KR101611059B1 - Composite Sandwich Panel - Google Patents

Abstract

The present invention relates to a composite sandwich panel which is excellent in heat insulation and flame retardancy and which is excellent in structural integrity and strength of a filler.
According to the present invention, there is provided a sandwich panel in which a filler (20) is filled between a pair of external skins (10, 12) facing each other and spaced apart from each other, the filler (20) comprising glass wool or mineral wool And a polyurethane foam layer (24) foam-molded between the mineral fiber board (22) and the other outer skin (12), wherein the mineral fiber board (22) A nonwoven fabric sheet 25 is disposed between the board 22 and the polyurethane foam layer 24 and the nonwoven fabric sheet 25 is provided with a composite sandwich panel in which a polyurethane foamed liquid penetrates to form a hardened reinforcing layer 26 .

Description

Composite Sandwich Panel < RTI ID = 0.0 >

The present invention relates to a composite sandwich panel, and more particularly, to a composite sandwich panel having a new structure which is excellent in heat insulation and flame retardancy and is excellent in the structural integrity and strength of a filler to increase the structural strength of the building.

Sandwich panels made of a metal panel such as galvanized steel or a pair of exterior skins made of TPO panels are lightweight, easy to install, and relatively inexpensive. Therefore, factory buildings and other prefabricated buildings It is widely used for the construction of walls and roofs of buildings. Mineral fiber boards such as foamed resin such as foamed styrofoam resin (EPS), foamed polyurethane resin, glass wool or mineral wool were used as the filler to be filled into the outer skin of the sandwich panel. Among them, the polyurethane foam resin is produced by foaming a polyurethane resin. However, since many pores are formed therein, it has an excellent heat insulating property, but the flame retardancy is low due to its weak fire. As a result, sandwich panels filled with polyurethane foam resin are vulnerable to fires because they are easily ignited during a fire and are burned or melted by the heat of a flame.

On the other hand, a sandwich panel using a mineral fiber board such as glass wool or mineral wool as a filler has an excellent flame retardancy and is not easily fired or melted in a fire, but an air layer formed inside a glass wool or a mineral wool And thus the heat insulating performance is relatively low as compared with the foamed polyurethane resin, which is unsatisfactory.

In addition, fillers such as polyurethane foam, glass wool or mineral wool, such as polyurethane foam filled inside the sandwich panel, are of a soft material, so the structural rigidity of the sandwich panel depends mainly on the outer skin of the metal material, There was a problem that it was relatively weak. In recent years, a composite filler sandwich panel has been introduced which has improved insulation performance and flame retardancy performance by adhering a heat insulating material and a flame retardant to the inside of a sandwich panel with an adhesive and filling them together inside the external skin. However, There is a problem in that the adhesion force between the different fillers made of the two materials is relatively weak, so that the structural integrity of the sandwich panel is low, so that it is easily broken by external impact.

Patent Publication No. 10-2006-0083466 (October 19, 2009)

The present invention has been made in view of the problems of the conventional sandwich panel as described above, and it is an object of the present invention to provide a prefabricated building made of a sandwich panel which is excellent in both heat insulating property and flame retardancy, To provide a composite sandwich panel of a new structure that is robust in structure but can increase the structural strength of the building.

According to an aspect of the present invention, there is provided a sandwich panel in which a filler (20) is filled between a pair of outer skins (10, 12) facing each other so as to face each other, wherein the filler (20) And a polyurethane foam layer (24) formed by foam molding between the mineral fiber board (22) and the other outer skin (12), wherein the polyurethane foam layer (22) The mineral fiber board 22 and the polyurethane foam layer 24 have a relatively dense structure than the mineral fiber board 22, A nonwoven fabric sheet 25 is disposed on the nonwoven fabric sheet 25 and a hardened reinforcing layer 26 is formed on the nonwoven fabric sheet 25. The reinforcing layer 26 is interposed between the mineral fiber board 22 and the polyurethane The composite sandwich panel is characterized in that the foam layer (24) is integrally bonded.

According to another aspect of the present invention, the mineral fiber board 22 is formed to have a smaller width and a length than the skin skins 10 and 12 so that the mineral fiber board 22 is formed at the edge of the skin skin 10 And the polyurethane foam layer 24 fills the peripheral space 28 between the edges of the skin skins 10 and 12 and the edge of the mineral fiber board 22 to form the mineral fiber board 22, The present invention provides a composite sandwich panel comprising:

According to the present invention, a mineral fiber board (22) having relatively excellent flame retardancy is disposed on one side skin (10) side between the skin panels (10, 12) of the sandwich panel and the mineral fiber board By forming the polyurethane foam layer 24 having a relatively excellent heat insulation performance between the skins 12 by foam molding, it is possible to provide a composite sandwich panel which is excellent in heat insulating property and also excellent in flame retardancy.

According to the present invention, a nonwoven fabric sheet 25 having a structure that is relatively more dense than the optical fiber board 22 is disposed between the polyurethane foam layer 24 and the mineral fiber board 22, The polyurethane foam layer 24 is formed between the mineral fiber board 22 and the other outer skin 12 by spraying the foamed liquid to form a polyurethane foam layer 22 at the junction of the mineral fiber board 22 and the polyurethane foam layer 24. [ The hardened reinforcing layer 26 penetrates into the nonwoven fabric sheet 25, and the panel strength of the sandwich panel is further increased. At this time, since the urethane foam liquid is directly sprayed on the relatively dense nonwoven fabric sheet 25, rather than directly sprayed on the mineral fiber board 22, the urethane foam liquid is excessively sprayed on the inside of the mineral fiber board 22 And thus it is possible to provide a composite sandwich panel in which the amount of the urethane foamed liquid is reduced while having an excellent appearance on the cross section.

In addition, since the mineral fiber board 22 and the polyurethane foam layer 24 of the filler 20 in which the heterogeneous materials are formed in combination are solidly bonded together through the reinforcing layer 26, the structural integrity of the composite filler To reduce the risk of detachment of the front and back skin 10, 12 or breakage of the sandwich panel due to structural weakness or external impact of the sandwich panel due to structural weakness of the joint surface of the composite filler.

The mineral fiber board 22 is formed so that its width and length are relatively smaller than that of the outer skin 10 and 12 so that the mineral fiber board 22 is disposed inside the outer skin 10, (24) surrounds the mineral fiber board (22) by filling the peripheral space (28) between the edge of the skin skin (10, 12) and the edge of the mineral fiber board (22) Which can be accomplished without fear of a sandwich panel.

1 is a cross-sectional view of one embodiment of the present invention;
2 is a cross-sectional view of another embodiment of the present invention
3 and 4 are cross-sectional views of a modified embodiment of the above embodiment
5 is a cross-sectional view of another embodiment of the present invention
6 is a cross-sectional view of another embodiment of the present invention
Figure 7 is a cross-sectional view of a modified embodiment of the embodiment of Figure 6;

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. 1 is a cross-sectional view of one embodiment of the present invention. As shown in the drawings, according to the present invention, there is provided a sandwich panel in which a filler 20 is filled between a pair of exterior skins 10, 12 arranged so as to be spaced apart from each other. The outer skins 10 and 12 are generally made of a metal panel coated with a silicone resin, a polyester resin, or a fluorine resin on the surface of a galvanized steel sheet having a thickness of about 0.31 to 0.8 mm. In some cases, Resin materials such as TPO or panels of other materials may be used. Of these skins, the outer skin 10 disposed at the upper part of the drawing is formed with the troughs 13 and the floor 14, and the outer skin 12 disposed at the lower part is formed substantially flat so as to constitute a sandwich panel for the roof . In a manufacturing process of an actual sandwich panel, the sandwich panel is laminated while the upper outer skin 10 is placed on the lower side and the lower outer skin 12 is placed on the upper side.

A filler disposed in contact with the upper external skin 10 among the fillers 20 uses a mineral fiber board 22 made of glass wool or mineral wool. The mineral fiber board 22 has excellent flame retardancy, so that when a fire is generated in a building assembled with a sandwich panel, it is not easily fired and the flame is prevented from being propagated rapidly. On the other hand, the filler disposed in contact with the lower outer skin 12 is composed of a foamed polyurethane foam layer 24. The polyurethane foam layer 24 is formed by preforming and molding the polyurethane foam liquid 22 on the mineral fiber board 22 and then spraying the polyurethane foam liquid onto the mineral fiber board 22 and the other external skin The urethane foam is foamed between the upper and lower molds 12 to fill the space therebetween.

On the other hand, a nonwoven fabric sheet 25 is interposed between the mineral fiber board 22 and the foamed urethane foam layer 24. The nonwoven fabric sheet 25 preferably has a porosity lower than that of the mineral fiber board 22 so that the structure is finer than the mineral fiber. Therefore, even when the urethane foamed liquid is injected onto the corrosion-resistant envelope 25, the depth of penetration of the urethane foamed liquid is relatively low compared with the case where the polyurethane foamed liquid is directly injected onto the mineral fiber board 22, Since the boundary between the mineral fiber board 22 and the polyurethane foam layer 24 is relatively clearly distinguished from the mineral fiber board 22 and the mineral fiber board 22, The thickness of the polyurethane foam layer 24 can be appropriately adjusted so that the heat insulating property and the flame retardant property of the sandwich panel product can be appropriately adjusted according to the required design conditions.

When the nonwoven fabric sheet 25 is placed on the mineral fiber board 22 and the polyurethane foamed liquid is injected into the mineral fiber board 22, the polyurethane foamed liquid passes through the pores of the nonwoven fabric sheet 25 to a certain depth from the surface of the mineral fiber board 22 The mineral fiber board 22 and the foamed urethane foam layer 24 are strongly bonded via the nonwoven fabric sheet 25 and the nonwoven fabric sheet 25 into which the polyurethane foam is impregnated is bonded to the reinforcing layer 26, So as to increase the strength of the composite sandwich panel in which the mineral fiber board 22 and the polyurethane foam layer 24 are laminated.

Therefore, the composite sandwich panel according to the present invention can provide a sandwich panel superior in structural rigidity and tensile strength as compared with a sandwich panel using only the mineral fiber board 22 or only the polyurethane foam layer 24. [ In addition, in the composite sandwich panel in which the composite material is laminated to form the filler 20, the reinforcement layer 26 is formed at the joining portion of the mineral fiber board 22 and the polyurethane foam layer 24 via the nonwoven fabric 25 , The structural integrity of the composite sandwich panel can be enhanced to overcome the structural weakness of the sandwich panel that can result from the reduced adhesion of the filler 20 to the composite 20 in a composite sandwich panel. Meanwhile, the right end of the composite sandwich panel of FIG. 1 ends with an angled joint 15 in which the upper skin 10 is extended, and the left end ends with a horizontal protrusion 16).

FIG. 2 shows another embodiment of the present invention in which a bottom skin skin 10a in contact with a mineral fiber board 22 is formed with a crest and a floor, and an upper skin skin 12a, which is in contact with the polyurethane foam layer 24, . In this case, the flat upper covering skin 12a is made of resin panels of various colors such as a TPO sheet so as to constitute the upper surface of the roof. The right end of the composite sandwich panel of the embodiment of FIG. 2 ends with a downwardly projecting mountain-shaped joint 15a in which the lower outer skin 10a is extended, and the right end ends with a horizontal extension (16a). The joining portion between adjacent panels of the sandwich panel can be finished by welding the joining portion of the TPO sheet strip having excellent durability and waterproofness by hot air or the like to the joint portion after penetrating the joining portion between adjacent panels through the joining bolts.

Fig. 3 is a modified embodiment of the embodiment of Fig. 2, in which the structure of the joint portion is different. That is, the lower external skin 10a is formed with a mountain-like joint 15a protruding downward at the lower end of the right end of the sandwich panel, and a small fastening protrusion 17 is formed at the upper end of the upper external skin 12a And a horizontal protrusion 16a having an upper outer skin 12a protruding horizontally in the upper part of the left end.

Fig. 4 shows another modified embodiment of the embodiment of Fig. 2, in which the structure of the joint portion is different. That is, a downwardly protruding mountain-type joint 15a is formed in a lower portion of the right end of the sandwich panel and a horizontal extension portion 16a in which an upper outer skin 12a is horizontally extended. Is not formed.

5 shows another embodiment of the present invention in which the upper outer skin 10 and the lower outer skin 12 are all made of flat panels without separate ridges. As described above, according to the present invention, it is needless to say that the outer skins 10 and 12 may be bent in various forms. Here, the mineral fiber board 22 is disposed on the upper portion and the polyurethane foam layer 24 is disposed on the lower portion. However, the upper and lower positions may be changed in actual construction. In this embodiment, a short step portion 17a having substantially the same size is formed on the upper and lower portions of the right end, and a horizontal protruding portion 16a engaged with the step portion 17a on the upper and lower ends of the left end.

6 is a perspective view of a mineral fiber board according to another embodiment of the present invention. As shown in FIG. 6, the upper and lower insulation materials made of the mineral fiber board 22 are formed to be shorter in width and length than the lower insulation material made of the polyurethane foam layer 24, And the polyurethane foam layer 24 is filled in the peripheral space 28 between the edges of the skin skins 10 and 12 and the edge of the mineral fiber board 22 So as to surround the mineral fiber board 22. According to such a configuration, the polyurethane foam layer 24 having a relatively high heat insulating property can be prevented from being exposed to the outside by covering the mineral fiber board 22, so that the vulnerability of the sandwich panel to the heat insulation can be eliminated, Can be achieved. Further, the structure of the joint portion in the embodiment of Fig. 6 is configured differently from the above-described embodiment. That is, the upper end of the upper skin 10 is slightly longer than the lower end of the right end, and the upper end and the lower end of the upper end are horizontally protruded.

7 is a modified embodiment of the above embodiment in which the polyurethane foam layer 24 is formed larger than the mineral fiber board 22 to prevent the mineral fiber board 22 from being exposed to the outside, This is the same as the embodiment, but the structure of the joint portion is modified. That is, the upper skin 10 on the right end is extended horizontally, the lower skin 12 is protruding horizontally horizontally, and the upper skin 10 has a long stepped portion so as to have a complementary shape with the right- The skin (12) has a short step portion.

Claims (2)

A sandwich panel in which a filler (20) is filled between a pair of outer skin (10, 12) spaced apart from each other and spaced apart from each other, the filler material (20) comprising glass wool or mineral wool And a polyurethane foam layer 24 formed by foam molding between the mineral fiber board 22 and the other outer skin 12. The mineral fiber board 22 and the other outer skin 12 are made of the same material, A nonwoven fabric sheet 25 having a structure that is relatively more dense than the mineral fiber board 22 is disposed between the polyurethane foam layers 24 and the reinforcing layer 26 cured by penetration of the polyurethane foamed liquid , And a mineral fiber board (22) and a polyurethane foam layer (24) are integrally joined to each other via the reinforcing layer (26).
The mineral fiber board according to claim 1, wherein the mineral fiber board (22) is formed to have a width and a length smaller than the outer skin (10, 12) And the polyurethane foam layer 24 surrounds the mineral fiber board 22 by filling the peripheral space 28 between the edges of the skin skins 10 and 12 and the edge of the mineral fiber board 22 Wherein the composite sandwich panel comprises:

Images