KR100948358B1 - Construction technique of steel box girder bridge and this - Google Patents

Abstract

PURPOSE: A steel box girder bridge and a construction method thereof are provided to reduce the use of steel through proper combination of high-strength concrete and steel according to compression and tensile stress. CONSTITUTION: A steel box girder bridge comprises a positive moment area(20) and a negative moment area(30). A part of the upper flange of the negative moment area is formed with a closed cross section(40), and the other part and the upper flange of the positive moment area are formed with an open cross section(50) in which a horizontal bracing of truss shape is attached. A deck slab(70) is prestressed and the lower flange of the negative moment area is combined with high-strength concrete(60).

Description

Steel box girder bridge and its construction method

The present invention relates to a steel box girder bridge and a construction method thereof, and in particular, only a predetermined section of the upper flange of the parent cement section is formed in the closed section, and the upper flange and the static moment of the parent cement section other than the upper flange of the closed section in the parent cement section. The upper flange of the section is formed by the opening section with truss-shaped horizontal bracing. The prestress is introduced into the upper slab slab of the parent cement section, and the high strength concrete is poured into a certain section of the lower flange of the parent cement section. The present invention relates to an economical steel box girder bridge and a construction method thereof.

In general, in the rectangular or formulation steel box girder bridge, the cross-sectional shape of the constant and parent cement sections consists of a closed cross-section consisting of two abdomen, upper and lower flanges.

As described above, the closed cross-section steel box girder bridge of the rectangular or formulation is only considering the convenience of manufacturing and assembling the steel box girder bridge rather than improving the economic efficiency by reducing unnecessary steel due to stress. Very serious situation.

That is, the upper flange of the constant moment section is a section subjected to compressive stress, and the slab slab mainly corresponds to the compressive stress, rather than the steel upper flange, so the closed steel upper flange does not properly correspond to the compressive stress, and is simply rectangular. Or, since it only plays the role of maintaining the shape of the formulation, it is a situation that wastes a large amount of steel due to the use of a large amount of steel does not play a role, and the upper flange of the parent cement section corresponds to the tensile stress structural efficiency However, since the lower flange has to cope with the compressive stress of the steel, a large amount of steel is used, causing uneconomical factors.

In addition, the steel-type steel box girder bridge is a cross section in which both the positive and the parent cement sections are opened, which reduces the amount of steel. However, as the upper flange of the parent cement section is opened, the tensile cracks are applied to the bottom plate slab of the parent cement section. There is a possibility that opening-type steel box girder bridges are not widely applied.

Therefore, the present invention was devised to solve the problems described above, the point portion (the middle portion of the piers installed in the inner section corresponding to the portion where the tensile stress is large in the upper section of the parent cement section of the steel box girder bridge) The 0.08L ~ 0.16L section of the long section (L) is composed of closed cross sections, and the upper flange of the parent flange section other than the upper flange of the closed flange section in the parent section is the truss shape. It consists of an opening section with horizontal bracing of 0.16L of ground span (L) on both sides of the point part with a prestress introduced into the upper slab slab of the parent cement section and the compressive stress of the lower flange of the parent cement section. The section of 0.32L is made by pouring high-strength concrete, and the upper flange steel and the bottom plate are closed in the upper flange of the parent cement section. Prestress is introduced into the slab to cope with tensile stress, and the upper flange of the parent cement section other than the closed flange upper flange and the upper flange of the constant moment section consist of an opening section to reduce the steel requirements and lower the parent cement section. In the flange, high-strength concrete is poured to cope with compressive stress, so the steel requirements are reduced by 20 to 40% to provide an economical steel box girder bridge and its construction method.

Steel box girder bridge according to the present invention for achieving the above object is a horizontally connected between the lower abdomen and the upper flange arranged horizontally between the upper part of the abdomen, left and right at regular intervals, the lower left and right sides of the abdomen A girder consisting of a lower flange disposed therein, the bridge comprising a positive moment section and a parent moment section according to a portion in which a positive bending moment and a negative bending moment occur in the girder while the girder is disposed. In the steel box girder bridge, in which the respective lengths (L) are the same in the longitudinal direction, the upper flange of the parent cement section of the steel box girder bridge has a section of 0.08L to 0.16L of the long length (L) at both sides of the closed section. And an upper flange of the parent flange section and the upper flange of the positive moment section other than the upper flange of the closed end face of the parent section. The horizontal flange is formed in the opening section is attached, the lower flange of the parent section is characterized in that the 0.16L ~ 0.32L section of the long section (L) is poured into a high-strength concrete of a certain thickness on both sides around the point portion. .

In addition, the steel box girder bridge construction method according to the present invention for achieving the above object is disposed in the left and right at regular intervals, the upper flange arranged horizontally between the upper portion of the abdomen, the lower left and right sides of the abdomen A girder consisting of a lower flange arranged horizontally connected therebetween, the positive moment section and the parent moment depending on a portion in which the positive and negative bending moments occur in the girder while the girder is disposed. In the steel box girder bridge construction method in which the respective lengths (L) are the same in the longitudinal direction of the bridge consisting of sections, the upper flange of the parent cement section of the steel box girder bridge is 0.08 L to 0.16 of the length (L) from both sides of the point portion. The L section is formed into a closed section, and the upper flange and the constant moment section of the parent cement section other than the upper flange of the closed section of the parent cement section. The upper flange is formed by the truss-shaped opening section attached to the truss, and the lower flange of the parent cement section is poured into high-strength concrete of 0.16L ~ 0.32L section of the long section (L) with a certain thickness. It is characterized by.

As described above, the steel box girder bridge and the construction method thereof according to the present invention, in the steel box girder bridge, expensive steel materials by using high-strength concrete and steel efficiently and appropriately in accordance with the compression and tensile stress in the constant and parent section Steel box girder bridge can reduce the requirement of 20-40%.

Hereinafter, with reference to the accompanying drawings, the present invention will be described in detail.

1 is an elevation view showing a rectangular steel box girder bridge according to the present invention, Figure 2 is a plan view showing a rectangular steel box girder bridge according to the invention, Figure 3 is a cross-sectional view taken along line AA of Figure 1, Figure 4 A cross-sectional view taken along line BB of FIG. 5 is an elevation view illustrating a steel box girder bridge according to the present invention, FIG. 6 is a plan view showing a steel box girder bridge according to the present invention, and FIG. 8 is a cross-sectional view taken along line BB of FIG. 5.

As shown in these figures, the steel box girder bridge (G) according to the present invention is arranged in the left and right, the abdomen 10 and the upper flange 12 disposed horizontally between the upper portion of the abdomen 10 at regular intervals. ) And a lower flange 14 which is horizontally connected between the lower left and right sides of the abdomen 10, the girder G being positively connected to the girder G in a state where the girder G is disposed. Steel box girder bridge (G) having the same length (L) in the longitudinal direction of the bridge consisting of the constant moment section 20 and the parent moment section 30, depending on the bending moment of the bending moment and negative (-) bending moment. ),

The upper flange 12 of the parent section (30) is a section corresponding to a large tensile stress, 0.08L of the ground length (L) on both sides based on the point portion (meaning the center portion of the piers installed in the inner) The upper flange 12 of the parent cement section 30 other than the upper flange 12 of the closed cross section 40 of the parent cement section 30 is formed as a closed section 40 in a closed state of ~ 0.16L section. ) And the upper flange 12 of the constant moment section 20 is formed with an opening end surface 50 to which the truss-shaped horizontal bracing 52 is attached, and the prestressed portion in the bottom plate slab 70 of the parent section section 30. Introduce the high-strength concrete of 0.16L ~ 0.32L section of the long section (L) on both sides of the point portion to the section corresponding to the large compressive stress of the parent flange section (30) lower flange (14) 60).

In addition, the prestress is introduced by the PC steel wire 80 into the bottom plate slab 70 of the upper flange 12 of the parent section (30).

And the upper flange 12 bottom plate slab 70 of the parent cement section 30 is provided with a precast composite or concrete fixing block 90 for introducing prestress, the precast composite or concrete fixing block ( 90) is a steel composite or high-strength concrete precast segment fixing block in consideration of ease of construction, and is manufactured in advance in the factory or on the site and assembled and installed. Therefore, quality control and constructability can be improved rather than construction by site casting. have.

In addition, the steel box girder bridge (B) is the abdomen 10 is composed of a corrugated steel sheet.

On the other hand, in pouring the high-strength concrete 60 to the lower flange 14 of the parent section (30) in the composite of the long section (L) of both sides around the point portion of the lower flange 14 of the parent section (30). Sections exceeding 0.16L-0.32L sections may be constructed by pouring high strength concrete 60b into thin sections to control the compressive stress of the entire parental section 30.

Steel box girder bridge (B) according to the present invention made of a configuration as described above can reduce the amount of steel 20 to 40% compared to the conventional closed steel box girder bridge, the opening portion of the upper flange 12 A truss-shaped horizontal bracing 52 is attached to resist torsion.

This results in the most efficient cross-section through the introduction of the closed section 40 and the prestress of the minimum section at the upper section of the parent cement section 30 and the synthesis of the high-strength concrete 60 at the bottom section of the parent section section. There is an effect.

Hereinafter, the construction of the steel box girder bridge according to the present invention having the configuration as described above.

As shown in Figures 1 to 8, the steel box girder bridge construction method according to the present invention is the upper flange arranged horizontally between the upper part of the abdomen 10 and the upper part of the abdomen 10, which are arranged at regular intervals A girder (G) comprising a lower flange (14) arranged horizontally between the lower left and right sides of the abdomen (10), the girder (G) is fixed to the girder (G) in a state arranged Steel box girder bridges having the same length (L) in the longitudinal direction of the bridge consisting of the positive moment section 20 and the parent moment section 30, depending on the part where the positive and negative bending moments occur. In the construction method, the upper flange 12 of the parent cement section 30 of the steel box girder bridge (B) is a 0.08L ~ 0.16L section of the long section (L) to both sides of the point portion to the closed section 40 And other than the upper flange 12 of the closed end face 40 of the parent section 30. The upper flange 12 of the parent cement section 30 and the upper flange 12 of the positive moment section 20 are formed as an opening end surface 50 to which the truss-shaped horizontal bracing 52 is attached. The lower flange 14 of 30) is poured into the high-intensity concrete 60 of 0.16L ~ 0.32L section of the long section (L) with a predetermined thickness on both sides around the point portion.

That is, the steel box girder bridge construction method according to the present invention is the upper portion of the parent moment section 30 other than the constant moment section 20, the upper flange 12 and the parent cement section 30, the closed section 40, the upper flange 12 In the flange 12, only the upper flange 12 necessary for the synthesis with the bottom plate slab 70 is secured, and the rest is removed, and the truss-shaped horizontal bracing 52 is attached to the open end surface 50, and the parent In the upper flange 12 of the cement section 30, a section corresponding to a large tensile stress portion, the 0.08L ~ 0.16L section of the long section (L) on both sides around the point portion composed of a closed cross-section (40), the parent Prestress is introduced into the upper section slab 70 of the cement section 30 and a section corresponding to the portion of the lower flange 14 of the parent cement section 30 where the compressive stress is large is large. ) 0.16L ~ 0.32L section is cast and composited with high strength concrete (60). The existing steel requirements are applied in the 0.08L ~ 0.16L section of the long section L to both sides of the point portion, which is a constant section of the upper flange 12 of the parent cement section 30, which is a section corresponding to the surface tensile stress. Prestress is introduced into the upper bottom plate slab 70 of the parent section 30 and the bottom plate slab 70 serves as a complement to the steel in the section corresponding to the compressive stress, that is, the upper flange 12 of the constant moment section 20. High strength concrete (60b) complements the existing steel in the 0.16L to 0.32L section of the long section (L) on both sides of the point portion, which is a certain section of the lower flange 14 of the parent section section 30. It has the effect of reducing 20 ~ 40% of the steel requirements of the box girder bridge.

Steel box girder bridge construction method as described above, after the steel box girder (G) is manufactured in the steel bridge manufacturing plant as described above, and then assembled and assembled in the same manner as the general closed steel box girder bridge, the lower portion of the parent section (30) Since the construction of the high-strength concrete 60 by placing only a portion of the compression stress of the flange 14 is large, the construction and installation is not complicated and there is also an easy effect.

This results in the introduction of prestress into the closed section 40 of the minimum section above the parent section 30 and the bottom plate slab 70 of the parent section section 30 and the high-strength concrete section of the section below the parent section section 30. 60b) It is intended to make construction easy and economical by constructing the most economical and efficient cross section by synthesis.

In addition, in the introduction of the prestress into the bottom plate slab 70 of the parent section (30), the precast composite or concrete fixing block 90 of the PC steel wire 80 is a factory or as a composite or concrete precast segment fixing block Since it is manufactured in advance on the floor slab 70 when the concrete is installed and installed in advance, it can facilitate the quality control and construction of the fixing block.

1 is an elevation view showing a rectangular steel box girder bridge according to the present invention,

2 is a plan view showing a rectangular steel box girder bridge according to the present invention,

3 is a cross-sectional view taken along the line A-A of FIG.

4 is a cross-sectional view taken along the line B-B of FIG.

Figure 5 is an elevation view showing a formulation steel box girder bridge according to the present invention,

Figure 6 is a plan view showing a steel box girder bridge formulation according to the present invention,

7 is a cross-sectional view taken along the line A-A of FIG.

8 is a cross-sectional view taken along the line B-B in FIG.

Explanation of symbols on the main parts of the drawing

10: abdomen 12: upper flange

14: lower flange 20: constant moment section

30: parent section 40: closed section

50: opening cross-section 52: horizontal bracing

60: high strength concrete 60b: high strength concrete

70: bottom plate slab 80: PC steel wire

90: precast rigid composite or concrete fixing block

B: Steel box girder bridge G: Girder
L: Soy sauce

Claims (6)

The lower part arranged horizontally between the lower abdomen 10 disposed at the left and right at regular intervals, the upper flange 12 disposed horizontally between the upper part of the abdomen 10, and the lower left and right sides of the abdomen 10. A girder (G) consisting of a flange (14), in which the positive (+) bending moment and the negative (-) bending moment occur in the girder (G) in the state in which the girder (G) is arranged, In the steel box girder bridge, in which the length L is the same in the longitudinal direction of the bridge including the cement section 20 and the parent cement section 30, The upper flange 12 of the parent cement section 30 of the steel box girder bridge (B) has a closed section (40) of 0.08L ~ 0.16L section of the long section (L) on both sides around the point portion, the parent The upper flange 12 of the parent cement section 30 and the upper flange 12 of the constant moment section 20 are other than the upper flange 12 of the closed section 40 of the cement section 30. 52 is attached to the end surface 50 is attached, the lower flange 14 of the parent cement section 30 is 0.16L ~ 0.32L section of the long section (L) on both sides of the point portion of the concrete (60) Steel box girder bridge, characterized in that synthesized by pouring. The method of claim 1, Prestress is introduced into the upper flange 12 bottom plate slab 70 of the parent section (30) by the PC steel wire 80, the precast steel composite or concrete fixing so that the PC steel wire 80 can be fixed Steel box girder bridge, characterized in that consisting of blocks (90). The method of claim 1, Steel box characterized in that the concrete (60b) is additionally poured in a thin section in the section 0.16L ~ 0.32L of the long section (L) on both sides of the point portion of the lower flange 14 of the parent section (30) Girder bridge. The lower part arranged horizontally between the lower abdomen 10 disposed at the left and right at regular intervals, the upper flange 12 disposed horizontally between the upper part of the abdomen 10, and the lower left and right sides of the abdomen 10. A girder (G) consisting of a flange (14), in which the positive (+) bending moment and the negative (-) bending moment occur in the girder (G) in the state in which the girder (G) is arranged, In the construction method of the steel box girder bridge, in which the lengths (L) are the same in the longitudinal direction of the bridge consisting of the cement section (20) and the parent section (30), The upper flange 12 of the parent section section 30 of the steel box girder bridge (B) forms a closed section 40 of the 0.08L ~ 0.16L section of the long section (L) on both sides of the point portion, the parent The upper flange 12 of the parent cement section 30 and the upper flange 12 of the constant moment section 20 are other than the upper flange 12 of the closed section 40 of the cement section 30. The lower flange 14 of the parent cement section 30 is formed with an opening end surface 50 to which the 52 is attached, and 0.16L to 0.32L section of the long span L is formed on both sides of the point portion. Steel box girder bridge construction method characterized in that the synthesis. The method of claim 4, wherein Prestress is introduced into the upper flange 12 bottom plate slab 70 of the parent section 30 by a PC steel wire 80, and precast steel composite or concrete fixing so that the PC steel wire 80 can be fixed Steel box girder bridge construction method characterized in that using the block (90). The method of claim 4, wherein Steel box girder bridge construction characterized in that the concrete (60b) is added to the thin section in the section 0.16L ~ 0.32L of the long section (L) on both sides around the point portion of the lower flange 14 of the parent cement section. Way.

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