KR101050145B1 - Construction method of continuous bridge applying pre-stress - Google Patents

Abstract

The present invention relates to a method for constructing a continuous bridge in which pre-stress is applied to a branch block disposed on a bridge.

Method for constructing a continuous bridge applying the pre-stress according to an embodiment of the present invention comprises the steps of arranging the piers at regular intervals; Arranging a point block to which a compressive stress is applied by placing a point girder on an upper part of the pier and placing concrete provided with a tension providing part on an upper part of the point girder; The flange of the box girders, the upper flange of which has an open or partially closed cross-sectional structure, is provided with a coupling hole formed in the box girders to expose the housing girder consisting of the box girders and the branch block or the box girders. Installing a preliminary bottom plate which is formed to be installable; Coupling the housing further provided with the preliminary bottom plate in the longitudinal direction to the branch block to be extended by the connection unit; And placing a complete bottom plate to form a bottom surface on top of the preliminary bottom plate.

By the above configuration, the present invention can improve the robustness of the continuous part by applying pre-stress to the branch block constituting the continuous bridge, and the bottom plate on the girder through the configuration of applying the pre-stress to the branch block. The air can be shortened by constructing part of the bridge, and the continuous bridge can be constructed with efficient cross section.

Pre-stressed, continuous bridge, box girder, spare bottom plate, PC strand

Description

Construction method of continuous bridge applying pre-stress {METHOD FOR CONSTRUCTING CONTINUOUS BRIDGE APPLYING PRE-STRESS}

The present invention relates to a method for constructing a continuous bridge in which pre-stress is applied to a branch block disposed on a bridge piers.

In general, the continuous bridge is provided so that the branch block is provided on the top of the bridge, the housing constituting the bridge at both ends of the branch block is arranged in a state extending in the longitudinal direction. In order to construct such a continuous bridge, a bridge is constructed to efficiently form short sides by synthesizing concrete on the girder using a box-type girder.

In general, steel box girders have a large torsional rigidity in the form of closed sections, but after concrete is synthesized, the upper flange is almost at the position of the neutral shaft, and the contribution to the working load is minimal. Therefore, recently, a steel box girder of a type in which a steel horizontal brace for securing safety during construction is applied to a box girder of an open section to which an upper flange is not connected.

However, the open-sided box-type girders are also a factor in increasing the member weight since the function of horizontal bracing is lost after concrete is synthesized. Accordingly, there is a need to develop a box-type girder having an early composite base plate that not only effectively reduces the amount of use of members such as horizontal bracing, but also requires no additional temporary formwork and supporting construction when concrete is poured.

In this way, a part of the concrete in the open section box girders in advance to replace the horizontal bracing function required during the construction, as well as to reduce the cross-sectional stiffness required for the steel box girders through the functional complement.

However, when constructing a residential girder provided with a preliminarily synthesized preparatory bottom plate, the branch block may be excessively bent due to the load of the girder itself and the fixed load and the use load generated during construction. On the other hand, in the state in which the housing is connected, the compressive stress due to the fixed load and the working load generated during self-installation or temporary construction may be excessively acting on the preliminarily synthesized preliminary deck between the two branch blocks.

In this case, the specification of the branch block is inevitably increased to sufficiently endure the increased load of the housing and the like, and it may be difficult to provide sufficient stress strength even if the specification is increased. As such, even if the specification of the branch block is increased, construction air may be delayed because construction must be performed in consideration of the stress intensity of the housing. In addition, economic disadvantages may occur due to an increase in subsidiary materials, and the like, and design of bridges may be disadvantageous because various variables must be further considered.

The present invention is made by recognizing at least one of the needs or problems occurring in the construction of the conventional continuous bridge as described above.

An object of the present invention is to improve the robustness of the continuous part by applying pre-stress to the branch block constituting the continuous bridge.

Another object of the present invention is to shorten the air by forming a part of the bottom plate at the same time to improve the continuous part robustness through the configuration of applying the pre-stress to the branch block.

Another object of the present invention is to facilitate the application of the housing having a preliminary bottom plate.

Another object of the present invention is to reduce the amount of steel and to be used as a formwork when placing the bottom plate during the second fixed loading by providing the required stiffness by the shortening of the air and the synthetic base plate.

Yet another object of the present invention is to allow a continuous bridge bridge to be constructed in an efficient cross section.

The method of constructing a continuous bridge applying pre-stress related to an embodiment for realizing at least one of the above problems may include the following features.

The present invention is basically based on the configuration that the robustness of the continuous part is improved by applying pre-stress to the branch block forming the continuous bridge.

According to one or more embodiments, a method of constructing a continuous bridge using pre-stress includes arranging piers at regular intervals; Arranging a point block to which a compressive stress is applied by placing a point girder on an upper part of the pier and placing concrete provided with a tension providing part on an upper part of the point girder; The flange of the box girders, the upper flange of which has an open or partially closed cross-sectional structure, is provided with a coupling hole formed in the box girders to expose the housing girder consisting of the box girders and the branch block or the box girders. Installing a preliminary bottom plate which is formed to be installable; Coupling the housing further provided with the preliminary bottom plate in the longitudinal direction to the branch block to be extended by the connection unit; And placing a complete bottom plate to form a bottom surface on top of the preliminary bottom plate.

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In this case, the branch block has a PC strand is disposed inside the concrete, the tension control portion is provided at the end of the PC strand is provided in accordance with the weight of the housing block connected to both ends of the branch block and the self-weight of the branch block Compression stress can also be adjusted.

And, the complete bottom plate may be made to be coplanar with the concrete of the point girders to be poured to form the floor of the bridge. Alternatively, the complete deck may be cast to be placed in the concrete of the upper and point girders of the residential girder to constitute the floor of the bridge.

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As described above, according to the present invention, it is possible to improve the robustness of the continuous part by applying pre-stress to the branch block forming the continuous bridge.

In addition, according to the present invention, through the configuration of applying the pre-stress to the branch block, it is possible to shorten the air by configuring a portion of the bottom plate at the same time to improve the continuous part robustness.

In addition, according to the present invention, the application of the housing having a preliminary bottom plate can be made easily.

In addition, according to the present invention, the required stiffness is given by the shortening of the air and the synthesized preliminary bottom plate, thereby reducing the amount of steel of the girder and making it possible to use it as a formwork when placing the bottom plate during the second fixed loading.

And also, according to the present invention, a continuous bridge can be constructed with an efficient cross section.

In addition, according to the present invention, the economic power can be increased through the shortening of air for constructing the continuous bridge and the reduction of the members constituting the bridge.

In order to help the understanding of the features of the present invention as described above, it will be described in detail with respect to the continuous bridge and the construction method applying the pre-stress associated with the embodiment of the present invention.

Hereinafter, exemplary embodiments will be described based on embodiments best suited for understanding the technical characteristics of the present invention, and the technical features of the present invention are not limited by the illustrated embodiments, It is to be understood that the present invention may be implemented as illustrated embodiments. Accordingly, the present invention may be modified in various ways within the technical scope of the present invention through the embodiments described below, and such modified embodiments fall within the technical scope of the present invention. And, hereinafter, in the symbols described in the accompanying drawings to help the understanding of the embodiments described, related components among the components that will have the same function in each embodiment are denoted by the same or extension number.

Embodiments related to the present invention are basically based on the configuration that the robustness of the continuous part is improved by applying pre-stress to the branch block constituting the continuous bridge.

1 illustrates an example of a configuration of a continuous bridge 100 to which pre-stress is applied according to an embodiment of the present invention.

The continuous bridge 100 has a bridge 110 forming a lower structure as a structure of a general continuous bridge at regular intervals, the branch block 120 is disposed on the bridge 110, the branch block ( The housingder 140 may be arranged at both ends of the 120 to be arranged in succession.

In this case, the branch block 120 may be provided with a concrete portion 122 provided with a tension providing portion 123 on top of the branch girders 121 made of a box shape. In this case, when the concrete portion 122 is a cross-section according to the cross-sectional structure of the point girders 121 is formed as a box-shaped girder, formwork may be installed by pouring. In contrast, the concrete portion 122 may be installed by placing a permanent formwork.

On the other hand, the concrete portion 122 may be formed an area for mounting the tension providing portion 123 when pouring. In this case, when the tension providing unit 123 is composed of the PC strand (123a), the concrete portion 122 may be formed with a hole (not shown) is inserted into the PC strand (123a). On the other hand, at least one end of the PC strand (123a) is provided with a tension adjusting portion (123b) may be configured to adjust the compressive stress in the longitudinal direction of the concrete portion 122.

As described above, due to the configuration of the tension providing unit 123 for applying the pre-stress (Pre-Stress), the branch block 120 is based on the center portion in a state disposed on the top of the piers 110 Stress intensities for bending moments caused by sagging downwards at both ends can be reinforced. In this case, the degree (strength) of the reinforced stress strength may be adjusted in consideration of the load of the housing head 140 and the subsidiary materials connected to the branch block 120 together with the load of the branch block 120.

On the other hand, the concrete portion 122 disposed on the upper portion of the point girders 121 may be configured to form a bottom plate of the bridge. In this case, the concrete itself may be configured to form a bottom plate, and as described below, the complete bottom plate 160 may be further poured on top of the concrete portion 122 to form a bottom plate of a bridge. .

On the other hand, the branch block 120 may be configured to be disposed on the pier 110 by using the bridge device 130. In this case, the teaching device 130 may be configured using the teaching device 130 generally known. Therefore, detailed description thereof will be omitted.

Both ends of the branch block 120 may be coupled to the housing 140 in a state extending in the longitudinal direction of the branch block 120. In this case, the housing girder 140 may be made of a general box girder. Alternatively, it may be made of a box-shaped girder 141 is provided with a preliminary bottom plate 142 as shown.

In addition, the box-type girder 141 may be configured by using an girder having an open flange structure, or may be configured by using a girder having a closed cross-sectional structure, or using a girder having a partial region having a closed cross-sectional structure. It can also be configured.

The housing 140 may be coupled to the end of the branch block 120 by the connecting portion 150 in the longitudinal direction.

In the upper part of the housing 140, the complete bottom plate 160 may be poured to form the same plane as the upper surface of the concrete part 122 constituting the branch block 120 to form a bottom plate of the bridge. . On the other hand, as mentioned above, the complete bottom plate 160 is cast on the top surface of the concrete portion 122 constituting the upper part of the housing tier 140 and the branch block 120 to form the bottom plate of the bridge. It can also be configured.

On the other hand, as will be described below, the preliminary bottom plate 142 that may be provided in the housing 140 may be configured by a precast method. Alternatively, the formwork 141e may be installed in the box girder 141 to form a preliminary bottom plate 142. In this case, the formwork 141e may be configured to be permanently mounted to the box-type girder 141 or to be removed after curing of the preliminary bottom plate 142.

In this case, when the housing bottom 140 is provided with a preliminary bottom plate 142, the complete bottom plate 160 is installed as a preliminary bottom plate 142 acts as a formwork when pouring, do not install a separate formwork. You don't have to. In addition, the complete bottom plate 160 may be synthesized on the upper part of the preliminary bottom plate 142 to have a stress intensity required for the bottom plate of the bridge.

The housing girder 140, in which the preliminary bottom plate 142 is synthesized, may be configured using a box-type girder 141 as shown in FIGS. 2A and 2B.

As shown in FIG. 2A, the box-type girder 141 may be formed of a steel girder having an open cross-sectional structure in which a portion of the main body 141a is opened (in the illustrated example, an upper flange region is opened). .

In addition, a plurality of connecting members 141c for synthesizing the preliminary bottom plate 142 may be provided in the upper flange region of the opened body 141a. In this case, the connecting member 141c may be configured in the form of a stud. When the preliminary bottom plate 142 is poured by the above structure, the connecting member 141c has a structure in which a part of the preliminary bottom plate 142 is embedded in the preliminary bottom plate 142. Cross sections of the structure can be formed.

On the other hand, a plurality of coupling holes 141b for coupling the connection part 150 may be formed in the end region of the girder body 141a.

On the other hand, both ends of the girder body (141a) may be further provided with a horizontal bracing (lateral bracing) as necessary to ensure safety during construction.

As shown in FIG. 2B, as an example of another configuration of the box-type girder 141, the box-type girder 141 may further include a closed cross-sectional area 141d in which an upper flange to be opened is connected with a constant width. have. In this case, the closed end region 141d may be formed at both end regions of the upper flange to be opened.

The configuration of the closed cross-sectional area 141d may provide reinforcement to prevent warping torsion or general twisting of the box-shaped girders 141 from occurring. In addition, the coupling force may be reinforced when the box-type girder 141 is connected.

On the other hand, the box-shaped girder 141 is provided with a closed cross-sectional area (141d) in the partial region may be further formed with a coupling hole (141b), the connection member 141c may be further provided. Since the description thereof is the same as that of FIG. 2A, a detailed description thereof will be omitted.

In addition to this configuration, the box-type girder 141 may be formed in a closed cross-sectional structure.

The preliminary bottom plate 142 may be formed in the upper flange area by using the box-type girder 141 of any one of the box-type girders 141, which may be configured as described above.

As an example of such a configuration, as illustrated in FIG. 3, the preliminary bottom plate 142 may be formed in a precast manner. In more detail, the preliminary bottom plate 142 configured in the precast manner so that the connection member 141c provided on the upper flange of the box-type girder 141 may be exposed to the outside and embedded in the completely bottom plate 160. ) May be formed with holes 142b. In this case, the hole 142b may be formed to a size that allows a portion of the complete bottom plate 160 to be poured to be filled to allow synthesis.

On the other hand, the upper surface of the preliminary bottom plate 142 may be further provided with a connecting member 142a so that the complete bottom plate 160 and the synthetic bottom and the synthetic force can be reinforced. In addition, the preliminary bottom plate 142 may be disposed to be coupled to the connection part 150 by exposing the coupling hole 141b formed in the box-shaped girder body 141a.

On the other hand, the precast preliminary bottom plate 142 may be made of a single structure, or may be configured to be connected to be arranged in a plurality of segmented structure. In this case, the preliminary bottom plate 142 may be further provided with a reinforcing member. For example, the reinforcing member may be made of a member such as a truss member or a lattice girder disposed in the axial direction of the preliminary bottom plate 142. On the other hand, the reinforcing member may be made of rebar. In this case, the preliminary bottom plate 142 may be formed of a reinforced concrete (RC) structure.

The preliminary bottom plate 142 may be formed in a different thickness according to the size and shape of the box-shaped girder 141.

Unlike the above, the preliminary bottom plate 142 may be formed in a manner that is directly poured on the upper flange of the box-shaped girder body (141a) using the formwork (141e).

In this case, as shown in Figure 4a, at least two or more box-shaped girders 141 constituting the housing girder 140 is coupled through the connection portion 150 along the longitudinal direction. The formwork 141e for forming the preliminary bottom plate 142 is installed in the upper flange region of each box-shaped girder 141 coupled as described above. The formwork 141e may be made of reinforcement for reinforcing bars for general concrete pouring.

As shown in FIG. 4B, concrete is poured into the formwork 141e installed in the upper flange region of the box-type girder 141 to form a preliminary bottom plate 142.

On the other hand, the formwork (141e) is installed in the upper flange area of the box-shaped girder body (141a) to form a preliminary bottom plate 142 stress due to the weight of the concrete acts only on the upper flange area of the box-shaped girder body (141a) Excessive compressive stress of the preliminary bottom plate 142 may be reduced.

In this case, some of the cast iron reinforced to form the preliminary bottom plate 142 may be exposed to the outside of the concrete to be cast so that it can be formed as a connecting member (142a). On the other hand, the coupling member 142a may be formed by coupling an additional member to the reinforcement cast iron for forming the preliminary bottom plate 142.

In this case, as shown in FIG. 4C, when each box-shaped girder body 141a is separated from the area A to which each box-shaped girder body 141a shown in FIG. 4B is connected, The gap member 142b may be further provided in an area where the two box-shaped girder bodies 141a are connected to facilitate separation. In this case, the gap material 142b may be configured such that the preliminary bottom plate 142 may be separated using an epoxy resin, mortar, or rubber packing material.

In addition, in the region where the coupling hole 141b to which the connection part 150 is coupled is formed, a formwork 141e is installed so that casting of concrete for forming the preliminary bottom plate 142 may be excluded. This may not be formed. That is, the preliminary bottom plate 142 may be formed in a state in which the segmented girders 141 may be segmented so that the box girders 141 provided with the preliminary bottom plate 142 may be easily carried. Also in this case, in order to exclude the casting of concrete, you may comprise using epoxy, a mortar, or a rubber packing material.

After the concrete is poured and cured to form the bottom plate 142 as described above, as shown in FIG. 4D, each box-shaped girder 141 on which the preliminary bottom plate 142 is formed is separated for easy transportation.

Unlike the above example, each box-shaped girder 141 may be formed in the bottom plate 142 as described above in the separated state.

The continuous bridge 100 may be constructed using the branch block 120 and the housing 140 having the above configuration.

More specifically, as illustrated in FIG. 5A, the piers 110 are disposed at regular intervals. The branch block 120 is formed on the upper portion of each of the pier 110 is arranged in this case, in this case, the branch girder 121 that constitutes the branch block 120 is disposed on the pier 110 The concrete part 122 is disposed on the upper flange of the branch girder 121.

And, as shown in Figure 5b, the concrete portion 122 is provided with a tension providing portion 123. In this case, the tension providing unit 123, as described above, the PC strand (123a) by the tension control unit 123b to adjust the compressive stress for the concrete portion 122 by the branch block 120 Can be configured. As such, when the branch block 120 is disposed above the pier 110, the branch block 120 may be disposed above the pier 110 by the bridge device 130.

After the branch block 120 is disposed in this manner, as shown in FIG. 5C, the housing 140 may be coupled to both ends of the branch block 120 such that the housing block 140 extends in the longitudinal direction by the connection part 150. Can be.

In this state, as shown in FIG. 1, the entire bottom plate 160 may be formed on the upper portion of the housing 140. In this case, the complete bottom plate 160 may be poured in the same plane as the concrete portion 122 of the point girders 141 to form the bottom of the bridge. Alternatively, the complete bottom plate 160 may be poured to form the bottom of the bridge on the preliminary bottom plate 142 and the concrete portion 122 of the branch girders 141 provided in the housing girder 140. .

The continuous bridge applying the pre-stress and the construction method thereof according to the present invention are not limited to the embodiments of the continuous bridge applying the pre-stress described above and the construction method thereof. All or some of the embodiments may be selectively combined to enable modifications.

1 is a cross-sectional view schematically showing an example of the structure of a continuous bridge to which pre-stress is applied according to an embodiment of the present invention.

2A and 2B are perspective views schematically illustrating examples of a box girder constituting a housing girder of a continuous bridge to which pre-stress is applied according to an embodiment of the present invention.

3 is a perspective view schematically showing an example of one configuration of a housing girder constituting the continuous bridge shown in FIG. 1 using the box-type girders shown in FIGS. 2A and 2B.

4A to 4D are perspective views schematically showing the structure of the housing girders constituting the continuous bridge shown in FIG. 1 using the box-type girders shown in FIGS. 2A and 2B and a procedure for manufacturing the same.

5A to 5C are schematic views illustrating a construction order of a continuous bridge to which pre-stress is applied according to an embodiment of the present invention.

* Description of the main parts of the drawings *

100 ... continuous bridge 110 ... pier

120 ... branch block 121 ... branch girder

122 ... concrete section 123 ... tension provision section

130 ... chairs 140 ... dwellingsMore

141 ... box girder 142 ... spare base plate

160 ... complete bottom plate

Claims (10)

delete delete delete delete delete delete Arranging the piers at regular intervals; Arranging a point block to which a compressive stress is applied by placing a point girder on an upper part of the pier and placing concrete provided with a tension providing part on an upper part of the point girder; The flange of the box girders, the upper flange of which has an open or partially closed cross-sectional structure, is provided with a coupling hole formed in the box girders to expose the housing girder consisting of the box girders and the branch block or the box girders. Installing a preliminary bottom plate which is formed to be installable; Coupling the housing further provided with the preliminary bottom plate in the longitudinal direction to the branch block to be extended by the connection unit; And placing a complete bottom plate to form a bottom surface on top of the preliminary bottom plate. According to claim 7, wherein the branch block is a PC strand is disposed inside the concrete portion, the tension control portion is provided at the end of the PC strand is provided to the load of the housing girder connected to both ends of the branch block and the self-weight of the branch block A method of constructing a continuous bridge using pre-stress, characterized in that the compressive stress of the branch block is adjusted accordingly. 8. The method according to claim 7, wherein the complete bottom plate is constructed to be coplanar with the concrete part of the point girders to form the floor of the bridge, or the complete bottom plate is arranged to be disposed on the upper part of the residential girder and the concrete part of the point girders. The construction method of the continuous bridge to which the pre-stress is applied, characterized in that it is poured to form the floor of the bridge. delete

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