JP2018178359A - Interior building material - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an interior building material 10 which is formed by using a flame-retardant resin foam 50, and which can be easily manufactured, and has sufficient strength and flame-retardancy.SOLUTION: The flame-retardant resin foam 50, which is the main body of the interior building material 10, is configured so that the flame-retardant is attached to the entire wall surface of the bubble of the foamed resin. The flame-retardant is composed of 100 pts.wt. or more based on 100 pts.wt. of the foamed resin. The flame-retardant is one or more compounds including calcium, boron, phosphorus, aluminum or magnesium. A metal foil is provided on the front surface side of the flame-retardant resin foam 50 and a glass cloth is provided on the back surface side.SELECTED DRAWING: Figure 1

Description

  BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to an interior building material used for indoor side walls and a ceiling, and relates to a building material for interior that is lightweight and excellent in flame retardancy and excellent in cushioning properties.

Plate-like interior building materials are used to form walls and ceilings in buildings. The wall surface and the ceiling need to have an appearance appropriate to the place and be sufficiently provided with strength and flame resistance as a building material.
And in the wall surface which a person contacts, it is preferable to have cushioning property which reduces the impact to a human body, even when a person falls and collides.

  Foamed resin is good as a building material because it is light in weight and excellent in heat insulation, and attempts have been made to eliminate inflammability, which is a drawback, as a building material for interiors.

Patent Document 1 describes a plate-like interior building material using an olefin-based flame-retardant resin foam having a thickness of 0.1 to 2 mm, and an azo-based compound, a sulfonyl hydrazide-based compound, and the like as a foaming agent. The use of nitroso compounds and the like, and the use of aluminum hydroxide, magnesium hydroxide and the like as a flame retardant are described.
As for the flame retardant resin foam, the foaming ratio is 1.5 to 7, and it is described that 80 to 150 parts by weight of the flame retardant is added to 100 parts by weight of the foamed base resin. The flame retardant is considered to be uniformly dispersed throughout the foam resin except for air bubbles.

In addition, Patent Document 2 describes that an inorganic filler and / or a flame retardant is added to the foam base resin to cause foaming, and using calcium carbonate or talc as the inorganic filler, inorganic filling It is described that the material becomes a core and air bubbles are generated.
As shown in FIG. 5, in the formed flame retardant resin foam 150, a small amount of the inorganic filler 130 is confined inside each of the cells 121 of the foamed resin 120, and the addition amount of the inorganic filler 130 is It is described that when the number is increased, closed cells can not be obtained.
From such a description, it is considered that the addition amount of the inorganic filler 130 is less than 100 parts by weight with respect to 100 parts by weight of the foamed resin 120.

JP-A-6-182916 JP-A-6-49254

The object of the present invention is a plate-like interior building material formed using a flame-retardant resin foam, which can be easily manufactured and has sufficient strength and flame resistance. To provide.
Another object of the present invention is to provide a building material for interior that has an aesthetic appearance indoors and has a cushioning property that reduces an impact on a human body.

  In order to achieve the above object, the building material for interior of the present invention is a plate-like building material for interior formed of a flame retardant resin foam, and the flame retardant resin foam is a foamed resin. It is characterized in that the flame retardant is adhered over the entire wall surface of the bubbles.

It is preferable that the said flame retardant is comprised with 100 weight part or more with respect to 100 weight part of said foamed resin.
Moreover, it is preferable that the said flame retardant is one or several types of compounds containing either calcium, boron, phosphorus, aluminum, or magnesium.

Moreover, it is preferable to equip the surface side of the said flame-retardant resin foam with metal foil.
Furthermore, it is preferable to equip the back surface side of the said flame-retardant resin foam with glass cloth.

The building material for interior of the present invention can be manufactured inexpensively by a simple process because it mainly comprises a flame retardant resin foam formed by processing a commercially available foamed resin, and a large amount of flame retardant It can be provided with excellent flame retardancy to be usable.
Then, by laminating a glass cloth, a metal foil or the like on the flame retardant resin foam, in addition to the original cushioning properties, excellent strength and dimensional stability can be provided, and heat shielding properties can be provided.
Moreover, a decorative film can be laminated on the surface, and a beautiful appearance can be exhibited indoors.

It is an explanatory view showing composition of a building material for interiors of the present invention. It is an explanatory view showing typically a cell structure in foaming resin before processing. It is explanatory drawing which shows an example of the cell structure of the formed flame retardant resin foam. It is explanatory drawing which shows the other example of the cell structure of the formed flame retardant resin foam. It is explanatory drawing which shows the cell structure of the flame-retardant resin foam described in patent document 2. FIG.

FIG. 1 shows an interior building material 10 which is an example of the present invention.
The interior building material 10 is a plate-like building material, and is composed mainly of a flame retardant resin foam 50, a back surface side reinforcing material 60 provided on the back side of the flame retardant resin foam 50, and a flame retardant resin A surface-side reinforcing material 70 provided on the surface side of the foam 50 and a decorative material 80 provided on the top of the surface-side reinforcing material 70 are provided.

The relationship between the air bubbles 21 of the foamed resin 20 constituting the flame retardant resin foam 50 and the flame retardant 30 is schematically shown by FIGS. 2 to 4, and the cell structure of the flame retardant resin foam 50 will be described.
That is, the flame retardant resin foam 50 is manufactured by adding the flame retardant 30 to the existing foamed resin 20.

  FIG. 2 is an explanatory view schematically showing the air bubble 21 of the foamed resin 20 used to form the flame retardant resin foam 50, and FIGS. 3 and 4 show the flame retardant 30 as the air bubble 21. It is an explanatory view showing the example which made it adhere.

  In the flame retardant resin foam 150 and the like described in Patent Document 1 and Patent Document 2, the resin serving as the base material is foamed in a state in which the flame retardant is mixed, whereas the flame retardant resin foam used in the present invention The body 50 is different in that the foamed resin 20 provided with the air bubbles 21 is processed to attach the flame retardant 30 to the wall surface in the air bubbles 21.

For this reason, the foamed resin 20 used for producing the flame-retardant resin foam 50 is limited to the foamed resin 20 provided with continuous cells 21 (through pores), but is provided with independent cells (independent pores) It is also possible to compress the foamed resin 20 into continuous cells 21.
In general, urethane resin, melamine resin, rubber sponge and the like are commercially available as the foamed resin 20 provided with the continuous type air bubbles 21. In addition, vinyl chloride, polyethylene, phenol resin and the like are highly likely to be marketed.

  As a method of making the flame retardant 30 adhere to the wall surface of the bubbles 21 of the foamed resin 20, a solution or slurry containing the flame retardant 30 is prepared, impregnated in the bubbles 21 of the foamed resin 20, and then dried. It can be manufactured.

In order to impregnate the foamed resin 20 with a solution or slurry containing the flame retardant 30, it is necessary to release air from the bubbles 21 of the foamed resin 20, so that the foamed resin 20 is immersed in the solution or slurry. Degassing should be done by pressure. For example, degassing and impregnation can be performed by sandwiching a long sheet of foam resin 20 continuously between rolls while holding it between two rolls in a liquid.
Moreover, as a method of drying the sheet-like foam resin 20 in which the flame retardant 30 was impregnated, it can carry out continuously by the existing sheet drying method.

FIG. 3 shows a state where particles (powder) of the dried flame retardant 30 adhere over the entire wall surface of the air bubble 21.
Whether the solution is dried and deposited or the slurry is dried, it is considered that the flame retardant 30 adheres to the entire wall surface of the air bubble 21.

  In FIG. 4, as in FIG. 3, particles (powder) of the flame retardant 30 adhere over the entire wall surface of the air bubble 21, but with the re-dissolution inhibitor 31 so that each particle does not dissolve again. It shows the case of integrated processing. That is, the respective particles are coated with the anti-resolubilizer 31 and are adhered and integrated with each other.

In the present specification, the flame retardant 30 is any solid substance that improves the flame retardancy by being attached to the foamed resin 20, and includes those that become noncombustible.
As a general flame retardant 30, one or more compounds containing any of calcium, boron, phosphorus, aluminum or magnesium are used.

  Therefore, water can be added to calcium carbonate, magnesium carbonate, aluminum hydroxide or the like described in Patent Documents 1 and 2 to form a fine slurry, which can be used as the flame retardant 30. Also, ammonium polyphosphate, boric acid, zinc borate, boehmite and the like can be used.

  However, since the particle diameter of the flame retardant 30 to be used has to be a size that can penetrate into the cells 21 of the foamed resin 20, the production cost can be increased if the flame retardant 30 needs to be finely pulverized. There is sex.

When the flame retardant 30 can be used as a solution, particularly as an aqueous solution, the size of the air bubbles 21 does not have to be at all concerned, and the production can be performed easily.
Examples of usable water-soluble flame retardants 30 include sodium borate, calcium acetate and ammonium phosphate.

As to the amount of the flame retardant 30 used, the more the flame retardant 30 is used relative to the foamed resin 20, the better the flame retardancy can be obtained. Therefore, it is preferable to increase the ratio of the flame retardant 30.
Specifically, the amount of the flame retardant 30 is preferably 100 to 1000 parts by weight with respect to 100 parts by weight of the foamed resin 20, and more preferably 300 parts by weight or more.

Water is practically used for preparation of the solution or slurry of the flame retardant 30.
And in order to impregnate this solution or slurry in the foamed resin 20, it is necessary to adjust the viscosity, and a viscosity modifier such as polyethylene oxide is appropriately selected and used.

  Moreover, it is also preferable to coat the surface of each particle of the flame retardant 30 with a re-dissolution inhibitor so that the dried flame retardant 30 does not dissolve again. By this, it can be set as the building material excellent in water resistance. For example, an ethylene-vinyl acetate copolymer can be used as a re-dissolution inhibitor.

Regarding the amount of the flame retardant 30 to be added to the foamed resin 20, and the amount of the viscosity modifier and the anti-resolubilizer to be added, the surface side is obtained by performing the flame retardancy test on the finished interior building material 10 It will be finally determined together with the heat shieldability of the reinforcing material.
For example, the determination is made based on the fact that the total calorific value measured by the corn calorimeter is 8 MJ / m ² or less.

Returning to FIG. 1, the interior building material 10 will be described.
The building material 10 for interiors is provided with the back surface side reinforcing material 60 on the back surface side of the flame retardant resin foam 50, and the surface side reinforcing material 70 on the surface side of the flame retardant resin foam 50. The cosmetic 80 is provided on the surface side reinforcing member 70. These are adhered and laminated using an adhesive as appropriate.

The building material 10 for interiors is about 5-10 mm in thickness, assuming that it is stuck on a gypsum board, It is preferable that it is a plate-shaped building material which can be carried by hand.
By selecting the material and the like of the back surface side reinforcing material 60 and the front surface side reinforcing material 70, it is possible to provide various strengths as well as providing the necessary strength as a building material.

As the back surface side reinforcing material 60, a material which is strong and prevents warping, that is, a material having excellent shape stability is preferable, and it is preferable to use a woven fabric made of metal fibers or glass fibers.
Considering the case where the building material 10 for interiors is stuck on a gypsum board, the flame retardant resin foam 50 provided with the foamed resin 20 contacts the gypsum board through the back surface side reinforcing material 60 such as glass cloth. And cushioning can be enhanced.

It is preferable to use a metal foil using iron, aluminum, copper or the like as the surface side reinforcing material 70.
By covering the flame retardant resin foam 50 provided with the foamed resin 20 with a metal foil, the heat shielding property is improved, and a building material excellent in cushioning property that does not cause injury when a person collides is provided. Can.

  By using the cosmetic 80, a beautiful appearance can be exhibited indoors. As the material, vinyl chloride, polyethylene, polypropylene, polyester or the like is used. Vinyl chloride also has the effect of improving flame retardancy and heat shielding properties.

Example 1
A polyurethane foam resin (foam density 25 kg / m ³ , thickness 5 mm) was used as the foam resin, and a sodium borate aqueous solution was used as the flame retardant solution.
Then, it was prepared to be 350 parts by weight of sodium borate, 22 parts by weight of a re-dissolution inhibitor, and 8 parts by weight of a viscosity modifier with respect to 100 parts by weight of the foamed resin.
After impregnating the foamed resin with the aqueous solution of the flame retardant, it was dried to form a flame retardant resin foam. The weight of the flame retardant resin foam after drying was about 5 times that of the foamed resin used.

To this flame retardant resin foam, a glass cloth with a thickness of 300 μm is attached as a back side reinforcement, an iron foil with a thickness of 50 μm is attached as a surface reinforcement, and a thickness of 100 μm made of vinyl chloride as a decorative material on this iron foil. The sheets of the above were attached to form the building materials for interiors.
The interior building materials, was set in a cone calorimeter, it was measured gross calorific value, a 6 mJ / m ^2, was lower than the total heating value 8 MJ / m ^2, which is recognized as non-flammable.

Comparative Example 1
The foamed resin (foaming density 25 kg / m ³ , thickness 5 mm) used in Example 1 is used in place of the flame retardant resin foam without processing, and as in Example 1, it is used as a back surface reinforcing material. A glass cloth, an iron foil as a surface reinforcing material, and a vinyl chloride sheet as a decorative material were attached to make a building material for interior for comparison.
When this interior building material was set in a corn calorimeter and the total calorific value was measured, it was 25 MJ / m < ² > and showed a high value exceeding the total calorific value of 8 MJ / m < ² > recognized as nonflammability.

Example 2
As a foamed resin, a foamed resin made of melamine (foaming density: 10 kg / m ³ , thickness: 7 mm) was used, and as a flame retardant, a surface of ammonium polyphosphate coated with calcium acetate was used.
Then, 500 parts by weight of the coated flame retardant, 31 parts by weight of the re-dissolution inhibitor, and 13 parts by weight of the viscosity modifier were prepared with respect to 100 parts by weight of the foamed resin.
After impregnating the foamed resin with the aqueous solution of the flame retardant, it was dried to form a flame retardant resin foam. The weight of the flame retardant resin foam after drying was about 6.5 times that of the foamed resin used.

A 300 μm thick SUS304 cloth (60 mesh) is adhered to this flame retardant resin foam as a back side reinforcing material, an aluminum foil having a thickness of 50 μm is adhered as a front side reinforcing material, and a decorative material on this aluminum foil Then, a 80 to 100 μm thick sheet made of polyolefin was attached to form a building material for interior.
The interior building materials, was set in a cone calorimeter, it was measured gross calorific value, a 3 MJ / m ^2, was lower than the total heating value 8 MJ / m ^2, which is recognized as non-flammable.

Comparative example 2
A non-processed melamine foam resin (foaming density 10 kg / m ³ , thickness 7 mm) is used instead of the flame retardant resin foam of Example 2, and in the same manner as Example 2, a back surface side reinforcing material is used A 300 μm thick SUS304 cloth (60 mesh) is adhered, a 50 μm thick iron foil is adhered as a surface reinforcing material, and a polyethylene 75 μm thick sheet is adhered as a decorative material to obtain a comparative interior building material.
The interior building materials, was set in a cone calorimeter, it was measured gross calorific value is 19MJ / m ^2, exhibited a high value in excess of the total calorific value 8 MJ / m ^2, which is recognized as non-flammable.

Example 3
A polyurethane foam resin (foam density 20 kg / m ³ , thickness 10 mm) was used as the foam resin, and a mixture of ammonium polyphosphate and calcium acetate in water was used as the flame retardant solution.
Then, 550 parts by weight of the flame retardant, 20 parts by weight of the re-dissolution inhibitor, and 7 parts by weight of the viscosity modifier were prepared with respect to 100 parts by weight of the foamed resin.
After impregnating the foamed resin with the aqueous solution of the flame retardant, it was dried to form a flame retardant resin foam. The weight of the flame retardant resin foam after drying was about 7 times that of the foamed resin used.

A 50 μm thick iron foil is attached to the back of this flame retardant resin foam as a back side reinforcing material, an 50 μm thick aluminum foil is attached as a top side reinforcing material, and polypropylene is made on this aluminum foil as a decorative material. A decorative sheet having a thickness of 75 μm was attached to form an interior building material.
The interior building materials, was set in a cone calorimeter, was measured gross calorific value is 5.8MJ / m ^2, it was lower than the total heating value 8 MJ / m ^2, which is recognized as non-flammable .

  Although the embodiment of the present invention has been described in detail with reference to FIG. 1 above, the specific configuration is not limited to this embodiment, and design changes to the extent that they do not deviate from the scope of the present invention Included in the invention.

  For example, as back surface side reinforcing material 60, a paper made of cellulose pulp such as kraft pulp is impregnated with a slurry such as aluminum hydroxide, and then a flame retardant backing paper etc. obtained by drying alone or glass It can also be used in conjunction with a cloth or the like.

10: Interior building materials 20: Foamed resin 21: Bubbles 30: Flame retardant 50: Flame retardant resin foam

In order to achieve the above object, the building material for interior of the present invention is a plate-like building material for interior formed of a flame retardant resin foam, and the flame retardant resin foam is a foamed resin. It is characterized in that the flame retardant is attached in layers over the entire wall surface of the bubbles.

In order to achieve the above object, the building material for interior of the present invention is a plate-like building material for interior decoration formed using a flame retardant resin foam, and the flame retardant resin foam is a continuous type. throughout the wall surface of the air bubble of the foamed resin with air bubbles, it is characterized in that the flame retardant is adhered to a layer with an ethylene-vinyl acetate copolymer.

Claims (5)

It is a plate-like interior building material formed using a flame retardant resin foam,
A building material for interior decoration, wherein the flame retardant resin foam is adhered to the entire wall surface of the foam resin foam.   The building material for an interior according to claim 1, wherein the flame retardant is constituted by 100 parts by weight or more with respect to 100 parts by weight of the foamed resin. The interior fire protection building material according to claim 1 or 2, wherein the flame retardant is one or more compounds containing any of calcium, boron, phosphorus, aluminum or magnesium.   The interior building material according to any one of claims 1 to 3, wherein a metal foil is provided on the surface side of the flame retardant resin foam.   The building material for interiors according to any one of claims 1 to 4, wherein a glass cloth is provided on the back side of the flame retardant resin foam.