KR101184654B1 - Method for constructing united joint of tube filled concrete block - Google Patents

Abstract

The present invention relates to a method for constructing an integral part of a steel pipe embedded concrete block, in particular, by installing a bridge device on an upper surface of a bridge or a shift, and placing a concrete block on the upper surface of the bridge device or precasting a concrete block. Mounting, but the concrete block installation process of integrally forming the upper and lower portions of the concrete block by burying each connection member in the axial direction; The unit filling steel pipe truss girder consisting of an upper chord, a lower chord, a vertical reinforcement and a yarn reinforcement is installed in the axial direction in the concrete block, and a truss is installed to fix the upper chord and the lower chord of the unit filled steel truss girder to the connecting member. fair; And a bottom plate forming process of forming a bottom plate on an upper surface of the unit filled steel pipe truss girder and an upper surface of the concrete block.
According to the present invention as described above, the upper and lower chords of the girder are embedded in the concrete block to integrate and control the compressive force and tensile force generated in the arch-shaped girder efficiently, and can be integrated in the branch portion, it can be continuous Corresponding to the tensile force and the compressive force, and the behavior such as bending, torsion, shrinkage, expansion can be controlled.

Description

Method for constructing integral part of steel pipe embedded concrete block unit {METHOD FOR CONSTRUCTING UNITED JOINT OF TUBE FILLED CONCRETE BLOCK}

The present invention relates to a method for constructing an integral part of a steel pipe embedded concrete block, and more particularly, by embedding a steel pipe in a concrete block and installing a bridge device between the concrete block and the pier to prevent displacement and temperature load caused by temperature change. The present invention relates to a method for constructing an integrated point of a steel pipe embedded concrete block.

In general, the bridge type is divided into steel bridge and concrete bridge in terms of material. Steel bridges have a disadvantage in that a large number of reinforcement materials are required because the manufacturing process such as welding or bolting a member element is complicated while the material is expensive, and it is vulnerable to buckling due to compressive load. In addition, concrete bridges have a disadvantage that excessive cross-sectional design is inevitable due to the large weight and additional construction cost such as formwork manufacturing process is burdened and quality control and maintenance are difficult. In order to supplement these shortcomings and maximize the advantages of each structural material, composite and composite structures are actively applied to meet the behavior of members.

The concrete filled steel pipe member proposed as one of the structural types satisfying these requirements is a structure that can improve the deformation performance, rigidity and strength of the member due to the mutual binding effect between the steel pipe and the filling material by filling the inside of the steel pipe with concrete material. It is absent.

The concrete filled steel pipe structure was developed for the purpose of increasing the strength and ductility of the pillar member whose axial compressive force acts as the main load.However, the concrete filled steel pipe structure has the advantages of excellent strength, excellent deformation performance, noise and vibration suppression effect. With the focus on, it has begun to find ways to use it as a bridge girder, and compared with a single steel pipe structure or reinforced concrete structure of the same section, excellent mechanical effects such as increased strength, deformation performance, and rigidity can be obtained.

Filled steel truss girder bridge has the advantage of increasing the efficiency of the girder by using the arch effect.

The filled steel tube truss girder bridge as shown in Fig. 1 as the upper chord 21, the lower chord 23 and the reinforcement 25 to the elastic support 13 to the coping portion 11 formed on the upper portion of the piers 10 The unit filling steel pipe truss girder 20 is formed, and the unit filling steel pipe truss girder 20 is interconnected and consists of a structure for installing the bottom plate 30 on the upper surface of the unit filling steel pipe truss girder 20.

On the other hand, the structure of the filled steel tube truss girder bridge is similar in structure to the truss structure, but unlike the truss member composed of the tension member and the compression member is characterized in that additional member forces such as bending and torsion.

In particular, in the case of the lower chord 23, a support type that can sufficiently cope with the tensile force due to the bending component or the like and the compressive force concentrated in the arc shape is required.

However, the elastic bearing type point treatment applied to general straight girders cannot sufficiently handle the above-mentioned action force generated by the arch of the filled steel truss girder bridge, and cannot reflect the mechanical advantages of the arch. There are some structural disadvantages.

In particular, in a bridge structure having a relatively small length-to-height ratio (rising ratio) in the shape of an arch (for example, when a pier or an alternating height is 10 m or less), it fails to cope with displacement and temperature load caused by temperature change. There is this.

The present invention is to solve the problems as described above, the upper and lower chords are embedded in the concrete block to integrate, and the concrete block is installed on the top of the bridge or shift, the bridge between the concrete block and the bridge or shift It is an object of the present invention to provide a method for constructing an integral part of a steel pipe embedded concrete block to cope with displacement and temperature load generated by temperature change in a device.

According to an aspect of the present invention,

A bridge device is installed on the upper surface of the bridge or alternator, and a concrete block is placed on the upper surface of the bridge device or a precast concrete block is mounted, and each connection member is throttled on the upper and lower ends of the concrete block. A concrete block installation step of integrally embedding in a direction; The unit filling steel pipe truss girder consisting of an upper chord, a lower chord, a vertical reinforcement and a yarn reinforcement is installed in the axial direction in the concrete block, and a truss is installed to fix the upper chord and the lower chord of the unit filled steel truss girder to the connecting member. fair; And a bottom plate forming process of forming a bottom plate on an upper surface of the unit filled steel pipe truss girder and an upper surface of the concrete block.

Here, the connecting member and the hollow steel pipe so that the filling material such as non-contraction mortar is filled therein; A plurality of shear keys coupled to the outer surface of the steel pipe to be integrated with the concrete block; And a flange formed at one end of the steel pipe such that the upper chord and the lower chord of the unit-filled steel truss girder are coupled by anchor bolts.

Here, the concrete block is formed integrally with the connecting member during pouring, and blocks out the flange portion of the connecting member so that the flange of the connecting member is exposed.

Here, the concrete block is filled with a filler such as non-shrink mortar in the block-out portion where the upper and lower chords of the connecting member and the unit filled steel tube truss girder are connected.

Here, the concrete block is formed integrally with the connecting member when pouring, protrudes the flange of the connecting member to the outside.

According to another aspect of the present invention,

Install a bridge device on the upper surface of the piers, and install a concrete block on the upper surface of the bridge device or mount the concrete block prefabricated in the form of precast, but integrally by burying the connecting member in the direction of the bridge in the lower end of the concrete block Forming a concrete block installation process; The unit filled steel pipe truss girder consisting of an upper chord, a lower chord, a vertical reinforcement and a yarn reinforcement is installed to be symmetrically spaced apart from each other in the axial direction from the concrete block. Truss installation process to fix on; And a bottom plate forming process of forming a bottom plate on an upper surface of each unit filled steel pipe truss girder and an upper surface of the concrete block.

Here, the connecting member and the hollow steel pipe so that the filling material such as non-contraction mortar is filled therein; A plurality of shear keys coupled to the outer surface of the steel pipe to be integrated with the concrete block; And flanges formed at both ends of the steel pipe such that the lower chord and the vertical reinforcement of the unit-filled steel tube truss girder are coupled by anchor bolts.

Here, the concrete block is formed integrally with the connecting member during pouring, and blocks out the flange portion of the connecting member so that the flange of the connecting member is exposed.

Here, the concrete block also fills a filler such as non-shrink mortar in the block out portion where the lower chord and the vertical reinforcement of the connecting member and the unit filled steel tube truss girder are connected.

Here, the concrete block is formed integrally with the connecting member when pouring, and protrudes the flange of the connecting member to the outside.

Here, too, the phase chords of the unit filled steel tube truss girder are interconnected or spaced a certain distance apart.

According to still another aspect of the present invention,

Install the device on the upper surface of the shift, and install the concrete block on the upper surface of the device, or mount the concrete block prefabricated in the form of precast, but the connecting member is embedded in the lower and upper surfaces of the concrete block, respectively. Concrete block installation process to form; The unit choke, lower chord, unit filled steel pipe truss girder consisting of a vertical reinforcement and yarn reinforcement is installed so as to be symmetrically spaced apart from each other in the axial direction in the concrete block, the lower chord and vertical reinforcement of the unit filled steel pipe truss girder is connected to the connecting member A truss installation process fixed to each; And a bottom plate forming process of forming a bottom plate on an upper surface of each unit filled steel pipe truss girder and an upper surface of the concrete block.

Here, the connecting member and the hollow steel pipe so that the filling material such as non-contraction mortar is filled therein; A plurality of shear keys coupled to the outer surface of the steel pipe to be integrated with the concrete block; And flanges formed at both ends of the steel pipe such that the lower chord and the vertical reinforcement of the unit-filled steel tube truss girder are coupled by anchor bolts.

Here, the concrete block is formed integrally with the connecting member during pouring, and blocks out the flange portion of the connecting member so that the flange of the connecting member is exposed.

Here, the concrete block also fills a filler such as non-shrink mortar in the block out portion where the lower chord and the vertical reinforcement of the connecting member and the unit filled steel tube truss girder are connected.

Here, the concrete block is formed integrally with the connecting member when pouring, and protrudes the flange of the connecting member to the outside.

Here, too, the phase chords of the unit filled steel tube truss girder are interconnected or spaced a certain distance apart.

According to the method of constructing the integrated steel pipe embedded concrete block branch part of the present invention configured as described above, the upper and lower chords of the girder are embedded in the concrete block to be integrated to efficiently control the compressive force and the tensile force generated in the arch girder. The branch portion can be integrated and continuous, and the behaviors of bending, torsion, shrinkage, expansion, and the like corresponding to the tensile force and the compressive force generated at the branch portion can be controlled.

1 is a side view showing the configuration of a conventional filled steel tube truss girder bridge,
Figure 2a and Figure 2b is a perspective view showing the configuration of the filled steel tube truss girder bridge according to the first embodiment of the present invention,
3A and 3B are side cross-sectional views of FIGS. 2A and 2B,
4 is a perspective view showing the configuration of a connection member according to a first embodiment of the present invention;
5 is a process chart for explaining a method for constructing a steel pipe embedded concrete block integrated branch according to a first embodiment of the present invention;
6 is a perspective view showing the configuration of a filled steel tube truss girder bridge according to a second embodiment of the present invention,
7 is a side cross-sectional view of FIG. 6, FIG.
8 is a process chart for explaining a method for constructing a steel pipe embedded concrete block integrated branch according to a second embodiment of the present invention;
9 is a perspective view showing the configuration of a filled steel tube truss girder bridge according to a third embodiment of the present invention,
10 is a side cross-sectional view of FIG. 9;
11 is a perspective view showing the configuration of a connecting member according to a third embodiment of the present invention;
12 is a process chart for explaining a method for constructing a steel pipe embedded concrete block integrated point according to a third embodiment of the present invention.

Hereinafter, the configuration of a filled steel tube truss girder bridge according to embodiments of the present invention will be described in detail with reference to the accompanying drawings.

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 defined in consideration of the functions of the present invention, and these may be changed according to the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification.

First Embodiment

2a and 2b is a perspective view showing the configuration of a filled steel tube truss girder bridge according to a first embodiment of the present invention, Figures 3a and 3b is a side cross-sectional view of Figures 2a and 3b, Figure 4 is a first view of the present invention It is a perspective view which shows the structure of the connection member which concerns on an Example.

2A to 4, the filled steel tube truss girder bridge 100 according to the first embodiment of the present invention includes a pier 110, a bridge device 120, a concrete block 130, and a connection member 140. ), A unit filled steel pipe truss girder 150, and the bottom plate 160.

First, the pier 110 is fabricated in a field casting or precast manner, which is conventional. Here, the pier 110 may be applied alternately as shown in Figure 2b, the alternating is also manufactured in a field casting or precast manner, such as the pier.

In addition, the chair device 120 corresponds to a tension device and a compressive force generated at the point portion of the concrete block 130 to be described below as a conventional chair device to control the behavior such as bending, torsion, shrinkage, expansion, etc. generated therein. It is provided on the upper surface of the bridge 110 (or alternating).

In addition, the concrete block 130 is manufactured in a field casting or precast method is installed on the upper surface of the teaching device 120, the connecting member 140 to be described below on both sides or one side, the lower end of each throttling It is formed integrally embedded in the direction. Here, the concrete block 130 also blocks out a corresponding portion of the connecting member 140 or protrudes the flange 145 of the connecting member 140 to the outside, and the unit to be described below with the connecting member 140. When the filling steel pipe truss girder 150 is coupled to the non-shrink mortar in the block out portion. Here, the concrete block 130 is preferably a plurality of anchors 131 protruded to be coupled to the bottom plate 160 to be described later on the upper surface.

And, as shown in Figure 4, the connecting member 140 is hollow steel pipe 141 so as to fill the filling material such as non-shrink mortar, and the outer surface of the steel pipe 141 to be integrated with the concrete block 130 A plurality of shear keys 143 coupled to each other, and the unit filling steel pipe truss girder 150 is composed of a flange 145 formed on both ends of the steel pipe 141 to be coupled by the anchor bolt 101. At this time, when the connection member 140 is located at the bottom of the concrete block 130, the steel pipe 141 is inclined as shown in FIG. 2B or 3B so that the steel pipe 141 is coupled with the lower chord 151 of the unit-filled steel tube truss girder 150. It is preferable to form or to form an arch shape (not shown).

In addition, the unit filling steel pipe truss girder 150 has a slope and the lower chord 151 is formed in the shape of an arch, the vertical reinforcement 153 is vertically coupled in the upper direction from the lower chord 151, and the vertical reinforcement 153 ) And the yarn reinforcement 155 coupled between the vertical reinforcement 153 and the upper chord 157 installed on the top of the vertical reinforcement 153 and the yarn reinforcement 155. Here, the unit filled steel pipe truss girder 150 is formed in a pair of two pairs, may be connected to each other through a horizontal reinforcement (not shown) according to the selection. Here, it is preferable that the plurality of anchors 159 protrude from the upper chord 157 of the unit-filled steel tube truss girder 150 to be coupled to the bottom plate 160 to be described below.

In addition, the bottom plate 160 is installed on the upper chord 157 of the unit-filled steel tube truss girder 150 and the upper surface of the concrete block 130 in a field casting or precast manner.

Hereinafter, with reference to the accompanying drawings a continuous construction method of the filled steel tube truss girder bridge according to the first embodiment of the present invention will be described in detail.

5 is a process chart for explaining a method for constructing a steel pipe embedded concrete block integrated point according to a first embodiment of the present invention.

First, the pier 110 (or alternating) is installed according to the design, and the piercing device 120 is installed on the upper surface of each pier 110 (S100).

Then, the concrete block 130 is placed on the upper surface of the pedestal device 120 or mounted on the pre-fabricated concrete block 130 (S110). In this case, each connecting member 140 is integrally formed on both sides or one side of the concrete block 130 at the lower end, and blocks the corresponding portion of the connecting member 140 or the flange of the connecting member 140. Protrude 145 to the outside.

The unit filled steel pipe truss girder 150 including the upper chord 157, the lower chord 151, the vertical reinforcement 153, and the yarn reinforcement 155 is mounted on the concrete block 130 using lifting equipment such as a crane. After installation in the axial direction, the lower chord 151 and the upper chord 157 end of each unit filled steel tube truss girder 150 is fixed to the connection member 140 of the concrete block 130 (S120). In this case, when the concrete block 130 is blocked out, the filling material such as non-shrink mortar is filled in the corresponding portion.

Then, the bottom plate 160 is continuously constructed to remove the expansion joints on the upper surface of each unit-filled steel tube truss girder 150 and the upper surface of the concrete block 130 (S130).

Second Embodiment

6 is a perspective view showing the configuration of a filled steel tube truss girder bridge according to a second embodiment of the present invention, Figure 7 is a side cross-sectional view of FIG.

6 and 7, the filled steel tube truss girder bridge 200 according to the second embodiment of the present invention includes a pier 110, a bridge device 120, a concrete block 230, and a connection member 140. ), A unit filled steel pipe truss girder 150, and the bottom plate 160.

First, in the second embodiment of the present invention, the pier 110, the bridge device 120, the connection member 140, the unit-filled steel tube truss girder 150, and the bottom plate 160 are the first embodiment. The same code | symbol is attached | subjected by the same structure as that, and the overlapping description is abbreviate | omitted.

In addition, the concrete block 230 is manufactured by in-situ casting or precast method is installed on the upper surface of the teaching device 120, the connection member 140, which will be described later on one side of the lower end of the integrally embedded in the axial direction Is formed. Here, it is also preferable that the concrete block 230 has an inclined surface 231 so that the unit filled steel pipe truss girder 150 on both sides of the upper end may be installed. Here, the concrete block 230 also blocks out the corresponding portion of the connecting member 140 or protrudes the flange 145 of the connecting member 140 to the outside, and the unit to be described below with the connecting member 140 When the filling steel pipe truss girder 150 is coupled to the non-shrink mortar in the block out portion.

Hereinafter, with reference to the accompanying drawings a continuous construction method of the filled steel tube truss girder bridge according to a second embodiment of the present invention will be described in detail.

8 is a process chart for explaining a method for constructing a steel pipe embedded concrete block integrated point according to a second embodiment of the present invention.

First, the bridge 110 is installed according to the design, and the bridge device 120 is installed on the upper surface of the bridge 110 (S200).

Then, the concrete block 230 is poured on the upper surface of the seating device 120 or mounted on the pre-fabricated concrete block 230 (S210). At this time, the connecting member 140 is integrally formed at both lower ends of the concrete block 230, and blocks the corresponding portion of the connecting member 140 or protrudes the flange 145 of the connecting member 140 to the outside. Let's do it.

The unit filled steel pipe truss girder 150 including the upper chord 157, the lower chord 151, the vertical reinforcement 153, and the yarn reinforcement 155 may be used to lift the concrete block 130 using lifting equipment such as a crane. After positioning in both directions in the axial direction, the lower chord 151 of each unit filled steel tube truss girder 150 is fixed to the connection member 140 (S220). In this case, when the concrete block 230 is blocked out, the filling material such as non-shrink mortar is filled in the corresponding portion, and the phase chord 157 of the unit-filled steel tube truss girder 150 is as shown in FIGS. 6 and 7. It is preferred that they are interconnected or spaced apart (not shown).

Then, the bottom plate 160 is continuously constructed to remove the expansion joints on the upper surface of each unit-filled steel tube truss girder 150 and the upper surface of the concrete block 230 (S230).

Third Embodiment

9 is a perspective view showing the configuration of a filled steel tube truss girder bridge according to a third embodiment of the present invention, Figure 10 is a side cross-sectional view of Figure 9, Figure 11 is a configuration of a connecting member according to a third embodiment of the present invention It is a perspective view shown.

9 and 10, the filled steel tube truss girder bridge 300 according to the third embodiment of the present invention includes an alternate 310, a bridge device 120, a concrete block 330, and a connection member 140. ), A unit filled steel pipe truss girder 150, and the bottom plate 160.

First, in the second embodiment of the present invention, the bridge device 120, the unit-filled steel tube truss girder 150, and the bottom plate 160 are given the same reference numerals in the same configuration as the first embodiment, and their overlapping descriptions are given. Is omitted.

Then, the alternating 310 is manufactured by the in-situ casting or precast method.

In addition, the concrete block 330 is manufactured by in-situ casting or precast method is installed on the upper surface of the teaching device 120, one side of the lower side and the upper surface of the connecting member 140 to be described below in the axial direction and It is formed integrally embedded in the vertical direction. Here, the concrete block 330 preferably has an inclined surface 331 so that the unit-filled steel tube truss girder 150 which one side edge of the upper end may be installed. Here, the concrete block 330 blocks out the corresponding part of the connecting member 140 or protrudes the flange 145 of the connecting member 140 to the outside, and the unit to be described below with the connecting member 140. When the lower chord 151 and the vertical reinforcement 153 of the packed steel pipe truss girder 150 are combined, the non-shrink mortar is filled in the block out portion. Here, the concrete block 330 is preferably a plurality of anchors 333 protruded to be coupled to the bottom plate 160 to be described later on the upper surface.

And, as shown in Figure 11, the connecting member 340 is formed in a hollow shape so as to fill the filling material such as non-shrink mortar inside, the steel pipe (341) is bent to form a "needle" and concrete blocks ( A plurality of shear keys 343 coupled to the outer surface of the steel pipe (341) to be integrated with the 330, and the unit filled steel pipe truss girder 150 is formed at both ends of the steel pipe (341) to be coupled by the anchor bolt 101 It consists of a flange 345. At this time, the lower end of the steel pipe 341 is preferably inclined or arched (not shown) as shown in FIG. 10 to be coupled to the lower chord 151 of the unit filled steel pipe truss girder 150.

Hereinafter, with reference to the accompanying drawings a continuous construction method of the filled steel tube truss girder bridge according to a third embodiment of the present invention will be described in detail.

12 is a process chart for explaining a method for constructing a steel pipe embedded concrete block integrated branch according to a third embodiment of the present invention.

First, the alternator 310 is installed according to the design, and the alternator device 120 is installed on the upper surface of the alternator 310 (S300).

Then, the concrete block 330 is poured on the upper surface of the seating device 120 or mounted on the pre-fabricated concrete block 330 (S310). At this time, the connection member 140 is integrally formed on one side lower end and the upper surface of the concrete block 330, and blocks the corresponding portion of the connection member 140 or the flange 145 of the connection member 140. Protrude to the outside.

The unit filled steel pipe truss girder 150 including the upper chord 157, the lower chord 151, the vertical reinforcement 153, and the yarn reinforcement 155 may be used to lift the concrete block 330 using lifting equipment such as a crane. The lower end portion is positioned in the axial direction and the upper surface portion in the vertical direction, and then the lower chord 151 and the end of the vertical reinforcement 153 of the unit-filled steel tube truss girder 150 are fixed to the connecting member 140 (S320). ). In this case, when the concrete block 330 is blocked out, the filling material such as non-shrink mortar is filled in the corresponding portion, and the phase chord 157 of the unit-filled steel tube truss girder 150 is shown in FIGS. 9 and 10. It is preferred that they are interconnected or spaced apart (not shown).

Then, the bottom plate 160 is successively constructed to remove the expansion joints on the upper surface of each unit-filled steel tube truss girder 150 and the upper surface of the concrete block 330 (S330).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood, however, that the invention is not to be limited to the specific forms thereof, which are to be considered as being limited to the specific embodiments, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims. .

110: pier 120: bridge device
130, 230, 330: concrete block 140, 340: connecting member
150 unit filled steel pipe truss girder 160 bottom plate
310: shift

Claims (12)

A bridge device is installed on the upper surface of the bridge or alternator, and concrete blocks are placed on the upper surface of the bridge device or mounted in precast form. Each connecting member consisting of a hollow steel pipe so as to be filled with the same filling material, a plurality of shear keys coupled to an outer surface of the steel pipe so as to be integrated with the concrete block, and flanges formed at both ends of the steel pipe are embedded in the axial direction. A concrete block installation step of integrally forming;
A unit filled steel pipe truss girder consisting of an upper chord, a lower chord, and a vertical reinforcement and a yarn reinforcement is installed in the axial direction in the concrete block, and the upper chord and the lower chord of the unit filled steel pipe truss girder are anchored to the flange of the connecting member. Truss installation process to fix with; And
Steel plate embedded concrete block integrated point construction method comprising a bottom plate forming process for forming a bottom plate on the upper surface of the unit filled steel pipe truss girder and the upper surface of the concrete block. delete The method of claim 1,
The concrete block,
Wherein the connection member is integrally formed when pouring, the steel pipe embedded concrete block integral point portion construction method characterized in that to block out the flange portion of the connection member to expose the flange of the connection member. The method of claim 3, wherein
The concrete block,
Method for constructing a steel pipe embedded concrete block integrated point portion, characterized in that filling the filling material such as non-shrink mortar in the block-out portion that the upper and lower chords of the connecting member and the unit filled steel pipe truss girder is connected. The method of claim 1,
The concrete block,
Wherein the connecting member is integrally formed when pouring, steel pipe embedded concrete block integrated point construction method, characterized in that to project the flange of the connecting member to the outside. A bridge device is installed on the upper surface of the pier, and a concrete block is placed on the upper surface of the bridge device or a precast concrete block is provided, and a filling material such as non-contraction mortar is filled in the lower end of the concrete block. To form a hollow steel pipe, a plurality of shear keys coupled to an outer surface of the steel pipe so as to be integrated with the concrete block, and each connecting member formed of flanges formed at both ends of the steel pipe in the axial direction to form a single body Concrete block installation process;
The unit filled steel pipe truss girder consisting of an upper chord, a lower chord, a vertical reinforcement and a yarn reinforcement is installed to be symmetrically spaced apart from each other in the axial direction in the concrete block, and the lower chord of the unit filled steel pipe truss girder is connected to the flange of the connection member. Truss installation process of fixing with anchor bolts; And
Steel plate embedded concrete block integrated point construction method comprising a bottom plate forming process for forming a bottom plate on the upper surface of each unit filled steel pipe truss girder and the upper surface of the concrete block. Install the device on the upper surface of the shift, and the concrete block is placed on the upper surface of the device or mounted in the precast form of the concrete block, but the lower end and the upper surface of the concrete block such as non-shrink mortar Each connecting member consisting of a hollow steel pipe so as to fill a filling material, a plurality of shear keys coupled to an outer surface of the steel pipe so as to be integrated with the concrete block, and flanges formed at both ends of the steel pipe are embedded in the axial direction. Concrete block installation process to form;
The unit choke, lower chord, unit filled steel pipe truss girder consisting of a vertical reinforcement and yarn reinforcement is installed so as to be symmetrically spaced apart from each other in the axial direction in the concrete block, the lower chord and vertical reinforcement of the unit filled steel pipe truss girder is connected to the connecting member Truss installation process of fixing each of the anchor bolts to the flange of the; And
Steel plate embedded concrete block integrated point construction method comprising a bottom plate forming process for forming a bottom plate on the upper surface of each unit filled steel pipe truss girder and the upper surface of the concrete block. delete The method according to claim 6 or 7,
The concrete block,
Wherein the connection member is integrally formed when pouring, the steel pipe embedded concrete block integral point portion construction method characterized in that to block out the flange portion of the connection member to expose the flange of the connection member. The method of claim 9,
The concrete block,
A method for constructing an integral part of a steel pipe embedded concrete block, comprising filling a filler such as non-shrink mortar to a block-out portion to which the lower chord and the vertical reinforcement of the connecting member and the unit filled steel pipe truss girder are connected. The method according to claim 6 or 7,
The concrete block,
Wherein the connecting member is integrally formed when pouring, steel pipe embedded concrete block integrated point construction method, characterized in that to project the flange of the connecting member to the outside. The method according to claim 6 or 7,
The phase chord of the unit filling steel pipe truss girder,
Steel pipe embedded concrete block integrated point construction method characterized in that the interconnected or spaced apart a certain distance.

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