KR20130135431A - Trust type prestressed concrete girder and manufacturing method for the same - Google Patents

Abstract

A trust type pre-stressed concrete girder according to the present invention is configured of an upper member, a web inclined member, and a lower member, wherein the web inclined member and the lower member are integrally formed of reinforced concrete, and applies pre-stress to the web inclined member and the lower member by at least one tendon continuously passing through the web inclined member and the lower member in which tensile force is generated by an external load. Further, the manufacturing method for a trust type pre-stressed concrete girder according to the present invention includes: a first step of preparing a mold in which a lower member and a web inclined member are molded; a second step of installing a rebar in the location where the web inclined member and the lower member are to be molded in the mold and installing a sheath duct passing the web inclined member and the lower member; a third step of forming the lower member and the web inclined member by pouring concrete in the mold; a fourth step of inserting a tendon in the sheath duct so as to pass through the web inclined member and the lower member; and a fifth step of installing a mounting device in both ends of the tendon and introducing pre-stress.

Description

TRUST TYPE PRESTRESSED CONCRETE GIRDER AND MANUFACTURING METHOD FOR THE SAME}

The present invention relates to a truss type prestressed concrete girder, wherein the truss type girder composed of an upper member, an abdominal slope member and a lower member is integrally formed with a reinforced concrete material and the abdominal slope member and the lower member By arranging the tension member passing through the interior continuously, the present invention relates to a truss type prestressed concrete girder that is light and economical and does not require a separate assembly process.

Girder is a structure installed on the bridge to support the load of the bridge in the bridge. Generally, girders commonly used in bridges include beam girders and truss girders. Beam-type girders are easier to manufacture than truss-type girders, but they are often used for bridges with shorter gaps because of their higher weight and sagging.Truss-type girders are less weight to bear than beam-type girders. It is widely used in bridges that have a long distance and have to support large loads.

There are various types of truss type girders, but the upper and lower chords are made of reinforced concrete, and the composite member is made of steel such as steel pipes. The composite truss girder combines the steel abdominal inclined material between the reinforced concrete upper and lower members. The abdominal inclined material made of segments near the bridge construction site is combined with the upper and lower members and the prestress is introduced into the lower member. It is mainly constructed by installing on the top.

Such a composite truss girder has been mainly used when the distance between the piers is far smaller than the beam type truss girder, due to the heterogeneity between the upper and lower members made of concrete and the double members made of steel, A connecting member was installed and the abdominal slope material was used in combination. In this case, there is a reinforcement problem to structurally stabilize the load by concentrating the load on the junction of the upper and lower members and the abdominal inclined material, and there is inefficiency in the construction of the upper and lower members and the abdominal inclined material separately. The need for continuous management due to corrosion of the steel has been a disadvantage that can cause serious problems in the safety of bridges.

The present invention has been made in order to solve the above problems, by integrally molding the lower member and the abdominal inclined material with reinforced concrete material, by arranging the tension member through the abdominal inclined material and the lower member continuously, The purpose of the present invention is to provide a truss type prestressed concrete girder with excellent durability and economy while maintaining the advantages of a light and rigid composite truss girder by simultaneously introducing prestress to the lower member.

The truss type prestressed concrete girder according to the present invention for achieving the above object is composed of an upper member and an abdominal inclined material and a lower member, wherein the abdominal inclined material and the lower member are integrally formed of reinforced concrete material,

It is characterized in that the prestress is provided to the abdominal inclined member and the lower member by at least one tension member which continuously passes through the abdominal inclined member and the lower member, which is caused by an external load.

In this case, the lower member may be characterized in that at least one tension member for providing a prestress to the lower member via some or all of the lower member is further installed.

In addition, the upper material may be any one of a reinforced concrete material formed integrally with the abdominal slope material or a steel material coupled to the abdominal slope material by a shear connecting material.

In addition, when the truss type prestressed concrete girder according to the present invention is applied to a simple bridge, the tension member, the lower member between the abdominal inclined materials and the abdominal inclined materials in a position symmetrical with respect to the center of the girder. It may be characterized in that it is installed to pass through.

In addition, when the truss type prestressed concrete girder according to the present invention is applied to the continuous bridge, the tension member is installed to pass through the lower member between the abdominal inclined materials and the abdominal inclined material having the most similar magnitude of tensile force applied. Become,

The upper material may be further provided with one or more tension members that provide prestress to the upper material via some or all of the upper material.

According to the present invention, a method of manufacturing a truss type prestressed concrete girder includes a first step of preparing a form for forming a lower member and an abdominal slope material, and wires reinforcing bars at positions where the lower member and abdominal slope material are to be formed on the formwork, and the abdomen A second step of installing a sheath pipe through the inclined material and the lower member; and a third step of forming the lower member and the abdominal slope material by placing concrete in the formwork; and through the abdominal slope material and the lower member to the sheath pipe. And a fourth step of inserting the tension member and a fifth step of installing a fixing device at both ends of the tension member and introducing prestress.

The truss type prestressed concrete girder according to the present invention is lighter and more rigid than the beam type prestressed concrete girder, and is easy to use in the construction of bridges having a long distance between piers.

In addition, the present invention solves the safety problem due to the concentration of the load point in the composite truss girder that the upper and lower members are made of reinforced concrete and the abdominal slope is made of steel, such as steel pipes, bridges due to corrosion of steel It solves the problem of deterioration of durability, and is light, strong and durable.

1 is an illustration of the tension material arrangement of the truss-type prestressed concrete girder according to the present invention.
2 is a plan view corresponding to FIG.
Figure 3 is an exemplary view when the tension member is disposed on the lower member of the concrete girder.
Figure 4 is an illustration of the tension material arrangement when the upper material of the concrete girder is steel.
5 is an exemplary view of a concrete girder including a vertical member.
6 is an exemplary view in which the tension material is disposed on the upper material of the concrete girder used in the continuous bridge.
7 is another exemplary diagram in which the tension member is disposed on the concrete girder.
8 is a view showing a fixing point of the tension member in the concrete girder.
9 is another exemplary view in which the tension member is disposed on the concrete girder.
10 is a perspective view when the upper material of the concrete girder is steel.
11 is a view showing a state of coupling of steel material to the upper point of the concrete girder.
12 is various embodiments in which the tension material is disposed on the concrete girder.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

Next, a truss type prestressed concrete girder according to a preferred embodiment of the present invention will be described with reference to FIGS. 1 to 13.

1 is an exemplary view showing a state in which the tension member 40 is disposed in the truss type prestressed concrete girder according to the present invention. The truss girder is composed of an upper member, an abdominal member and a lower member. The abdominal member includes an abdominal inclined member (or inclined member) installed in an inclined direction on the upper member and the lower member and a vertical member installed in a direction perpendicular to the lower member and the upper member.

The truss type prestressed concrete girder shown in FIG. 1 is composed of an upper member 10, an abdominal inclined member 20, and a lower member 30, and passes through the interior of the abdominal inclined member 20 and the lower member 30. The tension member 40 is installed. The tension member 40 may select a steel wire or a bundle of steel wires that are commonly used. As shown in FIG. 1, when prestress is introduced to the abdominal bevel material 20, the abdominal bevel material may be manufactured from reinforced concrete, unlike steel materials or the like, in a conventional composite truss girder. The biggest advantage of manufacturing the abdominal bevel material 20 in reinforced concrete is that unlike the composite truss girder, there is no need for a separate connecting member connecting the abdominal bevel material 20 and the lower member 30. This is because the abdominal inclination material and the lower member are made of the same material and can be manufactured integrally. The reason that the abdominal inclined material is not used as reinforced concrete in the past is that the reinforced concrete is able to withstand the compressive force well, but when the abdominal inclined material made of reinforced concrete material is easily destroyed at the point where the tensile force occurs due to the weak tensile force, to be. In order to solve this problem, in the present invention, the abdominal bevel material 20 is made of reinforced concrete, but is integrally formed with the lower member 30 and prestress is introduced into the abdominal bevel material 20.

The following table compares the axial force and the bending moment when the prestress is not applied to the abdominal inclined material and the lower member of the truss girder and when the prestress is introduced.

shaft
Force

Tensile force
remove

Bending moment

30%
decrease

As shown in Table 1 and Table 2, when the prestress was introduced to the abdominal inclined member and the lower member, the tensile force applied to the abdominal inclined member and the lower member was removed, and only the compressive force remained, and the bending moment was reduced by about 30%. Seems. In view of these results, if prestress is introduced into the abdominal inclined material, even if the abdominal inclined material made of reinforced concrete material that is weak in tensile force is not affected, the stability is not affected at all.

In the introduction of prestress to the abdominal inclined material, if the tension member is provided only via the abdominal inclined material, it is inevitably inferior to the rigidity of the lower point (the point where the lower member and the abdominal inclined material connect) or a separate protrusion below the lower member. Construction difficulties, such as the need to form a type anchorage will occur. Therefore, in order to solve this problem, it is most preferable to install the tension member passing through the abdominal slope material so as to continuously pass through the lower member.

As shown in FIG. 1, the tension member 40 has one end fixed to an upper end portion 15 of the abdominal inclination member 20 and reaches the descending point part 25 via the abdominal inclination member 20. After passing through the other lower point 25 through another abdominal slope material 20 through 30) may be installed so that the other end is fixed to the upper end of the other upper point 15.

In addition, as shown in FIG. 9, the tension member 40 has one end fixed to an upper end portion 15 of the abdominal bevel material 20 and reaches a lower point 25 via the abdominal bevel material 20. After passing through the lower member 30 of the section, the other end may be fixed to the other lower point 25.

When the tension member 40 passes through the abdominal slope member 20 and the lower member 30, the tension member 40 is not limited to that illustrated in FIG. 1 or 9, and the tension member may be disposed in various forms. Arrangement of the tension member 40 shown in Figure 7 is one example. If the gap between the pier is inevitably increases the height of the girder, if the height of the girder increases the angle formed by the abdominal slope material and the lower member becomes difficult to insert the wire into the sheath tube (not shown). In this case, as shown in FIG. 5, the vertical member 35 is disposed between the abdominal inclined members 30.

As described above, even when the tension member 40 continuously passing through the abdominal inclination material 20 and the lower member 30 is introduced and the prestress is simultaneously introduced into the abdominal inclination material 20 and the lower member 30, the abdominal inclination is also normal. Since a greater tensile force is generated in the lower member 30 than the ash 20, sufficient lower prestress is not provided to the lower member 30, so that the tension member 41 passing through part or all of the lower member 30 is further added. Need to install 6 is an exemplary view in the case where the tension member 41 is disposed on the lower member 30. As shown in FIG. 3, a plurality of tension members 41 may be disposed at the center of the girder where the tensile force is concentrated. In general, for convenience of construction, the lower member is often introduced with a predetermined prestress by fixing a tension member at both ends of the lower member. This is because it is difficult to separately install a protruding anchorage in order to introduce different prestresses for each section. Likewise, when the abdominal slope material and the lower member are integrally formed with reinforced concrete material, such difficulty is solved.

The upper material 10 of the truss type prestressed concrete girder according to the present invention may be selected from reinforced concrete or steel (10a). When the upper material is molded of reinforced concrete, it is molded integrally with the abdominal sloped material. In this case, since the upper member, the abdominal slope member and the lower member are all made of reinforced concrete, it can be molded integrally. In the case of forming the upper material 10 as shown in Figure 12 in order to facilitate the casting of the upper concrete slab can be exposed to the upper surface of the upper material and fixedly coupled to the I-shaped steel.

If it is important to reduce the weight of the girder because it is difficult to mount the girder to the pier according to the working environment of the bridge, it is preferable to select the steel (10a) than to manufacture the upper material integrally with reinforced concrete. This is because the total weight of the girder is smaller when the upper material is steel than the reinforced concrete material. Steel is fixedly coupled to the upper end of the abdominal slope by using the shear connector 11, as shown in FIG. The girders combined with steel are installed on the pier, and then the upper concrete slab 50 is poured to complete the bridge.

When the truss type prestressed concrete girder according to the present invention is applied to a simple bridge, a stress distribution almost symmetric with respect to the center of the girder appears. That is, the abdominal warp members at the same distance from the center of the girder generate almost the same tensile force.

Accordingly, as shown in FIG. 1, when the tension member is installed to pass through the abdominal inclined members and the lower members therebetween, the distribution of the tensile force is similar, the necessary prestress can be introduced without excessive stress of the prestress.

In addition, when the truss type prestressed concrete girder according to the present invention is applied to a continuous bridge has a more complex distribution of axial force than a simple bridge. Therefore, at this time, the abdominal inclined material that generates the most similar tensile force at the design stage is analyzed by analysis, and then the abdominal inclined material having the similar tensile force is designed to pass through the tension material. In addition, in the case of the continuous bridge, since the tension is likely to occur in the upper material 10, which is usually located on the upper portion of the intermediate piers, as shown in FIG. Remove

13 illustrates various embodiments of trussed prestressed concrete girder. As shown in FIG. 13, both ends of the concrete girder may be formed so that the lower member is inclined. In this case, the center of gravity of the concrete girder is lowered while being mounted on the pier, thereby preventing the concrete girder from overturning.

Looking at the manufacturing method of the truss-type prestressed concrete girder according to the present invention, the first step of preparing a form for forming the lower member and the abdominal slope material, and wires the reinforcement to the position where the lower member and the abdominal slope material to be formed in the formwork, The second step of installing a sheath pipe through the abdominal inclined material and the lower member; and the third step of forming concrete in the formwork and forming the lower member and the abdominal inclined material; and the abdominal inclined material and the lower member through the sheath pipe. And a fifth step of inserting the tension member so as to install a fixing device at both ends of the tension member and introducing a prestress. In manufacturing the girder according to the above production method, the lower member and the abdominal inclined material may be molded simultaneously, or the abdominal inclined material may be molded after a predetermined time has elapsed after the lower member is molded. When the upper material is selected as reinforced concrete, the lower member, the abdominal inclined material and the upper material may be molded in sequence or simultaneously.

10, 10a: upper material
15: upper point
20: abdominal bevel material
25: lower hit point
30: lower member
35: vertical material
40, 40a, 40b, 40c, 41, 42: tension member
50: upper concrete slab

Claims (6)

In the truss girder composed of the upper member, the abdominal inclined material and the lower member,
The abdominal slope material and the lower member is integrally molded of reinforced concrete material,
A truss-type prestressed concrete girder, characterized by providing prestress to the abdominal inclined member and the lower member by at least one tension member continuously passing through the abdominal inclined member and the lower member, which is caused by an external load.
The method of claim 1,
The truss type prestressed concrete girder, characterized in that the lower member is further provided with at least one tension member for providing a prestress to the lower member via part or all of the lower member.
The method of claim 1,
The upper material is a truss-type prestressed concrete girder, characterized in that any one of the reinforced concrete material formed integrally with the abdominal slope material or a steel material coupled to the abdominal slope material by a shear connection material.
The method of claim 1,
When the truss type prestressed concrete girder is applied to a simple bridge,
The tension member is a truss type prestressed concrete girder, characterized in that it is installed to pass through the lower member between the abdominal inclined materials and the abdominal inclined material in a symmetrical position with respect to the center of the girder.
The method of claim 1,
When the truss type prestressed concrete girder is applied to the continuous bridge,
The tension member is installed so as to pass through the abdominal inclined materials and the lower member between the abdominal inclined materials having the most similar magnitude of tensile force applied,
The truss type prestressed concrete girder, characterized in that the upper material is further provided with one or more tension members to provide the prestress to the upper material via part or all of the upper material.
In the manufacturing method of the truss type prestressed concrete girder,
A first step of preparing a formwork to be molded with the lower member and the abdominal slope material;
A second step of installing reinforcing bars at positions where the lower member and the abdominal bevel material are to be formed on the formwork and installing a sheath tube through the abdominal bevel material and the lower member;
A third step of forming a lower member and an abdominal slope material by pouring concrete into the formwork;
Inserting a tension member into the sheath tube through the abdominal slope member and the lower member; And
And a fifth step of installing fixing devices at both ends of the tension member and introducing prestress.

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