KR20190032893A - Composite Deck with Lattice Reinforcement and Steel Plate, and Manufacturing Method thereof - Google Patents

Abstract

The present invention relates to a lattice reinforcement rebar assembly-corrugated plate composite deck having a camber matching structure by a camber adjustment coupling member, and a manufacturing method thereof. According to the present invention, even if an upward camber of the corrugated plate is different from an upward camber of the lattice reinforcement rebar assembly, the upward camber of the corrugated plate is automatically adjusted to be fit to the upward camber of the lattice reinforcement rebar assembly when the lattice reinforcement rebar assembly and the corrugated plate are integrally coupled to each other, and thus the lower surface of a slab is able to stably maintain an original designed shape and linear shape without being downwardly convex or being an uneven shape when the slab is constructed by depositing concrete on the upper surface of the corrugated plate after the composite deck is installed in a site. According to the present invention, the composite deck comprises a camber adjustment intermediate connection member including a horizontal member, a vertical member, and a coupling part.

Description

Technical Field [0001] The present invention relates to a composite deck having a camber matching structure and a method of manufacturing the same,

The present invention relates to a lattice reinforcement reinforced assembly (Lattice Reinforcement) and a steel plate composed of a steel plate having a bent section, which is a composite deck of a "lattice reinforcing steel assembly-corrugated plate" Concretely, when constructing a composite deck by integrally joining a lattice reinforcing steel assembly and a corrugated plate made of a steel plate having a bent section, the lattice reinforcing steel assembly and the corrugated plates are provided with upward camber lattice reinforcement with a camber conforming structure that allows the slab to be constructed in a designed linear manner when the slab is constructed using a composite deck in situ by combining the lattice rebar assembly and the corrugated plate with the " camber " Reinforced steel assembly-corrugated plate composite deck and method of making same ".

In building a building such as a building, a "synthetic deck" constituted by arranging a reinforcing steel assembly on a plate of a steel material is installed, and concrete is laid on the composite deck at a predetermined thickness so that the reinforcing steel assembly is embedded in the concrete. Is proposed. As an example of such a conventional technique, Korean Patent Laid-Open Publication No. 10-2016-0145261 discloses a composite deck having a reinforcing assembly disposed in a concave portion, that is, a concave portion, in a curved steel plate.

The steel plate has a curved shape in which recesses are formed when viewed in the longitudinal direction, wherein a plurality of recesses are formed in the lateral direction with a gap therebetween, and an intermediate portion having a flat surface is present between the adjacent recesses. The concave portion and the intermediate portion are elongated in the longitudinal direction over the entire steel plate. For the sake of convenience, in the present specification, a steel plate having such a concave portion and a flat middle portion is called a "corrugated plate ".

The reinforcing bar assembly used for making the composite deck is composed of a plurality of longitudinal reinforcing bars extending in the longitudinal direction and arranged in parallel and a lattice member connecting the longitudinal reinforcing bars in a lattice pattern. For the sake of convenience, in the present specification, the steel reinforcing assembly used for making such a synthetic deck is called "a lattice reinforcing steel assembly ". In the case of the rebar assembly disclosed in Korean Patent Laid-Open Publication No. 10-2016-0145261, there are two phase currents, one subordinate current, and a grid member so that the cross section of the reinforcing bar assembly in the elongated direction, And when arranged in the concave portion of the corrugated plate, the bottom edge is located at the lower side and is arranged so as to have an inverted triangular cross section when viewed in the longitudinal direction.

In the prior art, a method of providing a foot support on the upper surface of the concave portion of the corrugated plate and disposing a lattice reinforcing steel assembly thereon when fabricating the composite deck is proposed. However, in this conventional technique, there is no consideration for "camber matching " which makes the camber of the lattice-reinforced steel assembly and the upward camber of the corrugated plate equal to each other.

For this purpose, it is desirable to increase the longitudinal span of the synthetic deck for space utilization of buildings, etc. To this end, the lattice rebar assembly is moved upward in the longitudinal direction so that the central portion of the longitudinal span of the lattice- Is imparted to the lattice rebar assembly. Upward camber may be provided to the corrugated plate, but the upward camber provided to the lattice-reinforced steel assembly due to errors in manufacturing and machining, transportation and storage, It is very difficult.

 The lattice rebar assembly has a large flexural stiffness, whereas the corrugated plate has a relatively smaller flexural stiffness than the lattice rebar assembly, so that the upward camber initially provided is reduced during transport, storage, etc., When combining the lattice rebar assembly, the lattice rebar assembly and the corrugated plate exhibit significant camber differences.

Although the upward camber of each of the lattice-reinforced steel assembly and the corrugated plate is different from each other and has an error, in the prior art, the lattice-reinforced steel frame assembly and the corrugated plate are formed on the corrugated plate The gap between the lattice rebar assembly and the corrugated plate may become uneven and irregular due to the difference in camber because the slab is constructed by placing the lattice rebar assembly on concrete.

In particular, in the case of the prior art, the lattice rebar assembly is simply a member to be placed on the top surface, the lattice rebar assembly acts as a "vertical load" against the corrugated plate, and after the installation of the lattice rebar assembly, When the concrete is poured, the corrugated plate is sagged downward due to the vertical load acting on the upper surface, and the interval between the lattice reinforcing steel assembly and the corrugated plate becomes excessively wide. As a result, the fact that the upward camber is applied to the corrugated plate is substantially ineffective and the difference (error) between the upward camber of the corrugated plate and the upward camber of the lattice-reinforced steel assembly becomes greater, The slab can not maintain the designed linearity in the beginning, and the slab is formed in a convex shape or a rugged shape in the downward direction. However, in the prior art, only the disposition of the lattice reinforcing steel assembly on the corrugated plate has been dispensed with, and no consideration is given to the problem caused by the above-described load action.

Korean Patent Publication No. 10-2016-0145261 (published on December 20, 2016).

The present invention has been developed in order to overcome the limitations of the prior art as described above, and it is an object of the present invention to construct a synthetic deck by integrally combining a lattice reinforcing steel assembly and a corrugated plate, wherein an upper camber and a lattice reinforcing steel assembly By making the upward camber of the corrugated plate automatically match and align with the upward camber of the lattice rebar assembly in the process of integrally combining the lattice rebar assembly and the corrugated plate, even if the upward camber is different from each other, The lower surface of the slab does not become convex or rugged when the concrete is laid on the upper surface of the corrugated plate and the slab is formed so as to be able to stably maintain the shape and linearity originally designed, How to make it The purpose is to provide.

In order to achieve the above object, according to the present invention, a plurality of concave portions extending in the longitudinal direction are formed in parallel to each other with a lateral gap therebetween, a middle portion of a flat surface between adjacent concave portions, A plate; A lattice rebar assembly having an upward camber, the lattice member comprising a longitudinally extending rod member connecting two phase currents and a bottom current, arranged in an inverted triangle, and a top current and bottom current; Wherein the lattice rebar assembly is disposed within each recess such that there is a gap between the bottom of the lattice rebar assembly and the top surface of the recess; The camber adjusting intermediate linking members are laterally arranged so as to face the middle portion of the corrugated plate between the upper ends of the adjacent lattice rebar assemblies disposed in the recesses so that the transversely opposite ends of the camber adjusting intermediate linking members are aligned with the lattice- And the camber adjusting intermediate linking member and the cam plate adjusting intermediate linking member are brought into close contact with each other or the gap between the middle portion of the corrugating plate and the camber adjusting intermediate linking member is minimized, So that the corrugated plate and the lattice rebar assembly are coupled with the same upward camber, with the upward camber of the corrugated plate aligned with the upward camber of the lattice rebar assembly.

The present invention also provides a method of fabricating such a composite deck, comprising: disposing a lattice rebar assembly in each recess such that there is a gap between the bottom of the lattice rebar assembly and the bottom of the recess; The camber adjusting intermediate linking member is laterally disposed so as to face the middle portion of the corrugated plate between the upper ends of the adjacent lattice rebar assemblies disposed in the recesses so that both ends of the camber adjusting intermediate linking member are positioned on the upper side of the lattice- To be coupled with the first connector And engaging and fixing the camber adjusting intermediate coupling member and the corrugated plate with the intermediate portion of the corrugated plate and the camber adjusting intermediate coupling member in close contact with each other or with the interval between the middle portion of the corrugated plate and the camber adjusting intermediate coupling member being minimized , The upward camber of the corrugated plate is aligned with the upward camber of the lattice rebar assembly to produce a composite deck in which the corrugated plate and the lattice rebar assembly are joined together with the same upward camber / RTI >

According to the present invention, when the synthetic deck is constructed by integrally joining the lattice reinforcing steel assembly and the corrugated plate, even if the upward camber of the corrugated plate and the upward camber of the lattice reinforcing steel assembly are different from each other, And the corrugated plate are automatically adjusted so that the upward camber of the corrugated plate is aligned with the upward camber of the lattice rebar assembly.

Therefore, when the composite deck completed in accordance with the present invention is installed on the site and the concrete is laid on the upper surface of the corrugated plate, when the slab is installed, the lower surface of the slab does not become convex downward or rugged, The linearity can be maintained stably.

Particularly, in the present invention, since the corrugated plate is firmly integrated with the lattice reinforcing steel assembly by the camber adjusting intermediate joint in the process of adjusting the upward camber of the corrugated plate to fit the upward camber of the lattice reinforcing steel assembly, When the slab is constructed using the deck, the corrugated plate has the additional advantage of being able to exhibit sufficient resistance to the pouring load of the concrete.

1 is a schematic perspective view of a lattice rebar assembly provided in the present invention.
Figure 2 is a schematic lateral side view of the lattice rebar assembly shown in Figure 1;
3 is a schematic perspective view of a corrugated plate provided in the present invention.
4 is a schematic perspective view showing a state in which a lattice-reinforced steel assembly according to the present invention is disposed in a concave portion of a corrugated plate;
Figure 5 is a schematic perspective view showing a state in which a camber adjusting intermediate linkage is installed between laterally adjacent lattice rebar assemblies with the lattice rebar assembly disposed in the recesses of the corrugated plate;
Figure 6 is a schematic longitudinal cross-sectional view at line AA position of Figure 5 corresponding to the longitudinal end position of the lattice rebar assembly.
7 is a schematic longitudinal cross-sectional view at line BB of Fig.
FIG. 8 is a schematic perspective view corresponding to FIG. 4 showing another embodiment of the present invention in which the stationary member is composed of an English letter M-shaped reinforcing bar.
FIG. 9 is a schematic perspective view corresponding to FIG. 4 showing the state in which the lattice rebar assembly shown in FIG. 8 is positioned in the recess.
Figure 10 is a schematic longitudinal cross-sectional view corresponding to Figure 6 showing the longitudinal end configuration of the lattice rebar assembly in the embodiment shown in Figure 9;
Figure 11 is a schematic longitudinal cross-sectional view corresponding to Figure 6 showing the longitudinal end configuration of the lattice rebar assembly with the lattice rebar assembly positioned within the recess using a spacer member as a further embodiment of the present invention .
12 and 13 are schematic perspective views of the first and second embodiments of the camber adjusting intermediate connector according to the present invention, respectively.
14 is a schematic longitudinal sectional view at the position of line CC in Fig. 5 corresponding to the position where the camber adjusting intermediate linkage is installed.
15 is a schematic perspective view showing a state in which the composite deck of the present invention is completed by the installation of the camber adjusting intermediate coupling member and the completion of the coupling of the camber adjusting intermediate coupling member and the corrugated plate.
16 is a schematic longitudinal sectional view at the line DD position in Fig. 15 corresponding to the position where the camber adjusting intermediate link member is installed.
17 is a schematic perspective view showing a state in which a concrete is inserted into a composite deck of the present invention to complete a slab.
18 and 19 are schematic longitudinal views corresponding to FIG. 16 showing a state in which the camber-adjusting reinforcing bar assembly and the upward camber of the corrugated plate are aligned with each other using the camber adjusting intermediate connector according to the third and fourth embodiments of the present invention, Sectional view.
Figure 20 is a corresponding schematic perspective view showing that a lattice rebar assembly with a staging member is also disposed in the recess of the corrugated plate at the longitudinal midpoint;
Figs. 21 and 22 are schematic longitudinal sectional views at the line FF position in Fig. 20, respectively.
23 is a schematic perspective view showing a state in which the composite deck of the present invention is completed by the installation and engagement of the camber adjusting intermediate link member and the vertical intermediate point mounting member.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Although the present invention has been described with reference to the embodiments shown in the drawings, it is to be understood that the technical idea of the present invention and its essential structure and operation are not limited thereby.

The lattice reinforcing steel assembly-corrugated plate composite deck 100 according to the present invention (hereinafter abbreviated as "synthetic deck" of the present invention) comprises a corrugated plate 2 having a concave portion 20, And the lattice rebar assembly 1 is integrally joined. FIG. 1 shows a schematic perspective view of a lattice-reinforced steel assembly 1 provided in the composite deck 100 of the present invention. In the embodiment according to the present invention shown in the drawing, the lattice-reinforced steel assembly 1 includes two phase currents 11 composed of rod members elongated in the longitudinal direction (the direction of the arrow XX in FIG. 1) And a grid member 13 connecting the upper current 11 and the lower current 12 in the form of a lattice to the lower current 12 which is located below the current 11 and is made of a rod member elongated in the longitudinal direction consist of. Figure 2 shows a schematic lateral side view of the lattice rebar assembly 1 shown in Figure 1, wherein the dashed line in Figure 2 represents a straight line. As shown in FIG. 2, when the lattice reinforcing steel assembly 1 is viewed from the side in the lateral direction, the upper and lower ends 11 and 12 are curved in a convex shape so as to have an "upward camber" do.

3 is a schematic perspective view of the corrugated plate 2 according to the present invention. As shown in the figure, the corrugated plate 2 has a recessed portion 20 recessed downward in a longitudinal direction And is a plate member made of a steel material. A plurality of recesses 20 are formed in the corrugated plate 2 so as to be spaced apart from one another in the transverse direction. Therefore, the intermediate portion 21 is present between the adjacent recesses 20. The intermediate portion 21 may be a flat surface.

Although not shown in the drawings, the corrugated plate 2 may also have an "upward camber" like the lattice rebar assembly 1, if desired. Of course, the corrugated plate 2 may not have an upward camber at all, in which case the corrugated plate 2 may have an upward camber of zero and the corrugated plate 2 may have a downwardly curved shape , It can be said that it has a minus (-) upward camber.

4 is a schematic perspective view showing a state in which a lattice rebar assembly 1 according to the present invention is disposed in a concave portion 20 of a corrugated plate 2 and in FIG 5 is shown a lattice rebar assembly 1 Is provided between the laterally neighboring lattice-reinforcing steel reinforcing assemblies 1 in a state where the camber-adjusting intermediate connecting member 3 is disposed in the concave portion 20 of the corrugated plate 2 is shown in a schematic perspective view . 6 shows a schematic longitudinal cross-sectional view at line AA position of FIG. 5, corresponding to the longitudinal end position of the lattice rebar assembly 1, and FIG. 7 illustrates a longitudinal cross-sectional view of the lattice rebar assembly 1, There is shown a schematic longitudinal cross-sectional view at line BB position of FIG. 5 corresponding to the midpoint of the direction. Means not only the longitudinal center of the lattice rebar assembly 1, but also any point between the longitudinal ends of the lattice rebar assembly 1.

  The lattice reinforcing steel assembly 1 is manufactured in advance and then lifted by a lifting device such as a crane for the production of the synthetic deck 100 and placed in the concave portion 20 of the corrugated plate 2. [ At this time, as illustrated in the figure, the concave portion 20 is formed so that the lower current 12 of the lattice-reinforced steel assembly 1 is located at the lower side, that is, the inverted triangular longitudinal shape of the lattice- As shown in Fig. However, when the lattice-reinforced steel assembly 1 is placed in the concave portion 20 of the corrugated plate 2, the longitudinal direction of the lattice-reinforced steel assembly 1 is positioned in the downward direction as illustrated in the figure, It does not have to be a triangle.

When fabricating the composite deck using the lattice reinforcing steel assembly 1 and the corrugated plate 2, when the lower portion of the lattice reinforcing steel assembly 1 is located in the concave portion 20, It is important to secure a sufficient space between the bottom surface 12 and the top surface of the concave portion 20 for covering the reinforcing steel.

4 to 7, the lattice-reinforcing steel assembly 1 is installed in the concave portion 20 in a state where the lattice-reinforcing steel assembly 1 is assembled in advance at both longitudinal ends of the lattice- The lattice reinforcing bar assembly 1 is positioned in such a manner that there is a gap between the bottom current 12 and the bottom top surface of the concave portion 20 by positioning the mounting member 6 to be supported on the upper surface of the corrugated plate 2 Is disposed in the concave portion 20. That is to say that the lattice reinforcement assembly 1 is preliminarily assembled with the lattice member 6 and the lattice reinforcement 6 is placed on the corrugated plate 2 such that the lattice member 6 transversely crosses over the concave portion 20, When the reinforcing bar assembly 1 is inserted into the concave portion 20, the lattice reinforcing bar assembly 1 is automatically inserted into the concave portion 20 in the form of a gap between the bottom plate 12 and the bottom surface of the concave portion 20 (20). Therefore, the arrangement work of the lattice rebar assembly 1 can be performed very easily and quickly.

In the above embodiment, the stationary member 6 includes a transverse extending member 60 which transversely intersects the concave portion 20, 11, respectively. Each of the two phase currents 11 provided in the lattice-reinforced steel assembly 1 is bound to the binding member 61 so that the mounting member 6 is assembled in advance at both longitudinal ends of the lattice- do. The transversely opposite ends of the transverse extending member 60 are placed on the upper surface of the intermediate portion 21 located on both sides of the concave portion 20 so that the mounting member 6 transversely crosses over the concave portion 20 The latticed reinforcing bar assembly 1 is disposed in the concave portion 20 in such a manner that there is a gap between the bottom surface 12 of the concave portion 20 and the bottom surface of the concave portion 20. That is, the lattice reinforcing steel assembly 1 is positioned in the concave portion 20 in a state of being suspended from the stationary member 6. In this state, the through-hole fastening member 63 such as a bolt is passed through both lateral ends of the transverse extending member 60 and the intermediate portion 21 of the corrugated plate 2, (6) may be securely coupled to the corrugated plate (2).

In the embodiment shown in Fig. 6, the binding member 61 provided on the mounting member 6 is formed in a ring shape with its lateral side opened, so that the upper current 11 is fitted in the annular part, 6 and the phase current 11 are coupled to each other. In the case of the mounting member 6 having the ring-shaped binding member 61, the mounting member 6 can be assembled to the lattice-reinforcing steel assembly 1 very quickly and conveniently. However, the shape and structure of the binding member 61 of the mounting member 6 are not limited to such an annular shape.

Fig. 8 is a schematic view showing a schematic configuration of the lattice-rebar assembly 1 at the longitudinal end position of the lattice-rebar assembly 1 corresponding to Fig. 6 for the embodiment of the present invention using another mounting member 6 whose shape of the binding member 61 is changed. Directional cross-sectional view is shown. As illustrated in Fig. 8, the binding member 61 of the fixing member 6 is made up of a letter U-shaped member that is opened upward, so that the image 11 is placed on the U-shaped portion, The upper current 11 may be bound to the binding member 61 and thus the mounting member 6 may be preassembled to the lattice-reinforcing steel assembly 1, by intercepting the open-shaped portion. Although not shown in the drawings, when the upper current 11 is bound to the U-shaped binding member 61 as described above, the upper current 11 is placed on the U- The upper current 11 can be fastened to the binding member 61 by using a linear binding means.

In the present invention, the mounting member 6 itself may be deformed into another shape. 9 is a schematic perspective view corresponding to FIG. 4 showing a state in which a lattice-reinforced steel assembly with a mounting member composed of an M-shaped reinforcing bars is located in a recess, according to another embodiment of the present invention , Fig. 10 is a schematic view corresponding to Fig. 6 showing the longitudinal end configuration of the lattice rebar assembly 1 in a state after the lattice rebar assembly 1 of the embodiment shown in Fig. 9 is located in the recess 20 A longitudinal cross-sectional view is shown. As shown in Figs. 9 and 10, the mounting member 6 is made of an alphabet letter M-shaped reinforcing bar so that the lower case 12 is placed in the center concave portion in the M- And the mounting member 6 is coupled to the lattice reinforcing steel assembly 1 and the M-shaped edge of the mounting member 6 is placed on the upper surface of the intermediate portion 21 so that the mounting member 6 is placed in the recess 20 in the lateral direction It can be installed across.

The method of disposing the latticed reinforcing bar assembly 1 in the concave portion 20 so that the lower current 12 is directly spaced from the bottom surface of the concave portion 20 in the present invention is not limited to the above- But is not limited to the use of the mounting member 6 as in the embodiment. 11 shows another embodiment of the present invention in which the spacer member 7 is used to position the lattice rebar assembly 1 in the longitudinal end of the lattice rebar assembly 1 with the lattice rebar assembly 1 positioned in the recess 20 Which corresponds to FIG. 6, showing a cross-sectional view taken along line AA 'of FIG. 11, by arranging the spacer member 7 on the upper surface of the bottom of the concave portion 20 and placing the lower current 12 of the lattice-reinforced steel assembly 1 on the spacer member 7, The reinforcing steel assembly 1 can be placed in the concave portion 20 in a floating form on the bottom surface of the concave portion 20. [

When the lattice reinforcing bar assembly 1 is disposed in the concave portion 20 using the abovementioned mounting member 6 or the spacer member 7, the mounting member 6 and the spacer member 7 are necessarily reinforced by the lattice It is not always necessary to install them on the longitudinally opposite ends of the reinforcing bar assembly 1. If the lattice-reinforced steel assembly 1 can be placed in the concave portion 20 in such a form that the lower current 12 directly contacts the bottom surface of the concave portion 20 and is spaced apart, the lattice-reinforced steel assembly 1 The mounting member 6 or the spacer member 7 may be provided at an arbitrary intermediate point in the longitudinal direction of the lattice-reinforced steel frame assembly 1 other than the longitudinally opposite ends of the lattice-reinforced steel frame assembly 1. It is also possible to provide a plurality of such mounting members 6 or the spacer members 7 in a plurality of three or more. The mounting member 6 provided at the longitudinal intermediate point of the lattice-reinforced steel assembly 1 is fixed to the lattice-reinforced steel assembly 1 and the corrugated plate (not shown) in the longitudinal direction in which the concave portion 20 is formed, 2) to be coincident with each other.

12 and 13 show a schematic perspective view of the first and second embodiments of the camber adjusting intermediate connector 3 according to the present invention. FIG. 14 shows a camber adjusting intermediate connector 3 3 in the position of the line CC of Fig. 5 corresponding to the position in which it is installed.

After the lattice rebar assembly 1 is placed in the recess 20 or the lattice rebar assembly 1 is placed in the recess 20 as described above, Of the lattice-reinforced steel frame assembly 1 are disposed between the upper ends 11 of the lattice-reinforced steel frame assembly 1 disposed adjacent to each other in the transverse direction. The camber adjusting intermediate linking member 3 according to the first and second embodiments shown in Figs. 12 to 14 includes a horizontal member 31 extending in the transverse direction, and a vertical member 31 extending vertically from both ends of the horizontal member 31 And the upper end of the vertical member 32 is provided with a fastening portion 33 which is engaged with the upper end 11 of the lattice-reinforced steel assembly 1, respectively. Particularly, in the first and second embodiments of the camber adjusting intermediate coupling member 3 shown in Figs. 12 to 14, the fastening portions 33 are formed in an annular shape bent upward and downward, And the upper portion 11 is fastened to the fastening portion 33 in a form in which the upper portion 11 and the upper portion 11 are engaged with each other. However, as will be described later, the shape and structure of the coupling portion 33 of the camber adjusting intermediate coupling member 3, and furthermore, the overall shape of the camber adjusting intermediate coupling member 3 are not limited thereto but may be modified.

A through hole 36 may be formed in the horizontal member 31. The through hole 36 may be a long hole extending in the transverse direction. When the through hole 36 is formed in the elongated hole, the penetration fastening means 35 is provided when the intermediate portion 21 and the horizontal member 31 of the corrugated plate 2 are fixed by the penetration fastening means 35, So that it is possible to flexibly cope with the positional change of the position. The plurality of through holes 36 may be formed. Furthermore, if necessary, a reinforcing rib 34 extending in the transverse direction for reinforcing the horizontal member 31 may be provided on the horizontal member 31. [

The camber adjusting intermediate linking member 3 having the above configuration is provided between the lattice-reinforcing steel assembly 1 disposed adjacent to each other in the transverse direction. The camber adjusting intermediate linking member 3 has the camber adjusting intermediate linking member 3, The camber adjusting intermediate linking member 3 is provided so that the upper ends of the vertical members 32 provided at both ends of the camber adjusting intermediate linking member 3 are fastened to the upper end 11, Facing the intermediate portion 21 of the corrugated plate 2 existing between adjacent lattice-reinforced steel assemblies 1.

The camber adjusting intermediate linking member 3 can be installed at a plurality of points in the longitudinal direction. As described above, the corrugated plate 2 is provided with a plurality of concave portions 20 arranged in a lateral direction, and each of the concave portions 20 is provided with the lattice-reinforced steel assembly 1 in the above-described manner. Each of the lattice rebar assemblies 1 disposed in each of the plurality of recesses 20 is referred to as a " first column lattice rebar assembly ", "second column lattice rebar assembly ", and" third column lattice rebar assembly Quot ;, the camber adjusting intermediate connector is disposed at a plurality of longitudinal positions between the adjacent phase currents in the first thermal lattice rebar assembly and the second thermal lattice rebar assembly, The camber adjusting intermediate link member is disposed at a plurality of points between the upper and the lower side in the rebar assembly and the third thermal lattice rebar assembly. At this time, the position of the camber adjusting intermediate connector disposed between the first column lattice rebar assembly and the second column lattice rebar assembly, and the position of the camber adjusting intermediate member located between the second column lattice rebar assembly and the third column lattice rebar assembly, The positions of the adjusting intermediate connectors may not necessarily be the same as each other, and it may be more preferable that they deviate from each other.

After the camber adjusting intermediate linking member 3 is installed between adjacent lattice reinforcing steel assemblies in the manner described above, the horizontal member 31 of the camber adjusting intermediate linking member 3 and the middle portion of the corrugated plate 2 facing it The composite deck 100 in which the lattice-reinforced steel assembly 1 and the corrugated plate 2 are combined is completed. 15 shows a schematic perspective view showing a state in which the composite deck of the present invention is completed by the installation of the camber adjusting intermediate linking member 3 and the completion of the engagement of the camber adjusting intermediate linking member 3 and the corrugated plate 2, 16 is a schematic vertical cross-sectional view taken along the line DD of Fig. 15 corresponding to the position where the camber adjusting intermediate link member 3 is provided, that is, following the state of Fig. 14, the horizontal member 31 And the intermediate portion 21 are in close contact with each other, are shown in a schematic vertical sectional view corresponding to Fig. FIG. 17 is a schematic perspective view showing a state in which concrete is placed in the composite deck 100 of the present invention to complete the slab 200. FIG. The dotted line in FIG. 16 shows the position of the corrugated plate 2 in FIG. 14, that is, the position of the corrugated plate 2 where the upward camber is not yet aligned with the upward camber of the lattice-reinforced steel assembly 1.

As previously mentioned, in order to extend the longitudinal span of the composite deck as much as possible, each of the lattice-reinforced steel assembly 1 and the corrugated plate 2 is designed so that the longitudinal span center portion rises upward, There is an upward convex camber. However, the lattice-reinforced steel assembly and the corrugated plate are separately manufactured and manufactured. Due to the errors occurring in the manufacturing, storage, and transporting processes, the upward camber of the lattice-reinforced steel assembly 1 and the upward camber of the corrugated plate 2, May be different from each other. Therefore, in the initial state in which the camber adjusting intermediate link member 3 is disposed so that the horizontal member 31 of the camber adjusting intermediate member 3 faces the intermediate portion 21 of the corrugated plate 2, A gap may be present between the member 31 and the intermediate portion 21. [

16, the horizontal member 31 of the camber adjusting intermediate linking member 3 and the upper surface of the intermediate portion 21 of the corrugated plate 2 are separated from each other, The interval between the horizontal member 31 of the camber adjusting intermediate linking member 3 and the intermediate portion 21 of the corrugated plate 2 is minimized So that the horizontal member 31 of the camber adjusting intermediate coupling member 3 and the intermediate portion 21 of the corrugated plate 2 are engaged and fixed. A through-hole fastening structure can be used for fastening the horizontal member 31 of the camber adjusting intermediate coupling member 3 and the intermediate portion 21 of the corrugated plate 2 to each other. That is, since the through hole 36 is formed in the horizontal member 31 as in the embodiment shown in the drawing, the through hole 36 and the vertically opposed connecting portion 21 35 and the finishing fastening member 37 such as a nut is fastened and fixed to the through-fastening means 35 so that the intermediate member 31 of the camber adjusting intermediate linking member 3 and the intermediate member 31 of the corrugated plate 2 The camber adjusting intermediate coupling member 3 and the corrugated plate 2 are integrally joined to each other. The camber adjusting intermediate coupling member 3 is provided in a state in which the through-hole fastening means 35 is installed in advance from the lower side to the upper side in the middle portion 21 of the corrugated plate 2, The through-hole 36 of the camber-adjusting intermediate connection member 3 and the through-hole fastening member 35 projected to the upper surface of the camber adjusting intermediate member 3 may be connected to the through- The through hole 36 is inserted into the through hole 36 from the top to the bottom so that the through hole 36 is passed through the intermediate portion 21, (Not shown).

Since the lattice rebar assembly 1 has greater rigidity than the corrugated plate 2, when the upward camber of the lattice rebar assembly 1 is different from the upward camber of the corrugated plate 2, When the horizontal member 31 of the adjusting intermediate coupling member 3 and the intermediate portion 21 of the corrugated plate 2 are engaged and fixed, the corrugated plate 2 at the position indicated by the dotted line in FIG. And is pulled toward the rebar assembly 1. At this time, the intermediate portion 21 of the corrugated plate 2 is pulled to be completely brought into close contact with the horizontal member 31, or the interval therebetween is narrowed and minimized. That is, when the lattice-reinforced steel assembly 1 is placed on the concave portion 20 due to the fact that the lattice-reinforced steel assembly 1 and the corrugated plate 2 have different upward cambers, It is possible to prevent the camber adjusting intermediate coupling member 3 and the corrugated plate 2 from being assembled in the middle portion of the corrugated plate 2 in the process of assembling the camber adjusting intermediate member 3 and the corrugated plate 2, The wave plate 21 is automatically pulled in the direction of the horizontal member 31 of the camber adjusting intermediate link member 3 so that the corrugated plate 2 has the same upward camber as the lattice rebar assembly 1, The interval between the corrugated plate 1 and the corrugated plate 2 is minimized.

As such, the upward camber of the corrugated plate 2 and the upward camber of the lattice rebar assembly 1 are adjusted such that when the corrugated plate 2 and the lattice rebar assembly 1 have the same upward camber, When the composite deck of the invention is installed on the site and the concrete is laid on the upper surface of the corrugated plate 2 and the slab is installed, the lower surface of the slab does not become convex downward or rugged, So that it can be stably maintained.

The intermediate portion 21 of the corrugated plate 2 is pulled in the direction of the horizontal member 31 so that the vertical distance between the intermediate portion 21 and the horizontal member 31 no longer changes, The corrugated plate 2 is firmly integrated with the lattice rebar assembly 1 when the camber adjusting intermediate connection member 3 and the corrugated plate 2 are firmly coupled with each other in a state in which the corrugated plate 31 is completely in close contact. Therefore, in the process of constructing the slab using the composite deck 100 of the present invention, which is completed by integrally assembling the corrugated plate 2 and the lattice-reinforced steel assembly 1, the concrete pouring load acting on the corrugated plate 2, Is transmitted to the lattice-reinforcing steel assembly (1) through the camber adjusting intermediate joint member (3), and the corrugated plate (2) can exhibit sufficient resistance against the pouring load of the concrete.

In the case of the camber adjusting intermediate connector 3 according to the first and second embodiments shown in Figs. 12 to 14 described above, the fastening portion 33 provided at the upper end of the vertical member 32 has a ring shape bent from top to bottom So that an annular shape is formed on the top of the phase current 11. However, the configuration of the coupling portion 33 in the camber adjusting intermediate coupling member 3 is not limited to this. Figs. 18 and 19 show a state in which the upward camber of the lattice-reinforcing steel assembly 1 and the corrugated plate 2 are aligned with each other using the camber-adjusting intermediate link 3 according to the third and fourth embodiments, Corresponding schematic longitudinal cross-sectional views are shown. 18 and 19, the state before the intermediate portion 21 of the corrugated plate 2 is brought into close contact with the horizontal member 31 of the camber adjusting intermediate member 3 is not shown for convenience.

In the case of the camber regulating intermediate connector 3 according to the third embodiment shown in Fig. 18 and the camber regulating intermediate connector according to the fourth embodiment shown in Fig. 19 as well as the camber regulating intermediate connector according to the first and second embodiments described above, And includes a horizontal member 31 extending in the vertical direction and a vertical member 32 extending vertically and the upper end of the vertical member 32 is fastened to the upper end 11 of the lattice- And a fastening portion 33 is provided. 18, the engaging portion 33 of the camber adjusting intermediate link member 3 according to the third embodiment is opened laterally, like the engaging member 61 of the mounting member 6 shown in Fig. 6 So that the phase current 11 is fitted in the annular portion through the open portion of the fastening portion 33 and fastened to each other.

19, the shape and configuration of the fastening portion 33 are the same as those of the fastening member 61 of the mounting member 6 shown in Fig. 8, in the case of the camber adjusting intermediate link 3 according to the fourth embodiment shown in Fig. . That is, the fastening portion 33 is formed in a letter U-shape that is opened upward, and the upper end 11 is placed on the U-shaped portion and the U-shaped open portion is interrupted by the bolt, (33) is engaged with the current elevation (11). Other configurations and effects of the camber adjusting intermediate connector 3 according to the third and fourth embodiments shown in Figs. 18 and 19 are the same as those described previously with respect to the camber adjusting intermediate connector of the first and second embodiments do. As described above, the shape and configuration of the camber adjusting intermediate connector 3 and the shape and configuration of the fastening portion 33 in the present invention are variously varied within the range in which the action of the camber adjusting intermediate connector 3 is performed in the same manner It can be changed.

In the present invention, in addition to the use of the camber adjusting intermediate connector 3 in matching the camber of both members while coupling the lattice-reinforced steel assembly 1 with the corrugated plate 2, the lattice- It is also possible to use an additional mounting member 6 provided at a longitudinal intermediate point of the mounting member. 20 shows a state in which the lattice reinforcing bar assembly 1 is attached to the corrugated plate 2 in a state in which the stationary member 6 is further provided not only at the longitudinally opposite ends of the lattice reinforcing bar assembly 1 but also at the mid- There is shown a schematic perspective view showing that it is disposed in the recess 20. 21 and 22 show schematic longitudinal cross-sectional views, respectively, at the line FF position of FIG. 20 showing the mounting member 6 provided at the midpoint of the lattice rebar assembly 1, Fig. 22 shows a state in which the reinforcing bar assembly 1 is simply disposed in the concave portion 20. Fig. 22 shows a state in which the fixing member 6 at the intermediate point and the corrugated plate 2 The state in which the linearity of the corrugated plate 2 is changed to coincide with the upward camber of the lattice-reinforced steel assembly 1 is shown. In Fig. 22, the dotted line indicates the position of the corrugated plate 2 in Fig.

As described above, even if the upward camber of the lattice-reinforced steel assembly 1 and the upward camber of the corrugated plate 2 do not coincide with each other in the case of the mounting member 6 provided at both ends of the lattice-reinforced steel assembly 1, When the lattice reinforcing steel assembly 1 is inserted into the concave portion 20, the both ends of the mounting member 6 are placed on the upper surface of the intermediate portion 21, respectively. However, in the case of the mounting member 6 provided at the intermediate point of the lattice-reinforced steel assembly 1, the lattice-reinforced steel assembly 1 and the lattice-reinforced steel- Since the corrugated plates 2 have mutually different upward cambers, the lateral ends of the stationary member 6 may not touch the upper surface of the intermediate portion 21 as shown in Fig. That is, when the lattice-reinforced steel assembly 1 is inserted into the concave portion 20, there may be a gap between both ends of the intermediate member 6 and the intermediate portion 21 of the corrugated plate 2.

As shown in Fig. 22, in the state where both lateral ends of the intermediate position fixing member 6 are spaced apart from the upper face of the intermediate portion 21, both ends in the transverse direction of the fixing member 6 and the intermediate portion 21 are in close contact with each other Or at least the interval between the lateral ends of the mounting member 6 and the intermediate portion 21 is minimized so that the transverse ends of the mounting member 6 and the intermediate portion 21 are engaged and fixed do. This procedure causes the cambers of the lattice-reinforced steel assembly 1 and the corrugated plate 2 to coincide primarily with the lattice-reinforced steel assembly 1 and the additional Combining is done. Since the mounting member 6 provided at the intermediate point of the lattice-reinforcing steel assembly 1 in the figure has the transverse extending member 60, the transverse direction ends of the transverse extending member 60 and the intermediate portion 21 are in close contact with each other Or at least the interval between the transverse ends of the transverse extending member 60 and the intermediate portion 21 is minimized so as to be engaged and fixed. At this time, a through-hole fastening structure can be used. That is, as shown in the figure, the through-hole fastening member 63 such as a bolt is passed through the transversely opposite ends of the transverse extending member 60 and the intermediate portion 21, The fastening members 64 are fastened to each other so that the transversely opposite ends of the transverse extending member 60 and the upper surface of the intermediate portion 21 are brought close to each other to the greatest extent or are brought into close contact with each other.

The mounting member 6 previously provided at the longitudinal intermediate point of the lattice rebar assembly 1 is adjusted such that the upward camber of the corrugated plate 2 and the upward camber of the lattice rebar assembly 1 are aligned with each other And functions as a member for integrally joining the lattice reinforcing steel assembly 1 and the corrugated plate 2 so that the lattice reinforcing bar assembly 1 is also provided at the longitudinal intermediate point of the lattice- The lattice reinforcing bar assembly 1 is inserted into the concave portion 20 in a state where the lattice reinforcing bar assembly 1 is previously provided and the both ends of the intermediate point holding member 6 are brought into close contact with the wave plate 2 It is possible to achieve upward camber matching and additional coupling between the lattice-reinforced steel assembly 1 and the corrugated plate 2 along the longitudinal rows where the recesses 20 are formed. In addition to upward camber matching using the camber adjusting intermediate link 3, upward camber alignment using a mounting member 6 provided at the longitudinal midway point of the lattice rebar assembly 1 is added to the lattice rebar assembly 1) and the corrugated plate 2, and the integration between the two members is further enhanced.

The upward camber matching operation using the camber adjusting intermediate link member 3 and the upward camber matching operation using the mounting member 6 provided at the longitudinal intermediate point of the lattice reinforcing steel assembly 1 are performed first May be performed at the same time. Also, even if the mounting member 6 previously provided at the intermediate point is made of the embodiment shown in Fig. 8, the upward camber matching operation using the mounting member 6 can be performed. Fig. 23 is a schematic perspective view showing a state in which the composite deck of the present invention is completed by the installation and engagement of the camber adjusting intermediate linking member and the longitudinal intermediate stopping member.

1: Lattice rebar assembly
2: corrugated plate
3: Camber adjustment intermediate connector
6:
11: Award current
12: Lower current
20:
21: Middle part

Claims (7)

A corrugated plate (2) having a plurality of concave portions (20) formed in parallel with each other with a lateral gap therebetween and having an intermediate portion (21) between adjacent concave portions (20) and having an upward camber; A lattice rebar assembly (20) having an upward camber and a grid member (13) connecting the two phase currents (11) and one bottom current (12) 1); 1. A composite deck 100 integrally coupled,
A lattice rebar assembly 1 is disposed in each recess 20 such that there is a gap between the bottom end 12 of the lattice rebar assembly 1 and the bottom top of the recess 20;
The camber adjusting intermediate linking member 3 is arranged so as to face the intermediate portion 21 of the corrugated plate 2 between the upper ends 11 of the adjacent lattice rebar assembly 1 disposed in the recess 20 And the transversely opposite ends of the camber adjusting intermediate link 3 are fastened to the upper plate 11 of the lattice reinforcing steel assembly 1. The intermediate portion 21 of the corrugated plate 2 and the camber The camber adjusting intermediate linking member 3 and the corrugated plate (not shown) are arranged in a state in which the adjusting intermediate linking member 3 is in close contact with each other or the interval between the intermediate portion 21 of the corrugated plate 2 and the camber adjusting intermediate linking member 3 is minimized. 2 are engaged and fixed so that the upward camber of the corrugated plate 2 is aligned with the upward camber of the lattice rebar assembly 1 so that the corrugated plate 2 and the lattice rebar assembly 1 have the same upward camber Wherein the composite deck comprises:
The method according to claim 1,
The camber adjusting intermediate connecting member 3 includes a horizontal member 31 extending in the lateral direction, a vertical member 32 provided at both ends of the horizontal member 31, And a fastening portion (33) that is engaged with the top end (11) of the lattice rebar assembly (1);
A through hole 36 is formed in the horizontal member 31;
When the camber adjusting intermediate coupling member 3 is disposed, the horizontal member 31 faces the intermediate portion 21 of the corrugated plate 2;
The fastening member 37 is fastened to the fastening means 35 after the fastening means 35 passes through the intermediate portion 21 and the through hole 36 so that the intermediate portion 21 is fastened to the horizontal member 31, Or the interval between the intermediate portion (21) of the corrugated plate (2) and the camber adjusting intermediate linking member (3) is minimized.
3. The method according to claim 1 or 2,
At both longitudinal ends of the lattice-reinforced steel assembly 1, there are respectively provided a mounting member 6 disposed laterally across the recess 20;
When the latticed reinforcing bar assembly 1 is disposed in each of the concave portions 20, the placing member 6 is placed on the upper surface of the intermediate portion 21 so that the lower current 12 and the concave portions 20 Wherein the lattice rebar assembly (1) is disposed in the recess (20) in such a manner that there is a gap between the floor top surfaces.
3. The method according to claim 1 or 2,
At a longitudinal intermediate point of the lattice-reinforced steel assembly 1, a mounting member 6 disposed laterally across the concave portion 20 is provided;
After the lattice rebar assembly 1 is disposed in each recess 20, the transverse ends of the mounting member 6 provided at the longitudinal intermediate point of the lattice rebar assembly 1 and the transverse ends of the corrugated plate 2 And the intermediate member 21 of the corrugated plate 2 are brought into close contact with each other or with the interval between the stationary member 6 and the intermediate portion 21 of the corrugated plate 2 being minimized, The upward camber of the corrugated plate 2 is aligned with the upward camber of the lattice-reinforced steel assembly 1 so that the corrugated plate 2 and the lattice of the lattice plate 2, Wherein the reinforcing steel assembly (1) is coupled with the same upward camber.
5. The method of claim 4,
The mounting member 6 provided at the longitudinal intermediate point of the lattice reinforcing steel assembly 1 includes a transverse extending member 60 transversely intersecting the concave portion 20, And a binding member (61) provided on the upper portion and coupled to each of the two phase currents (11);
The transverse extending member 60 of the mounting member 6 provided at the longitudinal intermediate point of the lattice reinforcing steel assembly 1 is disposed transversely of the transverse extending member 60 in a state in which the transverse extending member 60 is disposed across the concave portion 20. [ The through-hole fastening member 63 is inserted into and fastened to both ends of the intermediate portion 21 of the corrugated plate 2 so that the fastening member 6 provided at the longitudinal intermediate point of the lattice- 2). ≪ / RTI >
A corrugated plate (2) having a plurality of concave portions (20) formed in parallel with each other with a lateral gap therebetween and having an intermediate portion (21) between adjacent concave portions (20) and having an upward camber; A lattice rebar assembly (20) having an upward camber and a grid member (13) connecting the two phase currents (11) and one bottom current (12) 1) are integrally combined to fabricate the synthetic deck 100,
Disposing a lattice rebar assembly (1) in each recess (20) such that there is a gap between the bottom end (12) of the lattice rebar assembly (1) and the bottom top surface of the recess (20);
The camber adjusting intermediate linking member 3 is disposed so as to face the intermediate portion 21 of the corrugated plate 2 between the upper ends 11 of the neighboring lattice-reinforcing steel assemblies 1 disposed in the recesses 20, (11) of the lattice-reinforcing steel assembly (1) by arranging the camber-adjusting intermediate linking member (3) in the lateral direction so that both ends of the camber- And
The interval between the intermediate portion 21 of the corrugated plate 2 and the camber adjusting intermediate connection member 3 is in close contact or the interval between the intermediate portion 21 of the corrugated plate 2 and the camber adjusting intermediate member 3 is minimized , And coupling and fixing the camber adjusting intermediate linkage (3) and the corrugated plate (2) to each other;
The upward camber of the corrugated plate 2 is aligned with the upward camber of the lattice rebar assembly 1 such that the corrugated plate 2 and the lattice rebar assembly 1 are joined together with the same upward camber 100). ≪ / RTI >
The method according to claim 6,
Prior to placing the lattice-reinforced steel assembly 1 in the recess 20, a longitudinal intermediate point of the lattice-reinforced steel assembly 1 is provided with a mounting member 6 );
After the lattice-reinforced steel assembly 1 is disposed in each of the recesses 20, the lateral ends of the mounting member 6 provided at the longitudinal intermediate point of the lattice-reinforced steel assembly 1, 2 or the middle part 21 of the corrugated plate 2 is minimized so that the distance between the stationary member 6 and the corrugated plate 2 is minimized, The upward camber of the corrugated plate 2 is aligned with the upward camber of the lattice rebar assembly 1 so that the corrugated plate 2 is fixed to the corrugated plate 2, And the lattice rebar assembly (1) are joined together with the same upward camber.

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