FI95389C - Process for manufacturing fibrous composite material and fibrous composite material manufactured by the process - Google Patents

Description

1 95389

The invention relates to a method for producing a fibrous composite material, in which a mixture of fibrous starting materials is formed into a material web by a dry-forming principle or the like. The invention also relates to a fibrous composite-10 material obtained by the method.

Fiberglass composites, such as fiberglass felt, are used in buildings and other similar applications in connection with thermal insulation materials and roofing felts. Insulating materials such as glass and mineral wool and poly-urethane, usually in the form of carpets, sheets or wool, are subsequently coated or in connection with the manufacturing process with kraft paper, plastic layers, aluminum laminates or said glass fiber felt to improve strength or insulation. In demanding applications, such as flat roofs, the insulating material and the reinforcing glass fiber felt layer are protected from moisture by coating it with, for example, bitumen-based paste (pitch) or roofing felt. In further more demanding conditions, such as in flat roof structures of industrial plants and apartment buildings, the insulating material is coated with a layer of gravel, roofing felt or both in addition to the bitumen layer to withstand the human weight without cracks or dents. Building such a roof is laborious and will be expensive with all its layers.

30 In roofing felt, the fiberglass layer forms a load-bearing layer on the bitumen mat. In addition, the choice of materials must take into account the fire safety aspects of both installation and use.

The object of the present invention is to provide a method for producing a new type of composite material and a composite material which is suitable e.g. as a coating for insulating materials and as a support layer for roofing felt for buildings and similar objects. The method according to the invention is thus characterized in that the composite material is formed in the following steps: mixing the glass or mineral wool fibers with components of a thermoplastic binder consisting of thin and long fibers or powdery material, forming a mixture into a material web, compacting a material web, compacting into a composite by heat, softening or partially melting the binder.

The composite material 15 produced by the method of the invention has several advantages over known coatings. The composite obtained according to the invention is tough and can withstand even high stresses without breaking. It is also dimensionally stable, i.e. a plate made of material does not live and does not form cracks at the joints. Therefore, the composite of the invention is easily made denser than a fiberglass felt having a very open, porous structure. This is an advantage e.g. in that it does not need to be compacted by impregnating it with e.g. bitumen at least as much as fiberglass felt. The purpose of the sealing 25 is to prevent, for example, liquid polyurethane from flowing through the composite layer during the step of forming the insulating material.

The composite according to the invention also differs from conventional fiberglass composites in terms of its fiber type and bonding method. The fiber used is wool fiber, no. drawn glass as usual. In addition, conventional fiberglass composites use a liquid, crosslinkable thermosetting plastic, such as polyester resin, as a binder.

In addition, the composite according to the invention has a low weight per square meter, i.e. it is light and withstands well the refraction, compression and other space-saving packing operations II Itt t Carbon I I i II i 3 95389.

The invention also relates to a fibrous composite material formed from mixtures of fibrous starting materials 5 by forming a material web on a dry-forming principle or the like. The composite material according to the invention is characterized in that the composite material consists of mixed glass or mineral wool fibers and thermoplastic binder components consisting of thin and long fibers or a powdered melt or powdered material formed into a web of material, compressed and bonded.

Other preferred embodiments of the invention are characterized by what is set out in the claims below.

The invention is described in more detail below. by reference to the accompanying drawings, in which Figure 1 shows a composite material production line used in the method 20 of the invention, Figure 2 shows the structure of a composite material according to the invention, and Figure 3 shows the use of a composite material according to the invention in a flat roof structure.

Figure 1 shows a production line for a composite according to the invention and a method according to the invention, in which a mixture of fibrous starting materials is formed in a dry forming apparatus former 1 on an endless wire 2. Typically the fibrous material is mixed in a former, preferably a drum former, and screened as a continuous process. According to the invention, the fibers forming the composite are mainly glass or mineral wool fibers, the length of which may typically be e.g.

6 mm and a diameter of 4 to 6 pm. In this example, the binder components are of the same size. 95389 4 of thermoplastic fibers, e.g. polypropylene fibers or bicomponent fibers (e.g. polyethylene coated polypropylene fiber). The binder may also be formed of a powdered thermoplastic material. The blending ratios of the fibers depend on the desired properties of the product. Since glass or mineral wool fiber is a cheaper raw material than plastic fibers, the aim is, of course, to minimize the need for plastic fibers within the given product characteristics.

In the production of the roofing felt support layer, longer fibers can be used to ensure the required strength and, for example, polyamide fibers or polyester-based PET or PET bicomponent fibers can be used as binders, which also tolerate the heat generated by a thick bitumen layer than polypropylene fibers.

The formed material web 3 is conveyed through one or more pairs of rollers 4 and 5 (compactor and embossing rolls), in the nip formed by which the material web is pressed by a seal-20. The partially compacted material web 3 'is subjected to a thermal bonding or so-called to a thermobonding furnace 7, in which the binder fibers are partially softened or melted to bond the glass or mineral fibers into a three-dimensional structure. After the furnace, the finished composite 8 is optionally still hot calendered between calenders 9 and 10, resulting in a more or less compact composite mat 11.

During the above-mentioned process, the substance path can be sprayed with various additives in order to obtain a certain property profile ai-30. Figure 1 shows how the web 3 'is sprayed from the nozzles 6 from above and below with an additive such as thermosetting resin to improve the stiffness of the bonded web 8. Composite 8 can also be impregnated after the furnace with a polymer precursor such as monomer 35 for post-polymerization.

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Figure 2 shows a cross-section of an insulating material utilizing a composite according to the invention. At the bottom there is an insulating material 13, e.g. polyurethane, the next layer 12 is a composite according to the invention impregnated with bitumen and the top layer 14 is a protective layer of polyethylene film or nonwoven. Mainly, storage requires this protective layer, because otherwise the layers of insulating material arranged in stacks or wrapped in a roll will adhere to each other from their bitumen surfaces.

This type of multilayer material is ideal as a roofing material and requires no treatment other than sealing the joints of boards or carpets and roofing with felting. By omitting the insulating layer 13 15 and forming the bituminous composite layer 12 sufficiently thick, the structure is in principle a roofing felt reinforced with the composite according to the invention. On the other hand, if the bitumen in the layer 12 is replaced, for example, by an aluminum laminate layer, the composite according to the invention provides an effective and gas-tight insulating material for a wide variety of technical purposes.

The properties of the composite according to the invention can be varied by means of additives, such as adhesion promoters between glass or mineral wool fibers and binder fibers (cf. Fig. 1). The finished composite can also be impregnated with a polymer precursor, i.e. a monomer, in which case the composite, when completed, is a flexible semi-finished product which can be cured at the installation site, e.g. by heat or radiation, into a hard shell. Yet another possibility is to impregnate the composite according to the invention with a superabsorbent wave, e.g. a superabsorbent fiber in the form of a gel, whereby it is able to absorb a considerable amount of water without deteriorating the structure.

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Figure 3 shows how the roof of a flat-roofed building is covered with insulation boards with a coating according to the invention. The ceiling 16 of the building 15 may consist of a boarding, sheet metal profile strips, concrete slab or the like structure. On top of it, placed insulation boards 17 coated according to the invention are placed side by side, which consist of an insulation layer 18 and a bitumen-impregnated composite layer 19 covering it. When the entire roof is covered with insulation boards 17, it is ready after sealing and felting the joints 20. Compaction can be done, for example, by brushing with bitumen or in another similar way. In this way, a stable and e.g. walking-resistant roof insulation.

It will be apparent to those skilled in the art that the various embodiments of the invention are not limited to the examples set forth above, but may vary within the scope of the claims below.

Claims (13)

A process for producing a fibrous composite material, in which a mixture of fibrous starting materials is formed by a dry-forming process or the like, characterized in that the composite material is formed by: mixing glass or mineral wool fibers with , the material web (3) is formed from the mixture, the material web is compacted by compression, and the material web (3 ') is bonded to the composite (8) by heat, softening or partially melting the binder. Method according to Claim 1, characterized in that the composite (8; 12) is hot-calendered after bonding. Method according to Claim 1 or 2, characterized in that the composite (12; 19) is coated or impregnated on one side to be weather-resistant with a coating, such as bitumen or a plastic layer (14). Method according to Claim 1 or 2, characterized in that the composite (12; 19) is coated on both sides with bitumen to form a support layer for the roofing felt product. Method according to one of Claims 1 to 4, characterized in that the material web (3 ') is impregnated with a suitable interfiber adhesion promoter before the bonding step. Process according to one of Claims 1 to 5, characterized in that the composite (8) is impregnated with a polymer precursor, such as a monomer, for post-polymerization. 95389 Method according to one of Claims 1 to 6, characterized in that the composite (8) is impregnated with a superabsorbent. 7 95389 8. A fibrous composite material formed from a mixture of fibrous starting materials by forming a web of material by the dry forming principle or the like, characterized in that the composite material consists of a mixture of glass or mineral wool fibers and thermoplastic binder materials and longitudinal constituents consisting of and formed into a web of material (3), compressed and bonded into a composite (8) by softening or partially melting the binder. Composite according to Claim 8, characterized in that the composite (8) is hot-calendered after bonding. Composite according to Claim 8 or 9, characterized in that the composite (12; 19) is coated or impregnated on one side with a weather-resistant coating, such as bitumen or a plastic layer (14). Composite according to Claim 8 or 9, characterized in that the composite (12; 19) is: 25 coated on both sides with bitumen as a support layer for the roofing felt product. Composite according to one of Claims 8 to 11, characterized in that the composite (8) is impregnated with a polymer precursor, such as a monomer. A com according to any one of claims 8 to 12. position, characterized in that the composite (8) is impregnated with a superabsorbent. 1! i & li · i '! 4 S *! ! «95389