KR102378877B1 - Segment prestressed concrete girder and junction method of the same and bridge fast construction method using the same - Google Patents

Abstract

The present invention relates to a segmented PS concrete girder, a bonding method thereof, and a rapid construction method of a bridge using the same, in which a segmented PS concrete girder is easily assembled. The bonding method of the present invention comprises the steps of: manufacturing an end segment girder (16) in each factory; transporting a central segment girder (12), a middle segment girder (14) and an end segment girder (16) to a construction site; and arranging the end segment girder (16) on both sides of the middle segment girder (14).

Description

Segment prestressed concrete girder and junction method of the same and bridge fast construction method using the same}

The present invention relates to a segmented PS concrete girder, a bonding method thereof, and a rapid construction method of a bridge using the same. In particular, a plurality of segmented girders are joined through a joint tension material that passes through each joint surface to assemble a segmented PS concrete girder in the field. Segmented PS that is easy to use, and uniform bonding pressure is formed on the bonding surface to prevent some concrete from falling out or cracking at the bonding area, and to construct a bridge without installing a floor formwork, so that it can be joined for rapid construction. It relates to a concrete girder and its joining method, and to a rapid construction method of a bridge using the same.

In general, segmented PS concrete girders are assembled and constructed through tension after aligning each segmented girder made of segments on site. Therefore, the segmented girder needs to be joined before tensioning. If the joint surfaces do not match at the time of joining, non-uniform contact pressure is generated and some concrete falls off or cracks occur. As a well-known bonding method, a method is known in which a block-out portion is formed on an upper portion of the joint portion, and a reinforcing bar is exposed to the block-out portion to connect through a coupler. In this case, it is difficult to connect the coupler due to the narrow space of the block-out part. In addition, it is difficult to expect a uniform bonding pressure because bonding occurs on the upper side of the bonding surface.

As the background technology of the present invention, as Korean Patent Registration No. 10-1163456, 'segmented prestressed concrete box beam and its joining method' is proposed. In this joining method, in order to minimize the error that occurs when the segments are joined together, a flexible spacer is installed between the joint surfaces, and the epoxy is applied and exposed reinforcing bars are connected through a coupler at the same time, and then the epoxy is cured. After excitation, the method of joining through the introduction of prestress using a tension member is used. However, in this background art, it is difficult to connect the coupler due to the narrow space of the block-out part. In addition, it is difficult to expect a uniform bonding pressure during curing of the epoxy.

Korean Patent Registration No. 10-1163456

In the present invention, the assembly of the segmented PS concrete girder in the field is made simple and easy by joining a plurality of segmented girders through a joint tension material that inserts each joint surface, and a uniform joint pressure is formed on the joint surface to form some concrete at the joint. The purpose of this is to provide a segmented PS concrete girder that can prevent drop-out or cracks and can construct a bridge without installing a floor formwork so that it can be joined for rapid construction, a joining method thereof, and a rapid construction method of a bridge using the same. .

The integral bonding method of a segmented PS concrete girder according to a suitable embodiment of the present invention is a central segmented girder having a plurality of central bonding devices that are respectively connected through a sheath pipe for joining tension material on the central side and are spaced apart from both ends by a certain section and buried and the second intermediate side inserted in a certain section from both ends at a position displaced from the first intermediate joint tension material lead-in sheath tube and the intermediate joint joint tension material lead-in sheath tube, which are disposed on the same axis as the central joint joint tension material lead-in sheath tube A middle segmented girder having a plurality of intermediate joining devices each connected through a sheath pipe for joining tension material, and a sheath pipe for joining tension material at the end side buried coaxially with the second intermediate side joint tension material lead-in sheath pipe. manufacturing the end-segmented girder at each factory; After transporting the central segment girder, the middle segment girder and the end segment girder to the construction site, first align the middle segment girder on both sides of the center segment girder, and for the entry of the first intermediate joint tension material of each intermediate segment girder inserting the first joint tension material into the sheath pipe, engaging the front end with the central joining device and the central joining device, and tensioning at the same time to fix the other end to the ends of both intermediate segmented girder; Align the end segment girder on both sides of the intermediate segment girder, insert the end of the second joint tension member through the end-side joint tension member lead-in sheath pipe, engage the intermediate joining device, and tension the other end of the end segment girder Including;
The central bonding device and the intermediate bonding device have the same configuration, and include: a wedge socket having a tapered hole on one side on the central axis and a male screw on the other side; a plurality of split wedges disposed on the central axis of the wedge socket and facing the tapered hole; a cylindrical sleeve screwed to the rear end of the wedge socket; a wedge pusher disposed inside the cylindrical sleeve and having one end installed to support the rear end of the split wedge; a spring support plug disposed coaxially at the rear of the wedge pusher and screwed to the rear end of the cylindrical sleeve; a wedge pusher spring disposed between the wedge pusher and the spring support plug to push the wedge pusher forward; It characterized in that it includes; a bonding device fixing block having a plurality of annular grooves for fixing and screwed to the spring support plug to maintain a fixing state in the segmented girder in which a central bonding device or an intermediate bonding device is installed.

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In addition, when both the central bonding device and the intermediate bonding device are projected on the cross section of the segmented PS concrete girder, they are characterized in that they are arranged symmetrically left and right and up and down with respect to the center of the cross section of the segmented PS concrete girder.

In addition, after inserting the first joint tension material into the first intermediate joint tension material lead-in sheath tube, grouting into the inside of the central joint joint tension material lead-in sheath tube and the first intermediate joint tension material lead-in sheath tube; After inserting the tip of the second joint tension member into the end-side joint tension member lead-in sheath pipe, grouting into the inside of the second intermediate joint joint tension member lead-in sheath pipe and the end-side joint tension member lead-in sheath pipe; further includes characterized by being

According to the segmented PS concrete girder and its joining method and the rapid construction method of a bridge using the same of the present invention, a tension force is introduced into a plurality of pre-tensioned materials to form an equal bonding pressure on the joint surfaces between the segmented girders, so that partial concrete at the joint damage or cracks can be prevented.

In addition, since the assembly of the segment girder is completed within the time when the epoxy applied to the joint is hardened, it was possible to assemble up to 7 segments in the prior art.

In addition, it is possible to construct a bridge quickly by constructing a floor slab without installing a floor formwork after mounting and binding the segmented PS concrete girders on an abutment or pier.

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical spirit of the present invention together with the detailed description of the present invention, so the present invention is limited to the matters described in the accompanying drawings It should not be construed as being limited.
1a is a block diagram of a 5-segment PS concrete girder according to an embodiment of the present invention.
Figure 1b is a block diagram of a 7-segment PS concrete girder according to an embodiment of the present invention.
Fig. 2A is a cross-sectional view taken along line AA of Fig. 1A;
Fig. 2B is a cross-sectional view taken along line BB of Fig. 1A;
FIG. 2C is an arrangement state diagram of the fixing device projected onto the projection plane of the central axis of FIG. 1A; FIG.
3 is an enlarged view of part 'C' of FIG. 1A.
Figure 4 is an exploded perspective view of the central bonding device or the intermediate bonding device applied to the present invention.
5 (A) and (B) are a cross-sectional view of the joint part between the segment girder and the DD line.
Figure 6a is a manufacturing state diagram of a 5-segment PS concrete girder according to an embodiment of the present invention.
Figure 6b is a state diagram of assembling the middle segment girder to the center segment girder of Fig. 6a.
Figure 6c is a state diagram of assembling the end segment girder to the middle segment girder of Fig. 6a.
Figure 7a is a state diagram in which a plurality of segmented PS concrete girders manufactured by the present invention are arranged on a pier in a direction perpendicular to the pier and then bound with a transverse tension member.
7b is a state diagram in which a floor slab and a protective wall are sequentially constructed on the upper surface of the segmented PS concrete girder after binding of the segmented PS concrete girder shown in FIG. 7a.
Figure 8a is a modified perspective view of the bonding device applied to the present invention.
Fig. 8b is a longitudinal sectional view of Fig. 8a;
Fig. 8c is an exploded perspective view of Fig. 8a;
Figure 9 is an exemplary view of a segmented PS concrete girder assembled by applying the bonding device shown in Figure 8a.
10 is an enlarged view of any one joint of the segmental girder shown in FIG.
FIG. 11 is a state diagram in which the wedge socket is separated from any one of the segment girder-side bonding devices of FIG. 9;

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the presented embodiments are illustrative for a clear understanding of the present invention, and the present invention is not limited thereto.

1a and 1b, the segmented PS concrete girder 10 according to this embodiment may be manufactured in 5 segments or 7 segments, for example. Of course, the segmented PS concrete girder 10 is not limited to the illustrated number of segments.

In the segmented PS concrete girder 10, the middle segmental girder 14 is joined to the central segmented girder 12 through the first joint tension member 18 symmetrically with respect to the central segmented girder 12 arranged in the center, The end segment girder 16 is joined to the middle segment girder 14 through the second joint tension member 20 . At this time, a plurality of the first bonding tension member 18 and the second bonding tension member 20 are installed at positions deviated from each other in the same number, and the first bonding tension member 18 and the second bonding tension member 20 each have one end. After being clamped and tensioned by the central bonding device 100a and the intermediate bonding device 100b of the same configuration, each other end is connected to a fixing device known in the pretension method. In the present embodiment, the first bonding tension member 18 and the second bonding tension member 20 are each installed four, but the number is not limited thereto.

The central bonding apparatus 100a and the intermediate bonding apparatus 100b have the same structure. 3 and 4, the central bonding device 100a or the intermediate bonding device 100b has a wedge socket 110 having a tapered hole 111 on one side and a screw hole 112 on the other side on the central axis, and the It has a plurality of split wedges 120 disposed on the central axis of the wedge socket 110 and interfacing with the tapered hole 111, and a plug guide hole 130a penetrated on the central axis, and is screwed into the screw hole 112. A spring support plug 130 coupled to the wedge socket 110 and a wedge pusher having one end supporting the split wedge 120 and the other end inserted into the guide hole 130a of the spring support plug 130 ( 140 , and a wedge pusher spring 150 inserted into the outer peripheral surface of the wedge pusher 140 , one end supported by the spring support plug 130 and the other end supported by the wedge pusher 140 .

Among the components of the central bonding device 100a and the intermediate bonding device 100b, the wedge pusher 140 is pushed by the pusher spring 150 with a uniform contact pressure to the rear surface of the plurality of split wedges 120, so that a plurality of The split wedge 120 bites the first joint tension member 18 and the second joint tension member 20 at the same time and connects them to the corresponding girder side. Therefore, since the plurality of split wedges 120 are all arranged on the concentric shaft to exert the engagement force, the engagement and fixation force of the first joint tension member 18 and the second joint tension member 20 can be increased, and thereby the segment girder ( The bonding strength between 12 and 14 (14 and 16) can be improved.

The first joint tension member 18 and the second joint tension member 20 may be a stranded wire, a steel bar, a reinforcing bar, or the like. When both the central bonding device 100a and the intermediate bonding device 100b are projected on the cross section of the segmented PS concrete girder 10, the segmented PS concrete girder ( 10) is preferably arranged so as to be left and right and up and down symmetrically with respect to the cross-sectional center (O). In addition, as shown in FIG. 5 , the keyway 121 and the protruding key 141 are coupled to the joint surface between the central segmented girder 12 and the intermediate segmented girder 14 . Of course, the same keyway and protruding key are coupled to the joint surface between the middle segmental girder 14 and the end segmental girder 16 as well.

In this way, the segmented PS concrete girder 10 uses the first bonding tension material 18 and the second bonding tension material 20 to form an even bonding pressure on the bonding surfaces between the segment girder to prevent partial concrete breakage or cracking. can In addition, the segmented PS concrete girder 10 is bonded by applying epoxy to each joint. At this time, since the assembly of the segment girder can be completed before the epoxy applied to each joint unit hardens, it was possible to assemble up to 7 segments in the prior art.

A bonding method of the segmented PS concrete girder 10 configured in this way will be described.

First, as shown in Fig. 6a, a central segmented girder 12 having a plurality of central bonding devices 100a that are respectively connected through a sheath pipe (S1) for inlet in the central side and are spaced apart from both ends by a predetermined section and are buried, and the central side The first intermediate joint tension material inlet sheath pipe (S2) disposed on the same axis as the joint tension material inlet sheath pipe (S1) and the intermediate joint joint tension material inlet sheath tube (S2) are displaced from both ends by a certain section, An intermediate segmented girder 14 having a plurality of intermediate joining devices 100b, each connected through a sheath pipe S3 for introducing a second intermediate joint tension material, and a sheath pipe for introducing a second intermediate joint tension material S3 ) and the end-segmented girder 16 having a sheath pipe (S4) for inserting an end-side joint tension member buried on the same axis is manufactured at each factory.

Here, the central segment girder 12, the middle segment girder 14 and the end segment girder 16 are made of concrete, reinforcing bars (not shown) are reinforced, and a sheath pipe (not shown) for inserting a tension material (not shown) for this tension. 102) is installed.

Then, as shown in FIG. 6b, after transporting the central segmented girder 12, the intermediate segmented girder 14 and the end segmented girder 16 to the construction site, firstly, the middle segmental girder on both sides of the central segmented girder 12 (14, 14) are aligned, and the first joint tension material 18 is inserted into the first intermediate joint tension material lead-in sheath pipe (S2) of both intermediate segmented girders 14 and 14, respectively, and the ends are centrally joined. The device 100a and the central bonding device 100b are engaged and tensioned at the same time, and the other end is fixed to the ends of the intermediate segmented girder 14 on both sides. At this time, epoxy is applied between the central segmented girder 12 and the intermediate segmented girder 14 .

Here, after inserting the first joint tension material 18 into the first intermediate joint tension material lead-in sheath tube (S2), the central joint joint tension material lead-in sheath tube (S1) and the first intermediate joint tension material lead-in sheath tube ( Grouting is carried out into the interior of S2).

Then, as shown in FIG. 6c, the end segmental girder 16 is aligned on both sides of the intermediate segmental girder 14, and the end of the second joint tension material 20 is connected with the end-side joint tension material lead-in sheath pipe (S4). It is inserted and engaged with the intermediate bonding device (100b), and the other end is fixed to the end of the end segmented girder (16) by tension.

At this time, epoxy is applied between the middle segmental girder 14 and the end segmental girder 16 .

Here, after inserting the tip of the second joint tension member 20 into the end-side joint tension member lead-in sheath pipe (S4), the second intermediate joint tension member lead-in sheath pipe (S3) and the end-side joint tension member lead-in sheath pipe (S4) Grouting is carried out into the interior of S4).

In this way, the fixing of the second bonding tension material 20 is completed before the epoxy applied to each divided surface (junction) is cured, and a multi-step bonding method is applied, so that the number of segmented girders is not limited. .

A rapid construction method of a bridge using the segmented PS concrete girder 10 manufactured as described above will be described.

First, the segmented PS concrete girder 10 produced as shown in FIGS. 1A and 1B is lifted from the construction site of the bridge and mounted on the pier 200 (or abutment) as shown in FIG. 7A .

Then, through the transverse tension member 30, a plurality of segmented PS concrete girders 10 arranged side by side for each span are bound in a direction perpendicular to the bridge axis.

Here, the transverse tension member 30 has one end connected to the transverse bonding device 100c embedded in the segmented PS concrete girder 10 of one side disposed for every 1 span, and the other end is connected to the segmented PS concrete girder 10 of the other side. It is established through well-known settlement means. The transverse tension member 30 may be a stranded wire, a steel bar, a reinforcing bar, or the like. The lateral bonding apparatus 100c has the same configuration as the above-described central bonding apparatus 100a or the intermediate bonding apparatus 100b, and detailed description thereof is omitted.

Then, concrete is poured on the upper surfaces of the segmented PS concrete girders 10 bound as shown in FIG. 7B to construct the floor slab 40 of a certain thickness. Thereafter, the protective wall 50 is constructed on the floor slab 40 .

As described above, when the segmented PS concrete girder 10 according to the present invention is used, it is closely adhered in the direction at right angles to the throttle, and the binding is made simple, so that the floor slab 40 can be constructed without the installation of the floor formwork. Therefore, when the upper structure of the bridge is lost due to a flood or torrential rain, it is possible to perform rapid construction by applying the segmented PS concrete girder (10).

On the other hand, in the integral bonding method of the segmented PS concrete girder of the present invention, the central bonding device 100a or the intermediate bonding device 100b may be modified and configured as shown in FIGS. 8a to 8c. The central bonding device 100a or the intermediate bonding device 100b shown in FIGS. 8A to 8C is a wedge socket ( 110) is separated from the segmented girder and has the advantage of being able to solve it in the field. The modified central bonding device 100a or the intermediate bonding device 100b has the same configuration as in FIGS. 8A to 8C, and has a tapered hole 111 on one side on the central axis and a male screw 113 on the other side on the central axis. a socket 110; a plurality of split wedges 120 disposed on the central axis of the wedge socket 110 and facing the tapered hole 111; a cylindrical sleeve 160 screwed to the rear end of the wedge socket 110; a wedge pusher (140) disposed inside the cylindrical sleeve (160) and having one end installed to support the rear end of the split wedge (120); a spring support plug 130 disposed coaxially to the rear of the wedge pusher 140 and screwed to the rear end of the cylindrical sleeve 160; a wedge pusher spring 150 disposed between the wedge pusher 140 and the spring support plug 130 to push the wedge pusher 140 forward; Joint having a plurality of annular grooves 172 for fixing and screwing to the spring support plug 130 to maintain the fixing state in the segmented girder in which the central bonding device 100a or the intermediate bonding device 100b is installed. It includes a device fixing block 170;

Therefore, as shown in Fig. 10, the wedge socket 110 is exposed to the junction of the intermediate segmented girder 14 or the end segmented girder 16, so that a problem occurs when connecting and installing the first and second joint tensioners 18 and 20, As shown in FIG. 11 , the problem of failure can be easily solved by rotating the wedge socket 110 and separating it from the cylindrical sleeve 160 . On the other hand, the bonding apparatus fixing block 170 increases the anchoring force of the central bonding apparatus 100a and the intermediate bonding apparatus 100b in the corresponding segmental girder to increase the bonding force between the segmental girders.

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art can make various modifications and modified inventions without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by such variations and modifications, but only by the claims appended hereto.

10: segmented PS concrete girder
12: central segment girder
14: middle segment girder
16: end segment girder
18: first joint tension member
20: second bonding tension member
100a: central bonding device
100b: intermediate bonding device

Claims (8)

In the method of joining the segmented PS concrete girder (10),
A central segmented girder 12 having a plurality of central bonding devices 100a that are respectively connected through the central bonding tension material inlet sheath pipe (S1) and are buried at a predetermined interval from both ends, and the central side bonding tension material inlet sheath pipe (S1) and the first intermediate side joint tension material lead-in sheath pipe (S2) and the intermediate-side joint tension material lead-in sheath pipe (S2), which are disposed on the same axis as (S1), the second intermediate side joint is inserted in a certain section from both ends at a displaced position Intermediate segmented girder 14 having a plurality of intermediate bonding devices 100b each connected through the sheath pipe S3 for tension material inlet, and the second intermediate side joint tension material inlet sheath pipe S3 and coaxially buried Manufacturing the end-segmented girder 16 having a sheath pipe (S4) for pulling in the end-side joint tension material, respectively, at a factory;
After transporting the central segmental girder 12, the middle segmental girder 14 and the end segmental girder 16 to the construction site, firstly align the intermediate segmental girders 14 and 14 on both sides of the central segmented girder 12. and insert the first joint tension material 18 into the first intermediate joint tension material lead-in sheath pipe (S2) of both intermediate segmented girders 14 and 14, respectively, and connect the tip to the central joint device 100a and the center A step of fixing the other end to the end of the intermediate segmented girder 14 at the same time as being engaged with the device (100b);
The end segment girder 16 is aligned on both sides of the intermediate segment girder 14, and the end of the second joint tension member 20 is inserted into the end-side joint tension member lead-in sheath pipe (S4), and the intermediate joining device 100b ), and the other end is fixed to the end of the end segmented girder 16 by tensioning it; including;
The central bonding apparatus 100a and the intermediate bonding apparatus 100b have the same configuration, and a wedge socket 110 having a tapered hole 111 on one side and a male screw 113 on the other side on the central axis; a plurality of split wedges 120 disposed on the central axis of the wedge socket 110 and facing the tapered hole 111; a cylindrical sleeve 160 screwed to the rear end of the wedge socket 110; a wedge pusher (140) disposed inside the cylindrical sleeve (160) and having one end installed to support the rear end of the split wedge (120); a spring support plug 130 disposed coaxially to the rear of the wedge pusher 140 and screwed to the rear end of the cylindrical sleeve 160; a wedge pusher spring 150 disposed between the wedge pusher 140 and the spring support plug 130 to push the wedge pusher 140 forward; Joint having a plurality of annular grooves 172 for fixing and screwing to the spring support plug 130 to maintain the fixing state in the segmented girder in which the central bonding device 100a or the intermediate bonding device 100b is installed. The device fixing block 170; the integral bonding method of the segmented PS concrete girder, characterized in that it includes. delete delete The method of claim 1,
When both the central bonding device 100a and the intermediate bonding device 100b are projected on the cross section of the segmented PS concrete girder 10, they are arranged symmetrically left and right and up and down with respect to the cross-sectional center of the segmented PS concrete girder 10 Integral bonding method of segmented PS concrete girder, characterized in that there is. The method of claim 1,
After inserting the first joint tension material 18 into the first intermediate joint tension material lead-in sheath tube (S2), the central joint joint tension material lead-in sheath tube (S1) and the first intermediate joint tension material lead-in sheath tube (S2) performing grouting into the interior of the;
After inserting the tip of the second joint tension member 20 into the end-side joint tension member lead-in sheath pipe (S4), the second intermediate joint tension member lead-in sheath pipe (S3) and the end-side joint tension member lead-in sheath pipe (S4) Integral bonding method of segmented PS concrete girder, characterized in that it further comprises; Segmented PS concrete girder, characterized in that manufactured by the one-piece bonding method of any one of claims 1 or 5. Claims 1 or 5 comprising the steps of lifting the segmented PS concrete girder (10) manufactured by the one-piece bonding method of any one of claims 1 to 5 and placing it on a pier or abutment;
A step of binding a plurality of segmented PS concrete girders 10 arranged side by side for each span through the transverse tension member 30 in a direction perpendicular to the bridge axis;
Constructing a floor slab 40 of a certain thickness by pouring concrete on the upper surfaces of the bonded segmented PS concrete girders 10; A rapid construction method of a bridge using a segmented PS concrete girders, comprising: a. 8. The method of claim 7,
One end of the transverse tension member 30 is connected to the transverse bonding device 100c embedded in the segmented PS concrete girder 10 on one side arranged for every 1 span, and the other end is fixed to the segmented PS concrete girder 10 of the other side. , The lateral bonding device (100c) is a rapid construction method of a bridge, characterized in that it has the same configuration as the central bonding device (100a) or the intermediate bonding device (100b).

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