KR20160001273U - free access floor for building - Google Patents

Abstract

The present invention relates to an access floor for a building used as a floor plate in an advanced building, an office building, and an information building,
The double bottom plate 1 installed on the floor of the building constitutes a hollow portion 4 by being combined with the upper plate 2 and the lower plate 3 and the upper plate 2 and the lower plate 3 Each of which is made of a steel panel and the tip end portion of the edge wedge 10 of the upper plate 2 is doubly bent to form the double bending vertical wedge 12 in the vertical direction, 3 are vertically bent to form a double bending vertical wing Q in the vertical direction and the double bending vertical wing Q is in contact with the double bending vertical wing 12 of the upper plate The horizontal bending muzzle Q1 is horizontally bent upward inward from the tip of the double bending vertical wing Q of the lower plate and the vertical bending wing Q2 is bent vertically to bend the vertical bending wing Q2, (8) of the lower plate (3) so as to abut against the reinforcing support projection (6) and the bent surface (7) The edge wedge 10 of the upper plate 2 is formed with an embossing burring and is combined with the hole 9 as a binding portion 11 by bending a hole 9 in the bending jig Q1 And the support for the concentrated load is maximized.
The present invention as described above can improve the structure of the periphery edge (i.e., displacement part), which is the weakest part of the concentrated load in the double bottom plate, so that the concentrated load (concentrated load) ), Thereby reducing the thickness of the steel panel of the upper and lower plates, thereby reducing the load on the building and reducing the production cost, thereby contributing to the enhancement of competitiveness in enterprise operation and saving resources.

Description

Building access flooring {free access floor for building}

The present invention relates to an access floor for a building used as a floor plate in an advanced building, an office building, an information building, and the like, and more particularly to an access floor for a building, To an access floor for a building which is capable of withstanding a greater load than the access floor of Korean Registered Patent Registration No. 10-1118643.

In general, in the present invention, the double bottom floor is a so-called free access floor (sometimes referred to as an "access floor") or an OA floor, Cables and the like are easily wired to provide aesthetically pleasing appearance and to allow the indoor space to be utilized properly.

That is, as shown in FIG. 17, a double bottom plate (Access Floor) is constructed as a support base S on a building floor F such as an office, and a finish material C such as a carpet is laid on the access floor.

When the above-mentioned access floor is installed, a passage space is formed by a predetermined height, and a communication cable or an electric wire can be arranged in this space.

The access floor, which is conveniently used as described above, is entirely made of steel, and is composed of an upper plate 100 and a lower plate 200.

However, the double bottom plate should have a concentrated load of at least 3,000N when the internal load is R type and KSF 4760 should have a concentrated load of more than 5,000N. When measuring the load, The edge portion (i.e., the displacement portion) is not less than the above-mentioned load resistance.

In order to satisfy such a condition, the thickness of the upper plate 100 and the lower plate 200 made of steel, which constitute a double bottom plate, should be at least 1 to 1.4 mm, respectively.

In this case, as the raw material value of steel is increased, the cost of production is increased, which is a great burden to the operation of the enterprise.

The access floor, which is composed of the upper plate 100 and the lower plate 200, is in a hollow state when the access floor is hollow. Therefore, in a state in which the access floor is installed on the building floor F When walking, resonance phenomenon [Resonance Phenomena; Resonance phenomenon (resonance phenomenon)] occurred.

Further, there was a problem that the supporting force that can endure with the concentrated load of the peripheral edge is lowered.

In this case, when the access floor is installed in all directions and the impact is applied to the periphery, or a heavy office equipment, a book or furniture or the like is subjected to a load for a long time, the peripheral edge ) Is depressed or broken.

This phenomenon occurs not only in the above-mentioned hollow type of access floor but also in products in which concrete is injected into the hollow floor of the access floor.

In order to solve the above problem, the applicant (inventor) filed a patent application under the name of "double floor board for buildings" in the Korean Intellectual Property Office and registered as a patent 10-1118643 (Korean Registered Patent Publication No. 10-1118643 (2012). (Hereinafter referred to as 'pre-registration').

That is, the line registration design is designed to minimize the thickness of steel panels constituting the upper and lower plates constituting the access floor, It is possible to reduce the production cost by constructing a built-in interior material, and the resonance phenomenon [Resonance Phenomena; And the edge structure of the access floor has been improved to maximize the bearing capacity against the concentrated load.

This line registration design prevents the phenomenon that the edge part of the double bottom plate is impacted or the peripheral part is not recessed even when the heavy equipment such as office equipment, bookshelves or furniture is loaded for a long time. can do.

That is, a plurality of reinforcing support protrusions and edge portions of the upper edge of the upper plate are doubly bent at the peripheral edge of the double bottom plate to form a double bending vertical wing in the vertical direction, so that the concentrated load It is possible to maximize the bearing capacity.

In addition, when the thickness of the steel panel of the upper and lower plates is minimized and the wood in which the waste material is recycled is built in as an interior material in the hollow portion, the bearing capacity required for the double bottom plate is maximized It can be manufactured and used at an extremely low cost, thereby maximizing its competitiveness.

However, when a higher concentrated load is required on the edge of the double bottom plate (ie, the displaced portion), the thickness of the upper and lower steel panels may be increased again, It is necessary to increase the thickness of the packing as well as to increase the thickness of the steel.

As a result, the cost of raw materials and wood of steel is increased, which increases the cost of operation.

Korean Registered Patent Publication No. 10-1118643 (Announcement of Mar. 09, 2012)

Accordingly, the present invention is designed to solve the above problems, and the object of the present invention is to provide an access floor of Korean Registered Patent Publication No. 10-1118643 (hereinafter referred to as "line registration design"), The present invention provides an access floor for a building that can reinforce the edge structure to withstand a greater concentrated load.

As a first embodiment for achieving the object of the present invention,

The double bottom plate 1 installed on the floor of a building is constituted by a top plate 2 and a bottom plate 3 to constitute a hollow portion 4,

The top plate 2 and the bottom plate 3 are each made of a steel panel and the tip of the edge wedge 10 of the top plate 2 is doubly bent to form the double bending vertical wing 12 Vertical direction,

A hole 9 is formed in the edge wing 8 of the lower plate 3 and the edge wing 10 of the upper plate 2 is formed with an embossing burring as a binding portion 11, 9)

The vertical bending jig (Q) is further extended in the edge wing (8) of the lower plate (3), and the vertical bending jig (Q) is connected to the double bending vertical wing (12) of the upper plate Thereby maximizing the bearing capacity.

As a second embodiment for achieving the object of the present invention,

The double bottom plate 1 installed on the floor of a building is constituted by a top plate 2 and a bottom plate 3 to constitute a hollow portion 4,

The top plate 2 and the bottom plate 3 are each made of a steel panel and the tip of the edge wedge 10 of the top plate 2 is doubly bent to form the double bending vertical wing 12 Vertical direction,

The tip end portion of the edge wing (8) of the lower plate (3) is doubly bent to form a double bending vertical wing (Q) in a vertical direction,

The double bending vertical wing Q is in contact with the double bending vertical wing 12 of the upper plate and extends further from the tip of the double bending vertical wing Q of the upper plate to form a horizontal bending wing Q1, And the vertical bending jig Q2 is vertically bent to contact the reinforcing support projection 6 and the bent surface 7 of the lower plate 3,

An edge wedge 8 and a horizontal bent wedge Q1 of the lower plate 3 are formed with holes 9 and an edge wedge 10 of the upper plate 2 is provided with an embossing burring, (11) to be combined with the hole (9) so as to maximize the supporting force against the concentrated load.

As a third embodiment for achieving the object of the present invention,

The double bottom plate 1 installed on the floor of a building is constituted by a top plate 2 and a bottom plate 3 to constitute a hollow portion 4,

The top plate 2 and the bottom plate 3 are each made of a steel panel and the tip of the edge wedge 10 of the top plate 2 is doubly bent to form the double bending vertical wing 12 And further horizontally bending the horizontal bending jig 12a upwardly inward from the tip of the double bending vertical bending piece 12,

The tip end portion of the edge wing (8) of the lower plate (3) is doubly bent to form a double bending vertical wing (Q) in a vertical direction,

The double bending vertical wing Q is in contact with the double bending vertical wing 12 of the upper plate and extends further from the tip of the double bending vertical wing Q of the upper plate to form a horizontal bending wing Q1, And the vertical bending jig Q2 is vertically bent to contact the reinforcing support projection 6 and the bent surface 7 of the lower plate 3,

A hole 9 is formed in the edge bending piece 8 and the horizontal bending bending piece Q1 of the upper bending piece 12a and the lower bending piece 3 of the upper plate 2 and the edge wing 10 Is configured to engage with the hole 9 as the engaging portion 11 by embossing burring to maximize the supporting force against the concentrated load.

As a fourth embodiment for achieving the object of the present invention,

The double bottom plate 1 installed on the floor of a building is constituted by a top plate 2 and a bottom plate 3 to constitute a hollow portion 4,

The top plate 2 and the bottom plate 3 are each made of a steel panel and the tip of the edge wedge 10 of the top plate 2 is doubly bent to form the double bending vertical wing 12 And further horizontally bending the horizontal bending jig 12a upwardly inward from the tip of the double bending vertical bending piece 12,

The tip end portion of the edge wedge 8 of the lower plate 3 is doubly bent to form the horizontal horizontal bent wing Q1a in the horizontal direction,

The vertical bending jig Q2 is vertically bent again at the tip of the double horizontal bending jig Q1a so as to contact the reinforcing support projection 6 and the bending face 7 of the lower plate 3,

A hole 9 is drilled in the horizontal bending jig 12a of the upper plate 2 and the edge bending piece 8 and the double horizontal bending jig Q1a of the lower plate 3, 10 are combined with the hole 9 as a binding portion 11 by embossing burring to maximize the supporting force against a concentrated load.

The present invention has the following effects.

The first embodiment of the present invention is constituted by further extending the vertical bending jig (Q) to the edge wedge 8 of the lower plate 3 and also by forming the double bending vertical wing 12 of the upper plate 2, It is possible to maximize the supporting force against the concentrated load of the peripheral edge portion (i.e., the displacement portion) and to reduce the holding force to 30% or more when the vertical bending mound Q is not formed in the lower plate 3, (Concentrated load), and it is able to withstand an impact load of 3 times or more (JIS standard) as compared to the line registration design, and the breaking load is improved by 16% as compared with the line registration design .

In the second embodiment of the present invention, the double bending perpendicular fingertip Q of the lower plate is brought into contact with the double bending vertical fingertip 12 of the upper plate, and at the tip of the double bending vertical fingertip Q of the lower plate, The horizontal bending jig Q1 is horizontally bent to the upper side inward and bent perpendicularly again to the vertical bending jig Q2 so as to contact the reinforcing support projection 6 and the bent surface 7 of the lower plate 3 The bearing capacity of the edge (ie displacement part) against the concentrated load is improved by more than 55% and the breaking load is improved by more than 46%.

In the third embodiment of the present invention, the horizontal bending jig 12a is further extended horizontally from the top end of the double bending vertical bending piece 12 of the upper plate to the upper side of the top plate, And the double bending vertical wing Q is formed in a vertical direction so that the double bending vertical wing Q is in contact with the double bending vertical wing 12 of the upper plate, The horizontal bending jig Q1 is further bent horizontally from the front end of the lower plate 3 to the upper side in the upper side and the vertical bending jig Q2 is bent vertically to bend the vertical bending jig Q2 perpendicularly to the reinforcing support projection 6 of the lower plate 3, (Concentrated load) of the peripheral edge portion (that is, displacement portion) is improved by 55% or more and the breaking load is 46% or more .

In the fourth embodiment of the present invention, the horizontal bending jig 12a is further extended horizontally from the top end of the bifurcated vertical bending piece 12 of the upper plate to the upper side of the upper bending piece, The vertical bending jig Q2 is bent vertically again at the tip of the double horizontal bending jig Q1a to form a double horizontal bending jig Q1a in the horizontal direction so as to reinforce the bottom plate 3, The supporting force against the concentrated load of the peripheral edge portion (that is, the displaced portion) is improved by 55% or more compared with the line registration design by being brought into contact with the protruding portion 6 and the bent surface 7 The breaking load is also improved by 46% or more.

Therefore, the first to fourth embodiments of the present invention improve the structure of the peripheral edge (i.e., displacement portion), which is the weakest portion for the concentrated load in the double bottom plate, By reducing the thickness of the steel panels of the upper and lower plates by maximizing the bearing capacity against the concentrated load, it is possible to reduce the load on the building and reduce the production cost, thereby enhancing the competitiveness of the enterprise operation and contributing to resource saving.

1 to 10 show a first embodiment of a "double bottom plate for a building" according to the present invention, wherein Fig. 1 is an overall outline perspective view.
2 is a front view of a "double bottom plate for a building" according to the present invention.
3 is a plan view of a "double bottom plate for a building" according to the present invention.
Fig. 4 is a plan view of the lower plate in a state where the upper plate is removed from the "double bottom plate for building"
Fig. 5 is a schematic view showing various embodiments of the cross-sectional shape of the lower plate formed by the reinforcing support protrusion and the bent surface in the "double bottom plate for building " according to the present invention.
6 is a sectional view taken along the line AA in Fig. 3 according to the present invention.
Fig. 7 is an enlarged view of the portion "B" in Fig. 6 according to the present invention.
Fig. 8 is an enlarged view of a portion "C" in Fig. 6 according to the present invention.
Fig. 9 is a plan view showing a state in which a "double bottom plate for a building" according to the present invention is installed on a building floor.
10 is an enlarged cross-sectional view of the periphery of the building with the "building double bottom plate" according to the present invention installed on the floor of the building.
Figs. 11 to 12 show a second embodiment of a peripheral edge (i.e., a displacement portion) according to the present invention.
11 is an enlarged view of a peripheral edge (i.e., displacement portion) as in the portion "C" in Fig. 6,
Fig. 12 is an enlarged cross-sectional view of the periphery of the building with the "building double bottom plate" according to the present invention installed on the floor of the building.
13 to 14 show a third embodiment of a peripheral edge (i.e., displacement portion) according to the present invention.
13 is an enlarged view of a peripheral edge (i.e., a displacement portion) as in the portion "C" in Fig. 6,
Fig. 14 is an enlarged cross-sectional view of the periphery of the building with the "building double bottom plate" according to the present invention installed on the floor of the building.
15 to 16 show a fourth embodiment of a peripheral edge (i.e., displacement portion) according to the present invention.
Fig. 15 is an enlarged view of a peripheral edge (i.e., displacement portion) as in the portion "C" in Fig. 6,
Fig. 16 is an enlarged cross-sectional view of the periphery of the building with the "building double bottom plate" according to the present invention installed on the building floor.
17 is a cross-sectional view illustrating a conventional double bottom plate.

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

First, the configuration of the first embodiment of the present invention will be described with reference to Figs. 1 and 4 to 8 shown earlier.

The double bottom plate 1, which is installed and installed on the floor of a building such as a high-rise building, an office building and an information building, is constructed by combining the upper plate 2 and the lower plate 3 to form a hollow portion 4 And a plurality of reinforcement supporting protrusions 5 are formed on the edge where the upper plate 2 and the lower plate 3 are coupled to each other, (6).

The upper and lower plates 2 and 3 constituting the double bottom plate 1 are made of steel panels and have a thickness of 0.5 to 0.6 mm.

Wood, recycled plastic, concrete or the like, which recycles waste materials, is used as the interior material (5) embedded in the hollow portion (4).

The reinforcing supporting protrusions 6 are formed at a predetermined interval on the periphery of the lower plate 3 as shown in Fig. 4 (a plan view of the lower plate from which the upper plate has been removed) And protruding outwardly by a predetermined distance D1 (D2) from the folded surface 7,

5A, the cross section of the lower plate 3 formed by the reinforcing support protrusions 6 and the bent surface 7 is formed in a trapezoidal shape as shown in FIG. 5A, a triangle as shown in FIG. 5B, a circular arc as shown in FIG. 5C, and a square as shown in FIG. 5D.

As shown in Figs. 4 and 8, the upper plate 2 and the lower plate 3 are pierced by a hole 9 in the edge wedge 8 of the lower plate 3 above the bent surface 7 of the lower plate 3 And the upper and lower plates 2 and 3 are joined together with the hole 9 by the embossing buried burr 11 and the embossing buried buried portion 11 of the upper plate 2, do.

7, 8, and 10, the tip end of the edge wedge 10 of the upper plate 2 is doubly bent by a curling process to form the double-bending vertical wedge 12 in the vertical direction .

The vertical bending jig (Q) is further extended in the edge wing (8) of the lower plate (3), and the vertical bending jig (Q) is connected to the double bending vertical wing (12) of the upper plate Thereby maximizing the bearing capacity.

The function and effect of the present invention will be described below.

First, as shown in Fig. 9, the double bottom plate 1 of the present invention is installed on the floor of the building in all directions.

When the double bottom plate 1 is installed on the floor of the building, the double bending vertical fingers 12 formed on the top end of the upper plate 2 between the adjacent double bottom plates 1 are in contact with each other as shown in FIG.

The double bottom plate 1 of the present invention installed as described above is designed so that even if a shock is applied to a peripheral edge or a heavy office equipment or a product such as a bookcase or furniture is subjected to a load for a long time, It is possible to prevent the phenomenon of depression or destruction.

That is, since the plurality of reinforcing supporting protrusions 6 are formed on the peripheral edge of the lower plate 3 with the bent surface 7 as a starting point, the supporting force against the concentrated load is maximized You can do it.

The reinforcement supporting protrusions 6 and the bent surfaces 7 form the bottom plate 3 in a trapezoidal shape, a triangular shape, an arcuate shape, a square shape, or the like so that the load applied to the lower side is dispersed So that the support force can be maximized.

The edge portion of the edge plate 10 of the upper plate 2 is doubly bent so as to form the vertical bending direction of the vertical bending piece 12 in the vertical direction, The peripheral edge portion (i.e., the displacement portion) of the upper plate 2 is connected to the double bending vertical wing 12 of the upper plate 2 so as to form a concentrated load Concentrated load) can be maximized.

In this case, the bearing capacity for a concentrated load of 30% or more is improved compared to the line registration design when the vertical bending jig (Q) is not formed in the lower plate (3) The load (JIS standard) was destroyed once, but this design has no problem in shock more than 3 times, and the breaking load is improved by 16% compared with the design of the line.

The edges of the edge plate 8 of the lower plate 3 and the edges of the edge plate 10 of the upper plate 2 are joined to each other by the plurality of fastening portions 11 to increase the strength of the support.

Therefore, the peripheral edge of the double bottom plate 1 can maximize the supporting force against a concentrated load.

In FIG. 10, the peripheral portion distances D1, L and D2 of the adjacent double bottom plates 1 were found to be in the range of 8,000 N as a result of a concentrated load.

Even if the steel panels of the upper and lower plates 2 and 3 are fabricated to a thickness of 0.5 to 0.6 mm, a concentrated load of at least 3,000 N to 5,000 N required by KSF 4760 Of course, it is 8,000N more than 30,000% higher than the range of 5,000 ~ 6,000N of the line registration design. Therefore, the double bottom plate (1) can be manufactured at an extremely low cost while maximizing the bearing capacity against the concentrated load required for the double bottom plate It can maximize competitiveness.

That is, the thickness of the steel panels of the upper and lower plates 2 and 3 can be reduced by 16% or more, and the material value is reduced by 20%.

As the reinforcing supporting protrusions 6 are formed, the circumferential intervals a, c and b of the adjacent double bottom plates 1 are minimized as shown in FIG. 10, so that heavy office equipment, bookshelves, Is narrower than the width of a caster or a leg coupled to a vessel of the apparatus, so that the depression phenomenon can be further prevented.

In addition, since the hollow portion 4 of the double bottom plate is embedded with the interior material 5 such as wood, when walking is performed on the floor of the building, the resonance phenomenon [Phenomena; (2) and (3) are combined by embossing burring only at the periphery when the upper and lower plates 2 and 3 are combined. Therefore, the deformation of the material is minimized, (The flatness is less than 0.2 mm in the KS standard, but the present invention is less than 0.03 mm).

The present invention is configured such that a vertical bending jig (Q) is further elongated on an edge bending piece (8) of the lower plate (3) and is also engaged with a double bending vertical bending piece (12) of the upper plate A concentrated load of 30% or more is obtained when the vertical bending mover (Q) is not formed on the lower plate (3) by maximizing the supporting force against the concentrated load of the edge (i.e., displacement portion) (concentrated load), and it is able to withstand an impact load of 3 times or more (JIS standard) as compared with the line registration design, and the breaking load is improved by 16% as compared with the line registration design.

Therefore, by improving the structure of the edge (ie, displacement part), which is the most vulnerable part to the concentrated load in the double bottom plate, it is possible to improve the load on the concentrated load (concentrated load) By minimizing the thickness of the steel panels of the upper and lower plates by maximizing the bearing capacity, it is possible to reduce the load on the building and reduce the production cost, thereby enhancing the competitiveness of enterprise operation and saving resources.

Next, a second embodiment of the edge of the present invention (i.e., a displacement portion) will be described with reference to FIGS. 11 and 12 as follows.

That is, the double bottom plate 1 installed on the floor of the building is constituted by the upper plate 2 and the lower plate 3 to constitute a hollow portion 4, and the upper plate 2 and the lower plate 3 Are each formed of a steel panel and the tip end portion of the edge wedge 10 of the upper plate 2 is doubly bent to form the double bending vertical wedge 12 in the vertical direction.

The tip end portion of the edge wedge 8 of the lower plate 3 is doubly bent to form a double bending vertical wing Q in a vertical direction. The double bending vertical wing Q is formed in the double bending vertical wing 12 of the upper plate, And further extends from the tip end of the double bending vertical wing Q of the lower plate so as to horizontally bend the horizontal bending wing Q1 to the upper inside and bend the vertical bending wing Q2 vertically to bend the lower bending wing Q2, 3) and the bent surface (7).

An edge wedge 8 and a horizontal bent wedge Q1 of the lower plate 3 are formed with holes 9 and an edge wedge 10 of the upper plate 2 is provided with an embossing burring, (11) to be combined with the hole (9) so as to maximize the supporting force against the concentrated load.

In the second embodiment of the present invention as described above, the double bending perpendicular fingertip Q of the lower plate is brought into contact with the double bending perpendicular fingertip 12 of the upper plate, and at the tip of the double bending perpendicular fingertip Q of the lower plate The horizontal bending jig Q1 is horizontally bent to the upper side inward and the vertical bending jig Q2 is bent vertically to abut against the reinforcing support projection 6 and the bent surface 7 of the lower plate 3, The bearing capacity for the concentrated load of the periphery edge (ie, displacement part) is improved by 55% or more, the breaking load is improved by 46% or more, and the detailed action The effect is based on the description of the first embodiment.

Next, a third embodiment of the edge (i.e., displacement portion) of the present invention will be described with reference to FIGS. 13 and 14 as follows.

That is, the double bottom plate 1 installed on the floor of the building is constituted by the upper plate 2 and the lower plate 3 to constitute a hollow portion 4, and the upper plate 2 and the lower plate 3 Each of which is made of a steel panel and the tip end of the edge wedge 10 of the upper plate 2 is doubly bent to form a double bending vertical wedge 12 in a vertical direction, And further horizontally bending the horizontally bending jig 12a from the tip end of the bending vertical bending piece 12 to the upper side inside.

The tip end portion of the edge wedge 8 of the lower plate 3 is doubly bent to form a double bending vertical wing Q in a vertical direction. The double bending vertical wing Q is formed in the double bending vertical wing 12 of the upper plate, And further extends from the tip end of the double bending vertical wing Q of the lower plate so as to horizontally bend the horizontal bending wing Q1 to the upper inside and bend the vertical bending wing Q2 vertically to bend the lower bending wing Q2, 3) and the bent surface (7).

A hole 9 is formed in the edge bending piece 8 and the horizontal bending bending piece Q1 of the upper bending piece 12a and the lower bending piece 3 of the upper plate 2 and the edge wing 10 Is configured to engage with the hole 9 as the engaging portion 11 by embossing burring to maximize the supporting force against the concentrated load.

In the third embodiment of the present invention as described above, the horizontally bending jig 12a is horizontally bent to the upper side inward and further extended from the tip end of the bending vertical jig 12 of the upper plate, and the edge jig 8 of the lower plate 3, The tip end portion is double-folded to form a double-bending vertical wing Q in the vertical direction. The double-bending vertical wing Q is in contact with the double-bending vertical wing 12 of the upper plate, The horizontal bending jig Q1 is further bent horizontally from the top end of the vertical jig Q to the upper inner side and the vertical bending jig Q2 is bent vertically to bend the vertical bending jig Q2 to form the reinforcing support projection 6 of the lower plate 3 The supporting force against the concentrated load of the peripheral edge portion (that is, the displacement portion) is improved by 55% or more and the breaking load is increased by 46 % And the other detailed action effects are improved by the above- The description of one embodiment is used.

Next, a fourth embodiment of the edge (i.e., displacement portion) of the present invention will be described with reference to FIGS. 15 and 16. FIG.

That is, the double bottom plate 1 installed on the floor of the building is combined with the upper plate 2 and the lower plate 3 to form a hollow portion 4.

The top plate 2 and the bottom plate 3 are each made of a steel panel and the tip of the edge wedge 10 of the top plate 2 is doubly bent to form the double bending vertical wing 12 And further horizontally bending the horizontally bending jig 12a upwardly inward from the tip end of the bending vertical bending piece 12. [

The tip end portion of the edge wing 8 of the lower plate 3 is doubly bent to form the horizontal horizontal bending flute Q1a in the horizontal direction and the vertical bending flute Q2 Is bent so as to be brought into contact with the reinforcing support projection 6 and the bent surface 7 of the lower plate 3.

A hole 9 is drilled in the horizontal bending jig 12a of the upper plate 2 and the edge bending piece 8 and the double horizontal bending jig Q1a of the lower plate 3, 10 are combined with the hole 9 as a binding portion 11 by embossing burring to maximize the supporting force against a concentrated load.

In the fourth embodiment of the present invention constructed as described above, the horizontally bending jig 12a is horizontally bent to the upper side inwardly from the tip end of the bending vertical bending piece 12 of the upper plate, 8 are folded in a double direction to form a horizontal horizontal bending jig Q1a in the horizontal direction and the vertical bending jig Q2 is bent again vertically at the tip of the double horizontal bending jig Q1a to form a double- The support for the concentrated load of the peripheral edge portion (that is, the displaced portion) is reduced to 55% or more by the contact with the reinforcing support projection 6 and the bent surface 7, And the fracture load is improved by 46% or more, and other detailed operational effects are used in the description of the first embodiment.

1: double bottom plate 2: top plate
3: lower plate 4: hollow portion
5: Interior material 6: Supporting projection for reinforcement
7: Bending surface 8:
9: hole 10: edge of the edge
11: Bonding part 12: Double bending vertical wipe
12a: Horizontal bending muzzle Q: Vertical bending muzzle
Q1: Horizontal bending muzzle Q1a: Double horizontal bending muzzle
Q2: Vertical bending

Claims (4)

The double bottom plate 1 installed on the floor of a building is constituted by a top plate 2 and a bottom plate 3 to constitute a hollow portion 4,
The top plate 2 and the bottom plate 3 are each made of a steel panel and the tip of the edge wedge 10 of the top plate 2 is doubly bent to form the double bending vertical wing 12 Vertical direction,
A hole 9 is formed in the edge wing 8 of the lower plate 3 and the edge wing 10 of the upper plate 2 is formed with an embossing burring as a binding portion 11, 9)
The vertical bending jig (Q) is further extended in the edge wing (8) of the lower plate (3), and the vertical bending jig (Q) is connected to the double bending vertical wing (12) of the upper plate Wherein the supporting plate is provided with a plurality of projections. The double bottom plate 1 installed on the floor of a building is constituted by a top plate 2 and a bottom plate 3 to constitute a hollow portion 4,
The top plate 2 and the bottom plate 3 are each made of a steel panel and the tip of the edge wedge 10 of the top plate 2 is doubly bent to form the double bending vertical wing 12 Vertical direction,
The tip end portion of the edge wing (8) of the lower plate (3) is doubly bent to form a double bending vertical wing (Q) in a vertical direction,
The double bending vertical wing Q is in contact with the double bending vertical wing 12 of the upper plate and is further extended from the tip of the double bending vertical wing Q of the lower plate to form a horizontal bending wing Q1, And the vertical bending jig Q2 is vertically bent to contact the reinforcing support projection 6 and the bent surface 7 of the lower plate 3,
An edge wedge 8 and a horizontal bent wedge Q1 of the lower plate 3 are formed with holes 9 and an edge wedge 10 of the upper plate 2 is provided with an embossing burring, (11) is combined with the hole (9) so as to maximize the supporting force against a concentrated load. The double bottom plate 1 installed on the floor of a building is constituted by a top plate 2 and a bottom plate 3 to constitute a hollow portion 4,
The top plate 2 and the bottom plate 3 are each made of a steel panel and the tip of the edge wedge 10 of the top plate 2 is doubly bent to form the double bending vertical wing 12 And further horizontally bending the horizontal bending jig 12a upwardly inward from the tip of the double bending vertical bending piece 12,
The tip end portion of the edge wing (8) of the lower plate (3) is doubly bent to form a double bending vertical wing (Q) in a vertical direction,
The double bending vertical wing Q is in contact with the double bending vertical wing 12 of the upper plate and is further extended from the tip of the double bending vertical wing Q of the lower plate to form a horizontal bending wing Q1, And the vertical bending jig Q2 is vertically bent to contact the reinforcing support projection 6 and the bent surface 7 of the lower plate 3,
A hole 9 is formed in the edge bending piece 8 and the horizontal bending bending piece Q1 of the upper bending piece 12a and the lower bending piece 3 of the upper plate 2 and the edge wing 10 Is configured to engage with the hole (9) as a binding portion (11) by embossing burring to maximize the supporting force against a concentrated load. The double bottom plate 1 installed on the floor of a building is constituted by a top plate 2 and a bottom plate 3 to constitute a hollow portion 4,
The top plate 2 and the bottom plate 3 are each made of a steel panel and the tip of the edge wedge 10 of the top plate 2 is doubly bent to form the double bending vertical wing 12 And further horizontally bending the horizontal bending jig 12a upwardly inward from the tip of the double bending vertical bending piece 12,
The tip end portion of the edge wedge 8 of the lower plate 3 is doubly bent to form the horizontal horizontal bent wing Q1a in the horizontal direction,
The vertical bending jig Q2 is vertically bent again at the tip of the double horizontal bending jig Q1a so as to contact the reinforcing support projection 6 and the bending face 7 of the lower plate 3,
A hole 9 is drilled in the horizontal bending jig 12a of the upper plate 2 and the edge bending piece 8 and the double horizontal bending jig Q1a of the lower plate 3, (10) is combined with the hole (9) as an engaging portion (11) by embossing burring to maximize the supporting force against a concentrated load.

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