KR101774990B1 - Stress-distributing cable bridge using device for reducing sidewalk live load of cable fixture and method for constructing this same - Google Patents

Abstract

The present invention relates to a stress distributing cable bridge using a dedicated device for a crowd load on a fixated end of a cable and a construction method thereof. The purpose of the present invention is to prevent partial damage by completely distributing stress transferred to a cable to a box-shaped girder, to firmly maintain a cable bridge by securing a bearing force having a strength resisting against the stress transferred to the cable, allowing the cable to primarily support a fixated load such as a dead load or the like, and to allow a dedicated device for a crowd load to secondarily bear a live load when the live load is generated due to a crowd load without adding a cable, thereby securing structural stability. According to the present invention, the stress distributing cable bridge using the dedicated device for the crowd load on the fixated end of cable comprises: a box girder (10), a plurality of cables (20) and at least one dedicated device for the crowd load of the cable. The girder (10) supports a top plate of a bridge while being supported by a pier. The plurality of cables (20) are arranged through a main tower, has an end connected to the box girder or one side connected to a main cable installed through the main tower, and has the other side connected to the box girder to support the box girder. Lastly, at least one dedicated device for the crowd load of the cable is installed inside the box girder, and supports the box girder and the cables by a compression force opposite to a tensile force applied to the cables.

Description

TECHNICAL FIELD [0001] The present invention relates to a stress-dispersive cable bridge using a dedicated load device for a cable fixture, and a method of constructing the same.

The present invention relates to a bridge supported by a cable, and more particularly, to a bridge having a cable fixation stage for securing effective stability against dead loads and live loads by dividing the stress transmitted from a cable into a live load and a live load, The present invention relates to a stress dispersive cable bridge utilizing a dedicated cluster load device and a construction method thereof.

Bridges supported by cables are divided into suspension bridges and cable-stayed bridges. Bridge bridges are used for various purposes such as bridge bridge, bridge bridge, and bridge bridge.

Suspension bridges consist of reinforced girder, main cable, vertical suspension and auxiliary cable for lateral load support, pylon and anchorage. The reinforcement type girder supports the upper structure, and the weight of the reinforced type girder and the load of the pedestrian (vehicle) are transmitted to the main cable through the auxiliary cable, and the main cable receives the load transmitted through the auxiliary cable To the main tower and Anchorage.

A cable-stayed bridge is a bridge supporting a main span using a slant cable installed in a sloping direction from a main tower. Deck segments are sequentially installed on both pylons to form a main span and a side span, And the deck segments between the main span and the sidewall are connected to each other by using a warp cable.

The cable bridge according to the prior art has a structure in which a cable (ancillary cable or an inclined cable) is connected to a girder (particularly a box girder) and a girder has a cantilever upper flange blade (a narrow section) Since the cable is connected to the wing, the tensile force of the cable concentrates on the wing, and the wing is structurally weak, which causes deformation of the box girder. These problems require frequent maintenance and cause economic losses.

The patent document (Japanese Patent Application Laid-Open No. 10-2012-0072239) discloses a cable connector comprising: a first coupling member coupled to a lower end of an auxiliary cable hanging a girder portion while connected to a main cable of a suspension bridge; And a second joint which is coupled to the first joint through an elastic body and fixed to the girder. As described above, since the cross-sectional area of the reinforcement girder portion to which the auxiliary cable is connected is small, deformation of the reinforcement girder occurs have.

Published patent application No. 10-2012-0072239

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a cable type bridge structure in which a stress transmitted to a cable is dispersed in a box type girder as a whole to prevent local damage and to secure a supporting force of a size against a stress transmitted by a cable, It is important to keep the cable firmly in place and to support the fixed load such as dead load. Secondly, when the live load is caused by the cluster load, Disclosed is a cable bridge and its construction method.

The stress-relieved cable bridge utilizing the community load dedicated device of the cable fixing end according to the present invention comprises: a box girder supporting a bridge top plate while being supported by a pier; A plurality of cables disposed on the main tower and connected to the main girder with one end connected to the box girder or one side connected to the main tower and the other side connected to the box girder to support the box girder; And at least one cable group load carrying device installed in the box girder and supporting the box girder and the cable by a compressive force opposite to a tensile force acting on the cable, Wherein the cable is connected to a lug formed on a side wall of the box girder, the cable crowding load dedicated device is mounted inside the box girder, and the lug And is fixed to another side wall on the opposite side of the installed side wall to support the side wall on which the lug is mounted with the other side wall as a supporting base.

A method of constructing a stress-dispersed cable bridge utilizing a community load dedicated device of a cable fixing end according to the present invention is characterized in that a lug is formed outside the side walls on both right and left sides of the box girder, A first step of installing a cable harness dedicated device inside the box girder and installing the box girder on the lower structure of the bridge; A cable is disposed through the main tower and one side is installed on the main tower and the other side is installed on the lug of the box girder installed in the first stage or the upper part of the cable is connected to the main cable installed through the main tower, To the lug of the second step.

According to the stress distribution type cable bridge utilizing the community load dedicated device of the present invention and the construction method thereof, the cable is connected to the side wall of the box girder, and the stress transmitted through the cable is entirely dispersed in the box girder, It is possible to prevent the local damage of the connected part and the whole damage of the box girder and to secure the structural stability by connecting the cable by using the box girder having the stable box type sectional structure to increase the durability and reduce the maintenance cost .

The effect of maintaining the box girder and cable bridges for a long period of time even when various changes occur in the cable by changing the size of the supporting force corresponding to the change in the magnitude of the stress transmitted from the cable through the dedicated load- .

In addition, since the load of the cluster load dedicated device can bear the load without increasing the number of additional cables in addition to the number of cables supported only by the dead load, such as the live load such as the off-grid community load transmitted through the cable through the dedicated cluster load- There is economical effect of bridge.

FIGS. 1A and 1B are diagrams showing the entire structure of a stress-relieved cable bridge utilizing a community load dedicated device of a cable fixing end according to the present invention,
1A is a cable-stayed bridge,
Figure 1b is a suspension bridge.
FIG. 2 is a cross-sectional view of a stress-relieved cable bridge utilizing a community load dedicated device of a cable fixation end according to the present invention; FIG.
3 is a cross-sectional view of a cable bridge to which two box girders are applied, as another example of a stress-dispersive cable bridge utilizing a community load dedicated device of a cable fixing end according to the present invention.
4 to 8 are diagrams showing another example of a cable community load dedicated device applied to a stress distribution type cable bridge utilizing a community load dedicated device of a cable fixation end according to the present invention, respectively.
FIGS. 9 and 10 are a plan view and a front view, respectively, showing an example in which the cable cluster load dedicated device applied to the stress-dispersive cable bridge utilizing the dedicated load device of the cable fixation end according to the present invention is a movable type.

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and these may be changed according to the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification.

As shown in FIGS. 1A and 2, the stress-relieved cable bridge utilizing the community load dedicated device of the cable fixing end according to the present invention is installed on a pier 1 as a lower structure of a bridge, The cable 20 supporting the box girder 10 and the box girder 10 supporting the box girder 10 by the compressive force which is opposite to the tensile force applied to the cable 20, (20) and a box girder (10).

The box girder 10 is a steel box widely used in cable bridges in the form of a box with a rectangular cross section and a lug 11 is formed such that the cable 20 is connected to the side wall.

The lugs 11 are, for example, in the form of a rectangular plate provided with a hole and through which the end of the cable 20 is inserted and fixed.

The position of the lug 11 varies depending on the position of the cable 20 and in order to install the cable 20 on the left and right side walls of the box girder 10 when one box girder 10 is applied as shown in FIG. Lugs 11 are formed (fixed by welding or the like) on both side walls of the box girder 10, that is, on the outer surfaces of the first and second side walls.

The lugs 11 may be installed to the position of the cable 20 before installation of the bridge or may be installed with the wiring of the cable 20. [

In addition to welding, the lug 11 can also be installed in a bolt manner. For example, a plurality of bolts may be provided directly to the box girder 10 or through a plate, and a fixing plate having a plurality of bolt holes may be integrally formed in the lug 11, And then fastened by fastening the nut.

The cable 20 is a known product used in cable bridges and is fixed through the pylon 3 according to the type of cable stayed bridge and suspension bridge so that the end is connected to the lug 11 of the box girder 10, And is connected to the lug 11 of the box girder 10 after it is fixed to the main cable 4 which is wired laterally through the box girder 10.

The cable bundle load dedicated device supports the box girder 10 and the cable 20 by a compressive force opposite to a tensile force acting on the cable 20 with the box girder 10 as a support base, (See FIG. 5), a bolt-type cable assembly load-carrying device 40 (see FIG. 3), a load-dedicated device (see FIGS. 2 and 3), a reinforced cable crowd load dedicated device ) (See FIG. 6), a tensile linear cable community load dedicated device 50 (see FIG. 7), a hydraulic cable community load dedicated device 80, and the like.

Fig. 2 shows a spring-loaded cable community load dedicated device 70, which includes first and second fixing blocks 71 and 72, respectively, which are fixed to the opposing side walls of the box girder 10, A spring 73 fixed to the two fixing blocks 71 and 72 for supporting the first and second fixing blocks 71 and 72 and a spring housing 74 for protecting the spring 73.

The first and second fixing blocks 71 and 72 are fixed to the side walls in the same manner as the first and second fixing blocks 61 and 62 of the reinforcing cable group load carrying device 60 described later, The first and second spring connecting portions are formed.

The spring 73 is composed of first and second connecting portions 73b and 73c formed on both sides of the coil portion 73a and the coil portion 73a and integrally formed with the first and second connecting portions 73b and 73c The first connection portion 73b is formed in a bolt shape so that the nut 75 is fastened to the first and second fixing blocks 71 and 72. The first connection portion 73b is connected to the first and second fixing blocks 71 and 72, A head portion having a large cross-sectional area may be formed so as to be fixed to the second fixing block 72 by being fastened by the nut 75 after being inserted into the connection portion.

The spring housing 74 is tubular and box-like enclosing the coil portion 73a of the spring 73 and protects the spring 73. [

3, two box girders 10 can be applied. The two box girders 10 are spaced apart from each other by a predetermined distance, and the connecting members 10-1 of steel (steel plates, steel beams, etc.) Lt; / RTI > At this time, the connection member 10-1 and the spring-loaded cable community load dedicated device 70 are provided on the same line.

The lug 11 and the spring-loaded cable community load dedicated device 70 are arranged in a line so that the stress dispersion effect of the cable 20 can be enhanced. In the construction process, the lug 11 and the spring- For example, when the position of the lug 11 is changed so that the lug 11 is additionally installed in a place where there is no spring-loaded cable community load dedicated device 70, As shown in FIGS. 9 and 10, it is also possible to movably install the spring-loaded cable group load carrying device 70 on the box girder 10 so that the spring-loaded cable group load carrying devices 70 can be aligned in a row Do.

The spring-loaded cable group load carrying device (70) includes first and second moving plates (76, 77) and first and second rails (12, 13) formed on the inner circumferential surface of the box girder .

Fig. 4 shows a reinforced cable community load dedicated device 60, which includes first and second fixing blocks 61 and 62, respectively, which are fixed to opposite side walls of the box girder 10, first and second fixing blocks 61 and 62 And a reinforcing member 66 reinforcing the connection box 65 and the connection box 65 through the first and second bolts 63 and 64.

The first and second fixing blocks 61 and 62 may be fixed together with the lug 11 or may be welded to the side wall through bolts passing through the side walls and the first and second bolts 63 and 64 Have bolt fastening portions 61a and 62a supported by the respective nuts, respectively.

The bolt fastening portions 61a and 62a have a space through which the inside and the outside of the bolt fastening portions 61a and 62a pass for the operation of the nut.

The first and second bolts 63 and 64 are fixed to the first and second fixing blocks 61 and 62 and the connecting block 65 by the nuts, It is possible to adjust the pulling force of the cable 20 by tightening the nut.

The connection box 65 may be a box (tubular shape or the like) having a space formed therein and may be configured to pass through the inside and outside of the box for operation of the nut.

The reinforcing material 66 prevents the connection box 65 from being deformed by the stress transmitted from the cable 20 and can be formed in various forms such as a honeycomb shape and the periphery of the reinforcing member 66 is welded to the inner circumferential surface of the connection box 65 And fixedly integrated.

As shown in FIG. 5, the turnbuckle type cable crowd load dedicated device 30 has first and second side portions, which are respectively fixed to the inner circumferential surfaces of the side walls of the box girders 10 facing each other, The bolt bodies 31 and 32 and the female screw portions having different directions are screwed to the first and second bolt bodies 31 and 32 on both sides in the longitudinal direction to collect the first and second bolt bodies 31 and 32 And a nut body 33 for widening. The turnbuckle type cable community load dedicated device 30 includes a first and a second nut body which are opposite to each other on the side wall of the box girder 10, It is also possible to constitute a bolt body.

The first and second bolts 31 and 32 are fixed by welding or through a holder formed on the inner circumferential surface of the box girder 10, respectively.

Alternatively, the lug 11 and the first and second bolts 31, 32 may be secured together through bolts passing through the box girder 10. [

5, the first and second bolts 31 and 32 are arranged in the same line as the lugs 11 on both sides of the box girder 10, Type cable community load carrying device 30 distributes the stress transmitted to the lug 11 through both cables 20 to the box girder 10 as a whole.

The turnbuckle type cable crowd load dedicated device 30 having such a structure collects the first and second bolts 31 and 32 through the rotation of the nut body 33. In this process, A compressive force in a direction opposite to the tensile force of the cable 20 acts to prevent the side wall of the box girder 10 from being deformed by the cable 20. [

Figure 6 shows a bolted cable community load dedicated device 40 in which the bolted cable community load dedicated device 40 is arranged transversely (parallel, inclined, etc.) inside the box girder 10, A bolt 41 which is screwed to the inside of the side wall provided with the bolts 41 and which is screwed to a nut fixed in advance on the side wall of the bolt 41 and is fastened to the opposite side wall or the separate support wall 14, (42).

That is, the other side of the bolt 41 is passed through the side wall or the support wall 14 opposite to the side wall on which the lug 11 is installed.

7 shows a tension linear cable community load dedicated device 50 The tensioned linear cable community load dedicated device 50 is disposed in the box girder 10 in a horizontal direction (parallel or inclined) so that one side is fixed to the side wall of the box girder 10 on which the lug 11 is installed And a fixing port 52 for fixing the tension cable 51 while being supported by a sidewall opposite to the sidewall on which the lug 11 of the box girder 10 is provided or a separate supporting wall 14.

The bolt-type cable community load dedicated device 40 and the tensile linear cable community load dedicated device 50 are not limited to being applied only to the case where the lug 11 is formed on only one side wall of the box girder 10, It can be easily applied to both lugs 11 if the lug 11 has a height difference or a front-rear position difference.

6 and 7, the separate support wall 14 may be formed from the bottom of the box girder 10 to the ceiling and also serve to reinforce the box girder 10, or may be connected to the floor or the ceiling only .

8 shows a hydraulic cable harness dedicated device 80. The hydraulic cable harness dedicated device 80 is installed in the box girder 10 in a lateral direction (parallel, inclined, etc.) A hydraulic cylinder 81 fixed to the side wall provided with the lug 11 of the girder 10 and a rod 82 fixed to the side wall opposite to the side where the hydraulic cylinder 81 is provided and which is projected and retracted by hydraulic pressure.

The stress-dispersed cable bridge construction method utilizing the cluster load dedicated device of the cable fixation stage according to the present invention is as follows.

1. Manufacture and installation of box girders.

The lug 11 and the cable harness dedicated devices 30, 40, 50, 60, 70, and 80 are provided on the box girder 10 and prepared.

Construction of Piers 1 - Construction of Box Girders 10 on Piers 1 - Construction of Cable Bridges of the present invention is carried out on top of box girders 10, which will be appreciated by those skilled in the art, and thus a detailed description thereof will be omitted .

2. Cable installation and compression.

Connect the bottom of the cable (20) connected to the main tower or main cable to the lug (11). In order to facilitate the connection of the cable 20, the cable group load dedicated devices 30, 40, 50 may be in an initial state with no or little compression force, and after completing the installation of the cable 20, Lt; / RTI >

Through this process, the cable 20 has a tensile force to pull the lug 11 of the box girder 10 and the cable crowd load dedicated devices 30,40,50,60,70 connect the lug 11 to the cable The side wall of the box girder 10 is not bent and deformed by the tensile force of the cable 20 because the side wall of the box girder 10 has a pulling force in a direction opposite to the direction in which the cable 20 is pulled.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood, however, that the invention is not to be limited to the specific forms thereof, which are to be considered as being limited to the specific embodiments, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims. .

1: Pier, 2: Top plate
3: pylon,
10: box girder, 11: rug
12, 13: 1st and 2nd rails
20: Cable,
30: turnbuckle type cable community load dedicated device,
40: Bolt-type cable crowd load dedicated device,
50: Tension linear cable community load dedicated device,
60: Reinforced cable community load dedicated device,
70: Spring type cable cluster load dedicated device,

Claims (8)

A box girder supporting the bridge top plate while being supported by a pier;
A plurality of cables disposed on the main tower and connected to the main girder with one end connected to the box girder or one side connected to the main tower and the other side connected to the box girder to support the box girder;
And at least one cable community load dedicated device installed in the box girder and supporting the box girder and the cable by a compressive force opposite to a tensile force acting on the cable,
Wherein the box girder includes at least one lug formed on the outer surface of the sidewall corresponding to the cable,
The cable is connected to a lug formed on the side wall of the box girder,
The cable bundle dedicated load device is mounted inside the box girder and fixed to the other side wall opposite to the side wall on which the lug is installed so as to support the side wall on which the lug is mounted using the other side wall as a supporting base, Wherein the stress-dispersive cable bridges utilize a dedicated load-carrying device for the cable fixation stage. The box girder (10) according to claim 1, wherein the cable harness dedicated device comprises first and second fixing blocks (71, 72) respectively fixed to the side walls facing the box girder (10) And a spring housing 74 fixed to the blocks 71 and 72 to protect the first and second fixing blocks 71 and 72 and the spring 73. The spring- Wherein the device is a device for connecting a cable to a load-carrying device. The box girder (10) according to claim 1, wherein the cable group load carrying device comprises first and second fixing blocks (61, 62) respectively fixed to the side walls of the box girder (10) And a reinforcing member (66) for reinforcing the connection box, wherein the connection box (65) is connected through two bolts (63, 64). Stress - dispersive cable bridges. [2] The apparatus according to claim 1, wherein the cable group load dedicated device comprises first and second bolt bodies each having one side fixed to an inner circumferential surface of the side wall and a screw thread having an opposite direction on an outer circumferential surface, And a nut body for screwing the first and second bolts to the second bolt body so that the first and second bolts are screwed to the 2-bolt body. The stress distribution type cable Bridges. The cable harness of claim 1, wherein the cable harness dedicated device is disposed within the box girder while passing through another sidewall of the box girder or a separate support wall, and one side of which is fixed to a side wall of the box girder, And a fixture for supporting the tension cable while being supported by another side wall or another supporting wall opposite to the side wall on which the lug of the box girder is installed, characterized in that it is a tensile linear cable community load dedicated device Stress - dispersive cable bridges using dedicated devices. The box girder according to claim 1, wherein the cable harness dedicated device is mounted transversely to the inside of the box girder while passing through another side wall or another supporting wall of the box girder and fixed to a side wall of the box girder And a tightening nut screwed to the bolt at an outer side of the other side wall of the box girder, wherein the bolt-type cable group load carrying device is a dedicated bolt-type cable crowd load carrying device. The cable group load carrying device according to claim 1, characterized in that the cable group load dedicated device is a hydraulic type cable community load dedicated device which is installed in the box girder in the lateral direction and in which the end portions of the hydraulic cylinder and the rod are fixed to the box girder Stress - Distributed Cable Bridges in Cables. A lug is formed outside the left and right side walls of the box girder while a cable crowd load dedicated device is provided inside the box girder to coincide with the lug inside the box girder and the box girder is placed on the lower structure of the bridge ;
A cable is disposed through the main tower and one side is installed on the main tower and the other side is installed on the lug of the box girder installed in the first stage or the upper part of the cable is connected to the main cable installed through the main tower, The method comprising the steps of: (a) installing a cable bridge to a lug of the cable bridge; and (b) installing the cable bridge to the lug of the cable bridge.

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