KR102534188B1 - System for air gap control of block by selectively incorporating slice piece - Google Patents

Abstract

The present invention includes a top layer unit selectively provided by a predetermined thickness from the top and having an inter-particle porosity selectively controlled; a middle layer unit disposed below the top layer unit; and a base layer unit disposed under the middle layer unit to form an underlying layer.

Description

System for air gap control of block by selectively incorporating slice piece}

The present invention relates to a void control block system, and more particularly, to a void control block through selective incorporation of slice particles, in which an obtuse or acute angle slice is inserted into a void formed through the loading of aggregate so that the porosity is selectively controlled. It is a technical field related to the system.

A sidewalk block is a civil engineering material for paving sidewalks, so-called sidewalks, where pedestrians pass. In Korea, due to urban development and road pavement fashion decades ago, unpaved roads were paved with solid concrete or huge concrete slabs mixed with gravel. passed through the development phase.

Concrete pavement had difficulties in terms of maintenance, such as having to remove the entire concrete during re-construction, so it was converted to sidewalk block construction for sidewalks. It became easy.

In the case of Korea, since it corresponds to an environment with four seasons, in using and manufacturing a sidewalk block, many variables in terms of construction and materials must be considered, and product development or stability must be developed in consideration of the environment suitable for the four seasons.

The area of blocks is expanding day by day. Beyond the traditional boundaries of the past, it is being applied to various fields by grafting cutting-edge science and technology. It is safe to say that the block has already entered not only the residential space but also a part of our lives.

In addition, along with the awareness of eco-friendliness, there are some attempts at developing various technologies for eco-friendly block production, and there are also some prior patent documents.

For example, "method of manufacturing a water-permeable block using waste glass and a water-permeable block manufactured thereby (Registration No. 10-2144650, hereinafter referred to as Patent Document 1)" is such.

In the case of Patent Document 1, a method for manufacturing a water-permeable block using waste glass and a water-permeable block manufactured thereby are disclosed. A method for manufacturing a water permeable block using waste glass includes the steps of a) manufacturing foamed glass beads by recycling waste glass; b) preparing a material mixture by mixing foamed glass beads with an eco-friendly binder and water at a predetermined mixing ratio, and molding the prepared material mixture to produce a water-permeable block; Putting it into a hammer mill and firstly pulverizing to obtain a first pulverized glass; a2) obtaining firstly sorted pulverized glass by sorting the first pulverized glass into a size smaller than a predetermined size a3) obtaining second pulverized glass by secondarily pulverizing the first sorted pulverized glass with a ball mill step; a4) sorting the secondary pulverized glass into a predetermined size to obtain secondary pulverized glass; a5) preparing mixed powder by using second-sorted pulverized glass as a main raw material, mixing the main raw material with an additive such as a foaming agent, and mixing a predetermined amount of water with the prepared mixed powder to prepare a mixed dough; a6) molding the mixed dough into a spherical shape to produce molding beads; a7) It is characterized in that it is configured to include the step of sintering the molding beads at a high temperature of 700 ° C. to 900 ° C. and then cooling them to complete the foamed glass beads.

In addition, "functional concrete sidewalk block using recycled materials (Registration No. 10-1074770, hereinafter referred to as Patent Document 2)" also exists.

In the case of Patent Document 2, it relates to a functional concrete sidewalk block using recycled materials, and white cement, fine aggregate, and crushed stone are formed on the base layer of a sidewalk block formed of a concrete block composition composed of cement, crushed fine aggregate, sand, admixture, and water curing reaction water. At least one photocatalyst powder selected from glass powder, bauxite powder or waste alumina powder, waste sludge photocatalyst, coated waste sludge photocatalyst, anataseite, coated anatase powder, dolomite, sericite, and janghoseok. It relates to a functional concrete sidewalk block using recycled materials that is molded with a mortar obtained by adding hydraulic curing reaction water to the block surface layer composition composed of the above ore powder and admixture.

In addition, there is also "a method for manufacturing colored patterned sidewalk blocks using construction waste aggregate and a colored patterned sidewalk block manufactured by this method (Registration No. 10-0888703, hereinafter referred to as Patent Document 3)".

In the case of Patent Document 3, it relates to a method for manufacturing a color pattern sidewalk block using construction waste aggregate and a color pattern sidewalk block manufactured by this method, in particular, 25 to 30% by weight of Portland cement and calcium sulfoaluminate (CAS) A mortar filling step of filling a mold of a specific type with mortar formed by mixing 4 to 6 wt% of a fluidization reducing agent with respect to 100 of a mixture composed of 3 to 5 wt% and 65 to 72 wt% of construction waste aggregate; A color powder application step of applying color powder to a certain thickness on the upper surface of the filled mortar to express a specific color; A release spraying step of spraying a liquid color release on the upper surface of the color powder; a pattern forming step of forming a pattern of a specific shape by pressing the mortar sprayed with calla release with a press of a pattern forming machine; a curing step of drying the mortar that has undergone the pattern molding step at a temperature of 60 to 80° C. for 30 to 40 minutes; It consists of a coating material application step of applying a penetrating coating material to the upper surface of the cured mortar, which has the effect of preventing environmental pollution and harmonizing with the surrounding environment.

In the case of existing literature, methods and systems for producing eco-friendly sidewalk blocks using incineration ash are disclosed. There are still unresolved issues that need to be addressed.

Registration No. 10-2144650 Registration No. 10-1074770 Registration No. 10-0888703

The air gap control block system through selective incorporation of slice particles according to the present invention has been devised to solve the conventional problems as described above, and presents the following problems to be solved.

First, it is possible to selectively control the porosity of the voids between particles with respect to the upper layer.

Second, by providing frictional force to the aggregate, the position and void of the aggregate can be maintained constant.

Third, it is intended to provide block solidity through selective porosity control.

The problems to be solved in the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

The air gap control block system through selective incorporation of slice particles according to the present invention has the following problem solving means for the above problem to be solved.

The air gap control block system through the selective incorporation of slice particles according to the present invention includes a top layer unit selectively provided by a predetermined thickness from the top and selectively adjusting the porosity between particles; a middle layer unit disposed below the top layer unit; and a base layer unit disposed under the middle layer unit to form an underlying layer.

The top layer unit of the air gap control block system through selective incorporation of slice particles according to the present invention includes a plurality of component parts forming an aggregate of the top layer unit and providing air gaps and uniformity of the top layer unit; and a plurality of holding parts that form a resin slice and are selectively incorporated into the voids of the top layer unit to adjust the porosity of the top layer unit.

In the middle layer unit of the void control block system through selective incorporation of slice particles according to the present invention, the size and density of the aggregate in a predetermined area is selectively supplied to selectively control the density of the predetermined area, A first middle layer portion formed of a first aggregate and disposed thereon; And it may be characterized in that it comprises a second middle layer portion formed of the second aggregate and disposed below.

The top layer unit of the void control block system through selective incorporation of slice particles according to the present invention allows the porosity of the top layer unit to be selectively adjusted through a mixing ratio of the plurality of component parts and the resin slice. can be done with

In the resin slice of the air gap control block system through selective incorporation of slice particles according to the present invention, an acute angle and an obtuse angle with respect to the surface of the resin slice are set according to a preset surface angle, It may be characterized in that it is selectively incorporated between a plurality of component parts.

In the plurality of holding parts of the air gap control block system through selective incorporation of slice particles according to the present invention, the surface formed at an acute angle of the resin slice is incorporated in a space spaced apart from each other of the aggregates of the plurality of component parts, and the aggregate It may be characterized in that the porosity of the top layer unit is adjusted by contacting the surface.

In the plurality of holding parts of the air gap control block system through selective incorporation of slice particles according to the present invention, the surface formed at an obtuse angle of the resin slice contacts the surface of the aggregate and forms frictional force with the plurality of component parts to It may be characterized in that it provides motion resistance of the component part.

The plurality of holding parts of the air gap control block system through selective incorporation of slice particles according to the present invention may be characterized in that they selectively absorb or reflect wavelengths of visible light incident from the upper surface of the top layer unit.

According to the plurality of holding parts of the air gap control block system through selective incorporation of slice particles according to the present invention, the light amount of reflected light relative to incident light incident from the upper surface of the top layer unit is selectively adjusted according to the surface roughness of the resin slice that can be characterized.

In the top layer unit of the void control block system through selective incorporation of slice particles according to the present invention, the resin slice is partially adsorbed or adhered to the surface of the aggregate to selectively bond the plurality of component parts to each other. can

The air gap control block system through the selective incorporation of slice particles according to the present invention configured as described above provides the following effects.

First, a partitioned layer is formed, and the ratio of the aggregate and the gap can be selectively formed for each layer.

Second, the porosity of the upper layer can be selectively adjusted by providing a resin slice that selectively adjusts the voids formed by the aggregate in the layer corresponding to the upper layer.

Third, the control of the wavelength of the visible light on the surface and the control of the amount of light can be selectively controlled through the resin slice.

Fourth, through the porosity control, the durability against the load is improved and the permeability can be adjusted.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below.

1 is a cross-sectional side view showing a laminated structure of a gap control block system through selective incorporation of sliced particles according to an embodiment of the present invention.
FIG. 2 is an enlarged partial enlarged view of portion A of FIG. 1 in the air gap control block system through selective incorporation of slice particles according to an embodiment of the present invention.
3 is a conceptual diagram showing that a resin slice is provided to the top layer unit of the air gap control block system through selective incorporation of slice particles according to an embodiment of the present invention to adjust the porosity.
4 is a cross-sectional side view of a void control block system through selective incorporation of slice particles according to another embodiment of the present invention.
FIG. 5 is an enlarged partial enlarged view of portion B of FIG. 4 in a gap control block system through selective incorporation of slice particles according to an embodiment of the present invention.
6 is a conceptual diagram illustrating that resin slices are incorporated between pores of an aggregate of an air gap control block system through selective incorporation of slice particles according to an embodiment of the present invention.
7 is a first perspective view of a real shot of an air gap control block system through selective incorporation of slice particles according to an embodiment of the present invention.
8 is a real-time second perspective view of a gap control block system through selective incorporation of slice particles according to an embodiment of the present invention.
9 is a real photographed screen showing the surface of the top layer unit of the air gap control block system through selective incorporation of slice particles according to an embodiment of the present invention.
FIG. 10 is a side view illustrating that densities are alternately stacked for each partition area of a middle layer unit of an air gap control block system through selective incorporation of slice particles according to an embodiment of the present invention.
11 shows that the top layer unit and the middle layer unit of the void control block system through the selective incorporation of slice particles according to an embodiment of the present invention are alternately stacked with respect to density and alternately stacked according to the porosity in interconnection with each other. It is a side cross-sectional view shown.

Since the air gap control block system through selective incorporation of slice particles according to the present invention can have various changes and various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, or substitutes included in the technical spirit and scope of the present invention.

1 is a cross-sectional side view showing a laminated structure of a gap control block system through selective incorporation of sliced particles according to an embodiment of the present invention. FIG. 2 is an enlarged partial enlarged view of portion A of FIG. 1 in the air gap control block system through selective incorporation of slice particles according to an embodiment of the present invention. 3 is a conceptual diagram showing that a resin slice is provided to the top layer unit of the air gap control block system through selective incorporation of slice particles according to an embodiment of the present invention to adjust the porosity. 4 is a cross-sectional side view of a void control block system through selective incorporation of slice particles according to another embodiment of the present invention. FIG. 5 is an enlarged partial enlarged view of portion B of FIG. 4 in a gap control block system through selective incorporation of slice particles according to an embodiment of the present invention. 6 is a conceptual diagram illustrating that resin slices are incorporated between pores of an aggregate of an air gap control block system through selective incorporation of slice particles according to an embodiment of the present invention. 7 is a first perspective view of a real shot of an air gap control block system through selective incorporation of slice particles according to an embodiment of the present invention. 8 is a real-time second perspective view of a gap control block system through selective incorporation of slice particles according to an embodiment of the present invention. 9 is a real photographed screen showing the surface of the top layer unit of the air gap control block system through selective incorporation of slice particles according to an embodiment of the present invention. FIG. 10 is a side view illustrating that densities are alternately stacked for each partition area of a middle layer unit of an air gap control block system through selective incorporation of slice particles according to an embodiment of the present invention. 11 shows that the top layer unit and the middle layer unit of the void control block system through the selective incorporation of slice particles according to an embodiment of the present invention are alternately stacked with respect to density and alternately stacked according to the porosity in interconnection with each other. It is a side cross-sectional view shown.

As shown in FIG. 1, the air gap control block system through selective incorporation of slice particles according to the present invention includes a top layer unit (100), a middle layer unit (200), and a base layer unit ( base layer unit, 300).

First, as shown in FIGS. 1 to 3, the top layer unit 100 corresponds to the top layer and is selectively provided by a predetermined thickness.

In addition, the porosity between particles of the top layer unit 100 may be selectively adjusted.

The porosity between particles can be selectively adjusted through the aggregate 1 forming most of the top layer unit 100 and the resin slice 2 provided to the top layer unit 100 .

The type of aggregate 1 and the resin slice 2 forming the block system and control of porosity will be described later through a detailed description of the top layer unit 100 below.

In the case of the middle layer unit 200, it may be disposed below the top layer unit 100.

The middle layer unit 200 may be formed as a single layer as shown in FIG. 1 or may be formed as a multi-layer as shown in FIG. 4 .

As shown in the photos shown in FIGS. 7 to 8 , the single layer or multi-layer of the middle layer unit 200 may correspond to a degree that is difficult to visually check, but as shown in FIG. 5 , the middle layer unit 200 It is preferable to form a layer by the size and density of the aggregate 1 included in each layer.

The base layer unit 300 is disposed below the middle layer unit 200 and forms a base layer.

Base layer unit 300 is preferably to form the base layer unit 300 due to the use of aggregate (1) of a smaller size than the aggregate (1) forming the middle layer unit 200.

In the case of the base layer unit 300, a base layer is formed to support loads applied from the top layer unit 100 and the middle layer unit 200.

In addition, in order to support the load applied from the base of the base layer unit 300, the size of the aggregate 1 may be provided small.

The top layer unit 100 of the air gap control block system through selective incorporation of slice particles according to the present invention may include a plurality of component parts 110 and a plurality of holding parts 120.

In the case of the plurality of component parts 110, the aggregate 1 of the top layer unit 100 may be formed, and the air gap S and uniformity of the top layer unit 100 may be provided.

The component part 110 corresponds to the aggregate 1, and the top layer unit 100 can be formed by providing a plurality of component parts 110 corresponding to the aggregate 1.

In the case of the aggregate 1, it is preferable to be provided to all of the top layer unit 100, the middle layer unit 200, and the base layer unit 300, and in the case of the aggregate 1 of the top layer unit 100, the component It will be referred to as section 110.

The component part 110 is composed of particles having a size that can be seen with the naked eye, can form the main structure and shape of the top layer unit 100, and also provides an air gap (S) of the top layer unit 100 You may.

The plurality of component parts 110 of the top layer unit 100 may be selectively provided in particle size, and within the top layer unit 100, a plurality of component parts 110 are formed in a mutually stacked state. it is desirable

Depending on the size of each of the aggregates 1, a plurality of component parts 110 may form gaps S between them in a state in which the component parts 110 are loaded.

The top layer unit 100 is formed in a state in which a plurality of component parts 110 are loaded, and each of the plurality of component parts 110 may be bonded through a bonding material such as an asphalt binder to maintain its shape. .

The bonding material maintains a constant loading state of the plurality of component parts 110 so that the air gap S of the top layer unit 100 is kept constant.

The bonding material may be used to bond aggregates 1 of not only the top layer unit 100 but also the middle layer unit 200 and the base layer unit 300 .

In the case of the plurality of holding parts 120, the resin slice 2 is formed and selectively incorporated into the voids S of the top layer unit 100 to adjust the porosity of the top layer unit 100.

The holding unit 120 may be selectively incorporated into the gap S formed by mutually stacking the plurality of component units 110 .

In addition, the holding part 120 is to adjust the porosity by filling the gap (S) formed between the plurality of component parts (110).

In the case of the resin slice 2 forming the holding portion 120, it may be formed of synthetic resin or plastic, for example, polyethylene terephthalate (PET or PETE), high density polyethylene (HDP), poly It may correspond to synthetic resins such as polypropylene (PP) and polystyrene (PS).

The resin slice 2 is provided in the form of finely crushed synthetic resin or plastic. In the case of the finely crushed resin slice 2, it can be provided in a variety of shapes, but its size is similar to that of the aggregate 1. It is preferable to provide

In the case of the middle layer unit 200 of the void control block system through selective incorporation of slice particles according to the present invention, the size and density of the aggregate 1 in a predetermined area is selectively supplied, so that the density of a predetermined area is selectively The first middle layer portion 210 formed of the first aggregate 1-1 and disposed on the upper portion, and the second middle layer portion 220 formed of the second aggregate 1-2 and disposed on the lower portion ) may be included.

The first aggregate (1-1) and the second aggregate (1-2) may be selectively selected according to the size and shape of the aggregate (1), for example, as shown in FIG. 5, the upper portion of the aggregate (1) ), so that the size of the lower part may be formed so that the size of the aggregate 1 is small.

In the case of the aggregate 1, for example, materials such as sand or gravel may be used, and in the case of the size of the aggregate 1, it may be formed with a maximum aggregate size of 13 mm, and a small aggregate 1 of 1-2 mm may be used. may be

The first aggregate (1-1) and the second aggregate (1-2) may be set according to their sizes, and may be set according to the type and type of the aggregate (1).

In addition, the first middle layer portion 210 and the second middle layer portion 220, which are classified according to the size of the aggregate 1, may be formed with different densities depending on the aggregate 1 provided.

For example, in the case of the density of the aggregate 1, when the size of the aggregate is small, the density of the aggregate 1 may be high, and when the size of the aggregate 1 is provided in the case of a large size, the density of the aggregate 1 Although it may be lowered, the density of the aggregate 1 may be formed differently depending on the shape and type of the aggregate 1.

When a lot of voids S are formed between the aggregates 1, a difference may occur in the density of the aggregates 1 even if the size of the aggregates is the same.

In addition, for example, in the case of the first middle layer part 210 and the second middle layer part 220, they are formed according to the density of the aggregate 1 and the gap thereof. For example, the first middle layer part 210 is the upper part It is formed in the voids and the density is low, and the second middle layer portion 220 is formed at the bottom to form the voids and the density is high, so that the first middle layer portion 210 is easy to penetrate and permeate moisture or rainwater. may be provided.

The top layer unit 100 of the air gap control block system through selective incorporation of slice particles according to the present invention, through the mixing ratio of the plurality of component parts 110 and the resin slice 2, the porosity of the top layer unit 100 This can be optionally adjusted.

In the case of the mixing ratio, the number ratio of the component part 110 and the resin slice 2 may be set.

The mixing ratio of the plurality of component parts 110 and the resin slice 2 can adjust the porosity of the top layer unit 100. For example, when the ratio of the plurality of component parts 110 increases, the aggregate ( 1) Many voids (S) are formed, and as the ratio of the resin slices (2) increases, the porosity can be reduced through the inclusion of the resin slices (2) between the voids (S).

It is preferable that as the number of component parts 110 increases, more voids S are formed, and as the ratio of the component parts 110 increases, the porosity decreases.

In addition, although there is no fixed ratio or maximum or minimum ratio between the component part 110 and the resin slice 2, in order to reduce the porosity, the ratio of the resin slice 2 is the same as that of the component part 110 Providing it may lead to a problem of stability or solidity, and it is preferable that the user or manufacturer mixes the component part 110 and the resin slice 2 in a ratio corresponding to a ratio that does not have a problem in solidity or stability.

In the resin slice 2 of the air gap control block system through selective incorporation of slice particles according to the present invention, an acute angle and an obtuse angle with respect to the surface of the resin slice 2 are set according to a preset surface angle, and the gap S Depending on the structure and shape, it may be selectively incorporated between the plurality of component parts 110 .

As shown in FIGS. 2 to 3 and 6, in the case of the resin slice 2, an acute angle and an obtuse angle may be set on the surface according to the cut shape, and these cut shapes are formed according to the preset surface angle. it is desirable

In the case of the preset surface angle, the shape of the acute angle and the obtuse angle formed on the surface of the resin slice 2 is predetermined and provided to the top layer unit 100 after being selected.

Depending on the preset surface angle, the angles of the acute and obtuse angles formed on the surface of the resin slice 2 and the degree of the acute and obtuse angles may be preset, and are provided into the voids S according to the preset surface angles to selectively It is preferable to be incorporated between the component parts 110.

In the case of the resin slice 2, for example, the surface of the resin slice 2 formed at an acute angle may be incorporated or incorporated into a narrow gap or void S. In the case of the surface formed at an acute angle of the resin slice 2, , It can be incorporated between the narrow gaps (S).

In the plurality of holding parts 120 of the air gap control block system through the selective incorporation of slice particles according to the present invention, the surface formed at an acute angle of the resin slices 2 is formed between the aggregates 1 of the plurality of component parts 110. It is incorporated in the spaced apart space and can adjust the porosity of the top layer unit 100 by contacting the surface of the aggregate 1.

As described above, a portion of the resin slice 2 whose surface is formed at an acute angle is incorporated into the voids S formed by the plurality of component parts 110 to adjust the porosity formed in the top layer unit 100.

As shown in FIG. 6, the surface of the incorporated resin slice 2 contacts the surface of the component part 110 and fills the voids S formed through the plurality of component parts 110 to adjust the porosity. is to do

In addition, the resin slice 2 embedded in the void S is trapped between the plurality of component parts 110, as shown in FIGS. 2 and 3, and the resin slice 2 embedded in this way is In addition to adjusting the porosity of the top layer unit 100, the load applied from the top is also distributed along with the plurality of component parts 110.

In the case of a load, it is applied from the top of the top layer unit 100, and problems such as upper cracking and sinking of the top layer unit 100 can be prevented by distributing the load applied from the top downward.

The resin slice 2 can solve problems caused by the load applied from the top layer unit 100 being applied to the voids S through adjusting the porosity of the voids S between the component parts 110.

In the plurality of holding parts 120 of the air gap control block system through selective incorporation of slice particles according to the present invention, the surface formed at an obtuse angle of the resin slice 2 contacts the surface of the aggregate 1, and the plurality of component parts It is possible to provide motion resistance of the plurality of component parts 110 by forming frictional force with 110 .

The surface formed at an obtuse angle of the resin slice 2 may contact surfaces of the plurality of component parts 110, and the surface formed at an obtuse angle contacts the surfaces of the plurality of component parts 110 to A frictional force can be formed between them.

The motion resisting force is to hinder the movement of the plurality of component parts 110 and to form a friction force between the component part 110 and the contact surface of the resin slice 2 so that the motion resisting force is formed.

Depending on how much the obtuse angle formed on the surface of the resin slice 2 contacts the surface of the component part 110, the resin slice 2 can form the resistance to motion of the plurality of component parts 110, and the resistance to motion is frictional force It is preferable to form through.

For example, in the case of a plurality of component parts 110, each of the component parts 110 maintains the loaded position and forms a gap (S) through mutual loading, but each component part 110 can form a fine movement in the loaded position. , the resin slice 2 forms a frictional force on the surface of the component part 110 so that no minute movement is formed.

The resin slice 2 provides frictional force across the plurality of component parts 110 to form motion resistance between the plurality of component parts 110, and to keep the plurality of component parts 110 in a constant position and position is to do

The plurality of holding parts 120 of the air gap control block system through the selective incorporation of slice particles according to the present invention can selectively absorb or reflect wavelengths of visible light incident from the upper surface of the top layer unit 100.

In the case of the holding unit 120, a predetermined color can be displayed by selectively absorbing or reflecting wavelengths of visible light incident from the upper surface, and the predetermined color can be confirmed with the naked eye.

Each of the plurality of holding parts 120 may exhibit light, dark, and color by selectively absorbing or reflecting wavelengths of visible light, and the wavelengths of visible light that are selectively absorbed or reflected may selectively appear differently.

As shown in FIG. 9 , the holding part 120 allows a predetermined color to appear between the surface of the top layer unit 100 and the component part 110 .

For example, the holding part 120 selectively absorbs or reflects visible light wavelengths by including a material that absorbs or reflects some visible light wavelengths before being provided to the top layer unit 100. Some of the wavelengths can be absorbed or reflected.

According to the surface roughness of the resin slice 2, the plurality of holding parts 120 of the air gap control block system through the selective incorporation of slice particles according to the present invention compares the incident light incident from the upper surface of the top layer unit 100 with the reflected light The amount of light can be selectively adjusted.

Each of the plurality of holding parts 120, the resin slices 2, may be provided with different surface roughness, and the resin slices 2 may be capable of adjusting the amount of incident light and reflected light incident to the upper surface according to the surface roughness of the resin slice 2. .

Adjusting the incident light and the reflected light according to the surface roughness can adjust the transparency or opacity of the resin slice 2. For example, the incident light hits the surface of the resin slice 2, partially reflects it, and partially reflects it. ) is refracted into the interior so that the transparency can be adjusted.

For example, the roughness of the surface of the resin slice 2 may not be confirmed with the naked eye, but fine irregularities, etc. are formed to adjust the amount of light, and opacity can be adjusted through diffuse reflection through the irregularities.

In addition, the incident light and the reflected light may be adjusted not only according to the roughness of the surface of the resin slice 2, but also according to the voids S and the density of the particles constituting the resin slice 2.

The voids S and densities of the particles of the resin slice 2 are formed before being provided to the top layer unit 100, and may have preset densities and voids S of the particles.

In the top layer unit 100 of the void control block system through selective incorporation of slice particles according to the present invention, the resin slices 2 are partially adsorbed or adhered to the surface of the aggregate 1 to form a plurality of component parts 110 Optionally, they can be mutually bonded.

In the case of the resin slice 2, it may be partially adsorbed or adhered to the surface of the aggregate 1. For example, when the top layer unit 100 is heated above the melting temperature of the resin slice 2, the resin slice ( A part of 2) may be adsorbed to the surface of the aggregate 1 due to melting.

In the case of the resin slice 2, since it is a synthetic resin, the melting temperature may be lower than that of the aggregate 1. When this melting temperature is reached, the surface of the resin slice 2 is partially melted to form a plurality of components The part 110 is to be adhered or adsorbed.

Melting of the resin slice 2 is formed by applying artificial heat or pressure, and when the artificial heat or pressure is removed, the resin slice 2 solidifies and maintains a state in which the plurality of component parts 110 are adsorbed or adhered. will do

Selective mutual bonding is formed between the plurality of component parts 110 through the adsorption or maintenance of the adhered state of the resin slice 2 , and mutual bonding is preferably performed through the resin slice 2 .

The density of the aggregate 1 of the middle layer unit 200 of the air gap control block system through the selective incorporation of slice particles according to the present invention is selectively varied from top to bottom so that it is gradually distributed with respect to the load applied from the outside. can

In addition, it is possible to adjust the porosity for each partition area of the middle layer unit 200 by adjusting the density of the aggregate 1 .

For example, as shown in FIG. 10, the aggregate 1 constituting the middle layer unit 200 is selectively provided with the density of the particles, and is formed into a dense region and a low density region for each divided region. It can be.

As shown in Fig. 10, the high-density and low-density regions of the aggregate 1 may be alternately tiled.

When the dense area and the small area are alternately arranged in a checkerboard pattern in the middle layer unit 200, the load applied from the top is gradually distributed to the bottom, and the load can be effectively distributed downward through a cushion role. will be.

It is desirable to reduce the load concentrated on a part through the downward dispersion of the load, and to exhibit strong strength even under repeated load.

The top layer unit 100 of the air gap control block system through the selective incorporation of slice particles according to the present invention is selectively divided into predetermined partition areas, and the ratio of the aggregate 1 and the resin slice 2 is selectively adjusted to , the load applied from the top can be distributed.

The voids S are selectively adjusted by selectively adjusting the ratio of the aggregate 1 and the resin slice 2 of the top layer unit 100, and the porosity is selectively adjusted according to the selectively adjusted voids. can

The top layer unit 100 may be provided so that a low porosity part (lower) and a high porosity part (top) are repeated according to the porosity, and the repeatedly provided low part and high porosity part are alternately provided. can

Like the middle layer unit 200, the top layer unit 100 may also be tiled according to the porosity, and the density of the middle layer unit 200 depends on the high or low porosity disposed in the top layer unit 100. A portion with a high density and a portion with a low density may be sequentially formed.

As shown in FIG. 11, the top layer unit 100 and the middle layer unit 200 are alternately formed and arranged in a checkered pattern with the density of the aggregate 1 and the voids S across the top layer unit 100 and the middle layer unit 200. It can serve to absorb the shock caused by the external force applied from the top of (100), and can disperse the external force applied from the top downward.

The density of the aggregate 1 of the middle layer unit 200 and the porosity of the top layer unit 100 are provided in conjunction with each other, and the mill, small part and top layer unit 100 for the density of the middle layer unit 200 ), the upper and lower parts of the porosity are connected and can be arranged alternately.

The scope of the rights of the present invention is determined by the matters described in the claims, and parentheses used in the claims are not written for selective limitation, but are used for clear components, and descriptions in parentheses are also interpreted as essential components. It should be.

1: aggregate
2: resin slice
S: air gap
100: top layer unit
110: component part
120: holding unit
200: middle layer unit
210: 1 ^st middle layer unit
220: ^2nd middle layer unit
300: base layer unit

Claims (10)

A top layer unit selectively provided from the top by a predetermined thickness and having a porosity between particles selectively controlled;
a middle layer unit disposed below the top layer unit; and
A base layer unit disposed under the middle layer unit to form a base layer,
The top layer unit,
a plurality of component parts forming an aggregate of the top layer unit and providing air gaps and uniformity of the top layer unit; and
A plurality of holding parts that form a resin slice and are selectively incorporated into the voids of the top layer unit to adjust the porosity of the top layer unit;
The resin slice,
An acute angle and an obtuse angle with respect to the surface of the resin slice are selectively formed according to a preset surface angle, and are selectively incorporated between the plurality of component parts according to the structure and shape of the void,
The plurality of holding parts,
A surface formed at an acute angle of the resin slice is incorporated in a space spaced apart from each other of the aggregates of the plurality of component parts, and is in contact with the surface of the aggregate to adjust the porosity of the top layer unit. Selective of slice particles, characterized in that Air gap control block system through incorporation.
A top layer unit selectively provided from the top by a predetermined thickness and having a porosity between particles selectively controlled;
a middle layer unit disposed below the top layer unit; and
A base layer unit disposed under the middle layer unit to form a base layer,
The top layer unit,
a plurality of component parts forming an aggregate of the top layer unit and providing air gaps and uniformity of the top layer unit; and
A plurality of holding parts that form a resin slice and are selectively incorporated into the voids of the top layer unit to adjust the porosity of the top layer unit;
The plurality of holding parts,
Selectively absorbs or reflects wavelengths of visible light incident from the upper surface of the top layer unit,
The plurality of holding parts,
According to the surface roughness of the resin slice, the amount of reflected light relative to the incident light incident from the upper surface of the top layer unit is selectively adjusted.
The method of claim 1, wherein the middle layer unit,
The size and density of the aggregate in a predetermined area is selectively supplied to selectively control the density of the predetermined area,
A first middle layer portion formed of a first aggregate and disposed thereon; and
A void control block system through selective incorporation of slice particles, characterized in that it comprises a second middle layer portion formed of a second aggregate and disposed below.
The method of claim 1, wherein the top layer unit,
Characterized in that the porosity of the top layer unit is selectively controlled through the mixing ratio of the plurality of component parts and the resin slice, the air gap control block system through selective incorporation of slice particles.
delete delete The method of claim 1, wherein the plurality of holding parts,
Characterized in that the surface formed at an obtuse angle of the resin slice contacts the surface of the aggregate and forms frictional force with the plurality of component parts to provide motion resistance to the plurality of component parts. Void through selective incorporation of slice particles adjustable block system.
delete delete The method of claim 2, wherein the top layer unit,
The void control block system through selective incorporation of slice particles, characterized in that the resin slice is partially adsorbed or adhered to the surface of the aggregate to selectively bond the plurality of component parts to each other.

Images