A nozzle device includes a nozzle body and at least one second electrode. The nozzle body extends along a longitudinal axis, and has a top surface, a bottom surface for confronting a first electrode of a workpiece, a recess provided in the bottom surface, and a longitudinal channel extending downwardly from the top surface along the longitudinal axis to be in fluid communication with the recess. The longitudinal channel has an upper section and a lower tapered section which is tapered downwardly to form a lower communication port. The least one second electrode is disposed in the recess for being spaced apart from the first electrode.

An electroplating apparatus is provided that minimizes unplated regions when an alloy plating layer is provided on the surface of a thread on a steel pipe. An electroplating apparatus (10) includes an electrode (1), sealing members (2, 3), and a plating-solution supply unit (4). The electrode (1) faces the thread (Tm). The sealing member (2) is positioned within the steel pipe (P1). The sealing member (3) is attached to the end portion of the steel pipe (P1) and, together with the sealing member (2), forms a receiving space (8). The plating-solution supply unit (4) includes a plurality of nozzles (42). The nozzles (42) are positioned within the receiving space (8) and adjacent one end of the thread (Tm) and arranged around the pipe axis of the steel pipe (P1). The plating-solution supply unit (4) injects a plating solution between the thread (Tm) and electrode (1) through the nozzles (42). The direction in which plating solution is injected from the nozzles (42) is inclined at an angle larger than 20 degrees and smaller than 90 degrees toward the thread (Tm) relative to a plane perpendicular to the pipe axis.

An electrode device is provided with a closed part facing a bottom part of a bottomed hole when inserted inside the bottomed hole, and a flow through hole linking the inside and outside of the electrode device is formed in the electrode device. When surface treatment is implemented on the inner wall surface of the bottomed hole, the hollow electrode device is inserted into the inside of the bottomed hole, the electrolytic treatment solution is made to flow through the space inside the bottomed hole, and power is applied across the electrode device and the inner wall surface of the bottomed hole. The closed part faces the bottom part of the bottomed hole as an electrode across a prescribed surface area; therefore, electroplating at the bottom part of the bottomed hole proceeds to the same extent as other sites.

An electroplating apparatus is provided that minimizes unplated regions when an alloy plating layer is provided on the surface of a thread on a steel pipe. An electroplating apparatus (10) includes an electrode (1), sealing members (2, 3), and a plating-solution supply unit (4). The electrode (1) faces the thread (Tm). The sealing member (2) is positioned within the steel pipe (P1). The sealing member (3) is attached to the end portion of the steel pipe (P1) and, together with the sealing member (2), forms a receiving space (8). The plating-solution supply unit (4) includes a plurality of nozzles (42). The nozzles (42) are positioned within the receiving space (8) and adjacent one end of the thread (Tm) and arranged around the pipe axis of the steel pipe (P1). The plating-solution supply unit (4) injects a plating solution between the thread (Tm) and electrode (1) through the nozzles (42). The direction in which plating solution is injected from the nozzles (42) is inclined at an angle larger than 20 degrees and smaller than 90 degrees toward the thread (Tm) relative to a plane perpendicular to the pipe axis.

The present disclosure addresses methods to refine the geometry of micro features manufactured in various substrates. Such refinement includes improvement in edge roughness and roughness of aperture channel walls. The methods include deposition of material onto feature edges and surfaces as well as placement of micro fabricated inserts into coarse features. Foremost among the candidate technologies that can be employed for these purposes are two photon polymerization-based 3D nano printing and atomic force microscope nanopipette-based electroplating.

A method that can plate a predetermined position on various plating targets without implementing a pretreatment thereon is provided. A plating method is performed on a plating target using a plating solution, and the plating method includes at least a bubble ejection step of ejecting a bubble generated by a bubble ejection member to a plating solution. The bubble ejection member includes an electrode formed of a conductive material and an insulating material covering at least a part of the electrode, at least a part of the insulating material forms a bubble ejection port, and an air gap surrounded by the insulating material is formed between at least a part of the electrode and the bubble ejection port.

Provided is an apparatus for electro-forming. The apparatus for electro-forming includes a plating bath which is a space where a substrate is plated and a clamp disposed within the plating bath and configured to grasp the substrate disposed in a horizontal direction. The apparatus for electro-forming further includes an assembly including an anode spaced above the substrate and connected to an external power supply and a plating solution supply unit spaced above the substrate and configured to supply a plating solution. The apparatus for electro-forming also includes a driving unit configured to reciprocate the assembly in a horizontal direction at a distance from the substrate. The assembly further includes an insulator between the anode and the plating solution supply unit.

Aspects of the disclosure generally relate to an electroforming apparatus and method, including a support frame with at least one anode housing having a predetermined housing geometry. At least one anode can be carried by the at least one anode housing, and the at least one anode can also include a predetermined geometry.

Device for vertical galvanic metal deposition on a substrate comprising a first and a second device, arranged vertically parallel to each other; the first device comprising a first anode having a plurality of through-going conduits and a first carrier having a plurality of through-going conduits; wherein said first anode and said first carrier are connected to each other; wherein the second device comprises a first substrate holder adapted to receive a first substrate to be treated, wherein said first substrate holder at least partially surrounds the first substrate along its outer frame, wherein the first device further comprises a plurality of plugs, each plug comprising a through-going channel, each plug arranged such that it runs from the backside of the first carrier through a through-going conduit of the first carrier and further through the conduit of the first anode element, and the plugs are detachably connected to the first device.

A method for subjecting garment accessories to a surface electrolytic treatment provides various metallic colors to metallic garment accessories in a cost effective manner. The method can provide a first metallic color on one side of outer surface of the garment accessory and provide a second metallic color on the other side of the outer surface, by placing one or more metallic garment accessories in an electrolytic solution in a non-contact state with an anode and a cathode for passing electric current through the electrolytic solution, passing electric current through the electrolytic solution and generating a bipolar phenomenon on the garment accessory.