CS273772B1 - Laminated material for automobile and fancy goods industry - Google Patents

Abstract

The design concerns laminated material is based on fibrous web, containing synthetic textile secondary fibres and biconstituent foil fibres in the ratio of 50 : 50 percent by weight, glass textile with deposit of 140 percent by weight of epoxy resin related to the surface weight of basic glass textile and unwoven textile materials from 100 percent of polyester staple without deposit or with deposit of melt adhesive based on co-polyamide with the melting temperature between 120 and 130 degrees C at the reverse side, while the web is heat-treated and shaped into the required shape in a cold former under pressure.<IMAGE>

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to sheet composite materials composed of nonwoven fibrous layers and glass textile in combination with an epoxy-based thermosetting resin useful for the manufacture of automotive interior panels or fancy goods, such as briefcases and other types of luggage or specialty packaging.

These materials must meet the requirements for structural strength, stiffness, puncture and deflection resistance, dimensional stability, low weight, resistance to corrosion and bacterial influences, and resistance to extreme climatic conditions.

The aforementioned properties can be achieved by a combination of nonwoven fibrous layers produced by mechanical stiffening of carded webs by needle punching, glass fabric and thermosetting resins. The nonwoven fibers of the layer are composed of synthetic fibers, the epoxy-based thermosetting resin is applied to the glass fabric by impregnation. The sandwich of these materials, after preheating to a temperature at which the synthetic fibers used melt in the middle layer and soften the thermosetting resin used on the glass textile, for the time required to partially crosslink the thermosetting resin, is processed in a cold mold under pressure.

The nonwoven fibrous layer used to make said sheet composite is comprised of a mixture of textile fibers including fibers of split multi-component synthetic film having a fineness of 3 to 150 dtex. These fibers are in the fabric so that the fibers of the split film having a fineness above 10 dtex are oriented mostly horizontally, the other in all directions. The fabric is reinforced by needling and heat treatment by means of thermoplastic shrinkable fibers, when the surface is melted together with other fibers of the sheet formation ·

The materials used to date for automotive interior panels are generally based on polyurethane integral foams, or polypropylene filled with waste paper or wood flour, in combination with a nonwoven fabric obtained by laminating viscose fiber in the form of a fleece with a polypropylene fleece in a ratio of 80 to 20 wt. percent. All the above mentioned materials are used in the world, but their disadvantage is relatively high weight, lower resistance to deflection due to light degradation of polypropylene and especially the unavailability of some of the mentioned basic raw materials, such as polyurethanes in our economic conditions.

These drawbacks are overcome by a material based on fiber waste from the textile industry, treated as a fibrous web containing 50 wt. % of textile secondary raw materials based on polyester, polyacrylonitrile, polyamide and polypropylene in combination with 50 wt. % of bicomponent foil fibers. Bicomponent foil fibers are always fibers made from a two-layer foil, where the top of the foil is made of low-pressure polyethylene, for example LITEN VB 33, prepared by stereospecific polymerization, with a melting point of 136 ° C and the inside of the foil is made of isotactic polypropylene for example MOSTEM 5B4 12, m.p. 160-170 ° C. The weight ratio of the two components is 50:50 to 40:60 in favor of polypropylene. Another component of the described laminate is a glass fabric impregnated with a thermosetting epoxy based resin, for example CHS 1/33, and 100% polyester staple fiber based textile materials, resistant to temperatures of 160 to 200 ° C without apparent destruction, in the form of a nonwoven web.

The technical effect is that the combination of the said textile materials and the thermosetting resin, after heat treatment and subsequent cooling in the desired shape, interconnects the synthetic and glass fibers and cures the present resin resin. This produces a compact material characterized by high strength and

-r Λ

And the stiffness e of the creature 's stiffness 1 under extreme, climatic conditions. When the climatic conditions are indicated, the RV symbol always indicates the relative humidity.

The economic effect lies in the use of secondary textile raw materials, ie waste from the textile industry.

The laminate according to the invention is illustrated by way of example in the accompanying drawings, in which Fig. 1 is a 5-layer sandwich, 1 x nonwoven fibrous layer 2, 2 x epoxy-coated glass fabric 2, 2 x 100% polyester staple nonwoven fabric 3 Fig. 2 shows a 3-layer sandwich, 1 x nonwoven fiber layer. 1, 1 x epoxy-coated glass fabric 2, 1 x nonwoven textile material based on 100% polyester staple 3, Fig. 3 is a 5-layer sandwich 1 x nonwoven fibrous layer 1, 2 x nonwoven textile material of 100% polyester staple fiber, coated with a coating of 80 to 100 g / m copolyamide hot melt on the reverse side, melting point 120 to 130 ° C 4, 2 x epoxy-coated glass fabric 2, ^and Fig. 4 is a 3-layer sandwich, 1 x nonwoven fibrous layer 2> 1 ^x epoxy-coated glass fabric 2, 1 x nonwoven textile material based on 100% polyester 2 staple, the reverse side of the load m 80 to 100 g / m 2 of copolyamide hot melt adhesive having a melting point of 120 to 130 ° C.

The arrangement of the individual layers of the sandwich shown in the figures comprises a fiber layer 2 consisting of a fiber web of 10 mm thickness containing 50 wt. percent of synthetic textile secondary fibers and 50 wt. percent of bicomponent foil fibers made of double-layer foil, the top of the foil is made of low-pressure polyethylene LITEN VB 33, produced by stereospecific polymerization, with a melting point of 136 ° C and the inside of the foil is made of isotactic polypropylene M0STEN 58412 with a melting point Γ60 The weight ratio of the two components is 50: 50 to 40: 60 in favor of polypropylene, the glass textile 2 having a deposit of 140 wt. percent epoxy resin based on basis weight of glass base fabric 2, nonwoven fibrous material based on 100% polyester staple 3, nonwoven fibrous material based on 100% polyester staple, coated on the back with 80-100 g / m of hot melt adhesive copolyamide having a melting point of 120 to 130 ° C.

The method of production of the laminates according to the invention is illustrated by the following examples.

EXAMPLE 1 A fibrous layer 2 having a thickness of 10 mm containing 50 wt. percent of synthetic textile secondary fibers and 50 wt. percent of bicomponent foil fibers made of double-layer foil, the top side of the foil is made of low-pressure polyethylene LITEN VB 33 with a melting point of 136 ° C and the inside of the foil is made of isotactic polypropylene MOSTEN 58412 with a melting point of 160 to 170 ° C ratio of both components 50:

50 to 40:60 in favor of polypropylene is covered on both sides with a layer of glass textile 2 with a deposit of 140 wt. percent epoxy resin CHS 1/33 based on the basis weight of the glass base fabric. Two layers of non-woven textile material based on 100% polyester staple 2 are used to finish the back and front surface of the future product. 2 The layered sandwich is embedded in a heating device providing contact flat heating of the material under tension to 200 ° C. It is left in the heating apparatus for two minutes and, after removal, is immediately placed in a water-cooled mold placed in a pressing apparatus providing a specific pressure of 20 MPa. At this pressure, the material is left in the mold for two minutes, then the product is heated

CS 273772 B1 takes the tray out of the mold and treats the chip around the perimeter. The molding is already so stiff that there is no change in shape. The arrangement of the individual layers can be seen in Fig. 1.

Tensile strength of the resulting material: 64.0 MPa

Permanent deformation / 1 hour, load 1 kg, ° C, 94% RH /: 3.00 mm / 250 mm length

Example 2

The fiber layer 7 of Example 1 is covered on one side with a glass textile layer 2 according to Example 1 and a layer of nonwoven textile material 3 according to Example 1 on the glass textile side 2. The sandwich thus formed is inserted into the heating apparatus according to Example 1 and processed according to the example The arrangement of the individual layers is shown in FIG. 2.

Tensile strength of the resulting material: 53.0 MPa

Permanent deformation under the conditions of Example 1: 5.0 mm / 250 mm length

Example 3

The fiber layer 7 according to Example 1 is covered on one side and the other with a glass textile layer 2 according to Example 1. The lower side of the sandwich thus formed is covered with a fibrous nonwoven textile material based on 100 polyester staple fibers. GRILTEX 2P copolyamide hot melt adhesive with a melting point of 120 to 130 ° C. The top side of the sandwich thus formed remains uncovered. The sandwich is placed in the heating apparatus of Example 1. After removal, the heated sandwich is conveyed to the pressing apparatus of Example 1, where it is manually placed on top of the future product formed at this stage by the glass textile 2 of Example 1 nonwoven fibrous textile material. The whole assembly is inserted into a water-cooled mold placed in a pressing apparatus according to Example 1 providing a specific pressure of 15 to 19 MPa and is processed according to the procedure of Example 1. The arrangement of the individual layers is shown in Fig. 3.

Tensile strength of the resulting material: 63.5 MPa

Permanent deformation under the conditions of Example 1: 3.0 mm / 250 mm length

Example 4

The fibrous layer 1 of Example 1 is covered on one side with a glass textile layer 2 according to Example 1 and the sandwich thus formed is inserted into the heating apparatus of Example 1. After preheating, it is provided with a fibrous nonwoven textile material 4 according to Example 3. Then, the whole assembly is processed on a pressing apparatus according to Example 3. The arrangement of the individual layers can be seen in Fig. 4.

Tensile strength of the resulting material: Permanent deformation under the conditions of Example 1:

Claims (2)

SUBJECT OF THE INVENTION A laminate material for the automotive and haberdashery industry, comprising three to five layers of materials, comprising synthetic textile secondary fibers and bicomponent foil fibers and reinforced by heat treatment, characterized in that each layer consists of a fiber web (1) comprising 50 wt. % of textile secondary raw materials based on polyester, polyacrylonitrile, polyamide and polypropylene and 50 wt. percent of bicomponent foil fibers made of double-layer foil, the top side of which is made of low-pressure polyethylene, melting point 136 ° C, prepared by stereospecific polymerization, and the inside of the foil is made of isotactic polypropylene, melting point 160-170 ° C. ingredients are 50: 50 to 40: 60 in favor of polypropylene, the next layer is glass textile (2) with a coating 140 wt. percent epoxy resin based on basis weight of glass base textile and textile nonwoven based on 100% polyester staple (3). Laminate material for the automotive and haberdashery industry according to claim 1, characterized in that the textile nonwoven based on 100% polyester staple (3) is coated on the reverse side with a coating of 80 to 100 g / m copolyamide based hot melt adhesive. 120 to 130 ° C (4).