KR200347090Y1 - The structure management permeation water bridge - Google Patents

Abstract

The present invention is directed to a drainage structure of bridge top infiltration water for completely draining water that accumulates between the slab and upper asphalt concrete layers of the bridge.

In particular, the penetration guide groove portion is formed to extend to one side of the drain pipe so that the infiltration water flows into the drain pipe installed in the lowest portion of the upper surface of both sides of the concrete slab, and the cross section is bent in a U-shape to the penetration water guide groove portion The stainless steel panel is tightly fixed to the square groove, and the metal mesh net is fixed to the upper portion of the stainless steel panel through the mesh fixing member, and the stainless steel perforated pipe is installed between the penetrating water guide groove and the metal net mesh to drain the deceased Is done.

Accordingly, by quickly discharging the decayed water between the asphalt concrete pavement and the concrete slab to the outside, the durability of the bridge can be increased by preventing white phenomena, stalagmite, concrete oxidation, etc. caused by stagnation.

Description

The structure management permeation water bridge

The present invention relates to the drainage structure of the top surface of the bridge to completely drain the water accumulated between the upper slab of the bridge and the ascon layer of the upper part, and more specifically, to the drain pipe installed at the lowest part on both sides of the upper part of the concrete slab. A stainless steel panel which is formed to be bent into a U-shaped cross section corresponding to the square groove of the penetrating water guide groove and the penetrating water guide groove of the upper one side, and is fixed in close contact with the square groove, and is formed to extend along the square groove; It has an area that covers at least the upper portion of the stainless steel panel, and consists of a metal net that is fixed to the concrete slab by a mesh fixing member, so that a buildup between the slab and the asphalt concrete layer on the upper layer prevents oxidation of the concrete caused by water and bridges. Infiltration of the upper surface of the bridge to improve the durability It can relate to the structure.

As shown in Figure 1, the general structure of the conventional bridge 100 is a structure of a concrete slab 200 is mounted on the bridge and ascon on top of the structure consisting of a paving structure of the bridge slab is connected to both end slab and slab Since the expansion joint is formed with a jaw about 5 to 8 cm higher than the upper surface of the bridge, water pooling occurs between the slab 200 and the packaged ascon layer 600, and the water is stagnated without draining, causing repeated freezing and melting. As the upper surface of the concrete bridge and the structure are oxidized, it is impossible to have any effect on the load strength, and the oxidization of the concrete causes the white phenomena and surface cracks due to the leakage of the slab bottom plate, resulting in the durability degradation due to the strength of the material. There was a problem that the life of the bridge 100 is shortened as well as the main cause of the bridge slab 200 damage.

In other words, unlike bridges, bridges are absolutely required for durability, and such durability depends on the type of slab, waterproof layer, materials, and construction technology, but above all depends on the treatment of water that accumulates in the upper surface of the bridge. will be.

Therefore, ascon constituting the upper pavement of the bridge is permeable, so water will penetrate into the upper pavement of the bridge, so even if a separate waterproofing layer is installed, the water will accumulate on the waterproofing layer. have.

The purpose of the present invention to improve this, by installing a drain pipe on the slab of the bridge to prevent the white phenomena, stalagmite, concrete oxidation, etc. caused by stagnation of water between the asphalt concrete pavement and concrete slab to increase the durability of the bridge At the same time, to provide a drainage structure of the upper surface of the bridge to prevent large accidents caused by bridge damage.

1 is a cross-sectional view of a conventional bridge.

Figure 2 is a plan view of the present invention is installed.

Figure 3 is an enlarged configuration of an enlarged portion A of Figure 2 of the present invention.

Figure 4 is a perspective view of the present invention is installed on the slab of the bridge.

5 is a plan view of the stainless steel perforated tube is installed on the slab of the bridge according to another embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10 ... bridge 20 ... concrete slab

30.Drainer 40 ... Drainage pipe

50 penetration guide groove 60 stainless steel panel

70 ... metal net 80 ... stainless steel pipe

In order to achieve the above object, the present invention, the concrete slab is formed in the upper portion of the bridge, the coating layer and the asphalt concrete layer is formed by laminating the upper surface of the slab, the concrete slab is installed in the lowest portion on both sides of the upper surface of the concrete slab A penetration guide groove having a square groove extending to an upper side of the drain pipe;

A stainless steel panel corresponding to a square groove of the penetrating water guide groove and bent in a U-shape so as to closely adhere to the square groove, and formed along the square groove;

It has an area that covers at least the upper portion of the stainless steel panel, and comprises a metal mesh net that is fixed to the concrete slab by a mesh fixing member.

In addition, the stainless steel panel according to the present invention may be installed between a metal mesh net having a stainless steel perforated pipe having a plurality of through-holes to drain the drainage through the drain hole in the upper portion of the waterproof layer along the square groove formed therein.

In addition, preferably, the metal mesh net is preferably installed by laminating at least two different nets having different body size.

First, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

The following terms are terms set in consideration of functions in the present invention, which may vary depending on the intention or custom of the producer, and the definitions should be made based on the contents throughout the present specification.

Hereinafter, the technical configuration of the present invention according to the accompanying drawings in detail as follows.

As shown in Figures 2 to 4, the present invention is a penetration guide groove portion formed extending to one side of the drain pipe installed, a stainless steel panel tightly fixed to the penetration water guide groove, the metal is installed on the top of the stainless panel It is made of a large net (50).

First, the drain pipe 40 installed on the slab is installed at the lowest portion by measuring the level of both sides of the upper surface of the concrete slab 20 and grouting or urethane waterproofing on the outer peripheral surface of the pipe.

In addition, the infiltration water guide groove 50 having a square groove 51 is formed at one side of the upper portion of the drain pipe, and the penetration water guide groove 50 is formed along both sides of the upper portion of the concrete slab 20 and the expansion joint. Water is easily extended from one side of the upper portion of the drain pipe 40 installed in the upper surface position of the bridge 10 with a low gradient among the upper surface of the concrete slab so that the water is easily drained, and the extension direction is a positive angle in the installed expansion joint of the bridge. It is preferable that the one-sided gradient of the upper surface of the bridge extends to a low position in the direction in which the slope is formed.

On the other hand, the infiltration water guide groove 50 is attached to the stainless steel panel 60 to be fixed in close contact, the stainless steel panel 60, one end thereof is connected to one side of the drain pipe, the upper portion is U-shaped open It is bent and is fixedly installed along the square groove 51 of the penetrating water guide groove 50 so as to collect water that collects in the upper portion of the bridge to be led to the drain pipe.

That is, the penetrated water guide groove 50 is formed so as to drain the water into the drain hole 30 is provided with a stainless steel panel 60 that is bent to correspond to the inner shape of the inner square groove 51.

In this case, the stainless steel panel 60 is further provided with a stainless steel perforated pipe 80 having a plurality of through-holes to drain the drainage 90 through the drain pipe in the upper portion of the waterproof layer 70 as a square groove 51 formed inside. Can be.

In another embodiment, as shown in Figure 5, the penetration guide groove 50 may be formed in a plurality of extending in the direction of the center of the slab of the bridge from the side of the drain pipe, the penetration guide guide portion above The stainless steel panel 60 corresponding to the 50 may be fixedly installed.

In addition, a direction in which the plurality of stainless panels 60 extending in the bridge slab center direction extends to the upper surface of the bridge 10 is stretched so that the accumulated water adjacent to the expansion joint is easily drained. It is preferable that the joint portion is formed to extend in a direction forming a predetermined slope, and the extension length thereof may vary depending on the bridge 10.

On the other hand, the metal mesh net 50 is fixed to the concrete slab 20, has an area to cover at least the upper portion of the stainless steel panel 60, by the mesh fixing member 71 to the concrete slab 20 It is fixed.

In this case, the metal net 50 may be installed by a plurality of fixing pieces are fixed by Hilti after at least two or more different nets having a different size of the body is stacked and installed.

Preferably, the drain pipe 40 formed on both sides of the concrete slab 20 and the stainless steel perforated pipe 80 is installed in the upper portion of the metal mesh net 50 so as to generate a gap, but the size of the body eye of the metal mesh net 50 is different Two metal nets 50 are installed in duplicate.

In addition, the metal mesh net 50 may be installed only to correspond to the upper portion of the stainless steel perforated pipe 80, and the installation area of the metal mesh net 50 may be selectively adjusted according to the low state of the upper surface of the bridge 10.

In addition, the metal mesh net 50 is preferably to use a galvanized mesh in order to prevent corrosion as much as possible, depending on the development of the product may use a special plastic net or general metal or stainless steel net.

Referring to the operation of the present invention made of such a configuration as follows.

First of all, the present invention is designed to completely remove the infiltration water accumulated on the upper surface of the bridge, and the rainwater is accumulated at both edges of the slab since the centerline portion of the upper surface of the bridge is slightly higher and the edge portion on which the side rails are installed is low. Since the expansion joint, which is a joint device, forms a jaw about 5 to 8 cm higher than the upper surface of the slab, the rainwater is accumulated on both sides of the upper surface of the slab adjacent to the expansion joint.

Thus, the infiltration water guide groove, which is a drainage path, is inclined at a predetermined angle from the bridge expansion joint so that the pooled water can be easily discharged to the upper one side of the drain pipe installed in a position close to the expansion joint of the bridge so that the accumulated water can be easily drained. To extend.

Subsequently, a stainless steel panel bent in a U-shape, the upper portion of which is opened into a square groove of the formed penetrating water guide groove, and a stainless steel perforated tube having a plurality of through holes is installed inside the stainless panel. The metal net including the upper surface of the stainless steel panel is fixed to the mesh fixing member through Hilti.

For example, a metal mesh net (10mm × 200mm × bridge width) is installed in the upper part of the drain slab formed on both sides of the concrete slab and the stainless steel perforated pipe so that voids are generated, but two metal net meshes having different sieve sizes of the metal net mesh are stacked in duplicate. After fixing the mesh fixing member to the upper portion of the metal mesh net to be fixed through Hilti.

In this case, the metal mesh net is preferably formed by stacking two or more different nets having different sieve sizes, and in some cases, a plurality of penetrations having different angles toward the slab center of the bridge at the side of the drain pipe. The water guide groove may be formed, and after the stainless steel panel and the perforated pipe are installed in the penetrated water guide groove, two or more metal nets may be laminated and fixed thereon.

After installing the metal mesh net, the installed metal net mesh is prevented from moving, and after the tack coating spraying to wrap the asphalt concrete on the entire upper surface of the concrete slab, the asphalt layer is laid on the surface layer to be packed and compacted with a roller. Allowing the seepage water to drain between the asphalt asphalt pavement and the concrete slab on the top of the bridge.

Accordingly, the water is collected through the oil hole tube connected to one side of the drain pipe to discharge the drain pipe.

As described above, the present invention is capable of quickly discharging the deceased caused by the gradient of the waterproof layer to the outside to prevent corrosion of the top plate due to the water pool, as well as to prevent freezing due to the water pool in the winter. There is an advantage.

Although the present invention has been shown and described with respect to specific embodiments, it has been found that the present invention can be variously modified and changed without departing from the spirit or the field of the present invention provided by the following Utility Model Registration Claims. I want to.

As such, according to the present invention, the water penetrates between the asphalt concrete pavement and the concrete slab to quickly and easily discharge water, thereby preventing the top surface of the concrete bridge from being oxidized by the water and weakening the load strength. It prevents white phenomena due to leakage of water and can extend the life of bridges, and at the same time, it is effective in reducing construction cost, securing safety and maintaining efficiently.

Claims (3)

In the bridge 10, the concrete slab 20 is formed on the top of the pier, the coating layer and the ascon pavement layer 60 by the waterproofing liquid is laminated on the upper surface of the slab, Infiltration water guide groove 50, the square groove 51 is formed to extend to the upper one side of the drain pipe 40 installed in the lowest portion of both sides of the concrete slab 20, A stainless steel panel 60 corresponding to the square groove 51 of the penetrating water guide groove 50 and bent in a U-shape so as to be tightly fixed, and extending along the square groove 51; The bridge has an area of at least covering the upper portion of the stainless steel panel 60, characterized in that the bridge comprises a metal mesh net 50 is fixed to the concrete slab 20 by the mesh fixing member 71 Drainage structure of the top infiltration water. According to claim 1, The stainless steel panel 60, along the rectangular groove 51 formed in the inner side of the waterproofing layer 70 has a plurality of through-holes to drain through the drain pipe 40 Stainless steel perforated pipe 80 is a drainage structure of the upper surface of the bridge, characterized in that installed between the metal mesh net 50 is stacked on top. The drainage structure of the upper surface of the bridge, characterized in that the metal mesh net is installed by stacking at least two nets having different sieve eye sizes.