KR100538410B1 - The connecting device for pre-cast girder and installation method applied the connecting device - Google Patents

Abstract

The present invention relates to a girder sequencing device and an installation method using the same.

The present invention provides a girder support frame, which is seated on an upper surface of a ground structure such as a pier, and is provided with a seating surface having an inclined angle downward so as to support seating ends of girders installed to correspond to both sides of the upper surface.

The girder support frame can reduce the number of bridge bearings in half compared to the conventional one, and thus, it is much more advantageous to secure the podium distance of the bearings, thereby reducing the construction cost and increasing the stability of the bearings. The integrated bridge support combined with the girder support frame is fully restrained by the sliding phenomenon to ensure the stability of the constant support and accurate seismic performance in the event of an earthquake, and the girder support frame is a separate lifting device to raise the bridge for maintenance during use. Or it is possible to jack up using the impression jack on the girders frame without expanding the cross-section, it will have a feature that can significantly reduce the maintenance cost and ensure the work stability.

Description

Girder serializer and installation method using the same {The Connecting Device for Pre-cast Girder and Installation Method Applied the Connecting Device}

The present invention relates to a girder continuity device, and more particularly, to a girder continuity device and a method for providing a girder support frame so that the girder supporting the bridge deck structure can be assembled easily and stably on the upper surface of the pier. will be.

In general, the girder plays a role of supporting the bridge deck structure between the bridge deck and the bridge. There are various kinds of girder such as PSC BEAM, IPC-GIRDER, and PRE-FLEX BEAM. This type of girder is called precast girder, and the continuity of previous precast girders is mostly continuous only in the slab located in the upper part of the girder, and the structural problems such as cracking of the slab and dropping of fillers in the sequential part are not possible because the girder is not actually continuous. It is occurring. In addition, since the girder is separated in such a sequential portion, the bridge support supporting it cannot be arranged in two rows, thus increasing the number of supports. The two-row arrangement of the bridge support has a problem that the cross section of the bridge has to be enlarged to secure the edge distance of the support in the direction of the bridge, and the unbalance of the force of the bridge support due to the step of the precast girders facing each other and the horizontal load distribution during the earthquake The effect is that the effect is significantly reduced.

In the case of raising the bridge for maintenance of the bridge support in use, the existing precast girder has to install a separate lifting device or enlarge the cross section of the bridge to raise the bridge. Structural problems and bridge edges are often broken and lead to large accidents.

The sequencing method of precast girders that is currently applied has a considerable problem in terms of structural problems as well as stability and economic loss in maintenance.

Accordingly, the present invention was devised to solve the above problems, and an object of the present invention is to simply and continuously install and secure the girder continuously through the girder support frame provided on the upper surface of the pier, so that the precast girder is structurally completely continuous. In addition, by reducing the bridge support arrangement of the previous two rows to one row, 50% of the support volume is reduced, and the reduction of the cross section of the bridge greatly reduces the bearing cost by enormous economic cost reduction and integrated support in case of earthquake and earthquake. Function and stability can be maximized, and in the future, the maintenance of bridges can be achieved by using girder support frame without any additional device, which can drastically reduce maintenance cost and safe and simple maintenance.

The girder support frame of the present invention is formed by the inclined seating surface with the girder to maximize the effect of the pressure of the seating surface to completely suppress the upper slab crack phenomenon and the breakage of the edge of the girder support position occurring in the previous method Thus, the structural stability and durability of the entire bridge is to be sufficiently secured.

In order to achieve the above object, the present invention is seated on the upper surface of the ground structure, such as bridge pier, and the lower width than the upper width so that the end edges of the girders that are installed to correspond to each other on both sides of the girder can be seated and supported with a predetermined gap, respectively. It is characterized by providing a girder support frame having an inclined surface having a downward inclination angle that is gradually formed to be large.

Here, both inclined surfaces of the girder support frame will be able to form a vertical end and a horizontal end in a continuous repeating step shape along the inclination angle.

Here, the inclined surfaces formed on both sides of the girder support frame, the vertical end upward from the upper end of the inclined surface and the horizontal end is formed in the girder direction from the lower end of the inclined surface so that the inclined surfaces formed on both sides of the girder support frame can support the corresponding vertical and horizontal surfaces of the girder. It will be possible.

In addition, the girder support frame is formed of concrete formwork so that the strength reinforcing beam is formed integrally therein.

In addition, the upper support member is formed on both sides of the upper surface of the girder support frame to further protrude from the left and right to prevent the girder from falling or falling off.

In addition, the guide hole is further formed to connect and fix the girder through a steel bar or the like to the upper support member formed on the girder support frame.

In addition, it may be desirable to allow both ends of the strength reinforcing beam to protrude a predetermined width between the girder support frames adjacent to each other, and to allow the connection bracket to be connected and fixed to the protruding portion.

In addition, a sole plate may be further provided between the bottom surface of the girder supporting frame and the upper surface of the bridge so as to consider the installation of the integrated bridge support and the longitudinal gradient of the bridge. It would be desirable to arrange more than ten columns.

The gap between the upper support member and the girder of the girder support frame to be finished with a mortar or epoxy filler having excellent acupressure strength so as to sufficiently resist the pulling force during the bridge lifting operation using the girder support frame.

Each segment of the girder support frame manufactured in the factory is to be formed to be inclined to support the side connection member to accommodate the vertical step generated between each segment in consideration of the cross-sectional gradient of the bridge at the site connection.

According to the above characteristics, the present invention provides a method for continuously installing a girder on an upper surface of a ground structure such as a pier, the manufacturing step of manufacturing a girder support frame segment through the formwork; A girder support frame seating step of seating and fixing the segments of the girder support frame to the bridge support on the upper surface of the ground structure such as the piers installed at predetermined intervals; Connecting the girder support frames to connect the respective girder support frame segments; A girder seating step of mounting girder on both inclined surfaces of the girder support frame; A step of fixing the girder to connect the steel bar and the like through the guide hole formed in the support member of the girder support frame to fix the girder to the girder support frame; Filling a high strength mortar or epoxy into a corresponding gap between the girder and the girder support frame; This is done by doing

Further, after the girder fixing step, the filling step of filling the high-strength filler in the gap between the girder and the upper support member is further performed.

In addition, each field joint of the girder support frame segment further performs a mortar filling step of forming a formwork to fill the mortar.

In addition, for maintaining the bridge support in the future, when the bridge is raised, the step of raising the bridge by placing the jack on the lower surface of the girder support frame on the left and right side of the bridge support is further performed.

Hereinafter, preferred embodiments of the girder sequencing device according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 7, the present invention is to provide a girder support frame 100 that is seated on the upper surface of the structure, such as the piers 700, and simultaneously seats and supports the corresponding ends of the girders (800,900).

The girder support frame 100 has sloped surfaces 110 and 120 that are inclined downward so as to support corresponding ends of the girders 800 and 900, respectively, on both sides. That is, the inclined surfaces 110 and 120 are formed at a gentle inclination angle, and the corresponding ends of the girders 800 and 900 slide on the inclined surfaces 110 and 120, and at this time, the girder 800 It is preferable that the seating end of 900 is formed with a rounding or chamfering angle as shown. The girder support frame 100 is formed of concrete through formwork and a strength reinforcing beam 200 is formed therein.

Here, although the inclined surfaces 110 and 120 are not shown, the girder 800 and 900 may be formed in a stepped shape in which the horizontal and vertical ends are continuously formed in the inclination angle direction so as to have a height difference. It will be possible.

In addition, both ends of the strength reinforcing beam 200 protrude outward from the concrete end of the girder support frame 100 by a predetermined width, and the ends of the protruding strength reinforcing beam 200 are connected to the bracket 210. ) 220 is to be fastened, this connection bracket 210, 220 is to be connected to the strength reinforcement beam 200 of the adjacent girder support frame 100.

In addition, the upper support members 140 and 150 protrude from the upper surface of the girder support frame 100 so as to prevent conduction or separation of left and right girders 800 and 900, and the upper support members 140 and 150. The guide hole 160 is formed to connect and fix the girder (800,900) through a steel bar (170).

In addition, a bridge bearing 500 is provided between the bottom surface of the girder support frame 100 and the pier upper surface.

In addition, the bottom plate of the girder support frame 100 is provided with a sole plate 230 that can consider the installation of the bridge support 500 and the longitudinal gradient of the bridge.

In addition, when the bridge is raised for maintenance of the bridge support 500 during future use, the jack jack 600 is located between the bottom of the girder support frame 100 and the top of the pier.

The girder sequencing device configured as described above, during the installation operation, first performs a manufacturing step of manufacturing the girder support frame 100 through the formwork, and bridges on the upper surface of the ground structure such as the piers 700 installed at predetermined intervals. Performing the step of mounting the girder support frame 100 for each seating and fixing the girder support frame 100 to the support 500, the girder 800 on both inclined surfaces 110, 120 of the girder support frame 100 in succession Perform a girder seating step of seating (900). Then, the steel rods 170 are connected to the guide holes 160 formed in the upper support members 140 and 150 of the girder support frame 100 so that the steel rods 170 girder the girders 800 and 900. Performing a girder fixing step to be fixed to the support frame 100, and also filling the high-strength mortar or epoxy in the gap 300 between the upper support member 140, 150 and the girder 800, 900 When the filling step of filling the mortar by using the formwork in the joint portion of each segment of the girder support frame 100 is performed in succession, the installation is completed.

Here, during the manufacturing step of the girder support frame 100 segment form the strength reinforcing beam 200 in the girder support frame 100 to be produced integrally, both ends of the strength reinforcing beam 200 is supported by the girder A predetermined section is further protruded from the end of the frame concrete, and the strength reinforcement beam 200 of the girder support frame 100 installed adjacent to the protruding strength reinforcement beam 200 is connected through the brackets 210 and 220. 8 or 9 show another embodiment of the girder continuity device according to the present invention, which is perpendicular to the upper and lower ends of the inclined surfaces 110 and 120 of the girder support frame 100, respectively. 180 and the horizontal end 190 are formed. That is, the vertical end 180 is formed to have a predetermined width upward from an upper end of the inclined surfaces 110 and 120 so that the inclined surfaces 110 and 120 are formed. Corresponding ends of the girders (800, 900) in close contact with The girders are in close contact with the inclined surfaces 110 and 120 so that the facings are in close contact with each other, and the horizontal ends 190 are formed in a bridge direction outward from the lower ends of the inclined surfaces 110 and 120. The bottom of the corresponding end of the (800) and (900) is to be seated slide.

Therefore, the girder sequencing device according to the present invention is structurally completely integrated with the precast girder through the girder support frame provided on the upper surface of the pier, so that there is no cracking of the upper slab or peeling off of the continuous filler, which has occurred previously. There is an effect that complete structural integration of the girder is possible. Since the bridge support is installed under the supporting girder frame, by reducing the two rows of bridge supports to one row, 50% reduction in the number of bridge supports and the cross section of the bridge can be achieved, resulting in huge economic cost savings for the bridge construction. In addition, the girder support frame, which is constructed together with the bridge support to support the girder, has the role of a cross beam installed for lateral distribution of the precast girder at the same time, so that a separate cross beam is not required, and the position of the girder support is at the bottom of the precast beam. Since it is located in the will have an excellent effect on the lateral distribution of the load compared to the cross beam installed on the top of the conventional girder.

The girder support frame is manufactured at the factory and assembled at the same time as the integrated bridge support in the field, so it is possible to shorten the air and minimize the manufacturing and construction errors.In the case of the conventional crossbeam, maintenance is not possible while easy maintenance of the girder support frame is possible. There is a possible effect.

Since a single row of bridge support is installed at the bottom of the girder support frame, there is no step difference and no slipping or lifting of the support, which ensures maximum stability of the support function at all times and earthquakes, and guarantees the accurate seismic performance required in the design. Will have the effect.

Maintenance of work and maintenance of bridges by using girder support frames without the need for such a separate device for maintenance of bearings with the greatest cost burden and accident risk due to separate steel raising device or cross section expansion in current bridge maintenance It will have the effect of reducing the cost of the jacket.

1,2,3 is shown as the girder support frame of the present invention

   1 is a perspective view

   2 is a plan view

   3 is a front view

4,5,6,7,8,9 show an embodiment of the present invention

   4 is an installation front view

   5 is an installation perspective view

   Fig. 6 is a perspective view of the installation connection in a plane

   7 is a perspective view of the installation connection stepped

8 is a perspective view of a state in which a girder is installed in a girder support frame according to another embodiment of the present invention (description of reference numerals in the drawings) 100: girder support frame 110, 120: inclined surface 140, 150: upper support member 180: vertical end 190: Horizontal stage 200: Strength reinforcing beam 800, 900: Girder

Claims (13)

delete An inclined surface having a downward inclination angle, which is seated on an upper surface of a ground structure such as a bridge pier, and has a lower width than an upper width, so that the end edges of the girders installed on both sides of the upper surface can be seated and supported with a predetermined gap. A girder sequencing device characterized by providing a formed girder support frame. The method of claim 2, Girder sequencing device characterized in that both inclined surfaces of the girder support frame to form a vertical end and a horizontal end in a continuous repeating step-type along the inclination angle. The method of claim 2, The inclined surfaces formed on both sides of the girder support frame have a vertical end upward from an upper end of the inclined surface and a horizontal end formed in the girder direction from the lower end of the inclined surface to support the corresponding vertical and horizontal surfaces of the girder. Girder serialization device characterized in that. The method according to any one of claims 2 to 4, The girder support frame is formed of concrete formwork and girder sequencing device, characterized in that the strength reinforcing beam is formed integrally therein. The method of claim 5, Both sides of the upper surface of the girder support frame, girder continuity device characterized in that the upper support member is further protruded to prevent the left and right fall or separation of the girder. The method of claim 6, Girder continuity device characterized in that the guide hole is further formed to connect the girder to the upper support member formed on the girder support frame through a steel bar or the like. The method of claim 5, Girder sequencing device characterized in that both ends of the strength reinforcing beam protrudes a predetermined width between the girder support frame adjacent to each other and the connection bracket can be fixed to the protrusion. The method of claim 8, A girder continuity device, characterized in that a sole plate is further provided between the bottom of the girder support frame and the upper surface of the bridge to allow the installation of an integrated bridge support and the longitudinal gradient of the bridge. The method of claim 9, Girder sequencing device characterized in that the bridge support is arranged in at least one row of the bridge traveling direction. A method of continuously installing a girder on an upper surface of a ground structure such as a piers, the method comprising: manufacturing a girder support frame through formwork; An integrated bridge support installation step seated on an upper surface of a ground structure such as a bridge in the same manner as a bridge girder spacing; A girder support frame seating step of seating and fixing each girder support frame at the same interval as the bridge support on the installed integral bridge support upper surface; A connection step of connecting the girder support frame to an adjacent girder support frame by using a connection bracket to a protruding portion; A girder seating step of mounting girder on both inclined surfaces of the girder support frame; A girder fixing step of fixing the girder to the girder support frame by connecting steel bars and the like through guide holes formed in the upper support member of the girder support frame; Filling step of filling the high-strength filler in the gap between the girder and the upper bracket; An installation method using a girder continuity device, characterized in that by performing a; injection step of attaching a mold of a predetermined shape to the girder support frame joint to inject mortar of the joint. The method of claim 11, Installation method using a girder continuity device, characterized in that by further performing the girder bracket fastening step for fixing the girder and the girder through the connection bracket after the girder fixing step. The method of claim 11, An installation method using a girder continuity device, characterized in that to raise the bridge using the girder support frame by further positioning the jacks on the left and right sides of the bridge support bridge bottom support.