KR20090043932A - Self-launching movable scafolding system - Google Patents

Abstract

The present invention, for the construction of a girder installed on the bridge top of the bridge, the main frame is arranged long in the longitudinal direction of the girder; A plurality of side trusses installed at both sides of the main frame at predetermined intervals along the longitudinal direction of the girder, respectively; A suspension beam slidably coupled to each side truss in a width direction of the girder; An out frame coupled to each of the suspension beams by a frame support member and used as an outer formwork of the girder; And an inner frame installed at an upper portion of the out frame and used as an inner formwork of the girder;

The nose is a truss structure extending in the direction of the support structure in the support structure, the upper end is installed so as to be movable in the longitudinal direction of the girder with respect to the support structure and the nose, the lower end of the supporting structure A first support bracket mounted on a pier to transfer loads of the support structure and the nose to the pier, and an upper end of the support structure being installed to be movable in the longitudinal direction of the girder, and a lower end mounted on a pre-installed girder; And a second support bracket for transferring the load of the support structure and the nose to the piers, and fixed to an upper portion of each of the first support bracket and the second support bracket to be movable together with the first support bracket and the second support bracket. To move the support structure and the nose in the girder direction and the vertical direction A first leg coupled to the front end of the nose to be mounted to a launching wagon, a piers positioned forward in the traveling direction of the support structure, and a portion of the load of the support structure coupled to the rear end of the support structure; It provides a self-launching movable formwork, characterized in that it comprises a second leg for transmitting to the piers.

Description

Self-launching Movable Scafolding System

The present invention relates to a self-launching moveable formwork, and more particularly, to a self-launching mover formwork having an improved structure to be used more universally than the conventional self-launching mover.

Movable Scafolding System (MSS) refers to a structure that constructs a structure while continuously moving the formwork forward by using power such as hydraulic pressure. Mainly used in the construction of the bridge girders, there is an advantage that the air is shortened a lot compared to the case of installing and dismantling the formwork separately.

Self-launching mobile formwork means a mobile formwork for moving the formwork forward using a configuration installed together with a movable formwork such as a hydraulic jack, not an external structure such as a crane.

In general, a cross section of a bridge girder that is commonly used has a box type or a double tee type as shown in FIG. 1B as shown in FIG. 1A, and a strut type girder cross section is used recently as shown in FIG. 1C. This is because the type girders can be constructed in a wider width than the box girders or double tee girders. This means that the bar 1 shown on the cross section bears a part of the load so that a wider girder can be constructed.

Various types of movable formwork have been developed and used until now, but the conventional movable formwork is suitable for box or double tee type girder construction, but in the case of strut type girder section, the structure of the movable formwork and the bar (1) There was a problem that the construction is impossible due to the interference problem.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide a self-launching movable formwork that can be constructed regardless of the shape of a girder cross section such as a box type, a double tee type, a strut type, and the like.

In order to achieve the above object, the present invention,

As for the construction of the girder installed in the upper part of the bridge,

A main frame disposed to extend in the longitudinal direction of the girder;

A plurality of side trusses installed at both sides of the main frame at predetermined intervals along the longitudinal direction of the girder, respectively;

A suspension beam slidably coupled to each side truss in a width direction of the girder;

An out frame coupled to each of the suspension beams by a frame support member and used as an outer formwork of the girder; And

A support structure including an inner frame installed at an upper portion of the out frame and used as an inner formwork of the girder;

A nose that is a truss structure extending in the direction of travel of the support structure to the support structure;

The upper end is installed to be movable in the longitudinal direction of the girder with respect to the support structure and the nose, the lower end is mounted on the pier on the traveling side of the support structure to transfer the load of the support structure and the nose to the pier. The first support bracket,

A second support bracket mounted on the support structure so as to be movable in the longitudinal direction of the girder, and a lower end mounted on a pre-installed girder to transfer loads of the support structure and the nose to the piers;

It is fixed to the upper portion of each of the first support bracket and the second support bracket is movable with the first support bracket and the second support bracket, launching for moving the support structure and the nose in the girder direction and the vertical direction Wagon,

A first leg coupled to the front end of the nose to be mounted on a pier located forward in the traveling direction of the support structure;

And a second leg coupled to the rear end of the support structure to transfer a portion of the load of the support structure to the piers.

The first support bracket includes a bracket body and a support leg detachably coupled to the bracket body,

It is preferable that the lower end of the support leg is mounted on the upper portion of the pier.

A rail extending from the rear end of the support structure to the front end of the nose and a trolley movable along the rail,

Preferably, the first support bracket, the second support bracket, and the launching wagon are moved by the trolley.

As described above, according to the present invention, it is possible to provide a self-launching movable formwork capable of construction regardless of the shape of the girder cross section, such as box type, double tee type, strut type, and the like.

Hereinafter, one embodiment of the present invention will be described with reference to the drawings.

2 is a side view of a self-launching movable formwork according to an embodiment of the present invention, Figure 3 is a cross-sectional view of the line III-III shown in Figure 2, Figure 3a is a main frame and the structure coupled to the main frame shown in Figure 3 3B is a diagram illustrating a state in which the suspension beam is moved to both sides in the state illustrated in FIG. 3.

Self-launching movable formwork according to this embodiment is for the construction of the girder installed on the pier top of the bridge, the support structure, the nose 60, the first support bracket 70, the second support bracket 80, the launching wagon ( 90), the first leg 100, the second leg 110, the trolley 120.

The support structure includes a main frame 10, a side truss 20, a suspension beam 30, an out frame 40, and an inner frame 50.

The main frame 10 is arranged long in the longitudinal direction of the girder.

As shown in FIG. 3, the side truss 20 is installed above the main frame 10. The side truss 20 functions to support the suspension beam 30.

The suspension beam 30 is coupled to the side truss 20, so as to slide in the width direction of the girder.

The suspension beam 30 is coupled to each side truss 20, since the side truss 20 is coupled to both sides of the main frame 10, the suspension beam 30 is also spaced along the longitudinal direction of the girder. Is installed.

Both side trusses 20 form a hexagon in which the cross section is closed in a state of moving in a direction approaching the main frame 10.

The out frame 40 is coupled to the suspension beam 30 by a frame support member 41 and used as an external formwork for constructing a girder. The frame support member 41 generally uses a turnbuckle, and in this embodiment also uses a turnbuckle. The part indicated by the reference numeral 1 on the drawing is for supporting the girder.

The inner frame 50 is used as an internal formwork for constructing the girder.

Reinforcing bars are disposed between the inner frame 50 and the out frame 40, and concrete is poured. Reinforcement of the reinforcement of the reinforcement and concrete is a technique that can be fully understood by those of ordinary skill in the art to which the present invention will no longer be described in detail.

The nose 60 is configured to be coupled to the support structure, and extends and is coupled to a traveling direction of the support structure, that is, the right side of FIG. 2.

A rail 121 and a trolley 120 are installed at the support structure and the nose 60, and the rail 121 extends from the rear end of the support structure to the front end of the nose 60. The rail 121 is from the left end of the support structure shown in FIG. 2 to the right end of the nose 60 in the figure.

The first support bracket 70 is installed to be movable in the longitudinal direction of the girder with respect to the support structure and the nose 60 by the trolley 120.

The first support bracket 70 is composed of a bracket body 71 and a support leg 72 detachably coupled to the bracket body 71 at a lower portion of the bracket body 71.

The support leg 72, which is a lower structure of the first support bracket 70, is mounted on a pier located on the side of the support structure in the direction of travel, and transfers the load of the support structure and the nose 60 to the pier. .

The upper end of the second support bracket 80 is installed to the support structure to be movable in the longitudinal direction of the girder. The second support bracket 80 is also moved by the trolley 120 like the first support bracket 70.

The lower end of the second support bracket 80 is mounted on an already constructed girder and transmits the load of the support structure and the nose 60 to the piers.

The launching wagon 90 is fixed to an upper portion of the first support bracket 70 and the second support bracket 80 to move together with the first support bracket 70 and the second support bracket 80. It is possible to install.

The launching wagon 90 may include a hydraulic device to move the support structure and the nose 60 in the longitudinal direction of the girder and to move the vertical direction in the vertical direction.

The first leg 100 is installed at the front end in the advancing direction of the support structure of the nose 60. A lower end of the first leg 100 may be mounted on the pier in the forward direction of the support structure, and transmits the load of the support structure and the nose 60 to the pier.

The second leg 110 is coupled to the rear end of the support structure, and transmits the load of the support structure to the piers.

The first support bracket 70, the second support bracket 80, the first leg 100, the second leg 110 by the load of the support structure and the nose 60 is transmitted to the piers and supported. In addition, the reinforcement between the reinforcement between the out frame 40 and the inner frame 50 and the load of the concrete is also transmitted. However, it is determined which configuration supports the load according to the construction stage of the girder, which will be described later.

Hereinafter, a method for constructing a girder of a bridge using the self-launching movable formwork of the above-described embodiment will be described in detail.

First, as shown in FIG. 2, the rear end portion of the supporting structure is supported by one side piers P1 by the second support bracket 80, and the front end portion is supported by the first support bracket 70 by the other side piers P2. Install the support structure and the nose (60) in a state supported by).

In this state, as shown in FIG. 3, the reinforcing bar is placed between the out frame 40 and the inner frame 50 and concrete is poured.

At this time, in order to prevent the support leg 72 of the first support bracket 70 from being immersed in the poured concrete, it is possible to install a leg hole, which is a square tube having a hollow in the vertical direction, to prevent the separation of the leg hole. The support leg 72 is positioned at the

When the concrete poured between the out frame 40 and the inner frame 50 is cured, the launching wagon until the second leg 110 approaches the second support bracket 80, as shown in Figure 4a. Use 90 to move the support structure and nose 60 forward.

When the support structure and the nose 60 are moved, the load is transmitted to the piers P1 and P2 by the first support bracket 70 and the second support bracket 80.

At this time, before moving the support structure and the nose 60 using the launching wagon 90, as shown in Figure 3a to move the support structure and the nose 60 downward, and again in the state shown in Figure 3a As shown in 3b, the suspension beam 30 is moved in both directions. The suspension beam 30 dismantles the frame support member 41 before the support structure moves.

When the second leg 110 is no longer able to move due to interference with the second support bracket 80, as shown in FIG. 4B, the second support bracket 80 is used by the trolley 120. To move in the direction of the first support bracket (70).

At this time, the load is transmitted to the piers (P1, P2) by the second leg 110 and the first support bracket (70).

When the movement of the second support bracket 80 is completed, the support structure and the nose 60 are moved forward by using the launching wagon 90 again, and the first leg installed at the front end of the nose 60 ( 100 until it is mounted on the front pier P3 in the direction of movement of the support structure. This shifted state is shown in FIG. 4C.

Next, the support leg 72 of the first support bracket 70 is dismantled from the bracket main body 71 and moved using a trolley to be fixed on the front pier P3 in the moving direction of the support structure. This is shown in Figure 4d.

At this time, the load by the supporting structure, the nose 60, the constructed girder is transmitted to the piers (P1, P2, P3) by the second leg 110, the first support bracket 70 and the first leg 100. do.

The next step is to move the bracket body 71 of the first support bracket 70 to the upper portion of the support leg 72 fixed to the piers (P3) by using a trolley, and then combine. The completion of the coupling of the first support bracket 70 is shown in Figure 4e.

When the coupling of the first support leg 70 is completed, the support structure and the nose 60 are moved forward by the launch wagon 90 as shown in FIG. 4F, and the second leg 110 is supported by the second support 110. It moves until it is close to the bracket 80.

The load at this time is transmitted to the piers by the second support bracket 80 and the first support bracket 70.

When the movement of the support structure and the nose 60 is completed as shown in FIG. 4F, the second support bracket 80 is moved to an appropriate position as shown in FIG. 4G.

In the state shown in FIG. 4G, the support frame and the nose 60 are moved upward while the suspension beam 30 is moved as shown in FIG. 3, and then the out frame 40 and the inner frame 50 are moved. After reinforcing the reinforcing bar between the concrete and the curing will be. Of course, before the concrete is poured, the dismantled frame support member 41 is installed again.

When the concrete poured between the out frame 40 and the inner frame 50 is cured, the girder is constructed while repeating the process illustrated in FIGS. 4A to 4F.

Although the preferred embodiments of the present invention have been described above, the technical idea of the present invention is not limited to the described embodiments, and various embodiments may be implemented without departing from the technical idea of the present invention.

1A shows a cross section of a box girder;

1b is a cross-sectional view of a double tee girder;

1c is a cross-sectional view of the strut type girder.

2 is a side view of a self-launching moveable formwork in accordance with one embodiment of the present invention.

3 is a cross-sectional view taken along line III-III shown in FIG. 2;

3A is a view illustrating a state in which structures coupled to the main frame and the main frame illustrated in FIG. 3 move downward.

3B is a view showing a state in which the suspension beam is moved to both sides in the state shown in FIG.

4A to 4G are views for explaining step by step construction of the girder using the self-launching movable formwork shown in FIG.

** Explanation of symbols for the main parts of the drawing **

10: main frame 20: side truss

30: suspension beam 40: out frame

50: inner frame 60: nose

70: first support bracket 80: second support bracket

90: launch wagon 100: first leg

110: second leg 120: trolley

Claims (3)

As for the construction of the girder installed in the upper part of the bridge, A main frame disposed to extend in the longitudinal direction of the girder; A plurality of side trusses installed at both sides of the main frame at predetermined intervals along the longitudinal direction of the girder, respectively; A suspension beam slidably coupled to each side truss in a width direction of the girder; An out frame coupled to each of the suspension beams by a frame support member and used as an outer formwork of the girder; And A support structure including an inner frame installed at an upper portion of the out frame and used as an inner formwork of the girder; A nose that is a truss structure extending in the direction of travel of the support structure to the support structure; The upper end is installed to be movable in the longitudinal direction of the girder with respect to the support structure and the nose, the lower end is mounted on the pier on the traveling side of the support structure to transfer the load of the support structure and the nose to the pier. The first support bracket, A second support bracket mounted on the support structure so as to be movable in the longitudinal direction of the girder, and a lower end mounted on a pre-installed girder to transfer loads of the support structure and the nose to the piers; It is fixed to the upper portion of each of the first support bracket and the second support bracket is movable with the first support bracket and the second support bracket, launching for moving the support structure and the nose in the girder direction and the vertical direction Wagon, A first leg coupled to the front end of the nose to be mounted on a pier located forward in the traveling direction of the support structure; And a second leg coupled to the rear end of the support structure to transfer a portion of the load of the support structure to the piers. The method of claim 1, The first support bracket includes a bracket body and a support leg detachably coupled to the bracket body, Self-launching movable formwork, characterized in that the lower end of the support leg is mounted on the upper portion of the pier. The method of claim 1, A rail extending from the rear end of the support structure to the front end of the nose and a trolley movable along the rail, And the first support bracket, the second support bracket, and the launching wagon are moved by the trolley.

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