KR20190090987A - Side restraint type permeable pavement structure - Google Patents

Abstract

The present invention relates to a side restraint type permeable pavement structure, including: a permeable auxiliary base layer which is permeable by compaction of first filler on an upper portion of a natural ground; a plurality of permeable retaining wall blocks arranged on an upper portion of the permeable auxiliary base layer while forming separation and inducing water from the upper portion to the permeable auxiliary base layer of the lower portion; an impermeable pavement base layer formed by compaction of second filler having a smaller particle size than the first filler between the permeable retaining wall blocks; and a permeable pavement layer provided on an upper portion of the pavement base layer.

Description

Side restraint type permeable pavement structure

The present invention relates to a packaging structure that can ensure permeability and at the same time improve resistance to deformation, deflection, and the like due to lateral restraint.

As water quality problems are raised due to rapid industrial development and urbanization, many cities around the world have begun to address the need for an economically efficient and sustainable water circulation system for water protection. It also raised questions about the effectiveness of existing water management systems in ecosystem protection and water quality management. Due to the change of land use pattern due to urbanization, impervious layers have increased, causing problems such as flood damage, urban non-point pollution damage, groundwater depletion and ground subsidence, and river dryness. As an alternative to solving this problem, the United States first proposed a new urban planning technique called Low Impact Development (LID).

As an example of the structure for preventing the increase of the water-permeable layer, that is, the distortion of the water circulation, a permeable packaging structure has been presented in various ways, for example, Republic of Korea Patent No. 0703513, Styrene-based acrylic resin 50 ~ 75 wt%, styrene 20 to 25 wt% of an elastic packaging binder prepared by mixing and stirring 5 to 25 wt% of butadiene latex, 5 to 10 wt% of a filler, 1 wt% of a thickener, 1 wt% of an antifoaming agent, and 1 wt% of a stabilizer; Elastic permeable packaging, characterized in that by mixing and packing 75 to 80% by weight of the elastic chip mixed with a cork chip having a size of 1 ~ 5㎜, and then chopped with a 20 ~ 30kg roller heated to 50 ~ 80 ℃ Presenting a sieve.

However, according to the above technique, even if the permeability is secured, structural problems such as deformation and deflection that may occur in the base layer or the auxiliary base layer below the upper surface layer exist.

Republic of Korea Registered Patent

The present invention has been made to solve the above problems, it is to provide a packaging structure to ensure structural integrity by improving the water permeability and at the same time improve the resistance to deformation, deflection, and the like.

As a means for solving the above problems, the side-blocking permeable packaging structure according to the present invention (hereinafter referred to as the "packaging structure of the present invention") is a permeable permeable auxiliary layer by the compaction of the first filler on the base; A permeable retaining wall block arranged to form a plurality of spaced portions on the permeable auxiliary layer and allowing water from the upper side to be led to the permeable auxiliary layer on the bottom; An impermeable paver layer between the permeable retaining wall blocks due to compaction of a second filler having a smaller particle size than the first filler; It characterized in that it comprises a; permeable permeable packaging layer on the packaging layer.

As an example, a reinforcing grid is formed between the permeable retaining wall block and the permeable auxiliary layer in which a protrusion is formed in a lattice shape.

A plurality of fastening protrusions are inserted into and fastened to the protruding protrusion, and the receiving groove is formed in the lower surface of the permeable retaining wall block to accommodate the fastening protrusion.

As an example, the permeable retaining wall block may be formed of a permeable material or a permeable hole penetrating the upper and lower surfaces.

As an example, the permeable retaining wall block is characterized in that the storage hole penetrates in the transverse direction.

As an example, the permeable retaining wall block may have a storage hole formed in a groove shape in a transverse direction on a lower surface thereof.

As an example, the permeable retaining wall block may be formed with a permeable hole penetrating the upper and lower surfaces, wherein the permeable hole is filled with a third filling material.

As an example, between the packaging base layer and the permeable packaging layer, a support stabilizer layer of a permeable material is formed to guide a permeable retaining wall block to form a horizontal flow of water introduced from the permeable packaging layer.

As described above, the pavement structure of the present invention ensures permeability against rainwater, and at the same time structurally induces a lateral restraint (lateral confined pressure) effect on compaction load and vertical vehicle load during construction. Since it can prevent deformation, horizontal rolling, etc., there is an advantage of excellent durability.

1 is a perspective view showing an example of the present invention,
2 is a flowchart of water in the packaging structure of the present invention,
3 is a view showing the construction flow of the packaging structure of the present invention,
4 is a view showing the working load in the packaging structure of the present invention,
5A to 5D are perspective views showing an example of the permeable retaining wall block of one configuration of the present invention;
6 is a side cross-sectional view showing another example of the permeable retaining wall block of one configuration of the present invention.

Hereinafter, the configuration and operation of the present invention will be described in more detail with reference to the accompanying drawings. In describing the present invention, the term or word used in the present specification and claims is based on the principle that the inventor can appropriately define the concept of the term in order to best describe the invention of his or her own. It should be interpreted as meanings and concepts corresponding to the technical idea of

The packaging structure (1) of the present invention, as shown in Figure 1 is a permeable permeable auxiliary layer (2) by the compaction of the first filler on the upper base (g); A permeable retaining wall block (3) arranged to form a plurality of spaced apart on the permeable auxiliary layer (2) to direct water from the top to the permeable auxiliary layer (2) at the bottom; An impermeable packaging base layer (4) between the permeable retaining wall blocks (3) by compaction of a second filler having a smaller particle size than the first filler; It characterized in that it comprises a; permeable permeable packaging layer (5) on the packaging machine layer (4).

That is, in the present invention, as shown in FIG. 2, the water (w1) permeated by the water-permeable packaging layer (5) is a horizontal flow in the upper part of the paver layer (4) of the impermeable layer, while the lower flow through the permeable retaining wall block (3). (w3), and this lower flow (w3) is directed to the flow (w4) in the permeable permeable auxiliary layer (2) to induce penetration into the reservoir or ground (g) in the permeable auxiliary layer (2) In particular, by the permeable retaining wall block (3) to induce the lateral restraint it is possible to prevent the deformation, subsidence, etc. by firmly compacting the packaging layer 4 is to be presented a durable permeable packaging structure.

The permeable auxiliary layer (2) is formed by the compaction of the first filler on the top of the base (g) as shown in Figures 1 and 3, the first filler is a relatively large particle size, such as crushed stone, recycled aggregates can be used As can be seen, as mentioned above, the permeation aid layer 2 is a permeable structure that allows the permeation of the water permeated from the top or the ground base g.

The permeable retaining wall block (3) is arranged to form a plurality of spaced apart on the permeable auxiliary layer (2) and guides the water penetrated from the permeable packaging layer (5) to the permeable auxiliary layer (2) and at the same time the packaging base layer The lateral restraint effect is expressed in (4) to prevent settlement, deformation, horizontal rolling and the like against compaction load and vertical vehicle load during construction.

The permeable retaining wall block 3 preferably has a cross section of a lower light bar, so that the cross-sectional structure further improves resistance.

The permeable retaining wall block (3) is to be installed in the equilibrium on the permeable auxiliary layer (2) while forming a mutual separation as shown in the figure.

In addition, between the permeable retaining wall block 3 and the permeable auxiliary layer 2, a reinforcing grid 6 in which the protrusions 61 are formed in a lattice shape is placed so that the paving layer is formed together with the permeable retaining wall block 3. The lateral restraint effect is doubled in (4).

The reinforcing grid 6 may be installed in the entire upper part of the permeable auxiliary layer 2, but may be installed only at the position where the permeable retaining wall block 3 is installed.

As shown in FIG. 5A, the permeable retaining wall block 3 (3a) may be formed of a permeable material so that the permeable retaining wall block 3 itself may be permeable.

In addition, the permeable retaining wall block 3 (3b) shown in FIG. 5B is formed of a permeable hole 31 penetrating the upper and lower surfaces while using the impervious material so that water flows through the permeable hole 31. can do.

As shown in FIGS. 5A and 5B, the permeable wall block 3 may allow the storage hole 32 to penetrate in the longitudinal direction or the transverse direction. Is to allow the rain water and the like to penetrate into the water permeable auxiliary layer (2) while keeping a certain time in the storage hole (32).

In addition, as shown in FIG. 5C, the permeable retaining wall block 3 (3b) is provided with a permeable hole 31 penetrating the upper and lower surfaces thereof, and the third filling material 33 is filled in the permeable hole 31. Can be. The reason why the third filling material 33 is filled is to allow permeability while reinforcing strength, as well as to filter non-point contamination through the third filling material 33.

In addition, as shown in FIG. 5D, the permeable retaining wall block 3 (3d) has a storage hole 32 formed in a groove shape on a lower surface of the permeable retaining wall block 3 (3d) to store the rainwater that is permeated. At 32, the rainwater and the like penetrate the water permeable auxiliary layer 2 while being stored for a predetermined time.

In addition, the permeable retaining wall block 3 (3d) is formed so that the protrusions 34 are formed at the side end is not shown in the drawing, but the fastening groove is formed on the opposite surface of the permeable retaining wall block (3 (3d)) to be connected Make sure the fastening is done.

More preferably, the third filling material 33 is 10 to 30 parts by weight of solidifying agent, 1 to 10 parts by weight of calcium hyposulfite (CaSO2), and 1 to 3 parts by weight of tannin-containing plant extract, based on 100 parts by weight of coal ash. It is reasonable to include.

Since the solidifying agent has a variety of known techniques, description thereof is omitted.

The calcium hyposulfite (Calcium Hyposulfite, CaSO ₂ ) is produced by the reaction of the ethrin guide (acicular crystal) by the reaction with the lactate contained in the lime coal, the early strength is expressed by the early strength is expressed by the production of air Shorten it.

Meanwhile, in the case of heavy metals, the removal of the heavy metals is performed by adsorption. However, when heavy metals are present in the form of an aqueous solution, the adsorption by the coal ashes is not performed properly, and thus sufficient heavy metal removal efficiency cannot be expected.

The third filler 33 is further added to the tannin-containing plant extract for the removal of heavy metals in the form of ions in the aqueous solution. Tannins in tannin-containing plant extracts bind heavy metal ions to fix heavy metals. Tannin-containing plant extracts are extracted from various plants by various known techniques, and their detailed description is omitted.

As such, the third filling material 33 is formed so that non-point pollution such as heavy metals is treated from the incoming rainwater.

The paver layer 4 is formed by the compaction of the second filler having a smaller particle size than the first filler between the permeable retaining wall blocks 3 to provide compactness and impervious to the paver layer 4 itself. To have rigidity.

The second filler may be crushed stone, mixed aggregate, soil cement, circulating aggregate and the like.

As shown in FIG. 4, a structural operation relationship between the paver layer 4 having excellent rigidity and the permeable retaining wall block 3 and the reinforcing grid 6 is secured through such compact compaction.

In general, the supporting action is generated in relation to the floor load [1] such as the floor vehicle load. The horizontally expanding horizontal load [2] is generated for the floor load [1], and the permeable retaining wall block 3 and the reinforcing grid ( 6) the deformation and stress resistance mechanism behaves.

More specifically, the vertical axial compression stress (load) is generated in the pavement layer 4 due to the loading load [1] such as the vehicle load and the retaining wall in the pavement layer 4 due to the loading load [1]. Like the main earth pressure behavior, the horizontal lateral expansion stress (lateral expansion horizontal load [2]) acts on the inner surface of the permeable retaining wall block 3.

Accordingly, in the permeable retaining wall block 3, a horizontal confined load ([3], Confined Pressure) in the opposite direction is generated with respect to the horizontally expanding horizontal load [2]. In addition to this, the support grid 6 is supported by the reinforcing grid 6 so as to generate a lateral frictional resistance load [4] which resists the lateral expansion horizontal load [2]. It will enhance performance. In other words, by this mechanism of action it is to improve the resistance to deformation, deflection, and the like.

In addition, the present invention provides an embodiment for further increasing the resistance to deformation, deflection, and the like as shown in FIG.

As shown in FIG. 6, a plurality of fastening protrusions 62 are inserted into and fastened to the protruding protrusion 61 in the reinforcing grid 6, and the fastening protrusion 62 is formed on the bottom surface of the permeable retaining wall block 3. To accommodate the receiving groove 34 is formed.

That is, in the reinforcing grid 6 installed on the permeable auxiliary layer 2, the fastening protrusions 62 are installed on each protruding protrusion 61 at the position where the permeable retaining wall block 3 is installed, and the permeable retaining wall block The fastening protrusion 62 is accommodated in the receiving groove 34 formed in (3) so that the permeable retaining wall block 3 is directly fastened to the reinforcing grid 6.

In this way, the reinforcing grid 6 and the permeable retaining wall block 3 are integrated so that the above-mentioned horizontal constrained stress [3, Confined Pressure] and transverse frictional resistance load [4] are increased. To further increase the resistance to deformation and deflection.

In addition, the construction of the permeable retaining wall block 3 in the upper part of the reinforcing grid 6 according to the present embodiment is made easier.

The water-permeable packaging layer 5 is placed on the packaging layer 4 and made of compaction to be directly exposed to the outside can be composed of a permeable material itself to allow rain water to penetrate to the bottom. As the permeable packaging layer 5 is installed on the structurally stable packaging layer 4 as mentioned above, the permeable packaging layer 5 is automatically resistant to deformation and sag while having permeability.

In addition, the water permeability to guide the permeable retaining wall block (3) to form a horizontal flow (w2) of the water flowing from the permeable packaging layer (5) between the packaging layer (4) and the permeable packaging layer (5) The support stabilization layer 7 of the material may be placed. In particular, when the permeable packaging layer 5 is made of block packaging, the support stabilization layer 7 is placed so as to prevent lifting of the permeable packaging layer 5 by the flow of water in the horizontal direction.

The support stabilization layer 7 is not limited to its material, such as a non-woven fabric as long as it is a permeable material.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

1: packaging structure of the present invention 2: permeable auxiliary layer
3: permeable retaining wall block 4: paving layer
5: permeable packaging layer 6: reinforcing grid
7: support stable layer

Claims (9)

Permeable permeable auxiliary layer by the compaction of the first filler on the base;
A permeable retaining wall block arranged to form a plurality of spaced portions on the permeable auxiliary layer and allowing water from the upper side to be led to the permeable auxiliary layer on the bottom;
An impermeable paver layer between the permeable retaining wall blocks due to compaction of a second filler having a smaller particle size than the first filler;
A water-permeable packaging layer on the packaging layer;
Lateral restraint-type permeable packaging structure comprising a.
The method of claim 1,
Lateral restraint-type permeable packaging structure, characterized in that the reinforcing grid is formed between the permeable retaining wall block and the permeable auxiliary layer is formed in a grid-like projection.
The method of claim 2,
Side fastening paving structure, characterized in that the plurality of fastening projections are inserted into the protrusions are formed, the receiving groove is formed in the lower surface of the permeable retaining wall block receiving the fastening projections.
The method of claim 1,
The permeable retaining wall block is a side-permeable water-permeable paving structure, characterized in that the material is a permeable material or a permeable hole penetrating the upper and lower surfaces.
The method of claim 4, wherein
Side permeable paving pavement structure, characterized in that the permeable retaining wall block penetrates the storage hole in the transverse direction.
The method of claim 4, wherein
The permeable retaining wall block has a side-blocking permeable packaging structure characterized in that the storage hole is formed in the groove in the transverse direction on the lower surface.
The method of claim 4, wherein
The permeable retaining wall block is characterized in that the permeable hole penetrating the upper, lower surface, characterized in that the side hole-type permeable paving structure, characterized in that the third filler is filled.
The method of claim 4, wherein
Lateral restraint-type permeable packaging structure, characterized in that a plurality of anchors protruding from the lower surface of the permeable retaining wall block.
The method of claim 1,
Axial-type permeable pavement structure, characterized in that a support stabilization layer made of a permeable material for introducing into the permeable retaining wall block to form a horizontal flow of water introduced from the permeable packaging layer between the packaging base layer and the permeable packaging layer. .

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