KR102001515B1 - Assembly type polystyrene insulation foam - Google Patents

Abstract

The present invention relates to a prefabricated polystyrene insulator for construction work, which prevents polystyrene from being damaged by inserts when the inserts are driven into the polystyrene and the polystyrene is fixed to the surface of a wall, and more specifically, to a prefabricated polystyrene insulator for construction work, which fixes polystyrene by assembling covers, into which inserts are fitted, with previously punched assembly holes of the polystyrene. To this end, the present invention comprises: main polystyrene fixed to the surface of a wall of a building by inserts and having a plurality of assembly holes punched in the thickness direction; first stopper polystyrene inserted into a specific assembly hole selected from the plurality of assembly holes and having a fitting hole into which each of the inserts is fitted; and a plurality of absorbing members inserted into the polystyrene and absorbing the heat of the interior of the building. The first stopper polystyrene into which the inserts are inserted is assembled to the assembly holes formed at a specific position of the main polystyrene to fix the main polystyrene to the surface of the wall, and the remaining assembly holes are sealed with second stopper polystyrene.

Description

{Assembly type polystyrene insulation foam}

The present invention relates to a prefabricated styrofoam thermal insulation material for preventing damage to a styrofoam by an insert when the insert is stuck to a wall surface of the styrofoam, and more particularly, to a prefabricated styrofoam prefabricated with an insert, To a prefabricated styrofoam heat insulation material for building construction.

Generally, a polystyrene foam is inserted into a wall or a ceiling of a building or a lower portion of various slabs to insulate the room from the outside, thereby preventing leakage.

On the other hand, in order to fix the styrofoam to the wall surface or the like as described above, an insert is used. The insert typically includes a head having a peak through which the styrofoam penetrates, such as against a wall surface, and a body extending therefrom.

For example, the 'Styrofoam insert for construction' of Korean Patent No. 10-0572339 includes a body having a peak, a female screw part to which a hanger bolt is fastened, and a hook part for fastening the reinforcing bar to fix the styrofoam to the ridge.

However, as shown in FIG. 1, the styrofoam is broken (broken or pierced) (BK) when the insert 10 is inserted into the styrofoam 20 regardless of which type of insert 10 is used. There is a problem that leakage occurs in the broken gap.

Korean Patent No. 10-0572339 entitled " Styrofoam Inserts for Architects "

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a styrofoam assembly in which an insert is inserted into an assembly hole of a styrofoam drilled in advance to prevent damage to the styrofoam caused by an insert when the insert is inserted into the styrofoam. And to provide a prefabricated styrofoam insulation for building construction that fixes styrofoam.

To this end, the prefabricated styrofoam heat insulating material for building construction according to the present invention comprises: a main styrofoam fixed to a wall surface of a building by an insert and having a plurality of pierced holes perforated in the thickness direction; A first plug styrofoam inserted in a specific one of the plurality of the assemblies and having a fitting hole into which the insert is inserted; And an absorbing member installed in the styrofoam so as to absorb the indoor heat of the building, wherein the first plug styrofoam in which the insert is fitted is assembled to an assembling hole formed at a specific position of the main styrofoam to fix the main styrofoam to the wall surface And sealing the remaining assemblies with the second plug of styrofoam.

The first plug styrofoam may include an engaging projection located on a side of the wall of the building upon completion of assembly, and an insertion protrusion protruding from the engaging projection toward the front side opposite to the wall side to be assembled to the assembly hole, Wherein the first styrofoam is fitted to the rear surface of the main styrofoam from the rear side of the main styrofoam, and the first styrofoam is fitted to the front side of the main styrofoam, It is preferable that it is prevented from being separated.

The non-woven fabric may further include a non-woven fabric bonded to a front surface or a rear surface of the main styrofoam to prevent breakage of the main styrofoam, wherein the non-woven fabric has holes formed in the same shape and number as those of the non-woven fabric, So as to be coincident with the assembling hole of the main body.

In the present invention as described above, a first plug styrofoam having a fitting hole is assembled into a specific assembling hole of a plurality of assemblies formed on the main styrofoam, and the main styrofoam can be fixed to a wall or the like by inserting an insert into the fitting hole.

In addition, the present invention permits free selection of the position at which the insert can be stuck by making the remaining clips without the first closure styrofoam assembled closed with a second closure styrofoam.

1 is a perspective view showing a conventional styrofoam according to the prior art.
2 is a perspective view illustrating a prefabricated styrofoam thermal insulation material for building construction according to the present invention.
FIG. 3 is an enlarged view of the styrofoam of FIG. 2; FIG.
4 is an assembled state diagram of a prefabricated styrofoam thermal insulation material for construction work according to the present invention.
5 is an enlarged view of a closure Styrofoam according to another embodiment of the present invention.
6 is a rear view of a main styrofoam according to another embodiment of the present invention.
7 is a state in which the nonwoven fabric is adhered to the present invention.
8 is a sectional view taken along the line AA in Fig.
9 is a perspective view showing another embodiment of the prefabricated styrofoam heat insulation material for building construction according to the present invention.
Fig. 10 is a sectional view of Fig. 9. Fig.

Hereinafter, other objects and features of the present invention will be apparent from the description of embodiments with reference to the accompanying drawings. Unless defined otherwise, all terms used herein, including technical and scientific terms, Have the same meaning as commonly understood by those of ordinary skill in the art to which the invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the relevant art and are to be interpreted in an ideal or overly formal sense unless explicitly defined in the present application Do not.

Hereinafter, a prefabricated styrofoam heat insulation material for construction (hereinafter briefly referred to as a prefabricated styrofoam heat insulation material) according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2, the prefabricated styrofoam heat insulating material 100 includes a main styrofoam 110, a first plug styrofoam 120, and a second plug styrofoam 130. As shown in FIG. Further, in another preferred embodiment of the present invention, the nonwoven fabric 140 and the absorbent member 150 may be further included.

The first styrofoam 120 having the fitting hole 121 and the second styrofoam 130 having no fitting hole 121 are formed in the main styrofoam 110. The main styrofoam 110 has a plurality of assembling holes 111, And are assembled into the assembly holes 111 of the styrofoam 110, respectively.

The first plug styrofoam 120 is assembled to a specific assembly hole 111 of the plurality of assembly holes 111 formed in the main styrofoam 110 and the insertion hole 121 of the first plug styrofoam 120 is inserted 10 so that the main styrofoam 110 can be fixed to a wall surface or the like without any breakage.

The remaining plug assemblies 111 that are not assembled with the first plug styrofoam 120 can be closed (i.e., closed) by the second plug styrofoam 130 to thereby freely select a position at which the insert 10 can be inserted I will.

The nonwoven fabric 140 is adhered and fixed to the front or rear surface of the main styrofoam 110 and is fixed to the surface of the main styrofoam 110 after the nonwoven fabric 140 is flattened to prevent breakage of the main styrofoam 110 do.

The absorptive member 150 is installed in the interior of the building in which heating is performed, that is, the surface of the main styrofoam 110 so as to expose the outer surface thereof, absorbs the heat of the room due to heating, The cold air delivered from the installed wall surface is prevented from being transmitted to the room, and warmth can be felt on the wall surface of the room.

More specifically, the main styrofoam 110 is formed in the shape of a quadrilateral plate as in the usual case, and is manufactured to have a thickness of more than a certain thickness, and provides an adiabatic effect and a water leakage prevention effect,

The main styrofoam 110 is fixed to a wall surface of a building (hereinafter referred to as a ceiling or a lower portion of a sleeve) by means of an insert 10, and in particular, a plurality of assembling holes 111, .

The first plug styrofoam 120 or the second plug styrofoam 130 is selectively inserted into the plurality of assembly holes 111 formed in the main styrofoam 110 as described in the present invention to block the assembly hole 111 as described later.

At this time, the first plug styrofoam 120 is formed with the insertion hole 121 to prevent the main styrofoam 110 from being broken or broken when the insert 10 is assembled and the insert 10 is fixed by being inserted into a wall surface or the like. do.

However, since only the first plug styrofoam 120 or the second plug styrofoam 130 is fitted and sealed, the assembly hole 111 may be a clover-type or polygonal assembly hole 111 in addition to the circular shape as shown in FIG. .

In addition, the size and number of the assembly holes 111 can be adjusted as needed. For example, the assembly holes 111 may be provided in a grid pattern as well as various patterns including a concentric circle pattern.

In the main styrofoam 110, a plurality of absorbing members 150 are inserted at equal intervals or at equal intervals to form an absorbing member 150 for absorbing indoor warmth of a building in which heating is performed. As shown in FIG. 8, the absorbing member 150 is made of rod-shaped silver having a high thermal conductivity, and the cold air passing from the wall surface side is transmitted to the surface side through the absorbing member 150 One end of the absorptive member 150 is exposed to the outside of the main styrofoam 110 in the surface side direction and the other end of the absorptive member 150 has a length D of at least half of the thickness T of the main styrofoam 110 It is preferable to insert and dispose it so that it does not have.

Furthermore, the absorbing members 150 may be provided on the main styrofoam 110 at unequally spaced intervals. However, when the main styrofoam 110 is cut by a certain length according to the needs of the operator, Respectively.

Therefore, the resident of the room can have the effect of not feeling the outdoor cold air even though leaning against the wall of the room through the absorption member 150 absorbing the room temperature that has been raised due to the heating.

3, the first closure styrofoam 120 is inserted into a specific one of the assembly holes 111 of the main styrofoam 110, and the first closure styrofoam 120 is fitted with the insert 10, The insertion hole 121 is formed to pass through.

The first closure styrofoam 120 has the same shape as that of the assembly hole 111 so as to be fitted into the assembly hole 111 and to seal the assembly hole 111. The first closure styrofoam 120 is formed of a main styrofoam 110, Lt; RTI ID = 0.0 > 110 < / RTI >

Since the insert hole 121 of the first plug styrofoam 120 is the same as the cross sectional shape of the insert 10 so that the insert 10 is inserted into the first plug styrofoam 120 when the insert 10 is put on the wall, Without breaking it.

The position of the first closure styrofoam 120 is determined depending on the choice of the operator or the design of the building. The position of the first closure styrofoam 120 is determined depending on the position of the insert 10 used for fixing the main styrofoam 110 to the wall surface, ) Are selected.

4, the position of the insert 10 can be freely determined by assembling the first plug styrofoam 120 to any one of the assembling holes 111 of the main styrofoam 110, The insert 10 is inserted into the fitting hole 121 to prevent damage to the styrofoam.

The second plug styrofoam 130 is inserted into an assembling hole 111 in which the first plug styrofoam 120 is not inserted among the plurality of assembling holes 111 provided in the main styrofoam 110, (That is, closed).

Since the second closure styrofoam 130 functions to block the remaining remaining assemblies 111 after the position where the main styrofoam 110 is fixed by inserting the insert 10 through the first closure styrofoam 120, There is no ball 121.

The second plug styrofoam 130 also has the same shape as that of the assembly hole 111 so as to be fitted into the assembly hole 111 and to seal the assembly hole 111. The second plug styrofoam 130 is not protruded from the front or rear surface of the main styrofoam 110 And has the same thickness as the main styrofoam 110.

The first closure styrofoam 120 and the second closure styrofoam 130 are preferably provided to be selectively used in accordance with the field conditions. The first closure styrofoam 120 and the second closure styrofoam 130 130 are not necessarily the same as the number of the assembling holes 111. [

That is, the first closure styrofoam 120 and the second closure styrofoam 130 can be separated from the main styrofoam 110 to be installed in the field by cutting them with a punching machine or a blade in advance, May be provided more than the number of the assembly holes 111, including the extra portion, by cutting the separate styrofoam.

As shown in FIG. 5 (a), the present invention can be applied to a structure in which the first stopper styrofoam 120 is provided with the latching protrusion 120a. The stopper 120a is used to prevent the assembled first closure styrofoam 120 from being detached from the main styrofoam 110. [

For this purpose, the first closure styrofoam 120 protrudes from the locking protrusion 120a located at the wall surface side of the building upon completion of assembly, and to the front side opposite to the wall surface side from the locking protrusion 120a, And the insertion protrusion 120b.

As shown in FIG. 6, a seating groove 112 is formed on the rear surface of the main styrofoam 110, which is viewed from the side of the wall of the building when the assembly is completed, on which a locking projection 120a of the first styrofoam 120 is seated.

The seating groove 112 is formed in the same shape as the engaging projection 120a, thereby engaging with each other. The depth of the seating groove 112 is equal to the thickness of the locking protrusion 120a and prevents the main styrofoam 110 from protruding outward from the rear surface of the main styrofoam 110 when assembled with the first plug styrofoam 120, So as to be brought into close contact with the wall surface.

The protrusion 120a of the first plug styrofoam 120 protrudes in the circumferential direction of the insertion protrusion 120b because the diameter of the protrusion 120a is larger than that of the insertion protrusion 120b and is larger than the assembly hole 111. [

Therefore, when the first closure styrofoam 120 is fitted from the rear side of the main styrofoam 110, the first closure styrofoam 120 is prevented from falling to the front side. When the insert 10 is inserted into the fitting hole 121 of the first plug Styrofoam 120, the main styrofoam 110 is fixed to the wall surface or the like.

However, since the second plug styrofoam 130 is not a part where the insert 10 is assembled, it is not required to be composed of the locking protrusion 120a and the insertion protrusion 120b like the first plug styrofoam 120, the second closure styrofoam 130 may have the same structure as the first closure styrofoam 120 as shown in FIG.

The nonwoven fabric 140, which is not described above, is used to reinforce the strength of the main styrofoam 110. When the main styrofoam 110 is placed on a wall surface or a ceiling or the like, Corner portions).

7, the nonwoven fabric 140 is adhered to the front surface or the rear surface of the main styrofoam 110 to prevent breakage of the main styrofoam 110. In the nonwoven fabric 140, Holes 141 are formed.

Therefore, if the holes 141 of the nonwoven fabric 140 are adhered so as to coincide with the assembling holes 111 of the main styrofoam 110, the strength of the main styrofoam 110 is reinforced and the holes 141 of the nonwoven fabric 140 pass through the holes 141 A first closure styrofoam 120 and a second closure styrofoam 130 are assembled.

As shown in FIGS. 9 and 10, the prefabricated styrofoam heat insulation material 100 according to the present invention may be used to prevent the prefabricated styrofoam heat insulation material 100 from being damaged due to moisture, The moisture barrier layer 200 may be further formed.

As shown in the figure, the moisture barrier layer 200 of the present invention is provided with a plate shape so as to cover the surface of the styrofoam 100 so that the absorptive member 150 can be exposed to the outside.

For example, the moisture barrier layer 200 is a mixture of loess, tourmaline and muscovite in powder form, and has 20 to 25 parts by weight of loess and 16 to 22 parts by weight of muscovite per 100 parts by weight of tourmaline.

In addition, the moisture barrier layer 200 according to the present invention can be adhered to the outer surface of the foam 150 by mixing a curing agent to maintain the shape of the plate.

At this time, it is preferable that tourmaline is a tourmaline which is a tourmaline which generates a minute current of at least 0.02 A (amperes), and a mixture of powder of loam and muscovite is 200 to 350 mesh.

The moisture barrier layer 200 generates anions and emits far-infrared rays by the microcurrent of the tourmaline which is uniquely generated, thereby preventing foreign matter (e.g., mold) due to moisture from adhering to the surface of the moisture barrier layer 200, Because of its antimicrobial properties, loess helps the tourmaline to prevent the foreign matter from sticking.

In addition, muscovite is a mineral containing aluminum or iron substitute, which can maximize the effect of tourmaline when used together with tourmaline.

Further, the mixture constituting the moisture barrier layer 200 of the present invention, which is cured in the form of a plate on the styrofoam 110 in the form of powder, is subjected to a firing process to form microorganisms (including germs) parasitic on the tourmaline, Allow the mixture to form in a completely removed state.

As described above, the present invention has been described with reference to particular embodiments, such as specific elements, and specific embodiments and drawings. However, it should be understood that the present invention is not limited to the above- And various modifications and changes may be made thereto by those skilled in the art to which the present invention pertains.

Accordingly, the spirit of the present invention should not be construed as being limited to the embodiments described, and all of the equivalents of the claims, as well as the appended claims, are within the scope of the present invention .

10: Insert (Main Styrofoam Fixture)
110: main styrofoam
111: Assembly
112: seat groove
120: Staple No. 1 Styrofoam
120a:
120b: insertion projection
121: Insertion ball
130: Second Staple Styrofoam
140: Nonwoven fabric
141: hole

Claims (1)

A main styrofoam 110 fixed to the wall surface of the building by the insert 10 and having a plurality of holes 111 perforated in the thickness direction;
A first closure styrofoam 120 fitted in a specific one of the plurality of assembly holes 111 and having a fitting hole 121 into which the insert 10 is inserted;
A second closure styrofoam (130) for sealing the assembly hole (111) in which the first closure styrofoam (120) is not fitted among the plurality of the assembly holes (111); And
A plurality of absorption members 150 installed in the styrofoam 110 for absorbing the heat of the building,
The first plug styrofoam 120 fitted with the insert 10 is assembled to an assembly hole 111 formed at a specific position of the main styrofoam 110 to fix the main styrofoam 110 to the wall surface, (130) to seal the remaining assemblies (111)
The first plug styrofoam 120 protrudes from the engaging protrusion 120a located on the wall surface side of the building when the assembly is completed and the front surface side opposite to the wall surface side from the engaging protrusion 120a, And an insertion protrusion 120b to be assembled,
A seating groove 112 on which the locking protrusion 120a is seated is formed on a rear surface of the main styrofoam 110 facing the side of the wall of the building when the assembly is completed,
The first plug styrofoam 120 is prevented from being released to the front side when the first plug styrofoam 120 is fitted from the rear side of the main styrofoam 110,
The main styrofoam 110 may further include a nonwoven fabric 140 adhered to a front or rear surface of the main styrofoam 110 to prevent breakage of the main styrofoam 110. The nonwoven fabric 140 may have the same shape and number Wherein a hole 141 is formed in the main styrofoam 110 and the hole 141 of the nonwoven fabric 140 is adhered to the assembly hole 111 of the main styrofoam 110.

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