Abstract: The present application relates to an insertion sleeve (2), in which a guide wire (3) extends in order to guide the insertion sleeve (2). A cavity (23) is formed in the sleeve wall (22), which cavity extends in parallel with a longitudinal direction of the insertion sleeve (2) over the whole length of the sleeve, wherein said cavity (23) accommodates the guide wire (3). In addition to the cavity (23) at least one control wire (4) is integrated into the sleeve wall (22), which at least one control wire is designed to cause a curvature of the insertion sleeve (2).

Abstract: A vascular prosthesis (1) for connection to a natural cardiovascular system, includes a volume chamber (2), wherein the volume chamber (2) has, in a blood pressure range below a pressure threshold value D, a pressure-expansion behavior substantially corresponding to the pressure-expansion behavior of a natural blood vessel, while the volume of the volume chamber (2), depending on the pressure, increases by at least 10 cm3 in a blood pressure range above the pressure threshold value D. The vascular prosthesis (1) is configured as a textile tube, wherein the textile tube includes in the region of the volume chamber (2) an elastic yarn having a core made from silicone yarn around which a yarn made from polyethylene terephthalate (PET) is wrapped.

Abstract: The present application relates to an insertion sleeve (2), in which a guide wire (3) extends in order to guide the insertion sleeve (2). A cavity (23) is formed in the sleeve wall (22), which cavity extends in parallel with a longitudinal direction of the insertion sleeve (2) over the whole length of the sleeve, wherein said cavity (23) accommodates the guide wire (3). In addition to the cavity (23) at least one control wire (4) is integrated into the sleeve wall (22), which at least one control wire is designed to cause a curvature of the insertion sleeve (2).

Abstract: A vascular prosthesis (1) for connection to a natural cardiovascular system, includes a volume chamber (2), wherein the volume chamber (2) has, in a blood pressure range below a pressure threshold value D, a pressure-expansion behavior substantially corresponding to the pressure-expansion behavior of a natural blood vessel, while the volume of the volume chamber (2), depending on the pressure, increases by at least 10 cm3 in a blood pressure range above the pressure threshold value D. The vascular prosthesis (1) is configured as a textile tube, wherein the textile tube includes in the region of the volume chamber (2) an elastic yarn having a core made from silicone yarn around which a yarn made from polyethylene terephthalate (PET) is wrapped.

Abstract: Devices and methods for cleaning a roller of a system for processing strip-type material may involve a suction duct in addition to a nozzle that directs a gas flow onto a surface of the roller. The nozzle and the suction duct may be disposed in a hood that covers part of a circumference of the roller. Further, the nozzle can be disposed at an angle within a range of ±45 degrees with respect to a normal line extending orthogonally from the surface of the roller. Moreover, the nozzle may be spaced less than 50 mm apart from the surface of the roller.

Abstract: A process for melt dip coating a strip of high-tensile steel with alloy constituents including zinc and/or aluminum includes the following steps. The strip is heated in a continuous furnace initially in a reductive atmosphere to a temperature of approximately 650° C., at which the alloy constituents diffuse to the surface in small amounts. The surface, consisting predominantly of pure iron, is converted into an iron oxide layer by a short heat treatment at a temperature of up to 750° C. in a reaction chamber which is integrated in a continuous furnace and has an oxidizing atmosphere. In a subsequent annealing treatment at a higher temperature in a reductive atmosphere, this iron oxide layer prevents the alloy constituents from diffusing to the surface. In the reductive atmosphere, the iron oxide layer is converted into a pure iron layer to which the zinc and/or aluminum are applied in the molten bath with optimum adhesion.

Abstract: A method for coating a flat steel product manufactured from a high strength steel with a metallic coating, wherein the flat steel product is initially subjected to a heat treatment, in order then, in the heated state, to be hot-dip galvanized with the metallic coating in a melting bath containing overall at least 85% zinc and/or aluminum. The heat treatment includes heating the steel product in a reducing atmosphere, followed by converting a surface of the flat product to an iron oxide layer by a heat treatment lasting 1 to 10 secs in an oxidizing atmosphere, followed by annealing in a reducing atmosphere over a period of time which is longer than the duration of the formation of the iron oxide layer such that the iron oxide layer is reduced at least on its surface to pure iron, followed by cooling the product to a melting bath temperature.

Abstract: A method for coating a flat steel product manufactured from a high strength steel with a metallic coating, wherein the flat steel product is initially subjected to a heat treatment, in order then, in the heated state, to be hot-dip galvanized with the metallic coating in a melting bath containing overall at least 85% zinc and/or aluminum. The heat treatment includes heating the steel product in a reducing atmosphere, followed by converting a surface of the flat product to an iron oxide layer by a heat treatment lasting 1 to 10 secs in an oxidizing atmosphere, followed by annealing in a reducing atmosphere over a period of time which is longer than the duration of the formation of the iron oxide layer such that the iron oxide layer is reduced at least on its surface to pure iron, followed by cooling the product to a melting bath temperature.

Abstract: A process for melt dip coating a strip of high-tensile steel with alloy constituents including zinc and/or aluminum includes the following steps. The strip is heated in a continuous furnace initially in a reductive atmosphere to a temperature of approximately 650° C., at which the alloy constituents diffuse to the surface in small amounts. The surface, consisting predominantly of pure iron, is converted into an iron oxide layer by a short heat treatment at a temperature of up to 750° C. in a reaction chamber which is integrated in a continuous furnace and has an oxidizing atmosphere. In a subsequent annealing treatment at a higher temperature in a reductive atmosphere, this iron oxide layer prevents the alloy constituents from diffusing to the surface. In the reductive atmosphere, the iron oxide layer is converted into a pure iron layer to which the zinc and/or aluminium are applied in the molten bath with optimum adhesion.