KR101882206B1 - Insulation Fixture - Google Patents

Abstract

The present invention relates to a construction insulation material fixing device which is used to fix an insulation material to a concrete structure such as a wall and a slab. The device comprises: a bracket (30) fixed to a concrete structure (22); an interference prevention groove (23) formed along a rear edge of a boundary surface (21) of an insulation material (20) to form a space (G) where a bracket (30) is located; a rotation arm (40); a reversed conical head (51, 61); a forward conical portion (52, 62); an insert plate (70); a spring hanging pin (32); a return spring (80); a stopper (34); a vertical elongated hole (71); and a beveling portion (72).

Description

{Insulation Fixture}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat insulating material fixing apparatus for fixing a heat insulating material to a concrete structure such as a wall and a slab. More particularly, the present invention relates to a heat insulating material fixing apparatus for building, which is capable of continuously maintaining the adhesion between the heat insulating material and the concrete structure, .

Generally, a structure made of a concrete structure is provided with a plate-shaped heat insulating material on a concrete slab or a concrete wall for insulation between the floor and the outside.

For the construction of such a heat insulating material on a concrete slab or a concrete wall, the heat insulating material is fixed to the formwork, the concrete is laid, and the heat insulating material is adhered to the concrete structure to be fixed or fixed using a nail.

However, when the concrete structure is closely adhered to the concrete structure and fixed using a nail, there arises a problem that the insulation material is separated from the concrete structure or the insulation material and the insulation material are widened over time.

If the heat insulating material is separated from the concrete structure or the space between the heat insulating material and the heat insulating material spreads, the heat or cold air in the room flows out to the outside through the spreading gap, and the heat insulating performance of the building is greatly deteriorated.

Korean Patent Registration No. 10-0750343 (2007.08.17.) Korean Patent Registration No. 10-0900886 (Jun. 4, 2009) Korean Patent Registration No. 10-1311663 (2013.09.25.)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a heat insulating material fixing device for a building which can continuously maintain the adhesion between the heat insulating material and the heat insulating material and can maintain the adhesion between the heat insulating material and the concrete structure .

To achieve these and other advantages and in accordance with the purpose of the present invention, as embodied and broadly described herein, there is provided an apparatus for fixing a heat insulating material for construction, comprising: a bracket positioned behind an interface between two heat insulating materials and fixed to a concrete structure; An interference preventing groove formed along the rear side edge of the boundary surface of the heat insulating material to form a space in which the bracket is located; A rotary arm installed at the center of the bracket by a pivot pin; A pair of centering pins installed parallel to each other in a direction away from the concrete structure at both sides of the rotary arm; An inverted conical head formed at each end of the centering pin; A capillary portion formed at each end of the inverted conical head; An insert plate which is provided at an interface of the heat insulating material and is in close contact with each other when the two heat insulating materials meet, and inserted between the centering pins; A spring catch pin installed on the bracket; A return spring installed at one end of the centering pin and the spring engaging pin of the pair of centering pins to rotate the rotary arm in one direction; A stopper positioned in the middle of the rotation locus of the rotary arm rotated by the return spring and stopping the rotary arm at a fixed position; A vertical slot formed perpendicularly to the insert plate; And a chamfered portion formed at the outer side edge of the vertical slot toward the interference preventing groove and engaged with and engaged with the inverted conical head.

The present invention provides a method of manufacturing a semiconductor device, comprising: a buried portion bent into an interior of a heat insulating material from an insert plate and embedded in a heat insulating material; And a bent portion formed by bending an end portion of the buried portion.

The present invention as described above has an effect that the adhesion force between the heat insulating material 20 and the heat insulating material 20 and the adhesion force between the heat insulating material 20 and the concrete structure 22 can be maintained by the return spring 80 continuously.

Since the weft portions 52 and 62 are formed at the end portions of the inverted conical heads 51 and 61, it is possible to more smoothly enter the insert plate 70 entering between the centering pins 50 and 60 It is effective.

There is an effect that force can be applied to both the insert plate 70 and the heat insulating material 20 at the same time by the rotary arm 40 and the centering pins 50 and 60 which are subjected to rotational force in one direction by the return spring 80 .

Since the embedding portion 73 and the bending portion 74 that are embedded in the heat insulating material 20 are formed in the insert plate 70, the effect of greatly increasing the bonding force between the insert plate 70 and the heat insulating material 20 have.

Since the return spring 80 for rotating the rotary arm 40 in one direction is provided and the stopper 34 for stopping the rotary arm 40 is provided, it is possible to prevent the rotary arm 40 from being excessively rotated, There is an effect that the rotary arm 40 can be stopped at the position.

The direction in which the adjacent insert plates 70 are brought into close contact with each other by the chamfered portions 72 formed at the corners of the vertical slots 71 and the inverted conical heads 51 and 61 and the direction in which the heat insulating material 20 is moved toward the concrete structure 22 There is an effect that a force can be simultaneously applied in a direction in which the guide member is brought into close contact with each other.

The return spring 80, the centering pins 50 and 60, the inverted conical heads 51 and 61, and the lumbar part 52 by the interference preventing grooves 23 formed in the heat insulating material 20, It is possible to prevent interference due to the heat insulating material 20 when the heat sink 62 is moved.

1 is a cross-sectional perspective view
Fig. 2 is a cross-
3 is a cross-sectional view
4 is a perspective view
5 is a plan view showing the installation process according to the present invention.
6 is an exploded perspective view
7 is a perspective view showing an insert plate, a buried portion and a bent portion according to the present invention.

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

As shown in FIGS. 1 to 7, the present invention comprises a bracket 30 positioned behind an interface 21 where two insulation members 20 meet and fixed to a concrete structure 22; And an interference preventing groove 23 formed along the rear side edge of the interface 21 of the heat insulating material 20 to form a space G where the bracket 30 is located.

The bracket 30 may be formed using a steel plate having a predetermined thickness and may be fixed to the concrete structure 22 by using the concrete nail 24. In this case, The nail holes 31 are formed.

As shown in FIG. 2, when the two heat insulating materials 20 are brought into contact with each other, the interference preventing grooves 23 formed in the heat insulating materials 20 are formed to have an inverted trapezoidal shape.

At this time, the interference preventing groove 23 serves to prevent the bracket 30, the rotary arm 40, the centering pins 50 and 60, the return spring 80, and the like from interfering with the heat insulating material 20.

A rotary arm (40) installed at the center of a bracket (30) by a pivot pin (42); A pair of centering pins (50) (60) installed parallel to each other in a direction away from the concrete structure (22) at both sides of the rotary arm (40); Inverted conical heads 51 and 61 respectively formed at the ends of the centering pins 50 and 60; And conical weight portions 52 and 62 formed at the ends of the inverted conical heads 51 and 61, respectively.

The pivot pin 42 passes through a center hole 44 formed at the center of the rotary arm 40 and a pin hole 33 formed in the bracket 30 and is inserted into the pivot pin 42 projected to the rear surface of the bracket 30, Is formed by flattening and fixing.

The center distances from the pivot pins 42 to the centering pins 50 and 60 are formed at the same distance and the centering pins 50 and 60 are formed horizontally.

The inverted conical heads 51 and 61 and the conical weight portions 52 and 62 are integrally formed at the ends of the centering pins 50 and 60 as shown in Figs. 1 and 5, and the inverted conical head 51 ) 61 are brought into line contact with the chamfered portion 72 formed in the vertical long hole 71 described below and the lumen weight portions 52 and 62 are arranged in such a manner that the insert plate 70 is brought into contact with the centering pins 50 and 60 So that the insert plate 70 smoothly slides and enters.

Chamfering the edge of the insert plate 70 that meets the luminal weights 52 and 62 as shown in Figures 2, 5 and 7 causes the insert plate 70 to move between the centering pins 50 and 60 So that it can enter smoothly.

The present invention is characterized in that an insert plate (70) installed on an interface (21) of a heat insulating material (20) and in close contact with each other when two heat insulating materials (20) meet and inserted between the centering pins (50) (60); A spring catching pin 32 installed on the bracket 30; And a return spring 80 installed at one end of the centering pin 60 and the spring engaging pin 32 of the pair of centering pins 50 and 60 for rotating the rotating arm 40 in one direction .

(Not shown) having a reduced diameter is formed at the rear end of the spring engaging pin 32 as shown in FIGS. 2, 5 and 6, and then the spring (not shown) is inserted into the rivet hole 36 formed in the bracket 30, After the rear end of the latching pin 32 is inserted, the rear end of the spring latching pin 32 protruding rearward is pressed and fixed in the shape of a dish head.

The return spring 80 can be constituted by, for example, a tension coil spring formed by spirally winding a spring steel wire. A ring portion (not shown) is formed at both ends of the return spring 80, And the centering pin (60).

The annular grooves 37 and 63 are formed on the outer circumferential surfaces of the spring retaining pin 32 and the centering pin 60 so that the hooks formed at both ends of the return spring 80 can be hooked .

A stopper (34) is positioned in the middle of a rotation locus of a rotary arm (40) rotated by a return spring (80) and stops the rotary arm (40) at a fixed position. A vertical slot 71 formed perpendicularly to the insert plate 70; And a chamfered portion 72 which is formed at an outer side edge of the vertical slot 71 toward the interference preventing groove 23 and which meets and engages with the inverted conical heads 51 and 61.

A stopper 34 is provided at the rear end of the stopper 34 to fix the stopper 34 to the bracket 30 and a reduced diameter portion It can be press-fitted into the hole 35 and fixed.

The vertical slot 71 may be formed to pass through the left and right side surfaces of the insert plate 70 as shown in FIGS. 1 to 5 and 7, and may include an inverted conical head 51 formed at the edge of the vertical slot 71, (61).

For example, when the inverted conical heads 51 and 61 are formed at an angle of 45 degrees, the chamfered portions 72 are faced at an angle of 45 degrees so as to be in line contact with each other, The pins 50 and 60 and the inverted conical heads 51 and 61 are urged in the direction in which the insert plate 70 is in close contact with each other and the heat insulating material 20 is simultaneously subjected to a force .

The present invention includes a buried portion (73) that is bent into the interior of the heat insulating material (20) from the insert plate (70) and buried in the heat insulating material (20); And a bending portion 74 formed by bending the end portion of the buried portion 73 again.

The insert plate 70, the buried portions 73 and the bent portions 74 can be integrally formed by bending a steel plate having a constant thickness. The insert plate 70, The heat insulating material 20 is molded in a state where the buried portions 73 and the bent portions 74 are inserted so that the buried portions 73 and the bent portions 74 are buried in the heat insulating material 20. [

The surfaces of the insert plates 70 exposed to the outside are matched in the same plane as the interface 21 of the heat insulating material 20 so that when the interfacial surfaces 21 of the two heat insulating materials 20 are in close contact with each other, So that they are in close contact with each other.

A part of the insert plate 70 is projected into the interference preventing groove 23 so as to be caught by the inverted conical heads 51 and 61.

Since the heat insulating material 20 and the insert plate 70, the buried portion 73, and the bent portion 74 are provided symmetrically with respect to each other, the same reference numerals are used.

The rotating arms 40 and the centering pins 50 and 60, the inverted conical heads 51 and 61, the weights 52 and 62, the pivot pin 42, the return spring 80, 32 and the stopper 34 are repeatedly arranged at least at two positions spaced apart from each other along the vertical direction of the bracket 30.

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

As shown in FIGS. 1 to 7, when the concrete nail 24 is inserted into the concrete structure 22 through the nail hole 31 in a state in which the bracket 30 is vertically tightly attached to the concrete structure 22 , The bracket (30) is fixed to the concrete structure (22).

The insert plate 70 is inserted between the centering pins 50 and 60 while the one heat insulating material 20 is closely contacted with the concrete structure 22 and the insert plate 20 70 are brought into close contact with the boundary surface 21 of the adjacent heat insulating material 20 and the remaining heat insulating material 20 is pushed toward the concrete structure 22 so that both the insert plates 70 are brought into close contact with the centering pin 50 ) ≪ / RTI >

When the insert plate 70 thus enters between the centering pins 50 and 60, the insert plate 70 slides along the lug portions 52 and 62 and the rotary arm 40 And the return spring 80 is elongated and has an elastic restoring force in the shrinking direction while being rotated clockwise around the pivot pin 42. [

At this time, when the inverted conical heads 51 and 61 formed at the ends of the centering pins 50 and 60 meet the vertical slot 71, the rotary arm 40 is rotated by the retraction force of the return spring 80, The inverted conical heads 51 and 61 come into line contact with the chamfered portion 72 formed in the vertical slot 71 while the rotary arm 40 is rotated counterclockwise.

When the resilient force is applied by the return spring 80 in a state of being in contact with the inversed conical heads 51 and 61 and the chamfered portion 72 as described above, the insert plate 70 receives force in the direction in close contact with each other, 20 are simultaneously received and fixed in a direction in which they are brought into close contact with the concrete structure 22.

20: Insulation 21: Interface
22: concrete structure 23: interference prevention groove
24: concrete peg 30: bracket
31: nail hole 32: spring catch pin
33: pin hole 34: stopper
35: press-in hole 36: rivet hole
37,63: Annular groove G: Space
40: rotary arm 42: pivot pin
44: center hole 50, 60: centering pin
51, 61: inverted conical head 52, 62:
70: insert plate 71: vertical slot
72: face mounting 73:
74: bent portion 80: return spring

Claims (2)

A bracket (30) located behind the interface (21) where the two insulation members (20) meet and fixed to the concrete structure (22);
An interference preventing groove 23 formed along the rear side edge of the interface 21 of the heat insulating material 20 to form a space G where the bracket 30 is located;
A rotary arm (40) installed at the center of the bracket (30) by a pivot pin (42);
A pair of centering pins (50) (60) installed parallel to each other in a direction away from the concrete structure (22) at both side front surfaces of the rotary arm (40);
Inverted conical heads 51 and 61 respectively formed at the ends of the centering pins 50 and 60;
Retaining portions 52 and 62 respectively formed at the ends of the inverted conical heads 51 and 61;
An insert plate 70 installed on an interface 21 of the heat insulating material 20 and closely adhered to each other when the two heat insulating materials 20 meet and inserted between the centering pins 50 and 60;
A spring retaining pin 32 installed on the bracket 30;
A return spring 80 installed at one end of the pair of centering pins 50 and 60 on both the centering pin 60 and the spring latching pin 32 for rotating the rotary arm 40 in one direction, ;
A stopper (34) positioned in the middle of a rotation locus of the rotary arm (40) rotated by the return spring (80) to stop the rotary arm (40) at a predetermined position;
A vertical slot 71 formed perpendicularly to the insert plate 70;
A chamfered portion 72 formed at an outer side edge of the vertical slot 71 toward the interference preventing groove 23 and engaged with the inverted conical heads 51 and 61;
And a heat insulating material fixing unit for heat insulating the building. The method according to claim 1,
A buried portion 73 bent from the insert plate 70 into the heat insulating material 20 and buried in the heat insulating material 20;
A bent portion 74 formed by bending an end portion of the buried portion 73;
And a heat insulating material fixing unit for heat insulating the building.

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