KR101131969B1 - Continuous Construction Method for Composite Bridge using Prestressed I-Type Girder - Google Patents

Abstract

The present invention relates to a method for continuously constructing multiple spans in a composite bridge using PSC type I girders, wherein a plurality of PS type I girders are manufactured, but the first tendon 40 is centered. Installing a plurality of anchorages 30 at each end to penetrate the through, and secure the installation space of the secondary tendon 60 by using a portion that the cross section is enlarged at the end of the girder while fixing the knitting side to the left and right of the primary tendon 40 In order to ensure that the projections 50 are fixed to the secondary tendon 60 on both sides of each end, and at the same time, the side span girders 10 and the center span girders 20 according to the arrangement direction of the secondary tendon 60 A first step (S1) of post-tensioning the primary tendons (40) of the respective girders (10, 20); After carrying the PS-type I girder (10, 20) to the site, using a crane mounted between the side bridge girder (10) between the shift (1) and the pier (2) and the center span girder between the bridges (2) A second step S2 of passing through 20; A protrusion 50 formed at one end of the side span girder 10, one end of which is disposed on one end of the shift 1 while inserting the secondary tendon 60 through the PSC type I girders continuously installed in the longitudinal direction. One end of the center span girder 20 disposed on the same pier (2) with the other end of the side span girder (10) is disposed on the pier (2) passing through the inside of the side span girder (10) from It penetrates and is fixed to the protrusion 50 formed at one end of the center span girder 20, and the same pier from the protrusion 50 formed at the other end of the side span girder 10 disposed on the pier 2. (2) a plurality of repetitive processes of penetrating the inside of the center span girder 20 disposed on the protrusion 50 formed at one end of the center span girder 20 disposed on the other piers 2 Center span girder (20) From the protrusion 50 formed at the other end of the center span girder 20 at the other end to the protrusion 50 formed at the other end of the side span girder 10 on which one end is disposed on the alternate end 1 of the other end. A third step (S3) of structurally binding side and center span girders 10 and 20 to be fixed; In the simple bridge state, install the intermediate connecting portion connecting the horizontal beam and the longitudinal direction connecting the PSC I type girders in the transverse direction, connect the Sofit plate 70 to the bottom, and the bottom plate slab concrete in the field to continually synthesize After forming the structure, the fourth step (S4) of removing the temporary support and installing a permanent support; And a fifth step (S5) of fixing the secondary tendons 50 by prestressing the respective spans. Since it includes a compressive force by prestressing the entire structure to increase the span length and solve the problem of the top plate cracks, by applying a multi-span continuous structure of more than three spans to improve the runability, construction properties and construction costs and maintenance costs It can reduce and increase the durability of the bridge.

PSC type I girder, composite bridge, side span, center span, sequencing method, secondary tendon

Description

Continuous Construction Method for Composite Bridge using Prestressed I-Type Girder}

The present invention relates to a method for continuously constructing a multi-span in a composite bridge using PS-type I girder, and more specifically, to separate the side-span girders and the center-span girders, and to cross each other with a secondary tendon The present invention relates to a multi-span sequencing method for composite bridges using PS-type I girders, which can increase span length, reduce construction cost and maintenance cost, and increase bridge durability by introducing prestressing compressive force to the entire structure. .

Prestressed Concrete (PSC) Bridges constructed using Type I girders are heavily weighted and have a large load difference depending on their location.

In general, the method of continuity of the PSC type I girder uses a method of mounting the PSC type I girder on the installed shifts and piers, and continually placing the connection part and the bottom plate slab between the mounted girders. Although there is a problem in that the cracks occur in the connection portion by the repetition of the changing load, durability is inferior.

In order to solve this problem, a method of adding a secondary tendon has been attempted, and as such a method, Korean Patent Registration No. 10-0724739 discloses a "method of constructing a PS-C girder bridge using a fixing device capable of adjusting tension force". The pore method of the patent is to form a protrusion at the end connected to the continuously installed girders to penetrate the secondary tendon in the longitudinal direction, and through the continuously installed girders through the secondary tendon all at once to tension and repair when necessary To mitigate this problem.

However, when constructing multi-span bridges, if the tension force is applied to the entire girder with one continuous secondary tendon, the compressive force applied to the entire structure will be weakened. It is difficult to apply due to the increase, especially when the tension is relieved for repair, there is a problem that the cracks occur in the upper bottom plate and the connection to the durability of the bridge falls.

Therefore, the technical problem of the present invention for solving the above problems is the PSC (PSC) that can increase the span, reduce the construction cost and maintenance costs by increasing the compression length by the prestressing to the whole structure It is to provide a multi-span continuous method for a composite bridge using an I-girder.

The present invention to solve the above technical problem,

Both ends are provided with a plurality of anchorages at both ends so that the primary tendons penetrate the center, and both ends are secured to secure the installation space of the secondary tendons by using a portion having an enlarged cross section, and both sides are fixed to the left and right sides of the primary tendons. Both side surfaces adjacent to each other are formed with projections on which secondary tendons are fixed, and both end side girders and side end girders are formed so as to face only one end side in accordance with a direction in which the protrusions are formed. A first step of dividing the girder into center span girders formed only toward the end sides adjacent to the first girder, and then post-tensioning the primary tendons of the respective girders by fixing units at both ends;

A second step of carrying the PS I type girders to a site and using a crane to mount side-girder girders between shifts and piers and to mount center-girder girders between piers;

A center span girder, which is disposed at the pier at the same time through the pier side end of the lateral girder and the lateral girder disposed on the pier from the protrusion formed at the alternating side end of the lateral girder disposed between the alternating and the pier. The secondary tendon is settled between the protrusions formed at one end portion adjacent to the pier via the pier side end portion of, and from the protrusions formed at the pier side end portion of the side span girder, the second tendon is disposed at the same pier as the pier side end portion. The second secondary tendon is fixed to an end side protrusion which is disposed at the same pier as other center span girders or other side span girders adjacent to the center span girders or through the ends of the center span girders, and the center span girders of the other side span girders. With other center span girders or other side span girders of span girders An end side protrusion disposed in one pier penetrates one end of the other center span girder or another side span girder disposed in the same pier as the adjacent end, and sets another secondary tendon to a protrusion formed at the other end. Repeatedly, a third step of structurally binding side span and center span girders;

In the simple bridge state, the intermediate beam connecting the horizontal beams and the longitudinal connecting the PSC I-girders in the lateral direction is installed, and the bottom plate slab concrete is poured and cured in the field by connecting the sofit plate at the bottom to form a continuous composite structure. After forming, the fourth step of removing the temporary stand and install the permanent stand; And

A fifth step of prestressing and fixing the secondary tendons for each span; Provides a multi-span continuous method of the composite bridge using PS C type girder comprising a.

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According to the multi-span sequencing method of the composite bridge using the PS-type I girder of the present invention as described above, the continuous span length is increased, the number of installation points of the expansion joint device is greatly reduced, By applying it, it is possible to improve the driving performance of the vehicle and reduce the maintenance cost, and the amount of construction materials such as concrete, reinforcing steel and prestressing steel used in bridge construction by structural continuity of girder and minimizing prestress loss of tendon installed continuously. Can be significantly reduced compared to the conventional method.

In addition, by compressing the tendons continuously in the state where the upper slab and the PS-type I girder are structurally synthesized, prestressing force can be introduced to the entire structure, and successive tendons are intersected at the intermediate connection to provide good compressive force. It can be delivered to the structure to eliminate the problem of cracking in the upper slab near the intermediate connection that is commonly encountered in continuous composite bridge can significantly increase the durability of the bridge.

Hereinafter, a multi-span continuous method of a composite bridge using a PSC type I girder according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

5 is a front side projection view illustrating each step of the multi-span continuous method according to an embodiment of the present invention, and FIG. 8 is a flowchart of the multi-span continuous method according to an embodiment of the present invention.

5 and 8, the multi-span sequencing method of the composite bridge using the PS-type I girder according to an embodiment of the present invention, the PS-type I girder is a side span 10 and the center span 20 The first step (S1) to produce and post-tensioning the primary tendon 40, and to lift the PS I-type girder (10, 20) and shift (1) and piers ( 2) the second step (S2) to be mounted on, the third step (S3) for inserting the secondary tendon 60 into the mounted girders (10, 20), and the intermediate slab and cross beams to install the upper slab concrete A fourth step (S4) of pouring and curing, and a fifth step (S5) of tensioning and fixing the secondary tendon 60 for each span.

Each step will be described in more detail with reference to the drawings.

FIG. 5A shows a first step of manufacturing the PS I type girder. As can be seen in Figures 5a and 8, the first step (S1) is a step of manufacturing a plurality of PS I-girder constituting the upper portion of the bridge, the side span at the production site adjacent to the factory or bridge construction site Produced by separating the girder 10 and the center span girder 20.

The CS-type I girder (10, 20) is provided with a plurality of fixing holes 30 at each end so that the primary tendon 40 is fixed at both ends through the center, the installation of the secondary tendon 60 Blocks are formed at the top of each end to secure space, and protrusions 50 are formed at each side to bias the secondary tendons 60 to the left and right of the primary tendons 40. At this time, according to the direction in which the secondary tendon 60 is disposed in the girder is produced by dividing the side span girders 10 and the center span girders 20.

1 and 2 are perspective views of the side span girders 10 and the center span girders 20 according to an embodiment of the present invention, Figures 3 and 4 are side span girders 10 according to an embodiment of the present invention And front and planar side projection views of the center span girders 20.

Referring to the drawings, the side-girder 10 is a girder for connecting the alternating portion 1 and the pier 2, each forming a protrusion 50 on both sides of one end, the secondary tendon 60 is the The sheath tube is inserted to penetrate longitudinally from each protrusion 50 to the other end portion through the inside of the central portion. Further, sheath pipes are formed on both sides of the other end, respectively, and the sheath pipe can penetrate in the longitudinal direction from the protrusion 50 to the other end of the adjacent position without passing through the center portion of the secondary tendon 60. Insert

The center span girder 20 is a girder connecting the pier 2 and the pier 2 to form protrusions 50 on both sides of both ends of the girder 20, and the secondary tendons 60 are formed. The sheath tube is inserted to penetrate in the longitudinal direction from the protrusion 50 to each end of the adjacent position without passing through the central portion.

Next, the primary tendon 40 installed in the girder is tensioned by a post-tensioning method, and fixed to the fixing unit 30 installed at both ends.

FIG. 5B shows a second step of mounting the PS I-girder to the shift 1 and the pier 2.

As can be seen in the drawing, the second step (S2) is a step of lifting and mounting the manufactured girder, the PS I-type girders (10, 20) are transported to the site and alternately using a crane Mount it on the support base installed on the upper part of (1) and pier (2). At this time, the side span girder 10 is mounted between the shift 1 and the pier 2 and the center span girder 20 is mounted between the bridges 2.

Figure 5c shows a third step of inserting the secondary tendon 60 in the longitudinal direction to the mounted CS C-girder, the third step (S3) is a mounted girder (as can be seen in the figure) Inserting the secondary tendon (60) in the 10,20), in the case of three spans, the side span (10) girder and the center span girders (20) are connected to each other, and if more than four spans as described above The center span girders 20 that are continuous in the center together are also connected to each other.

FIG. 6 is a projection view showing a state in which primary and secondary tendons 40 and 60 are inserted and installed at ends of side span girders 10 disposed on shifts 1 according to an embodiment of the present invention, and FIG. According to one embodiment of the invention is a projection view showing a state in which the primary and secondary tendon (40, 60) is inserted into the central connection portion disposed on the pier (2).

Referring to FIGS. 6 and 7, a secondary tendon 60 is inserted through the side span girders 10 and the center span girders 20 continuously installed in the longitudinal direction, and the side spans are disposed on the shift 1. A protrusion 50 formed at one end of the center span girder 20 continuously penetrating the inside of the side span girder 10 from the protrusion 50 formed at one end of the girder 10 and disposed on the piers 2. Settle to the anchorage 30 in the.

And, in the case of three spans, as shown in the figure, from the protrusion 50 formed at one end of the side span girder 10 on which one end is disposed on the pier 2, the center span girder 20 continuously disposed thereon. It penetrates inside and is fixed to the fixing unit 30 in the protrusion part 30 formed in one end part of the side span girder 10 in which one end part is arrange | positioned on the other piers 2.
In addition, from the protrusion 30 formed at the other end of the center span girder 20, the second tendon 20 is alternately formed of the side span girder 10 formed at the other end with respect to the center span girder 20. It is fixed to the protrusion part 50 formed in the other end part arrange | positioned above. At this time, in the case of more than four spans, the center span girders 20 are also bonded as described above.

By performing the above process for the entire girder (10, 20), the side span and the center span girders (10, 20) are structurally bound by the secondary tendon (60).

In addition, as can be seen in the figure, the secondary tendons 20 inserted continuously are arranged to penetrate left and right and up and down between the center and the ends of the girders 10 and 20 and cross each other at the intermediate connection part. As a result, it is possible to transmit structurally good compressive force to the bridge, thereby eliminating the problem of cracking in the upper slab near the intermediate joint, which is often found in continuous composite bridges, thereby significantly increasing the durability of the bridge.

Figure 5d shows a fourth step of installing the intermediate connection and cross beams and placing the concrete of the upper slab. That is, the fourth step (S4) is a step of forming a composite bridge by installing a variety of members and placing concrete, after installing the intermediate connecting portion, cross beam, sofit plate, etc., to form the upper slab 80 Heal by pouring.

That is, when the girder is mounted in two or more in the transverse direction to secure the width of the bridge in a simple bridge state in which the CS-type I girder (10,20) is mounted between the shift (1) and the bridge (2) A horizontal beam is installed to connect each girder 10 and 20 in the lateral direction, and an intermediate connection part is installed to connect the girders 10 and 20 mounted on the pier 2 in the longitudinal direction. Connect 70. Then, in order to form the upper slab 80 constituting the bottom plate of the bridge, the concrete is poured and cured to form a bridge of a continuous composite structure based on the girder 10, 20, and then remove the backrest and permanent support Install it.

5E illustrates a fifth step of tensioning the secondary tendon 60 by span length.

As shown in FIG. 5E, the fifth step S5 is a step of tensioning the secondary tendons 60, through which the secondary tendons 60 penetrating while continuously binding the girders 10 and 20. Prestressing for each span (Prestressing) is fixed to each anchorage 30 to give a tension force to offset the dead and live loads applied to the bridge.

Through such a step, the PS-type I girder composite bridge having a composite section and structurally bound by the multi-span continuous method of the present invention is completed.

1 is a perspective view of a side span girder according to an embodiment of the present invention.

2 is a perspective view of a center span girder according to an embodiment of the present invention.

3 is a front side and a planar side projection view of the side span girders according to an embodiment of the present invention.

4 is a front side and a planar side projection view of a center span girder according to an embodiment of the present invention.

FIG. 5 is a front side projection view illustrating each step of the multi-span sequencing method of a composite bridge using PS I-girder according to an embodiment of the present invention, and FIG. 5A illustrates a first process of manufacturing a PS I-girder. FIG. 5B shows a second step of mounting the PS-I girder to the alternating and piers, and FIG. 5C shows a second step of longitudinally inserting the secondary tendon into the mounted CS-I girder. FIG. 5D shows the fourth step of installing the intermediate connection and the cross beam and placing the concrete of the upper slab, and FIG. 5E shows the fifth step of tensioning the secondary tendon by span length. .

6 is a projection view showing a state in which the primary and secondary tendon is inserted into the end portion of the side span portion provided on the shift by an embodiment of the present invention.

7 is a projection view showing a state in which the primary and secondary tendon is inserted into the connection point portion installed on the piers according to an embodiment of the present invention.

8 is a flowchart of a multi-span sequencing method of a composite bridge using PS I-girder according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

1: Shift 2: Pier

10: side span girder 20: middle span girder

30: anchorage 40: 1 primary tendon

50: protrusion 60: the second tendon

70: Sofitt plate 80: Upper slab

Claims (2)

A plurality of anchorages 30 are installed at both ends so that the primary tendons 40 penetrate the center, and an installation space of the secondary tendons 60 is secured by using a portion having an enlarged cross section, and the primary tendons ( In order to fix the knitting side to the left and right sides of the 40), both sides adjacent to both ends are formed with protrusions 50 on which the secondary tendons 60 are fixed, respectively, according to the forming direction of the protrusions 50. Produced by dividing the side span girder 10 is formed so that the protrusion 50 is directed only to one end side and the center span girder 20 is formed so that both ends side the protrusion 50 is directed only to the end side adjacent to each end Then, the first step (S1) of post-tensioning the primary tendon (40) of each girder (10, 20) by the fixing unit 30 at both ends; After carrying the PS I type girders 10 and 20 to the site, between the shift 1 and the pier 2 using a crane so that the protrusions 50 at both ends face the pier 2. A second step (S2) of mounting side span girders (10) and a center span girder (20) between the piers (2); From the projection 50 formed at the end of the alternating side 1 of the side girder 10 arranged between the alternating member 1 and the pier 2, on the inside of the side girder 10 and on the pier 2. Adjacent to the pier 2 through the pier (2) side end of the center span girder 20, which is disposed at the same time in the pier 2 through the pier (2) side end of the side span girder 10 is disposed The secondary tendon 60 is fixed between the protrusions 50 formed at one end of the side, and from the protrusion 50 formed at the end of the pier 2 side of the side span girder 10, the pier 2 side. The center span of another center span girder 2 or another side span girder 10 adjacent to the center span girder 20 through both ends of the center span girder 20 disposed in the pier 2 such as an end. The other secondary tendon 60 is fixed to the end side protrusion 50 disposed in the same pier 2 as the girder 20. The end side protrusion 50 disposed in the same pier 2 as another center span girder 20 or another side span girder 10 of the center span girder 20 has an adjacent end and the same pier 2. Repeat the process of fixing another secondary tendon 60 to the protrusion 50 formed at the other end through the other end of the other center span girder 20 or the other side span girder 10 is arranged, the side span and A third step S3 of structurally binding the center span girders 10 and 20; In the simple bridge state, install the intermediate connecting portion connecting the horizontal beam and the longitudinal direction connecting the PSC I type girders in the transverse direction, connect the Sofit plate 70 to the bottom, and the bottom plate slab concrete in the field to continually synthesize After forming the structure, the fourth step (S4) of removing the temporary support and installing a permanent support; And A fifth step (S5) of prestressing and fixing the secondary tendon (50) for each span; Multi-span sequencing method of the composite bridge using PS C-type girder comprising a. delete

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