KR102347089B1 - Steel-concrete composite rahmen structure and construction method thereof - Google Patents

Abstract

The present invention provides a steel-concrete composite Rahmen structure that adopts prestress by using a steel bar embedded in wall portions after installation of girders, thereby facilitating adoption of prestress and shortening of the construction period. The steel-concrete composite Rahmen structure of the present invention includes: a pair of wall portions (100); a columnar steel girder (300) installed to stand on upper parts of the wall portions (100); a steel girder (200) installed for an edge thereof to be placed on an upper part of the columnar steel girder (300); a pair of tension devices (400) coupled to the front and rear of the columnar steel girder (300), respectively, to apply preload to the steel girder (200); and a floor plate (500) formed by pouring concrete (C) so that the tension devices (400) are embedded. The tension device (400) includes a body member (410) coupled to one side and the other side of the columnar steel girder (300); and a tension member (420) coupled to a lower flange of the steel girder (200) with a lower end thereof coupled to an inner side of the body member (410) and an upper end protruding upward out of the body member (410), wherein the tension member (420) is coupled to the body member (420) in a structure capable of moving in a lateral directions.

Description

Steel composite ramen structure and its construction method

The present invention relates to the field of construction, and more particularly, to a steel composite ramen structure and a construction method thereof.

Ramen structure bridges are widely used for crossing rivers with small to medium spans. Since there is no expansion joint for the Ramen structure bridge, it has the advantage of convenient maintenance of the bridge structure.

Ramen-structured bridges have a slightly longer span, and to secure maximum space under the bridge, pre-stress or pre-flex load is used to secure span span and height.

However, in the case of a concrete girder with prestress (PSC) or a steel composite girder (PF) with pre-placement load, the self-weight of the girder is heavy, and large equipment must be brought into the site to construct it. In some cases, it is necessary to install a temporary road to bring in large equipment to the site, which increases the process and construction cost.

The present invention is devised to solve the above problems, and since the prestress is introduced using a steel rod embedded in the wall after the girder is installed, it is easy to introduce the prestress and has the advantage of shortening the construction time.

In order to solve the above problems, the rigid Ramen structure of the present invention includes a pair of wall parts 100; a columnar steel type 300 installed in a standing structure on the upper part of the wall part 100; a steel girder 200 installed so that an edge is raised on the upper part of the columnar steel type 300; In order to introduce a preceding load to the steel girder 200, a pair of tension devices 400 coupled to the front and rear of the column steel type 300, respectively; A bottom plate 500 formed by pouring concrete C so that the tension device 400 is embedded; but, the tension device 400 is a body coupled to one side and the other side of the rigid column type 300 . member 410; The lower end is coupled to the inner side of the body member 410, and the upper end protrudes to the upper portion of the body member 410, and the tension member 420 is coupled to the lower flange of the steel girder 200. In addition to including, The tension member 420 is coupled to the body member 410 in a structure capable of flowing along the lateral direction.

The body member 410 includes a side portion 411 forming a side surface; an upper surface portion 412 and a lower surface portion 413 installed to close the upper surface and the lower surface of the side surface portion 411; It is preferable to include; a fixing plate 414 installed in a section between the upper surface portion 412 and the lower surface portion 413 to fix the tension member 420 .

A long hole h is formed in the upper surface portion 412 and the fixing plate 414 in the lateral direction, and the tension member 420 is moved along the long hole h before being fixed, and the fixing plate 414 It is preferable that the lower side and the upper side of the lower flange of the steel girder 200 are fixed by a nut.

The side part 411 is a member installed along the lateral direction, and is installed as a pair spaced apart from the front and rear of the tension member 420, and one side and the other side of the body member 410 are open. It is preferable to be

It is preferable that a protrusion 310a having a round structure convex in the upward direction is formed on the upper surface of the steel column 300, and the protrusion 310a is a protrusion having a semicircular structure with respect to the lateral direction.

It is preferable that a groove portion 210 corresponding to the protrusion 310a is formed on the lower surface of the edge portion of the steel girder 200 .

A reinforcing member 220 is installed on one side and the other edge of the steel girder 200 in the vertical direction based on the groove 210 of the steel girder 200, and a central reinforcing member 230 in the central portion of the groove 210 along the vertical direction. ) is preferably further combined.

The protrusion 310a is formed by a protrusion plate 310 coupled to the upper surface of the columnar steel type 300 , and the protruding plate 310 is coupled to protrude from the upper surface of the columnar steel type 300 to one side and the other side. a plate 311 being; a protrusion member 312 coupled to form the protrusion 310a on the upper surface of the plate 311; Reinforcement plate 313 coupled along the downward direction from the lower surface of the plate 311; includes, and the tension member 420 is installed through the plate 311 and the steel girder 200 lower flange it is preferable

The reinforcing plate 313 is installed on one side, the other edge, and the center of the plate 311, and is preferably coupled in a plate structure along the front-rear direction.

A protruding girder 240 is coupled to the outside of one end of the steel girder 200, and an inclined tensile member 600 is coupled to the protruding girder 240, and the upper end of the inclined tensile member 600 is the protruding girder. It is preferable that the upper end is coupled to one edge of 240 , and the lower end of the inclined tension member 600 is fixed to the lower side of the columnar type 300 in a buried structure.

It is preferable that the inclined tension member 600 is installed to be inclined downwardly toward the other side, and the upper surface of one edge of the protruding girder 240 has an inclined portion 241 inclined downward toward one side.

The inclination of the inclined portion 241 is preferably formed to be perpendicular to the axial direction of the inclined tension member 600 .

A method for constructing a steel composite ramen structure according to an embodiment of the present invention includes: a wall part construction step of constructing a pair of the wall parts 100 so that the lower surface of the inclined tension member 600 is buried; a projecting wall portion construction step of pouring the projecting wall portion 110 so that the central portion of the inclined tension member 600 is buried; An installation step of the rigid pillar type and the tension device for installing the pillar type 300 and the tension device (400); A protrusion plate installation step of installing the protrusion plate 310 on the upper part of the columnar type 300; a steel girder mounting step of mounting the steel girder 200; a protruding girder coupling step of coupling the protruding girder 240 coupled to the inclined tension member 600 to the steel girder 200; a tension device coupling step of moving the tension member 420 coupled to the tension device 400 in the lateral direction to couple it to the steel girder 200; introducing a preceding load to the steel girder 200 by introducing a tensile force to the tensile member 420; and a concrete pouring step in which the concrete (C) is poured to form the floor plate (500), and the poured concrete (C) is filled in the tension device (400).

The steel composite ramen structure according to the present invention introduces a preceding load to the steel by tensioning the steel rod after the installation of the girder. have.

1 is an enlarged view of one side of a steel composite ramen structure according to an embodiment of the present invention;
Figure 2 is a perspective view of one side of the steel composite ramen structure according to an embodiment of the present invention.
3 is a perspective view of a tension device according to an embodiment of the present invention;
4 is a view showing that the tension device is fastened to the steel girder according to an embodiment of the present invention;
5 is a cross-sectional view showing that the tension device is fastened to the steel girder according to an embodiment of the present invention;
6 is a perspective view showing that the tension member is moved in the tension device according to an embodiment of the present invention;
7 is a view showing that the lower part of the columnar steel type according to an embodiment of the present invention is embedded in a wall part;
8 is a view showing that the bottom plate is formed by pouring concrete according to an embodiment of the present invention, and the inside of the tension device is filled
9 is a perspective view of a steel girder according to an embodiment of the present invention;
10 is a perspective view of a steel girder in which concrete is pre-synthesized according to an embodiment of the present invention;
11 is a perspective view of a body member according to an embodiment of the present invention;
12 is a perspective view illustrating that a tension member is coupled to a body member according to an embodiment of the present invention;
13 is a front view of a steel composite ramen structure according to an embodiment of the present invention;
14 is a view of a protrusion plate according to an embodiment of the present invention;
15 is a side view of a ramen structure in which a protruding girder and an inclined tension member are installed according to an embodiment of the present invention;
16 is a view showing that the inclined tension member is embedded in the protruding wall portion according to an embodiment of the present invention;
17 is a view showing that the protruding girder and the steel girder are combined after the inclined tension member is coupled to the protruding girder according to an embodiment of the present invention;
18 is a process diagram of a concrete pouring step according to an embodiment of the present invention;

An embodiment of the steel composite ramen structure and its construction method according to the present invention will be described in detail with reference to the accompanying drawings, and in the description with reference to the accompanying drawings, the same or corresponding components are given the same reference numbers A redundant description thereof will be omitted.

In addition, terms such as first, second, etc. used below are merely identification symbols for distinguishing the same or corresponding components, and the same or corresponding components are limited by terms such as first, second, etc. no.

In addition, the term "coupling" does not mean only when there is direct physical contact between each component in the contact relationship between each component, but another component is interposed between each component, so that the component is in the other component. It should be used as a concept that encompasses even the cases in which each is in contact.

Hereinafter, with reference to the accompanying drawings, it will be described in detail with respect to the steel composite ramen structure and its construction method.

The rigid composite Ramen structure of the present invention includes a pair of wall portions 100; a columnar steel type 300 installed in a standing structure on the upper part of the wall part 100; Steel girder 200 is installed so that the edge is raised on the upper part of the columnar type 300; In order to introduce a preceding load to the steel girder 200, a pair of tension devices 400 coupled to the front and rear of the columnar steel type 300, respectively; Including, the tension device 400 is a body member 410 coupled to one side and the other side of the columnar steel type 300; ); The lower end is coupled to the inner side of the body member 410, and the upper end protrudes to the upper portion of the body member 410, and the tensile member 420 is coupled to the lower flange of the steel girder 200. In addition to including, the tensile member ( 420 is coupled to the body member 410 in a structure capable of flowing along the lateral direction.

Since the Ramen structure bridge is a bridge structure without joints, it is widely applied to rivers with small to medium spans. To increase the span and secure the maximum space under the bridge, concrete girders with pre-stress (PSC) or steel composite girders (PF) with pre-place loads are sometimes used. requires large equipment.

To this end, there is a problem in that a temporary road needs to be additionally constructed at the site. In this case, there are problems in that the construction cost increases and the construction period increases.

Since the present invention can introduce a preceding load to the steel girder 200 by tensioning the tension member 420 coupled to the tension device 400 after mounting the steel girder 200, there is no need to carry large equipment into the field, The introduction of the preceding load can be carried out easily.

The tension member 420 is coupled to the tension device 400 and the upper end is fixed to the lower flange of the steel girder 200 . A through hole through which the tension member 420 passes is formed in the lower flange, and the through hole formed in the tension member 420 and the lower flange is misaligned due to manufacturing errors occurring during the manufacturing of steel girder and construction errors occurring during on-site installation. Often times.

However, in the present invention, since the tension member 420 is moved and coupled in the lateral direction, the tension member 420 can be installed even when construction errors and manufacturing errors occur.

When the tension member 420 is tilted due to construction errors and manufacturing errors, the preceding load to be introduced cannot be clearly introduced, and if the error is severe, the tension member 420 may be broken.

The body member 410 includes a side portion 411 forming a side surface; an upper surface portion 412 and a lower surface portion 413 installed to close the upper surface and the lower surface of the side portion 411; It is preferable to include; a fixing plate 414 installed in a section between the upper surface portion 412 and the lower surface portion 413 to fix the tension member 420 .

As shown in FIG. 3 , the side portions of the body member 410 are all open. This is induced to be filled up to the inside of the body member 410 when the concrete c is poured to form the bottom plate. Also, the lower end of the tension member 420 protrudes below the fixing plate 414 and is fastened by a nut.

A long hole (h) is formed in the upper surface portion 412 and the fixing plate 414 in the lateral direction, and the tension member 420 is moved before fixing along the long hole (h), and the fixing plate 414 lower side and the steel girder It is preferable to be fixed by a nut on the upper side of the lower flange of (200).

As shown in FIG. 6 , the tension member 420 is moved in the lateral direction by the long hole h formed in the upper surface portion 412 and the fixing plate 414 , and it is possible to overcome manufacturing errors and construction errors.

The side portion 411 is a member installed along the lateral direction, and is spaced apart from the front and rear of the tension member 420 to be installed as a pair, and one side and the other side of the body member 410 are preferably of an open structure. do.

In this case, as shown in Figs. 3 and 6, the side portions 411 are installed at a distance from each other along the front-rear direction.

A protrusion 310a having a convex round structure is formed on the upper surface of the steel column 300 in the upper direction, and the protrusion 310a is preferably a protrusion having a semicircular structure with respect to the lateral direction.

In addition, it is preferable that the groove portion 210 corresponding to the protrusion 310a is formed on the lower surface of the edge portion of the steel girder 200 .

In the region around the groove 210 of the steel girder 200, a plurality of reinforcing members are formed as shown in FIG. 4 to secure the rigidity of the steel girder.

More specifically, a reinforcing member 220 installed in a standing structure along the vertical direction is installed on one side and the other edge of the steel girder 200 based on the groove portion 210, and the central portion of the groove portion 210 has the vertical direction. Accordingly, it is preferable that the central reinforcing member 230 is further coupled.

The protrusion 310a may be formed by a protrusion plate 310 coupled to the upper surface of the columnar shape 300 , the protrusion plate 310 being a plate coupled to protrude from the upper surface of the columnar shape 300 to one side and the other side. (311); a protrusion member 312 coupled to form a protrusion 310a on the upper surface of the plate 311; Reinforcing plate 313 coupled along the downward direction from the lower surface of the plate 311; includes, and the tension member 420 is preferably installed through the plate 311 and the steel girder 200 lower flange.

The coupling plate 310 is installed in a structure in which the upper surface is in contact with the lower flange of the lower flange of the steel girder 200, and is formed in the same structure as in FIGS. 7 and 14 .

The reinforcing plate 313 is installed on one side, the other edge, and the center of the plate 311, and is preferably coupled in a plate structure along the front-rear direction.

A protruding girder 240 is coupled to the outside of one end of the steel girder 200, and an inclined tensile member 600 is coupled to the protruding girder 240, and the upper end of the inclined tensile member 600 is the protruding girder. It is preferable that the upper end is coupled to one edge of 240 , and the lower end of the inclined tension member 600 is fixed to the lower side of the columnar type 300 in a buried structure.

In this case, the protruding girder 240 is coupled to each other so as to protrude outward from the end of the steel girder 200 as shown in FIG. 17 . The protruding girder 240 is a structure installed to fix the upper end of the inclined tension member 600 installed in an inclined structure, and may be manufactured in the same cross section as the steel girder 200 .

It is preferable that the inclined tension member 600 is installed to be inclined downwardly toward the other side, and the upper surface of one edge of the protruding girder 240 has an inclined portion 241 inclined downward toward one side.

In this case, the inclination of the inclined portion 241 is preferably formed to be perpendicular to the axial direction of the inclined tension member 600 .

A method for constructing a steel composite ramen structure according to an embodiment of the present invention includes: a wall part construction step of constructing a pair of the wall parts 100 so that the lower surface of the inclined tension member 600 is buried; a projecting wall portion construction step of pouring the projecting wall portion 110 so that the central portion of the inclined tension member 600 is buried; An installation step of the rigid pillar type and the tension device for installing the pillar type 300 and the tension device (400); A protrusion plate installation step of installing the protrusion plate 310 on the upper part of the columnar type 300; a steel girder mounting step of mounting the steel girder 200; a protruding girder coupling step of coupling the protruding girder 240 coupled to the inclined tension member 600 to the steel girder 200; a tension device coupling step of moving the tension member 420 coupled to the tension device 400 in the lateral direction to couple it to the steel girder 200; introducing a preceding load to the steel girder 200 by introducing a tensile force to the tensile member 420; and a concrete pouring step in which the concrete (C) is poured to form the floor plate (500), and the poured concrete (C) is filled in the tension device (400).

In this case, the steel girder 200 is manufactured in a factory and loaded after being brought into the site, but the groove portion 210 is formed in the steel girder 200 during factory production and the reinforcing member 220 is installed.

In addition, in the concrete pouring step, the inside of the tension device 400 is filled, so that the tension member 420 and the tension device 400 are synthesized.

The inclined tension member 600 is installed to be embedded in the protruding wall part 110 and the wall part 100 as shown in FIG. 16 , and the lower end of the inclined tension member 600 is embedded in the wall part 100 , and the central part protrudes. It is embedded in the wall part 110 .

The protruding girder 240 and the steel girder 200 may be manufactured in a pre-assembled state and mounted at the site, and after the protruding girder 240 is combined with the inclined tension member 600, the steel girder 200 will be coupled to it. may be

The coupling portion J of the protruding girder 240 and the steel girder 200 is preferably coupled by welding or bolts.

In the concrete pouring step, it is poured as shown in FIG. 18 so that both the protruding girder 240 and the inclined tension member 600 are buried.

c : concrete h : long hole
100: wall part 110: protruding wall part
200: steel girder 210: groove
220: reinforcing member 230: central reinforcing member
240: protrusion girder 241: inclined part
300: columnar steel type 310a: stone
310: stone plate 311: plate
312: stone member 313: reinforcing plate
400: tension device 410: body member
411: side part 412: upper surface part
413: lower portion 414: fixed plate
420: tension member 500: bottom plate
600: inclined tension member

Claims (13)

a pair of wall parts 100;
a columnar steel type 300 installed in a standing structure on the upper part of the wall part 100;
a steel girder 200 installed so that an edge is raised on the upper part of the columnar steel type 300;
In order to introduce a preceding load to the steel girder 200, a pair of tension devices 400 coupled to the front and rear of the column steel type 300, respectively;
A bottom plate 500 formed by pouring concrete (C) so that the tension device 400 is embedded;
The tension device 400 is
a body member 410 coupled to one side and the other side of the columnar steel type 300;
The lower end is coupled to the inner side of the body member 410, and the upper end protrudes to the upper portion of the body member 410, and the tension member 420 is coupled to the lower flange of the steel girder 200;
The tension member 420 is
In addition to being coupled to the body member 410 in a structure capable of flowing along the lateral direction,
The body member 410 is
a side portion 411 forming a side surface;
an upper surface portion 412 and a lower surface portion 413 installed to close the upper surface and the lower surface of the side surface portion 411;
and a fixing plate 414 installed in a section between the upper surface portion 412 and the lower surface portion 413 to fix the tension member 420;
The upper surface portion 412 and the fixing plate 414 have
A long hole (h) is formed along the lateral direction, and the tension member 420 is moved along the long hole (h) before being fixed,
It is fixed by a nut on the lower side of the fixing plate 414 and the upper side of the lower flange of the steel girder 200,
The side part 411 is
As a member installed along the lateral direction, it is spaced apart from the front and rear of the tension member 420 and installed as a pair,
One side and the other side of the body member 410 have an open structure,
A protrusion 310a of a round structure convex in the upward direction is formed on the upper surface of the columnar steel type 300,
The protrusion 310a is a protrusion of a semicircular structure with respect to the lateral direction,
A groove portion 210 corresponding to the protrusion 310a is formed on the lower surface of the edge portion of the steel girder 200,
A reinforcing member 220 is installed on one side and the other edge of the steel girder 200 in the vertical direction based on the groove portion 210,
A central reinforcing member 230 is further coupled to the central portion of the groove portion 210 in the vertical direction,
The protrusion 310a is formed by a protrusion plate 310 coupled to the upper surface of the columnar shape 300,
The protrusion plate 310 is
a plate 311 coupled to one side and the other to protrude from the upper surface of the columnar steel type 300;
a protrusion member 312 coupled to form the protrusion 310a on the upper surface of the plate 311;
Containing; reinforcing plate 313 coupled along the downward direction from the lower surface of the plate 311;
The tensile member (420) is a steel composite ramen structure, characterized in that installed through the plate (311) and the lower flange of the steel girder (200).
delete delete delete delete delete delete delete According to claim 1,
The reinforcing plate 313 is
It is installed on one side, the other edge, and the central portion of the plate (311), and is characterized in that it is coupled in a plate structure along the front-rear direction.
10. The method of claim 9,
A protruding girder 240 is coupled to the outside of one end of the steel girder 200,
An inclined tension member 600 is coupled to the protruding girder 240,
The upper end of the inclined tension member 600 is coupled to one edge of the protruding girder 240,
The lower end of the inclined tension member (600) is a rigid composite ramen structure, characterized in that it is fixed to the lower side of the wall portion (100) of the columnar steel type (300) in a buried structure.
11. The method of claim 10,
The inclined tension member 600 is installed to be inclined downwardly toward the other side,
The upper surface of one edge of the protruding girder (240) is a rigid ramen structure, characterized in that the inclined portion (241) inclined downward toward one side is formed.
12. The method of claim 11,
The inclination of the inclined portion (241) is formed to be perpendicular to the axial direction of the inclined tension member (600).
The method for constructing the steel composite ramen structure of claim 12,
a wall part construction step of constructing a pair of the wall parts 100 so that the lower surface of the inclined tension member 600 is buried;
a projecting wall portion construction step of pouring the projecting wall portion 110 so that the central portion of the inclined tension member 600 is buried;
An installation step of the rigid pillar type and the tension device for installing the pillar type 300 and the tension device (400);
A protrusion plate installation step of installing the protrusion plate 310 on the upper part of the columnar type 300;
a steel girder mounting step of mounting the steel girder 200;
a protruding girder coupling step of coupling the protruding girder 240 coupled to the inclined tension member 600 to the steel girder 200;
a tension device coupling step of moving the tension member 420 coupled to the tension device 400 in the lateral direction to couple it to the steel girder 200;
introducing a preceding load to the steel girder 200 by introducing a tensile force to the tensile member 420;
A concrete pouring step in which the concrete (C) is poured to form the bottom plate (500), and the poured concrete (C) is filled in the tension device (400); construction method.

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