An electrolytic treatment apparatus 1 (1A) configured to perform an electrolytic treatment on a target substrate includes a substrate holder 10 and an electrolytic processor 20. The substrate holder 10 includes an insulating holding body 11 configured to hold the target substrate and an indirect negative electrode 12 disposed within the holding body 11. A negative voltage is applied to the indirect negative electrode 12. The electrolytic processor 20 is disposed to face the substrate holder 10 and configured to apply a voltage to the target substrate and an electrolyte in contact with the target substrate.

It is configured that a frame body is locked to a back panel by: inserting a number of first pins of the frame body into a number of first holes of the back panel; moving a fastening body outward by a moving mechanism of a lock mechanism; and fitting a notch into a concave portion at the tip of the first pin.

It is configured that a frame body is locked to a back panel by: inserting a number of first pins of the frame body into a number of first holes of the back panel; moving a fastening body outward by a moving mechanism of a lock mechanism; and fitting a notch into a concave portion at the tip of the first pin.

The present invention provides a composite processing method and device for a texture on an inner surface of a bearing shell of a radial sliding bearing. A surface of a workpiece to be processed is processed by laser to obtain a micron-level texture, an obtained workpiece with the micron-level texture on a surface is placed on a compression device, and the workpiece with the micron-level texture on the surface is subjected to an electro-deposition reaction to obtain a workpiece with a nano-level texture on a surface. The processing device includes an inner spin-printing electrode electrochemical deposition system, a laser irradiation system and a motion control system. The inner spin-printing electrode electrochemical deposition system includes the inner spin-printing electrode, a direct current power supply, the bearing shell and a compression roller.

A plating apparatus allows a substrate holder to be serviced easily while ensuring easy access to the substrate holder and while a substrate is being processed in the plating apparatus. The plating apparatus includes a plating section for plating a substrate, a substrate holder for holding the substrate, a substrate holder transporter for holding and transporting the substrate holder, a stocker for storing the substrate holder, and a stocker setting section for storing the stocker therein. The stocker includes a moving mechanism for moving the stocker into and out of the stocker setting section.

A plating apparatus allows a substrate holder to be serviced easily while ensuring easy access to the substrate holder and while a substrate is being processed in the plating apparatus. The plating apparatus includes a plating section for plating a substrate, a substrate holder for holding the substrate, a substrate holder transporter for holding and transporting the substrate holder, a stocker for storing the substrate holder, and a stocker setting section for storing the stocker therein. The stocker includes a moving mechanism for moving the stocker into and out of the stocker setting section.

Provided is a technique configured to cause a first actual operation to be started in a short time when the actual operation of a substrate processing component group is performed a plurality of times. A substrate processing system 10 includes a substrate processing apparatus 11 having a substrate processing component group 20 and a controller 40. The substrate processing component group 20 is configured to perform a test operation and an actual operation. The substrate processing component group 20 has a first substrate processing component and a second substrate processing component. When the actual operation is performed a plurality of times, the controller 40 causes the first substrate processing component to perform the test operation and causes the actual operation of the first substrate processing component to be started after completion of the test operation of the first substrate processing component.

Provided is a technique configured to cause a first actual operation to be started in a short time when the actual operation of a substrate processing component group is performed a plurality of times. A substrate processing system 10 includes a substrate processing apparatus 11 having a substrate processing component group 20 and a controller 40. The substrate processing component group 20 is configured to perform a test operation and an actual operation. The substrate processing component group 20 has a first substrate processing component and a second substrate processing component. When the actual operation is performed a plurality of times, the controller 40 causes the first substrate processing component to perform the test operation and causes the actual operation of the first substrate processing component to be started after completion of the test operation of the first substrate processing component.

A substrate holder for vertical galvanic metal deposition on a substrate, comprising a first substrate holder part and a second substrate holder part, wherein both said parts comprise an inner metal comprising part and an outer non-metallic part in which the substrate holder further comprises a hanging element in each substrate holder part, a first sealing element in each substrate holder part, a second sealing element between the inner metal comprising part and the outer non-metallic part of the substrate holder, a fastening system for detachably fastening both substrate holder parts to each other, a first contact element in each substrate holder part for forwarding current from an outer source through the hanging element to the at least second contact element, and a second contact element in each substrate holder part for forwarding current from the at least first contact element to the substrate to be treated.

A substrate holder for vertical galvanic metal deposition on a substrate, comprising a first substrate holder part and a second substrate holder part, wherein both said parts comprise an inner metal comprising part and an outer non-metallic part in which the substrate holder further comprises a hanging element in each substrate holder part, a first sealing element in each substrate holder part, a second sealing element between the inner metal comprising part and the outer non-metallic part of the substrate holder, a fastening system for detachably fastening both substrate holder parts to each other, a first contact element in each substrate holder part for forwarding current from an outer source through the hanging element to the at least second contact element, and a second contact element in each substrate holder part for forwarding current from the at least first contact element to the substrate to be treated.