KR102129130B1 - Composite deck plate for adhering z-shaped latticed bar, and manufacturing method for the same - Google Patents

Abstract

The upper end of the lattice muscle forming the steel wire truss structure for the combination of the corrugated 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 of the deck plate unit unit. By being welded to the lower plate, it is possible to implement a long span in a motionless bar, formwork and no reinforcement method on the floor plate of a building and bear a high load of pour load, and also minimize the amount of concrete filling in the bone deck plate. Provided is a synthetic deck plate attached to a Z-type steel wire and lattice muscle, which can greatly reduce its own weight and significantly reduce the thickness of a steel sheet compared to an existing bone-shaped deck plate.

Description

Z-shaped steel wire lattice muscle attached synthetic deck plate and its manufacturing method {COMPOSITE DECK PLATE FOR ADHERING Z-SHAPED LATTICED BAR, AND MANUFACTURING METHOD FOR THE SAME}

The present invention relates to a synthetic deck plate, more specifically, for the combination of a corrugated deck plate (Corrugated Deck Plate) and a steel truss structure so as to implement a long span on a floor plate of a building and bear a heavy load of pour load. A synthetic deck plate for attaching a Z-shaped steel wire lattice muscle to a deck plate unit unit, and a method for manufacturing the same.

The deck plate used for the floor plate of a building has been used widely as a representative floor plate material because it has the advantages of shortening the air and reducing labor costs by acting as a formwork when pouring concrete.

The floor board composed of beams and slabs occupies about 60% of the total construction cost, and the higher the structure is, the more it affects economic efficiency such as building weight, available area, material savings, and energy saving. And a deck plate that satisfies the needs of lightweight and long-span technology.

These deck plates are divided into a bone deck plate and a flat deck plate with a reinforced truss according to its shape, and are classified into a formwork and a load supporting structure according to the purpose of use.

Specifically, the bone deck plate may be used for a formwork that bears only concrete pouring load, or may be used for a structure that plays a role of a tensile material after concrete synthesis, and such a bone deck plate is danced to implement a long span. As the thickness increases, the thickness of the steel sheet needs to be thickened. Accordingly, there is a problem in that it is difficult to secure economic efficiency.

In particular, when the bone-shaped deck plate is danced in order to realize a long span, it can lose its adhesion to concrete and adhere to it as deformation occurs due to compression buckling of the upper flange and web of the deck plate. There is a problem 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 formwork into a thin plate, and an upper steel bar for a load-supporting structure and a lower steel bar in a truss form are integrated with the lower steel sheet for formwork. Is used only as a simple formwork and lacks rigidity, and there is a possibility of lateral buckling of the upper compression-side rebar of the structural rebar truss. In addition, the flat plate deck with a reinforced truss has a problem in that it is difficult to implement a long span because the material is filled in the entire dance of the reinforced truss type deck plate, and the waste of material is large and the self-weight is greatly increased.

On the other hand, Figure 1 is a perspective view showing a deck plate system according to the prior art.

As shown in Figure 1, the end continuation deck plate system using a cap plate according to the prior art, by combining the cap plate 13 for reinforcement of the parent to the deck plate body 11 to ensure the continuity of the end , By constructing a truss-type reinforcing bar 14 connecting the flat portion 11a to close the rib 12a opened in the width direction of the deck plate body with the lateral distribution with the adjacent ribs, the opened rib 12a when pouring concrete ) To prevent cracking and lateral buckling of the deck plate, and to resist external forces acting.

In addition, the end continuity deck plate system using a cap plate according to the prior art is to ensure the stability of the deck shape and end continuity by closing the open end face. That is, the cap plate 13 for reinforcing the parent cement is formed to cover the opened upper surface of the ribs 12a opened at both ends in the longitudinal direction of the deck plate body 11, and the cap plate 15 for reinforcing the positive moment Is formed so as to cover the open upper surface of the rib 12a opened centrally in the longitudinal direction of the deck plate body 11.

On the other hand, Figure 2 is a perspective view showing the configuration of a deck panel according to the prior art.

Referring to FIG. 2, the deck panel according to the related art forms a truss structure by connecting upper and lower rebars 22 and 23 with a lattice material 24 bent in a zigzag form. And, it is configured to be fixed at predetermined intervals on the closing plate 21 by a spacer 25 bent in the form of a cross to cross the truss structure. Here, the finishing plate 21 is generally made of a material that does not require a separate anti-corrosion coating, such as a plated steel plate, and is generally composed of a corrugated plate to increase local strength.

The deck panel according to the prior art is composed of a span between beams or pillars as a unit, supported on them, and then poured concrete on top to form a slab. In the completed slab, the upper and lower rebars 22 and 23 constitute the main reinforcing bar of the slab, and the closing plate 21 closes the lower surface of the slab. Lattice muscles are seated on the upper part of the deck panel as needed to reinforce the local strength of the slab and to add cast steel.

The deck panel according to the prior art forms a continuous deck by being connected over compensation such as 1 beam, and thus becomes a working platform for construction, and forms a reinforced concrete slab integrally with concrete after pouring of concrete.

However, in the deck panel according to the related art, since the truss structure is coupled to the finishing plate 21 by the spacers 25 intersecting it, various problems are caused. That is, when the weight or equipment of the worker moves on the finishing plate 21 and the concrete is injected, the load is transmitted to the truss structure through the spacer 25, and the spacer 25 has a longitudinal stress. Since it is transmitted only by its own bending, the actual truss structure cannot act as a girder with respect to the finishing plate 21.

Therefore, the deck panel according to the prior art has a small load-resistant, and it is difficult to function as a work deck without additional reinforcement. In addition, since the truss structure becomes a longitudinal strength member upon completion of the slab, it is installed exactly vertically by a spacer 25 having a complicated bend, even though it must be installed with a proper interval perpendicular to the finishing plate 21 Since it is practically impossible, the truss structure is installed in a twisted state, thereby causing deformation of the finished slab and lowering strength.

On the other hand, as a prior art for solving the above-mentioned problems, Republic of Korea Patent No. 10-963579: "Integrated truss root deck plate" invention is disclosed, will be described with reference to FIG.

Figure 3 is a view showing a deck plate reinforced with a truss root according to the prior art, a) of Figure 3 is a front view of the deck plate reinforced with a truss root, Figure 3b) is a truss for reinforcing the deck plate It is a perspective view of the root.

Referring to Figure 3 a), the deck plate reinforced with a truss root according to the prior art, the top plate 31, side plates 32 bent downwardly at both ends of the top plate, and each side The unit unit composed of the lower plates 33 bent horizontally at the end of the plate is repeatedly formed in the lateral 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 upper reinforcing bar and the lower reinforcing bar are arranged with corrugated reinforcing reinforcing bars 41. 40 is coupled to cover a part of the upper plate and the lower plate of the deck plate 30 and the front surface of the side plate. Such a deck plate can be constructed in a long span without a temporary holding, and it is effective in alleviating the stress generated on the compression side by allowing the deck plate and the truss muscle to be integrally operated.

However, in connecting the truss muscle 40 and the deck plate 30, a reinforcement stiffener 35 is formed to strengthen the rigidity of the upper and lower plates 31, 33 and the side plates 32, and the truss muscle 40 It is welded by a reinforcement stiffener 35 to cover a part of the upper plate 31 and the lower plate 33 of the deck plate 30 and the front surface of the side plate 32.

Further, the lower portion of the leg portion 41b is formed to be bent upward, and the upper portion of the leg portion 41a is horizontally bent to extend over the upper portion of the upper plate 31. In addition, the deck plate reinforced with the truss root according to the prior art, in order to reinforce the slab main reinforcing bar 50, after forming the lower portion of the leg (41b) by crossing each other, the main reinforcing bar on the upper portion. Accordingly, when the truss muscle 40 and the deck plate 30 are connected, the welding must be performed at the part where each reinforcement stiffener is formed, and cross-forming is required to connect the lower part of the leg and the main slab of the slab, so the constructability is very poor. .

In addition, as shown in b) of FIG. 3, the truss bar 40 arranges the upper reinforcing bar 42 and the lower reinforcing bar 43 in parallel, and reinforces the waveforms in the upper reinforcing bar 42 and the lower reinforcing bar 43. Reinforcing bars (41) are arranged, and welded and fixed at points where each reinforcing bar is in contact to form a truss shape.

Specifically, the corrugated reinforcing bar 41 bends the upper end and the lower end of each other inward and outward to form leg portions 41a and 41b, respectively. At this time, the upper leg portion (41a) is horizontally bent to the outside so as to be positioned on the upper plate 31 of the deck plate 30, the lower leg portion (41b) is bent upward inward to the inner side of the deck plate (30) It is positioned on the lower plate 33. By bending the lower leg portion 41b upward, the slab main reinforcement 50 can be spaced apart from the deck plate lower plate 33 without using a separate spacer.

The truss muscle 40 is welded to the reinforcement stiffener 35 to cover a part of the upper plate 31 and the lower plate 33 of the deck plate 30 and the front surface of the side plate 32.

However, in the case of a deck plate reinforced with a truss muscle according to the related art, the length of the truss muscle is increased by forming the upper portion of the leg to cover the upper plate of the upper plate, and bending the lower portion of the leg upward to increase the amount of rebar There was a disadvantage that the self-weight increased. In addition, in the case of a deck plate reinforced with a truss root according to the related art, the thickness of the deck plate increases as the leg portion is formed up to the upper portion of the upper plate, thereby reducing the total floor area of the building.

On the other hand, as another prior art, Korean Patent Registration No. 10-1747097, which is patented and registered by the applicant of the present invention, discloses an invention titled "Integral Reinforced Truss Deck Plate with Horizontal Supporting Hardware and Method for Producing the Same" It is referred to in this specification and forms part of the present invention, and will be described in detail with reference to FIG. 4.

Figure 4 is a view showing a transverse support hardware-integrated reinforced truss deck plate according to the prior art, Figure 4 a) is a cross-sectional view of a transverse support hardware-integrated reinforced truss deck plate, Figure 4 b) is a transverse support It is a perspective view of an integrated steel structure truss deck plate.

As shown in Figure 4, the transverse supporting hardware-integrated reinforced truss deck plate according to the prior art, unit unit 60, reinforcing bar 70, connecting reinforcement plate 80, upper reinforcing bar 91, lower Reinforcing bar (92), transverse steel (93), through-reinforcing bar (94) and includes a coupling plate (95).

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

The reinforcing bar 70 is formed in a truss form in the longitudinal direction of both side plates 62, and includes a bent portion 72 horizontally bent from the bottom to the side plate 62, and also, the reinforcing bar upper portion 71 And a reinforcing bar body 73.

The upper reinforcing bar 91 is welded and coupled in the upper portion of the reinforcing bar 70, and extends in the longitudinal direction of the unit unit 60, and the lower reinforcing bar 92 is welded and coupled in the upper portion of the bent portion 72, unit unit 60 ) In the longitudinal direction.

The transverse steel materials 93 are arranged to be spaced apart at predetermined intervals in the longitudinal direction of the top plate 61, and are joined at a length corresponding to the width of the top plate 61 on the top surface of the top plate 61.

The through reinforcing bar 94 is formed integrally with the transverse steel material 93, and is formed in the transverse direction on the upper surface of the upper plate 61 to the bottom of the place where the reinforcing reinforcing bar 70 and the upper reinforcing bar 91 cross and join. It is welded to the reinforcing bar 70 while passing through.

Specifically, the top plate 61 of the unit unit 60 is formed in the form of a horizontal plate, and the lateral width of each outermost top plate of the unit unit 60 formed of at least one top plate, bottom plate and side plate. Is formed at a length of 1/2 of the lateral width of the top plate 61, and the lateral ends of each outermost top plate include vertical bent portions 61a and 61b, respectively, which are vertically bent.

In addition, each of the vertical bending portions 61a and 61b of the adjacent unit units 60 are mutually coupled and connected to each other by a fastening device 61c formed to be spaced apart at predetermined intervals in the longitudinal direction of the upper plate 61, At this time, the horizontal steel material 93 is formed of L-shaped steel including a lower plate and a vertical plate, and the upper plate 61 is coupled to the lower plate by a fastening device at regular intervals in the lateral direction. In addition, the transverse steel material 93 is to be coupled by the vertical bent portions 61a and 61b, but is coupled by a slit and a fastening device formed in the middle portion of the transverse steel material 93.

The through-reinforcing bar 94 is welded to the lower plate or the vertical plate, and extends transversely to a length corresponding to the distance between adjacent vertical bent portions.

According to the transverse supporting hardware-integrated reinforced truss deck plate according to the prior art, the horizontal plate is disposed at regular intervals on the upper plate of the deck plate and connected by a fastening device, thereby lowering the height of the deck plate while buckling the deck plate. And it is possible to prevent the sagging and opening in the vertical direction, and also, it is formed integrally with the transverse steel and by arranging through the reinforcing bars extending in the transverse direction while passing through the lower portion where the reinforcing bars and the upper reinforcing bars intersect. It provides a transverse restraint effect to the reinforcing bar and can smoothly transmit the compressive force acting on the reinforcing bar. In addition, it is possible to secure local buckling performance even when using a thin plate of reinforcing bar and transverse steel. Due to the bending of the reinforcing bars in the horizontal direction, it is possible to secure the reinforcing bar thickness.

However, in the case of the transverse support steel-integrated rebar truss deck plate according to the above-described conventional technology, the reinforcing rebar is formed integrally with the transverse steel and extends in the transverse direction while penetrating the lower portion where the reinforcing bar and the upper rebar intersect. Since the structure is arranged, there is a problem that the structure is complicated.

Republic of Korea Patent No. 10-963579 (application date: December 21, 2007), the name of the invention: "truss muscle integrated deck plate" Republic of Korea Patent No. 10-1255464 (application date: July 27, 2011), the name of the invention: "End plate continuation deck plate system using a cap plate" Republic of Korea Registered Patent No. 10-1747097 (application date: December 22, 2015), the name of the invention: "Short-sided reinforced truss deck plate and its manufacturing method" Republic of Korea Patent No. 10-1731244 (application date: December 22, 2015), the name of the invention: "Bending rebar truss deck plate attached to the connection reinforcement plate and its manufacturing method" Japanese Patent Publication No. 1994-322872 (published on November 22, 1994), title of invention: "Deck Plate" Japanese Patent Publication No. 2013-209838 (published date: October 10, 2013), title of invention: "Reinforcement member of deck plate and synthetic slab structure using the reinforcement member" Republic of Korea Patent No. 10-1366716 (application date: September 1, 2011), the name of the invention: "web section reinforced deck plate" Republic of Korea Patent No. 10-1389113 (application date: November 23, 2012), the name of the invention: "truss girder integrated deck plate"

Technical problem to be achieved by the present invention for solving the above-described problem is, the upper end of the lattice muscle forming the steel wire truss structure for the combination of the bone deck plate and the steel wire truss structure is attached to the lattice muscle receiving groove of the deck plate unit unit , The lower end of the lattice muscle is to be welded to the lower plate of the deck plate unit unit, to provide a synthetic deck plate attached to the Z-type steel wire lattice muscle and a method for manufacturing the same.

Another technical problem to be achieved by the present invention, by minimizing the amount of concrete poured into the bone deck plate can significantly reduce the self-weight, compared with the existing bone deck plate, the steel plate thickness can be significantly reduced, Z-type steel wire lattice muscle attached synthesis It is to provide a deck plate and its manufacturing method.

As a means for achieving the above-described technical problem, the Z-shaped steel wire lattice muscle-attached synthetic deck plate according to the present invention is a bone-shaped deck plate (Corrugated Deck Plate), and a unit unit composed of a top plate, a bottom plate, and both side plates is transverse. A deck plate unit unit formed repeatedly in the direction, continuously connected to each other in the lateral direction by a fastening device, and formed with a lattice muscle receiving groove bent at both ends of a horizontal plate-shaped upper plate; An upper reinforcing bar disposed on the deck plate unit unit and extending in a longitudinal direction; A lower reinforcing bar disposed in a lower portion of the deck plate unit unit and extending in a longitudinal direction; Each of the upper and lower rebars is combined with each other to form a steel wire truss structure, the upper end is bent and attached horizontally to be accommodated in the lattice muscle receiving groove, and a Z-shaped lattice arranged in a zigzag shape (Z-shaped) along the longitudinal direction muscle; And a horizontal reinforcing steel spaced apart at predetermined intervals in a lengthwise direction of the upper plate of the deck plate unit unit to prevent the deck plate unit unit from being opened and to improve bending rigidity. Including, but the upper end of the lattice muscle forming the steel wire truss structure is attached to the lattice muscle receiving groove of the deck plate unit unit, the lower end of the Z-type lattice muscle is welded to the lower plate of the deck plate unit unit, the steel wire The truss structure and the deck plate unit unit are integrated, and each of the deck plate unit units is a lower plate, a lower bending portion, an upper bending portion, a lattice muscle receiving groove, an upper plate and an upper plate connecting portion formed by bending in a pressing manner. Made, the upper plate formed in the form of a horizontal plate is bent at both ends in the lateral direction to form the lattice muscle receiving groove, and the Z-shaped lattice so that the horizontal reinforcement hardware can be continuously disposed on the upper surface of the deck plate unit unit It is characterized in that the upper ends of the muscles and the upper rebars are disposed below the upper plate of the deck plate unit unit.

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Here, the lattice muscle is composed of a lower end of the lattice muscle, a lattice muscle bend, and an upper end of the lattice muscle, and may be arranged in a zigzag form along the longitudinal direction of the synthetic 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 muscle is horizontally bent to extend in the lateral direction by a predetermined length to secure the reinforcing bar thickness, and may be welded to the lower plate of the deck plate unit unit.

Here, the lattice muscle bent portion of the lattice muscle is formed to be inclined along the longitudinal direction of the synthetic deck plate, and is characterized in that the zigzag shape as a whole is repeatedly formed.

Here, the lattice muscle is composed of cross-sectional muscles arranged in a zigzag shape, the upper end of the cross-sectional muscles is bent to ensure a covering thickness, and by placing the upper reinforcing bar on the upper part of the lattice muscle bending portion, about 20 mm The coating thickness can be secured.

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On the other hand, as another means for achieving the above-described technical problem, the Z-type steel wire lattice muscle attached synthetic deck plate and its manufacturing method according to the present invention, a) a corrugated deck plate (Corrugated Deck Plate), top plate, bottom plate And a unit unit consisting of both side plates is repeatedly formed in the transverse direction, connected to each other continuously in the transverse direction by a fastening device, and a deck plate unit unit having a lattice muscle receiving groove bent at both ends of the upper plate in the form of a horizontal plate. Forming a; b) forming a Z-shaped lattice muscle in which the upper and lower ends are bent; c) forming a steel wire truss structure by welding-bonding an upper rebar to an upper portion of the bent portion of the Z-type lattice, and welding-bonding a lower rebar to the lower portion of the bent portion of the Z-type lattice; d) disposing the steel wire truss structure in the longitudinal direction and attaching the upper end of the Z-shaped lattice muscle to the lattice muscle 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) after combining the horizontal reinforcement hardware which is continuously arranged in the transverse direction to the upper plate at predetermined intervals in the longitudinal direction on the upper portion of the deck plate unit unit, concrete is post-poured to complete the Z-type lattice muscle-attached synthetic deck plate. Including the step, the upper end of the lattice muscle forming the steel wire truss structure is bent and attached horizontally to be accommodated in the lattice muscle receiving groove of the deck plate unit unit, and the lower end of the Z-type lattice muscle is the deck plate unit. The steel wire truss structure and the deck plate unit unit are integrated by being welded to the lower plate of the unit, and the deck plate unit units of step a) are each formed by bending in a pressing manner, the lower plate, the lower bending portion, and the upper bending portion , Lattice muscle receiving groove, the upper plate and the upper plate connecting portion, the upper plate formed in the form of a horizontal plate is bent at both ends in the lateral direction to form the lattice muscle receiving groove, in step f) the horizontal reinforcement hardware is It is characterized in that the upper end of the Z-shaped lattice muscle and the upper reinforcing bar are disposed below the upper plate of the deck plate unit unit so as to be continuously disposed on the upper surface of the deck plate unit unit.

According to the present invention, the upper end portion of the lattice muscle forming the steel wire truss structure is coupled to the lattice muscle receiving groove of the deck plate unit unit, and the lower end of the lattice muscle is formed of the deck plate unit unit for the combination of the bone deck plate and the steel wire truss structure. By being welded to the lower plate, it is possible to implement a long span in a moveless bar, formwork and no reinforcement method on the floor plate of a building and bear a high load of pour load.

According to the present invention, it is possible to significantly reduce the self-weight by minimizing the amount of concrete poured into the bone deck plate, and can significantly reduce the thickness of the steel sheet compared to the existing bone deck plate, thereby significantly reinforcing the amount of reinforcing bar compared to the existing reinforced truss deck plate. By reducing, it is possible to reduce the cost of floor plate construction by more than 20% on average.

According to the present invention, it is possible to simplify the process and shorten the air by implementing a one-way floor structure system capable of omitting the use of a right angle girder and a beam.

According to the present invention, it is possible to construct a long spanned non-barrier and non-muscular reinforcement over 8m beyond the limitations of the existing 250mm non-barrier formwork deck plate.

According to the present invention, it is possible to increase the total floor area of the building by about 10% in response to the effect of reducing floor height compared to the existing floor plate.

According to the present invention, it is possible to improve the economics for the composite floor plate, such as long span, reduced self-weight, reduced cross-section, and can improve the economics and safety of the slab system.

1 is a perspective view showing a deck plate system according to the prior art.
Figure 2 is a perspective view showing the configuration of a deck panel according to the prior art.
3 is a view showing a deck plate reinforced with a truss root according to the prior art.
4 is a view showing a transverse support hardware-integrated reinforced truss deck plate according to the prior art.
5 is a view showing a cross-sectional shape of a synthetic deck plate attached to a Z-type steel wire lattice according to an embodiment of the present invention.
6 is a cross-sectional view showing that a steel wire truss structure is formed by combining an upper reinforcing bar and a lower reinforcing bar and a lattice in a Z-type steel wire lattice muscle attached synthetic deck plate according to an embodiment of the present invention.
7 is a cross-sectional view showing a combined shape of a steel truss structure and a deck plate in a synthetic deck plate attached to a Z-type steel wire lattice according to an embodiment of the present invention.
8 is a cross-sectional view showing a horizontal reinforcement hardware disposed on the top of a synthetic deck plate attached to a Z-type steel wire lattice according to an embodiment of the present invention.
9 is a view showing the arrangement of a steel wire truss structure on a deck plate in a synthetic deck plate attached to a Z-type steel wire lattice according to an embodiment of the present invention.
10 is an exploded view of a Z-shaped steel wire lattice muscle attached synthetic deck plate according to an embodiment of the present invention.
11 is an operation flow diagram of a method of manufacturing a synthetic deck plate attached to a Z-type steel wire lattice according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains may easily practice. However, the present invention can be implemented in many different forms and is not limited to the embodiments described herein. In addition, in order to clearly describe the present invention in the drawings, parts irrelevant to the description are omitted, and like reference numerals are assigned to similar parts throughout the specification.

Throughout the specification, when a part “includes” a certain component, this means that other components may be further included rather than excluding other components unless specifically stated to the contrary.

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

5 is a view showing a cross-sectional shape of a synthetic deck plate attached to a Z-shaped steel wire lattice according to an embodiment of the present invention, wherein a) in FIG. 5 shows the deck plate unit unit 110, and b) in FIG. 5 It is a diagram showing that the deck plate unit units are connected in the width direction.

5, the Z-shaped steel wire lattice muscle attached synthetic deck plate unit unit 110 according to an embodiment of the present invention, each of the lower plate 111, the lower bending portion formed by bending (Pressing) method (112), the upper bent portion (114), the lattice muscle receiving groove (115), the top plate (116) and the top plate connecting portion (117).

The deck plate unit unit 110 is a bone-shaped deck plate that occupies the skeleton of a synthetic deck plate, and takes a trapezoidal shape with one side as a whole.

The upper plate 116 extends in the longitudinal direction of the deck plate unit unit 110 and is formed on the upper portion of the deck plate unit unit 110. The upper plate 116 is formed in the form of a horizontal plate. In addition, the upper plate 116 is bent at both ends in the lateral direction to form the lattice muscle receiving groove 115.

The side plate is made of a lower bent portion 112, an upper bent portion 113, and a lattice muscle receiving groove 115, and is bent from both ends in the lateral direction of the upper plate 115. The side plate is formed to extend in the longitudinal direction of the composite deck plate, like the top plate 115. At this time, the side plate may be formed to be bent at least twice in the transverse direction. Since the side plate is formed to bend more than once, it is possible to increase the bonding performance with concrete to be poured later.

The lower plate 111 is formed horizontally from the bottom of the side plate, and is formed to extend in the longitudinal direction of the composite deck plate.

In addition, as shown in b) of FIG. 5, two deck plate unit units 110 may be connected in the width direction by the reference plate A by the upper plate connecting portion 117.

On the other hand, Figure 6 is a cross-sectional view showing that forming a steel wire truss structure by combining the upper and lower rebar and the lattice muscle in a Z-type steel wire lattice muscle attached synthetic deck plate according to an embodiment of the present invention.

Referring to Figure 6, in the Z-type steel wire lattice muscle attached synthetic deck plate according to an embodiment of the present invention, the lattice muscle 140 is for reinforcing the structural rigidity of the deck plate unit unit 110, the lower end of the lattice muscle ( 141), consisting of a lattice muscle bent portion 142 and a lattice muscle upper end portion 143, the Z-shaped lattice muscle 140 is combined with the upper reinforcing bar 120 and the lower reinforcing bar 130 to form a steel wire truss structure. .

The lattice muscle 140 is arranged in a zigzag form, and is formed along the longitudinal direction of the synthetic deck plate. The upper reinforcing bar 120 is welded to the upper part of the lattice muscle bending part 142 of the Z-type lattice muscle 140, and the lower reinforcing bar below the lattice muscle bending part 142 of the Z-type lattice muscle 140. 130 can be welded and joined.

Accordingly, the upper reinforcing bar 120 and the lower reinforcing bar 130 serve as upper and lower chords, respectively, and the lattice muscle 140 serves as a private material, so that the Z-shaped lattice muscle 140 and the upper reinforcing bar are used. And the lower reinforcing bars 120 and 130 are reinforced trusses to reinforce structural rigidity and strength of the composite deck plate.

The upper end portion of the lattice muscle 143 extends in the longitudinal direction of the composite deck plate, is bent horizontally in advance, and can be horizontally attached or welded to be accommodated in the lattice muscle receiving groove 115 of the deck plate unit unit 110. have.

The lower end of the lattice muscle 141 is bent horizontally, and is bent so as to extend transversely by a predetermined length in order to secure the reinforcing bar covering thickness.

In the end, the lattice muscle 140 is bent in the longitudinal direction of the synthetic deck plate from the top, and the bottom 141 of the lattice muscle is welded to the bottom plate 111 of the deck plate unit unit 110, thereby comparing the amount of reinforcement of the lattice muscle compared to the prior art. Can be reduced.

The lattice muscle bent portion 142 of the Z-shaped lattice muscle 140 is formed to be inclined along the longitudinal direction of the synthetic deck plate, and the shape inclined in a zigzag form as a whole is repeatedly formed. At this time, the lattice muscle bent portion 142 may be formed of the same rebar as the upper reinforcing bar 120 and the lower reinforcing bar 130 at both ends in the longitudinal direction of the synthetic deck plate.

On the other hand, Figure 7 is a cross-sectional view showing the combined shape of the steel wire truss structure and the deck plate in the Z-type steel wire lattice muscle attached synthetic deck plate according to an embodiment of the present invention, Figure 8 is a Z-type steel wire according to an embodiment of the present invention It is a cross-sectional view showing the horizontal reinforcement hardware placed on the top of the lattice muscle-attached synthetic deck plate.

Referring to Figures 7 and 8, Z-type steel wire lattice muscle attached composite deck plate according to an embodiment of the present invention, the deck plate unit unit 110, the upper reinforcement 120, the lower reinforcement 130 and the Z-type It includes a lattice muscle 140, and further includes a horizontal reinforcement hardware 150, as shown in Figure 9 to be described later.

Deck plate unit unit 110 is a corrugated deck plate (Corrugated Deck Plate), the unit unit consisting of the top plate 116, the bottom plate 111 and both side plates is formed repeatedly in the transverse direction, the transverse direction by the fastening device It is continuously connected to each other, and the lattice muscle receiving groove 115 is formed at both ends of the upper plate 116.

The upper reinforcing bar 120 is disposed above the deck plate unit unit 110 and extends in the longitudinal direction.

The lower reinforcing bar 130 is disposed under the deck plate unit unit 110 and extends in the longitudinal direction.

The Z-shaped lattice muscle 140 is combined with the upper reinforcement 120 and the lower reinforcement 130 to form a steel wire truss structure, and the upper end portion 143 is bent to be attached to the lattice muscle receiving groove 115, It is arranged in a zigzag shape (Z shape) along the longitudinal direction.

8, the length of the upper plate 116 of the deck plate unit unit 110 to prevent the spreading of the deck plate unit unit 110 and improve the bending stiffness, as shown in FIG. They are spaced apart at predetermined intervals in the direction.

Accordingly, the upper end portion 143 of the lattice muscle 140 forming the steel wire truss structure is attached to the lattice muscle receiving groove 115 of the deck plate unit unit 110, and the Z-shaped lattice muscle 140 The lower end 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.

As shown in FIG. 7, the Z-shaped lattice bar 140 manufactured to correspond to the bone deck plate unit unit 110 and the upper reinforcing bar 120 and the lower reinforcing bar 130, which are compression reinforcing bars, are respectively welded to each other. By constructing a steel wire truss structure, a reinforced truss. The Z-shaped lattice muscle 140 is composed of cross-sectional muscles arranged in a zigzag shape, and the upper end of the cross-sectional muscle is bent to ensure a covering thickness, and the upper reinforcement ( By arranging 120), a covering thickness of about 20 mm can be secured. In addition, the deck plate unit unit 110 is welded and integrated at the upper end portion 143 and the lower end portion 141 of the Z-shaped lattice muscle 140, respectively.

Z-type steel wire lattice muscle-attached synthetic deck plate according to an embodiment of the present invention is a synthetic deck plate combining a bone-shaped 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 as shown in reference numeral B, is attached to the lattice muscle receiving groove 115 of the deck plate unit unit 110, the lower end portion 141 of the Z-shaped lattice muscle 140 is the The steel plate truss structure and the deck plate unit unit 110 are integrally welded to the lower plate 111 of the deck plate unit unit 110 while maintaining the opening height of the existing bone-shaped deck plate as it is. It is a deck plate with integrated steel wire truss that is capable of realizing a long span and that can bear heavy loads of pour loads.

8, the length of the upper plate 116 of the deck plate unit unit 110 to prevent the spreading of the deck plate unit unit 110 and improve the bending stiffness, as shown in FIG. They are spaced apart at predetermined intervals in the direction. At this time, the deck plate unit unit 110 may be formed with a groove, as illustrated by reference numeral C.

For example, the upper surface of the deck plate unit unit 110 is continuously reinforced in the transverse direction with a horizontal reinforcing hardware 150 such as an L-shaped steel member or reinforcing bar to prevent the deck plate unit unit 110 from expanding and to improve flexural rigidity. Can. At this time, the top of the Z-shaped lattice muscle 140 and the upper reinforcement 120 so that the horizontal reinforcement hardware 150 for reinforcing the transverse direction can be continuously disposed on the upper surface of the deck plate unit unit 110 The deck plate unit unit 110 is disposed below the upper plate 116.

On the other hand, Figure 9 is a view showing the arrangement of the steel wire truss structure on the deck plate in the Z-type steel wire lattice muscle attached synthetic deck plate according to an embodiment of the present invention, Figure 10 is a Z-type steel wire according to an embodiment of the present invention It is a developed view of a lattice muscle-attached synthetic deck plate.

As shown in Fig. 9, the Z-shaped lattice muscles 140a and 140b disposed in the bone-shaped deck plate are each composed of cross-sectional muscles arranged in a zigzag shape, and the upper ends of these cross-section muscles are bent to ensure a covering thickness. And, the upper end portion 143 of the lattice muscle is attached to the lattice muscle receiving groove 115 of the deck plate unit unit 110, and also, the deck at the upper end portion 143 and the lower end portion 141 of the Z-type lattice muscle 140. The plate unit unit 110 is welded and integrated with each other.

In addition, as shown in FIG. 10, the upper plate of the deck plate unit unit 110 so that the upper end of the lattice muscle 140 is located below the upper plate 116 of the deck plate unit unit 110. (116) Lattice muscle receiving grooves 115 are formed at both ends. That is, the lattice muscle receiving portion 114 is formed horizontally on the upper surface of the deck plate unit unit so that the upper end portion of the lattice muscle 143 is located below the upper plate 116 of the deck plate unit unit.

In this way, by integrating the steel wire truss and formwork deck plate, it is possible to implement a long span during construction without local buckling even if a thin plate plate is used, and when the synthetic slab is formed, the adhesion to concrete due to the lattice muscle 140 increases. Castles can be secured.

[Production Method of Z-type Steel Wire Lattice Root Attached Composite Deck Plate]

11 is an operation flow diagram of a method of manufacturing a synthetic deck plate attached to a Z-type steel wire lattice according to an embodiment of the present invention.

Referring to Figure 12, the method of manufacturing a Z-shaped steel wire lattice muscle attached composite deck plate according to an embodiment of the present invention, first, as a bone deck plate comprising an upper plate 116, a lower plate 111 and both side plates , Lattice muscle receiving groove 115 forms a deck plate unit unit 110 is formed (S110).

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

Next, the upper rebar 120 is welded to the upper portion of the bent portion 142 of the Z-type lattice muscle, and the lower reinforcing bar 130 is welded to the lower portion of the bending portion 142 of the Z-type lattice muscle to weld the steel wire truss. A structure is formed (S130).

Next, the steel wire truss structure is disposed in the longitudinal direction and the Z-shaped lattice muscle upper end portion 143 is attached to the lattice muscle receiving groove 115 of the deck plate unit unit 110 (S140).

Next, the coupling plate is fixed to both ends of the deck plate unit unit 110, and the deck plate unit unit 110 is connected in the width direction (S150).

Next, the horizontal reinforcing hardware 150 is coupled to the deck plate unit unit 110 at predetermined intervals in the longitudinal direction (S160).

Subsequently, after pouring the concrete in the bone-shaped deck plate, by pouring the overlaid concrete on the top, the Z-type lattice muscle-attached synthetic deck plate is completed (S170).

After all, according to an embodiment of the present invention, the upper end portion 143 of the lattice muscle 140 forming the steel wire truss structure for the combination of the corrugated deck plate and the steel wire truss structure is the deck plate unit unit ( 110) is attached to the lattice muscle receiving groove 115, 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, and accordingly In the bottom plate, a long span can be implemented in the form of a movable bar, a formwork and a non-backing method, and a heavy load can be borne.

According to an embodiment of the present invention, by minimizing the amount of concrete poured into the bone deck plate, the self-weight can be greatly reduced, and the thickness of the steel sheet can be significantly reduced compared to the existing bone deck plate, and accordingly, compared to the existing reinforced truss deck plate. By drastically reducing the amount of reinforcing bars, the average floor construction cost can be reduced by more than 20%.

According to an embodiment of the present invention, by implementing a one-way floor structure system capable of omitting the use of a right angle girder and a beam, it is possible to simplify the process and shorten the air.

According to the embodiment of the present invention, it is possible to construct a long spanned copperless bar and a barless reinforcement of more than 8m beyond the limitations of the existing 250mm copper bar formwork deck plate.

According to an embodiment of the present invention, it is possible to increase the total floor area of the building by about 10% in response to the floor height reduction effect in which the thickness of the floor plate is reduced compared to the existing floor plate.

According to an embodiment of the present invention, it is possible to improve the economic efficiency for the composite floor plate, such as long span, reduced self-weight, reduced cross-section, it is possible to improve the economy and safety of the slab system.

The above description of the present invention is for illustration only, and a person having ordinary knowledge in the technical field to which the present invention pertains can understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope of the present invention is indicated by the following claims rather than the above detailed description, and it should be interpreted that all changes or modified forms derived from the meaning and scope of the claims and equivalent concepts thereof are included in the scope of the present invention. do.

100: synthetic deck plate
110: deck plate unit unit
120: upper reinforcement
130: lower reinforcement
140: Lattice root
150: horizontal reinforcement hardware
111: bottom plate
112: lower bend
114: upper bend
115: Lattice muscle accommodating home
116: top plate
116: top plate connection
141: Lattice muscle lower part
142: Lattice muscle bend
143: upper end of the lattice muscle

Claims (13)

As a corrugated deck plate, a unit unit consisting of an upper plate 116, a lower plate 111, and both side plates is repeatedly formed in the transverse direction, and is continuously connected to each other in the transverse direction by a fastening device. A deck plate unit unit 110 in which a lattice muscle receiving groove 115 bent at both ends of the flat plate-shaped upper plate 116 is formed;
An upper reinforcing bar 120 disposed in an upper portion of the deck plate unit unit 110 and extending in a longitudinal direction;
A lower reinforcing bar 130 disposed in a lower portion of the deck plate unit unit 110 and extending in a longitudinal direction;
The upper reinforcing bar 120 and the lower reinforcing bar 130 are combined with each other to form a steel wire truss structure, and the upper end portion 143 is bent and attached horizontally to be accommodated in the lattice-receiving groove 115, along the longitudinal direction. Z-shaped lattice muscle 140 arranged in a zigzag shape (Z-type); And
The deck plate unit unit 110 is arranged to be spaced apart at predetermined intervals in a longitudinal direction of the upper plate 116 of the deck plate unit unit 110 to prevent the spreading and to improve the bending rigidity, and to the upper plate 116 It includes a horizontal reinforcement hardware 150 that is continuously arranged in the transverse direction,
The upper end portion 143 of the lattice muscle 140 forming the steel wire truss structure is attached to the lattice muscle receiving groove 115 of the deck plate unit unit 110, and the lower end portion 141 of the Z-shaped lattice muscle 140 ) 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,
The deck plate unit unit 110 is a lower plate 111, a lower bent portion 112, an upper bent portion 114, a lattice muscle receiving groove 115, and an upper plate 116 that are bent by a pressing method, respectively. ) And the upper plate connecting portion 117, the upper plate 116 formed in the form of a horizontal plate is bent at both ends in the lateral direction to form the lattice muscle receiving groove 115,
The upper end of the Z-shaped lattice muscle 140 and the upper reinforcing bar 120 so that the horizontal reinforcing hardware 150 can be continuously disposed on the upper surface of the deck plate unit unit 110 is the deck plate unit unit 110 Z-type steel wire lattice muscle attached synthetic deck plate, characterized in that disposed below the upper plate (116). delete According to claim 1,
The Z-shaped lattice muscle 140 is composed of a lattice muscle lower end portion 141, a lattice muscle bending portion 142, and a lattice muscle upper end portion 143, characterized in that it is arranged in a zigzag form along the longitudinal direction of the synthetic deck plate. Z-shaped steel wire lattice muscle attached synthetic deck plate. According to claim 3,
The upper reinforcing bar 120 is welded to the upper portion of the bent portion 142 of the Z-shaped lattice muscle 140, and the lower reinforcing bar 130 is located below the bending portion 142 of the Z-shaped lattice muscle 140. Z-shaped steel wire lattice muscle attachment type synthetic deck plate characterized by being welded and joined. According to claim 3,
The lower end portion of the lattice muscle 141 is bent horizontally so as to extend in a lateral direction by a predetermined length to secure the reinforcing bar thickness, and is characterized in that it is welded to the lower plate 111 of the deck plate unit unit 110. Z-type steel wire lattice muscle attached synthetic deck plate. According to claim 3,
The lattice muscle bent portion 142 of the Z-shaped lattice muscle 140 is formed to be inclined along the longitudinal direction of the synthetic deck plate, and the Z-shaped steel wire lattice muscle is characterized in that the sloping shape is repeatedly formed in a zigzag form as a whole. Attachable synthetic deck plate. According to claim 3,
The Z-shaped lattice muscle 140 is composed of cross-sectional muscles arranged in a zigzag shape, and the upper end of the cross-sectional muscle is bent to ensure a covering thickness, and the upper reinforcement ( 120) Z-shaped steel wire lattice muscle attachment type synthetic deck plate, characterized in that a coating thickness of about 20 mm is secured by arranging. delete a) As a corrugated deck plate, a unit unit consisting of an upper plate 116, a lower plate 111, and both side plates is repeatedly formed in the transverse direction, and is continuously connected to each other in the transverse direction by a fastening device. , Forming a deck plate unit unit 110 in which the lattice muscle receiving groove 115 bent at both ends of the horizontal plate-shaped upper plate 116 is formed;
b) forming a Z-shaped lattice muscle 140 in which the upper end portion 143 and the lower end portion 141 are bent;
c) a steel wire truss structure by welding-bonding an upper reinforcing bar 120 to an upper portion of the bent portion 142 of the Z-type lattice muscle, and welding a lower reinforcing bar 130 to a lower portion of the bending portion 142 of the Z-type lattice muscle. Forming a;
d) disposing the steel wire truss structure in the longitudinal direction and attaching the Z-shaped lattice muscle upper end portion 143 to the lattice muscle receiving groove 115 of the deck plate unit unit 110;
e) fixing the coupling plates to both ends of the deck plate unit unit 110 and connecting the deck plate unit unit 110 in the width direction; And
f) After the deck plate unit unit 110 is coupled to the horizontal reinforcing hardware 150 continuously arranged in the transverse direction to the upper plate 116 at predetermined intervals in the longitudinal direction, concrete is post-poured to form a Z-shaped lattice Comprising the step of completing the muscle-attached synthetic deck plate,
The upper end 143 of the lattice muscle 140 forming the steel wire truss structure is bent and is horizontally attached to be accommodated in the lattice muscle receiving groove 115 of the deck plate unit unit 110, and the Z-shaped lattice muscle ( The lower end portion 141 of 140) 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,
The deck plate unit unit 110 of step a) is a lower plate 111, a lower bending portion 112, an upper bending portion 114, a lattice muscle receiving groove 115, each of which is bent in a pressing manner, It consists of the top plate 116 and the top plate connecting portion 117, the top plate 116 formed in the form of a horizontal plate is bent at both ends in the lateral direction to form the lattice muscle receiving groove 115,
In step f), the upper end of the Z-shaped lattice muscle 140 and the upper reinforcing bar 120 so that the horizontal reinforcing hardware 150 may be continuously disposed on the upper surface of the deck plate unit unit 110 is the deck plate unit. A method of manufacturing a Z-shaped steel wire lattice muscle attached composite deck plate, which is disposed below the top plate 116 of the unit 110. delete delete delete delete

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