KR101234615B1

KR101234615B1 - Planter for green wall

Info

Publication number: KR101234615B1
Application number: KR1020120011342A
Authority: KR
Inventors: 정지수; 이영길
Original assignee: 주식회사 그리움
Priority date: 2012-02-03
Filing date: 2012-02-03
Publication date: 2013-02-20

Abstract

PURPOSE: A planter is provided to supply water continuously and evenly in the whole planter at any height without constructing a separate wall watering system. CONSTITUTION: A planter main body(110) has a water inlet(111) on the top and a water drainage(112) on the bottom. A water storage(120) stores water and falls overflown water. A first vegetation part(130) is filled with vegetation soil(101) and arranged between multiple water storages. The outer section of the first vegetation part has water permeability. A second vegetation part(140) is filled with vegetation soil and separated from the lower inner wall of the planter main body. A water flow inducing part(150) induces falling water from the water storage due to the overflow into the next water storage and have the water stored in the next water storage. A first storage partition wall(121) is separated from the rear inner wall of the planter main body. The right and the left parts of the partition wall are tightly fixed to the right and the left inner walls of the main body. A second storage partition wall(122) transmits water stored in a water storage space which is formed between the first storage partition wall and the second storage partition wall. The upper end of a first vegetation partition wall(131) is connected to the lower end of the first storage partition wall. A second vegetation partition wall(132) forms a vegetation soil storage space between the first vegetation partition wall. A first vegetation partition wall(141) of the second vegetation part is identical to the first vegetation partition wall of the first vegetation part. A second vegetation partition wall(142) of the second vegetation part is solid unlike the second vegetation partition wall of the first vegetation part which is a net shape.

Description

Planter for Wall Landscape {Planter for green wall}

The present invention relates to a wall landscaping plant that can decorate a landscape of a wall structure such as a wall or an elevation of an indoor / outdoor space such as a home, an office, a self-employed office, a partition wall for dividing an individual office space of an office, or a fence.

Landscaping is a general term for various kinds of decorations that provide various facilities and interiors that are friendly to the surrounding landscape. Landscaping provides people with a sense of peace and rest. Indoor landscaping has the effect of purifying the room air, supplying oxygen, and absorbing and shielding a certain amount of noise. In addition, it is known to have the effect of saving energy by keeping the indoor moisture and preventing the room temperature from falling. In particular, various skin diseases such as atopy caused by harmful gas generated from building materials and furniture such as sick house syndrome have become a problem. In the case of indoor landscaping due to the air purification function of plants, there is an excellent effect in improving such problems. .

Currently, the green industry is growing in importance as a new growth engine and future industry of the country, and due to the influence of narrow land, improvement of the quality of life of people, green life for health, and environmental concern, roof landscape as well as wall landscape Its importance is growing day by day.

In general, the wall landscape according to the existing is being constructed by a professional construction method by experts, due to constraints such as watering and drainage method, wall attachment method, in this case the construction cost is high. In the case of a professional construction method, it is generally made in a fixed and semi-permanent installation form, there is a difficulty in changing, moving, demolition of the wall landscape without the help of experts. This may result in maintenance costs and removal costs.

In addition, problems such as water connection work of water hoses for watering and fixing the hoses, such as changes, movement, the hassle and difficulty of dismantling, wall damage for wall attachment of wall landscaping plant, etc. The reality is that the public is not easily accessible in the office.

For this reason, in the home or general office, there may be a side effect that the wall landscaping is neglected due to excessive maintenance costs or neglect of management. And all men and women are very fond of wall landscaping and want to cultivate plants by installing wall landscaping for environmental improvement and emotional stability by indoor air purifying function. However, construction cost, maintenance cost, Due to the burden of demolition costs and new interior costs due to demolition, the situation is not easy to access.

Patent Publication No. 10-1043958 (published Jul. 23, 2010)

The object of the present invention is to provide a continuous and stable water supply evenly to the entire upper and lower parts at any height without having to install a separate wall irrigation system, and to facilitate installation, modification, movement, demolition and storage without expert assistance. It is to provide a wall landscaping plant that can freely configure the wall landscape space in the shape or size.

Wall surface landscaping plant according to the present invention for achieving the above object,

A planter body having a space therein and having a shape in which a front part is opened, an inlet is formed in an upper face, and a drain hole is formed in a lower face; The plant is formed to store water and freely drop the overflowed water, and the outer portion is formed to have a permeability, and is disposed up and down inside the plant body to form a water flow space communicating vertically. A plurality of water reservoirs spaced apart from an inner wall of the rear portion of the main body; At least one first vegetation portion filled with vegetation soil and disposed between the water storage portions, and having an outer portion permeable to the vegetation soil; The vegetation soil is filled therein and is disposed between the lowermost water reservoir of the water reservoirs and the lower surface of the plant body, and forms a drainage space for discharging the overflowed water from the inside of the plant body. A second vegetation part spaced apart from an inner wall of the lower surface part; And a water flow inducing unit which overflows from the water storage unit except the lowest water storage unit among the water storage units so that the falling water is guided and stored in the water storage unit adjacent to the lower side.

According to the present invention, there is no need to construct a separate wall irrigation system such as a conventional boiler pipe type hose connection or installation of water pipes, and evenly and continuously supply water to the entire upper and lower parts of the plant, thereby reducing costs. Can solve the hassle and difficulty. As a result, there is a useful effect that makes it possible for all ages and sexes to easily and freely enjoy wall landscaping activities in their lives.

In addition, according to the present invention, by freely assembling and installing planters in any place or any structure of the wall without the help of experts, it is possible to freely configure the wall landscaping space in the desired shape or size, water flow between the planters Can be connected in the form of a mesh.

Therefore, no matter how the planters are connected up, down, left, and right, they can function organically as a single plant, and thus can easily install, change, move, remove and store them, and provide a vegetation environment suitable for plant growth. As a result, anywhere in the living room wall, porch wall, kitchen wall, office wall space, self-employed office substitutes, office partition wall, fence, etc., where you can grow and observe green plants just by installing the plant according to the present invention. In addition, it can greatly contribute to the prevention and improvement of atopy disease, which is one of the big social problems in recent years, and has a useful effect that can contribute greatly to the wall green life, green culture change and popularization.

1 is a side cross-sectional view of a wall landscaping plant according to an embodiment of the present invention.
Figure 2 is a perspective view of the plant for wall landscaping of Figure 1;
3 is a view for explaining the process of coupling the plant of Figure 2 into a plurality of up and down.
4 is a view for explaining a process in which the plant of FIG.
FIG. 5 is a perspective view illustrating a state in which the plant of FIG. 1 is coupled up, down, left, and right through a process of FIGS. 3 and 4.
Figure 6 is a perspective view showing a state in which the water supply tank and the drain container are coupled to the upper and lower parts of the plant of Figure 2;
7 is an exploded perspective view of FIG. 6.
8 is a perspective view of the plant of Figure 6, showing a state in which the drain container is coupled according to another example.
FIG. 9 is a perspective view illustrating an example in which the flower bed and the support stand are attached to the lower surface of the drain box in the plant of FIG. 6.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a side cross-sectional view of a wall landscaping plant according to an embodiment of the present invention. 2 is a perspective view of the wall landscaping plant of FIG.

Referring to FIGS. 1 and 2, the wall landscaping plant 100 includes a planter body 110, water storage units 120, at least one first vegetation unit 130, and a second vegetation unit. 140, and water flow guides 150.

The planter body 110 has a space therein and has a shape in which the front part is opened. The planter body 110 has a top portion, a bottom portion, a rear portion, and a left and right portion formed in a closed form, respectively. The inlet 111 is formed in the upper surface of the planter body 110, and the drain port 112 is formed in the lower surface of the planter body 110.

The water reservoirs 120 are formed to store water and freely drop the overflowed water. The water reservoirs 120 are formed so that the outer portion, that is, the outer portion facing the first vegetation portion 130 or the second vegetation portion 140 has water permeability. Accordingly, water stored in the water storage units 120 may be supplied to the first vegetation unit 130 or the second vegetation unit 140 adjacent to the lower side through the outer portions of the water storage units 120. .

If the water stored in the water storage unit 120 directly flows into the vegetation soil 101, the temporary excessive supply of water to the vegetation soil 101 of the first vegetation 130 or the second vegetation section 140, and thus It may cause adverse effects and side effects on the vegetation environment. However, since the outer portion of the water storage unit 120 has water permeability, water stored in the water storage unit 120 may slowly and naturally infiltrate the vegetation soil 101 for a long time. Therefore, the above-mentioned problem can be solved and an optimal vegetation environment can be implemented.

The water reservoirs 120 are disposed up and down inside the plant body 110. Here, the water reservoirs 120 are spaced apart from the inner wall of the rear portion of the plant body 110 to form a water flow space communicated up and down. Although the water storage unit 120 is shown as being provided with three, it may be provided with two or four or more.

The vegetation soil 101 is filled in the first vegetation part 130. The first vegetation part 130 is disposed between the water storage parts 120. When the water storage unit 120 is provided in three, the first vegetation unit 130 may be provided in two, one by one between the water storage unit 120. The first vegetation part 130 has an outer portion, that is, a lower portion adjacent to the first vegetation part 130 or the second vegetation part 140 has water permeability. Therefore, water introduced into the first vegetation part 130 may pass through each outer portion of the first vegetation part 130 and flow into the first vegetation part 130 or the second vegetation part 140 adjacent to the lower side. Can be.

The vegetation soil 101 is filled in the second vegetation part 140. The second vegetation part 140 is disposed between the lowermost water storage part 120 and the lower surface part of the planter body 110. The second vegetation part 140 is spaced apart from the inner wall of the lower surface of the plant body 110 to form a drainage space 113 for discharging the overflowed water from the inside.

Water penetrating into the second vegetation part 140 is introduced into the second vegetation part 120, and the first vegetation part 130 passes through the vegetation soil 101 of the first vegetation part 130. One water flows in sequentially and is captured. In this case, when the water collected by the second vegetation part 140 is excessively overflowed, the overflowed water is a drainage space between the second vegetation part 140 spaced apart from the inner wall of the bottom surface of the plant body 110. It may flow into 113 and be discharged.

The water flow guide part 150 allows the water that is overflowed from the water storage part 120 except for the lowermost water storage part 120 to be led to and stored in the water storage part 120 adjacent to the lower side. The water flow guide 150 is disposed between the water reservoirs 120, respectively. And, each of the water flow guide 150 is from the inner wall of the rear portion of the plant body 110 so that water overflowed from the water reservoir 120 located on the upper side can be led to the water reservoir 120 adjacent to the lower side Protruding forward may be made in a form extending along the left and right directions of the plant body (110).

An operation example of the wall landscaping planter 100 having the above-described configuration will be described below with reference to FIG. 1. In FIG. 1, solid arrows indicate direct flow and dashed arrows indicate permeate flow.

Water introduced through the inlet 111 of the plant body 110 is primarily stored in the water storage unit 120 of the uppermost layer. Thereafter, the water that overflows the storage capacity of the uppermost water storage unit 120 is free to fall. Water dropped from the uppermost water storage unit 120 is secondarily stored by the uppermost water flow guide unit 150 to the second upper water storage unit 120. Thereafter, the overflowed water exceeds the storage capacity of the water storage unit 120 of the next vehicle layer is free fall. The water dropped from the water storage unit 120 of the next car layer is stored in the water storage unit 120 of the lowest layer by the water flow guide unit 150 of the next car layer.

Through this process, water is sequentially stored in all the water storage units 120 from the top water storage unit 120 to the lowest water storage unit 120, and then the storage capacity of the water storage unit 120 of the lowest layer is stored. The excess overflowed water flows into the drainage space 113 between the second vegetation part 140 and the inner wall of the lower surface of the planter body 110. Water introduced into the drainage space 113 is drained through the drain hole 112 of the plant body 110. As such, the water introduced through the inlet 111 of the plant body 110 may be supplied to the water storage units 120 continuously and stably.

Meanwhile, water stored in the water storage units 120 passes through the water storage units 120, respectively, and flows into the first vegetation units 130 and the second vegetation unit 140, respectively. At this time, the water flowing into the first vegetation portion 130 of the uppermost layer passes through the vegetation soil 101 and then passes through the outer portion of the first vegetation portion 130 and flows into the first vegetation portion 130 of the second layer. . Water introduced into the first vegetation portion 130 of the second layer passes through the vegetation soil 101 and then passes through the outer portion of the first vegetation portion 130 and flows into the second vegetation portion 140. When the water collected by the second vegetation part 140 is excessively overflowed, the overflowed water is drained through the space between the second vegetation part 140 spaced apart from the inner wall of the lower surface of the plant body 110. Flows into 113).

The above-described water storage unit 120 may include a first storage partition 121 and a second storage partition 122. The first storage partition wall 121 is placed upright and spaced apart from the inner wall of the rear surface of the plant body 110. The first storage partition 121 may be disposed to be inclined such that an upper end thereof is located closer to the inner wall of the rear part of the plant body 110 than the lower end thereof. The left and right portions of the first storage partition wall 121 are fixed to the inner walls of the left and right surfaces of the plant body 110 and fixed.

The second storage partition 122 has a lower end connected to the lower end of the first storage partition 121 to form a water storage space between the first storage partition 121. To this end, the second storage partition 122 is fixed to the left and right portions in close contact with the inner wall of the left and right surface portion of the plant body 110. The second storage partition 122 may be inclined so that the lower end thereof is located closer to the inner wall of the rear part of the plant body 110 than the upper end thereof.

The second storage partition 122 has permeability to permeate the water stored in the water storage space to the first vegetation part 130 or the second vegetation part 140 adjacent to the lower side. For example, the second storage barrier 122 may include a direct blocking film 122a made of a water-permeable material such as a sponge. As another example, the second storage partition wall 122 may be formed in a plurality of perforations are formed in the partition body, the permeable material is planted in each of the perforations.

On the other hand, the water storage unit 120, in addition to the above-described partition wall form, the outer portion toward the first vegetation unit 130 or the second vegetation unit 140 has a water permeability and has a space for storing water, for example The outer portion may be formed in various forms such as a hose having water permeability, and may be made of various materials such as metal and plastic.

The first vegetation part 130 may include a first vegetation partition 131 and a second vegetation partition 132. An upper end of the first vegetation barrier rib 131 is connected to a lower side of the first storage barrier rib 121. The first vegetation partition 131 may be inclined so that the upper end thereof is located closer to the inner wall of the rear part of the plant body 110 than the lower end thereof. The left and right portions of the first vegetation partition wall 131 are fixed to the inner wall of the left and right surfaces of the plant body 110 and fixed.

The second vegetation partition wall 132 has a lower end connected to the lower end of the first vegetation partition wall 131 to form a vegetation soil storage space between the first vegetation partition wall 131. To this end, the second vegetation partition 132 is fixed to the left and right portions in close contact with the inner wall of the left and right surface portion of the plant body 110. In addition, the second vegetation partition wall 132 may be inclined so that the lower end thereof is located closer to the inner wall of the rear part of the plant body 110 than the upper end thereof. The second vegetation partition wall 132 may be inclined at the same angle as the second storage partition wall 122, and a lower end of the second vegetation partition wall 132 may be connected to an upper end of the second storage partition wall 122.

Therefore, the first vegetation part 130 is separated from each other up and down and each inlet has a 'c' shape inclined to face upwards and is installed in the plant body 110 in an elevation structure, the first vegetation part 130 The soil layer of the vegetation soil 101 stored in the) can be prevented from falling, due to gravity. In addition, the vegetation soil 101 may be stably stored in the first vegetation part 130.

The second vegetation partition 132 is formed in the form of a mesh. When the first vegetation part 130 and the first vegetation part 130 and the second vegetation part 140 are sealed to each other and blocked, the root growth of the plant planted in the vegetation soil 101 is not free. However, when the second vegetation partition wall 132 is formed in a net form, the root growth of the plant may grow freely between the first vegetation part 130 and between the first vegetation part 130 and the second vegetation part 140. It can be an environment. Therefore, the soil layers of the first vegetation part 130 may be connected, and the soil layer of the first vegetation part 130 and the soil layer of the second vegetation part 140 may be connected. In addition, the root growth of the plant can be spread throughout the planter 100 without clogging either up, down, left, or right.

The first vegetation partition 141 of the second vegetation part 140 may be configured in the same manner as the first vegetation partition 131 of the first vegetation part 130. In addition, unlike the second vegetation partition 132 of the first vegetation part 130, the second vegetation partition wall 142 of the second vegetation part 140 may be formed in a closed shape instead of a mesh.

On the other hand, the upper surface portion of the plant body 110 may be formed in a concave shape of the letter "V" along the left and right directions. The upper surface portion of the planter body 110 may include an upper coupler 114a. The upper coupler 114a may be provided in plural, and may be formed in an upper surface portion of the plant body 110 extending in a concave shape in a semicircle along the left and right directions.

The lower surface of the planter body 110 may be formed in a convex shape with a 'V' opposite to the shape of the upper surface of the planter body 110. The lower surface of the planter body 110 may include a lower coupler 114b formed in the same shape as the upper coupler 114a. That is, the lower coupler 114b may be formed in the same pattern and shape as the upper coupler 114a.

Therefore, as shown in FIG. 3, the plurality of planters 100 may be coupled to be connected up and down. That is, in the state where the 'V' convex lower surface of the upper planter 100 is inserted into the 'V' concave upper surface of the lower planter 100, both sides of the first coupling mechanism 102 are the upper planter. By fitting to the lower coupler 114b of the (100) and the upper coupler (114a) of the lower planter 100, respectively, the upper planter 100 and the lower planter 100 structurally without shaking front and rear It can be combined stably up and down. Here, the first coupling mechanism 102 is formed in a form in which two cylinders respectively fitted to the lower coupling hole 114b of the upper planter 100 and the upper coupling hole 114a of the lower planter 100 are connected in parallel. , And can be coupled to the lower coupler 114b of the upper planter 100 and the upper coupler 114a of the lower planter 100 in a slide manner.

The planter body 110 may be formed such that the inlet 111 and the drain 112 face each other up and down. Accordingly, when the upper planter 100 and the lower planter 100 are coupled, the drain port 112 of the upper planter 100 may be connected to the inlet 111 of the lower planter 100. Therefore, the remaining water after filling all the water storage unit 120 of the upper planter 100 is discharged through the outlet 112 of the upper planter 100 is introduced through the inlet 111 of the lower planter 100 After that, it may be stored in the water storage unit 120 of the lower planter 100. As a result, no matter how many of the planters 100 are connected up and down, the water supply to all the planters 100 can be made evenly and stably, and can function as a single plant as a whole.

The left and right side portions of the planter body 110 include left and right couplers 115a and 115b of the same shape, respectively. The left coupler 115a may be provided in plurality in the left surface portion of the plant body 110 and arranged up and down. The left coupler 115a may be formed as a circular groove. The right couplers 115b may be formed on the right surface of the plant body 110 in the same pattern and shape as the left couplers 115a.

Therefore, as shown in FIG. 4, the plurality of planters 100 may be coupled to the left and right. That is, in the state in which the left planter 100 and the right planter 100 are arranged side by side, the left end of each of the second coupling mechanisms 103 is connected to the right coupling hole 115b of the left planter 100. Fitted to each other, the right end of each of the second coupling mechanism 103 is fitted to the left coupling hole (115a) of the right planter 100, the left planter 100 and the right planter 100 is coupled left and right Can be. Here, the second coupling mechanism 103 may be formed in a cylindrical shape.

Left and right inlet and outlet 116a and 116b may be formed at each lower side of the left and right surface portions of the planter body 110. The left and right inlet drains 116a and 116b are respectively disposed to correspond to the drainage space 113 of the planter body 110 and face each other from side to side.

Accordingly, when the left planter 100 and the right planter 100 are coupled, the right inlet 116b of the left planter 100 may be connected to the left inlet 116a of the right planter 100. . Therefore, the excess water of the left and right planter 100 has a natural water flow between left and right, so that the water can be evenly distributed between the left and right planter 100. As a result, no matter how many of the planters 100 are connected to the left and right, all the planters 100 may have an equal water supply, and may function as a single plant as a whole.

Through the process as shown in Figures 3 and 4, the user can simply connect the plant 100 to the top, bottom, left and right as shown in Figure 5 without the help of a specialist, so that the plant 100 to the desired shape It can be installed freely and installed as a whole plant simply. In addition, the landscaping space of any shape may be formed by connecting the planters 100 to the top, bottom, left and right, and thus the landscaping space may have a mesh-type water supply structure. Therefore, even and stable water supply can be expected in all landscaping spaces, thereby realizing an optimal vegetation environment.

In addition, there is no need to construct a separate wall irrigation system, such as installing a conventional boiler plumbing hose or installing a watering pipe in order to supply water to the water storage units 120 of the planters 100 separately. Can reduce the hassle and difficulty. As a result, there is a useful effect that makes it possible for all ages and sexes to easily and freely enjoy wall landscaping activities in their lives.

On the other hand, as shown in Figure 6, the water supply tank 160 is coupled to the upper surface portion of the planter body 110, the drain container 170 may be coupled to the lower surface portion of the planter body 110. The water supply container 160 and the drain container 170 may be used for the case where it is difficult to control the water supply of the planter 100, the amount of drainage, or the stable water supply and the drainage management.

The water supply container 160 is formed to contain water and supply the water to the inlet 111 of the plant body 110. As illustrated in FIG. 7, the lower surface portion of the water supply container 160 is formed in a convex shape with a 'V' along the left and right directions so that the 'V' concave upper surface portion of the plant body 110 is inserted. Accordingly, the water supply container 160 may be stably coupled with the planter body 110. The lower surface of the water supply container 160 includes a water supply coupling device 161 coupled by the upper coupling device 114a of the plant body 110 and the first coupling device 102. The water supply container coupler 161 may be formed in the same shape as each of the upper and lower couplers 114a and 114b of the plant body 110. The water supply container 160 may be variously modified in height and shape in a category having a 'V' convex shape in which the lower surface is coupled to the planter body 110.

An inlet 162 may be formed on an upper surface of the water supply container 160 to supply water to the interior of the water supply container 160. A drain hole 163 may be formed on the lower surface of the water supply container 160 to be connected to the inlet 111 of the plant body 110. Accordingly, the water supplied to the inlet 162 of the feeder 160 may be introduced into the inlet 111 of the plant body 110 through the drain 163 of the feeder 160.

Left and right inlet and outlet 164 may be formed on the left and right sides of the water supply container 160. In a state in which a plurality of planters 100 each having a water supply container 160 are coupled side by side, the water supply containers 160 may be connected to each other through water flow through the left and right inlet 164. Accordingly, if water is supplied to the central water supply container 160, water may be supplied from the central water supply container 160 to the left and right water supply containers 160. Since the left and right water supply tanks 160 are supplied with water to supply water to the planters 100 coupled thereto, the water flows smoothly in all directions.

Then, the left and right hose connector 165 may be formed on the upper surface of the water supply container 160. Accordingly, when the height of the water tanks 160 are different in the state in which the planters 100 are coupled, or when the water flow is connected between the planters 100 spaced apart from each other by necessity in shape of the flower bed, The hose connector 165 may be connected to the water supply tank 160 with a hose or the like. For example, in a state in which the planters 100 are coupled up, down, left, and right, when the heights of the uppermost layers of the left planter 100 and the right planter 100 are different from each other, the left and right inlet 164 may not be utilized. By connecting the left and right inlet drain 164 of the water supply tank 160 and the left and right hose connector 165 of the low water supply tank 160 with a hose, the water flow can be continued.

The drain container 170 is formed to contain water discharged from the drain hole 112 of the plant body 110. The upper surface of the drain container 170 is formed in a concave shape of the letter "V" along the left and right directions so that the lower surface of the plant body 110 is inserted. Accordingly, the drain container 170 may be stably coupled with the planter body 110. The upper surface portion of the drain container 170 includes a drain container coupler 171 coupled by the lower coupler 114b of the plant body 110 and the first coupling mechanism 102. The drain container coupler 171 may be formed in the same shape as the upper and lower coupler (114a, 114b) of the plant body 110, respectively. The drain container 170 may be variously modified in height and shape in a category in which the upper surface has a 'V' concave shape that can be coupled to the planter body 110.

The drain container 170 is provided with an inlet 172 on the upper surface. The inlet 172 allows water drained through the drain 112 of the plant body 110 connected to the upper side of the drain container 170 to be introduced into the drain container 170. Combined inlet and drain 173 is formed on the left and right sides of the drain container 170, which serves as a water flow connection and water discharge between the left and right drain boxes 170. Therefore, water introduced through the inlet 172 of at least one of the left and right drainage vessels 170 may be mutually drained into the left and right drainage vessels 170 through the combined inlet and drain 173. . In addition, the water introduced into the drain bucket 170 may be forcibly discharged through the combined inlet and drain 173 of the drain bucket 170 located at the outermost side of the left and right drain bucket 170.

On the other hand, after fixing the planter 100 of the uppermost layer on the wall, it is possible to make the wall landscape space by connecting the planters 100 from the top to the bottom. However, due to wall damage or other hassles and difficulties, in order to implement the wall landscape space and freely move the planters 100 by connecting the planters 100 to the wall without any work, the planter 100 Reinforcement of the support so as not to fall back and forth to the lower portion of the), or as shown in Figure 8, it can be configured to form a drain can 270 to serve as a support. For example, the drain container 270 may have a front and rear width that is wider than the front and rear width of the planter 100 to serve as a support function as well as a drainage function. In this case, the drain container 270 stably supports the planter 100, and also allows a larger capacity for storing water. The drain container 270 may be deformed in various forms in the range of stably supporting the planter 100, and may be deformed in a size capable of storing more water.

In the case described above, by stacking up the planters 100 by connecting the planters 100 from the bottom up on the drain 270 placed on the ground, the wall landscaping space can be realized without any damage or work on the wall, and the position of the planters 100 is moved. May also be implemented freely.

As another example, as shown in FIG. 9, the flower bed and the support 180 may be reinforced and attached to the lower surface of the drain container 170.

Meanwhile, a water supply device including a water pump and a hose may be installed between the drain container 170 and the water supply container 160 for watering the planter 100. In this case, the water filled in the drain container 170 is supplied to the water storage unit 120 via the water supply container 160 only if water is filled in the drain container 170 if necessary, without a separate watering facilities such as water supply. After being circulated through the process to be recovered to the drain container 170, it is possible to use more convenient and useful.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

110. Plant body 120. Water storage
130 .. The first vegetation part 140 .. The second vegetation part
150 .. water flow guide 160 .. water reservoir
170,270..Drain 180..Flower bed & support

Claims

A planter body having a space therein and having a shape in which a front part is opened, an inlet is formed in an upper face, and a drain hole is formed in a lower face;
The plant is formed to store water and freely drop the overflowed water, and the outer portion is formed to have a permeability, and is disposed up and down inside the plant body to form a water flow space communicating vertically. A plurality of water reservoirs spaced apart from an inner wall of the rear portion of the main body;
At least one first vegetation portion filled with vegetation soil and disposed between the plurality of water storage portions, the outer portion having water permeability;
The plant is filled with vegetation soil and disposed between the lowermost water reservoir of the plurality of water reservoirs and the lower surface of the plant body, and forms a drainage space for discharging the overflowed water from the inside. A second vegetation part spaced apart from an inner wall of the lower surface part of the main body; And
A water flow inducing unit which overflows from the water storage unit except the lowest water storage unit among the plurality of water storage units, and thus the falling water is guided to and stored in the next water storage unit below;
Wall landscaping plant comprising a.

The method of claim 1,
Each of the plurality of water storage units,
A first storage partition wall disposed upright and spaced apart from an inner wall of the rear of the plant body, and the left and right portions are fixed to the inner wall of the left and right sides of the plant body;
A lower end connected to a lower end of the first storage barrier rib to form a water storage space between the first storage barrier and a second storage barrier having permeability to permeate the water stored in the water storage space. Wall landscaping plant

The method of claim 2,
The first vegetation part,
A first vegetation partition wall having an upper end connected to a lower end side of the first storage partition wall, and having a left and right portion tightly fixed to an inner wall of the left and right sides of the plant body;
A lower surface is connected to the lower end of the first vegetation barrier ribs to form a vegetation soil storage space between the first vegetation barrier ribs and comprises a vegetation barrier wall wall characterized in that it comprises a mesh form.

The method of claim 1,
An upper surface portion of the plant body is formed in a concave shape along a 'V' along a left and right direction, and includes an upper coupling hole;
A lower surface portion of the plant body has a convex shape of 'V' opposite to that of the upper surface portion of the plant body and includes a lower coupling portion formed in the same shape as the upper coupling portion;
The left and right sides of the planter body wall landscaping plant, characterized in that it comprises a left and right coupling sphere of the same shape, respectively.

The method of claim 1,
The upper surface of the planter body is concave in the form of a 'V' along the left and right direction and comprises an upper coupling, the lower surface of the planter body is convex 'V' to be opposite to the shape of the upper surface of the planter body A lower coupler formed in the same shape as the upper coupler;
It is formed to contain water and supply it to the inlet of the plant body, the lower surface portion is formed in a convex shape 'V' along the left and right direction so that the upper surface portion of the plant body is inserted and the first coupling sphere and the first coupling of the plant body A water tank including a water tank coupler coupled by a mechanism; And
It is formed to contain the water discharged from the drain of the plant body, the upper surface portion is formed in a concave shape of the letter 'V' along the left and right directions so that the upper portion is inserted into the lower portion of the plant body, and Wall planter for landscaping characterized in that it comprises a drain pipe including a drain pipe coupler coupled by a coupling mechanism.