NO159909B - POLYCARBONATE ART PLASTIC PLATE AND PROCEDURE FOR MANUFACTURING PLASTIC PLATE. - Google Patents

Abstract

1. Plastics board, consisting of a core layer of polycarbonate plastics containing not more than 0.5% by weight of a UV absorber, and consisting, on at least one side of the core layer, of a covering layer of plastics, coextruded with the core layer, containing at least 3% by weight of a UV absorber, characterised in that the covering layer consists of polycarbonate plastics.

Description

The invention relates to a plastic plate, consisting of a core layer of polycarbonate plastic and, at least on one side of the core layer, a coextruded cover layer of plastic, which cover layer contains at least 3% by weight of an ultraviolet absorber. The invention also relates to a method for the production of plastic sheets.

Polycarbonate plastics only have a limited weather resistance. Above all, they are damaged by ultraviolet radiation. Ultraviolet absorbers inserted into the plastic can protect the interior of a polycarbonate plastic sheet, but have no effect on the surface. In order to protect the surface, it is proposed according to DE-OS 1 694 273 to apply a varnish layer which can consist of three parts of an ultraviolet absorber and five parts of polymethyl methacrylate or polycarbonate

According to DE-OS 28 32 676, when producing a polycarbonate plastic sheet, it is proposed to apply a polymethyl methacrylate layer with a content of an ultraviolet absorber using co-extrusion.

In both cases, polymethacrylate plastics are preferably used for the cover layer, because such substances have high weather resistance and their surface is less susceptible to damage from ultraviolet radiation. A disadvantage of a cover layer of polymethacrylate is the lower toughness, compared to polycarbonates. If polycarbonate plastic sheets are placed under tension, for example in a bent state, tensile stresses will occur in the convex surface which can lead to cracking in the cover layer. With the eye, one can determine the increasing crack formation as a matting of the initially glossy surface. Also, the scratches will tend to go

further into the polycarbonate core layer, so that the coated plate does not retain the polycarbonate plastic's high breaking strength. Above all, the susceptibility to hailstorms increases. These disadvantages are even more noticeable when it comes to hollow profile boards, because there is a particularly large stretch on the convex side when laid in a bent manner.

The purpose of the invention is to avoid the reduction in fracture toughness that a polymethyl methacrylate layer causes,

without renouncing the protection provided by the ultraviolet absorber contained in the layer.

It has surprisingly been found that the aforementioned disadvantages can be avoided, while maintaining the protective effect of the tire layer, if

the cover layer consists of co-extruded polycarbonate plastic.

By using the same material for the core layer and the cover layer, both layers will have the same stretchability, so that there is no increased cracking in the cover layer under stress either.

It is surprising that rapid weathering does not occur on the surface of the tire layer when the tire layer contains the least

3, preferably at least 5% by weight of the ultraviolet absorber, despite the fact that the polycarbonate in the cover layer's surface will be fully exposed to ultraviolet radiation. The absorption of the ultraviolet rays will first take place inside the cover layer. The observed benefits only occur with a cover layer that is co-extruded with the core layer.

As mentioned, the invention can also be realized with a method for producing a plastic sheet, by co-extruding a core layer of polycarbonate plastic and a cover layer of plastic containing at least 3% by weight of an ultraviolet absorber, on at least one side of the core layer, by means of a plastic slit nozzle in which plasticized masses for the formation of the core and cover layers are pressed in by means of two extruders, characterized by the fact that a polycarbonate plastic is used as the plastic for the formation of the cover layer.

The simplest embodiment is shown in:

Figure 1 showing a section through a one-sided coated solid board,

figure 2 shows a section through a preferred embodiment where the plate is an extruded hollow chamber plate with a layer on both sides.

The core screen 1 in a massive plate can have a thickness of, for example, 2-10 mm, preferably 3-8 mm. As a rule, the outer sides of the core layer are mutually parallel and flat, but they can also be wavy or - primarily in the assembled or built-in state - uniaxially bent. The core layer can also be dome-shaped vault or be three-dimensionally deformed in another way.

The core layer 1 may also contain one or more hollow chambers 2. These hollow chambers preferably extend parallel to each other and run in straight lines through the core layer. Preferably, these are stepped double or triple plates, where the core layer 1 consists of two flat, parallel walls 3,4 which are uniformly connected to each other by means of steps 5. The hollow chambers 2 can optionally be divided by means of one or more further intermediate walls. The walls 3,4 and the steps 5 usually have wall thicknesses of between 0.3-2mm. The core layer, including the hollow chambers, has a thickness of, for example, 5-50, preferably 6-10mm.

The surface area and the surface shape of the core layer follow the requirements of the intended application and can be chosen to a large extent as needed within the framework of the technical manufacturing conditions. Flat-lying boards ideally have a right-angled surface and edge lengths of 0.5-6m. Longer solid sheets or webs can be rolled.

The core layer 1 has at least one and preferably on both sides

a cover layer 6 which differs from the core layer in that it has a higher content of ultraviolet absorber. The thickness must be sufficient to absorb more than 90%, preferably more than 99%, of a vertically incident ultraviolet radiation of 280-380 nm. The percentage is calculated on the non-reflected share. To achieve this, a thickness of 5-50 µm will be sufficient, but thicknesses of up to 100 µm can be applied.

The cover layer contains at least 3% by weight and preferably 5-15% by weight of a common ultraviolet absorber for plastics. The preferred content of ultraviolet absorbers is between 0.4 and 2.5g/m 2 but can possibly be increased to 5g per square metre. The higher the concentration, the thinner the cover layer is, so that the necessary absorption can take place within the cover layer. Below 0.4g/m, protection of the cover layer's surface against weather degradation is no longer guaranteed. The protection is more effective the higher the total per The amount of absorber used per square meter is Suitable ultraviolet absorbers are 2-hydroxy-4-n-octoxy-benzophenone, 2-hydroxy-4-methoxybenzonphenone, 2-(2'-hydroxy-5<1->methylphenyl)-benztriazole and other compositions of 2-hydroxy- benzophenones or benzotriazole, further 2,4-di-hydroxybenzoylfuran, salicylic acid phenyl ester, racorsindisal icylate, resorcimono- and di-benzoate, benzyl benzoate, stilbene, g-methylumbelliferone and its benzoate. Numerous additional ultraviolet absorbers are known and commercially available. Particular preference is given to ultraviolet absorbers which have low volatility at the processing temperature, that is to say particularly absorbers which have the highest possible molecular weight. In the chosen concentration, the absorber must be as homogeneously mixable as possible with the plastic material. The core layer can be completely free of absorbers or can contain these in a significantly lower concentration than in the cover layer. A concentration of 0.5% by weight is not exceeded.

The polycarbonate plastic is usually derived from an aromatic bisphenol or a mixture of such bisphenols, particularly bisphenol A. All polycarbonate plastics that can be processed into sheets with high toughness and light transmission are suitable as material for both the core layer and the cover layer.

The layers preferably, but not necessarily, consist of the same extrudable plastic material, disregarding the concentration of the ultraviolet absorber. The layers can be glass-clear or colorless or in the usual way be coloured, cloudy or pigmented, but the invention has its greatest significance for highly light-permeable masses.

The cover layer is provided at the same time as the core screen using coextrusion.

For the co-extrusion, well-known multi-material slit nozzles are used in which the plasticized masses are impressed by means of two extruders. The extrusion takes place at temperatures between 240 and 300°C.

The new sheets are suitable as glass and building elements, above all in the open, where the side exposed to sunlight is provided with the covering layer. The boards are advantageously used where tensile forces can act on the boards, for example in the case of a bent laying of massive boards or stepped double boards. This type of laying is often used in greenhouses and has previously led to heavy damage as a result of hail. With the invention, such damage is avoided.

Example

By co-extrusion using a multi-material slit nozzle fed by two extruders, a two-layer polycarbonate sheet is provided. In one extruder, an extrudable thermoplastic polycarbonate molding compound without an ultraviolet absorber is processed. In the second extruder, a mixture of 90% by weight of the same polycarbonate molding compound and 10% by weight of 2-hydroxy-4-n-octoxybenzophenone as ultraviolet absorber goes to the multi-material nozzle. The flow of this mixture forms a cover layer with a thickness of 30 µm on one surface of the core layer. The core-<1> layer is formed from the pure polycarbonate molding compound and has a thickness of 3mm. After the nozzle, the plastic forging is smoothed in a smoothing plant with three rollers.

In the case of penetrating sunlight, this plate will cast an even shadow that does not show surface disturbances. A similar image will appear from the plate's surface against one whose screen reflected sunlight.

The plate produced in this way is bent elastically with a radius of curvature of 0.5 mm and is exposed to the weather in the open air. After 2 years of exposure to the weather, the board is scratch-free. For comparison, an extruded plate smoothed in a smoothing machine was painted on

its surface after extruding none. The varnish was uniformly applied by means of varnish application rollers which worked opposite to the direction of extrusion. The lacquer solution consisted of 18% polycarbonate with a molecular weight of approx. 20000, 2% of the above-mentioned ultraviolet absorber and 80% dichloroethane. The solvent was then expelled into a drying oven with a gradually increasing temperature up to 100°C. The final varnish layer thickness was 30 ym.

The shadow image of this disc showed partial dots, orange-peel-like surface texture and optical disturbances resulting from an incomplete course and inclusions of dust particles.

In the case of such a board which is flexed elastically and exposed to the effects of the weather, it will already be possible to determine some cracks after a year. After 2 years, it can be determined that the plate has received numerous cracks. Crack formation is considered to be due to solvent residues in the polycarbonate and the low molecular weight. The lower molecular weight is necessary to obtain a high lacquer concentration, because it is thereby possible to avoid additional surface disturbances caused by skin formations when the solvent evaporates and disturbances in the lacquer process.

Claims (5)

1. Plastic sheet, consisting of a core layer of polycarbonate plastic f which does not contain more than 0.5% by weight of an ultraviolet absorber, and which on at least one side of the core layer has a cover layer of plastic co-extruded with the core layer, which cover layer contains at least 3% by weight of an ultraviolet absorber, characterized in that the cover layer consists of polycarbonate plastic e.g. 2. Plastic sheet according to claim 1, characterized by the thickness of the cover layer of 5 to 50 um. 3. Plastic sheet according to claim 1 or 2, characterized in that the core layer has a thickness of 0.3 to 20 mm. 4. Plastic sheet according to claim 3, characterized in that the core layer has longitudinally continuous cavities. 5. Method for producing a plastic sheet according to claims 1-4, by coextrusion of a core layer of polycarbonate plastic and a cover layer of plastic containing at least 3% by weight of an ultraviolet absorber, on at least one side of the core layer, by means of a plastic slit nozzle in which plasticized masses for forming the core and cover layers are pressed in by means of two extruders, characterized in that a polycarbonate plastic is used as plastic for the formation of the cover layer.