KR102568981B1 - Composite Girder Structure using Precast Form and its Construction Method - Google Patents

Abstract

The present invention relates to a composite girder structure using a precast formwork and a construction method thereof.
For this purpose, in the composite girder structure using the precast formwork of the present invention, a composite girder formed by connecting a plurality of girder segments equipped with I-shaped steel and concrete blocks by a joint is installed on an abutment or pier formed for the construction of a bridge, , formed by installing precast formwork between adjacent composite girders in the width direction of the bridge.
Thus, the present invention can solve the difficulty of the formwork installation work caused by the low form height, and can more smoothly perform the work of forming the composite girder by arranging and connecting the girder segments on the abutments or piers.

Description

Composite Girder Structure using Precast Form and its Construction Method

The present invention relates to a composite girder structure used for the construction of small-scale bridges and a construction method thereof, and more particularly, to a low shape by installing a precast formwork between adjacent composite girders arranged spaced apart from each other in the width direction of the bridge. Using precast formwork, which solves the difficulty of formwork installation work caused by high temperatures and improves the joint structure of girder segments connected to each other to form a composite girder, enabling the construction of a structurally stable bridge without the formation of temporary supports. It is about a composite girder structure.

The steel composite girder is an integration of steel and concrete, and is usually formed by filling the inside of a steel box with concrete, but as shown in FIG. A construction method has been proposed in which a steel composite girder is manufactured by pouring concrete, the steel composite girder is placed at the site, and cast-in-place concrete is installed on top of the steel composite girder.

In constructing a bridge using such a steel composite girder equipped with I-shaped steel and concrete blocks, a plurality of steel composite girders prepared in advance are placed on the upper part of the abutment or pier, but the steel composite girder extends in the longitudinal direction of the bridge. and a plurality of them are arranged so as to be spaced apart from each other in the width direction of the bridge, and a formwork for forming a bridge deck is installed between adjacent steel composite girders that have been placed.

In installing the formwork between adjacent steel composite girders, conventionally, each plate constituting each part of the formwork is transported to the installation location, and the transported plate materials are sequentially installed on the composite girder or surrounding structures to be assembled. completed the formwork.

However, the steel composite girder using I-shaped steel has a low mold height, so it is difficult to secure a working space to install the formwork by on-site assembly method. In particular, there is a problem in that a lot of manpower and time are required for the installation work of the formwork, and there is a great risk of accidents due to the unstable posture of the worker.

On the other hand, in constructing a bridge using a steel composite girder, when a long steel composite girder is required, such as a continuous bridge, a plurality of girder segments manufactured to a predetermined length are connected to each other to manufacture a composite girder to the required length, will use

More specifically, the girder segment is made by pouring concrete on the lower flange of the I-shaped steel, and the end of the I-shaped steel is made of concrete to protrude from the block by a certain length. In connecting adjacent girder segments, Adjacent girder segments are arranged in a line structure so that the protruding steel materials at the ends of the adjacent girder segments face each other, and a gusset plate is installed at the joint of the adjacent girder segments to bind and fix the adjacent girder segments together. .

As a prior art document related to such a composite girder, Korean Patent Publication No. 10-2008-0008841 (published on January 24, 2008, hereinafter referred to as 'prior art document') has been proposed. As shown in FIG. 1, the composite girder according to the prior art document connects the lower flanges 13 on the end side of the steel I-girders 10 facing each other by welding, and then the steel I-girders 10 facing each other. ) Attach the steel plate 20 to the connection between the upper flange 11 and the web 12 of the end side, and fasten the steel plate 20 to the I-girder 10 with bolts so that the upper flange 11 and the web (12) are connected and fixed to each other.

However, as in the prior art literature, when the ends of the I-girders 10 are connected to each other using the steel plate 20, the two I-girders 10 move in different directions to the steel plate 20. When shear force is applied, there is a high possibility that the steel plate 20 will be damaged due to the structural characteristics of the steel plate 20 made of a flat plate structure, and if the steel plate 20 is damaged, the two I-girders 10 The connection structure may collapse, resulting in serious accidents such as bridge collapse.

In addition, in order to connect the ends of the adjacent I-girders 10 by welding and the steel plate 20 as described above, the ends of the I-girders 10 disposed adjacent to each other before the connection work must maintain abutted state without sagging. should be able to Accordingly, the connection work of the I-girder 10 could be limitedly performed only in a place where a support point such as a temporary cradle can be formed.

Publication No. 10-2008-0008841 (published on January 24, 2008)

The present invention has been made to solve the above problems, and an object of the present invention is to provide a composite girder structure using a precast formwork so that a formwork can be easily installed between adjacent composite girders.

Another object of the present invention is to provide a composite girder structure using a precast form that allows the width of the precast form to be adjusted in consideration of design changes or construction errors of the composite girder according to site conditions.

Another object of the present invention is to provide a composite girder structure that can easily connect adjacent girder segments without a support point such as a temporary stand by improving the joint connection structure between girder segments constituting the composite girder.

Another object of the present invention is to provide a composite girder structure with improved convenience in connecting joints between girder segments.

The composite girder structure using the precast formwork of the present invention, which achieves the above object and eliminates the conventional defects, consists of an upper flange 311, a lower flange 312 and a web 313. A girder segment 300 in which a concrete block 320 is formed on the lower flange 312 of the I-shaped steel 310 and both ends of the I-shaped steel 310 in the longitudinal direction protrude from the concrete block 320; Composite girder 100 with a plurality of girder segments 300 by being installed in a joint to bind and fix the I-shaped steel 310 ends of adjacent girder segments 300 to each other by being arranged in a line structure to extend in the longitudinal direction of the bridge. ) to form a joint means 400; And it is installed to connect the two composite girders 100 between the two composite girders 100 formed to be spaced apart from each other in the width direction of the bridge to form a pouring space for forming a bridge floor plate, and concrete is poured in the pouring space. Including, the precast formwork 200, the first panel portion 210 is seated on the concrete block 320 of the one side composite girder 100, and the composite girder The I-shaped steel material 310 of (100) is spaced apart from the web 313 to form a pouring space around the web 313, and the second panel part 220 faces the first panel part 210 while being spaced apart. It is located in the place where it is seated on the concrete block 320 of the other composite girder 100, and is spaced apart from the web 313 of the I-shaped steel 310 of the composite girder 100 to form a pouring space around the web 313, , The first panel part 210 and the second panel part 220 are each fixed to the web 313 by the fastening mechanism 240, and the loop part 230 is the upper end of the first panel part 210. and the upper end of the second panel part 220 are connected to each other, and the tubular support 241 of the fastening mechanism 240 has a thread formed on the inner circumferential surface of the outer end so that the outer end is the first panel part 210 or the second It is closely attached to the panel portion 220, the inner end is fixed to the web 313 of the I-shaped steel member 310, and the fastening bolt 242 secures the first panel portion 210 or the second panel portion 220. It is characterized in that the panel portion is fixed to the tubular support 241 while passing through and fastened to the outer end of the tubular support 241 .

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Particularly, the fastening mechanism 240 includes a reinforcing ring 243 installed so that a part of it protrudes from the upper surface of the loop part 230; A connecting bar 244 installed to connect the upper ends of the adjacent girder segments 300 in the width direction of the bridge; and a connecting line 245 connecting the reinforcing ring 243 and the connecting bar 244 so that the loop portion 230 is supported by the connecting bar 244 .

On the other hand, in the composite girder structure using the precast formwork according to another embodiment of the present invention, the lower flange 312 of the I-shaped steel material 310 composed of the upper flange 311, the lower flange 312, and the web 313 A girder segment 300 in which a concrete block 320 is formed, and both ends in the longitudinal direction of the I-shaped steel member 310 protrude from the concrete block 320; Composite girder 100 with a plurality of girder segments 300 by being installed in a joint to bind and fix the I-shaped steel 310 ends of adjacent girder segments 300 to each other by being arranged in a line structure to extend in the longitudinal direction of the bridge. ) to form a joint means 400; And it is installed to connect the two composite girders 100 between the two composite girders 100 formed to be spaced apart from each other in the width direction of the bridge to form a pouring space for forming a bridge floor plate, and concrete is poured in the pouring space. Including, the precast formwork 200, the first panel portion 210 is seated on the concrete block 320 of the one side composite girder 100, and the composite girder The I-shaped steel material 310 of (100) is spaced apart from the web 313 to form a pouring space around the web 313, but is fixed to the web 313 by the fastening mechanism 240, and the second panel portion 220 ) is located at a place facing the first panel part 210 while being spaced apart, and is seated on the concrete block 320 of the other composite girder 100, and the I-shaped steel material 310 web 313 of the composite girder 100 ) to form a pouring space around the web 313, but is fixed to the web 313 by the fastening mechanism 240, and the loop part 230 connects the upper end of the first panel part 210 and the second The upper ends of the panel portion 220 are connected to each other, and the loop portion 230 has a structure integral to the first panel portion 210, so that the first area 231 is formed and integrally formed with the second panel portion 220. The second area 232 is formed in the structure of, and the first panel corresponds to the distance between adjacent composite girders 100 so that the control block 233 connects the first area 231 and the second area 232. The distance between the part 210 and the second panel part 220 is adjusted, but the control block 233 is formed on one side of the first control groove 233a into which the end of the first panel part 210 is inserted. And, the second control groove 233b into which the end of the second panel part 220 is inserted is formed on the other side, and the end of the panel part 220 is inserted into the control groove by adjusting the depth of the first panel part 210 and It is characterized in that it is made to adjust the distance between the second panel portion 220.

In addition, in the composite girder structure using a precast formwork according to another embodiment of the present invention, the lower flange 312 of the I-shaped steel material 310 composed of the upper flange 311, the lower flange 312, and the web 313 A girder segment 300 in which a concrete block 320 is formed and both ends in the longitudinal direction of the I-shaped steel 310 protrude from the concrete block 320; Composite girder 100 with a plurality of girder segments 300 by being installed in a joint to bind and fix the I-shaped steel 310 ends of adjacent girder segments 300 to each other by being arranged in a line structure to extend in the longitudinal direction of the bridge. ) to form a joint means 400; And it is installed to connect the two composite girders 100 between the two composite girders 100 formed to be spaced apart from each other in the width direction of the bridge to form a pouring space for forming a bridge floor plate, and concrete is poured in the pouring space. Including, the joint means 400 has a supporting protrusion 430 protruding from one end of the girder segment 300, and the other side of the girder segment 300 A mounting protrusion 440 protrudes from the end and is seated on the support protrusion 430 of the other girder segment 300, and a fixing bracket 450 is installed at one end of the girder segment 300, and a hinge at the other end The bracket 460 is installed to rotate around the hinge shaft 461, and a locking member 462 is provided so that the outer end is coupled to the fixing bracket 450.

In particular, the supporting protrusion 430 is formed by protruding the lower half of the I-shaped steel 310 in the longitudinal direction and installing a supporting plate 431 on the upper end, and the holding protrusion 440 is formed by I-shaped steel 310 It may be formed by protruding the upper half in the longitudinal direction and installing a mounting plate 441 seated on the support plate 431 at the lower end.

Furthermore, the joint means 400 protrudes in the width direction of the girder segment 300 from the fixing piece 411 fixed to the web 313 of the I-shaped steel 310 and the fixing piece 411. An angle plate 410 made of the formed fastening piece 412 and installed at the joint of the web 313 to fasten the web 313 of the adjacent girder segment 300; and a flat plate 420 installed at a joint of the upper flange 311 to fasten the upper flange 311 of the adjacent girder segment 300.

In addition, the reinforcing bar 321 and the sheath pipe 322 inside the concrete block 320 protrude from the end of the concrete block 320 in the longitudinal direction of the girder segment 300, and protrude from the adjacent girder segment 300. The reinforcing bars 321 are coupled by the reinforcing bar coupler 510, and the adjacent girders are connected by the connecting concrete blocks 530 formed by installing formwork between the concrete blocks 320 of the adjacent girder segments 300 and placing and curing the concrete. The concrete blocks 320 of the segments 300 may be connected.

On the other hand, in the construction method of the composite girder structure using the precast formwork of the present invention, the composite girder structure using the girder segment 300 formed by forming the concrete block 320 on the lower flange 312 of the I-shaped steel 310 Regarding the construction method, one end of the girder segment 300 is placed so as to face another adjacent girder segment 300 in a state where the other end of the girder segment 300 is supported on an abutment or pier, but at one end of the girder segment 300 A segment mounting step (S10) of allowing the protruding protruding protrusion 440 to be seated on the supporting protrusion 430 protruding from another girder segment 300; A segment that binds the locking member 462 of the hinge bracket 460 installed on the upper flange 311 of the other girder segment 300 to the fixing bracket 450 installed on one side of the upper flange 311 of the girder segment 300 Binding step (S20); A reinforcing bar connection step (S30) of connecting the reinforcing bar 321 protruding from the concrete block 320 of the adjacent girder segment 300 with the reinforcing bar coupler 510; Formwork is installed between adjacent girder segments 300, and concrete is poured and cured to form a connected concrete block 530 connecting the concrete blocks 320 of the adjacent girder segments 300 (S40). ); A precast formwork 200 including a first panel portion 210, a second panel portion 220, and a loop portion 230 is disposed between adjacent girder segments 300 in the width direction of the bridge, but the first panel A plurality of precast forms ( 200) along the longitudinal direction of the girder segments 300; a formwork arrangement step (S50); and a formwork fixing step (S60) of fixing the precast formwork 200 to the girder segments 300.

In addition, in the formwork fixing step (S60), the first panel part 210 or the second panel part 220 is disposed so as to come into contact with the tubular support 241 coupled to the I-shaped steel material 310, and the fastening bolt A panel unit fastening step of fastening 242 to the tubular support 241 (S61); A connecting bar installation step of installing a connecting bar 244 connecting the upper end of the adjacent girder segments 300 in the width direction of the bridge (S62); And a connection line installation step (S63) of connecting the reinforcing ring 243 and the connection bar 244 provided in the loop part 230 of the precast formwork 200 with a connection line 245; may include.

According to the composite girder structure using the precast formwork of the present invention, the formwork can be installed by a simple assembly method in which the precast formwork is transported to the site, placed between adjacent composite girders, and fixed with a fastening mechanism. It is possible to promote workability by omitting the process of assembling each part of the formwork in a narrow work space due to the high temperature.

In addition, since the precast formwork including the loop part divided into the first area, the second area, and the control block can adjust the distance between the first panel part and the second panel part, an error occurs during design change or installation process according to site conditions. Therefore, even if the distance between adjacent composite girders is changed, the precast formwork can be installed while allowing this.

In particular, a composite girder formed by connecting a plurality of girder segments by a joint means can realize high rigidity at the joint due to the stable joint structure provided by the joint means, so it is possible to implement a structurally more stable bridge.

Furthermore, the mounting protrusion formed on the girder segment is mounted so that it is seated on the supporting protrusion formed on the other girder segment, and the girder segments disposed adjacent to each other are temporarily coupled through the operation of binding the locking member of the hinge bracket to the fixing bracket. , Connecting work of girder segments can be performed without a support point such as a temporary stand supporting the end of the girder segment from the bottom, so that workability can be promoted.

In addition, it is possible to construct a structurally more stable joint by bonding the adjacent girder segments together by fastening the upper flange of the adjacent girder segment using a flat plate and fastening the web of the adjacent girder segment using an angle plate. do.

In addition, since the connecting concrete blocks constructed between adjacent girder segments connect the concrete blocks of the girder segments to each other, adjacent girder segments can be connected in a more robust structure.

1 is an exemplary view showing the connection structure of a composite girder according to prior art literature;
2 is a perspective view of a composite girder structure according to an embodiment of the present invention;
3 is a perspective view showing a state in which a precast formwork is installed according to an embodiment of the present invention;
4 is a front view showing another structure of a precast formwork according to an embodiment of the present invention;
5 is a perspective view of a girder segment to which a joint means according to an embodiment of the present invention is applied.
6 is a side view of a girder segment to which a joint means according to an embodiment of the present invention is applied;
7 is a perspective view showing a state in which girder segments are connected by joint means according to an embodiment of the present invention;
8 is a perspective view of a girder segment to which a joint means according to another embodiment of the present invention is applied;
9 is a perspective view showing a state in which girder segments are connected by joint means according to another embodiment of the present invention;
10 is a front view showing a state in which girder segments are connected by joint means according to another embodiment of the present invention;
11 is an exemplary view showing a state in which girder segments of the present invention are connected without temporary cradle;
12 is a perspective view showing a state in which a second mounting bracket having a breakaway prevention bump of the present invention is seated on a first mounting bracket;
13 is a block diagram showing a construction method of a composite girder structure using a precast formwork in time series according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail based on the matters shown in the drawings, but if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. do.

2 to 5, in the composite girder structure using the precast formwork 200 of the present invention, a plurality of girder segments 300 equipped with an I-shaped steel material 310 and a concrete block 320 are connecting means A composite girder 100 is formed by being connected at 400, a plurality of composite girders 100 are formed to be spaced apart in the width direction of the bridge on an abutment or pier, and a free space is placed between adjacent composite girders 100 in the width direction. The cast formwork 200 is installed, and it is possible to solve the difficulty of installation work caused by the low height of the composite girder 100 in the process of installing the formwork to pour concrete on the top.

As shown in FIG. 5, the girder segment 300 is an I-shaped steel material formed by connecting an upper flange 311 and a lower flange 312 with a web 313 facing each other while being spaced apart in the vertical direction. It is made of a concrete block 320 formed at the lower end of the 310, that is, the lower flange 312, and the concrete block 320 has a reinforcing bar 321 and a sheath pipe 322 around the lower flange 312, and By installing a formwork and pouring concrete, the girder segment 300 in which the I-shaped steel 310 and the concrete block 320 are integrated is configured.

On the other hand, the reinforcing bar 321 and the sheath pipe 322 of the concrete block 320 protrude from both ends of the concrete block 320 in the longitudinal direction of the girder segment 300, and the strand 323 extends through the sheath pipe 322. Penetrates the girder segments 300 in the longitudinal direction through, and compressive force can be introduced to each girder segment 300 in advance by fixing the strands 323 in a tensioned state in the process of forming the girder segments 300. there is.

A plurality of such girder segments 300 are arranged in a line structure, and the I-shaped steel members 310 of the girder segments 300 adjacent in the longitudinal direction are connected by the joint means 400, and the composite extends in the longitudinal direction of the bridge. A girder 100 is formed.

Eventually, the composite girder 100 is formed by connecting two or more girder segments 300 with a joint 400 according to the length of the bridge to be constructed, and the girder segments 300 are lifted with heavy equipment such as a crane to While placing and fixing on abutments or piers, the ends of adjacent girder segments 300 are connected with joint means 400 to form a composite girder 100 in which only both ends are mounted on piers or abutments without a separate temporary stand.

The precast formwork 200 is installed between adjacent composite girders 100 installed on abutments or piers to form a pouring space in which concrete for forming a bridge floor plate is poured. It is transported and installed between the girders 100.

Meanwhile, as shown in FIG. 2, the precast formwork 200 according to an embodiment of the present invention includes a first panel portion 210, a second panel portion 220, and a loop portion 230, The first panel portion 210 is seated on the concrete block 320 of one side composite girder 100 among adjacent composite girders 100 and is spaced apart while facing the web 313 of the corresponding I-shaped steel member 310. It is made in the form of a plate material in the posture to form a concrete pouring space around the web 313.

The first panel portion 210 is fixed to the web 313 of the I-shaped steel member 310 by a fastening mechanism 240 .

The second panel portion 220 is seated on the concrete block 320 of the other composite girder 100 among the adjacent composite girders 100 and faces the web 313 of the I-shaped steel 310 of the composite girder 100. It is made in the form of a plate material in a vertical position spaced apart from each other to form a concrete pouring space around the web 313, and is preferably symmetrical with the first panel portion 210.

The second panel portion 220 is fixed to the web 313 of the I-shaped steel member 310 by the fastening mechanism 240 .

The loop part 230 is made in the form of a plate connecting the upper ends of the first and second panel parts 210 and 220 to each other, and the first and second panel parts 210 and 220 and the loop part 230 are integrally formed. The precast formwork 200 has an arched structure as a whole.

In installing the precast formwork 200 as described above between adjacent composite girders 100 installed on abutments or piers, the composite girder 100 ) may be different for each installation location. On the other hand, since the precast formwork 200 prefabricated in a factory always has a constant width, an adjustment structure for improving field applicability may be further included.

That is, the precast formwork according to another embodiment of the present invention is composed of a first panel portion 210, a second panel portion 220, and a loop portion 230, as shown in FIG. 4, the loop portion ( 230) is formed integrally with the first panel part 210 and forms a part of the loop part 230, and the first area 231 integrally formed with the second panel part 220 to form the loop part 230 It is divided into a second region 232 forming another part of, and the end of the first region 231 and the end of the second region 232 may be connected by the control block 233.

At this time, both sides of the control block 233 have a first control groove 233a into which the end of the first panel part 210 is inserted and a second control groove 233b into which the end of the second panel part 220 is inserted. ) is formed to extend in the longitudinal direction, and the first control groove 233a and the second control groove 233b adjust the depth into which the ends of the panel parts 210 and 220 are inserted, and the first panel part 210 and the control groove It is made so that the distance between the two panel parts 220 can be adjusted.

For example, when the end of the first panel part 210 or the end of the second panel part 220 is deeply inserted into the first control groove 233a or the second control groove 233b, the first panel part 210 and The distance between the second panel portions 220 decreases, and conversely, the end of the first panel portion 210 or the end of the second panel portion 220 is moved to the first control groove 233a or the second control groove 233b. When inserted shallowly, the distance between the first panel portion 210 and the second panel portion 220 increases.

3 and 4, the fastening mechanism 240 for fixing the precast formwork 200 to the web 313 of the I-shaped steel 310 is a tubular support 241 fixedly installed to the web 313 And, it is composed of a fastening bolt 242 fastened to the tubular support 241 through the first panel portion 210 or the second panel portion 220.

The tubular support 241 has a cylindrical shape, an inner end is welded and fixed to the web 313, and an outer end contacts the first panel part 210 or the second panel part 220, but a fastening bolt ( 242) is formed on the inner circumferential surface of the outer end.

In such a fastening mechanism 240, after concrete is poured into the pouring space formed by the precast formwork 200 and the precast formwork 200 is integrated with the bridge deck, the fastening bolt 242 is inserted into the tubular support 241 It is possible to finish cleanly without exposing the fastening bolt 242 by removing it from and filling the hole from which the fastening bolt 242 is separated.

The fastening mechanism 240 configured as described above fixes the panel portions 210 and 220 of the precast formwork 200 to the I-shaped steel member 310, and as shown in FIGS. 2 to 4, the precast formwork 200 A reinforcing ring 243, a connecting bar 244, and a connecting line 245 may be further included so that the loop portion 230 of the I-shaped steel 310 is additionally supported.

The reinforcing ring 243 is installed embedded in the loop portion 230 of the precast formwork 200 and connected to the connection line 245, and a portion of the reinforcing ring 243 protrudes upward from the loop portion 230.

The reinforcing ring 243 is fixed by fixing the lower end of the reinforcing ring 243 while being embedded in the inside of the loop part 230 during the manufacturing process of the precast formwork 200, so that the reinforcing ring 243 is integrally precast. A formwork 200 may be formed.

On the other hand, as shown in FIG. 4, when the loop portion 230 of the precast formwork 200 includes the first area 231, the second area 232, and the control block 233, the reinforcing ring ( 243) may be provided in the control block 233.

The connecting bar 244 is installed to connect the upper ends of the girder segments 300 adjacent to each other in the width direction of the bridge to form a structure in which the upper ends of the connecting lines 245 are bound.

The connecting bar 244 is fixed by welding one end of the steel bar to the upper flange 311 of the one girder segment 300, and welding the other end of the steel bar to the upper flange 311 of the other girder segment 300. It can be installed in a fixed way.

The connection line 245 connects the reinforcing ring 243 and the connecting bar 244, and is in the form of a wire rod having an upper end bound to the connecting bar 244 and a lower end bound to the reinforcing ring 243, such as a wire rope or iron wire. As a member of, it may be a flexible member or a member having a predetermined rigidity.

5 to 12, the joint means 400 of the present invention is one side or the other side of the girder segments 300 so that the ends of the adjacent girder segments 300 are connected to each other and mounted without a separate temporary support. A supporting protrusion 430, a mounting protrusion 440, a fixing bracket 450, and a hinge bracket 460 are provided.

The supporting protrusion 430 protrudes from one end of the girder segment 300, and as shown in FIGS. 5 and 6, the lower half of one side of the I-shaped steel 310 protrudes in the longitudinal direction. Can be formed there is.

In this way, a support plate 431 in a horizontal posture is installed at the upper end of the support protrusion 430 formed by protruding the lower half of one side of the I-shaped steel 310 in the longitudinal direction, and at the end of the support plate 431 One or more binding protrusions 432 are formed to protrude.

On the other hand, as shown in FIG. 9, the supporting protrusion 430 may be formed by protrudingly installing a separate bracket on the web 313 of the I-shaped steel 310, and this supporting protrusion 430 is a girder segment At one end of the 300, it protrudes from the side of the web 313 in the width direction of the girder segment 300, and is installed on both sides of the web 313 to have a horizontal upper surface.

The mounting protrusion 440 protrudes from the other end of the girder segment 300, and as shown in FIGS. 5 and 6, it can be formed by protruding the other upper half of the I-shaped steel 310 in the longitudinal direction. there is.

In this way, a horizontal mounting plate 441 is installed at the lower end of the mounting protrusion 440 formed by protruding the upper half of the other side of the I-shaped steel member 310 in the longitudinal direction, and the binding protrusion 432 penetrates. One or more coupling holes 442 are formed in the mounting plate 441 .

Meanwhile, as shown in FIG. 9, the mounting protrusion 440 may be formed by protrudingly installing a separate bracket on the web 313 of the I-shaped steel 310, and the mounting protrusion 440 is a girder segment. Protrudes from the side of the web 313 at the other end of the 300 in the width direction of the girder segment 300 and in the longitudinal direction of the girder segment 300, respectively, on both sides of the web 313 to have a bottom surface in a horizontal posture. It is installed, but is installed higher than the first mounting bracket 430 so that the bottom surface is placed on the upper surface of the first mounting bracket 430 of the other girder segment 300.

According to the supporting protrusion 430 and the supporting protrusion 440 as described above, the supporting protrusion 440 of one girder segment 300 is mounted on the supporting protrusion 430 of the other girder segment 300, FIG. 7 and As shown in FIG. 9, the mounting state of the adjacent girder segments 300 can be implemented.

On the other hand, the supporting protrusion 430 configured to install the bracket on the web 313 on one side of the girder segment 300 is formed to protrude in the longitudinal direction of the girder segment 300 as well as the width direction of the girder segment 300. it is desirable

This is because when the supporting protrusion 430 protrudes in the longitudinal direction of the girder segment 300, the web 313 of the other girder segment 300 is in the process of coupling the ends of the adjacent girder segments 300 to each other. ), it is possible to construct a more stable joint because the flow in the horizontal direction is restricted while being inserted between the

In addition, at the bottom end of the support protrusion 430 configured to install the bracket on the web 313 on one side of the girder segment 300, a release prevention bump 443 is formed to protrude downward, and the detachment prevention bump 443 is a mounting protrusion In a state where the lower surface of the supporting protrusion 440 is placed in the correct position on the upper surface of the supporting protrusion 430, it is caught on the rear end of the supporting protrusion 430 to prevent the supporting protrusion 440 from slipping and escaping from the supporting protrusion 430.

On the other hand, as shown in FIGS. 5 and 10, the fixing bracket 450 is fixedly installed on the upper flange 311 at one end of the girder segment 300, and the locking member provided in the hinge bracket 460 ( 462) and a fixed shaft 451 in a horizontal position. At this time, the fixing shaft 451 is composed of a bolt assembled to the fixing bracket 450 in a detachable structure and can be configured to be fixed to the fixing bracket 450 by being fastened with a nut.

As shown in FIGS. 5 and 10, the hinge bracket 460 is fixedly installed on the upper flange 311 so as to be located on the opposite side of the fixing bracket 450, and the hinge shaft 461 in a horizontal position, and a part includes a locking member 462 coupled to the hinge shaft 461 in a rotatable structure and another part coupled to the fixed shaft 451. Accordingly, since the adjacent girder segments 300 can be temporarily coupled, the connection work of the girder segments 300 can be smoothly performed even in a place where there is no support point such as a temporary cradle during the connection work.

In addition, as shown in FIGS. 7 and 10, the locking member 462 has a binding hole 463 through which the fixing shaft 451 passes, or a part in the lateral direction of the locking member 462. It is formed in an open groove structure and may be configured to be coupled with the fixed shaft 451.

It is preferable that the fixing bracket 450 and the hinge bracket 460 are fixed to the upper flange 311 by bolt fastening so that they can remain or be removed after the construction of the composite girder structure is completed.

As described above, the joint means 400 of the present invention binds the I-shaped steel members 310 of adjacent girder segments 300 mounted without temporary supports to each other to form a composite girder 100 together with a plurality of girder segments 300. For forming, an angle plate 410 and a flat plate 420 may be further included.

As shown in FIGS. 5 to 8, the angle plate 410 allows the webs 313 of the I-shaped steel 310 of the adjacent girder segments 300 to be connected to each other and fixed. (313) Consisting of a fixing piece 411 that is in close contact with the side face and a fastening piece 412 formed to protrude from the fixing piece 411 in the width direction of the girder segment 300, the fixing piece 411 At the end of the I-shaped steel 310, it is fixed to the side of the web 313 by bolting or welding, and the fastening piece 412 is the fastening piece 412 of the angle plate 410 installed on the other girder segment 300. ) Can be bound by fastening with bolts 471 and nuts 472 facing each other.

These angled plates 410 are installed on both left and right sides of the web 313, respectively.

The flat plate 420 is to allow the upper flanges 311 of the I-shaped steel 310 of the adjacent girder segments 300 to be connected and fixed to each other, to both the upper flanges 311 of the two adjacent girder segments 300. It is arranged in close contact and is fixed to the upper flange 311 due to bolt fastening, thereby binding the upper flange 311 of the adjacent girder segment 300.

As such, the joint means 400 including the angle type plate 410 and the flat plate 420 can improve the joint stiffness of the girder segment 300 as the joint area is increased due to the angle type plate 410. .

Meanwhile, as shown in FIGS. 1 to 4 and 7, a reinforcing bar coupler 510 and a connecting concrete block 530 may be further provided between adjacent girder segments 300.

The reinforcing bar coupler 510 connects the reinforcing bars 321 protruding from the concrete blocks 320 of the adjacent girder segments 300 to each other, and the reinforcing bars 321 protruding from the concrete block 320 are inserted at both ends While binding, it may be combined with the reinforcing bar 321.

The connecting concrete block 530 is formed between adjacent girder segments 300 and is integrated with the concrete block 320, and the I-shaped steel 310 of the adjacent girder segments 300 is connected by the connecting means 400. After being connected, and after the reinforcing bars 321 are connected by the reinforcing bar coupler 510, a formwork surrounding the space between the concrete blocks 320 is installed to form a pouring space, and concrete is poured and cured in the pouring space. do.

Hereinafter, the construction method of the composite girder structure using the precast formwork of the present invention will be described in detail.

The construction method of a composite girder structure using a precast formwork of the present invention uses a girder segment 300 formed by forming a concrete block 320 on the lower flange 312 of an I-shaped steel 310, and the segment mounting step (S10), segment binding step (S20), reinforcing bar connection step (S30), connected concrete block forming step (S40), formwork arrangement step (S50), and formwork fixing step (S60) are sequentially performed.

In the segment mounting step (S10), the girder segment 300 formed by forming the concrete block 320 on the lower flange 312 of the I-shaped steel 310 is placed on the abutment or pier, but the girder segment ( 300) proceeds to be mounted by the first mounting bracket 430 and the second mounting bracket 400.

One composite girder 100 may be formed by connecting two or more girder segments 300, but hereinafter, an embodiment in which abutments and abutments are connected using two girder segments 300 will be mainly described.

One of the adjacent girder segments 300 is lifted with heavy equipment and placed on one abutment, but the girder segment 300 is arranged so that one end of the girder segment 300 is fixed to the abutment and the other end faces the other abutment. do. At this time, one end of the girder segment 300 may be mounted on a bridge seat installed on the shift.

In addition, another adjacent girder segment 300 is also lifted with heavy equipment and placed on the other abutment, but one end of the girder segment 300 is fixed to the abutment and the other end of the girder segment 300 installed on one abutment While facing, the mounting protrusion 440 provided at the end of the other girder segment 300 is seated on the support protrusion 430 provided at the end of the girder segment 300 on one side.

On the other hand, the girder segment 300 supported by the supporting protrusion 430 and the holding protrusion 440 is restrained in its relative movement in the vertical and horizontal directions in the subsequent segment binding step (S20), until binding to maintain a stable bonded state.

The segment binding step (S20) is a process of fixing the mounted girder segment 300 with the fixing bracket 450 and the hinge bracket 460, and the locking member of the hinge bracket 460 installed on the one side girder segment 300 ( Rotate the locking member 462 around the hinge shaft 462 so that the binding hole 463 of 462 is inserted into the fixing bracket 450 of the other girder segment 300, and the fixing shaft 451 is the fixing bracket 450 and the binding hole 463 are formed by sliding coupling so as to pass through.

As described above, the ends of the adjacent girder segments 300 are mounted in a state of being engaged with each other by the support protrusion 430 and the mounting protrusion 440, and by the combination of the fixing bracket 450 and the hinge bracket 460 Since it is temporarily coupled, it is possible to stably maintain the temporarily coupled state even without a separate hypothetical holder.

After that, in order to implement the main coupling in a state where the adjacent pair of girder segments 300 are simply temporarily coupled, the upper flange 311 and the lower flange of the adjacent girder segments 300 using the flat plate 420 ( 312) is fastened, and the web 313 of the adjacent girder segment 300 is fastened using the angle plate 410 composed of the fixing piece 411 and the fastening piece 412.

In the reinforcing bar connection step (S30), after the adjacent girder segments 300 are connected by the joint means 400, the reinforcing bars 321 protruding from the concrete block 320 and the reinforcing bars 321 are connected using the reinforcing bar coupler 510. It consists of connecting

In the connected concrete block forming step (S40), which proceeds thereafter, after the connection of the reinforcing bars 321 by the reinforcing bar coupler 510 is completed, a formwork is installed around it, and the adjacent concrete block 320 is formed by pouring and curing the concrete. It consists of forming a connecting concrete block 530 to connect.

As a result, composite girders connecting the abutments to the abutments are formed, and a plurality of composite girders 100 are formed at regular intervals in the width direction of the bridge.

Meanwhile, the formwork arrangement step (S50) is a process of arranging the precast formwork 200 between adjacent composite girders, and the first panel part 210, the second panel part 220 and the loop part 230 are The precast formwork 200 including the precast formwork 200 is disposed between adjacent girder segments 300 in the width direction of the bridge, and the first panel portion 210 is seated on the concrete block 320 of the one girder segment 300, The second panel portion 220 is seated on the concrete block 320 of the other girder segment 300, and a plurality of precast forms 200 are arranged in the longitudinal direction of the composite girder.

The next step of fixing the formwork (S60) is to fix the precast formwork 200 to the girder segments 300, including the panel fastening step (S61), connecting bar installation step (S62), and connection line installation step (S63). ) may be included.

The panel unit fastening step (S61) consists of fixing the first panel unit 210 and the second panel unit 220 to the I-shaped steel material 310 using the tubular support 241 and the fastening bolt 242. .

The tubular support 241 may be installed on the web 313 of the I-shaped steel member 310 prior to installation of the precast formwork 200, or installed on the web 313 in the process of manufacturing the girder segment 300. there is.

On the other hand, the outer surfaces of the first panel part 210 and the second panel part 220 of the precast formwork 200 are in close contact with the end of the tubular support 241, and the fastening bolt 242 is the first panel part ( 210) or the second panel portion 220 is fastened to the tubular support 241 while the panel portions 210 and 220 are fixed to the web 313.

The connection bar installation step (S62) is a process of forming a structure for supporting the loop portion 230 of the precast formwork 200 in the girder segment 300, and the connection bar 244 is installed in the precast formwork 200 It consists of installing to connect the upper flange 311 of the girder segment 300 adjacent in the width direction of the bridge while extending in a horizontal position at the vertical upper part of the bridge.

Meanwhile, an end of the connecting bar 244 may be fixed to the upper flange 311 by welding.

In the connection line installation step (S63), the upper end of the connection line 245 is bound and fixed to the connection bar 244, and the lower end of the connection line 245 is bound and fixed to the reinforcing ring 243, thereby reinforcing the reinforcing ring 243 and the connection line. 245 and the connecting bar 244 through which the loop portion 230 of the precast formwork 200 is supported on the upper flange 311. As a result, it is possible to prevent the precast formwork 200 from being damaged or moved while a worker pours concrete on the upper part.

As described above, the composite girder structure using the precast form and the construction method of the present invention easily forms a concrete pouring space by transporting and installing the pre-fabricated precast form 200 between the composite girders 100. Therefore, despite the low mold height, the installation work of the formwork can proceed smoothly.

In addition, the connection work of the girder segments 300 arranged adjacently can be performed without the formation of support points such as piers, so that the workability of the composite girder structure can be improved.

On the other hand, when the loop portion 230 of the precast formwork 200 is divided into the first area 231, the second area 232, and the control block 233, design changes or composite girders according to site conditions ( Since the distance between the first panel part 210 and the second panel part 220 can be adjusted in response to the change in the distance between the composite girders 100 according to the construction error of 100), the installation work of the precast formwork 200 can be carried out more easily.

The composite girder structure using the precast formwork and its construction method according to the present invention described above can be changed into other specific forms by those skilled in the art without changing the technical spirit or essential features of the present invention. It will be appreciated that this can be implemented.

Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting, and the scope of the present invention is indicated by the claims to be described later rather than the foregoing detailed description, and the meaning and meaning of the claims All changes or modified forms derived from the scope and equivalent concept should be construed as being included in the scope of the present invention.

100: composite girder 200: precast formwork
210: first panel portion 220: second panel portion
230: loop part 231: first area
232: second area 233: control block
233a: first control groove 233b: second control groove
240: fastening mechanism 241: tubular support
242: fastening bolt 243: reinforcing ring
244: connection bar 245: connection line
300: girder segment 310: I-shaped steel
311: upper flange 312: lower flange
313: web 320: concrete block
321: rebar 322: sheath pipe
323: strand wire 400: joint means
410: Angled plate 411: Fixing piece
412: fastening piece 420: flat plate
430: supporting protrusion 431: supporting plate
432: binding protrusion 440: mounting protrusion
441: Mounting plate 442: Coupling hole
443: departure prevention bump 450: fixed bracket
451: fixed axis 460: hinge bracket
461: hinge axis 462: locking member
463: binding hole 471: bolt
472: nut 510: rebar coupler
520: joint pipe 530: connection concrete block

Claims (11)

A concrete block 320 is formed on the lower flange 312 of the I-shaped steel 310 composed of the upper flange 311, the lower flange 312, and the web 313, and the amount of the I-shaped steel 310 in the longitudinal direction A girder segment 300 having an end protruding from the concrete block 320;
Composite girder 100 with a plurality of girder segments 300 by being installed in a joint to bind and fix the I-shaped steel 310 ends of adjacent girder segments 300 to each other by being arranged in a line structure to extend in the longitudinal direction of the bridge. ) to form a joint means 400; and
It is installed to connect the two composite girders 100 between the two composite girders 100 formed to be spaced apart from each other in the width direction of the bridge to form a pouring space for forming a bridge floor plate, and concrete is poured into the pouring space. Including; integrated precast formwork 200;
In the precast formwork 200, the first panel portion 210 is seated on the concrete block 320 of the one-side composite girder 100, and the I-shaped steel 310 web 313 of the composite girder 100 It is spaced apart from the web 313 to form a casting space around the web 313, and the second panel portion 220 is located at a place facing the first panel portion 210 while being spaced apart from the concrete block 320 of the other composite girder 100. ), and is spaced apart from the web 313 of the I-shaped steel material 310 of the composite girder 100 to form a pouring space around the web 313, and the first panel part 210 and the second panel part 220 is fixed to the web 313 by the fastening mechanism 240, and the loop part 230 connects the upper end of the first panel part 210 and the upper end of the second panel part 220 to each other, ,
The tubular support 241 of the fastening mechanism 240 has a thread formed on the inner circumferential surface of the outer end so that the outer end is in close contact with the first panel part 210 or the second panel part 220, and the inner end is made of I-shaped steel It is fixed to the web 313 of the 310, and the fastening bolt 242 passes through the first panel part 210 or the second panel part 220 and is fastened to the outer end of the tubular support 241, and the panel part A composite girder structure using a precast formwork, characterized in that it is fixed to the tubular support (241).
delete delete According to claim 1,
The fastening mechanism 240,
a reinforcing ring 243 installed so that a part protrudes from the upper surface of the loop part 230;
A connecting bar 244 installed to connect the upper ends of the adjacent girder segments 300 in the width direction of the bridge; and
A connecting line 245 connecting the reinforcing ring 243 and the connecting bar 244 so that the loop portion 230 is supported by the connecting bar 244;
A composite girder structure using a precast formwork, characterized in that it further comprises.
A concrete block 320 is formed on the lower flange 312 of the I-shaped steel 310 composed of the upper flange 311, the lower flange 312, and the web 313, and the amount of the I-shaped steel 310 in the longitudinal direction A girder segment 300 having an end protruding from the concrete block 320;
Composite girder 100 with a plurality of girder segments 300 by being installed in a joint to bind and fix the I-shaped steel 310 ends of adjacent girder segments 300 to each other by being arranged in a line structure to extend in the longitudinal direction of the bridge. ) to form a joint means 400; and
It is installed to connect the two composite girders 100 between the two composite girders 100 formed to be spaced apart from each other in the width direction of the bridge to form a pouring space for forming a bridge floor plate, and concrete is poured into the pouring space. Including; integrated precast formwork 200;
In the precast formwork 200, the first panel portion 210 is seated on the concrete block 320 of the one-side composite girder 100, and the I-shaped steel 310 web 313 of the composite girder 100 It is spaced apart from the web 313 to form a pouring space around the web 313, but is fixed to the web 313 by the fastening mechanism 240, and the second panel portion 220 is spaced apart from the first panel portion 210. It is located at the opposite place and is seated on the concrete block 320 of the other composite girder 100, and is spaced apart from the web 313 of the I-shaped steel 310 of the composite girder 100 to form a pouring space around the web 313 However, it is fixed to the web 313 by the fastening mechanism 240, and the loop part 230 connects the upper end of the first panel part 210 and the upper end of the second panel part 220 to each other,
In the loop part 230, the first area 231 is formed on the first panel part 210 as an integral structure, and the second area 232 is formed on the second panel part 220 as an integral structure. , The first panel part 210 and the second panel part 220 correspond to the distance between the adjacent composite girders 100 so that the control block 233 connects the first area 231 and the second area 232 Adjust the distance between, but the control block 233 is formed on one side of the first control groove 233a into which the end of the first panel part 210 is inserted, and the end of the second panel part 220 A second control groove 233b into which is inserted is formed on the other side, and the distance between the first panel part 210 and the second panel part 220 is adjusted by adjusting the depth into which the end of the panel part is inserted into the control groove. Composite girder structure using precast formwork, characterized in that made to.
A concrete block 320 is formed on the lower flange 312 of the I-shaped steel 310 composed of the upper flange 311, the lower flange 312, and the web 313, and the amount of the I-shaped steel 310 in the longitudinal direction A girder segment 300 having an end protruding from the concrete block 320;
Composite girder 100 with a plurality of girder segments 300 by being installed in a joint to bind and fix the I-shaped steel 310 ends of adjacent girder segments 300 to each other by being arranged in a line structure to extend in the longitudinal direction of the bridge. ) to form a joint means 400; and
It is installed to connect the two composite girders 100 between the two composite girders 100 formed to be spaced apart from each other in the width direction of the bridge to form a pouring space for forming a bridge floor plate, and concrete is poured into the pouring space. Including; integrated precast formwork 200;
In the connecting means 400, a support protrusion 430 is protruded from one end of the girder segment 300, and a supporting protrusion 440 is protruded from the other end of the girder segment 300 to form another girder segment It is seated on the supporting protrusion 430 of the 300, a fixing bracket 450 is installed at one end of the girder segment 300, and a hinge bracket 460 rotates around the hinge axis 461 at the other end A composite girder structure using a precast form, characterized in that a locking member 462 is provided so that the outer end is coupled to the fixing bracket 450.
According to claim 6,
The support protrusion 430 is formed by protruding the lower half of the I-shaped steel 310 in the longitudinal direction and installing a support plate 431 on the upper end,
The mounting protrusion 440 is formed by protruding the upper half of the I-shaped steel 310 in the longitudinal direction and installing the mounting plate 441 seated on the supporting plate 431 at the lower end. Precast formwork, characterized in that Composite girder structure using
According to claim 6,
The joint means 400,
It consists of a fixing piece 411 fixed to the web 313 of the I-shaped steel 310 and a fastening piece 412 formed to protrude from the fixing piece 411 in the width direction of the girder segment 300, An angle plate 410 installed at the joint of the web 313 to fasten the web 313 of the adjacent girder segment 300; and
A flat plate 420 installed at the joint of the upper flange 311 and the lower flange 312 to fasten the upper flange 311 and the lower flange 312 of the adjacent girder segments 300;
A composite girder structure using a precast formwork, characterized in that it further comprises.
According to claim 1 or 6,
The reinforcement 321 and the sheath pipe 322 inside the concrete block 320 protrude from the end of the concrete block 320 in the longitudinal direction of the girder segment 300, and the reinforcement protrudes from the adjacent girder segment 300 ( 321) is coupled by the reinforcing bar coupler 510, and adjacent girder segments ( A composite girder structure using a precast formwork, characterized in that the concrete blocks 320 of 300) are connected.
It relates to a construction method of a composite girder structure using a girder segment 300 formed by forming a concrete block 320 on a lower flange 312 of an I-shaped steel 310,
In a state where the other end of the girder segment 300 is supported on an abutment or pier, one end is disposed so as to face another adjacent girder segment 300, but a mounting protrusion 440 protruding from one end of the girder segment 300 Segment mounting step (S10) of allowing to be seated on the support protrusion 430 protruding from another girder segment 300;
A segment that binds the locking member 462 of the hinge bracket 460 installed on the upper flange 311 of the other girder segment 300 to the fixing bracket 450 installed on one side of the upper flange 311 of the girder segment 300 Binding step (S20);
A reinforcing bar connection step (S30) of connecting the reinforcing bar 321 protruding from the concrete block 320 of the adjacent girder segment 300 with the reinforcing bar coupler 510;
Formwork is installed between adjacent girder segments 300, and concrete is poured and cured to form a connected concrete block 530 connecting the concrete blocks 320 of the adjacent girder segments 300 (S40). );
A precast formwork 200 including a first panel portion 210, a second panel portion 220, and a loop portion 230 is disposed between adjacent girder segments 300 in the width direction of the bridge, but the first panel A plurality of precast forms ( 200) along the longitudinal direction of the girder segments 300; a formwork arrangement step (S50); and
A formwork fixing step (S60) of fixing the precast formwork 200 to the girder segments 300;
Construction method of a composite girder structure using a precast formwork, characterized in that it comprises a.
According to claim 10,
In the form fixing step (S60),
The first panel part 210 or the second panel part 220 is disposed so as to come into contact with the tubular support 241 coupled to the I-shaped steel member 310, and the fastening bolt 242 is fastened to the tubular support 241. Panel part fastening step (S61) to;
A connecting bar installation step of installing a connecting bar 244 connecting the upper end of the adjacent girder segments 300 in the width direction of the bridge (S62); and
A connection line installation step (S63) of connecting the reinforcing ring 243 and the connection bar 244 provided in the loop portion 230 of the precast formwork 200 with a connection line 245;
Construction method of a composite girder structure using a precast formwork, characterized in that it comprises a.

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