KR20180124242A - fastener, truss deck plate adhered to insulating materials and method of constructing the slab in use with the same - Google Patents

Abstract

The present invention relates to an expansion wing type fastener for connecting and supporting an insulation material to a bottom surface of a steel plate of an integrated truss deck without forming any holes or grooves in the insulation material, an integrated truss deck with an insulation material using the same, and a slave construction method thereof, and especially to an expansion wing type fastener for restoring non-productivity and unreliability of adhesive construction by mechanical connection without penetrating holes to an insulation material for fastening, an integrated truss deck with an insulation material using the same, and a slave construction method thereof. The expansion wing type fastener comprises: a fastener core part; and a fastener outer container.

Description

[0001] The present invention relates to a fastener, a truss deck, and a method of constructing the same,

The present invention relates to an extended blade-type fastener for connecting and supporting a heat insulating material to the bottom surface of a steel plate of a truss-integral deck without forming any holes or grooves in the heat insulating material, a truss integral deck with a heat insulating material and a method of constructing the slab, The present invention relates to an extended blade fastener for recovering the non-productivity and unreliability of an adhesive due to mechanical connection without penetrating a hole for fastening, a truss integral deck with a heat insulating material using the fastener, and a slab construction method thereof.

Usually, the deck to which the heat insulating material is attached is applied as a roof slab in contact with the outside air among the slabs to enhance the heat insulating performance inside.

In the existing heat insulating material removal type decking deck, the heat insulating material is located between the truss and the steel sheet, and the trusses and the heat insulating material are connected to each other by the long bolt.

Therefore, after the completion of slab construction, it is very burdensome to recover the steel sheet by unloading a huge amount of long bolts (the cost is higher than that of the short bolt).

As a conventional technique for solving such a burden, there is proposed what is known in Patent Documents 1 and 2.

The truss deck plate having the heat insulating material of Patent Document 1 (Korean Patent No. 10-1125549) connects the heat insulating material to the bottom surface of the steel plate through fixing means.

That is, in Patent Document 1, a hole is made in the steel plate and the heat insulating material, and the heat insulating material is connected and supported by fastening the long bolt and nut through the hole.

Such Patent Document 1 has the following problems.

First, since holes for fastening bolts are to be drilled in the heat insulating material, the thermal bridges, which are heat transferred through the long bolts, can cause marks on the finish. That is, the finishing material is constructed so that the exposed bolts and nuts on the bottom surface of the heat insulating material are not exposed.

Second, the heat conduction rate (heat transfer rate) is very large due to the upper and lower through holes of the heat insulating material, and the heat insulating performance is deteriorated.

Third, it is very complicated to drill holes in both the steel plate and the heat insulating material, and to make the hole of the open steel plate and the hole of the heat insulating material hard to fit, and a separate work for fitting again. To solve this problem, it is necessary to stack steel plates and insulation materials together and drill at one time.

Fourth, although it is not necessary to demarcate the steel plate, it is impossible to recover the long bolt, and the unit price is expensive, and the overall weight is increased, which is disadvantageous to the interlayer reduction and the long span.

On the other hand, in Patent Document 2 (Korean Patent No. 10-1706086), it has been proposed that a heat insulating material is adhered to the bottom surface of a steel sheet with an adhesive.

When the heat insulating material is adhered to the bottom surface of the steel sheet by using the adhesive, there is no burden on the process of removing the steel sheet and recovery of the long bolt.

However, due to the nature of the adhesive, the composition (adhesion of the steel sheet and the insulating material) and reliability (the degree of adhesion of the insulating material in the steel sheet) is not very good.

That is, if the surface of the steel sheet and the heat insulating material is, for example, 600x1200, it is necessary to wait until the adhesive is applied to the area, and the manufacture is almost impossible.

Further, when the adhesive performance of the adhesive deteriorates, the heat insulating material is very dangerous from falling off the steel sheet.

That is, the deterioration of the deterioration of the adhesive, which is affected by moisture or temperature, over time, can be intensified.

Patent Document 1: Korean Patent No. 10-1125549 Patent Document 2: Korean Patent No. 10-1706086

Disclosure of the Invention The present invention has been conceived in order to solve the above-mentioned problems, and it is an object of the present invention to provide an expanding blade type fastener that restores both non-productivity and unreliability of an adhesive by mechanical connection without penetrating a hole for fastening, It is an object of the present invention to provide a truss integral type deck and a method of constructing the slab.

In order to achieve the above-mentioned object, an extended blade-type fastener according to claim 1 of the present invention is an extended blade type fastener for supporting a heat insulating material on a bottom surface of a steel plate as a deck plate, A flange formed at an upper end of the column; a flange protruding between upper and lower ends of the column to be engaged with the upper surface of the through hole of the steel plate; A fastener core portion; And a convex portion which is fitted between the flange and the vane and is disposed between the upper surface of the vane and the outer circumferential surface of the cylinder at the upper end and the lower surface engaging jaw which is caught at the lower surface of the through hole of the steel plate at the upper end, , Each of the blades having a needle shape inclined upward toward the outside with the lower end thereof being expandably (spreadable).

In the expanded blade type fastener according to claim 2 of the present invention, the cylinder at the position where the upper surface engaging jaw is formed is further formed with a slot penetrating in the radial direction.

According to a third aspect of the present invention, there is provided a truss-integral deck with a heat insulating material, comprising: a heat insulating material; a deck on which a truss is fixed on a steel sheet placed on the heat insulating material; and a plurality of through holes formed in the steel sheet, Wherein the wedge-shaped fastener of the plastic material has a cylindrical shape, a plurality of blades formed along the lower end of the cylindrical shape, a wedge extending downward from the lower end of the cylindrical shape, A fastener core portion protruding between upper and lower ends of the cylinder and including an upper surface engaging jaw which is engaged with an upper surface of the through hole of the steel plate; And a convex portion which is fitted between the flange and the vane and is disposed between the upper surface of the vane and the outer circumferential surface of the cylinder at the upper end and the lower surface engaging jaw which is caught at the lower surface of the through hole of the steel plate at the upper end, The fastener outer tube is inserted into the heat insulating material, and when the fastener core portion is pulled up while being caught by the steel plate, the plurality of blades are expanded outward and inserted into the heat insulating material in an anchor form.

According to a third aspect of the present invention, there is provided a method of constructing a truss-integrated deck with a heat insulating material, comprising the steps of: preparing a deck on an upper surface of a heat insulating material and having a plurality of through holes formed therein; Fastening a fastener-shaped fastener of a plastic material into the insulator until a flange of the fastener core is caught on the upper surface of the through-hole; Pulling up the upper flange of the fastener outer tube in the extended blade-type fastener while holding the upper flange of the extended blade-type fastener in the bottom of the through hole of the steel plate when the extended blade type fastener is inserted into the heat insulating material; Expanding the plurality of blades of the fastener core portion outwardly when the flange portion is pulled up and the fastener core portion is pulled up with respect to the fastener outer cylinder and passes the lower convex portion of the fastener outer tube; When the fastener deep portion is pulled up until the upper surface engaging jaw protruding outside the elongated hole of the fastener is placed on the upper surface of the through hole of the steel plate, the plurality of wings are inserted into the heat insulating material in an anchor form step; And a truss-integrated deck to which the heat insulating material is connected is installed in the beam and pouring concrete.

The present invention has the following effects.

There is no burden on the demoulding process, long bolt and steel plate collection by attaching the heat insulating material to the sloping deck.

Further, by supporting the heat insulator on the steel plate without penetrating it, the heat conduction rate (heat transmission rate) due to penetration is low, and the heat insulating performance is excellent.

Further, it is not necessary to finish the fastener exposed on the lower surface of the heat insulating material invisibly, and the heat bridging phenomenon is prevented through the penetrated fastener, so that the stain does not occur.

In addition, even if the insulator does not penetrate, it acts as an anchor of the ship which can not move the ship by digging into the bottom of the water area, so that the insulation can be surely connected.

In addition, the flange of the fastener and the ring that is caught by the concrete in which the long hole is laid serve as a ring, and the coupling force with the concrete can be further increased.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 and Figure 2 are exploded and assembled perspective views illustrating an extended blade fastener in accordance with a preferred embodiment of the present invention.
Fig. 3 is a perspective view of the expanded wing type fastener of Fig. 2 after the operation is completed; Fig.
Figs. 4 to 7 are cross-sectional views showing a procedure for constructing a slab of a truss-integral deck with a heat insulator using the wing-type fastener of Fig. 2; Fig.

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

FIG. 3 is a perspective view of the extended wing type fastener of FIG. 2 after the operation of the extended wing type fastener is completed; FIGS. 4 to 6 are perspective views of the extended wing type fastener according to the preferred embodiment of the present invention. FIG. 7 is a cross-sectional view showing a procedure for constructing a slab of a truss integral deck with a heat insulator using the extended blade type fastener of FIG. 2; FIG.

As shown in FIG. 1, the extended wing type fastener 100 according to the present embodiment includes a fastener core portion 300 and a fastener outer cylinder 500 in which the fastener core portion 300 is fitted.

The fastener core portion 300 includes a cylinder 310, a plurality of blades 330 formed along the lower end of the cylinder 310, a wedge 350 extending downward from the lower end of the cylinder 310, A flange 370 formed at the upper end of the cylinder 310 and an upper surface engaging protrusion 390 formed between the upper and lower ends of the cylinder 310.

The cylinder (310) is in the form of a rod extending from the upper surface of the heat insulating material (30) to a predetermined depth.

The plurality of vanes 330 are installed at predetermined intervals along the perimeter of the boundary phenomenon between the cylinder 310 and the wedge 350.

The lower end of the vane 330 is fixed on its boundary line, and the pointed upper end is disposed outwardly upward.

That is, the wing 330 is in the form of an elongated rod close to the needle shape.

The wedge 350 is in the shape of an arrowhead and has a configuration in which the cylinder 310 is initially pierced into the heat insulating material 30 so as to easily penetrate to a predetermined depth.

The flange 350 has a larger diameter than the cylinder 310 and is a portion to be caught later when the fastener core portion 300 is pulled up and serves as a step to place a coupling force therebetween when the concrete is poured.

The upper surface engaging jaw 390 is a jaw that rests on the upper surface of the perimeter of the through hole 11 of the steel plate 10. The lower surface of the upper surface engaging jaw 390 becomes a skirt-like bottom surface gradually increasing in thickness from the upper side to the lower side.

The skirt-shaped upper surface engaging jaw 390 is surrounded by the fastener outer cylinder 500 when it first digs into the through hole 11 without being resisted by the fastener, Lt; RTI ID = 0.0 > a < / RTI >

At this time, a long hole 380 is formed in the radial direction of the cylinder 310 in order to lessen the resistance when the upper surface locking jaw 390 is lifted.

It is preferable that the long hole 380 is longer than the upper and lower portions of the skirt.

The long hole 380 is an empty space and acts as a space for elastically deforming the resistance applied to the upper surface engaging jaw 390 when the cylinder 310 is pulled out of the through hole 11 so that the resistance against the protrusion can be instantaneously nailed I can feel it.

The fastener outer cylinder 500 includes a pipe 510, a bottom engaging protrusion 530 formed at the upper end of the pipe 510 and a convex portion 550 formed at the lower end of the pipe 510.

The pipe 510 is sandwiched between the flange 370 and the upper end of the blade 330 so as to surround the outer circumferential surface of the cylinder 310.

As shown in FIG. 1, when the fastener core portion 300 is fitted above the fastener outer cylinder 550, the upper ends of the blades 330 are at least positioned on the outer side of the convex portion 550 by elastic deformation.

The lower jaw 530 is hooked around the lower surface of the through hole 11 of the steel plate 10 and has an inverted skirt shape in which the thickness becomes thicker as it goes up from the upper jaw 530.

Accordingly, the upper surface locking jaw 390 and the lower surface locking jaw 530 serve to fix the insertion position of the fastener 100.

The convex portion 550 is formed to be convex around the lower end of the pipe 510 and serves to expand the wing 330 outwardly when the fastener core portion 300 rises.

Hereinafter, it will be described that the extended wing-type fastener 100 is applied to a truss-integrated deck with a heat insulating material.

As shown in Fig. 4, the truss-integral deck comprises a steel plate 10 and a plurality of truss girders 20 having a truss girder 20 fixed in the longitudinal direction of the steel plate 10, .

A plurality of through holes 11 are formed in the steel plate 10 between the truss girder 20 and the truss girder 20.

The truss girder 20 includes a phase current 21 and a bottom current 23 and a lattice material 25 connecting them.

A foot 26 bent in the horizontal direction is welded and fixed to the welding projection 15 of the steel plate 10 in the lattice material 25. [

The heat insulating material 20 is placed on the bottom surface of the steel plate 10 of the truss-integrated deck and the expanding blade fastener 100 connects the deck and the heat insulating material as shown in FIG. 6 through the through hole 11.

4, when the extended wing-type fastener 100 assembled as shown in FIG. 4 is inserted only up to a predetermined depth into the heat insulating material 20 through the through-hole 11, the lower latching jaw 530 of the fastener outer cylinder 500, And is caught by the peripheral bottom surface of the through-hole 11. At this time, it is preferable to insert the flange 370 until the flange 370 touches the upper surface of the through hole 11.

5, when the flange 370 is pulled up and pulled up, when the upper fastening protrusion 390 is placed on the upper surface of the through hole 11 as the fastener core portion 300 is raised with respect to the fixed fastener outer cylinder 500, You do not have to pull it up.

That is, when the cylinder 310 is raised, the wings 330 are widened with respect to the convex portion 550, and are inserted into the heat insulating material 20 in the form of a ellipse to receive and support the heat insulating material 20.

Therefore, the fastener 100 is caught by the upper surface engaging jaw 390 and the lower surface engaging jaw 530 on the upper and lower surfaces of the through hole 11, and the heat insulating material 20 is fixed to the steel plate 10.

When the truss-integrated deck with the heat insulating material assembled in the state shown in Fig. 6 is installed on the beam, the concrete C is placed on the deck, and the construction of the slab is completed as shown in Fig.

The concrete C can be coupled to the truss girder 20 and the additional reinforcing bars but also to the mutual coupling force through the flange 370 and the elongated hole 380 of the extended blade type fastener 100 to form a more stable slab .

The extended wing type fastener 100 may be made of a metal or a plastic material, but is preferably made of a plastic material in terms of efficiency of molding or elastic deformation. Particularly, the fastener core portion 300 is preferably made of a plastic material.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. It goes without saying that such changes are within the scope of the claims.

10: steel plate 11: through hole
15: welding projection 20: truss girder
21, present current 23: bottom current
25: Lattice ashes 26: Putt
100: wing fastener 300: fastener deep
310: Cylinder 330: Wing
350: Wedge 370: Flange
380: long hole 390: top jaw
500: fastener outer tube 510: pipe
530: lower jaw 550: convex portion

Claims (4)

An extended blade type fastener for supporting a heat insulating material on a bottom surface of a steel plate as a deck plate,
A wedge extending downward from a lower end of the cylindrical body; a flange formed on an upper end of the cylindrical body; and a flange formed on the upper and lower ends of the cylindrical body, An upper surface engaging jaw which is engaged with an upper surface of the through hole of the fastener;
And a convex portion which is fitted between the flange and the vane and is disposed between the upper surface of the vane and the outer circumferential surface of the cylinder at the upper end and the lower surface engaging jaw which is caught at the lower surface of the through hole of the steel plate at the upper end, ≪ / RTI >
Wherein each of the wings is a needle-like shape that is inclined upward toward the outside while the lower end thereof is fixed so as to be expandable (widened).
The method according to claim 1,
And an elongated hole penetrating in the radial direction is further formed in the cylinder at the position where the upper surface engaging jaw is formed.
And a fastening fastener of a plastic material inserted through a plurality of through holes formed in the steel plate to support the heat insulating material in a supporting manner,
The plastic wing-type fastener is characterized in that,
A wedge extending downward from a lower end of the cylindrical body; a flange formed on an upper end of the cylindrical body; and a flange formed on the upper and lower ends of the cylindrical body, An upper surface engaging jaw which is engaged with an upper surface of the through hole of the fastener;
And a convex portion which is fitted between the flange and the vane and is disposed between the upper surface of the vane and the outer circumferential surface of the cylinder at the upper end and the lower surface engaging jaw which is caught at the lower surface of the through hole of the steel plate at the upper end, ; ≪ / RTI >
Wherein the fastener outer tube is embedded in the heat insulating material, and when the fastener core portion is pulled up while being caught by the steel plate, the plurality of wings expand to the outside and are anchored to the heat insulating material in an anchor form.
Preparing a deck on which a truss is fixed on a steel plate placed on an upper surface of the heat insulating material and having a plurality of through holes;
Fastening a fastener-shaped fastener made of a plastic material into the heat insulating material until the flange of the fastener core is caught on the upper surface of the through-hole;
Pulling up the upper flange of the fastener outer tube in the extended blade-type fastener while holding the upper flange of the extended blade-type fastener in the bottom of the through hole of the steel plate when the extended blade type fastener is inserted into the heat insulating material;
Expanding the plurality of blades of the fastener core portion outwardly when the flange portion is pulled up and the fastener core portion is pulled up with respect to the fastener outer cylinder and passes the lower convex portion of the fastener outer tube;
When the fastener deep portion is pulled up until the upper surface engaging jaw protruding outside the elongated hole of the fastener is placed on the upper surface of the through hole of the steel plate, the plurality of wings are inserted into the heat insulating material in an anchor form step;
And a step of installing a truss-integrated deck to which the heat insulating material is connected in a beam and pouring concrete.

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