KR101942842B1 - Deck-Plate for Long Span - Google Patents

Abstract

The present invention relates to a deck-plate for a long span, and more specifically, to a deck-plate for a long span which is formed by providing a truss girder to a corrugated deck. To this end, the corrugated deck has a pair of corrugated side surface plates extended towards an upper part at both end parts of a corrugated ground plate, thereby disposing a crossbeam formation unit at an inner side. At an upper end of the corrugated side surface plate, a horizontal plate is extended in an outer horizontal direction. In addition, at the crossbeam formation unit of the corrugated deck, a spacer is fastened to be combined at each predetermined distance in a longitudinal direction, and the truss girder is coupled to the spacer. Therefore, the deck-plate for a long span simplifies assembling manufacture and construction, and reinforces the corrugated deck.

Description

Deck-Plate for Long Span

The present invention relates to a deck plate for an elongated span, and more particularly to a deck plate for a long span, which comprises a deck plate having a pair of lateral side plates extending upwardly from both ends of a bottom plate, To a long span deck plate in which spacers are fitted at intervals in the longitudinal direction and the truss girder is fitted to the spacers.

Generally, architectural structures can be subdivided into steel structure, reinforced concrete structure, and steel reinforced concrete structure, which are classified according to the construction method of the structure that forms beams and columns as a basic structure of the building.

Most slabs are constructed by forming a bottom plate or a roof. In order to form a slab, a column and a beam are formed of steel or reinforced concrete, a concrete is placed between the adjacent beams, And when the curing of the concrete is completed, it is possible to provide a completed bottom plate or a roof by demolding the form.

However, the conventional slab construction method described above requires a large amount of material as a material to support the formwork, and it is necessary to place a plurality of reinforcing bars and to pour concrete. After the curing of concrete, the concrete is removed, There is a problem that a process is required.

In order to solve these problems, various types of truss girders have been manufactured by welding the upper reinforcing bars and the lower reinforcing bars directly to the corrugated lattices, and decks made of wood, synthetic resin or metal are bonded to the lower part of the truss girders, A deck plate capable of increasing the workability and securing the structural stability of the slab is actively produced.

The deck plate is generally constructed by placing both ends between adjoining beams and placing concrete on top of the deck plate. The interval between the beams is about 3 to 4 m, and the length of the deck plate is also corresponding .

However, in recent years, the three-dimensional design of the building has made it necessary to mount the deck plate in a long span of 4 m or more depending on the site conditions, and accordingly, it is required to fabricate the deck plate so as to correspond to the long span . However, in order to increase the length of the deck plate corresponding to the bending moment, the height of the truss girder should be increased to ensure sufficient bending rigidity. However, since the height of the slab is to be sufficiently secured, The amount of concrete to be poured is also increased.

In order to solve such a problem, recently, a truss girder is provided in a bone provided in a bone deck by utilizing a bone deck having a sufficient height so that, when concrete is inserted for the later slab construction, A deck plate for an elongated span is formed.

Conventionally proposed deck plates for long spans are disclosed in Korean Patent Laid-open No. 10-2006-0011235 entitled " Reinforced deck type floor structure for long span and method of constructing thereof " (published on Mar. 2, 2006, Quot;). The above prior art document 1 can be applied flexibly to the conditions of the construction site by making the deck deck extendable in the width direction and a pair of lower reinforcing bars are disposed at the lower part centering on the upper reinforcing bars, By arranging the truss girder with the triangular structure, the technical effect that can realize the building having the wide space of the long span is demonstrated.

Also, as a similar concept, there is a reverse osmosis truss girder insertion deck (Registered on September 22, 2017, hereinafter referred to as "prior art document 2") of Korean Patent No. 10-1783035. In the prior art document 2, a truss girder of a triangular structure is arranged in the reverse direction, unlike the prior art document 1, so that a pair of reinforcing bars can exhibit a sufficient tensile strength. Further, the lattice bar of the truss girder is bent, And the concrete is fastened by a coupling means such as a piece or a bolt, so that stable mounting is possible.

However, the prior art document 1 as well as the prior art document 2 do not provide a sufficient coupling force between the pieces or bolts, so that the truss girder can not be stably installed when the concrete is pushed later, There is a problem that a sufficient and sufficient coating thickness can not be formed due to the fact that the spacing space between the deck and the truss girder can not be stably secured.

In addition, due to the use of the thin deck, the deck itself is twisted or deformed due to the weight or shrinkage of the concrete when the concrete is pushed in later, and thus there is an additional problem that it can not provide stable beams in terms of structure or shape.

Korean Patent Laid-Open No. 10-2006-0011235 (published on Mar. 2, 2006, entitled "Reinforced deck type floor structure for long span and method of building the same" Korean Registered Patent No. 10-1783035 (Registered Jul. 22, 2017, Name of invention: Reverse osmosis truss girder insertion type deck)

The present invention has been conceived in order to solve the above-mentioned problems, and it is an object of the present invention to provide a deck plate for long spans by combining a truss girder and a tec so as to secure sufficient binding force not to flow at the time of pouring concrete, The present invention provides a deck plate for an elongated span that has a predetermined thickness of concrete covering and is sufficiently rigid so that deformation of a thin deck is not caused by the loading or contraction of concrete.

In order to achieve the above object, the present invention provides a long span deck plate (LD) having a truss girder (200) formed on a bony deck (100), wherein the bony deck (100) A pair of lateral side plates 120 are formed on both ends of the lateral side plate 120 and the lateral side plate 120 is formed on the inner side of the bottom plate 120, The truss girder 200 includes a pair of lattice bars 220 which are coupled to the lower reinforcing bar 210 so as to be inclined outwardly and upper reinforcing bars 230 are formed on the lattice bars 220, And a spacer 300 is fitted to the beam forming part 130 of the bony deck 100 at regular intervals in the longitudinal direction and the truss girder 300 is fitted to the center of the spacer 300. [ The lower reinforcing bar 210 of the stator 200 is elastically deformed to be engaged with the lower reinforcing bar 210, A pair of lattice mounts 360 are provided on the inner side of the spacer 300 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, More than half of the height of the lattice bar 220 is mounted on the mounting part 360. The pair of side plate 120 is formed with a guide surface 122 so as to have an inclination inward toward the lower side, At least one step portion 121 is formed on the surface 122 so as to be bent to one side and the spacer 300 has a shape corresponding to the bone side plate 120 and is inclined inward toward the lower side, And at least one latching protrusion 310 is formed in a shape corresponding to the stepped portion 121. In this case,

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In addition, the spacer 300 may be formed with a through-hole 330 to allow the poured concrete to pass therethrough.

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The bone deck 100 is provided with a plurality of beam forming units 130 and a horizontal plate 140 is extended horizontally outwardly from the top of the bone side plate 120 located at both ends, And a floorboard (150) is horizontally formed on an upper end of the bottom side plate (120) positioned between the forming portions (130).

According to the long span deck plate (LD) of the present invention, the spacer can be fitted to the bony deck at regular intervals in the longitudinal direction, and the truss girder can be coupled to the spacer, so that the assembling can be simplified.

Further, when the concrete is poured for further construction, a sufficient bonding force is secured so that the truss girder does not flow in the convex portion of the bony deck, so that stable and efficient construction can be achieved.

In addition, the shape of the beam-shaped deck can be kept constant by the spacer in spite of the pushed load or shrinkage of the concrete, thereby preventing the deformation of the thin-walled deck.

In addition, since the spacers are spaced apart from each other between the deck girder and the deck girder, the truss girder can be provided at a predetermined position, so that a standardized concrete covering having a uniform thickness can be formed.

In addition, at least one step is formed in the bone side plate of the bone deck so that the rigidity of the bone deck itself can be ensured. In addition, since the spacer has a shape corresponding to the step, It is possible to perform stable fastening in the joining, and further, the 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 engaged with the truss girder, thereby assuring the efficiency of manufacture and construction when connecting the truss girder.

In addition, the spacer may have through holes formed therein to allow the poured concrete to pass therethrough, so that the concrete can be faithfully spilled even if spacers are provided in the pouring portion.

By providing a deck plate having an inverted triangular structure, a pair of upper reinforcing bars are provided, so that it is possible to stably strengthen the bending stress acting on the slab, and at the same time, the amount of reinforcing bars to be additionally disposed to form the slab is reduced, It is an object of the present invention to provide a deck plate for a long span capable of securing the efficiency of a long span.

1 and 2 are exploded perspective views showing a deck plate for a long span and a coupled state thereof according to an embodiment of the present invention.
3 is a sectional view showing a fastening method of a long span deck plate according to an embodiment of the present invention;
4 is a perspective view of a spacer of a deck plate for an elongated span according to various embodiments of the present invention.
5 is a cross-sectional view showing a state in which a slab is installed using a long span deck plate according to an embodiment of the present invention.
6 and 7 are exploded perspective views showing a deck plate for a long span according to another embodiment of the present invention and a state of engagement thereof.
8 is a sectional view showing a fastening method of a long span deck plate according to another embodiment of the present invention.
9 is an exploded perspective view showing a state of engagement of a long span deck plate according to another embodiment of the present invention.

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

1, the deck plate LD for long span of the present invention is formed by providing a truss girder 200 on a deck 100 of a deck, A spacer 300 is additionally provided for stably connecting the truss girder 200 within the frame 100.

The bone deck 100 includes a pair of bone side plates 120 extending upward from both ends of the bottom plate 110 and a beam forming part 130 is provided on the inner side of the bottom plate 110, A horizontal plate 140 is extended horizontally outwardly.

The bony deck 100 is preferably formed by bending a thin sheet of metal material, bending a thin metal plate having a predetermined width and length, bending both ends around the bore bottom plate 110, The plate 120 is formed, and the bone plate 120 is again bent outward in the horizontal direction to form a horizontal plate 140.

A reinforcing bend 111, which is bent upward, may be formed on the bottom of the bottom plate 110. The reinforcing bending portion 111 functions not only to stably reinforce the bone deck 100 due to its own weight or deformation, but also to function as a lanyard fixture for providing a later ceiling material.

Coupling bending portions 141 and 142 are formed at the outer ends of the pair of horizontal plates 140 of the bony deck 100 so that the coupling bending portions 141 and 142 of adjacent bony decks 100 By integrally bending them in a state of being vertically folded as shown in FIG. 3 in a state where they are superimposed on each other, the bone decks 100 can be mutually fastened and expanded in the width direction.

Further, by folding the fastening bending portions 141 and 142, it is possible to prevent leakage of the paste when the concrete is laid, and it is possible to reinforce the relatively weak connecting portion.

As shown in Fig. 9, by forming the reinforcing protrusions 160 formed by press forming on the surface of the bony deck 100, deformation and bending due to the concrete load can be prevented .

The spacer 300 may be inserted into the beam-forming part 130 provided at the inner side of the bony deck 100 at regular intervals in the longitudinal direction. 4, the spacer 300 may be formed to have a predetermined thickness by using a synthetic resin material. The spacer 300 may be manufactured to form a reinforcing flange portion 350 having a predetermined height along a rim by applying a press to the thin metal plate .

In addition, as shown in FIG. 7 or 9, one wire can be bent and formed to have a predetermined shape, so that it can be fitted to the beam-forming portion 130 of the bone-shaped deck 100.

The spacers 300 are formed so that the overall shape of the spacers 300 corresponds to the shapes of the beam forming portions 130 of the bone deck 100. Thus, even when the spacers 300 are provided, Since the beam-forming portion 130 is reinforced by the spacer 300, a certain shape can be maintained.

Also, since the truss girder 200 can be partly joined to the spacer 300, the truss girder 200 can be stably and easily coupled to the spacer 300, .

Accordingly, the spacer 300 is stably fitted into the inside of the bone-shaped deck 100 when the concrete for later construction is stuck, as well as the truss girder 200 is coupled to the spacer 100, 100 in the beam forming portion 130, and can be stably fixed, thus enabling efficient construction.

Since the bone deck 100 is formed in a thin plate shape, the bone deck 100 may be elastically deformed outward by a certain amount in the course of providing the spacer 300 in the beam forming part 130, so that the fitting can be easily performed. However, it is preferable that the guide surface 122 is formed so that the spacer 300 is inclined inwardly downward as a whole so that the spacer 300 can be smoothly inserted along the bone side plate 120 of the bone-shaped deck 100.

The bone side plate 120 of the bone deck 100 is formed with at least one step portion 121 bent inward with respect to the lower portion and the spacer 300 has a shape corresponding to the step portion 121 At least one latching jaw 310 may be formed.

3, when the spacer 300 is inserted along the bone side plate 120 of the bone-shaped deck 100, the catching jaw 310 is caught by the jaws 121 It is possible to prevent separation in the reverse direction, so that a strong bonding force can be secured.

In the long span deck plate (LD) of the present invention, the truss girder (200) has a pair of lattice bars (220) coupled to the lower reinforcing bar (210) 220 are coupled to the upper reinforcing bars 230 to form inverted triangular structures.

The truss girder 200 having an inverted triangular structure may be formed by vertically inverting a product formed by a pair of lower reinforcing bars provided at the lower portion of the upper reinforcing bar, .

Since the deck plate 200 having the inverted triangular structure is provided, it is possible to stably restrain the bending stress acting on the slab, which is completed with concrete pouring, by taking a structure in which the pair of upper reinforcing bars 230 are provided. . In addition, it is possible to reduce the amount of reinforcing bars to be additionally installed to form the slab, thereby ensuring the efficiency of construction.

Alternatively, the spacer 300 may be made of a plate having a predetermined thickness using a synthetic resin material, or may be formed such that a reinforcing flange portion 350 having a predetermined height is formed by pressing a thin plate of a metal material with a press.

In order to stably provide the truss girder 200 having the inverted triangular structure described above to the spacer 300, the spacer 300 is formed with elastic deformation such that the lower reinforcing bar 210 of the truss girder 200 is fitted and fitted to the spacer 300. [ The fitting groove 320a may be provided.

Therefore, even if there is no separate fastening means, since the truss girder 200 can be stably fastened only to the spacer 300 fitted to the deck 100, the truss girder 200 can be stably fastened only by simple fitting, have.

The through hole 330 may be formed in the spacer 300 so that the poured concrete can pass therethrough and even if the spacer 300 is provided in the beam forming portion 130, It is possible to faithfully fill the space of the beam-forming portion 130 provided between the spacers 300. [0050]

In addition, an insertion groove 370 may be formed in the lower portion of the spacer 300 in a shape corresponding to the reinforcing bend 111 formed at the lower portion of the bend bottom plate 110. By inserting the fitting groove 370 into the reinforcing bent portion 111, the spacer 300 can be stably fixed, and a strong supporting force can be ensured.

In another embodiment, the spacer 300 may be formed by bending a wire W as shown in FIGS. 8, the spacer 300 may be formed to have a shape corresponding to the shape of the beam-forming portion 130 of the bone-shaped deck 100, so that the bone-shaped deck 100 ) Is reinforced.

8, a plurality of step portions 121 are formed on the bone side plate 120 of the bone deck 100, and the spacers 300 are formed in a shape corresponding to the step portion 121 So that one stopper 310 can be formed. Both ends of the wire W constituting the spacer 300 are horizontally bent to form a foot portion 340. The foot portion 340 is formed on the bottom plate 110 of the bone deck 100, So that the spacer 300 can be stably fixed to the bone-shaped deck 100 by implementing the foot portion 340 to be fitted to the step portion 121 formed adjacent to the bone-shaped deck 100.

As shown in FIG. 9, the spacer 300 is formed of a wire W, and the foot portion 340 can be extended so as to be self-supporting. Thus, when the truss girder 200 is provided, buckling can be prevented and a strong supporting force can be secured.

8 may be provided with a fitting groove 320b which is elastically deformed so that the lower reinforcing bar 210 coupled to the truss girder 200 having the inverted triangular structure described above is inserted into the center of the spacer 300, have.

The spacer 300 applied to the present invention may be configured such that the lattice mounting portion 360 is formed 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 .

As a preferred embodiment of the truss girder 200, a pair of lattice bars 220 are coupled to the upper reinforcing bar 210 at an upper portion thereof, and upper reinforcing rods 220 are provided at upper portions of the lattice bars 220 The lattice bar 220 is mounted on the V-shaped lattice mounts 360a and 360b so that the lower reinforcing bars 320a and 320b are coupled to the fitting grooves 320a and 320b, The truss girder 200 can be stably installed around the torsion bar 210.

In the meantime, the long span deck plate LD according to the present invention includes a deck plate LD which is formed by vertically folding the deck-shaped deck 100 formed with one beam forming portion 130 continuously through the coupling bending portions 141 and 142, 9, the plurality of beam-forming portions 130 are provided on the bottom of the bone-shaped deck 100, and a plurality of beam-forming portions 130 are provided on the top of the bottom side plate 120 And a floorboard 150 may be horizontally formed on the upper end of the side wall plate 120 positioned between the neighboring beam forming units 130.

In the case where the length is relatively shorter than the typical span length, the construction can be ensured by applying the bony deck 100 formed with the plurality of beam forming portions 130, and when the plurality of beam forming portions 130 are formed, The height (dancing) of the player can be relatively low.

It will be understood by those skilled in the art that the above-described deck plate LD for long spans according to the present invention can be embodied in other specific forms without departing from the technical ideas or essential features of the present invention You will understand.

It is to be understood, therefore, that the above description is intended to be illustrative, and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, Ranges and equivalents thereof are to be construed as being included within the scope of the present invention.

LD: Deck plate for long span 100: Bone deck
110: rib bottom plate 111: reinforcement bend
120: rib side plate 121:
122: guide surface 130:
140: horizontal plate 141, 142: fastening bend
200: truss girder 210:
220: Lattice bar 230: Upper bar
300: spacer 310:
320a, 320b: a fitting groove 330: a through hole
340: foot portion 350: reinforcing flange
360a, 360b: Lattice mounting portion W: Wire

Claims (8)

In a long span deck plate (LD) in which a truss girder (200) is provided on a bony deck (100)
The bone deck 100 includes a pair of bone side plates 120 extending upward from both ends of the bottom plate 110 and a beam forming part 130 is provided on the inner side of the bottom plate 110, A horizontal plate 140 is extended horizontally outwardly,
The truss girder 200 has a pair of lattice bars 220 sloping outwardly from the lower reinforcing bar 210. The upper reinforcing bars 230 are coupled to the upper portion of the lattice bar 220, And,
The spacer 300 of the bone-shaped deck 100 is fitted into the beam-forming part 130 at regular intervals in the longitudinal direction,
The spacer 300 is provided at the center thereof with a fitting groove which is elastically deformed so that the lower reinforcing bar 210 of the truss girder 200 is fitted and fitted. The lattice bar 220 of the truss girder 200 A pair of lattice mounts 360 are provided at an angle corresponding to the inclination of the lattice bar 220 so that more than half of the height of the lattice bar 220 is secured to the mount 360 Lt; / RTI >
The pair of bone side plates 120 is formed with a guide surface 122 so as to have an inclination inward toward the bottom and at least one step portion 121 bent to one side is formed on the guide surface 122 The spacer 300 is formed to have a shape corresponding to the bone side plate 120 and inclined inward toward the lower side so that the insertion is guided smoothly. At least one latching protrusion (310) is formed in the deck plate (30).
delete delete The method according to claim 1,
Wherein the spacer (300) is formed with a through hole (330) so that the poured concrete can pass therethrough.
delete delete delete The method according to claim 1,
The bone deck 100 is provided with a plurality of beam forming parts 130 and a horizontal plate 140 is extended horizontally outwardly from the top of the bone side plate 120 located at both ends, And a floorboard (150) is horizontally formed on an upper end of the bone side plate (120) positioned between the side walls (130).

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