portion of the frame is not particularly limited as long as it can support the entire frame structure according to the three-dimensional shape of the frame. For example, in a quadrangular flat frame, a quadrangular support part may be formed using a-beam or flat iron, and a network structure may be formed by welding or assembling the support part to form a quadrangular flat frame. In the cylindrical frame, a circular support may be formed on a portion corresponding to the upper and lower surfaces of the cylinder by using a-beam or flat iron, and a network structure may be formed by welding or assembly to the support.

The support of the frame may be provided with a bolt or screw fastener or band fastener for fixing the three-dimensional recording system according to the present invention.

According to an exemplary embodiment, the frame is a tower-type steel frame for planting containers for stereoscopic greening, and may include a columnar support part and a fixing part of a network structure connected to the support part to form a tower shape. The frame may be formed in a tower shape by stacking columnar frames having a predetermined height, for example, a height of 60 cm or 30 cm.

The frame as described above may be connected to the cylindrical support plate, the cylindrical support plate may be configured to be fixed directly to the ground, or may be configured to be provided with a wheel at the lower end is movable. When the frame is removable, it can be easily moved indoors and outdoors according to seasons and climate change.

The cylindrical support plate may be provided with a motor, a roller and a reducer, they may be provided to rotate slowly by the electric power.

According to another exemplary embodiment, the frame may be quadrangular flat. Such a frame can be used for wall stereo recording. The quadrangular flat frame may be manufactured to be standardized in a predetermined length, such as 120 cm x 120 cm or 60 cm x 120 cm, and connects the standard quadrangular flat frame up, down, left and right. It can be used for wall stereo recording to be assembled and installed on the outer wall, inner wall and retaining wall of a building.

According to another exemplary embodiment, the frame is a soundproof wall stereoscopic recording frame. The frame may be configured by welding or assembling a quadrangular flat frame on both sides of the H-beam, and may be used for soundproof wall stereoscopic recording having a soundproof wall function of a roadside.

According to another exemplary embodiment, the frame is a Higgs stereoscopic frame. The frame may be configured by welding or assembling a quadrangular flat frame between H-Beams installed at a constant height, for example, every 120 cm, at a predetermined height, for example, 90 cm, and installed on both front and rear surfaces of the H-beam. As a result, it can be used for fixed fence stereo recording with a boundary fence function.

Mounting the planting container for fence stereoscopic recording A support base can be attached to the bottom of the frame and a wheel can be attached to the bottom of the support base to form a movable fence stereoscopic recording for movable indoor partitions.

According to another exemplary embodiment, the frame is a plant cultivation container installation frame for three-dimensional greening of railings of overpasses, bridges, and apartment houses. The frame is assembled to a certain size, such as a horizontal 60cm × 45cm square flat frame connected in the longitudinal direction by using a steel band (Band) on the railings of the apartment house porch railings such as overpass or bridge railings or apartments Can be fixed at

According to another embodiment, the frame is a cylindrical plant type container planting container installation frame, such as street lamps and park lamps. The frame may be configured by assembling and connecting two semi-circular frames with bolts or screws using a column such as a street lamp or a park lamp as a center column.

According to another exemplary embodiment, the frame is a columnar planting container installation frame for stereoscopic recording. A pipe column may be installed at the center of the circular support plate, and two semi-circular frames having a predetermined height, for example, 45 cm or 30 cm may be assembled by bolting or screwing around the pipe pillar. It may be configured to be fixed, or may be configured to be movable by installing a wheel below the circular support plate.

The present invention also provides two or more of the above-described three-dimensional plant cultivation container for greening; And it provides a stereoscopic greening system comprising a frame fixed to the two or more stereoscopic planting containers for planting.

The stereoscopic recording system may be provided with a water supply system to automatically supply water, but may be manually supplied.

The stereoscopic greening system may further include a water supply pipe for supplying each of the plant cultivation containers. The water supply pipe can provide each plant cultivation container with water or nutrient solution required for plant growth.

In the greening system according to the present invention, since the liquid supplied to the plant cultivation container provided on the upper side of the frame is drained through the drainage pipe and the drain hole of each plant cultivation container arranged vertically, it is drained in any one plant. Liquid drained from the vessel does not enter the soil receptacle of another plant cultivation vessel.

The stereoscopic greening system is preferably provided with a dropper button (dropper button) in the area of the water supply pipe to the plant cultivation container. By the drop button it is possible to adjust the appropriate amount of water supplied to each plant cultivation container. The water supply pipe may include a water supply main hose provided horizontally on an upper side of the frame and a branch hose provided in a vertical direction. The water supply branch pipe and the water supply pipe may be connected using a connection connector.

In addition, the water supply branch pipe may be further provided with a water supply hose provided adjacent to the position where the plant cultivation container is installed in order to independently supply to two or more plant cultivation containers arranged vertically. The drop button is preferably provided in a portion from which the water supply hose is derived from the water supply branch pipe. For example, a hole can be drilled at a predetermined interval in a branch hose, and a drop button can be assembled into the hole. At this time, by connecting the flushing valve (Flushing Valve) to the lower end of the feed pipe can be adjusted to supply a certain amount of water into the plant cultivation container through the drop button by the water pressure applied in the feed pipe.

In the present invention, as described above, the water supply and drainage facilities are installed for each individual plant cultivation container as an independent individual, and according to the characteristics of the cultivated plant, an appropriate amount of water or nutrient solution (water containing nutrients) is provided through the drop button. By being configured to be supplied to the cultivation container, an appropriate amount of water (nutrient solution) may be supplied through a dropper button to promote smooth growth of the cultivated plant.

The three-dimensional recording system may further include a water storage tank, and at least one of a filter, a pump, and a timer may be further installed beside the water storage tank. The filter shows the function of filtering the foreign substances contained in the water to be supplied. The pump serves to supply the water in the water storage tank to the water supply pipe installed at the top of the frame.The timer adjusts the water supply interval and the water supply time to adjust the proper amount. Water can be automatically fed to the plant cultivation vessel.

In the case of using the pump, an air valve may be installed above the water supply main pipe. When water is supplied to the water supply pipe installed at the top of the frame using a pump in the water storage tank for water supply, air in the water supply hose may be discharged through the air valve to enable smooth water supply.

When the stereoscopic recording system is small, manual water supply may be performed by connecting a lake connected to the water pipe to the water supply main pipe, instead of the automatic water supply system using the above-described filter, pump and timer.

The stereoscopic greening system may be further provided horizontally at the lower end of the frame, and may further include a drainage lake for draining the drained liquid through the drainage pipe and the drain of the plant cultivation container. It is possible to drain the liquid drained by this drainage lake to a certain place. The drainage lake is preferably connected to the drains of the plant cultivation vessels provided at the bottom of the frame.

The stereoscopic recording system may be configured to be movable with a wheel at the bottom of the frame.

It may further include a frame fixing for installing two or more of the frame. For example, an H-beam may be used to fix two or more quadrangular flat frames.

The present invention also provides a method of manufacturing a three-dimensional greening system comprising the steps of preparing the above-described frame, installing a water supply pipe on the frame, and installing the plant cultivation container for the three-dimensional greening described above. .

According to the present invention, various plants can be three-dimensionally recorded regardless of the type of plant. For example, coral, cheongeum, guanyin, boston fern, guardian reef, five-colored horse mackerel, Namcheon, ivy, Aran, Hoya, queer serpentus, Macmun-dong, Sasa, silver iron, gold-iron, butterfly, Pepe, Shingoum, cauliflower, Poinsettia and the like can be applied to the stereoscopic recording system according to the present invention.

The purpose and configuration of the present invention described above will be more clearly understood through the following description associated with the appended drain 63.

Hereinafter, with reference to the drawings will be described in detail a preferred embodiment of the present invention.

The plant growing container for stereoscopic recording according to the present invention and the stereoscopic greening system using the same are arranged in various forms by combining and arranging independent plant-type plant growing containers attached to the water supply line and the drainage line in various forms to form a stereoscopic greening system. Improving urban landscape by securing more green space on natural or artificial ground and preventing viral infection caused by soil pollution or pests among cultivated plants to promote smooth growth of cultivated plants.

4 and 5 are an exploded perspective view and an assembled perspective view showing the configuration of the three-dimensional green plant cultivation container according to the present invention.

As shown in Figure 4, the part constituting a part of the three-dimensional greening plant cultivation container, the bottom of the shape is provided with a drain pipe 62 of the body, the soil receiving portion 66 may be provided Body 61 comprising a; Side fixing clip (65) of the function of coupling and fixing the wire mesh of the body (61) and the frame (Frame) of the plant cultivation container; And a soil receiving part 66 capable of planting a cultivated plant provided with a drainage hole 66a.

The parts can be made of plastic injection molded products.

FIG. 5 is a perspective view of a plant cultivation container incorporating parts illustrating the configuration of the plant cultivation container for stereoscopic greening shown in FIG. 4.

As an assembly method, the soil receiving portion 66 is assembled to the body 61, and the assembly method may be fitting, welding, joining, etc., but is not limited thereto, and an assembly method known in the art may be applied. have.

As shown in Figures 4 and 5, the soil receiving portion 66 and the body 61 assembled as described above is composed of a single independent three-dimensional planting container for planting.

As illustrated in FIG. 7, the soil receiving portion included in the assembled three-dimensional greening plant cultivation container has a downward inclination angle and is positioned so that the opening faces upward. Accordingly, the soil receiving portion of the plant cultivation vessel is not abnormal in receiving sunlight, and the water supplied to the soil receiving portion may be easily drained toward the drain port 63 through the drainage hole without being stored in the plant cultivation vessel.

In addition, the connection method with the wire mesh attached to the frame (Frame) which is basically installed to connect and fix the three-dimensional green plant cultivation container in the vertical and horizontal direction, as shown in Figures 6 and 9, plant cultivation container By fixing the side fixing clip 65 attached to the left and right sides of the plant cultivation container adjacent to the left and right sides of the plant cultivation container, the plant cultivation container can be completely fixed to the frame without shaking.

The above-described method of installing the planting container for stereoscopic greening in a frame, by connecting and combining a plurality of planting containers for stereoscopic greening, can be installed as a three-dimensional greening sculptures on walls, slopes and curved surfaces, so that It has the advantage of securing more green space on natural or artificial ground.

7 illustrates a cross-sectional structure when the two planting containers for three-dimensional greening are arranged vertically. The two vessels are connected via a drain connection lake 68, a drain connection pipe 64, or a protruding drain 63, and the drainage flows from the drain pipe of the upper vessel to the drain pipe 62 of the body of the lower vessel. can do.

As shown in Figures 4 and 7, the soil receiving portion 68, the drain connection pipe 64 or the projecting drain 63 to extend to the drain pipe 62 of the body of the lower container, the soil receiving portion The drain line connecting groove 67 may be included.

FIG. 8 shows a three-dimensional greening system by fixing the above-described three-dimensional green plant cultivation container to a quadrangular frame as a first embodiment of the present invention. In addition, a wall stereoscopic recording system can be configured using the quadrangular frame shown in FIG. 8.

The four-sided frame is a four-shape (A) steel frame (steel angle) in order to produce a four-shape a-shape frame, using a flat iron cross-shaped to install the support in the center portion of the four-shape a-shape frame stable without structural shaking To produce. Then, the wire mesh connection support is connected to the square steel frame frame of the square shape by using the a-beam and flat iron, and then a wire mesh is attached to the end of the support, for example, by welding a 15-cm by 15-cm-long grid. A flat frame of each shape can be produced. The quadrangular flat frame can be produced in two standard sizes: 120 cm wide x 120 cm wide and 120 cm wide x 60 cm wide. According to the wall surface stereoscopic greening area, a flat wall frame having a quadrangular shape can be assembled and assembled through a bolt and nut fastening hole for assembly, so that a wall surface stereoscopic greening system having a certain area can be made, and separation and disassembly can be facilitated.

The horizontal and vertical specifications of the quadrangular frame are one example and can be designed and changed according to the size of the place where they are to be installed.

In addition, the quadrangular flat frame can be fixed to the wall surface using an anchor (Anchor).

After fixing the flat plate-shaped frame on the wall in the same manner as described above, the three-dimensional green plant cultivation container of FIG. 5 is fixedly connected to the wire mesh of the flat plate-shaped frame, and the water supply line and the drain line are installed. By doing so, a stereoscopic recording system can be configured.

After the three-dimensional planting container is installed on the frame, the water supply line and the drainage line are installed.

The water supply line includes a water supply main pipe (Main Hose) 81 installed horizontally in the uppermost frame and a branch water supply pipe (Branch Hose) 82 installed vertically with the water supply main pipe (81). Connection of the water supply main pipe 81 and the water supply branch pipe 82 may be made using a connection connector.

Drill holes at regular intervals in the water supply branch pipe 82 installed in the vertical direction of the water supply main pipe 81, insert a drop button, and connect a thin water supply hose to the protruding portion of the drop button to drop spike at the end of the hose. (69) can be installed. The drop spike 69 may be used by directly plugging the soil accommodated in the soil container 66.

Insertion depth of the drop spike 69 may be installed in accordance with the root depth of the plant planted in the soil receiving portion (66). Through the drop spike 69, water or nutrient solution can be directly supplied to the root of the plant planted in the soil receiving portion 66, so that there is an advantage that it can be efficiently supplied even with a small amount of water or nutrient solution.

The method of supplying the water supplied through the water supply branch pipe 82 through the drop button is to connect a flushing valve to the lowest end of the water supply branch pipe installed in the vertical direction to apply a constant water pressure in the water supply branch pipe, The water pressure in the branch pipe allows a certain amount of water to be fed into each plant cultivation container through a dropper button.

The water supplied to each plant cultivation vessel through the vertical water supply pipe 82 and the drop button is used as a nutrient to the cultivation plants in the plant cultivation vessel, and the remaining water after the cultivation plants absorbs a certain amount of water is soil. It flows down through the drain hole of the receiving portion and is discharged downward through the drain port 63 again.

The stereoscopic recording system may include a water storage tank and may further include a filter, a pump and a timer.

When water is supplied using the pump, the water supply main pipe is preferably provided with an air valve.

The water discharged from each plant cultivation vessel flows down through the drain pipe at the bottom of the lowermost plant cultivation vessel, and connects the drain hoses arranged in the horizontal direction to the drain pipes at the bottom of several plant cultivation vessels at the bottom. Water discharged from the cultivation vessel can be drained to a designated place through the drain hose.

After completing the installation of the water supply and drainage lines as described above, the three-dimensional recording system is completed.

In the present invention, since the water supply line and the drain line are separately provided in each plant cultivation container as described above, the growth soil pollution and the pest virus of the plant planted in the plant cultivation container of the upper layer are stored in the plant cultivation container of the lower layer. As it is not transmitted to planted plants, it is possible to maintain and grow individual cultivated plants.

In addition, in the present invention, by installing a pump and a timer near the water storage tank, water is supplied at a constant pumping pressure by the pump and the timer when water is supplied to the plant cultivation container, and at a predetermined interval, for example, 3 Watering once a day or once every 5 days and once watering time may also be controlled to allow automatic watering only for a certain time, such as 3 minutes to 5 minutes. This can promote the smooth growth of cultivated plants, and the growth and growth management of cultivated plants is not only easy, but also has the advantage of minimizing the waste of water supplied. In addition, a filter may be further provided if necessary.

The wall stereoscopic greening system can be installed on the retaining wall and the outer wall of the building in the city to create the natural appearance of the building, and can be installed on the lobby or indoor wall of a large building such as a hotel or a department store. In addition, it can exhibit indoor humidity control and indoor air purification along with the composition of the indoor landscape.

The stereoscopic recording system may be used as a stereoscopic recording system for railings of an overpass or a bridge in a second embodiment.

The frame for the three-dimensional greening system for railing hangers of bridges or bridges is made of a square steel frame with a steel angle, and a wire mesh connection support is welded to a four-shaped frame using a steel steel connection. For example, a grid-shaped wire mesh of 15 cm in width x 15 cm in width may be welded to the end portion of the support for fabrication to produce a quadrangular flat frame for railing hangers of bridges or bridges with wire mesh.

It is preferable that the quadrangular flat frame for railing hangers of overpasses or bridges be manufactured in a small size capable of mounting 12 plant cultivation containers as 60 cm x 45 cm in size. The mutual connection method of the quadrangular flat frame, the mounting method of the plant cultivation container, and the installation method of the supply / drain line are as described above.

The method for fixing the quadrilateral flat frame to the bridge railing upper pipe is performed by using a steel band through a band fastener which is drilled in a square shape frame made of a-shape and using the steel pipe and the upper pipe of the bridge railing. By connecting.

A three-dimensional greening system for railings on bridges and bridges can be installed not only on one side of the bridge, but also on both sides, and on the veranda side of apartment houses such as apartments. In this case, the exterior of the apartment can be represented as a more eco-friendly and beautiful landscape as the harmony between architecture and nature.

Fig. 10 shows the structure of the soundproof wall stereoscopic recording system as the third embodiment of the stereoscopic recording system.

As shown in Fig. 10, following the floor-based concrete pouring, the H-Beam is installed at regular intervals, such as 120 cm, with retaining wall concrete pouring up to a certain height of the ground, and shown in Fig. 8 on both sides of the H-beam. By welding or assembling the rectangular flat plate frame as described above, the basic frame of the soundproof wall stereoscopic recording system can be constructed.

The method of mounting the plant cultivation container for three-dimensional greening on the constructed soundproof wall frame and the installation method of the water supply line and the drainage line are the same as those described in the above-described other embodiments.

In the case of the soundproof wall stereoscopic greening system, when there is a condominium such as a roadway and an apartment in the city, natural cultivated plants can be observed on both sides of the road side and the apartment side by installing at the boundary of the apartment complex. It can improve the urban landscape, and can mitigate air pollution by absorbing air pollutants and supplying oxygen to cultivated plants.

Fig. 11 relates to a fourth embodiment of the stereoscopic recording system and shows the configuration of a Higgs stereoscopic recording system.

Higgs stereo recording system can be divided into two types, outdoor and indoor. For outdoor use, it can be used for boundary fences of schools, buildings, factories, etc., and for indoor use, it can be used for partitions in the lobby of large buildings. For indoor partitions, it is preferable to manufacture a movable type, not a fixed type.

First, the boundary fence (outdoor use) is installed by installing the H-shaped steel 160 of a certain height, for example, 90 cm, along with the foundation concrete placing that can install H-Beam at regular intervals (eg, 120 cm).

Between the H-shaped steel and the H-shaped steel, a flat frame having a quadrangular shape as shown in FIG. 8 may be installed by a welding or assembly installation method. The method of installing the square-shaped flat frame on both the front and rear surfaces of the H-beam is the same as that described in the description of the soundproof wall stereoscopic recording system. The installation method of the water supply line and the drainage line is also as described above.

In the case of the above-mentioned boundary fence (outdoor use), when the quadrangular flat frame is formed in a curved shape rather than a flat type, it is not a straight boundary type fence but also a Higgs-type stereoscopic greening system having a curved shape according to the curved boundary line. Production installation is possible.

In the case of building partitions (indoors), unlike fixed-bound fences, they are made of movable type. After making a fence support base for indoor partitions using steel angle and steel plate, attach the wheels under the support base.

After installing two H-beams 160 at both ends of the support base center line, a flat-shaped frame (Fig. 8) having a quadrilateral shape between H-beams and H-beams is installed on both sides of the H-beam by welding or assembling installation method. It is. The method of mounting the plant cultivation container and installing the supply / drainage line in the flat plate-shaped frame (Fig. 8) is as described above.

However, in case of manufacturing a portable three-dimensional recording system for indoor partitions, it is necessary to install a separate water storage tank, a drainage storage tank, and an iron box for storing a pump and a timer.

The above-mentioned Higgs-type three-dimensional greening system can enhance three-dimensional greening plants from both sides of the installation fence, thereby improving the city and interior aesthetics. There is an advantage that can be moved to place the interior partition.

12A to 12F are perspective views showing a frame configuration of a tower type stereoscopic recording system as a fifth embodiment of the stereoscopic recording system.

As shown in FIG. 12A, a frame is first manufactured in a columnar shape to construct a tower type stereoscopic recording system. Specifically, the a-beam (Steel Angle) is made of a circular frame having a certain diameter of the a-beam frame 101 is installed on the upper and lower sides, and two flat a-beam steel frame 101 to support the connection ( 102), and a column pipe 103 in the center of the circular a-beam frame 101 to establish a structurally stable columnar frame first by connecting the circular a-beam frame with a reinforcement flat 106.

After connecting a plurality of wire mesh connecting flat iron 107 to the circular a-beam steel frame 101 of the cylindrical frame by welding, the wire mesh 104 having a grid shape of, for example, a width of 15 cm × 15 cm in width is rounded. By welding, a cylindrical frame to which a wire mesh is attached can be constructed.

The diameter of the cylindrical frame may be produced in various sizes depending on the shape of the desired three-dimensional greening system or the plant to be grown, but the height may be standardized into two types of 60 cm and 30 cm. According to the height of the tower type stereoscopic recording system, the standardized cylindrical frame can be assembled and stacked as a tower type stereoscopic recording system of a certain height.

The assembling and laminating method of the columnar frame can be easily assembled and laminated through the assembling bolt and nut fastening hole 105, and there is an advantage in that the disassembly and disassembly are also easy.

12B and 12C illustrate cylindrical support plates capable of connecting and installing the cylindrical frame shown in FIG. 12A.

As the cylindrical support plate shown in Figure 12b, it can be made of an iron plate. By attaching the wheel 110 under the cylindrical support plate can be easily manufactured to move indoors and out, the motor 111, the reducer 112 and the roller 113 can be installed inside the cylindrical support plate. 12A is assembled by using the bolt-nut and the cylindrical frame shown in FIG. 12A, connected to the center pipe 114 of the reducer, and installed on the four rollers 113 shown in FIG. 12A. As the cylindrical frame rotates at a slow speed using electric power, for example, once every 4 to 5 minutes, people looking at the tower stereoscopic recording system can feel more vivid and beautiful in the visual dimension.

The tower type stereoscopic recording system may be manufactured in a rotary type using electric power as described above, but may be manufactured in a fixed type without installing the motor 111, the reducer 112, and the roller 113 inside the cylindrical support plate. FIG. 12D illustrates an example in which the fixed cylindrical support plate shown in FIG. 12C is fixed to the ground.

12E illustrates a tower-shaped iron frame constructed by stacking columnar iron frames.

After assembling the cylindrical support plate and the cylindrical frame as described above, the three-dimensional green plant cultivation container of Figure 5 is fixedly connected to the wire mesh 104 of the cylindrical frame.

After the installation of the planting container for stereoscopic greening of FIG. 5 is completed, the water supply line and the drainage line are installed. Figure 12f shows an example of installing the water supply line in the tower frame. The arrow indicates the water supply direction. Figure 13 illustrates a tower stereoscopic recording system.

In the sixth embodiment, the three-dimensional recording system can be used as a three-dimensional recording system for a street lamp or a park lamp hanger.

As shown in Figure 14, the frame for street lamp or park lamp hanger three-dimensional recording system for the production of two semi-circular frame 191 using a flat iron and then fixed with a support connecting rod 192, the support for connecting the wire mesh again Weld (193). Subsequently, two semicircular frames having a wire mesh can be manufactured by welding the wire mesh 104 having a grid width of 15 cm x 15 cm in a circular shape to the ends of the wire mesh connecting support 193. By assembling the two semi-circular frames with the streetlight column or the park column column through the assembling bolt or the screw fastener 195, the frame of the three-dimensional greening system for the street lamp or the park column hanger can be installed.

The method of mounting the plant cultivation container and the supply / drainage line installation method to the frame are as described above.

The three-dimensional greening system for street lamp or park lamp hanger as described above is easy to install and disassemble and easy replacement of cultivated plants according to the seasonal change has the advantage of easy maintenance.

Fig. 15 relates to the seventh embodiment of the stereoscopic recording system and shows the configuration of the columnar stereoscopic recording system.

Column type stereoscopic recording system is divided into outdoor use for installation at roadside or park outdoor exhibition hall, and indoor use for apartment living room, school classroom, general office, and indoor use. It is desirable to.

First, in the case of outdoor use, by welding a column pipe 215 of a certain diameter and a certain height to the center of the circular steel support plate 211 having a constant diameter and fixed to the ground by an anchor on the outer side of the circular steel support plate A steel pillar frame is made by drilling an anchor hole. The semicircular frame having a predetermined height (FIG. 14) attached with a wire mesh that can be connected to the column pipe 215 is fixed with a support connection on the outside of two semicircular flat irons to cover the diameter of the pipe pillar 215 using flat iron. After joining the support for connecting the wire mesh to the support by welding, and then connected to the wire mesh 104 of the horizontal 15cm x 15cm interval grid-shaped wire mesh in a semi-circular shape to produce a columnar frame attached to the wire mesh.

The height of the semi-circular frame can be adjusted in various ways depending on the type of system desired, but it can be produced in two types, 45cm and 30cm. The frame of the columnar stereoscopic greening system having a certain height may be constructed by assembling and connecting the semi-circular frame with a bolt or screw around the pipe pillar 215.

The installation method of the plant cultivation container and the supply / drainage line installation method to the columnar three-dimensional greening system frame are as described above.

Next, in the case of an indoor columnar stereoscopic recording system, the frame is manufactured in the same way as the outdoor one, but four wheels 213 are attached to the bottom of the round iron support plate 211 to easily move from place to place. It is characterized in that it is manufactured in a smaller size than the specification of the outdoor type.

Since the indoor columnar three-dimensional greening physical cultivation system is manufactured in a small size, it may be convenient to move the water pipe to the toilet or the veranda without installing a separate water supply / drainage line and connect the hose to the water pipe for manual water supply.

As described above, the plant cultivation container for stereoscopic greening and the stereoscopic greening system using the same according to the present invention are not only diverse in application, but above all, the conventional planar green space utilization dimension on a natural or artificial ground of a narrow area in the city center. It is possible to secure a three-dimensional green space. As a result, a pleasant natural environment can be created in harmony with urban buildings and nature, the replacement effect of the ground mandatory landscaping area under the Building Act, and the urban landscape improvement through greening of the outer wall of the building can be expected. It can have the effect to prevent environmental pollution by absorbing air pollutants and supplying oxygen, and to alleviate heat island phenomenon in the city and to control the humidity of the earth.

In addition, when installing large stereoscopic recording systems such as wall stereoscopic recording, retaining wall stereoscopic recording, soundproof wall stereoscopic recording, tower stereoscopic recording, etc., a standardized frame can be installed by assembling and connecting a standardized frame. Therefore, not only the installation construction is easy but also the disassembly construction also has a simple feature.

In addition, unlike the conventional technology, independent water supply and drainage lines are separately installed for each plant cultivation container, thereby preventing mutual contamination between cultivated soils by growing soil pollution or cultivating plant pest viruses, and it is easy to replace cultivated plants according to seasonal changes. . In addition, when a timer, a pump, and a drop button are provided, maintenance of cultivated plants can be facilitated by supplying an appropriate amount of water for a predetermined time at a predetermined time, thereby facilitating smooth growth of the cultivated plants. Has the advantage of simplicity and ease.

The present invention described above is not limited to the above-described exemplary embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

61: body 62: drain pipe of the body
62a: hole 63: drain
64: drain connection pipe 65: side fixing clip
66: soil receiving portion 66a: drainage hole
67: drain line connection groove 68: drain connection lake
69: Drop Spike 81: Main Hose
82: Branch Hose

Claims (24)

Body;
A drain pipe of the body provided inside the body;
A drain provided on a bottom surface of the body and not closed by a drain pipe of the body;
A soil receiving portion detachably provided in the body, the soil receiving portion provided with an opening for accommodating or removing a plant or soil and at least one drainage hole, and separated from the liquid passing through the drain pipe of the body. ; And
It is a plant cultivation container including a water supply means for supplying water or nutrient solution through the opening of the soil receiving portion,
Each unit of the plant cultivation container is a three-dimensional green plant cultivation container, characterized in that the water supply and drain independently. The plant growing container for three-dimensional greening according to claim 1, wherein the water supply means includes a drop spike having a hollow in the longitudinal direction. The plant growing container according to claim 1, wherein one end of the water supply means is inserted into the soil container. The plant cultivation container of claim 1, wherein the soil receiving portion is formed with a drainage line connecting groove. The method according to claim 1, wherein the soil container is a three-dimensional greening plant cultivation container is a horizontal cross-sectional shape of the bottom surface is a polygonal shape of any one of a circle or a triangle, a square, a pentagon, a hexagon, a hexagon and an octagon. The plant cultivation container for stereoscopic greening according to claim 1, wherein the drain hole has a structure projecting downward. The plant cultivation container for stereoscopic greening according to claim 6, wherein the drain hole is further provided with a drain connection pipe. The plant cultivation container for three-dimensional greening according to claim 7, comprising a drain connection lake connected to a lower end of the drain connection pipe. The three-dimensional green plant growing container according to claim 1, wherein the opening of the soil receiving portion is formed on an inclined surface of more than 0 degrees and less than 90 degrees with respect to the lower surface of the plant growing container. The plant container for stereoscopic greening according to claim 1, wherein the drainage hole of the soil container includes a plurality of holes located at the side and bottom of the soil container. The plant cultivation container of claim 1, wherein the plant cultivation container further comprises at least one fixing clip on at least one of a lower side and a side surface. The plant cultivation container of claim 1, wherein a part of one end of the drain pipe of the body is connected to the drain port, and a hole is formed in a side of the drain pipe of the body. The frame which fixed two or more plant cultivation containers for stereoscopic greening of any one of Claims 1-12. The frame according to claim 13, wherein the frame includes a support portion and a fixing portion supported by the support portion and capable of fixing the plant cultivation container and having a network structure. The frame of claim 13, wherein the frame has a tower, columnar, quadrilateral, cone, or pyramidal shape. The frame according to claim 13, wherein the frame is for tower-type stereoscopic recording, wall stereoscopic recording, soundproof wall stereoscopic recording, fence stereoscopic recording, railing stereoscopic recording, or cylindrical rack type stereoscopic recording. The frame of claim 13, wherein the frame is stationary or movable with wheels. Two or more plant cultivation containers for stereoscopic greening according to any one of claims 1 to 12; And a frame to which the two or more stereoscopic planting containers are fixed. 19. The stereoscopic recording system according to claim 18, further comprising a water supply system. 20. The water supply system of claim 19, wherein the water supply system includes a water supply main pipe and a water supply branch pipe connected to the water supply main pipe in a vertical direction, wherein the water supply branch pipe includes a drop button and a water supply lake for supplying water to each plant cultivation container. Stereo recording system to do. The flushing valve according to claim 20, further comprising: a flushing valve provided at a lowermost end of the water supply branch pipe; An air valve provided at an upper portion of the water supply main pipe; A timer for controlling a water supply interval and a water supply time of the water supply system; A filter connected with the water supply system; Pump; And a storage tank for water supply. 19. The stereoscopic greening system according to claim 18, further comprising a drainage lake connected to at least one drain of the plant cultivation vessel. 19. The stereoscopic recording system according to claim 18, wherein the stereoscopic recording system is for tower stereoscopic recording, wall stereoscopic recording, soundproof wall stereoscopic recording, fence stereoscopic recording, railing stereoscopic recording or cylindrical rack type stereoscopic recording. 19. The stereoscopic recording system according to claim 18, wherein the stereoscopic recording system is fixed or movable with wheels.

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