KR102724950B1 - Improved Truss Temporary Bridge Structure Using Triangular Unit Truss Segment - Google Patents

Abstract

Provided is an improved truss temporary bridge structure using a triangular unit truss segment as a horizontal bridge. The improved truss temporary bridge structure using a triangular unit truss segment as a horizontal bridge comprises: truss girders installed on both left and right sides, respectively, after triangular unit truss segments including a lower chord material and a diagonal material are connected and assembled in a longitudinal direction (front and rear direction, bridge axis direction); T-shaped cross beams having both ends coupled to the truss girders on both left and right sides by a coupling structure; and steel decks or concrete decks installed between the truss girders on both left and right sides and above the cross beams. According to the present invention, the triangular unit truss structure is improved to facilitate assembly and installation, to be firmly coupled, to be easily manufactured and stored, to have excellent recyclability of materials, to have excellent constructability, to increase cross-sectional rigidity, and to be applied to a small-span temporary bridge to a large-span temporary bridge.

Description

{Improved Truss Temporary Bridge Structure Using Triangular Unit Truss Segment}

The present invention relates to an improved truss construction bridge structure using triangular unit truss segments, and more particularly, to an improved truss construction bridge structure using triangular unit truss segments, which improves the joint structure of the triangular unit truss segments and the crossbeam to enable rapid and sturdy assembly, and at the same time facilitates reinforcement into a two-column or three-column type and expansion of the height.

The present invention relates to an improved truss bridge structure using triangular unit truss segments.

As an example of a prior art related to a truss bridge, Korean Patent Publication No. 10-0848869, “Truss bridge using triangular unit truss” is disclosed. This prior art is characterized in that, in a truss girder, a triangular unit truss is used as a basic truss member (100), a symmetrically fixed PS steel anchoring device (120) that can anchor and tension PS steel (126) in both directions, which is composed of an anchorage pressure plate (124) and an anchorage reinforcing steel plate (122), is fixedly attached to the lower surface of a lower chord (110) of the triangular unit truss, and a movable PS steel anchoring device (300) that can be attached and detached to the symmetrically fixed PS steel anchoring device (120) that can anchor and tension PS steel (126) in both directions (see claim 1), and the purpose thereof is to increase the rigidity of the truss bridge, reduce the weight of the truss bridge, and at the same time improve the construction workability of the PS steel anchoring device, thereby reducing the cost required for the PS steel anchoring device.

However, the above-mentioned conventional technology does not increase the cross-sectional rigidity of the truss bridge itself but increases the load-bearing capacity, so when applied to a long span, there is a problem that it is difficult to apply to a long span because a lot of deflection and vibration occur. In addition, since the above-mentioned conventional technology requires that the PS steel be tensioned on the lower surface of the truss bridge after the truss bridge is placed on the bridge piers and the bridge is alternated, there is a problem that the constructability is disadvantageous because construction may be difficult or impossible in cases where the lower part of the bridge is near a river, intersection, or mountainous area.

Therefore, the development of a truss girder bridge that improves the above problems is required.

Republic of Korea Patent Publication No. 10-0848869

The present invention has been made to solve the above problems, and an object of the present invention is to provide a truss bridge structure using an improved triangular unit truss girder which is convenient to assemble and install, has strong joints, is easy to manufacture and store, has excellent recyclability of materials, has good constructability, and has increased sectional rigidity, and can be applied from small-scale temporary bridges with small spans to large-scale temporary bridges with long spans by improving the triangular unit truss structure.

An improved truss girder bridge structure using triangular unit truss segments according to a first embodiment of the present invention comprises: a truss girder installed on each of the left and right sides after triangular unit truss segments including bottom chords and braces are connected and assembled in a longitudinal direction (front-backward direction, bridge axial direction); T-shaped crossbeams having both ends connected to the truss girders on the left and right sides by a connecting structure; The present invention relates to a method for manufacturing a truss girder, comprising: a steel deck or concrete deck installed between the truss girders on the left and right sides and above the crossbeams; and the connecting structure comprises: a triangular vertical bracket connected to the lower side of the triangular unit truss segment; a horizontal bracket connected to the beam of the triangular unit truss segment while being above the triangular vertical bracket; a connecting steel plate installed on the upper surface of the flange of the T-shaped crossbeam; a first connecting bolt connecting the front and rear vertical brackets and the abdomen of the T-shaped crossbeam interposed therebetween; a second connecting bolt connecting the flange of the T-shaped crossbeam and the connecting steel plate; and a third connecting bolt connecting the front and rear ends of the connecting steel plate and the horizontal bracket.

The longitudinal connection assembly of the above triangular unit truss segments can be performed by installing the lower chords of the front and rear triangular unit truss segments so that they are in contact with each other front and rear, assembling the lower chords of the front and rear using connecting steel plates and connecting bolts, installing an upper chord connecting the upper ends of the triangular unit truss segments, and assembling the upper chord and the upper ends of the triangular unit truss segments using connecting steel plates and connecting bolts.

An improved truss construction bridge structure using triangular unit truss segments according to a second embodiment of the present invention comprises: a plurality of double-column truss girders installed on each of the left and right sides after triangular unit truss segments including bottom chords and braces are connected and assembled in the longitudinal direction (front-backward direction, bridge axial direction); T-shaped crossbeams having both ends connected to the double-column truss girders on the left and right sides by a connecting structure; The present invention relates to a structure comprising: steel decks or concrete decks installed between the double-column truss girders on the left and right sides and on the upper sides of the crossbeams; and the connecting structure comprises: a plurality of triangular vertical brackets connected to the lower sides of the plurality of triangular unit truss segments; a plurality of horizontal brackets connected to the upper sides of the plurality of triangular vertical brackets and to the beams of the triangular unit truss segments; a connecting steel plate installed on the upper surface of the flange of the T-shaped crossbeam; a first connecting bolt connecting the plurality of front and rear vertical brackets and the web of the T-shaped crossbeam sandwiched between them; a second connecting bolt connecting the flange of the T-shaped crossbeam and the connecting steel plate; and a third connecting bolt connecting the front and rear ends of the connecting steel plates and the plurality of horizontal brackets.

The longitudinal connection assembly of the above triangular unit truss segments may be characterized by installing the lower chords of a plurality of the front and rear triangular unit truss segments so that they are in contact with each other front and rear, assembling the lower chords of the front and rear using a connecting steel plate and a connecting bolt, installing an upper chord connecting the upper ends of the triangular unit truss segments, and assembling the upper chord and the upper ends of the triangular unit truss segments using a connecting steel plate and a connecting bolt.

The transverse connection assembly of the multiple-column truss girders installed on the left and right sides above can be accomplished by installing a gap-maintaining lower chord between the lower chords of the multiple-column truss girders and connecting them with the lower chords on both sides with bolts, and installing a gap-maintaining upper chord between the upper chords of the multiple-column truss girders and connecting them with the upper chords on both sides with bolts.

An improved truss construction bridge structure using triangular unit truss segments according to a third embodiment of the present invention comprises: a two-stage truss girder in which triangular unit truss segments including a bottom chord and a saddle member and inverted triangular unit truss segments including an upper chord and a saddle member are connected and assembled vertically and simultaneously in a longitudinal direction (front-backward direction, bridge axial direction) and then installed one on each of the left and right sides; T-shaped crossbeams in which both ends are connected to the two-stage truss girders on the left and right sides by a connecting structure; The present invention relates to a structure comprising: steel decks or concrete decks installed between the two-stage truss girders on the left and right sides and above the crossbeams; and the connecting structure comprises: a triangular vertical bracket connected to the lower side of the triangular unit truss segment; a horizontal bracket connected to the beam of the triangular unit truss segment while being above the triangular vertical bracket; a connecting steel plate installed on the upper surface of the flange of the T-shaped crossbeam; a first connecting bolt connecting the front and rear vertical brackets and the abdomen of the T-shaped crossbeam interposed therebetween; a second connecting bolt connecting the flange of the T-shaped crossbeam and the connecting steel plate; and a third connecting bolt connecting the front and rear ends of the connecting steel plate and the horizontal bracket.

The vertical connection assembly of the above-mentioned triangle unit truss segments and the inverse triangle unit truss segments can be accomplished by inserting a connecting H-shaped steel between the opposing vertices of the triangle unit truss segments and the inverse triangle unit truss segments, and then assembling them with a connecting steel plate and a connecting bolt. The longitudinal connection assembly of the above-mentioned triangle unit truss segments and the inverse triangle unit truss segments can be accomplished by installing the lower chords of the front and rear triangle unit truss segments so that they are in contact with each other, and assembling the lower chords of the front and rear using a connecting steel plate and a connecting bolt. The upper chords of the above-mentioned inverse triangle unit truss segments can be installed so that they are in contact with each other with each other, and assembling the upper chords of the front and rear using a connecting steel plate and a connecting bolt.

An improved truss construction bridge structure using triangular unit truss segments according to a fourth embodiment of the present invention comprises: a double-column type two-stage truss girder in which triangular unit truss segments including a bottom chord and a saddle member and inverted triangular unit truss segments including an upper chord and a saddle member are connected and assembled vertically and simultaneously in a longitudinal direction (front-backward direction, bridge axial direction) and then installed in multiple numbers on each of the left and right sides; T-shaped crossbeams in which both ends are connected to the double-column type two-stage truss girders on the left and right sides by a connecting structure; The present invention relates to a method for making a truss girder, comprising: a steel deck or concrete deck installed between the two-stage truss girders of the left and right sides and above the crossbeams; and the connecting structure comprises: a plurality of triangular vertical brackets connected to the lower sides of the plurality of triangular unit truss segments; a plurality of horizontal brackets connected to the upper sides of the plurality of triangular vertical brackets and to the beams of the plurality of triangular unit truss segments; a connecting steel plate installed on the upper surface of the flange of the T-shaped crossbeam; a first connecting bolt connecting the plurality of vertical brackets at the front and rear and the abdomen of the T-shaped crossbeam sandwiched between them; a second connecting bolt connecting the flange of the T-shaped crossbeam and the connecting steel plate; and a third connecting bolt connecting the front and rear ends of the connecting steel plate and the plurality of horizontal brackets.

The vertical connection assembly of the above-mentioned triangle unit truss segments and the inverse triangle unit truss segments can be accomplished by inserting a connecting H-shaped steel between the opposing vertices of the triangle unit truss segments and the inverse triangle unit truss segments, and then assembling them with a connecting steel plate and a connecting bolt. The longitudinal connection assembly of the above-mentioned triangle unit truss segments and the inverse triangle unit truss segments can be accomplished by installing the lower chords of the front and rear triangle unit truss segments so that they are in contact with each other, and assembling the lower chords of the front and rear using a connecting steel plate and a connecting bolt. The upper chords of the above-mentioned inverse triangle unit truss segments can be installed so that they are in contact with each other with each other, and assembling the upper chords of the front and rear using a connecting steel plate and a connecting bolt.

The horizontal connection assembly of the above-mentioned two-stage truss girders, each installed on both left and right sides, may be accomplished by installing a gap-maintaining lower chord between the lower chords of the above-mentioned two-stage truss girders and fastening them with bolts to the lower chords on both sides, installing a gap-maintaining upper chord between the upper chords of the above-mentioned two-stage truss girders and fastening them with bolts to the upper chords on both sides, and installing a gap-maintaining connecting member in the center of the above-mentioned two-stage truss girders and fastening them with bolts.

The T-shaped cross-section of the above embodiments may be characterized in that the central portion, excluding the two end portions where the connecting structure is connected, is an I-shaped or H-shaped portion equipped with a lower flange.

According to the present invention, the triangular unit truss structure is improved so that assembly and installation are convenient, the joint is strong, manufacturing and storage are easy, the material recyclability is excellent, the constructability is good, and the sectional rigidity is increased, and it can be applied from small-scale temporary bridges with small spans to large-scale temporary bridges with long spans.

Figure 1a is an exploded side view and cross-sectional view of a truss girder of the first embodiment of the present invention.
Figure 1b is an exploded perspective view and a combined perspective view of a truss girder of the first embodiment of the present invention.
Figure 1c is an assembled side view and an assembled perspective view of the truss girder of the first embodiment of the present invention.
Figure 1d is a cross-sectional view of the truss construction bridge structure of the first embodiment of the present invention.
Figure 1e is a perspective view of the truss construction bridge structure of the first embodiment of the present invention.
Figure 2a is an exploded side view and cross-sectional view of a truss girder of the second embodiment of the present invention.
Figure 2b is an exploded perspective view and a combined perspective view of a truss girder of the second embodiment of the present invention.
Figure 2c is an assembled side view and an assembled perspective view of a truss girder of the second embodiment of the present invention.
Figure 2d is a cross-sectional view of a truss construction bridge structure of the second embodiment of the present invention.
Figure 2e is a perspective view of a truss construction bridge structure of the second embodiment of the present invention.
Figure 3a is an exploded side view and cross-sectional view of a truss girder of the third embodiment of the present invention.
Figure 3b is an exploded perspective view and a combined perspective view of a truss girder of the third embodiment of the present invention.
Figure 3c is an assembled side view and an assembled perspective view of a truss girder of the third embodiment of the present invention.
Figure 3d is a cross-sectional view of a truss bridge structure according to the third embodiment of the present invention.
Figure 3e is a perspective view of a truss construction bridge structure of the third embodiment of the present invention.
Figure 4a is an exploded side view and cross-sectional view of a truss girder of the fourth embodiment of the present invention.
Figure 4b is an exploded perspective view and a combined perspective view of a truss girder of the fourth embodiment of the present invention.
Figure 4c is an assembled side view and an assembled perspective view of a truss girder of the fourth embodiment of the present invention.
Figure 4d is a cross-sectional view of a truss construction bridge structure of the fourth embodiment of the present invention.
Figure 4e is a perspective view of a truss construction bridge structure of the fourth embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. When adding reference numerals to components in each drawing, the same components are given the same numerals as much as possible even if they are shown in different drawings. In addition, when describing embodiments of the present invention, if it is determined that a specific description of a related known configuration or function hinders understanding of the embodiments of the present invention, the detailed description thereof will be omitted.

Also, in describing components of embodiments of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only intended to distinguish the components from other components, and the nature, order, or sequence of the components are not limited by the terms. When it is described that a component is "connected," "coupled," or "connected" to another component, the component may be directly connected or connected to the other component, but another component may also be "connected," "coupled," or "connected" between each component.

Hereinafter, an improved truss bridge structure using the triangular unit truss segment of the present invention will be described with reference to the drawings.

FIG. 1a is an exploded side view and a cross-sectional view of a truss girder of a first embodiment of the present invention, FIG. 1b is an exploded perspective view and a combined perspective view of a truss girder of a first embodiment of the present invention, FIG. 1c is an assembled side view and an assembled perspective view of a truss girder of a first embodiment of the present invention, FIG. 1d is a cross-sectional view of a truss construction bridge structure of a first embodiment of the present invention, FIG. 1e is a perspective view of a truss construction bridge structure of a first embodiment of the present invention, FIG. 2a is an exploded side view and a cross-sectional view of a truss girder of a second embodiment of the present invention, FIG. 2b is an exploded perspective view and a combined perspective view of a truss girder of a second embodiment of the present invention, FIG. 2c is an assembled side view and an assembled perspective view of a truss girder of a second embodiment of the present invention, FIG. 2d is a cross-sectional view of a truss construction bridge structure of a second embodiment of the present invention, FIG. 2e is a perspective view of a truss girder of a second embodiment of the present invention, FIG. 3a is an exploded side view and a cross-sectional view of a truss girder of a third embodiment of the present invention, FIG. 3b is an exploded perspective view and a combined perspective view of a truss girder of a third embodiment of the present invention, FIG. 3c is an assembled side view and an assembled perspective view of a truss girder of a third embodiment of the present invention, FIG. 3d is a cross-sectional view of a truss girder of a third embodiment of the present invention, FIG. 3e is a perspective view of a truss girder of a third embodiment of the present invention, FIG. 4a is an exploded side view and a cross-sectional view of a truss girder of a fourth embodiment of the present invention, FIG. 4b is an exploded perspective view and a combined perspective view of a truss girder of a fourth embodiment of the present invention, FIG. 4c is an assembled side view and an assembled perspective view of a truss girder of a fourth embodiment of the present invention, and FIG. 4d is a cross-sectional view of a truss girder of a fourth embodiment of the present invention. This is a cross-sectional view of a truss-type bridge structure according to the fourth embodiment of the invention, and FIG. 4e is a perspective view of the truss-type bridge structure according to the fourth embodiment of the invention.

(First embodiment)

An improved truss girder bridge structure using triangular unit truss segments according to a first embodiment of the present invention comprises: a truss girder (10) installed on each of the left and right sides after triangular unit truss segments (12) including bottom chords (122) and braces (124) are connected and assembled in a longitudinal direction (front-backward direction, bridge axial direction); T-shaped crossbeams (30) whose both ends are connected to the truss girders (10) on the left and right sides by a connecting structure; The steel deck or concrete deck (40) installed between the truss girders (10) on both the left and right sides and on the upper side of the crossbeams (30); the connecting structure comprises a triangular vertical bracket (51) connected to the lower side of the triangular unit truss segment (12), a horizontal bracket (52) connected to the beam (124) of the triangular unit truss segment (12) on the upper side of the triangular vertical bracket (51), a connecting steel plate (54) installed on the upper surface of the flange of the T-shaped crossbeam (30), a first connecting bolt (55) connecting the front and rear vertical brackets and the abdomen of the T-shaped crossbeam (30) inserted between them, a second connecting bolt (56) connecting the flange of the T-shaped crossbeam (30) and the connecting steel plate (54), and a third connecting bolt (57) connecting the front and rear ends of the connecting steel plate (54) and the horizontal bracket (52). may include:

The triangular unit truss segment (12) of the present embodiment may include a lower chord (122) installed on the lower side, and a brace (124) extending upward from both ends of the lower chord (122) and coupled to each other on the upper side.

The triangular unit truss segment (12) may include end segments installed at both ends of the bridge and a central segment installed at the center.

The short segment may be formed in a right triangle shape with the short segment (124) being vertical, and the central segment may be formed in a triangle shape with both of the short segments (124) being inclined.

The above-mentioned lower current (122) and the upper current (124) can be made of H-shaped or I-shaped steel. The upper current (126) described below can also be made of H-shaped or I-shaped steel.

The above T-shaped crossbeam (30) may include a vertically installed abdomen and a flange that is horizontally connected to the upper end of the abdomen. In addition, the T-shaped crossbeam (30) may be an I-shaped or H-shaped beam with a lower flange provided in the central portion, excluding both ends where the connecting structure is connected. By providing the lower flange, the rigidity of the crossbeam may be increased. That is, it is possible to quickly and easily connect between triangular unit truss segments (12) and at the same time increase the rigidity.

The above-mentioned triangular vertical bracket (51) may include a pair of triangular-shaped flange brackets that are joined by welding or the like to the lower sides of both flanges of the triangular unit truss segment (12) member (124), and a plate-shaped connecting bracket that is joined by welding or the like to the ends of both flange brackets. In addition, the flange bracket and the connecting bracket may be formed by bending a single steel plate and then joined by welding or the like to the lower sides of both flanges of the member (124).

The above horizontal bracket (52) is on the upper side of the triangular vertical bracket (51) and can be joined to the beam (124) of the triangular unit truss segment (12) by welding, etc. That is, it can be installed between the web and both flanges of the H-shaped and I-shaped beam (124) and then joined to the web and both flanges by welding, etc.

The above-mentioned joining plate (54) may include a joining body installed on the upper surface of the flange of the T-shaped crossbeam (30), and joining members provided on the front and rear ends of the joining body. The joining member may be inserted between the two flanges of the saddle (124) with a narrower width than the joining body, and may be installed so as to overlap on the upper side of the horizontal bracket (52).

The above first coupling bolt (55) can connect the front and rear vertical brackets and the abdomen of the T-shaped crossbeam (30) inserted therebetween. That is, the first coupling bolt (55) can be connected by fastening it to the bolt hole formed in the connecting bracket of the triangular vertical bracket (51) and the abdomen of the T-shaped crossbeam (30). The bolt hole and the first coupling bolt (55) can be multiple.

The above second connecting bolt (56) can connect the flange of the T-shaped crossbeam (30) and the connecting steel plate (54). That is, the flange of the T-shaped crossbeam (30) and the connecting steel plate (54) can be connected by fastening the second connecting bolt (56) to the bolt hole formed in the flange of the T-shaped crossbeam (30). The bolt hole and the second connecting bolt (56) can also be multiple.

The third connecting bolt (57) can connect the connecting member, which is the front and rear end portion of the connecting steel plate (54), and the horizontal bracket (52). That is, the connecting member, which is the front and rear end portion of the connecting steel plate (54), and the horizontal bracket (52) can be connected by fastening the third connecting bolt (57) to the bolt hole formed in the horizontal bracket (52). The bolt hole and the third connecting bolt (57) can also be multiple.

The longitudinal connection assembly of the above triangular unit truss segments (12) can be performed by installing the lower chords (122) of the front and rear triangular unit truss segments (12) so that they are in contact with each other, installing a connecting plate (60) on the side surface of the lower chords (122) of the front and rear triangular unit truss segments, and fastening a connecting bolt. In addition, the upper chord (126) connecting the upper ends of the triangular unit truss segments (12) can be installed, and the upper chord (126) and the upper ends of the triangular unit truss segments (12) can be assembled using a connecting plate (60) and a connecting bolt. The upper chord (126) can be installed one by one for each triangular unit truss segment (12), one by one for each of a plurality of segments, or one by one for the entire length of the truss girder (10).

The construction bridges of the present embodiment and the embodiments described below can have a sidewalk (80) installed on the side. The sidewalk can have a T-shaped crossbeam (30) extended further outward from the truss girder (10), a floor plate installed on the upper side of the extension, and a guardrail installed on the side. The guardrail can be formed in a truss structure.

In addition, the temporary bridges of the present embodiment and the embodiments described below can be installed between abutments, between abutments and piers, or between piers, and can be installed in the form of a simple bridge or a continuous bridge.

(Second embodiment)

Below, an improved truss bridge structure using a triangular unit truss segment (12) according to a second embodiment of the present invention is described.

This embodiment may include the same configuration as the above-described embodiment. The description of the same configuration as the above-described embodiment may be omitted. The omitted description may refer to the description of the above-described embodiment.

An improved truss construction bridge structure using triangular unit truss segments according to a second embodiment of the present invention comprises: a plurality of double-column truss girders (10a) installed on each of the left and right sides after triangular unit truss segments (12) including bottom chords (122) and braces (124) are connected and assembled in the longitudinal direction (front-backward direction, bridge axial direction); T-shaped crossbeams (30) whose both ends are connected to the double-column truss girders (10a) on the left and right sides by a connecting structure; The steel deck or concrete deck (40) is installed between the double-column truss girders (10a) on the left and right sides and on the upper side of the crossbeams (30); and the connecting structure comprises: a plurality of triangular vertical brackets (51) connected to the lower side of the plurality of triangular unit truss segments (12), a plurality of horizontal brackets (52) connected to the beam (124) of the triangular unit truss segments (12) while on the upper side of the plurality of triangular vertical brackets (51), a connecting steel plate (54) installed on the upper surface of the flange of the T-shaped crossbeam (30), a first connecting bolt (55) connecting the front and rear ends of the plurality of vertical brackets and the abdomen of the T-shaped crossbeam (30) inserted between them, a second connecting bolt (56) connecting the flange of the T-shaped crossbeam (30) and the connecting steel plate (54), a front and rear end of the connecting steel plate (54) and a plurality of the It may include a third connecting bolt (57) that connects the horizontal bracket (52).

In this embodiment, multiple truss girders can be installed on each of the left and right sides of the T-shaped crossbeam (30). For example, a two-column truss girder in which two truss girders are installed, a three-column truss girder in which three truss girders are installed, etc. can be installed. Accordingly, a double-column truss girder (10a) can be connected to the left and right ends of the T-shaped crossbeam (30) by a connecting structure.

The joint structure of this embodiment can quickly and firmly join the T-shaped crossbeam (30) and the double-column truss girder (10a) even when the number of trusses girders increases due to its structural flexibility. In other words, the number of trusses girders can be increased to a necessary level and joined by only replacing the joint steel plate (54). The double-column truss girder (10a) can greatly increase the rigidity of the truss girder compared to the single-column truss girder. Therefore, when the load that the temporary bridge must support increases, the number of truss girders can be quickly and easily increased.

The number of triangle vertical brackets (51), horizontal brackets (52), etc. of the joint structure is provided in multiples as many as the number of truss girders. In addition, a plurality of joint members are formed at each of the front and rear ends of the joint steel plate (54). That is, the joint steel plate (54) may include a joint body installed on the upper surface of the flange of the T-shaped crossbeam (30), and a plurality of joint members provided at each of the front and rear ends of the joint body. The joint members may be formed to have a narrow width so as to be inserted between each of the flanges of the triangular unit truss segments (12) of the braces (124).

The longitudinal connection assembly of the above triangle unit truss segments (12) is installed so that the lower chords (122) of multiple triangle unit truss segments (12) at the front and rear are in contact with each other at the front and rear, the lower chords (122) at the front and rear are assembled using a connecting plate (60) and a connecting bolt, an upper chord (126) is installed at the tops of the triangle unit truss segments (12), and the upper chord (126) and the upper ends of the triangle unit truss segments (12) can be assembled using a connecting plate (60) and a connecting bolt.

The horizontal connection assembly of the multiple-piece truss girder (10a) installed on both left and right sides can be accomplished by installing a gap-maintaining lower chord (70) between the lower chords (122) of the multiple-piece truss girder (10a) and fastening it to the lower chords (122) on both sides with bolts, and installing a gap-maintaining upper chord (72) between the upper chords (126) of the multiple-piece truss girder (10a) and fastening it to the upper chords (126) on both sides with bolts. The gap-maintaining lower chord (70) and the gap-maintaining upper chord (72) can horizontally connect and assemble the multiple-piece truss girder (10a) and at the same time, can greatly increase the rigidity of the multiple-piece truss girder (10a).

(Third embodiment)

Hereinafter, an improved truss bridge structure using a triangular unit truss segment (12) according to a third embodiment of the present invention will be described.

This embodiment may include the same configuration as the above-described embodiments. The description of the same configuration as the above-described embodiments may be omitted. The omitted description may refer to the description of the above-described embodiments.

An improved truss construction bridge structure using a triangular unit truss segment (12) according to a third embodiment of the present invention comprises: a two-stage truss girder (10b) in which triangular unit truss segments (12) including a bottom chord (122) and a beam (124) and inverted triangular unit truss segments (12a) including an upper chord (126) and a beam (124) are connected and assembled vertically and simultaneously in a longitudinal direction (front-backward direction, bridge axial direction) and then installed one on each of the left and right sides; T-shaped crossbeams (30) in which both ends are connected to the two-stage truss girders (10b) on the left and right sides by a connecting structure; The steel deck or concrete deck (40) is installed between the two-stage truss girders (10b) on the left and right sides and on the upper side of the T-shaped crossbeams (30); and the connecting structure comprises: a triangular vertical bracket (51) connected to the lower side of the triangular unit truss segment (12), a horizontal bracket (52) connected to the beam (124) of the triangular unit truss segment (12) while on the upper side of the triangular vertical bracket (51), a connecting steel plate (54) installed on the upper surface of the flange of the T-shaped crossbeam (30), a first connecting bolt (55) connecting the front and rear vertical brackets and the abdomen of the T-shaped crossbeam (30) inserted therebetween, a second connecting bolt (56) connecting the flange of the T-shaped crossbeam (30) and the connecting steel plate (54), and a second connecting bolt (56) connecting the front and rear ends of the connecting steel plate (54) and the horizontal bracket (52). It may include a third coupling bolt (57).

In the two-stage truss girder (10b) of the present embodiment, triangular unit truss segments (12) including a bottom chord (122) and a saddle member (124) and inverted triangular unit truss segments (12a) including an upper chord (126) and a saddle member (124) are connected and assembled vertically and simultaneously in the longitudinal direction (front-backward direction, axial direction) and then installed one on each of the left and right sides. That is, the triangular unit truss segments (12) having a wider lower side are installed on the lower side, and the inverted triangular unit truss segments (12a) having a wider upper side are installed on the upper side, and their vertices are connected and assembled to each other, and these are formed by connecting and assembling in the longitudinal direction. Accordingly, the saddle members (124) of the two-stage truss girder (10b) are installed in an approximately X shape, the lower chord (122) is installed on the lower side, and the upper chord (126) is installed on the upper side. This embodiment can quickly and easily increase the height of a truss girder, thereby greatly increasing the flexural strength of the truss girder.

The upper portions of the two-stage truss girder (10b) can be interconnected by introducing the aforementioned T-shaped crossbeam (30) and connecting structure between the inverted triangle unit truss segments (12a). That is, the T-shaped crossbeam (30) can be turned over and installed between the inverted triangle unit truss segments (12a), and connected by applying the connecting structure. This can increase the lateral resistance of the two-stage truss girder (10b).

The upper and lower connection assembly of the above-mentioned triangle unit truss segments (12) and the inverted triangle unit truss segments (12a) can be accomplished by inserting a connecting H-shaped steel (128) between the opposing vertices of the triangle unit truss segments (12) and the inverted triangle unit truss segments (12a), and then assembling them using a connecting steel plate (60) and a connecting bolt.

In addition, the longitudinal connection assembly of the above-described triangle unit truss segments (12) and the inverted triangle unit truss segments (12a) is installed so that the lower chords (122) of the front and rear triangle unit truss segments (12) are in contact with each other at the front and rear, and the lower chords (122) at the front and rear are assembled using a connecting plate (60) and a connecting bolt, and the upper chords (126) of the inverted triangle unit truss segments (12a) are installed so that they are in contact with each other at the front and rear, and the upper chords (126) at the front and rear are assembled using a connecting plate (60) and a connecting bolt.

(4th implementation)

Hereinafter, an improved truss construction bridge structure using a triangular unit truss segment (12) according to a fourth embodiment of the present invention will be described.

This embodiment may include the same configuration as the above-described embodiments. The description of the same configuration as the above-described embodiments may be omitted. The omitted description may refer to the description of the above-described embodiments.

An improved truss construction bridge structure using a triangular unit truss segment (12) according to a fourth embodiment of the present invention comprises: a plurality of double-column type two-stage truss girders (10c) installed on each of the left and right sides, wherein triangular unit truss segments (12) including a bottom chord (122) and a beam (124) and inverted triangular unit truss segments (12a) including an upper chord (126) and a beam (124) are connected and assembled vertically and simultaneously connected and assembled in a longitudinal direction (front-backward direction, bridge axial direction); T-shaped crossbeams (30) in which both ends are connected to the double-column type two-stage truss girders (10c) on both left and right sides by a connecting structure; The steel deck or concrete deck (40) is installed between the two-stage truss girders (10c) of the left and right sides and on the upper side of the crossbeams (30); and the connecting structure comprises: a plurality of triangular vertical brackets (51) connected to the lower side of the plurality of triangular unit truss segments (12), a plurality of horizontal brackets (52) connected to the beams (124) of the plurality of triangular unit truss segments (12) while on the upper side of the plurality of triangular vertical brackets (51), a connecting steel plate (54) installed on the upper surface of the flange of the T-shaped crossbeam (30), a first connecting bolt (55) connecting the front and rear ends of the plurality of vertical brackets and the abdomen of the T-shaped crossbeam (30) inserted between them, a second connecting bolt (56) connecting the flange of the T-shaped crossbeam (30) and the connecting steel plate (54), a plurality of connecting bolts (56) connecting the front and rear ends of the connecting steel plate (54) and the plurality of It may include a third connecting bolt (57) that connects the above horizontal bracket (52).

The upper and lower connection assembly of the above-described triangle unit truss segments (12) and the inverted triangle unit truss segments (12a) can be carried out by inserting a connecting H-shaped steel (128) between the opposing vertices of the triangle unit truss segments (12) and the inverted triangle unit truss segments (12a), and then assembling them with a connecting steel plate (60) and a connecting bolt. In addition, the longitudinal connection assembly of the above-described triangle unit truss segments (12) and the inverted triangle unit truss segments (12a) can be carried out by installing the lower chords (122) of the front and rear triangle unit truss segments (12) so that they are in contact with each other, assembling the lower chords (122) of the front and rear bottom chords (122) with a connecting steel plate (60) and a connecting bolt, and installing the upper chords (126) of the inverted triangle unit truss segments (12a) so that they are in contact with each other with each other with each other, and assembling the upper chords (126) of the front and rear top chords (126) with a connecting steel plate (60) and a connecting bolt.

The horizontal connection assembly of the multiple-piece double-column type 2-stage truss girders (10c) installed on both left and right sides can be accomplished by installing a gap-maintaining lower chord (70) between the lower chords (122) of the double-column type 2-stage truss girders (10c) and fastening them with bolts to the lower chords (122) on both sides, installing a gap-maintaining upper chord (72) between the upper chords (126) of the double-column type 2-stage truss girders (10c) and fastening them with bolts to the upper chords (126) on both sides, and installing a gap-maintaining connecting member (74) in the center of the double-column type 2-stage truss girders (10c) and fastening them with bolts.

In the above, even though all the components constituting the embodiments of the present invention have been described as being combined or operated in combination, the present invention is not necessarily limited to these embodiments. That is, within the scope of the purpose of the present invention, all of the components may be selectively combined and configured or operated in one or more. In addition, the terms "include," "compose," or "have" described above, unless specifically stated to the contrary, mean that the corresponding component may be inherent, and therefore should be interpreted as including other components rather than excluding other components. All terms, including technical or scientific terms, have the same meaning as generally understood by a person of ordinary skill in the art to which the present invention belongs, unless otherwise defined. Commonly used terms, such as terms defined in a dictionary, should be interpreted as being consistent with the contextual meaning of the relevant technology, and shall not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present invention.

The above description is merely an illustrative description of the technical idea of the present invention, and those skilled in the art will appreciate that various modifications and variations may be made without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to explain it, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within a scope equivalent thereto should be interpreted as being included in the scope of the rights of the present invention.

10: Truss girder
10a: Double truss girder
10b: 2-stage truss girder
10c: Double-tier truss girder
12: Triangular Unit Truss Segment
12a: Inverted triangle unit truss segment
122: Ha Hyun-jae
124: Private property
126: Sang Hyun-jae
128: H-beam connection
30: T-shaped crossbeam
40: Steel deck or concrete deck
51: Triangle vertical bracket
52: Horizontal bracket
54: Bonding plate
55: First coupling bolt
56: Second connecting bolt
57: Third connecting bolt
60: Connecting plate
70: Maintaining the gap
72: Current status of maintaining gap
74: Gap-maintaining connector
80: Press Department

Claims (11)

A truss girder in which triangular unit truss segments including the lower chord and the lower chord are connected and assembled longitudinally (front-backward, axial direction) and then installed one on each side;
T-shaped crossbeams whose ends are connected to the truss girders on both left and right sides by a connecting structure;
Includes steel decks or concrete decks installed between the truss girders on both the left and right sides and on the upper side of the crossbeams;
The above-mentioned connecting structure includes a triangular vertical bracket connected to the lower side of the triangular unit truss segment, a horizontal bracket connected to the upper side of the triangular vertical bracket and the beam of the triangular unit truss segment, a connecting steel plate installed on the upper surface of the flange of the T-shaped crossbeam, a first connecting bolt connecting the front and rear vertical brackets and the abdomen of the T-shaped crossbeam sandwiched therebetween, a second connecting bolt connecting the flange of the T-shaped crossbeam and the connecting steel plate, and a third connecting bolt connecting the front and rear ends of the connecting steel plate and the horizontal bracket.
The above triangular vertical bracket includes a pair of flange brackets connected to the lower sides of both flanges of the triangular unit truss segment, and a plate-shaped connecting bracket connected to the ends of the pair of flange brackets.
The above first connecting bolt connects the abdomen of the T-shaped crossbeam and the connecting brackets of the front and rear triangular vertical brackets while the abdomen of the T-shaped crossbeam is inserted between the connecting brackets of the front and rear triangular vertical brackets,
The above horizontal bracket is connected between a pair of flanges of the beam of the above triangular unit truss segment,
The third connecting bolt is characterized in that it is connected in a state where the front and rear ends of the connecting steel plate overlap the upper side of the horizontal bracket.
An improved truss girder bridge structure using triangular unit truss segments. In claim 1,
The longitudinal connection assembly of the above triangular unit truss segments is characterized in that the lower chords of the front and rear triangular unit truss segments are installed so that they are in contact with each other front and rear, the lower chords of the front and rear triangular unit truss segments are assembled with connecting steel plates and connecting bolts, the upper chord connecting the upper ends of the triangular unit truss segments is installed, and the upper chord and the upper ends of the triangular unit truss segments are assembled with connecting steel plates and connecting bolts.
An improved truss girder bridge structure using triangular unit truss segments. A multi-column truss girder in which triangular unit truss segments including the lower hull and the lower member are connected and assembled longitudinally (front-backward, axial direction) and then installed in multiple units on each side;
T-shaped crossbeams whose ends are connected to the double-column truss girders on both sides by a connecting structure;
Includes steel decks or concrete decks installed between the double-column truss girders on both the left and right sides and on the upper side of the crossbeams;
The above-described connecting structure includes a plurality of triangular vertical brackets connected to the lower sides of the plurality of triangular unit truss segments, a plurality of horizontal brackets connected to the upper sides of the plurality of triangular vertical brackets and to the beams of the plurality of triangular unit truss segments, a plurality of connecting steel plates installed on the upper surface of the flange of the T-shaped crossbeam, a first connecting bolt connecting the plurality of front and rear vertical brackets and the abdomen of the T-shaped crossbeam sandwiched therebetween, a second connecting bolt connecting the flange of the T-shaped crossbeam and the plurality of connecting steel plates, and a third connecting bolt connecting the front and rear ends of the plurality of connecting steel plates and the plurality of horizontal brackets.
The above triangular vertical bracket includes a pair of flange brackets connected to the lower sides of both flanges of the triangular unit truss segment, and a plate-shaped connecting bracket connected to the ends of the pair of flange brackets.
The above first connecting bolt connects the abdomen of the T-shaped crossbeam and the connecting brackets of the front and rear triangular vertical brackets while the abdomen of the T-shaped crossbeam is inserted between the connecting brackets of the front and rear triangular vertical brackets,
The above horizontal bracket is connected between a pair of flanges of the beam of the above triangular unit truss segment,
The third connecting bolt is characterized in that it is connected in a state where the front and rear ends of the connecting steel plate overlap the upper side of the horizontal bracket.
An improved truss girder bridge structure using triangular unit truss segments. In claim 3,
The longitudinal connection assembly of the above triangular unit truss segments is characterized in that the lower chords of the plurality of front and rear triangular unit truss segments are installed so that they are in contact with each other front and rear, the lower chords of the front and rear are assembled with connecting steel plates and connecting bolts, the upper chords connecting the upper ends of the triangular unit truss segments are installed, and the upper chords and the upper ends of the triangular unit truss segments are assembled with connecting steel plates and connecting bolts.
An improved truss girder bridge structure using triangular unit truss segments. In claim 3,
The transverse connection assembly of the multiple-column truss girders installed on both the left and right sides is characterized by installing a gap-maintaining lower chord between the lower chords of the multiple-column truss girders and fastening them with bolts to the lower chords on both sides, and installing a gap-maintaining upper chord between the upper chords of the multiple-column truss girders and fastening them with bolts to the upper chords on both sides.
An improved truss girder bridge structure using triangular unit truss segments. A two-stage truss girder in which triangular unit truss segments including lower chords and saddles and inverted triangular unit truss segments including upper chords and saddles are connected and assembled vertically and then connected and assembled longitudinally (front-backward, axial direction) and then installed one on each of the left and right sides;
T-shaped crossbeams whose ends are connected to the two-stage truss girders on both left and right sides by a connecting structure;
Includes steel decks or concrete decks installed between the two-stage truss girders on both the left and right sides and on the upper side of the crossbeams;
The above-mentioned connecting structure includes a triangular vertical bracket connected to the lower side of the triangular unit truss segment, a horizontal bracket connected to the upper side of the triangular vertical bracket and the beam of the triangular unit truss segment, a connecting steel plate installed on the upper surface of the flange of the T-shaped crossbeam, a first connecting bolt connecting the front and rear vertical brackets and the abdomen of the T-shaped crossbeam sandwiched therebetween, a second connecting bolt connecting the flange of the T-shaped crossbeam and the connecting steel plate, and a third connecting bolt connecting the front and rear ends of the connecting steel plate and the horizontal bracket.
The above triangular vertical bracket includes a pair of flange brackets connected to the lower sides of both flanges of the triangular unit truss segment, and a plate-shaped connecting bracket connected to the ends of the pair of flange brackets.
The above first connecting bolt connects the abdomen of the T-shaped crossbeam and the connecting brackets of the front and rear triangular vertical brackets while the abdomen of the T-shaped crossbeam is inserted between the connecting brackets of the front and rear triangular vertical brackets,
The above horizontal bracket is connected between a pair of flanges of the beam of the above triangular unit truss segment,
The third connecting bolt is characterized in that it is connected in a state where the front and rear ends of the connecting steel plate overlap the upper side of the horizontal bracket.
An improved truss girder bridge structure using triangular unit truss segments. In claim 6,
The upper and lower connection assembly of the above triangle unit truss segments and the inverted triangle unit truss segments is performed by inserting a connecting H-shaped steel between the opposing vertices of the above triangle unit truss segments and the inverted triangle unit truss segments, and then assembling them with a connecting steel plate and a connecting bolt.
The longitudinal connection assembly of the above triangle unit truss segments and the inverse triangle unit truss segments is characterized in that the lower chords of the front and rear triangle unit truss segments are installed so that they are in contact with each other, the lower chords of the front and rear triangle unit truss segments are assembled with connecting steel plates and connecting bolts, and the upper chords of the inverse triangle unit truss segments are installed so that they are in contact with each other, and the upper chords of the front and rear triangle unit truss segments are assembled with connecting steel plates and connecting bolts.
An improved truss girder bridge structure using triangular unit truss segments. A two-stage truss girder with multiple columns installed on each side, in which triangular unit truss segments including lower chords and saddles and inverted triangular unit truss segments including upper chords and saddles are connected and assembled vertically and in the longitudinal direction (front-backward direction, axial direction) at the same time;
T-shaped crossbeams connected to the two-stage truss girders on both sides by a joint structure at both ends;
Includes steel decks or concrete decks installed between the two-stage truss girders on both the left and right sides and on the upper side of the crossbeams;
The above-described connecting structure includes a plurality of triangular vertical brackets connected to the lower sides of the plurality of triangular unit truss segments, a plurality of horizontal brackets connected to the upper sides of the plurality of triangular vertical brackets and to the beams of the plurality of triangular unit truss segments, a plurality of connecting steel plates installed on the upper surface of the flange of the T-shaped crossbeam, a first connecting bolt connecting the plurality of front and rear vertical brackets and the abdomen of the T-shaped crossbeam sandwiched therebetween, a second connecting bolt connecting the flange of the T-shaped crossbeam and the plurality of connecting steel plates, and a third connecting bolt connecting the front and rear ends of the plurality of connecting steel plates and the plurality of horizontal brackets.
The above triangular vertical bracket includes a pair of flange brackets connected to the lower sides of both flanges of the triangular unit truss segment, and a plate-shaped connecting bracket connected to the ends of the pair of flange brackets.
The above first connecting bolt connects the abdomen of the T-shaped crossbeam and the connecting brackets of the front and rear triangular vertical brackets while the abdomen of the T-shaped crossbeam is inserted between the connecting brackets of the front and rear triangular vertical brackets,
The above horizontal bracket is connected between a pair of flanges of the beam of the above triangular unit truss segment,
The third connecting bolt is characterized in that it is connected in a state where the front and rear ends of the connecting steel plate overlap the upper side of the horizontal bracket.
An improved truss girder bridge structure using triangular unit truss segments. In claim 8,
The upper and lower connection assembly of the above triangle unit truss segments and the inverted triangle unit truss segments is performed by inserting a connecting H-shaped steel between the opposing vertices of the above triangle unit truss segments and the inverted triangle unit truss segments, and then assembling them with a connecting steel plate and a connecting bolt.
The longitudinal connection assembly of the above triangle unit truss segments and the inverse triangle unit truss segments is characterized in that the lower chords of the front and rear triangle unit truss segments are installed so that they are in contact with each other, the lower chords of the front and rear triangle unit truss segments are assembled with connecting steel plates and connecting bolts, and the upper chords of the inverse triangle unit truss segments are installed so that they are in contact with each other, and the upper chords of the front and rear triangle unit truss segments are assembled with connecting steel plates and connecting bolts.
An improved truss girder bridge structure using triangular unit truss segments. In claim 8,
The horizontal connection assembly of the above-mentioned two-stage truss girders, each installed on both left and right sides, is characterized in that a gap-maintaining lower chord is installed between the lower chords of the above-mentioned two-stage truss girders and is fastened with bolts to the lower chords on both sides, a gap-maintaining upper chord is installed between the upper chords of the above-mentioned two-stage truss girders and is fastened with bolts to the upper chords on both sides, and a gap-maintaining connecting member is installed in the center of the above-mentioned two-stage truss girders and is fastened with bolts.
An improved truss girder bridge structure using triangular unit truss segments. In any one of claims 1 to 10,
The above T-shaped cross-section is characterized in that the central part, excluding the two ends where the above-mentioned connecting structure is connected, is an I-shaped or H-shaped part with a lower flange.
An improved truss girder bridge structure using triangular unit truss segments.