KR20210002744U - Plant port module for greenwall - Google Patents

Abstract

The present invention is a plant port module for a green wall that is inserted into a tray module for a green wall that has a built-in pump circulation system and is aligned and coupled to a body frame through which water is circulated. Both ends from the inside of the plant pot and green wall plant pot module having a side part having a second side that is continuously arranged in an octagonal pipe shape, and a bottom part having a plurality of second through-holes and a bottom part formed to cover the bottom surface of the side part It is characterized in that it includes a water supply wick stored in the tray module for the green wall through the pair of second through-holes.

Description

Plant port module for green wall {PLANT PORT MODULE FOR GREENWALL}

The present invention relates to a vertical cultivation module for plants, and more particularly, to a modular plant pot specialized for green wall that supplies water and nutrients to plants by circulating water.

Recently, an increasing number of households cultivate flowerpots in apartments, etc. for the purpose of air purification or ornamentation, and in bus stops, parks, corporations, hotels, or government offices, flowerpots are often used to calm people's hearts and create an aesthetically pleasing space.

However, in the interior where flowerpots are usually arranged, a method in which one flowerpot occupies one space and is horizontally arranged is used, but the need for arranging a large number of flowerpots in a narrow space is also increasing, There is a need to create an aesthetic design through flowerpots in which various plants are planted by arranging flowerpots vertically or on the wall. On the other hand, in the case of arranging flowerpots horizontally, there is also the inconvenience of additionally using a water tray under the flowerpot stand to supply moisture to each flowerpot.

In an effort to solve this problem, a multi-assembly flowerpot device has been recently provided. For example, in Korean Patent Application Laid-Open No. 20-0477950, a "vertical garden planter device" was invented, but this is the case in which the water (W) falls through the water inlet 120 and the permeable hole 110 through which the water (W) passes. It should be arranged so that it is always in a straight line with the direction, and in the case of hydroponics, water (W) is always supplied, so there is no problem, but in the case of soil culture, there is a problem that the supply of water cannot be controlled.

As another example, "the name of the invention vertical garden module" was invented in Korean Patent Registration No. 10-1488380, but this is because the port 30 is located in the area where the water supplied through the perforated top plate 110 falls. In a manner in which falling water is always supplied to the port 30, it is easy for hydroponics as in the prior art described above, but there is a problem that is not excellent for soil cultivation that requires control of the supply of water.

In addition, plants grow toward light according to their phototropism, and indoor flowerpots depend on sunlight or LEDs for plants entering through a building window. Such light is injected in a very limited direction, and in general, during vertical cultivation, it is impossible to move the flowerpot according to the light due to the large body that is assembled by connecting a plurality of ports. Therefore, for photosynthesis of plants, it is necessary to constantly rotate each pot in which plants are planted. However, referring to the prior art, the rectangular plant pot is extremely rotatable in units of 90°, and is cylindrical. The shape of the plant pot can be rotated 360°, but there is a problem in that it is difficult to rotate at an accurate and constant angle.

In addition, plants grow toward light according to phototropism, and the grown stems and leaves are twisted downwards according to the law of gravity. There was a problem that could deviate from it.

In addition, the amount of soil stored in the plant pot varies depending on the size of the planted plant. Since the watering wick is located at the bottom of the plant pot by the input, there is a problem in that the water shortage phenomenon occurs in the plant because the mole is not sufficiently supplied to the soil inside the pot through the watering wick.

Korean Patent Publication No. 20-0477950 Korean Patent Publication No. 10-1488380

A first object of the present invention for solving the above problems is to provide a plant pot module for a green wall, capable of both hydroponics and soil cultivation.

A second object is to provide a plant pot module for a green wall, which is easy to assemble and disassemble in a tray module for a green wall.

A third object is to provide a plant pot module for a green wall, which prevents the plant pot from being separated from the object module by the leaves of a plant growing luxuriantly.

A fourth object is to provide a plant pot module for a green wall that enables proper water supply to plant roots and soil by allowing a watering wick to be positioned at an appropriate height in the plant pot.

In order to achieve the above object, the present invention,

An octagonal pipe-shaped insertion hole protrudes from the front, a fixing protrusion is formed on the side end of the insertion hole, a pump circulation system is built in, and a plant pot module for a green wall inserted into a tray module for a green wall that is aligned and coupled to the green wall body frame through which water circulates In

A side portion in which a first side having a plurality of first through-holes is formed and a second side adjacent to the first side are continuously formed in an octagonal pipe shape corresponding to the insertion hole, and a plurality of second through-holes are formed and the A plant pot consisting of a bottom portion formed to cover the bottom surface of the side portion; and

In a rope shape, both ends are exposed through the pair of second through-holes from the inside of the plant pot, and a water supply wick disposed so as to be in contact with the water stored in the tray module for the green wall; includes,

The plant pot, a plant pot module for a green wall, characterized in that the fixing projection groove of a corresponding shape is formed through the upper end of the side portion so that the fixing projection is inserted.

The side portion, with an inclination of 3 to 5°, is characterized in that it is formed to become narrower from the top to the bottom.

The first through-hole is formed through the first side so that the lower end is rounded in a rectangular shape, and is characterized in that it is formed in a plurality of horizontally and in a row spaced apart.

The first through-hole is characterized in that the width is formed to be 3.5 mm or more and 4.9 mm or less.

The water supply wick is characterized in that it is made of a cotton material.

The water supply wick is characterized in that the length exposed to the outside of the bottom surface of the plant pot is formed to be 1/2 of the height of the tray module for the green wall.

The water supply wick is characterized in that both ends are provided with a plastic finish covering the set area.

According to an embodiment of the present invention, it is characterized in that it further comprises a pair of fixing rings for fixing the set point of the water supply wick respectively to the first through hole of the first side of the pair.

The fixing ring is characterized in that it is composed of a 'C'-shaped protruding ring and a wing-shaped aggregate of a corresponding shape so that it can be inserted into the first through hole.

The fixing ring is characterized in that the ring is inserted into the first through hole through the water supply wick to fix the water supply wick at a height of 2/3 from the bottom of the plant pot.

The plant port module as described above is arranged so that the first through hole is opened in the water circulation direction during hydroponics to supply water and nutrients to the plants, and in soil cultivation, the water circulation direction and the first through hole are arranged to be opposite to each other And, it is possible to provide water and nutrients to the plant by a watering wick coupled to the plant port so as to be connected to the tray module through the second through hole.

In addition, in a way that the plant pot module of the octagonal pipe shape is inserted and coupled into the port insertion hole of the tray module of the corresponding shape, positioning of the plant pot for uniformly distributing light is easy.

In addition, by combining the fixing protrusion formed in the port insertion hole of the tray module and the fixing projection groove of the plant pot formed to correspond to the fixing projection, it is possible to prevent the plant pot module from being separated from the tray module.

Not only that, the fixing ring can fix the watering wick at the set position of the plant pot, so that the watering wick is placed at the set height inside the plant pot to prevent water shortage in the plant.

1 is a photograph showing a state in which the "plant port module for green wall" of the present invention is coupled to the "body frame".
Figure 2 is a perspective view of the "plant pot" shown in Figure 1 viewed from above.
3 is a perspective view of the "plant port module for green wall" shown in FIG. 1 as viewed from below.
4 is a view showing a path through which the "water supply wick" shown in FIG. 3 is fixed by a "fixing ring" and water is absorbed into the "plant pot".
5 is a view showing a first embodiment and a second embodiment of the "fixing ring" shown in FIG.
6 is a partial perspective view of the "tray module for green wall" shown in FIG.
7 is a view showing a protective cover included in the "plant pot" shown in FIGS. 1 to 4 .

Hereinafter, a preferred embodiment of the plant pot module 1 (hereinafter, “plant pot module”) for a green wall according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a photograph showing a state in which the "plant port module (1)" of the present invention is coupled to the "green wall body frame (F) (hereinafter, "body frame")".

As shown in FIG. 1 , the plant pot module 1 is inserted into the green wall tray module T (hereinafter, “tray module”) coupled to the green wall body frame (F). In more detail, the body frame (F) has a tray module (T) arranged in rows and columns to enable vertical cultivation of plants, and a pump circulation system (not shown) is built in to circulate water. The pump circulation system pulls up water from the water tank (not shown) located at the lower end of the body frame F to the top of the body frame F and releases it from the top. The released water is supplied to the plant pot module (1) and the tray module (T) while falling by gravity. That is, the supplied water is firstly dropped using a water pipe (not shown) built inside the body frame (F) and is partially stored in the tray module (T) or supplied to the plant port module (1) to be described later, and secondarily It is a principle that the water supply wick 30 mounted on the plant port module 1 slowly provides water and nutrients to the plant from the water stored in the tray module T according to the osmotic pressure method.

The gist of the present invention is to provide a plant pot module (1) that is mutually coupled to a tray module (T) specialized for this body frame (F).

Figure 6 is a partial perspective view of the "tray module (T)" shown in Figure 1, with reference to Figure 6, to summarize about the tray module (T) coupled with the present invention.

The tray module T includes a port insertion hole t10 , a guide pipe t30 , a first through hole t50 and a fixing protrusion t11 .

The port insertion hole (t10) is formed to be spaced apart from each other in the shape of an octagonal pipe protruding at a set angle through the front of the tray module (T).

The guide pipe t30 penetrates the bottom surface of the tray module T adjacent to the port insertion hole t10 and vertically protrudes upward and downward in a circular pipe shape.

A plurality of first through-holes t50 are formed through the rear surface of the tray module T corresponding to the upper guide pipe t30 to be arranged in rows and columns.

The fixing protrusion t11 will be described together with the fixing protrusion groove 1131 to be described later for easy understanding.

Based on the components for the tray module (T) described above, the plant pot module (1) of the present invention will be described in detail.

2 is a perspective view of the "plant pot 10" shown in FIG. 1 as viewed from above, and FIG. 3 is a perspective view of the "plant pot module 1" shown in FIG. 1 as viewed from below.

As shown in FIGS. 2 and 3 , such a plant port module 1 includes a plant port 10 and a water supply wick 30 .

The plant pot 10 is largely composed of a side part 11 and a bottom part 13 .

The side portion 11 has a first side surface 111 having a plurality of first through-holes 1111 formed thereon, and a second side surface 113 adjacent to the first side surface 111 is continuously arranged in an octagonal pipe shape.

The bottom part 13 is formed so that a plurality of second through-holes 131 are formed to cover the bottom surface of the side part 11 .

In addition, the water supply wick 30 is formed in a band or rope shape, and both ends from the inside of the plant pot module 1 are exposed through a pair of second through holes 131 and are stored in the tray module T. in contact with water.

The aforementioned plant pot 10 is formed so that the setting angle becomes narrower from the upper end to the lower end. This shape facilitates fastening and separation of the fixing protrusion t11 and the fixing protrusion groove 1131 to be described later by the elastic force of the opening side of the plant port 10 when the plant port module 1 is inserted into the tray module T. do. In this case, it is preferable that the set angle is formed to be 3 to 5°. The reason is, a slope exceeding 5° may reduce the space provided for the planted plant by narrowing the internal volume of the plant pot 10, and a slope of less than 3° causes a problem in which the elastic force of the opening of the plant pot 10 is reduced. because it becomes

In addition, the first through hole 1111 is formed in a rectangular shape in which the long diameter is disposed in the longitudinal direction of the first side surface 111 so that the short diameter of the lower end is rounded, and is formed to be spaced apart in a plurality of horizontally and in a row. The width of the minor diameter is preferably formed to be 3.5 mm or more and 4.9 mm or less. During hydroponics, the first through hole 1111 is opened to face the falling water direction so that water is always provided to the plant, and in soil cultivation, the first through hole 1111 is provided so as not to face the water circulation, that is, the falling water direction. to prevent soil loss by dripping water. In general, during hydroponics, hydro balls or sponges are used instead of soil, and in the case of hydro balls, they are generally formed with a diameter of 5 mm to 9 mm. Therefore, if the minor diameter width of the first through hole 1111 is less than 3.5 mm, a sufficient amount of water may not be provided, and if it exceeds 4.9 mm, there is a risk of loss of contents such as hydro balls. It is preferable that it is 4.9 mm or less.

In addition, the water supply wick 30 is preferably made of a cotton material. The water supply wick 30 should be free to suck in and take out water, the water should flow freely according to the absorption of the soil, and it should be prevented from smelling due to always holding water, so it is preferably made of cotton. In addition, it is preferable that the water supply wick 30 has a length exposed to the outside of the plant port 10 that is 1/2 of the height of the tray module (T). When the tray module (T) is formed to a length of more than 1/2 compared to the height, the end of the water supply wick 30 that is far away from the plant port 10 absorbs water and is transferred into the plant port 10 Absorption is not smooth, which can lead to the growth of bacteria such as mold. In addition, if it is formed to a length less than 1/2 compared to the height of the tray module (T), the length is not wet enough for the movement of water may cause a problem that the plant does not sufficiently absorb the required amount of water.

In addition, the water supply wick 30 is provided with a plastic finishing part 31 surrounding the set area at both ends. The strip or rope-shaped water supply wick 30 may be untied due to the nature of the fiber material, when cutting, when entering and discharging into the first through hole 1111, or in the process of absorbing water for a long time. Therefore, in order to solve this problem, the closing part 31 is formed to surround both end regions except for the portion for absorbing water, thereby preventing the knot crystals at both ends from being untied.

1 and 6, the tray module (T) protrudes from the front in the shape of an octagonal pipe of a size corresponding to the plant pot 10, and is provided with a fixing protrusion t11 formed by protruding one or more inner side ends do. As shown in FIGS. 2 and 3 , the plant pot 10 is formed by having an area corresponding to the fixing protrusion t11 in one or more of the first side 111 and the second side 113 adjacent to the opening. A fixing protrusion groove 1131 is formed. The fixing protrusion t11 preferably has a rectangular parallelepiped shape, but may be formed as a hemispherical protrusion. In the case of the fixing protrusion groove 1131, it is preferably a rectangular groove along the shape of the fixing projection t11, but it may be a circular groove. The coupling method between the fixing projection t11 and the fixing projection groove 1131 requires rotation of a set angle with a constant schedule so that the plant planted in the plant pot module 1 can contain light uniformly, and each side to be rotated All of these should be firmly fixed.

4 is a view showing a path through which water is absorbed into the "plant port 10" by fixing the "water supply wick 30" shown in FIG. 3 by the "fixing ring 50", and FIG. 4 is a view showing the first embodiment and the second embodiment of the "fixing ring 50".

4, a pair of fixing rings 50 for fixing the set point of the water supply wick 30 to the first through hole 1111 of the pair of first side surfaces 111, respectively, are additionally included do. This fixing ring 50 is coupled to the first through hole 1111 corresponding to the height of 2/3 from the bottom of the plant pot (10).

5, the fixing ring 50 may be formed in various shapes.

As shown in (a), the fixing ring (50a) is a rod having a “C” shape in the longitudinal direction, and two parallel sides are in the thickness of the water supply wick 30 and the first through hole 1111. It is formed to be spaced apart to correspond to the thickness of the corresponding plant pot (10) area. At this time, the distance between the two parallel sides is formed to be narrower than the set value, so that when the fixing ring 50a is fastened, the water supply wick 30 is compressed to further strengthen the binding force. The fixing ring 50a is preferably coupled to each of the first through-holes 1111 of the pair of first side surfaces 111 facing each other in the direction in which the openings are opposed to each other.

As shown in (b), the fixing ring 50b is formed in the shape of a wing tongs, and a pair of wing tongs is inserted into the first through hole 1111 adjacent to each other, so that a pair of winged tongs is inserted into the water supply wick 30 ) can also be fixed by wrapping. The fixing ring 50b is composed of a pipe-shaped body, one side of which is cut in the longitudinal direction, and wing tongs coupled to the outer surface of the cut-out position at 180°. The fixing ring (50b) is integrally formed with a synthetic resin having elasticity of the body and the wing tongs, so that when the wing tongs are closed, the incision is opened and passes through the first through hole 1111 to hold the water supply wick 30 do. After installing the watering wick 30 through the second through hole 131 of the plant port 10, a hydro ball or culture soil is put in, and when a plant is planted, the watering wick 30 is pushed down and the plant port (10) is located on the underside of According to the embodiment of Figures 4 and 5, the water supply wick 30 is fixed to the set height inside the plant pot side part 111 by a pair of fixing rings (50). The water wick 30 can absorb and supply water up to a set height by crossing the inside of the plant pot 10 to a set height, as shown in FIG. 4 .

7 is a view showing the protective cover 70 seated in the "plant pot 10" shown in FIGS. 1 to 4 .

As shown in (a) of Figure 7, the plant pot 10 has a protective cover on the top of the soil or hydroball inside the plant pot 10 in which the plant is planted to prevent the soil or hydroball from escaping after planting the plant ( 70) is installed. The protective cover 70 has a shape and size corresponding to the inner circumferential surface of the upper end of the plant pot 10, is formed in an octagonal plate shape, a through hole is formed so that the branch of a plant planted in the central area escapes, and one side is cut It can be easily installed in the plant pot 10 in which the plant is planted.

As shown in (b), the protective cover 70 is preferably formed of a sponge-like porous material sheet. The protective cover 70 may be formed of a sponge or nonwoven fabric. It is possible to prevent the soil or hydroball from escaping from the plant port 10 installed in the tray to be inclined while allowing air to easily pass into the plant port 10 in which the plant is planted.

The plant port module 1 as described above is arranged so that the first through hole 1111 is opened in the water circulation direction during hydroponic cultivation to supply water and nutrients to the plants, and in the case of soil cultivation, the water circulation direction and the first The through hole 1111 is arranged so that it is opposite, and water and nutrients are provided to the plant by the water supply wick 30 coupled with the plant port 10 so as to be connected to the tray module T through the second through hole 131. can make it happen

In addition, in such a way that the plant pot module 1 of the octagonal pipe shape is inserted and coupled into the port insertion hole t10 of the tray module T of the corresponding shape, the positioning of the plant pot 1 for uniformly distributing light (positioning) is easy.

In addition, by combining the fixing protrusion t11 formed in the port insertion hole t10 of the tray module T and the fixing protrusion groove 1131 of the plant pot 10 formed to correspond to the fixing projection t11, the plant pot module ( 1) can be prevented from being separated from the tray module (T).

In addition, the fixing ring 50 can fix the water supply wick 30 to the set position of the plant port 10 so that it can be in contact regardless of the amount of soil.

As mentioned above, although preferred embodiments of the present invention have been described with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains will implement the present invention in other specific forms without changing its technical spirit or essential features. It can be understood that Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

Green wall body frame (F)
Tray module for green wall (T)
Plant pot module for green wall (1)
Plant Pot (10)
side (11)
first side (111)
1st hole (1111)
second side (113)
Fixed projection groove (1131)
Bottom (13)
2nd hole (131)
water wick (30)
Finish (31)
Fixing hook (50)
manure pad(70)

Claims (4)

An octagonal pipe-shaped port insert protrudes from the front, a fixing protrusion is formed on the side end of the insert, and a pump circulation system is built-in to align and combine with the green wall body frame through which water is circulated. In the module,
A side portion in which a first side having a plurality of first through-holes is formed and a second side adjacent to the first side are continuously formed in an octagonal pipe shape corresponding to the port insertion hole, and a plurality of second through-holes are formed, a plant pot comprising a bottom part formed to cover the bottom surface of the side part; and
In a rope shape, both ends are exposed through the pair of second through-holes from the inside of the plant pot, and a water supply wick disposed to contact the water stored in the tray module for the green wall; includes,
The plant pot, a plant pot module for a green wall, characterized in that the fixing projection groove of a corresponding shape is formed through the upper end of the side part so that the fixing projection is inserted.
The method of claim 1,
Further comprising a pair of fixing rings for fixing the set point of the water supply wick respectively to the first through hole of the pair of the first side,
The fixing ring is a rod having a "U" shape in its longitudinal section, and its two parallel sides are spaced apart to correspond to the thickness of the water supply wick and the thickness of the plant pot area corresponding to the first through hole. A plant port module for green wall, characterized in that.
The method of claim 1,
Further comprising a pair of fixing rings for fixing the water supply wick to the first through hole of the first side of the pair, respectively,
It consists of a pipe-shaped body in which one side of the fixing ring is cut in the longitudinal direction, and wing clamps coupled to the outer surface of the 180° position of the cut-off position, wherein the body and the wing clamps are integrally formed of a synthetic resin having elasticity. Plant port module for green wall, characterized in that the incision is opened when the wing tongs are closed.
4. The method according to claim 2 or 3,
The fixing ring is
A plant pot module for a green wall, characterized in that the ring is inserted into the first through hole through the water wick to fix the water wick at a height of 2/3 from the bottom of the plant pot.

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