Method to produce an insulating pipe section for pipeworks and a pipe section

The invention claimed is: 1. A method for applying a flexible cladding material to an outer surface of an insulation layer for a pipe section comprising the following steps: providing the insulation layer in the shape of a cylinder having a cylindrical central opening, providing a first and a second supporting element defining a gap between the first and second supporting element, of which at least the first element is movable towards and away from the second supporting element between a first position in which the two supporting elements are close to each other, thereby nearly closing the gap and a second position in which the supporting elements are at a distance from each other, thereby defining the gap being larger than the gap in the first position, arranging a layer of the flexible cladding material between the insulation layer and the two supporting elements in such manner that an adhesive surface of the layer of flexible cladding material is facing towards the insulation layer, or in such a manner that an adhesive surface of the insulation layer is facing towards the layer of flexible cladding material, moving the insulation layer and the supporting elements in relation to each other in such manner that the insulation layer and at least a part of the layer of the flexible cladding material is moved through the gap between the first and the second supporting element, whereby the two supporting elements are moved towards each other after the insulation layer and the layer of the flexible cladding material with its major diameter has passed through the gap between the first and the second supporting element and wherein the flexible cladding material is adhesively connected to the insulation layer during or after the mentioned process steps. 2. The method according to claim 1 , wherein, the layer of the flexible cladding material is arranged on a carrier having the two supporting elements being relatively movable in a horizontal plane to each other; the insulation layer being arranged on the layer of the flexible cladding material above the gap between the two supporting elements of the carrier; wherein at least one of the two supporting elements of the carrier is moved from the first position into the second position, thereby widening the gap; wherein the insulation layer together with the layer of the flexible cladding material is lowered into an area at least partly below the carrier; wherein at least one of the two supporting elements of the carrier is moved from the second position to the first position thereby bringing two areas of the layer of the flexible cladding material surrounding the insulation layer into an adjacent position to each other and wherein the two areas of the layer of the flexible cladding material are connected to each other. 3. The method according to claim 1 , wherein, the layer of the flexible cladding material is arranged on a carrier having the two supporting elements being relatively movable in a horizontal plane to each other; the insulation layer being arranged on the layer of the flexible cladding material above the gap between the two supporting elements of the carrier; wherein the insulation layer together with the layer of the flexible cladding material is lowered through the gap into an area at least partly below the carrier; wherein at least one of the two supporting elements of the carrier is moved, thereby closing the gap and bringing two areas of the layer of the flexible cladding material into an adjacent position to each other, surrounding the insulation layer and wherein the two areas of the layer of the flexible cladding material are connected to each other. 4. The method according to claim 1 , wherein, at least one surface of the layer of the flexible cladding material is provided with a covering that is removed to expose an adhesive surface before positioning the insulation layer on the adhesive surface of the layer of the flexible cladding material. 5. The method according to claim 1 , wherein, the supporting elements are moved in such manner that they each exerts a pressure on the flexible cladding material towards the insulation layer. 6. The method according to claim 1 , wherein, the two adjacent areas of the layer of the flexible cladding material are connected to each other by using at least one adhesive tape. 7. The method according to claim 1 , wherein, the layer of the flexible cladding material is a UV light curable fiberglass reinforced polyester mat that after application on the insulation layer is cured in a curing station by using at least one light source emitting UV light. 8. The method according to claim 1 , wherein, a core is inserted into the central cylindrical opening of the insulation layer before positioning the insulation layer in the area of the supporting elements. 9. The method according to claim 6 , wherein, the insulation layer is turned around its middle axis before connecting the two areas of the layer of the flexible cladding material being adjacent to each other. 10. The method according to claim 1 , wherein, the first and second supporting elements are moved simultaneously and equally. 11. The method according to claim 1 , wherein, the insulation layer is interrupted by a slit being arranged radially forming two ends of the insulation layer being arranged adjacent to each other and wherein the layer of the flexible cladding material is fixed to the insulation layer leaving one end of the insulation layer free of and therefore not covered by the layer of the flexible cladding material. 12. The method according to claim 11 , wherein, the insulation layer is elastified in the area of the one end not covered by the layer of the flexible cladding material. 13. A pipe section for heat insulation consisting of an insulation layer having an outer surface and an outer cladding made of a layer of a flexible fiberglass reinforced polyester mat, produced according to the method according to claim 1 , wherein, the layer of the flexible cladding material has a circumferential length being exactly a circumferential length of the outer surface of the insulation layer or up to a maximum of 5% shorter of the circumferential length of the outer surface of the insulation layer and wherein the layer of the flexible cladding material is directly fixed on an outer surface of the insulation layer. 14. The pipe section according to claim 13 , wherein, the layer of the flexible cladding material is fixed to the outer surface of the insulation layer via an adhesive being part of the layer of the flexible cladding material. 15. The pipe section according to claim 14 , wherein, the layer of the flexible cladding material has been cured by UV-light. 16. The pipe section according to claim 13 , wherein, the insulation layer has an outer cylindrical diameter between 500 mm and 1.200 mm. 17. The pipe section according to claim 13 , wherein, the insulation layer is interrupted by a slit being arranged radially forming two ends of the insulation layer being arranged adjacent to each other and wherein the layer of the flexible cladding material is fixed to the insulation layer leaving one end of the insulation layer free of and therefore not covered by the layer of the flexible cladding material. 18. The insulation element according to claim 13 , wherein, the insulation layer is elastified in an area of one end not covered by the layer of the flexible cladding material.