KR100665876B1 - The prestressed opening trapezoid waveform still girder construction method of having installed concrete caisson in the upper flange - Google Patents

Abstract

A construction method for a prestressed open-top type wavy steel girder bridge by installing a concrete caisson on an upper flange is provided to decrease the cross section of an upper flange by having excellent stress distribution and absorbing the stress of an upper flange using a concrete caisson. A construction method for a prestressed open-top type wavy steel girder bridge by installing a concrete caisson on an upper flange comprises the steps of welding a lower flange(14) composed of a steel plate having the appointed size on each lower part of a pair of wavy steel plates(12), welding an upper flange(16) composed of a steel plate having the appointed size on each upper part of the wavy steel plates to be separable, manufacturing an open-top type wavy steel girder(10) and installing all over a span of a bridge, placing bottom concrete on the top of the lower flange in the open-top type wavy steel girder and placing a rectangular or U-shaped concrete caisson(20) on the top of the upper flange simultaneously, unifying the lower flange and the bottom concrete with a shear connector and curing concrete, placing a strand on the bottom concrete through a pre-laid sheathe pipe, applying prestress partially, placing deck concrete on the upper flange, unifying the upper flange and the deck concrete using a shear connector and curing the concrete, applying prestress on the remaining strands buried under the bottom concrete, and applying prestress on the deck concrete in the tension area of a support.

Description

The prestressed opening trapezoid waveform still girder construction method of having installed concrete caisson in the upper flange}

1 is a perspective view showing a conventional opening type corrugated steel girder,

FIG. 2 is a front view illustrating a state in which bottom concrete is poured on the upper surface of the lower flange of FIG. 1;

3 is an exemplary view showing a stress distribution state when the concrete caisson is not formed on the upper flange of FIG.

Figure 4 is a side view showing a state in which prestress is introduced to the bottom concrete of FIG.

5 is a front view illustrating a state in which the upper deck concrete is poured into the upper flange of FIG.

FIG. 6 is a side view illustrating a state in which prestress is introduced into floor concrete and bridge upper deck concrete of FIG. 5;

FIG. 7 is a front view showing a state in which the upper secondary dead concrete pavement, railing, etc. are loaded on the deck upper concrete of FIG. 6;

8 is a perspective view showing an opening-type corrugated steel girder formed with a concrete caisson integrated with a shear connector in the upper flange according to the present invention,

9 is a front view illustrating a state in which concrete caisson and bottom concrete are formed by placing concrete on the upper surface of the upper flange and the lower flange of FIG. 8;

10 is an exemplary view showing a stress distribution when the concrete caisson is synthesized in the upper flange of FIG.

FIG. 11 is a front view illustrating a state in which bridge deck concrete is formed on the concrete caisson of FIG. 9; FIG.

12 is a moment diagram of the opening-type steel girders due to the uncured bridge upper deck concrete load when the upper deck concrete is placed on the concrete caisson of FIG.

13 is a perspective view illustrating a state in which a prestressed opening type corrugated steel girder having a concrete caisson formed on an upper flange according to the present invention is installed on a point portion;

FIG. 14 is a moment diagram of an opening-type steel girder by the point lowering in FIG. 13;

FIG. 15 is a moment change diagram of an opening-type steel girder due to the point lowering in FIG. 13;

16 is a side view showing a prestressed opening type corrugated steel girder formed with a concrete caisson on the upper flange according to the present invention,

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

FIG. 18 is an enlarged detailed view of a portion “A” of FIG. 16;

19 is a comparison showing the stress distribution according to the presence or absence of concrete caisson in the upper flange,

20 is a front view showing a state in which formwork is fixed to the corrugated steel sheet to form a concrete caisson in the opening-type corrugated steel girder according to the present invention,

 Figure 21 is a side view showing a state showing the compressive force by welding the anchorage to the upper flange when the bottom flange to the bottom flange of the opening-form corrugated steel girder according to the present invention, the tension of the portion of the parent portion with PS steel,

22 is a side view showing a buried anchorage of the concrete caisson;

23 is a plan view showing a single buried anchorage of the concrete caisson,

24 is a plan view showing a plurality of embedded anchorage of the concrete caisson;

25 is a side view showing a protruding anchorage of the concrete caisson;

26 is a plan view showing a single protruding anchorage of the concrete caisson;

27 is a plan view showing a plurality of projecting anchorage of the concrete caisson;

28 is a perspective view showing a state in which a single fixing unit is installed on the upper flange,

29 is a perspective view illustrating a state in which a plurality of fixing units are installed in the upper flange.

-Explanation of the symbols for the main parts of the drawings-

10: opening shaped corrugated steel girders 12: corrugated steel sheet

14: lower flange 16: upper flange

20: concrete caisson 22: floor concrete

30: deck upper concrete 40: prestress

50: branch 60: handrail

62: packing 70: PS steel

74: Uneven formwork mounting plate 76: Formwork

80: concrete diaphragm 82: constant moment anchor

84: parent anchorage fixture 86: fixing wedge

88: steel die 90: round bar

92: bolt 94: shear connector

96: rebar 98: steel anchorage

100: prestressed opening type corrugated steel girder bridge

The present invention relates to a method of constructing a prestressed open-form corrugated steel girder bridge in which a concrete caisson is installed on an upper flange. Particularly, an uncured bridge upper deck concrete is synthesized by synthesizing a concrete caisson of rectangular or formulation to an upper flange of an open-form corrugated steel girder. The present invention relates to a construction method of a prestressed opening type corrugated steel girder bridge in which a concrete caisson is installed in an upper flange to absorb the stress of the upper flange into the concrete caisson to reduce the cross section of the upper flange.

In general, the construction order of the prestressed composite bridge using corrugated steel sheet is as shown in Figs. 1 to 7, the abdomen is a pair of corrugated steel sheet 12, the lower portion of the pair of corrugated steel sheet 12 Welding the lower flange 14 made of a steel plate of a constant size, and welding the upper flange 16 made of a steel sheet having a predetermined size on each upper portion of the corrugated steel sheet 12 separately welded, corrugated steel girders (10) is fabricated (see Fig. 1), and the fabricated corrugated steel girder 10 is installed over the bridge foreground.

Subsequently, the bottom concrete 22 is placed on the upper surface of the lower flange 14 in the corrugated steel girder 10 (see FIGS. 2 and 3), and the lower flange 14 and the bottom concrete 22 are sheared as connecting materials. After integrally curing the concrete, the strand is laid through a sheath pipe which is pre-embedded in the bottom concrete 22, and a prestress 40 is introduced into a portion thereof (see FIG. 4).

Subsequently, the upper deck concrete 30 is poured over the upper flange 16 (see FIG. 5), and the upper flange 16 and the bridge upper deck concrete 30 are integrally cured as a shear connector, and then cured. The prestress 40 is introduced into the remaining portion of the strand of the concrete embedded in the bottom concrete 22, while the prestress 40 is also introduced into the upper deck concrete 30 in the tension zone of the point portion 50. 6)

Subsequently, handrail 60, pavement 62, etc. are constructed on the upper surface of the bridge deck concrete 30. (See FIG. 7).

In the prestressed composite bridge construction method using the corrugated steel sheet 12 constructed as described above, only the lower flange 14 of the opening-type corrugated steel girder 10 is synthesized into the bottom concrete 22 during the bridge construction step. Since the prestress 40 is introduced, the upper deck 16 receives an uncured bridge on the upper deck concrete 30, and thus the upper flange 16 is subjected to excessive stress, so the upper flange of the corrugated steel girder 10 is exposed. There is a disadvantage that the steel cross section of (16) is greatly required.

That is, the conventional prestressed composite bridge construction method using corrugated steel sheet has a problem that the stress of the upper flange is relatively increased because the neutral axis is lowered because only the bottom concrete is synthesized when there is no concrete caisson in the upper flange.

Accordingly, the present invention has been made to solve the problems described above, the first object of the construction method of the prestressed opening type corrugated steel girder bridge installed concrete caisson in the upper flange according to the present invention is the upper surface of the lower flange When placing concrete on the upper flange, the concrete flange of rectangular or formulation is cast on the upper surface of the upper flange at the same time. The upper flange stress is absorbed into the concrete caisson to reduce the upper flange steel cross section.

In addition, a second object of the construction method of the prestressed opening type corrugated steel girder bridge in which the concrete caisson is installed on the upper flange according to the present invention is a bridge during construction of a continuous composite member composed of steel and floor concrete and the upper flange and concrete caisson When the upper deck concrete load is applied, the parent moment part, which is the intermediate point, may generate excessive tensile stress in the concrete caisson during construction. To control this, the method of reducing tensile stress by pre-traction by the point drop during construction and / or concrete caisson It can be divided into the method of offsetting the tensile stress by direct prestressed by the anchorage hardened to the upper flange in.

The construction method of the prestressed opening type corrugated steel girder bridge in which the concrete caisson is installed on the upper flange according to the present invention for achieving the above object is to make the abdomen as a pair of corrugated steel sheets, and to be fixed to the lower portion of the pair of corrugated steel sheets. Welding and welding the lower flange made of a steel sheet of size, by welding the upper flange made of a steel sheet having a constant size to each upper portion of the corrugated steel sheet separately to produce a steel girder, bridge the manufactured steel girder bridge After installation over the foreground, after placing the bottom concrete on the lower flange in the steel girder, and curing the concrete by integrating the bottom flange and the bottom concrete with a shear connector, through the sheath pipe pre-embedded in the bottom concrete After laying the strand and introducing prestress to a part of the strand, The upper deck concrete is bridged on the upper part of the bridge, the upper flange and the upper deck concrete are bridged together as a shear connector to cure, and the prestress is introduced to the remaining strands embedded in the bottom concrete, In the prestress composite bridge construction method using corrugated steel sheet which is constructed by introducing prestress to the upper deck concrete of bridge

When placing the bottom concrete on the upper surface of the lower flange is characterized in that the curing of the concrete caisson of the rectangular or formulation on the upper flange at the same time.

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

8 is a perspective view showing an opening-type corrugated steel girder according to the present invention, Figure 9 is a front view showing a state in which the concrete caisson and the bottom concrete is formed by placing concrete on the upper surface and the upper flange of the upper flange of Figure 8, FIG. 10 is an exemplary view illustrating a stress distribution when a concrete caisson is synthesized in the upper flange of FIG. 9, and FIG. 11 is a front view illustrating a state in which upper deck concrete is formed on the concrete caisson of FIG. 9. FIG. 9 is a moment diagram of an opening-type steel girder due to uncured bridge upper deck concrete load when the upper deck concrete is poured into the concrete caisson of FIG. 9, and FIG. 13 is a prestressed opening type which is installed with a concrete caisson on the upper flange according to the present invention. Fig. 14 is a perspective view showing a state in which a corrugated steel girder is installed on a point portion, and Fig. 14 is an opening-type steel by the point lowering of Fig. 13. FIG. 15 is a moment change diagram of an opening steel girder due to the point lowering of FIG. 13, and FIG. 16 illustrates a prestressed opening steel corrugated steel girder having a concrete caisson installed on an upper flange according to the present invention. It is a side view, FIG. 17 is sectional drawing along the AA line of FIG. 16, and FIG. 18 is the detailed view which expands the "A" part of FIG.

As shown in these figures, the construction method of the prestressed opening type corrugated steel girder bridge in which the concrete caisson is installed on the upper flange according to the present invention, the abdomen is a pair of corrugated steel sheet 12, the pair of corrugated steel sheet A lower flange 14 made of a steel plate of a constant size is welded to the lower part of the 12, and the upper flange 16 made of a steel plate having a predetermined size is welded to each upper portion of the corrugated steel sheet 12 separately. After joining, an open shaped corrugated steel girder 10 is manufactured, and the prepared open shaped corrugated steel girder 10 is installed over the bridge foreground, and then the lower flange 14 in the open shaped corrugated steel girder 10. The bottom concrete 22 is poured on the upper surface, the lower flange 14 and the bottom concrete 22 are integrated with a shear connecting material to cure concrete, and then the sheath previously embedded in the bottom concrete 22. After laying the strand through the pipe, the prestress 40 is introduced to a portion thereof, and the upper deck concrete bridge 30 is placed on the upper flange 16, and the upper flange 16 and the upper deck deck bridge After the concrete 40 is integrated and cured as a shear connector, the prestress 40 is introduced with respect to the remaining strand of the concrete embedded in the bottom concrete 22, while the upper deck concrete in the bridge portion in the tension region of the branch portion 50 is introduced. In the prestress composite bridge construction method using a corrugated steel sheet in which the prestress 40 is also introduced and constructed at (30),

When placing the bottom concrete 22 on the upper surface of the lower flange 14, the concrete caisson 20 of the rectangular or formulation is simultaneously poured on the upper surface of the upper flange 16.

Here, the reason for forming the concrete caisson 20 is that the lower flange 14 during the construction of the prestressed opening-type corrugated steel girder 10 is synthesized with the bottom concrete 22 and uncured while the prestress 40 is introduced. When the upper deck concrete 30 is loaded, the upper flange 16 is subjected to excessive stress, so the cross section of the upper flange 16 is greatly required.

In order to solve this problem, the concrete caisson 20 of the rectangular or formulation is formed on the upper flange 16 and is still subjected to the load of the upper deck concrete 30, so that the stress of the upper flange 16 is applied to the concrete caisson 20. This is to reduce the steel cross section of the upper flange 16 by absorbing.

That is, when the concrete caisson 20 on the upper flange 16 is synthesized not only to the bottom concrete 22 but also to the concrete caisson 20, the neutral axis is upward, as shown in FIG. 10, of the upper flange 19. The stress is reduced to achieve a good stress distribution.

On the other hand, the concrete caisson 20 may be strongly resistant in the compression region due to the material properties of the concrete, but the resistance is weak in the tensile region.

That is, in the point portion 50 of the continuous bridge that becomes the parent portion when placing the upper deck concrete 30 bridge on the concrete caisson 20, the upper deck concrete 30 is the bridge upper deck concrete (30) The tensile stress on the concrete caisson 20 is temporarily increased significantly.

In order to alleviate this, the prestress is introduced directly into the concrete caisson tension zone.
Preflection to reduce the size of the parent moment of the point portion 50 by lowering the point portion 50 and to increase the moment of the center moment of the inter-gear region in which the compressive stress is generated in the concrete caisson 20 to adjust the bending to match the material properties By introducing, it is possible to reduce the tensile stress generated in the cross section of the concrete caisson 20 on the upper flange (16).
That is, it is characterized by lowering the point portion and introducing prefraction.

In addition, the point portion 50 is thickened than the constant moment bottom concrete 22 is poured into the parent cement portion bottom concrete (22a).

That is, when placing the bottom concrete 22, the mounting plate 74 for installing the uneven formwork on both sides of the corrugated steel sheet 12 in order to pour thicker than the constant moment bottom concrete 22 on the parent concrete portion bottom concrete 22a. Attaching, inserting the formwork 76 to the inside of the uneven form mounting plate 74, the bottom concrete (22a) is poured into the parent portion to form the bottom concrete (22a).

In addition, the inter-center central moment is arranged prestressed sheath pipe on the bottom flange 22 of the lower flange 14, the branch parent portion is prestressed sheath pipe on the upper deck concrete 30 bridge of the upper flange (16) side do. The arrangement of the anchorage is as described above.

And, Figure 19 is a comparative view showing the stress distribution according to the presence or absence of concrete caisson in the upper flange, in the case where there is no concrete caisson 20 in the conventional upper flange 16, since only the bottom concrete 22 is synthesized neutral axis When the upper flange 16 is lowered to be relatively high, but the concrete caisson 20 is present in the upper flange 16 of the present invention, the neutral shaft is synthesized because not only the bottom concrete 22 but also the concrete caisson 20 are synthesized. It can be seen that the upward stress is reduced in the upper flange 16 has a good stress distribution, the advantage is to reveal the technical core of the present invention.

20 is a front view showing a state in which the form is fixed to the abdomen of the corrugated steel sheet to form a concrete caisson in the opening-form corrugated steel girder according to the present invention, Figure 21 is a view of the opening-form corrugated steel girder according to the present invention When the bottom concrete is placed on the bottom concrete, the anchorage is welded to the upper flange and the compressive force is shown by tensioning the parent portion with PS steel, and FIG. 22 is a side view showing the embedded anchorage of the concrete caisson. 23 is a plan view showing a single buried anchorage of the concrete caisson, FIG. 24 is a plan view showing a plurality of buried anchorages of the concrete caisson, FIG. 25 is a side view showing a protruding anchorage of the concrete caisson, and FIG. 26 is a cone A plan view showing a single protruding anchorage of the litcaisson, and FIG. 27 shows a plurality of protruding anchorages of the concrete caisson. 28 is a perspective view illustrating a state in which a single fixing unit is installed in the upper flange, and FIG. 29 is a perspective view illustrating a state in which a plurality of fixing units are installed in the upper flange.

As shown in these figures, the construction of the concrete caisson 20 of the prestressed opening-type corrugated steel girder bridge in which the concrete caisson is installed on the upper flange according to the present invention is the upper part of the abdomen of the corrugated steel sheet 12 when the bottom concrete 22 is placed The fixing wedge 86 is attached to both sides, and the L-shaped steel formwork 88 is welded and installed on the fixing wedge 86, and the upper surface of the L-shaped steel formwork 88 is fixed to the stationary rod 90 and the bolt 92. After fixing to), the shear connecting member 94 and the reinforcing bars 96 are placed inside the L-shaped steel formwork 88, and concrete is poured into the L-shaped steel formwork 88 to be constructed.

On the other hand, when installing the concrete caisson 20 on the upper flange 16, the method for reducing the tensile stress generated in the concrete caisson 20 is installed in the upper flange 16, the shear connecting member 94 at regular intervals. And welding the steel anchoring holes 98 to both sides of the parent section of the inner branch portion 50 and the upper flange 16, and fixing the PS steel 70 between the steel anchoring holes 98 and at the same time. By tensioning the cement, a compressive force is introduced to control the occurrence of tensile stress on the upper flange 16 of the point portion when the bottom concrete 22 is placed.

That is, in the construction method of the prestressed opening type corrugated steel girder bridge in which the concrete caisson is installed on the upper flange according to the present invention, the composite concrete caisson 20 is installed by installing the shear connecting member 94 at regular intervals on the upper flange 16. The steel anchoring holes 98 are welded and joined to both sides of the inner portion of the parent cement section, and the PS steel 70 is fixedly installed between the steel anchoring holes 98 and at the same time, the compressing force is introduced by tensioning the branch portions. By controlling the tensile stress generated excessively in the upper flange 16 and the concrete caisson 20 at the time of placing the concrete floor.

Here, the upper flange 16 is a steel anchoring hole 98 is firmly connected to the upper surface by welding, and the structure that can simultaneously resist the steel anchoring hole 98 and the pressure of the concrete at the time of pre-stress introduction and fixing,

The upper flange 16 is installed so as to be embedded or protrudes in a concrete caisson 20 formed of concrete.

In addition, the steel fixing hole 98 uses a single type or a plurality of types according to the fixing of the PS steel 70.

As described above, the construction method of the prestressed opening type corrugated steel girder bridge provided with a concrete caisson on the upper flange according to the present invention has the following effects.

First, the present invention has a good stress distribution when the concrete caisson of the rectangular or formulation on the upper flange on the upper flange to receive an uncured bridge upper deck concrete load, the stress of the upper flange is absorbed by the concrete caisson, Has the effect of reducing the steel cross section.

Secondly, the present invention reduces the size of the parent moment by the preflection due to the point drop during construction, and instead increases the moment of the central moment moment in which the compressive stress is generated in the concrete caisson, thereby adjusting the bending to match the material properties. There is an effect of reducing the cross-sectional size of.

Third, the present invention is to install the steel anchoring hole in the upper flange in the upper flange parent section of the inner point portion to reduce the cross-section of the upper flange and concrete caisson by introducing a compressive force on the top of the parent cement portion as the PS steel is tensioned There is.

Fourth, the present invention has the advantage that it can effectively resist the compressive stress generated in the inner point portion by forming the concrete placed on the upper surface of the lower flange portion of the inner portion of the parent portion section thicker than the concrete placed in the constant moment section.

Claims (7)

The abdomen is a pair of corrugated steel sheets, and a lower flange made of a steel plate of a constant size is welded to the lower portion of the pair of corrugated steel sheets, and an upper flange made of a steel plate having a constant size on each upper portion of the corrugated steel sheet. Welded to separate, respectively, to produce a steel girder, install the produced steel girder over the bridge foreground, and then the bottom concrete is placed on the upper top of the lower flange in the steel girder, and the bottom flange and the bottom concrete shear connecting material After curing the concrete by integrating the furnace, the strands are laid through the sheath pipe pre-embedded in the bottom concrete, the prestress is introduced into a portion thereof, and the upper deck concrete is poured into the upper flange, and the upper After the flange and the upper deck concrete of the bridge is integrated and cured as a shear connector, the bar In introducing a prestress with respect to the strands of the embedded residue on the other hand concrete, prestressed composite bridge construction method using the corrugated steel plate of the construction by introducing a prestress in the upper bridge deck concrete in the tension zone branch portion, Construction method of the pre-stressed opening type corrugated steel girder bridge with the concrete caisson installed on the upper flange, characterized in that when the bottom concrete is placed on the upper flange, the concrete caisson of the rectangular or formulated casting on the upper flange at the same time. The method of claim 1, The concrete caisson is formed by attaching a fixed wedge to the upper both sides of the upper abdomen of the corrugated steel plate when the bottom concrete is poured, install the L-shaped steel formwork to the fixed wedge, and fix the upper surface of the L-shaped steel formwork with a fixed round bar and bolt Construction of a prestressed opening type corrugated steel girder bridge with concrete caisson installed on the upper flange, characterized in that the reinforcement of the shear connecting material and the reinforcing bar inside the L-shaped steel formwork, and cast concrete to the L-shaped steel formwork. Way. The method of claim 1, In order to reduce the cross-sectional size of the concrete caisson, the point portion is lowered to reduce the size of the parent moment, and at the same time, the pre-fraction for adjusting the bending by increasing the moment of the center moment of the inter-region in which the compressive stress is generated in the concrete caisson is introduced. Construction method of the prestressed opening type corrugated steel girder bridge with a concrete caisson installed on the upper flange. The method of claim 1, The point portion of the construction method of the prestressed opening type corrugated steel girder bridge with a concrete caisson installed on the upper flange, characterized in that the curing of the parent cement floor concrete thicker than the bottom moment concrete. The method of claim 4, wherein In order to pour thicker than the constant moment bottom concrete on the bottom concrete when the floor concrete is poured, attach the mounting plate for the uneven formwork on both sides of the corrugated steel sheet, and insert the formwork inside the mounting plate for the uneven formwork installation The construction method of the prestressed opening type corrugated steel girder bridge in which the concrete caisson is installed on the upper flange, characterized in that the bottom concrete is formed by pouring concrete into the parent part. The method of claim 1, Shear joints are installed at regular intervals on the upper flange to form a composite concrete caisson, welded steel fixtures on both sides of the parent cement section, which are inner branches, and are excessively generated on the concrete caissons of the parent portions of the branch by PS steel. Construction method of the prestressed opening type corrugated steel girder bridge with a concrete caisson installed on the upper flange, characterized in that to cancel the tensile stress. The method of claim 6, The upper flange is rigidly joined to the upper surface of the steel fixture by welding, and when the prestress is introduced into the fixed structure and can resist at the same time as the anchorage of the steel fixture and concrete, embedded in the concrete caisson which is poured into the upper flange formed concrete A method of constructing a prestressed opening shaped corrugated steel girder bridge with a concrete caisson characterized in that the steel fittings are installed to partially protrude.

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