KR20160026200A - System for floating superstructure of bridge by using computer - Google Patents

Abstract

The present invention relates to a system for floating an upper structure (30) of a bridge composed of the upper structure (30) and a lower structure (70). The system comprises: multiple hydraulic jacks (80) which are installed between the bottom surfaces of multiple horizontal beams (12) and the top surface of a coping (40), respectively, to float the upper structure (30) according to supplied hydraulic pressure; multiple pressure sensors (90) which are installed between the top surfaces of the hydraulic jacks (80) and the bottom surfaces of the horizontal beams (12), respectively; a computer (100) which controls the hydraulic pressure supplied to the hydraulic jacks (80) according to the pressure sensed signal provided from the pressure sensors (90), respectively; a hydraulic pump (200) which generates multiple hydraulic pressures to paths according to the control of the computer (100), respectively; and a valve block (300) which allows the hydraulic jacks (80) to uniformly float the upper structure (30) by controlling the hydraulic pressure of each hydraulic jack (80).

Description

[0001] The present invention relates to a system for floating superstructure of a bridge,

More particularly, the present invention relates to an upper structure lifting system for a bridge using a computer, and more particularly to an upper structure lifting system for a bridge using a computer, And a pressure sensor is installed between the upper surface of the hydraulic jack and the lower surface of the bar so that a computer can control each hydraulic pressure provided to the plurality of hydraulic jacks according to a pressure detection signal provided from a plurality of pressure sensors, To an upper structure float system of a bridge using a computer to float the upper structure evenly so that the upper structure is safely floated without being damaged entirely.

In addition, each of the cross bars in the form of a rectangular plate is horizontally placed on the bottom of the slab and the girder surfaces on both sides above the spaces between the plurality of girders on the copings, and a hydraulic jack is provided between the bottom surface of each of the girders and the top of the copings, A pressure sensor is installed between the bottom surfaces of the respective girders, and the hydraulic pressure applied to the plurality of hydraulic jacks is adjusted by a computer in accordance with a pressure detection signal provided from a plurality of pressure sensors, so that the plurality of hydraulic jacks float the upper structure uniformly, The present invention relates to a computer-assisted superstructure floatation system for bridges so that the structure is floated safely without being damaged entirely.

Japanese Patent Application Laid-Open No. 10-2009-0131443 (published on December 29, 2009) A steel composite bridge in which a slab and a girder are integrated,

In a steel composite bridge including a plate-like bridge including a longitudinally formed slab and a girder,

At least two slabs 120 and a girder portion 110 are prepared so that the girder portion can be formed in a rectangular cross-section or a spherical cross-sectional shape, and the slab is connected to the inside of the upper end of the girder portion The slab and the girder are formed so as to be integrally formed by machining a steel material so that the upper surface of the slab and the girder are opened so that the concrete can be poured into the interior of the girder. A steel frame (100); And

And a concrete (200) placed in the steel frame and filled in the steel frame to be cured while being embedded in the steel frame assembly.

However, in order to maintain the steel composite bridge in which the slab and the girder are integrated according to the conventional technique, a plurality of jacks are provided on the bottom surface of the slab to lift up the slab integrated with the girder, When the load applied to each jack is different, the slab is irregularly floated and the slab is generally cracked.

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the above-mentioned problems, and it is an object of the present invention to provide a hydraulic jack, which is installed between a bottom surface of a slab and a bottom surface of a girder, And a pressure sensor is installed between the upper surface of the hydraulic jack and the lower surface of the cross bar. Then, the computer controls the hydraulic pressure provided to the plurality of hydraulic jacks according to the pressure detection signal provided from the plurality of pressure sensors, So that the upper structure can float evenly without causing damage to the upper structure, thereby providing an upper structure floatation system of a bridge using a computer.

In addition, each of the cross bars in the form of a rectangular plate is horizontally placed on the bottom of the slab and the girder surfaces on both sides above the spaces between the plurality of girders on the copings, and a hydraulic jack is provided between the bottom surface of each of the girders and the top of the copings, A pressure sensor is installed between the bottom surfaces of the respective girders, and the hydraulic pressure applied to the plurality of hydraulic jacks is adjusted by a computer in accordance with a pressure detection signal provided from a plurality of pressure sensors, so that the plurality of hydraulic jacks float the upper structure uniformly, Another object is to provide a computerized superstructure floatation system for allowing a structure to float safely and without damage in its entirety.

In order to achieve this object,

According to an aspect of the present invention,

A plurality of girders 20 integrally formed on the bottom surface of the slab 10 at intervals in the longitudinal direction and a plurality of girders 20 on the coping 40 are provided on the bottom of each space between the plurality of girders 20, An upper structure 30 having a plurality of rectangular beams 12 in the form of a rectangular plate erected horizontally so as to be integrated on the surface of the girder 20, a coping 40 partially supporting the plurality of girders 20, A system for lifting an upper structure (30) in a bridge comprising a lower structure (70) having a pillar base (60) and a column (50) formed between the pier foundation (60)

A plurality of hydraulic jacks 80 for lifting the upper structure 30 in accordance with the hydraulic pressure provided between the bottom surface of the plurality of beams 12 and the upper surface of the copings 40 between the plurality of girders 20, ;

A plurality of pressure sensors (90) provided between the upper surface of the plurality of hydraulic jacks (80) and the bottom surface of the cross bar (12);

A computer (100) for adjusting respective hydraulic pressures provided to the plurality of hydraulic jacks (80) according to respective pressure sensing signals provided from the plurality of pressure sensors (90);

A hydraulic pump 200 for generating a plurality of hydraulic pressures on the respective paths under the control of the computer 100; And

Each of the valves provided in accordance with the control of the computer 100 controls each of the hydraulic pressures provided from the hydraulic pump 200 to control the respective hydraulic pressures provided to the hydraulic jacks 80, A valve block (300) for causing the hydraulic jack (80) to float the upper structure (30) evenly;

And a control unit.

According to another aspect of the present invention,

A plurality of girders 120 and a plurality of girders 120 on a bottom surface of the slab 110 are integrally formed on the bottom surface of the girder 120. The girder 120 is installed on the lower surface of the slab 110, (130) having a plurality of beams (112) in the form of a rectangular plate erected horizontally so as to be integrated on the surface of the girder (120), a coping (140) partially supporting the plurality of girders (120) A system for lifting an upper structure (130) in a bridge comprising a lower structure (160) having a pillar base (160) and a pillar (150) formed between the pillar foundation (160)

A plurality of hydraulic jacks 180 installed between the lower surface of the plurality of girders 120 and the upper surface of the copings 140 to float the upper structure 130 according to the hydraulic pressure provided;

A plurality of pressure sensors 190 provided between the upper surface of the plurality of hydraulic jacks 180 and the bottom surface of the plurality of girders 120;

A computer 1100 for controlling respective hydraulic pressures provided to the plurality of hydraulic jacks 180 according to respective pressure sensing signals provided from the plurality of pressure sensors 190;

A hydraulic pump 1200 for generating a plurality of hydraulic pressures under the control of the computer 1100, respectively; And

Each of the valves provided in accordance with the control of the computer 1100 controls each of the hydraulic pressures provided from the hydraulic pump 1200 to control the respective hydraulic pressures provided to the hydraulic jacks 180, A valve block (1300) for causing the hydraulic jack (180) to float the upper structure (130) evenly;

And a control unit.

The computers 100 and 1100 are notebook computers.

And the valve is a solenoid valve.

The present invention is characterized in that a rectangular plate shaped bottom plate 12 is provided at the upper portion of each space between a plurality of girders 20 on the coping 40 and horizontally arranged so as to be integrated with the bottom surface of the slab 10 and the surface of the girders 20 on both sides, A hydraulic jack 80 is provided between the upper surfaces of the copings 40 and a pressure sensor 90 is installed between the upper surface of the hydraulic jack 80 and the lower surface of the cross bar 12. The computer 100 is provided with a plurality of pressure sensors 90, Since the plurality of hydraulic jacks 80 can float the upper structure 30 evenly by regulating the respective hydraulic pressures provided to the plurality of hydraulic jacks 80 in accordance with the pressure sensing signal provided from the upper structure 30, There is an effect of being safely floated without being damaged.

Each rectangular beam 112 in the form of a rectangular plate is horizontally placed on the bottom of the slab 110 and on both sides of the girder 120 on the top of each space between the plurality of girders 120 on the coping 140, A hydraulic jack 180 is installed between the bottom surface of the girder 120 and the upper surface of the coping 140 and a pressure sensor 190 is installed between the upper surface of the hydraulic jack 180 and the bottom surface of each girder 120, Since the plurality of hydraulic jacks 180 float the upper structure 130 uniformly by controlling the respective hydraulic pressures provided to the plurality of hydraulic jacks 180 according to the pressure sensing signal provided from the plurality of pressure sensors 190, There is an effect that the structure 130 is safely floated without being damaged entirely.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view showing an embodiment of an upper structure floatation system of a bridge using a computer according to the present invention. FIG.
Fig. 2 is a block diagram showing an embodiment of a system for controlling the driving of the hydraulic jack shown in Fig. 1. Fig.
FIG. 3 is a cross-sectional view showing another embodiment of the upper structure floating system of a bridge using a computer according to the present invention.
Fig. 4 is a block diagram showing an embodiment of a system for controlling the driving of the hydraulic jack shown in Fig. 3. Fig.

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

1 is a cross-sectional view showing an embodiment of an upper structure floatation system of a bridge using a computer according to the present invention, and is composed of an upper structure 30, a lower structure 70, a hydraulic jack 80 and a pressure sensor 90 . The upper structure 30 is formed by integrating the slab 10, the plurality of beams 12 and the plurality of girders 20. The substructure 70 comprises a coping 40, a column 50 and a pier foundation 60.

The present invention will now be described in detail with reference to FIG.

Fig. 2 is a block diagram showing an embodiment of a system for controlling the driving of the hydraulic jack 80 shown in Fig. 1, and includes a computer 100, a hydraulic pump 200 and a valve block 300. Fig.

1 and 2, the bridge is composed of the upper structure 30 and the lower structure 70 first. At this time, the upper structure 30 includes a plurality of girders 20 integrally formed on the bottom surface of the slab 10 at intervals in the longitudinal direction, and a plurality of girders 20 on the copings 40, And a plurality of cross beams 12 in the form of a rectangular plate erected horizontally so as to be integrated with the bottom surface and the surface of the girders 20 on both sides. The substructure 70 has a column 50 formed between the copings 40, the pier foundation 60 and the pier foundation 60 partially supporting the plurality of girders 20 and the copings 40. Between the center of the bottom surface of the plurality of girders 20 and the upper surface of the copings 40, respective coplanar devices are installed, which are not shown in the drawings.

The plurality of hydraulic jacks 80 float the upper structure 30 according to the hydraulic pressure provided between the bottom surface of the plurality of beams 12 and the upper surface of the copings 40 between the plurality of girders 20. At this time, one or more hydraulic jacks 80 may be installed between the girders 20 depending on the working environment.

A plurality of pressure sensors (90) are installed between the upper surface of the plurality of hydraulic jacks (80) and the bottom surface of the cross beam (12). At this time, the pressure sensor 90 outputs a voltage corresponding to the pressure applied to the pressure sensor 90 itself.

The computer 100 controls each of the hydraulic pressures provided to the plurality of hydraulic jacks 80 through the control of the hydraulic pump 200 and the valve block 300 in accordance with the pressure sensing signals provided from the plurality of pressure sensors 90, do. At this time, the computer 100 analyzes the pressure sensing signals provided from the plurality of pressure sensors 90, and controls the hydraulic jacks 80 such that the hydraulic jacks 80 are provided with high hydraulic pressure, The upper structure 30 is floated so as not to be tilted to either side.

That is, the hydraulic pump 200 generates a plurality of hydraulic pressures on the respective paths according to the control of the computer 100 and provides them to the valve block 300, respectively. At this time, the computer 100 is preferably a notebook computer.

The valve block 300 drives each valve provided under the control of the computer 100 to control the respective hydraulic pressures supplied from the hydraulic pump 200 to adjust the respective hydraulic pressures provided to the hydraulic jacks 80 So that the plurality of hydraulic jacks 80 float the upper structure 30 evenly. The valve should be a solenoid valve.

3 is a cross-sectional view showing another embodiment of the upper structure floatation system of a bridge using a computer according to the present invention, and is composed of a superstructure 130, a substructure 170, a hydraulic jack 180, and a pressure sensor 190 . The upper structure 130 is formed by integrating the slab 110, the plurality of beams 112, and the plurality of girders 120. The substructure 170 comprises a coping 140, a column 150 and a pier foundation 160.

The present invention will now be described in detail with reference to FIG.

4 shows a block diagram of an embodiment of a system for controlling the driving of the hydraulic jack 180 shown in Fig. 1, comprising a computer 1100, a hydraulic pump 1200 and a valve block 1300. Fig.

3 and 4, the bridge is composed of a superstructure 130 and a substructure 170 first. At this time, the upper structure 130 includes a plurality of girders 120, which are integrally formed on the bottom surface of the slab 110 at intervals in the vertical direction, and a plurality of girders 120 on the copings 140, And a plurality of cross beams 112 in the form of a rectangular plate erected horizontally so as to be integrated with the bottom surface and the surface of the girders 120 on both sides. The substructure 170 has a column 150 formed between the copings 140, the pier foundation 160 and the bridge foundation 160 and the copings 140 partially supporting the plurality of girders 120. Between the center of the underside of the plurality of girders 120 and the upper surface of the copings 140, respective coplanar devices are installed, which are omitted in the drawings.

The plurality of hydraulic jacks 180 are installed between the bottom surface of the plurality of girders 120 and the upper surface of the copings 140, respectively, and float the upper structure 130 according to the hydraulic pressure. At this time, one or more hydraulic jacks 180 may be installed between the bottom surface of each girder 120 and the upper surface of the coping 140, depending on the working environment. When installing the hydraulic jack 180 between the bottom surface of the girder 120 and the upper surface of the coping 140, a coaxial device installed between the bottom of the girder 120 and the upper surface of the coping 140 should be avoided.

A plurality of pressure sensors 190 are installed between the upper surface of the plurality of hydraulic jacks 180 and the bottom surface of the plurality of girders 120, respectively. At this time, the pressure sensor 190 outputs a voltage corresponding to the pressure applied thereto.

The computer 1100 controls each of the hydraulic pressures provided to the plurality of hydraulic jacks 180 according to the pressure sensing signals provided from the plurality of pressure sensors 190 through the control of the hydraulic pump 1200 and the valve block 1300 do. At this time, the computer 1100 analyzes the pressure sensing signals provided from the plurality of pressure sensors 190, and controls the hydraulic jacks 180 so that the hydraulic jacks 180 are provided with high hydraulic pressure, The upper structure 130 is floated so as not to be tilted to either side.

That is, the hydraulic pump 1200 generates a plurality of hydraulic pressures on the respective paths under the control of the computer 1100 and provides them to the valve block 1300, respectively. At this time, the computer 1100 is preferably a notebook computer.

The valve block 1300 drives each valve provided under the control of the computer 1100 to control the respective hydraulic pressures supplied from the hydraulic pump 1200 to adjust the respective hydraulic pressures supplied to the hydraulic jacks 180 So that the plurality of hydraulic jacks 180 float the upper structure 130 evenly. The valve should be a solenoid valve.

The present invention provides a rectangular plate-shaped cross beam 12, which is installed on the bottom surface of the slab 10 and on both sides of the girder 20 so as to be integrated on the top of each space between the plurality of girders 20 on the coping 40, And a pressure sensor 90 is installed between the upper surface of the hydraulic jack 80 and the lower surface of the beam 12. The computer 100 is provided with a plurality of pressure sensors 90 Since the plurality of hydraulic jacks 80 float the upper structure 30 evenly by regulating the respective hydraulic pressures provided to the plurality of hydraulic jacks 80 in accordance with the pressure sensing signal provided from the pressure sensor There is an advantage of being safely floated without being damaged.

Each rectangular beam 112 in the form of a rectangular plate is horizontally placed on the bottom of the slab 110 and on both sides of the girder 120 on the top of each space between the plurality of girders 120 on the coping 140, A hydraulic jack 180 is installed between the bottom surface of the girder 120 and the upper surface of the coping 140 and a pressure sensor 190 is installed between the upper surface of the hydraulic jack 180 and the bottom surface of each girder 120, Since the plurality of hydraulic jacks 180 float the upper structure 130 uniformly by controlling the respective hydraulic pressures provided to the plurality of hydraulic jacks 180 according to the pressure sensing signal provided from the plurality of pressure sensors 190, There is an advantage that the structure 130 is safely levitated without being damaged entirely.

Although the preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. In addition, it is a matter of course that various modifications and variations are possible without departing from the scope of the technical idea of the present invention by anyone having ordinary skill in the art.

10, 110: Slab
12, 112:
20, 120: girder
30, 130: upper structure
40, 140: Copping
50, 150: Column
60, 160: Bridge pier foundation
70, 170:
80, 180: Hydraulic Jack
90, 190: Pressure sensor
100, 1100: computer
200, 1200: Hydraulic pump
300, 1300: valve block

Claims (4)

A plurality of girders 20 integrally formed on the bottom surface of the slab 10 at intervals in the longitudinal direction and a plurality of girders 20 on the coping 40 are provided on the bottom of each space between the plurality of girders 20, An upper structure 30 having a plurality of rectangular beams 12 in the form of a rectangular plate erected horizontally so as to be integrated on the surface of the girder 20, a coping 40 partially supporting the plurality of girders 20, A system for lifting an upper structure (30) in a bridge comprising a lower structure (70) having a pillar base (60) and a column (50) formed between the pier foundation (60)
A plurality of hydraulic jacks 80 for lifting the upper structure 30 in accordance with the hydraulic pressure provided between the bottom surface of the plurality of beams 12 and the upper surface of the copings 40 between the plurality of girders 20, ;
A plurality of pressure sensors (90) provided between the upper surface of the plurality of hydraulic jacks (80) and the bottom surface of the cross bar (12);
A computer (100) for adjusting respective hydraulic pressures provided to the plurality of hydraulic jacks (80) according to respective pressure sensing signals provided from the plurality of pressure sensors (90);
A hydraulic pump 200 for generating a plurality of hydraulic pressures on the respective paths under the control of the computer 100; And
Each of the valves provided in accordance with the control of the computer 100 controls each of the hydraulic pressures provided from the hydraulic pump 200 to control the respective hydraulic pressures provided to the hydraulic jacks 80, A valve block (300) for causing the hydraulic jack (80) to float the upper structure (30) evenly;
Wherein the upper structure float system of a computer-assisted bridge.
A plurality of girders 120 and a plurality of girders 120 on a bottom surface of the slab 110 are integrally formed on the bottom surface of the girder 120. The girder 120 is installed on the lower surface of the slab 110, (130) having a plurality of beams (112) in the form of a rectangular plate erected horizontally so as to be integrated on the surface of the girder (120), a coping (140) partially supporting the plurality of girders (120) A system for lifting an upper structure (130) in a bridge comprising a lower structure (160) having a pillar base (160) and a pillar (150) formed between the pillar foundation (160)
A plurality of hydraulic jacks 180 installed between the lower surface of the plurality of girders 120 and the upper surface of the copings 140 to float the upper structure 130 according to the hydraulic pressure provided;
A plurality of pressure sensors 190 provided between the upper surface of the plurality of hydraulic jacks 180 and the bottom surface of the plurality of girders 120;
A computer 1100 for controlling respective hydraulic pressures provided to the plurality of hydraulic jacks 180 according to respective pressure sensing signals provided from the plurality of pressure sensors 190;
A hydraulic pump 1200 for generating a plurality of hydraulic pressures under the control of the computer 1100, respectively; And
Each of the valves provided in accordance with the control of the computer 1100 controls each of the hydraulic pressures provided from the hydraulic pump 1200 to control the respective hydraulic pressures provided to the hydraulic jacks 180, A valve block (1300) for causing the hydraulic jack (180) to float the upper structure (130) evenly;
Wherein the upper structure float system of a computer-assisted bridge.
The method according to claim 1 or 2,
Wherein the computer (100, 1100) is a notebook computer.
The method according to claim 1 or 2,
Wherein the valve is a solenoid valve.

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