KR20040009056A - Bracket for connecting prestressed concrete beam, prestressed concrete bridge using thereof and method for connecting prestressed concrete beam using thereof - Google Patents

Abstract

PURPOSE: A bracket for connecting the ends of prestressed concrete beams is provided to keep the continuation of a PSC beam bridge firmly and to heighten safety. CONSTITUTION: The bracket for connecting the ends of prestressed concrete beams comprises: a floor plate(21) where both prestressed concrete beams are placed; vertical side plates(22) erected vertically on both floor plates(21); many studs(22a) formed on the inside of the vertical side plate(22) to couple with a prestressed concrete beam in one; and many vertical reinforcing ribs(21a) formed on the top of the floor plate(21) to reinforce the floor plate(21).

Description

BRACKET FOR CONNECTING PRESTRESSED CONCRETE BEAM, PRESTRESSED CONCRETE BRIDGE USING THEREOF AND METHOD FOR CONNECTING PRESTRESSED CONCRETE BEAM USING THEREOF}

The present invention relates to the connection of prestressed concrete beams (hereinafter referred to as 'PSC beams') bridge ends, and more particularly, the continuous of the ends of the PSC beams with only one support member at the bottom of the PSC beams. The present invention relates to a PSC beam end connecting bracket device for maintaining a state, a continuous PSC beam bridge having a beam connecting structure using the same, and a construction method thereof.

In the PSC beam bridge, a conventional PSC beam is manufactured in the form of a simple beam at a bridge construction site and is lifted and installed at the top of the bridge. As the PSC beam is constructed as a simple beam, the central section of the simple beam acts as an excessive bending moment to increase the cross section, and when it is constructed as a simple beam of 25 to 30m, the span cannot be lengthened due to the weight of concrete. There is a restriction.

In addition, when the construction of the PSC beam as a simple beam, the consumption of the steel wire, which is a tension material increases more and the necessity of increasing the cross-sectional view of the PSC beam, there is a disadvantage in that the economical efficiency in construction. In order to overcome this disadvantage, conventionally, the PSC beam is mounted on a pier and then sequential. In the case of constructing the PSC beam which is manufactured in advance, the cross section can be reduced, so that the PSC beam bridge constructed in a discontinuous state can be reduced. Construction is possible up to 25 to 60m long compared to the span.

1A and 1B are side views illustrating a connection structure of a conventional PSC beam bridge end. FIG. 1A is a state in which a PSC beam 6 is simply mounted on a bridge 2, and FIG. 1B is a PSC beam 6. It is a state where the concrete 7 was poured in between and upper part, and it was made continuous. FIG. 2 is an enlarged view of portion A of FIG. 1B in order to show the connection structure of the conventional PSC beam bridge end in detail.

As shown in the drawing, the conventional PSC beam bridge is provided with two feet 4 on top of the pre-built bridge 2 and the PSC beam 6 is mounted on each of the feet 4, and then the PSC beam ( The bottom surface of 6) and the top surface of the base 4 were bound together by welding or bolting, and concrete was poured between the neighboring PSC beams 6 to continuously continually PSC beams.

As described above, the conventional PSC beam bridge that simply pours concrete between two PSC beams 6 and continually has a problem in that safety is poor in continuity due to a slight poor bonding force.

In addition, the conventional PSC beam bridge is provided with two feet (4) on the top of the bridge (2), the cross section of the top of the bridge (2) must be large in order to install these feet (4) only causes an increase in construction cost Rather, there was a problem of poor aesthetic quality.

Accordingly, the present invention was developed to solve the problems of the prior art in connecting the PSC beam end when constructing the PSC beam bridge, it is installed on the two PSC beam end facing the PSC beam end connection bracket made of steel By making the PSC beam ends continuous with each other, it is an object to maintain the continuity of the PSC beam bridges and to further improve the safety.

Further, an object of the present invention is to reduce the number of bridge permanent supports provided in a pier during the end sequencing operation of the PSC beam, and to eliminate the need for temporary supports or auxiliary supports.

Figure 1a and Figure 1b is a side view showing the connection structure of the conventional PSC beam bridge end, Figure 1a is a state in which the PSC beam is mounted on the bridge, Figure 1b is placed between the mounted PSC beam and the concrete is continuous It is a state.

FIG. 2 is an enlarged view of portion A of FIG. 1B.

Figure 3a is a perspective view showing a bracket for connecting the PSC beam end in accordance with the present invention, Figure 3b is a perspective view schematically showing the shape that the bracket is coupled to one end of the PSC beam, Figure 3c is shown in Figure 3b Side view of a PSC beam.

FIG. 4A is a schematic view showing a shape in which a PSC beam having a PSC beam end connection bracket shown in FIG. 3A coupled to one end thereof is mounted on a piers, and FIG. 4B shows an end of a neighboring PSC beam inserted into the bracket. 4C is a side view illustrating a state in which end portions of neighboring PSC beams are inserted into the bracket, FIG. 4D is a cross-sectional view taken along the line BB of FIG. 4C, and FIG. 4E is a view similar to FIG. 4D. It is sectional drawing in which concrete is poured between both PSC beams.

5 is a side view showing a shape in which a steel wire is installed on top of a PSC beam connected according to the present invention.

* Explanation of Signs of Major Parts of Drawings *

2: pier 3: bridge permanent support

10: PSC beam 20: bracket

21: bottom plate 21a: rib

22: vertical side wall 22a: stud

In order to achieve the above object, in the present invention, a PSC beam end connection bracket which is provided at both ends of the PSC beam constituting the PSC beam bridge to connect and continually connect both PSC beams, the brackets are both prestressed concrete beams A bottom plate on which an end bottom surface of the bottom plate is placed, and a vertical side plate integrally provided upright on both sides of the bottom plate; A plurality of studs are formed on one side inner surface of the vertical side plate to be integrally coupled to both side PSC beams; The upper surface of the bottom plate is provided with a bracket for connecting the PSC beam end, characterized in that a plurality of vertical reinforcing ribs are formed to reinforce the bottom plate.

In addition, the present invention provides a PSC beam bridge formed by successive PSC beams on both sides by the above-described PSC beam end connection brackets. Specifically, the PSC beam bridge according to the present invention includes a bottom plate and a bottom plate. It has a vertical side plate that is integrally provided vertically on both sides and a plurality of studs are formed on one side inner surface of the vertical side plate, and a plurality of vertical reinforcing ribs are formed on the top surface of the bottom plate to reinforce the bottom plate. Steel brackets are integrally coupled to the ends of the prestressed concrete beams on each side of the bridge, each end of one of the prestressed concrete beams so that the studs of the steel brackets are embedded in one of the prestressed concrete beams. Is placed on one side of the other side of the prestressed concrete beam Connecting steels are integrally provided at both sides, and an end of the other prestressed concrete beam is placed on the other side of the steel bracket to be joined by welding the end side of the steel bracket and the connecting steel; A concrete PSC beam bridge is provided between the two side PSC beams and between the one side PSC beam and the bracket so that both side PSC beams are integrally connected to each other.

In addition, in the present invention, as a sequencing method of the PSC beams on both sides of the PSC beam bridge, a bottom plate and a vertical side plate which are vertically vertically provided on both sides of the bottom plate and integrally provided are provided on the inner surface of the vertical side plate. A step of manufacturing a single side PSC beam by having a plurality of studs and a steel bracket having a plurality of vertical reinforcing ribs formed on the top surface of the bottom plate to reinforce the bottom plate, so that the stud is embedded in one side of the PSC beam ; Lifting the one side PSC beam coupled to the end of the bracket and mounting it on a bridge permanent support installed on an upper portion of the bridge; Connecting both ends of the other side of the prestressed concrete beam to be connected to the one side of the prestressed concrete beam by connecting the connecting steels integrally with each other, and placing the other side of the prestressed concrete beam in the open one side of the bracket; Welding and connecting the connecting steel and the bracket of the other prestressed concrete beam; And placing concrete between the space between the other side PSC beam and the vertical sidewall of the bracket and the space between the two side PSC beams to integrally combine the brackets with the other PSC beams and to integrate and continually integrate both PSC beams. Provided is a sequencing method of both PSC beams of the PSC beam bridge, comprising a.

According to the present invention as described above, since the bracket is used for the end continuity of both PSC beams, only one bridge permanent support may be installed on the top of the bridge. Therefore, the space required for placing the bridge permanent support is reduced, so that the cross section of the bridge can be reduced as compared with the conventional case, and construction cost can be reduced. In particular, it is possible to improve the economics of bridge construction by reducing the number of expensive bridge permanent supports. In particular, since only one bridge permanent support is installed in the upper part of the bridge, the cross section of the PSC beam can be reduced, thereby reducing the height of the bridge, thereby making the span of the PSC beam bridge longer. In addition, in the present invention, since both PSC beams are not simply connected to concrete, but both PSC beams are connected by a bracket of steel integrally connected to each PSC beam, the connection strength of the beam is excellent and substantially A perfect beam can be achieved.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3a is a perspective view showing a bracket 20 for PSC beam end connection according to the present invention, Figure 3b schematically shows a shape in which the bracket 20 is coupled to one end of the PSC beam (10). 3C is a side view of the PSC beam 10 shown in FIG. 3B.

As shown in the figure, the bracket 20 according to the present invention has a shape in which three sides are open, and has a bottom plate 21 and two vertical side plates 22 vertically upright on both sides. .

The interval between the width of the bottom plate 21 and the vertical side plate 22 corresponds to the width of the PSC beam 10, so that the end of the PSC beam 10 can be easily placed on the bottom plate 21. It is preferable that the distance between the bottom plate 21 and the vertical side plate 22 is greater than the width of the PSC beam 10.

A plurality of studs 22a protrude from inner surfaces of both vertical side plates 22 of the bracket 20 to increase coupling force with the PSC beam 10 on one side when concrete is placed. The stud 22a is formed only on one side at the center of the vertical side plate 22. The reason is described later.

On the upper surface of one side of the bottom plate 21, a plurality of reinforcing ribs 21a, which are erected upwards at their intermediate points, are formed. As described below, the reinforcing rib 21a is deformed by the load when the bottom plate 21 is deformed by the load when the bracket 20 is coupled to one end of the PSC beam 10. To prevent it.

As shown in FIG. 3B, the bracket 20 according to the present invention is integrally coupled to one end thereof in the manufacture of one side PSC beam 10. That is, when manufacturing one side PSC beam 10, the end of the PSC beam 10 is placed in the bracket 20 so that the end of the end is approximately in the center of the bracket 20 in advance, and the concrete is poured into the bracket ( The PSC beam 10 is manufactured in a state in which 20) is integrally coupled to the end thereof. A stud 22a is formed on one side of the vertical side plate 22 of the bracket 20 so that the bracket 20 is integrally coupled to the end of the PSC beam 10, and the stud 22a is integrally manufactured. Since it is formed only where the end of the PSC beam 10 is located, as shown in Figure 3a, it exists only on one side when viewed from the center of the vertical side plate (22). Thus, no studs 22a are formed where the ends of the connected PSC beams 10 'are placed.

On the other hand, the connecting steel plate 23 is integrally attached to both sides of the end of the other PSC beam 10 'to be placed on one side of the bracket 20. A stud (not shown) is also protruded inside the connecting steel sheet 24, so that the connecting steel sheet 24 is integrally formed at both ends of the PSC beam 10 'at the time of manufacturing the connected PSC beam 10'. Combined.

Next, the connection structure of the PSC beam bridge end using the PSC beam end connection bracket of this invention is demonstrated.

FIG. 4A shows a shape in which the PSC beam 10 having the PSC beam end connection bracket 20 shown in FIG. 3A coupled to one end thereof is mounted on the piers 2. As shown in FIG. 4A, after the permanent support 3 is installed on the pier 2, the prefabricated PSC beam 10 is lifted and mounted on the pier, which is coupled to the end of the PSC beam 10. The bracket 20 is mounted on the PSC beam 10 so that the center of the permanent support (3).

At this time, the end of the PSC beam 10 is pressed only to one side of the bracket 20, the eccentric load acts on the bottom plate 21 of the bracket 20, a plurality of perpendicular to the bottom plate 21 When the ribs 21a are formed, the bottom plate 21 is reinforced by the ribs 21a to prevent the bottom plate 21 from being deformed due to such an eccentric load.

Of course, as described above, after the bracket 20 is integrally mounted at the end of the one side PSC beam 10, the bracket is first lifted and mounted on the bridge permanent support 3, in addition to the method of mounting the bracket 20 first. After mounting the bridge 20 on the bridge permanent support (3), it is also possible to install the formwork for the production of one side PSC beam 10 to manufacture the one side PSC beam 10 on the bridge. That is, in addition to the method of prefabricating one side PSC beam 10, it is also possible to cast concrete directly on site.

After mounting the PSC beam 10 having the bracket 20 coupled to the end on the bridge permanent support 3 of the bridge 2 as above, the neighboring PSC beam 10 'is lifted and the end is lifted. Insert into bracket 20 to integrate. In FIG. 4B, a state in which an end of the neighboring PSC beam 10 ′ is inserted into the bracket 20 is shown in perspective view, FIG. 4C is a side view illustrating insertion, and FIG. 4D in FIG. 4C. A cross section along line BB is shown.

As shown in the figure, since the ribs 21a are formed on the bottom plate 21 of the bracket 20, the ends of the neighboring PSC beams 10 'are provided at the ends of the PSC beams 10 already installed. It is located at a predetermined interval.

When the end of the neighboring PSC beam (10 ') is located in the bracket 20, the end side surface of the bracket 20 and the connecting steel plate 23 of the PSC beam (10') abut each other, the connection steel sheet 23 ) And the end side of the bracket 20 are integrally connected to each other by welding.

As described above, after the bracket 20 is placed on the permanent support 3 of the piers 2 and the PSC beams 10 and 10 'are inserted and mounted on both sides, as in the conventional method, both sides The concrete 11 is poured into a space between the PSC beams 10 and 10 'and a space between the bracket 20 and the neighboring PSC beam 10' so that both PSC beams 10 and 10 'and the bracket ( By integrating 20, both PSC beams 10 and 10 'are continuous with each other. FIG. 4E is a view similar to FIG. 4D, in which the concrete 11 is poured between the two PSC beams 10, 10 '.

As described above, when the protruding member 23 is buried in both sides of the neighboring PSC beam 10 'in advance, the concrete is disposed between the neighboring PSC beam 10' and both vertical side plates 22 of the bracket 20. When the 11 is poured, since the protruding member 23 is embedded in the poured concrete 11, the bracket 20 and the neighboring PSC beam 10 'are integrally formed.

After the two PSC beams 10 and 10 'are continuous with each other by pouring concrete 11, steel wires may be inserted into the two PSC beams 10 and 10' as in the conventional method and tensioned if necessary. In some cases, as shown in FIG. 5, after the wire fixing devices 25 and 25 ′ are respectively installed on the PSC beams 10 and 10 ′, the wires 26 are tensioned to apply a prestress force. It can also be reinforced.

As described above, in the present invention, since the PSC beams 10 and 10 'on both sides are integrated with each other by the bracket 20, the upper structure of the bridge composed of both PSC beams 10 and 10' is continuously formed as a whole.

As described above, in the present invention, one side PSC beam is manufactured with the brackets pre-installed at the end of one side PSC beam, and the one side PSC beam is placed on one bridge permanent support on the bridge and then the other side PSC. By integrating the beam with the bracket, it is possible to continually continually bilateral PSC beams on one bridge permanent support.

Thus, in the present invention, since the bracket is used for end continuation of both PSC beams, only one bridge permanent support may be installed on the upper part of the bridge. That is, only one bridge permanent support capable of supporting the bracket is required on the bridge.

As only one bridge permanent support is used, the space required for placing the bridge permanent support is reduced, so that the cross section of the bridge can be reduced as compared with the conventional case, and construction cost can be reduced. In particular, since the number of expensive bridge permanent bearings can be reduced, it is possible to improve the economics of bridge construction.

In addition, since the present invention is provided with only one support on the top of the piers can be reduced in cross-section of the PSC beam to reduce the height of the bridge can be made longer span of the PSC beam bridge.

In addition, in the present invention, not only the two PSC beams are simply connected to concrete, but also the two PSC beams are connected by a bracket of steel integrally connected to each PSC beam, so that the beam connection strength is excellent and substantially A perfect beam can be achieved.

Claims (3)

A prestressed concrete beam end connection bracket installed at both ends of the prestressed concrete beams constituting the prestressed concrete beam bridge to connect and continually connect both prestressed concrete beams, The bracket includes a bottom plate 21 on which the end bottom surfaces of both side prestressed concrete beams 10 and 10 'are placed, and a vertical side plate integrally provided upright on both sides of the bottom plate 21 ( 22); A plurality of studs 22a are formed on one inner surface of the vertical side plate 22 to be integrally coupled to the prestressed concrete beam 10 on one side; Prestressed concrete beam end connection brackets, characterized in that a plurality of vertical reinforcing ribs (21a) is formed on the upper surface of the bottom plate (21) to reinforce the bottom plate (21). A prestressed concrete beam bridge formed by successive prestressed concrete beams, It has a bottom plate 21 and a vertical side plate 22 integrally provided vertically upright on both sides of the bottom plate 21, a plurality of studs (22a) on one inner surface of the vertical side plate 22 Formed on the upper surface of the bottom plate 21, the steel brackets 20 having a plurality of vertical reinforcing ribs 21a formed to reinforce the bottom plate 21, respectively, the prestressed concrete on both sides of the bridge. Integrally coupled to the ends of the beams 10, 10 ′, The end of one side prestressed concrete beam 10 is placed on one side of the steel bracket 20 so that the stud 22a of the steel bracket 20 is embedded in one side of the prestressed concrete beam 10, and the other side The connecting steel 23 is integrally installed on both sides of the prestressed concrete beam 10 ', so that an end of the other prestressed concrete beam 10' is placed on the other side of the steel bracket 20 so that the steel bracket An end side of the 20 and the connecting steel 23 are coupled; Concrete is poured between the two prestressed concrete beams 10 and 10 'and between the one prestressed concrete beam 10' and the bracket 20 so that both prestressed concrete beams 10 and 10 'are integrated with each other. Prestressed concrete beam bridge, characterized in that connected to. As a continuous method of both sides of the prestressed concrete beams of the prestressed concrete beam bridge, It has a bottom plate 21 and a vertical side plate 22 integrally provided vertically upright on both sides of the bottom plate 21, a plurality of studs (22a) on one inner surface of the vertical side plate 22 The steel bracket 20 having a plurality of vertical reinforcing ribs 21a is formed on the top surface of the bottom plate 21 to reinforce the bottom plate 21, and the stud 22a has one side of the prestressed concrete. Manufacturing one side of the prestressed concrete beam 10 by being embedded in the beam 10; Lifting the one side prestressed concrete beam 10 coupled to the end of the bracket 20 and mounting it on the bridge permanent support 3 installed on the top of the pier; On both sides of the ends of the other prestressed concrete beam 10 'to be connected to the one side prestressed concrete beam 10, the connecting steel 23 is integrally manufactured, respectively, and the other prestressed concrete beam 10' is manufactured. Positioning the inside of the open side of the bracket (20); Welding and connecting the connecting steel 23 and the bracket 20 of the other prestressed concrete beam 10 'to each other; And The concrete is placed in the space between the other prestressed concrete beam 10 'and the vertical side wall 22 of the bracket 20 and the space between the two prestressed concrete beams 10 and 10'. 20) both sides of the prestressed concrete beam bridge, comprising the step of integrally combining the other prestressed concrete beam (10 ') and the two sides of the prestressed concrete beam (10, 10') to be integrated. Continuous process of prestressed concrete beams.