KR20180134734A - Spacer module for stripping deck, stripping deck and insulating deck having spacer - Google Patents

Abstract

The present invention relates to a deck including a truss girder and a bottom plate of a metal steel plate. The deck includes: a truss girder including a lower and an upper chord member arranged on a bottom plate to bear a tensile and a compressive load, respectively; a spacer module to support the truss girder upwards, and separate the lower chord member of the truss girder from a bottom by a predetermined height to support the lower chord member; the bottom plate fixed on a lower portion of the spacer module; and a fixing member fixing the spacer module and the bottom plate. The spacer module includes: an upper plate formed by folding a metal plate, and coupled to the lower chord member by welding; a side plate bent downwards from both ends of the upper plate to form a side; and a coupling plate wherein both ends of the side plate are bent in an inward horizontal direction to be coupled to the bottom plate. A reinforcing protrusion protrudes upwards from a longitudinal center of one side of the upper plate, the side plate, and the coupling plate to allow the lower chord member to be seated thereon and reinforce bending strength of the spacer module. According to the present invention, since a single steel plate is used to construct a spacer, creation of a weak portion by coupling steel and a synthetic resin material can be prevented, and an increase in manufacturing costs of a spacer by insert injection can be prevented.

Description

TECHNICAL FIELD [0001] The present invention relates to a spacer module for a de-molding deck, a de-molding deck having the de-molding deck and an insulation deck having the spacer module,

The present invention relates to a spacer module provided in a de-molding deck, and more particularly to a deck comprising a bottom plate of a metal plate and a truss girder, the bottom surface of which engages with a bottom plate, To a spacer module that allows the truss girder to be spaced a predetermined distance from the bottom plate to allow removal of the bottom plate after concrete placement / 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 manufactured by insert injection, a spacer body formed of a metal and a spacer body made of a synthetic resin material are produced by insert injection, so that separation between both materials can be caused by temperature change. Typically, demolding decks are mass produced and stored in factories and then applied to the construction site at time intervals. In this case, when the temperature difference between the temperature of the spacer module and the temperature of the spacer module is large, the coefficient of thermal expansion of the metal material and the synthetic resin material are different from each other, causing material separation at the joints of the two members, .

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 deformation-type deck having the spacer module.

It is another object of the present invention to provide a spacer module for a de-molding deck having enhanced bonding strength and a de-molding deck having the same, while preventing the occurrence of fragile portions due to the combination of a steel material and a synthetic resin material.

It is another object of the present invention to provide a spacer module for a deformation-type deck and a deformation-type deck having the same, in which a deck machining process can be easily performed by forming a structure in which a bottom plate, a spacer and a truss girder are electrically connected to each other.

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 module for supporting the truss girder upward and supporting the bottom current of the truss girder at a predetermined height from the floor; A bottom plate fixed to a lower portion of the spacer module; And a fixing member for fixing the spacer module and the bottom plate, wherein the spacer module comprises: a top plate formed by folding a sheet of metal plate material and joined to the bottom plate by welding; A side plate bent downward from both ends of the upper plate to form side surfaces; And a fastening plate having opposite ends of the side plates bent in an inner horizontal direction and engaged with the bottom plate, wherein the upper plate, the side plate, and the fastening plate have projecting upward in a longitudinal central portion thereof, , The bending stiffness of the upper plate, and the bending and compression stiffness of the side plate.

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

The fastening plate may be formed with a fastening protrusion protruding from the fastening hole, threaded inward, and threadedly engaged with the fastening member.

The bending reinforcement portion may be formed on the side surfaces of the upper plate, the side plate, and the fastening plate so as to increase the cross-sectional moment of the plate material to increase the bending strength.

And a rustproof cap of a synthetic resin material inserted into the fastening plate to relieve the external exposed surface of the fastening plate.

Further, the rustproof cap may have an insertion slot into which the fastening plate is inserted into the side surface inside; An opening is formed in an upper part of the ridgeline cap so as to secure a coating depth of the ridgeline cap side plate; A protrusion groove is formed in a lower end portion of the insertion slot to insert the reinforcing protrusion; And a through hole through which the fixing member passes may be formed on a bottom surface of the projection groove.

The rustproof cap may be formed with a ridge protruding from the lower end surface of the rustproof cap along the outer periphery of the through-hole.

In addition, the rustproof cap may include a finished curved surface portion formed at a lower surface of the rustproof cap.

At this time, the curved surface of the finished curved surface portion may be a curved surface protruding outward from the bottom surface of the rustproof cap, or a curved surface in which the bottom surface of the rustproof cap is recessed inward.

The upper portion of the rustproof cap may extend to the lower end of the upper plate, and may support the lower end surface of the upper plate.

Further, the upper part of the rustproof cap may be formed such that one side thereof is in close contact with the inside of the side plate and extends upward by a predetermined length.

The lower end of the rustproof cap may extend outwardly from the side plate.

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. And the lower portion is fixed by the bottom plate and the fixing member; A top plate formed by folding a sheet of metal sheet material and joined to the bottom sheet by welding; 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; And a spacer module protruded upward in a longitudinal center portion of the upper plate, the side plate, and the fastening plate to form a reinforcing projection for seating the lower plate and reinforcing the bending strength of the spacer module.

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 module for supporting the truss girder upward and supporting the bottom current of the truss girder at a predetermined height from the floor; A heat insulator disposed under the spacer module; 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 module and the bottom plate, wherein the spacer module includes a top plate formed by folding a sheet of metal plate material and joined to the bottom plate by welding; A side plate bent downward from both ends of the upper plate to form side surfaces; And a fastening plate having opposite ends of the side plates bent in an inner horizontal direction and engaged with the bottom plate. The fastening plate is protruded upward at a longitudinal central portion on one side of the upper plate, the side plate and the fastening plate, And a spacer module having a reinforcing projection for reinforcing the bending strength of the spacer module.

In the spacer module for a deformation type deck according to the present invention as described above, the following effects can be expected.

That is, since the spacer module is constructed using a single steel plate, it is possible to prevent the occurrence of fragile parts due to the combination of the steel material and the synthetic resin material, and also to prevent the increase in the manufacturing cost of the spacer due to insert injection.

Further, the spacer module according to the present invention reinforces the rigidity against the bending moment generated in the upper plate and the side plate while using a single steel plate, and effectively resists the tensile force between the spacer module and the bottom plate due to the load applied to the bottom plate There is an effect that can be.

In the present invention, the bottom plate, the spacer module, and the truss girder are electrically connected to each other so that the deck is connected to the positive after the bottom plate is installed, and the entire deck is subjected to an electric cutting So that it is possible to construct the construction.

Further, the spacer module according to the present invention has an advantage that the size of the exposed synthetic resin material is minimized after the bottom plate is removed, and the construction finish surface can be made beautiful.

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.
2 is a perspective view showing a deformation-type deck provided with a spacer module according to a specific embodiment of the present invention;
3 is a perspective view showing a concrete embodiment of the spacer module according to the present invention.
4 is an exemplary view showing an intermediate processing state of the space module according to the present invention;
5 is an exemplary view showing an intermediate processing state of a space module according to another embodiment of the present invention;
6 is a perspective view showing an embodiment of a rustproof cap provided to a spacer module according to the present invention.
7 is a partial cross-sectional view showing an embodiment of a spacer module to which a rustproof cap according to the present invention is coupled.
8 is a sectional view showing another embodiment of the rustproof cap provided in the spacer module according to the present invention.
9 is a sectional view showing still another embodiment of the rustproof cap provided in the spacer module according to the present invention.
10 is a sectional view showing still another embodiment of the rustproof cap provided in the spacer module according to the present invention.
11 is a side view showing a specific embodiment of a de-molding deck having a spacer module according to the present invention.
12 is a side view of a de-molding deck provided with a spacer module according to the present invention in a different direction.
FIG. 13 is an exemplary view showing a moment generated in a spacer module for a deformation-type deck according to a specific embodiment of the present invention; FIG.
FIG. 14 is a side view showing a concrete embodiment of the heat insulating deck provided with the spacer module according to the present invention. FIG.
15 is a sectional view showing an example in which another embodiment of the rustproof cap provided in the spacer module according to the present invention is applied.
16 is a sectional view showing an example in which another embodiment of the rustproof cap provided in the spacer module according to the present invention is applied.
17 is a cross-sectional view showing an example in which another embodiment of the rustproof cap provided in the spacer module according to the present invention is applied.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, a deformation-type deck / thermal deck having a spacer module for a de-molding deck and a spacer module 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 a spacer module according to a specific embodiment of the present invention, FIG. 3 is a perspective view showing a specific embodiment of the spacer module according to the present invention, FIG. 5 is an exemplary view showing an intermediate processing state of a space module according to another embodiment of the present invention, and FIG. 6 is a cross-sectional view illustrating a state in which the spacer module according to an embodiment of the present invention, 7 is a partial cross-sectional view showing an embodiment of a spacer module to which a rustproof cap according to the present invention is coupled, and Fig. 8 is a perspective view of a rustproof cap Fig. 9 is a sectional view showing still another embodiment of the rustproof cap provided in the spacer module according to the present invention, and Fig. 10 is a cross- 11 is a side view showing a specific embodiment of a deformation-type deck provided with a spacer module according to the present invention, and Fig. 12 is a side view of a spacer according to the present invention. Fig. 13 is a view illustrating an example of a moment generated in a deformation-type spacer module according to a specific embodiment of the present invention, and Fig. 14 is a cross- Fig. 8 is a side view showing a concrete embodiment of the heat insulating deck provided with the spacer module according to the invention. Fig.

2, the deformation-type deck provided with the spacer module according to the present invention includes a truss girder 100, a bottom plate 200, and a bottom plate 200 between the truss girder 100 and the bottom plate 200. [ And a spacer module (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 module 300.

The bottom plate 200 supports the lower end of the spacer module 300 and is formed of a metal plate. The bottom plate 200 is a part that is poured into the deck and is removed after curing of the concrete when the slab is constructed. The bottom plate 200 is fixed to the spacer module 300 ).

The spacer module 300 is spaced from the bottom plate 200 and supports the truss girder 100. The spacer module 300 is formed by folding one sheet of the metal plate material so that the upper plate 310, the side plate 320, ).

3 and 4, the longitudinal metal plate is folded to form an upper plate 310, a side plate 320, and a fastening plate 330, as shown in FIGS.

On the other hand, the upper plate 310 is provided with reinforcing protrusions 312 protruding in the longitudinal direction at the center thereof. At this time, the reinforcing protrusion 312 is formed by pressing the upper plate 310 upward.

The reinforcing protrusions 312 serve to increase the bending strength by enlarging the second moment of the cross section of the upper plate 310 as well as to the portion where the lower plate 120 is welded.

The reinforcing protrusions 312 may extend from the side plate 320 to the fastening plate 330 so that the upper plate 310 and the side plates 320 and the side plates 320, (330). ≪ / RTI >

The fastening plate 330 is formed with a fastening hole 332 for screwing the fastening member 400 passing through the bottom plate 200.

At this time, the fastening hole 332 is formed with a cylindrical fastening protrusion 334 which protrudes above the fastening plate 330 and has a screw thread formed on the inside thereof, so that the fastening member 400 is screwed with the thread of the fastening protrusion And a stable bonding force is secured.

Meanwhile, the spacer module 300 may be manufactured in various sizes depending on the size of the deformation-type deck. At this time, the larger the size of the spacer module 300, the larger the bending moment generated in the upper plate 310 and the side plate 320, and thus the bending strength needs to be further reinforced.

Accordingly, as shown in FIG. 5, another embodiment of the spacer module according to the present invention may further include a bending reinforcing portion 316 at a side portion for reinforcement of additional bending strength.

The bending reinforcing portion 316 is formed by bending the side surfaces of the upper plate 310, the side plate 320 and the fastening plate 330 upward.

At this time, the bending reinforcing portion 316 also serves as a reinforcing rib, thereby increasing the cross-sectional moment of the plate material to increase the bending strength and additionally provide a welding point with the bottom plate 120.

The spacer module 300 may further include a rustproof cap 500 for rusting the exposed surface after the bottom plate 200 is removed.

That is, when the decking deck according to the present invention is removed, the bottom surface of the connecting plate 330 is exposed to the outer surface of the structure when the bottom plate 200 is removed.

Accordingly, a rustproof cap 500 may be inserted into the fastening plate 330 of the spacer module 300 to prevent the fastening plate 330 of the exposed metallic material from being corroded.

As shown in FIG. 6, the rustproof cap 500 is a synthetic resin material cap having an insertion slot 510 for insertion into the fastening plate 330.

Specifically, the rustproof cap 500 is formed with an insertion slot 510 in which the fastening plate 330 is inserted inwardly in the side surface, and an incised opening 520 is formed in an upper part of the rustproof cap 500, Likewise, the rustproof cap 500 is configured to completely cover the bottom of the side plate 320 to the outside.

A protrusion groove 530 is formed in the lower end of the insertion slot 510 so that the protruding protrusion 312 is inserted.

A through hole 540 through which the fixing member 400 passes is formed on the bottom surface of the protrusion groove 530 so that the fixing member 400 passing through the bottom plate 200 is inserted into the through hole 540, And to be coupled to the fastening protrusion 334 through the fastening hole 332.

Meanwhile, when the decking deck according to the present invention is removed after the concrete curing, the lower surface of the rustproof cap 500 is exposed to the outside of the concrete.

That is, the lower surface of the square rustproof cap 500 is exposed on the slab installation surface while being arranged in a matrix form at regular intervals.

Such an exposure pattern hinders the appearance of the slab construction surface, thereby hindering the completeness of the construction.

Accordingly, in order to minimize the area of the rustproof cap (500) exposed after the slab is constructed, the rustproof cap (500) may have various shapes.

As shown in FIG. 8, another embodiment of the rustproof cap is formed by projecting a finishing protrusion on the lower end surface of the rustproof cap.

Preferably, the finishing projection is protruded along the outer periphery of the through-hole.

As a result, the concrete mortar is shielded by the flow of the concrete mortar, and only the finishing protrusion, which has a hole through which the fixing member passes, is exposed at the center of the slab construction finish surface, so that the exposed surface of the rustproof cap can be significantly reduced .

In another embodiment of the anti-rusting cap, as shown in FIG. 9, the lower end surface of the anti-rusting cap is formed as a curved finished surface.

That is, the bottom surface of the rustproof cap is formed as a curved surface protruding between both ends of the insertion slot of the rustproof cap.

Thus, only the curved line of the bottom surface of the rustproof cap is exposed on the slab construction finish surface. Therefore, only the linear exposed surface is formed on the slab construction finish surface, so that the exposed surface of the rustproof cap can be minimized.

Alternatively, as shown in FIG. 10, a finished curved surface portion 560 'of the lower end surface of the anticorrosive cap is formed as a curved surface recessed toward the inside of the lower surface of the anticorrosive cap.

Accordingly, only the both ends of the lower end of the rustproof cap 500 are exposed on the slab construction finish surface. Therefore, only a pair of linear exposed surfaces are formed on the slab construction finish surface, so that the rustproof cap 500 can be stably supported on the bottom plate while the exposed surface of the rustproof cap 500 is minimized .

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. 11 and 12. FIG.

As shown in these figures, with the de-molding deck coupled, the bottom plate 120 is seated on the upper plate 310 reinforcement protrusion 312 of the spacer module 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 330 and the bottom plate 200 of the spacer module 300 are coupled by the fixing member 400. 12, the fixing member 400 passing through the metal bottom plate 200 penetrates through the through hole 540 of the rustproof cap 500 and is fastened to the fastening protrusions (not shown) of the fastening plate 330 334, respectively.

After the concrete laid on the bottom plate 200 is cured so that the spacer module 300 is embedded, the bottom plate 200 is removed.

13 shows a moment generation form due to a load in a state where the spacer module 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 module 300 is formed of a steel plate, the bending moment due to a load becomes a problem in the present invention, and therefore, the present invention will be described in detail with reference to FIG.

As shown in FIG. 13, 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, the upper / lower current is connected to the current / lower current of the frame or continuous deck, so that a tensile force is generated between the bottom plate 200 and the spacer module 300.

13, a bending moment (M'max) that is increased in proportion to the separation distance is formed in the fastening plate 330 due to the tensile force at a fixing point of the fastening hole 332, A maximum bending moment Mmax / M'max at both ends is generated in the side plate 320, and a bending moment Mmax is increased in proportion to the distance from the joining point, Is generated.

A maximum bending moment is generated in the spacer module 300 at a connecting portion between the connecting plate 330 and the side plate 320 and at a connecting portion between the side plate 340 and the top plate 355.

Due to the bending moment, the coupling plate 330 and the side plate 320, and the side plate 320 and the top plate 310 are displaced in the direction in which they are widened.

The reinforcing protrusion 312 prevents displacement between the coupling plate 330 and the side plate 320 and between the side plate 320 and the upper plate 310 to resist the moment .

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

13, the bending moment generated in the upper plate 310, the side plate 320, and the coupling plate 330 of the spacer module 300 according to the present invention is smaller than the bending moment generated between the upper plate 310 and the lower plate 330, The distance from the coupling point with the coupling plate 120 to the outside and the distance from the coupling hole 322 to the outside of the coupling plate 330 are proportional to each other.

Accordingly, in the present invention, the distance from the coupling point of the upper plate 310 to the lower plate 120 to the outer side and the distance from the coupling hole 322 to the outer side of the coupling plate 330 are minimized to minimize the bending moment generated .

14, the heat-insulating deck provided with the spacer module according to the present invention further includes a heat insulating material 600. As shown in FIG.

At this time, the heat insulating material 600 is provided at the lower end of the fastening plate 330, and the bottom plate 200 is provided at the lower end of the heat insulating material 600.

The fixing member 400 'penetrates the bottom plate 200 and the heat insulating material 600 and is engaged with the fastening protrusion 334.

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.

For example, the shape of the rustproof cap 500 may be different depending on the size and shape of the spacer module 300.

15, when the length of the upper plate 310 of the spacer module 300 is relatively long, the upper portion of the rustproof cap may protrude from the upper plate 310 to reinforce the bending stress generated in the upper plate 310, And may extend to the lower end.

In this case, the length between the supporting points of the upper plate 310 is shortened, and the strength against warpage is improved.

16, the lower portion of the rustproof cap 500 is extended and protruded to the outside of the side plate 320, so that the spacer module 300 is stably mounted on the bottom plate 200 Or < / RTI >

16, when the length of the side plate 320 of the spacer module 300 is relatively long, a portion of the upper portion of the rustproof cap may be bent in a predetermined direction, And may be formed to extend in close contact with the upper surface of the side plate 320.

In this case, one side surface of the side plate 320 is supported by the extended portion of the rustproof cap 500, so that a reinforcing rib is formed on the side plate 320.

The present invention relates to a deck comprising a bottom plate and a truss girder of a metallic steel plate, the bottom surface of which engages with the bottom plate and the top surface of which engages with the truss girder to separate the truss girder from the bottom plate by a predetermined distance And a spacer module for removing a bottom plate after concrete pouring / curing. According to the present invention, since the spacer is constructed by using 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 an increase in the manufacturing cost of the spacer due to insert injection can be prevented.

100: Truss girder 110: Phase current
120: current 130: lattice
200: bottom plate 300: spacer module
310: upper plate 312: reinforcing projection
316: bending reinforcement 320: side plate
330: fastening plate 332: fastening hole
334: fastening protrusion 400, 400 ': fastening member
500: rustproof cap 510: insertion slot
520: opening 530:
540: Through hole 550: Closing projection
560: Finishing curved surface portion 600: Insulation material

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 module for supporting the truss girder upward and supporting the bottom current of the truss girder at a predetermined height from the floor;
A bottom plate fixed to a lower portion of the spacer module; And
And a fixing member for fixing the spacer module and the bottom plate,
The spacer module is formed by folding a sheet of metal plate material,
A top plate coupled to the bottom plate by welding;
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,
On one side of the upper plate, the side plate and the fastening plate,
And a reinforcement protrusion protruding upward in the longitudinal center portion to seat the bottom plate and to increase the flexural rigidity of the top plate and the flexure and compressive rigidity of the side plate.
The method according to claim 1,
Wherein the fastening plate is formed with a fastening hole for screwing with the fastening member.
3. The method of claim 2,
In the fastening plate,
And a fastening protrusion protruding from the upper portion of the fastening hole and having a screw thread formed on an inner side thereof and screwed with the fastening member.
The method of claim 3,
On the side surfaces of the upper plate, the side plate and the fastening plate,
Wherein the bending reinforcement is bent upward to enlarge a cross-sectional secondary moment of the plate to increase a bending strength of the deformation-preventing deck.
5. The method according to any one of claims 1 to 4,
And a fastening plate inserted into the fastening plate,
And a rustproof cap of a synthetic resin material for preventing the external exposed surface of the fastening plate.
6. The method of claim 5,
The rust-
An insertion slot in which the fastening plate is inserted into the side surface side is formed;
An opening is formed in an upper part of the ridgeline cap so as to secure a coating depth of the ridgeline cap side plate;
A protrusion groove is formed in a lower end portion of the insertion slot to insert the reinforcing protrusion;
And a through hole through which the fixing member passes is formed on a bottom surface of the protrusion groove.
The method according to claim 6,
The upper portion of the anti-
Wherein the spacer module extends to the lower end of the upper plate and supports the lower end surface of the upper plate.
The method according to claim 6,
The upper portion of the anti-
Wherein the one side is in close contact with the inside of the side plate and is formed to extend upward by a predetermined length.
The method according to claim 6,
The rustproof cap lower end portion
And a spacer module extending outwardly from the side plate.
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;
And the lower portion is fixed by the bottom plate and the fixing member;
One sheet of metal plate is folded and formed,
A top plate coupled to the bottom plate by welding;
A side plate bent downward from both ends of the upper plate to form side surfaces; And
And a fastening plate, wherein both end portions of the side plate are bent in an inner horizontal direction to engage with the bottom plate;
On one side of the upper plate, the side plate and the fastening plate,
And a reinforcing protrusion protruding upward in the longitudinal center portion to seat the bottom end and to reinforce the flexural strength of the spacer module.
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 module for supporting the truss girder upward and supporting the bottom current of the truss girder at a predetermined height from the floor;
A heat insulator disposed under the spacer module;
A bottom plate fixed to the bottom of the heat insulating material; And
And a fixing member passing through the heat insulating material and fixing the spacer module and the bottom plate,
The spacer module is formed by folding a sheet of metal plate material,
A top plate coupled to the bottom plate by welding;
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,
On one side of the upper plate, the side plate and the fastening plate,
And a reinforcing protrusion protruding upward in the longitudinal center portion to seat the bottom plate and to reinforce the flexural strength of the spacer module.

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