KR101082418B1 - mold apparatus for forming concrete slab of bridge - Google Patents

Abstract

The present invention relates to a formwork apparatus for forming concrete girder for bridges. Its construction is to form a slab 104 into concrete on the upper surface of the beam 106 placed perpendicular to the extending direction of the piers on the girders 102 continuously installed on the piers of the bridges. Post (3) for supporting the loop frame (1) Loop transfer unit is installed on the upper surface of the girder (102) so that the loop frame (1) and the post (3) can be moved along the extension direction of the bridge ( 11) a side frame 23 installed upright at both ends of the roof frame 1, a support frame 25 extending from a lower end of the side frame 23 toward the center of the bridge, and a top of the support frame 25. The bottom foam 27 for forming the bottom surface of the slab 104, the side foam 31 for forming the side surface of the slab 104, the bottom foam 25 and the side foam 31 to the base For installation on the frame (25) The supporting frame 25 form a base (35) provided in the upper surface characterized in that it comprises a roof frame (1) for lifting the roof frame for starting up and down parts.

Formwork, girder, bridge, concrete, device, mold

Description

Mold apparatus for forming concrete slab of bridge

The present invention relates to a formwork, and more particularly, to a formwork for forming slabs for bridges.

Bridge work should be done in order to install trains, roads, etc. in the air on the ground or above the water. There are various bridge construction methods, but basically, girders are continuously placed on the piers constructed at regular intervals and slabs or railway tracks are installed on them. In particular, the present invention relates to a formwork for forming a slab that forms the basis of the top plate of a piers, as shown in FIG.

The girder 102 is installed on the pier 100 and the slab 104 is placed on the girder. On the slab 104 is installed asphalt or sidewalk blocks for vehicles and pedestrians. Since no heavy load is applied to the walkway block for passersby, a bridge can be designed that does not require installing the girders 102 throughout the width of the bridge. And the beam 106 using the shaped steel at regular intervals is installed in the girder 102 and the slab is installed by pouring concrete with a predetermined thickness thereon. In placing the slab in the bridge shown, the empty space S between the beams becomes a problem. That is, it is difficult to install the formwork in the empty space (S).

SUMMARY OF THE INVENTION An object of the present invention is to provide a formwork device for placing concrete slabs, ie slabs, in a bridge of the shape as shown in FIG. In particular, it is an object of the present invention to provide a formwork device for placing concrete in the empty space (S) between the beams.

The purpose of the above is to form a slab of concrete on the upper surface of the beam placed perpendicular to the direction of extension of the bridge on the girders continuously installed on the bridge piers.

Truss-shaped roof frame spaced apart from the upper surface of the girder to have a wider width than the left and right width of the bridge for supporting the loop frame, the post fixed to the upper surface of the girder so that the post can be moved along the extension direction of the bridge Loop transfer part installed on the upper surface of the girder Side frame of the truss structure is installed upright on both ends of the loop frame Support frame extending from the lower end of the side frame toward the center of the bridge Slab as installed on the upper support frame Bottom form for forming the bottom of the side Form for forming the side of the slab Side form for forming the bottom form and the side foam on the support frame The base is installed on the top of the support frame Starting the loop frame in the vertical direction Loop frame lift for It is achieved by a mold apparatus for molding for slab bridges, comprising a step of including.

According to a feature of the present invention, the loop transfer part is installed along the extension direction of the bridge to the buried bolt installed upright on the upper surface of the girder, the rail is provided to be detached from the buried bolt by being installed above the buried bolt It includes a wheel that is installed at the bottom of the post to enable the rolling motion.

According to the above configuration, a formwork device for evenly placing concrete evenly on the entire upper surface of the bar that is spaced apart at regular intervals to support the slab of the bridge is provided. In particular, the formwork is able to continuously form the slab while being moved along the extension direction of the bridge by the loop feeder.

Hereinafter, with reference to the accompanying drawings in the detailed description of the present invention will be described in more detail. 2 is a schematic perspective view of a formwork for forming a slab for a bridge according to an embodiment of the present invention, Figure 3 is a front view thereof and Figure 4 is a partial side view. 5 to 7 is a front configuration diagram according to the progress of the work. Related to the prior art will be referred to the reference numeral of FIG.

The present invention is for concrete molding the slab 104 on the upper surface of the beam 106 that is placed perpendicular to the direction of extension of the pier on the girders 102 that are continuously installed on the pier 100 of the bridge.

The truss-shaped loop frame 1 is installed to be spaced apart from the upper surface of the girder 102 in the upward direction. The left and right widths W of the roof frame 1 have a width wider than the left and right widths of the bridge (approximately 25 m). The length L of the loop frame is determined to be smaller than the spacing between the beams 106 and 106. In FIG. 3, the loop frame 1 is half-displayed while one side is raised and the other side is lowered.

The post 3 as a pillar is for supporting the roof frame 1 and is fixed to the upper surface of the girder 102. According to an embodiment of the present invention, a loop frame lifting unit for lifting the roof frame 1 in the vertical direction is provided.

The loop frame lift unit may be configured as follows. The length of the post 3 is adjusted by the hydraulic cylinder 7, and the post 3 can be a combination of square pipes 3a and 3b for male and female coupling. In addition, the square pipe may be provided with a plurality of length setting holes 9 and the fixing pins (not shown) may be inserted into the length setting holes 9 to maintain the length of the post 3 to a desired degree.

The loop transfer part 11 is installed on the upper surface of the girder 102 so that the post 3 can be moved along the extension direction of the bridge.

According to a feature of the present invention, the loop transfer part 11 is installed along the extension direction of the bridge to the buried bolt 13 is installed upright on the upper surface of the girder 102, the buried bolt 13 is installed by A rail 15 detachably installed from the bolt 13 includes a wheel 17 installed at a lower end of the post 3 to enable rolling motion along the rail 15. When the concrete is poured, the buried bolt 13 is embedded in the slab (104). When the curing is completed, the rail 15 is dismantled from the buried bolt 13 is transported to the rear and installed again. During formwork installation and curing, the wheels 17 should not be rolled along the rails 15 so that the roof frame 1 is fixed. To this end, the lower end of the post (3) is provided with a screw jack 19 is adjustable. By rotating the lever 19a of the screw jack 19, it is possible to selectively determine whether the wheel 17 and the rail 15 are rolling. In FIG. 3, for convenience of understanding, one side represents a screw jack 19 and the other side represents a wheel 17.

The wheel 17 may be driven to rotate by using the electric motor 21 or manpower.

Side frame 23 of the truss structure is installed upright on both ends of the loop frame (1). The side frame 23 is installed to extend toward the bottom of the bridge. The connection part of the loop frame 1 and the side frame 23 may include a known reinforcement frame to reinforce rigidity, which is similarly connected to the side frame 23 and the supporting frame 25 described later. This applies.

Support frame 25 is installed to extend toward the center of the bridge from the lower end of the side frame (23). Substantial elements of the formwork are installed on the support frame 25.

The bottom foam 27 is to be installed on the base frame 25 to form the bottom of the slab 104. The bottom foam 27 is supported by the bottom foam support frame 29. The side foam 31 is supported by the side foam support frame 33 to form the side of the slab 104. The side foam 31 is for shaping the protruding bottom face 104a, the side face 104b, and the protruding top face 104c of the slab 104, and has a substantially d-shaped shape in front view. The bottom foam 27 and the side foam 31 are installed in a state spaced apart by a predetermined height from the upper surface of the support frame 25 through the form base 35 of the truss structure. The bottom foam 27 and the side foam 31 may be made of metal sheet or wood plywood.

As mentioned, the post 3 supporting the loop frame 1 is adjustable in length. This means that the mounting height of the support frame 25 can be adjusted soon, and further, the bottom foam 27 and the side foam 31 can be raised or lowered to a curing height.

According to the actual situation of the bridge (for example, curved section, etc.), it should be possible to adjust the setting position of the bottom foam 27 and the side foam 31.

Referring to FIG. 4, in the space between both ends of the bottom foam 27 and the beam 106, a filling form 37 made of wood may be installed. The filling foam 37 is selectively installed by the filling foam support 39. The filling foam support portion 39 is composed of a bracket 41 and a support 43 on which the filling foam 37 can be placed. The bottom of the support 43 is supported by the upper surface of the flange 106a constituting the beam. Support 43 is also possible to adjust the length, the bottom can be coupled to the rubber plate 45 for preventing slipping.

Hereinafter, the use state of the formwork apparatus according to the embodiment of the present invention with reference to FIG. 5 or less will be described with reference to the front view. 5 shows a state in which the bottom foam 27 and the side foam 31 are installed at positions corresponding to the design, and are ready for concrete pouring.

Although not continuously connected to the formwork device, the side foam 31 is additionally provided with an accessory foam 47 for forming the protrusion inner surface 104d of the slab. The screw jack 19 of the post is supported on the upper surface of the rail 15 in place of the wheel 17 or together with the wheel 17 to prevent the roof frame 1 from flowing along the rail. The roof frame 1 is in a raised state by the hydraulic cylinder 7. Of course, the filling foam 37 in FIG. 4 is also completely filled, so that the narrow gap between the bottom foam 27 and the beam 106 is completely filled. Reinforcing bars (T) for maintaining the rigidity of the slab 104 should be laid before the concrete is poured. In the state of Figure 5 the casting and curing of the concrete is made and curing takes 1-2 days.

When curing is completed, the fixing pin 10 is separated from the length setting hole 9, and then the hydraulic cylinder 7 is operated to lower the loop frame 1. As a result, the bottom foam 27 and the side foam 31 are demolded while descending together with the support frame 25. The falling height of the loop frame 1 may be approximately 1m. Thus, the slab as shown in Figure 6 is formed in one section, that is, the section between the particular beam and the neighboring beam.

7 shows a state in which only the wheel 17 touches the rail 15 by rotating the screw jack 19 up. This is to ensure that all formwork including the roof frame 1 is transported along the rail 15 to the next section. Rail 15, which was installed in the section where the curing is completed, should be separated from the buried bolt 13 and installed again for the subsequent section.

In the figure, the slab 104 is inclined at a slight angle to the left and right, which means a curved section of the bridge. In this case, the height of the foam base 35 respectively installed on the left and right will be different as shown.

It is clear that the specific configuration of the bottom foam 27 and the side foam 31 will vary depending on the specific design of the bridge. Therefore, their shape does not limit the scope of the present invention. Similarly, the loop frame 1, the side frame 23 and the supporting frame 25 may also be sufficiently modified by a simple design change.

1 is a schematic partial cutaway perspective view of a bridge to which the present invention is applied.

2 is a schematic perspective view of a formwork for forming a slab for a bridge according to an embodiment of the present invention, Figure 3 is a front view thereof and Figure 4 is a partial side view. 5 to 7 is a front configuration diagram according to the progress of the work.

Explanation of symbols on the main parts of the drawings

One ; Loopframe 3; Post

11; Loop feeder

13; Buried bolt 15; rail

17; Wheel 21; Electric motor

23; Side frame 25; Support frame

27; Bottom foam 31; Side foam

35; Foam base 37; Filling foam

47; Subform 102; Girder

104; Slab 106; Bo

Claims (2)

For forming the slab 104 in concrete on the upper surface of the beam 106 placed perpendicular to the extending direction of the piers on the girders 102 continuously installed on the piers of the bridge, A truss type roof frame (1) installed spaced apart from an upper surface of the girder (102) and having a width wider than the left and right widths of the bridge; A post (3) erected on an upper surface of the girder (102) to support the loop frame (1); A loop conveying part (11) installed on the upper surface of the girder (102) so that the loop frame (1) and the post (3) can be moved along the extension direction of the bridge; A side frame 23 having a truss structure installed upright at both ends of the loop frame 1; A support frame 25 extending from the lower end of the side frame 23 toward the center of the bridge; A bottom foam (27) and a side foam (31) installed on the support frame (25) and for molding the bottom and side surfaces of the slab (104), respectively; A foam base 35 installed on an upper surface of the supporting frame 25 to install the bottom foam 25 and the side foam 31 on the supporting frame 25; And A loop frame lifter for starting the loop frame 1 in a vertical direction; , ≪ / RTI > The loop transfer part 11 is a buried bolt 13 which is installed upright on the upper surface of the girder 102, is installed along the extension direction of the bridge, the rail 15 is detachably installed on the buried bolt 13 And a wheel 17 installed at a lower end of the post 3 to roll along the rail 15. The side frame 23 is installed upright in the loop frame 1 to be in the form of floating in the air, The bottom foam 27 is supported by the bottom foam support frame 29 installed on the foam base 35, The side foam 31 is supported by the side foam support frame 33 installed on the foam base 35, The loop frame 1 and the post 3 and the side frame 23 and the supporting frame 25 connected to the loop frame 1 are simultaneously moved along the extension direction of the bridge by the loop transfer part 11. Formwork apparatus for forming the slab for the bridge, characterized in that. delete

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