KR0137466Y1 - Deck panels of reinforced concrete slabs - Google Patents

Abstract

The present invention discloses a deck panel of improved construction.

Conventional deck panel is coupled to the finishing plate by the spacer material, the girder is curved, it is difficult to install the girder correctly and did not play the role of girder.

In the present invention, the conventional problem is solved by directly bonding the girder to the finishing plate by a bracket.

Description

Deck panels of reinforced concrete slabs

1 is an exploded perspective view showing the structure of a conventional deck panel.

2 is a cross-sectional view of the bonded state after the concrete injection.

Figure 3 is an exploded perspective view showing the configuration of the deck panel according to the present invention.

4 is a schematic cross-sectional view showing the joining method.

5 to 7 are perspective views showing various other embodiments of the present invention.

* Explanation of symbols for main parts of the drawings

G: Girder B1, B2: Upper and lower reinforcing bars

L: Lattice P: Finishing Plate

1,11,21,31,41: Bracket 42: Flange part

43: bracket 44: weld tab

45: restriction tab

The present invention relates to a reinforced concrete slab structure, and more particularly to a deck panel that allows for quick reinforcement and work.

Reinforced concrete structure is a composite structure that uses a combination of concrete as a compression material and rebar as a tension material, and constitutes the predominance of general building structures.

The most common method for constructing such reinforced concrete structures is to construct formwork to form the outer surface of concrete, reinforce the reinforcement on the formwork, and inject concrete to form the mold when the curing is completed. It takes place to remove it.

Such formwork is hypothesized by general plywood and lumber, etc. Since the work of reinforcing bar reinforcement on the formwork should have a substantial strength. Therefore, the construction of the formwork itself is a kind of construction work for the furniture structure, and the removal of the formwork after curing of the concrete also becomes the structure dismantling work, which requires considerable air.

In particular, the concrete surface and the formwork is easy to be attached, there is a lot of difficulty in dismantling, accordingly, the surface of the structure is poor to require a separate finishing work, and the formwork with weak durability is damaged, generating a large amount of waste materials after the completion of the construction.

The problem of using formwork has been improved in two directions. One solution is to improve the formwork itself and to make it easier to install and dismantle, to create a beautiful surface that requires no finishing work, and to use it repeatedly due to its high durability.

Another solution is to use no formwork, that is, use the structure used to form the exterior of concrete as part of the reinforced concrete structure.

In such a formless process, a deck plate having a large corrugate cross section has been conventionally used. Deck plate has great bending and shear stiffness, so that workers can work on it only by straddling between beams or pillars, and it becomes part of the finishing material of the slab, so disassembly is unnecessary and wiring and There are a number of advantages to installing pipes in a bend.

However, in order to prevent corrosion of the deck plate, painting must be done on the exposed surface, and it is difficult to settle on the surface of the deck plate. In addition, the thickness of the slab is also increased to have a problem of lowering the layer height.

Proposed to solve the problem of such a deck plate is a deck panel as shown in FIG. Shown is a deck panel disclosed in Utility Model Publication No. 93-3882, etc., such a deck panel is a lattice material (L) that is bent in a zigzag form between the upper and lower reinforcement (B1, B2) To form a girder (G), which is predetermined on the finishing plate (P) by a spacer material (S) that is bent in a mountain shape to intersect the girder (G). It is configured to be fixed by spacing of.

Here, the finishing plate (P) is made of a material that does not require a separate anticorrosive coating, such as a plated steel sheet and is generally configured in the form of a corrugated plate for increasing the local strength.

The deck panel (D ') is composed of a span between the beams or pillars and supported on them, and then cast concrete from the upper portion to form a slab as shown in FIG.

In the finished slab, the upper and lower reinforcing bars (B1, B2) constitute the main reinforcing bar of the slab, and the finishing plate (P) closes the lower surface of the slab. The upper part of the deck panel is provided with a mesh reinforcing bar (M) as necessary to reinforce the local strength of the slab and to add the main reinforcing bar.

Such a deck panel (D ') is connected through the compensation of one beam, etc. to form a continuous deck (deck), it becomes a work platform of construction, and after the casting of concrete (C) reinforced concrete integrally with the concrete (C) It will make up the slab.

However, in the conventional deck panel (D) as described above, since the girder (G) is bonded to the finishing plate (P) by the spacer material (S) intersecting thereto, it causes various problems.

In other words, when the weight or equipment of the worker is placed on the finishing plate (P) and moved and the concrete is injected, the load is transmitted to the girder (G) through the spacer material (S). Since the stress in the direction can only be transmitted by its own bending, the actual girder G cannot act as a girder with respect to the finishing plate P. Therefore, such a deck panel (D) has a small load resistance, it is difficult to function as a work deck without additional reinforcement.

In addition, since the girder (G) becomes the longitudinal strength member at the completion of the slab, even if the girder (G) is to be installed to maintain a proper interval perpendicular to the finishing plate (P), it is exactly vertical by the spacer material (S) having a complex bend It is practically impossible to install so that the girder G is installed in a warped state, thereby causing a problem of causing deformation of the finished slab and lowering the strength.

In view of such a conventional problem, an object of the present invention is to provide a deck panel in which the girder efficiently reinforces the load of the finishing plate and can be installed vertically accurately.

Deck panel according to the present invention for achieving the above object is characterized in that to join the bracket (bracket) along the installation position of the girder on the finishing plate and to join the girder to the bracket.

According to this configuration, the girder can be installed exactly vertically with respect to the finishing plate, as well as efficiently receive and reinforce the load of the finishing plate, thereby greatly increasing the load capacity.

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

In FIG. 3, the girder G formed by connecting the upper and lower reinforcing bars B1 and B2 with the lattice material L bent in a zigzag is arranged in two rows on the finishing plate P. And are joined between the brackets 1 to be coupled with the finishing plate P to form the deck panel D.

In the embodiment of FIG. 3, the bracket 1 constitutes an L-shaped lug by a steel plate or the like, which is configured between two brackets 1 as shown in FIG. The girder G can be easily joined to the bracket 1 by placing the lower reinforcement B2 of (G) and pressing and energizing, ie resistance welding, the two pressure electrodes W1 and W2 from the outside. It becomes possible.

Preferably each bracket 1 can be joined to the finishing plate P by spot welding, which is also a kind of resistance welding.

The bracket 1 may be formed of a steel wire as shown in FIGS. 5 to 6 in addition to a plate such as a steel sheet.

First, the bracket 11 of FIG. 5 is formed by bending the steel wire into a door shape and bending both ends to the outside, and then placing the lower reinforcing bar B2 of the girder G between the two brackets 11. It is a structure to join.

Meanwhile, the embodiment shown in FIG. 6 is a configuration for bonding and supporting the girder G with one bracket. First, the configuration of FIG. 6 (a) is bent to the side of the door-shaped bracket 21 laterally. It forms a support portion 21a on which the lower reinforcement B2 of the girder G is placed, and bends the legs 21b and 21c at both ends in opposite directions to each other.

On the other hand, the bracket 31 of FIG. 6 (b) is configured to continuously support the bracket 21 of (a) in the longitudinal direction of the girder G to form the support part 31a. The lower reinforcing bar B2 of the girder G of FIGS. 6A and 6B is mounted on the supporting parts 21a and 31a, and then the lower reinforcing bars B2 and the supporting parts 21a and 31a are joined to each other. Support the girder (G).

On the other hand, the configuration of FIG. 7 facilitates the installation of the bracket 41 and the installation of the girder G to the bracket 41 and the joining of the bracket 41 and the girder G as well as the closing plate P. The longitudinal reinforcement of) is also possible.

The bracket 41 is composed of blanking and bending of the fin material having the same length as that of the finishing plate P, and includes a flange portion 42 to be joined to the finishing plate P and a predetermined portion. Alternately provided bracket portions 43 arranged thereon at design intervals.

The bracket portion 43 has two welding tabs 44 which are bent upwards, and preferably has a restriction tab 45 which is bent a portion of the welding tab 44 laterally.

When the brackets 41 are arranged on the finishing plate P and the plurality of positions of the flanges 42 are joined to the finishing plate P by spot welding or the like, the brackets 41 are finished plates (P). It acts as a longitudinal strength member that reinforces longitudinal strength with respect to).

Next, when the lower reinforcing bar B2 of the girder G enters between the two welding tabs 44 of the bracket part 43, the lower part of the lower reinforcing bar B2 contacts the limit tab 45 to set its height.

Then, the girder G is joined to the bracket 41 by pressing and energizing the pressure electrodes W1 and W2 from the outside of the two welding tabs 44 as shown in FIG.

As described above, according to the present invention, the girder may not only be accurately installed on the finishing plate but also form an integral structure with the finishing plate to provide a deck panel having a high load capacity.

Claims (6)

In the deck panel for reinforced concrete slab construction consisting of joining the girder formed by connecting the upper and lower reinforcing bar to the finishing plate, the brackets along the installation position of the girder (G) on the finishing plate (P) A deck panel of reinforced concrete slabs, characterized in that the girder (G) is bonded to the brackets (1,11,21,31,41) by arranging 1,11,21,31,41. The deck panel of reinforced concrete slab according to claim 1, wherein the brackets (1, 11) are L-shaped and arranged in two rows. The deck panel of reinforced concrete slab according to claim 2, wherein the bracket (1) is configured in the form of a lug bent over a steel sheet. The deck panel according to any one of claims 1 to 3, wherein the brackets (11, 21, 31) are formed by bending steel wires. According to claim 1, wherein the bracket 41 is a flange portion 42 to be bonded to the closing plate (P) and the bracket portion 43 to which the girder (G) is to be bonded alternately arranged Featuring deck panels of reinforced concrete slabs. The lower portion of the lower reinforcement (B2) is in contact with the two welding tabs (44) in which the bracket portion (43) is to be inserted between the lower reinforcement (B2) of the girder (G). Deck panel of reinforced concrete slab, characterized in that it comprises a limit tab (45).