The present invention relates to processes that may be used singly or in combination to prevent lithium (or alkali metal) plating or dendrite buildup on bare substrate areas or edges of electrode rolls during alkaliation of a battery or electrochemical cell anode composed of a conductive substrate and coatings, in which the electrode rolls may be coated on one or both sides and may have exposed substrate on edges, or on continuous or discontinuous portions of either or both substrate surfaces.

An electronic component includes an element main body and at least a pair of outer electrodes on the element main body. The outer electrodes each include an underlying electrode layer positioned so as to be in contact with the element main body and a plating layer positioned so as to be in contact with the underlying electrode layer. The plating layer includes a Ni—Sn alloy plating layer positioned so as to be in contact with the underlying electrode layer.

Methods and systems for scalable production of lithium metal through electrodeposition.

A plating processing apparatus in which a plating object is immersed in a plating solution to form a plating layer on a surface of the plating object. A plating tank contains the plating solution, and a power supply roller is rotated while supplying electric power to the plating object, and conveys the plating object to be immersed into the plating solution contained in the plating tank and then moved to the outside of the plating solution. An anode case is disposed inside the plating tank and held in electrical contact with the plating solution contained in the plating tank, and a control panel controls electric power supplied to the power supply roller and the anode case. A first busbar electrically connects the power supply roller and the control panel, and a second busbar electrically connects the anode case and the control panel.

A decoupled plating system is provided for producing lithium. In a general embodiment, the present disclosure provides a feed tank configured to supply a lithium-rich aqueous electrolyte stream, a plating tank that is configured to receive an organic electrolyte and plate out lithium metal from that organic electrolyte, and one or more lithium replenishment cells configured to receive both electrolytes, keep them separated, and selectively move lithium ions from the aqueous electrolyte into the spent organic electrolyte stream. The present system and process can advantageously reduce operating costs and/or improve energy efficiency in production of lithium metal and associated products.

Provided is a film forming apparatus for forming a metal film, capable of uniformly pressurizing a substrate surface with an electrolyte membrane subjected to the fluid pressure of an electrolytic solution containing metal ions during film formation even when an insoluble anode is used. A housing of the apparatus includes a partition member between the anode and the electrolyte membrane, for partitioning a housing chamber into first and second housing chambers. The partition member includes a porous body impregnated with cation exchange resin. The first housing chamber houses the anode insoluble in a first electrolytic solution. The second housing chamber has formed therein a hermetically sealed space in which a second electrolytic solution containing metal ions is enclosed within the housing, by the electrolyte membrane and the partition member. The apparatus is also provided with a pump (pressure unit) that pressurizes the second electrolytic solution in the second housing chamber.

An electroplating device for electroplating an alloy comprising a plurality of metals on a workpiece includes an electroplating bath, a plurality of groups of anodes, and a power supply device. The electroplating bath contains an electroplating solution in which the workpiece as a cathode is at least partially immersed. Each of the plurality of groups of anodes provides at least one metal required for electroplating. An electrolytic potential of at least one metal of each group of anodes is distinct from that of at least one metal of any other group of anodes. The power supply device adjusts the proportion of current transmitted to each group of anodes according to the proportion of the metals in the alloy.

A continuous process for manufacturing electrical current collectors for primary and secondary batteries by electrochemical deposition, comprising i) providing a first roll and a second roll for winding a continuous electrically conductive substrate co-acting as a working electrode, wherein depending on polarity the working electrode can act as an anode or a cathode, wherein the substrate has first and second parallel sides, a first side whereat deposition or partial dissolution occur, and a second side acting as a counter electrode to close a circuit.

An electroplating device includes an electroplating bath containing an electroplating solution into which a workpiece to be electroplated as a cathode is at least partially immersed, a first anode provided in the electroplating bath, and a liquid spraying device. The liquid spraying device includes a main body part having at least one inlet for conveying the electroplating solution into the main body part, and a plurality of nozzles installed on the main body part. At least part of the nozzles are positioned such that a flow direction of the electroplating solution ejected from the nozzle is substantially parallel to a direction of a power line formed by the first anode and the cathode.

An electroplating device for electroplating an alloy comprising a plurality of metals on a workpiece includes an electroplating bath, a plurality of groups of anodes, and a power supply device. The electroplating bath contains an electroplating solution in which the workpiece as a cathode is at least partially immersed. Each of the plurality of groups of anodes provides at least one metal required for electroplating. An electrolytic potential of at least one metal of each group of anodes is distinct from that of at least one metal of any other group of anodes. The power supply device adjusts the proportion of current transmitted to each group of anodes according to the proportion of the metals in the alloy.