KR101044469B1 - Combined projection beam and prestressed concrete girder - Google Patents

Abstract

PURPOSE: A prestressed concrete girder attached with an overhanging beam is provided to secure structural safety by increasing cross sectional stiffness and to improve constructability by placing slab concrete for a bridge easily. CONSTITUTION: A prestressed concrete girder attached with an overhanging beam comprises an upper flange, a web, an overhanging beam coupled to a joint of the upper flange and the web and provided with a first rigid shear connector, a composite board formed to make the lower part buried in two sides of the upper flange and the top exposed and provided with a horizontal connecting hole, a second rigid shear connector inserted and fixed to the connecting hole of the composite board, a first strand(200) installed into a sheath pipe, a second strand(210) installed into the sheath pipe and drew out from the overhanging beam, and a fixing device(300) installed to the web and one end of the overhanging beam.

Description

Combined projection beam and prestressed concrete girder

The present invention relates to a prestressed concrete girder with a protruding beam that can be easily installed in multi-span without protruding beam is coupled to the T-girder to increase the stiffness of the cross-section as well as without having to continuously arrange the PS steel in the continuous bridge.

Prestressed concrete (PSC) is a prestressed concrete (PSC) in which compressive stress is introduced in advance in order to offset the tensile stress that occurs in the concrete.In this case, prestress is introduced to the PS steel (PC steel wire, PC steel bar, etc.). Is introduced by fixing in concrete.

The emergence of this PSC structure created an opportunity to overcome the shortcomings of RC concrete, which is vulnerable to tension. Currently, the use of PS steels is active and various construction methods are being developed, and the construction of the PSC structure is widely performed.

In conventional bridge systems using PSC girders, PSC girders are manufactured at a site near a plant or bridge construction site, transported to the site, mounted between bridge piers or between bridges and shifts, and then placed in place using concrete floor plates and A crossbeam was constructed. However, when the bridge deck is constructed with cast-in-place concrete, there is a problem in that construction costs are required because work by manpower, such as installation of a copper bar and formwork, is required.

In the multi span continuous bridge, the PS steel is continuously placed on the girders to reduce the parent moment occurring at the upper part between the girders and the girders. However, when the PS steel is continuously disposed on the girder, there is a problem in that the amount of prestress loss is increased, so that the number of spans in which the PS steel is installed is limited.

The present invention has been made to solve the above problems, to ensure structural safety by increasing the cross-sectional stiffness, and to install a key block on the upper flange to facilitate the concrete slab bridge deck slab to improve the workability is attached The purpose is to provide a prestressed concrete girder. In addition, the object of the present invention is to provide a prestressed concrete girder with protruding beams that can be combined with the PSC girder to minimize the prestress loss and to increase structural safety and improve construction.

The present invention, in order to achieve the above object, PSC girder comprising an upper flange and the abdomen, the upper flange; An abdomen coupled to a bottom surface of the upper flange; Protruding beams which are installed at both ends of the PSC girder and are coupled to right angles formed by the upper flange and the abdomen, the first rigid connecting member being formed on the side so that the cross beams are structurally integrated; A composite plate having a plurality of transverse connecting holes formed in a longitudinal direction as a plate-shaped member protruding upward from the inside on both upper surfaces of the seating groove and the upper flanges so that the bottom plate reinforcing bars can be seated in the transverse direction; A transverse second rigid connecting member inserted into the transverse connecting hole and installed to be fastened to the composite plate so that adjacent PSC girders are structurally integrated with each other; A first strand attached to the sheath tube so as to have a concave curve at the center portion in the longitudinal direction of the abdomen of the PSC girder; It is built in a sheath tube so as to be a concave curve in the longitudinal direction at the center of the PSC girder passing through the protruding beam formed on one side about the abdomen at one end of the PSC girder, the other at the other end of the PSC girder A second strand drawn out from the protruding beam formed on one side of the abdomen; And a fixing device installed at one end of the abdomen at both ends in the longitudinal direction of the PSC girder and at one end of the protruding beams formed at both sides of the abdomen, wherein one end of the second strand is fixed to the second stranded wire. One end of the protruding beam installed on one end of the PSC girder and one end of the PSC girder having one end, and the fixing of the other end of the second stranded line is adjacent to the other end of the PSC girder having the other end of the second stranded line It provides a prestressed concrete girder with a protrusion beam is characterized in that it is fixed to one end of the protrusion beam installed in.

The present invention having the above configuration has the following effects.

First, the present invention can minimize the stress loss during the installation of PS steel in the parent section in the multi-span bridge, the structural stability is high.

Second, the present invention can increase the cross-sectional stiffness, and can be easily integrated the structure by installing a rigid connection member is structurally stable and excellent in construction.

Third, the present invention is easy to install the bottom plate formwork by installing a key block on the upper flange is excellent in workability.

1 is a first embodiment of a PSC girder of the present invention.
2 is a second embodiment of a PSC girder of the present invention.
3 is a third embodiment of a PSC girder of the present invention.
Figure 4 is a perspective view of the upper protrusion block is coupled to the central upper surface of the upper flange only a part of the central portion of the PSC girder of the present invention.
5 is a perspective view of the upper protrusion block is coupled to the upper surface of the center of the upper flange over the entire length of the PSC girder of the present invention.
Figure 6 is a side view of the PS steel of the present invention is installed.
7 is a side view of the PS steel of the present invention installed in one PSC girder.
8 is a plan view in which the second stranded wire of the present invention is installed.
Fig. 9 is a sectional view of the center portion where the PSC girder of the present invention is installed.
Fig. 10 is a sectional view of the first embodiment of the point portion where the PSC girder of the present invention is installed.
Fig. 11 is a sectional view of the second embodiment of the point portion in which the PSC girder of the present invention is installed.
12 is a perspective view of the composite plate and the second rigid connecting member of the present invention installed on the upper flange.
13 is a cross-sectional view of the arrangement of the first strand and the second strand in the PSC girder according to the present invention.
14 is a perspective view of a bridge constructed by installing a closing plate on an upper side of an upper flange.

Hereinafter, with reference to the accompanying drawings will be described in detail the concrete contents of the prestressed concrete girder with a protrusion beam according to the present invention.

1 is a first embodiment of the PSC girder of the present invention, and FIG. 2 is a second embodiment of the PSC girder of the present invention. Figure 3 is a third embodiment of the PSC girder of the present invention, Figure 4 is a perspective view of the upper protrusion block is coupled to the central upper surface of the upper flange only a portion of the central portion of the PSC girder of the present invention. Figure 5 is a perspective view of the upper protrusion block is coupled to the central upper surface of the upper flange over the entire length of the present invention PSC girder, Figure 6 is a side view of the PS steel of the present invention is installed. 7 is a side view of the PS steel of the present invention installed in one PSC girder. Fig. 8 is a plan view in which the second stranded wire of the present invention is installed, and Fig. 9 is a cross-sectional view of the central portion in which the PSC girder of the present invention is installed. Fig. 10 is a sectional view of the first embodiment of the point portion provided with the PSC girder of the present invention, and Fig. 11 is a sectional view of the second embodiment of the point portion provided with the PSC girder of the present invention. 12 is a perspective view of the composite plate and the second rigid connecting member of the present invention installed on the upper flange, Figure 13 is a cross-sectional view according to the arrangement position of the first strand and the second strand in the PSC girder according to the present invention. 14 is a perspective view of a bridge constructed by installing a closing plate on an upper side of an upper flange.

The present invention relates to a prestressed concrete girder with a protruding beam, and more specifically, in a PSC girder including an upper flange and an abdomen, an upper flange, an abdomen coupled to a center bottom surface of the upper flange, and both ends of the PSC girder. Being installed is coupled to the right angled portion formed by the upper flange and the abdomen, the first beam is formed with a first rigid connection member on the side so that the cross beams are structurally integrated, the bottom plate reinforcement in the transverse direction A composite plate member having a plurality of transverse connecting holes formed in a longitudinal direction on the upper surface of both sides of the seating groove and the upper flanges so as to be seated therein, and inserted into the transverse connecting hole to the composite plate. Installed side by side so that adjacent PSC girders are structurally integrated with each other The second rigid connecting member, the first stranded wire in the sheath pipe so as to be concave in the center portion in the longitudinal direction of the abdomen of the PSC girder, the protruding beam formed on either side about the abdomen at one end of the PSC girder A second strand drawn through the sheathing pipe so as to be concave in the longitudinal direction at the center of the PSC girder, and drawn out from the protruding beam formed at one side about the abdomen at the other end of the PSC girder; And a fixing device installed on both sides of the abdomen at both ends in the longitudinal direction of the PSC girder and on the rear surface of the protruding beams formed on both sides of the abdomen, wherein one end of the second stranded wire is one end of the second stranded wire. One end of the protruding beam installed in the neighboring PSC girder and one end of the PSC girder, and fixing the other end of the second stranded wire And the other end of the PSC girder having the other end of the second stranded wire is fixed to one end of the protruding beam installed in the neighboring PSC girder.

The present invention may further comprise an upper protrusion block coupled to the central upper surface of the upper flange only a portion of the central portion of the PSC girder or an upper protrusion block coupled to the central upper surface of the upper flange over the entire length of the PSC girder.

In another aspect, the present invention is characterized in that the lower flange is widened to the lower part of the abdomen in the branch portion.

The protruding beam 140 may be combined in various forms. Preferably, the protruding beam 140, the upper flange 120, and the abdomen 110 are integrally poured by concrete pouring. As the cross-sectional shape of the protruding beam 140 may be used a variety of shapes, such as circular, but preferably have a rectangular shape. The protrusion beam 140 may be coupled to a portion where the upper flange 120 and the abdomen 110 are coupled to increase the rigidity of the PSC girder 100 and increase the center of the cross section to maximize the PS steel wire eccentric moment. In addition, the protruding beam 140 is a place where the second stranded wire 210 installed in the parent section is fixed, and the second stranded wire 210 may not be continuously installed on the PSC girder 100 by the protruding beam 140. . That is, the number of PSC girders 100 in which steels are installed due to stress loss when PS steels are continuously installed in a girder in a multi-span continuous bridge is limited. According to the protrusion beam 140 of the present invention, the number of PSC girders 100 is provided. Regardless, the second stranded wire 210 may be installed in the PSC girder 100. In addition, the first rigid connection member 500 is installed on the side of the protruding beam 140, so that it can be easily integrated with the horizontal beam 10 to be constructed later. The first rigid connection member 500 is protruded by the fixing length from the side of the protruding beam 140 is coupled to the reinforcing bar 40 of the cross beam 10 to withstand the load sufficiently. Therefore, the reinforcing beams 40 and the cross beams 10 are easily coupled to the first rigid connection member 500 and the reinforcing bar 40 of the cross beam 10 by being integrated.

 The second stranded wire 210 passes through the protruding beam 140 at one end of the PSC girder 100 and is drawn out of the protruding beam 140 at the other end of the PSC girder 100, but the second stranded wire 210 is fixed. It is fixed to one end of the protruding beam 140 in the installed PSC girder 100 and the neighboring PSC girder 100. The second stranded wire 210 according to the present invention does not continuously install the steel wire in a multi-span continuous bridge, and installs the second stranded wire 210 in one girder and the fixing is the PSC girder in which the second stranded wire 210 is installed ( One end of the protruding beam 140 of the PSC girder 100 adjacent to the 100. That is, one end of the second stranded wire 210 is fixed to one end of the protruding beam 140 of the PSC girder 100 adjacent to one end of the PSC girder 100 on which the second stranded wire 210 is installed, and the other end of the second stranded wire 210 is fixed. The two strands 210 are fixed to the protruding beam 140 of the PSC girder 100 adjacent to the other end of the PSC girder 100 is installed. As shown in FIGS. 7 and 8, when the second stranded wire 210 is installed in the PSC girder 100, the second stranded wire 210 starts at the one end protruding beam 140 of the PSC girder 100. The central part is located on the abdomen 110 of the PSC girder 100 and the end is drawn out from the other end protruding beam 140 of the PSC girder 100. That is, the second strand 210 is arranged in a curved shape in the longitudinal direction of the PSC girder 100, and is disposed in a curved shape in the lateral direction, and when viewed as a whole, the second strand 210 is three-dimensionally connected to the PSC girder 100. It is curved. Therefore, the second stranded wire 210 according to the present invention can reduce the parent moment without being continuously installed in the PSC girder 100, and can also minimize the loss of stress due to the continuous installation of the tension member is structurally stable.

As shown in FIGS. 4 and 5, the upper protrusion block 130 may be installed in the PSC girder 100 as a whole, and is not required for the stress distribution in the point portion, so that the upper protrusion block 130 may be installed in the portion except the point portion of the PSC girder 100. It may be. The upper protrusion block 130 is integrally coupled to the central portion of the upper surface of the upper flange 120. The upper protrusion block 130 increases the eccentric moment of the PS steel wire by raising the center of the cross section, and reduces the tensile stress of the upper flange during tension by reducing the upper arm moment of the girder. In addition, the upper protrusion block 130 serves to increase the rigidity of the PSC girder 100.

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The composite plate 400 has lower portions embedded at both sides in the horizontal direction of the upper flange 120, and the upper end thereof is formed to protrude. A transverse connecting hole 420 spaced apart from each other in the longitudinal direction is formed at the protruding upper end of the composite plate 400. Composite plate 400 may be used in a variety of shapes, such as circular, rhombus, but is preferably formed in a rectangular shape.

The second rigid connection member 510 is inserted into and fixed to the connection hole 420 of the composite plate 400. The second rigid connecting member 510 is connected to the connecting member of the adjacent PSC girder 100 and serves to structurally integrate the PSC girder 100 with each other.

The present invention may further include a seating groove so that the bottom plate rebar can be seated in the transverse direction on the upper surface of the composite plate.

The seating groove 410 of the composite plate 400 serves to help the reinforcement of the upper bottom to be seated in the transverse direction to facilitate the assembly of the reinforcement of the bridge top plate.

The present invention may further include a closing plate installed between the upper flanges and a key block installed at the lower side of the upper flange so that one end of the closing plate can be supported. Alternatively, a closing plate installed between the upper flanges and a side upper portion of the upper flange may further include a coupling groove formed so that one end of the closing plate may be coupled.

The closing plate 610 is installed between the upper flange 120 of the PSC girder 100 and the upper flange 120 of the neighboring PSC girder 100. The finishing plate 610 may serve as formwork when placing concrete on the upper part of the bridge, but wood, deck plates, and the like may be used, but preferably, precast concrete plates are used.

Key block 600 is installed using a bolt or the like on the lower side of the upper flange 120 to support the closing plate 610 is installed between the PSC girder (100). The closing plate 610 installed between the upper flanges 120 of the PSC girder 100 may be installed on the upper side of the upper flange 120. In this case, the closing plate 610 is coupled to both ends of the coupling groove 121 formed in the upper side of the transverse side of the upper flange 120.

After the integration process of each PSC girder 100 is made as described above by the present invention, the upper reinforcement is reinforced and the concrete is poured to install the upper structure of the bridge.

PSC girder 100 described in the present invention is made through the following process.

The present invention is a method for manufacturing a PSC girder comprising an upper flange and the abdomen, (a) installing the PSC girder (100) bottom formwork, (b) reinforcing the reinforcement on the bottom formwork (c) installing the sheath tube after reinforcing the reinforcing bars, (d) installing the side formwork after the step (c), (e) installing the protruding beam 140 formwork on the side formwork, and reinforcing the reinforcing bars. (F) installing the formwork of the upper flange 120 and the top protrusion block 130, (g) placing and curing concrete; (h) removing the formwork in the steps (a) to (g), and (i) inserting the first and second strands 200 and 210 into the sheath tube to install the second strand 210 ) Is a method of manufacturing a prestressed concrete girder with a protrusion beam, characterized in that the step of drawing out a protruding beam 140 to a predetermined length, (j) the step of introducing the stress to the PSC girder by tensioning the first stranded wire. .

In step (i), both ends of the second stranded wire 210 are drawn out to a predetermined length out of the protruding beam 140. Both ends of the drawn second stranded wire 210 are fixed to the protruding beam 140 of the PSC girder 100 adjacent to the PSC girder 100 on which the second stranded wire 210 is installed, and the stress is applied to the PSC girder 100. It serves to introduce.

As described above, the preferred embodiment of the prestressed concrete girder and the manufacturing method with the protruding beam according to the present invention has been described, which is described as at least one embodiment, whereby the technical idea of the present invention and its configuration and operation are not limited. The scope of the technical idea of the present invention is not limited or limited by the drawings or the description with reference to the drawings. In addition, the concept and embodiment of the invention presented in the present invention may be used by those skilled in the art as a basis for modifying or designing to other structures for carrying out the same purpose of the present invention. The equivalent structure modified or changed by those skilled in the art to which the present invention pertains is to be bound by the technical scope of the present invention described in the claims, and the spirit or scope of the invention described in the claims. Various changes, substitutions and alterations are possible without departing from the scope of the invention.

10: crossbeam 20: upper bridge
100: PSC girder 110: abdomen
120: upper flange 130: upper protrusion block
140: protrusion beam 150: lower flange
200: first stranded wire 210: second stranded wire
300: fixing device 400: composite plate
500: first rigid connector 510: second rigid connector
600: key block

Claims (9)

In the PSC girder comprising the upper flange and the abdomen,
Upper flange;
An abdomen coupled to a bottom surface of the upper flange;
Protruding beams which are installed at both ends of the PSC girder and are coupled to right angles formed by the upper flange and the abdomen, the first rigid connecting member being formed on the side so that the cross beams are structurally integrated;
A composite plate having a plurality of transverse connecting holes formed in a longitudinal direction as a plate-shaped member protruding upward from the inside on both upper surfaces of the seating groove and the upper flanges so that the bottom plate reinforcing bars can be seated in the transverse direction;
A transverse second rigid connecting member inserted into the transverse connecting hole and installed to be fastened to the composite plate so that adjacent PSC girders are structurally integrated with each other;
A first strand attached to the sheath tube so as to have a concave curve at the center portion in the longitudinal direction of the abdomen of the PSC girder;
It is built in a sheath tube so as to be a concave curve in the longitudinal direction at the center of the PSC girder passing through the protruding beam formed on one side about the abdomen at one end of the PSC girder, the at the other end of the PSC girder A second strand drawn out from the protruding beam formed on one side of the abdomen; And
A fixing device installed at one end of the abdomen at both ends in the longitudinal direction of the PSC girder and at one end of the protruding beam formed on both sides of the abdomen,
One end of the second strand is anchored to one end of the protruding beam installed in the PSC girder adjacent to one end of the PSC girder with one end of the second strand, and the other end of the second strand is fixed of the second strand The prestressed concrete girder with protruding beams, characterized in that the other end of the PSC girder having the other end is fixed to one end of the protruding beams installed in the neighboring PSC girder.
The method of claim 1,
The prestressed concrete girder with a protrusion beam further comprises a; the upper protrusion block coupled to the upper surface of the central upper flange only a part of the central portion of the PSC girder. The method of claim 1,
The prestressed concrete girder with a protrusion beam further comprises; the upper protrusion block coupled to the upper surface of the upper flange center over the entire length of the PSC girder. The method of claim 1,
Prestressed concrete girders attached to the protruding beam, characterized in that the lower flange is widened to the lower part of the abdomen at the point portion.
delete delete The method of claim 1,
A closing plate installed between the upper flanges; And
The prestressed concrete girder with a protruding beam, characterized in that it further comprises; a key block is installed on the lower side of the upper flange so that one end of the closing plate can be supported.
The method of claim 1,
A closing plate installed between the upper flanges; And
The prestressed concrete girder with a protruding beam, characterized in that it further comprises; a coupling groove that one end of the closing plate is coupled to the upper side of the upper flange. delete

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