KR20190094644A - Prestressed Steel-Concrete Composite Girder - Google Patents

Abstract

The present invention relates to a prestressed steel composite girder, which is easy to place concrete on an upper side portion of a lower flange of I-shaped steel, is integrally composed with the steel, and implements tensile force having a strong strand to reduce girder depth and improve durability. That is, the present invention includes: an upper flange; a web plate connected to the bottom of the upper flange; I-shaped steel formed by a lower flange connected to a lower end of the web plate; a cylindrical concrete filling unit allowing concrete to be placed in a space part formed by attaching a cover member to an upper side of the lower flange; a stud bolt installed in the concrete filling unit; and a strand inserted into a sheath tube provided in a concrete part placed in the concrete filling unit to be cured and having tensile force.

Description

Prestressed Steel-Concrete Composite Girder}

The present invention relates to a prestressed steel composite girder, and more specifically, it is easy to place concrete on the upper side of the lower flange of the steel of I-type, and it is synthesized integrally with the steel and the strand is exerted a strong tension to form the girder. The present invention relates to a prestressed composite girder capable of reducing the height and increasing durability.

In general, concrete has excellent resistance to compressive stress, but resistance to tensile stress is very weak. Therefore, when a girder including concrete is used, the tension of concrete generated by dead or live load acting on the girder Consideration should be given to offsetting stresses.

To this end, the high-strength strand is tensioned to the girders including concrete, and compressive stress is introduced into the concrete in advance, thereby making it possible to offset the tensile stress generated in the concrete according to the dead load or live load acting on the girder during public use. .

The girders (prestressed girders) in which compressive stress is introduced by such strands are prestressed concrete girders made of concrete only and steel of I type, depending on the composition of the material forming the girders. It is divided into Prestressed Steel Composite Girder with concrete section at the bottom of

Prestressed concrete girders are eccentric along the axis of symmetry at both ends of the girders by embedding a tension member inside the reinforced concrete girder, projecting both ends of the tension member to the outside of both ends of the girder, and then tensioning the tension member using hydraulic devices. By applying the compressive force to have to cancel the tensile stress occurring in the reinforced concrete girder, the tension method has a pretension method and post-tension method depending on the tensioning method of the tension material.

However, when the load capacity of the existing bridge constructed by using the prestressed concrete girder is reduced, the brackets are fixed to both ends of the prestressed concrete girder, and both ends of the tension member are fixed to the brackets using the anchorage, and then the hydraulic pressure is reduced. Girder girder steel method is used to make the girders stronger by tensioning with the device, but such a method has a problem that there are many difficulties in management as it is girder strong at the stage where the load capacity of the existing bridge is already lowered.

In addition, the conventional method is due to the partial pre-stressing causes the tensile cracking of the concrete in the lower flange, so that corrosion occurs on the lower surface, there was a problem between the short length.

Prestressed steel composite girders are steel of I-type, hardened concrete laid to enclose the lower flange of the steel, strands formed to apply compressive stress to the concrete at both ends of the concrete, and anchors fixing both ends of the PC strand It is configured to include.

The prestressed composite girder is configured to introduce compressive stress into the concrete only by the tension of the strand wire installed in the concrete without applying bending deformation to the steel.

Such prestressed girder can reduce the burden on the weight of concrete when the tension is introduced, thereby increasing the tension efficiency and reducing the height of the girder for the same area.

However, in the conventional prestressed steel composite girders, the concrete placed on the lower flange has to reinforce a lot of reinforcing bars to reinforce the internal tension, and the steel wire is inserted into the sheath pipe that is provided in a straight line inside the concrete. Increasing the tension force, the cost and time for the tension work increases, the height of the girder heightened, there was also a problem of falling durability.

KR 10-0948896 KR 10-1151773 KR 10-1275000 KR 10-1664165 KR 10-1581752

The present invention has been made in order to solve this problem, by the concrete filling part by attaching a cover member on the upper side of the lower flange of the I-shaped steel to facilitate the concrete pouring while concrete and steel to be integrally synthesized, concrete The inner sheath pipe provides the prestressed composite girders that the strands can exert strong tension and lower the height of the girders and increase their durability.

 The present invention comprises an upper flange, an abdominal plate connected to the bottom of the upper flange, an I-type steel consisting of a lower flange connected to the lower end of the abdominal plate, and a space portion formed by attaching a cover member to the upper side of the lower flange. It includes a cylindrical concrete filling portion to allow concrete to be poured, a stud bolt installed inside the concrete filling portion, and a stranded wire inserted into a sheath tube provided inside the concrete portion to be poured into the concrete filling portion to have tension. It features prestressed rigid composite girders.

The cover member is composed of an upper surface plate and a side plate formed by bending one side end of the upper surface plate and a pair of cover members opposed to each other. Each upper plate is attached to both sides of the abdominal plate of the steel so as to face each other. The upper surface of the lower flange is characterized in that each side plate is attached.

The concrete filler is characterized in that formed on both sides based on the abdominal plate of the steel.

The cover member is characterized in that it is provided with an upper surface plate is formed in the curved surface portion in the direction of the cross-sectional direction at both side points in the longitudinal direction of the girder.

The sheath pipe is characterized in that the curved surface forming portion is provided in the direction of the cross-sectional direction at both side points in the longitudinal direction of the girder.

The prestressed rigid girder according to the present invention is constructed by a cylindrical concrete filling part formed by attaching a cover member to an upper side of a lower flange of an I-type steel, and the steel material and the concrete part are synthesized integrally, and thus the outer part of the concrete part is covered with a cover member. This greatly increases the concrete portion formed on the upper side of the lower flange of the steel has the effect of reducing the material while reducing the mold height of the girder.

In addition, the sheath pipe provided in the concrete portion of the present invention can be fixed by exerting a strong tension applied to the stranded wire at the anchorages at both ends of the girder by the curved surface forming portion that is raised in the cross-sectional direction at both points in the longitudinal direction of the girder. It has an effect.

1 is a cross-sectional view showing the configuration of a prestressed rigid composite girder according to the present invention.
Figure 2 is a side cross-sectional view showing the line AA 'of Figure 1 in the prestressed rigid girder according to the present invention.
Figure 3 is a side cross-sectional view showing the line B-B 'of Figure 1 in the prestressed rigid girder according to the present invention.
Figure 4 is a side cross-sectional view showing the configuration of a conventional prestressed rigid girder.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

According to the present invention, an upper flange 110, an abdominal plate 120 connected to a bottom surface of the upper flange 110, and a lower flange 130 connected to a lower end of the abdominal plate 120 to form a prestressed rigid girder. It is provided with an I-type steel 100 made of).

The upper surface of the upper flange 110 has a plurality of stud bolts 112 are installed to be coupled to the slab concrete is placed on the upper flange 110, the upper flange 110 and the slab concrete layer can be combined integrally. Make sure

In addition, a cylindrical concrete filling part 300 in which concrete is poured is provided on the space formed by attaching the cover member 200 to the upper side of the lower flange 130, and the space part of the concrete filling part 300 is rectangular or It may be provided in a variety of polygons, etc., but it is preferable to provide a quadrangle easy to promote workability or durability.

The stud bolt 310 is installed inside the concrete filling part 300, but the upper surface of the lower flange 130 of the steel material 100 positioned inside the concrete filling part 300 and the upper plate 210 of the cover member 200. And the stud bolts 310 are installed on the inner surface of the side plate 220, respectively, the concrete portion 400 is formed by pouring concrete in the concrete filling portion 300 is the steel member 100 inside the cover member 200 To be synthesized in an integrally coupled state.

The sheath pipe 500 is provided inside the concrete part 400 that is poured into the concrete filling part 300 to insert the strand wire 600, and then the strand wire 600 is fixed by the fixing holes 700 at both ends of the girder. It will settle with tension applied.

The cover member 200 forming the cylindrical concrete filling part 300 consists of a top plate 210 and a side plate 220 formed by bending one side end of the top plate 210 and facing each other. Of the cover member 200.

Each upper plate 210 is attached to both sides of the abdominal plate 120 of the steel 100 by using a pair of cover members 200 as described above to face each other, and the upper surface of the lower flange 130 of the steel 100. Each side plate 220 is attached.

That is, the concrete filling part 300 is divided by a configuration in which the cover members 200 are respectively attached to both sides of the abdominal plate 120 of the steel 100 by the pair of cover members 200. The concrete is poured into the divided concrete filling unit 300 so that the steel 100 and the concrete are integrally synthesized.

In addition, the upper surface plate 210 of the cover member 200 has a curved surface portion 212 is formed in both sides of the girder longitudinal direction in the direction of the cross-sectional direction is formed in the upper portion of the inlet for placing concrete in the concrete filling section 300 In addition to facilitate the concrete placing through the expanded portion to facilitate the placement of the sheath pipe 500 having the curved surface forming portion 510 to be described later.

The sheath pipe 500 is provided inside the concrete part 400 to be poured into the concrete filling part 300 to insert the strand 600, but the sheath pipe 500 is changed at both sides of the girder in the longitudinal direction. The curved surface forming portion 510 is provided in the cross-sectional direction.

The curved surface forming portion 510 of the sheath pipe 500 is formed to form a curved surface corresponding to the curved surface portion 212 formed on the upper surface plate 210 of the cover member 200, the curved surface of the sheath pipe 500 The thickness layer of the concrete portion 400 located above the portion 510 is not thinner than the middle portion of the girder and corresponds to a compressive stress with a thickness layer that is substantially the same or wider.

The curved surface forming portion 510 of the sheath pipe 500 is upwardly in the direction of the cross-sectional surface at both side points in the longitudinal direction of the girder, thereby being inserted into the sheath pipe 500 so as to have a tension force by the anchorage 700. It is easy to work on the tension of the) so that the strong tension can be exerted.

Hereinafter, the embodiment of the prestressed rigid girder according to the present invention will be described in detail.

Prestressed rigid girder according to the present invention is concrete is poured into the concrete filling portion 300 formed by attaching the cover member 200 on the upper side of the lower flange 130 of the steel 100 in the longitudinal direction of the girder as shown in FIG. The concrete part 400 will be formed.

At this time, the cover member 200 is formed by the concrete filling part 300 is divided by the configuration in which a pair of cover members 200 are attached to both sides of the abdominal plate 120 of the steel material 100 and the concrete filling part The stud bolt 310 is installed on the inner side of the 300 and the steel material 100 and the concrete part 400 are integrally synthesized, and the outer part of the concrete part 400 is wrapped with the cover member 200 so that durability is greatly increased. It is possible to reduce the mold height of the girder since the concrete portion 400 is formed on the upper side of the lower flange 130 of the steel material 100.

In addition, the upper surface plate 210 of the cover member 200 according to the present invention has a curved surface portion 212 is formed in both sides of the girder longitudinal direction in the direction of the cross-sectional direction to cast concrete on the concrete filling section 300 In order to facilitate the concrete pouring through the portion of the inlet upper side for expansion and facilitate the arrangement of the sheath pipe 500 having the curved surface forming portion 510 to be described later.

The sheath pipe 500 is provided inside the concrete part 400 to be poured into the concrete filling part 300 to insert the strand 600, but the sheath pipe 500 is changed at both sides of the girder in the longitudinal direction. The curved surface forming portion 510 is provided in the cross-sectional direction.

That is, the curved surface forming portion 510 of the sheath tube 500 has a curved surface corresponding to the curved portion 212 formed on the upper surface plate 210 of the cover member 200, the curved surface of the sheath tube 500 The thickness layer of the concrete portion 400 located on the upper portion of the forming portion 510 is not thinner than the middle portion of the girder, and thus may correspond closely to the compressive stress with a substantially equal or wide thickness layer.

In addition, the strand 600 is inserted into the sheath pipe 500 by the curved surface forming portion 510 which is upward in the cross-sectional direction of the sheath pipe 500 provided in the concrete portion 400, the fixing holes 700 at both ends of the girder. Exhibits a strong tension applied to the strand 600 to be able to settle.

As described above, the prestressed rigid girder of the present invention is formed by the cylindrical concrete filling part 300 formed by attaching the cover member 200 to the upper portion of the lower flange 130 of the I-type steel 100 and the steel 100. Since the concrete part 400 is synthesized in an integrated state, it is not necessary to use as many rebars as in the prior art, so that the work is convenient and material saving is made, and the outer part of the concrete part 400 is covered with the cover member 200. Due to the large increase in durability as well as to form the concrete portion 400 on the upper side of the lower flange 130 of the I-type steel 100 can reduce the mold height of the girder.

In addition, since the sheath pipe 500 provided in the concrete part 400 of the present invention has a curved surface forming part 510 which is upward in the cross-sectional direction at both side points in the girder longitudinal direction, the sheath pipe 500 is inserted into the sheath pipe 500. The strand 600 will be able to settle by exerting a strong tension in the anchorages at both ends of the girder.

In the above, the present invention has been described with reference to the above embodiment, but various modifications can be made within the technical scope of the present invention.

100: steel 110: upper flange
112: stud bolt 120: abdominal plate
130: lower flange 200: cover member
210: upper plate 212: curved portion
220: side plate 300: concrete live part
310: stud bolt 400: concrete part
500: sheath tube 510: curved surface forming portion
600: strand 700: anchorage

Claims (5)

I-type steel (100) consisting of an upper flange (110), an abdominal plate (120) connected to the bottom of the upper flange (110), and a lower flange (130) connected to a lower end of the abdominal plate (120),
A cylindrical concrete filling part 300 in which concrete is poured into a space formed by attaching the cover member 200 to the upper side of the lower flange 130;
A stud bolt 310 installed inside the concrete filling part 300;
Prestressed steel composite girders, characterized in that it comprises a strand 600 to be inserted into the sheath pipe 500 is provided in the interior of the concrete portion 400, which is poured into the concrete filling portion 300 to have a tension force.
The method of claim 1,
The cover member 200 is composed of a top plate 210 and a side plate 220 formed by bending one side end of the top plate 210 and a pair of cover members 200 facing each other. Each of the upper plate 210 is attached to both sides of the abdominal plate 120 of the (100) facing each other and the side plate 220 is attached to the upper surface of the lower flange 130 of the steel 100 is characterized in that the configuration Prestressed composite girder.
The method of claim 1,
The concrete filling unit 300 is prestressed steel composite girders, characterized in that formed on both sides based on the abdominal plate 120 of the steel material (100).
The method of claim 1,
The cover member 200 is a prestressed girder, characterized in that provided with the upper surface plate 210 is formed with a curved surface portion 212 is raised in the direction of the cross-sectional direction at both sides of the girder longitudinal direction.
The method of claim 1,
The sheath pipe 500 is prestressed girder, characterized in that the curved surface forming portion 510 is provided in the direction of the cross-sectional direction at both side points in the longitudinal direction of the girder.

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