DE102010001269A1 - Plastic molded body for use as non-skid floor cover in wet barefoot areas of sanitary elements, such as bathtubs, has structures and micro-structured upper surfaces, where plastic mold body is made of thermoplastic materials - Google Patents

Abstract

The plastic mold body has structures and micro-structured upper surfaces, where the plastic mold body is made of thermoplastic materials and polymethacrylate. The plastic mold body has a layer that is made of polymethacrylate. The polymethacrylate layer is filled with mineral filler. The plastic mold body has two layers made of thermoplastic materials.

Description

Field of the invention

The invention relates to non-slip sanitary elements, such as bathtubs, shower trays and treads made of plastics.

As plastics, for example, cast or extruded acrylic glasses come (PMMA) in question, which are marketed under the brand name PLEXIGLAS ^® GS and PLEXIGLAS ^® XT from Evonik Röhm GmbH.

Furthermore, standard thermoplastics can be used for this purpose, such as styrene-acrylonitrile copolymers (SAN), polystyrene (PS), acrylonitrile-butadiene-styrene copolymers (ABS) or polycarbonate (PC).

High temperature plastics such as polyphenylene sulfoxide (PPSU) can also be used.

The sanitary element can also be designed as a plastic composite, a non-slip executed decorative layer of the aforementioned plastics is applied by conventional methods, such as coextrusion or lamination, on a support layer.

Optionally, the sanitary article may still have a reinforcement which is applied in the form of a fibrous polymer material on the underside of the sanitary article. The fiber-containing polymer material, for example glass fiber reinforced polyester, is applied, for example, by spraying on the underside of the sanitary article.

State of the art

Non-slip sanitary elements are known. In the SI Information 2004, page 126 (AT-Fachverlag Fellbach) is an anti-slip coating "Duschogrip ^® " Duscholux for the entire shower tray program described.

The disadvantage of this solution is that the anti-slip coating must be subsequently applied to the surface of the sanitary element.

The super-flat design shower tray "Purano ^® " by Hüppe is also equipped with anti-slip coating in the form of a coating. Again, there is the disadvantage that the coating must be applied subsequently to the sanitary object.

Coatings also have the disadvantage of being more soiled than the rest of the surface of the sanitary element and difficult to clean. There is still no experience of the durability of the slip-resistant effect of subsequently applied coatings.

U.S. Patent 3,942,199 (Kollsman) describes sanitary elements on which slip-resistant coverings are applied. These consist of island-shaped elevations of, for example, 4.5 mm in diameter, which are 6 mm apart (measured from the center of). The height of the islands is 0.5 mm. A roughness of the surface of the island-like elevations is not mentioned. Any tests or exams of the. slip-resistant effect are not described.

US-OS 2004/0148892 (Kitakado) describes a surface for sanitary elements that has post-applied structures. The structures serve to dissipate the surface water. Information about height, distribution or roughness of the structures are not made. Any tests or tests of anti-slip effect are not described.

US-OS 2002/0146540 (3M, Johnston et al.) Describes a post-applied film with water-draining structures. The structures serve to promote the discharge of water in certain directions. Information about height, distribution or roughness of the structures are not made. Any tests or tests of anti-slip effect are not described.

GB 2,156,672 (ICI) describes a non-slip surface of sanitary ware. The antislip effect is achieved by embedded glass beads in the polymer matrix, the glass beads have a diameter of 200 microns to 800 microns and are introduced in the amount of less than 5 wt .-% in the polymer. Any tests or tests of anti-slip effect are not described.

EP 1 323 368 (Hüppe) describes a method and an apparatus for producing a tub body, wherein the surface of the mold has a structure with slip-resistant properties. The surface is additionally roughened by means of a blasting process with granular granules. Numerical values for the depth of roughness are not disclosed, any tests or tests of anti-slip effect are not described.

US 2001/0046588 (Sturtevant, Cullivan) describe a non-slip surface of polyethylene moldings to which a layer of polyurethane is applied by spraying. The PU layer remains rough, preventing slippage of objects on the surface.

task

In view of the state of the art discussed, the object now was to develop a slip resistance for sanitary elements which meets the requirements DIN 51097 "Testing of floor coverings - Determination of slip-resistant property - Wet-loaded barefoot areas - Approach-inclined plane" (November 1992) and that is easy to clean, dispenses with the need for the additional coating step of applying it and with which the sanitary element blank is easily reshaped.

solution

It has now been found that PLEXIGLAS ^® GS SW has a slip-inhibiting effect (Example 1).

The surface of the slip-resistant plastic layer has structures, such as knobs, diamonds, rectangles, squares or circles, which come from the plastic surface. The protruding structures may be arranged regularly over the surface, wherein irregular arrangements are possible, for example, an accumulation of structures in particularly contaminated areas of the sanitary elements.

The regular arrangement of the raised structures on the surface is preferred. The distance between the raised structures is between 500 μm and 6,000 μm, preferably around 1,500 μm and 4,500 μm. This is the first structuring.

The number of raised structures is between 1 and 500 pieces / cm ² , preferably between 1 and 250 pieces / cm ² . The height of the raised structure is between 500 μm and 20 μm.

However, it turns out that one as above or in the U.S. Patent 3,942,199 described structure is insufficient to a classification of the non-slip surface in the class A to C of DIN 51097 to reach. (see Example 1)

In addition to the structures described above, the arrangement according to the invention has a further roughness. The mean surface roughness of the roughness (R _a ) is 1 μm to 50 μm, preferably 1 μm to 40 μm and very particularly preferably 1 μm to 15 μm. (determined after DIN EN ISO 4287 and 4288 ).

This microroughness is achieved, for example, by steps in the manufacturing process. In the case that one prepares the plastic moldings by the known methods of cast polymerization, by a roughness of the chamber plates used for Polymerisationskammerbau glass, in the case of production of the plastic moldings by extrusion by adding diffuser beads, as for example in the DE 43 27 464 are described. Furthermore, the roughness of the surface can be achieved by fillers, such as granules of minerals.

• • Einmal die erhabenen Strukturen mit einer Höhe zwischen 500 μm und 20 μm, einem Abstand zwischen 500 μm und 6.000 μm und Anzahl der erhabenen Strukturen zwischen 1 und 500 Stück/cm² und
• • einer Mikrorauhigkeit zwischen 1 μm bis 50 μm, bevorzugt bei 1 μm bis 40 μm und ganz besonders bevorzugt bei 1 μm bis 15 μm.

The plastic molding according to the invention thus has two roughnesses:

• • Once the raised structures with a height between 500 microns and 20 microns, a distance between 500 microns and 6,000 microns and number of raised structures between 1 and 500 pieces / cm ² and
• A microroughness of between 1 μm and 50 μm, preferably between 1 μm and 40 μm and most preferably between 1 μm and 15 μm.

The microroughness covers the raised structures and / or covers the "valley" between the raised structures

For example, the material is marketed under the name PLEXIGLAS ^® Structure Swing by Evonik Röhm GmbH and is used in interior design and trade fair construction, for example for balcony railings, windbreak walls, door glazings, entrance roofs, partition walls, door glazing, banisters, shower enclosures, shelves, cabinet doors, Advertising displays, exhibition stands, side tables, light walls and wardrobes used.

The required micro-roughness can also be achieved by filling the plastics molding with particulate inorganic fillers ES having the corresponding particle size distribution.

Suitable particulate inorganic fillers FS are primarily aluminum oxides, aluminum hydroxides or alumina hydrates. Optionally, other known per se particulate fillers such as alkaline earth oxides, silica and / or titanium oxide in various modifications, clays, silicates, metals or metal alloys, metal oxides, synthetic materials such as ceramics, glass flour, porcelain, slag or finely divided silica, quartzes, kaolin , Talc, mica, feldspar, apatite, barytes, gypsum, chalk, limestone, dolomite or mixtures of the aforementioned components.

The amount of filler is, based on the polymer, 2 wt .-% to 80 wt .-%, preferably between 20 wt .-% and 70 wt .-% and most preferably between 55 wt .-% and 70 wt. -%.

The product PLEXICOR ^® FreeStyle uses a mineral filler called LUZENAC SE SUPER (manufacturer: Paltentaler Minerals GmbH & Co KG).

By means of the solution according to the invention one is able to provide the entire surface of the sanitary element, in particular edges and bends, slip-resistant, especially in flat shower trays.

Another object of the invention is to arrange a filled coextrusion layer on a base body made of an unfilled thermoplastic. The amount of filler in the coextrusion layer, based on the amount of polymer in the coextrusion layer, is between 2% by weight and 40% by weight, preferably between 15% by weight and 30% by weight, and most preferably between 6 wt .-% and 20 wt .-%.

As thermoplastics, for example, cast or extruded acrylic glasses come (PMMA) in question, which are marketed under the brand name PLEXIGLAS ^® GS and PLEXIGLAS ^® XT from Evonik Röhm GmbH.

Furthermore, standard thermoplastics can be used for this purpose, such as styrene-acrylonitrile copolymers (SAN), polystyrene (PS), acrylonitrile-butadiene-styrene copolymers (ABS) or polycarbonate (PC).

High temperature plastics such as polyphenylene sulfoxide (PPSU) can also be used.

As plastics for the coextrusion layer, the abovementioned plastics could also be used.

Embodiment of the invention

The PLEXIGLAS ^® structural panel was rebuilt into an apparatus DIN 51097 installed and tested.

The inventive solution avoids zones of the sanitary element, which are not equipped slip-resistant. The anti-slip board can be single-layered, two-layered (Example 1) or be multi-layered. Multilayer sanitary elements can be produced by coextrusion of the corresponding molding compositions.

As reinforcing layers all known in sanitary element reinforcement layers can be used. Results PLEXIGLAS ^® structural panel Angle (°) Curled (CL) 5 pearl 5 WW086 SF (SF = skin friendly) 6 Pluto 6 WBF99SW (SW = swing) 12 / certificate no. 67160404.001

The product PLEXIGLAS ^® structure, surface swing reached after DIN 51097 the evaluation group A.

Beispiel 2: Messung einer lediglich microrauhen Oberfläche

Beispiel 3: Messung der erfindungsgemäßen Oberfläche

The structures of the Plexiglas ^® structure, surface Swing are about 58 μm high, have a distance of 3 to 8 mm and are diamond-shaped (example 2). Example 1: Measurement of a merely structured surface

Example 2: Measurement of a microrough surface only

Example 3: Measurement of the surface according to the invention

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 3942199 [0011, 0022]
• US 2004/0148892 [0012]
• US 2002/0146540 [0013]
• GB 2156672 [0014]
• EP 1323368 [0015]
• US 2001/0046588 [0016]
• DE 4327464 [0024]

Cited non-patent literature

• SI Information 2004, page 126 (AT-Fachverlag Fellbach) [0007]
• DIN 51097 "Testing of floor coverings - Determination of slip-resistant property - Wet-loaded barefoot areas - Method of loading inclined plane" (November 1992) [0017]
• DIN 51097 [0022]
• DIN EN ISO 4287 [0023]
• 4288 [0023]
• DIN 51097 [0038]
• DIN 51097 [0041]

Claims (12)

Use of plastic moldings made of thermoplastics with structured and micro-rough surfaces as anti-slip flooring in wet barefoot areas. Non-slip floor covering for wet barefoot areas, characterized in that it consists of a plastic molded body with structured and micro-rough surfaces. Sanitary element, characterized in that it is equipped with a non-slip floor covering according to claim 2. Use according to claim 1, characterized in that the plastic molding consists of poly (meth) acrylate. Use according to claim 4, characterized in that the plastic molding consists of at least one layer of poly (meth) acrylate. Use of plastic moldings according to claim 4 as slip-resistant covering for sanitary elements, characterized in that on the surface of the plastic molded body raised structures are arranged, wherein the distance of the structures between 500 microns and 6,000 microns, the amount of the raised structures between 1 and 500 pieces / cm ² and the height of the raised structures between 20 microns and 500 microns and the micro-roughness is between 1 micron to 50 microns. Use of plastic moldings according to claim 6 as slip-resistant covering for sanitary elements, characterized in that on the surface of the plastic molded body are arranged sublime structures, wherein the distance of the structures between 1,500 microns and 4,500 microns, the amount of raised structures between 1 and 250 pieces / cm ² and the height of the raised structures between 20 microns and 500 microns and the micro-roughness of the raised structures is between 2 microns to 40 microns. Use of plastic moldings according to claim 7 as anti-slip covering for sanitary elements, characterized in that raised structures are arranged on the surface of the plastic molded body, the spacing of the structures being between 1,500 μm and 4,500 μm, the amount of the raised structures being between 1 and 250 pieces / cm ² and the height of the raised structures between 20 microns and 500 microns and the micro-roughness of the raised structures is between 1 micron to 15 microns. Use according to claim 4, characterized in that the plastic molding consists of at least one layer of poly (meth) acrylate and the poly (meth) acrylate layer is filled with a mineral filler. Use according to claim 9, characterized in that the amount of filler is between 20 wt .-% and 80 wt .-%. Use according to claim 4, characterized in that the plastic molding consists of at least two layers of thermoplastic materials and a layer is filled with a mineral filler. Use according to claim 11, characterized in that the amount of filler in the filled layer of thermoplastic material is between 2% by weight and 40% by weight.