KR101732457B1 - Girder height adjustable device and method - Google Patents

Abstract

The present invention relates to a device for controlling level of a girder when installing a bridge, comprising: a flat base support installed on the upper surface of two or more piers (10) or a bridge (20), respectively and coupled to the same by a fixing device (110); a lifting device comprising a first cylinder main body mounted on one side of the base support, and a first flange mounted inside the cylinder main body to be operated by an external hydraulic pressure source; and a movable support (300) having one side in contact with the first flange and the other side supporting a girder.

Description

{Girder height adjustable device and method}

The present invention relates to an apparatus for precisely controlling the height of a bridge, and relates to an invention for adjusting the height and the horizontal of a bridge using a hydraulic cylinder.

The invention of Patent Document 001 relates to an apparatus and a method for replacing a bridge support of a girder bridge. In this case, the elevating means is installed, and a height adjusting means such as a screw jack or a hydraulic jack is installed inside the box type girder so as to adjust the height of the pedestal and the height of the box type girder. The invention of Patent Document 00 is characterized in that an elevating means such as a plurality of hydraulic jacks is installed around a bridge support between a bridge pier or an alternating upper surface provided with a box type girder and a bottom surface of the box type girder, And a height adjustment means such as a screw jack or a hydraulic jack is provided between the upper end of the pedestal and the inner bottom surface of the box-shaped girder so as to coincide with the elevation center line so as to adjust the height of the pedestal .

Patent Document 002 relates to a method of exchanging a quasi-apparatus, Patent Document 002 discloses a bidirectional hydraulic device including sliding means disposed on a lower surface of a hydraulic jack and base means for permitting or fixing bidirectional or bidirectional movement of the sliding means, A one-way hydraulic device or a fixed-end hydraulic device, and the supporting device for the field assembly is used to displace the slab in one direction or both directions to replace the concrete device. According to Patent Document 002, it is possible to alleviate the lateral displacement acting on the bridge pier during expansion and contraction due to the temperature displacement in the direction perpendicular to the throttle or throttle while supporting the slab during the replacement period of the whirlpool apparatus, and effectively reduce the impact due to the upper live load . It is also convenient to minimize the damage of the bridge structure by preventing perforation for installing an anchor on existing structure, and to adjust the width and width by making it to be prefabricated according to the weight of the upper part. It is convenient to install the hydraulic jack on the alternation and pier, The effect of replacing.

Patent Literature 003 relates to a bridge lifting device, in which a prefabricated girder lower support portion is used without using an anchor bolt at all. A lift part having a hydraulic jack installed at an alternation between the girder and the girder side or at the upper side of the bridge pier; A support member positioned on an upper side of the hydraulic jack of the lifting unit and including a supporting member lifted and lowered by the operation of the hydraulic jack; And a bracket disposed on both ends of the support portion, and a girder lower support portion provided to surround the lower portion of the girder, wherein the hydraulic jack mounted on the upper surface of the alternate or pier is operated to support the support portion and the girder lower support portion So that the beams or the girders are lifted at the same time, and the side space between the girders and the girders is utilized.

According to the patent document 003, it is easy to install and dismantle without damaging the concrete structure of alternating and piers, and the work space can be easily secured, so that it is easy to replace the left unit, It is claimed that there is an effect that the construction cost can be greatly reduced due to the easy recycling of the components. Also, it can prevent the accident of the beam or the girder in advance even when the hydraulic jack is suddenly lost, .

KR 10-1130166 B1 (Mar. 28, 2012) KR 10-0961547 B1 (June 7, 2010) KR 10-0964729 B1 (2010.06.21.)

The present invention relates to an apparatus for precisely controlling the height of a bridge, and relates to an invention for adjusting the height and the horizontal of a bridge using a hydraulic cylinder.

In order to solve the problems of the related art, the girder horizontal apparatus according to the present invention is installed on two or more piers (10) or alternate (20) upper surfaces, and is formed in a flat plate shape. A first cylinder body 201 mounted on one side of the base support and a first plenum (not shown) mounted inside the cylinder body and operated by an external hydraulic pressure source 203 202), a movable support 300, one side of which is in contact with the first flange, and the other side of which supports the girder.

 A laser beam horizontal oscillator 401 mounted on one side of the girder and horizontally oscillating a laser beam; a laser beam sensor 402 mounted on the other side of the girder to detect a laser beam; A controller 403 for calculating an angle of the girder from the laser beam sensor 402 and the laser beam sensor 402; .

A horizontal unit 404 mounted on one side of the girder to measure the horizontal position of the girder, and a controller 405 for calculating the angle of the girder from the horizontal unit.

The girder horizontal devices presented above include valves. And a valve (500) for controlling the supply of hydraulic pressure to the elevating device (200) on both sides of the girder to maintain the girder horizontal from the angle calculated from the controller (403). And a valve 500 for controlling the hydraulic pressure supplied to the elevating device 200 on both sides of the girder to maintain the girder horizontal from the angle calculated from the controller 405. [

And a second lifting device 600, one side of which is in close contact with the first flange and the other side of which is in close contact with the moving support,

The second elevating apparatus 600 described above is constructed such that the second cylinder body 601 and the second flange 602 are positioned horizontally and the moving holes 603 and 604 are provided at both ends of the second cylinder body and the second flange And vertically moving bodies 605 and 606, which are in contact with the inclined surfaces of the moving sills, are fixed to the moving supports.

A method of adjusting a height of a girder, comprising: measuring a slope angle of a girder (S100) from a horizontal measurement device mounted on the girder; measuring the slope angle (S200) for individually actuating each of the lift devices mounted on the platform,

A method of adjusting a height of a girder, comprising: measuring a slope angle of a girder (S100) from a horizontal measurement device mounted on the girder; measuring the slope angle And a variable elevating step (S300) for actuating a lift device mounted on the lifting device and adjusting a lift amount by measuring a real time angle change value from the measuring device.

Since the girder horizontal adjustment of the present invention uses a hydraulic cylinder, it is possible to easily adjust the horizontal level of the girders without using heavy equipment.

The present invention uses a double hydraulic cylinder and enables precise displacement adjustment, so that accurate level adjustment is possible.

Since the spherical contact surface of the present invention is formed between the flange and the moving plate, the side load according to the tilt angle of the girder is reduced, thereby preventing the deviation of the cylinder.

The present invention uses a slip prevention plate between the moving plate and the girder, thereby preventing sliding between the girder and the moving plate.

The present invention uses a laser level meter, which is controlled in real time, so that the level can be accurately and quickly adjusted.

Fig. 1 is a detailed view of the horizontal adjustment device on one side of the girder.
Fig. 2 shows a hydraulic device for horizontal adjustment of the girder.
FIG. 3 is a schematic view of a girder horizontal apparatus
Fig. 4 is a cross-sectional view of a girder horizontal apparatus
5 is a cross-sectional view of the sliding plate
Fig. 6 is a cross-sectional view showing the curved groove of the first plunger and the movable support,

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

(Embodiment 1) A girder horizontal apparatus according to the present invention is a girder horizontal apparatus for elevating a girder and adjusting the horizontal position of the girder when a bridge is installed. The girder horizontal apparatus is installed on two or more pier 10 or alternate upper surfaces, A first cylinder body 201 mounted on one surface of the base support, and a second cylinder body 201 mounted on the inside of the cylinder body, (200) comprising a first plenum (202) operated by a hydraulic pressure source (203), a movable support (300) having one side contacting the first plenum and the other side supporting a girder do.

The anchor bolt may include a plurality of anchoring bolts, a plurality of anchor bolts to be fastened to the anchor bolts, a fastening nut to be screwed with the anchor bolts, and a plurality of through holes through the anchor bolts, And a base support fixed to the bridge or alternately.

The lift device includes an oil receiving space formed in the first cylinder body, a piston coupled to the oil receiving space and connected to the first flange, an O-ring formed between the piston and the inner surface of the first cylinder body, And a first opening and a second opening formed inside the first cylinder and formed on both sides, respectively, on which the piston is formed. The first opening and the second opening allow the outer high pressure oil to flow in and out to move the first plenum and move the girder upward or downward by the movement of the first plenum.

A first flangeless coupling having an inner diameter equal to the outer diameter of the first flange is formed on one surface of the movable support to prevent the first flange from being separated from the first flannel, , And the outside is supported by the reinforcing plate.

The other surface of the movement support is in close contact with the girder, and a girder movement prevention plate 700 made of rubber is coupled to prevent the girder from coming off. The girder transfer prevention plate is formed in a plate shape, and a groove or projection shaped frictional coefficient increasing device is formed on both sides.

The plurality of support bars are fastened by bolts capable of fixing the support bars, and the plurality of support bars are fastened to the support bars A guide bush which is capable of guiding the movable support in the axial direction of the plurality of support bars is fastened. The guide bush is fixed to the movable support and is movable along the plurality of support bars.

The end of the first flange forms a spherical contact hole 209, and a spherical contact groove 303 is formed on the contact surface of the movable support. The radius of the contact groove is smaller than the radius of the contact hole so that the upper end point of the contact hole is always in contact with the movement support. That is, the load acting on the lifting device always acts as the axial load. This is to prevent side load caused by the inclined surface of the girder from giving a side load to the lifting device and breakage of the lifting device and departure from the girder.

(Embodiment 2) In Embodiment 1, the girder horizontal apparatus is constituted by a laser beam horizontal oscillator 401 mounted on one side of a girder and horizontally emitting a laser beam, A controller 403 for calculating an angle of the girder from the laser beam horizontal oscillator 401 and the laser beam sensor 402; .

The laser beam horizontal oscillator forms a fixed plate fixed to one surface of the girder, and the fixed plate fixed to one surface of the girder is stably fixed to the vacuum adsorber, the magnetic device, or the equally displaceable device.

The fixed plate of the laser beam horizontal oscillator forms a vertical plate formed vertically from the fixed plate, the vertical plate supports the rotary shaft, and the bearing is coupled between the rotary shaft and the vertical plate. The rotary shaft joins a protruding rod which is weight-mounted in the radial direction of the shaft, and mounts the laser beam oscillator in the vertical direction of the protruding rod. Therefore, even if there is a tilting angle of the fixing plate, the projecting rod always maintains a constant vertical direction by the weight, so that the laser beam oscillator always oscillates the beam horizontally.

The laser beam sensor forms a fixing plate fixed to one surface of the girder, and the fixing plate fixed to one surface of the girder is stably fixed to the girder by means of a vacuum adsorber, a magnetic device, or the like.

The fixing plate forms a vertical plate formed vertically from the fixing plate, and the vertical plate is coupled to the axis of the laser beam sensing plate. The laser beam sensing plate is mounted on the bottom so that the vertical surface is maintained by gravity.

The laser beam horizontal oscillator and the laser beam detector are operated using the electric energy of the charger installed therein, and a wireless transceiver is formed which operates wirelessly or transmits data wirelessly.

The controller forms a wireless transceiver. The angle of the girder is measured using the data received from the laser beam sensor, and the elevation height of one side or the other side of the girder is calculated.

(Embodiment 3) In Embodiment 1, the girder horizontal apparatus includes a horizontal unit mounted on one side of the girder intermediate side to measure the horizontal of the girder, and a controller 405 for calculating the angle of the girder from the horizontal unit.

The horizontal plate forms a fixing plate fixed to one surface of the girder, and the fixing plate fixed to one surface of the girder stably fixes the girder by means of a vacuum adsorber, a magnetic device, or an apparatus that can evenly replace the same.

A horizontal unit is mounted on the fixing plate. The horizontal unit is powered by the internal battery and sends the internal tilt angle to the controller wirelessly.

The controller forms a wireless transceiver. The angle of the girder is measured using the data received from the leveler, and the elevation height of one side or the other side of the girder is calculated.

(Embodiment 4) In Embodiment 2, the girder horizontal apparatus includes a valve 500 for controlling the supply of hydraulic pressure to the elevating apparatus 200 on both sides of the girder so as to maintain the girder horizontal from the angle calculated from the controller 403; .

The valve regulates the amount of oil supplied into the first cylinder or interrupts or connects the oil supply. The valve is operated by the control signal of the controller. That is, the controller controls the flow rate supplied to the inside of the first cylinder to automatically operate the calculated angular correction value of the girder.

The valve supplies oil from the oil supply unit. The oil supply unit is operated manually or automatically. The oil supply unit is composed of an oil tank, an oil pump, and a pressure measuring device.

(Embodiment 5) In Embodiment 3, the girder horizontal apparatus includes a valve 500 for controlling the supply of hydraulic pressure to the elevating apparatus 200 on both sides of the girder so as to maintain the girder horizontal angle calculated from the controller 405; .

The valve regulates the amount of oil supplied into the first cylinder or cuts off the oil supply. The valve is operated by the control signal of the controller. That is, the controller controls the flow rate supplied to the inside of the first cylinder to automatically operate the calculated angular correction value of the girder. The valve is supplied with oil from the oil supply unit. The oil supply unit is operated manually or automatically. The oil supply unit consists of an oil tank, an oil pump, and a pressure device.

(Embodiment 6) In any one of Embodiments 1 to 5, the girder horizontal apparatus includes a second elevation device 600 (one of the first elevator apparatus 600 and the second elevator apparatus 600), one side of which is in close contact with the first plenum, ). ≪ / RTI >

The second lift device is formed of a second cylinder and a second flange. The second cylinder and the second plant are formed in the same axial direction as the first cylinder and the first plant. The second lift device is operated at a speed that is twice or less than that of the first lift device of the first lift device, so that it is operated more precisely than the first lift device.

(Embodiment 7) In Embodiment 6, in the second elevator device 600 of the girder horizontal device, the second cylinder body 601 and the second flange 602 are horizontally positioned, and the second cylinder body 606 are mounted on both ends of the second plenum and the vertical moving bodies 605, 606 contacting the slopes of the moving sills are fixed to the moving support.

The second lifting device is coupled to the second cylinder and the second plunger and is operated by the oil pressure, and the moving direction of the second plunger is formed at right angles to the moving direction of the first plunger.

At both ends of the second plunger and the second cylinder, a moving rod is mounted. On each of the moving surfaces, an inclined surface is formed. A friction plate is attached to the inclined surface. Teflon or MC nylon material is used for the friction plate material.

Each one of the vertical moving bodies forms respective inclined surfaces which are in contact with the inclined surfaces of the respective moving elements. And the other side of each vertical moving body is fixed to one side of the moving frame. That is, when the hydraulic pressure is supplied to the inside of the second cylinder, the second cylinder and the second plant are extended, and a moving rod coupled to both ends of the second cylinder and the second flanger is opened. An inclined surface is formed on one side of the moving tool so that the vertical moving body is pushed by sliding of the inclined surface, and the vertical moving body is vertically moved by the inclined surface. The vertical moving bodies are fixed to the moving frame and raise the moving support by the upward movement of the moving frame.

A guide groove for guiding movement in one direction is formed on the other side of the moving tool, and the guide groove is coupled to the guide rail. Therefore, there is an effect of suggesting the moving direction of the moving tool.

And is coupled to the guide rail and the first flange connecting portion. One side of the connection portion is coupled to the first flange, and the other side of the connection portion fixes the guide rail. The connecting portion forms a protruding end, and the protruding end is in close contact with the groove of the moving frame. Each of the protruding ends is fastened by a combination of a groove and a projection, and enables one-directional movement.

(Embodiment 8) A bridge height adjustment method for adjusting the horizontal level of a girder, comprising: measuring a slope angle of a girder (S100) from a horizontal measurement apparatus mounted on the girder; adjusting the horizontal level of the girder from an inclination angle obtained from the measurement step (S200) for individually operating the lift devices mounted on both sides of the girder in order to make the lift devices individually operate.

(Embodiment 9) A bridge height adjustment method for adjusting the horizontal level of a girder, comprising: measuring a slope angle of a girder from a horizontal measurement apparatus mounted on the girder; adjusting a horizontal level of the girder from an inclination angle obtained from the measurement step; And a variable elevating step (S300) for operating a landing gear mounted on both sides of the girder to measure a real time angle change value from the measuring apparatus and adjusting the amount of elevation.

10: Pier 20: Shift
30: girder 100: base support
110: Fixing device 200: Lift device
201: first cylinder body 201, 202: first plunger
203: Hydraulic supply source 300: Movement support
301: support bar 401: laser beam horizontal oscillator
402: laser beam sensor 403: controller
404: Leveler 405: Controller
500: valve 600: second lift device
601: second cylinder body 602: second plunger
603: Moving mouth 604: Moving mouth
605: vertical moving body 606: vertical moving body
700: girder transfer plate

Claims (9)

A girder horizontal apparatus for elevating a girder (30) and adjusting the horizontal position of the girder when a bridge is installed,
A base support 100 installed at two or more pier 10 or alternate 20 upper surfaces and formed in a flat plate shape and fastened at a pier or alternately by a fixing device 110;
A lifting device 200 comprising a first cylinder body 201 mounted on one side of the base support and a first plenum 202 mounted inside the cylinder body and operated by an external hydraulic pressure source 203;
The first plenum end contact portion 209 is in close contact with the contact groove 303, and the first plenum end contact portion 209 is in close contact with the contact groove 303, A movable support 300 for supporting the girder on the other side;
The plurality of through bars are pierced with a plurality of support bars (301) provided alternately or at a pier, and the plurality of support bars guide the plurality of support bars in the axial direction of the plurality of support bars Can guide bush;
And a girder moving prevention plate (700) formed in a rubber material and having a groove or a projection on both sides and mounted between the other surface of the moving support and the girder and preventing the girder from being separated.

The method according to claim 1,
A laser beam horizontal oscillator 401 mounted on one side of the girder 30 and horizontally emitting a laser beam;
A laser beam sensor 402 mounted on the other side of the girder to sense a laser beam;
A controller 403 for calculating an angle of the girder from the laser beam horizontal oscillator 401 and the laser beam sensor 402; A girder horizontal device comprising:
The method according to claim 1,
A horizontal unit 404 mounted on one side of the intermediate side of the girder to measure the horizontal position of the girder;
And a controller (405) for calculating the angle of the girder from the horizontal.
The method of claim 2,
And a valve (500) for controlling the supply of hydraulic pressure to the elevating device (200) on both sides of the girder to maintain the girder horizontal from the angle calculated from the controller (403).
The method of claim 3,
And a valve (500) for controlling the hydraulic supply amount to the elevating device (200) on both sides of the girder to maintain the girder horizontal from the angle calculated from the controller (405).

The method according to any one of claims 1 to 5,
(600), one side of which is in close contact with the first plenum, and the other side of which is in close contact with the movement support.
The method of claim 6,
The second elevating device 600 is constructed such that the second cylinder body 601 and the second flange 602 are horizontally positioned and the moving holes 603 and 604 are mounted on both ends of the second cylinder body and the second flange And vertically moving bodies (605, 606) contacting with the same inclined surface as the inclined surface of the moving mouth are fixed to the moving support.
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