A method of electro-chemical plating is disclosed. The catholyte is delivered to the cathode chamber. The catholyte is controlled at a first temperature before flowing into the cathode chamber. The anolyte is provided at room temperature. The temperature of the anolyte is lowered from the room temperature to a second temperature before delivering into the anode chamber. The second temperature is equal to or lower than the first temperature. The plating surface of the substrate is immersed in the electrolyte. The substrate is biased to a direct current (DC) voltage. The biased substrate attracts ions of the metal in the electrolyte toward the plating surface so as to electroplating the metal onto the substrate.

A method for producing a metal porous body includes the steps of: performing electrical conduction treatment on a surface of a skeleton of a sheet-like resin porous body having the skeleton with a three-dimensional network structure, to obtain a conductive resin porous body having a conductive layer; performing electroplating treatment on a surface of a skeleton of the conductive resin porous body to obtain a plated resin porous body having a metal plating layer; and performing treatment of removing at least the resin porous body from the plated resin porous body to obtain a metal porous body. In the electroplating treatment, power was supplied to a rotation shaft of a rotating electrode roller by bringing a power supply brush formed by a material containing carbon as a main component into sliding contact with the rotation shaft.

A method for producing a metal porous body includes the steps of: performing electrical conduction treatment on a surface of a skeleton of a sheet-like resin porous body having the skeleton with a three-dimensional network structure, to obtain a conductive resin porous body having a conductive layer; performing electroplating treatment on a surface of a skeleton of the conductive resin porous body to obtain a plated resin porous body having a metal plating layer; and performing treatment of removing at least the resin porous body from the plated resin porous body to obtain a metal porous body. In the electroplating treatment, power was supplied to a rotation shaft of a rotating electrode roller by bringing a power supply brush formed by a material containing carbon as a main component into sliding contact with the rotation shaft.

An apparatus is disclosed for applying a coating to a desired object including a rotatable container having at least one container wall. An electrolyte can be retained within the container, the at least one container wall made of a material that does not allow the electrolyte to pass through the at least one container wall of the container. An anode can be positioned within the container. The apparatus can include a mount for securing the desired object such that a surface of the desired object is exposed to the electrolyte. A controller can be in electrical communication with the anode and the mount, wherein when power is supplied from the controller to the anode and the mount, particles in the electrolyte are deposited on the desired object forming a composite coating.

An applicator for no-bath plasma gel electrolytic oxidation of a workpiece made of a valve metal or an alloy thereof; the applicator movable over a surface of a workpiece to be treated. The applicator including an electrode connectable to a power supply and configured for applying electric voltage to a gap between the electrode and a workpiece. A gel electrolytic medium body is mounted in a holder being in an electric contact with the electrode.

An applicator for no-bath plasma gel electrolytic oxidation of a workpiece made of a valve metal or an alloy thereof; the applicator movable over a surface of a workpiece to be treated. The applicator including an electrode connectable to a power supply and configured for applying electric voltage to a gap between the electrode and a workpiece. A gel electrolytic medium body is mounted in a holder being in an electric contact with the electrode.

Systems and methods for tin antimony plating are provided. One plating method includes doping a tin (Sn) plating solution with antimony (Sb). One method also includes electroplating a component using the antimony-doped tin plating. The antimony-doped tin plating formed by one method includes between about 1% and about 3% antimony.

Systems and methods for tin antimony plating are provided. One plating method includes doping a tin (Sn) plating solution with antimony (Sb). One method also includes electroplating a component using the antimony-doped tin plating. The antimony-doped tin plating formed by one method includes between about 1% and about 3% antimony.

The present invention relates to a plating apparatus and a plating method for partially forming a plating film on an object to be plated. The plating apparatus includes: a rotary electrode configured to be rotatable; a plating solution holding unit arranged to the rotary electrode and configured to hold a plating solution; and a power supply unit configured to apply a voltage between the portion to be plated and the rotary electrode.

The present embodiment relates to an internal combustion engine having an anodic oxide coating formed on at least a portion of an aluminum-based wall surface facing a combustion chamber. The anodic oxide coating has a plurality of nanopores extending substantially in the thickness direction of the anodic oxide coating, a first micropore extending from the surface toward the inside of the anodic oxide coating, and a second micropore present in the inside of the anodic oxide coating; the surface opening diameter of the nanopores is 0 nm or larger and smaller than 30 nm; the inside diameter of the nanopores is larger than the surface opening diameter; the film thickness of the anodic oxide coating is 15 m or larger and 130 m or smaller; and the porosity of the anodic oxide coating is 23% or more.