JPH0742081A - Method for coating of woven fabric with elastic body - Google Patents

Abstract

PURPOSE: To improve adhesion between silicone and a textile fabric by carrying out a corona discharge treatment on the textile fabric and thereafter applying silicone rubber. CONSTITUTION: After irradiating the textile fabric at frequency of about 1-500 KHz, voltage of about 3-50 KV and in an irradiation amount of 10-1000 μAh/m<2> , liq. silicone rubber is applied and cured to obtain the silicone coated textile fabric having improved adhesion between silicone and the textile fabric.

Description

Detailed Description of the Invention

The present invention relates to a method for coating textile fabrics with elastic bodies, in particular silicone rubber.

BACKGROUND OF THE INVENTION Industrial and natural textile fabrics and surfacing textile materials are often known to be provided with coatings of polymeric materials in order to achieve improved technical applicability.

The number of such polymeric materials is large and there are many objectives of improving industrial properties.

Thus, for example, it is desired that the woven fabrics used have to have improved water repellency or have improved sewing properties. It is generally desirable to provide woven fabrics with reduced gas permeability or improved flame resistance.

There are many polymeric materials used to achieve the different properties of woven fabrics and are associated with all known polymeric materials.

Among these materials, silicone is of significant importance in many respects. It imparts very good water repellency to the surface of treated textile fabrics and surface-forming textile materials. Further, the addition of silicone changes the handleability in terms of flexibility and elasticity, and imparts “silicone handleability” familiar to those skilled in the art. The special product helps to give the fabrics coated with it some flame resistance.

Among the silicone products that can be used, silicone rubber offers particular advantages. It can be applied to woven fabrics or surfacing fabric materials by various techniques, where it can be crosslinked under suitable conditions to the corresponding silicone elastomers. Furthermore, it forms excellent mechanical and thermal protection for coated fabrics, as silicone elastomers are characterized by a very high thermal stability.
Fabrics coated with polydimethylsiloxane also provide good cold flexibility and high comfort.

The coating of industrial textile fabrics and surface-forming textile materials with silicone rubber is a known method, ie the uncrosslinked rubber material is optionally dipped from a solution of the rubber, rolled or printed, sprayed, or Doctor blade (doctor bl
Coat by application in ade).

Based on chemical and physical modifications, silicones can be produced for printing and exhaust processes as well as for solvent application processes.
As a result, these products can be applied to virtually all textile materials and fibers according to many application methods.

Considering environmental acceptability, the number of solvent-free application systems is now increasing. The reason is that not only is the process less energy consuming than the system in which the solvent has to be removed, but for example the complete recovery of the organic solvent requires considerable industrial resources.

On the other hand, for coating with a solid coating amount of about 20 to 100 g / m ² , it has a sufficiently low viscosity that can be handled by a doctor blade without adding a solvent, while mechanical stress is exerted in a crosslinked state. Silicone rubber materials that provide relatively high mechanical strength to form a coating that can
It has been known for several years under the name of liquid silicone rubber.

These are polydimethylsiloxanes having terminal vinyl groups in the polymer chain, at least 150 m ² / g
Products based on special auxiliaries for the introduction of calcined silicic acid and reinforcing silicic acid having a BET specific surface area of 1 into the polymer.

These products can be crosslinked by simultaneously reacting with a low molecular weight or high molecular weight polymethylhydrogen siloxane in the presence of a platinum catalyst.

A technical drawback of coatings with such products is that they exhibit low adhesion to organic substrates.

In this regard, the technical literature makes a series of proposals for avoiding this drawback. For example, an organosilicon compound which has the effect of improving the adhesion of the silicone rubber coating can be added to the organopolysiloxane rubber. Furthermore, it is known that in some cases the adhesion of the coating can be markedly improved, for example by treating the textile material with a dilute solution of the organosilicon compounds mentioned before application of the coating material. However, in the case of mechanically highly distorted textile materials, such as industrial textile materials, in particular for the production of airbags in the automobile industry, the improved coating adhesion achieved is not yet sufficient for the intended use.

In the present invention, the woven fabric or the surface-formed woven fabric material is made of silicone rubber in the production of the surface-formed woven fabric material or woven fabric excellent in the adhesion of the applied silicone rubber elastic layer, particularly the woven fabric for airbags. Provided is a method of making the above textile material or textile fabric which is exposed to silent electric discharge (corona discharge) prior to application.

Surprisingly, the use of the adhesion promoter in the organopolysiloxane material alone in combination with the corona discharge treatment provides a particularly strong bond between the silicone elastomer layer and the backing fabric used to make the airbag. It was discovered that binding occurred.

The electrical discharge generators of the invention for modifying the polymer surface are known under the concept of corona electrodes, and plastics for improving the adhesion of dyes, paints, adhesives and coatings. , Became popular for surface treatment of paper and metal.

Preferably a corona discharge with a frequency of 1 to 500 kHz, especially 5 to 30 kHz is used.

The voltage is 3 to 30 kV, preferably 20 to 3
It may be 0 kV.

Depending on the fiber, generally 10 to 1000
A dose of μAh / m ² is sufficient. Higher doses do not lead to further improvement in adhesion.

The corona discharge can be carried out in air or an inert gas at room temperature. Some atmospheric humidity, for example above 50%, is relatively advantageous.

The coating with liquid silicone rubber is preferably carried out in a continuous device and is immediately subjected to corona treatment. If the corona treatment and the coating are carried out in a spatially separated device with staggering, it is necessary to apply high doses to achieve the full effect according to the invention. This is because over a fairly long period of time, the active centers on the textile fabric, which are formed by the corona discharge and promote adhesion, regress.

The following examples explain the invention in more detail.

[0025]

EXAMPLES The following materials were used: Fabric cloth: Polyamide fabric cloth with a titre of 470 dtex Liquid silicone rubber, component A: 100 parts by weight of polydimethylsiloxane having vinyl end groups and a viscosity of 10 Pa.s Hexa 30 parts by weight of calcined silicic acid (BET 300 m ² / g) pretreated with 4.33 parts by weight of methyldisilazane Platinum catalyst in the form of platinum-vinyl-siloxane complex 0.00
Mixture of 7 parts by weight Liquid silicone rubber, component B * Mixture of component A except that 3 parts by weight of methylhydrogensilane having 4 mmol / g SiH groups are used instead of platinum catalyst Binder preparation: Ethanol solution of silane resin containing vinyl group 100% by weight (containing 60% resin) a) γ-aminopropyltriethoxysilane 7.5
Parts by weight b) γ-aminopropyltriethoxysilane 15 parts by weight c) γ-methacryloxypropyltrimethoxysilane 15 parts by weight d) γ-metharylpropyltrimethoxysilane 1
5 parts by weight e) γ-glycidoxypropyltrimethoxysilane
Dye paste mixed with 15 parts by weight, blue: Disperse pigment in linear polydimethylsiloxane with trimethylsiloxy ends (viscosity 25 Pa · s) Examples 1-9 Liquid silicone rubber, binder preparation and dye paste in Table 1 Mixed together in the proportions shown. The viscosity of the mixture is about 1
It was 00 Pa · s.

This mixture was applied to a polyamide woven fabric with a roller-assisted doctor blade to give a gap of 50 μm.
(gap) Width applied.

Subsequent vulcanization was carried out by heating with hot air for 2 minutes at 175.degree.

The polyamide woven fabrics of Examples 6 to 8 were subjected to corona irradiation (potential 25 kV) before coating. Table 1
Is the street.

The polyamide woven fabric of Control Example 9 contained no binder and was not corona-irradiated prior to coating.

Adhesion to silicone rubber coatings, backing materials was evaluated according to the scratch test method described in SNV Standard Test 198498.

The resulting textile coating bonded relatively strongly to the underlying fabric. Therefore the coating as a whole could not be removed from the underlying fabric, so that its adhesion could not be determined directly in the peel test. The coating was therefore separated by the diagonal alternating drawing method and the adhesion determined by the number of strokes required for its release. This is shown in Table 1.

[0032]

[Table 1]

The specification and examples herein are illustrative and
It will be appreciated that those skilled in the art will be able to contemplate other embodiments which are not limiting of the invention and are also within the spirit and scope of the invention.

Features and aspects of the invention are as follows: In producing a silicone-coated woven fabric by applying liquid silicone rubber to a woven fabric and curing it,
The woven fabric is subjected to corona treatment prior to the application of silicone,
A method of making a silicone coated woven fabric thereby improving the adhesion between the silicone and the woven fabric.

2. Corona treatment is performed at a frequency of about 1 to 500 kHz, a voltage of about 3 to 30 kV, and about 10 to 1000 μA.
The method according to the above 1, which is carried out at a dose of h / m ² .

3. Corona treatment frequency is about 5-30kHz
z, voltage of about 20-30 kV, method of 2 above, carried out in an atmosphere of air or an inert gas at a humidity of at least about 50%. 4. The method of claim 1 wherein the silicone is applied to the woven fabric directly after the corona treatment.

5. A coated woven fabric produced by the method of the above 1.

Claims (4)

[Claims] 1. When producing a silicone-coated woven fabric by applying and curing liquid silicone rubber to the woven fabric, the woven fabric is subjected to a corona treatment prior to application of the silicone, whereby the silicone and the woven fabric are A method of making a silicone-coated woven fabric that improves the adhesion between. 2. Corona treatment is performed at a frequency of about 1 to 500 kHz, a voltage of about 3 to 30 kV and about 10 to 100.
The method according to claim 1, which is carried out at a dose of 0 μAh / m ² . 3. The method of claim 1 wherein the application of silicone to the woven fabric is carried out directly after corona treatment. 4. A coated woven fabric produced by the method of claim 1.