KR101176040B1 - Porous block - Google Patents

Abstract

PURPOSE: A water permeable block with a water permeable core and a construction method thereof are provided to improve underground water contamination prevention and air purification functions by filling a water permeable core with an environmentally-friendly material. CONSTITUTION: A water permeable block with a water permeable core comprises a water-permeable block surface layer(12), a rainwater storage space layer(14), a water-permeable core insertion part, and a water-permeable core(20). The rainwater storage space layer is formed on the bottom of the water-permeable block surface layer. The water-permeable core insertion part is formed on one corner of the block. The water-permeable core is inserted into the water-permeable core insertion part.

Description

Sustainable drainable permeable block combined with permeable core and construction method

The present invention relates to a sustainable drainage permeable block combined with a permeable core and a construction method thereof, and more particularly, a rainwater storage space layer is formed below the permeable block surface layer, and one edge of the block can be inserted into the permeable core. The present invention relates to a sustainable drainage permeable block having a permeable core insert portion inserted into the permeable core insert portion, and a construction method thereof.

In modern cities, due to the rapid urbanization, the natural drainage area is markedly reduced. Consequently, rainwater causes continuous runoff of surface water, and in densely populated areas, 95% of rainwater has already been converted to surface water, increasing the pressure on the already draining drainage systems.

In addition, due to the effects of abnormal climate such as global warming, the type of precipitation has also changed considerably, and the pattern is also increasing in the form of heavy rainfall and precipitation is concentrated in a certain period of time. Long-term economic and social costs are expected to increase due to shortages.

For this reason, industrialized countries have already developed construction methods to continuously improve the infrastructure of roads, storing rainwater drained into surface water in temporary storage spaces and allowing natural drainage to the ground to reduce drainage loads and consider environmental aspects. It is the state that introduction and practical use. Accordingly, the present invention has been made in view of the development of sustainable eco-friendly permeable structure suitable for the domestic situation in view of such social necessity and domestic reality.

Due to the increased risk of flooding due to the increased incidence of sudden heavy rainfall, developed countries are constantly considering the storage facilities of rainwater and expanding their installations. In Korea, it is time to expand the permeation pavement to increase the ecological area ratio of roads, and to study and apply various construction methods.

However, realistically, the method of permeation that is applied to the existing sidewalk is a method using a porous concrete block. If the continuous post-management is not performed after construction in Korea's urban environment, the permeation efficiency is continuously reduced after 6 months after construction, and thus the surface drainage The problem of returning to the same level as the drainage load occurs.

Therefore, in order to solve these problems, the pitchers are mainly used in Europe and the United States, but the Seoul city has a realistic problem that is difficult to use in the sidewalk due to the gap regulation (2-3㎜) when constructing the sidewalk. There is a separate need for a sustainable permeability structure.

Due to the increased incidence of intensive rainfall, the average annual rainfall in Seoul increased from 1,231.5 mm / year in the 1970s to 1,595.3 mm / year in the 2000s, an increase of 30% over 30 years. In particular, in the late 1990s, the average rainfall increased markedly due to several heavy rainfalls.

In the case of Seoul, the number of rainfall days of 50 mm / day or more, which indicates intensive rainfall, is increasing from 5 days a year in the 1970s to 8 days in the 2000s. In particular, concentrated rainfall is concentrated in June, July and August, and the potential for flood damage during the flood season is rapidly increasing, and there is a need for urgent measures to be in place to counteract the increase in sudden concentration of rainfall. It is becoming.

Before rain, most rainwater penetrated into the ground, but now the surface is paved with an impervious surface, such as asphalt, and in the case of sudden heavy rain that exceeds the storm drainage maintenance level, the stormwater flows to the surface and flows into the lowlands as a result of flood damage. It is causing. In the case of Seoul, the impermeable area ratio of the total area of 605.5㎢ was only 7.8% in 1962, but it increased to 18.6% in 1970 as development began in the late 1960s, and then increased steadily to 37.2% in 1982 and 2005. It reaches 48%.

In the case of Seoul, forests occupy 25.4% of the area, and most of them are located in the suburbs, so the urban area is almost impervious. Impervious soil pavement surveys show that 44.45% of the regions have less than 0–10% pavement rates, corresponding to Grade 1, which are land-use types in green and off-space. In addition, 48.20% of Seoul's total area is impervious soil pavement, and more than 70% is impervious packaging. Therefore, there is a growing need for a separate restoration project that enables pitchers in urbanized areas.

A comprehensive review of the existing research results and existing permeation methods suggests that there are significant problems in current domestic maintenance. If this problem is not solved fundamentally, only the sidewalk block at the surface layer is replaced with a pitcher and used after construction, which causes defects such as irregularity and sinking of the sidewalk block due to the loss of the lower permeable layer. The reduction will cause a loss of functionality. Currently, most permeable pavement packages in Korea have no standard for maintenance and evaluation of functions after construction, and do not have an inspection door to conduct evaluation. In addition, it is difficult to maintain its function continuously except for the early stage of construction since there is no method for restoring the permeability index to the existing level after the permeation index decreases.

Although it is possible to recover to the pitcher index at the beginning of installation through the management using specialized equipment, it is also difficult because large-scale equipment is not available due to the current domestic press conditions. Therefore, in order to make a sustainable permeability structure in Korea, it is considered that it should be changed to a permeable structure layer suitable for domestic conditions, and development of a new structure for future maintenance is essential.

Due to the effects of abnormal climate such as global warming and the continuous development of cities, precipitation patterns change. In other words, the change in precipitation type has the problem of increasing the pressure on the natural drainage system due to the change in the form of precipitation in the short term and the concentration of precipitation for a certain period of time, and the loss of permeability due to the continuous decrease of the index. In addition, there is a problem of a decrease in water permeability and ground subsidence due to excessive drainage during heavy rains. As the permeability falls and the rainwater falls and the natural drainage rate of the ground falls in preparation for the rainfall, there is a problem that water is accumulated on the surface of the sidewalk and thus violates the walking environment. Since it is judged that there is a problem in preventing the above problems by only improving the permeation block, the above problems can be effectively prevented through the improvement of the permeation structure as well as the permeation block. It is also necessary to take countermeasures against nonpoint sources.

The present invention is to improve the above problems by using a pitcher block and a pitcher core has a water purification function, purifying action and air purification function with the improvement of the pitcher's function, the pitcher block and the pitcher block when the pavement core is manufactured separately The purpose of the present invention is to provide a method for constructing a permeable water permeable block packaging that is excellent in preventing groundwater contamination and air purification, by improving the permeability function by coupling between and filling environmentally friendly materials in the permeable core.

In the present invention, the rainwater storage space layer 14 is formed below the permeable block surface layer 12, and the permeable core insert 18 is formed at one corner of the block so that the permeable core 20 can be inserted therein. The present invention relates to a sustainable drainage permeable block in which the permeable core 20 is inserted into the permeable core insert 18.

The present invention has a water purification, purification and air purification function with the improvement of the permeation function by using the permeation block and the permeable core, and separately produced between the permeability block and the permeation block when paving the sidewalk and inside the permeable core By filling the eco-friendly material into the water, the water permeation function is improved, and groundwater pollution prevention and air purification function are excellent.

The present invention is to combine the permeable core between the permeation block and increase the permeation area as the permeation area is increased and effective to improve the effective permeation function and replace the auxiliary base layer of the existing permeable substructure of the base form having excellent temporary storage space By installing blocks, the effect of effective pitching is effective.

1 is a perspective view showing a pitcher block and a pitcher core of the present invention.
Figure 2 is an exploded perspective view showing a permeable block and a permeable core of the present invention.
Figure 3 is a perspective view showing a permeable block of the present invention.
Figure 4 is an exploded perspective view showing a permeable core of the present invention.
5 is a cross-sectional view showing a permeable core of the present invention.
Figure 6 is an exploded cross-sectional view showing a water permeable core of the present invention.
Figure 7 is a plan view showing an upper cap in the pitcher core of the present invention.
Figure 8 is a bottom view showing a lower cap in the pitcher core of the present invention.
Figure 9 is a state diagram showing the shape of the water permeable inside the permeable core of the present invention.
10 is a cross-sectional view showing a drainage package constructed with a permeable block of the present invention.
Figure 11 is a plan view showing the drainage packaging constructed with a permeable block of the present invention.
Figure 12 is a plan view showing a drainage packaging constructed with a permeable block of the present invention.
Figure 13 is a cross-sectional view showing the drainage packaging constructed with a permeable block of the present invention.
14 is a cross-sectional view showing a drainage package constructed with a permeable block of the present invention.
Figure 15 is a perspective view showing a check hole in the water permeable block packaging of the present invention.
Figure 16 is a plan view showing the inspection port in the permeable block drainage packaging of the present invention.
Figure 17 is a perspective view of the base block in the permeable block drainage packaging of the present invention.
18 is a bottom view and a cross-sectional view showing a substrate block of the present invention.
Figure 19 is a bottom view and a sectional view showing a base block of the present invention.
20 is a detailed view showing the composition and composition showing the base block in the drainage pavement constructed with a permeable block of the present invention.
21 is a perspective view showing the compression mechanization equipment used in the construction method of the present invention.
Figure 22 is a photograph showing the forceps equipment used in the construction method of the present invention.

In the present invention, the rainwater storage space layer 14 is formed below the permeable block surface layer 12, and the permeable core insert 18 is formed at one corner of the block so that the permeable core 20 can be inserted therein. The present invention relates to a sustainable drainage water permeable block in which a water permeable core is coupled to the water permeable core insert 18.

In the permeable block of the present invention, the permeable core insert 18 is characterized in that it is any one form selected from hexahedral, cylindrical, cylindrical, spherical and pyramidal form.

In the sustainable drainage permeable block of the present invention, the permeable core 20 includes a core body 22 having a space therein; A core upper cap 24 coupled to an upper portion of the core body 22 and having an upper surface formed in a net shape; And it is coupled to the lower portion of the core body 22, characterized in that consisting of the lower core cap 26, the lower surface is formed in a net form. In the sustainable drainage permeable block of the present invention, the permeable core 20 is selected from a hexahedral shape, a cylindrical shape, a cylindrical shape, a cylindrical shape, a spherical shape and a pyramidal shape so as to be inserted into the permeable core insert portion 18 of the permeable block 10. It is characterized by any one form. In the sustainable drainage permeable block of the present invention, the permeable core 20 is characterized in that any one of the eco-friendly materials selected from ocher balls, clay balls, ceramic balls, and barley stone balls is inserted therein.

The present invention comprises the steps of installing the anti-sediment sheet 110 on the base 100; Installing the base block 120 having an excellent temporary storage space after installing the anti-sedimentation sheet 110; Installing a sand loss prevention sheet 130 on the top of the base block 120; Installing a sand layer 140 after installing the sand loss prevention sheet 130 to smooth the flattening operation; Installing a permeable block 10 on which a permeable core is formed after laying the sand layer 140; Inserting the crushed stone into the lower portion of the permeable core insert 18 formed at the edge of the block formed between the permeable block 10 and the permeable block 10 and striking the crushed stone layer by striking with a dedicated rubber hammer (bar); And installing the permeable core 20 in the permeable core inserting portion 18 of the corner portion formed between the permeable block 10 and the permeable block 10. It is about.

In the present invention, the base block 120 is a mixed block of recycled aggregate including soybean gravel, crushed stone and rubble and clay block crushed stone, and has a porosity of 20 to 30%. In the present invention, the base block 120 is characterized in that a plurality of rainwater storage space grooves 16, 16-1 are formed on the bottom.

1 to 3, the size of the permeable block 10 used in the present invention is generally A = 200 mm, length B = 200 mm and height T = 60 mm and can be produced in various ways according to the specifications of the permeable core In addition, the most commonly used standards of the pitcher core insert 18 formed at the corner of the pitcher block 10 are horizontal A '= 50mm, vertical B' = 50mm and height C '= 60mm, but the size, design and pitch of the block It depends on the coefficient.

12, 17 to 19, the storage base block 120 installed in the present invention is a block that can replace the auxiliary base layer of the existing permeable substructure. The basic specification of the storage substrate block 120 used in the present invention is 500mm in width x 500 in length (1000) mm x height T 120 to 300mm. The storage base block 120 used in the present invention is an environmentally friendly material made by mixing recycled aggregates such as soybean gravel, crushed stone, rubble and clay block crushed stone, and ensuring porosity of 20-30% (average 25%) or more. It is a material that allows effective pitching and temporarily stores rainwater.

In the present invention, the pitcher core may be manufactured in various forms such as a hexahedral box, a cylindrical box, a cylindrical box, a spherical box, and a pyramidal box, and as shown in FIGS. 1 to 3, or a hexahedral box or FIGS. 13 to 15. It is preferable to produce a cylindrical box as shown.

1 to 16, the present invention is a construction method for installing the permeable core 20 in the edge portion of the permeable core insertion portion 18 generated between the permeable block 10 and the permeable block 10. In the present invention as shown in Figure 9, the interior of the pitcher core 20 is an environmentally friendly construction method to fill the eco-friendly materials such as clay ball, ocher ball, ceramic ball, barley stone crushed stone. Clay, loess, ceramics, and elvan have the function of purifying water by themselves, and have the function of purifying air by generating negative ions.

As shown in FIG. 10, the present invention is designed to prevent groundwater contamination and air pollution at the same time, and a construction method of installing a base block 120 having an excellent temporary storage space by substituting an auxiliary base in an existing permeable substructure. to be. Substrate block 120 having an excellent temporary storage space is designed to block and install the existing subbase layer.

The base block 120 used in the present invention is preferably to use the same action as the water purification ecological block, it is a slag material having a low carbon, high strength, high durability and multi-component mixed cement, polyvinyl acetate fiber and It is preferable that such reinforcing fiber new materials, performance enhancing materials such as artificial zeolites, and admixture components such as metakaolin are contained.

18 to 19, the base block 120 having the excellent temporary storage space in the present invention has a plurality of rainwater storage space grooves (16, 16-1) is formed on the bottom, the rainwater storage space grooves (16, 16-1) can be manufactured in various forms. The base block 120 used in the present invention has a plurality of rainwater storage space grooves formed on the bottom thereof to expand the excellent temporary storage space.

The base block 120 used in the present invention is a temporary storage space of blocked rainwater, and stores the rainwater to allow natural drainage to the ground, thereby increasing the permeability during heavy rains and heavy rains and preventing ground subsidence by long-term infiltration of rainwater. It can prevent.

The base block 120 having the excellent temporary storage space in the present invention as shown in Figure 12 is an eco-friendly material that is mixed with eco-friendly materials such as recycled aggregates such as soybean, crushed stone, rubble, and clay block crushed stone, and excellent temporary storage space The base block 120 having the dimensions is based on the width 500mm x length 500mm x height T 120 to 300mm / width 500mm x height 1000mm x height T 120 to 300mm and the porosity is 20% -30% (average 25%) It is designed to be secured. The height is variable depending on the local rainfall intensity.

In the present invention, the base block 120 having the excellent temporary storage space can be installed in the lower portion of the rectangular box or the bottom portion of the block to expand the excellent temporary storage space, inserting a hole in the lower portion of the block It is desirable to increase the temporary storage space by increasing capacity or increasing porosity.

Example 1 Construction of Sustainable Drainable Permeable Block Package

① Install sink prevention sheet on the base plate.

② Install the base block with the excellent temporary storage space after installing the settlement sheet. The base block having excellent temporary storage space is 500 mm wide x 500 (1000) mm wide x 120-300 mm high.

③ Install sand loss prevention sheet on top of base block.

④ Install sand and royal layers 20 to 50mm after installing sand loss prevention sheet to smooth the flattening work.

⑤ Install sand and royal layer (20-50mm) and install permeable block.

⑥ Install the pitcher core at the corner between the pitcher block and the pitcher block.

The method of the present invention is a new permeability packaging method using water permeation block 10 and the permeable core 20 to improve water permeability, water purification and purification, and air purification. The method of the present invention is to produce a pitcher core 20 separately to combine between the pitcher block 10 and the pitcher block 10 at the time of pavement packaging to improve the pitcher function by filling the environmentally friendly material in the pitcher core 20 and In addition, it is excellent in groundwater pollution prevention and air purification. The method of the present invention is effective in improving the permeability and increasing the permeability as the permeable area is increased by coupling the permeable core 20 between the permeable blocks 10. The method of the present invention is to improve the substructure to replace the existing subbase of the substructure of the permeable substructure to provide an effective permeable function by installing a base-type block having excellent temporary storage space.

In the method of the present invention as shown in Fig. 9 is an eco-friendly packaging method using an eco-friendly material by filling using the ocher ball, clay ball, ceramic ball, ganban crushed stone, etc. in the process of the present invention, ocher, clay, ceramic, Elvan has its own function of water purification and water purification, which is effective in preventing groundwater contamination. In addition, the method of the present invention is effective in preventing air pollution because it has a function to purify the pollutants in the air by generating negative ions in the environment-friendly material itself.

In the method of the present invention as shown in Figures 4 to 9, the size of the material entering the inside of the permeable core 20 should be able to maintain 8 ~ 10mm. This is because the hole size of the top of the core and the bottom of the bottom is 5 mm in width and length.

4 to 9 in the method of the present invention, the permeable core 20 is preferably provided with a filter 28 in the form of a non-woven fabric for water purification on the inner bottom.

4 to 9, the overall thickness of the permeable core 20 in the method of the present invention is based on 3 mm. The method of the present invention facilitates the coupling with the upper end by designing the upper portion of the lower portion of the pitcher core 20 in the form of "b", by designing the upper surface of the upper portion of the pitcher core 20 in the form of a grid 25. It is designed to transmit rainwater effectively.

4 to 9, the pitcher core 20 in the construction method of the present invention can provide a comfortable walking environment by limiting the hole size of the mesh 25 to 5mm horizontally and vertically so that heels and high heels do not fall out when walking. It is designed to be. In the method of the present invention, the pitcher core 20 is designed in the form of a net such that the bottom of the bottom of the pitcher core is the same as the top of the upper part, and is designed to effectively transmit water. The method of the present invention is designed to prevent the phenomenon that the upper end is separated by adding a semi-circular projection to the engaging portion to facilitate the coupling of the upper end and the lower end of the pitcher core 20.

The material of the permeable core 20 used in the method of the present invention is a high-cost-strength strength and eco-friendly material by using environmentally friendly polypropylene, and the thickness of the permeable core 20 is 3 to 5 mm to prevent cracking or cracking when walking. The upper and lower surfaces of the pitcher core 20 are manufactured in the form of a net so that the rain can be effectively passed. The interval is limited to 5 to 8 mm so that the heel or high heels do not fall out when walking.

As shown in FIG. 12, the base block 120 having the excellent temporary storage space in the method of the present invention is reduced by 50 mm to 80 mm from the height of the auxiliary base layer of the existing permeable substructure, thereby reducing the construction cost and increasing the permeability. It is possible to prevent ground subsidence due to the loss of the lost and crushed stone layer, and to prevent ground subsidence due to the loss of the sand layer, auxiliary base layer and the separation of other blocks.

In the method of the present invention, the permeable core 20 has an absorption and offset effect of non-point source generated due to initial rainfall, and the method of the present invention maintains an effective permeability through the permeable core 20 and has excellent temporary storage space. Through the storage base block 120 having a temporary storage of rainwater to allow the natural drainage to the ground, it prevents water condensation and water overflow phenomenon on the sidewalk during heavy rains and heavy rains and at the same time maintains a constant permeability It is effective to provide a comfortable walking environment.

The method of the present invention can increase the water permeability of the rainwater by installing the permeable core 20, and is effective in providing a safe and comfortable walking environment with a continuous permeation function during heavy rains or long-term heavy rains. In addition, the method of the present invention is filled with environmentally friendly materials such as ocher ball, clay ball, ceramic ball, ganban stone crushed in the pitcher core 20 has the function of preventing the groundwater contamination by purification and water purification function of the rain, and also loess, Negative ions are generated in clay, ceramics, elvan and others to purify the air to prevent air pollution.

15 to 18, the installation of the permeable block 10 of the present invention should be installed while checking the installation 30 to check the effectiveness and continuous inflow of rainwater to derive improvement measures with verification of a sustainable permeability method. The inspection hole 30 installed in the permeable block 10 of the present invention is provided with a permeable core 20-1 having a cylindrical shape.

The packing of the permeable block 10 of the present invention cleans the inside of the permeable core 20 when the contaminant or foreign matter is filled in the inside of the permeable core 20 as the time passes after the installation is reduced. Then, by replacing and refilling new eco-friendly materials such as ocher balls, clay balls, ceramic balls, and crushed rock stones, the water purification function, water purification function, and groundwater pollution prevention function can be continuously performed. .

In the construction method of the present invention, the block edge portion formed between the permeation block 10 and the permeation block 10 has a pitcher to prevent subsidence because the flow rate of the water may be settled due to the loss of sand because the flow velocity of the water is very fast. It is preferable to put the crushed stone in the lower part of the core so that the bottom is compacted using a separately prepared compacting plate or using a dedicated rubber hammer.

In the construction method of the present invention, the crushed stone layer is crushed by putting a crushed stone in the lower portion of the permeable core insert 18 formed at the edge of the block formed between the permeable block 10 and the permeable block 10 and then using a dedicated rubber hammer (bar). It is preferable to insert the post-permeable core.

When the worker lifts or transports the pitcher block 10 and the pitcher core 20 in the method of the present invention, the clamping equipment as shown in FIG. 22 uses or lifts the crimping equipment 300 as shown in FIG. It is preferable to use it. The permeation block 10 used in the construction method of the present invention has a problem in that it cannot use a crimping machine used in the existing site because the air is not adsorbed and exits. Therefore, the permeable block 10 used in the construction method of the present invention is preferably constructed using a close contact pad 310 made of a strong adsorption pad.

10: pitcher block 20: pitcher core
30: access door
300: compression mechanization equipment 310: contact pad
320: coupling fixture 330: coupling arm

Claims (5)

A rainwater storage space layer is formed below the permeable block surface layer, a permeable core inserting portion is formed at one corner of the block so that the permeable core can be inserted therein, and a permeable core is inserted into the permeable core inserting portion.
The permeable core insert is formed in any one form selected from hexahedral, cylindrical, cylindrical, spherical and pyramid shape,
The permeable core includes a core body having a space formed therein; A core upper cap coupled to an upper portion of the core body and having an upper surface formed in a net shape; And it is coupled to the lower portion of the core body, the lower surface consists of a core lower cap is formed in a net form,
The pitcher core is any one selected from the form of a hexagonal box, a cylindrical box, a cylindrical box, a spherical box and a pyramidal box to be inserted into the pitcher core insertion portion of the pitcher block is combined Sustainable drainable pitcher block. According to claim 1, The permeable core is a sustainable drainage water permeable block combined with a permeable core, characterized in that any one of the eco-friendly material selected from ocher ball, clay ball, ceramic ball, barley crushed stone is inserted therein. Installing a sheet for preventing settlement on the base;
Recycled aggregates including soybeans, crushed stone and rubble and clay block crushed stone are mixed and blocked, and the porosity is 20 ~ 30%, and a plurality of rainwater storage space grooves are formed at the bottom to form a base block having temporary storage space Installing on the top of the sheet for preventing settlement;
Installing a sand loss prevention sheet on the top of the base block;
Laying a sand layer after the sand loss prevention sheet is installed to smooth the flattening operation;
Installing a pitcher block after laying the sand layer;
Inserting the crushed stone into the lower portion of the permeable core insert formed at the edge of the block formed between the permeable block and the permeable block and compacting the crushed stone layer; And
A method for constructing a sustainable drainage permeable block packaging incorporating a permeable core, comprising the step of installing a permeable core at a permeable core insertion portion at an edge portion formed between the permeable block and the permeable block.


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