KR101036199B1 - The bridge support change method of construction for which bridge upper part structure draw equipment and this were used - Google Patents

Abstract

PURPOSE: A bridge superstructure lifting device and a replacing method of a bridge bearing by using the same are provided to safely replace a bridge bearing without using a hydraulic jack. CONSTITUTION: A bridge superstructure lifting device comprises a hydraulic jack overturning prevention and bearing failure prevention plate(10), a hydraulic jack(20), a reinforcing material(30), a displacement preventing member(40), and a plate[(50). The hydraulic jack is installed on the hydraulic jack overturning prevention and bearing failure prevention plate in every direction. The reinforcing material is installed through the hydraulic jack phase. The displacement preventing member is installed in both sides on the reinforcing material. The plate is installed between the upper side of reinforcing material and the displacement preventing member.

Description

The bridge support change method of construction for which bridge upper part structure draw equipment and this were used}

The present invention relates to a bridge upper structure lifting device and a bridge bearing replacement method using the same, in particular, when the bridge bearing replacement, even if the bridge in the longitudinal, transverse gradient is large or the bending deformation of the superstructure is largely absorbed rotational deformation smoothly Simple reinforcement that can absorb horizontal displacement due to temperature expansion and contraction, hydraulic jack fall prevention and acupressure breaking prevention plate, displacement restraint and plate are installed in the existing hydraulic jack inexpensively and safely without using a special hydraulic jack. It relates to a bridge superstructure lifting device that can replace the bridge support and bridge support replacement method using the same.

In general, existing domestic bridges are not sufficiently designed for earthquakes, so earthquake-resistant reinforcement is required by replacing many bridge bearings in accordance with current seismic design specifications. Earthquake-resistant reinforcement work is done.

Here, the bridge is a bridge bearing is a device for transmitting various loads (vibration, earthquake, wind, temperature change) in the upper portion of the bridge, the bridge bearing, which has been applied from the past until now Existing method fills the space of the die with steel plate, steel pipe, H beam, etc. on the top or bottom of the hydraulic jack, raises the bridge upper structure by operating the hydraulic jack, and raises the existing bridge bearing while raising the bridge upper structure. After dismantling, install the new bridge support.

This is because the conventional hydraulic jack does not fully absorb various displacements such as horizontal and rotational displacements, and thus often cause additional damage to the bridge superstructure due to abnormal behavior of the bridge superstructure.

Thus, in order to solve the problems described above, J.P.C flat jack excellent in reinforcing bridge support and the bridge support precision construction method has been proposed.

In the conventional flat jack, the upper surface is formed as a flat plate so as to be supported by the lower surface of the plate girder, the steel bridge, and the steel box-shaped bridge, and the stainless steel sheet having a thickness of 1.5 to 3 mm is welded along the inner space of the locking jaw formed at both lower sides. The upper surface of the jack is formed in a predetermined shape so that the spherical bearing portion is attached to the stainless steel sheet, and the stainless steel sheet formed in the inner space of the locking jaw of the upper surface of the jack is in contact with the sliding and stretching of the bridge. A port support consisting of a high-pressure compressed rubber pad and a PTFE plate is formed in the inner space of the locking jaw formed on both sides of the upper part so as to operate in only one direction, and the lower surface is formed in a spherical shape so as to rotate in all directions. A spherical bearing portion of a predetermined shape having a sliding support for surface contact with the plate; The upper surface is formed in a concave shape such that the spherical bearing portion is curved in contact with the spherical lower portion, a PTFE plate is formed thereon, both sides are formed in a wing shape, and the new bridge support is set by hydraulic pressure supplied to one side. In the hydraulic cylinder portion for lifting the upper plate and the upper structure of the bridge bridge is installed, the hydraulic cylinder is a sliding bearing, the upper surface is formed in a concave shape so as to be curved contact with the spherical lower portion of the spherical bearing portion The acupressure surface of the PTFE plate having a plurality of concave small grooves is formed thereon, and the grease mixed with the metallic soap is stored on the acupressure surface to minimize frictional resistance with the spherical lower portion of the spherical bearing part. It is characterized by.

Conventional bridge bearing JPC flat jack with excellent construction and reinforcement of the bridge structure and the precision construction method of the bridge bearing using the same can be absorbed and adjusted various displacements when replacing the existing bridge bearing, but it is necessary to manufacture a special hydraulic jack, Not only does it cost a lot of manufacturing costs due to the special hydraulic jacks, but this also causes an increase in construction costs.

Accordingly, the present invention has been made to solve the problems described above, even when the bridge bearing replacement, even if the longitudinal and transverse gradient of the bridge is large or the bending deformation of the superstructure is large, smoothly absorb the rotational deformation. In order to absorb the horizontal displacement according to the temperature expansion and contraction, a simple reinforcement, hydraulic jack fall prevention plate, acupressure breaking prevention plate, displacement restraint plate and plate are additionally installed in the existing hydraulic jack, so that it is inexpensive without the use of special expensive hydraulic jack. The purpose of the present invention is to provide a bridge superstructure raising device and a bridge support replacement method using the same so that the bridge support can be safely replaced.

Bridge upper structure lifting device according to the present invention for achieving the above object is a hydraulic jack fall prevention and pressure breaking prevention plate; A hydraulic jack installed in front, rear, left and right on the hydraulic jack fall prevention plate and the acupressure destruction preventing plate; A reinforcing member fixedly installed on the hydraulic jack; A displacement binding member fixed to both sides of the reinforcement member; Characterized in that it consists of a plate fixedly installed between the reinforcing material upper surface and the displacement binding material.

In addition, the bridge support replacement method using the bridge upper structure lifting device according to the present invention for achieving the above object is to replace the existing bridge support using the bridge upper structure lifting device of any one of claims 1 to 8. As a construction method, the step of installing a plate on the lower surface of the upper structure around the existing bridge bearing installed between the upper structure and the lower structure of the existing bridge (I); Install a hydraulic jack fall prevention and acupressure break prevention plate across the lower structure side and upper surface of the existing bridge bearing side, install a hydraulic jack on the hydraulic jack fall prevention and acupressure break prevention plate, install a reinforcement on the hydraulic jack and Installing a bridge upper structure pulling device for raising the bridge upper structure by installing a displacement binding material on the reinforcement (II); (IV) raising the bridge upper structure by a predetermined height by applying hydraulic pressure to the hydraulic jack of the bridge upper structure raising apparatus; Removing the existing bridge bearing while the bridge superstructure is raised (V); Installing a new bridge support in a portion where the existing bridge support is removed (VI); Installing a chemical anchor in the lower portion of the new bridge support, reinforcing the rebar on the chemical anchor, install the formwork around the reinforcement, and then cast mortar on the formwork to form a bridge bearing concrete (Ⅶ) ; After the bridge bearing concrete is formed, it is characterized in that the step of lowering the bridge upper structure, and dismantling the bridge upper structure lifting device (Ⅷ).

As described above, the bridge upper structure lifting apparatus and the bridge support replacement method using the same according to the present invention has the following effects.

First, the present invention does not require an expensive special hydraulic jack when replacing the bridge bearing, and replaces the bridge bearing at a very low cost by using a simple reinforcement and a hydraulic jack fall prevention and acupressure breaking prevention plate, a displacement restraint member and a plate in the existing hydraulic jack. can do.

Second, the present invention absorbs various displacements (horizontal, rotation, etc.) generated when the bridge upper structure is raised, so that the bridge bearing can be safely replaced.

Third, the present invention can replace the bridge support very economically because it can be used and compatible with all hydraulic jacks regardless of the load tonnage or scale of the hydraulic jack.

1 is an exemplary view showing a bridge upper structure lifting apparatus according to the present invention 1,
2 is an exemplary view showing a bridge superstructure lifting apparatus according to the present invention;
Figure 3 is a perspective view showing a hydraulic jack fall prevention and pressure breaking prevention plate of the bridge upper structure lifting apparatus according to the present invention,
Figure 4 is a side view showing a hydraulic jack fall prevention and pressure breaking prevention plate of the bridge upper structure lifting apparatus according to the present invention,
5 is a plan view showing a hydraulic jack fall prevention and acupressure break prevention plate of the bridge upper structure lifting apparatus according to the present invention,
Figure 6 is a perspective view showing a reinforcement of the bridge upper structure lifting apparatus according to the present invention,
7 is a front view showing the reinforcement of the bridge superstructure lifting apparatus according to the present invention,
8 is a side view showing a reinforcement of the bridge upper structure lifting apparatus according to the present invention,
Figure 9 is a perspective view showing a displacement binding material of the bridge upper structure lifting apparatus according to the present invention,
10 is a front view showing a displacement binding material of the bridge upper structure lifting apparatus according to the present invention,
11 is a plan view showing a displacement binding material of the bridge upper structure lifting apparatus according to the present invention,
12 is a perspective view showing a plate of the bridge superstructure lifting apparatus according to the present invention,
13 is a front view showing a plate of the bridge superstructure lifting apparatus according to the present invention,
14 is a side view showing a plate of the bridge superstructure lifting apparatus according to the present invention,
15a to 15h is a process diagram showing the process of replacing the bridge support using the bridge upper structure lifting apparatus according to the present invention.

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

1 is an exemplary view showing a bridge upper structure lifting apparatus according to the present invention, Figure 2 is an exemplary view showing a bridge upper structure lifting apparatus according to the present invention.

As shown in these figures, the bridge upper structure lifting device (A) according to the present invention includes a hydraulic jack fall prevention and acupressure break prevention plate (10); A hydraulic jack 20 installed in front, rear, left, and right sides on the hydraulic jack fall prevention plate and the acupressure destruction preventing plate 10; A reinforcing member 30 fixedly installed on the hydraulic jack 20; A displacement binding member 40 fixed to both sides of the reinforcement member 30; It consists of a plate 50 is fixedly installed between the upper surface of the reinforcing material 30 and the displacement binding member 40.

That is, the bridge upper structure lifting device according to the present invention, as shown in Figures 1 and 2, hydraulic jack fall prevention and acupressure break prevention plate 10, hydraulic jack 20, reinforcing material 30, displacement binding material 40 ) And the plate 50 are organically coupled device.

Here, the hydraulic jack fall prevention and acupressure break prevention plate 10, as shown in Figures 3 to 5, the steel plate 12 having a predetermined width and length; Vertical plates 14 formed at right angles to the upper and lower surfaces of the steel sheet 12 at predetermined positions of inner portions from one end of the steel sheet 12; It consists of an inclined plate 16 integrally formed at an end of the steel plate 12 and the upper and lower portions of the vertical plate 14 to be inclined.

The hydraulic jack fall prevention and acupressure break prevention plate 10 functions to prevent fall of the hydraulic jack 20 installed thereon and break pressure due to load on the side edges of the bridge substructure P.

In addition, the hydraulic jack 20 is installed on the hydraulic jack fall prevention and acupressure break prevention plate 10, the general four hydraulic jacks are installed.

Such a hydraulic jack 20 is installed between the hydraulic jack fall prevention and acupressure break prevention plate 10 and the bottom of the reinforcing material 30, to control the load by the lack of load due to the cutting of the existing bridge support (OS) later work. do.

6 to 8, the lower portion of the H beam 31 using the H beam 31 including the upper and lower flanges 32 and 34 and the web 36. A cut portion 38 is formed by cutting a predetermined portion of the flange 34 and the web portion 36 in an inverted U-shape, and a reinforcing plate perpendicularly between the upper portion and the upper flange 32 of the cut portion 38 ( 39) is attached.

In addition, the displacement binding member 40 is, as shown in Figure 9 to 11, the steel plate 42 made of a rectangular shape; A vertical plate 44 vertically integrally formed from one side of the steel plate 42; Consists of a reinforcing plate 46 formed to have a predetermined slope between the other end of the steel plate 42 and the upper end of the vertical plate 44, and serves to support the bridge upper structure (G).

And the plate 50 is formed in a triangular shape, as shown in Figures 12 to 14, it is disposed on the bridge superstructure (G) and the reinforcement 30 to function to cushion the gap therebetween.

Meanwhile, as illustrated in FIGS. 1 and 2, the steel bar pressure plate 60 is attached to the reinforcing material 30, and the steel bar pressure plate is intersected between the reinforcing materials 30 to which the steel bar pressure plate 60 is attached. Displacement preventing steel bar 70 is fixed to the 60, the H beam 80 is installed in the center of the reinforcing material 30, the hydraulic jack 20 is further installed on the H beam (80).

Here, the additional hydraulic jack 20 is installed to the hydraulic jack 20 to the H-beam 80 on the upper surface of the bridge substructure (P) in order to respond to unexpected load changes, the additional hydraulic jack (on the H-beam 80 ( 20).

In particular, the steel bar 70 serves to control the displacement of the reinforcing material (30).

Hereinafter, the bridge support replacement using the bridge upper structure lifting apparatus according to the present invention having the configuration as described above will be described.

15A to 15H are process diagrams illustrating a process of replacing a bridge support using a bridge superstructure lifting apparatus according to the present invention.

As shown in these drawings, the bridge support replacement method using the bridge upper structure lifting device according to the present invention is a method for replacing the existing bridge support using the bridge upper structure lifting device (A) as described above, the existing bridge (I) installing a plate (50) on the lower surface of the upper structure (G) around the existing bridge support (OS) installed between the upper structure (G) and the lower structure (P) of (B); The hydraulic jack fall prevention and acupressure break prevention plate 10 is installed on the lower structure (P) side and the upper surface of the existing bridge support (OS) side, and the hydraulic jack (A) on the hydraulic jack fall prevention and acupressure break prevention plate 10. 20), the reinforcement 30 is installed on the hydraulic jack 20, the displacement restraint 40 is installed on the reinforcement (30) by the bridge upper structure lifting device for raising the bridge upper structure (G) (A) installing step (II); Applying hydraulic pressure to the hydraulic jack 20 of the bridge upper structure lifting device A to raise the bridge upper structure G by a predetermined height (IV); (V) removing the existing bridge support (OS) while the bridge superstructure (G) is raised; (VI) installing a new bridge support (NS) in a portion where the existing bridge support (OS) is removed; After installing the chemical anchor (CC) in the lower portion of the new bridge support (NS), the reinforcement (S) is placed on the chemical anchor (CC), form (F) around the reinforcement (S) reinforcement after (S) forming a bridge bearing concrete (SC) by pouring mortar (M) in the form (F); After the bridge bearing concrete (SC) is formed, the bridge upper structure (G) is lowered, and the bridge upper structure lifting device (A) is dismantled.

In addition, after the bridge upper structure lifting device (A) is installed, the steel bar pressure plate 60 is attached to the reinforcement material 30, and the steel bar pressure plate across the reinforcement material 30 to which the steel bar pressure plate 60 is attached. The displacement preventing steel bar (70) is fixed to the 60, the H beam 80 is installed on the bridge substructure (P) in the middle of the reinforcement (30), the hydraulic jack (H) on the H beam (80) Add reinforcement step (III) of the reinforcing material 30 to install 20).

That is, the bridge support replacement method using the bridge upper structure lifting device according to the present invention is the plate 50 installation step (I), the bridge upper structure lifting device (A) installation step (II), reinforcement 30 reinforcement step (III) ), Bridge upper structure (G) raising step (IV), existing bridge support (OS) removal step (Ⅴ), new bridge support (NS) installation step (VI), bridge support concrete (SC) forming step (Ⅶ) and It is a method to replace the existing bridge support (OS) with a new bridge support (NS) by sequentially carrying out the dismantling step (A) of the bridge superstructure lifting device (A).

Hereinafter, the bridge bearing replacement method using the bridge upper structure lifting device according to the present invention made of the steps as described above will be described in detail by dividing each step.

First, the installation step (I) of the plate 50 is an existing bridge installed between the upper structure (G) and the lower structure (P) of the existing bridge (B) to install the reinforcement (30) of the bridge upper structure lifting device (A) After the surface of the upper structure (G) to clean the surface of the upper structure (G), the plate 50 is installed on the lower surface of the upper structure (G).

Subsequently, the bridge upper structure lifting device (A) installation step (II) is installed in close contact with the hydraulic jack fall prevention plate and acupressure break prevention plate 10 across the lower structure (P) side and the upper surface of the existing bridge support (OS) side and And installing a hydraulic jack 20 on the hydraulic jack fall prevention and acupressure break prevention plate 10, install a reinforcement 30 on the hydraulic jack 20, and displace the binding member 40 on the reinforcement 30. Install the bridge upper structure lifting device (A) for the bridge to raise the upper structure (G).

Subsequently, in the reinforcement step (III) of the reinforcement 30, after installing the bridge upper structure lifting device (A), the steel bar pressure plate 60 is attached to the reinforcement 30, the steel bar pressure plate 60 is attached to the reinforcement (30) is fixed to the steel bar pressure plate (60) to prevent displacement of the steel bar 70, and install the H beam 80 on the bridge substructure (P) in the middle of the reinforcement (30), The reinforcing material 30 reinforcing step (III) for installing the hydraulic jack 20 on the H beam 80 is added.

This is to install the H-beam 80 on the bridge substructure (P), which is the conventional bridge support (OS) cut portion in order to respond to the unexpected load change, and further on the H-beam 80 To place.

Subsequently, in the pulling-up of the bridge superstructure G, the hydraulic step 20 is applied to the hydraulic jack 20 of the bridge superstructure lifting device A to simultaneously raise the bridge superstructure G by a predetermined height.

At this time, it is preferable to apply a computer automatic lifting system in order to ensure the safety during the lifting of the bridge superstructure.

Subsequently, the existing bridge support (OS) removing step (V) removes the existing bridge support (OS) in the state in which the bridge superstructure (G) is lifted by the bridge superstructure lifting device (A).

Subsequently, in the step (VI) of the installation of the new bridge support (VI), the new bridge support (S) is removed at the portion where the existing bridge support (OS) is removed while the bridge superstructure (G) is lifted by the bridge superstructure lifting device (A). Install NS.

Subsequently, in the bridge supporting concrete (SC) forming step (Ⅶ), a chemical anchor (CC) is installed on the lower portion of the newly established bridge support (NS), the reinforcing bars (S) are disposed on the chemical anchor (CC), and the reinforcing bars ( S) After the form (F) is installed around the reinforcement, the mortar (M) is poured into the form (F) to form a bridge bearing concrete (SC).

Subsequently, the dismantling step of the bridge upper structure lifting device A lowers the bridge upper structure G after forming the bridge bearing concrete SC, and uses the bridge upper structure lifting device used to replace the existing bridge bearing. Dismantle A).

10: hydraulic jack fall prevention and shiatsu break prevention plate 12: steel plate
14: vertical plate 16: inclined plate
20: hydraulic jack 30: reinforcement
31: H beam 32: upper flange
34: lower flange 36: web
38: incision 39: reinforcement plate
40: displacement binding member 42: steel sheet
44: vertical plate 46: reinforcement plate
50: plate 60: steel bar pressure plate
70: displacement preventing steel 80: H beam
A: Bridge superstructure lifting device B: Bridge
CC: chemical anchor F: formwork
G: Bridge superstructure M: Mortar
NS: New Bridge Support OS: Existing Bridge Support
P: Bridge substructure S: Reinforcing bar
SC: bridge bearing concrete

Claims (15)

Hydraulic jack fall prevention and acupressure destruction prevention plate (10); A hydraulic jack 20 installed in front, rear, left, and right sides on the hydraulic jack fall prevention plate and the acupressure destruction preventing plate 10; A reinforcing member 30 fixedly installed on the hydraulic jack 20; A displacement binding member 40 fixed to both sides of the reinforcement member 30; A plate 50 fixedly installed between the upper surface of the reinforcing member 30 and the displacement restraint member 40, wherein the hydraulic jack fall prevention and acupressure break prevention plate 10 includes a steel plate 12 having a predetermined width and length; Vertical plates 14 formed at right angles to the upper and lower surfaces of the steel sheet 12 at predetermined positions of inner portions from one end of the steel sheet 12; The inclined plate 16 is formed to be integrally formed at the end of the steel plate 12 and the upper and lower portions of the vertical plate 14, the hydraulic jack 20 is on the hydraulic jack fall prevention and acupressure breaking prevention plate (10) It is composed of four front, rear, left and right, and the reinforcing material 30 is the lower flange 34 of the H beam 31 by using the H beam 31 composed of upper, lower flanges 32 and 34 and the web 36. And the web portion 36 is cut in a predetermined portion in an inverted U shape to form an incision 38, and a reinforcing plate 39 is vertically attached between the upper portion and the upper flange 32 of the incision 38. The displacement binding member 40 includes a steel plate 42 made of a rectangular shape; A vertical plate 44 vertically integrally formed from one side of the steel plate 42; It consists of a reinforcing plate 46 formed to have a constant inclination between the other end of the steel plate 42 and the upper end of the vertical plate 44, the plate 50 is formed in a triangular shape, to the reinforcing material 30 Steel bar pressure plate 60 is attached, the displacement preventing steel bar 70 is fixed to the steel bar pressure plate 60 is installed across the reinforcing material 30 to which the steel bar pressure plate 60 is attached, the center of the reinforcing material 30 H beam (80) is installed in, the bridge upper structure lifting apparatus, characterized in that the hydraulic jack (20) is installed on the H beam (80). delete delete delete delete delete delete In the method of replacing the existing bridge support using the bridge superstructure lifting device (A) of claim 1,
Installing the plate 50 on the lower surface of the upper structure G with respect to the existing bridge support OS installed between the upper structure G and the lower structure P of the existing bridge B;
The hydraulic jack fall prevention and acupressure break prevention plate 10 is installed on the lower structure (P) side and the upper surface of the existing bridge support (OS) side, and the hydraulic jack (A) on the hydraulic jack fall prevention and acupressure break prevention plate 10. 20), the reinforcement 30 is installed on the hydraulic jack 20, the displacement restraint 40 is installed on the reinforcement 30 to raise the bridge upper structure for raising the bridge upper structure (G) Installing device (A) (II);
Applying hydraulic pressure to the hydraulic jack 20 of the bridge upper structure lifting device A to raise the bridge upper structure G by a predetermined height (IV);
(V) removing the existing bridge support (OS) while the bridge superstructure (G) is raised;
(VI) installing a new bridge support (NS) in a portion where the existing bridge support (OS) is removed;
After installing the chemical anchor (CC) in the lower portion of the new bridge support (NS), the reinforcement (S) is placed on the chemical anchor (CC), the form (F) around the reinforcement (S) reinforcement after (S) forming a bridge bearing concrete (SC) by pouring mortar (M) in the form (F);
After the bridge bearing concrete (SC) is formed, the bridge upper structure (G) is lowered, and the bridge upper structure lifting device (A) to dismantle the bridge superstructure lifting device, characterized in that the bridge support using the lifting device Replacement method. The method of claim 8,
After installing the bridge upper structure lifting device (A), the steel bar pressure plate 60 is attached to the reinforcing material 30, and the steel bar pressure plate 60 across the reinforcing material 30 to which the steel bar pressure plate 60 is attached. The displacement preventing steel bar (70) is fixedly installed, and the H beam 80 is installed on the bridge substructure (P) in the middle of the reinforcing material (30), and the hydraulic jack (20) on the H beam (80). Bridge support replacement method using the bridge superstructure, characterized in that the addition of the reinforcing material 30 to install the reinforcement step (III). The method of claim 8,
The bridge upper structure lifting device (A) is a hydraulic jack fall prevention and acupressure breaking prevention plate (10); A hydraulic jack 20 installed in front, rear, left, and right sides on the hydraulic jack fall prevention plate and the acupressure destruction preventing plate 10; A reinforcing member 30 fixedly installed on the hydraulic jack 20; A displacement binding member 40 fixed to both sides of the reinforcement member 30; A plate 50 fixedly installed between the upper surface of the reinforcing member 30 and the displacement restraint member 40, wherein the hydraulic jack fall prevention and acupressure break prevention plate 10 includes a steel plate 12 having a predetermined width and length; Vertical plates 14 formed at right angles to the upper and lower surfaces of the steel sheet 12 at predetermined positions of inner portions from one end of the steel sheet 12; The inclined plate 16 is formed to be integrally formed at the end of the steel plate 12 and the upper and lower portions of the vertical plate 14, the hydraulic jack 20 is on the hydraulic jack fall prevention and acupressure breaking prevention plate (10) It is composed of four front, rear, left and right, and the reinforcing material 30 is the lower flange 34 of the H beam 31 by using the H beam 31 composed of upper, lower flanges 32 and 34 and the web 36. And the web portion 36 is cut in a predetermined portion in an inverted U shape to form an incision 38, and a reinforcing plate 39 is vertically attached between the upper portion and the upper flange 32 of the incision 38. The displacement binding member 40 includes a steel plate 42 made of a rectangular shape; A vertical plate 44 vertically integrally formed from one side of the steel plate 42; Consists of a reinforcing plate 46 formed to have a predetermined slope between the other end of the steel plate 42 and the upper end of the vertical plate 44, the plate 50 is a bridge upper structure lifting, characterized in that formed in a triangular shape Bridge bearing replacement method using device. delete delete delete delete delete

Images