KR0171484B1 - Launching scaffold for setting slab form of bridge - Google Patents

Abstract

Mounting the PC beam between the bridges and installing the formwork and ridges for placing the main slab on the upper part and the sidewalk slabs on both sides of the main slab with concrete, In order to be able to work quickly and quickly, workers are provided on both sides of the PC beam to provide a work platform for laying the formwork and clubs, but the steel frame around the PC beam in the direction crossing the PC beam to support the work platform A structure is connected to form a main body, and a roller is installed at a lug base of the main body to provide a conveying means for moving the main body on a rail provided on an upper portion of the main slab as the roller is driven. In the case of passing through, opening means for opening the lower steel structure to the hinge portion axis And, the upright on the upper portion of the upper steel frame structure of the body, and offer the die and the upper die mounting slabs movable scaffolding of a bridge, characterized by yirueojim by installing a crane to transport the materials for Shore hypothesis.

Description

Mobile scaffolding for installing the upper slab formwork on the bridge

1 is a longitudinal cross-sectional view showing the overall configuration of a mobile scaffold for installing upper slab formwork of a bridge according to the present invention.

Figure 2 is a longitudinal sectional view showing a conveying means according to the present invention.

3 is a schematic configuration diagram illustrating a construction method of a bridge according to the prior art.

[Industrial use]

The present invention relates to a movable scaffold for installing a slab girdle of a bridge of the present invention, and more particularly, in forming a slab by placing concrete on an upper portion of a bridge, so that an operator can ride and install the slab forming formwork. A mobile scaffold provided.

[Prior art]

As is well known, a number of publicly known methods have been proposed as methods for constructing bridges such as railway bridges, road bridges, and bridges.

As one of these methods, the conventional method installs a pier spaced by a certain distance on the ground, mounts a PC (Pre-concrete) beam between the bridges, and installs slabs with concrete on the top. .

More specifically, FIG. 3 illustrates a method of constructing a bridge related to the above-described prior art, which will be described below with reference to this drawing.

Reference numeral 1 in the drawing denotes a pier, and a PC beam 3 is mounted on the upper portion of the pier between other pier not shown.

Here, the upper part of the PC beam (3) is provided with a glove (5) as a base on which the rail of the roadway or railway will later be placed, and the slab (5) includes wing parts (51) on both sides to be used for sidewalks later. This slab (5) is to be poured as a concrete.

On the other hand, in order to pour the slab (5) with concrete, the formwork 7 and the copper bar (9) for supporting it are installed on both sides of the PC beam (3), which is done by hand one by one.

To realize this, scaffolds 11 are installed on both sides of the base of the PC beam 3, which is temporarily installed for use as a scaffold when the worker installs the formwork 7 and the club 9. Lose.

As described above, after the worker installs the formwork 7 and the club 9, the reinforcing bar 13 is placed on the upper side of the PC beam 3, and then concrete is poured by the pump car 15. After a certain period of time, when the curing of the concrete is completed, the formwork (7), the club (9) and the scaffold (11) temporarily installed are dismantled, which is done by hand as in the installation company.

[Problem trying to solve the invention]

However, the problem associated with the above-described prior art is that in order to install the slab formwork 7 or the club 9, the first step is to install a scaffold 11 that allows the worker to go up and perform the construction work.

Here, the scaffold 11 described above is to tie the steel pipe to the PC beam (3) using the iron wire, and to construct the scaffolding and railings manually by using plywood and rope on the upper side, such a construction work safety accident Not only does it always carry a risk, but it also causes air delay and waste of unnecessary materials.

That is, since the above-mentioned scaffold 11 is temporarily installed by hand, the work space is narrow and the structure is poorly installed. When climbing to the scaffold 11 and installing the formwork 7 and the club 9, it falls. The risk of

In addition, in order to install the scaffold 11, a material such as a steel pipe or plywood is required, and a large amount of loss occurs due to the fall of the material during dismantling.

In addition, since the scaffold 11 has to be directly installed by a worker at a high place, the work is complicated and difficult, resulting in air delay.

[Means to solve the problem]

The present invention has been made in order to solve the above problems of the prior art, the purpose is to install the scaffolding to install the formwork and slabs for slabs, even without temporarily installing them manually, the operator boarded the PC beam It is to provide a mobile scaffold for the installation of the upper slab formwork of a bridge to move safely along the road.

Accordingly, the present invention mounts the PC beam between the bridge, and the formwork and the copper bar to install the main slab and the sidewalk slab on the both sides of the concrete as the concrete, the worker on both sides of the PC beam A work platform for placing the formwork and the flat boarding on board is provided, and the work platform is connected to the upper steel structure crossing the upper side of the PC beam, and hinged to the end of the upper steel structure supporting the work benches on both sides. The lower steel structure which extends in the direction crossing the lower side of the PC beam is opened and closed to form a main body, and a roller is installed on the base of the lug provided to support the main body, thereby driving the roller. It has a conveying means for moving the main body along the rail provided on the upper portion of the main slab, the main body When passing through the pier, the hinge portion has an opening and closing means for moving the lower steel structure to open the axis, and upright on the upper steel structure of the main body, to transport the formwork and copper cladding material We propose a mobile scaffold for installing the upper slab formwork of a bridge including a crane.

EXAMPLE

DESCRIPTION OF THE PREFERRED EMBODIMENTS A preferred embodiment of the present invention will be described below in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram showing a mobile scaffold for installing an upper slab formwork of a bridge according to the present invention, wherein reference numeral 3 in the drawing shows a PC beam mounted between the bridges.

The main slab 50 is installed on the upper part of the PC beam 3 as a base on which a roadway or railway rail is to be placed. On both sides of the main slab 5, the sidewalk slab 53 to be used for the sidewalk is provided. Is poured as concrete.

Here, the mobile scaffold of the present invention is to form the main slab 50 and the sidewalk slab 53 on both sides of the main slab 50 to the upper side of the PC beam (3) and the club ( In the construction of 9), it is possible to provide an activity space for the worker to ride and move along both sides of the PC beam 3 to work safely and quickly.

In order to realize this, the mobile scaffold of the present invention is to install the work platform 21 on both sides of the PC beam (3), the work platform 21 is a footrest 23 and the operator can move up, and safety The railing 25 is considered.

As the supporting means of the work table 21 described above, an upper steel structure 27 is provided which crosses the upper side of the PC beam 3 and is bent downward at both ends to form a substantially 'c' shape. The work bench 21 is supported inward, that is, facing the PC beam 3.

In this case, the upper steel frame structure 27 is assembled by a plurality of flat steel or c-shaped steel bar, the description thereof will be omitted.

The lower steel structure 29 is hinged to both ends of the upper steel structure 27 described above, which extends in a direction transverse to the lower side of the PC beam 3 and the ends thereof are fastened to each other. At this time, the bracket 33 is installed at the ends of both lower lower steel structure 29, it is coupled through the coupling pin 35.

Therefore, the lower steel structure 29 is opened and closed in both directions around the hinge portion 31 when the locking pin 35 is released. This opening and closing operation is provided with a separate opening and closing means, which is realized by the hydraulic cylinder 37 is fixed to the upper steel structure (27).

More specifically, the hydraulic cylinder 37 is hinged to the upper steel structure 27, because the piston rod 39 drawn out from the hydraulic cylinder 37 is hinged to the lower steel structure (29) When the hydraulic cylinder 37 is operated, the lower steel frame structure 29 is moved around the hinge portion 31.

On the other hand, the operation of the hydraulic cylinder 37 is controlled by the hydraulic controller and the hydraulic motor bar, which is a known technique, further description thereof will be omitted.

As described above, the powder composed of the upper steel frame structure 27 and the lower steel frame structure 29 supporting the work table 21 is conveyed along the PC beam 3 placed between the piers.

In this case, the main body is supported by a lug 41 installed below the upper steel frame structure 27, and a roller 43 is installed at a base thereof, and a rail 45 provided above the PC beam 50. It is possible to flow on the

Here, the main body is moved on the rail 45 as the roller 43 is driven, and the conveying means for realizing this will be described later with reference to the drawings.

In addition, the fall prevention roller 47 is provided on the outer steel frame structure 29 in contact with the lower surface of the PC beam 3, which is provided to prevent shaking during the movement of the main body.

The crane 55 is installed upright on the upper portion of the upper steel frame structure 27 of the main body described above. The crane 55 is installed for transporting the formwork 7 and the conduit 9, and its construction is as known in the art.

In the drawings, reference numeral 57 denotes a ladder, which is provided as a worker's passage.

2 is for driving the mobile scaffold according to the present invention, which shows the transfer means of the main body.

As stated, the upper steel structure 27 of the body is seated on the rail 45 via the lug 41 and the roller 43, the transfer means of the present invention is the roller 43 The main body is moved by driving.

More specifically, the rotating shaft 61 of the roller 43 is supported by the lug 41 via a bearing (not shown), and the first sprocket 63 is mounted on one end of the rotating shaft 61.

On the other hand, the above-described upper steel structure 27, the drive motor 65 is installed, the second sprocket 67 is rotated by the drive motor 65 is a bracket (on the lower surface of the upper steel structure 27) It is connected via the chain 75 and the 3rd sprocket 73 of the drive shaft 71 which is fixed so that the movement is possible through 69.

The fourth sprocket 79 is mounted on both ends of the above-described drive shaft 71, which is connected to the first sprocket 63 via the chain 77, and thus the drive motor 65 mentioned above. ) Is transmitted to the roller 43 described above.

Therefore, the transfer means according to the present invention is automatically moved in accordance with the operation of the drive motor 65, the drive motor 65 is operated by an operation panel not shown. In addition, the drive motor 65 is also possible to operate by a remote controller, which is a well-known technique will be omitted description.

Referring to the operation of hypothesizing the slab formwork 7 and the copper bar 9 supporting the same by the mobile scaffold of the present invention having the above-described configuration is as follows.

That is, the mobile scaffold according to the present invention has a main slab 50 on which a rail of a roadway or a railroad is to be placed on the upper side of the PC beam 3 mounted on the piers, and the sidewalk slabs 51 on both sides of the main slab 50. In order to place the formwork (7) and clubbing (9) for placing.

In order to realize this, the mobile scaffold according to the present invention is mounted by a crane (not shown) to be seated on the rail 45 on the PC beam 3.

When the mounting of the mobile scaffold is completed, the above-described driving motor 65 is operated to move the work bench 21 mounted on the main body to the formwork position. At this time, by operating the crane (55) upright on the upper steel frame structure 27 of the main body to transport the formwork 7 and the copper bar (9) installation material to the work table (21).

Therefore, the worker who climbed up the said work bench 21 only needs to install the formwork 7 and the installation material for the 9 in both sides of the PC beam 3, and the like.

Subsequently, the main slab 50 is formed by pouring concrete on the upper side of the PC beam 3 to form a main slab. After curing of the main slab 50 is completed, the concrete is further formed in the form 7. By pouring the slab 51 to form a press.

After curing of the sidewalk slab 51 is completed, the formwork 7 and the club 9 are dismantled again, which is transported to the upper part of the main body by a crane 55 unlike the conventional one, which continues It is transported to the next working position and used to repeat the above operations.

On the other hand, the above-mentioned mobile scaffold is sealed to the pier during transfer to the next working position, wherein the lower steel structure 29 of the present invention is opened by the opening and closing means and closed again after passing through the pier.

[Effects of the Invention]

As in the embodiment described above, the mobile scaffolding installation of the upper slab formwork of the bridge according to the present invention, unlike the conventional one by one manual installation, while the worker moves along the PC beam to work safely and quickly Able to know.

In other words, the mobile scaffold according to the present invention does not need to install a separate scaffold to install the formwork or copper bar. Therefore, it is possible to substantially eliminate safety accidents, air delays and waste of unnecessary materials that may occur when the scaffold is manually installed.

In addition, the mobile scaffold according to the present invention can be moved quickly, and facilitates the operator's activities not only contribute to shortening the air, but also ensures the safety of the operator.

Claims (4)

In laying down the main slab on which the rail of the driveway or railway will be placed on the upper side of the PC beam mounted on the pier, and the formwork and the copper bar for placing the sidewalk slabs on both sides of the main slab; A workbench installed at both sides of the PC beam for the operator to install the formwork and the club; A lower steel structure supporting the workbench and having an upper steel structure crossing the upper side of the PC beam, hinged to an end of the upper steel structure and extending in a direction across the lower side of the PC beam to be opened and closed. A main body composed of; A conveying means installed at a base of a lug provided to support the main body, and moving the main body along a rail provided at an upper portion of the main slab by driving the roller; When the main body is to pass through the piers, removable scaffolding for installing the upper slab formwork of the bridge, characterized in that it comprises an opening and closing means for opening the lower steel structure to the lower axis. The mobile scaffold according to claim 1, wherein a crane is installed on the upper part of the upper steel structure of the main body to transport the formwork and the material for installing the flat barb. According to claim 1, The transfer means is connected to the third sprocket via a chain between the drive motor is installed on the upper steel structure and the second sprocket directly connected to the drive motor, the bracket on the lower surface of the upper steel structure The first sprocket is connected via a chain between the drive shaft which is rotatably supported by the drive shaft and the fourth sprocket provided at both ends of the drive shaft, and is composed of a rotation shaft fixed integrally with the roller 43. A mobile scaffold for the installation of upper slab formwork on a bridge. The method of claim 1, wherein the opening and closing means is a hydraulic cylinder hinged to both sides of the upper steel structure, the piston rod drawn out downward from the hydraulic cylinder and hinged to the lower steel structure, and rotates the upper steel structure and the lower steel structure A movable scaffold for installing an upper slab formwork of a bridge, characterized in that it is composed of a hinge portion to be supported, and fastening pins that characterize the distal ends of both lower steel structures.