KR100565359B1 - Continuous Bridge Construction Method - Google Patents

Abstract

The present invention relates to a bridge sequencing method using a bridge girder, the bridge girder upper flange end, such as I type, T type, U type, box girder, etc. The upper inner steel including digging, high-strength screw reinforcing and screw steel rods are made to protrude the upper flange, and the bridge girder formed with the upper inner steel is installed in a simple beam method, and the upper inner steel is placed before slab concrete pouring. The present invention relates to a bridge sequencing method in which a sequential load of a slab concrete is fixed by a nut member to a sequential means, thereby more efficiently improving the sequential construction of bridges with a burden on existing secondary dead and live loads.

Continuous, high strength threaded rod, high strength threaded rod, connecting frame

Description

Continuous Bridge Construction Method

1A and 1B are a longitudinal sectional view and a plan view of a state in which RC and PSC girder are connected by using a sequencing method according to the present invention.

Figures 2a, 2b, 2c, 2d and 2e show the construction according to the sequence of connecting the RC and PSC girder using the sequencing method according to the present invention.

<Description of Symbols for Main Parts of Drawings>

10: pier 20: bridge bearing

100: RC and PSC girder 200: serialization means

210: horizontal member of serializing means 220: vertical member of serializing means

230: nut member

300: slab concrete 310: slab steel

The present invention allows the continuity of bridge girders such as RC and PSC girders to be continued to slab concrete loads in addition to secondary dead loads and live loads, so that the slab concrete occupies about one third of the total load in the conventional simple beam installation method. The present invention relates to a more economical and efficient bridge continuity construction method by supporting the dead weight of the bridge girder. Conventional methods of sequencing bridge girders include a method of introducing a continuous reinforcement to a slab concrete or a steel wire around a connecting part to introduce tension, and a continuous method using a rising / falling point of a branch. Secondary or live loads were to be supported, but slab concrete and beams were supported by a simple beam structure. That is, the conventional bridge sequencing method has continued the girder for bridges in such a way that only the secondary dead and live loads, which occupy one third of the total load, are supported by continuous beams.

In addition, in order to continually develop the slab concrete dead weight, the sequential construction method using PC steel bar was proposed for the PSC girder, but the pre-stress introduced by fatigue is lost due to the continuous cyclic load on the anchorage during live load and the anchorage is lost. There is a possibility of breakage, and it is difficult to insert and tension PC steel rod during construction, and it is impossible to install on site due to the error of insertion hole during manufacturing. It is pointed out that a problem arises in that a large stress step is generated and a crack occurs in a concrete part nearby, and it is not widely used recently.

Due to the problems of the prior art as described above, the necessity of developing alternative construction methods in consideration of workability and economics has been raised.

 An object of the present invention was created to overcome the shortcomings of the continuity means of the bridge girder, including the existing RC and PSC girder, more secure, durable and easy to use construction only bridge construction girder And to provide a bridge sequencing method using the sequencing means.

In particular, the present invention provides an upper inner steel including a high-strength threaded steel rod by digging a groove of sufficient length to install a continuity means such as a connecting frame at the end when manufacturing RC girder and reinforced concrete girder. It is manufactured to protrude and installed in a simple beam method on the bridge substructures, such as bridge piers, shifts, and the nut member through the sequencing means to the upper inner steel prior to slab concrete

It is possible to efficiently and economically construct bridges to reduce the profile height or cross-sectional size of bridge girder such as RC and PSC girder or to increase the support length by continually girder to support slab concrete load by continuous beam structure. Technical features, the best embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains can be easily carried out, with reference to Figures 1 and 2 Then, each of them will be examined on the basis of the bridge girder which is RC and PSC girder and the bridge continuous method using the same.

<RC and PSC girder (bridge girder)>

RC and PSC girder 100 of the present invention is manufactured by a conventional RC and PSC girder manufacturing method, the manufactured RC and PSC girder is installed by using the bridge support on the bridge over the multi-span and the end is connected to each other continuous beam Function as.

Figures 1a and 1b is a longitudinal cross-sectional view and a plan view showing a state in which each end of the connection portion of the RC and PSC girder 100 of the present invention is connected to each other by the sequencing means 200.

Each RC and PSC girder 100 has a plurality of upper inner steel 110 is formed to protrude to extend the blocked groove 120 formed at the upper flange end of the RC and PSC girder, the upper inner steel 110 corresponding to each other ) Is connected by the serialization means (200). This connection causes the RC and PSC girders to function as continuous beams to each other. The groove 120 is finally filled by placing the slab concrete 300, etc., and becomes a space for accommodating the sequencing means 200 to be described later.

The length (L), thickness (H) and width (D) of the groove 120 is preferably to be formed to a minimum, in the case of the length (L) at least the continuation means 200 can be accommodated, the installation It is installed in the parent section generating section, such as the point portion to facilitate the operation, the thickness (H) is at least of the continuum means so that the horizontal member 210 of the sequencing means 200 to be described later can be accommodated in the groove The thickness of the cross beam is determined to be slightly larger than the thickness of the upper flange of the RC and PSC girders, and the width D is preferably formed to be at least according to the widthwise installation number of the upper inner steel to be installed.

At this time, the length of the protruding upper inner steel 100 is formed to have a length that does not reach the line indicated by a in FIG. That is, when the upper inner steel 110 is fastened to the horizontal member 210 of the sequencing means 200 by the nut member 230 by preventing it from protruding beyond the end formwork vertically installed at the ends of the RC and PSC girder. Make it easy to introduce tension.

The continuation means 200 is a horizontal member 210 is fixed to each end of the upper inner steel 110 to be connected to each other, installed in a direction perpendicular to the upper inner steel material; And a vertical member 220 connecting the horizontal members to each other.

The sequencing means 200 has a function of connecting the upper inner steel 110 of the RC and PSC girder to each other by the horizontal member 210 and the vertical member 220, the upper inner steel 110 is a nut member ( When tightened by 230, the support band is to be introduced so that the tensile force is introduced.

Horizontal member 210 has a hole is formed so that the end of the upper inner steel 110 of the RC and PSC girder 100 connected to each other as shown in Figure 1b is accommodated in the groove 120 of the RC and PSC girder The width is determined by the number of installations of the upper inner steel to be connected. In FIG. 1B, four upper inner steels are formed to have widths that can be installed at regular intervals.

Two horizontal members, each of which passes through each of the upper inner steels to be connected, are installed facing each other so that the horizontal members can be perpendicular to the upper inner steels.

The member connecting the two horizontal members to each other is the vertical member 220. The vertical member and the horizontal member are connected to each other structurally so that the vertical member functions as a point member and the horizontal member functions as a continuous member. In other words, the horizontal member should not be interrupted by the longitudinal member. In addition, the vertical member 220 should have the same strength as the yield strength of the upper inner steel 110 adjacent to each other as shown in Figure 1b to ensure the strength and can use a steel plate (Steel Plate) having a predetermined thickness, etc. have. Furthermore, the horizontal member 210 should also have strength and rigidity capable of resisting shear force and moment due to the yield tensile strength of the upper internal steel, and steel sheets having a predetermined thickness may also be used.

As a result, the continuation means 200 is manufactured in the shape of a connecting frame in which the horizontal member 210 and the vertical member 220 are coupled to each other, and the continuation means is formed inside the upper flange of the RC and PSC girder, and as a whole bridge In the bore, the RC and PSC girders are formed in the parent section, which includes the pier top points connected to each other. In other words, it acts as a tensile reinforcing bar resisting the parent moment occurring at the point.

The upper inner steel 110 is fastened to the sequencing means 200 to form a screw thread on the protruding end, the length of the upper inner steel 110 through the hole formed in the horizontal member of the sequential means to be a position further protruded further from the horizontal member. Is adjusted. The nut member 230 is fastened to the screw thread, and when the screw is rotated, the nut member is moved while being supported by the horizontal member 210 toward each RC and PSC girder, and the horizontal member is moved by the vertical member 220. Since it is constrained, the nut member is finally tightened to be continuous with the upper inner steel. This continuity eventually plays a role of resisting the parent moments generated at the point due to the slab concrete weight, so that the upper internal reinforcement resists the concrete self-weights generated in the upper part of RC and PSC girder. It can be reduced, thereby making it possible to produce a cross-sectional size that can resist its own weight. As a result, it is possible to construct longer and longer RC and PSC bridges in the same span, and it is possible to construct RC and PSC bridges with smaller cross-sectional sizes.

3 to 6 show other embodiments of the continuation means 200, wherein the four continuation means are to be installed on the horizontal member 210 after the upper inner steel is tensioned using a nut member to the continuation means. As it is intended to be as convenient for manufacturing and construction is not necessarily limited to the sequencing means of the present invention by these embodiments.

3 illustrates that the horizontal member 210 and the vertical member 220 have a lattice-like structure as shown in FIGS. 1A and 1B, and the horizontal member 210 may be further formed in the middle. The upper inner steel 110 is installed through a hole previously formed in the horizontal member and is tightened and fixed to the horizontal member by the nut member 230 so that tension force (tensile force) is introduced into the upper inner steel.

4 is manufactured in the same structure as in FIG. 3, but for easily installing the upper internal steel material in the horizontal member, as shown in FIG. 3, a hole is formed so as to penetrate the upper internal steel material in the horizontal member. Rather than installing the end of the upper inner steel directly into the hole in such a way as to insert the upper inner steel 110 in the horizontal member 210 using the upper inner steel guide groove 240 in the hole in the guide groove. Finally, the upper inner steel is installed in such a manner that the end penetrates the horizontal member. Compared with the sequential means 200 according to FIG. 3, the workability for installing the upper internal steel material is very excellent.

3 and 4, the horizontal member 210 does not form a hole, such as a circular in advance, the continuous means in the shape of the sequential means of the completed state of Fig. And the semi-circular holes are formed in the horizontal members of the upper and lower serialization means (200a. 200b), respectively. To form. At this time, after placing the upper inner steel 110 in the semi-circular hole of the lower continuation means 200b, the upper continuation means 200a is installed thereon, and the upper and lower continuation means are fastened and combined as anchor members. Finally, the upper inner steel can be easily installed in the sequencing means.

FIG. 6 shows that the vertical member 220 of the sequential means 200 is not manufactured with a plate member such as a steel plate, but only the horizontal member is installed so that the upper inner steel material penetrates, and the rod-shaped rod is formed at the end as the vertical member. As a method of connecting the horizontal members to each other by using a connecting member, there is an advantage that a member that can be easily obtained in the field can be used, and an installation interval of the horizontal member can be easily adjusted by adjusting the length of the vertical member. .

<Continuous Chemical Processing of RC and PSC Girder>

RC and PSC girder sequencing method of the present invention by connecting the ends of the RC and PSC girder 100 produced as described above to each other using the continuity means 200 at the point portion to function as a continuous beam and slab concrete (300) ), And will be described with reference to FIG.

2A to 2E are flowcharts schematically showing the RC and PSC girders of the present invention according to the installation procedure.

First, as shown in FIG. 2A, first, bridge support 20 is installed on a plurality of bridges 10. In this case, unlike the case of installing the RC and PSC girder in a pure simple beam or a conventional continuous beam method, the bridge support 20 is connected in advance in the present invention so that the PSC girder functions substantially as a continuous beam, each RC and The bridge support capable of supporting the PSC girder may be provided with one bridge support, but it is preferable to allow two bridge supports 20 to be installed.

The RC and PSC girder 100 may be manufactured in an I-type or U-shaped cross section, and the upper internal steel 110 for continuity is installed in the RC and PSC girder 100. The upper flange end of the RC and PSC girder 100 is formed with a groove 120 having a predetermined shape so that the upper inner steel protrudes to form the upper inner steel and the center line of the corresponding opposite RC and PSC girder 100. It is connected to each other by the sequencing means 200 in the installed state to match.

The groove 120, when the RC and PSC girder 100 is the I-beam, the thickness of the groove 120 is smaller than the thickness of the upper flange, so that the abdominal (web) of the RC and PSC girder 100 is not exposed , U-shaped girder to ensure a sufficient thickness so that the upper inner steel 110 is arranged in two rows up and down.

In the embodiment of the present invention, a thread is formed at the end of each upper inner steel 110 and is inserted into a hole formed in the horizontal member of the continuous steel, and is tightened by the nut member 230 so that each upper inner steel of the continuous means The tensile force is introduced while being supported by the horizontal member 210. The horizontal member 210 is connected to each other by the vertical member 220 so that the continuity means has the shape of the connecting frame as a whole, preferably made of steel, but is not limited thereto.

The upper inner steel 110 is to be reinforced to the parent section in the continuous beam (point portion of the continuous beam) by the tension force due to the parent acting on the upper flange of the RC and PSC girder 100 by the parent in the section. It is structurally functioning as a reinforcing bar. The upper inner steel having the function of the tensile reinforcing bar is connected by the continuation means 200 as shown in Figs. 1, 3 to 6 at the point portion, RC and PSC girder 100 is continuous to pour the upper slab concrete 300 In order to support the static moment of the RC and PSC girder 100 due to its own weight, it is possible to manufacture the RC and PSC girder 100 having a smaller cross-sectional size.

In addition, the upper internal steel 110 is protruded from the RC and PSC girder 100 so as not to exceed the end surface of the RC and PSC girder 100, the tensile force is introduced more easily when tightened by a nut member, the upper internal steel The steel bar may be used to form a thread, and when the coupler is formed with a thread, rebar or PC strand may be used.

In addition, it is desirable to minimize the spacing of the upper inner steel material 110, and preferably to be concentrated close to the abdomen formed in the lower portion of the groove 120 of the RC and PSC girder 100. As such, when the upper inner steel is placed in the RC and PSC girder 100, it is possible to prevent the breakage of the thin portion outside the upper flange of the RC and PSC girder 100 due to the tensile force, and to secure sufficient coating thickness. You can do it. In addition, it is possible to reduce the thickness of the horizontal member 210 of the sequencing means 200 to be continuous by connecting the upper inner steel (200). A plurality of upper inner steels are installed in consideration of the width of the upper flange of the RC and PSC girder 100 and the like.

Thereafter, as shown in Figure 2c so that the lower end surface of the groove 120 of the RC and PSC girder 100 can be connected to each other before the slab concrete to be compressed by the slab concrete weight when placing the slab concrete 300 Install the connecting wall 400, diaphragm or partition wall. The barrier rib may generally use concrete or non-contraction mortar, but is not limited thereto.

After the connection wall 400 is formed, as shown in FIG. 2D, the upper internal steel material 110 having the thread formed therein is fastened so that the tensile force is introduced into the horizontal member of the sequencing means 200 by using the nut member 230. It is preferable to use a washer at this time.

When the sequencing of the upper inner steel 110 is completed using the sequencing means 200 as described above, the slab concrete (310, deformed rebar, etc.) is laid as shown in FIG. 100 is integrated with slab concrete. As a result, in the present invention, the integrated slab and the RC and PSC girder 100 can resist the bridge rails formed on the slab, the secondary dead loads such as the paving layer, and the live loads such as the traffic loads.

At this time, the slab steel 310 does not support the slab concrete weight, but acts as a tensile reinforcement for the parent portion of the point with the upper inner steel 200 for the secondary dead and live loads.

The slab concrete is filled in the groove 120 formed in the RC and PSC girder 100, integrated with the RC and PSC girder 100 and the connecting wall to integrally resist the secondary dead and live loads, so construction and quality control It should be noted that

According to the present invention, in the continuous construction of bridge girders such as RC and PSC girders over multiple spans, RC and PSC girders are designed to continuously cross RC and PSC girders before placing slab concrete, thereby enabling more efficient cross-sectional design of RC and PSC girders. It is possible to reduce construction cost and shorten the air through the manufacture of girder, and it is economical and constructable because it does not need a separate prestressing anchorage for continuity of RC and PSC girder, and it is the same by using optimized RC and PSC girder. It is possible to build bridges between long and long, and even lower bridges can be constructed between the same sites.

Claims (12)

delete delete In constructing the bridge girders in a continuous beam method over a multi span, A high-strength steel that penetrates the groove and the upper portion formed through the end of the block and protrudes toward the groove, or has a thread formed at the end. Bridge girder including the upper inner steel protruding into the bridge upper structure, The upper inner steel of the bridge girder is connected to each other so that the tensile force is introduced into the upper inner steel by using the sequencing means to sequentially bridge each girder and then to form the slab concrete on the continuous bridge girder Bridge sequencing method. 4. The bridge sequencing method according to claim 3, wherein the continuity means is arranged to be close to the abdomen of the bridge girder. 4. The bridge sequencing method according to claim 3, wherein a connecting wall for connecting portions other than grooves formed at the ends of each bridge girder to each other before the slab concrete is formed is further formed between the bridge girders. 4. The method according to claim 3, wherein the position where the upper inner steel material and the continuity means of the bridge girder are formed is a portion of generating a parent moment in the continuous beam. According to claim 3, wherein the end portion of the upper inner steel is formed with a thread and the end penetrating the horizontal member is supported by the horizontal member of the continuous means by the nut member is fastened by the tensile force is introduced into the upper inner steel Bridge sequencing method. The method of claim 3, wherein the serialization means, Each end of the upper inner steel to be connected to each other is fixed, the horizontal member is installed in a direction perpendicular to the upper inner steel; And A vertical member connecting the horizontal members to each other; It includes, The horizontal member and the vertical member is a continuous bridge method, characterized in that formed integrally or assembled with each other. The method of claim 8, wherein the horizontal member and the vertical member is connected to each other by overlapping each other in a lattice form of the horizontal member and the vertical member formed of a plate, or the rod-shaped rod-shaped end portion in the horizontal member which is a plate Bridge member continuous method characterized in that the vertical member is connected to each other by a nut member to connect the horizontal member and the vertical member. 9. The method of claim 8, wherein the fixing of the upper inner steel material forms a screw thread at an end of the upper inner steel material and fixes the upper inner steel material having the screw thread through a hole formed in the horizontal member. 11. The method of claim 10, wherein the hole of the horizontal member is a hole formed directly in the horizontal member or formed by integrally forming the horizontal member and the vertical member divided into the lower and the upper and formed by the combination of the groove formed in each of the lower and upper Bridge sequencing method, characterized in that. The method of claim 8, wherein the fixing of the upper inner steel, the upper inner steel is formed by forming a thread at the end of the upper inner steel and the upper inner steel is inserted into the guide groove connected to the hole formed in the horizontal member Bridge continuation method, characterized in that fixed to be located.

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