KR20200008356A - Truss deck for long-span slab - Google Patents

Abstract

The present invention relates to a truss deck for a long span, which, when a reinforced concrete slab is constructed by using a truss deck, guarantees a sheathing thickness of a lower chord constituting a steel wire truss without an additional spacer, while mechanically and solidly fixating the steel wire truss and a deck plate for guaranteeing mutual integrity. To this end, the truss deck for a long span according to the present invention comprises: a deck plate having a flat unit monolithically connected to an upper end of a valley unit; and a steel wire truss composed of a lower chord provided in a longitudinal direction at a lower portion of the valley unit, a pair of upper chords provided at an upper portion of the lower chord, and a pair of waveform lattices which are formed in a waveform, and of which an upper portion is coupled to the inside of the upper chords and a lower portion is coupled to the outside of the lower chord. Here, a support stepped projection unit, which is inwardly bent in an L shape, is formed at a corner of a lower end of the valley unit of the deck plate. In addition, a lower foot, which is bent in an outer horizontal direction to be supported with an upper portion of the support stepped projection unit, is provided at a lower end of the waveform lattices.

Description

Truss deck for long-span slab}

In the present invention, when the reinforced concrete slab is constructed using a truss deck, it secures the thickness of the lower chord constituting the steel truss without a separate spacer, and simultaneously secures the steel truss and the deck plate mechanically to secure mutual integrity. It is about the long span truss deck.

Reinforced concrete slabs are constructed using permanent formwork or temporary formwork. However, since the temporary formwork is labor-intensive and has a disadvantage of poor workability, construction methods have recently been shifted to a permanent formwork method.

Accordingly, a method of placing concrete directly on top of a deck plate or placing reinforcing steel and placing concrete on the top of a flat deck plate, or placing a concrete on a truss deck that has a flat steel truss or a triangular steel truss attached to an upper surface of a flat steel plate, is used. .

In addition, as shown in Figure 1, conventionally used to increase the bending rigidity of the member by bending the deck plate to increase the cross-sectional secondary moment so that the valley and the floor is formed alternately for use in the long span (registered patent) 10-1783035).

However, such a prior art should be arranged so that the chord is spaced apart from the deck plate in order to ensure the thickness of the coating. Therefore, there is an inconvenience in that a separate spacer is fixed to the deck plate to support the lower chord.

In addition, the upper triangular truss girder is to be welded to the deck plate top plate or step. However, at this time, since the welded portion is exposed to the lower side, there is a fear that the welded deck plate may be corroded during use.

In addition, in case of welding failure, the steel wire truss may be separated from the deck plate during lifting or worker operation.

In order to solve the above problems, the present invention is to provide a long span truss deck that can secure the thickness of the lower chord constituting the steel wire truss without a separate spacer.

The present invention is to provide a truss deck for long span that can solve the problems caused by the welding coupling of these members by mechanically combining the steel wire truss with the deck plate.

The present invention is to provide a long span truss deck that can solve the problems caused by the separation of these members by securing the steel wire truss firmly with the deck plate to secure mutual integrity.

According to a preferred embodiment of the present invention, a flat plate is integrally connected to the upper end of the valley; And a lower chord provided in the longitudinal direction at the lower part of the valley, and formed as a pair of upper chords and corrugations provided at the upper part of the lower chord, the upper part of which is coupled to the inside of the upper chord, and the lower part of the lower chord that is coupled to the outside Steel wire truss consisting of a pair of corrugated lattice; Consists of, the bottom edge of the valley plate of the deck plate is formed with a support stepped bent in the L-shape inward, the lower end of the corrugated lattice is bent in the outer horizontal direction is provided with a lower foot supported on the top of the support stepped portion It provides a long span truss deck, characterized in that.

The present invention according to another preferred embodiment provides a truss deck for long spans, characterized in that the lower coupling groove is inserted into the valley side wall of the upper portion of the support stepped portion is inserted into the end of the lower foot.

According to another preferred embodiment of the present invention, the upper end of the corrugated lattice is provided with a support bent to the outer bottom of the upper chord, and the lower end of the support part is provided with an upper foot bent in the outer horizontal direction and supported on the sidewall of the valley part. It provides a long span truss deck characterized in that the.

The present invention according to another preferred embodiment provides a truss deck for the long span, characterized in that the upper coupling groove portion is bent to the end of the upper foot is formed in the upper side of the valley.

According to another preferred embodiment of the present invention, there is provided a truss deck for long spans, characterized in that a transverse spacer is provided between the pair of corrugated lattices to maintain the spacing of the corrugated lattice.

The present invention according to another preferred embodiment provides a truss deck for the long span, characterized in that the upper end of the corrugated lattice is provided with a horizontal extension bent in the horizontal direction of the phase current.

The present invention according to another preferred embodiment provides a long span truss deck, characterized in that the bent reinforcement bent inclined inwardly formed on the side wall of the valley.

According to the present invention has the following effects.

First, it can be supported by mounting the lower foot formed at the bottom of the corrugated lattice to the a-shaped support end portion bent inward to the lower edge of the valley portion of the deck plate. Accordingly, since the lower chord of the steel truss is spaced apart from the bottom of the valley by a predetermined distance, the cover thickness of the lower chord can be sufficiently secured without a separate lower spacer.

Second, the deck plate and the steel wire truss can be easily coupled by biting the lower foot of the corrugated lattice in the lower coupling groove formed on the side wall of the valley at the upper part of the support step. Accordingly, the deck plate and the steel wire truss can be firmly fixed without a separate welding process, and various problems associated with the conventional welding process can be solved.

Third, when the upper foot formed by vertically bending the support formed at the top of the corrugated lattice is supported on the upper sidewall of the valley, the steel truss does not open even if the worker steps on the top of the steel truss during work or movement. I can keep it.

Fourth, when the upper foot of the corrugated lattice is inserted into the upper coupling groove formed in the upper side of the valley side wall of the deck plate, the steel wire truss can be more firmly fixed to the deck plate. This can prevent the falling of the deck plate and steel wire truss during lifting and transport.

1 is a cross-sectional view showing a conventional truss deck.
Figure 2 is a perspective view showing the coupling relationship between the deck plate and the steel wire truss of the truss deck for long span of the present invention.
Figure 3 is a cross-sectional view of the truss deck for long span of the present invention.
4 is an enlarged view of a portion A of FIG. 3.
5 is an enlarged view of a portion B of FIG. 3.
Figure 6 is a cross-sectional view of the truss deck for the long span of the present invention with a transverse spacer.
Figure 7 is a cross-sectional view of the truss deck for the present invention span provided with a horizontal extension.

Hereinafter, the present invention will be described in detail according to the accompanying drawings and preferred embodiments.

Figure 2 is a perspective view showing the coupling relationship between the deck plate and the steel wire truss of the truss deck for long span of the present invention, Figure 3 is a cross-sectional view of the truss deck for long span of the present invention. 4 is an enlarged view of portion A of FIG. 3, and FIG. 5 is an enlarged view of portion B of FIG. 3.

As shown in Figures 2 and 3, the truss deck for the long span of the present invention comprises a deck plate (1) in which the flat portion 12 is integrally connected to the upper end of the valley (11); And a lower chord 21 provided at a lower portion of the valley 11 in the longitudinal direction, a pair of upper chords 22 provided at an upper portion of the lower chord 21, and a waveform so that the upper chord 22 is formed. A steel wire truss (2) composed of a pair of corrugated lattices (23) coupled to the inside of the lower portion and coupled to the outside of the lower chord (21); Consisting of, the bottom edge of the valley portion 11 of the deck plate 1 is formed with a support stepped portion 111 is bent in the L-shape inward, the bottom of the corrugated lattice 23 is bent in the outer horizontal direction A lower foot 231 is provided on the upper portion of the support stepped portion 111.

According to the present invention, the cover thickness of the lower chord 21 constituting the steel truss 2 can be secured without a separate spacer, and the steel truss 2 can be firmly fixed to the deck plate 1 to ensure integrity. It is to provide a long span truss deck.

The deck plate 1 is formed such that the flat portion 12 is integrally connected to the upper end of the valley 11.

The valleys 11 may be provided in a single or a plurality of rows.

The flat portion 12 is integrally connected to the upper end of the valley (11).

Deck plate 1 composed of the valley portion 11 and the flat portion 12 may be formed by bending the iron plate.

At this time, the end portion of the outermost flat portion 12 is formed with a coupling portion 121 bent in an inverted U-shape can be configured to overlap the end of the adjacent deck plate (1) (Fig. 3, etc.).

The reinforcing rib 122 may be bent to protrude along the longitudinal direction of the deck plate 1 to reinforce the bending rigidity of the deck plate 1 at the center of the flat part 12.

The steel wire truss 2 is formed by a lower chord 21 provided in the longitudinal direction at the lower portion of the valley 11, a pair of upper chords 22 provided in the upper part of the lower chord 21, and a corrugated top. Is coupled to the inside of the upper choke 22, the lower portion is composed of a pair of corrugated lattice 23 is coupled to the outside of the lower chord (21).

The corrugated lattice 23 is provided in a pair so that the lower part is respectively coupled to both sides of the lower chord 21, and the upper part is respectively coupled to the inside of the left and right upper chords 22.

The corrugated lattice 23 is bent in the outer horizontal direction at the bottom to form a lower foot 231.

As shown in FIG. 4, the corrugated lattice 23 has a lower foot 231 formed by extending a predetermined length to a lower portion of the lower chord 21 and horizontally bending it outward.

In addition, the lower edge of the valley portion 11 of the deck plate 1 is formed with a support stepped portion 111 bent in the L-shape inward.

The corrugated lattice 23 is supported by a lower foot 231 formed at a lower end thereof mounted on an upper portion of the support step 111.

As such, when the lower foot 231 of the corrugated lattice 23 is supported by the support step 111 formed at the lower end of the valley 11, the lower chord 21 constituting the steel wire truss 2 is the valley 11. It is spaced apart from the bottom surface by a certain distance. Therefore, the covering thickness of the lower chord 21 can be sufficiently secured without a separate lower spacer for supporting the lower chord 21.

In addition, it is possible to save the amount of concrete that is filled in the valley 11 by the support step 111.

In addition, it is possible to reduce the local buckling effect by reducing the thickness ratio of the side wall and the bottom of the valley 11 while maintaining the amount of steel.

As shown in FIG. 4, a lower coupling groove 112 into which an end of the lower foot 231 is inserted may be bent on a sidewall of the valley 11 of the upper support step 111.

Since the lower foot 231 of the corrugated lattice 23 is coupled to the deck plate 1 by the lower coupling groove 112, the steel wire truss 2 may be firmly fixed.

Therefore, the steel wire truss 2 can be fixed to the deck plate 1 without a welding process.

In addition, conventionally, the deck plate (1) and corrugated lattice (23) by bolts, the work to remove the deck plate (1) after the completion of the slab construction was very cumbersome.

However, in the case of the present invention it is also easy to remove the deck plate (1) after the completion of the slab construction.

As shown in FIG. 5, the upper end of the corrugated lattice 23 is provided with a support part 232 that is bent to the lower side of the upper chord 22, and the lower end of the support part 232 is bent in an outer horizontal direction. An upper foot 233 supported on the upper sidewall of the valley 11 may be provided.

As such, when the upper foot 233 is supported on the side wall of the valley 11, even if the worker steps on the upper portion of the steel truss 2 during work or movement, the steel truss 2 can be safely maintained without opening. have.

In addition, as shown in FIG. 5, an upper coupling groove 113 into which an end of the upper foot 233 is inserted may be bent on an upper sidewall of the valley 11.

The upper coupling groove 113 may be formed to be bent into a U-shape open side.

Therefore, since the upper and lower portions of the upper foot 233 can be configured to be caught inside the upper coupling groove 113, the steel wire truss 2 can be firmly fixed to the deck plate 1. This can prevent falling of the deck plate 1 and the steel wire truss (2) during lifting and transport.

In addition, the upper coupling groove 113 may be fixed to the deck plate (1) the upper foot 233 by spot welding at the top.

In this case, since the welded part is not exposed to the outside, there is no fear of corrosion of the deck plate 1.

As described above, when the lower foot 231 is inserted into and fixed to the lower coupling groove 112, and the upper foot 233 is inserted into and fixed to the upper coupling groove 113, the deck plate 1 and the steel wire truss ( 2) can be more firmly integrated.

6 is a cross-sectional view of the truss deck for the long span of the present invention provided with a lateral spacer.

As shown in FIG. 6, a lateral spacer 3 may be provided between the pair of corrugated lattice 23 to maintain the spacing of the corrugated lattice 23.

Since the pair of corrugated lattice 23 is maintained at a constant interval by the lateral spacers 3, it is possible to prevent the pair of phase currents 22 from being retracted from each other by external force or the like. Accordingly, it is possible to prevent the upper foot 233 from falling out of the upper coupling groove 113.

The lateral spacers 3 can be naturally fixed by the elasticity of the corrugated lattice 23 simply by being sandwiched between the corrugated lattice 23.

7 is a cross-sectional view of the truss deck for the long span of the present invention provided with a horizontal extension.

As illustrated in FIG. 7, the upper end of the corrugated lattice 23 may be provided with a horizontal extension part 234 bent in an outer horizontal direction of the upper chord 22.

The steel wire truss (2) because the upper chord 22 is formed to protrude a certain height above the flat portion 12 of the deck plate 1, it may be difficult for the worker to step on the work or movement.

Therefore, by horizontally bending the upper end of the corrugated lattice 23 to the outside of the upper current 22 to form a horizontal extension portion 234, the horizontal extension portion 234 at the same level as the upper current 22 and the upper current 22 ) Can be configured to facilitate operation and movement of workers.

At this time, the horizontal extension portion 234 is connected to the cantilever type from the upper choke 22, it can be bent downward when a working load is applied.

Therefore, the horizontal extension portion 234 of the adjacent steel wire truss 2 can be configured to be supported at both ends by overlapping joints with the connecting reinforcement 24 and fixed by a binding line or tack welding.

The side walls of the valleys 11 may be provided with a bending reinforcing portion 114 bent inclined inward.

When the bending reinforcement 114 is formed, the cross-sectional coefficient of the side wall of the valley 11 is increased, so that local bucking can be prevented.

1: Deck Plate 11: Goal
111: support step portion 112: lower coupling groove portion
113: upper coupling groove 114: bending reinforcement
12: flat portion 121: coupling portion
122: reinforced rib 2: steel truss
21: Lower Present 22: Upper Present
23: Corrugated Lattice 231: Lower Foot
232: support 233: upper foot
234: horizontal extension portion 24: connecting rebar
3: transverse spacer

Claims (7)

A deck plate 1 having a flat portion 12 integrally connected to an upper end of the valley 11; And
The lower chord 21 provided in the longitudinal direction at the lower portion of the valley 11, a pair of upper chord 22 provided in the upper portion of the lower chord 21 and a waveform formed in the upper portion of the upper chord 22 A steel wire truss (2) composed of a pair of corrugated lattices (23) coupled to the inside and coupled to the outside of the lower chord (21); Consisting of
The lower edge of the valley portion 11 of the deck plate 1 is formed with a support stepped portion 111 bent inwardly in a L-shape,
The lower end of the corrugated lattice (23) truss deck for the long span, characterized in that the lower foot 231 is bent in the outer horizontal direction is supported on the upper portion of the support step (111).
In claim 1,
Truss deck for long spans, characterized in that the lower coupling groove 112 is bent to the end portion of the lower foot 231 is formed in the side wall of the valley (11) above the support stepped portion (111).
In claim 1,
The upper end of the corrugated lattice 23 is provided with a support portion 232 bent to the outer lower portion of the upper chord 22, the lower end of the support portion 232 is bent in the outer horizontal direction to the upper side of the valley 11 Truss deck for long spans, characterized in that the upper foot 233 is supported.
In paragraph 3
Truss deck for long spans, characterized in that the upper coupling groove 113 is bent to the end of the upper foot 233 is inserted into the upper side of the valley (11).
The method of claim 3 or 4,
Truss deck for long spans, characterized in that between the pair of corrugated lattice (23) is provided with a transverse spacer (3) to maintain the spacing of the corrugated lattice (23).
In claim 1,
Truss deck for the long span, characterized in that the upper end of the corrugated lattice 23 is provided with a horizontal extension portion 234 bent in the horizontal direction of the outer choke 22.
In claim 1,
Truss deck for long spans, characterized in that the bent reinforcement portion 114 is formed inclined inwardly on the side wall of the valley (11).

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