KR101609616B1 - Steel horizontal assembly for forming a hollow slab - Google Patents

Abstract

The present invention relates to a steel-frame horizontal assembly for the formation of a hollow slab. The present invention comprises: an asymmetric I-shaped steel frame in which the width of a lower flange is bigger than the upper flange; a wire member for an upper slab, including a support fixing part in an end part of a body part so that the body part stays away from the upper flange; a deck plate for a lower slab, placed in the lower flange; and a light hollow body placed between the wire member and the deck plate. The support fixing part of the wire member comprises: a separation support part separating the body part and the upper flange of the I-shaped steel frame while being bent downward from the end part of the body part; a hanging fixing part forming a concave groove, into which an outer end part of the upper flange is horizontally inserted, while touching the separation support part; and an inducing part bent in the end part of the hanging fixing part to induce the upper flange to be inserted into the concave groove.

Description

Technical Field [0001] The present invention relates to a steel horizontal assembly for forming a hollow slab,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a steel frame horizontal assembly for forming a hollow slab, and more particularly, to a combined structure of a lightweight shear reinforcement for weight reduction of a slab while constructing a double structure of an I-type steel frame and a slab .

The hollow slab structure can reduce the weight of the horizontal structure by omitting the concrete of the neutral axis portion having a small structural function at the cross section of the slab, which is advantageous for high-rise buildings. Moreover, since the amount of concrete pouring can be reduced, It is an environmentally friendly structure.

Since it is not so easy to form a hollow inside the hollow slab structure at the construction site, it is generally manufactured in a half PC type factory and jointed with beams and pillars in the field in general.

However, since the hollow slab PC member manufactured in the factory can not be easily transported, it is not easy to connect between the PC members, and it is not easy to precisely construct the joint between the beam and the column in the field There is a problem that defects such as cracks and leakage on the joints are generated.

Methods for forming a hollow slab directly on site have been studied, for example, an integrated lightweight aggregate for two-way hollow slabs and a two-way hollow slab according to Registration No. 10-1229450 .

The hollow slab structure of the registration number 10-1229450 includes a slab bottom reinforcing bar 210 which is lattice-matched, as shown in FIG. 1; An integral lightweight aggregate (100) installed above the slab bottom reinforcement (210), the lightweight main body (110) being positioned within the lattice space of the slab bottom reinforcement (210); A slab upper reinforcing bar 220 arranged on the upper projection piece 120 of the integrated lightweight aggregate and being latticed; Hooks are formed on upper and lower portions of the support shaft 231 so that the upper claw 232a is caught by the upper slab reinforcement 220 and the lower claw 232b is caught by the side connection piece 130 of the integral lightweight aggregate A fixing hook 230 fixedly restraining the slab upper reinforcing bar 220 and the integral lightweight aggregate 100; A slab concrete 240 to be laid in a thickness such that the slab bottom reinforcing bar 210 and the slab upper reinforcing bar 220 are embedded; And a reinforcing spacer 250 configured to be assembled and connected to the lower reinforcing bar 251 and the upper reinforcing bar 252 by the connecting bolt 253. The reinforcing bar spacer 250 has a connecting bolt 253 And the slab upper reinforcing bar 220 is placed so as to pass through the through hole 151 of the corner connecting piece of the integrated lightweight aggregate and the slab lower reinforcing bar 210 is placed on the lower reinforcing bar 251 of the reinforcing spacer, Is mounted on the upper reinforcing bar 252 of the reinforcing spacer.

The above-described conventional hollow slab structure can be installed in the field, but the structure of the integrated lightweight aggregate 100 is complicated, so that it is difficult to place a concrete concrete between the lightweight main bodies 110, The lightweight body 110 is placed on the upper surface of the lightweight body 110 and the integrated hook 200 is fixed to the upper reinforcing bar 220 by the fixing hook 230 The movement of the lightweight main body 110 can be restrained only if it is placed in the correct position, but it is not easy to precisely align the movement of the lightweight main body 110, 210, and 220 are exposed to the air, they are easily corroded and the durability of the slab is deteriorated.

KR 10-1229450 B1

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a hollow slab which is capable of reducing the weight of the girder member, An object of the present invention is to provide a steel frame horizontal assembly capable of improving the economic efficiency by reducing the amount of material used, improving the workability, and improving the functionality such as interlayer noise.

According to a preferred embodiment of the present invention for solving the above problems, an asymmetric I-shaped steel frame having a lower flange width than an upper flange is provided, and a supporting portion is provided at an end portion of the body portion so that the body portion is spaced apart from the upper flange A deck plate for a lower slab to be placed on the lower flange and a lightweight hollow body placed between the deck plate and the wire member, A retaining portion for separating the upper flange and the body portion of the I-shaped steel frame while being bent downward; a retaining portion for forming a groove for inserting the outer end of the upper flange in a horizontal direction while being engaged with the spacing support portion; And a guide portion bent at an end of the upper flange to guide insertion of the groove of the upper flange A steel horizontal assembly for forming a hollow slab is provided.

At this time, the guide portion of the wire member may further include a support end capable of pressing the upper surface of the lightweight hollow body, and an insertion fixing groove may be further provided on the upper end of the lightweight hollow body so as to correspond to the support end.

According to another aspect of the present invention, there is provided a steel frame horizontal assembly for forming a hollow slab, wherein the web of the I-type steel frame is further provided with a through hole and the lightweight hollow body is fitted and fixed to the through hole.

The steel frame horizontal assemblies may be provided with transverse reinforcing bars or laminates between the opposite I-shaped steel webs to provide a two-way slab structure.

Since the upper flange of the I-shaped steel frame, which is a girder member, is positioned below the steel bar for the slab, the coating thickness is increased, thereby minimizing the occurrence of micro cracks usually occurring in the concrete in the portion where the upper flange is located.

Further, the present invention can fix a lightweight hollow body by using a through-hole of a steel wire member or an I-type steel frame for slab construction, thereby reducing the amount of material used for the steel or concrete as well as the spacer or lightweight hollow body fixing means, To improve the workability, and to improve precision workability and economy.

Further, the present invention has a steel structure, and the exposed surface of the steel is located only at the lower part, so that the amount of the refractory coating and the amount of the anticorrosive paint are greatly reduced, and the control of the noise vibration by the double slab structure, And to expect a structural improvement of.

Further, the present invention reduces the fixed load, thereby reducing the size of the cross-sectional surface of the member, thereby reducing the thickness of the member.

1 is a perspective view showing a hollow slab structure according to the prior art.
2 is an exploded perspective view and a cross-sectional view of an entire steel horizontal assembly according to an embodiment of the present invention.
3 is a partial perspective view showing an embodiment of a wire member which is a constitution of the steel frame horizontal assembly.
Fig. 4 is an explanatory diagram showing a connection relationship between a wire member and an I-beam steel frame in the present invention.
5 is a perspective view illustrating a structure for fixing a lightweight hollow body in the present invention and a state in which a lightweight hollow body is fixed using the same.
6 is an incisional perspective view showing a structure for making the steel horizontal assembly of the present invention have a two-way slab structure.
FIG. 7 is an exploded perspective view of an entire steel horizontal assembly according to another embodiment of the present invention. FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in order to obscure or obscure the technical idea of the present invention due to the detailed description of the known structure in describing the present invention, the description of the structure of the above known structure will be omitted.

The present invention relates to a steel horizontal assembly for forming hollow slabs, comprising an I-beam steel frame 10, a wire member 20 positioned above the I-beam steel frame 10 to construct an upper slab 60a, A deck plate 30 positioned below the steel frame 10 to construct a lower slab 60b and a load placed between the steel wire member 20 and the deck plate 30 to reduce the load of the slab 60 Is made up of a lightweight hollow body (40).

FIG. 2 is a partial perspective view and a cross-sectional view of an entire embodiment of the above-described steel frame horizontal assembly.

The I-beam steel frame 10 is a girder member for supporting the overall load of the horizontal structure such as the slab 60 constructed by the steel frame horizontal assembly. The I-beam steel frame 10 is composed of an upper flange 11 and a lower flange 12, 13 and has an asymmetric shape with a larger width of the lower flange 12 than the upper flange 11 so as to facilitate mounting of the deck plate 30 by the lower flange 12. [

In addition, the I-beam steel frame 10 may be formed with a camber so as to be convex upward to increase rigidity.

3 is a partial perspective view showing an embodiment of the wire member 20 located on the upper portion of the I-beam steel frame 10.

The iron wire member 20 is for constructing the upper slab 60a between the I-shaped steel bars 10 facing each other and includes a body portion 20a which functions as a main structural member of the upper slab 60a And a support rest portion 20b for connection with the I-form steel frame 10. [

The body portion 20a of the iron wire member 20 serves to prevent cracking of the upper slab 60a and minimize sagging by substituting the upper steel wire so that the longitudinal iron wire and the transverse iron wire have a lattice shape.

The supporting portion 20b provided at the end of the body portion 20a is connected and fixed to the upper flange 11 of the I-shaped steel frame 10 and the upper portion of the body portion 20a is separated from the upper flange 11, The position of the flange 11 can be downwardly adjusted to increase the covering thickness of the upper flange 11 and the shear reinforcement function of the concrete placed on the upper portion of the upper flange 11, So that microcracks are not generated in the substrate.

3, the supporting portion 20b is bent downward at the end portion of the body portion 20a to separate the upper flange 11 of the I-shaped steel frame 10 from the body portion 20a, And a guiding part 23 folded at the end of the retaining part 22. The guiding part 22 is provided with a supporting part 21,

The upper flange 11 of the I-shaped steel frame 10 is moved downward with respect to the upper slab 60a and the body portion 20a of the wire member 20 buried in the upper slab 60a as described above, And the length thereof is set to be about 20 mm or so and determines the final coating thickness of the upper flange 11.

The hook fixing part 22 is formed to have a groove 22a for inserting the outer end of the upper flange 11 so that the wire member 20 can be fixed to the I-beam steel frame 10.

The groove (22a) allows the upper flange (11) to be inserted into the groove (22a) by utilizing the elastic action of the latch fixing part (22). A guide portion 23 for guiding the outer end of the upper flange 11 is provided at the end of the groove 22a to facilitate the insertion of the groove 22a of the upper flange 11. [ FIG. 4 illustrates a process in which the outer end of the upper flange 11 is inserted into the groove 22a.

A deck plate (30) is mounted on the lower flange (12) of the I-beam steel frame (10). The deck plate 30 forms a lower slab 60b together with the concrete while functioning as a mold for the concrete placed thereon.

The deck plate 30 may have a concavo-convex cross-section, but preferably a flat deck plate is used in which a L-shaped rib 31 is projected upwardly so as to perform integrated behavior with concrete placed on the upper portion .

The lightweight hollow body 40 placed between the wire member 20 and the deck plate 30 is made of a lightweight synthetic resin material and has a double structure in which a slab structure is formed to prevent transmission of noise between layers, The insulation is improved and the horizontal structure is reduced in weight, thereby reducing the dancing of the girder members such as the I-type steel frame 10, thereby achieving the structure of the slim floor, reducing the amount of steel and concrete used, do.

The lightweight hollow body 40 exhibiting the above-mentioned operational effects functions as a concrete molding for forming the upper slab 60a and the lower slab 60b on the other hand. Therefore, the lightweight hollow body 40 installed to be spaced apart from the upper surface of the deck plate 30 is fixed so that its position is not easily changed by the putting pressure or buoyancy force when the concrete is poured, So that it can be maintained uniformly.

The lightweight hollow body 40 may be fixed by fixing a band member to a spacer 32 fixed to the deck plate 30 and wrapping the lightweight hollow body 40 with the band member. The supporting end 24 is further provided on the guide portion 23 of the described wire member 20 and the supporting end 24 is pressed against the upper surface of the lightweight hollow body 40, 24 so that the lightweight hollow body 40 sandwiched therebetween can not easily move.

5 shows an example of a wire member 20 having a support end 24 provided on a guide portion 23 for fixing the lightweight hollow body 40 and an example of a state in which the lightweight hollow body 40 is fixed Respectively.

5 (a), the support end 24 is inclined downward from the end of the guide portion 23 toward the outside of the I-shaped steel frame 10, that is, toward the lightweight hollow body 40 . 5 (b), the guide 23 is elastically restored while the upper flange 11 is inserted into the groove 22a, thereby pressing the lightweight hollow body 40 placed on the lower portion as shown in FIG. 5 (b).

5C is a side view of the lightweight hollow body 40 in which the insertion fixing groove 41 is elongated and the supporting end 24 of the wire member 20 is inserted into the insertion fixing groove 41 An example is shown. The structure in which the support end 24 is inserted into the insertion fixing groove 41 prevents the lightweight hollow member 40 from moving right and left together with confirming that the lightweight hollow member 40 is located at a predetermined position So that precision construction can be achieved.

The lightweight hollow body 40 is placed between the I-shaped steel frames 10 facing each other so that the concrete between the upper slab 60a and the lower slab 60b and the lightweight hollow body 40 Type concrete beam 50 orthogonal to the I-beam steel frame 10 as shown in FIG. 2 (c).

Therefore, the steel horizontal assembly of the present invention has a two-way slab structure using the I-shaped concrete beam 50 orthogonal to the one-directional slab structure having the I-shaped steel frame 10 as a girder member, The size of the slab 60 may be reduced or the width of the slab 60 may be increased.

FIG. 6 is an exploded perspective view showing an example in which the two-way slab structure is formed.

In the two-way slab structure, in the web portion of the I-type concrete beam 50 formed between the angles of the lightweight hollow bodies 40, a transverse reinforcing bar 51 is provided between the opposed webs 13 of the I- Is installed.

The transverse reinforcing bars 51 are formed such that each end is welded to the web 13 of the I-shaped steel frame 10 or the through hole is provided in the web 13 so that the transverse reinforcing bar 51 can be mounted in the through hole. More preferably the reinforcing bar fixing groove 25 is provided in the guide portion 23 of the wire member 20 and the reinforcing bar fixing groove 25 is fixed to the lateral reinforcing bar 51. [

The configuration in which the transverse reinforcing bar 51 is mounted on the reinforcing bar fixing groove 25 provided in the guide portion 23 avoids the troublesome work for forming the welding or the through hole, And also has an advantage of preventing welding deformation or sectional defects from occurring in the I-beam steel frame 10.

In addition, a stranded wire (not shown) for introducing a prestress may be further provided on the web portion of the I-type concrete beam 50.

7 is a perspective view of a steel horizontal assembly to illustrate another embodiment of the present invention.

In the steel frame horizontal assembly according to the above-described embodiment, as the means for preventing the lightweight hollow body 40 from easily deviating from the correct position by the work of pouring or buoyancy of concrete, it is preferable to provide the support end 24 to the wire member 20 However, in the present embodiment, the means for optimizing the section of the I-beam steel frame 10 is used, so that the separate fixing means as described above can be omitted.

The I-beam steel frame 10, which is a girder member for supporting the load of the slab 60, is designed on the basis of the maximum bending moment acting thereon, and the bending stress generated thereby is borne by the upper and lower flanges 11 and 12 . On the contrary, the influence of the cross-sectional size of the web 13 connecting the upper and lower flanges 11 and 12, particularly the middle portion of the web 13, on the flexural stiffness of the member is negligible. Therefore, reducing the cross-sectional size of the web 13 allows the cross-section of the I-beam steel frame 10 to be optimized while reducing the amount of steel used.

To this end, a plurality of through holes 14 are further provided in the web 13 of the I-beam steel frame 10 in this embodiment. The through hole 14 formed in the web 13 suppresses the use of unnecessary steel material to have an optimal cross-sectional shape of the I-beam steel frame 10, but at the same time, as the mounting and fixing means of the lightweight hollow body 40 Function improves workability and precision and enables material reduction.

That is, in the present embodiment, the lightweight hollow body 40 is fitted into the through holes 14 of the respective webs 13 of the I-shaped steel frame 10 opposed to each other, do. At this time, by setting the size of the through hole 14 to correspond to the cross-sectional size of the lightweight hollow body 40, the lightweight hollow body 40 is prevented from floating due to the buoyancy of the concrete The fixing state can not be easily changed even if the operator is careless, and the gap between the upper surface of the deck plate 30 and the upper surface of the deck plate 30 can be accurately maintained without providing the spacer 32 at the lower portion.

In this embodiment, the transverse reinforcing bars 51 and the stranded wires are provided in the web portion of the I-type concrete beam 50 to have a two-way slab structure, which is not different from the previous embodiment.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the invention is not limited to the disclosed embodiments, but, on the contrary, It is obvious that it will be possible to carry out various modifications thereof. It is therefore intended that such modifications are within the scope of the invention as set forth in the claims.

10; I-form steel frame 11; The upper slab
12; A lower slab 13; Web
14; Through hole 20; The wire member
20a; Body portion 20b; Jinggo Government
21; Spacing support 22; [0034]
22a; Groove 23; Guide portion
24; Support end 25; Home
30; Deck plate 31; live
32; Spacers 40; Lightweight hollow body
41; An insertion fixing groove 50; Type I concrete beam
51; Transverse reinforcement 60; Slab
60a; Upper slab 60b; The lower slab

Claims (8)

An asymmetric I-shaped steel frame 10 having a larger width of the lower flange 12 than the upper flange 11 and an asymmetric I-shaped steel frame 10 having a larger width at the end of the body portion 20a such that the body portion 20a is spaced apart from the upper flange 11 A lower slab deck plate 30 which is mounted on the lower flange 12 and a deck plate 30 which is placed between the iron wire member 20 and the deck plate, Lightweight hollow body 40,
The supporting part 20b of the wire member 20 is bent downward at the end of the body part 20a to be spaced apart from the upper flange 11 of the I- And a hook fixing part 22 for forming a groove 22a for inserting an outer end of the upper flange 11 in a horizontal direction while being engaged with the spacing support part 21, And a guide portion 23 that is bent at the end portion to guide insertion of the groove 22a of the upper flange 11,
The guide portion 23 of the wire member 20 is further provided with a support end 24 formed to be sloped downward outward with respect to the I-beam steel frame 10. The support end 24 is connected to the lightweight hollow body 40, And the position of the lightweight hollow body (40) is fixed by pressing the upper surface of the hollow hollow body (40). delete The lightweight hollow body according to claim 1, wherein an insertion fixing groove (41) for inserting the supporting end (24) is provided at an upper end of the lightweight hollow body (40), and a supporting end (24) Characterized in that the position of the lightweight hollow body (40) is fixed. delete 2. A steel horizontal assembly for forming a hollow slab according to claim 1, characterized in that a further lateral reinforcement (51) is provided between each of the opposed webs (13) of the I-form steel frame (10). The apparatus according to claim 5, wherein the guide portion (23) of the wire member (20) further comprises a reinforcing bar fixing groove (25), and the reinforcing bar fixing groove (25) Steel horizontal assembly for hollow slab formation. The assembly as claimed in any one of the preceding claims, wherein the deck plate (30) is a flat deck plate (30) with an upwardly projecting ribbed rib (31). The steel horizontal assembly for forming a hollow slab according to claim 1, wherein the I-shaped steel frame (10) has a camber formed to be convex upward.

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