KR101795510B1 - Deck panel for construction - Google Patents

Abstract

The deck plate, the truss girder, and the reinforced portion are improved in structural strength and coupling relation to provide a modular deck panel. The deck panel can be used on the side of the building during the construction, And at the same time reduce the generation of various kinds of construction waste materials, thereby making it possible to design environmentally friendly buildings.

Description

[0001] DECK PANEL FOR CONSTRUCTION [0002]

The present invention relates to a building deck panel capable of shortening the air by improving the structure.

The most widely used construction method is reinforced concrete structure because reinforced concrete structure is good in stiffness, durability, fire resistance, vibration resistance, and sound insulation.

Since the conventional formwork method used for building such a reinforced concrete structure is complicated in process, it is difficult to disassemble the formwork and formwork, and a large amount of waste material is generated. Therefore, the method using the deck panel is now being applied to the floor or ceiling slab .

The deck panel includes a deck plate and a truss girder.

The deck plate serves as a formwork and serves as a surface of a concrete structure after the construction, and may be formed of a zinc steel sheet to prevent corrosion due to concrete. A plurality of such deck plates may be connected to form a floor or a ceiling of a building.

The truss girder includes a lattice portion having a predetermined waveform and a fixing portion for firmly fixing the lattice portion. The lattice portion and the fixing portion may be formed as reinforcing bars and fastened on the deck plate.

These deck panels are made in a certain place and are transported to the building site and placed on the floor or ceiling of the building. After the concrete is laid, the building structure is formed after a certain period of curing process.

However, such a conventional deck panel has a problem that it is limited to use only on a slab of a floor or ceiling of a building, and there is a drawback that the air of the entire building is long.

Further, since the deck plate and the truss girder are assembled by welding, the assembling time is somewhat long, and assembly tolerance can be caused.

In addition, the construction method using a conventional deck panel involves a site laying process for connecting each deck panel. This is because there is a problem that the quality of the construction depends on the increase in the labor cost, the increase of the material cost, or the skill of the on-site technical work due to the long construction period due to the welding or the reinforcement work.

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 improve the structure of the deck panel and to modularize the structure of the deck panel to shorten the air of the reinforced concrete building, And an eco-friendly architectural deck panel capable of minimizing construction waste.

According to an aspect of the present invention, there is provided a plate deck plate comprising: a plate-like upper deck plate having at least one pair of rib-shaped ribs whose openings are opposed to each other; A top truss girder including a pair of lattices formed in a predetermined waveform and in which bent portions bent at a lower pitch are disposed in the rib; And an upper surface reinforcement portion coupled to the upper surface deck plate or the upper surface truss girder.

In addition, the bent portion and the pair of ribs may be combined by an electric pressure point method.

The upper surface truss girder may further comprise: an upper current coupled to an upper pitch of the pair of lattices and fixing the pair of lattice upper portions; And a pair of lower ends spaced apart from the rib by a predetermined distance and disposed in parallel with each other under the pair of lattices.

The upper surface deck plate may further include an upper surface coupling part protruding outside the upper surface deck plate, the upper surface coupling part being formed in a C shape and having a free end spaced apart from the upper surface deck plate.

The upper surface reinforcement portion may include a fifth upper surface stiffener coupled to the free end of the upper surface coupling portion and having opposite ends coupled to the pair of lower ends, respectively.

The upper surface reinforcing portion may include a second upper surface stiffener coupled to the free end of the upper surface coupling portion and the fifth upper surface stiffener at the current time.

Also, at least two or more of the pair of lattices may be arranged parallel to the upper surface deck plate.

The upper surface reinforcing portion may have one end coupled to an inner side of one of the pair of lattices and the other side of the pair of ribs of the plurality of pair of lattices and the other end is coupled to the other inner side of the pair of lattices and the upper side of the pair of ribs And a plurality of first upper surface stiffeners coupled to the first upper surface stiffener.

The upper surface reinforcing portion may include a pair of third upper surface stiffeners which are coupled to the inner sides of the pair of lattices and the lower side surfaces of the pair of lower lids, respectively, and are vertically disposed with respect to the pair of lower lids.

The upper surface reinforcing portion may include a pair of fourth upper surface stiffeners which are arranged horizontally to each other, one of which is vertically coupled to the upper side of the phase current, and the other of which is vertically coupled to the lower ends of the pair.

According to another aspect of the present invention, there is provided a side deck plate comprising: a plate-shaped side deck plate having at least one pair of rib-shaped ribs whose openings are opposed to each other; A side truss girder including a pair of lattices formed in a predetermined waveform and in which a bending portion bent at a lower pitch is disposed in the rib; And a side reinforcing part coupled to the side deck plate or the side truss girder.

In addition, the bent portion and the pair of ribs may be combined by an electric pressure point method.

The side truss girder may further comprise: a top current coupled to an upper pitch of the pair of lattices and fixing the pair of lattice upper portions; And a pair of lower ends spaced apart from the rib by a predetermined distance and disposed in parallel with each other under the pair of lattices.

The upper surface of the side deck plate may have a U-shaped cross-section, and the free end may be spaced apart from the upper surface of the side deck plate.

The side reinforcing portion may include a fifth side reinforcing member coupled to the free end of the side coupling portion and having opposite ends coupled to the pair of lower ends, respectively.

The side reinforcing portion may include a free end of the side coupling portion and a second side reinforcement joined to the fifth side reinforcement.

In addition, at least two or more of the pair of lattices may be arranged parallel to the side deck plate.

The side reinforcing portion may have one end coupled to the inside of the one of the pair of lattices and the pair of the ribs of the plurality of the pair of lattices and the other end to the inside of the other pair of lattices and the other side of the pair of ribs And a plurality of first lateral stiffeners coupled to the first lateral stiffeners.

The side reinforcing portion may include a first coupling portion coupled to the inner side of the pair of lattices and the lower side of the pair of lower lids, And a third side stiffener including a pair of third side stiffeners.

The side reinforcing parts are horizontally disposed one above the other, one of which is vertically coupled to the upper side of the upper current side, the other is vertically coupled to the lower side of the pair of lower side plates, And a pair of fourth side stiffeners including a plurality of second side stiffeners.

The present invention can provide a deck panel having excellent structural rigidity such that it can be disposed not only on the upper surface but also on the side surface of the compartment.

In addition, the present invention has an advantage that a deck panel having a low height is provided, so that the internal space of a building can be widely utilized.

Further, the present invention can provide a deck panel in which the construction period is shortened and the construction waste material can be reduced.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1A is a perspective view of a top surface deck panel according to an embodiment of the present invention; FIG.
1B is a partially enlarged view of a top surface deck panel according to an embodiment of the present invention;
1C is an enlarged view of an engaging portion of a deck plate and a truss girder according to an embodiment of the present invention.
1D is a partial view of a top surface deck plate according to an embodiment of the present invention.
Fig. 2 is a further arrangement of a top surface reinforcement according to an embodiment of the invention in Fig. 1b. Fig.
FIG. 3A is a perspective view of a side deck panel according to an embodiment of the present invention; FIG.
3B is a partial enlarged view of a side deck panel according to an embodiment of the present invention;
3C is a partial view of a side deck plate according to an embodiment of the present invention.
FIG. 3D is an enlarged view of an engaging portion of a locking projection and a third side reinforcement according to an embodiment of the present invention;
Figure 4 is a top and bottom side deck panel according to an embodiment of the present invention.
Fig. 5 is a view showing a wall deck panel disposed on one side in Fig. 4; Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Unless defined otherwise, all terms used herein are the same as the generic meanings of the terms understood by those of ordinary skill in the art, and where the terms used herein contradict the general meaning of the term, they follow the definitions used herein.

It is to be understood, however, that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

Unlike the conventional deck panel, the present invention provides a deck panel having a low height and high strength, and the deck panel can be disposed not only on the upper surface but also on the side surface of the building.

Although the basic technical ideas of the top deck panel and the side deck panel are the same, since there are mutual structural differences, the top deck panel and the side deck panel will be described in detail below.

FIG. 1B is a partially enlarged view of a top deck panel according to an embodiment of the present invention. FIG. 1C is a perspective view of a deck plate and a truss girder according to an embodiment of the present invention. FIG. 1D is a partially enlarged view of a top deck plate according to an embodiment of the present invention, and FIG. 2B is a view in which a top surface reinforcing portion according to an embodiment of the present invention is additionally disposed in FIG. 1B.

The upper surface deck panel 100 according to an embodiment of the present invention may include a top surface deck plate 110, a top truss girder 120, and a top surface reinforcement 130.

The upper surface deck plate 110 may have at least one pair of Ribs 115 arranged in a mutually opposed manner and may be formed as a rectangular plate. Although a total of three pairs of the ribs 115 are shown in the drawing, the present invention is not limited thereto.

Referring to FIGS. 1C and 1D, the rib 115 may be formed by bending the upper surface deck plate 110 or may be coupled to the upper surface deck plate 110.

1D, the upper surface deck plate 110 is formed with a female coupling portion 117a and a male coupling portion 117b at one side and the other side of the long side, And at the construction site. The shape of the male engaging portion 117a and the male engaging portion 117b may be the same as those of the male engaging portion 117b and the female engaging portion 117b. Alternatively, the female engaging portion 117a and the male engaging portion 117b may be press-

Referring to FIG. 1d, the upper surface deck plate 110 may have a locking protrusion 119 disposed at the center in the longitudinal direction.

Although the upper surface deck plate 110 is not shown, the embossed portion may be formed at regular intervals to improve mechanical strength. Such an embossing portion may be formed by pressing the upper surface deck plate 110 of the metal material.

In addition, the upper surface deck plate 110 may be formed of a zinc plate or a zinc-plated metal plate to prevent corrosion caused by the concrete placed after being disposed in the dry matter.

The upper surface truss girder 120 may include a pair of lattices 121, an upper current 122 or a lower current 123.

Specifically, the lattice 121 may have a predetermined waveform and may include a bent portion 121a having a lower pitch. When the bent portion 121a is disposed in the rib 115 May be formed as a pair of lattices 121.

Therefore, in the embodiment, the lattice 121 is disposed directly above the upper deck plate 110 to provide a deck panel 100 having a height lower than that of the conventional deck panel 100, The thickness of the concrete slab (not shown) is reduced, and the space efficiency inside the building can be increased.

At least two or more of the pair of lattices 121 may be arranged parallel to the upper deck plate 110. As shown in the figure, a total of three pairs of lattices 121 may be disposed, but the present invention is not limited thereto.

Referring to FIGS. 1C and 1D, the lattice 121 may be formed by bending as a reinforcing bar, and the bent portion 121a and the pair of ribs 115 may be combined with each other by an electric- . The electric pressure point method is to pressurize high-voltage electricity between the bending portion 121a and the rib 115 to increase the mechanical and physical bonding strength and improve the productivity, unlike the conventional bonding method.

The upper surface truss girder 120 may include a phase current 122 coupled to an upper pitch of the pair of lattices 121 and fixing the upper portion of the pair of lattices 121.

The phase current 122 may be coupled between the upper pitches of the pair of lattices 121 as long straight-line reinforcing bars. Such a coupling method may be realized by the above-described electric point method.

The upper surface 122 of the top deck plate 110 protrudes outside the upper deck plate 110 and is formed in a U shape and has a free end connected to the upper surface deck plate 110, As shown in FIG.

The upper surface fastening portion 122a may be disposed to intersect with a side fastening portion 222a or an upper surface fastening portion of another building module (not shown), and an auxiliary stiffener (not shown) may be inserted So that the overall mechanical strength can be improved.

The upper surface truss girder 120 includes a pair of lower ends 123 disposed below each of the pair of lattices 121 and spaced apart from the rib 115 by a predetermined distance and disposed in parallel with each other can do.

A first upper surface stiffener 131 and a third upper surface stiffener 133 which will be described later may be disposed between the rib 115 and the lower side 123, 100 can be further improved.

In addition, each of the lower currents 123 may be coupled to the lower pitch of the pair of lattices 121 as a long straight-line reinforcing bar, and such a coupling method may be implemented by the above-described electric point method.

The upper surface reinforcement 130 may be coupled to the upper surface deck plate 110 and / or the upper surface truss girder 120 to improve the strength of the deck panel 100. The upper surface reinforcement 130 may include a first upper surface stiffener 131, A second upper surface stiffener 132, a third upper surface stiffener 133, a fourth upper surface stiffener 134 or a fifth upper surface stiffener 135.

Each of the top surface reinforcing portions 130 may be formed as a long reinforcing bar or a bent reinforcing bar.

The first upper surface stiffener 131 has one end coupled to the inside of one of the pair of lattices 121 and the pair of the ribs 115, And may be formed in a double bent shape which is coupled to the inside of the other end of the pair of lattices 121 and the side of the pair of ribs 115.

That is, two pairs of lattices 121 disposed at the outermost sides of one upper deck plate 110 are coupled in a straight line shape, and one end and the other end of the first upper surface stiffener 131 intersected with each other are connected to each other And may be formed in a diagonal shape.

One of the first top surface stiffeners 131 may be arranged in a pitch of the waveform of the lattice 121 and a plurality of the first top surface stiffeners 131 may be disposed in the same direction or in correspondence with the adjacent first top surface stiffeners 131 .

The second upper surface stiffener 132 can be engaged with the free end of the upper current 122, the upper surface fastener 122a, and a fifth upper surface stiffener 135 described later, As shown in Fig.

The third upper surface stiffener 133 is coupled to each of the inner sides of the pair of lattices 121 and the lower side of the pair of lower ends 123, As the third upper surface stiffener 133 of the pair.

The third upper surface stiffener 133 may be disposed at equal intervals on the upper deck plate 110 disposed on the entire upper side of the building or may be disposed only on the edge.

The fourth upper surface stiffener 134 is disposed horizontally with respect to one another, one of which is vertically coupled to the upper side of the phase current 122 and the other of which is vertically coupled to the pair of lower ends 123, Four-face stiffener 134, as shown in Fig.

A truss structure auxiliary stiffener 133a may be disposed between the pair of third top surface stiffeners 133 or the pair of fourth top surface stiffeners 134 to improve mechanical strength.

The middle portion of the fifth upper surface stiffener 135 may be coupled to the free end of the upper surface coupling portion 122a and the opposite ends of the fifth upper surface stiffener 135 may be coupled to the pair of lower ends 123, respectively.

That is, the deck panel 100 of the present invention including the top surface reinforcement 130 according to the embodiment of the present invention reduces the void space between the truss girders 120, which is superior in durability And reduce the amount of concrete to be poured, thereby shortening the construction cost and the concrete curing time, and as a result, the construction cost can be reduced.

Here, the rib 115, the lattice 121, the phase current 122, or the bottom current 123 may be formed to be long in parallel with the long side of the upper surface deck plate 110.

The third upper surface stiffener 133, the fourth upper surface stiffener 144 or the fifth upper surface stiffener 135 may be formed parallel to the short side of the upper surface deck plate 110.

In addition, the coupling between the above-described components may be combined with welding or a separate coupling member, but they may be combined by the above-described electric power point method.

Hereinafter, a side deck panel according to an embodiment of the present invention will be described.

FIG. 3A is a perspective view of a side deck panel according to an embodiment of the present invention, FIG. 3B is a partially enlarged view of a side deck panel according to an embodiment of the present invention, FIG. 3C is a side deck panel according to an embodiment of the present invention, FIG. 4 is an exploded perspective view of a top deck panel and a side deck panel according to an embodiment of the present invention. FIG. And FIG. 5 is a view in which a wall deck panel is disposed on one side in FIG.

The side deck panel 200 according to an embodiment of the present invention may include a side deck plate 210, a side truss girder 220, and a side reinforcing portion 230.

The side deck plate 210 may include at least one pair of ribs 211 having openings arranged opposite to each other, and may be formed as a rectangular plate. Although two pairs of the pair of ribs 211 are shown in the drawing, the present invention is not limited thereto.

3B and FIG. 3C, the ribs 211 may be formed by bending the side deck plate 210 or may be coupled to the side deck plate 210. In addition, as shown in FIG.

In addition, the side deck plate 210 may be formed of a zinc sheet or a zinc-plated metal plate to prevent corrosion caused by concrete placed after being disposed in the dry matter.

3C, the side deck plate 210 has an arm engaging portion 217a and a male engaging portion 217b formed on one side and the other side of the long side, And at the construction site. The shape of the male engaging portion 217a and the male engaging portion 217b may be the same as those of the female engaging portion 217a and the female engaging portion 217b. Alternatively, the female engaging portion 217a and the male engaging portion 217b may be pressurized by an electric pressure pointing method or alternately spaced apart as shown in FIG. 3c (d).

Referring to FIGS. 3B and 3D, the side deck plate 210 according to the embodiment may have a locking protrusion 219 formed at a central portion thereof in the long-side direction.

The latching protrusion 219 may be formed by bending the side deck plate 210 or may be coupled to the side deck plate 210 separately. However, in consideration of the strength reinforcement of the side deck plate 210, .

3A through 4, the supporting hooks 219a are fitted in the locking protrusions 219 so that the third side stiffeners 233 to be described later are spaced apart from the side deck plates 210 at regular intervals And can maintain a constant spacing.

Also, although the side deck plate 210 is not shown, the embossed portion may be formed at regular intervals to improve the mechanical strength. Such an embossing portion may be formed by pressing the side deck plate 210 of the metal material.

The side truss girder 220 may include a pair of lattices 221, a top current 222 or a bottom current 223.

Specifically, the lattice 221 may have a predetermined waveform and may include a bent portion 221a bent at a lower pitch. The bending portion 221a may be formed in the rib 211, May be formed as a pair of lattices 221.

Therefore, in the embodiment, the lattice 221 is disposed directly above the upper deck plate 210 to provide a deck panel 200 having a height lower than that of the conventional deck panel 200. As a result, The thickness of the concrete slab is reduced and the space efficiency inside the building can be increased.

At least two or more of the pair of lattices 221 may be disposed parallel to the side deck plate 210 and two pairs of lattices (not shown) may be disposed on one side deck plate 210 221 may be disposed.

In addition, the lattice 221 may be formed by bending as a reinforcing bar, and the bending portion 221a and the pair of ribs 211 may be coupled by an electric pressure-pushing method. The electric pressure pointing method is to pressurize high-voltage electricity between the bending portion 221a and the rib 211 to increase the mechanical and physical bonding strength unlike the conventional bonding method.

The side truss girder 220 may include an upper phase current 222 coupled to an upper pitch of the pair of lattices 221 and fixing the upper side of the pair of lattices 221.

The phase current 222 may be coupled between the upper pitches of the pair of lattices 221 as a long straight line reinforcing bar, and such a coupling method may be realized by the above-described electric point method.

The side plates 222 are formed in a U-shape and protrude outward from the side deck plate 210. The side plates 222 are formed with a free end spaced apart from the side deck plate 210, As shown in FIG.

The side fastening portion 222a may be disposed so as to intersect with the upper side fastening portion 122a or the side fastening portion of another building module (not shown), and an auxiliary stiffener (not shown) may be inserted So that the overall mechanical strength can be improved.

The side truss girder 220 may include a pair of lower legs 223 spaced apart from the rib 211 by a predetermined distance and disposed in parallel to each other below the pair of lattices 221 .

The first side stiffener 231 and the third side stiffener 233 may be disposed between the rib 211 and the lower side 223, 200 can be further improved.

In addition, each of the lower currents 223 may be coupled to the lower pitch of the pair of lattices 221 as a long straight-line reinforcing bar, and this coupling method may be implemented by the above-described electric point method.

On the other hand, as a conventional construction method, concrete pouring using a deck panel on the side of a building is not used. This is because conventional deck panels can not tolerate the load of such concrete because the load of the concrete being laid is greater at the side than at the top.

However, since the side deck panel 200 of the present invention is excellent in mechanical strength, it can be applied to a side surface of a building, which can shorten air and efficiently secure an internal space.

Specifically, the side reinforcement 230 may be coupled to the side deck plate 210 and / or the side truss girder 220 to improve the strength of the deck panel 200. The first side reinforcement 231 The second lateral stiffener 232, the third lateral stiffener 233, the fourth lateral stiffener 234 or the fifth lateral stiffener 235.

Each of the side reinforcing portions 230 may be formed as a long reinforcing bar or a bent reinforcing bar.

One end of the first side stiffener 231 is coupled to the inside of one of the pair of lattices 221 and the pair of the ribs 211, And may be formed in a double bent shape that is coupled to the inside of the other end of the pair of lattices 221 and the pair of ribs 211.

That is, the pair of lattices 221 disposed at the outermost sides of the one side deck plate 210 are coupled to each other in a straight line shape, and the one end and the other end of the first side stiffener 231 intersect with each other And may be formed in a diagonal shape.

One of the first lateral stiffeners 231 may be arranged in a pitch of the waveform of the lattice 221 and a plurality of the first lateral stiffeners 231 may be disposed in the same direction or in the same direction as the adjacent first lateral stiffeners 231 .

The second side stiffener 232 can be engaged with the free end of the phase current 222, the side fastening portion 222a and a fifth side stiffener 235 described later, As shown in Fig.

The third side stiffener 233 is coupled to each of the inside of the pair of lattices 221 and the lower side of the pair of lower ends 223, The third side stiffener 233 can be disposed in the vicinity of the second side surface of the second side surface.

The third side stiffener 233 may be disposed at equal intervals on the upper deck plate 210 disposed on the entire upper side of the building or may be disposed on the edge only. However, as shown in consideration of the load of the concrete, It is preferable to arrange a plurality of them.

In addition, the third side stiffener 233 may include a U-shaped first engaging portion 233a on the outer side of the side deck plate 210. The first engaging portion 233a intersects the second engaging portion 234a of the fourth side reinforcing member 234, which will be described later, of the adjacent side surface, so that the mechanical strength of the deck panel 200 can be improved.

The fourth side stiffener 234 is disposed horizontally with respect to one another, one of which is vertically coupled to the upper side of the phase current 222 and the other of which is vertically coupled to the pair of lower ends 223, 4 side stiffeners 234 as shown in FIG.

In addition, the fourth side stiffener 234 may include a C-shaped second coupling portion 234a outside the side deck plate 210. The second engaging portion 234a intersects the first engaging portion 233a of the third side reinforcing member 233 on the adjacent side surface to improve the mechanical strength of the deck panel 200. [

In order to improve mechanical strength between the pair of third side stiffeners 233 or the pair of fourth side stiffeners 234, truss-structured auxiliary stiffeners 233b and 234b may be disposed, respectively .

The fifth side stiffener 235 may be coupled to the free end of the side coupling part 222a and the opposite ends of the fifth side stiffener 235 may be coupled to the pair of lower ends 223, respectively.

That is, the side deck panel 200 of the present invention including the side reinforcement 230 according to the above-described embodiment of the present invention forms a general wall form through mutual coupling through the male and female spaces between the truss girders 220 And thus the durability of the building is improved compared with the prior art, and at the same time, the construction cost can be reduced by shortening the air.

Here, the rib 211, the lattice 221, the phase current 222, or the bottom current 223 may be formed long in parallel to the long side of the side deck plate 210.

The third side stiffener 233, the fourth side stiffener 244 or the fifth side stiffener 235 may be formed parallel to the short side of the side deck plate 210.

In addition, the coupling between the above-described components may be combined with welding or a separate coupling member, but they may be combined by the above-described electric power point method.

As shown in Fig. 4, after the upper deck panel 100 and the side deck panel 200 described above are disposed, the other compartment buildings where the deck panels 100 and 200 described in the present invention are disposed are combined As shown in FIG. 5, a wall deck panel may be disposed on the side of the side wall to place the concrete.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined by the appended claims. Range and its equivalent range.

100: upper surface deck panel 110: upper surface deck plate
115: a pair of ribs 120: upper surface truss girder
121: A pair of Lattice 122: Phase Current
123: a pair of bottom faces 130: upper face reinforcement part
131: first upper surface stiffener 132: second upper surface stiffener
133: third upper surface stiffener 134: fourth upper surface stiffener
135: fifth upper surface stiffener 200: side deck panel
210: side deck plate 211: a pair of ribs
220: side truss girder 221: a pair of lattices
222: Phase current 223: A pair of bottom current
230: side reinforcing part 231: first side reinforcing part
232: second side stiffener 233: third side stiffener
234: fourth side stiffener 235: fifth side stiffener

Claims (20)

A plate-shaped upper surface deck plate in which at least one pair of rib-shaped ribs whose openings are arranged to face each other are arranged;
A top truss girder including a pair of lattices formed in a predetermined waveform and in which bent portions bent at a lower pitch are disposed in the rib; And
And an upper surface reinforcing portion coupled to the upper surface deck plate or the upper surface truss girder,
Wherein the upper surface truss girder comprises an upper phase current coupled to an upper pitch of the pair of lattices and fixing the upper portion of the pair of lattices and an upper phase current that is parallel to the ribs at a predetermined interval, A pair of bottom currents,
Wherein the top deck panel further comprises a top surface coupling protruding outside the top deck plate, the top deck panel being formed in a U-shape and having a free end spaced apart from the top deck plate.
The method according to claim 1,
Wherein the bent portion and the pair of ribs are coupled by an electric pressure point method.
delete delete The method according to claim 1,
The upper surface-
And a fifth upper surface stiffener coupled to the free end of the upper surface coupling portion and having opposite ends coupled to the pair of lower ends, respectively.
6. The method of claim 5,
The upper surface-
And a second upper surface stiffener joined to the free end of the upper surface fastener and the fifth upper surface stiffener at the current time.
The method according to claim 1,
Wherein at least two of the pair of lattices are arranged parallel to the upper surface deck plate.
8. The method of claim 7,
The upper surface-
One end of the lattice is coupled to the inner side of the one of the pair of lattices and the pair of the ribs and the other end is coupled to the other inner side of the other lattice and the upper side of the pair of ribs, A building deck panel comprising a top surface stiffener.
The method according to claim 1,
The upper surface-
And a pair of third upper surface stiffeners joined to each of the inner side of the pair of lattices and the lower side of the pair of lower ends, the pair of third upper surface stiffeners being disposed perpendicularly to the pair of lower ends.
The method according to claim 1,
And a pair of fourth upper surface stiffeners disposed horizontally relative to each other, one of which is vertically coupled to the upper side of the phase current, and the other of which is vertically coupled to the pair of lower side currents.
A plate-shaped side deck plate in which at least one pair of rib-shaped ribs whose openings are arranged so as to face each other are arranged;
A side truss girder including a pair of lattices formed in a predetermined waveform and in which a bending portion bent at a lower pitch is disposed in the rib; And
And a side reinforcing portion coupled to the side deck plate or the side truss girder,
Wherein the side truss girder comprises an upper phase current coupled to an upper pitch of the pair of lattices and fixing the upper portion of the pair of lattices and an upper phase current that is parallel to the ribs at a predetermined distance from the lower side of the pair of lattices A pair of bottom currents,
The side deck panel of claim 1, wherein the side deck panel further comprises a side coupling part protruding outside the side deck plate, the side deck panel being formed to have a U-shape and having a free end spaced apart from the side deck plate.
12. The method of claim 11,
Wherein the bent portion and the pair of ribs are coupled by an electric pressure point method.
delete delete 12. The method of claim 11,
The side reinforcing portion
And a fifth side stiffener coupled to the free end of the side coupling portion and having opposite ends coupled to the pair of lower ends, respectively.
16. The method of claim 15,
The side reinforcing portion
And a second side stiffener joined to the free end of the side closure and the fifth side stiffener at the current time.
12. The method of claim 11,
Wherein the pair of lattices is disposed parallel to at least two of the side deck plates.
18. The method of claim 17,
The side reinforcing portion
One end of the lattice is coupled to the inner side of the one of the pair of lattices and the pair of the ribs and the other end is coupled to the other inner side of the other lattice and the upper side of the pair of ribs, A building deck panel comprising one side reinforcement.
12. The method of claim 11,
The side reinforcing portion
A pair of lattice inner sides and a pair of lower ends of the pair of lower laths, the pair of laths being vertically arranged with respect to the pair of lower laths and having a U- A building deck panel comprising three side stiffeners.
12. The method of claim 11,
One pair of which is vertically coupled to the upper side of the phase current and the other one of which is vertically coupled to the pair of lower frames and which includes a second coupling portion having a C shape outside the side deck plate, A building deck panel comprising a fourth side stiffener.

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