KR102186162B1 - Deck-Plate with Spacer for Long Span - Google Patents

Abstract

The present invention relates to a deck plate for a long span.
To this end, in the present invention, in a long span deck plate formed by having a truss girder provided on a bone-type deck, the bone-type deck has a pair of bone side plates extending upward at both ends of the bone-type deck, so that a beam forming part is formed on the inner side. It is provided, a horizontal plate is extended horizontally outside the upper end of the bone-shaped deck, spacers are fitted at regular intervals in the longitudinal direction to the beam forming portion of the bone-shaped deck, and a truss girder is coupled to the spacer.
This simplifies assembly, fabrication and construction, and enables reinforcement of the bone-shaped deck.

Description

Deck-Plate with Spacer for Long Span}

The present invention relates to a deck plate for a long span, and more particularly, a pair of bone side plates extending upwardly to both ends of the bone bottom plate to have a bone-shaped deck provided with a beam forming portion on the inside thereof, the beam forming portion It relates to a deck plate for a long span in which spacers are fitted at regular intervals in the longitudinal direction, and a truss girder is fitted to the spacers.

In general, architectural structures can be subdivided into steel structures, reinforced concrete structures, and steel reinforced concrete structures, which are classified according to the construction method of structures forming beams and columns as the basic skeleton of a building.

In most buildings, slabs are constructed by forming a floor plate or roof. In general, to form a slab, columns and beams are formed with steel or reinforced concrete, and a formwork is placed between adjacent beams, and then concrete is poured on the top. When curing of the concrete is completed, it is possible to provide a finished deck or roof by demolding the formwork.

However, the above-described conventional slab construction method required a copper bar as a material to support the formwork, and a number of reinforcing bars were placed and concrete was poured. There was a problem that a process was required.

In order to solve this problem, in recent years, the upper and lower reinforcing bars are welded with a wave-type lattice bar to manufacture various shapes of truss girders. Deck plates that can improve workability and ensure structural stability of the slab are being actively produced by omitting them.

In general, the deck plate described above has both ends mounted between adjacent beams, and concrete is placed on the top of the deck plate for construction, and the interval between the beams is within 3 ~ 4m, so the length of the deck plate also corresponds to this. It is made possible.

However, in recent years, as the three-dimensional design of the building is made, it is necessary to mount the deck plate between the long span of 4 m or more depending on the site conditions, and accordingly, the need to manufacture the deck plate to correspond to the long span has emerged. . However, in the case of extending the length of the deck plate in response to the bending moment, the height of the truss girder should be increased to secure sufficient bending stiffness, but the self-weight increases due to the increase of the slab height, so There was a problem that the amount of concrete to be poured also increased.

In order to solve this problem, in recent years, by using a bone deck having a sufficient height, a truss girder is provided in the valley provided on the bone deck, so that the beam is integrated under the slab by the concrete provided in the valley when concrete is placed for later slab construction. A deck plate for long span formed of

As a conventionally proposed deck plate for a long span, the'Reinforcement deck type floor structure for a long span and its construction method' of Korean Patent Publication No. 10-2006-0011235 (published on February 3, 2006, hereinafter'prior technical literature 1) '). The prior art document 1 is manufactured so that the bone-type deck has expandability in the width direction, so that it can be flexibly applied to the conditions of the construction site, and a pair of lower rebars are arranged at the bottom of the upper rebar in the valley as a whole. By arranging a truss girder with a triangular structure, the technical effect of realizing a building with a long span and wide indoor space was exhibited.

In addition, as a similar concept, there is a'inverted triangular truss girder insertion deck' (registered on September 22, 2017, hereinafter referred to as'prior technical document 2') of Korean Patent Registration No. 10-1783035. Unlike the prior art document 1, the prior art document 2 arranges a triangular truss girder in the reverse direction, so that a pair of reinforcing bars exhibits sufficient tensile strength, and further, the lattice bar of the truss girder is bent and mounted on the deck. Therefore, by choosing a structure that is fastened with a coupling means such as pieces or bolts, it is possible to securely mount it, and to accommodate some distribution that the weight of concrete is concentrated on the deck.

However, in the prior art document 1 as well as in the prior art document 2, the truss girder is not stably settled when concrete is poured later, as the fastening through a piece or bolt does not provide sufficient bonding force. There was a problem of separation, and in particular, there was a problem in that a constant and sufficient cover thickness was not formed as the space between the deck and the truss girder was not securely secured.

In addition, as the thin deck is used, the deck itself is distorted or deformed due to its own weight or contraction when concrete is poured later, and thus there is an additional problem in that structurally and geometrically stable beams cannot be provided.

Republic of Korea Patent Publication No. 10-2006-0011235 (published on February 3, 2006, title of invention: reinforced deck-type floor structure for long span and its construction method) Korean Patent Registration No. 10-1783035 (registered on September 22, 2017, title of invention: inverted triangular truss girder insertion deck)

The present invention was conceived to solve the above problems, and in manufacturing a deck plate for long span by combining a truss girder and a tech, sufficient bonding force is ensured so that it does not flow during concrete pouring, and the truss girder is placed in a certain position. It is an object of the present invention to provide a long-span deck plate having sufficient rigidity to ensure that a standardized concrete cover of a certain thickness is secured and the thin-shaped deck is not deformed by the pouring load or contraction of the concrete.

In order to achieve the above object, the present invention provides a truss girder 200 on a bone deck 100 for a long span deck plate (LD), wherein the bone deck 100 is a bone bottom plate 110 A pair of bone side plates 120 are extended to the top at both ends of) to provide a beam forming part 130 on the inner side, and a horizontal plate 140 on the outside horizontally at the top of the bone side plate 120 The truss girder 200 has a pair of lattice bars 220 at an upper portion of the lower reinforcing bar 210 obliquely coupled to the outside, and an upper reinforcing bar 230 at the upper portion of the lattice bar 220, respectively. It is combined to have an inverted triangle structure, and the beam forming part 130 is provided with spacers 300 at regular intervals in the longitudinal direction, and the spacer 300 is manufactured by bending a wire W, The end portion is horizontally bent to form a foot portion 340, and the bone side plate 120 of the bone-shaped deck 100 has at least one stepped portion 121 bent inside with respect to the lower portion thereof, and the spacer At least one locking jaw 310 is formed in a shape corresponding to the stepped portion 121 of 300, so that the spacer 300 is fitted to the beam forming portion 130 of the bone-shaped deck 100, and the At the center of the spacer 300, a fitting groove 320b that is elastically deformed so that the lower reinforcing bar 210 of the truss girder 200 is fitted is provided.

delete

In addition, in the foot portion 340 of the spacer 300, both ends of the wire W are horizontally bent, and the stepped portion 121 formed adjacent to the valley bottom plate 110 of the bone deck 100 In the foot portion 340 is fitted.

In addition, the bone deck 100 is provided with a plurality of beam forming portions 130, the horizontal plate 140 is formed to extend horizontally outside the upper end of the bone side plate 120 located at both ends, adjacent A floorboard 150 is horizontally formed on the top of the bone side plate 120 located between the beam forming parts 130.

In addition, the spacer 300 has a V-shaped lattice mounting portion 360b at an angle corresponding to the inclination of the lattice bar 220 so that the lattice bar 220 of the truss girder 200 can be stably mounted. Is formed.

In addition, the spacer 300 is bent upwardly outward to both sides around the fitting groove 320b to form a V-shaped lattice mounting portion 360b at an angle corresponding to the inclination of the lattice bar 220, and again The iron wire W is bent so that the foot portion 340 is horizontally bent outward in a downwardly bent state.

In addition, the wire W forming the spacer 300 is bent in a shape symmetrical in the longitudinal direction as a whole, so that a pair of V-shaped lattice mounting portions 360b are symmetrical around a pair of fitting grooves 320b. The foot portions 340 formed at both ends in the width direction are also formed in a shape symmetrical in the length direction.

According to the long span deck plate LD of the present invention, spacers are fitted to the bone-shaped deck at regular intervals in the longitudinal direction, and a truss girder can be coupled to the spacer, thereby simplifying assembly and manufacturing.

Furthermore, there is an advantage that stable and efficient construction is possible because sufficient bonding force is secured so that the truss girder does not flow within the shape of the bone deck even when concrete is placed for future construction.

In addition, since the beam forming part of the bone-shaped deck can maintain a certain shape by the spacer despite the pouring load or contraction of concrete, it is possible to prevent the thin bone-shaped deck from being formed and deformed.

In addition, since the spacer secures a certain gap between the bone-shaped deck and the truss girder, the truss girder can be provided in the correct position, so that a standardized concrete covering of a certain thickness can be formed.

In addition, the bone side plate of the bone deck may have at least one stepped portion to secure the rigidity of the bone-shaped deck itself, and the spacer was inserted into the beam forming portion as a locking step was formed in a shape corresponding to the stepped portion in the spacer. Stable fastening is possible in bonding, and further, reverse separation can be prevented.

In addition, the spacer is provided with a fitting groove that is elastically deformed so that the lower reinforcing bar of the truss girder is fitted, so that manufacturing and construction efficiency can be secured in combining the truss girder.

In addition, by having a deck plate of an inverted triangle structure, a pair of upper reinforcing bars are provided, so that stable reinforcement against the bending stress applied to the slab is possible, and at the same time, the amount of reinforcing bars that must be additionally laid to form the slab is reduced. It is an object of the invention to provide a deck plate for a long span that can secure the efficiency of

1 and 2 are exploded perspective views showing a long span deck plate and a combined state thereof according to an embodiment of the present invention.
Figure 3 is a cross-sectional view showing a fastening method of the deck plate for a long span according to an embodiment of the present invention.
Figure 4 is an exploded perspective view showing a coupled state of a long span deck plate according to another embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail based on the items shown in the drawings.

The long span deck plate (LD) of the present invention is formed by being provided with a truss girder 200 on the bone deck 100 as shown in FIG. 1, and the bone deck as shown in the exploded perspective view of FIG. 2 In order to stably couple the truss girder 200 within 100, a spacer 300 is additionally provided.

The bone-shaped deck 100 has a pair of bone side plates 120 extending upward at both ends of the bone bottom plate 110 to provide a beam forming part 130 inside, and the bone side plate 120 A horizontal plate 140 is formed to extend horizontally outside the upper end.

The bone-shaped deck 100 is preferably produced by bending a thin sheet of metal, and bending a sheet of metal having a certain width and length, but bending both ends around the bottom plate 110 to form a pair of bone sides A plate 120 is formed, and the bone side plate 120 is again bent in an outer horizontal direction to form a horizontal plate 140 to be manufactured.

A reinforcing bent portion 111 bent upward may be formed at a lower portion of the valley bottom plate 110. The reinforcing bent part 111 may function to enable stable reinforcement of the bone-shaped deck 100 from its own weight or deformation, as well as function as a fixture for mounting a ceiling material in the future.

Fastening bent portions 141 and 142 are formed at outer ends of the pair of horizontal plates 140 of the bone deck 100, so that the fastening bent portions 141 and 142 of the adjacent bone deck 100 are mutually In the state of being mounted so as to be overlapped, by integrally bending the bone-shaped decks 100 in a geom-folding manner as shown in FIG. 3, the bone-shaped decks 100 may be mutually fastened and expanded in the width direction.

Further, by folding the fastening bent portions 141 and 142, there is an advantage in that leakage of the paste can be prevented during concrete pouring, and reinforcement of a connection portion, which may be relatively weak, is possible.

In addition, as shown in Fig. 4, by forming a reinforcing unevenness 160 formed by pressing on the surface of the bone-shaped deck 100, deformation and bending due to a concrete load as a limit that a thin metal plate can have is prevented. Can be prevented.

A spacer 300 may be fitted to the beam forming part 130 provided on the inner side of the bone-shaped deck 100 at regular intervals in the longitudinal direction. The spacer 300 may be manufactured to have a certain thickness using a synthetic resin material, and may be manufactured such that a reinforcing flange portion having a certain height is formed along the rim by applying a press to a thin metal plate.

In addition, as shown in FIG. 2 or 4, by bending one wire to have a certain shape, it may be fitted and coupled to the beam forming part 130 of the bone-shaped deck 100.

The spacer 300 is manufactured so that the overall shape corresponds to the shape of the beam forming part 130 of the bone deck 100, so that when the spacer 300 is provided, despite the load or contraction of concrete to be poured later, Since the beam forming part 130 is reinforced by the spacer 300, a certain shape can be maintained.

In addition, the spacer 300 is manufactured in a shape in which a part of the truss girder 200 can be coupled, so that the truss girder 200 can be stably and easily coupled to the spacer 300, thereby simplifying assembly and manufacturing. Is exerted.

Therefore, even when placing concrete for future construction, the spacer 300 is stably fitted into the inside of the bone deck 100, as well as the truss girder 200 is also coupled to the spacer 100, so that the bone deck ( It does not flow within the beam forming part 130 of 100), and is stably fixed to enable efficient construction.

In addition, the bone side plate 120 of the bone deck 100 has at least one stepped portion 121 that is bent inside with respect to the lower portion, and the spacer 300 has a shape corresponding to the stepped portion 121. At least one locking protrusion 310 may be formed.

Thus, as shown in FIG. 3, when the spacer 300 is inserted along the bone side plate 120 of the bone deck 100, the locking jaw 310 is caught by the stepped portion 121 Separation in the reverse direction can be prevented, so a solid coupling force can be secured.

On the other hand, in the deck plate (LD) for a long span of the present invention, the truss girder 200 has a pair of lattice bars 220 on the upper portion of the lower reinforcing bar 210 obliquely coupled to the outside, and the lattice bar ( It is preferable that the upper reinforcing bars 230 are coupled to the upper part of 220) to have an inverted triangle structure.

In the truss girder 200 having an inverted triangle structure, a product formed to be connected to each other by a pair of lattice bars is provided with a pair of lower reinforcing bars under the generally manufactured upper reinforcing bar. .

The present invention is provided with a deck plate 200 of an inverted triangle structure, as it takes a structure in which a pair of upper reinforcing bars 230 are provided, it is possible to stably reinforce the bending stress acting on the slab completed by concrete pouring There is. In addition, since it is possible to reduce the amount of reinforcing bars that must be additionally laid to form a slab, it is possible to secure construction efficiency.

Meanwhile, as illustrated in FIGS. 1 to 4, in an exemplary embodiment, the spacer 300 may be formed by bending a wire W. Even when the spacer 300 is made of iron wire (W), as shown in the cross-sectional view of FIG. 3, it is manufactured in a shape corresponding to the shape of the beam forming part 130 of the bone-shaped deck 100, and the bone-shaped deck 100 ) Is desirable to be reinforced.

In addition, as shown in FIG. 3, a plurality of stepped portions 121 are formed on the bone side plate 120 of the bone deck 100, and the spacer 300 has a shape corresponding to the stepped portion 121 at least. One locking projection 310 may be formed. However, both ends of the iron wire (W) constituting the spacer 300 are horizontally bent to form the foot portion 340, and the foot portion 340 is the valley bottom plate 110 of the bone deck 100 By implementing the foot portion 340 to be fitted to the stepped portion 121 formed adjacent to, the spacer 300 can be manufactured to be stably fixed to the bone-shaped deck 100.

In another shape, as shown in FIG. 4, the spacer 300 is made of a wire W, but the foot portion 340 may be expanded to enable self-standing. As a result, when the truss girder 200 is provided, it is possible to prevent buckling and secure a solid support.

Meanwhile, a fitting groove 320b that is elastically deformed so that the lower reinforcing bar 210 coupled to the truss girder 200 having an inverted triangle structure may be provided in the center of the spacer 300 shown in FIG. 3. have.

In addition, the spacer 300 applied to the present invention has a lattice mounting portion 360b at an angle corresponding to the inclination of the lattice bar 200 so that the lattice bar 220 of the truss girder 200 can be stably mounted. Can be provided.

Therefore, as a preferred embodiment of the truss girder 200, a pair of lattice bars 220 on the upper portion of the lower reinforcing bar 210 are obliquely coupled to the outside, and upper reinforcing bars ( 230) is combined to have an inverted triangle structure, the lattice bar 220 is mounted on the V-shaped lattice mounting portion 360b, so that the truss centering on the lower reinforcing bar 210 coupled to the fitting groove 320b The girder 200 may be stably mounted.

On the other hand, the long-span deck plate (LD) according to the present invention is a bone-shaped deck 100 on which one beam forming portion 130 is formed is continuously folded through a bent portion 141 and 142 as a medium in the width direction. It is also possible to construct in an expanded shape, but as shown in FIG. 4, a plurality of beam forming portions 130 are provided on the bone-shaped deck 100, and the top of the bone side plates 120 located at both ends The horizontal plate 140 extends horizontally to the outside, and the floorboard 150 may be horizontally formed on the top of the valley side plate 120 positioned between the adjacent beam forming portions 130.

If the length of the span is relatively shorter than the length of the normal span, by applying the bone-shaped deck 100 on which a plurality of beam forming portions 130 are formed, workability can be secured, and when a plurality of beam forming portions 130 are formed, the beam The height (dance) of the can be formed relatively low.

The long span deck plate (LD) according to the present invention described above can be implemented in other specific forms without changing the technical spirit or essential features of the present invention by those of ordinary skill in the art. You can understand.

Therefore, the embodiments described above are illustrative in all respects and should be understood as not limiting, and the scope of the present invention is indicated by the claims to be described later rather than the detailed description described above, and the meaning of the claims and All changes or modifications derived from the scope and equivalent concept should be interpreted as being included in the scope of the present invention.

Therefore, the embodiments described above are illustrative in all respects and should be understood as not limiting, and the scope of the present invention is indicated by the claims to be described later rather than the detailed description described above, and the meaning of the claims and All changes or modifications derived from the scope and equivalent concept should be interpreted as being included in the scope of the present invention.

LD: Long span deck plate 100: Bone deck
110: valley bottom plate 111: reinforcement bend
120: bone side plate 121: stepped portion
122: guide surface 130: beam forming portion
140: horizontal plate 141, 142: fastening bend
200: truss girder 210: lower reinforcement
220: Lattice bar 230: upper rebar
300: spacer 310: jamming jaw
320b: fitting groove 340: foot portion
350: reinforcement flange 360b: lattice mount
W: wire

Claims (7)

In the long span deck plate (LD) formed by being provided with a truss girder 200 on the bone deck 100,
The bone-shaped deck 100 has a pair of bone side plates 120 extending upward at both ends of the bone bottom plate 110 to provide a beam forming part 130 inside, and the bone side plate 120 ) At the top of the horizontal plate 140 is formed to extend horizontally,
In the truss girder 200, a pair of lattice bars 220 at an upper portion of the lower reinforcing bar 210 are obliquely coupled to the outside, and an upper reinforcing bar 230 is coupled to each of the upper portions of the lattice bar 220 to form an inverted triangle. Has the structure of,
The beam forming part 130 is provided with spacers 300 at regular intervals in the longitudinal direction, and the spacer 300 is manufactured by bending a wire W, and both ends are horizontally bent to form a foot part 340 ) Is formed,
The bone side plate 120 of the bone-shaped deck 100 has at least one stepped portion 121 bent inside with respect to a lower portion thereof, and the spacer 300 has at least one shape corresponding to the stepped portion 121. The locking protrusion 310 is formed so that the spacer 300 is fitted to the beam forming part 130 of the bone deck 100, and the lower reinforcement of the truss girder 200 is at the center of the spacer 300 A deck plate for a long span, characterized in that a fitting groove (320b) that is elastically deformed so that the 210 is fitted thereto is provided.
delete The method of claim 1,
In the foot portion 340 of the spacer 300, both ends of the iron wire W are horizontally bent, and the stepped portion 121 formed adjacent to the bone bottom plate 110 of the bone-shaped deck 100 A deck plate for a long span, characterized in that the foot portion 340 is fitted.
The method of claim 1,
The bone deck 100 is provided with a plurality of beam forming portions 130, and a horizontal plate 140 is formed to extend horizontally outside the top of the bone side plates 120 located at both ends, forming adjacent beams A deck plate for a long span, characterized in that a floor plate 150 is formed horizontally at the top of the valley side plate 120 positioned between the parts 130.
The method of claim 1,
The spacer 300 has a V-shaped lattice mounting portion 360b formed at an angle corresponding to the inclination of the lattice bar 220 so that the lattice bar 220 of the truss girder 200 can be stably mounted. A deck plate for a long span, characterized in that.
The method of claim 5,
The spacer 300 is bent upwardly outward to both sides around the fitting groove 320b to form a V-shaped lattice mounting portion 360b at an angle corresponding to the inclination of the lattice bar 220, and then downward again. A deck plate for a long span, characterized in that the iron wire (W) is bent to be horizontally bent outward from the bent state to provide the foot portion (340).
The method of claim 6,
The iron wire (W) forming the spacer 300 is bent in a shape symmetrical in the longitudinal direction as a whole, so that a pair of V-shaped lattice mounting portions 360b are formed symmetrically around a pair of fitting grooves 320b. , Long-span deck plate, characterized in that the foot portion 340 formed at both ends in the width direction is also formed in a shape symmetrical in the length direction.

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