KR100640684B1 - Deck plate - Google Patents

Abstract

The present invention relates to a deck plate, the configuration is a lower plate member having a plate shape, a cylindrical member which is located on one surface of the lower plate member, has a receiving space therein, and penetrates the lower portion of the cylindrical member, the tension It is made of a material having rigidity against compression and compression, the lower truss member having a certain length, the lower truss member is spaced apart and penetrates the upper portion of the cylindrical member, and is made of a material having rigidity against tension and compression, It includes an upper truss member having a predetermined length and an inner filling material filled in the inner space of the cylindrical member to surround the lower truss member and the upper truss member passing through the cylindrical member to bind the lower truss member and the upper truss member. A multi-directional truss structure with excellent stability and placed on its lower surface It can support the deck plate even if the direction of the support is installed in any direction, the installation direction of the support is free, there is no space for sound propagation can reduce the noise, can be installed in buildings such as apartments, There is no need to connect the reinforcing bars, so the time required to construct the building is shortened, and welding is not performed to interconnect the reinforcing bars, thereby maintaining the strength of the truss structure formed by the bars.

Description

Deck plate

1 is a view for explaining an example of a conventional deck plate

Figure 2 is an exploded perspective view of the deck plate according to an embodiment of the present invention

3 is an exploded perspective view of the cylindrical member of the deck plate shown in FIG.

4 is a view for explaining how the deck plate shown in FIG. 2 withstands bending stress

FIG. 5 shows an example of the seams of the deck plate shown in FIG. 2; FIG.

The present invention relates to a deck plate, and more particularly to an integrated deck plate used in each floor of the building.

In general, when constructing the floor slab of the building is composed of the slab structure made of reinforcement and concrete. In order to pour concrete, formwork is necessary on the floor. Originally, the deck plate has been applied to the construction site as a bendable steel formwork method that replaces the wooden formwork method that the on-site functional personnel worked on.

1 shows such a conventional deck plate.

As shown in FIG. 1, the conventional deck plate 1 has a plate shape in which a bent shape is repeatedly formed. Usually, the bending part 2 in which the cross-sectional shape was formed in the shape of a trapezoid is repeated.

Reinforcing bars are arranged on the upper surface of the deck plate 1 and concrete is poured. However, until the concrete is completely solidified to receive the force, the deck plate 1 must withstand the weight of the concrete before solidifying, which is poured on the upper surface. Therefore, the support 3 needs to be placed on the lower surface of the deck plate 1 for this purpose. Such support may have the form of a beam or wall.

However, as shown in FIG. 1, the conventional deck plate 1 has a problem in that the support 3 is required only in a direction intersecting with a direction in which the bent portion 2 is elongated.

That is, there is a problem that the conventional deck plate 1 cannot be supported by only the support body installed in a direction parallel to the direction in which the bent portion 2 is formed long.

In addition, the conventional deck plate (1) does not take a multi-directional truss structure with excellent stability, can be applied to a building having a general steel structure, but in some cases it is not possible to install a wall that serves as the support at regular intervals There was a problem that it can not be applied to buildings such as apartments.

That is, the wall of an apartment, etc. has various forms according to the size and structure of a room. Therefore, the wall of the apartment, such as the direction is not constant in the horizontal and vertical, and the wall does not exist continuously in either direction, and the wall is designed to be discontinuously arranged in various directions and different span (span), so that the existing deck plate (1) had a problem that it can not be applied to the apartment.

In addition, the conventional deck plate (1) has a problem that the sound is propagated to the space formed by the bent portion 2 can not reduce the noise.

In addition, the concrete deck is placed on the upper part of the conventional deck plate (1) after the reinforcement bars are connected by hand of the field worker, it takes a lot of time to connect the reinforcement bars, it takes a long time required to construct the building There was a downside. That is, although welding was performed by connecting the reinforcing bars, the welding took a long time, and there was a problem in that the load supporting ability of the truss of the reinforcing bars was lowered due to the strength of the reinforcing bars due to the heat of welding.

The present invention has been proposed in order to solve the above problems, the object of which is to take a multi-directional truss structure with excellent stability and can support the deck plate even if the direction of the support placed on the lower surface is installed in any direction The installation direction of the support is free, there is no space for sound propagation to reduce noise, can be installed in buildings such as apartments, there is no need to connect the power reinforcing bar, the time required to construct the building is shortened, The present invention provides a deck plate capable of maintaining the strength of the truss structure formed by the rebars because no welding is performed to interconnect the rebars.

Deck plate according to the present invention for achieving the above object is a lower plate member having a plate shape, located on one surface of the lower plate member, a cylindrical member having a receiving space therein, and penetrates the lower portion of the cylindrical member It is made of a material having rigidity against tension and compression, and has a lower truss member having a certain length, and is separated from the lower truss member and penetrates the upper portion of the cylindrical member, and has a rigidity against tension and compression. The inner truss member is filled in the inner space of the upper truss member and the cylindrical member having a predetermined length, and surrounds the lower truss member and the upper truss member passing through the cylindrical member to bind the lower truss member and the upper truss member. Characterized in that it comprises a filler.

In addition, the lower truss member of the deck plate according to the present invention, the horizontal lower tension compression material having a predetermined length, and is placed to cross the horizontal lower tension compression material, made of a vertical lower tension compression material having a constant length. The upper truss member is

It is characterized by including a horizontal upper tension compression material having a predetermined length, and a vertical upper tension compression material that is placed to intersect with the horizontal upper tension compression material.

In addition, the lower truss member and the upper truss member of the deck plate according to the invention is characterized in that it is provided with a reinforcing bar.

In addition, the inner filler of the deck plate according to the present invention is initially flowed while maintaining a flow state to surround the lower truss member and the upper truss member, and hardened over time, the lower truss member and the upper truss member Characterized in that the material is firmly fixed to each other.

In addition, the inner filler of the deck plate according to the invention is characterized in that the cement mortar consisting of a mixture of sand, cement and water.

In addition, the inner filler of the deck plate according to the invention is characterized in that the resin cured after flow.

In addition, the cylindrical member of the deck plate according to the present invention is coupled to an upper portion of the first lower cylindrical portion having a first half of a semicircle in one direction on the upper portion, and the first lower cylindrical portion, the first groove below A second lower cylinder portion having a semicircular second groove provided in the same direction as the upper portion, and having a third lower groove formed in a direction different from the second groove, and coupled to an upper portion of the second lower cylinder portion; It has a semi-circular fourth groove provided in the same direction as the third groove in the lower side, and the intermediate cylinder portion having a semi-circular fifth groove provided in a direction different from the fourth groove, and coupled to the upper portion of the intermediate cylinder portion; The first upper cylindrical portion and the first upper cylindrical portion having a semicircular sixth groove provided below in the same direction as the fifth groove, and having a seventh groove of a semicircle provided in a different direction from the sixth groove. Combined above Below it is characterized in that it comprises a second upper cylindrical portion having a first groove 8 of the class provided in the same direction as the seventh groove.

In addition, the tubular member of the deck plate according to the present invention is formed with a screw hole formed with a screw tab, the lower plate member is formed with a through hole through which the screw can pass, the screw through the through hole in the lower plate member The lower plate member and the cylindrical member are coupled to each other by being fastened.

In addition, when the deck plates of the deck plate according to the present invention are installed side by side in parallel in plurality, the ends of the lower truss member and the upper truss member is bent in order to interconnect adjacent lower truss members and upper truss members, respectively It has a bent portion, it is fastened to each of the bent portion of the lower truss member and the upper truss member is fastened, characterized in that it further comprises a joint portion having a 'c' shape as a whole.

Hereinafter, a deck plate according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 to 5 show a deck plate according to an embodiment of the present invention, Figure 2 is an exploded perspective view of the deck plate according to an embodiment of the present invention, Figure 3 is a cylinder member of the deck plate shown in Figure 2 4 is a view for explaining a state in which the deck plate shown in FIG. 2 withstands bending stress, FIG. 5 is a view showing an example for the joint of the deck plate shown in FIG. will be.

2 to 5, the deck plate 100 according to the embodiment of the present invention is a lower plate member 10, the cylindrical member 20, the lower truss member 30, the upper truss member 40 and an internal filler 50 are included.

The lower plate member 10 has a plate shape and a lower plate through-hole 12 is formed.

The cylindrical member 20 is located on one surface of the lower plate member 10, and has a receiving space therein, and in this embodiment, has a structure that is divided and assembled, and the first lower cylinder portion 21 and the second The lower cylinder part 22, the intermediate cylinder part 23, the 1st upper cylinder part 24, and the 2nd upper cylinder part 25 are included.

The first lower cylinder portion 21 has a cylindrical shape, one surface of which is open, and has a semicircular first groove 212 in one direction.

The second lower cylinder portion 22 is coupled to the upper portion of the first lower cylinder portion 21, and has a semicircular second groove 222 provided in the same direction as the first groove 212 below. The upper side has a semicircular third groove 224 provided in a direction different from the second groove, that is, in the embodiment orthogonal to the first groove 212. The first grooves 212 and the second grooves 222 are combined to form a circular through hole.

The intermediate cylinder portion 23 is coupled to the upper portion of the second lower cylinder portion 22, and has a semicircular fourth groove 232 provided in the same direction as the third groove 224 below. The semicircular fifth groove 234 is provided in a direction orthogonal to the fourth groove. The third groove 224 and the fourth groove 232 are combined to form a circular through hole.

The first upper cylindrical portion 24 is coupled to the upper portion of the intermediate cylindrical portion 23, and has a semicircular sixth groove 242 provided in the same direction as the fifth groove 234 below the upper cylindrical portion 23. The semicircular seventh groove 244 is provided in a direction orthogonal to the sixth groove. The fifth groove 234 and the sixth groove 242 are combined to form a circular through hole.

The second upper cylindrical portion 25 is coupled to the upper portion of the first upper cylindrical portion 24 and has a semicircular eighth groove 252 provided in the same direction as the seventh groove 244 below. The seventh groove 244 and the eighth groove 252 are combined to form a circular through hole.

The lower truss member 30 penetrates the lower portion of the cylindrical member 20 and is made of a material having rigidity against tension and compression, and has a predetermined length. In addition, the lower truss member 30 is disposed to intersect the horizontal lower tension compressive material 32 having a predetermined length and the horizontal lower tension compressive material 32 and have a vertical lower tension compressive material 34 having a predetermined length. )

In addition, the horizontal lower tension compression material 32 and the vertical lower tension compression material 34 pass through a circular through hole formed by the semicircular grooves.

The upper truss member 40 is spaced apart from the lower truss member 30 and penetrates the upper portion of the cylindrical member 20, and is made of a material having rigidity against tension and compression, and has a predetermined length. The upper truss member 40 is disposed to intersect with the horizontal upper tension compressive material 42 having a predetermined length and the horizontal upper tension compressive material 42 and have a vertical upper tension compressive material 44 having a constant length. Is made of.

In addition, the horizontal tension compressor 42 and the vertical tension compressor 44 penetrate a circular through hole formed by a groove having a semicircular shape.

Meanwhile, in the present embodiment, the lower truss member 30 and the upper truss member 40 are provided with reinforcing bars.

The inner filler 50 is filled in the inner space of the cylindrical member 20 to bind the lower truss member 30 and the upper truss member 40 passing through the cylindrical member 20.

The internal filler 50 is flowed while maintaining the flow state at the time of injection, and is filled while surrounding the lower truss member 30 and the upper truss member 40, and then cured as time passes and the lower truss is filled. It is made of a material for firmly fixing the member 30 and the upper truss member 40 to each other. In this embodiment, the inner filler 50 is made of cement mortar made of a mixture of sand, cement and water.

In addition, in the present embodiment, the tubular member 20 is formed with a screw hole 28 having a screw tab, and the lower plate member 10 is formed with a lower plate through-hole 12 through which a screw can pass. The lower plate member 10 and the tubular member 20 are coupled to each other by fastening the screw 14 through the lower plate through-hole 12 in the lower plate member 10.

In addition, when the deck plate 100 is installed side by side in parallel in this embodiment, in order to interconnect the lower truss member 30 and the upper truss member 40 to each other, the lower truss member 30 And the ends of the upper truss member 40 have bent portions 36 and 46 that are bent and bent, and are fastened by being fastened to the bent portions 36 and 46 of the lower truss member 30 and the upper truss member 40, respectively. A joint portion 80 having a 'c' shape is further included.

Deck plate 100 according to an embodiment of the present invention having the structure as described above is used is assembled as follows.

First, a method of assembling the deck plate 100 according to the embodiment of the present invention will be described. The first lower cylinder part 21 is disposed in plural, and the shape of the deck plate 100 is arranged in a lattice shape.

Subsequently, as shown in FIG. 3, the horizontal lower tension compresses 22 are placed on the first grooves 212.

Subsequently, the second lower cylinder parts 22 are positioned above the first lower cylinder parts 21, respectively. Then, the first groove 212 and the second groove 222 are joined to form a circular through hole.

Subsequently, the vertical lower tension compresses 34 are placed on the third grooves 224 provided in the second lower cylinder part 22. Of course, the horizontal lower tension compresses 32 mounted on the first grooves 212 and the vertical lower tension compresses 34 mounted on the third grooves 224 are perpendicular to each other.

Next, the intermediate cylinder portion 23 is positioned above the second lower cylinder portion 22. At this time, the third groove 224 and the fourth groove 232 to face each other, as well as the third groove 224 and the fourth groove 232 is to form a circular through hole.

Subsequently, the horizontal upper tension compresses 42 are placed on the fifth groove 234 provided above the intermediate cylinder portion 23.

Next, the first upper cylindrical portion 24 is positioned above the intermediate cylindrical portion 23. At this time, the fifth groove 234 and the sixth groove 242 face each other, as well as the fifth groove 234 and the sixth groove 242 is to form a circular through hole.

Subsequently, the vertical upper tension compresses 44 are placed on the seventh groove 244 provided above the first upper cylindrical portion 24.

Next, the second upper cylindrical portion 25 is positioned above the first upper cylindrical portion 24. In this case, the seventh groove 244 and the eighth groove 252 face each other, and of course, the seventh groove 244 and the eighth groove 252 form a circular through hole.

Subsequently, an internal filler 50 made of cement mortar made of a mixture of sand, secant and water is injected from above the tubular member 20.

Then, after a certain time, the internal filler 50 is hardened to firmly bind the lower truss member 30 and the upper truss member 40.

That is, the loads of tension and compression applied to the lower truss member 30 and the upper truss member 40 are to be tolerated by the attachment force between the reinforcing bars and the inner filler 50. In detail, the compressive load applied to the lower truss member 30 and the upper truss member 40 is supported by an internal filler and a tensile load is supported by rebar. Shear load and adhesion are borne by the hardening of the internal filler and rebar.

In addition, the bending stress applied to the lower truss member 30 and the upper truss member 40 generates a load such as the band diagram shown in FIG. 4. At this time, the point A of Figure 4 serves as a lever, and the further away from the point A, the load gradually becomes stronger and acts in the vertical direction. Arrow B in Figure 4 shows the direction in which the load is applied.

In addition, the load applied in the vertical direction is to be endured by the internal filler 50 composed of the cement mortar. Cement mortar is capable of withstanding such vertical loads because it is a material that can withstand the load applied in the vertical direction, that is, it is sufficiently strong.

Subsequently, as shown in FIG. 2, the screw 14 is fastened to the screw hole 28 formed in the tubular member 20 through the lower plate through-hole 12 of the lower plate member 10 to lower plate member 10. ) And the cylinder member 20 are combined.

Next, a method of using the deck plate 100 according to the embodiment of the present invention will be described.

First, the steel structure of the building is formed. In other words, the steel structure is constructed by stacking steel frames in accordance with the number of floors of the building being constructed.

Subsequently, the support is bonded between the steel structures forming each layer. At this time, the support may be more sparsely coupled to the number than when using the conventional deck plate (1).

In addition, the direction in which the support is joined is also not limited by the provision of the conventional deck plate 1. That is, the support is to be fixed between the steel structures as easy to install according to the shape of the steel structures.

Subsequently, the multi-directional deck plate 100 according to the present invention having a predetermined size and previously assembled is moved to a floor to be installed by using a crane or the like.

Such a multi-directional deck plate 100 is made in advance in the factory or the like by the method described above. Therefore, the construction site is installed by using a crane or the like, the manpower in the field is reduced, and also because it is strictly manufactured in the factory, the quality is also guaranteed.

Subsequently, the multi-directional deck plate 100 moved to the layer to be installed is seated on the steel frame and the supports forming each layer. In addition, the multi-directional deck plates 100 manufactured in a unit size are laid on the bottom of the structure to fit the planar shape of the structure, and the adjacent multi-directional deck plates 100 are contacted. That is, even if the concrete is placed on the multi-directional deck plate 100, the multi-directional deck plate 100 is in close contact with each other so that the concrete does not leak down to settle the multi-directional deck plate 100.

In addition, the corners of the structure may be finished with a multi-directional deck plate manufactured in the shape of the corner in advance. Since the plan and dimensions of the structure are determined from the design stage of the structure, the unit multi-directional deck plate 100 takes several, and the shape of the lower plate 10 of the multi-directional deck plate 100 to close the corner and Since dimensions can also be determined in advance, based on this, the multi-directional deck plate 100 may be manufactured in advance.

In addition, the coupling of the multi-directional deck plate 100, that is, the coupling between the lower truss member 30 and the upper truss member 40 is made by the joint portion 80. That is, as illustrated in FIG. 4, the joint part 80 may be inserted into the bent parts 36 and 46 provided at the ends of the lower truss member 30 and the upper truss member 40.

Subsequently, concrete is poured on the upper surface of the deck plate 100.

In addition, the concrete is to be smeared evenly between the horizontal lower tension compression material 32, the vertical lower tension compression material 34, the horizontal upper tension compression material 42 and the vertical upper tension compression material (44).

Subsequently, waiting for the concrete to cure is the completion of the floor construction of the desired floor. That is, the construction period is remarkably shortened because it is not necessary to arrange the reinforcing bars before placing concrete on the desired floor, which is a conventional construction method.

In addition, unlike the conventional building method, since the multi-directional deck plate 100 may be simultaneously coupled to a plurality of floors and concrete may be poured, the construction period may be further reduced.

In addition, as described above, the supports may be fixed between the steel structures in various directions according to the steel structure without limiting the direction of the supports fixedly coupled between the steel structures in a certain direction.

In addition, it is not necessary to weld the point where each of the horizontal lower tension compressive material 32 and the vertical lower tension compressive material 34 meet each other, so that each of the horizontal lower tension compressive material 32 and the vertical lower tension compressive material are welded. It is possible to prevent the strength of (34) from decreasing.

On the other hand, in the present embodiment, the internal filler was described as cement mortar consisting of a mixture of sand, cement and water, but is not limited thereto. That is to say, even if the internal filler is formed of a resin that is cured after flow, the same effect is obtained.

As described above, the deck plate according to the present invention has a multi-directional truss structure with excellent stability, and can support the deck plate in any direction in which the direction of the support placed on the lower surface thereof is installed. It can reduce noise because there is no space for sound propagation, and can be installed in buildings such as apartments, and there is no need to connect power reinforcing bars. As a result, the rebars have the effect of maintaining the strength of the truss structure. While the invention has been described with reference to one embodiment shown in the accompanying drawings, it is intended to be illustrative, and those skilled in the art will understand that various modifications and equivalent embodiments are possible from this. Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

Claims (9)

A lower plate member having a plate shape; A cylindrical member positioned on one surface of the lower plate member and having a receiving space therein; A lower truss member penetrating a lower portion of the cylindrical member and made of a material having rigidity against tension and compression, and having a predetermined length; An upper truss member spaced apart from the lower truss member, penetrating an upper portion of the cylindrical member, made of a material having rigidity against tension and compression, and having a predetermined length; And And an inner filling material filling the inner space of the tubular member and enclosing the lower truss member and the upper truss member passing through the tubular member to bind the lower truss member and the upper truss member. . The method of claim 1, The lower truss member, Horizontal lower tension compressive material having a constant length, It is placed to intersect with the horizontal lower tension compressive material, made of a vertical lower tension compressive material having a certain length, The upper truss member, Horizontal upper tension compressive material having a constant length, A deck plate, characterized in that it is placed to intersect the transverse upper tension compressive material, and comprising a vertical upper tension compressive material having a predetermined length. The method of claim 2, The lower truss member and the upper truss member, Deck plate, characterized in that provided with rebar. The method of claim 1, The internal filler, The deck plate is characterized in that the initial flow is maintained while surrounding the lower truss member and the upper truss member, and hardened over time to secure the lower truss member and the upper truss member firmly to each other . The method of claim 4, wherein The internal filler, Deck plate, characterized in that the cement mortar consisting of a mixture of sand, cement and water. The method of claim 4, wherein The internal filler, Deck plate, characterized in that the resin is cured after flow. The method of claim 1, The cylindrical member, A first lower cylinder portion having a first circular groove in one direction at an upper portion thereof; It is coupled to the upper portion of the first lower cylindrical portion, the lower portion has a semicircular second groove provided in the same direction as the first groove, the upper portion has a semicircular third groove provided in a direction different from the second groove A second lower barrel portion; It is coupled to the upper portion of the second lower cylindrical portion, the lower portion has a semi-circular fourth groove provided in the same direction as the third groove, the upper portion has a semi-circular fifth groove provided in a different direction from the fourth groove Intermediate tube part; It is coupled to the upper portion of the intermediate tube, the lower side has a sixth groove of the semi-circle provided in the same direction as the fifth groove, the upper portion having a seventh groove of the semicircle provided in a different direction from the sixth groove Upper cylinder; And And a second upper cylindrical portion coupled to an upper portion of the first upper cylindrical portion, and below the second upper cylindrical portion having a semicircular eighth groove provided in the same direction as the seventh groove. The method of claim 1, The tubular member is formed with a screw hole with a screw tab formed therein, The lower plate member is formed with a through hole through which the screw can pass, Deck plate, characterized in that the lower plate member and the cylindrical member is coupled to each other by fastening the screw through the through hole in the lower plate member. The method of claim 1, When the deck plates are installed side by side in parallel, in order to interconnect adjacent lower truss members and upper truss members, respectively, An end of the lower truss member and the upper truss member has a curved portion bent, The deck plate, characterized in that the hook portion is fastened to each of the bent portion of the lower truss member and the upper truss member, the joint portion having a 'c' shape as a whole.

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