KR102616235B1 - Sheet-shaped reinforcing member grid having low expansion ratio - Google Patents

Abstract

The present invention provides an adhesive layer (100) formed of asphalt material; It is formed of a low elongation material with an elongation of 1 to 6%, and is formed in a structure in which a plurality of horizontal members 211 and a plurality of vertical members 212 are combined in a grid-like structure, and at the top of the adhesive layer 100 Stacked grid 200; Plate-shaped reinforcement using a low-elongation grid, which is formed of a material containing asphalt and includes a covering layer 300 laminated on the top of the grid 200, and is provided on site in the form of a plate of a predetermined standard. By presenting the member (A), it is possible to prevent reflection cracks in the upper pavement of the expansion joint, prevent plastic deformation of the road pavement, and prevent reflection cracks in the overlay pavement.

Description

Plate-shaped reinforcing member using low elongation grid {SHEET-SHAPED REINFORCING MEMBER GRID HAVING LOW EXPANSION RATIO}

The present invention relates to the construction field, and more specifically to a plate-shaped reinforcing member using a low-elongation grid.

Plastic deformation and damage to road pavements are rapidly increasing due to the rapid increase and enlargement of vehicles, abnormal weather conditions, and climate change.

In order to respond to these environmental changes, efforts are being made to improve the durability of pavements by improving the performance of asphalt pavement materials or by inserting grid reinforcements at the bottom of the pavement layer, but the effectiveness is still there. has not been sufficiently verified.

In particular, to prevent frequent pavement damage due to reflection cracks that occur at the joints of underpasses and covered structures, steel expansion joints and asphalt-based elastic expansion joints have been applied, but elastic asphalt due to water leaks and abnormal weather There have been limitations in solving fundamental problems due to damage to the floor.

The present invention was developed to solve the above problems, and provides a low-elongation grid that prevents reflection cracks in the upper pavement of expansion joints, prevents plastic deformation of road pavements, and prevents reflection cracks in overlay pavements. The purpose is to present the plate-shaped reinforcing member used.

In order to solve the above problem, the present invention includes an adhesive layer 100 formed of asphalt material; It is formed of a low elongation material with an elongation of 1 to 6%, and is formed in a structure in which a plurality of horizontal members 211 and a plurality of vertical members 212 are combined in a grid-like structure, and at the top of the adhesive layer 100 Stacked grid 200; Plate-shaped reinforcement using a low-elongation grid, which is formed of a material containing asphalt and includes a covering layer 300 laminated on the top of the grid 200, and is provided on site in the form of a plate of a predetermined standard. Present absence (A).

The grid 200 is preferably made of glass fiber material.

The grid 200 is preferably made of polyester resin.

The grid 200 includes the steps of passing polyester resin through an extrusion cylinder and extracting it in the form of a flat bar; Forming the extracted bar into the horizontal member 211 and vertical member 212 in the form of a strip through a cooling and stretching process; It is preferably manufactured by a manufacturing method including the step of arranging a plurality of the horizontal members 211 and the vertical members 212 in a grid and combining the intersection points.

The coating layer 300 preferably includes a non-woven fabric layer or a PE coating layer 310.

The grid 200 includes a main body 210 formed by combining the plurality of horizontal members 211 and the plurality of vertical members 212 in a grid-like structure; One end of the plurality of horizontal members 211 extends to the outside of one end of the vertical member 212a of the main body 210, a horizontal member protrusion 221; It is preferable to include a horizontal member non-protruding portion 222 formed by the other end of the plurality of horizontal members 211 being positioned on the other end vertical member 212b of the main body 210.

The main body 210 of the grid 200 is located inside the adhesive layer 100 and the covering layer 300, and the edge of the adhesive layer 100 and the covering layer 300 is located outside the edge of the main body 210, An extra part 240 is formed between the edge of the main body 210 and the edge of the adhesive layer 100 and the covering layer 300, and the horizontal member protruding part 221 and the horizontal member non-protruding part 222 are formed in the extra part. It is preferable to combine the horizontal member protruding portion 221 of the other plate-shaped reinforcing member A1 formed at 240 and installed adjacent to the horizontal member non-protruding portion 222 in an overlapping structure.

The grid 200 includes vertical member protrusions 231, where upper ends of the plurality of vertical members 212 extend to the outside of the upper horizontal member 211a of the main body 210; It is preferable to further include a vertical member non-protruding portion 232 formed by the lower ends of the plurality of vertical members 212 being positioned on the lower horizontal member 211b of the main body 210.

The vertical member protruding portion 231 and the vertical member non-protruding portion 232 are formed in the redundant portion 240, and the vertical member protruding portion 231 of the other plate-shaped reinforcing member A installed adjacently, and the vertical member non-protruding portion 232, are formed in the redundant portion 240. It is desirable to combine the protrusions 232 in an overlapping structure.

The present invention is a method of reinforcing the expansion joint (10) using the plate-shaped reinforcing member (A), and the upper part of the expansion joint (10) formed between the concrete package (11) on one side and the concrete package (12) on the other side. Installing a plurality of the plate-shaped reinforcing members (A) so that the other edge of one plate-shaped reinforcing member (A) installed adjacent to one side overlaps with one edge of the other plate-shaped reinforcing member (A1); A method of reinforcing an expansion joint comprising the step of forming an upper package 13 on the expansion joint 10 is presented.

The present invention is a plastic deformation prevention method using the plate-shaped reinforcing member (A), wherein a plurality of the plate-shaped reinforcing members (A) are installed on the upper part of the base layer (20) or auxiliary base layer at a point where shear stress is expected to be large. , allowing the other edge of the adjacent plate-shaped reinforcing member (A) to overlap with the edge of the other plate-shaped reinforcing member (A1); A method for preventing plastic deformation is presented, which includes forming an upper package 21 on the base layer 20 or the sub-base layer.

The present invention is an overlay paving method using the plate-shaped reinforcing members (A), wherein a plurality of the plate-shaped reinforcing members (A) are installed on the upper part of the concrete package (30) at a point where shear stress is expected to be large, Overlapping the other edge of the adjacent plate-shaped reinforcing member (A) with one edge of the other plate-shaped reinforcing member (A1); We present an overlay paving method comprising: forming an asphalt pavement (31) on top of the concrete pavement (30).

The present invention proposes a plate-shaped reinforcing member using a low-elongation grid that prevents reflection cracks in the upper pavement of expansion joints, prevents plastic deformation of road pavements, and prevents reflection cracks in overlay pavements.

1 and below show an embodiment of the present invention,
Figure 1 is an exploded perspective view of a first embodiment of a plate-shaped reinforcing member.
Figure 2 is an exploded perspective view of a second embodiment of a plate-shaped reinforcing member.
Figure 3 is a photograph of a first embodiment of a grid.
Figure 4 is a photograph of a second embodiment of a plate-shaped reinforcing member.
Figure 5 is a plan view of a second embodiment of the grid.
Figure 6 is a plan view of a third embodiment of a plate-shaped reinforcing member.
Figures 7 and 8 are diagrams showing the use state of the third embodiment of the plate-shaped reinforcing member.
Figure 9 is a state of use of the fourth embodiment of the plate-shaped reinforcing member.
Figures 10 to 12 are process diagrams of a reinforcement method using plate-shaped reinforcement members.

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

As shown in Figure 1 and below, the plate-shaped reinforcing member (A) according to the present invention is basically composed of an adhesive layer 100, a grid 200, and a covering layer 300.

The adhesive layer 100 is formed of asphalt material and has the structure of a self-adhesive asphalt adhesive layer.

The grid 200 is formed of a high-strength, low-elongation material (glass fiber, polyester resin, etc.) with an elongation of 1 to 6%, and has a plurality of horizontal members 211 and a plurality of vertical members 212 in a grid shape. It is formed as a combined structure and is laminated on top of the adhesive layer 100.

The covering layer 300 is formed of a material containing asphalt and is laminated on the top of the grid 200. It may have a configuration in which a non-woven fabric layer or a PE coating layer 310 is laminated on an asphalt adhesive layer 320, and may be impregnated with asphalt. It may also be configured as a self-adhesive nonwoven sheet 330.

This plate-shaped reinforcing member (A) has high strength, but a grid with low elongation is inserted inside, making it difficult to store and transport in a rolled form.

Therefore, unlike conventional reinforcement sheets that are provided to the site in a rolled form, they are provided to the site in the form of plates of a certain standard and are constructed by connecting (overlapping) them.

The grid 200 made of polyester resin is manufactured by the following process.

Polyester resin is passed through an extrusion cylinder and extracted in the form of a flat bar.

The extracted bar is formed into strip-shaped horizontal members 211 and vertical members 212 through a cooling and stretching process.

A plurality of horizontal members 211 and vertical members 212 are arranged in a grid, and the intersection points are joined by laser welding or the like.

Grids manufactured by this manufacturing method are characterized by low elongation (1 to 6%) and high tensile strength (15 to 100 kn/m2).

In order to prevent reflection cracks in the upper pavement of the expansion joint, prevent plastic deformation of the road pavement, and prevent reflection cracks in the overlay pavement, it is advantageous for the grid buried inside the pavement to have a low elongation, and it is advantageous to have a high elongation. When used, the reinforcing effect is small and cracks and steps in the road pavement may occur.

Table 1 shows the tensile strength and tensile elongation (elongation) of four examples of the grid used in the present invention.

Meanwhile, the plate-shaped reinforcing member (A) according to the present invention is provided on site in the form of plates of a predetermined standard and is constructed by connecting (overlapping) them. A grid must also be installed at the joint (overlapping portion) to ensure stable strength. Expression is possible.

For this purpose, the grid 200 includes a main body 210, a horizontal member protrusion 221, a horizontal member non-protruding portion 222, a vertical member protrusion 231, and a vertical member non-protrusion 232. (FIG. 5)

The main body 210 is formed by combining a plurality of horizontal members 211 and a plurality of vertical members 212 in a grid-like structure.

The horizontal member protrusion 221 is formed by extending one end of the plurality of horizontal members 211 to the outside of one vertical member 212a of the main body 210.

The horizontal member non-protruding portion 222 is formed by positioning the other end of the plurality of horizontal members 211 on the other end vertical member 212b of the main body 210. (It is not formed to extend outward.)

The vertical member protrusion 231 is formed by extending the upper ends of the plurality of vertical members 212 to the outside (upper side) of the upper horizontal member 211a of the main body 210.

The vertical member non-protruding portion 232 is formed by positioning the lower ends of the plurality of vertical members 212 on the lower horizontal member 211b of the main body 210. (It is not formed to extend outward.)

In the plate-shaped reinforcing member (A), the main body 210 of the grid 200 is located inside the adhesive layer 100 and the covering layer 300, and the adhesive layer 100 and the covering layer 300 are located on the outside of the edge of the main body 210. The edge of is located, and an extra portion 240 is formed between the edge of the main body 210 and the edges of the adhesive layer 100 and the coating layer 300 (FIG. 6).

Here, the horizontal member protrusion 221 and the horizontal member non-protruding portion 222 are formed in the redundant portion 240, and the horizontal member protrusion 221 of the other plate-type reinforcement member A1 installed adjacently and the horizontal member non-protruding portion ( 222) are combined into an overlapping structure (Figures 7 and 8).

In addition, the vertical member protruding portion 231 and the vertical member non-protruding portion 232 are formed in the redundant portion 240, and the vertical member protruding portion 231 and the vertical member non-protruding portion of the other plate-shaped reinforcing member A installed adjacently. (232) combines in an overlapping structure (Figure 9).

Therefore, when the plate-shaped reinforcing members (A) are constructed by splicing (overlapping) in the field, the redundant portions 240 of the reinforcing members A and A1 on both sides are constructed so as to overlap each other, and the redundant portions 240 are Since the horizontal member protrusion 221 or the vertical member protrusion 231 is located, the overall grid is installed without any gaps, which has the effect of enabling stable development of strength.

Hereinafter, an embodiment of the reinforcement method using the plate-shaped reinforcement member (A) according to the present invention will be described.

Figure 10 relates to a method of reinforcing the expansion joint (10) using a plate-shaped reinforcing member (A) according to the present invention.

A plurality of plate-shaped reinforcement members (A) are installed on the upper part of the expansion joint 10 formed between the concrete package 11 on one side and the concrete package 12 on the other side, and are installed adjacent to each other in the manner described above. Ensure that the other edge of one side of the plate-shaped reinforcing member (A) overlaps with the edge of one side of the other plate-shaped reinforcing member (A1).

The upper package 13 is formed by pouring concrete (or asphalt concrete) on the top of the expansion joint 10.

Figure 11 relates to a method for preventing plastic deformation using a plate-shaped reinforcing member (A) according to the present invention.

A plurality of plate-shaped reinforcing members (A) are installed on the upper part of the base layer (20) or sub-base layer at a point where shear stress is expected to occur, and the other side edge of one plate-shaped reinforcing member (A) installed adjacent to the other plate-shaped reinforcement member is installed. Ensure that one edge of member A1 overlaps.

The upper packaging body 21 is formed by pouring concrete (or asphalt concrete) on the upper part of the base layer 20 or the subbase layer.

Figure 12 relates to an overlay packaging method using a plate-shaped reinforcing member (A) according to the present invention.

A plurality of plate-shaped reinforcing members (A) are installed on the upper part of the concrete package (30) at a point where large shear stress is expected to occur, and the other edge of one plate-shaped reinforcing member (A) and the other plate-shaped reinforcing member installed adjacent to each other are installed. Make sure that one edge of (A1) overlaps.

The asphalt pavement (31) is formed by pouring asphalt concrete on the upper part of the concrete pavement (30).

Since the above is only a description of some of the preferred embodiments that can be implemented by the present invention, as is well known, the scope of the present invention should not be construed as limited to the above embodiments, and the scope of the present invention described above Both the technical idea and the technical idea underlying it will be said to be included in the scope of the present invention.

A: Plate-shaped reinforcing member 10: Expansion joint
11: Concrete package on one side 12: Concrete package on the other side
13: upper package 20: base layer
21: upper package 30: concrete package
31: Asphalt pavement 100: Adhesive layer
200: Grid 210: Body
211: horizontal member 212: vertical member
221: horizontal member protruding part 222: horizontal member non-protruding part
231: Vertical member protruding part 232: Vertical member non-protruding part
240: Extra part 300: Covering layer

Claims (12)

An adhesive layer 100 formed of asphalt material;
It is formed of a low elongation material with an elongation of 1 to 6%, and is formed in a structure in which a plurality of horizontal members 211 and a plurality of vertical members 212 are combined in a grid-like structure, and at the top of the adhesive layer 100 Stacked grid 200;
It includes a covering layer 300 formed of a material containing asphalt and laminated on top of the grid 200,
It is provided to the site in the form of a plate of a certain standard,
The grid 200 is,
A main body 210 formed by combining the plurality of horizontal members 211 and the plurality of vertical members 212 in a grid-like structure;
One end of the plurality of horizontal members 211 extends to the outside of one end of the vertical member 212a of the main body 210, a horizontal member protrusion 221;
It includes a horizontal member non-protruding portion 222 formed by the other end of the plurality of horizontal members 211 being positioned on the other end vertical member 212b of the main body 210,
The main body 210 of the grid 200 is located inside the adhesive layer 100 and the coating layer 300,
The edges of the adhesive layer 100 and the coating layer 300 are located outside the edge of the main body 210,
An extra portion 240 is formed between the edge of the main body 210 and the edges of the adhesive layer 100 and the coating layer 300,
The horizontal member protruding portion 221 and the horizontal member non-protruding portion 222 are formed in the extra portion 240,
A plate-shaped reinforcing member (A) using a low-elongation grid, characterized in that the horizontal member protruding portion 221 of another plate-shaped reinforcing member A1 installed adjacently and the non-protruding portion 222 of the horizontal member are combined in an overlapping structure. According to paragraph 1,
The grid 200 is a plate-shaped reinforcing member (A) using a low-elongation grid, characterized in that it is formed of a glass fiber material. According to paragraph 1,
The grid 200 is a plate-shaped reinforcing member (A) using a low-elongation grid, characterized in that it is formed of a polyester resin material. According to paragraph 3,
The grid 200 is,
Extracting polyester resin into a flat bar shape by passing it through an extrusion cylinder;
Forming the extracted bar into the horizontal member 211 and vertical member 212 in the form of a strip through a cooling and stretching process;
Arranging a plurality of the horizontal members 211 and vertical members 212 in a grid and combining the intersection points;
A plate-shaped reinforcing member (A) using a low-elongation grid, characterized in that it is manufactured by a manufacturing method comprising: According to paragraph 1,
The coating layer 300 is a plate-shaped reinforcing member (A) using a low-elongation grid, characterized in that it includes a non-woven fabric layer or a PE coating layer 310. delete delete According to paragraph 1,
The grid 200 is,
Upper ends of the plurality of vertical members 212 include vertical member protrusions 231 extending outward from the upper horizontal member 211a of the main body 210;
A vertical member non-protruding portion 232 formed by the lower ends of the plurality of vertical members 212 being positioned on the lower horizontal member 211b of the main body 210;
A plate-shaped reinforcing member (A) using a low-elongation grid further comprising: According to clause 8,
The vertical member protruding portion 231 and the vertical member non-protruding portion 232 are formed in the extra portion 240,
A plate-shaped reinforcing member (A) using a low-elongation grid, characterized in that the vertical member protruding portion 231 of another plate-shaped reinforcing member (A) installed adjacently and the non-protruding portion 232 of the vertical member are combined in an overlapping structure. A method of reinforcing the expansion joint (10) using the plate-shaped reinforcing member (A) of any one of claims 1 to 5, 8, and 9,
A plurality of the plate-shaped reinforcing members (A) are installed on the upper part of the expansion joint 10 formed between one side of the concrete package 11 and the other side of the concrete package 12, and one side of the plate-shaped reinforcing member is installed adjacent to the other side. Overlapping the other edge of (A) with one edge of the other plate-shaped reinforcing member (A1);
Forming an upper package 13 on the expansion joint 10;
An expansion joint reinforcement method comprising: A plastic deformation prevention method using the plate-shaped reinforcing member (A) of any one of claims 1 to 5, 8, and 9,
A plurality of the plate-shaped reinforcing members (A) are installed on the upper part of the base layer (20) or the sub-base layer at a point where shear stress is expected to be large, and the other plate-shaped reinforcing member (A) installed adjacent to the other edge and the other plate-shaped reinforcing member (A) are installed adjacent to each other. Overlapping one edge of the reinforcing member (A1);
Forming an upper package 21 on the base layer 20 or the subbase layer;
A plastic deformation prevention method comprising: An overlay packaging method using the plate-shaped reinforcing member (A) of any one of paragraphs 1 to 5, 8, and 9,
A plurality of the plate-shaped reinforcing members (A) are installed on the upper part of the concrete package (30) at a point where shear stress is expected to be large, and the other side edge of one side of the plate-shaped reinforcing member (A) installed adjacent to the other side is reinforced. causing one edge of the member (A1) to overlap;
Forming an asphalt pavement (31) on top of the concrete pavement (30);
An overlay packaging method comprising:

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