KR101357005B1 - Deck system for slab improved piping structure - Google Patents

Abstract

The present invention relates to an integrated slab deck system of which the lower structure is shaped into an omega so that the weight of the concrete can be reduced, wherein the integrated slab deck system comprises: a bottom plate forming the lower bottom of a slab deck; lower chord members functioning as longitudinal tensile reinforcing bars; upper chord members functioning as compressive reinforcing bars; lattices integrally fixing the upper chord members and the lower chord members, fixed to the bottom plate, and functioning as shear struts; and omega-type forms installed between the lattices longitudinally arranged on the bottom plate and formed by forming plate members into reversed trapezoids of which the narrow bottom sides are fixed on the bottom plate, wherein the omega-type form has piping grooves formed at the top thereof, formed to be transversely dented at predetermined depths, mounted with piping pipes. According to the present invention, the piping pipes are buried at the lower sides of the upper chord members even if the piping pipes are buried across the omega-type forms so that the amount of concrete usage is not increased by the piping pipes regardless of the thickness of the upper concrete.

Description

Slab deck system with improved piping structure {DECK SYSTEM FOR SLAB IMPROVED PIPING STRUCTURE}

The present invention relates to an integrated slab deck system, and more particularly, to an integrated slab deck system in which an omega-type (Ω) deck has a substructure to reduce the weight of concrete, and to a slab such as an electric wiring pipe and a water supply drainage. The invention relates to an integrated slab deck in which a piping structure is individualized to facilitate embedding of pipes.

In the floor slab of general buildings, truss decks, which use thin steel sheets attached to the bottom of steel wire trusses as formwork and rebar, have been widely used in domestic construction sites for a long time.

The floor slab applying this truss deck has the function to omit temporary supports until concrete curing, compared to conventional reinforced concrete slabs. The advantage is that you can.

On the other hand, when the span of the slab is increased, the thickness of the slab should be increased, but the increase in thickness is directly connected to the weight of the slab. Accordingly, the thickness of the slab is thickened, but several methods are used to actually reduce the concrete amount to a minimum.

Applicant has developed and registered a truss deck weight reduction method that reduces the amount of concrete of the substructure without load by installing an omega formwork on the bottom plate in Korean Patent Registration No. 10-1128446 as a solution for this. have.

Briefly describing the applicant's prior art, the prior art, as shown in Fig. 1, the lower chord 14 is applied to the bottom plate 20 as the host reinforcing bar and the upper chord 12 is applied as the compression reinforcement The lattice 16 which performs the role of a shear strut while fixing the upper chord 12 and the lower chord 14 integrally is fixed.

At this time, the lattice 16 is fixed to the welding projection formed on the bottom plate 20 by welding (for details, see the drawings and detailed description of Patent No. 10-1128446). And between the lattice, the omega formwork is fixed to the bottom plate.

At this time, the fixing method may be applied to various types of fixing method, one of which is inserted into the end of the omega formwork 30 between the weld projection formed on the bottom plate and the end of the lattice 16 to form the omega formwork 30 It is to fix on the bottom plate (20).

The omega formwork 30 is formed by molding the steel sheet into the Ω type using the same material or synthetic resin as the truss deck formwork 20, and the height is approximately 10 cm from the thickness of the slab constructed using a triangular truss deck It is desirable to meet the minimum fire resistance standards by subtracting the degree (10 cm for 20 cm slabs, 15 cm for 25 cm slabs and 20 cm for 30 cm slabs).

If the mutual distance between the left and right walls of the omega formwork (30) is maximized within the limit to secure the concrete covering thickness of the steel wire constituting the steel truss, the angle of the left and right walls depends on the triangular outline shape of the lattice (16). It becomes a trapezoidal form.

Subsequently, when the concrete is poured onto the bottom plate 20 and cured, the conventional omega integral slab tech is formed in which the hollow is formed on the inner surface of the omega formwork 30.

However, such conventional techniques have the following problems.

In other words, electrical pipes are basically buried in the floor slab of the actual building. If necessary, pipes for other purposes (water supply / drainage / heating / ventilation, etc.) may be buried. Hereinafter, such pipes are collectively referred to as a 'pipe pipe'.

When such a pipe is installed in the longitudinal direction of the omega formwork can be installed in the empty space inside the omega formwork, there is no problem, but if it is to be installed in the direction across the omega formwork, It can only be installed across the top of the cover and the top of the current.

That is, as shown in Figure 2, the pipe pipe 40 is buried through the upper portion of the omega formwork 30, the cover 31 and the top of the top (12), accordingly the thickness of the upper concrete 50 Thickening.

Therefore, there is a problem that the effect of the omega-tech developed for the purpose of reducing the amount of concrete is reduced due to the embedding of the piping pipe.

Republic of Korea Patent No. 10-1128446

The present invention has been made to solve the conventional problems as described above, the present invention in the omega slab deck system, even if the pipe pipe is embedded in the direction across the omega formwork, so as not to affect the upper concrete thickness It is to provide a slab deck system with improved piping structure.

According to a feature of the present invention for achieving the above object, the present invention provides an integrated slab deck system, comprising: a bottom plate forming a bottom bottom of the slab deck; Ha Hyun-wa and the role of the reinforcing bar of the slab deck; Sanghyeon and the role of the compression reinforcing bar of the slab deck; A lattice fixed to the bottom plate while integrally fixing the upper chord and the lower chord and serving as a shear strut of the slab deck; It is provided between the lattice arranged in the longitudinal direction on the bottom plate, the plate-like member is formed into an inverted trapezoidal shape is configured to include an omega form die fixed to the bottom plate narrow base: The formwork includes: a cover forming an upper surface which is a long side of a cross-sectional shape of an inverted trapezoidal shape; And a pair of sidewalls extending from both ends of the lid and fixed to the bottom bottom surface, the pair having a relative distance closer to the bottom surface: wherein the lid has a predetermined depth in the transverse direction of the lid; The recess is formed so that the pipe groove is formed so that the pipe pipe can be seated.

In this case, the pipe groove may be continuously formed between adjacent omega formwork, so that the pipe pipe is arranged in a straight line.

The pipe grooves may be formed in a plurality of different depths along the longitudinal direction of the omega formwork.

In addition, the pipe groove may be formed to a depth such that when the pipe pipe is seated, the top height of the pipe pipe is lower than the bottom of the phase present.

On the other hand, the present invention provides an integrated slab deck system, comprising: a bottom plate forming a bottom bottom of the slab deck; Ha Hyun-wa and the role of the reinforcing bar of the slab deck; Sanghyeon and the role of the compression reinforcing bar of the slab deck; A lattice fixed to the bottom plate while integrally fixing the upper chord and the lower chord and serving as a shear strut of the slab deck; It is provided between the lattice arranged in the longitudinal direction on the bottom plate, the plate-like member is formed into an inverted trapezoidal shape is configured to include an omega form die fixed to the bottom plate narrow base: The formwork includes: a cover forming an upper surface which is a long side of a cross-sectional shape of an inverted trapezoidal shape; A pair of side walls extending from both ends of the cover and fixed to the bottom bottom surface, the relative distances being closer to the bottom surface, wherein the pair of side walls allow a pipe pipe to pass therethrough. It includes a slab deck system with an improved piping structure in which the plumbers are respectively formed in opposite directions.

In this case, the hollow pipe having a diameter corresponding to the diameter of the plumbing hole, it may be configured to further include an insertion tube which is inserted between the pair of plumbing holes to allow the pipe pipe to penetrate.

The pipe hole may be continuously formed between adjacent omega dies, and the pipe pipe may be formed to penetrate in a straight line.

In addition, a plurality of plumbing holes may be formed with different diameters along the longitudinal direction of the omega formwork.

And it may be configured to further include a stopper for shielding the plumbing pipe is not piped.

In the slab deck system with improved piping structure according to the present invention as described above, even if the pipe pipes are embedded in the direction across the omega formwork, the pipe pipes can be buried under the upper chord, thus affecting the upper concrete thickness. There is an advantage that the concrete usage is not increased due to the pipe pipe.

In addition, in the present invention, since the pipe is buried through the pipe groove or plumber, the operator can position the buried in the correct position, especially when the slab deck system is applied to the modular modular housing method where construction errors are important. There is an advantage to reduce the error.

1 is a perspective view of an omega slab deck system according to the prior art;
Figure 2 is a cross-sectional view showing a state in which the pipe pipe is piped to the conventional omega slab deck system.
Figure 3 is a perspective view showing a first embodiment of the slab deck system according to the present invention.
4 is a cross-sectional view showing a pipe pipe is piped in the first embodiment of the slab deck system according to the present invention.
5 is a perspective view showing a second embodiment of the slab deck system according to the present invention.
6 is an exploded perspective view showing components constituting the second embodiment of the slab deck system according to the present invention.
7 is a cross-sectional view showing a pipe pipe is piped in the second embodiment of the slab deck system according to the present invention.

Hereinafter, a slab deck system having an improved piping structure according to a specific embodiment of the present invention will be described with reference to the accompanying drawings.

Figure 3 is a perspective view showing a first embodiment of the slab deck system according to the present invention, Figure 4 is a cross-sectional view showing a pipe pipe is piped to the first embodiment of the slab deck system according to the present invention.

Basically, the slab deck system according to the present invention is provided with a bottom plate and a top chord, a top chord, a bottom chord and a lattice of the same shape and coupling structure as the bottom plate and the top chord, the bottom chord and the lattice disclosed in Korean Patent No. 10-1128446. .

That is, as shown in FIG. 3, the lower chord 220 is applied to the bottom plate 100 as the host reinforcing bar and the upper chord 210 is applied to the compressed rebar and the upper chord 210 and the lower chord 220 The lattice 230 which performs the role of the shear strut while fixing the integrally is fixed.

At this time, the lattice 230 is preferably fixed by welding to the welding projection formed on the bottom plate (100). And between the lattice 230, it is preferable that the omega formwork 300 is fixed to the bottom plate (100).

At this time, the fixing method may be applied to various types of fixing methods, one of which is inserted into the end of the omega formwork 300 between the end of the weld projection formed in the bottom plate 100 and the end of the lattice 230, the omega formwork ( 300 is fixed on the bottom plate 100.

The omega formwork 300 is formed by using the same material or synthetic resin as the bottom plate 100 in the form of a steel sheet in the Ω, the height of the coating thickness of the reinforcing bar in the thickness of the slab constructed using a triangular truss deck It is set in consideration.

If the mutual distance between the left and right walls of the omega formwork is maximized within the limit to secure the concrete covering thickness of the steel wire constituting the steel truss, the angle of the left and right walls is inverted trapezoidal shape according to the triangular outer shape of the Lattice 230. Becomes

On the other hand, in the slab deck system according to the first embodiment of the present invention, the pipe groove 410 is formed in the cover 310 of the omega formwork 300.

The pipe groove 410 is formed to be recessed to a predetermined depth in the transverse direction of the cover 310 so that the pipe pipe 400 is seated, preferably as shown in Figure 3, adjacent omega type Continuously formed between the formwork 300, it is formed so that the pipe pipe 400 can be arranged in a straight line.

In addition, the pipe grooves 410 are formed in a plurality along the longitudinal direction of the omega formwork 300, it is preferable to allow a plurality of pipe pipes 400 can be installed in various locations depending on the site situation. Do.

And the depth of the pipe groove 410 may be configured in a variety of forms, preferably to a depth that can be moved to the pipe pipe 400 accumulated in the pipe groove 410 below the upper current 210. Is formed.

This is to prevent the thickness of the upper concrete due to the piping of the pipe pipe 400 becomes thick.

A first embodiment of the slab deck system according to the present invention is shown in FIG. 4 in which a plumbing pipe is installed and concrete is poured.

As shown in this, the pipe pipe 400 is placed in the pipe groove 410 of the top of the omega formwork 300, between the omega formwork 300 through the lower portion of the upper current 210 It is seated in the pipe groove 410 of the adjacent omega formwork 300.

Therefore, the thickness of the upper concrete 500 due to the piping of the pipe pipe 400 is the same as before the pipe pipe 400 is embedded.

Hereinafter, a second embodiment of the slab deck system according to the present invention as described above will be described in detail with reference to the accompanying drawings.

5 is a perspective view showing a second embodiment of the slab deck system according to the present invention, Figure 6 is an exploded perspective view showing the components constituting the second embodiment of the slab deck system according to the present invention, Figure 7 2 is a cross-sectional view showing a state in which a pipe is piped in a second embodiment of the slab deck system according to the present invention.

The slab deck system according to the second embodiment of the present invention has the same bottom plate, upper chord, lower chord and lattice structures as the slab deck system according to the first embodiment described above.

That is, as shown in FIG. 5, the lower chord 220 applied to the bottom plate 100 as the owner reinforcing bar and the upper chord 210 applied to the compressed rebar, and the upper chord 210 and the lower chord 220. The lattice 230 which performs the role of the shear strut while fixing the integrally is fixed. And the fixing of the lattice 230 is preferably fixed by welding to the welding projection formed on the bottom plate (100).

In addition, the omega formwork 300 is fixed to the bottom plate 100 between the lattice 230. At this time, the fixing method of the omega formwork 300 is as described above.

The omega formwork 300 is set in consideration of the thickness of the tensile reinforcement in the thickness of the slab constructed using a triangular truss deck height, the mutual spacing of the left and right walls of the omega formwork 300 is a steel wire truss If the maximum length within the limit to ensure the concrete coating thickness of the steel wire to constitute the angle of the left and right walls becomes inverted trapezoidal shape according to the triangular outer shape of the lattice is also the same as the first embodiment of the present invention.

On the other hand, in the second embodiment of the slab deck system according to the present invention, a pair of plumbing holes 420 are formed in the side wall 320 facing the omega formwork 300.

The pipe hole 420 is a through hole on the side wall 320 to allow the pipe pipe 400 to pass through the pipe pipe 400 in consideration of the diameter of the pipe pipe 400 so that the pipe pipe 400 can freely pass therethrough. do.

At this time, the plumbing hole 420 is continuously formed between the adjacent omega formwork 300, as shown in Figure 5, it is preferable that the pipe pipe 400 is formed so as to penetrate in a straight line. Do.

In addition, the plumbing hole 420 is formed in a plurality along the longitudinal direction of the omega formwork 300, it is preferable to allow a plurality of pipe pipes 400 can be installed in various locations depending on the site situation. In addition, it is also possible to be formed in a variety of sizes so that various types of plumbing pipe can be properly arranged as needed.

On the other hand, the slab deck system according to the second embodiment of the present invention, as shown in Figure 6, the insertion pipe 430 and the stopper 450 further comprises as an accessory.

At this time, the insertion tube 430 is a hollow pipe having a diameter corresponding to the diameter of the plumbing hole 429, sandwiched between the plumbing holes 420 formed opposite to both side walls 320 of the omega formwork 300 The pipe pipe 400 penetrates through the insertion tube 430 to prevent the concrete 500 placed on the outer surface of the omega formwork 300 from being introduced into the omega formwork 300. It is to.

In addition, the stopper 450 is to prevent the plumbing pipe 420 that is not piped to the actual plumbing pipe 400 among the plumbing holes 420 in which a plurality is formed, and the concrete 500 poured through the plumbing pipe 420 is It is to prevent the inflow into the omega formwork 300.

In the second embodiment of the slab deck system according to the present invention, a pipe pipe is installed and concrete is shown in FIG. 7.

As shown in this, the pipe pipe 400 is placed on the intubation tube 430 penetrating through the side wall 320 of the omega formwork 300, an omega type adjacent through the lower portion of the upper current 210 It passes through the plumbing hole 420 of the formwork 300.

Therefore, in the second embodiment of the present invention, the thickness of the upper concrete 500 due to the piping of the pipe pipe 400 is the same as before the pipe pipe 400 is embedded.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

For example, the present invention may be implemented by applying the first and second embodiments as described above in combination.

That is, the cover of the omega formwork is formed with a pipe groove for piping the pipe pipe, a pipe hole is formed on the side wall, various constructions such as the diameter of the pipe pipe or pipe position, pipe spacing, relative position of the upper and lower chords And according to the design environment it is also possible to selectively select any one of the piping groove or plumber at the construction site to enable the piping pipe.

The present invention relates to an integrated slab deck system that forms a substructure with an omega-type deck to reduce concrete weight, and according to the present invention, even if the pipe pipe is buried in a direction crossing the omega-type die, Since the pipe can be embedded, there is no effect on the upper concrete thickness, there is an advantage that the concrete usage is not increased due to the pipe pipe.

100: bottom plate 210: phase present
220: low current 230: Lattice
300: omega formwork 310: cover
320 side wall 400 pipe pipe
410: plumbing groove 420: plumber
430: insertion tube 450: stopper
500: concrete

Claims (9)

In an integrated slab deck system,
A bottom plate forming a bottom bottom of the slab deck;
Ha Hyun-wa and the role of the reinforcing bar of the slab deck;
Sanghyeon and the role of the compression reinforcing bar of the slab deck;
A lattice fixed to the bottom plate while integrally fixing the upper chord and the lower chord and serving as a shear strut of the slab deck; And
It is provided between the lattice arranged in the longitudinal direction on the bottom plate, and comprises an omega formwork in which the plate-shaped member is formed into an inverted trapezoidal shape, the narrow bottom of the inverted trapezoid is fixed to the bottom plate:
The omega formwork,
A cover forming an upper surface which is a long side of a cross-sectional shape of an inverted trapezoidal shape;
A pair of sidewalls extending from both ends of the cover and fixed to the bottom bottom surface, the pair of side walls being formed closer to the bottom surface with a relative distance:
On the pair of side walls,
Plumbing pipes are formed in opposite directions so that pipe pipes can pass through:
The hollow pipe having a diameter corresponding to the diameter of the plumbing pipe, the slab deck system with improved piping structure, characterized in that it comprises an insertion pipe which is inserted between the pair of plumbing pipes to allow the pipe pipe to penetrate.
delete The method of claim 1,
The plumber,
Slab deck system with improved piping structure, characterized in that it is formed continuously between adjacent omega formwork, so that the pipe pipe can be arranged to pass through in a straight line.
The method according to claim 1 or 3,
The plumber,
Slab deck system with improved piping structure, characterized in that the plurality is formed with a different diameter along the longitudinal direction of the omega formwork.
5. The method of claim 4,
Slab deck system with improved piping structure, characterized in that the piping pipe further comprises a stopper for shielding the plumbing pipe is not piped.
delete delete delete delete

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