A portable electroplating system with components integrated into a complete system, rather than separated and disjointed. A single electroplating system can be self-contained to include all necessary rectifiers, tanks, cleaning functionalities, and other helpful or necessary items. By using smaller components than conventional electroplating systems, the system can allow for more economical use of chemicals, solutions, and energy and can be utilized more efficiently towards a unique shape or size of object to be plated. The system can also include wheels to make the system portable. A rack management system can be employed to move objects from one location to another within the system.

A portable electroplating system with components integrated into a complete system, rather than separated and disjointed. A single electroplating system can be self-contained to include all necessary rectifiers, tanks, cleaning functionalities, and other helpful or necessary items. By using smaller components than conventional electroplating systems, the system can allow for more economical use of chemicals, solutions, and energy and can be utilized more efficiently towards a unique shape or size of object to be plated. The system can also include wheels to make the system portable. A rack management system can be employed to move objects from one location to another within the system.

A portable electroplating system with components integrated into a complete system, rather than separated and disjointed. A single electroplating system can be self-contained to include all necessary rectifiers, tanks, cleaning functionalities, and other helpful or necessary items. By using smaller components than conventional electroplating systems, the system can allow for more economical use of chemicals, solutions, and energy and can be utilized more efficiently towards a unique shape or size of object to be plated. The system can also include wheels to make the system portable. A rack management system can be employed to move objects from one location to another within the system.

A processing liquid supplying apparatus supplies a processing liquid to a processing unit which processes a substrate. The processing liquid supplying apparatus includes a supply pipe to which a processing liquid inside a processing liquid tank that stores the processing liquid is fed and which supplies the processing liquid, which is fed from the processing liquid tank, to the processing unit, a return pipe which is branched and connected to the supply pipe to return a processing liquid inside the supply pipe to the processing liquid tank, a first heating unit which heats a processing liquid inside an upstream-side portion to be heated that is set in the supply pipe upstream from a branched position to which the return pipe is connected, a second heating unit which heats a processing liquid inside a downstream-side portion to be heated that is set in the supply pipe downstream from the branched position, a cooling unit which cools a processing liquid inside a portion to be cooled that is set in the return pipe, and a first filter which is interposed in the supply pipe upstream from the upstream-side portion to be heated and removes particles in a processing liquid.

A processing liquid supplying apparatus supplies a processing liquid to a processing unit which processes a substrate. The processing liquid supplying apparatus includes a supply pipe to which a processing liquid inside a processing liquid tank that stores the processing liquid is fed and which supplies the processing liquid, which is fed from the processing liquid tank, to the processing unit, a return pipe which is branched and connected to the supply pipe to return a processing liquid inside the supply pipe to the processing liquid tank, a first heating unit which heats a processing liquid inside an upstream-side portion to be heated that is set in the supply pipe upstream from a branched position to which the return pipe is connected, a second heating unit which heats a processing liquid inside a downstream-side portion to be heated that is set in the supply pipe downstream from the branched position, a cooling unit which cools a processing liquid inside a portion to be cooled that is set in the return pipe, and a first filter which is interposed in the supply pipe upstream from the upstream-side portion to be heated and removes particles in a processing liquid.

A plating apparatus includes a plating tank and a plating unit that performs electrolytic plating on an object. The plating unit includes a workpiece passage region including a partition wall that allows passage of the plating solution but does not allow passage of the object, the workpiece passage region passing the object from above toward below, an injection unit that injects the plating solution from below toward above, a mixing unit that mixes the plating solution injected by the injection unit and the object to be plated passing through the workpiece passage region, an anode outside the workpiece passage region, a cathode inside the workpiece passage region including a hollow region through which a mixed fluid of the plating solution and the object to be plated passes from below toward above, and a guidance unit that guides the mixed fluid to the workpiece passage region.

A plating apparatus includes a plating tank and a plating unit that performs electrolytic plating on an object. The plating unit includes a workpiece passage region including a partition wall that allows passage of the plating solution but does not allow passage of the object, the workpiece passage region passing the object from above toward below, an injection unit that injects the plating solution from below toward above, a mixing unit that mixes the plating solution injected by the injection unit and the object to be plated passing through the workpiece passage region, an anode outside the workpiece passage region, a cathode inside the workpiece passage region including a hollow region through which a mixed fluid of the plating solution and the object to be plated passes from below toward above, and a guidance unit that guides the mixed fluid to the workpiece passage region.

An electroplating method for producing magnetic conducting materials, such as charging coils used in induction charging of electronic devices, comprising the following steps: constant tension releasing conducting material, such as cooper wire, the conducting material then undergo these process: alkaline washing then clean water washing, degreasing, acidic washing then clean water washing, continuous plating, clean water washing, drying, infrared measuring the diameter and retracting the conducting material. The method allows electroplating preparation of uniform and dense distribution of iron and nickel coating layer on the surface of conducting material, wherein, the thickness of the coating layer is 210 m. Since the conducting material is non-magnetic, but through the electroplating preparation, the entire charging coil is magnetized to become magnetic material, which when used during induction charging provides the coil with electro resistance that reducing high-frequency skin effect and improving electro induction.

Electroless plating is accomplished by forming a metal salt and a polymer solution as a binder into a solid electrolyte block and depositing metal on the surface by rubbing or brushing the solid electrolyte block onto a surface with minimal or no water and without an electric potential/power source. The solid electrolyte block is also conformable/moldable and can be used to deposit metal on to both conductive and nonconductive surface through electroless deposition process.

A deformation verification system of a vehicle body includes a dip tank in which fluid is contained. The dip tank has a transparent window from the outside to see the inside. A moving device is configured to lower the vehicle body into the fluid, to move the vehicle body in the fluid and to raise the vehicle body. A camera is installed to detect the form of the vehicle body through the transparent window.