KR101896450B1 - Structure of semi arch bridge and construction method thereof - Google Patents

Abstract

The present invention provides a semi-arch bridge structure which can be applied to a bridge of a medium or small cultivation as a steel material usage amount is reduced and economical, esthetic, and easy construction can be performed by subsidiarily applying an arch structure while using a conventional bridge girder. The semi-arch bridge structure comprises: a girder which is installed between an abutment and another abutment, an abutment and a pier, or a pier and another pier; an arch rib of an arch shape which is installed on the upper side of the girder and has a height gradually increasing toward the center; a bridge surface bonding block which is installed on the end of the girder and is combined with the end of the arch rib; a hanger which vertically connects the girder and the arch rib; and an arch spring guide which is provided on the bridge surface bonding block and is combined with the end of the arch rib. The arch spring guide may have a concave groove portion in which an end portion of the arch rib contacts and is coupled.

Description

Technical Field [0001] The present invention relates to a semi-arch bridge structure,

The present invention relates to a semi-arch bridge structure which can be economically designed by applying an arch structure to an arch structure while using a conventional bridge girder, thereby allowing the girder to bear the dead load including the weight of the girder, and the live load to be burdened by the arch rib.

Conventional arch bridges have been used mainly for bridges and marine bridges where aesthetics in urban areas are required because they can be constructed with excellent aesthetic appearance and long span, while the economical efficiency is poor due to a large amount of steel material used.

The construction of the existing arch bridge first installs a plurality of temporary venting in the center of the span, assembles a bridge structure such as a girder, assembles an arch rib and a hanger, and assembles an arch structure. In this case, since the concentrated load, which is the reaction force of the temporary vent, is reversely loaded, an uneven load is loaded on the hanger, and unnecessary force moment is generated in the arch rib, which is a main cause of increasing the amount of steel .

Therefore, although the existing arch bridge has excellent aesthetic appearance and long span, economical efficiency is disadvantageous and it is recognized that it is very expensive in small and medium span bridges and its usability is limited.

 Accordingly, development of an arch bridge which can be applied to a bridge of small and medium span, is excellent in aesthetics, is economical, and is easy to construct is required.

Korean Registered Utility Model No. 20-0312173

The present invention is to provide a semi-arch bridge structure which can be applied to small and medium span bridges because it is economical, aesthetic and easy to construct because the amount of steel used is reduced by using an existing bridge girder while auxiliary arch structure is applied.

A semiautomatic structure according to an example of the present invention includes a girder installed between alternating and alternating, alternating and piercing, or between a pier and a pier; An arch-shaped arch rib provided on the upper side of the girder and having a height gradually increasing toward a central portion; A bridge joint block installed at an end of the girder and coupled to an end of the arch rib; A hanger for vertically connecting the girder and the arch rib; And an arch spring guide which is provided in the bridge face joint block and to which an end of the arch rib is engaged. The arch spring guide may be formed with a concave groove portion to which the end of the arch rib is abutted.

In addition, an inclined guide portion may be formed around the recessed portion of the arch spring guide.

In addition, the arch spring guide may further include an arch rib fixing anchor embedded in the bridge bridge junction block and coupled to the recess groove.

The arch spring guide may further include a fixing bolt coupled to the bridge block and coupled to the guide block.

The arch spring guide may further include a spring guide shear key embedded in the bridge face joint block and coupled to the center of the groove.

In addition, the girder is first installed to bear a dead load including its own weight, and after the installation of the girder, the arch rib and the hanger are installed, and the hanger is tensioned between the arch rib and the girder to connect the hanger to the arch rib and the girder So that the arch rib can bear a part of the live load.

The upper end of the arch rib is in contact with the recessed portion before tensioning between the arch rib and the girder. When the hanger is connected to the arch rib and the girder by tensioning the arch rib and the girder, The entire end of the rib can be brought into contact with the recessed portion.

In addition, an inclined guide portion is formed around the recessed portion of the arch spring guide, and the guide portion prevents the arch rib from being separated from the arch spring guide before tensioning between the arch rib and the girder, The end of the arch rib can be guided to be seated in the recessed groove.

In addition, the cross section of the arch spring guide and the arch rib may be circular or rectangular.

A method of semi-arch construction construction according to an example of the present invention includes the steps of installing a girder over alternating and alternating, alternating and piercing, or between piers and piers; An arch bridge is provided at both ends of the girder with an arch spring guide having concave recessed portions and inclined guide portions formed around the recessed portions. Arcuate arch ribs having a height gradually increasing toward the center are installed on the upper side of the girder Installing a hanger vertically connecting the arch rib and the girder; And connecting the hanger to the arch rib and the girder by coupling the arch rib and the girder to each other and coupling the end of the arch rib to the recess groove of the arch spring guide.

The arch spring guide may include an arch rib fixing anchor buried in the bridge bridge junction block and coupled to the recess groove, a fixing bolt coupled to the bridge bridge block and coupled to the guide bridge, And a spring guide shear key coupled to the center of the recess.

The semi-arch bridge structure of the present invention is economical for a bridge of medium and small span by making the girder bear a dead load including its own weight, and the arch rib is made to bear a live load, and can be convenient for construction.

1 is a view showing a semi-arch bridge structure of the present invention.
2 is a side view and a cross-sectional view of an arch spring guide of a semi-arch bridge structure of the present invention.
Figs. 3A-3D are views before and after the introduction of tensile force on the hanger in the semi-arch bridge structure of the present invention. Fig.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In the drawings, like reference numerals are used to refer to like elements throughout the drawings, even if they are shown in different drawings. In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the difference that the embodiments of the present invention are not conclusive.

In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, May be "connected "," coupled "or" connected ".

Hereinafter, a semi-arch bridge structure according to an example of the present invention will be described with reference to FIGS. 1 to 3. FIG.

A semi-arch bridge structure according to an example of the present invention includes a girder 20 installed between alternation 10 and alternation 10, alternation 10 and bridge 10, or between bridge 10 and bridge 10, ; An arcuate arch rib (30) provided on the upper side of the girder (20) and having a height gradually increasing toward a central portion; A bridge block 40 installed at an end of the girder 20 and coupled to an end of the arch rib 30; A hanger 50 for vertically connecting the girder 20 and the arch rib 30; And an arch spring guide 60 provided in the bridge bridge 40 and coupled to an end of the arch rib 30, the arch spring guide 60 having an end portion of the arch rib 30 Concave recessed grooves 62 that are tangent to each other can be formed.

The semi-arch bridge structure of the present embodiment is constructed between alternating (10) and alternating (10), alternating between (10) and bridge (10). Or between the bridge pier 10 and the bridge pier 10. Hereinafter, for the sake of convenience, description will be made on the assumption that it is provided between the bridge pier 10 and the bridge pier 10.

The girders 20 may be installed over a pair of bridge piers 10 spaced apart at regular intervals. The girder 20 of the present embodiment is similar to a conventional bridge girder 20 other than an arch bridge. In other words, the girder 20 of the present embodiment can be designed to bear most of the loads, such as the weight of the girder 20 and the dead load of the bridge structure unlike the normal arch bridge. The girder 20 of the present embodiment may be a steel structure, a steel composite structure, a prestressed concrete structure, a square pipe, an I beam, a round steel pipe, or the like.

The arch ribs 30 are provided on the upper side of the girder 20 and may be arcuate shapes having a height gradually increasing from both ends to the center. The arch ribs 30 of this embodiment can be designed to bear only a partial load such as a live load by being installed after the completion of the installation of the bridge structure such as the girder 20 or the like and being installed between the girder 20 and the girder 20. Therefore, its role can be somewhat different from the existing arch bridge.

The semi-arched bridge structure of the present embodiment is characterized in that after the assembly of the girder 20, after the composite of the girder 20 and the deck, or after the construction of the barrier wall, The arch ribs 30 are stretched to join the hanger 50, so that the arch ribs 30 bear the load. Therefore, the load bearing ratio of the girder 20 and the arch rib 30 can be adjusted depending on the size of the tension. Therefore, the present embodiment can facilitate the installation work of the arch rib 30 and the hangers 50 and the like.

At both ends of the girder 20, a bridge bridge 40 may be installed. That is, the bridge block 40 may be provided on both ends of the girder 20, or on both sides of the girder 20. The bridge block 40 may be installed before the girder 20 when the bridge block 40 is installed on both sides of the girder 20. The bridge block 40 may be formed of a reinforced concrete structure or the like.

The hanger 50 can vertically connect and connect between the arch rib 30 and the girder 20. [ That is, the arch ribs 30 and the girders 20 may be vertically connected to each other or may be inclined at a predetermined angle so that the two members are connected to each other. The hanger 50 can be engaged after tensioning between the arch ribs 30 and the girders 20. [ The hanger 50 may first be coupled to the lower side of the arch rib 30 and the arch rib 30 and the girder 20 may be pulled together and then joined to the girder 20. [ In other words, the arch ribs 30 can bear the load by connecting the hanger 50 after tensioning the arch ribs 30 and the girders 20.

)가 발생할 수 있다. 아치리브(30)와 거더(20)를 상호 인장하기 전에는 아치리브(30)의 단부의 상측이 교면접합블럭(40)에 접하고, 아치리브(30)와 거더(20)를 상호 인장한 후 아치리브(30)의 단부 전체가 교면접합블럭(40)에 접하게 된다. 따라서 아치리브(30)의 제작 시 단부의 회전변위를 산정하여 제작하게 되는데, 이 회전변위를 얼마로 하느냐에 따라 하중 부담 비율도 달라질 수 있다.The arch rib 30 and the girder 20 are mutually stretched to join the hanger 50 to the rotary rib 30,

) May occur. Before the arch rib 30 and the girder 20 are stretched together, the upper side of the end portion of the arch rib 30 is in contact with the bridge block 40. The arch rib 30 and the girder 20 are stretched together, The entire end of the rib 30 is brought into contact with the bridge block 40. Therefore, when the arch rib 30 is manufactured, the rotational displacement of the end portion is produced. However, the load burden ratio may vary depending on the rotational displacement.

The arch spring guide 60 may be provided on the face-to-face bonding block 40 to which the end of the arch rib 30 is coupled. The arch spring guide 60 may be formed with a recessed groove 62 to which the end of the arch rib 30 is brought into contact. The recessed groove portion 62 is formed as a plane portion as a portion to which the end portion of the arch rib 30 is inserted and joined and the inclined guide portion 64 can be formed around the recessed portion 62.

The ends of the arch ribs 30 may come into contact with the upper ends of the arch ribs 30 immediately after being inserted into the recessed grooves 62 and may be entirely brought into contact with the recessed grooves 62 after the girders 20 and the arch ribs 30 are stretched.

The guide portion 64 of the arch spring guide 60 prevents separation of the end portion of the arch rib 30 before the end portion of the arch rib 30 is inserted into the recessed portion 62 and is completely engaged, The end portion of the arch rib 30 can be guided to be seated in the recessed portion 62.

The arch spring guide 60 may further include an arch rib fixing anchor 66 embedded in the bridge block 40 and coupled to the recessed portion 62 with a nut or the like. That is, the arch-rib fixing anchor 66 is installed in advance in the bridge block 40 and is inserted into the through hole formed in the recessed portion 62 and then protruded and then engaged by fastening the nut. After the arch ribs 30 are installed, the arch rib fixing anchors 66 are inserted into the through holes formed in the end portions of the arch ribs and then protruded. Then, the arch ribs 30 are fastened to the bridge block 40 Can be combined.

The arch spring guide 60 may further include a fixing bolt 68 coupled to the bridge block 40 and coupled to the guide portion 64. The fixing bolts 68 may be inserted in the guide block 64 and then embedded in the bridge block 40 or may be fastened after the nuts are first embedded in the bridge block 40.

The arch spring guide 60 may further include a spring guide shear key 69 embedded in the bridge joint block 40 and coupled to the center of the recess groove 62. The spring guide shear key 69 can stably fix the arch spring guide 60 to the bridge bridge 40 with respect to the compressive force and the shear force applied from the arch rib 30.

In the semi-arch bridge structure of this embodiment, the girder 20 is first installed and burdens a dead load including its own weight, and then the arch rib 30 and the hanger 50 are installed, and the gap between the arch rib 30 and the girder 20 And the hanger 50 is connected to the arch ribs 30 and the girders 20 by tension so that part of the live load can be made burdened by the arch ribs 30. [

The tension between the arch ribs 30 and the girders 20 may be a steel bar or a steel wire that directly connects the arch ribs 30 and the girders 20. [ The upper side of the hanger 50 may be first coupled to the arch rib 30 and then the lower side of the hanger 50 and the girders 20 may be pulled together.

The lower side of the hanger 50 is spaced apart from the girder 20 by a predetermined distance before the arch rib 30 and the girder 20 are stretched and the upper side of the arch rib 30 is located on the upper side of the recessed portion 62 . The lower side of the hanger 50 is brought into contact with the girder 20 when the arch rib 30 and the girder 20 are pulled together and the entire end of the arch rib 30 can contact the recessed portion 62. The arch rib 30 can be engaged by fastening the nut to the arch rib fixing anchor 66 protruding from the through hole of the recessed portion 62. [

The cross section of the arch spring guide 60 and the arch rib 30 may be circular or rectangular. That is, when the arch rib 30 is circular, the arch spring guide 60 is also preferably formed in a circular shape. In this case, the guide portion 64 may be formed in a conical shape. Further, when the arch ribs 30 are rectangular, the arch spring guide 60 is also preferably formed in a rectangular shape. In this case, the guide portion 64 may be formed in a square shape. The guide portion 64 may also be formed in an asymmetrical shape.

Hereinafter, a method of constructing a semi-arch bridge structure according to an example of the present invention will be described.

The semi-arch structure construction method according to an example of the present invention is characterized in that the girder 20 is disposed between the alternation 10 and the alternation 10, the alternation 10 and the bridge 10, or between the bridge 10 and the bridge 10, ; A bridge bridge 40 having a concave groove portion 62 and an arch spring guide 60 having an inclined guide portion 64 formed around the groove portion 62 is installed at both ends of the girder 20 And an arched rib 30 is provided on the upper side of the girder 20. The hanger 50 connects the arch rib 30 and the girder 20 vertically, ; The arch ribs 30 and the girders 20 are stretched to connect the hanger 50 to the arch ribs 30 and the girders 20 and the ends of the arch ribs 30 are connected to the arch springs 30, (62) of the guide (60).

A portion not described in this embodiment can be applied to the explanation in the semi-arch bridge structure described above.

In this embodiment, the bridge pier 10 and the like are installed first. Thereafter, girders 20 are provided on the upper side of these pier 10. The installation of the girder 20 may be the same as that of a normal bridge construction method. Further, after the girder 20 is installed, a deck, a barrier wall, a package, and the like can be installed or constructed.

After the girder 20 is installed, the bridge block 40 can be installed. The bridge joint block 40 may be installed with the girder 20 or may be installed before the girder 20 is installed depending on its position.

Thereafter, the arch rib 30 and the hanger 50 can be installed. In this case, the hanger 50 is spaced apart from the girder 20 by a predetermined distance, and the end of the lower rib is brought into contact with the upper side of the recessed portion 62 of the arch spring guide 60 only on the upper side.

The hanger 50 is coupled to the girder 20 and at the same time the end of the arch rib 30 is coupled to the arch spring guide 60. [

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. That is, within the scope of the present invention, all the constituent elements may be constituted or operated selectively in combination with one or more. Furthermore, the terms "comprises", "comprising", or "having" described above mean that a component can be implanted unless otherwise specifically stated, But should be construed as including other elements. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10: Pier (alternating)
20: Girder
30: arch rib
40: face joint block
50: Hanger
60: Arch Spring Guide
62:
64: guide portion
66: Arch rib fixed anchor
68: Fixing bolt
69: Spring guide shear key

Claims (11)

Alternations and alternations, alternations and piers, or girders installed between piers and piers;
An arch-shaped arch rib provided on the upper side of the girder and having a height gradually increasing toward a central portion;
A bridge joint block installed at an end of the girder and coupled to an end of the arch rib;
A hanger for vertically connecting the girder and the arch rib;
And an arch spring guide provided to the bridge joint block and coupled to an end of the arch rib,
The arch spring guide
A concave groove portion in which an end of the arch rib is engaged with the concave groove portion is formed,
Wherein the arch spring guide further comprises a spring guide shear key embedded in the bridge face joint block and coupled to a center portion of the recess.
The method according to claim 1,
Wherein an inclined guide portion is formed around the recessed portion of the arch spring guide.
The method of claim 2,
Wherein the arch spring guide further comprises an arch rib fixing anchor embedded in the bridge bridge junction block and coupled to the recess groove.
The method of claim 2,
Wherein the arch spring guide further comprises a fixing bolt coupled to the bridge bridge junction block and coupled to the guide section.
delete The method according to claim 1,
The girder is installed first to bear a dead load including its own weight, and after the installation of the girder, the arch rib and the hanger are installed, and the hanger is connected to the arch rib and the girder by tensioning the arch rib and the girder, The arch ribs being partly occupied by the arch ribs.
The method of claim 6,
Wherein an upper end of the arch rib abuts against the recessed portion before tensioning between the arch rib and the girder, and when the hanger is connected to the arch rib and the girder by tensioning the arch rib and the girder, And the entire end portion is in contact with the recessed portion.
The method of claim 6,
Wherein an inclined guide portion is formed around the recessed portion of the arch spring guide,
The guide portion
Wherein the arch rib is prevented from being separated from the arch spring guide before tensioning between the arch rib and the girder, and the end of the arch rib is seated in the recess groove during tensioning. .
The method of claim 6,
Wherein the arch spring guide and the arch rib are circular or square in cross section.
Alternating and alternating, alternating and piercing, or installing a girder between the piers and the piers;
An arch bridge is provided at both ends of the girder with an arch spring guide having concave recessed portions and inclined guide portions formed around the recessed portions. Arcuate arch ribs having a height gradually increasing toward the center are installed on the upper side of the girder Installing a hanger vertically connecting the arch rib and the girder;
And connecting the hanger to the arch rib and the girder and coupling the end of the arch rib to the recessed portion of the arch spring guide by tensioning the arch rib and the girder,
The arch spring guide includes an arch rib fixing anchor buried in the bridge bridge block and coupled to the groove groove, a fixing bolt coupled to the bridge bridge block and coupled to the guide portion, Further comprising a spring guide shear key coupled to a central portion of the portion. delete

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