KR20190070032A - Composite deck plate for adhering z-shaped latticed bar, and manufacturing method for the same - Google Patents

Abstract

The present invention relates to a composite deck plate for adhering a Z-shaped steel wire latticed bar and a manufacturing method for the same. According to the present invention, an upper end unit of a latticed bar, which forms a steel wire truss structure for engaging a corrugated deck plate with the steel wire truss structure, is adhered to a latticed bar accommodation groove on a unit of the deck plate, and a lower end unit of the latticed bar is welded and engaged with a lower plate of the unit of deck plate. Accordingly, the present invention is able to realize a long span by a non-supporting post, non-mold, and non-reinforcement method on a floor plate of a building, bear a high placement load, minimize a concrete filling volume placed in the corrugated deck plate, greatly reduce its own weight, and greatly reduce a steel plate thickness compared with that of the conventional corrugated deck plate.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a composite deck plate for a Z-type steel wire lattice muscle attaching type composite plate,

The present invention relates to a composite deck plate, and more particularly, to a composite deck plate for realizing a long span in a floor plate of a building and for combining a corrugated deck plate and a steel truss structure so as to bear a high- The present invention relates to a composite deck plate for attaching a Z-shaped steel wire lattice root to a deck plate unit unit, and a manufacturing method thereof.

The deck plate used in the bottom plate of a building is widely used as a representative bottom plate material because it has advantages such as shortening of air and labor saving by performing a role of a concrete when casting concrete.

The bottom plate composed of beams and slabs occupies about 60% of the total frame construction cost. The higher the floor of the building, the greater the economical efficiency such as the weight, the usable area, And a deck plate that satisfies the need for weight reduction and long span technology is required.

Such a deck plate is divided into a deck plate having a deck shape and a plate deck plate having a deck having a truss depending on the deck plate.

Specifically, the deck deck plate can be used for a formwork to bear only the concrete pouring load, or as a structure for acting as a tensile material after the concrete is synthesized. Such a deck plate can be used for dancing (Opening Height) And the thickness of the steel sheet must be increased. As a result, it is difficult to secure economical efficiency.

Particularly, when such a dome-shaped deck plate is danced to realize a long span, the deck plate is deformed due to compression buckling of the upper flange and the web, the adhesive force with the laid concrete can be lost, There is a problem in that it is not suitable for the following.

In addition, the flat plate deck plate with a reinforcing truss is formed by forming a lower steel plate for a form plate into a thin plate, and a reinforcing truss made of an upper reinforcing bar and a lower reinforcing steel for a load supporting structure in a truss form is integrated with a lower steel plate for a form, Is insufficient in rigidity because it is used only as a simple form, and there is a possibility of lateral buckling of the upper compression side reinforcing bars of the structural reinforcing truss. In addition, the flat deck plate with a reinforcing truss is filled with concrete in the entire dancing of the reinforcing steel truss type deck plate, so that the waste of the material is large and the weight is greatly increased, so that it is difficult to realize the long span.

1 is a perspective view showing a deck plate system according to the prior art.

1, the end sequential deck plate system utilizing the cap plate according to the prior art is constructed by connecting the deck plate body 11 with the cap plate 13 for reinforcing the momentum reinforcement to secure the continuity of the end portions A truss type assembling reinforcing bar 14 connecting the flat portion 11a to close the rib 12a opened in the width direction of the deck plate main body so as to close the transverse distribution with the adjacent ribs is formed so that the ribs 12a Of the deck plate and lateral buckling of the deck plate, and to resist the acting external force.

Further, in the end portion continuous deck plate system utilizing the cap plate according to the related art, the opening end face is closed to secure the stability of the deck shape and continuity of the end portion. That is, the momentum-reinforcing cap plate 13 is formed to cover the open upper surface of the rib 12a opened at both ends in the longitudinal direction of the deck plate body 11, Is formed so as to cover the open upper surface of the rib (12a) opened at the center in the longitudinal direction of the deck plate body (11).

2 is a perspective view showing a configuration of a deck panel according to a conventional technique.

Referring to FIG. 2, a deck panel according to the related art forms a truss structure by connecting the upper and lower reinforcing bars 22 and 23 to a lattice material 24 bent in a Zig-Zag shape. And fixed at predetermined intervals on the finishing plate 21 by spacers 25 bent in a mountain shape so as to cross the truss structures. In this case, the finishing plate 21 is generally made of a material such as a plated steel sheet, which does not require a separate coating, and is formed in the form of a corrugated plate for increasing local strength.

The deck panel according to the prior art is constructed in units of spans between the beams and pillars, and is supported on these beams, and then the concrete is laid on the deck panel to constitute the slab. In the completed slab, the upper and lower reinforcing bars 22 and 23 constitute the cast iron root of the slab, and the finishing plate 21 finishes the lower face of the slab. In the upper part of the deck panel, the lattice muscles are seated as needed, thereby reinforcing the local strength of the slab and adding the cast iron rods.

The deck panel according to the prior art is connected to a compensation of one beam or the like to form a continuous deck to become a work platform for construction and to form a reinforced concrete slab integrally with the concrete after the concrete is poured.

However, in the deck panel according to the related art, the truss structure is coupled to the finishing plate 21 by the spacer 25 intersecting with the truss structure, thereby causing various problems. That is, when the worker's body weight, equipment, or the like is moved on the finishing plate 21 and the concrete is injected, the load is transmitted to the truss structure through the spacer 25, and the stress in the longitudinal direction of the spacer 25 The actual truss structure can not act as a girder for the finishing plate 21 because it can transmit only by its own deflection.

Therefore, the deck panel according to the related art has a small load-bearing capacity, which makes it difficult to function as a working deck without additional reinforcement. In addition, since the truss structure is a longitudinal strength member at the time of completion of the slab, the truss structure is vertically installed by the spacer 25 having a complicated bend even though the truss structure should be installed at an appropriate interval perpendicular to the finishing plate 21 Is practically impossible and the truss structure is installed in a twisted state, thereby causing the deformation of the finished slab and lowering the strength.

On the other hand, as a prior art for solving the above-mentioned problems, Korean Patent No. 10-963579 discloses an invention called "truss near monolithic deck plate ", which will be described with reference to Fig.

 3 (a) is a front view of a deck plate reinforced by truss roots, and Fig. 3 (b) is a truss plate for reinforcing a deck plate. Fig. It is a perspective view of a muscle.

Referring to FIG. 3A, a deck plate reinforced by truss roots according to the related art includes an upper plate 31, side plates 32 bent downward at both ends of the upper plate, A unit unit composed of the lower plates 33 bent horizontally at the end of the plate is repeatedly formed in the transverse direction and the deck plate 30 is connected by the connecting means 34 formed at the free end of the lower plate.

At this time, the upper reinforcing bar 42 and the lower reinforcing bar 43 are arranged in parallel, the corrugated reinforcing bars 41 are disposed on the upper reinforcing bar and the lower reinforcing bar, and the truss- (40) is coupled so as to cover a part of the upper plate and the lower plate of the deck plate (30) and the entire surface of the side plate. Such a deck plate is capable of long span construction without a standing posture, and the deck plate and truss roots behave integrally, thereby reducing the generation stress on the compression side.

The reinforcing stiffener 35 is formed for reinforcing the rigidity of the upper and lower plates 31 and 33 and the side plate 32 while the truss roots 40 are connected to the deck plate 30, Joined by a reinforcing stiffener (35) so as to cover a part of the top plate (31) and the bottom plate (33) of the deck plate (30) and the front surface of the side plate (32).

The lower leg portion 41b is formed to be upwardly bent and the leg portion upper portion 41a is horizontally bent so as to extend to the upper portion of the upper plate 31. [ Further, in the deck plate reinforced by the truss roots according to the related art, the lower leg portions 41b are formed so as to intersect each other in order to lay the slab cast iron rope 50, and then the cast iron rope is laid on the upper portion thereof. When the truss rope 40 and the deck plate 30 are connected to each other, it is necessary to weld them at the portions where the reinforcing stiffeners are formed. In order to connect the lower leg portions to the slab root portions, .

3 (b), the truss roots 40 are arranged such that the upper reinforcing bars 42 and the lower reinforcing bars 43 are arranged in parallel, and the reinforcing bars 42 and 43 are reinforced A reinforcing bar (41) is disposed, and welded and fixed at the point where each reinforcing bar contacts, thereby forming a truss shape.

Specifically, the corrugated reinforcing bars 41 are bent inward and outward to form legs 41a and 41b, respectively. At this time, the upper leg portion 41a is horizontally bent outward to be positioned on the upper plate 31 of the deck plate 30, and the lower leg portion 41b is bent upwardly inward, So as to be positioned on the lower plate 33. By bending the lower leg portion 41b upwardly, the slab cast iron rope 50 can be separated from the deck plate lower plate 33 without using a separate spacer.

The truss rope 40 is welded to the reinforcing stiffener 35 so as to cover the top plate 31 and a part of the bottom plate 33 and the front surface of the side plate 32 of the deck plate 30.

However, in the case of the deck plate reinforced by the truss roots according to the related art, the upper portion of the leg portion is formed so as to cover the upper plate of the upper plate, and the lower portion of the leg portion is bent upward to increase the length of the truss roots, And the weight thereof is increased. Further, in the case of the deck plate reinforced by the truss roots according to the related art, since the leg portion is formed up to the upper portion of the upper plate, the thickness of the deck plate is increased and the floor area of the building is decreased.

On the other hand, Korean Patent Registration No. 10-1747097, filed by the applicant of the present invention and registered as a prior art, discloses an invention entitled " a lateral reinforcing steel truss deck plate-integrated reinforced truss deck plate and a manufacturing method thereof " Which is incorporated herein by reference, and which is part of the present invention, will be described in detail with reference to FIG.

4 (a) is a cross-sectional view of a reinforced truss deck plate having a transverse support hardware integral body, and Fig. 4 (b) is a cross- This is a perspective view of a steel reinforced truss deck plate.

As shown in FIG. 4, the transverse supporting hardware integral truss deck plate according to the related art includes a unit unit 60, a reinforcing bar 70, a connecting reinforcing plate 80, an upper reinforcing bar 91, A reinforcing bar 92, a transverse steel 93, a penetrating reinforcing bar 94 and an engaging plate 95.

Unit units 60 composed of an upper plate 61, both side plates 62 and lower plates 63 are repeatedly formed in the transverse direction and are connected to each other in the transverse direction by the fastening device. At this time, the unit unit 60 is a bony deck plate occupying the skeleton of the deck plate, and takes a trapezoidal shape as a whole. The unit unit 60 may be constituted by one or more upper plate 61, side plate 62 and lower plate 63. At this time, the unit unit 60 may have a shape repeated in the transverse direction, and the unit units 60 may be continuously connected by the connecting means at both ends of the lower plate 63 of the unit unit 60.

The reinforcing bar 70 is formed in a truss shape in the longitudinal direction of both side plates 62 and includes a bent portion 72 which is horizontally bent to the side plate 62 at the lower portion. And a reinforcing steel body 73.

The upper reinforcing bar 91 welds on the upper portion of the reinforcing bar 70 and extends in the longitudinal direction of the unit unit 60. The lower reinforcing bar 92 welds on the upper portion of the bending portion 72, As shown in Fig.

The transverse steel members 93 are spaced apart from each other by a predetermined distance in the longitudinal direction of the top plate 61 and are joined to each other with a length corresponding to the width of the top plate 61 on the top surface of the top plate 61.

The penetrating reinforcing bar 94 is integrally formed with the transverse reinforcement 93 and is formed transversely on the upper surface of the upper plate 61 so that the reinforcing bar 70 and the upper reinforcing bar 91 cross each other, And is welded to the reinforcing steel bar 70.

Specifically, the upper plate 61 of the unit unit 60 is formed in the form of a horizontal plate, and the lateral width (width) of each outermost top plate of the unit unit 60 formed by at least one of the upper plate, Is formed to have a length half of the lateral width of the top plate 61, and each lateral end of each outermost top plate includes vertical bent portions 61a and 61b bent perpendicularly.

The vertical bent portions 61a and 61b of the adjacent unit units 60 are connected to each other by a fastening device 61c that is coupled to each other and spaced apart at a preset interval in the longitudinal direction of the upper plate 61, At this time, the transverse steel 93 is formed of an L-shaped steel including a lower plate and a vertical plate, and the upper plate 61 is engaged with the lower plate by a fastening device at regular intervals in the transverse direction. The transverse steel 93 is joined by the fastening device to the slit formed in the center portion of the transverse steel 93 so as to be coupled by the vertical bent portions 61a and 61b.

The penetrating rebar 94 is welded to the bottom or vertical plate and extends transversely to a length corresponding to the distance between adjacent vertical bends.

According to the present invention, there is provided a transverse reinforcing steel truss deck plate comprising: a transverse steel material disposed on a top plate of a deck plate at regular intervals and connected by a fastening device, It is possible to prevent sagging and widening in the vertical direction and to arrange a penetrating reinforcing bar integrally formed with the transversely extending steel material and extending in the transverse direction through the lower portion where the reinforcing steel bar intersects with the upper reinforcing bar, It is possible to smoothly transmit the acting compressive force to the deck plate and to secure the local buckling performance even when the deck plate of the thin plate is used by the reinforcing steel and the lateral steel, It is possible to secure the thickness of the reinforcing steel coating due to the horizontal bending of the reinforcing bars.

However, in the case of the reinforcing truss deck plate integrated with a lateral support metal fitting according to the above-described conventional technique, the reinforcing truss deck plate is formed integrally with the transverse reinforcement steel, and penetrates the lower portion where the reinforcing steel and the upper reinforcing steel intersect, There is a problem that the structure becomes complicated.

Korean Registered Patent No. 10-963579 filed on Dec. 21, 2007, entitled "Truss Near Deck Deck Plate" Korean Patent No. 10-1255464 filed on July 27, 2011, entitled "End-Continuous Deck Plate System Utilizing Cap Plate" Korean Patent No. 10-1747097 filed on Dec. 22, 2015, entitled "Horizontal Directional Supported Steel Reinforced Truss Deck Plate and Method of Making the Same" Korean Patent No. 10-1731244 filed on Dec. 22, 2015, entitled "Bonded Reinforced Steel Truss Deck Plate with Connection Plate and Method of Making the Same" Japanese Unexamined Patent Publication No. 1994-322872 (published on Nov. 22, 1994), entitled "Deck Plate" Japanese Unexamined Patent Publication No. 2013-209838 (Publication Date: Oct. 10, 2013), entitled "Composite Slab Structure Using Deck Plate & Korean Patent No. 10-1366716 filed on September 1, 2011, entitled "web-side reinforced deck plate" Korean Patent No. 10-1389113 filed on November 23, 2012, entitled "Truss girder integral deck plate"

SUMMARY OF THE INVENTION In order to solve the above problems, an object of the present invention is to provide a lattice truss structure in which an upper end of a lattice muscle forming a steel wire truss structure is attached to a lattice muscular receiving groove of a deck plate unit unit And a lower end portion of the lattice muscle is welded to the lower plate of the deck plate unit unit, and a method of manufacturing the composite deck plate.

Another object of the present invention is to provide a Z-type steel wire lattice close-coupled composite which can greatly reduce the weight of concrete by minimizing the amount of concrete placed in the deck plate, Deck plate and a method of manufacturing the same.

As a means for achieving the above-mentioned technical object, a Z-type steel wire lattice muscle attaching type synthetic deck plate according to the present invention is characterized in that a unit deck comprising an upper plate, a lower plate and both side plates is repeatedly formed A deck plate unit unit connected to each other in a transverse direction continuously by a fastening device and having lattice fringing grooves formed at both ends of an upper plate; An upper reinforcing bar disposed on the deck plate unit and extending in the longitudinal direction; A lower reinforcing bar disposed at a lower portion of the deck plate unit and extending in the longitudinal direction; A Z-shaped lattice root which is joined to the upper and lower reinforcing bars to form a steel wire truss structure, an upper end bent and attached to the lattice muscular receiving groove, and arranged in a Z-shape along the longitudinal direction; And a horizontal reinforcing steel piece spaced apart at predetermined intervals in the longitudinal direction of the upper plate of the deck plate unit unit to prevent the deck plate unit unit from spreading and improve the bending stiffness, Characterized in that an upper end portion of the muscle is attached to a lattice muscle close-accommodating groove of the deck plate unit unit and a lower end portion of the lattice muscle is welded to a lower plate of the deck plate unit unit so that the steel wire truss structure and the deck plate unit unit are integrated .

The deck plate unit unit includes a lower plate, a lower bent portion, an upper bent portion, a lattice nearest groove, an upper plate, and an upper plate connecting portion bent by a pressing method, And is bent at both ends to form the lattice muscular receiving groove.

Here, the lattice root is composed of the lower end of the lattice, the lattice root bend, and the upper end of the lattice, and may be arranged in a zigzag shape along the longitudinal direction of the composite deck plate.

Here, the upper reinforcing bar may be welded to the upper portion of the bent portion of the lattice muscle, and the lower reinforcing bar may be welded to the lower portion of the bent portion of the lattice muscle.

Here, the lower end of the lattice may be horizontally bent so as to extend in a lateral direction by a predetermined length to secure a thickness of the reinforcing steel coating, and may be welded to the lower plate of the deck plate unit.

Here, the lattice root bend of the lattice muscle is formed to be inclined along the longitudinal direction of the composite deck plate, and is inclined in a zigzag form repeatedly.

The upper end of the cross-section muscle is bent so as to secure a coating thickness, and the upper reinforcing bar is disposed on the upper portion of the lattice flexion portion, A coating thickness can be ensured.

Here, the upper end of the lattice muscle and the upper reinforcing bar are disposed below the upper plate of the deck plate unit unit so that the horizontal reinforcement steel can be continuously disposed on the upper surface of the deck plate unit unit.

As another means for achieving the above technical object, the Z-type steel wire lattice muscle attaching type synthetic deck plate and method of manufacturing the same according to the present invention include: a) a bone deck plate including an upper plate, a lower plate and both side plates A step of forming a deck plate unit unit in which a lattice musculature receiving groove is formed; b) forming a Z-shaped lattice roughened upper and lower ends; c) welding an upper reinforcing bar to an upper portion of the bent portion of the Z-shaped lattice muscle, and welding a lower reinforcing bar to a lower portion of the bent portion of the Z-shaped lattice muscle to form a steel wire truss structure; d) disposing a steel wire truss structure in the longitudinal direction and attaching the Z-shaped lattice proximal upper end portion to the lattice muscular receiving groove of the deck plate unit unit; e) fixing the coupling plate to both ends of the deck plate unit unit and connecting the deck plate unit unit in the width direction; And f) joining a horizontal reinforcing steel material to the upper portion of the deck plate unit at predetermined intervals in the longitudinal direction, and then pouring the concrete back to complete a Z-type latticed muscle attaching synthetic deck plate, And the lower end of the lattice muscle is welded to the lower plate of the deck plate unit so that the steel wire truss structure and the deck plate unit unit are integrated .

According to the present invention, the upper end of the lattice muscle forming the steel wire truss structure for attaching the bone deck plate and the steel wire truss structure is attached to the lattice muscle receiving groove of the deck plate unit unit, and the lower end of the lattice muscle is attached to the deck plate unit unit Welded to the bottom plate, the bottom span of the building can realize the long span in a free-standing, no-form and no-fit manner, and can bear a high load load.

According to the present invention, it is possible to largely reduce the self weight by minimizing the amount of concrete charged in the deck deck plate, and to significantly reduce the thickness of the steel plate compared to the existing deck plate. Accordingly, Reducing floor construction costs by an average of 20% or more can be saved.

According to the present invention, by implementing a one-way floor structure system which can omit the use of right angle direction girders and beams, the process can be simplified and air can be shortened.

According to the present invention, it is possible to go beyond the limit of the conventional 250 mm plate-shaped deck plate and to construct the span span of 8 m or more and the seamless installation.

According to the present invention, the floor area of a building can be increased by about 10% corresponding to the effect of reducing the floor height of the floor compared to the existing floor.

INDUSTRIAL APPLICABILITY According to the present invention, it is possible to improve the economical efficiency of the composite bottom plate such as the long span, the weight reduction, the section reduction, and improve the economical and safety of the slab system.

1 is a perspective view showing a deck plate system according to the prior art.
2 is a perspective view showing a configuration of a deck panel according to a conventional technique.
3 is a view showing a deck plate reinforced by truss roots according to the prior art.
FIG. 4 is a view showing a conventional reinforced concrete truss deck plate having a horizontal supporting hardware.
Fig. 5 is a view showing a cross-sectional shape of a Z-type steel wire latticed muscle attaching type synthetic deck plate according to an embodiment of the present invention.
6 is a cross-sectional view showing that a steel wire truss structure is formed by joining an upper reinforcing bar and a lower reinforcing steel together with a lattice muscle in a Z-shaped steel wire latticed muscle close-fitting synthetic deck plate according to an embodiment of the present invention.
FIG. 7 is a cross-sectional view showing a combined shape of a steel wire truss structure and a deck plate in a Z-type steel wire lattice close-fitting composite deck plate according to an embodiment of the present invention.
8 is a cross-sectional view showing that a horizontal reinforcing steel material is arranged on an upper part of a Z-type steel wire lattice muscle attaching type synthetic deck plate according to an embodiment of the present invention.
Fig. 9 is a view showing the arrangement of a steel wire truss structure on a deck plate in a Z-type steel wire lattice close-coupled synthetic deck plate according to an embodiment of the present invention.
Fig. 10 is an exploded view of a Z-type steel wire lattice muscle attaching type synthetic deck plate according to an embodiment of the present invention.
11 is a flowchart of a method of manufacturing a Z-type steel wire lattice muscle attaching type synthetic deck plate according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

[Z-shaped steel wire lattice muscle attaching type synthetic deck plate (100)]

Fig. 5 is a view showing a cross-sectional shape of a Z-type steel wire lattice muscle attaching type synthetic deck plate according to an embodiment of the present invention, wherein Fig. 5a shows the deck plate unit unit 110, And the deck plate unit units are connected in the width direction.

5, the Z-type steel wire lattice muscle attaching type synthetic deck plate unit unit 110 according to the embodiment of the present invention includes a lower plate 111 which is formed by bending in a pressing manner, An upper bend portion 113, a lattice near-muscle receiving groove 114, an upper plate 115, and an upper plate connecting portion 116. [

The deck plate unit unit 110 is a bony deck plate that occupies the skeleton of the composite deck plate, and takes a trapezoidal shape as a whole.

The top plate 114 extends in the longitudinal direction of the deck plate unit unit 110 and is formed on the top of the deck plate unit unit 110. This top plate 145 is formed in the form of a horizontal plate. Further, the top plate 115 is bent at both ends in the transverse direction to form the lattice near-field receiving grooves 114. [

The side plate includes a lower bent portion 112, an upper bent portion 113, and a lattice near-receiving groove 114, and is bent from both ends of the upper plate 115 in the transverse direction. The side plates extend in the longitudinal direction of the composite deck plate like the top plate 115. At this time, the side plates may be formed to be bent at least twice in the lateral direction. The side plates are formed to bend more than once, thereby enhancing the bonding performance with concrete to be laid later.

The lower plate 111 is formed horizontally from the lower end of the side plate and extends in the longitudinal direction of the composite deck plate.

5 (b), the two deck plate unit units 110 can be connected in the width direction, as shown by a reference numeral A, by the top plate connecting portion 116. As shown in Fig.

FIG. 6 is a cross-sectional view showing a steel wire truss structure formed by joining an upper reinforcing bar and a lower reinforcing steel together with a lattice muscle in a Z-shaped steel wire latticed muscle close-fitting synthetic deck plate according to an embodiment of the present invention.

6, the Lattice root 140 in the Z-shaped steel wire lattice close-coupled synthetic deck plate is provided to reinforce the structural rigidity of the deck plate unit unit 110, The L-shaped lattice root 140 is joined to the upper and lower reinforcing bars 120 and 130 to form a steel wire truss structure .

The lattice roots 140 are arranged in a zigzag form and are formed along the longitudinal direction of the composite deck plate. An upper reinforcing bar 120 is welded to the upper portion of the Lattice root bend portion 142 of the Z type lattice root 140 and a lower reinforcing bar 120 is welded to the lower portion of the Lattice root bend portion 142 of the Z type lattice root 140. [ (130) can be welded and coupled.

Accordingly, the upper reinforcing bars 120 and the lower reinforcing bars 130 serve as upper and lower currents, respectively, and the lattice roots 140 serve as a workpiece. Thus, the Z- And the lower reinforcing bars 120 and 130 reinforce the structural stiffness and strength of the composite deck plate as reinforcing trusses.

The lattice-like upper end portion 143 extends in the longitudinal direction of the composite deck plate, is previously horizontally bent, and can be attached or welded to the lattice near-field receiving groove 114 of the deck plate unit unit 110.

The lower end 141 of the lattice is bent horizontally and bent so as to extend in the lateral direction by a predetermined length in order to secure the thickness of the reinforcing steel covering.

As a result, the lattice root 140 is bent in the longitudinal direction of the composite deck plate at the upper portion and the lower end 141 of the lattice is welded to the lower plate 111 of the deck plate unit 110, Can be reduced.

The Lattice root bend portion 142 of the Z-type lattice root 140 is formed to be inclined along the longitudinal direction of the composite deck plate, and the inclined form is repeatedly formed in a zigzag form as a whole. At this time, the Lattice root bend 142 may be formed of the same reinforcing bars as the upper and lower reinforcing bars 120 and 130 at both longitudinal ends of the synthetic deck plate.

7 is a cross-sectional view showing a combined shape of a steel wire truss structure and a deck plate in a Z-type steel wire lattice close-fitting composite deck plate according to an embodiment of the present invention, and Fig. 8 is a cross- Sectional synthetic metal deck plate having a lattice-muscle-attached synthetic deck plate.

7 and 8, a Z-type steel wire latticed muscle-attached composite deck plate according to an embodiment of the present invention includes a deck plate unit unit 110, an upper reinforcing bar 120, a lower reinforcing bar 130, Lattice root 140, and further includes a horizontal reinforcement metal 150 as shown in FIG. 9 to be described later.

The deck plate unit unit 110 is a corrugated deck plate having unit units composed of an upper plate 115, a lower plate 111 and both side plates repeatedly formed in the transverse direction, And the lattice near muscle receiving grooves 114 are formed at both ends of the upper plate 115. [

The upper reinforcing bars 120 are disposed on the upper portion of the deck plate unit 110 and extend in the longitudinal direction.

The lower reinforcing bars 130 are disposed below the deck plate unit 110 and extend in the longitudinal direction.

The Z-shaped lattice root 140 is joined to the upper and lower bars 120 and 130 to form a steel wire truss structure. The upper end 143 is bent and attached to the lattice near- (Z-shaped) along the longitudinal direction.

8, the horizontal reinforcement metal piece 150 has a length (length) of the top plate 115 of the deck plate unit unit 110 so as to prevent the deck plate unit unit 110 from being opened and to improve the bending stiffness, Spaced at predetermined intervals in the direction of the arrow.

The upper end portion 143 of the lattice muscle 140 forming the steel wire truss structure is attached to the lattice muscular receiving groove 114 of the deck plate unit unit 110 and the Z- The lower end portion 141 is welded to the lower plate 111 of the deck plate unit unit 110 so that the steel wire truss structure and the deck plate unit unit 110 are integrated.

7, the Z-shaped lattice roots 140, the upper reinforcing bars 120, and the lower reinforcing bars 130, which are compression reinforcing bars and tensile reinforcing bars, Thereby constituting a reinforcing bar truss which is a steel truss structure. The Z-shaped lattice root 140 is composed of a cross-sectional root arranged in a zigzag shape. The upper end of the cross-sectional root is bent so as to secure a covering thickness, and the upper reinforcing bars 120 can be provided so that a coating thickness of about 20 mm can be ensured. The deck plate unit unit 110 is welded to and integrated with the upper end portion 143 and the lower end portion 141 of the Z-shaped lattice root 140, respectively.

The Z-type steel wire lattice muscle attaching type synthetic deck plate according to the embodiment of the present invention is a synthetic deck plate combining a bone deck plate unit unit 110 and a steel wire truss structure. The lattice muscle 140 forming the steel wire truss structure, The upper end portion 143 of the Z-type lattice root 140 is attached to the lattice near-field receiving groove 114 of the deck plate unit unit 110 as shown by the reference numeral B and the lower end portion 141 of the Z- The steel wire truss structure and the deck plate unit unit 110 are welded to the lower plate 111 of the deck plate unit unit 110 so that the dancing of the existing deck plate is maintained It is a single-deck plate with steel-truss, which is capable of long span implementation and can bear high load loads.

8, the horizontal reinforcement metal piece 150 has a length (length) of the top plate 115 of the deck plate unit unit 110 so as to prevent the deck plate unit unit 110 from being opened and to improve the bending stiffness, Spaced at predetermined intervals in the direction of the arrow. At this time, the deck plate unit unit 110 may be formed with a groove as shown by reference numeral C in FIG.

For example, the upper surface of the deck plate unit unit 110 is continuously reinforced in the transverse direction by the horizontal reinforcing steel member 150 such as an L-shaped steel member or a reinforcing bar, thereby preventing the deck plate unit unit 110 from spreading and improving the bending stiffness . At this time, the upper ends of the Z-shaped lattice roots 140 and the upper reinforcing bars 120 are positioned at the upper side of the deck plate unit unit 110 so that the horizontal reinforcing steel pieces 150 for reinforcing the lateral direction can be continuously disposed on the upper surface of the deck plate unit unit 110. [ And is disposed below the top plate 115 of the deck plate unit unit 110. [

9 is a view showing the arrangement of a steel wire truss structure on a deck plate in a Z-type steel wire lattice close-fitting synthetic deck plate according to an embodiment of the present invention, and Fig. 10 is a cross- Is a developed view of a lattice muscle attaching synthetic deck plate.

As shown in Fig. 9, the Z-shaped lattice roots 140a and 140b disposed in the bony deck plate are each composed of a cross-sectional root arranged in a zigzag pattern, and the upper ends of these root roots are bent And the lattice proximal portion 143 is attached to the lattice near-field receiving groove 114 of the deck plate unit unit 110. Further, the deck plate unit unit 110 is attached to the deck plate near the upper end 143 and the lower end 141 of the Z- And the plate unit unit 110, respectively.

10, the upper end of the deck plate unit unit 110 may be positioned below the upper plate 115 of the deck plate unit unit 110, And a lattice near-muscle receiving groove 114 is formed at both ends of the lattice near- That is, the lattice near-end receiving portion 114 is formed horizontally on the upper surface of the deck plate unit so that the lattice-like upper end portion 143 can be positioned below the upper plate 115 of the deck plate unit unit.

By integrating the steel truss and the deck plate in this manner, it is possible to realize a long span when the deck plate is used without local buckling, and the adhesion force with the concrete due to the lattice root 140 is increased, Sex can be secured.

[Method of Manufacturing Z-shaped Steel Wire Lattice Muscle Attach Type Composite Deck Plate]

11 is a flowchart of a method of manufacturing a Z-type steel wire lattice muscle attaching type synthetic deck plate according to an embodiment of the present invention.

12, a method of manufacturing a Z-type steel wire lattice muscle attaching type synthetic deck plate according to an embodiment of the present invention is firstly a bone deck plate including an upper plate 115, a lower plate 111 and both side plates , And a deck plate unit unit 110 in which the lattice nerve receiving groove 114 is formed (S110).

Next, the upper end portion 143 and the lower end portion 141 form a bent Z-shaped lattice root 140 (S120).

Next, the upper reinforcing bar 120 is welded to the upper portion of the Z-shaped lattice muscle bending portion 142 and the lower reinforcing bar 130 is welded to the lower portion of the bent portion 142 of the Z- Thereby forming a structure (S130).

Next, a steel wire truss structure is arranged in the longitudinal direction and the Z-type lattice near-end upper end portion 143 is attached to the lattice near-field receiving groove 114 of the deck plate unit unit 110 (S140).

Next, the engaging plates are fixed to both ends of the deck plate unit unit 110, and the deck plate unit units 110 are connected in the width direction (S150).

Next, the horizontal reinforcing steel member 150 is coupled to the upper portion of the deck plate unit 110 at predetermined intervals in the longitudinal direction (S160).

Subsequently, the concrete is placed in the bone deck plate, and then the overlay concrete is placed on the concrete, thereby completing the Z-type latticed muscle attaching synthetic deck plate (S170).

As a result, according to the embodiment of the present invention, the upper end 143 of the lattice root 140 forming the steel wire truss structure for joining the corrugated deck plate and the steel wire truss structure is connected to the deck plate unit unit The lower end 141 of the Z-shaped lattice muscle 140 is welded to the lower plate 111 of the deck plate unit unit 110, It is possible to realize a long span in the bottom plate in the form of a free-standing, no-form and no-stay type, and to bear a high load load.

According to the embodiment of the present invention, it is possible to greatly reduce the self weight by minimizing the amount of concrete charged in the deck-shaped deck plate, significantly reduce the thickness of the steel plate compared to the existing deck plate, By drastically reducing the amount of rebar, we can reduce floor construction costs by more than 20% on average.

According to an embodiment of the present invention, a one-way floor structure system which can omit the use of a right angle direction girder and a beam can be implemented to simplify the process and shorten the air.

According to the embodiment of the present invention, it is possible to go beyond the limit of the conventional 250 mm plate-shaped deck plate and to construct the span span of 8 m or more and the seamless installation.

According to the embodiment of the present invention, the floor area of the building can be increased by about 10% corresponding to the floor height reduction effect in which the bottom plate thickness is reduced compared to the existing bottom plate.

According to the embodiment of the present invention, it is possible to improve the economical efficiency of the composite bottom plate such as the long span, the weight reduction, the section reduction, and improve the economical efficiency and safety of the slab system.

It will be understood by those skilled in the art that the foregoing description of the present invention is for illustrative purposes only and that those of ordinary skill in the art can readily understand that various changes and modifications may be made without departing from the spirit or essential characteristics of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: synthetic deck plate
110: Deck plate unit
120: Upper reinforcing bar
130:
140: Lattice root
150: Horizontal reinforcement hardware
111:
112: Lower bend
113: upper bend
114: lattice tightening groove
115: top plate
116: top plate connection
141: Lower end of Lattice
142: Lattice root bend
143: Lattice upper part

Claims (13)

As a corrugated deck plate, a unit unit composed of an upper plate 115, a lower plate 111 and both side plates is repeatedly formed in a transverse direction and connected to each other in a transverse direction by a fastening device, A deck plate unit unit 110 having lattice near muscle receiving grooves 114 at both ends of a plate 115;
An upper reinforcing bar 120 disposed at an upper portion of the deck plate unit 110 and extending in the longitudinal direction;
A lower reinforcing bar 130 disposed at a lower portion of the deck plate unit 110 and extending in the longitudinal direction;
The upper end portion 143 is bent and attached to the lattice near muscle receiving groove 114 and is coupled to the upper reinforcing bar 120 and the lower reinforcing bar 130 to form a zigzag Z A Z-type lattice root 140 disposed in the Z-type lattice structure; And
A horizontal reinforcing metal piece 150 spaced apart at predetermined intervals in the longitudinal direction of the top plate 115 of the deck plate unit unit 110 to prevent the deck plate unit unit 110 from being opened and to improve the bending stiffness Including,
An upper end portion 143 of the lattice root 140 forming the steel wire truss structure is attached to the lattice muscular receiving groove 114 of the deck plate unit unit 110 and the lower end portion 141 of the Z- Is welded to a lower plate (111) of the deck plate unit unit (110) to integrate the steel wire truss structure and the deck plate unit unit (110). The method according to claim 1,
Each of the deck plate unit units 110 includes a lower plate 111, a lower bent portion 112, an upper bent portion 113, a lattice near-muscle receiving groove 114, a top plate 115 And a top plate connecting part (116), and the top plate (115) formed in the form of a horizontal plate is bent at both ends in the transverse direction to form the lattice near muscle receiving groove (114) A muscle - attached synthetic deck plate. The method according to claim 1,
The Z-shaped lattice root 140 is composed of a lower end 141 of the Lattice, a near-lattice bend 142 of the Lattice, and an upper end 143 of the Lattice, and is arranged in a zigzag form along the longitudinal direction of the composite deck plate A Z-type steel wire lattice close-coupled synthetic deck plate. The method of claim 3,
The upper reinforcing bar 120 is welded to the upper portion of the bent portion 142 of the Z-shaped lattice root 140 and the lower reinforcing bar 130 is welded to the lower portion of the bent portion 142 of the Z- And is welded and joined to each other. The method of claim 3,
The lower end portion 141 of the lattice is horizontally bent so as to extend in a transverse direction by a predetermined length in order to secure a thickness of the reinforcing steel coating and welded to the lower plate 111 of the deck plate unit unit 110 Z-shaped steel wire lattice stick-attached synthetic deck plate. The method of claim 3,
The Lattice root bend (142) of the Z-type lattice root (140) is formed to be inclined along the longitudinal direction of the composite deck plate, and a zigzag inclined form is repeatedly formed. Attachable composite deck plate. The method of claim 3,
The Z-shaped lattice root (140) is composed of a cross-sectional root arranged in a zigzag shape. The upper end of the cross-sectional root is bent so as to secure a covering thickness, 120) is disposed to secure a coating thickness of about 20 mm. The method according to claim 1,
The upper ends of the Z-shaped lattice roots 140 and the upper reinforcing bars 120 are connected to the deck plate unit unit 110 so that the horizontal reinforcing steel strips 150 can be continuously disposed on the upper surface of the deck plate unit unit 110. [ Is disposed below the upper plate (115) of the Z-shaped steel wire lattice root attaching type synthetic deck plate. a) forming a deck plate unit unit (110) having a lattice muscle nerves receiving groove (114) formed of a top plate (115), a bottom plate (111) and both side plates;
b) forming a Z-shaped lattice root (140) with a top end (143) and a bottom end (141) bent;
c) welding the upper reinforcing bar 120 to the upper portion of the Z-shaped lattice muscle bending portion 142 and welding the lower reinforcing bar 130 to the lower portion of the bending portion 142 of the Z- ;
d) disposing a steel wire truss structure in the longitudinal direction and attaching the Z-shaped lattice proximal upper end portion (143) to the lattice muscular receiving groove (114) of the deck plate unit unit (110);
e) fixing the coupling plate to both ends of the deck plate unit unit 110 and connecting the deck plate unit unit 110 in the width direction; And
f) joining the horizontal reinforcement steel (150) to the deck plate unit unit (110) at predetermined intervals in the longitudinal direction, and then pouring the concrete to complete the Z-type latticed muscle attaching synthetic deck plate,
An upper end portion 143 of the lattice root 140 forming the steel wire truss structure is attached to the lattice muscular receiving groove 114 of the deck plate unit unit 110 and the lower end portion 141 of the Z- ) Is welded to the lower plate (111) of the deck plate unit unit (110) to integrate the steel wire truss structure and the deck plate unit unit (110) Gt; 10. The method of claim 9,
The deck plate unit unit 110 of step a) includes a lower plate 111, a lower bent part 112, an upper bent part 113, a lattice near-field receiving groove 114, And an upper plate 115 formed of a top plate 115 and a top plate connecting portion 116 and formed in the form of a horizontal plate are bent at both ends in the transverse direction to form the lattice near- A method for manufacturing a Z-type steel wire latticed muscle attaching synthetic deck plate. 10. The method of claim 9,
The lattice root 140 in the step b) includes the lower end 141 of the lattice, the lattice nearest bend 142 and the upper end 143 of the lattice, and is arranged in a zigzag shape along the longitudinal direction of the composite deck plate Wherein the Z-shaped steel wire latticed muscle attaching type synthetic deck plate is manufactured. 12. The method of claim 11,
The lattice root 140 of the step b) is composed of a cross-sectional root arranged in a zigzag pattern. The upper end of the cross-sectional root is bent to secure a coating thickness, Wherein the upper reinforcing bar (120) is disposed to secure a coating thickness of about 20 mm. 10. The method of claim 9,
The upper ends of the Z-shaped lattice roots 140 and the upper reinforcing bars 120 are connected to the deck plate unit 110 so that the horizontal reinforcing steel pieces 150 can be continuously disposed on the upper surface of the deck plate unit unit 110 in step f) Like steel lattice lattice-muscle attaching type composite deck plate is disposed below the upper plate (115) of the unit (110).

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