KR101271597B1 - Building insulation fixtures - Google Patents

Abstract

PURPOSE: An insulation material fixing unit for construction is provided to improve the insulation effects by blocking the exit and entrance of the cool and hot air through a hole formed in an insulation material. CONSTITUTION: An insulation material fixing unit for construction comprises a set anchor(20), a spacer(30), a moving sleeve(40), a foam sealing member(50), a left spring sheet(60), a compressed spring(70), a washer(25), an angle(23), and an angle fixing nut(28). The spacer is inserted into a hole(24) formed in an insulation member(22) and is supported by a concrete wall(26). The moving sleeve is inserted into an outer circumference of the spacer and comprises a cover flange(42). The foam sealing member is attached to the cover flange. The compressed spring is installed between a left spring sheet on the left of the spacer and a right spring sheet(48) on the right of the moving sleeve. The foam sealing member is attached to the insulation member in clamping the angle fixing nut so that the exit and entrance of the hot and cool air through the hole is blocked.

Description

Building insulation fixtures

The present invention relates to a building insulation fixture, and more particularly, to a building insulation fixture to be suitable for improving the heat insulation effect by closing the hole for installing the set anchor for fixing the stone.

In general, the stone used for building interior and exterior materials is a rectangular hole 14 for installing the set anchor 13 in the heat insulating material 12 installed between the concrete wall 10 and the stone 11 as shown in the accompanying drawings. After cutting using a tool such as a knife to remove and then install the set anchor 13 to the concrete wall (10), the angle (15) for fixing the stone (11) set anchor (13) by the nut (16) Was supposed to install.

However, such a general stone fixture has a problem that the heat or cold air is moved by a relatively large hole 14 formed in the heat insulating material 12 for the set anchor 13 is installed, the heat insulating effect is lowered.

The present invention has been made to solve the above problems, its purpose is to close the perforated hole in the heat insulating material for installation of the set anchor to prevent cold or warm air passing through the building insulation that can reduce heating and cooling costs In providing a fixture.

In order to achieve the object of the present invention, a metal insert through which the set anchor is penetrated to the center is inserted into a hole formed in the heat insulating material so as to be supported by the concrete wall surface, and inserted into the outer circumferential surface of the spacer to slide in the axial direction. A cover flange in the form of a disc covering the surface of the heat insulating material is formed at the left end of the movable sleeve, and the foam sealing material that is in close contact with the surface of the heat insulating material is bonded to the cover flange by double-sided tape, and fixed to the left end of the spacer by the angle fixing nut. A plurality of locking projections are formed radially on the outer circumferential surface of the left spring sheet to be formed, and a plurality of slide grooves coupled to the locking projections are formed on the inner circumferential surface of the movable sleeve, and have an "L" shape extending from the left end surface of the movable sleeve to the slide groove. A projection entry groove with a path is formed in the movable sleeve and the right side of the movable sleeve The building insulation fastener is provided by a compression spring installed between the right formed in the spring seat portion and the left spring seat.

As described above, the present invention has a structure of blocking a hole formed in the heat insulating material by blocking the movable sleeve to block the flow of hot and cold air inside and outside through the hole formed in the heat insulating material, thereby improving the heat insulating effect.

In addition, since the movable sleeve is configured to move left and right by the compression spring, even if there is an error due to the thickness of the insulation or other reasons, the movable sleeve is moved to the left and right in a flexible manner and is always preloaded by the compression spring. It is effective to maintain.

Furthermore, the compressive strength of the spacer is improved by the metal insert inserted into the center of the spacer, and thus the effect of fixing the stone more firmly can be expected.

In addition, even if the surface of the heat insulating material is uneven, the foam sealing material installed on the cover flange of the movable sleeve is deformed flexibly, there is an effect that can maintain the adhesion.

1 is a view showing a typical stone fixture
Figure 2 is a cross-sectional view showing a building insulation fixture according to the invention
Figure 3 is an exploded perspective view showing a building insulation fixture according to the invention
Figure 4 is a partial cross-sectional perspective view showing the movable sleeve and the spacer according to the present invention
5 is a perspective view showing a left spring sheet according to the present invention
Figure 6 is a perspective view of the movable sleeve according to the present invention

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

2 to 6, the spacer 30 having the metal insert 32 through which the set anchor 20 penetrates to the center is inserted into the hole 24 formed in the heat insulating material 22. To cover the surface of the heat insulating material 22 on the left end of the movable sleeve 40 slid in the axial direction to be supported by the concrete wall surface 26 and slid in the axial direction. And a foam sealing material 50 formed of a foam material in close contact with the surface of the heat insulating material 22 to the cover flange 42 by the double-sided tape 52.

The spacer 30 may be molded using a synthetic resin, and the metal insert 32 is for reinforcing the axial compressive strength of the spacer 30, and after cutting the metal pipe, Insert in the center of the interior.

In addition, a circular flange 34 supported on the concrete wall surface 26 is formed at the right end of the spacer 30, and a reinforcing rib 36 is formed at the outer corner of the circular flange 34 for strength reinforcement. .

Then, a plurality of locking projections 62 are formed radially on the outer circumferential surface of the left spring sheet 60 fixed to the left end of the spacer 30 by the angle fixing nut 28, and the locking projections 62 and A plurality of slide grooves 44 to be coupled are formed on the inner circumferential surface of the movable sleeve 40, and a circular hole 64 through which the set anchor 20 penetrates is drilled in the center of the left spring sheet 60.

That is, the slide groove 44 is formed in the axial direction to guide when the movable sleeve 40 moves in the axial direction.

Further, a projection entry groove 46 having a "L" shaped path extending from the left end surface of the movable sleeve 40 to the slide groove 44 is formed in the movable sleeve 40, and the right side of the movable sleeve 40 is formed. A compression spring 70 is installed between the right spring sheet 48 and the left spring sheet 60 formed at the end.

Such a projection entry groove 46 is a block formed in the right spring sheet 48 when the compression spring 70 is inserted into the movable sleeve 40 and then the right spring sheet 48 is assembled to the movable sleeve 40. If the right spring sheet 48 is rotated in the direction in which the slide groove 44 is formed after the insertion of the machine 62, the right spring sheet 48 may be prevented from being separated from the movable sleeve 40.

In addition, the movable sleeve 40, the compression spring 70, the left spring sheet 60 is assembled in advance in the production plant, and then using the double-sided tape 52 to adhere the foam sealing material 50 to the cover flange 42 If left, the air can be significantly shortened because it can be used immediately on site.

On the other hand, the hole 24 formed in the heat insulating material 22 can be perforated in a circular shape, in the drawing, reference numeral 21 denotes a stone, 23 denotes an angle for supporting the stone 21, 25 denotes an angle The washer installed between the 23 and the right spring sheet 48 is shown, and 27 is a pin for preventing the stone 21 from being separated.

Hereinafter, the operation according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 2 to 6, the assembly of the movable sleeve 40, the compression spring 70, and the left spring seat 60 is performed by inserting the compression spring 70 into the movable sleeve 40. The left spring sheet 60 is pushed into the movable sleeve 40 in the state where the locking projection 62 formed on the left spring sheet 60 is aligned with the projection entry groove 46 formed on the movable sleeve 40 and then slides again. When the groove 44 is rotated in the formed direction, the locking projection 62 is caught while being positioned in the slide groove 44 via the “L” shaped projection entry groove 46, and the left spring sheet 60 is caught. It is assembled to the movable sleeve 40.

Then, when the foam sealing material 50 is bonded to the cover flange 42 formed on the movable sleeve 40 by using the double-sided tape 52, the movable sleeve 40, the compression spring 70, the left spring sheet 60 Is assembled into one, and at the same time the foam sealing material 50 is bonded to the cover flange 42 formed on the movable sleeve 40 by the double-sided tape 52, this assembly process is pre-assembled in the production plant before the construction site, Construction can be done conveniently and quickly on site.

On the other hand, in the state where the set anchor 20 is installed on the concrete wall surface 26 to fix the stone 21, the center of the set anchor 20 is substantially coincident with the set anchor 20 and the concrete wall surface 26 to be exposed. After the hole 24 is drilled through the heat insulating material 22, the spacer 30 is inserted into the set anchor 20 so that the set anchor 20 penetrates into the center of the metal insert 32 inserted into the spacer 30. When fitted, the circular flange 34 formed on the right end of the spacer 30 is in close contact with the concrete wall surface (26).

Then, the movable sleeve 40 is inserted into the spacer 30 to insert the movable sleeve 40 assembled together with the compression spring 70 and the left spring seat 60 into the hole 24 formed in the heat insulating material 22. Insert the washer (25) and the angle (23) to the set anchor (20) and tighten the angle fixing nut (28), the left spring seat 60 is the spacer 30 and the metal insert (32) It is in close contact with the left end of the.

Thus, in the process of tightening the angle fixing nut 28, the movable sleeve 40 is gradually pushed to the right side by the compression spring 70, and the foam sealing material 50 which is installed on the cover flange 42 of the movable sleeve 40. The hot and cold air flows in and out through the hole 24 formed in the heat insulating material 22 to be in close contact with the surface of the heat insulating material 22.

That is, even if there is an error in the thickness of the heat insulating material 22, since the movable sleeve 40 moves flexibly to the compression spring 70 in left and right directions, the foam sealing material 50 maintains the adhesion by the elastic force of the compression spring 70. Done.

20: set anchor 21: stone
22: insulation 23: angle
24: hole 25: washer
26: concrete wall 27: pin
28: angle fixing nut 30: spacer
32: metal insert 34: round flange
36: reinforcement rib 40: movable sleeve
42: cover flange 44: slide groove
46: projection entry groove 48: right side spring seat
50: foam sealing material 52: double-sided tape
60: left spring seat 62: locking projection
64: round hole 70: compression spring

Claims (1)

Insert the spacer 30 inserted in the center of the metal insert 32 through which the set anchor 20 penetrates into the hole 24 formed in the heat insulating material 22 so as to be supported by the concrete wall surface 26. A disc-shaped cover flange 42 covering the surface of the heat insulating material 22 is formed at the left end of the movable sleeve 40 which is fitted to the outer circumferential surface of the ash 30 and slides in the axial direction, and closely adheres to the surface of the heat insulating material 22. The outer circumferential surface of the left spring sheet 60 is bonded to the cover flange 42 by a double-sided tape 52 and fixed to the left end of the spacer 30 by an angle fixing nut 28. A plurality of engaging projections 62 are formed radially on the inner surface, and a plurality of slide grooves 44 coupled to the engaging projections 62 are formed on the inner circumferential surface of the movable sleeve 40 and the left end surface of the movable sleeve 40 is formed. Movable sleeve 40 having a projection entry groove 46 having a "L" shaped path leading from the slide groove 44 to the slide groove 44 Formation, and the movable sleeve insulator construction clamp, characterized in that configured 40 by installing a compression spring 70 between the right spring seat 48 and the left spring seat 60 formed on the right end of the.

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