KR101295326B1 - Vegitation block - Google Patents

Abstract

The present invention relates to a block capable of growing a plant while preventing soil from flowing down, and more particularly, a base block having upper and lower openings stacked in a stepped shape; and an upper end opening and penetrating at one side. A ball is formed and installed in the base block to store rain water; And a plate having a plurality of holes into which rainwater is introduced to be installed in the upper portion of the reservoir, and normally closing the hole, and when rainwater flows into the hole, the plate is opened by the weight of the rainwater so that rainwater flows into the reservoir. It is installed in the opening and closing portion having a door for opening and closing the hole; including, in the state in which the rain water is stored in the storage unit to close the upper end of the storage unit to prevent the rain water stored in the storage unit to escape from the storage unit, It is achieved by the vegetation block, characterized in that for supplying rainwater stored through the through-hole into the base block. Accordingly, it is possible to store the rainwater for a long time by preventing the stored rainwater to escape from the storage by evaporation, there is an advantage that the plant grows wild for a long time by continuously supplying rainwater to the plant growing in the basic block during the drought.

Description

Vegetation block

The present invention relates to a block in which a plant can grow natively while preventing soil from flowing down, and more specifically, to store rainwater when it rains, to use rainwater when it does not rain, and to store the rainwater that evaporates and escapes. The present invention relates to a vegetation block in which a plant can grow for a long time by supplying rainwater stored in a plant that grows in a block during a drought while preventing it from being stored for a long time.

Conventional vegetation block is provided with a space for storing rainwater, but this has a problem that the stored rainwater is not evaporated properly stored rainwater. In particular, depending on the climate, that is, if the drought is severe, plants growing in the vegetation block must be supplied with continuous water to overcome the drought. In the case of the conventional vegetation block, it is necessary to supply a large amount of rainwater without adjusting the water supply amount. So, if the drought persists, there is a problem that the plants growing in the vegetation block is dead.

The present invention has been made in order to solve the above problems, install a storage unit for storing rainwater inside the base block, it is possible to store the rainwater for a long time by preventing the stored rainwater to evaporate out of the storage unit, when the drought The purpose is to provide a vegetation block that the plant can grow for a long time by continuously supplying rainwater to the plants growing in the block.

An object of the present invention, the top and bottom openings are stacked in the form of a staircase; And, the top is open, the through-hole is formed on one side, the storage unit is installed in the base block to store rain water; And a plate having a plurality of holes into which rainwater is introduced to be installed in the upper portion of the reservoir, and normally closing the hole, and when rainwater flows into the hole, the plate is opened by the weight of the rainwater so that rainwater flows into the reservoir. It is installed in the opening and closing portion having a door for opening and closing the hole; including, in the state in which the rain water is stored in the storage unit to close the upper end of the storage unit to prevent the rain water stored in the storage unit to escape from the storage unit, It is achieved by the vegetation block, characterized in that for supplying rainwater stored through the through-hole into the base block.

In addition, the through hole may be formed to be inclined upward from the bottom of the reservoir.

In addition, the base block may be formed with a guide groove on the outer surface of the base block so that rainwater flows directly into the storage unit without passing through the inside of the upper base block in the stacked base block.

In addition, the filter membrane is installed in front or rear of the opening formed in one side of the storage unit to prevent rain water stored in the storage unit quickly exits to the base block; may further include.

The apparatus may further include a supply unit installed in the through hole and supplying rainwater stored in the storage unit to the inside of the base block.

In addition, when the amount of rainwater stored in the storage unit is large, the amount of rainwater supplied by the supply unit decreases, and when the amount of rainwater stored in the storage unit is small, the opening of the supply unit is controlled to increase the supply amount of rainwater supplied by the supply unit. It may further include a control valve.

According to the present invention, the storage unit storing rainwater can store rainwater for a long time, and in particular, by installing a door that opens and closes the upper end of the storage unit to prevent the stored rainwater from evaporating and escaping from the storage unit, the rainwater can be stored for a long time. . Accordingly, even if the drought persists by continuously supplying rainwater to the plants growing in the base block, it is possible to prevent the plants from drying out and at the same time the plants can grow on their own.

1 is an exploded perspective view of a vegetation block according to an embodiment of the present invention.
2 is a side cross-sectional view of FIG. 1.
3 is a cross-sectional view showing a state of use of the vegetation block according to an embodiment of the present invention.
4 is an exploded perspective view of a vegetation block according to another embodiment of the present invention.
5 is a side cross-sectional view of FIG. 4.
6 and 7 are cross-sectional views showing the operating state of the vegetation block according to another embodiment of the present invention.
8 is a cross-sectional view showing a state of use of the vegetation block according to another embodiment of the present invention.
9 is a cross-sectional view showing another embodiment of the door in the present invention.
10 is a perspective view showing another embodiment of the storage unit in the present invention.

An object of the present invention, the top and bottom opening base blocks (1, 1a, 1b) are stacked in a staircase shape; and the top is opened, through-holes 22, 22 'is formed on one side, Storage units (2, 2a, 2b) installed in the blocks (1, 1a, 1b) to store rainwater; And a plurality of holes 311 through which rainwater flows, and plates 31, 31a and 31b installed on the upper portions of the storage parts 2, 2a and 2b, and normally close the holes 311 and the holes 311. When the rainwater is introduced into the door, the door is opened at the bottom of the plates 31, 31a and 31b to open and close the holes 311 so that the rainwater is opened by the weight of the rainwater so that the rainwater flows into the storage portions 2, 2a and 2b. Opening and closing portion (3) having a (32, 32 '), including, but the opening and closing portion 3 is the upper end of the storage portion (2, 2a, 2b) in a state in which rain water is stored in the storage (2, 2a, 2b) Closed to prevent rainwater stored in the reservoirs 2, 2a, and 2b from evaporating and escaping from the reservoirs 2, 2a, and 2b, and bringing rainwater stored through the through holes 22 and 22 'into the basic block. It is achieved by a vegetation block characterized in that the feeding.

In addition, the storage unit 2 may have a through hole 22 inclined upward from the bottom of the storage unit 2.

In addition, the base blocks 1, 1a and 1b do not pass through the inside of the upper base blocks 1, 1a and 1b in the stacked base blocks 1, 1a and 1b, and rainwater is stored in the storage units 2 and 2a. , 2b), the guide groove 11 may be formed on the outer surface of the base block (1, 1a, 1b).

In addition, the filtration membrane is installed in the front or rear of the through hole 22 formed in one side of the storage unit 2 to prevent the rain water stored in the storage unit 2 quickly exits to the base block ( 6); may further include.

In addition, the supply unit 4 is installed in the through hole 22 'and supplies rainwater stored in the storage unit into the base blocks 1a and 1b.

In addition, when the amount of rainwater stored in the storage units 2a and 2b is large, the supply amount of rainwater supplied by the supply unit 4 decreases, and when the amount of rainwater stored in the storage units 2a and 2b is small, the supply unit 4 It may further include a control valve (5) for adjusting the opening of the supply unit 4, so that the supply amount of rain water to be supplied.

1 is an exploded perspective view of a vegetation block according to an embodiment of the present invention;

2 is a side cross-sectional view of FIG.

3 is a cross-sectional view showing a state of use of the vegetation block according to an embodiment of the present invention;

4 is an exploded perspective view of a vegetation block according to another embodiment of the present invention;

5 is a side cross-sectional view of FIG.

6 and 7 are cross-sectional view showing an operating state of the vegetation block according to another embodiment of the present invention,

8 is a cross-sectional view showing a state of use of the vegetation block according to another embodiment of the present invention;

9 is a cross-sectional view showing another embodiment of the door 32 'in the present invention;

10 is a perspective view showing another embodiment of the storage unit 2b in the present invention.

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

As shown in Figures 1 to 3, the vegetation block according to an embodiment of the present invention, the base block, the storage unit and the opening and closing portion.

The base block 1 is formed in a rectangular box shape having approximately upper and lower openings, and a guide groove 11 is formed at the front side thereof, and the insertion groove 12 is fixed to the storage portions 2 at both inner side surfaces and the inner rear surface. It is formed long in the vertical direction. Then, after installing the storage part 2 and the opening and closing part (3) in the interior of the base block (1), and fills the soil remaining in the space remaining after the installation is fixed to the slope adjacent to the mountain or river and road. After stacking the present invention in the form of a step thereon, the above-described method is repeated to stack the present invention.

The storage unit 2 is formed of a waterproof concrete or reinforced plastic to prevent rainwater from escaping in the form of a rectangular box having an approximately upper end, and includes an insertion groove 12 of the base block 1 on both outer sides and the rear surface thereof. The projection 21 is fitted to the) is formed, the through hole 22 is formed inclined from the bottom of the storage unit 2 in the upper front. This is to store the maximum amount of rainwater in the storage unit (2). If the through hole 22 is formed horizontally, the rain water may be stored up to the position where the through hole 22 starts, but in order to supply rain water stored in the storage unit 2 to the foundation block 1, a separate supply may be performed. Means are needed. Therefore, the through-hole 22 is formed to be inclined upwardly from the bottom of the storage part 2 so that even water stored in the bottom of the storage part 2 can be supplied. Then, the projection 21 of the storage unit 2 is inserted into the insertion groove 12 of the base block 1 is disposed inside the rear of the base block (1). At this time, the inside of the storage unit 2, the gravel is installed as the height of the through-hole 22, and after the gravel is installed, the soil is filled in the through-hole 22. This is to absorb the rainwater stored in the storage unit 2 to the soil filled in the through hole 22 to supply the soil filled in the foundation block (1). For example, when the gravel is not laid on the bottom of the storage unit 2, the soil filled in the base block 1 may flow into the storage unit 2 through the through hole 22. Therefore, the gravel is laid at the bottom of the storage unit 2, and the gravel is filled by the height of the through hole 22 to prevent the soil from entering the inside of the storage unit 2 through the through hole 22.

The opening and closing part 3 includes a plate 31 and a door 32 to open and close the upper opening of the storage part 2.

The plate 31 is formed of waterproof concrete, reinforced plastic, or steel to support the weight of the earth and sand filled in the base block 1 in the form of "b" while having a substantially lower end and having a side cross-section. A plurality of holes 311 are formed at the rear of the bottom and cover the top opening of the storage unit 2. In addition, the plate 31 may be formed by protruding the flow preventing piece 312 to be fitted into the insertion groove 12 of the base block 1 on both sides. This is because, in the process of laminating the present invention, the plate 31 may be pushed by the soil and flow forward. Therefore, to prevent the plate 31 from flowing in the interior of the base block (1), on both sides of the plate 31 is formed a flow preventing piece 312 to be fitted into the insertion groove 12 of the base block (1) It is. In this case, the length of the insertion groove 12 of the base block 1 is formed to correspond to this, so that the top end of the plate 31 coincides with the top end of the base block 1. This is because, when the plate 31 protrudes from the base block 1, the base block 1 to be stacked on the upper part may be caught by the plate 31 in the process of stacking the present invention, and the gap may be formed therebetween. Therefore, in order to prevent this, the uppermost end of the plate 31 and the uppermost end of the base block 1 are to coincide.

Here, the reason for arranging the bottom of the plate 31 under the top end of the base block 1 is to lay gravel on the top of the plate 31. This is because the holes 311 of the plate 31 may be blocked by earth and sand. If the gravel is first placed directly on the hole of the plate 31, the earth and sand are blocked to prevent the holes 311 of the plate 31 from being blocked. can do. If the bottom of the plate 31 is located at the top of the base block 1, the gravel will roll down without being fixed on the plate 31. Therefore, in order to lay gravel on the bottom of the plate 31, it is preferable to arrange the bottom of the plate 31 below the top of the base block (1).

As shown in FIGS. 1 and 2, the door 32 has a substantially concave rectangular panel shape and is made of silicon having excellent elasticity, and when the weight of the rainwater is greater than or equal to a certain weight, the rainwater into the storage unit 2. A plurality of inlet holes 321 are formed on one surface thereof so as to flow in, and are in close contact with the bottom of the plate 31 so as to open and close the holes 311 of the plate 31. That is, although the inlet hole 321 of the door 32 is normally blocked, when rain water is accumulated on the upper part of the door 32 and becomes over a certain weight, the inlet hole 321 is opened while the cut portion of the inlet hole 321 opens. 321 is opened and rainwater flows into the storage unit 2, and when the weight of rainwater accumulated on the upper portion of the door 32 is less than a certain weight, the cut portion of the inlet hole 321 is retracted and flows in. The ball 321 is closed. Accordingly, since the inlet hole 321 of the door 32 is normally kept closed, the water stored in the storage unit 2 is prevented from evaporating and escaping through the hole 311 of the plate 31. . The inlet hole 321 of the door 32 may be formed as a slit long cut. That is, the slit structure is because the inflow of rainwater can be sent down more quickly and a larger amount of rainwater to the storage unit (2).

Here, the filtration membrane 6 may be installed in front of or behind the through hole 22 of the storage unit 2.

The filtration membrane 6 is provided in the form of a metal mesh or a nonwoven fabric at the rear of the through hole 22 or to cover the front wall of the storage part 2, that is, at the front and rear of the through hole 22. . This is to prevent the earth and sand filled in the through hole 22 of the storage unit 2 from excessively absorbing rainwater stored in the storage unit 2 and supplying the soil to the earth block filled in the base block 1. For example, when the drought persists, a constant water supply is necessary to prevent the plants planted in the foundation block 1 from dying. However, when the rainwater stored in the storage unit 2 is excessively absorbed and supplied to the plant, the rainwater stored in the storage unit 2 may be rapidly consumed to prepare for a persistent drought. Accordingly, the filtration membrane 6 is placed in front of and behind the through hole 22 so as to slow down the consumption of the rain water stored in the storage unit 2, that is, the rain water slowly penetrates through the through hole 22. The filtration membrane 6 prevents the soil from filling the through hole 22 from flowing into the storage 2. Of course, it is selected in consideration of the air permeability of the filtration membrane 6 so that the water planted in the foundation block 1 does not dry out. Accordingly, even if the drought lasts for a long time, the filtration membrane 6 slows down the consumption of rain water to prevent the plants planted in the foundation block 1 from drying out.

In the case where the filtration membrane 6 described above is a metal mesh, the filter membrane 6 may be fixed to the rear of the through hole 22, and gravel may be omitted in the storage 2.

Meanwhile, as shown in FIGS. 4 to 8, the vegetation block according to another embodiment of the present invention includes a base block 1a, a storage unit 2a, an opening and closing unit 3, and a supply unit 4. It further includes a control valve (5).

The base block 1a is formed in a rectangular box shape with substantially upper and lower openings, and a guide groove 11 is formed on the front surface, and the insertion groove 12 is vertical so that the storage portions 2a are fixed to both inner surfaces thereof. It is formed long in the direction. Then, after installing the storage part 2a, the opening and closing part 3, the supply part 4 and the control valve 5 in the inside of the foundation block 1a, the soil is filled in the remaining space after installation and adjacent to the mountain or the river. Secure to the slope of the bank. After stacking the present invention in the form of a step thereon, the above-described method is repeated to stack the present invention. A description thereof will be described later.

The storage portion 2a is formed of a synthetic resin material to prevent rainwater from escaping in the form of a rectangular box having an uppermost opening, and a protrusion fitted into the insertion groove 12 of the base block 1a on both outer sides thereof. 21 is formed, and a through hole 22 'into which the supply part 4 is fitted is formed in front of the upper end. And the projection 21 of the storage part 2a is fitted in the insertion groove 12 of the base block 1a, and is arrange | positioned inside the back of the base block 1a. A description thereof will be described later.

The opening and closing part 3 includes a plate 31a and a door 32 to open and close the upper end opening of the storage part 2a.

The plate 31a is formed of a reinforced plastic or steel to support the weight of the earth and sand filled in the base block 1a in the form of a rectangular box having an open top and a low height, and a plurality of plates 31a behind the bottom of the plate 31a. A hole 311 is formed and covers the top opening of the reservoir 2a. Here, the plate 31a may be bent downward by one region around the plate 31a so as to fit around the outer circumference of the storage unit 2a. Accordingly, the plate 31a can be prevented from falling out to the bottom of the storage part.

Here, the reason for arranging the bottom of the plate 31a under the upper end of the storage part 2a is to lay gravel on the top of the plate 31a. This is because the holes 311 of the plate 31a may be blocked by soil or sand. If the gravel is first placed directly on the hole of the plate 31a, the soil or sand blocks the gravel and the holes 311 of the plate 31a. This can be prevented from clogging. If the bottom of the plate 31a is located at the top of the reservoir 2a, the gravel will roll down without being fixed on the plate 31a. Therefore, in order to lay gravel on the bottom of the plate 31a, it is preferable that the bottom of the plate 31a is disposed below the upper end of the reservoir 2a.

Here, a mesh (not shown) may be installed instead of the plurality of holes 311 formed in the plate 31a.

The door 32 is hinged to the bottom surface of the plate 31a in the form of a substantially rectangular panel, and a return spring 34 is installed on the hinge shaft 33 so as to block the hole 311 of the plate 31a. do. At this time, the elastic force of the return spring 34 is to open the door 32 when the weight of the rain water is more than a certain weight, the door 32 is formed to be concave to collect the rain water. Therefore, when rainwater gathers and the weight is greater than a certain weight, the door 32 is opened and rainwater flows into the storage unit 2a, and rainwater is stored in the storage unit 2a, and when the weight of the rainwater is less than a certain weight, the door ( 32 rotates to block the holes 311 of the plate 31a to prevent rainwater stored in the storage unit 2a from evaporating and escaping through the holes 311. Here, the door 32 has been described as being closed by the return spring 34, but by omitting the return spring 34 and quoting the two-arm scale function, the weight 32 (opposed) on the opposite side of the door about the hinge axis 33 Can be closed by closing it. At this time, the weight is set to the weight of the weight so that the door is opened when the rain water collects on the door with a certain degree heavy than the weight of the door around the hinge axis.

Meanwhile, as illustrated in FIG. 9, the door 32 ′ has a substantially concave rectangular panel shape, and is formed of silicon having excellent elasticity, and the rainwater flows into the storage unit 2a when the weight of the rainwater is greater than or equal to a certain weight. A plurality of inflow holes 321 are formed on one surface thereof, and are formed to be in close contact with the bottom surface of the plate 31a to open and close the hole 311 of the plate 31a. That is, although the inlet hole 321 of the door 32 'is normally blocked, rain water collects on the upper part of the door 32', and if the inlet hole 321 is cut, the inlet hole (321) is opened. 321 is opened and rainwater flows into the storage unit 2a. If the weight of rainwater accumulated on the upper portion of the door 32 'is less than a certain weight, the cut portion of the inlet hole 321 is closed and the inlet hole 321 is closed. ) Is closed. Accordingly, since the inlet hole 321 of the door 32 'is normally kept closed, the water stored in the storage unit 2a is prevented from evaporating and escaping through the hole 311 of the plate 31a. .

The supply part 4 has a tube 42 and a wick 41 which absorbs the water in the tube 42, and supplies water stored in the storage part 2a to the front interior of the base block 1a. . Here, the supply part 4 may omit the tube 42 and only the wick 41 may be used, and the wick 41 may be a fiber or sponge having excellent elasticity and absorbing water well. Accordingly, the wick 41 absorbs the water stored in the storage unit 2a and moves to the earth and sand filled in the base block 1a so that the earth and sand are wet. At this time, the plants planted in the soil will be absorbed by the soil and grow native. Therefore, by supplying the water stored in the storage unit 2a in the drought to the plants planted in the base block 1a, it is possible to prevent the plants from being killed in the drought.

The control valve 5 includes a rotary bar 51 hinged to the bottom of the plate 31a and rotated, a pressing piece 52 for pressing the supply part 4 to one end of the rotary bar 51, and a rotary bar ( Float 53 provided in the other end of 51 is provided. For example, when water rises in the storage part 2a, the float 53 rises, and the pressing piece 52 descends and presses the supply part 4. Accordingly, the pressing piece 52 presses or releases the supply unit 4 to adjust the amount of water supplied by the supply unit 4 to the earth and sand filled in the basic block 1a. A description thereof will be described later.

Meanwhile, the storage unit 2b may be formed by omitting the protrusion 21 as shown in FIG. 10, and extending the upper end outward so as to be placed around the upper end of the base block 1b, and inserting a plate. The inner side can be formed stepped. In this case, the above-described insertion groove 12 of the base block 1b may be omitted, and the plate 31b may be formed flat.

Hereinafter, with reference to the accompanying drawings will be described in detail the state of use of the vegetation block according to an embodiment of the present invention.

After the foundation block 1a is installed on the ground, a certain amount of soil is filled in the foundation block 1a, and the storage unit 2a, the opening and closing unit 3, and the supply unit 4 are coupled to each other to form the foundation block 1a. Install on the inside. Then, plant the plants in the remaining space and fill the soil. At this time, the earth and sand behind the base block (1a) is compacted so as to be in close contact with the rear of the base block (1a).

When the first vegetation block is installed, the foundation block 1a is again installed thereon, and the above method is repeated and stacked in a step shape.

At this time, when it rains, rainwater penetrates into the earth and sand filled in the vegetation block disposed at the top, and some of the water is introduced into and stored in the storage unit 2a through the holes 311 of the plate 31a. Soak under the rear of 1a). That is, part of the rainwater is filled in the storage portion 2a and the rest is absorbed into the inclined ground.

If the rain falls less, since the rainwater directly descends through the guide groove 11 formed on the front surface of the foundation block 1a and reaches the upper surface of the plate 31a, the rainwater does not pass through the soil filled in the interior of the foundation block 1a. Plate 31a can be reached directly. Therefore, even if there is little rain, rainwater can be easily stored in the storage unit 2a (see FIG. 8).

Here, when the rainwater is filled in the reservoir 2a, when the water level rises, the float 53 of the control valve 5 rises, and the pressing piece 52 descends. Therefore, the pressing piece 52 presses the supply part 4, and the rain water stored in the storage part 2a is supplied little by little to the earth-filled soil which filled the base block 1a.

In droughts, for example, plants need more water. At this time, it is possible to know the persistence of the drought with the amount of rain water stored in the storage unit 2a. That is, since a large amount of rainwater is stored in the storage unit 2a, it is possible to store a large amount of rainwater in the storage unit 2a because it is raining, and that the rainwater of the storage unit 2a is reduced is a storage unit 2a. ) Means that it will not rain for long periods of time while supplying rainwater to the soil.

For this reason, it can be seen that the drought lasted as the rainwater stored in the storage unit 2a decreased, and when the drought persisted, the plants planted in the foundation block 1a needed a larger amount of rainwater because they had been kept dry for a long time. Done.

However, when the rainwater of the storage part 2a decreases, the floating material 53 descends and the pressing piece 52 which pressed the supply part 4 rises. As a result, the opening of the supply part 4 becomes large, and more rainwater stored in the storage part 2a can be supplied to the earth and sand, thereby preventing the plant planted in the vegetation block from being killed. (See FIGS. 6 and 7. )

As described above, the present invention by supplying rainwater stored in plants planted in the basic block (1a) during the drought does not rain by storing rainwater when raining, it is possible to prevent the plant from being killed, in particular rainwater is evaporated The door 32 is prevented from escaping into the hole 311 of the plate 31a so that rain water can be stored in the storage unit 2a for a long time, so that the plant can grow long in the vegetation block even if the drought persists.

In addition, in the vegetation block of the present invention, by forming a space without filling gravel or soil in the storage unit 2a, a float can be installed inside the storage unit 2a, and after a lot of rain, the storage unit 2a. Water is filled in the float 53 floats to squeeze the wick 41 of the supply (4). When the water is filled in the storage unit 2a in this way, there will be a lot of moisture in the earth and sand outside the storage unit 2a. Therefore, it is preferable to limit the discharge of the water in the storage unit 2a to the outside to a minimum. If there is little moisture in the external earth and sand after the rain does not come out of the water through the wick (41) to the external earth and sand through the wick 41, the water in the storage unit (2a) is reduced and the float 53 is lowered at this time The wick 41 is gradually released from the pressing state and supplies a sufficient amount of water from the reservoir 2a to the external soil. That is, by forming the inside of the storage unit 2a into an empty space, a larger amount of water can be stored, and at the same time, the amount of water supplied to the external soil by installing the float 53 can be changed according to the moisture content of the external soil. .

In describing the present invention described above, even if the embodiment is different, the same reference numerals are used for the same configuration, and the description may be omitted as necessary.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Shall not be construed as being understood. Therefore, a person having ordinary knowledge in the technical field to which the present invention pertains may easily implement other forms of the present invention within the same scope as the above-described embodiments, or the present invention only by the description of the embodiments of the present invention. It will be possible to practice the invention in the same and equal range.

1, 1a, 1b; Foundation block
11; Guide groove
12; Insert groove
2, 2a, 2b; The storage unit
21; spin
22, 22 '; Through hole
3; draw
31, 31a, 31b; plate
311; hole
312; Flow prevention piece
32, 32 '; door
33; Hinge axis
34; Return spring
321; Inflow ball
4; Supplier
41; Wick
42; tube
5; Control valve
51; Rotating bar
52; Pushing piece
53; floating matters

Claims (1)

A base block having upper and lower openings stacked in a stepped shape;
An upper end of the opening and a through hole formed at one side thereof, the storage unit being installed in the base block to store rain water; And
A plurality of holes in which rainwater is introduced is formed, and the plate is installed on the upper part of the storage unit. Normally, the hole is closed and when rainwater flows into the hole, the rainwater flows into the storage unit by opening by the weight of the rainwater. To include, the opening and closing portion provided on the bottom of the plate having a door for opening and closing the hole,
In the state where the rainwater is stored in the storage unit, the opening and closing unit closes the upper end of the storage unit to prevent the rainwater stored in the storage unit from being evaporated from the storage unit, and the rainwater stored through the through hole is stored in the basic block. Supplies
The storage part is formed in the through hole is inclined upward from the bottom of the storage part,
The base block is a guide groove is formed on the outer surface of the base block so that rain water flows directly into the storage unit without passing through the inside of the upper base block in the stacked base block,
Further comprising a filtration membrane is installed in front of or behind the opening formed in one side of the storage unit to prevent rain water stored in the storage unit quickly exits to the base block,
A supply unit installed in the through hole and supplying rainwater stored in the storage unit into the base block;
When the amount of rainwater stored in the storage unit is large, the supply amount of rainwater supplied by the supply unit decreases, and when the amount of rainwater stored in the storage unit is small, opening of the supply unit is increased so that the supply amount of rainwater supplied by the supply unit increases. Vegetation block further comprising a control valve for adjusting.

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