The present invention relates to a method for forming a multidimensional structure, comprising: providing an electrode and a substrate in a fluid, wherein the fluid comprises an electrolyte and a precursor agent dispersed therein; applying an electric potential difference between the substrate and the electrode to reduce or oxidise the precursor agent, thereby depositing a solid material; measuring current between the substrate and the electrode; and moving the electrode within the fluid to form a multidimensional structure of the solid material. Also provided is a device for forming a multidimensional structure.

The present invention relates to a method for forming a multidimensional structure, comprising: providing an electrode and a substrate in a fluid, wherein the fluid comprises an electrolyte and a precursor agent dispersed therein; applying an electric potential difference between the substrate and the electrode to reduce or oxidise the precursor agent, thereby depositing a solid material; measuring current between the substrate and the electrode; and moving the electrode within the fluid to form a multidimensional structure of the solid material. Also provided is a device for forming a multidimensional structure.

An anode plate for a film plating machine and a film plating machine are provided. The anode plate is formed by splicing a plurality of anode plate splicing units, and two adjacent anode plate splicing units are separated by an insulating medium. Each anode plate splicing unit is connected with a power supply. The anode plate is applicable to film plating machines of different breadth.

An anode plate for a film plating machine and a film plating machine are provided. The anode plate is formed by splicing a plurality of anode plate splicing units, and two adjacent anode plate splicing units are separated by an insulating medium. Each anode plate splicing unit is connected with a power supply. The anode plate is applicable to film plating machines of different breadth.

An e-coat line includes a frame supporting a process track configured to extend along a process direction, a workpiece rack moveably supported on the frame, and a plurality of electrodes supported on an electrode rack. The rack includes support members configured to hold a plurality of hollow workpieces in a predetermined arrangement, and the workpiece rack is moveable relative to the frame between a raised position and a lowered position. The plurality of electrodes are supported on the electrode rack in a predetermined arrangement complementary to the predetermined arrangement of the plurality of hollow workpieces on the support members. The electrode rack is moveable relative to the workpiece rack in a direction crossing the process direction between a first position, in which the plurality of electrodes are extended along and overlapping with the support members to fit within the plurality of hollow workpieces, and a second position, in which the plurality of electrodes are retracted away from the support members to be removed from the plurality of hollow workpieces.

An e-coat line includes a frame supporting a process track configured to extend along a process direction, a workpiece rack moveably supported on the frame, and a plurality of electrodes supported on an electrode rack. The rack includes support members configured to hold a plurality of hollow workpieces in a predetermined arrangement, and the workpiece rack is moveable relative to the frame between a raised position and a lowered position. The plurality of electrodes are supported on the electrode rack in a predetermined arrangement complementary to the predetermined arrangement of the plurality of hollow workpieces on the support members. The electrode rack is moveable relative to the workpiece rack in a direction crossing the process direction between a first position, in which the plurality of electrodes are extended along and overlapping with the support members to fit within the plurality of hollow workpieces, and a second position, in which the plurality of electrodes are retracted away from the support members to be removed from the plurality of hollow workpieces.

Electroplating apparatus includes an electroplating tank that stores an electrolyte solution in which at least objects to be electroplated and magnetic media sink, and at least one magnetic rotator rotatably arranged under the electroplating tank so as to generate an alternating magnetic field. The magnetic rotator is arranged to section an internal space of the electroplating tank into a first space occupying a space above the magnetic rotator and a second space occupying a remaining space other than the first space. The magnetic rotator is arranged to be movable in a lateral direction intersecting a rotational axis of the magnetic rotator, allowing the objects to be shifted between a condition of being present in the electrolyte solution and in the first space and a condition of being present in the electrolyte solution and in the second space.

A bulk finishing system including a plurality of liquid immersion workstations defining a finishing process for a plurality of metal work pieces processed therethrough. Each of the plurality of liquid immersion workstations includes a tank, and the plurality of metal work pieces are conveyed through a group of one or more of the respective tanks of the plurality of liquid immersion workstations by non-contact magnetic conveyance provided by an inclined downstream tank end wall forming a work piece exit slide, with a magnetic conveyor extending along an exterior side of the inclined downstream tank end wall. The plurality of work pieces are introduced loosely in bulk to each one of the group of tanks of the plurality of liquid immersion workstations.

A bulk finishing system including a plurality of liquid immersion workstations defining a finishing process for a plurality of metal work pieces processed therethrough. Each of the plurality of liquid immersion workstations includes a tank, and the plurality of metal work pieces are conveyed through a group of one or more of the respective tanks of the plurality of liquid immersion workstations by non-contact magnetic conveyance provided by an inclined downstream tank end wall forming a work piece exit slide, with a magnetic conveyor extending along an exterior side of the inclined downstream tank end wall. The plurality of work pieces are introduced loosely in bulk to each one of the group of tanks of the plurality of liquid immersion workstations.

A plant for immersion treatment of vehicle bodies may include at least one skid configured to support a body; at least one process liquid tank; a line configured to convey the at least one skid above the at least one tank; and/or a device configured to overturn and immerse, inside the at least one tank, the body on the at least one skid positioned over the at least one tank using the conveyor line. The at least one skid may include a base part and a support part. The support part may be supported rotatably on the base part using a rotatable shaft with axis arranged transverse to a direction of movement of the at least one skid on the conveyor line, so that the support part is rotatable between a first upper position and a second position for immersing the body in the at least one tank.