KR101317753B1 - The bridge construction technique for which a construction cable was used - Google Patents

Abstract

Concrete temporary bridge using a cable according to the present invention is installed on both sides of the ground, a pair of alterations each having a first cable installation portion and a second cable installation portion is formed at the upper end, both ends of the first cable installation portion The primary cable is coupled to each other, and both ends in the longitudinal direction are respectively installed at the upper end of the shift so as to be supported by the primary cable, the lower end of the steel formwork is formed with a plurality of vertical material coupling holes are formed in the vertical direction; The upper end is coupled to the vertical coupling hole, a plurality of vertical members disposed along the longitudinal direction of the steel formwork, and are installed on the steel formwork and supported on the upper ends of the vertical members, respectively, the third cable installation portion is formed at both ends in the longitudinal direction, respectively. Both ends of the upper slab and the second cable installation portions are respectively coupled to the secondary cable to elastically support the lower ends of the vertical members, and the steel After removing the formwork, the primary cable and the secondary cable, both ends are respectively coupled to the third cable installation portion, and includes a tertiary cable that elastically supports the lower ends of the vertical members.

Description

Concrete bridge with cable {THE BRIDGE CONSTRUCTION TECHNIQUE FOR WHICH A CONSTRUCTION CABLE WAS USED}

The present invention relates to a concrete temporary bridge using a cable, and more particularly to a concrete temporary bridge using a cable that can be easily installed in the top plate of the bridge even in the terrain difficult to reinforce assembling and concrete placing.

In general, bridges are elevated structures that can be constructed to cross rivers, lakes, straits, bays, canals, lowlands, or other traffic or structures.

The bridge is composed of shifts and bridges fixed to the ground of rivers, rivers, and the like, and a top plate supported by the shifts and bridges to allow vehicles or people to communicate.

However, in the conventional bridges, rebar assembly and concrete placing process for the construction of the top plate is difficult in the depth of the deep or steep terrain.

Documents related to the present invention include Korean Patent Application Publication No. 10-2010-0025163 (March 09, 2010), which discloses a PSC girder bridge construction method and an alternate wall structure used therein for easy maintenance. have.

An object of the present invention is to install the vertical members that act as a pier to the bottom of the steel formwork on which the upper slab is installed, and by elastically supporting the bottom of the vertical members with a support cable, the top plate of the bridge easily in the terrain difficult to reinforce assembling and concrete casting To provide a concrete bridge bridge using a cable that can be constructed.

The present invention is installed on both sides of the ground, respectively, a pair of alternations each having a first cable installation portion and a second cable installation portion is formed on the top, the primary cable is coupled to both ends of the first cable installation portion, respectively, Both ends of the longitudinal direction are respectively installed at the upper end of the shifts to be supported by the primary cable, the lower end is a steel formwork formed with a plurality of vertical member coupling holes penetrating up and down along the longitudinal direction, the upper end is coupled to the vertical member coupling holes, A plurality of vertical members disposed along the longitudinal direction of the steel formwork, upper slabs installed on the steel formwork and supported at the upper ends of the vertical members, respectively having third cable installation portions a at both ends in the longitudinal direction, and the second cable Both ends are respectively coupled to the installation portions, the secondary cable for elastically supporting the lower ends of the vertical members, the steel formwork and the primary cable and the secondary cable After the removal of the block, both ends are respectively coupled to the third cable installation, characterized in that it comprises a tertiary cable for elastically supporting the lower ends of the vertical members.

Here, the steel formwork is preferably coupled to the first cutout portion along the longitudinal direction and the first connection member for connecting the first cutout portion to the bottom surface so as to be respectively divided in the transverse direction.

In addition, the first connection member is coupled to each of the upper end and the lower end of the first cutout, a pair of first connecting plate and a plurality of first fastening holes are formed up and down, and are inserted through the first fastening holes It is preferable that a plurality of first fastening members are provided through the steel formwork.

In addition, the lower end of the vertical member is formed with a first through-hole through which the primary cable is laterally coupled, and a second through-hole formed below the first through-hole, the second cable is coupled through the side It is preferable.

In addition, the upper end of the vertical member is projected in the slab installation groove through the vertical member coupling hole, it is preferable to be integrally coupled to the upper slab.

In addition, the upper edge portion of the vertical member has a length up and down, the lower end is preferably further provided with a plurality of branches supporting the bottom surface of the slab installation groove.

In addition, at both ends of the steel formwork in the transverse direction, the second cutout is formed along the longitudinal direction so as to be divided in the transverse direction, respectively, a pair of working scaffold having a length along the longitudinal direction of the steel formwork is further installed, It is preferable that a second connection member for connecting the second cutout is coupled to the top and bottom of the working scaffold.

In addition, the second connection member is coupled to the upper and lower ends of the second cutout, respectively, a pair of second connecting plate and a plurality of first fastening holes are formed up and down and are inserted through the first fastening holes It is preferable that a plurality of first fastening members are penetrated to the steel formwork.

In addition, the second cutting portion is further formed with a beam insertion hole along the longitudinal direction of the working scaffold, it is preferable that a horizontal beam for supporting the working scaffold is inserted in the beam insertion hole.

The present invention is to install the vertical members supporting the lower end of the steel formwork, and the lower end of the vertical members to be elastically supported by a support cable, it is easy to construct the top plate of the bridge even in the terrain difficult to reinforce assembling and concrete casting Have

1 is a side view for showing a state of installing a concrete temporary bridge using a cable according to the present invention.
Figure 2 is a side view for showing a state of completing the installation of a concrete temporary bridge using a cable according to the present invention.
Figure 3 is a cross-sectional view of the main part to show the installation state of the vertical member and the secondary cable and the tertiary cable in the concrete temporary bridge using the cable according to the present invention.
Figure 4 is a cross-sectional view for showing the steel formwork in the concrete temporary bridge using the cable according to the present invention.
5 is a view for showing the working scaffolding of the steel formwork in the concrete temporary bridge using the cable according to the present invention.

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

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving it will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings.

The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims.

In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

1 is a side view for showing the state of the concrete construction bridge using the cable according to the present invention, Figure 2 is a side view for showing a state of completing the installation of the concrete temporary bridge using the cable according to the present invention.

And, Figure 3 is a cross-sectional view of the main part for showing the installation state of the vertical member and the secondary cable and the tertiary cable in the concrete temporary bridge using the cable according to the present invention.

In addition, Figure 4 is a cross-sectional view for showing the steel formwork in a concrete temporary bridge using a cable according to the invention, Figure 5 is a view for showing the working scaffolding of steel formwork in a concrete temporary bridge using a cable according to the present invention. .

1 to 5, the concrete temporary bridge using the cable according to the present invention is a pair of alternating 100, the primary cable 200, steel formwork 300, a plurality of vertical materials ( 400, upper slab 500, secondary cable 600, and tertiary cable 700.

First, the pair of shifts 100 are installed on both grounds, such as rivers and rivers 10, respectively.

The first cable installation unit 110 for installing the primary cable 200 to be described later, and the second cable installation unit for installing the secondary cable 600 to be described later (above the shifts 100) 120 is formed respectively.

The first cable installation unit 110 and the second cable installation unit 120 may be formed on both side surfaces of the alternations 100, respectively.

Here, the first cable installation unit 110 and the second cable installation unit 120 is provided with a coupling (not shown) for coupling both ends of the primary cable 200 and the secondary cable 600 which will be described later Can be.

The coupler may have a structure that can be opened and closed to enable coupling and detachment of the primary lower cable 200.

The primary cable 200 is fixed to the first cable installation unit 110 formed on the upper end of the primary tension by the both ends of the primary tension (100). Here, the primary cable 200 may be made of a metal beam having a certain strength,

At this time, the primary cable 200 may form a straight line horizontally at the upper end of the shift 100 in a state where both ends are fixed to the first cable installation unit 110.

As shown in more detail in Figures 4 and 5, the steel formwork 300 is installed at both ends in the longitudinal direction at the top of the alternating 100 to be supported by the primary cable 200, respectively.

Here, the slab installation groove 310 is formed in the upper end of the steel formwork 300 along the longitudinal direction.

In addition, a plurality of vertical material coupling holes 320 penetrate upward and downward along a longitudinal direction at a lower end of the steel formwork 300.

In addition, the steel formwork 300 may be formed on the bottom surface of the slab installation groove 310 in the longitudinal direction so that the first cutout portion 311 along the longitudinal direction.

In addition, a first connection member 330 for connecting the first cutout 311 may be coupled to an upper end and a lower end of the slab installation groove 310.

The first connection member 330 is coupled to the upper and lower ends of the first cutout portion 311, and a pair of first connection plates 331 having a plurality of first fastening holes formed up and down, and the A plurality of first fastening members 332 inserted into the first fastening holes and coupled to the steel formwork 300 may be provided.

At both ends of the steel formwork 300 in a lateral direction, a pair of working scaffolds 350 having a second cutout portion 351 formed along the longitudinal direction may be further installed to be split in the lateral direction.

The pair of working scaffolding 350 may be installed to have a length along the longitudinal direction of the steel formwork 300.

In addition, a second connection member 360 for connecting the second cutout 351 may be coupled to the upper and lower ends of the working scaffold 350.

The second connection member 360 is coupled to the upper and lower ends of the second cutout 351, respectively, and a pair of second connection plates 361 having a plurality of second fastening holes formed up and down, and the A plurality of second fastening members 362 may be provided to be inserted through the second fastening holes and coupled to the steel formwork 300.

Here, the beam insertion hole 352 may be further formed in the second cutout 351 along the longitudinal direction of the working footing 350.

In addition, a horizontal beam 370 may be inserted into the beam insertion hole 352 to reinforce strength by supporting the longitudinal direction of the working footing 350.

The cross beam 370 may be made of a metal beam having a certain strength, and is used for reinforcing the strength of the working scaffold 350.

That is, the working footing 350 can be easily coupled and separated by the second connection member 360, through which the horizontal beam 370 can be easily installed.

In addition, after the concrete 520 of the upper slab 500 to be described later is cured in the slab installation groove 310 of the steel formwork 300, a separating material (not shown) may be applied to be easily separated. .

As the separator, polytetrafluoroethylene (PTFE) may be used.

In addition, rails 380 having guide grooves formed along the longitudinal direction may be installed at both ends of the steel formwork 300 in the width direction.

Work rails (not shown) may be installed on the rails 380 so as to be movable by a driving force of a manual or driving motor.

As shown in more detail in FIG. 3, the plurality of vertical members 400 may be formed to have a length up and down, and may be manufactured using a metal beam or reinforced concrete.

Such vertical members 400 may be disposed along the longitudinal direction of the steel formwork 300 in a state where the upper end is penetrated through the vertical member coupling hole 320 described above.

Here, a first through-hole 420 through which the secondary cable 600 to be described later penetrates laterally through the lower side of the vertical member 400 is coupled to the secondary cable 600 to be described later, and the first The second through hole 430 is formed above the through hole 420 to allow the tertiary cable 700 to be laterally coupled to the third hole 700.

In addition, the upper ends of the vertical members 400 protrude and are positioned in the slab installation groove 310 through the vertical member coupling holes 320, and are integrally coupled to the upper slab 500 to be described later.

In addition, the upper edge portion of the vertical member 400 has a length up and down, the lower end may be further provided with a plurality of branch zones 410 for supporting the bottom surface of the slab installation groove (310).

The branch support 410 serves to support the upper ends of the vertical members 400 to maintain a predetermined height.

The upper slab 500 is installed in the slab installation groove 310 of the steel formwork 300 to form a top plate of the bridge.

This, the upper slab 500 is supported on the top of the vertical member 400, the second cable installation portion 120 may be formed on both sides of the upper slab 500, respectively.

That is, both ends of the third lower cable 600 to be described later may be coupled to the second cable installation unit 120, respectively.

Here, the upper slab 500 can be installed through the process of assembling the reinforcing bars 510 in the slab installation grooves 310, and after pouring concrete 520 to the assembled reinforcing bars 510, curing for a predetermined time. have.

The reinforcing bar 510 may be bound in a form of supporting the upper ends of the vertical members 400 from below.

In addition, the upper slab 500 is installed in the state in which both ends in the longitudinal direction are mounted on the upper end of the shift 100 when the steel formwork 300 described above.

Here, a separate support member (not shown) may be installed between the longitudinal ends of the upper slab 500 and the upper ends of the shifts 100.

Here, a separate coupler (not shown) may be installed in the second cable installation unit 120. The coupler, which is not shown, may be opened and closed to allow the second lower cable 600 to be coupled and separated. It can have

Both ends of the secondary cable 600 are respectively coupled to the second cable installation parts 120 to elastically support lower ends of the vertical members 400.

The secondary cable 600 may be manufactured using a metal wire and may be coupled to the first through hole 420 formed at the lower ends of the vertical members 400.

And, both ends of the longitudinal direction of the secondary cable 600 is coupled to the second cable installation portion 120, respectively.

In this case, both ends of the longitudinal direction of the secondary cable 600 may be coupled by separate fastening members (not shown) in the state inserted into the second cable installation unit 120.

That is, since the secondary cable 600 elastically supports the vertical members 400 upwards, the vertical members 400 may be stably installed, and after the installation of the upper slab 500 is completed, the secondary lower cables Can be demolished.

The tertiary cable 700, after dismantling the steel formwork 300, the primary cable 200 and the secondary cable 600, both ends are respectively coupled to the third cable installation portion 530, the vertical member 400 Elastic support of the bottom of the).

The tertiary cable 700 may be manufactured using a metal wire in the same manner as the above-described secondary cable 600, and is coupled to the second through hole 430 formed at the lower ends of the vertical members 400.

And, both ends of the tertiary cable 700 is temporarily fixed to the rear of the shift during the upper slab installation process.

Subsequently, after dismantling the steel formwork 300, the primary cable 200, and the secondary cable 600, both ends of the tertiary cable 700 are fixed to the third cable installation unit 530, respectively.

At this time, both ends of the longitudinal direction of the tertiary cable 700 may be coupled to the third cable installation unit 530 by a separate fastening member (not shown).

That is, the tertiary cable 700 elastically supports the vertical members 400 upwards, and the tertiary cable 700 is used as a permanent structure for supporting the supports, unlike the secondary cable 600 described above.

As a result, the present invention by installing the vertical member 400 supported by the primary lower cable 500 at the bottom of the steel formwork 300, the upper slab 500 is installed, even in the terrain difficult to reinforce assembling and concrete casting The top plate of the bridge can be easily constructed.

Although specific embodiments of the concrete temporary bridge using the cable of the present invention have been described so far, it is obvious that various embodiments can be modified without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

It is to be understood that the foregoing embodiments are illustrative and not restrictive in all respects and that the scope of the present invention is indicated by the appended claims rather than the foregoing description, It is intended that all changes and modifications derived from the equivalent concept be included within the scope of the present invention.

100: alternate 110: first cable mounting portion
120: second cable installation portion 200: primary cable
300: steel formwork 310: slab mounting groove
311: first cutout 320: vertical member coupling hole
330: first connecting member 331: first connecting plate
332: first fastening member 350: working scaffold
351: second incision 352: beam insertion hole
360: second connecting member 361: second connecting plate
362: second fastening member 370: cross beam
380: rail 400: vertical
410: branch zone 420: first through hole
430: second through hole 500: upper slab
510: rebar 520: concrete
530: third cable installation portion 600: secondary cable
700: tertiary cable

Claims (9)

A pair of shifts, each of which is installed on both sides of the ground, each of which has a first cable installation part and a second cable installation part formed on an upper end thereof;
A primary cable having both ends coupled to the first cable installation unit;
Longitudinal both ends are respectively installed at the upper end of the shift to be supported by the primary cable, the lower end of the steel formwork at least two vertical material coupling holes are formed in the vertical direction;
An upper end coupled to the vertical member coupling hole and at least two vertical members disposed along a longitudinal direction of the steel formwork;
An upper slab installed on the steel formwork and supported at upper ends of the vertical members, and having third cable installation portions formed at both ends in a longitudinal direction thereof;
A second cable coupled to both ends of the second cable installation parts to elastically support lower ends of the vertical members; And
After the steel formwork and the primary cable and the secondary cable dismantling, both ends are respectively coupled to the third cable installation portion, the tertiary cable for elastically supporting the lower end of the vertical member; cable comprising a Used concrete temporary bridge.
The method of claim 1,
The steel formwork,
A first incision along the longitudinal direction on the bottom surface such that the respective divisions in the transverse direction are possible;
Concrete temporary bridge using a cable, characterized in that the first connection member for connecting the first cutout is coupled.
3. The method of claim 2,
The first connection member,
A pair of first connection plates which are respectively coupled to the upper end and the lower end of the first cutout and have at least two first fastening holes formed up and down; And
At least two first fastening members inserted through the first fastening holes and penetrated by the steel formwork; and a concrete temporary bridge using a cable.
The method of claim 1,
At the bottom of the vertical members,
A first through hole through which the primary cable is laterally coupled; And
It is formed below the first through-hole, the second through-hole through which the secondary cable is coupled to the side; Concrete temporary bridge using a cable, characterized in that formed.
The method of claim 1,
The upper end of the vertical members,
Provisionally positioned in the slab installation groove through the vertical material coupling hole, concrete temporary bridge using a cable, characterized in that coupled to the upper slab integrally.
The method of claim 5,
In the upper edge portion of the vertical member,
The concrete temporary bridge using a cable having a length up and down, the lower end is further provided with at least two branches supporting the bottom surface of the slab installation groove.
The method of claim 1,
At both ends of the steel formwork in the transverse direction,
A second incision is formed along the longitudinal direction so as to be divided in the transverse direction, and a pair of working scaffold having a length along the longitudinal direction of the steel formwork is further installed,
At the top and bottom of the working scaffold,
Concrete temporary bridge using a cable, characterized in that the second connecting member for connecting the second cutout is coupled.
The method of claim 7, wherein
The second connection member,
A pair of second connecting plates which are respectively coupled to the upper and lower ends of the second cutout and have at least two first fastening holes formed up and down; And
At least two first fastening members inserted through the first fastening holes and penetratingly coupled to the steel formwork, the concrete temporary bridge using a cable provided therewith.
The method of claim 7, wherein
In the second incision,
A beam insertion hole is further formed along the longitudinal direction of the working scaffold,
In the beam insertion hole,
Concrete temporary bridge using a cable, characterized in that the horizontal beam is inserted for supporting the working scaffold.

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