KR100840190B1 - I-beam segment connection method equipped with prestress steel synthetic concrete upper flange for continuous bridge - Google Patents

Abstract

A connection method for an I-beam segment equipped with prestressed steel-combined concrete upper flange for a continuous bridge is provided to increase rigidity reinforcement and sectional rigidity by interconnecting the I-beam segment divided into main and sub moment units. A connection method for an I-beam segment equipped with prestressed steel-combined concrete upper flange for a continuous bridge includes the steps of: processing the I-beam segment to manufacture a main moment unit I-beam segment(10a) with prestressed steel-combined concrete upper flange; processing the I-beam segment to manufacture a sub moment unit I-beam segment(10b) with prestressed steel-combined concrete upper flange; and connecting the main moment unit I-beam segment with the sub moment unit I-beam segment.

Description

I-beam segment connection method equipped with prestress steel synthetic concrete upper flange for continuous bridge}

The present invention relates to a method for connecting an I beam segment having a prestressed steel composite concrete flange for continuous bridges.

Conventionally, when installing a bridge using a rolled steel I-type steel beam, a steel wire is installed in the lower part of the steel for increasing rigidity, and a tensile force is introduced to the steel wire to introduce a prestress into the I-type steel beam to resist a load acting. A bridge has been constructed.

However, there is a need for maintenance to prevent corrosion and unwinding of the steel wire and a problem of maintaining maintenance to maintain a constant prestress force on the I beam by periodically introducing a tensile force to the steel wire and a rolled steel I type steel. If the beam is used as it is, the rigidity is reduced, so that the use of the rolled steel beam is increased to overcome this, which is disadvantageous in economic efficiency, and there is a side that is impossible to construct a bridge between long spans. Although it is economical to apply prestress by attaching high strength steel plate of lower flange or upper and lower flange, it is impossible to construct bridge between long diameter due to the limitation of shape of existing rolled steel I-type steel beam.

Thus, the present invention was devised to solve the problems described above, after separately manufacturing the I-beam segment having a pre-stressed rigid composite concrete upper flange into the constant moment portion and the parent portion portion, the positive, parent portion portion I By connecting the beam segment, the upper part of the prestressed composite concrete for the continuous bridge that is lower than the conventional static and parental section I beam segment without the prestressed rigid concrete upper flange, and can be longer and more economically, but also increases the rigidity reinforcement and the stiffness of the cross section. It is an object of the present invention to provide a method for connecting an I beam segment having a flange.

In order to achieve the above object, a method for connecting an I beam segment having a prestressed rigid composite concrete upper flange for continuous bridges according to the present invention is a positive moment portion having a rigid composite concrete upper flange in which a prestress is introduced by processing an I beam segment. To fabricate the I beam segment, and to fabricate the parent cement portion I beam segment having the pre-stressed reinforced concrete upper flange, while interconnecting the fabricated positive and parent cement segments I beam segments. do.

As described above, the I-beam segment connecting method having the prestressed steel composite concrete flange for continuous bridges according to the present invention enables the construction of bridges between low heights and long diameters, and at the same time, economical rigidity and cross-sectional rigidity are increased. There is this.

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

1 is a side view showing an I-beam bridge having a pre-stressed composite concrete upper flange according to the present invention, Figure 2 is a moment of the I beam bridge having a pre-stressed composite concrete upper flange according to the present invention I beam One side view, Figure 3 is a cross-sectional view showing a constant moment I beam of the I-beam bridge having a pre-stressed composite concrete upper flange according to the present invention, Figure 4 is a pre-stressed composite concrete upper flange according to the present invention I Fig. 5 is a sectional view showing the parent portion portion I beam of the beam bridge, and Fig. 5 is a sectional view showing the parent portion portion I beam of the I beam bridge having the prestressed composite concrete upper flange according to the present invention.

As shown in these drawings, the I-beam segment connecting method having a continuous bridge prestressed rigid concrete upper flange according to the present invention is a static moment having a rigid composite concrete upper flange in which prestress is introduced by processing the I-beam segment 10 The secondary I beam segment 10a is fabricated, and the I beam segment 10 is fabricated to produce the parent cement portion I beam segment 10b having a rigid synthetic upper flange into which prestress is introduced. The parent cement portion I beam segments 10a and 10b are interconnected.

6A through 6D, the bottom flange of the I beam segment 10 may be formed by raising the I beam segment 10 in a direction opposite to the load. 12) a high-strength steel plate 14 is padded, the upper flange 16 is reinforced with a reinforcing bar 18, the L-shaped formwork 20 is installed, and after loading the pre-fraction load vertically upwards, The high strength steel plate 14 is welded to the flange 12, and the high flange 16 is poured into the high flange 22, and the high strength concrete 22 is cast and cured, and then the pre-stress is removed. The branches have a constant moment portion I beam segment 10a.

Also, as shown in FIGS. 7A to 7E, the parent cement portion I beam segment 10b is formed by raising the I beam segment 10 in a direction opposite to the load, and thus, the upper and lower portions of the I beam segment 10. The high strength steel sheet 14 is attached to the flanges 16 and 12, and the pre-fraction load is loaded vertically downward, and then the high strength steel sheet 14 is applied to the upper and lower flanges 16 and 12 of the I beam segment 10. After welding, the pre-fraction load is removed, and steel fixing holes 26a and 26b for fixing and fixing the PS steel 24 at both ends of the upper flange 16 are installed, and the sheath 28 and the reinforcing bar 18 are provided. After the installation, the L-form formwork 20 to pour and cure the high-strength concrete (22), and then install the PS steel material 24 into the steel fixing holes (26a, 26b) and the tension is introduced into the steel A parent cement portion I beam segment 10b having a synthetic concrete upper flange is fabricated.

And the connection between the positive and the parent portion I beam segment (10a, 10b) is a-shaped steel brackets at both ends of the connecting portion upper clearance 33 to prevent sagging after mounting of the positive, parent portion I beam segment (10a, 10b) (34) is installed, horizontal load is applied by the hydraulic jack (36), and the non-contraction concrete 38 is poured and connected.

Here, the steel fixtures (26a, 26b) for fixing the PS steel material 24 attached to both ends of the upper flange (16) of the parent cement portion I beam segment (10b) is provided, the steel fixtures (26a, 26b In the form of a triangular bracing plate 30 attached to the center of the plate-shaped fixing plate 28, the simple steel fixing hole 26a for introducing prestress only to the upper flange 16, and the upper flange 16 and the bottom plate slab. It consists of a composite steel anchoring hole 26b which introduces prestress into 32.

Hereinafter, an I beam segment connection construction having a prestressed rigid concrete upper flange according to the present invention having the above configuration will be described.

15 is a side view illustrating an I beam bridge of an I beam bridge having a prestressed composite concrete upper flange according to the present invention, and FIG. 16 is an I beam bridge of an I beam bridge having a prestressed composite concrete upper flange according to the present invention. It is a top view showing the.

As shown in these drawings, the I-beam segment connecting method having a continuous bridge pre-stressed composite concrete upper flange according to the present invention while producing a constant moment portion I beam segment (10a), but rises in the direction opposite to the working load After manufacturing the introduced I-beam segment 10, the high-strength steel plate 14 is applied to the lower flange 12 of the I-beam segment 10, and after introducing an upward force into the hydraulic jack 36, the lower flange 12 The high strength steel sheet 14 is welded to the upper flange 16, the high strength concrete 22 is poured and cured on the upper flange 16, and the prestress is introduced into the steel I beam segment 10 by releasing the upward force of the hydraulic jack 36. After manufacturing the constant moment portion I beam segment (10a),

Subsequently, the parent beam portion I beam segment 10b is fabricated, but the I beam segment 10 is introduced into the direction opposite to the working load so as to produce upper and lower flanges 16 and 12 of the I beam segment 10. A high strength steel sheet 14 is applied to the upper and lower flanges 16 and 12 to weld the high strength steel sheet 14 to the upper and lower flanges 16 and 12. Steel fittings 26a and 26b for introducing prestress are installed at 16, and after the high-strength concrete 22 is poured and cured, it is tensioned with PS steel 24 to prestress the steel I beam segment 10. After introduction to produce the parent portion I beam segment 10b,

The positive and parent portion I beam segment (10a, 10b) is connected and assembled by a connecting steel plate, but the positive and parent cement I beam segment (10a, 10b) having a pre-stressed rigid composite concrete upper flange (16) on-site In assembling in the connection, the a-shaped steel bracket (34) to the stem portion 33 to prevent the sagging caused by the clearance between the concrete ridge portion of the upper flange 16 of the positive, parent cement I beam segment (10a, 10b) ) And a hydraulic jack 36 is installed on it, and the axial concrete (38) is poured into the spacing part 33 in the state where the horizontal load is applied. After mounting the fixed and parent cement portion I beam segments 10a and 10b to the pier 40 and the alternating 42, the bottom slab slab 18 is placed and the concrete 22 is poured and cured.

Here, when the prestress is selectively introduced into the bottom plate slab 32 of the parent portion I beam segment 10b, the sheath 19 is disposed at the composite steel anchoring hole 26b when the bottom plate slab 32 is placed. After curing the concrete, the PS steel 24 is inserted into the sheath 19 to introduce the prestress, and then complete the construction of the bridge upper structure.

In addition, by installing the elastic rubber 46 fixed to the inner side of the L-shaped formwork 20 with a high-tensile bolt 44, it is installed while preventing the concrete from flowing down during concrete pouring.

1 is a side view showing an I-beam bridge having a prestressed rigid concrete upper flange according to the present invention,

Figure 2 is a side view showing a constant moment portion I beam of the I-beam bridge having a prestressed steel composite concrete upper flange according to the present invention,

3 is a cross-sectional view showing a constant moment portion I beam of the I-beam bridge having a prestressed steel composite concrete upper flange according to the present invention,

Figure 4 is a side view showing the parent portion portion I beam of the I-beam bridge having a prestressed steel composite concrete upper flange according to the present invention,

5 is a cross-sectional view showing the parent beam portion I beam of the I-beam bridge having a prestressed steel composite concrete upper flange according to the present invention,

6a to 6d is a process diagram showing a process for producing a constant moment portion I beam of the I-beam bridge having a pre-stressed composite concrete upper flange according to the present invention,

7a to 7e is a process chart showing the process of manufacturing the I-beam of the parent portion of the I-beam bridge having a pre-stressed composite concrete upper flange according to the present invention,

8 is a cross-sectional detail view showing an L-shaped formwork of an I-beam bridge having a prestressed rigid concrete upper flange according to the present invention;

9 is a perspective view showing a simple steel fixture of the I-beam bridge having a pre-stressed steel composite concrete upper flange according to the present invention,

10 is a front view showing a simple steel anchoring hole of an I-beam bridge having a prestressed steel composite concrete upper flange according to the present invention,

11 is a plan view showing a simple steel anchoring hole of an I-beam bridge having a prestressed steel composite concrete upper flange according to the present invention,

12 is a perspective view showing a composite steel anchorage of the I-beam bridge having a prestressed steel composite concrete upper flange according to the present invention,

13 is a front view showing a composite steel anchorage of the I-beam bridge having a pre-stressed steel composite concrete upper flange according to the present invention,

14 is a plan view showing a composite steel anchorage of the I-beam bridge having a prestressed steel composite concrete upper flange according to the present invention,

15 is a side view showing an I beam connecting portion of an I beam bridge having a prestressed rigid concrete upper flange according to the present invention;

16 is a plan view showing an I beam connecting portion of an I beam bridge having a prestressed rigid concrete upper flange according to the present invention;

Explanation of symbols on the main parts of the drawing

10: I beam segment

10a: constant moment portion I beam segment with prestressed rigid concrete upper flange

10b: parent portion I beam segment with prestressed rigid concrete upper flange

12: lower flange 14: high strength steel sheet

16: upper flange 18: rebar

19: sheath 20: L formwork

22: high strength concrete, concrete 24: PS steel

26a: Simple Steel Fittings 26b: Composite Steel Fittings

28: fixing plate 30: brace plate

32: bottom plate slab 33: clearance part

34: A type steel bracket 36: Hydraulic jack

38: non-contraction concrete 40: pier

42: Shift 44: High tension bolt

46: elastic rubber B: I-beam bridge

Claims (6)

I beam segment 10 is fabricated to produce a constant moment portion I beam segment 10a having a steel composite upper flange with prestress introduced thereto, While processing the I beam segment 10 to produce a parent cement portion I beam segment (10b) having a steel composite upper flange of the pre-stress introduced, I-beam segment connection method having a pre-strength rigid composite concrete upper flange for continuous bridges, characterized in that for interconnecting the produced positive, parent portion I beam segment (10a, 10b). The method of claim 1, The constant moment I beam segment 10a is formed by rising the I beam segment 10 in a direction opposite to the load, and attaching a high strength steel plate 14 to the lower flange 12 of the I beam segment 10. After reinforcing bars 18 are installed in the upper flange 16, the L-shaped formwork 20 is installed, and the pre-fraction load is loaded vertically upward, the high strength steel plate 14 is welded to the lower flange 12. To the upper flange 16, the high-strength concrete 22 is poured and cured, and then the pre-fraction load is removed to produce the positive moment part I beam segment 10a having the rigid composite upper flange with prestress. I-beam segment connection method having a pre-stressed rigid composite concrete upper flange for continuous bridges. The method of claim 1, The parent portion I beam segment 10b is formed by high-strength steel sheet 14 on the upper and lower flanges 16 and 12 of the I beam segment 10 by raising the I beam segment 10 in a direction opposite to the load. And load the high strength steel plate 14 to the upper and lower flanges 16 and 12 of the I-beam segment 10 by welding after preloading the load vertically downward. After removing the steel fittings 26a and 26b to fix the PS steel 24 at both ends of the upper flange 16, and installing the sheath 28 and the reinforcing bars 18, the L-shaped formwork 20 is removed. After mounting and curing high-strength concrete 22, inserting and reinforcing the PS steel 24 into the steel fitting holes 26a and 26b and tensioning the parent cement portion I beam segment having a steel composite concrete upper flange in which prestress is introduced. Prestressed steel composite flange for continuous bridges characterized in that the manufacturing 10b I-beam segment connections that. The method of claim 1, The connection between the positive and the parent part I beam segments 10a and 10b is a-shaped steel bracket at both ends of the upper part of the connecting part 33 to prevent sagging after the mounting of the positive and parent part I beam segments 10a and 10b. 34), I-beam segment connection method having a pre-stressed rigid composite concrete upper flange for continuous bridges, characterized in that after placing a horizontal load with a hydraulic jack (36), pour non-contraction concrete (38). delete delete

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