KR100433700B1 - Mold system for slab concrete of bridge - Google Patents

Abstract

PURPOSE: A form system for placing slab concrete for a bridge is provided to execute installation and dismantlement conveniently and to improve competitive power for a price. CONSTITUTION: A form system for placing slab concrete for a bridge comprises hanger bolts(300) horizontally seated to the upper parts of PSC(Pre-Stressed Concrete) beams; vertical bars(200) each including a square pipe(210) and clamps(400) each having a wedge hole; a joining unit joining the hanger bolts and the clamps; plural multi-beams(100) each including an inner beam(110), an outer beam(120), and fixing units; and a flooring material(500) seated on the multi-beams. A thread is formed to the ends of the hanger bolt. The ends of the clamps are joined to the side walls of the square pipe. Angles(130) to be seated on the vertical bar are formed to the inner beam. The angle is formed to one end of the outer beam and the inner beam is inserted into the other end of the outer beam. The fixing unit joins the outer beam and the inner beam.

Description

Mold system for slab concrete of bridge

The present invention relates to a slab formwork for placing concrete on top of a PSC beam, and more particularly, to a steel slab formwork applied to a bridge.

Conventional slab formwork is mainly used wood, but because the wood formwork is used only three times, the economical fall, the installation and dismantling of the formwork to install the lower scaffold, there was a disadvantage in terms of installation cost or time .

Steel formwork is proposed to improve this. Conventional steel formwork should be welded and fixed to the structure by cutting, welding, taping, etc. at the construction site, so power must be supplied to a high place, and the worker can carry the welding mechanism to cut and weld the steel plate. There was a problem of falling and a high probability of a safety accident.

In order to solve such a problem, Utility Model No. 180256 or Registration Utility Model No. 222611 proposes steel formwork which is not by welding.

1A and 1B illustrate the formwork of the utility model No. 180256. First, the c channel 10 is installed using the clip bar 18 on the upper side of the PSC beam 1. The clip bar 18 is fixed to the reinforcing bar 16 above the PSC beam 1. And the girder 12 is installed in two opposing c-channel 10, the girder 12 is composed of a steel pipe 12a and a lumber 12b, the lumber 12b is a floor material on the top It is for fixing the plywood 14 to be placed, and the concrete is poured after the plywood 14 is installed on the wood 12b.

By the way, according to this method, if the reinforcing bar 16 is not fixed at regular intervals and specifications, workability is disadvantageous, and since the steel pipe 12a mounted on the c channel 10 is not fixed, the stability of the work is improved. There is a problem falling.

In addition, when the distance between the PSC beam 1 is different, such as a curved road, it is difficult to install, and there is no way to adjust the gap between the PSC beam 1 and the flooring plywood 14, so that the width between the PSC beam 1 is different. In this case, there was an inconvenience of using plywood cut in the field as a sealing agent.

Figure 2a and 2b schematically shows the design of the proposed utility model No. 222611 proposed to solve this problem, Figure 2a is a state in which the slab formwork is installed between the PSC beam, Figure 2b is a view of the slab formwork The configuration is shown.

Looking at the configuration of this design, the brackets (23, 33) of the L-shape is attached to both ends, a plurality of crossbars 20 consisting of the inner beam 22 and the outer beam 24, and one end of the bracket (23) Bolted to the 33, the other end is mounted on the upper end of the PSC beam (P) thunk plate (41, 42) for mounting the crossbar 20 between the two PSC beam (P) and the bracket ( Filler plates 72 and 71 and spacer plates (not shown) fixed between the horizontal portions 22 and 33 and the thunk plates 41 and 42, and the cross bars 20 on the cross bars 20. It comprises a plurality of vertical poles 80 to be mounted in a right angle direction, and a flooring material 90 is mounted on top of the vertical poles 80.

Since the slab formwork having such a configuration can not only adjust the length of the crosspiece 20 according to the distance between the PSC beam at the time of installation, but also adjust the gap with the flooring material 90 using the filler plates 71 and 72. In comparison with the method of FIG. 1, the work efficiency can be said to be greatly improved, but the thunk plates 41 and 42 fixing the crossbar 20 and the PSC beam, the filler plates 71 and 72 and the spacer plate (not shown) There are a lot of component parts such as si) It takes a long time to assemble it, there is a need to improve it.

The present invention is to solve this problem, the object is to provide a more simple and economical slab formwork for bridge construction.

1A and 1B are a perspective view and a cross-sectional view showing a state in which a conventional slab formwork is installed on a PSC beam;

Figure 2a, Figure 2b is a perspective view and a detailed configuration showing a state in which other conventional slab formwork is installed

3 is a block diagram of a formwork system according to an embodiment of the present invention

4 is an exploded perspective view of the clamp and the hanger plate;

5 is a side view showing a formwork system installed according to an embodiment of the present invention between the PSC beams;

FIG. 6 is an enlarged view illustrating a portion A of FIG. 5.

7 is a plan view showing a form installed formwork according to an embodiment of the present invention

* Description of the symbols for the main parts of the drawings *

100: multi beam 110: inner beam

120: outer beam 122: nut fixing plate

124: nut 126: bolt

200: vertical pole 210: square pipe

220: fixing plate 300: hanger bolt

310: hanger nut 400: clamp

402: wedge hole 410: hanger plate

411: bolt hole 412: first vertical portion

413: stepped portion 414: second vertical portion

415: jamming jaw 420: wedge pin

500: flooring 520: supplement

522: nail

In order to achieve the above object, the present invention is longer than the width of the upper portion of the PSC beam, a thread is formed at both ends, and hanger bolt 300 is horizontally mounted on the upper portion of the PSC beam; Longitudinal column 200 including a square pipe 210, the U-shaped cross section and both ends are coupled to the side wall of the square pipe 210, the clamp 400 is formed with a wedge hole 402 on one side Wow; Coupling means for coupling the hanger bolt 300 and the clamp 400; An inner beam 110 having an angle 130 mounted on an upper portion of the vertical pole 200 is formed at one end thereof, and an outer beam at which the angle 130 is formed at one end thereof and the inner beam 110 is inserted at the other end thereof. 120 and a plurality of multi-beams 100 including fixing means for coupling the outer beam 120 and the inner beam 110; It provides a formwork system for slab concrete pouring for the bridge comprising a flooring 500 mounted on top of the multi-beam (100).

A fixing plate 220 having a width larger than that of the square pipe 210 is installed on the top surface of the square pipe 210.

In addition, the coupling means has one end is formed with a bolt hole 411 is coupled to the hanger bolt 300, the other end hanger plate 410 is formed with a locking step (415); It includes a wedge pin 420 is inserted through the wedge hole 402 of the side of the clamp 400 is fixed by the locking step 415.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a configuration diagram of a formwork system according to an embodiment of the present invention, which is vertically fixed in a longitudinal direction adjacent to the upper side of the PSC beam, and is perpendicular to the longitudinal direction of the longitudinal pole 200. It includes a multi-beam 100 is installed in the direction and both ends are mounted on the upper portion of the vertical pole 200, and the flooring material 500 is placed on the upper portion of the multi-beam 100 for placing concrete.

Longitudinal column 200 is composed of a square square pipe 210 and the fixing plate 220 is installed on the upper surface of the square pipe 210. The coupling of the fixed plate 220 and the square pipe 210 is by a conventional coupling means such as screws.

The fixing plate 220 is preferably formed of wood so that the flooring material 500 or the supplementary material 520 for sealing can be easily fixed with nails or screws, but is not limited thereto.

In addition, the width of the fixing plate 220 is preferably larger than the lower square pipe 200, which is because the square pipe 200 is not in close contact with the side of the PSC beam due to the clamp 400 to be described later, the fixing plate 220 ) So as to be adjacent to the side of the PSC beam to realize an approximate sealing, and furthermore, the filler 520 for the final sealing is adjacent to the side of the PSC beam, so to fix it with a nail 522 or the like. This is because the fixing plate 220 is preferably located at the bottom.

In order to fix the vertical pole 200 to the upper side of the PSC beam, the method proposed by the present invention has a length longer than the width of the upper surface of the PSC beam and a hanger bolt 300 and a threaded end formed at both ends, and a hanger bolt The hanger plate 410 coupled to the 300, the clamp 400 formed on the side of the square pipe 210, the wedge pin 420 connecting the clamp 400 and the hanger plate 410 is to be used.

The hanger bolt 300 is loaded on both ends of the multi-beam 100, the vertical pole 200, the flooring material 500 and the cast concrete, so it must have a suitable diameter and rigidity to withstand such loads .

One end of the hanger plate 410 is coupled to the end of the hanger bolt 300, the hanger plate 410 is formed with a bolt hole 411 through which the hanger bolt 300 penetrates, the bolt hole 411 After the hanger bolt 300 is inserted, the hanger nut 310 is fixed. By coupling the hanger plate 410 and the clamp 400 by the wedge pin 420, the longitudinal pole 200 coupled with the clamp 400 is fixed to the side of the PSC beam, which will be described later.

When the vertical pole 200 is fixed, both ends of the multi-beams 100 in the horizontal direction are mounted on the vertical pole 200. The multi-beam 100 should be adjustable in length, in the drawing, the multi-beam 100 is inserted into the outer beam 120 of the C-shaped steel, and the inner beam having a rectangular cross section inserted in one end of the outer beam 120 Although it is configured to include 110, the shape of the outer beam 120 is not limited to the C-shaped steel, of course.

Since the inner beam 110 can be inserted into one end of the outer beam 120 is to adjust the length of the multi-beam 100, once the length is determined, both should be fixed, in the embodiment of the present invention To this end, by installing a nut 124 on the outer beam 120 and forming a nut hole (not shown) to the side of the outer beam 120 to which the nut 124 is attached, the bolt 126 inserted into the nut 124 End of the) is pressed to secure the side of the inner beam (110).

Without attaching the nut 124, it is also possible to simply form a nut hole (not shown) on the side of the outer beam 120, and to squeeze and fix the side of the inner beam 110 through the bolt 126. . In the drawing, since the outer beam 120 is made of C-shaped steel, the nut fixing plate 122 is installed to attach the nut 124. However, the nut fixing plate 122 is unnecessary in the case of a square pipe.

In the outer beam 120 and the inner beam 110, at the opposite end of the portion where the outer beam 120 and the inner beam 110 are coupled, an L-shape consisting of a vertical portion and a horizontal portion, for mounting on the vertical pole 200 An angle of the 130 is formed, the vertical portion is coupled to the end of the outer beam 120 and the inner beam 110 by welding, etc., the horizontal portion is mounted on the vertical pole (200). Since the angle 130 is for mounting the multi-beam 100 to the vertical pole 200, the existence of the mountable horizontal portion is essential, but the vertical portion may be omitted.

After mounting a plurality of such multi-beams 100 in the vertical direction and the vertical pole 200, the flooring material 500 is placed on the top, if there is a gap in the vicinity of the PSC beam supplements 520 to fill them up Install. The flooring material 500 or the supplementary material 520 is usually made of wood such as plywood, but is not limited thereto, and thus, a plate such as FRP material may be used instead.

4 is a diagram illustrating a coupling relationship between the hanger plate 410 and the clamp 400. The hanger plate 410 includes a first vertical portion 412 and a first vertical portion in which a bolt hole 411 is formed. And a second vertical portion 414 forming a stepped portion 413 between the 412 and a locking jaw 415 formed at a lower end of the second vertical portion 414.

The clamp 400 has a shape in which three vertical plates are coupled in a U-shaped or U-shaped, and both ends of the U-shaped are joined by welding or the like to the side of the square pipe 210, and the wedge pins 420 are formed on the vertical plates of the side. The penetrating wedge hole 402 is formed, and the wedge hole 402 may be formed on only one side or both on opposite sides.

In such a configuration, when the hanger plate 410 is inserted into the clamp 400 from the end where the locking step 415 is formed, and the locking step 415 is positioned lower than the wedge hole 402, the wedge pin 420. ) Is inserted into the wedge hole 402. At this time, the wedge pin 402 is caught by the locking jaw 415, and the vertical pole 200 coupled to the clamp 400 is fixed.

5 is a cross-sectional view showing a slab formwork according to an embodiment of the present invention between two PSC beams (P), a length greater than the width of the upper portion of the PSC beam (P) above the PSC beam (P) The hanger bolt 300 is placed, the vertical pole 200 is installed adjacent to the side portion of the PSC beam, the multi-beam 100 is mounted on the opposite longitudinal pole 200, the multi-beam 100 of It is shown that the flooring 500 is placed on the top.

FIG. 6 is an enlarged view of a portion A of FIG. 6, in which a hanger plate 410 is fixed to a hanger bolt 300 mounted on an upper portion of the PSC beam P, and the hanger plate 410 and the square pipe are fixed. It can be seen that the clamp 400 coupled to the side of the 210 is coupled by the wedge pin 420.

A fixing plate 220 is attached to the square pipe 210, and an angle 130 of one end of the multi-beam 100 is mounted on the fixing plate 220, and an upper portion of the angle 130 and the multi-beam 100 is mounted. The flooring material 500 is mounted on, and the supplementary material 522 is mounted on the gap between the PSC beam and the flooring material 500 for sealing. On the other hand, if the flooring material 500, the supplementary material 522, and the fixing plate 220 are all formed of wood such as plywood, they can be easily fixed using the nails 522 or screws.

FIG. 7 illustrates a plane in which formwork according to an embodiment of the present invention is installed between two PSC beams. The vertical poles 200 are fixed in the longitudinal direction of the PSC beam and face each other, and angles formed at both ends thereof. A plurality of multi-beams 100, 130 is mounted on the vertical pole 200 is arranged at regular intervals.

Hanger bolts 300 for fixing the vertical pole 200 are spaced at a larger interval than the multi-beam 100, but is not limited to this, the installation interval of the multi-beam 100 or hanger bolts 300 is expected It can be arbitrarily determined according to the working load or process conditions.

Using the formwork system having the above configuration, after placing both the flooring material 500 and the supplementary material 520, the concrete is put through the curing and curing process, look at the process of dismantling the formwork system after curing As follows.

First, when the wedge pin 420 is removed from the bottom, the stand 200 is attached to the flooring 500 and the supplement 520 only by the nail 522, and thus can be easily removed and the stand 200 ), The multibeam 100 is naturally separated. Next, the uppermost flooring material 500 and the supplementary material 520 are attached to the concrete without any other fixing device, and thus can be easily removed.

The hanger bolt 300 and the hanger nut 310 are in a state of being buried in concrete, and the protruding hanger plate 410 may be cut out.

In the above description, but limited to the preferred embodiment of the present invention, various modifications or changes by those skilled in the art in the practice of the present invention is possible, such modifications or changes are based on the technical idea of the present invention rights It is natural to belong to the scope.

According to the present invention, since the slab formwork for bridges can be installed and dismantled more easily and quickly, the construction capacity can be improved as well as the price competitiveness can be improved.

Claims (3)

A hanger bolt 300 longer than a width of an upper portion of the PSC beam and having threads formed at both ends thereof and horizontally mounted on the upper portion of the PSC beam; Longitudinal column 200 including a square pipe 210, the U-shaped cross section and both ends are coupled to the side wall of the square pipe 210, the clamp 400 is formed with a wedge hole 402 on one side Wow; Coupling means for coupling the hanger bolt 300 and the clamp 400; An inner beam 110 having an angle 130 mounted on an upper portion of the vertical pole 200 is formed at one end thereof, and an outer beam at which the angle 130 is formed at one end thereof and the inner beam 110 is inserted at the other end thereof. 120 and a plurality of multi-beams 100 including fixing means for coupling the outer beam 120 and the inner beam 110; Floor material 500 mounted on top of the multi-beam 100 Formwork system for slab concrete pouring for bridges The method of claim 1, Formwork system for slab concrete pouring for the bridge is installed on the top surface of the square pipe 210 has a fixed plate 220 having a larger width than the square pipe 210 The method of claim 1, The coupling means A hanger plate 410 having a bolt hole 411 coupled to the hanger bolt 300 at one end thereof, and a locking jaw 415 formed at the other end thereof; The wedge pin 420 is inserted through the wedge hole 402 on the side of the clamp 400 and fixed by the locking step 415. Forming system for slab concrete pouring for bridges