KR101989004B1 - Double composite girder for bridge - Google Patents

Abstract

The present invention relates to a double composite girder for a bridge which can maximize structural support effects. The double composite girder (A) for a bridge comprises: a steel box (10) of a rectangular container shape filled with concrete (C); a lower flange (30) below the steel box (10) in a longitudinal direction of the steel box (10); and a web (20) arranged between the steel box (10) and the lower flange (30), wherein a top surface thereof is formed in curvature corresponding to a bottom surface of the steel box (10) to connect the steel box (10) and the lower flange (30) to be longitudinally installed on a center of an upper surface of the lower flange (30). The double composite girder further comprises: a center span unit (100) formed between two adjacent bridge posts or between an abutment and a bridge post; and a point span unit (200) formed on a point of the bridge post or the abutment to be connected to the span unit (100). The center span unit (100) is divided into a first filling section (X) where concrete is filled from an arch-shaped bottom unit (121) to an upper flange (110a, 110b) and a second filling section (Y) where concrete is filled from the arch-shaped bottom unit (121) to a prescribed height. The first and the second filling section (X, Y) are divided by a blocking plate (140). The concrete filling amounts of the first and the second filling section (X, Y) are different.

Description

Double composite girder for bridge}

The present invention relates to a double composite girder for bridges, and in particular, includes a steel box that can be filled with concrete, a web formed perpendicularly to the bottom surface of the steel box, and a lower flange formed perpendicular to the bottom of the web. The invention relates to a double composite girder for bridges.

In general, a bridge refers to an expensive structure that is constructed to cross rivers, lakes, straits, bays, canals, or other traffic or structures. Such bridges are classified into various types according to materials, structures, or manufacturing methods, and recently, girder bridges having excellent construction, maintenance, and strength have been constructed. Recently, many composite girders are used to form girders through the synthesis of steel and concrete, and these composite girders can be subdivided into steel box and plate structures.

Among them, the composite girders using the steel box structure, in which the number of application cases is increasing, are combined with the steel girders and the concrete filled therein to be integrated with each other so that the concrete functions as a compression material of the steel girders. According to the composite girder of the steel box structure, the compression part of the girder can minimize the use of steel materials by utilizing the concrete with the low cost of materials, thereby efficiently supporting the compressive stress, and in the tension section of the girder Efficiently support tensile stress using steel materials.

That is, in the composite girder of the steel box structure, the characteristics and advantages of each material can be utilized in correspondence with the kind of force acting on the girder. However, the weight of the steel girders is increased due to the weight of concrete filled inside the box-shaped steel girders, and accordingly, webs and lower flanges that structurally support the steel girders have a disadvantage of being expensive due to the large amount of expensive steel requirements. .

Republic of Korea Patent No. 10-0950027 (2010.03.22)

Thus, in order to solve the above problems, the present invention partitions the inside of the box-shaped steel girders into several sections according to moments, filling a relatively small amount of concrete in the constant moment sections, and relatively in the parent section sections. Filling a large amount of concrete, by forming a different amount and height of the concrete to be filled in accordance with the moment of the girder to provide a composite girder for the bridge that can maximize the structural support effect while minimizing the increase in the weight of the girder according to the concrete.

The present invention for achieving the above object is provided with a rectangular container-shaped steel box 10 is filled with concrete (C) therein, the steel material along the longitudinal direction of the steel box 10 A lower flange 30 is provided below the box 10, and the web 20 is connected between the steel box 10 and the lower flange 30 so that the steel box 10 and the lower flange 30 are connected to each other. Is provided, the upper surface of the web 20 corresponds to the lower surface of the steel box 10, the lower surface of the web 20 is installed in the longitudinal direction in the center of the upper surface of the lower flange (30) In the double composite girder (A) for the losing bridge,

The double composite girder is a central span portion 100 formed between two adjacent piers or between an alternating and piers and a point span portion 200 formed on a point of the piers or alternates and connected to the central span portion 100. The steel box 10 is provided with upper flanges 110a and 110b on the left and right sides in the longitudinal direction, and a U-shaped box 120 is provided below the upper flanges 110a and 110b. The U-shaped box 120 has an arcuate bottom portion 121 and the arcuate shape which are adjacent to the upper flanges 110a and 110b toward the center of the center span portion 100 from the point span portion 200 to the bottom surface thereof. Arched side portions 122a and 122b connecting the arcuate bottom portion 121 and the upper flanges 110a and 110b are formed at left and right sides of the bottom portion 121, and the arcuate shape is formed inside the U-shaped box 120. The side portions 122a and 122b are connected to each other to form the arcuate shape by external force. In order to prevent the bottom portion 121 from being deformed in the direction of gravity, at least one shape retaining material 300 is provided at a predetermined interval, and the center span portion 100 is from the arcuate bottom portion 121 to the upper flange. The first charging section (X) to be filled with concrete up to (110a, 110b) and the second charging section is filled with concrete from the arcuate bottom portion 121 to a predetermined height on both sides in the longitudinal direction of the first charging section (X) It is divided into (Y), the cross-sectional thickness of the concrete is filled in the second charging section (Y) becomes thicker toward the point span section 200 from the central span section 100, the first charging section ( X) and the second charging section (Y) is partitioned by the blocking plate 140 so that the concrete on the first charging section (X) side of the second charging section (Y) concrete around the blocking plate 140 Highly charged, the concrete and the point span portion of the second charging section (Y) The center span portion 100 and the point span portion 200 are partitioned by an inner finish plate 130a formed at a predetermined height on an area where 200 meets each other, and ends of the second charging section Y. It is provided with a web closing plate (130b) formed in the vertical direction to connect the end of the arcuate bottom portion 121 and the lower flange 30, the point span portion plate (top) 210 is provided and is connected to the upper flanges (110a, 110b), and the left and right of the point span portion 200 is provided with a point span side portion (222a, 222b) connected to the arcuate side (122a, 122b) The lower flange 30 is provided at the lower end of the point span part 200 to connect the web dead plate 130b and the lower flange 30 to both ends of the steel box 10 in the longitudinal direction. Point span section closing plate 230 or the diaphragm 180 is provided to the left and right point span section Is connected to the parts (222a, 222b), the point span portion 200 is formed inside the point span portion 220, the concrete filled in the point span portion 220 is the point span portion finish plate ( It is filled so as to correspond to the height of the inner finishing plate 130a installed inside the 230, the horizontal reinforcing material 500c of the wing shape in a portion of the center span portion 100 along the longitudinal direction on the outside of the web 20 It provides a double composite girders for bridges, characterized in that is formed in a curved form.

In addition, a stopper 150 is formed on an inner surface of the arcuate side portions 122a and 122b of the second charging section Y so as to be spaced apart from the arcuate bottom portion 121 by a predetermined height, and the arcuate bottom portion 121 is formed. Concrete is filled between the stoppers 150, and a central span space 190 is formed between the stoppers 150 and the upper flanges 110a and 110b of the second charging section Y. It provides a double composite girder for bridges.

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In addition, at least one vertical reinforcing material (400a, 400b) is provided on the inner surface of the arcuate side portions (122a, 122b) of the inner left and right of the U-shaped box 120, the double composite girders for bridges to provide.

In addition, the arcuate bottom portion 121 is provided with a shear connector 160 at a predetermined interval, the reinforcing wire mesh (top) in the upper portion of the shear connector 160 of the arcuate bottom portion 121 of the first charging section (X) ( 170 is provided, and the second charging section (Y) and the double connection girder for the bridge, characterized in that the reinforcing bar 171 is provided on the upper portion of the shear connection member 160 of the point span section 200. do.

In addition, the wing-shaped horizontal reinforcement (500a, 500b) is provided on the inner side of the arcuate side portions (122a, 122b) along a portion of the center span portion 100 and the longitudinal span of the point span portion (200). A double composite girder for bridges is provided.

In addition, a diaphragm 180 is formed at predetermined intervals in the point span portion space 220 and the second charging section Y, and a portion of the diaphragm 180 is located between the point span portion space 220 and the space. Openings 182 connecting the inside of the second charging section Y are formed, and the upper flanges 110a and 110b on the left and right sides are formed on an upper portion of the diaphragm 180 formed in the second charging section Y. It provides a double composite girders for bridges, characterized in that the upper connecting plate 181 is connected to each other.

In addition, the bottom surface of the lower flange 30 provided in the point span section 200 provides a double composite girder for bridges, characterized in that the sole plate 250 is provided.

In addition, the filling height (H1) of the concrete filled in the both ends of the central span portion 100 is a double composite girder for bridges, characterized in that lower than the concrete filling height (H2) in the interior point space 220. To provide.

In addition, the lower flange 30 provides a double composite girder for bridges, characterized in that the width W1 of the central span 100 is narrower than the width W2 of the point span 200. .

In addition, when the double composite girder is provided in a single span, the lower flange 30 in the single span has a thickness T1 of the central span 100 and the thickness T2 of the point span 200. It provides a double composite girders for bridges, characterized in that formed thicker than).

Through the above problem solving means, the present invention provides the following effects.

According to the present invention, while reducing the amount of concrete used in the composite girder, by filling a relatively large amount of concrete in the parent section, it is possible to increase the structural stability.

In addition, the compressive force can be distributed to both ends in the longitudinal direction based on the shape of the arcuate bottom to effectively reduce the generation of bending moment and shear force acting on the composite girder.

In addition, according to the present invention, since the maintenance personnel can be introduced into the interior of the girder through the point span portion, it can be made easier to maintain, repair and management than the conventional synthetic girder.

In addition, according to the present invention, since the total amount of steel required compared to the structure of a general composite girder is reduced, the material cost required for construction can be reduced to ensure economic feasibility.

In addition, according to the present invention, by installing a wing-shaped curved horizontal reinforcement having a predetermined width on the inside of the steel box and / or the outer surface of the web, the effective buckling length of the side of the steel box and the web is reduced to the external force Structural support performance can be improved.

1 is a perspective view schematically showing a double composite girder for a bridge according to an embodiment.
Figure 2a is an enlarged front view showing a portion of the double composite girder for bridges installed adjacent to the alternating according to an embodiment.
Figure 2b is an enlarged front view showing a portion installed adjacent to the pier of the double composite girder for bridges according to an embodiment.
3 is a perspective view showing a steel box and its internal configuration, the web and the lower flange according to an embodiment.
4 is a cross-sectional view showing the outermost cross section of the girder as a cross section of the line II ′ of FIG. 2A.
FIG. 5 is a cross-sectional view illustrating a boundary surface of the point span section and the center span section as a cross-sectional view taken along the line II-II ′ of FIG. 2B.
6 is a cross-sectional view taken along line III-III ′ of FIG. 2B.
FIG. 7A is a cross-sectional view taken along the line IV-IV ′ of FIG. 2B, and is a cross-sectional view of one point where a diaphragm is formed in the second charging section.
FIG. 7B is a plan view of one point where the diaphragm according to FIG. 7A is formed.
(A), (b), and (c) of FIG. 8 are cross-sectional views showing cross-sections of lines V-V ', VI-VI', and VIII-VIII 'of FIG. 2B, respectively.
9 is a perspective view showing a lower flange shape according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be construed as being limited to the following embodiments. This embodiment is provided to more completely explain the present invention to those skilled in the art.

In the drawings, parts irrelevant to the description are omitted to clearly describe the proposed invention, and like reference numerals denote like elements or parts throughout the specification. In addition, when a part "contains" a certain component, this means that the component may further include other components, without excluding other components, unless specifically stated otherwise. Furthermore, when the same component is provided at the left, right and / or up and down, respectively, it can be distinguished by attaching alphabetical codes (eg, 10a and 10b) from the left and the upper side.

In addition, the terms "... unit", "... unit", "... module", and the like described in the specification mean a unit for processing at least one function or operation, which means hardware or software or hardware and It can be implemented in a combination of software.

In each step, an identification code (first, second, etc.) is used for convenience of description, and the identification code does not describe the order of each step, and each step does not explicitly describe a specific order in context. It may be carried out in a different order than described above. That is, each step may be performed in the same order as specified, may be performed substantially simultaneously, or may be performed in the reverse order.

1 is a perspective view schematically showing a double composite girder for a bridge according to an embodiment. According to Figure 1 in the double composite girder for bridges according to an embodiment of the rectangular container-shaped steel box 10 is filled with concrete (C) therein, the steel box 10 along the longitudinal direction of the steel box 10 A lower flange 30 is provided below, and a web 20 including a curved horizontal reinforcement 500c is provided between the steel box 10 and the lower flange 30 so that the steel box 10 and the lower flange are provided. 30 can be connected. The arcuate bottom portion 121, which is the bottom of the steel box 10, may be formed as a curved surface, as described below. Accordingly, the top surface of the web 20 may be formed in a curve corresponding to the arcuate bottom portion 121. . In addition, according to FIG. 1, the double composite girder for bridges according to the present invention includes a central span portion 100 formed between two adjacent piers or between a bridge and a bridge and a point span portion 200 formed on a point of a bridge or an alternating bridge. Can be distinguished. That is, in the present invention, the area that is placed on the point of the bridge or the alternating means the point span portion 200, the area floating in the air may mean the center span portion (100).

In addition, the central span 100 according to an embodiment may be divided into a first charging section (X) and a second charging section (Y) to the extent that the concrete is filled. Specifically, the center span 100 of the present invention is the first filling section (X) that is filled with concrete from the arched bottom portion 121 to the upper flange (110a, 110b), and the concrete from the arched bottom portion 121 It may be divided into a second charging section (Y) that is charged only up to a certain height.

On the other hand, the steel box 10 may be provided with upper flanges (110a, 110b) on the upper left and right sides, respectively. The upper flanges 110a and 110b according to an embodiment of the present invention may be formed to protrude a predetermined distance from the side of the steel box 10 to the left and right. The upper flanges 110a and 110b may be connected to the point span upper plate 210 extending from the center span 100 to cover the top surface of the point span 200. Specifically, the point span portion closing plate 230 may be formed on the side end portion of the point span portion 200 formed on the alternating portion. Currently, the perspective view shown in FIG. 1 is a view showing a point span portion finishing plate 230 is provided. The diaphragm 180 may be provided in the girder inner space at a predetermined distance interval, as described below. In this regard, the diaphragm referred to in the present invention is to be disposed at right angles to the member axis inside the steel box in order to maintain the shape of the closed cross-section member in the steel box, to prevent buckling of each member subjected to bending, and to increase the rigidity against torsion It may be formed into a plate-shaped partition wall.

Figure 2a is a cross-sectional view showing a part of the girder which is installed adjacent to the upper portion of the double composite girders for bridges according to the present invention. Further, Figure 2b is a cross-sectional view showing a part of the girder installed adjacent to the bridge in the double composite girders for bridges according to the present invention. According to an embodiment of the present invention, the girder provided between the alternating portion and the piers may have one end portion in the shape according to FIG. 2A and the other end portion in the shape according to FIG. 2B. According to another embodiment of the present invention, the girder provided between the piers and the piers are provided in both sides of the shape as shown in Figure 2b, it may be provided in a symmetrical shape with respect to the center point in the longitudinal direction. Therefore, the following description can be applied to both ends of the girder.

2A and 2B, the lower flange 30 may be formed over the center span portion 100 and the point span portion 200. In detail, the lower flange 30 may be formed in the form of FIG. 9 to be described later, and may form a lower surface of the point span portion 200 and a lower surface of the central span portion 100.

Also, referring to FIGS. 2A and 2B, the first charging section X and the second charging section Y of the central spanning part 100 may be partitioned by the blocking plate 140. That is, the blocking plate 140 is formed at the end of the first charging section (X) in a plane perpendicular to the longitudinal direction to block the side of the first charging section (X), thereby filling the first charging section (X). The concrete may be prevented from flowing to the point span portion 200 side. Furthermore, in the region where the second charging section (Y) and the point span section 200 meet, an internal finishing plate (130a) and a web finishing plate (130b) are provided, respectively, so that the flow of concrete filled in the second charging section (Y). Can be prevented. In detail, at the end of the second charging section (Y) may be provided with an internal finish plate 130a of a predetermined height on the top of the filled concrete. That is, the inner finish plate 130a is provided with a predetermined height on the interface between the central spanning portion 100 and the point spanning portion 200, and may divide the central spanning portion 100 and the point spanning portion 200. have. In addition, the height of the concrete filled in the point span portion 200 may be different from the height of the concrete filled in the second charging section (Y). Preferably, the point span portion 200 may be filled with concrete up to the height of the inner finish plate (130a) is formed. 2A and 2B, a web finishing plate 130b may be provided between the web 20 and the point span part 200. The upper end of the web finish plate 130b is connected to the end of the arcuate bottom portion 121 extending from the center span portion 100 to the point span portion 200, and the lower end of the web finish plate 130b is the point span portion ( It may be connected to the lower flange 30 of the 200. In addition, the point span portion 200 side of the web finish plate 130b is exposed to the concrete filled into the point span portion 200, the web 20 may be connected to the center of the opposite side.

In addition, as illustrated in FIGS. 2A and 2B, the point span end plate 230 or the diaphragm 180 may be provided at both ends of the steel box 10 in the longitudinal direction. Wherein the point span portion finishing plate 230 is a member that does not function as a structural member, the diaphragm 180 is a member that is located on the pier or alternating point 600 to function as a structural member.

Accordingly, the outermost end portion of the girder A mounted on the alternating girder A as shown in FIG. 2A is provided with a point span portion finishing plate 230, and as shown in FIG. 2B, on the point 600 of the pier. A diaphragm 180 may be provided at the outermost end of the girder A located.

3 is a perspective view showing the detailed configuration of the steel box 10, the web 20 and the lower flange 30 according to an embodiment of the present invention. According to FIG. 3, the steel box 10 has arched bottom portions 121a and 122b formed on the left and right sides of the arcuate bottom portion 121 and the arcuate bottom portion 121, respectively, and the left and right arched side portions 122a and 122b. ) May include upper flanges 110a and 110b respectively formed on the upper flanges. Preferably, a longitudinal center line of the upper flanges 110a and 110b may be disposed on the arcuate side portions 122a and 122b. That is, the steel box 10 may be formed as a U-shaped U-shaped box 120 by the arcuate bottom portion 121 and the arcuate side portions 122a and 122b formed on the left and right sides of the arcuate bottom portion 121. Furthermore, the arcuate bottom portion 121 forming the bottom of the U-shaped box 120 may be formed in a curved surface along the longitudinal direction. Preferably, the U-shaped box 120 may be provided with an arcuate bottom portion 121 formed in a curved surface at the lower portion of the upper flange (110a, 110b) formed in a straight line along the longitudinal direction, left and right of the arcuate bottom portion 121 An arcuate side portion (122a, 122b) is provided in the can be connected to the upper flange (110a, 110b). Therefore, the arcuate side portions 122a and 122b may decrease in height from the point span portion 200 toward the center span portion 100.

According to one embodiment of the invention, as shown in Figure 1, the upper end of the arcuate side (122a, 122b) is formed in a straight line and the lower end is formed in a curve, the arcuate side (122a, 122b) has a height at the center thereof It can be the smallest. That is, the arched bottom portion 121 and the upper flanges (110a, 110b) may be closer to the center span portion 100 from the point span portion 200, the U-shaped box ( The depth of 120 may be formed shallowest. The stopper 150 may be selectively provided inside the U-shaped box 120. Preferably, the stopper 150 may be provided in the U-shaped box 120 formed in the second charging section Y of the central span 100, and the U-shaped box of the first charging section X may be provided. The stopper 150 may not be provided at the 120. The stopper 150 may be formed to be spaced apart from the arcuate bottom portion 121 by a predetermined height, and may be formed in a wing shape having a predetermined length on each of the left and right arcuate side portions 122a and 122b. The stopper 150 is configured to adjust the filling amount of the concrete filling into the U-shaped box 120, when the stopper 150 is provided, the concrete is formed with a stopper 150 in the U-shaped box 120 It can only be filled up to height. Therefore, in the second charging section (Y), concrete is formed only up to the height of the stopper 150, in the second charging section (Y) between the stopper 150 and the upper flange (110a, 110b) 'center span space 190 An empty space called ')' may be formed. In addition, the shape-retaining material 300 may be provided at a predetermined interval in the shape of connecting the arcuate side portions 122a and 122b formed at the left and right sides of the U-shaped box 120. Preferably, the shape maintaining material 300 may be formed in the arcuate bottom portion 121, may be formed spaced apart from the arcuate bottom portion 121 by a predetermined distance. The shape maintaining member 300 may be formed to prevent the arcuate bottom portion 121 or the arcuate side portions 122a and 122b from being deformed by an external force. According to one embodiment, when the girders pre-fabricated to a predetermined length moves to the construction site, the arched bottom portion 121 or the arched side portions 122a and 122b are prevented from being deformed by gravity. Preferably, the shape-retaining material 300 may be formed at both ends of the girders made in advance, and further include a surface having a '-' shape or a vertical surface including a surface parallel to the arcuate bottom portion 121. The cross section may be formed to have a 'ㅗ' or 'b' shape.

In addition, inside the U-shaped box 120, a horizontal reinforcing member for preventing deformation of the arched side portions 122a and 122b together with the shape retaining material 300 may be provided at the left and right arched side portions 122a and 122b, respectively. have. The horizontal reinforcement may be formed to protrude in a wing shape on the arcuate side portions 122a and 122b spaced apart from the arcuate bottom portion 121 by a predetermined distance in the U-shaped box 120.

Preferably, the horizontal reinforcing material may be formed between the stopper 150 and the upper flanges 110a and 110b at regular intervals along the direction of gravity. 1, 2A and 2B, the horizontal reinforcing material according to an embodiment of the present invention may be formed on the left and right inside of the U-shaped box 120 in some section of the central span 100. In addition, the horizontal reinforcing material may extend to the point span portion 200 may be formed on the left and right inside of the point span portion side portion (222a, 222b), respectively. Furthermore, this horizontal retaining material may be formed in a curve along the longitudinal direction on the outside of the web (20). Specifically, in some sections of the center span 100, the horizontal reinforcing material (500c) on the outside of the web 20 may be formed in a curved shape spaced apart from the lower flange 30 by a predetermined distance.

On the other hand, the U-shaped box 120 formed in the center span portion 100 is connected to the point span portion 200 at its end. In detail, the arcuate bottom portion 121 of the U-shaped box 120 is connected to the web closing plate 130b as described above, and the arcuate side portions 122a and 122b of the U-shaped box 120 are the point span portion 200. It is connected with the point span side portion 222a, 222b constituting the side of the. That is, the point span section 200 is a point span upper plate 210 and the lower flange 30, respectively formed on the top and bottom, the point span side portions 222a and 222b respectively formed on the left and right in the longitudinal direction and the girder longitudinal direction Each of the outermost ends of the point span portion finishing plates 230 is finished, and the point span portion 220 may be formed inside the point span portion 200. Furthermore, since the inner finish plate 130a is not formed to the heights of the upper flanges 110a and 110b, the point span space 220 and the central space subspace inside the second charging section Y may be connected to each other.

4 to 8 are cross-sectional views of the double composite girders for bridges at a predetermined position. 4 to 8, at least one shear connecting member 160 may be formed in common. According to an embodiment of the present invention, the shear connector 160 is configured to hold concrete flowing in the steel, and a rebar 171 and / or a reinforcing wire mesh 170 may be further provided thereon. . Preferably, in the first charging section X of the center span 100, a plurality of shear connecting members 160 may be selectively provided on the arcuate bottom portion 121 and / or the arcuate side portions 122a and 122b. The reinforcing wire mesh 170 may be provided at an upper portion of the arcuate bottom portion 121. The lower flange 30 and the branch span side portions 222a and 222b of the second charging section Y and the point span portion 200 may be selectively provided with a plurality of shear connecting members 160 and the lower flange 30. Reinforcement bar 171 may be provided at the top. 4 is a cross-sectional view taken along line II ′ of FIG. 2A. As described above, the point span portion finishing plate 230 may be provided at the outermost end of the point span portion 200 formed on the shift. The point span section closing plate 230 forms a point span space 220 together with the point span side parts 222a and 222b connected to the left and right sides, and the concrete filled to the point span space 220 to a predetermined height. Can prevent flow. In addition, in FIG. 4, a sole plate 250 formed of a material such as steel sheet may be provided under the lower flange 30 to uniformly apply a load acting on the girder support. As the girder is placed on the alternating or pier, the soleplate 250 may contact the point 600. In addition, as described above in FIG. 4, horizontal reinforcing members 500a and 500b may be formed at the left and right arcuate side portions 122a and 122b and the point span portion side portions 222a and 222b, and specifically, the second charging section Y. And at least one horizontal reinforcing material 500b may be provided at the point span part 200. In addition, the horizontal reinforcement (500b) may be formed in a wing shape having a predetermined length on the arcuate side portion (122a, 122b) and the point span portion side portion (222a, 222b) of the upper portion of the concrete filled area. In addition, Figure 4 shows that the horizontal reinforcing material (500b) is formed in each of the upper, lower, left, right, a total of four are formed, but in order to secure additional structural stability in the alternating section of the girder in which the tension and compression is repeated as described above In order to provide at least four or more horizontal reinforcement (500b), if the girder height is low, four or less horizontal reinforcement (500a, 500b) may be installed. Preferably, the alternating section according to an embodiment may be part of the second charging section (Y).

FIG. 5 is a cross-sectional view of the U-shaped box 120 viewed from II-II 'of FIG. 2B. That is, FIG. 5 is a diagram illustrating a cross section of an interface between the point span portion 200 and the center span portion 100. Referring to FIG. 5, vertical reinforcing members 400a and 400b may be provided at predetermined intervals in the arcuate side portions 122a and 122b at one point of the U-shaped box 120. Vertical reinforcement (400a, 400b) is formed in a plate shape having a predetermined width may be provided on the arcuate side (122a, 122b), the upper portion is connected to the upper flange (110a, 110b), the lower portion of the inner finishing plate ( 130a) may be formed to reach a point higher than the formed height. Preferably, the lower portion of the vertical reinforcement (400a, 400b) may be formed in a downward oblique shape toward the arcuate side portions (122a, 122b) from the center span portion space 190.

6 is a cross-sectional view taken along the line III-III 'of FIG. 2B. According to FIG. 6, the second charging section Y may be provided with a central span space 190 and a stopper 150, and concrete may be filled between the stopper 150 and the arcuate bottom 121. According to one embodiment of the present invention, the concrete filled in the second charging section (Y) may be filled between the stopper 150 and the arcuate bottom portion 121, the filling thickness may be formed to a certain height. . In addition, according to another embodiment of the present invention, the cross-sectional thickness of the concrete filled in the second charging section (Y) may be thicker toward the point span section 200 from the center span section (100). However, in this case, it should be noted that the filling height (H1) of the concrete filled in the both ends of the center span portion 100 is lower than the height (H2) of the concrete filled in the point span space (220). That is, the concrete filled in the second charging section (Y) may be filled to a height lower than the height of the inner finish plate.

FIG. 7A is a cross-sectional view of IV-IV ′, which is a point at which the diaphragm 180 is formed in the center span space 190 of the second charging section Y, and the point span space 220 and the second charge as described above. The diaphragm 180 may be provided at a predetermined distance over the center span space 190 of the section Y. According to FIG. 7A, a portion of the diaphragm 180 may be connected to the left and right spaces of the diaphragm 180 to form an opening 182 through which an operator can enter and exit. Preferably, the opening 182 having a width and a height of a predetermined length is formed in the center of the diaphragm 180, so that the worker has a center diameter of the second filling section Y from the point span space 220 to the inside of the girder. The executive space 190 may be moved. Furthermore, FIG. 7B is a plan view of an arbitrary point at which the diaphragm 180 is located, and an upper connection plate 181 is provided at the upper end of the diaphragm 180 to connect the left and right upper flanges 110a and 110b to each other. Can be. Preferably, the center of the upper connecting plate 181 may be formed on the diaphragm 180, and the left and right sides of the upper connecting plate 181 may be connected to the upper flanges 110a and 110b, respectively.

FIG. 8 is a diagram illustrating cross sections of the first charging section X in the central span 100. In detail, (a), (b), and (c) of FIG. 8 are cross-sectional views taken along lines V-V ', VI-VI', and VIII-VIII 'of FIG. 2B, respectively. First, in FIG. 8, the horizontal reinforcement material 500c may be formed on the outer circumferential surface of the web 20 in common. The horizontal reinforcement material 500c may be formed to extend in the longitudinal direction on one side of the outer circumferential surface of the web 20, and may be formed in a wing shape having a predetermined width. Preferably, the plate-shaped horizontal reinforcement (500c) may be formed in an arc shape. Furthermore, according to (a) and (b) of FIG. 8, the horizontal reinforcing material 500a may be provided inside the arcuate side portions 122a and 122b of the first charging section X. However, referring to FIG. 8 (c), the first filled is thinned in the section where the arcuate side portions 122a and 122b and the upper flanges 110a and 110b are closer, that is, near the center of the girder. The horizontal reinforcing material 500a formed in the section X may be selectively provided and may be formed to be buried.

In addition, it may be formed continuously with the horizontal reinforcing material (500b) formed in the second charging section (Y), or may be intermittently formed only in the first charging section (X).

9 is a view showing the shape of the lower flange 30 according to another embodiment of the present invention. Referring to FIG. 9, the lower flange 30 may have a width W1 of the center span portion 100 narrower than a width W2 of the point span portion 200. In addition, when the double composite girder is formed of a single span, the lower flange 30 of the single span may have a thickness T1 of the center span 100 to be thicker than the thickness T2 of the point span 200. Can be. Accordingly, even when a tensile force is applied to the lower flange, it is possible to secure a structure that the lower flange can cope by increasing the thickness instead of reducing the width.

In summary, the core idea of the present invention is that the concrete filled in the steel box is charged differently from each other over the point span portion, the first charging section (X) and the second charging section (Y) to reduce the weight of the girder It is characterized in that the structural stability can be secured against external forces and moments. In particular, the first filling section (X) of the central span portion is filled with all the concrete up to the height of the upper flange is formed, in the second filling section (Y) is filled with concrete only by a certain height from the arched bottom portion is filled into the girder. It should be noted that it is a feature and unique effect of the present invention that the structural stability can be secured while reducing the amount of concrete, and thus the amount of concrete and steel used can be reduced to increase the economic efficiency.

In addition, although embodiments of the present invention have been described and described, those of ordinary skill in the art may add, change, delete, or add to the elements within the scope not departing from the spirit of the present invention described in the claims. The present invention may be modified and modified by various additions and the like, which will also be included within the scope of the present invention.

Furthermore, in describing the embodiments of the present invention, when it is determined that a detailed description of a known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. The terms used above are terms defined in consideration of functions in the embodiments of the present invention, which may vary according to the intention or custom of the user or operator. Therefore, the definition should be made based on the contents throughout the specification. Accordingly, the above detailed description is not intended to limit the invention to the disclosed embodiments, and the appended claims should be construed as including other embodiments.

10: steel box 20: web
30: lower flange 100: center span portion
110a, 110b: Upper flange 120: U-shaped box
121: arcuate bottom 122a, 122b: arcuate side
130a: internal finish plate 130b: web finish plate
140: blocking plate 150: stopper
160: shear connector 170: reinforcing wire mesh
171: rebar 180: diaphragm
181: upper connecting plate 182: opening
190: center span space 200: point span
210: branch span plate 220: branch span space
222a, 222b: point span portion side 230: point span portion finish plate
250: sole plate 300: shape retaining material
400a, 400b: Vertical stiffener 500a, 500b, 500c: Horizontal stiffener

Claims (11)

A rectangular container-shaped steel box 10 filled with concrete C is provided therein, and a lower flange 30 is provided below the steel box 10 along a length direction of the steel box 10. A web 20 is provided between the steel box 10 and the lower flange 30 so that the steel box 10 and the lower flange 30 are connected to each other, and an upper surface of the web 20 is formed of the steel. In the bridge double composite girders (A) corresponding to the bottom surface of the box 10, the bottom surface of the web 20 is provided in the longitudinal direction in the center of the upper surface of the lower flange (30),
The double composite girder is a central span portion 100 formed between two adjacent piers or between an alternating and piers and a point span portion 200 formed on a point of the piers or alternates and connected to the central span portion 100. The steel box 10 is provided with upper flanges 110a and 110b on the left and right sides in the longitudinal direction, and a U-shaped box 120 is provided below the upper flanges 110a and 110b. The U-shaped box 120 has an arcuate bottom portion 121 and the arcuate shape which are adjacent to the upper flanges 110a and 110b toward the center of the center span portion 100 from the point span portion 200 to the bottom surface thereof. Arched side portions 122a and 122b connecting the arcuate bottom portion 121 and the upper flanges 110a and 110b are formed on the left and right sides of the bottom portion 121. The side portions 122a and 122b are connected to each other to form the arcuate shape by external force. At least one shape retaining material 300 is provided at regular intervals to prevent the bottom portion 121 from being deformed in the direction of gravity.
The central spanning part 100 is provided at both sides of the first charging section X and the first charging section X in which the concrete is filled from the arcuate bottom part 121 to the upper flanges 110a and 110b. The second filling section (Y) is filled with concrete to the predetermined height from the arched bottom portion 121, the cross section thickness of the concrete is filled in the second charging section (Y) is the center span portion 100 From the point span portion 200 toward the thicker, the first charging section (X) and the second charging section (Y) is partitioned by the blocking plate 140 to the center around the blocking plate 140 The first charging section (X) side concrete is filled higher than the second charging section (Y) side concrete, and formed at a predetermined height on the area where the concrete of the second charging section (Y) and the point span portion 200 meet. The center span part 100 and the point span part 200 are formed by an inner finish plate 130a. The web finishing plate 130b is provided at the end of the second charging section (Y) in a vertical direction to connect the end of the arcuate bottom portion 121 and the lower flange 30, and the A point span upper plate 210 is provided at an upper end of the point span part 200 to be connected to the upper flanges 110a and 110b. Point span portion side portion (222a, 222b) to be connected is provided, the lower flange 30 is provided at the lower end of the point span portion 200 is connected to the web finishing plate (130b) and the lower flange (30) And, at both ends of the longitudinal direction of the steel box 10 is provided a point span portion closing plate 230 or a diaphragm 180 is connected to the left and right point span portion side portion (222a, 222b), the point diameter A point span part space 220 is formed inside the cavern 200, and the point span part space 220 is formed. The concrete to be filled is filled to correspond to the height of the inner finishing plate 130a installed inside the point span portion finishing plate 230, the center span portion 100 along the longitudinal direction on the outside of the web 20 Double composite girder for bridges, characterized in that the horizontal reinforcement (500c) of the wing shape is formed in a curved shape in a section. The stopper 150 is formed on an inner surface of the arcuate side portions 122a and 122b of the second charging section Y so as to be spaced apart from the arcuate bottom portion 121 by a predetermined height. Concrete is filled between the 121 and the stopper 150, and a central span space 190 is formed between the stopper 150 and the upper flanges 110a and 110b of the second charging section Y. Double composite girders for bridges, characterized in that formed. delete The bridge of claim 1, wherein at least one vertical reinforcement (400a, 400b) is provided on the inner side surfaces of the arcuate side portions (122a, 122b) inside and outside the U-shaped box (120) at regular intervals. Double composite girder. According to claim 1, wherein the arcuate bottom portion 121 is provided with a shear connector 160 at a predetermined interval, the upper portion of the shear connector 160 of the arcuate bottom portion 121 of the first charging section (X). It is provided with a reinforcing wire mesh 170, the reinforcing bars 171, characterized in that the reinforcing bar 171 is provided on the upper portion of the shear connection member 160 of the second charging section (Y) and the point span portion (200). Synthetic girder. According to claim 1, The horizontal reinforcing material (500a, 500b) of the wing shape in the inner portion of the arcuate side portion (122a, 122b) along the longitudinal direction of the section and the point span portion 200 of the central span portion (100) Double composite girders for bridges, characterized in that the provided. The diaphragm 180 is formed at predetermined intervals in the point span part space 220 and the second charging section Y, and the part of the diaphragm 180 has the point span part space. An opening 182 connecting the 220 and the inside of the second charging section Y is formed, and the upper flange 110a on the left and right sides of the diaphragm 180 formed in the second charging section Y is formed. Double bridge girder, characterized in that the upper connecting plate 181 is connected to each other, 110b. 2. The double composite girder for bridges according to claim 1, wherein a sole plate (250) is provided on a lower surface of the lower flange (30) provided in the point span part (200). According to claim 1, wherein the filling height (H1) of the concrete filled in the both ends of the center span portion 100 is a bridge, characterized in that lower than the concrete filling height (H2) in the point span portion space 220 Double composite girder. The double compound of claim 1, wherein the lower flange 30 has a width W1 of the center span portion 100 that is smaller than a width W2 of the point span portion 200. Girder. According to claim 1, Wherein the double composite girders are provided in a single span, the lower flange 30 in the single span has a thickness T1 of the center span portion 100 is the point span portion 200 Double composite girder for bridges, characterized in that formed thicker than the thickness (T2).

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