The present invention provides a method for producing a coated stainless steel member, comprising: performing Wood's strike nickel plating on a stainless steel substrate, and then performing cationic electrodeposition on a formed Wood's strike nickel plating layer.

A method for producing a motor vehicle that includes producing and painting a bodyshell having a platform composed of metal and a vehicle body composed of metal which is configured for placement on the platform, producing and painting a main floor composed of metal separately from a remainder of the bodyshell, and attaching the main floor to the previously painted platform and/or the previously painted vehicle body.

A method for producing a motor vehicle that includes producing and painting a bodyshell having a platform composed of metal and a vehicle body composed of metal which is configured for placement on the platform, producing and painting a main floor composed of metal separately from a remainder of the bodyshell, and attaching the main floor to the previously painted platform and/or the previously painted vehicle body.

The invention relates to a method for introducing a media outlet (6) into a hollow profiled section (1), in which method a first media outlet passage (7), via which a medium can flow out of a cavity (2) in the hollow profiled section (1), is introduced by means of a first tool into an outer wall (5) of the hollow profiled section (1), and in which method a second tool is introduced into the cavity (2) in the hollow profiled section (1) via the first media outlet passage (7), and by means of said second tool at least one second media outlet passage (8) is introduced into an inner profiled section web (4) of the hollow profiled section (1). The invention further relates to a method for providing a hollow profiled section (1), in which the hollow profiled section (1) is extruded and a media passage (6) is introduced into the hollow profiled section (1) in a method according to any of the preceding claims, a geometry of the profiled section web (4) being selected depending on a position of the first media outlet passage (7) and the hollow profiled section (1) being extruded with the selected geometry of the profiled section web (4).

The invention relates to a method for introducing a media outlet (6) into a hollow profiled section (1), in which method a first media outlet passage (7), via which a medium can flow out of a cavity (2) in the hollow profiled section (1), is introduced by means of a first tool into an outer wall (5) of the hollow profiled section (1), and in which method a second tool is introduced into the cavity (2) in the hollow profiled section (1) via the first media outlet passage (7), and by means of said second tool at least one second media outlet passage (8) is introduced into an inner profiled section web (4) of the hollow profiled section (1). The invention further relates to a method for providing a hollow profiled section (1), in which the hollow profiled section (1) is extruded and a media passage (6) is introduced into the hollow profiled section (1) in a method according to any of the preceding claims, a geometry of the profiled section web (4) being selected depending on a position of the first media outlet passage (7) and the hollow profiled section (1) being extruded with the selected geometry of the profiled section web (4).

A coated component includes a metallic body defining an inner volume configured to retain a fluid therein. The metallic body includes a plurality of segments, at least one weld joint attaching the plurality of segments, an outer surface, and an inner surface facing and defining the inner volume. The component further includes a chrome-free protective coating disposed on each of the outer surface and the inner surface. The coating includes an epoxy layer, and an oxide layer disposed between the epoxy layer and the respective outer surface and inner surface.

An automotive member or a feed oil pipe includes: a member made of a ferritic stainless steel containing predetermined components containing 10.5% to 18.0% of Cr in mass %; a metal fitting made of an aluminized stainless steel sheet, the metal fitting being attached to the member; and a gap structure defined between the member and the metal fitting, the gap structure being exposed to a chloride environment, where the metal fitting has an Al-plating weight per unit area of 20 g/m.sup.2 or more and 150 g/m.sup.2 or less on a surface corresponding to a gap of the gap structure, and surfaces of the metal fitting and the non-aluminized member other than the gap are coated with a cation electrodeposition coating film having a thickness of 5 m to 35 m.

An automotive member or a feed oil pipe includes: a member made of a ferritic stainless steel containing predetermined components containing 10.5% to 18.0% of Cr in mass %; a metal fitting made of an aluminized stainless steel sheet, the metal fitting being attached to the member; and a gap structure defined between the member and the metal fitting, the gap structure being exposed to a chloride environment, where the metal fitting has an Al-plating weight per unit area of 20 g/m.sup.2 or more and 150 g/m.sup.2 or less on a surface corresponding to a gap of the gap structure, and surfaces of the metal fitting and the non-aluminized member other than the gap are coated with a cation electrodeposition coating film having a thickness of 5 m to 35 m.

A method of making a breath sensing tube includes: (A) dispersing a nanowire material in a solution in a dielectriphoretic bath, such that the nanowire material is formed into individual nanowires and nanowire aggregates; (B) adsorbing the nanowire aggregates on a bath electrode through dielectrophoresis so as to obtain a nanowire-containing solution containing the individual nanowires; contacting sensor electrodes of a substrate with the nanowire-containing solution; and subjecting the nanowire-containing solution to dielectrophoresis, so that one of the individual nanowires is adsorbed to the sensor electrodes to interconnect the sensor electrodes.

A method of making a breath sensing tube includes: (A) dispersing a nanowire material in a solution in a dielectriphoretic bath, such that the nanowire material is formed into individual nanowires and nanowire aggregates; (B) adsorbing the nanowire aggregates on a bath electrode through dielectrophoresis so as to obtain a nanowire-containing solution containing the individual nanowires; contacting sensor electrodes of a substrate with the nanowire-containing solution; and subjecting the nanowire-containing solution to dielectrophoresis, so that one of the individual nanowires is adsorbed to the sensor electrodes to interconnect the sensor electrodes.