A polymer workpiece is described. The workpiece has an upper main surface, a lower main surface, an injection-mold separating surface and a flow attack edge surface. The flow attack edge surface is formed in the region between the injection-mold separating surface and the lower main surface as a planar surface with an angle α with respect to the injection-mold separating surface of 20° to 70°, and/or deviates by an amount a from 0.0 mm to 0.5 mm from the planar surface.

A polymer workpiece is described. The workpiece has an upper main surface, a lower main surface, an injection-mold separating surface and a flow attack edge surface. The flow attack edge surface is formed in the region between the injection-mold separating surface and the lower main surface as a planar surface with an angle α with respect to the injection-mold separating surface of 20° to 70°, and/or deviates by an amount a from 0.0 mm to 0.5 mm from the planar surface.

A belt for drive systems includes: an elastic and flame-retardant belt body made from a polymeric material and at least one flame retardant additive, the belt body having a cover layer as a belt back and a substructure which has a force transmission zone; and a tension member embedded in the belt body, wherein the belt body is partially or completely provided with a coating, which coating is single- or multi-layered.

The invention relates to tetrahydrofuran derivatives of the formula (I)

##STR00001##

in which the radical R1 has the definition (CH.sub.2═CH—CO—O—(CHR3—CH.sub.2—O).sub.m—CH.sub.2)— and the radical R2 has the definition (CH.sub.2═CH—CO—O—(CHR4—CH.sub.2—O).sub.n—CH.sub.2)—, in which the radicals R3 and R4 independently of one another are hydrogen or methyl, and with the proviso that the sum of the indices m and n is a number in the range from 0 to 20.

The compounds (I) are suitable for coating the surfaces of solid substrates, more particularly for coating plastics.

The invention relates to tetrahydrofuran derivatives of the formula (I)

##STR00001##

in which the radical R1 has the definition (CH.sub.2═CH—CO—O—(CHR3—CH.sub.2—O).sub.m—CH.sub.2)— and the radical R2 has the definition (CH.sub.2═CH—CO—O—(CHR4—CH.sub.2—O).sub.n—CH.sub.2)—, in which the radicals R3 and R4 independently of one another are hydrogen or methyl, and with the proviso that the sum of the indices m and n is a number in the range from 0 to 20.

The compounds (I) are suitable for coating the surfaces of solid substrates, more particularly for coating plastics.

An UV (ultraviolet), IR (infrared) and NIR (near infrared) protection system and method for surfaces or substrates that experience degradation from solar radiation, UV/IR/NIR exposure. The method for protecting a substrate from UV degradation includes treating a surface of the substrate to allow a UV blocking agent to adhere to the surface of the substrate, applying the UV blocking agent to the surface of the substrate, and allowing the surface of the substrate to harden, thereby adhering the UV blocking agent to the surface of the substrate. The UV/IR/NIR protection system is tunable so that specific ranges of the UV spectrum may be blocked to reduce or eliminate UV degradation. The UV protection system may be in the form of a dispersion, suspension, emulsion, or in other liquid application form; in a solid particle form; or a pre-mold/precast transfer medium when applied to or it becomes the given substrate.

A method of manufacturing a coated low-friction medical device, such as low-friction medical tubing, including applying a coating to one or more selected portions of a surface of low-friction medical tubing to indicate at least one marking formed along the surface of the low-friction medical tubing, and simultaneously or substantially simultaneously: (a) curing the applied coating to a designated temperature (which is above the temperature at which the low-friction medical tubing begins to decompose and shrink) to adhere the applied coating to the surface of the low-friction medical tubing, (b) utilizing one or more anti-shrinking devices to counteract or otherwise inhibit the shrinking of the low-friction medical tubing, and (c) exhausting any harmful byproducts resulting from curing the low-friction medical tubing to a temperate above the temperature at which the low-friction medical tubing begins to decompose.

A method of manufacturing a coated low-friction medical device, such as low-friction medical tubing, including applying a coating to one or more selected portions of a surface of low-friction medical tubing to indicate at least one marking formed along the surface of the low-friction medical tubing, and simultaneously or substantially simultaneously: (a) curing the applied coating to a designated temperature (which is above the temperature at which the low-friction medical tubing begins to decompose and shrink) to adhere the applied coating to the surface of the low-friction medical tubing, (b) utilizing one or more anti-shrinking devices to counteract or otherwise inhibit the shrinking of the low-friction medical tubing, and (c) exhausting any harmful byproducts resulting from curing the low-friction medical tubing to a temperate above the temperature at which the low-friction medical tubing begins to decompose.

This invention provides a method for manufacturing decorated-parts of high design-quality and reliability, since the exposed surface of the base coat-layer is not bulged, and thus the color of said coat-layer is distinct. The method for manufacturing decorated-parts of this invention comprises a base coat-layer-forming process, a surface coat-layer-forming process and a laser-decorating process. In the base coat-layer-forming process, a resin-base material of a highly light color at a lightness-level of 70 or more or a clear and colorless resin base-material is formed. In the surface coat-layer forming process, the surface coat-layer of a less-bright color at a lightness-level of 20 or less is formed on the base coat-layer. In the laser-decorating process, the first laser-processed groove penetrating the surface coat-layer and exposing partially the base coat-layer is made by irradiating the infrared laser onto such surface coat-layer, thus providing a fine decoration onto the surface of said decorated-part.

This invention provides a method for manufacturing decorated-parts of high design-quality and reliability, since the exposed surface of the base coat-layer is not bulged, and thus the color of said coat-layer is distinct. The method for manufacturing decorated-parts of this invention comprises a base coat-layer-forming process, a surface coat-layer-forming process and a laser-decorating process. In the base coat-layer-forming process, a resin-base material of a highly light color at a lightness-level of 70 or more or a clear and colorless resin base-material is formed. In the surface coat-layer forming process, the surface coat-layer of a less-bright color at a lightness-level of 20 or less is formed on the base coat-layer. In the laser-decorating process, the first laser-processed groove penetrating the surface coat-layer and exposing partially the base coat-layer is made by irradiating the infrared laser onto such surface coat-layer, thus providing a fine decoration onto the surface of said decorated-part.