KR100964155B1 - A precast deck slab of a bridge - Google Patents

Abstract

The present invention basically prevents the occurrence of the bending moment of the precast deck when lifting, to quickly mount the lifted precast deck on the girder of the piers, precast deck on the girder of the piers It is an object of the present invention to provide a precast deck for bridges with lifting aids that can be reused for lifting the other precast deck after removing the warpage means from the deck.

Bridge precast deck according to the present invention for achieving the above object is disposed on the upper side of the precast deck to prevent bending to prevent the occurrence of the bending moment generated during the lifting of the precast deck Means; A plurality of fixing means for detachably coupling the precast sole plate and the anti-bending means to each other and fixing the anti-bending means to the precast sole plate; And a plurality of wire hangers formed on any one of the bending preventing means and the fixing means and the precast bottom plate such that a lifting wire for lifting the precast bottom plate is connected.

Bridge, Precast, Deck, Lifting, Bending Moment, Horizontal

Description

A precast deck slab of a bridge with lifting aids

The present invention relates to a precast deck for bridges, and more particularly, to prevent the occurrence of bending moments of the precast deck, during lifting, and to quickly mount the lifted precast deck on the girder of the bridge Bridges with lifting aids, which allow the precast deck to be placed on the girder's girder and then disengage the anti-bending means from the deck and re-use for re-lifting the other precast deck. It relates to a precast sole plate.

As shown in FIG. 1, a bridge using a general precast deck is provided in a width direction (A direction) of a bridge 20 over a plurality of bridges 20; 20a, 20b,... At least two girders 30 are arranged side by side, and the first step of arranging the two ends of the girders 30 so as to span the piers 20a and 20b facing each other.

Thereafter, after the first step, the second step of arranging the plurality of precast bottom plates 40 adjacent to each other in the longitudinal direction (B direction) on the girder 30.

Next, after proceeding to the second step, the construction is carried out by proceeding to the third step of packing with asphalt (not shown) on the precast bottom plate (40).

In the process of constructing the bridge as described above, the precast deck 40 is produced in advance by concrete pouring in the ground production site, the precast deck 40 is a separate crane (not shown) equipment, etc. After being lifted by it, it will be put on the girder 30.

In the related art, after the lifting wire is connected to the precast bottom plate 40 and installed, the lifting wire is connected to the ground using a lifting machine such as crane equipment.

More specifically, as shown in FIGS. 2 and 3, the precast bottom plate 40 is formed such that the lifting ring portions 41 are protruded, respectively, at positions adjacent to the upper edges of the precast bottom plate 40. After fabricating in advance, the lifting wires 42 are connected to the lifting ring portions 41, respectively, and the hook hooks 43 of the crane equipment are hooked to the lifting wires 42, and the precast floor is mounted using the crane equipment. The plate 40 is to be lifted from the ground.

However, according to the lifting method of the precast bottom plate 40 according to the prior art, as shown in Figure 3, the lifting ring portion 41 is integrally installed on the upper end side of both ends of the precast bottom plate 40 There is an advantage that the precast bottom plate 40 can be lifted in a horizontal state.

On the other hand, since the stress is concentrated on both ends of the precast sole plate 40, the bending moment in which the center of the precast sole plate 40 sags downwards as a virtual dotted line of the member number 40 'during the lifting process causes the bending moment to be rounded as a whole. There was a problem that occurred, even when lifting the precast bottom plate 40 in a bent state, there was also a problem that self-cracking caused by the sagging of the center of the precast bottom plate 40.

In order to prevent the precast bottom plate 40, which is the aforementioned problem, from bending, as shown in FIG. 4, the structure 70 and the precast bottom plate 40 disposed on the upper part of the precast bottom plate 40. Between)), connecting the lower ends of the intermediate lifting traction wires 60 to both sides and the center of the precast sole plate 40, respectively, and the upper ends of the intermediate lifting traction wires 60 to both sides of the structure 70. After connecting to the center and each, and then connecting the lifting wire 42 to the upper edge of the structure 70, hook hook 43 of the crane equipment to the lifting wire 42, precast using the crane equipment There is also a prior art in which the bottom plate 40 is lifted from the ground.

The prior art shown in FIG. 4 has the advantage of preventing bending moment generation of the precast sole plate 40 as shown in FIG. 3 and the precast sole plate 40 to be lifted while maintaining the horizontal state. There was an advantage, but there was a closed end to set the same length of the intermediate lifting traction wire 60 is installed at three points to maintain the precast bottom plate 40 in a horizontal state, the lifting machine such as a crane Due to the left and right flow of the intermediate lifting traction wire 60 while being mounted on the girder's girder, there is a closed end in which the precast bottom plate 40 is severely flowed from side to side with respect to the structure 70. There was a secondary problem that can not be carried out quickly to mount the cast bottom plate 40 in place of the girder.

The present invention was created to solve the above problems, basically prevents the occurrence of the bending moment of the precast deck when lifting, it is possible to quickly mount the lifted precast deck to the girder of the piers After the precast deck is placed on the girder's girder, the anti-bending means can be removed from the deck to provide a precast deck for bridges that can be reused to re-lift other precast decks. For the purpose of

Bridge precast deck provided with a lifting aid according to the present invention for achieving the above object is disposed on the upper side of the precast bottom plate is generated bending moment generated when the precast bottom plate lifting Warpage preventing means for preventing the water; A plurality of fixing means for detachably coupling the precast sole plate and the anti-bending means to each other and fixing the anti-bending means to the precast sole plate; And a plurality of wire hangers formed on any one of the bending preventing means and the fixing means and the precast bottom plate such that a lifting wire for lifting the precast bottom plate is connected.

According to the bridge precast deck provided with a lifting aid according to the present invention, the following effects can be expected.

First, according to the present invention, it is basically to prevent the occurrence of the bending moment of the precast deck when lifting, to quickly mount the lifted precast deck to the girder of the piers, and to the girder of the piers After the precast deck is completed, the anti-bending means can be removed from the deck and reused to re-lift other precast decks. It can be used in common when lifting.

Secondly, according to the present invention, the bending prevention means by simply configuring the fixing means for further minimizing the generation of the bending moment of the precast deck and the mutual coupling between the precast deck and the warpage prevention means There is an advantage that the fastening and separation between the precast bottom plate can be carried out quickly, and the fasteners of the fixing means can be installed together when manufacturing the precast bottom plate, thereby shortening the assembly and disassembly process of the fixing means. .

Third, according to the present invention, the number of lifting hangers on which the lifting wires are installed is optimized, and the length of the lifting wires is not limited to the set length. It can be implemented easily.

Fourth, according to the present invention, the left and right length extending a predetermined length to the left and right both ends on the basis of the area where the bending moment is generated, and the front and rear length extending to a predetermined length to both front and rear ends on the basis of the center of the precast bottom plate The length of the bending preventing means can be freely designed and can be used in common when lifting the precast flooring plate produced in various sizes with no large variation in appearance size.

Fifth, according to the present invention, by forming a forklift inlet through which the forklift of the forklift is introduced in the front and rear direction in the bending preventing means, it is possible to use a forklift when moving a short distance from the ground to another position.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the precast deck for bridges according to the present invention will be described in detail.

5 is an external perspective view of the precast deck according to the present invention, which shows a state before being mounted on the girder of the bridge, and FIG. 6 is a view showing the precast deck shown in FIG. 7 is a cross-sectional view showing the configuration of a wire loop coupled to a wire hanger formed on the bending preventing means for hanging the lifting wire, and FIG. &Quot; Front view in side view, showing another embodiment of the present invention.

Bridge precast deck according to the invention is provided with a lifting aid, as shown in Figures 5 and 6, the lifting aid is a bending preventing means 200, a fixing means 300, and a wire It comprises a hanger 500.

The bending preventing means 200 is disposed in an area where a bending moment generated during lifting of the precast bottom plate 100 is generated among the upper regions of the precast bottom plate 100, thereby preventing a bending moment from occurring. Do it. That is, it is disposed on the upper side of the precast bottom plate 100 serves to prevent the bending moment generated when the precast bottom plate 100 is lifted.

Here, in order to lift the precast sole plate stably in a horizontal state, it is preferable to fix both ends of the precast sole plate with a lifting wire, and then lift it using a machine such as a crane. The bending point in which the precast bottom plate is bent in the downward direction and the virtual dotted line 40 'is generated, and the portion where the bending moment is generated maximum increases toward the center of the precast bottom plate.

Therefore, in the present invention, the bending prevention means 200 is fixed to the precast bottom plate 100 in the bending moment maximum generation area among the bending moments, so as to act as a resistor so that bending moments are not generated. It is.

In addition, the present invention, the bending prevention means 200 is extended to a predetermined length to the left and right both ends on the basis of the center or the center of the precast bottom plate 100 which is the area where the bending moment of the precast bottom plate 100 is generated It is more preferable to extend and have the left and right length, and the front and rear length extending to a predetermined length to the front and rear both ends on the basis of the center of the precast bottom plate 100. That is, the present invention is installed to be limited to the central region of the precast bottom plate 100, the bending prevention means 200, the bending moment is generated to the maximum or in all directions around the central region of the precast bottom plate 100 By manufacturing the expanded size and fixed to the precast bottom plate 100, it is possible to suppress the occurrence of the bending moment.

And, as shown in Figure 5, the warp preventing means 200 may be formed in a size having a size substantially the same as the upper surface size of the precast bottom plate 100.

That is, when the precast floor plate 100 is made in a rectangular shape having a constant length and width, the warp preventing means 200 is also produced in a rectangular shape having a constant length and width, but correspondingly to prevent bending The length of the width and length of the means 200 is made into the rectangular shape substantially equal to the length of the width and length of the precast bottom plate 100, or the length of the length is slightly reduced.

As shown in FIG. 5, the warp preventing means 200 according to the present invention interconnects the beams of the “I” shape having a large area of the upper and lower horizontal plates 211 and 213 parallel to each other, and thus, the precast floor. Although the steel frame structure has a shape substantially similar to that of the upper surface of the plate 100, the present invention is not limited thereto and may be a structure capable of exerting resistance to the bending moment of the precast bottom plate 100.

On the other hand, the fixing means 300 according to the present invention is provided with a plurality as shown in the drawings, in more detail to be installed in a plurality at regular intervals in the horizontal direction of the precast floor plate 100. In the present invention, the four columns in the transverse direction of the precast floor plate 100 are spaced apart at regular intervals so as to be arranged in two rows, and are installed at points a, b, c, d, e, f, g, and h. . These fixing means 300 may be installed differently from each other, evenly installed to each other.

The fixing means 300 according to the present invention detachably couples the precast sole plate 100 and the anti-bending means 200 to each other, and fixes the anti-bending means 200 to the precast sole plate 100. In this case, the bending prevention means 200 is installed to be fixed in a state spaced apart from the precast bottom plate 100 by a predetermined interval or installed to be fixed in a state that is in contact with the upper surface of the precast bottom plate 100. In an embodiment of the present invention, the bending preventing means 200 may be installed to be fixed while being in contact with the upper surface of the precast bottom plate 100.

In addition, the wire hanger 500 according to the present invention, the bending prevention means 200 and the fixing means 300 and the precast bottom plate 100 so that the lifting wire 400 for lifting the precast bottom plate 100 is connected. It is formed in any one of).

5, 6, 7, the wire hanger 500 of the present invention is formed at the four edges of the bending preventing means 200, and more specifically, the upper portion constituting the bending preventing means 200. It is formed to protrude on the horizontal plate (210). That is, protruding at four points of positions I, J, K, and L, which are spaced apart by a predetermined distance from both ends of the central portion of the bending preventing means 200.

Here, the separation distance of the wire hangers 500 respectively installed at the I and K points is the same as the separation distance of the wire hangers 500 respectively installed at the J and L points, and the level is more reliably maintained when the precast deck 100 is lifted. The distance between the points I and K and the distance between the points J and L is more advantageous, and the center of the distance between the points I and K and the point between the points J and L are the centers of the precast deck 100. The distance between the point I and the point K from the center of the precast deck 100 is the same, and the distance between the point J and the point L from the center of the precast deck 100 is the same.

In the wire hanger 500, the installation hole 510 is formed to penetrate through the wire ring 530 in the center thereof.

As shown in FIGS. 5 and 7, the wire ring 530 has a ring body 520 bent in a ring shape with one side open so that the wire hanger 500 can be inserted therein, and the ring body 520. It penetrates the mounting holes 510 of both ends 521 and 522 and the wire hanger 500, and is screwed to either end of the both ends 521 and 522 of the ring body 520, the ring body 520 It is made to include a departure prevention member 523 to prevent the departure from the wire hanger 500.

Referring to the process of installing the wire ring 530 configured as described above are as follows.

First, the ring body 520 is inserted into the ring portion 410 formed at one end of the lifting wire 400, and then the wire hanger 500 is inserted into the opening 520a of the ring body 520. The separation preventing member 523 penetrates through both ends 521 and 522 of the ring main body 520 and the installation hole 510 of the wire hanger 500, and among both ends 521 and 522 of the ring main body 520. Screw on either end.

Here, an operation hole 523a is formed at one end of the release preventing member 523, and an operation lever (not shown) is inserted into the operation hole 523a to rotate the release preventing member 523. When the separation prevention member 523 is screwed to any one of both ends 521 and 522 of the ring body 520.

According to the present invention, the lifting wire 400 is installed on the wire hanger 500 formed at four points of I, J, K, and L by the above process. The lifting wire 400 is connected and installed, and the lifting wire 400 is connected to the wire hanger 500 formed at the J and L points, respectively.

Therefore, in the present invention, when installing two lines of the lifting wire 400, thereby hanging the two lines of the lifting wire 400 with the hook hook 700 of the crane equipment, the hook hook 700 of the two lines It is possible to change the position to hang the lifting wire 400.

Referring to the process of lifting the precast deck according to the invention configured as described above to be mounted on the girder (see Figure 1) of the piers (see Figure 1) as follows.

First, the bending prevention means 200 is fixedly installed on the upper part of the precast bottom plate 100 manufactured in the ground by the fixing means 300.

Thereafter, the lifting wire 400 is connected to the wire hanger 500 formed on any one of the bending preventing means 200 or the fixing means 300 and the precast bottom plate 100, and then the lifting wire 400 is connected to the crane. Hook on the hook hook 700 of the lifting equipment, such as to operate the crane to lift the precast floor plate 100 from the ground to be mounted on the girder of the piers.

Therefore, the present invention is basically because the bending prevention means 200 is disposed in the region where the bending moment generated when lifting the precast bottom plate 100 among the upper region of the precast bottom plate 100 is generated It is possible to prevent the occurrence of the bending moment of the precast floor plate 100 at the time.

In addition, the present invention is the precast bottom plate 100 is lifted because the precast bottom plate 100 is fixed to the bending prevention means 200 with respect to the bending prevention means 200, because they are connected to each other in a fixed state. ) Can be quickly mounted in position on the girder (see Figure 1) of the piers (see Figure 1).

On the other hand, in the present invention, since the fixing means 300 detachably couples the precast sole plate 100 and the bending preventing means 200 to each other, after the precast sole plate 100 is completed on the girder of the piers. The anti-bending means 200 can be separated from the bottom plate and reused to lift another precast bottom plate again, and the anti-bending means 200 according to the present invention is manufactured in various sizes in which the variation in appearance size is not large. At the time of lifting the precast bottom plate 100 can be used in common.

So far, the basic configuration of the present invention has been described. Hereinafter, the detailed structure of the components of the present invention will be described.

First, the fixing means 300 according to the present invention comprises a fastener 310, a fastening rod member 320, and a pressing member 330, 332 in a simple configuration.

Fixture 310 is provided with a screw hole 311 therein, and a plurality of support parts 312 on the outer surface, and is installed to be vertically buried in the interior of the precast bottom plate 100, screw hole 311 ) Is installed to be exposed to the upper surface of the precast bottom plate (100).

Fixture 310 according to the present invention bar is installed together during the production of the precast bottom plate 100, by arranging the fixture 310 in advance in the formwork (not shown) for manufacturing the precast bottom plate 100 When the concrete is solidified after curing, the fixture 310 is installed to be buried inside the precast floor plate 100.

Fastening rod member 320 according to the present invention penetrates the bending preventing means 200 up and down, the lower end side is screwed into the screw hole 311 of the fixture 310, the threaded portion 321 is formed on the outer peripheral surface.

The pressing members 330 and 332 according to the present invention are provided on the fastening rod member 320 and serve to press the bending preventing means 200 to be in contact with the upper surface of the precast bottom plate 100. .

In a more detailed embodiment of the fixing means 300 according to the present invention, the upper end of the fastening rod member 320 is formed to protrude to the upper side of the bending preventing means 200, the pressing member 330 is the bending preventing means The upper surface of the fastening rod member 320 is formed in the shape of a bolt head portion to press the upper surface of the 200. (Fixing means first embodiment)

Here, the reason why the pressing member 330 is formed in the shape of a bolt head is, by rotating the fastening rod member 320 with a work tool such as an operation wrench so that the lower end is screwed into the screw hole 311 of the fixture 310. This is to facilitate the coupling of the operation wrench.

In addition, in another embodiment of the fixing means 300 according to the present invention, the bending preventing means 200 so that the fastening rod member 320 of the portion penetrated into the inside of the bending preventing means 200 is visible from the side. It has a horizontal groove portion 210 that is open to the side, the pressing member 332 is located in the horizontal groove portion 210 and then press the bottom surface 212 that is the upper surface of the lower horizontal plate 213 of the horizontal groove portion 210 It is configured to form a nut screwed to the fastening rod member 320 so as to constitute. (Second embodiment of the fixing means) Here, the length of the fastening rod member 320 in the configuration to explain the second embodiment of the fixing means By using a short, the bolt head-shaped pressing member 330 may be positioned above the upper horizontal plate 211 constituting the horizontal groove 210.

In addition, the present invention constitutes a fixing means 300 to which both the pressing members 330 and 332 described in the first and second embodiments described above are applied, thereby preventing bending on the precast base plate 100. The means 200 more securely couples.

In addition, between the pressing member 330 and the upper surface of the bending preventing means 200, the auxiliary pressing nut member 331 may be interposed on the outer surface of the fastening rod member 320 by screwing.

On the other hand, the bending prevention means 200 according to the present invention by forming a forklift inlet 250 through which the forklift 900 of the forklift is introduced in the front and rear direction, by using a forklift or a forklift when moving a short distance from the ground to another position. It can be used to load the precast bottom plate 100 or to cast the precast bottom plate 100 in concrete and then demolished in the formwork after solidification, to prevent bending corresponding to the fork inlet 250 The strength reinforcing member 270 is further provided on the upper surface of the means 200.

In other words, when the precast bottom plate 100 is to be loaded, the precast bottom plate 100 is lifted up by a forklift, moved to a loading position and loaded, and then the fixing means 300 is separated to prevent bending means ( After the coupling state between the 200 and the precast bottom plate 100 is released, only the bending prevention means 200 is moved back to the forklift and placed on the upper surface of the next precast bottom plate 100 to be loaded, and then fixed. Using the means 300 repeats the sequence of coupling the warp preventing means 200 and the precast bottom plate 100 to each other.

In addition, in the case where the precast bottom plate 100 is to be demolded from the formwork, the fastener 310 constituting the fixing means 300 of the present invention is precast bottom plate (when forming the precast bottom plate 100). 100 is manufactured to be buried in the interior, only the screw hole 311 is made to open to the upper surface, and after the concrete constituting the precast bottom plate 100 is completely solidified, the rest of the fixing means except the fixture 310 By fixing the bending prevention means 200 to the upper surface of the precast bottom plate 100 using the configuration of the 300, it is possible to demould the molded precast bottom plate 100 from the formwork.

In addition, the present invention does not constitute the wire hanger 500 as described above, and as shown in FIG. 8, the fastening rod member 320 constituting the fixing means 500 at both ends of the lifting wire 400. Of course, it can be formed to be integral to the upper portion of.

In addition, although the present invention shows an example of fixing the bending preventing means 200 in contact with the upper surface of the precast bottom plate 100, the bending preventing means 200 is extended by extending the length of the fastening rod member 320. Of course, it can be configured to be fixed in a state spaced apart from the upper surface of the precast bottom plate 100 by a predetermined height.

1 is a perspective view showing a construction state of a conventional precast bridge deck.

Figure 2 is a perspective view showing an example showing a method of lifting a precast bottom plate according to the prior art.

3 is a front view of FIG. 2;

Figure 4 is a perspective view showing another example showing a method of lifting a precast bottom plate according to the prior art.

5 is an external perspective view of the precast deck according to the present invention, showing a state before being mounted on the girder of the bridge;

FIG. 6 is a front view of the frcas bottom plate shown in FIG. 5 as viewed from the side in the direction of the leader line “A”; FIG.

Figure 7 is a cross-sectional view showing the configuration of the wire hook coupled to the wire hanger formed in the bending preventing means for hanging the lifting wire.

FIG. 8 is a front view of the frcas bottom plate shown in FIG. 5 viewed from the side in the direction of the leader line “A”, showing another embodiment of the present invention; FIG.

100: precast bottom plate 200: bending prevention means

210: horizontal groove 250: forklift inlet

300: fixing means 310: fixture

311: screw hole 312: support

320: fastening rod member 330,332: pressure member

400: lifting wire 500: wire hanger

Claims (7)

A bending prevention means (200) disposed on an upper side of the precast bottom plate (100) to prevent a bending moment generated when lifting the precast bottom plate (100); A plurality of fixing means 300 for detachably coupling the precast bottom plate 100 and the bending prevention means 200 and fixing the bending prevention means 200 with respect to the precast bottom plate 100. )and; A plurality of bending prevention means 200 and the fixing means 300 and any one of the precast bottom plate 100 to be connected so that the lifting wire 400 for lifting the precast bottom plate 100 is connected Bridge precast bottom plate provided with a lifting aid, characterized in that comprises a wire hanger (500). The method of claim 1, The fixing means 300, A screw hole 311 and a plurality of support parts 312 are provided on an outer surface thereof, and are installed to be vertically buried in the precast bottom plate 100, wherein the screw hole 311 is precast. A fixture 310 installed to be exposed to an upper surface of the bottom plate 100; A fastening rod member 320 which is screwed into the screw hole 310 of the fixture 310 by penetrating the bending preventing means 200 upward and downward, and having a screw portion on an outer circumferential surface thereof; It is provided on the fastening rod member 320, including the pressing member 330, 332 for pressing the bending preventing means 200 to be in contact with the upper surface of the precast bottom plate 100 Precast deck for bridges with lifting aids. The method of claim 2, The upper end of the fastening rod member 320 is formed to protrude to the upper side of the bending preventing means 200, The pressing member 330 is a precast floor for a bridge provided with a lifting assistance device, characterized in that formed in the shape of a bolt head on the upper end of the fastening rod member 320 to press the upper surface of the bending preventing means (200) plate. The method of claim 2, The bending preventing means 200 is provided with a horizontal groove portion 210 that is open to the side so that the fastening rod member 320 of the portion penetrated into the bending preventing means 200 is visible from the side. The pressing member 332 is located in the horizontal groove portion 210 is characterized in that it is formed in the shape of a nut screwed to the fastening rod member 320 to press the bottom surface 212 of the horizontal groove portion 210 Precast deck for bridges with lifting aids. The method of claim 1, The wire hanger 500, Bridge precast bottom plate provided with a lifting aid, characterized in that formed protruding at the four edges of the bending preventing means (200). The method of claim 1, The bending preventing means 200, Left and right lengths that extend a predetermined length to both left and right ends on the basis of a region where the bending moment of the precast bottom plate 100 is generated, and are fixed to both front and rear ends on the basis of the center of the precast bottom plate 100. A precast floor plate for a bridge provided with a lifting aid, characterized in that it has a length before and after extending. The method according to any one of claims 1 to 6, The bending prevention means 200 is a precast bottom plate for a bridge provided with a lifting assistance device, characterized in that the forklift inlet 250 is formed in which the forklift of the forklift is introduced in the front and rear direction.

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