KR20020001480A - Steel form for slab concrete applicable to P.C. beam or Steel Box methods - Google Patents

Abstract

The present invention relates to a slab formwork applied to a bridge PC beam or a steel box method, and each inner beam has a plurality of inner beams having horizontal portions with bolt holes at one end thereof; The inner end of the inner beam is accommodated therein in one end direction, and the inner beam can slide in the longitudinal direction, and has an opposite horizontal part having the same shape as the horizontal part having the bolt hole of the inner beam. A plurality of outer beams corresponding to each inner beam; A plurality of longitudinal supports disposed substantially perpendicular to the longitudinal direction of each outer beam and spaced apart at regular intervals in the longitudinal direction of the outer beam and positioned above the outer beam; A plurality of thunk plates having one end positioned at an edge of the upper surface of the PC beam at one end of each inner beam and having bolt holes formed at the other end thereof; A filler plate positioned between the thunk plate and the horizontal portion of the inner beam or the outer beam and extending in a direction perpendicular to the longitudinal direction of the inner beam; Coupling means having a bolt penetrating upward from a bottom of a horizontal portion of the inner beam and a nut located at an upper surface of the thunk plate to engage the bolt hole of the thunk plate and the bolt hole of the inner beam; Disclosed is a slab formwork comprising at least one floor covering installed on the plurality of longitudinal supports.

Description

Formwork for slab concrete in the PC beam method or steel box method {Steel form for slab concrete applicable to P.C. beam or Steel Box methods}

The present invention relates to a slab formwork applied to the P.C. beam (Pre-Concrete Beam) method and the steel box (Steel Box) method, and more particularly to a steel slab formwork applied to the bridge.

The slab formwork used in the conventional PC beam method is mainly used wood, but because the wood formwork is used only three times, it is less economical, and because the scaffolding for the installation and dismantling of formwork must be installed, the scaffolding cost is also high. There was a problem that takes a long time to install.

Therefore, steel formwork has been proposed, but the conventional steel formwork is required to be fixed to the structure by cutting, welding, taping, etc. at the construction site, thereby supplying power to a high place. There is a problem that the workability, such as the operator to carry the welding mechanism to cut and weld the steel plate is inferior and the probability of occurrence of a safety accident.

As an example of not applying the welding method, "Slab formwork for bridges" is proposed in the Republic of Korea Utility Model No. 180256, Figures 6 and 7 are diagrams for these.

However, this formwork should use the reinforcing bar 16 on the upper part of the PC beam 1, and if the reinforcing bar is not fixed at regular intervals and specifications, workability is disadvantageous and safety is also low.

In addition, since the steel beam 12a to be installed is not fixed, the work stability is lowered.

In addition, since there is no way to adjust the gap between the plywood 14 and the PC beam (1) there is an inconvenience that must be used in the field cut between the PC beam is not constant width.

In addition, even in the use of the sealing agent, the conventional formwork has a problem that sealing is difficult because there is no support base for the sealing agent when the sealing agent is administered.

The present invention has been made to solve the problems of the conventional wood and steel formwork structure as described above, an object of the present invention is to provide a slab formwork for bridges that can be adjusted in height and width without welding to the structure.

Another object of the present invention is to provide a slab formwork for bridges that is simple to install and dismantle.

Another object of the present invention is to provide a slab formwork in which the work can be safely proceeded.

Other purposes of the present invention may be various, but will be understood through the detailed description and drawings described below.

1 is a schematic exploded perspective view of an embodiment of a slab formwork according to the invention

2A is a schematic front view of an embodiment in which the slab formwork according to the invention is mounted between PC beams;

2B is a schematic plan view of an embodiment in which the slab formwork according to the invention is mounted between PC beams;

3 is a schematic exploded perspective view of another embodiment of a slab formwork according to the invention

4 is a schematic perspective view of an embodiment of placing slabs using slab formwork according to the present invention;

5A and 5B are schematic cross-sectional views showing differences between the use of the slab formwork according to the present invention and the use of conventional steel slab formwork, respectively, in the addition of a sealing agent.

6 and 7 are schematic cross-sectional and schematic perspective views each showing an example of a conventional slab formwork.

Explanation of symbols on the main parts of the drawings

20, 120: outer beams 71, 72, 172: filler plate 90: vertical support

30, 130: inner beam 100: flooring

In order to achieve the above object, the present invention provides a plurality of inner beam having a horizontal portion having a bolt hole in the upper side of the one end of the PC beam side slab is installed between a pair of horizontal PC beam; The inner end of the inner beam is accommodated therein in one end direction, and the inner beam can be slid in the longitudinal direction, and the opposite horizontal having substantially the same shape as the horizontal part having the bolt hole of the inner beam at the other end. A plurality of outer beams each having a portion and corresponding to each inner beam; A plurality of longitudinal supports disposed substantially in a direction perpendicular to the longitudinal direction of each outer beam and positioned above the outer beam; A plurality of thunk plates having one end positioned at an edge of the upper surface of the PC beam at one end of each inner beam and having bolt holes formed at the other end thereof; A plate shape disposed between the thunk plate and the horizontal portion of the inner beam or the outer beam and extending in a direction perpendicular to the longitudinal direction of the inner beam, the plurality of open grooves in the same direction as the longitudinal direction of the inner beam toward the PC beam; Filler plate is formed; A bolt penetrating upward from a bottom of a horizontal portion of the inner beam and a nut located on an upper surface of the thunk plate to fasten the bolt hole of the thunk plate and the bolt hole of the inner beam and the bolt hole of the thunk plate; Means; It provides a slab formwork comprising at least one flooring material installed on the plurality of longitudinal supports.

In the present invention, it is preferable that the inner beam and the outer beam have coupling means for limiting relative positions of each other.

In the present invention, the bolt hole in the horizontal portion of the inner beam and the outer beam is preferably a long hole in each longitudinal direction.

In the present invention, the filler plate preferably has a vertical portion connecting the first horizontal portion, the stepped second horizontal portion, and the first and second horizontal portions in a crank shape perpendicular to the longitudinal direction.

In the present invention, the plate is located between the filler plate and the horizontal portion of the inner beam, and has a groove coinciding with the second long hole of the inner beam and the open groove of the filler plate, the plate having the same thickness as the vertical portion of the filler plate It is preferred to further include a spacer plate in the shape.

In the present invention, each edge of the filler plate and the plywood is preferably in close contact or sealing with each other using a sealing agent or the like.

In the present invention, the nut of the coupling means and the thunk plate is preferably galvanized to prevent the occurrence of rust.

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

Formwork of the present invention is composed of a plurality of beam structure, a plurality of vertical support and plywood, but for convenience of description, one beam structure will be described first.

1 is a schematic exploded perspective view of a slab formwork according to the present invention, as shown, the formwork according to the present invention is a pair of pillars and a plurality of pillars to connect the plurality of beam structures mounted between the PC beams in one Plate 71, 72, a plurality of vertical support 90 is mounted on the beam structure, and the flooring material 100 is mounted on the vertical support, the beam structure is an outer beam 20 and the inner beam ( 30, thunk plates 41 and 42, spacer plates 51 and 52, and first and second coupling means 81, 82, 61 and 62.

The outer beam 20 has a plurality of pairs of vertical plates 25 spaced apart at regular intervals on top of each other in a shape of 'ㅁ' shaped steel (box beam), and a bracket 23 is coupled to one end of the outer beam. Both vertical surfaces of the other end of 20 have bolt holes 21 penetrated in place.

The bracket 23 has a vertical portion 23a and a horizontal portion 23b, as shown, the vertical portion 23a is welded to the outer beam 20 and the horizontal portion 23b is It is positioned substantially parallel to the upper surface of the outer beam 20, and has a long hole 24 in the longitudinal direction of the outer beam 20.

The inner beam 30 has a long hole 32 in the longitudinal direction in the vertical plane in the 'c' shaped steel shape, one end of which is inserted into the other end side of the outer beam 20 to slide a certain distance, the other end A bracket 33 having substantially the same shape as the bracket 23 coupled to one end of the outer beam 20 is coupled thereto.

That is, the bracket 33 welded to the inner beam has a vertical portion 33a and a horizontal portion 33b, and the horizontal portion 33b is positioned higher than an upper surface of the inner beam 30 and the outer beam. Similar to the long hole 24 of the has a long hole 34 in the longitudinal direction.

The thunk plates 41 and 42 are coupled to the upper holes 24 and 34 of the horizontal portions 23b and 33b of the brackets 23 and 33, respectively, and the nut is biased at one end to the thunk plate. The balls 41a and 42a are formed, and the other end is located in the upper surface of the PC beam as described later.

Between the thunk plates 41 and 42 and the horizontal portions of the brackets 23 and 33 are preferably spacer plates 51 and 52 having bolt holes, and the spacer plates serve as washers. do.

The thunk plates 41 and 42 and the horizontal portions 23b and 33b of the respective brackets are coupled by a bolt 61 and a nut 62 as first coupling means. The long hole of each of the horizontal portions 23b and 33b and the thunk plate 41 and 42 and the bolt head under the protruding horizontal portion of the bracket coupled with the inner beam 20 and the outer beam 30 The nut 62 is fastened through the bolt grooves of the spacer plates 51 and 52.

The bolt 61 is an angular bolt, the thread of which is rectangular in shape, it is advantageous to withstand the load, the head of the bolt 61 and the nut 62 is preferably about 27mm in size.

In addition, since the nut 62 and the thunk plate 71 and 72 are embedded together when placing concrete, it is more preferable to prevent galvanization to prevent rust.

The filler plates 71 and 72 are located between the fastened spacer plates 51 and 52 and the thunk plates 41 and 42, respectively. The same applies to the same), a first horizontal portion 72a, a second horizontal portion 72b having a level difference with the first horizontal portion, and a vertical portion 72c connecting the first and second horizontal portions. have. The first horizontal portion 72a has an open groove 73 extending toward the end thereof, and the second horizontal portion 72b is a bottom plate to be described later. The height of the vertical portion 72c is the spacer plate. It is preferable that the height of the 52 and the flooring material 100 be substantially the same. In addition, the filler plate 72 extends in a direction perpendicular to the longitudinal direction of the inner beam 30.

That is, the filler plate 72 is bent in two opposite directions at right angles to the longitudinal direction of the inner beam 30 so as to have a height difference and two horizontal planes parallel to each other. It is open and has a plurality of grooves arranged at regular intervals and is mounted between the thunk plate 42 and the spacer plate 52 at the open groove position.

On the other hand, the long hole 32 formed on the vertical surface of the inner beam is preferably coupled to the bolt hole 21 and the second coupling means of the outer beam 20, in this case, for example, the bolt 81 is the outer The bolt head is disposed on a vertical surface of the beam and is fastened to the nut 82 through the bolt hole of the outer beam and the second long hole of the inner beam. In the state where the inner beam is sufficiently inserted into the outer beam, the second coupling means is not essential because the inner beam is supported in the horizontal direction.

The vertical support 90 is preferably a square pipe having a cross section of 'ㅁ', which is mounted on an upper surface of the outer beam 20 and is limited in position by a vertical plate 25 of an upper surface of the outer beam. .

On the other hand, the wood may be mounted on the upper surface of the vertical support 90 in the longitudinal direction of the vertical support. This is to fix the position by coupling by the coupling means such as the wood and nails or rivets when using the plywood as the flooring material.

On the other hand, the flooring material 90 may use a FRP material or plywood, or coated plywood, it may not be required when using the FRP material.

2A and 2B are schematic front and plan views, respectively, when the slab formwork according to the present invention is installed in a PC beam. As shown, the formwork of the present invention is adjustable in length and has a plurality of beam structures spaced at regular intervals, respectively. And a pair of pillar plates 71 and 72 fixing the plurality of beam structures, and a plurality of vertical supports 90 mounted on the upper surfaces of the plurality of beam structures at regular intervals in the longitudinal direction of the beam structure. , Consisting of plywood 100 on a plurality of longitudinal supports and are installed in the above order.

The installation method of the slab formwork,

The plurality of beam structures are mounted between the PC beams P at regular intervals by adjusting the lengths of the plurality of beam structures, but when the length is adjusted, the slide distance in the outer beam 20 of the inner beam 30 is roughly adjusted. The length is adjusted and the pair of thunk plates 41 and 42 and the first coupling means 61 and 62 are moved for fine length adjustment. At this time, one end of the pair of thunk plate is positioned on the upper surface of the PC beam to support the beam structure.

Next, the pair of pillar plates 71 and 72 are used to open the groove between the thunk flakes 41 and 42 and the spacer plates 51 and 52 at both ends of the plurality of beam structures. Insert 73 to connect each beam structure.

On the other hand, the plurality of square pipes 90 are mounted on the upper surface of the beam structure at regular intervals, and the flooring material 100 is installed on the plurality of square pipe upper surfaces.

Finally, a gap formed between the flooring material 100, the beam structure, and the filler plate is sealed using a sealing means such as a sealing agent (not shown). Before using this sealing agent, the inner surface of the inner beam 30 along the open groove (not shown) in which the pillar plates 71 and 72 are fitted to the thunk plate side so that no gap is formed between the vertical portion of the pillar plate and the flooring material. It is advantageous to use a sealing agent to adjust the length by moving in the longitudinal direction.

After that, the concrete is poured on the upper part of the PC beam and the flooring to cure.

On the other hand, when dismantling work only if the bolt 61 of the first coupling means, the inner beam 30 and the outer beam 20 and the filler plate 71, 72 can be easily separated, the upper part of the PC beam The thunk plate 41 and 42 and the nut 62 located in the immersed in concrete. However, in the present invention, since the thunk plates 41 and 42 and the nut 62 are galvanized, the thunk plates 41 and 42 and the nut 62 may be almost semi-permanently.

3 is a schematic exploded perspective view of another embodiment of the slab formwork according to the present invention, the outer beam 120, the inner beam 130, the bracket 123 to withstand a greater load compared to the embodiment of FIG. ), The vertical support 190, the outer beam side pillar plates 175a, 75b, and the like have been changed.

Compared to the outer beam 20 of FIG. 1, the outer beam 120 has the upper vertical plate 25 removed, and the nut 182 and the bolt 181 fixed to the position of the existing bolt hole of FIG. Compared to the inner beam 30 is coupled to the inner beam 130, the longitudinal hole is missing.

The bolt 181 is fastened to a nut 182 fixed to the outer beam so that the inner beam 130 is inserted into the outer beam 120 and fixed at an appropriate position. The passing bolt 181 compresses the vertical plane of the inner beam 130 to fix the relative positions of the inner beam and the outer beam.

Compared to the bracket of FIG. 1, the brackets 123 and 133 have long holes of the horizontal portion 123a changed to bolt holes 151 and 152, and the vertical portions 123b are changed into a 'ㅁ' shaped steel shape. To withstand heavy loads.

Unlike the vertical support of Figure 1, the vertical support 190 is preferably bar using a C-shaped steel, in order to withstand a greater load. In addition, it is preferable to fix the wood plate 191 to the upper part of the vertical support using a coupling means such as a bolt, if necessary, which prevents the lifting between the flooring 100 and the vertical support 190 and subsequently the flooring material. This is to facilitate the use of coupling means such as nails or bolts when the need arises for the 100 to be fixed on the longitudinal support 190.

Unlike the outer beam side pillar plate 71 of FIG. 1, the outer beam side pillar plate 171 includes a pair of bent first plates 171 a and a second plate 171 b that are symmetrical to each other. The first and second plates 171a and 171b have a plurality of first and second open grooves 174a and 174b facing each other spaced apart at regular intervals in the longitudinal direction, respectively.

This is to make the process of adjusting the gap between the flooring material 100 and the filler plates 72 and 171 more easily and simply, first, the filler plate 72 of the inner beam side is formed in the open groove 73 of the plate. After fixing as close to the inner beam side PC beam as possible, one end of the bottom member 100 is brought into close contact with the vertical portion 72c of the inner beam side filler plate 72, and the inside of the outer beam side filler plate 171 is provided. The position of the located first plate 171a is adjusted according to the first open groove 174a to be in close contact with the other end of the flooring material 100. Finally, after adjusting the position of the second plate 171b located on the outer side of the outer beam side filler plate 171 according to the second open groove 174b, it is fixed so as to fill the excited gap with the outer beam side PC beam. do.

Through the above method, it is possible to eliminate the space between the flooring material 100 and the filler plates 72 and 171 to the extent that no sealing agent is required, and also to adjust the position of the inner beam side filler plate 72. No safety and easy operation is possible.

4 is an embodiment having a configuration as described above, using a plurality of slab formwork according to the present invention installed to fill the space between the PC beam (P) and the cross beam (C) and then to place the slab (S) It is a schematic perspective view.

5A and 5B are partial cross-sectional views of the slab formwork and the conventional slab formwork according to the present invention, respectively, and the same role parts are designated by the same numerals. When the sealing agent (S) is added, in the case of the form according to the present invention, the filler plate 41, 42 to adjust the interval with the flooring material 100, the horizontal portion 23b of the inner beam 23 Since the sealing agent (S) is introduced in the state supported by the), the sealing is easy and there is no waste of the sealing agent and the sealing state is also strong. On the other hand, in the case of the conventional formwork, effective sealing is very difficult because there is no means for adjusting the gap between the flooring material 100 and the other structure of the formwork, and there is no support for preventing the falling of the introduced sealing.

As described above, by using the slab formwork for bridges applied to the PC beam according to the present invention, it is not necessary to use a scaffold, and the flooring material and the PC beam side, that is, the filler plate, are mounted on the bracket of the inner plate and the outer plate of the beam structure. By being supported by and being able to adjust the gap, the sealing is effective in sealing and there is no fear of the sealing agent falling down.

Also, in order to prevent concrete from flowing out of the formwork before curing under conditions where the distance between the PC beams is not constant, such as curved roads, skewed roads, and narrowed roads, Since the plywood should be cut and used in the field, the worker has to work with the cutting machine on the upper part of the PC beam, so the work is complicated, there is a risk of work as well as a lot of material loss, but according to the present invention In addition to adjusting the width of the formwork according to the distance between the PC beams during installation, the floor plate can be used to adjust the gap with the flooring material by using the filler plate, so that a certain flooring material can be used. There is a favorable advantage in that.

In addition, in the above-mentioned registered utility model No. 180256, in the "slab formwork for bridges", the beam supporting the floor is not supported at all and is free to play, so there is a risk of falling during work, which is disadvantageous in terms of safety, and also in the upper part. In the beam structure according to the present invention, since the inner beam and the outer beam are completely fixed by the shank plate and the filler plate, the risk of work is significantly reduced.

In addition, in the prior art to dismantle the bolt spaced apart from the dismantling hole by pushing the bolt dismantling mechanism through the dismantling hole, in the present invention can immediately dismantle the bolt, it is advantageous in the dismantling operation.

Claims (5)

A slab formwork consisting of a plurality of beam structures, wherein each beam structure is provided between a pair of PC beams of which the upper surface is substantially horizontal An inner beam connected to the body and at one end of the PC beam, the inner beam having a horizontal portion having a bolt hole at an upper side thereof; An outer beam having a body in which the inner end of the inner beam is slid in a longitudinal direction by accommodating the other end of the inner beam at one end thereof, and a horizontal portion having a bolt hole at the other end thereof; Coupling means for determining a relative position between the body of the inner beam and the body of the outer beam; A first thunk plate positioned above the horizontal portion of the inner beam, having a bolt hole corresponding to the bolt hole of the inner beam, and having one end positioned at an edge of an upper surface of the PC beam; A second thunk plate positioned above the horizontal portion of the outer beam, having a bolt hole corresponding to the bolt hole of the outer beam, and having one end positioned at an edge of the upper surface of the PC beam; A first pillar plate positioned between the first thunk plate and the horizontal portion of the inner beam and connecting the beam structures to each other; A second pillar plate positioned between the second thunk plate and the horizontal portion of the outer beam and connecting the beam structures to each other; Equipped with A plurality of longitudinal supports disposed substantially perpendicular to the longitudinal direction of the outer beam and positioned above the outer beam; First coupling means having a bolt penetrating upward from a bottom surface of the horizontal portion of the inner beam and a nut located at an upper surface of the first thunk plate for engaging with the bolt hole of the first thunk plate and the horizontal bolt hole of the inner beam and; Second coupling means having a bolt penetrating upward from a bottom surface of the horizontal portion of the outer beam and a nut located on an upper surface of the second thunk plate for engaging with the bolt hole of the second thunk plate and the horizontal bolt hole of the outer beam; and; At least one flooring material installed on the plurality of longitudinal supports Slab formwork containing The method according to claim 1, The flooring material is a slab formwork selected from FRP, plywood, coated plywood The method according to any one of claims 1 and 2, The nuts of the first and second coupling means and the 1.2 thunk plate are galvanized. Slab formwork The method according to any one of claims 1 to 3, The first pillar plate has a plate shape extending in a direction perpendicular to the longitudinal direction of the inner beam, and comprises a first horizontal portion formed along the extended longitudinal direction, a second horizontal portion stepped therein, and a vertical portion connecting them. And a plurality of open grooves fitted into the bolts penetrated in the first horizontal portion in the same direction as the longitudinal direction of the inner beam toward the PC beam, The second pillar plate has a plate shape extending in a direction perpendicular to the longitudinal direction of the outer beam, and comprises a first horizontal portion formed along the extended longitudinal direction, a second horizontal portion stepped therein, and a vertical portion connecting them. And a slab formwork having a plurality of open grooves inserted into the bolts through the first horizontal portion in the same direction as the longitudinal direction of the outer beam toward the PC beam. The method according to any one of claims 1 to 3, The first pillar plate has a plate shape extending in a direction perpendicular to the longitudinal direction of the inner beam, and comprises a first horizontal portion formed along the extended longitudinal direction, a second horizontal portion stepped therein, and a vertical portion connecting them. And a plurality of open grooves fitted to the bolts penetrated in the first horizontal portion in the same direction as the longitudinal direction of the inner beam toward the PC beam, The second filler plate is composed of a first plate and a second plate each having a bent plate shape, The first plate has a plate shape extending in a direction perpendicular to the longitudinal direction of the outer beam, and has a horizontal portion and a vertical portion formed along the extended longitudinal direction, and the horizontal portion has a longitudinal direction of the outer beam toward the PC beam. Having a plurality of open grooves fitted into the pierced bolt in the same direction, The second plate has a plate shape extending in a direction perpendicular to the longitudinal direction of the outer beam, and has a horizontal portion and a vertical portion formed along the extended length direction, and in the horizontal portion in a direction opposite to the open groove of the first plate. Having a plurality of open grooves opened and fitted into the pierced bolts Slab formwork