Lithium battery fabrication process using multiple atmospheric plasma nozzles

1 . A method of forming an electrode for a lithium battery cell, the method comprising: forming a first gas-carried stream of atmospheric plasma-activated particles of an electrode material for the lithium battery cell; forming a second gas-carried stream of atmospheric plasma-activated metal particles in which at least some of the metal particles are partially melted in the plasma-activated second gas stream, the partially-melted metal particles being characterized by the presence of some part solid-part liquid metal particles and/or liquid metal droplets; simultaneously co-directing the first stream and the second stream of atmospheric plasma-activated particles toward a surface of a lithium battery cell member, the cell member being in ambient air with its surface positioned to be impacted by the co-directed first and second streams of plasma activated particles, the co-directed streams of particles forming a deposited coating on the surface, the deposited coating initially comprising particles of electrode material in porous overlying layers and with intermixed partially-melted metal particles, the partially-melted metal particles cooling and re-solidifying in the deposited coating such that the particles of electrode material and re-solidified particles of metal are bonded to each other and the deposited coating of layered particulate electrode material is bonded to the surface of the cell member substrate as an electrode for a lithium battery cell. 2 . A method of forming an electrode for a lithium battery cell as recited in claim 1 in which the coating of particles of electrode material is deposited on a flat surface of a non-electrode cell member. 3 . A method of forming an electrode for a lithium battery cell on a cell member surface as recited in claim 1 in which the first and second streams of atmospheric plasma activated particles are co-directed and maintained in fixed paths in which the streams are brought together and mixed at a focal area, and a surface of the cell member is moved through the focal area to enable the co-directed streams to apply a deposited coating over a selected surface area of the cell member. 4 . A method of forming an electrode for a lithium battery cell on a cell member surface as recited in claim 1 in which co-directed first and second streams of atmospheric plasma activated particles are brought together and mixed at a focal area, and the streams and focal area are moved together to apply a deposited coating of electrode material particles over a selected surface area of the cell member. 5 . A method of forming an electrode for a lithium battery cell as recited in claim 1 in which the deposited coating is cooled to promote re-solidification of the partially-melted metal particles. 6 . A method of forming an electrode for a lithium battery cell as recited in claim 1 in which the cell member is a sheet of porous separator material for the lithium battery cell or is a metal current collector for an electrode for the lithium battery cell. 7 . A method of forming an electrode for a lithium battery cell as recited in claim 1 in which the particles of electrode material used in forming the first gas-carried particle stream have an average dimension in the range of about one micrometer to fifty micrometers and the metal particles used in forming the second gas-carried particle stream have a smaller average dimension. 8 . A method of forming an electrode for a lithium battery cell as recited in claim 1 in which the thickness of the applied layered particulate electrode material is up to about two hundred micrometers and is at least three times the average dimension of the particles of electrode material. 9 . A method of forming an electrode for a lithium battery cell as recited in claim 1 in which the particles of electrode material are selected for an anode of the lithium battery cell and the metal particles are selected to be electrochemically compatible with the anode particles in the lithium battery cell. 10 . A method of forming an electrode for a lithium battery cell as recited in claim 1 in which the particles of electrode material are selected for a cathode of the lithium battery cell and the metal particles are selected to be electrochemically compatible with the cathode particles in the lithium battery cell. 11 . A method of forming an electrode for a lithium battery cell as recited in claim 1 in which a first combination of first and second gas-carried particle streams of atmospheric plasma-activated particles is used to form a lithium battery cell anode layer comprising an anode material electrode layer on an anode current collector foil and a second combination of first and second gas carried-particle streams of atmospheric plasma-activated particles is used to form a lithium battery cell cathode layer comprising an cathode material electrode layer on a cathode current collector foil; and the lithium battery anode layer is placed on one face of a sheet of porous separator material for a lithium battery cell with the anode material electrode layer in contact with the separator face, and the lithium battery cathode layer is placed on the opposite face of the sheet of the porous separator material with the cathode material electrode layer in contact with the separator face. 12 . A method of forming an electrode for a lithium battery cell as recited in claim 1 in which a first combination of first and second gas-carried particle streams of atmospheric plasma-activated particles is used to form a lithium battery cell anode material layer on one face of a sheet of porous separator material for a lithium battery cell and a second combination of first and second gas-carried particle streams of atmospheric plasma-activated particles is used to form a lithium battery cell cathode material layer on the opposite face of a sheet of porous separator material for a lithium battery cell; and, subsequently, a gas-carried stream of atmospheric plasma-activated metal particles is deposited as an anode current collector layer on the anode material layer on the separator face and another gas-carried stream of atmospheric plasma-activated metal particles is deposited as a cathode current collector layer on the cathode material on the opposite face of the separator layer. 13 . A method of forming an electrode for a lithium battery cell as recited in claim 11 in which two or more adjacently positioned combinations of first and second combinations of gas-carried particle streams of atmospheric plasma-activated particles are used to concurrently form lithium battery cell anode layers on adjacently moving anode current collector foils; two or more adjacently positioned combinations of first and second combinations of gas-carried particle streams of atmospheric plasma-activated particles are used to concurrently form lithium battery cell cathode layers on adjacently moving cathode current collector foils; and pairs of the two or more thus formed anode and cathode members are concurrently placed on opposite sides of porous separators. 14 . A method of forming an electrode for a lithium battery cell as recited in claim 12 in which lithium battery cathode material layers, cathode current collector layers, lithium cell battery anode material layers, and anode current collector layers are concurrently applied to the faces of two or more sheets of porous separator materials using two or more combinations of atmospheric plasma generation devices. 15 . A method of forming electrodes for lithium battery cells comprising: using a gas-carried stream of atmospheric plasma-activated lithium cell an