KR102617262B1 - Construction method of integrated girder without abutment and girder constructed by this method - Google Patents

Abstract

The present invention relates to a non-shift integrated girder construction method and a girder constructed thereby, and the housing box in which the girder is seated and supported is structured to be connected to the upper part of a plurality of piles, thereby reducing the pile diameter, improving workability and It has the effect of improving constructability and construction precision.
The present invention for realizing this includes a pile construction step of constructing a plurality of piles 10 perpendicular to the ground at regular intervals on one side of the bridge construction section; (ST 1) the lower part at the upper end of the pile 10 A housing box installation step of installing a plurality of housing boxes 20 forming an open structure; (ST 2) a girder seating step of seating one end of the girder 30 on the upper surface of the housing box 20; (ST 3 ) A box connecting step of connecting the plurality of housing boxes 20 using a connecting plate 40; (ST 4) combining a finishing plate 50 for finishing the open bottom of the housing box 20 It is characterized in that it includes a finishing plate joining step; (ST 5) and a concrete pouring step of pouring concrete mortar into the interior of the housing box 20; (ST 6).

Description

Construction method of integrated girder without abutment and girder constructed by this method {Construction method of integrated girder without abutment and girder constructed by this method}

The present invention relates to a non-shift integrated girder, and more specifically, to a non-shift integrated girder construction method that can shorten the construction period while improving construction efficiency in the non-shift bridge construction process, and the girder structure constructed thereby. It's about.

In the case of a general bridge, abutments, which are the lower structure of the bridge, are installed at the starting and end points, and girders, which are the upper structure, are seated and installed on the abutments.

Meanwhile, in recent years, the non-abutment method of ramen bridge construction has been implemented to improve construction efficiency. In this no-abutment method, piles are constructed at the abutment areas and girders are placed on them.

However, the zero-shift construction method in the prior art had problems such as lowering workability and increasing construction costs because large-diameter piles were used to improve the bearing capacity of the girder, which required larger drilling equipment.

In addition, as the piles and girders are matched in a non-shift method, management of pile construction errors has become important, and a way to complement this is required.

Republic of Korea Patent Registration No. 1831770 (registered on February 19, 2018) Republic of Korea Patent Registration No. 1787321 (registered on October 11, 2017)

The present invention was proposed to improve the problems in the prior art described above, and its purpose is to provide a construction form that allows miniaturization of the pile diameter to improve workability and economic efficiency during the bridge construction process.

In addition, errors in pile construction can be easily compensated for, and the purpose is to improve economic feasibility by shortening the construction period and simplifying construction by improving constructability.

The construction method of the present invention to achieve the above object includes a pile construction step of constructing a plurality of piles perpendicular to the ground at regular intervals on one side of the bridge construction section; A housing box installation step of installing a plurality of housing boxes with an open lower part at the upper end of the pile; A girder seating step of seating one end of the girder on the upper surface of the housing box; A box connecting step of connecting the plurality of housing boxes using a connecting plate; A finishing plate combining step of combining a finishing plate for finishing the open bottom of the housing box; and a concrete pouring step of pouring concrete mortar into the interior of the housing box.

This non-shift integrated girder construction technology of the present invention has a structure in which the housing box in which the girder is seated and supported is coupled to the upper part of a plurality of piles, thereby reducing the pile diameter, improving workability and constructability, and improving construction precision. shows an improving effect.

In particular, rapid construction is possible through integration of piles and abutments, thereby reducing the construction period by eliminating the need for separate formwork and rebar placement processes for abutment concrete.

In addition, by mounting the integrated girder and housing box on the top of the pile through factory production, labor costs and construction period are shortened by minimizing on-site welding work.

In addition, it shows the advantage of improved safety due to structural integration through concrete mortar pouring inside the housing box.

1 is a diagram showing a pile construction state according to a first embodiment of the present invention.
2 and 3 are diagrams showing the housing box installation state in the present invention.
Figures 4 and 5 are diagrams showing a girder seated in the housing box in the present invention.
Figure 6 is a cross-sectional view of the inside of the housing box in the present invention.
Figures 7 to 9 are diagrams of box connection and finishing plate assembly in the present invention.
Figures 10 and 11 are diagrams showing the construction state of a no-shift integrated girder in the present invention.
Figure 12 is an exploded view of a housing box according to a second embodiment of the present invention.
Figure 13 is a cross-sectional view of the zero-abutment integrated girder construction state according to the third embodiment of the present invention.
Figure 14 is an enlarged view of part A of Figure 13.
Figure 15 is a plan cross-sectional view of the inside of a housing box according to a fourth embodiment of the present invention.
Figure 16 is an embodiment in which the zero-shift integrated girder of the present invention is applied.

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

Embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. This example is provided to more completely explain the present invention to those with average knowledge in the art.

Accordingly, the shapes of components expressed in the drawings may be exaggerated to emphasize a clearer description. It should be noted that the same configuration may be indicated by the same reference numeral in each drawing. Additionally, detailed descriptions of the functions and configurations of known technologies that are judged to unnecessarily obscure the gist of the present invention may be omitted.

First, the construction process of the zero-abutment integrated girder according to the first embodiment of the present invention is as follows through FIGS. 1 to 11.

<Pile construction stage>(ST 1)

On one side of the bridge construction section, a plurality of piles 10 are installed vertically to the ground at regular intervals.

That is, at this time, it can be confirmed that four piles 10 have been constructed as shown in FIG. 1.

<Housing box installation step>(ST 2)

Afterwards, a plurality of housing boxes 20 having an open lower part are installed at the upper end of the pile 10.

At this time, the housing box 20 that is installed has a structure in which the upper plate 22 is assembled on the upper part of the housing body 21 forming a square shape as shown in Figures 2 and 3, and the inside of the housing box 20 With the upper end of the pile 10 retracted, the upper plate 22 is integrally welded with the pile 10. At this time, it can be seen that a pouring hole 22a for pouring concrete has been formed in the upper plate 22.

<Girder seating stage>(ST 3)

When construction of the housing box 20 is completed, one end of the girder 30 of the I-beam structure is seated on the upper surface of the housing box 20, as shown in FIGS. 4 and 5.

<Box connection step>(ST 4)

Afterwards, the operation of connecting the plurality of housing boxes 20 using the connection plate 40 is performed.

That is, at this time, as shown in FIGS. 7 to 9, the two connecting plates 40 forming a “C” shaped cross-sectional structure are assembled and fastened in a symmetrical form between the housing boxes 20 forming a regular interval. desirable.

<Finish plate joining step>(ST 5)

Once the assembly of the connection plate 40 is completed in this way, a process of combining the finishing plate 50 for finishing the open bottom of the housing box 20 is performed.

At this time, the finishing plate 50 is made up of two pairs centered on the pile 10 to form a symmetrical structure and bolted. The inside of the finishing plate 50 has a semicircular shape to prevent interference with the pile 10. The pile support groove 51 is formed and welded to the pile 10.

<Concrete pouring stage>(ST 6)

Figures 10 and 11 show the girder construction structure. Afterwards, the work of pouring concrete mortar into the inside of the housing box 20 through the pour hole 22a is performed to complete the construction of the no-shift integrated girder.

The zero-shift integrated girder of the present invention, which is constructed in this way, can improve construction stability by forming a support structure in which a plurality of piles 10 are connected at the upper end by the housing box 20.

Therefore, the non-shift integrated girder of the present invention has a structure in which the housing box in which the girder is seated and supported is coupled to the upper part of a plurality of piles, so that the pile diameter can be reduced, improving workability and constructability, and construction precision. It shows an improving effect.

Meanwhile, Figure 12 shows a second embodiment of the present invention, in which a rear plate 23 is formed on the rear side of the housing box 20 to be detachable.

When this configuration is achieved, during the integrated girder construction process, the back of the housing body 21 forming the housing box 20 is in an open form, so in the process of mounting the housing box 20 on the upper part of the pile 10. The connection with the pile 10 can be easily confirmed, and the assembly work of the back plate 23 can be additionally performed after welding the connection with the pile 10, which has the advantage of reducing construction errors. indicates.

In addition, Figures 13 and 14 show a third embodiment of the present invention. In the housing box installation step (ST 2), the housing box 20 has a retaining wall 25 on one side in the form of a wall at a certain height. A structured structure is formed.

At this time, a reinforcing layer (25a) is formed on the retaining wall portion (25) to a certain thickness to strengthen adhesion to the girder (30) and improve surface strength, and the reinforcing layer (25a) contains 1 to 10% by weight of cobalt naphthenate, 5-20% by weight of polybenzimidazene, 10-30% by weight of urethane fine powder, 1-10% by weight of naphthyl malonic acid, 20-40% by weight of polysulfone resin, 5-10% by weight of phenylalanine sahydroxylase, dimethyl It is preferable to have a mixed composition of 10 to 20% by weight of glutarate and 1 to 15% by weight of sodium hexanitrocobaltate.

When such a configuration is achieved, since the housing box 20 is provided with the retaining wall portion 25 integrally, the support capacity of the end of the girder 30 is improved and construction precision can be improved.

In addition, since the reinforcing layer 25a is formed in the retaining wall portion 25, the adhesion and strength with the girder 30 can be strengthened.

In particular, since the reinforcing layer 25a contains a mixture of cobalt naphthenate and polybenzimidazene components, surface oxidation and discoloration of the retaining wall portion 25 are prevented, the urethane fine powder performs an elastic function, and naphthyl malonic acid is used to form urethane. It performs a catalytic function to prevent hardening of fine powder. In addition, the polysulfone resin prevents surface cracking of the reinforcement layer 25a, phenylalanine tetrahydroxylase and dimethyl glutarate improve surface flatness by strengthening the bonding force between the compositions during the coating process, and hexanitro cobalt Sodium acid exhibits an advanced effect of strengthening the adhesion with the retaining wall portion 25.

In addition, Figure 15 shows a fourth embodiment of the present invention, and inside the housing box 20, a plurality of reinforcing partition walls 21a are provided at regular intervals to reinforce the strength of the central part of the housing body 21, and the reinforcing partition walls It can be seen that a structure filled with reinforcing filler (21b) is formed between (21a).

At this time, the reinforcing filler (21b) is 30 to 45% by weight of polycarbonate resin, 5 to 20% by weight of bone ash, 1 to 10% by weight of metallocene polyethylene, 10 to 20% by weight of glycol monoethyl ether, and allyl phenyl ether. It is mixed at a ratio of 10 to 20% by weight and 5 to 25% by weight of fluorinated ketone.

When such a configuration is achieved, the overall support strength and durability of the housing box 20 are improved due to the configuration of the reinforcing partition wall 21a and the reinforcing filler 21b.

In particular, the reinforcing filler (21b) contains a mixture of bone ash and metallocene polyethylene, so the supporting strength can be strengthened, and the polycarbonate resin improves the close bonding force with the inner wall of the housing main body (21). Col monoethyl ether suppresses the generation of internal bubbles and voids, and allyl phenyl ether and fluorinated ketone improve the flexibility of palocarbonate resin, thereby improving the flexible function of the filler.

In addition, although specific embodiments of the present invention have been described and shown above, it is obvious that the zero-abutment integrated girder of the present invention can be implemented in various modifications by those skilled in the art.

For example, as shown in FIG. 16, the girder can be constructed not only in the form of a beam but also in the form of a steel pipe.

Therefore, such modified embodiments should not be understood individually from the technical spirit or scope of the present invention, and such modified embodiments should be included within the scope of the appended claims of the present invention.

10: File 20: Housing box
21: housing body 22: upper plate
23: back plate 25: retaining wall part
30: girder 40: connection plate
50: Finishing plate 51: Pile support groove

Claims (7)

A pile construction step (ST 1) of constructing a plurality of piles (10) perpendicular to the ground at regular intervals on one side of the bridge construction section;
A housing box installation step (ST 2) of installing a plurality of housing boxes 20 with an open lower part at the upper end of the pile 10;
A girder seating step (ST 3) of seating one end of the girder 30 on the upper surface of the housing box 20;
A box connecting step (ST 4) of connecting the plurality of housing boxes 20 using a connecting plate 40;
A finishing plate combining step (ST 5) of combining the finishing plate 50 for finishing the open bottom of the housing box 20;
A concrete pouring step (ST 6) of pouring concrete mortar into the housing box 20 through the concrete pouring hole 22a formed at the top of the housing box 20;
Including,
In the housing box installation step (ST 2), the housing box 20 is constructed with a retaining wall 25 on one side in the form of a wall and provided at a certain height,
The retaining wall portion 25 is coated with a reinforcing layer 25a to a certain thickness to strengthen adhesion to the girder 30 and improve surface strength, and the reinforcing layer 25a is formed of cobalt naphthenate, polybenzimidazene, and urethane. A non-shift integrated girder construction method characterized by a mixed composition of fine powder, naphthyl malonic acid, polysulfone resin, phenylalanine tetrahydroxylase, dimethyl glutarate, and sodium hexanitrocobaltate. In claim 1,
In the housing box installation step (ST 2), the upper end of the pile 10 is inserted into the housing box 20, which has a structure in which the upper plate 22 is assembled on the upper part of the housing body 21, which has a square shape. A non-shift integrated girder construction method, characterized in that the upper plate 22 is integrally welded with the pile 10 in this state. In claim 1,
In the box connection step (ST 4), two connection plates (40) forming a "ㄷ"-shaped cross-sectional structure are assembled and fastened in a symmetrical form between housing boxes (20) at regular intervals. Integrated girder construction method. In claim 1,
The finishing plates 50 in the finishing plate combining step (ST 5) form a symmetrical structure in pairs centered on the piles 10, and have a semicircular shape on one side to prevent interference with the piles 10. A non-shift integrated girder construction method characterized in that a pile support groove (51) is formed and bolting is performed with the housing box (20). delete delete According to the construction method of any one of claims 1 to 4, a housing box provided with a retaining wall at the upper end of the pile is connected, and a girder is mounted on the upper part of the housing box. Integral girder.

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