KR200224166Y1 - A Large Infiltration Well - Google Patents

Abstract

The present invention is used in large penetration protection facilities to collect large quantities of rainwater flowing through the pavement and penetrate it underground. In particular, it can be used in conjunction with stormwater penetration facilities such as infiltration trenches, penetration holes, and small infiltration vessels. The present invention relates to a penetrating well to restrain and restore the natural cycle as much as possible. The upper and lower ends of the hollow wall, which form the walls of the penetrating well, are formed of an impermeable concrete part 11 to have high strength, and the remaining intermediate part is made of porous concrete part. A hollow wall (10) formed of (12) to exhibit a flexural strength of 1.5 to 3.0 N / mm 2 while maintaining a porosity of 20 to 40% and a permeability coefficient of 0.3 to 3 cm / sec; A concrete pedestal 20 for supporting the lower end of the hollow wall 10; Concrete roof body 30 to cover the top of the hollow wall 10 so as to be open and close; as a feature of the technical configuration, to secure the water resources through the cultivation of groundwater and to preserve the soil ecosystem, In general, it contributes to the increase of the base flow of the river to maintain the clean water quality, and in the rain it is effective to prevent flood damage by reducing the amount of rain discharged to the river.

Description

A Large Infiltration Well

The present invention is used in large penetration protection facilities to infiltrate rainwater underground by being buried underground. It is about a large penetration well that can be restored.

Recently, due to the city's population concentration, land development is increasing, and pavement of land surface is rapidly progressing.

Such pavement increases the runoff's global runoff and reduces underground infiltration, resulting in groundwater depletion and consequent ground subsidence in areas of consolidation strata such as clay. In the case of groundwater disturbance such as groundwater desalination due to reverse osmosis of seawater occurs.

In addition, in general, the base flow of the stream is reduced to pollute the water quality, and during rainfall, the river flow is rapidly increased to cause flood damage.

Accordingly, measures were required to infiltrate rainwater underground, and recently, permeable concrete (aka porus concrete) has been developed and applied to pavements such as roads and squares.

It is true that the pavement layer constructed of permeable concrete is able to pass rainwater underground, contributing to the enhancement of groundwater.

However, only a fraction of the rainwater that flows out of the pitched concrete pavement in rainy weather is discharged to the base of the road, and most of the rainwater flows out to the river through the underground drainage channel, so it is very difficult for groundwater to be stabilized. I don't see a big effect.

That is, in general, the pavement layer of the ground surface is inclined so that rainwater flows out to the side in a short time, so the amount of permeation is small, and conventionally, since the side openings of the road and underground drainage pipes are formed of a concrete structure that is not permeable, Rainwater is being discharged into rivers.

Therefore, in order to infiltrate rainwater underground, it is much more efficient to use the trenches and underground trenches of roads where most rainwater passes for a long time than the ground pavement where the rainwater temporarily flows. After collecting rainwater, it is urgently required to install a small infiltration container and a large infiltration tank that slowly infiltrate and store oil.

Accordingly, the present invention is designed to meet the above-described demands in dimensions, and is particularly designed to penetrate underground while collecting and storing large quantities of rainwater flowing in the pavement layer.

Therefore, the purpose of the present invention is to make the concrete structure used as the large penetration protection facility in the ground to be permeable, while restraining the earth's runoff and restoring it to the natural cycle as much as possible by restraining the rainfall of the earth from the rainwater, while linking it with rainwater penetration facilities such as the infiltration trench, infiltration side hole and the small infiltration container. In addition to securing water resources and conserving soil ecosystems through the cultivation of groundwater, it contributes to the increase of the base flow of rivers in normal times to maintain clean water quality and to reduce the amount of rainwater discharged to rivers during rainfall. It is to provide a large penetration protection to prevent damage.

The present invention for achieving the above object is formed by the impermeable concrete portion of the upper and lower ends of the hollow wall to form the wall of the penetration well to have a high strength and to form the remaining intermediate portion of the porous concrete portion to maintain the porosity 20 to 40% bending strength 1.5 A hollow wall 10 having a permeability coefficient of 0.3 to 3 cm / sec, a concrete pedestal supporting the lower end of the hollow wall, and a concrete roof covering the top of the hollow wall so as to be openable and closeable. It provides a large penetration well consisting of a sieve.

1 is an exploded perspective view of a penetration in accordance with a first embodiment of the present invention

2 is a cross-sectional view of an infiltration facility constructed using an infiltration well according to a first embodiment of the present invention;

Figure 3 is an exploded perspective view of the penetration in accordance with a second embodiment of the present invention

4 is a cross-sectional view of an infiltration facility constructed using a penetration well according to a second embodiment of the present invention;

<Explanation of symbols for the main parts of the drawings>

10: hollow wall 11: impermeable concrete

11a: connection ring 11b: connection groove

12: porous concrete part 20: concrete pedestal

21: step 30: concrete roof body

31: large horn large hall 32: cover

33: top 33a: opening

34: Vertical pipe 34a: Pipe connecting groove

35: Small horn coronation 36: Cover

101: gravel layer 102: permeable sheet

W: Penetration well facility t: Penetration trench

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

1 and 3 show a large penetration well according to the first and second embodiments of the present invention.

As shown in these figures, the penetration well according to the present invention has a component that is roughly divided into a hollow wall 10, a concrete pedestal 20, and a concrete roof body 30.

The hollow wall 10 is a structure that permeates the ground while temporarily storing rainwater collected into the penetration well.

The hollow wall 10 is formed of a hollow body in which an iron wire assembly (not shown) interwoven with a horizontal iron wire and a vertical iron wire is embedded in the interior of the wall, and the upper and lower ends are formed of an impermeable concrete part 11 having high strength using fine aggregates. And the remaining intermediate portion is formed of the porous concrete portion 12 that is permeable using crushed stone.

The connecting ring 11a and the connecting groove 11b are formed at upper and lower ends formed of the impermeable concrete part 11 so as to be connected when they are stacked and embedded in the ground.

Porosity, flexural strength, and permeability coefficients vary depending on the size of aggregate and the maximum and minimum dimensions of aggregates, and the strength decreases with increasing porosity and permeability coefficient. The coefficient is lowered. Therefore, the dimensions of the aggregates to be used should be examined according to the use of stormwater infiltration products.

The porous concrete part 12 of the hollow wall 10 according to the present invention has a physical property showing a flexural strength of 1.5 to 3.0N / mm2 and a permeability coefficient of 0.3 to 3 cm / sec while maintaining a porosity of 20 to 40%.

The porous concrete part 12 uses crushed stone having an aggregate particle size of 15 to 30 mm, the unit cement amount is 220 to 450 kg / m2, the water cement ratio is 25 to 40%, and the cement aggregate ratio is 1: 5 to 8.5. It is preferable to exhibit physical properties of 25% of porosity, 2.0N / mm2 of bending strength, and 0.5cm / sec of permeability by using a crushed stone having an aggregate particle diameter of 20 mm.

The concrete pedestal 20 is a structural material supporting the lower end of the hollow wall (10).

The concrete pedestal 20 is made of strong aggregate using the fine aggregate, has a ring shape, basically, the top surface is formed stepped so that the lower end of the hollow wall (10) stepped portion 21 of the top surface It is fitted in the installation.

The concrete roof body 30 is a structural material that covers the upper portion of the hollow wall 10 so as to be openable.

This concrete roof body 30 is made of solid strength using fine aggregates.

1 shows a first embodiment of a concrete roof body 30.

As shown in the concrete roof body 30 according to the first embodiment of the present invention, the lower end portion is fitted to the upper end portion of the hollow wall 10 and a large horn large tube 31 to the top, and large The cover 32 is provided to be opened and closed in the upper opening of the horn tube 31.

The concrete roof body 30 according to the first embodiment of the present invention configured as described above is effectively used when the penetration protection facility W is independently installed in the ground, as shown in FIG. do.

3 shows a second embodiment of a concrete roof body 30.

As shown in the concrete roof body 30 according to the second embodiment of the present invention, the lower plate is formed to fit to the upper end of the hollow wall 10, the upper plate forming an opening hole 33a in one side (33), a vertical pipe 34 fitted with its lower end fitted around the opening hole 33a of the upper plate 33, and the lower end fitted with an upper end of the vertical pipe 34, Murad is composed of a small horn large tube 35 and a cover 36 which is installed to be opened and closed in the upper opening of the small horn large tube 35.

In the above, a predetermined portion of the side wall of the vertical pipe 34 has a thin connection pipe groove 34a formed to be easily drilled.

The concrete roof body 30 according to the second embodiment of the present invention configured as described above is effectively used when the penetration protection facility is installed in the ground in connection with other drainage facilities such as the penetration trench or the penetration side opening.

Referring to the operation according to the installation of the subject innovation configured as described above are as follows.

The present invention is used to construct underground large penetration protection facilities, and such large penetration protection facilities can be installed independently and provide penetration functions in connection with other penetration facilities such as penetration trenches, penetration holes, and small penetration containers. It can also be done.

Figure 2 shows an example of the installation of the penetrating well facility (W) independently installed in conjunction with other infiltration facilities using the infiltration well according to the first embodiment of the present invention, Figure 4 is according to a second embodiment An example of the installation of the penetration protection facility W in which the penetration trench T is connected using the penetration well is shown.

As shown in these drawings, the present invention is embedded in the ground as the concrete pedestal 20, the two-stage hollow wall 10 and the concrete roof body 30 are sequentially stacked, and the top surface is installed to be horizontal to the ground. .

A gravel layer 101 is installed in the periphery of the side wall and the lower part of the hollow wall 10 to uniformly distribute the effluent, and the concrete roof 30 is buried by soil.

The permeation sheet 102 is wrapped around the gravel layer 101 so as not to flow into the gravel layer.

On the other hand, the infiltration well facility (W) of Fig. 4 to which the penetration well according to the second embodiment of the present invention is applied, the penetration trench (T) is connected, and the permeation pipe (P) of the penetration trench (T) is It is installed while penetrating the pipe connecting groove (34a) formed in the vertical pipe 34 of the roof body (30).

The penetration protection facility installed in the above structure has a large rainwater treatment amount per one facility, and therefore is particularly effective in factories, public facilities and houses, and can be installed under an artificial tank, thus having a low oil effect.

In addition, it is installed vertically deep and penetrates into the shear surface, so that it functions effectively in a layer having good water permeability.

Therefore, according to the present invention, rainwater is collected in the interior of Jeongho in order to reduce the burden of rivers, and in general, water is collected in the ground to improve the groundwater.

On the other hand, the subject innovation is to build a penetration facility applied in various structural forms in addition to the above construction examples, the description thereof will be omitted since it can be easily implemented according to the technical idea of the subject innovation.

The present invention is constructed to be permeable as described above and installed in connection with excellent infiltration facilities such as infiltration trenches, infiltration side mouths, and small infiltration tubs.

By restraining stormwater runoff and restoring it to the natural cycle as much as possible, it compensates the damage of the natural environment due to the pavement of the earth's surface.

Cultivate groundwater to secure water resources and preserve underground ecosystems.

Prevents disasters caused by groundwater disturbances such as ground subsidence and groundwater salting caused by depletion of groundwater.

In general, it contributes to the increase of the base flow of the river to maintain clean water quality and to prevent flood damage by reducing the amount of rainwater discharged to the river during rainfall.

It prevents and suppresses the heat island effect caused by the pavement of the earth's surface to maintain a pleasant environment.

Existing drainage facilities can be scaled down, access to sewers not required, and drainage can be reduced, thereby reducing the cost of drainage.

As described above, the present invention is a very useful design that has various effects such as the conservation of natural ecosystems, the securing of water resources, the maintenance of the normal flow of rivers, and the reduction of drainage treatment costs.

Claims (4)

The steel wire assembly interwoven with the horizontal iron wire and the vertical iron wire is embedded into a large hollow wall which is embedded in the inside of the wall and the upper and lower sides thereof are opened. The upper and lower ends of the hollow wall are formed of impermeable concrete parts 11 having high strength using fine aggregates. , The remaining intermediate portion using the crushed stone, while maintaining the porosity 20-40%, the hollow wall 10 formed of the porous concrete portion 12 having a flexural strength of 1.5 ~ 3.0N / ㎜ and having a permeability coefficient of 0.3 ~ 3cm / sec and ; The lower end of the hollow wall (10) is fitted to the upper end and is formed in a ring shape concrete support (20) to support the lower end of the hollow wall (10); The porous concrete part 12 of the hollow wall 10 is used for the crushed stone having an aggregate particle size of 15 ~ 30mm, the unit cement amount is 220 ~ 450kg / ㎡ and the water cement ratio is 25 ~ 40% Large penetration penetrating furnace, characterized in that formed by mixing the cement aggregate ratio 1: 5 ~ 8.5. According to claim 1, further comprising a concrete roof body 30 that covers the upper portion of the hollow wall (10), the roof 30 is fitted to the lower end of the upper end of the hollow wall (10) The large penetrant well characterized in that it consists of a large horn large tube 31 and a cover 32 installed to be opened and closed in the upper opening of the large horn large tube 31. According to claim 1, further comprising a concrete roof 30 to cover the upper portion of the hollow wall 10, the roof 30 is formed so that the lower end is fitted to the upper end of the hollow wall (10) While the upper plate 33 which forms the opening hole 33a in one side portion, the lower end is fitted around the opening hole 33a of the upper plate 33, and the vertical pipe 34 which is raised upward, and the vertical pipe ( 34) is characterized in that the lower end is fitted with a small horn large tube 35 is fitted in the upper portion, and the cover 36 is installed to be opened and closed in the opening of the upper surface of the small horn large tube (35). Large penetration