KR101855446B1 - Spacer for stripping deck, stripping deck and insulating deck having spacer - Google Patents

Abstract

The present invention is characterized in that the bottom surface is coupled to the bottom plate and the top surface is coupled with the truss girder to separate the truss girder from the bottom plate to allow the bottom plate to be removed after concrete pouring / The present invention relates to a decking deck having a truss girder which is provided on a bottom plate and includes a bottom current and a top current which bear a tensile load and a compressive load, respectively; A spacer supporting the truss girder upward and supporting the lower end of the truss girder at a predetermined height from the floor; A bottom plate fixed to a lower portion of the spacer; And a fixing member for fixing the spacer and the bottom plate, wherein the spacer is formed by folding a sheet of metal plate material and bent at a predetermined angle along a longitudinal center line; A side plate bent downward from both ends of the upper plate to form side surfaces; And a fastening plate having both ends of the side plate bent in an inner horizontal direction and engaged with the bottom plate. According to the present invention, since the spacer is constituted by using a single steel plate, it is possible to prevent the occurrence of the weak portion due to the combination of the steel material and the synthetic resin material, and to prevent the increase in the manufacturing cost of the spacer due to the insert injection It is effective.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a decking deck spacer, a decking deck having the decking deck spacer,

More particularly, the present invention relates to a deck comprising a bottom plate of a metal plate and a truss girder, wherein the bottom surface is coupled to the bottom plate, and the top surface is coupled to the truss girder Thereby allowing the truss girder to be spaced a predetermined distance from the bottom plate so that the bottom plate can be removed after concrete pouring / curing.

In the slab of general architecture, the truss deck, which is used as a formwork and reinforcing steel by attaching a thin steel plate to the bottom of the steel truss, has been widely used in domestic construction works for a long time.

The slab to which the truss deck is applied has the function of omitting the stiffening strut until the concrete curing as compared with the conventional reinforced concrete slab such as the timber formwork and the thin steel plate attached to the lower part of the steel truss plays the role of the mold, The advantage is that you can earn time.

However, in the case of the truss deck, it is recognized that the decking deck (decking deck) is excellent in terms of economy because the bottom plate can not be applied as a structural member due to problems such as adhesion with cured concrete. However, since the truss cutter is welded to the bottom plate, it can not be separated. Therefore, a technique has been developed for providing a spacer between the truss girder and the bottom plate to separate the bottom plate after concrete curing.

An example of a spacer applied to the above deformation-type deck is disclosed in Korean Patent No. 1237323.

The spacers of such a deformation-type deck are basically capable of being stably fixed to the bottom plate at the bottom while being easily detachable after concrete curing. Secondly, the spacers of the deformation- The spacer must have a stable bond with the bottom plate.

That is, since there is no separate form for the deformation-type deck, when the concrete is placed after being mounted on the frame, the bottom plate supports the weight of the concrete, and thus a tensile force is generated between the bottom plate and the spacer. .

However, in the prior art shown in Fig. 1, the spacer is fixed on the steel plate, and it depends on the fixing force of the bolt which is inserted into the spacer body through the steel plate. Therefore, when the weight of the concrete is increased, the spacer can not be stably fixed to the steel plate because the bolt fixing force to the spacer body formed of the synthetic resin material is relatively weak.

Furthermore, since the coupling force between the spacer head formed of a metal and the spacer body formed of a synthetic resin material also depends on the coupling force between the spacer body and the two members due to injection of the insert in the head, a weak portion is formed between the spacer body and the head There was a problem that could occur.

In addition, since the spacer according to the prior art is produced by insert injection, the spacer head formed of a metal and the spacer body formed of a synthetic resin material are produced by insert injection, which increases a production cost and increases a construction cost.

On the other hand, since the deformation-type deck is standardized and manufactured in the factory, it is common that a cutting process is carried out according to the field conditions at the time of field construction. At this time, the deformation data is usually processed by an electric cutting method (plasma cutting machine or the like).

In this case, since the decking deck according to the prior art is connected via the spacer body, which is an insulator, to the bottom plate and the truss girder, the electrical connection between the bottom plate and the truss girder is cut off, It is necessary to change the connection of electrodes during cutting. As a result, it is necessary to change the electrode connection after the welding process of the spacers to one truss girder is completed, thereby reducing the workability and economical efficiency of the deck.

Korea Patent No. 1237323

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide stable connection between a spacer and a bottom plate so that the tensile force And a deck having the de-molding deck spacer.

It is another object of the present invention to provide a spacer for a de-molding deck having enhanced bonding strength and a deck having the same, while preventing the occurrence of a weak portion and an increase in manufacturing cost due to the combination of a steel material and a synthetic resin material.

The present invention provides a spacer for a deformation-type deck and a deck having the deformation-deck spacer, in which a welding process between a spacer and a truss girder can be easily performed by forming a structure in which a bottom plate, a spacer and a truss girder are electrically connected.

According to an aspect of the present invention, there is provided a truss girder comprising: a truss girder provided on a bottom plate, the truss girder including a lower current and an upper current that bear a tension and a compressive load; A spacer supporting the truss girder upward and supporting the lower end of the truss girder at a predetermined height from the floor; A bottom plate fixed to a lower portion of the spacer; And a fixing member for fixing the spacer and the bottom plate, wherein the spacer is formed by folding a sheet of metal plate material and bent at a predetermined angle along a longitudinal center line; A side plate bent downward from both ends of the upper plate to form side surfaces; And a fastening plate having both ends of the side plate bent in an inner horizontal direction and engaged with the bottom plate.

At this time, the fastening plate may have a fastening hole for screwing with the fastening member.

Here, the engaging groove may be formed in a notch shape to increase the engaging length of the fixing member.

The upper plate may be provided with cutting grooves formed at both sides of the central portion at a predetermined depth in the inward direction.

The side plate may be formed to be inclined to the outside of the upper plate.

The side plates may be formed vertically downward from the upper plate.

The spacer includes a reinforcing rib formed by folding the outer end of the upper plate and the outer end of the side plate so as to reinforce the strength against the flexural load generated at the boundary between the side plate and the upper plate or the fastening plate .

The spacer may be formed by pressing a metal plate to a forming frame having a shape of a triangular (isosceles) column, and both ends protruding outward by a predetermined length?.

Further, the fastening plate may be provided with a rust preventive coating for rust prevention of the external exposed surface after the bottom plate is removed.

The rustproofing cloth may have a protruding portion protruding downward at a predetermined thickness at the fastening hole position of the fastening plate.

The rust preventive coating may include a reinforcement portion formed between the fastening plate and the side plate at a predetermined height to reinforce the resistance strength against the bending moment generated in the fastening plate and the side plate engaging portion.

According to another aspect of the present invention, a truss girder is provided on a bottom plate and includes a bottom current and a top current to bear a tensile load and a compressive load, respectively. A bottom plate and a fixing member; The spacer includes a top plate formed by folding a sheet of metal plate and bent at a predetermined angle along a longitudinal center line; A side plate bent downward from both ends of the upper plate to form side surfaces; And a fastening plate having both ends of the side plate bent in an inner horizontal direction and engaged with the bottom plate.

The present invention also provides a truss girder comprising: a truss girder provided on a bottom plate, the truss girder including a lower current and an upper current that bear a tension and a compressive load, respectively; A spacer supporting the truss girder upward and supporting the lower end of the truss girder at a predetermined height from the floor; A heat insulating material disposed under the spacer; A bottom plate fixed to the bottom of the heat insulating material; And a fixing member passing through the heat insulating material and fixing the spacer and the bottom plate, wherein the spacer is formed by folding a sheet of metal plate material and bent at a predetermined angle along a longitudinal center line; A side plate bent downward from both ends of the upper plate to form side surfaces; And a spacer including both end portions of the side plates bent in an inner horizontal direction and coupled with the heat insulating material.

The following effects can be expected in the deformation-type spacer according to the present invention as described above.

That is, since the spacer is made of a single steel plate, it is possible to prevent the occurrence of weak portions due to the combination of the steel material and the synthetic resin material, and to prevent the increase in the manufacturing cost of the spacer due to the insert injection.

Further, the spacer according to the present invention has the effect of reinforcing the rigidity against the bending moment generated in the bending portion while using a single steel plate, and effectively restraining the tensile force between the spacer and the bottom plate due to the load applied to the bottom plate have.

In the present invention, the bottom plate, the spacer, and the truss girder are electrically connected to each other to connect the deck after the bottom plate is installed, and the entire deck is electrically disconnected by an electric cutting method (plasma cutter, etc.) There is an effect that it can be processed and constructed.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view showing a de-molding deck having a de-molding deck spacer according to the prior art; Fig.
FIG. 2 is a perspective view illustrating a deformation-type deck having a spacer according to a specific embodiment of the present invention; FIG.
FIGS. 3A to 3C are views showing a manufacturing process of a deformation-type spacer according to a specific embodiment of the present invention; FIG.
4 is a side view showing a specific embodiment of a deformation-type deck provided with a spacer according to the present invention;
5 is a side view of another embodiment of a de-molding deck having spacers according to the present invention in a different orientation.
6 is an exemplary view showing moments generated in a deformation-type deformation spacer according to a specific embodiment of the present invention.
Fig. 7 is an exemplary view showing another embodiment of a deformation-type spacer according to the present invention; Fig.
Figures 8A-8C illustrate various embodiments of a spacer according to the present invention.
FIG. 9 is a side view showing a concrete embodiment of the heat insulating deck provided with the spacer according to the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, a deformation-type deck / thermal deck having a spacer and spacers according to a specific embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a perspective view illustrating a deformation type deck having spacers according to a specific embodiment of the present invention, FIGS. 3A to 3C are views illustrating a process of manufacturing a deformation type deformation spacer according to a specific embodiment of the present invention, FIG. 4 is a side view showing a deformation type deck having a spacer according to the present invention, FIG. 5 is a side view showing another embodiment of a deformation type deck having a spacer according to the present invention, 6 is an exemplary view showing a moment generated in a deformation-type spacer according to a specific embodiment of the present invention.

2 and 3, a deformation-type deck having spacers according to the present invention includes a truss girder 100, a bottom plate 200, and a plurality of truss girders 100, And a spacer unit 300 provided in the spacer 300.

As shown in FIG. 2, the truss girder 100 includes a bottom current 120 applied as a main reinforcement of a slab, an upper current 110 applied as a compressive reinforcing bar, and an upper current 110 and a lower current 120 And a lattice 130 serving as a shear strut integrally.

In this case, when the decking deck is applied to the continuous slab, for example, when the load conditions are different, it is also possible that the bottom current 120 acts as a compressive reinforcement and the current 110 acts as a tensile reinforcement.

The lattice 130 is fixed to the phase current 110 and the bottom current 120 by welding.

Meanwhile, the lower current 120 is supported by the spacer 300.

The spacer 300 is provided to support the truss girder 100 by being separated from a bottom plate 200 to be described later. The one side of the upper plate 355, the side plate 340 and the fastening plate 350, .

In order to clarify the structure of the spacer 300, the spacer 300 will be described with reference to an example of a manufacturing process of the spacer 300.

As shown in FIG. 3A, in order to manufacture the spacer according to the present invention, a rectangular metal plate is first provided.

At this time, cutting grooves 310 are formed on both sides of the central portion of the metal plate. The cutting grooves 310 are formed in order to reduce the material consumption of the load-free portion of the spacer 300 and allow the cement mortar to be densely packed with the aggregate under the spacer 300 at the time of construction.

At both ends of the metal plate, a coupling hole 320 for guiding the coupling position is formed in screwing the spacer 300 with the bottom plate 200.

Next, the metal plate on which the cutting grooves 300 are formed is bent along the longitudinal center line while both side faces are bent downward.

That is, the central portion of the metal plate is bent to both sides along the center line, and both ends are bent downward.

Such a bending form is easy to utilize the forming frame F as shown in Fig. 3A.

As shown in FIG. 3A, the forming frame F has a shape of a triangular (isosceles) column, and both ends are protruded outward by a predetermined length?.

When the metal plate is pressed on the forming frame F as described above, as shown in FIG. 3B, the metal plate has a central portion bent in a longitudinal direction, and both side ends are bent downward to form a side plate.

At this time, the side plate 340 has an outwardly inclined shape, and the outer end of the upper plate 355 is folded with a part of the side plate to form a reinforcing rib 330.

The reinforcing rib 330 functions to reinforce the strength of the spacer due to the flexural load against the flexural load generated at the boundary between the side plate 340 and the upper plate 355.

That is, the reinforcing ribs 330 function to transmit the axial force of the side plates 340 without deforming the members by forming the upper plate and the upper side of the side plates 340 as rigid bodies, To prevent out-of-plane buckling.

Next, the end portion of the steel plate bent downward is again bent inward to form a fastening plate 350 as shown in FIG. 3C.

At this time, the fastening plate 320 is formed in the fastening plate 350 as described above.

When the fastening plate 350 is in contact with the bottom plate 200, a screw threaded through the bottom plate 200 is screwed into the fastening hole 320 so that the spacer 300 is fastened to the bottom plate 200 200).

The bottom plate 200 supports the lower end of the spacer 300 and is formed of a metal plate. As shown in FIG. 4, the bottom plate 200 includes a fixing member 400 penetrating through the through-hole 320, a portion of the bottom plate 200, which is poured into the deck at the time of slab construction and removed after curing of the concrete, (Not shown).

Hereinafter, a structure in which a deformation type deck according to a specific embodiment of the present invention is combined will be described with reference to FIGS. 4 and 5. FIG.

As shown in these figures, with the de-molding deck coupled, the bottom current 120 is seated in the bend of the top plate 350 of the spacer unit 300 and fixed by welding.

At this time, a groove is formed in the seating portion, so that the seating position of the lower case 120 can be guided.

The fastening plate 320 and the bottom plate 200 of the spacer 300 are coupled by the fixing member 400. That is, as shown in FIG. 5, The bottom plate 200 and the fastening plate 350 are coupled to each other by screwing the member 400 to the fastening hole 320.

6 shows a moment generation form due to a load in a state where the spacer 300 and the truss girder 100 are coupled to the bottom plate 200. In FIG.

When the bottom plate is fastened to a synthetic resin material having a rectangular parallelepiped shape (a synthetic resin material having a specific volume) as in the prior art, the action of the bending moment is not a big problem, and the bonding force between the synthetic resin material and the dissimilar member is problematic.

On the other hand, since the entire spacer 300 is formed of a steel sheet, the bending moment due to the load is a problem in the present invention, and will be described in detail with reference to FIG.

As shown in FIG. 6, when the deformation-type deck according to the present invention is mounted on the frame, when the concrete is poured on the deck, the bottom plate 200 receives a downward load due to the weight of the poured concrete .

At this time, since the upper / lower current is connected to the upper / lower current of the frame or continuous deck, a tensile force is generated between the bottom plate 200 and the spacer 300.

6, a bending moment is generated in the fastening plate 350 in proportion to the spacing distance between the fastening holes 320 and the lower plate 355, A bending moment that is increased in proportion to a distance from the joining point is generated outside the joining unit 120 at present, and a moment corresponding to the maximum bending moment is generated in the side plate 340.

A maximum bending moment is generated in the spacer 300 at a connecting portion between the connecting plate 350 and the side plate 340 and at a connecting portion between the side plate 340 and the top plate 355.

Such a bending moment causes displacement of the fastening plate 350 and the side plate 340 and the side plate 340 and the upper plate 355 in a direction in which they are widened.

At this time, the reinforcing ribs 330 prevent the displacement between the fastening plate 350 and the side plates 340 and between the side plates 340 and the upper plate 355 to store the moment .

The upper plate 355 is bent so that the side plate 340 formed of the same plate as the upper plate 355 is formed with a reinforcing rib 330 protruding outward from the spacer 300 and folded The reinforcing ribs 330 form rigid joints to improve the rigidity of the bent portion of the spacer 300.

That is, the spacer 300 according to the present invention can produce a single sheet of metal plate by bending and folding, thereby remarkably reducing the manufacturing cost, and reinforcing the bending moment resistance strength generated in the steel plate type spacer, .

6, the bending moment generated in the upper plate, the side plate 340, and the fastening plate 350 of the spacer according to the present invention is greater than the bending moment generated from the coupling point between the upper plate 355 and the lower plate 120 And the distance from the fastening hole 320 to the outside of the fastening plate 350 is proportional.

7, another embodiment of the spacer according to the present invention includes the side plate 340 formed in the vertical direction and the outer side from the joining point of the upper plate 355 and the lower plate 120 And the distance from the fastening hole 320 to the outside of the fastening plate 350 can be minimized, the bending moment generated in the spacer can be minimized.

6, when the side plate 340 is formed in an inclined shape, the maximum moment of the top plate 355 can be reduced and the rigidity of the side plate 340 can be secured 7, when the side plate 340 is formed in a vertical shape, the maximum moment can be reduced in the upper plate 355 and the fastening plate 350. [

Meanwhile, the spacer according to the present invention may be configured in various embodiments according to the object and form of the coating.

Hereinafter, various embodiments of the spacer according to the coating will be described in detail with reference to the accompanying drawings.

First, FIG. 8A shows an embodiment in which a coating for preventing rusting of the spacer fastening plate is provided.

That is, after the decking deck according to the present invention is removed, the bottom surface of the connecting plate 350 is exposed to the outer surface of the structure.

Accordingly, in order to prevent the exposed metal material fastening plate 350 from being corroded, the fastening plate 350 of the spacer 300 may be provided with a rust preventive coating 360A.

Meanwhile, FIG. 8B shows an embodiment in which a bonding cover 360B for minimizing the exposed surface of the spacer 300 is provided after completion of the construction.

As described above, when the bottom plate is removed after the deformation type deck according to the present invention, the bottom surface of the building plate is exposed to the outer surface of the structure. At this time, in order to minimize the exposed surface, , And the fastening plate 350 may be provided with a coupling cover 360B having a protruding portion protruding downward to a predetermined thickness.

At this time, it is preferable that the projecting portion is formed at a position corresponding to the fastening hole, so that a minimum exposed portion is formed only at the engagement position of the engagement member.

8C shows an embodiment in which a reinforcing cover 360C is provided to reinforce the fragile portion due to the bending moment of the spacer.

That is, as described above, the connecting portion between the fastening plate 350 and the side plate 340 becomes one of the fragile sections according to the load of the spacer 300 according to the present invention.

This embodiment basically provides a reinforcing cover 360C having a reinforcing portion formed at a predetermined height between the fastening plate 350 and the side plate 340 to cover the fastening plate 350 .

Therefore, when the fastening plate 350 and the side plate 340 are displaced by the bending moment, the reinforcing portion is resistant to the displacement, so that the resistance strength against the bending moment is increased.

Of course, it is also possible to apply the embodiments shown in Figs. 8A, 8B and 8C in combination with the spacer according to the purpose of use.

As shown in FIG. 9, the heat-insulating deck provided with the spacer according to the present invention further comprises a heat insulating material 500.

At this time, the heat insulating material 500 is provided at the lower end of the fastening plate 320, and the bottom plate 200 is provided at the lower end of the heat insulating material 500.

The fixing member 400 'penetrates through the bottom plate 200 and the heat insulating material 500 and penetrates through the fastening plate 320.

Therefore, when the bottom plate 200 is removed after the construction, the surface of the heat insulating material 500 is exposed at the lower end rather than the concrete surface.

It is to be understood that the invention is not limited to the disclosed embodiment, but is capable of many modifications and variations within the scope of the appended claims. It is self-evident.

The present invention is characterized in that the bottom surface is coupled to the bottom plate and the top surface is coupled with the truss girder to separate the truss girder from the bottom plate to allow the bottom plate to be removed after concrete pouring / The present invention relates to a deformation-type deck having a spacer formed by using a single steel plate, so that it is possible to prevent the occurrence of a weak portion due to the combination of a steel material and a synthetic resin material and to prevent an increase in the manufacturing cost of the spacer due to insert injection There is an effect that can be.

100: Truss girder 110: Phase current
120: current 130: lattice
200: bottom plate 300: spacer
310: cutting groove 320: fastening hole
330: reinforcing rib 340: side plate
350: fastening plate 355: top plate
360A: Anti-rust coating 360B:
360C: reinforcement cloth 400: fixing member
500: Insulation

Claims (11)

A truss girder provided on the bottom plate and including a lower current and an upper current which respectively bear tension and compressive load;
A spacer supporting the truss girder upward and supporting the lower end of the truss girder at a predetermined height from the floor;
A bottom plate fixed to a lower portion of the spacer; And
And a fixing member for fixing the spacer and the bottom plate,
The spacer is formed by folding a sheet of metal plate,
An upper plate bent at a predetermined angle along a longitudinal center line;
A side plate bent downward from both ends of the upper plate to form side surfaces; And
And a fastening plate having both ends of the side plate bent in an inner horizontal direction and engaged with the bottom plate,
In the fastening plate,
A fastening hole for screwing with the fixing member is formed,
The fastening hole
Formed in a notch shape:
Wherein,
And is formed to be inclined to the outside of the upper plate,
The spacer
And a reinforcing rib formed by folding the outer end of the upper plate and the outer end of the side plate to reinforce the strength against the flexural load generated at the boundary between the side plate and the upper plate,
In the fastening plate,
After the bottom plate is removed, a rust preventive coating is provided for anti-rusting of the exterior exposed surface,
The rust-
And a protruding portion protruding downward to a predetermined thickness at a position of the fastening hole of the fastening plate.
delete delete The method according to claim 1,
In the upper plate,
And a cut groove formed at both sides of the center portion and having a predetermined depth cut inward.
delete delete delete delete The method according to claim 1,
The rust-
And a reinforcing portion formed at a predetermined height between the fastening plate and the side plate to reinforce the resistance strength against the bending moment generated in the fastening plate and the side plate engaging portion.
A truss girder provided on the bottom plate and including a bottom current and a top current which respectively bear a tensile force and a compressive load;
A bottom plate and a fixing member;
One sheet of metal plate is folded and formed,
An upper plate bent at a predetermined angle along a longitudinal center line;
A side plate bent downward from both ends of the upper plate to form side surfaces; And
And a fastening plate having both ends of the side plate bent in an inner horizontal direction and engaged with the bottom plate,
In the fastening plate,
A fastening hole for screwing with the fixing member is formed,
The fastening hole
Formed in a notch shape:
Wherein,
And is formed to be inclined to the outside of the upper plate,
And a reinforcing rib formed by folding the outer end of the upper plate and the outer end of the side plate to reinforce the strength against the flexural load generated at the boundary between the side plate and the upper plate,
In the fastening plate,
After the bottom plate is removed, a rust preventive coating is provided for anti-rusting of the exterior exposed surface,
The rust-
And a protruding portion protruding downward to a predetermined thickness at a position of the fastening hole of the fastening plate.
delete

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