KR200389495Y1 - The constructed structure of concrete erosion prevention plate - Google Patents

Abstract

The present invention relates to a concrete anticorrosive plate installation structure and method, the structural concrete having a chipping surface chipping (aging) damage; A binding member installed in a net shape on the chipping surface of the structure concrete; A coupling member for fixing a portion of the binding member to the structure concrete to couple the binding member to the structure concrete; Coated concrete placed on a chipping surface of the structural concrete in which the binding member is installed; And a plurality of protrusions protruding at a predetermined interval, the anti-corrosive plate having the protrusions buried in the coated concrete and having one surface having the protrusions pressed onto the coated concrete. By this configuration, the present invention not only provides the function of protecting structure concrete from moisture or harmful gas in the air, but also the joint surface between structure concrete and coated concrete or coated concrete and coated concrete according to vibration or temperature change. It provides the effect of fundamentally solving the problem of separation or dropping. In addition, the anticorrosive plate formed with the protrusion of the present invention can provide a waterproofing and anti-corrosion effect permanently in one construction, thereby providing an effect of saving social resources.

Description

Constructed structure of concrete erosion prevention plate

The present invention relates to a concrete anticorrosive plate installation structure, and in detail, the coating concrete is cast through the binding member on the chipping surface of the aged structural concrete, and the protrusion of the anticorrosive plate is embedded in the coated concrete, thereby compressing the anticorrosive plate structurally. An integrated concrete anticorrosive plate installation structure.

Concrete has a chemically strong alkalinity (pH = 12.5). Concrete surfaces exposed to air or in closed spaces are chemically alkaline due to chemical reactions with various harmful gases (eg carbon dioxide, acid or chlorine ions). Neutralization, which leads to loss of energy, proceeds, which is called aging of concrete. As the concrete ages, the strength of the concrete decreases and the steel corrosion rapidly progresses. In addition, concrete structures are made by mixing cement and sand gravel with water. As the concrete hardens, the mixed water is evaporated into the atmosphere and the portion occupied by water remains as space, and concrete forms a porous structure. The waterproof effect can not be expected.

As a conventional technology, corrosion prevention or waterproofing to prevent aging of concrete can be classified into new concrete structures and concrete structures that have been aged, and new concrete structures are generally coated on concrete surfaces, and a long time after construction Therefore, the concrete that has undergone considerable aging has been delayed by removing the aged concrete surface and applying new coated concrete, or by coating the newly coated concrete surface to block the contact between moisture and harmful gas and concrete in the air.

However, when the aging concrete is removed and new coated concrete is applied in this prior art, the bonding of the existing concrete and the newly coated concrete is maintained by the adhesive strength of the adhesive or the adhesive strength of the cement. The cotton will fall off or separate after a long period of time.

This phenomenon occurs because the joint surface is dropped due to the vibration continuously applied to the concrete structure, or the difference in expansion and expansion due to the temperature change occurs because the expansion coefficient between the existing concrete and the coated concrete is different. Will be. That is, when the expansion and contraction is repeatedly generated at different rates according to the temperature change, frictional force is generated at the joint surface, which causes the adhesive surface to be separated.

Even when the coated concrete surface is coated in order to block the contact of harmful gas, the above problems occur in the adhesive portion between the concrete surface and the painted surface.

In order to solve the above problems, the present invention, in repairing and reinforcing aging concrete, can prevent the separation of the adhesive surface by expansion and contraction due to vibration or temperature change as well as blocking moisture and harmful gases in the atmosphere. The purpose of the present invention is to provide a concrete anticorrosive plate installation structure to be installed so as to structurally integrate the coated concrete and the anticorrosive plate on the existing structure concrete.

In order to achieve the above object, the concrete anticorrosive plate installation structure of the present invention is a structure concrete having a chipping surface chipping (aging) damaged portion; A binding member installed in a net shape on the chipping surface of the structure concrete; A coupling member for fixing a portion of the binding member to the structure concrete to couple the binding member to the structure concrete; Coated concrete placed on a chipping surface of the structural concrete in which the binding member is installed; And an anticorrosive plate having a plurality of protrusions formed at predetermined intervals on one surface, wherein the protrusions are buried in the coated concrete, and one surface having the protrusions is pressed onto the coated concrete.

In this case, the protrusion of the anticorrosive plate has a stud shape, the end of which forms a head, the cross-sectional area of the head is larger than the cross-sectional area of the pillar portion, the cross-sectional area changes sharply at the boundary between the head portion and the pillar portion It is done.

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

1 is a schematic view showing a concrete anticorrosive plate installation structure of the present invention, Figure 2 is a cross-sectional view of the concrete anticorrosive plate installation structure of the present invention.

As shown in Figure 1 and 2, the concrete anticorrosive plate installation structure of the present invention is the binding member 20 is installed on the structure concrete (10) having a chipping surface chipping aging damage portion (chipping) The coupling members 50 and 51 are installed to fix a part of the binding member 20 to the structural concrete 10 so as to couple the binding member 20 to the structural concrete 10. In addition, the coated concrete 30 is cast on the structural concrete 10 on which the binding member 20 is installed, and the anticorrosive plate 40 having a plurality of protrusions 41 formed on one surface with a predetermined interval is formed. The protrusion 41 is buried in the coated concrete 30 so that one surface having the protrusion 41 is pressed against the coated concrete 30.

At this time, the protrusion part 41 of the anticorrosive plate 40 has a stud shape that forms an end of the head, and thus the anticorrosive plate 40 has a structure in which the anticorrosive plate 40 is hardly separated or detached from the coated concrete 30.

The present invention is to solve the problem that the existing structure concrete 10 and the coated concrete 30 is separated or dropped, the binding force between the structure concrete 10 and the coated concrete 30 on the chipping surface of the existing structure concrete 10 By installing the binding member 20 for strengthening the binding to the coupling member (50, 51) and placing the coated concrete 30 thereon, the structural concrete 10 and the coated concrete 30 is structurally integrated It is configured to prevent the separation or dropping phenomenon occurring between the structural concrete 10 and the coated concrete 30.

In addition, the bonding of the coated concrete 30 and the anticorrosive plate 40 is that the projections of the anticorrosive plate 40 are buried in the coated concrete 30 before the coated concrete 3 is completely solidified after pouring the coated concrete 30. As the anticorrosive plate 40 is compressed, the anticorrosive plate 40 blocks moisture or harmful gases in the air, thereby preventing aging of the structural concrete, as well as the coated concrete 30 and the anticorrosive plate. (4) is structured so as to be united structurally so that no dropping or separation occurs.

In particular, the protrusion 41 of the anticorrosive plate 40 has a stud shape where the end forms a head, the cross-sectional area of the head is larger than the cross-sectional area of the pillar, and the change of the cross-sectional area at the boundary between the head and the pillar. Has a structure that occurs rapidly. As a result, the solidified stress is concentrated between the head part and the pillar part of the protrusion part 41 through the process of solidifying the coated concrete 30, thereby increasing the bonding force between the anticorrosive plate 40 and the coated concrete 30.

Hereinafter, a concrete anticorrosive plate installation method for installing the characteristic structure of the present invention described above will be described.

First, the aged damaged portion of the structural concrete 10 is chipped to remove it. (Chipping Process) At this time, it is preferable to chip a part including the aged damaged part to the part which has not yet been aging, and the surface cleaning process of arranging the bent portion of the chipping surface after chipping may be performed.

After the chipping process, a mesh-shaped binding member 20 is installed on the chipping surface of the structural concrete. (Binding member installation process) As a binding member, steel is mainly used, and other strengths are guaranteed. And a material having a surface material having a high bonding strength with the structural concrete and the coated concrete may be used. The binding member 20 is preferably arranged to form a net shape by installing in an orthogonal manner to maintain a predetermined interval.

After the binding member installation process, a portion of the binding member 20 is fixed to the structure concrete 10 by the coupling members 50 and 51 to couple the binding member 20 to the structure concrete 10. Binding member bonding process)

Figure 3 is a perspective view showing a temporary example of fixing the binding member to the concrete using the coupling member. As shown in FIG. 3, the binding member 20 is temporarily installed on the chipping surface of the structure concrete 10 and drilled a hole with a drill to bond the coupling bolt to the binding member using the fixing member ( Secure part of 20) to the coupling bolt. Coupling members (50, 51) is preferably installed to maintain a certain interval so that the entire binding member 20 can be completely fixed to the structural concrete (10). Through this coupling member, the binding member is fixed to the structure concrete and integrated.

After the binding member joining process, the coated concrete 30 is poured on the chipping surface of the structural concrete 20 on which the binding member 20 is installed. (Coated concrete placing process)

The projection 41 of the anticorrosive plate 40 before the covering concrete 30 is completely hardened to the anticorrosive plate 40 having a plurality of protrusions 41 protruding from one surface at a predetermined interval after the coating concrete pouring process. Is pressed onto the coated concrete 30 so as to be completely buried in the coated concrete 30. (Anti-corrosion plate crimping process) The anticorrosive plate is generally composed of reinforcing fibers and resin such as glass fiber, carbon fiber or aramid fiber, and It is made of a material that can not penetrate harmful gases and moisture. As a result, the anticorrosive plate is waterproof and protects the structural concrete from harmful gases in the atmosphere.

Figure 4 is a perspective view showing a temporary example of the anticorrosive plate formed with a projection on one surface.

As shown in FIG. 4, a plurality of protrusions 41 are formed on one surface of the anticorrosive plate 40 at regular intervals, and the protrusions 41 have a stud shape in which the ends form heads. It is as if a plurality of nails are embedded in the anticorrosive board. That is, the protrusion part 41 has a structure in which the cross-sectional area of the head is approximately two times larger than the cross-sectional area of the pillar part at the bottom of the head part, and the shape of the protrusion part may be variously modified within a range that maintains the difference in the cross-sectional area. In addition, in order that the solidification stress of the coated concrete described below is concentrated between the head and the pillar of the protrusion, a structure in which the cross-sectional area is rapidly changed at the boundary between the pillar and the head is preferable.

Due to the structure of the protrusion part 41, the solidified stress is concentrated between the head and the pillar part of the protrusion part 41 through the process of hardening the coated concrete during the anticorrosive plate pressing process, so that the anticorrosive plate 40 has a stronger bonding force. The coated concrete 30 may be compressed to be integrated with each other.

The above-described anticorrosive plate of the present invention may be constructed by attaching to a structural concrete mold in the construction of a new structural concrete, in which case the anticorrosive plate may be directly compressed onto the structural concrete to provide permanent waterproofing and corrosion protection of the structural concrete. .

As described above, the concrete anticorrosive plate installation structure of the present invention has a mechanical structure in which the structural concrete, the coated concrete, and the anticorrosive plate are structurally integrated to prevent the separation of the adhesive surface from expansion and contraction caused by vibration or temperature change. .

As described above, the present invention has been described with reference to the above embodiments, but is not necessarily limited thereto, and various modifications may be made without departing from the scope and spirit of the present invention.

As described above, the concrete anticorrosive plate installation structure and method of the present invention is installed so that the structural concrete, the coated concrete and the anticorrosive plate is structurally integrated, thereby providing a function of protecting the structural concrete from moisture or harmful gases in the air. And, it provides the effect of fundamentally solving the problem of separation or separation between the structural concrete and the coated concrete or the coated concrete or the coated coating according to the vibration or temperature change. In addition, the anticorrosive plate formed with the protrusion of the present invention can provide a waterproofing and anti-corrosion effect permanently in one construction, thereby providing an effect of saving social resources.

In addition, by installing the anticorrosive plate of the present invention projected to the construction of the new structure concrete attached to the concrete structure frame provides a permanent corrosion protection and waterproof effect of the concrete structure.

1 is a schematic view showing a concrete anticorrosive plate installation structure of the present invention.

2 is a cross-sectional view of the concrete anticorrosive plate installation structure of the present invention.

Figure 3 is a perspective view showing a structure for fixing the binding member to the structural concrete using the coupling member.

4 is a perspective view of the anticorrosive plate having protrusions formed on one surface of the present invention.

* Description of the symbols for the main parts of the drawings *

10: structural concrete 20: binding member

30: coated concrete 40: anticorrosive plate

41: projection 50, 51: coupling member

Claims (2)

Structure concrete having a chipping surface where the aging damage chipped; A binding member installed in a net shape on the chipping surface of the structure concrete; A coupling member for fixing a portion of the binding member to the structure concrete to couple the binding member to the structure concrete; Coated concrete placed on a chipping surface of the structural concrete in which the binding member is installed; And A concrete anticorrosive plate mounting structure comprising a plurality of protrusions protruding at a predetermined interval, the anticorrosive plate is formed in which the protrusion is buried in the coated concrete and one surface having the protrusion is pressed on the coated concrete . The method of claim 1, The protrusion of the anticorrosive plate has a stud shape in which an end forms a head, a cross-sectional area of the head is larger than a cross-sectional area of the pillar, and a change in cross-sectional area occurs rapidly at the boundary between the head and the pillar. Concrete anticorrosive plate installation structure.