KR102276215B1 - Point part structure for prestressed concrete beam bridge - Google Patents

Abstract

The present invention relates to a point part structure of a prestressed concrete beam bridge, comprising: a pedestal device configured on an upper part of a pier and an abutment; and a prestressed concrete beam including an attachment steel plate configured at a position opposite to the pedestal device and attached to the pedestal device, and a mounting/lifting reinforcing plate configured in a position opposite to a temporary support or a hydraulic jack installed on the upper part of the pier and the abutment adjacent to the attachment steel plate. The present invention can prevent deterioration in structural rigidness.

Description

Point part structure for prestressed concrete beam bridge

The present invention relates to a structure in which horizontal mounting of a prestressed concrete beam is facilitated when mounting or raising a prestressed concrete beam in a branch portion of a prestressed concrete beam bridge, damage, etc. are controlled, and overturning can be controlled.

A bridge is a structure that allows crossing over a river, lake, strait, bay, canal, valley, or other transportation route or structure, and is composed of a pier or abutment, a girder installed on a pier or abutment, and a slab installed on the girder.

The bridge construction method is constructed in the order of erecting a plurality of piers or abutments and mounting a plurality of girders on the piers or abutments. At this time, the girders are not fixed to the piers or abutments, but are placed on a temporary bearing. In this way, a number of girders are mounted on the pier and the top plate is constructed by pouring slab concrete on the upper part of the girders.

Here, the Prestressed Concrete Beam (hereinafter referred to as "PSC Beam") bridge uses a PSC beam as the upper girder. Compared to other construction methods such as steel bridges, the construction cost is lower, there is no corrosion, and it has good durability and maintenance. It is a widely used construction method because it is possible to construct a relatively long-span bridge due to low maintenance cost and low deflection or vibration. It is a method of constructing a slab by manufacturing a PSC beam on the ground and placing it on a pier or abutment. The PSC beam used here is a structural member with a high height compared to its width, and since the center of gravity is located at the top, it is possible to conduct even a small lateral force. This has a very high disadvantage.

In particular, since it takes a long time to put the PSC beam on the pier or abutment and pour the slab, the incidence rate of the beam falling due to the overturning of the beam is very high.

As an example for solving this problem, in Korean Patent Registration No. 10-1713653, a pedestal device is installed on the upper surface of the pier, and a beam body on the pedestal device, a predetermined distance along the longitudinal direction of the beam body, and the circumference of each beam body As it protrudes at a right angle in the form of a crossbeam from the part, the upper end is reinforced with reinforcing bars at the same height as the beam body, and is formed in a rectangular integral form through concrete, and the bottom is installed on the upper part of the pier

A bridge construction method using a fall prevention PSC beam is proposed, which is supported on a pedestal to prevent overturning and installs two or more fall-prevention PSC beams composed of a fall-prevention part used as a crossbeam.

However, in the case of the above technology, the effect of overturn prevention is expected, but when installing the PSC beam, a temporary screw jack of 50 Ton or more is usually installed before and after the abutment and pier seating devices, and the PSC beam is mounted on the top of the temporary bearing (Screw Jack) As shown in FIG. 7, the concrete surface under the PSC beam is not produced flat without irregularities and a lot of irregularities occur, making horizontal mounting difficult, and the concrete of the PSC beam in contact with the temporary support is damaged or cracked, and often There is a problem in that a fall accident occurs due to overturning during or after mounting.

In addition, in the case of raising work using hydraulic jacks to replace the seat system during public use, the PSC beam, slab, bridge auxiliary facilities, and vehicle load act in a complex way, causing the concrete under the PSC beam to be damaged or cracked, which impairs structural integrity. there is a problem.

Korean Patent Registration No. 10-1713653

Accordingly, it is an object of the present invention to provide a structure of a point part that can prevent a PSC beam from being damaged when the PSC beam is mounted or raised and enables horizontal mounting to control safety accidents such as overturning.

As a means for solving the above-mentioned problems, the branch structure of the prestressed concrete beam bridge of the present invention (hereinafter referred to as "the structure of the present invention") includes: a pedestal device configured on a pier or abutment; It includes an attachment steel plate configured at a position opposite to the seating device and attached to the seating device, and a mounting/lifting reinforcing plate configured in a location opposite to a temporary support or hydraulic jack installed on a pier or abutment adjacent to the attachment steel plate. It is characterized in that it comprises a; prestressed concrete beam.

As an example, the mounting/lifting reinforcing plate is characterized in that it is composed of a plurality of studs embedded in the beam body and a reinforcing plate body in which the surface opposite to the temporary support or hydraulic jack is exposed from the beam body.

As an example, the reinforcing plate body is characterized in that it is composed of a steel plate in which the stud protrudes and is in contact with the beam body, and an elastic plate attached to the steel plate so that the exposed surface is soft with the beam body.

As an example, the elastic plate and the beam body are in contact with a protective frame is composed of an elastic material is characterized in that the protective frame is attached only to the beam body.

As an example, a plurality of fastening holes are formed in the reinforcing plate body, and a fastening protrusion opposite to any fastening hole is formed on the plate of the temporary support, so that the fastening protrusion is inserted into the opposite fastening hole according to the mounting position of the temporary support. characterized.

As an example, a screw thread is formed in the fastening hole, a second fastening hole in which a screw thread is formed is formed in the plate, and the fastening protrusion is threaded so that it is fastened by rotation to the opposite fastening holes and second fastening holes, respectively. characterized in that

As described above, the structure of the present invention prevents cracks and damage of the beam body made of concrete when the PSC beam is mounted on a pier or abutment or when the PSC beam is raised using a hydraulic jack to replace the pedestal device, thereby preventing deterioration of structural integrity. There are advantages to doing so.

1 and 2 are cross-sectional views showing the structure of the present invention.
3 is a schematic diagram of one embodiment of the present invention;
4 and 5 are a cross-sectional view and a bottom view showing another embodiment of the present invention.
6 is a cross-sectional view showing another embodiment of the present invention.
7 is a photograph showing the lower surface of the PSC beam.

Hereinafter, the configuration and operation of the present invention will be described in more detail based on the accompanying drawings. In describing the present invention, the terms or words used in the present specification and claims are based on the principle that the inventor can appropriately define the concept of the term in order to best describe his invention. It must be interpreted as a meaning and concept consistent with the technical idea of

Structure (1) of the present invention, as shown in Figures 1 and 2, a pier (a) or abutment (b) a pedestal device (2) configured on the top; An attachment steel plate 31 which is configured at a position opposite to the bridge seat device 2 and is attached to the bridge seat device 2, and adjacent to the attachment steel plate 31, it is installed on the pier (a) or the abutment (b) Prestressed concrete beam (3) comprising a temporary support (4) or a mounting/lifting reinforcing plate (32) configured at a position opposite to the hydraulic jack;

That is, the structure (1) of the present invention is a PSC beam (3) during mounting and raising of the PSC beam (3) at the junction of the pier (a) or abutment (b) and the PSC beam (3) in the prestressed concrete beam bridge. ) to control damage or overturning.

Since there are various known technologies of the seat device 2, a detailed description thereof will be omitted.

The PSC beam 3 includes a beam body 33 made of concrete, an attachment steel plate 31 as configured on the lower surface of the drawing of the beam body 33, and a mounting and lifting reinforcing plate 32 characterized in that Of course, the beam body 33 is not shown in the drawings, but the known configuration of the existing PSC beam is included, such as a tension reinforcing bar to which pre-stress is introduced.

The attachment steel plate 31 can be attached by a known method such as welding with the pedestal device 2 that is already installed on the pier (a) or the pier (b) after the PSC beam 3 is mounted on the temporary support (4). configuration to be

In particular, in the present invention, the temporary support (4) installed on the pier (a) or the abutment (b) as shown in FIGS. 1 and 2 by pre-configuring the mounting/lifting reinforcing plate 32 on the beam body 33 . When raising the PSC beam (3) with a hydraulic jack, such as when mounted on a pedestal or replacing the seat device (2), the temporary support (4) or the hydraulic jack is placed in contact with the beam body (33) to prevent damage to the beam body (33), and at the same time, the horizontal mounting This is to make it possible to control overturning.

The mounting and lifting reinforcing plate 32 has a plurality of studs 321 embedded in the beam body 33 and a reinforcing plate body 322 in which the surface opposite to the temporary support 4 or the hydraulic jack is exposed from the beam body 33 . ) is characterized in that it is composed of.

Here, it is reasonable to use a material superior in rigidity than concrete, such as steel, for the mounting/lifting reinforcing plate 32 .

As shown in FIG. 7, the reinforcing plate body 322 of the smooth surface is exposed on the lower surface of the beam body 33 having a surface in which the smoothness is decreased, so that the beam body (4) or the beam body when mounted or raised by a hydraulic jack ( 33) is to control the overturn by maintaining the horizontal, and to control the damage of the concrete beam body 33 by the rigidity.

On the other hand, in the case where a lateral load such as strong wind acts after the PSC beam 3 is mounted on the temporary support 4, damage may occur at the joint where the mounting/lifting reinforcing plate 32 is embedded in the beam body 33. Such failure may eventually lead to deterioration of the structural integrity of the entire structure.

Accordingly, in the present invention, an embodiment to solve the above problems by making it possible to absorb a certain amount of impact against such a lateral load is presented in FIG. 3 .

In this embodiment, as shown in FIG. 3, the reinforcing plate body 322 is a steel plate 322-1 and the steel plate 322-1 in which the stud 321 protrudes and is in contact with the beam body 33. It is attached to the exposed surface of the beam body 33 and is characterized in that it is composed of an elastic plate 322-2.

According to this configuration, the elastic plate 322-2 relieves the pressing force of the temporary support 4 or the hydraulic jack generated by the lateral load.

In addition, in this embodiment, the elastic plate 322-2 and the beam body 33 are in contact with the protective rim 323 is composed of an elastic material, the protective rim 323 is attached only to the beam body (33). More examples are provided.

The protective rim 323 is configured at a portion where the elastic plate 322-2 and the beam body 33 contact each other, as shown in the drawing, to alleviate the impact that may be applied to the beam body 33 .

For example, when the PSC beam 3 is placed on the temporary support 4, the placement operation to accurately contact the temporary support 4 with the elastic plate 322-2 can be completed through several corrections. This is to prevent the beam body 3 from collided with the support 4 and the elastic plate 322-2 around the beam body 3 from being damaged.

In particular, the protective rim 323 is attached only to the beam body 33, which is when the temporary support 4 presses the elastic plate 322-2, and the elastic plate 322-2 is the beam as shown in the drawing. It is to control the interference with the protective rim 323 in the body 33 and the gap (∂) is generated.

When the elastic plate 322-2 and the protective rim 323 are attached, the protective rim 323 is the beam body ( 33) There is a problem that may cause damage to the beam body (33) portion if this pressurization occurs repeatedly to pressurize the part.

Therefore, in the present invention, the protection frame 323 is attached only to the beam body 33, so that only when mounted as described above, the protection frame 323 protects the beam body 33 and the elastic plate 322-2. The elastic plate 322-2 generated by the elastic restoration of the beam body 33 and the gap (∂) are not to interfere with each other.

On the other hand, when a lateral load such as a strong wind is applied after the PSC beam 3 is mounted on the temporary support 4, the PSC beam 3 may be overturned. In the present invention, the resistance to such lateral load is improved to improve the resistance to the lateral load as described above. Examples to solve the problem are presented in FIGS. 4 and 5 .

In this embodiment, a plurality of fastening holes 324 are formed in the reinforcing plate body 322 , and the plate 41 of the temporary support 4 has a fastening protrusion 42 opposite to an arbitrary fastening hole 324 . is formed so that the fastening protrusion 42 is inserted into the opposite fastening hole 324 according to the mounting position of the temporary support 4 .

That is, a plurality of fastening holes 324 are formed in the reinforcing plate body 322, and the width of the reinforcing plate body 322 is larger than the plate 41 of the temporary support 4 as shown in FIG. A plurality of fastening protrusions 42 protruding from the plate 41 of the temporary support 4 while making it easy to mount the PSC beam 3 by (4) are each positioned opposite to the reinforcing plate body 322 when mounted. The fastening protrusion 42 is inserted into the opposing fastening hole 324 to control the overturn of the PSC beam 3 by a lateral load by rigid fixing.

In addition to this, an embodiment for more robust fixing of the plate 41 and the reinforcing plate body 322 of the above-mentioned temporary support 4 is presented in FIG. 6 , and in this embodiment, the fastening hole 324 has a screw thread. is formed, and a second fastening hole 411 in which a screw thread is formed is formed in the plate 41 , and the fastening protrusion 42 is composed of a head 421 and a bar-shaped body 422 , the body 422 is characterized in that the thread is formed so as to be fastened by rotation to the fastening hole 324 and the second fastening hole 411, respectively, which are opposed to each other.

That is, after the PSC beam 3 is mounted on the temporary support 4 , the second fastening hole 411 formed in the plate 41 of the temporary support 4 and the fastening hole 324 formed in the reinforcing plate body 322 are temporarily The temporary support 4 and the reinforcing plate body (4) by inserting and fastening the fastening protrusion (42) by rotation into the fastening hole (324) opposite to the second fastening hole (411) formed in the plate (41) of the base (4) ( 322 is to be firmly fixed to control the overturn of the PSC beam (3).

Those skilled in the art from the above description will be able to see that various changes and modifications are possible without departing from the technical spirit of the present invention. Accordingly, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

1: Structure of the present invention 2: Seating device
3: PSC beam

Claims (6)

a pedestal device configured on a pier or abutment; and
It includes an attachment steel plate configured at a position opposite to the seating device and attached to the seating device, and a mounting/lifting reinforcing plate configured at a location opposite to a temporary support or hydraulic jack installed on a pier or abutment adjacent to the attachment steel plate. A prestressed concrete beam that includes;
The mounting and lifting reinforcing plate,
It consists of a plurality of studs embedded in the beam body, and a reinforcing plate body in which the side opposite to the temporary support or hydraulic jack is exposed from the beam body,
The reinforcing plate body,
A steel plate in contact with the beam body, an elastic plate attached to the steel plate and having an exposed surface that is soft with the beam body, and an elastic material along a portion where the elastic plate and the beam body are in contact with the elastic plate are not attached to the elastic plate. The branch structure of the prestressed concrete beam bridge, characterized in that it includes a protective rim that is attached only to the beam body.
delete delete delete The method of claim 1,
A plurality of fastening holes are formed in the reinforcing plate body, and fastening protrusions opposite to any fastening holes are formed on the plate of the temporary support, and the fastening protrusions are inserted into the opposite fastening holes according to the mounting position of the temporary support. Branch structure of prestressed concrete beam bridge.
6. The method of claim 5,
A screw thread is formed in the fastening hole, a second fastening hole in which a screw thread is formed is formed in the plate, and a screw thread is formed in the fastening protrusion so that the fastening hole and the second fastening hole are fastened by rotation to the opposite fastening holes and second fastening holes Branch structure of prestressed concrete beam bridge with

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