JPH0582819B2 - - Google Patents

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to architectural shapes used for sound absorption, heat insulation, interior materials, exterior materials, etc. that perform sound absorption and heat insulation, specifically, for forming walls. The present invention relates to a method for manufacturing a construction material comprising a fiber shell in which a rising plate part is connected to the end side of a main plate part, a sound-absorbing heat-insulating material, and a mounting part for attaching the shell and the sound-absorbing heat-insulating material to a wall base.

[Conventional technology]

In order to facilitate handling during construction and provide a function as a construction material, the above-mentioned construction material has sufficient shape retention for the shell and the mounting portion, and has a predetermined mounting strength. In order to ensure this, it is important that the connection strength between the mounting portion and the shell/sound absorbing/insulating material is high. Conventionally, as a manufacturing method for such architectural shapes, there is a method of integrally forming the mounting part and the shell with a material plate for the shell such as glass paper. The entire shell material plate, which is integrally connected to the shell part, is impregnated with a shape-retaining synthetic resin such as phenol or polypropylene, and press-molded into a predetermined shape. There are known methods of installing sound absorbing and insulating materials such as
144632).

[Problem that the invention seeks to solve]

However, when using the conventional manufacturing method, the curing of the synthetic resin impregnated into the shell material plate gives shape retention and connection strength to the shell part and the mounting part, so it takes time to harden the synthetic resin. mosquito,
There is a problem that the productivity of architectural shapes decreases. However, using a thermoplastic synthetic resin that can shorten the curing time requires heating and cooling equipment, which increases the cost of production equipment. The material is limited to heat-resistant materials. In addition, no matter which synthetic resin is used, press equipment is required, resulting in high equipment costs.Furthermore, since the entire shell material board is impregnated with synthetic resin, the sound absorption and heat insulation properties of the building material There is a problem that tends to cause a decrease in
As a manufacturing method for architectural shapes that solves these problems, one sheet has a main plate part and a part corresponding to the rising plate part of a shell in which a rising plate part is connected to the end of the main plate part for forming a wall surface. The sound-absorbing and heat-insulating material is bonded with adhesive to the portion corresponding to the main plate portion of the shell material plate, and then the shell material plate is folded at the boundary between the portion corresponding to the main plate portion and the rising plate portion. The shell is bent to form a predetermined shape along the sound-absorbing and heat-insulating material, and the rising plate portion is bonded to the end face of the sound-absorbing and heat-insulating material to form a main body of the construction material. A possible method is to attach the angle-shaped mounting fittings constituting the mounting portion to the shell of the main body with adhesive,
By using this manufacturing method, for example, even if the shell does not have shape-retaining properties, it is possible to maintain the shape-retaining properties of the entire building material by following the sound-absorbing and heat-insulating material. However, according to the manufacturing method of architectural shapes considered here, after forming the shape body, a step of gluing the mounting bracket to the shape body is required, which poses a problem of increasing costs due to an increase in manufacturing steps. Furthermore, since the mounting bracket is bonded with one side of the adhesive surface in contact with the shell, the external force acting on the form body attached to the wall base will not be applied to the one side of the adhesive surface. There is a risk that the shell will act intensively on the sound absorbing and insulating material, and the shape material body and the mounting bracket may easily come apart.To prevent this, if a strong adhesive is used, the shell There is a risk that the molded material will peel off and, as a result, it will not be possible to maintain a stable mounted state, and a problem will remain in the connection between the profile body and the mounting bracket.

Therefore, it is an object of the present invention to produce architectural shapes with excellent shape retention using inexpensive production equipment and with high productivity.
An object of the present invention is to provide a method for manufacturing a construction material that can be manufactured and attached to a wall base with high attachment strength.

[Means for solving problems]

The features of the method for manufacturing architectural shapes according to the present invention are as follows:
The main plate part of a fibrous shell with a rising plate part connected to the end of the main plate part for forming a wall surface, and the part corresponding to the main plate part of one shell material board having a part corresponding to the rising plate part. , bonding the sound absorbing and insulating material with an adhesive, and then bending the shell material plate at the boundary between the portion corresponding to the main plate portion and the portion corresponding to the rising plate portion to form the shell into a predetermined shape; One side of a mounting bracket for attaching an angled profile is interposed between the rising plate part and the end face of the sound absorbing heat insulating material, and the rising plate part is bonded to the end face of the sound absorbing heat insulating material with an adhesive. It's there to do. The effects and effects thereof are as follows.

[Effect]

The shell is impregnated with a shape-retaining synthetic resin in order to hold the shell in a predetermined shape by using the sound-absorbing and insulating material as a back-up material by bonding the main plate part and the rising plate part of the shell to the sound-absorbing and insulating material with adhesive. This process is not necessary. Moreover, the production process includes a process of bonding a sound absorbing and insulating material to a portion corresponding to the main plate part of the shell material plate, and bending the shell material plate to form a shell of a predetermined shape.
a step of interposing one side of a mounting bracket for attaching an angled profile between the rising plate part and the end face of the sound-absorbing heat-insulating material, and adhering the rising plate part to the end face of the sound-absorbing heat-insulating material; Since it can be made into a process, it is possible to efficiently produce architectural shapes with fewer steps, and each step can be performed by hand, so it is possible to reduce costs without using special manufacturing equipment. becomes possible.

Further, one surface of the angle-shaped mounting bracket is sandwiched between the rising plate portion of the shell and the end face of the sound-absorbing and heat-insulating material, and is bonded to the front and back surfaces of the mounting bracket. In addition to improving the integrity with the shape material body, it is possible to expect a higher adhesive strength with the shape material body, and it is possible to manufacture a construction shape material that can be attached to a wall base with high attachment strength.

〔Effect of the invention〕

Therefore, according to the present invention, the production equipment is simple and inexpensive, has good workability, has excellent sound absorption and heat insulation properties, as well as shape retention, and has high mounting strength to the wall base. We have now been able to provide a method for producing architectural shapes with high corrosion resistance. Of course, it goes without saying that a machine may be used to implement the method of the present invention to automate production.

〔Example〕

Embodiments of the present invention will be described below based on the drawings. First, to explain the construction material to be manufactured, the construction material 1 is an interior material, and as shown in FIG. A shell 2 made of glass paper and having a U-shaped cross section with a series of rising plate portions 2B, a sound-absorbing and heat-insulating material 3 made of glass wool filled in the recess of this shell 2, and the rising plate portion 2B and the sound-absorbing heat-insulating material. 3 and angle-shaped mounting brackets 9 which are separately interposed and fixed between the two. It is formed so that it can be fixed to the wall base by inserting nails or screws into the nail holes or screw holes 8 provided in the mounting bracket 9.

Next, a method for manufacturing the building material 1 and its manufacturing steps will be explained in order.

[1] As shown in FIG. 1A, a flat shell material plate 6 having portions corresponding to the main plate portion 2A and the rising plate portions 2B of the shell 2 is made from glass paper.

[2] As shown in FIG. 1B, a fold line 7 is formed at the boundary between a portion corresponding to the main plate portion and a portion corresponding to the rising plate portion of the shell material plate 6. The fold line 7 is formed by pressing a blunt object such as the back of a cutter blade against the boundary.

[3] As shown in FIG. 1C, adhesive is applied to the entire one side of the shell material plate 6. The adhesive may be applied by spraying, brushing, or rolling.

[4] As shown in FIG. 1D, the sound-absorbing and heat-insulating material 3 formed into a predetermined shape is pressed and adhered to a portion corresponding to the main plate portion of the shell material plate 6. Note that the sound-absorbing and heat-insulating material 3 has shape-retaining properties.

[5] As shown in FIG.
B and the end face of the sound absorbing heat insulating material 3, one side of the angle-shaped mounting bracket 9 is interposed, and the rising plate portion 2B is pressed against the end face of the sound absorbing heat insulating material 3 and bonded. do.

As the shell material plate 6, a glass paper having a weight of 80 to 500 g per square meter and a thickness of about 0.8 to 4 mm is used.

As the adhesive, it is desirable to use a quick-drying adhesive such as solvent-type chloroprene.

The sound absorbing and insulating material 3 has a density of 16 kg/m ³ or more and a thickness of 12 mm or more, preferably a density of 32 kg/m 3 or more.
Glass ^wool with a size of about 40 mm and a thickness of about 40 mm is used.

To give an example of the actual dimensions of the construction material 1, the width, length, and thickness are 600 mm, 2000 mm, and 54 mm, respectively.

[Another example]

Next, another embodiment of the present invention will be shown. .

In step [5] shown in the above embodiment, an adhesive is applied to the end face of the sound absorbing and heat insulating material 3 before bending the shell material plate 6.

In the step [3] shown in the above example, when applying the adhesive to the shell material plate 6, the shell material plate 6 was slightly bent to the opposite side at the fold line 7, as shown in FIG. Apply adhesive in condition.
In this case, since the adhesive is sufficiently filled in the folding line 7, when the shell material plate 6 is bent to form the shell 2, the rising plate portion 2B can be made self-adhesive, and even more The shape retention of the shell 2 can be improved.

The shell 2 is made of organic fiber nonwoven fabric instead of glass paper.

The sound absorbing heat insulating material 3 is not glass wool,
Constructed from organic fibers such as cotton (felt) and rock wool.

A cosmetic cloth nonwoven fabric, film, etc. is pasted on the surface of the shell 2.

The fold line 7 is formed on the shell material plate 6 after the sound absorbing and heat insulating material 3 is adhered to a portion corresponding to the main plate portion of the shell material plate 6.

[Brief explanation of drawings]

The drawings show an embodiment of the method for manufacturing a building material according to the present invention, and FIG. 1A to 3E are manufacturing process diagrams, FIG. , E are manufacturing process diagrams showing another embodiment. 2A...Main plate part, 2B...Rising plate part, 2...
... shell, 3... sound absorbing and insulating material, 6... material board for shell.

Claims (1)

[Claims] 1. A fibrous shell 2 in which a rising plate part 2B is connected to the edge of the main plate part 2A for forming a wall surface, a sound-absorbing heat-insulating material 3, and installation of the shell 2 and the sound-absorbing heat-insulating material 3 to the wall base. A method for manufacturing a construction material consisting of a main plate part 2A and a rising plate part 2B of the shell 2, the sound-absorbing heat insulation being applied to a portion corresponding to the main plate part of one shell material plate 6, which has a part corresponding to the main plate part 2A and the rising plate part 2B of the shell 2. The shell material 3 is bonded with an adhesive, and then the shell material plate 6 is bent at the boundary between the portion corresponding to the main plate portion and the portion corresponding to the rising plate portion to form the shell 2 into a predetermined shape. One side of a mounting bracket 9 for attaching an angled profile is interposed between the rising plate part 2B and the end face of the sound absorbing heat insulating material 3, and the rising plate part 2B is attached to the end face of the sound absorbing heat insulating material 3. A method of manufacturing architectural forms that are bonded with adhesive.