Electrochemical sodium metal halide battery, and method for producing same

1 . An electrochemical sodium metal halide battery, comprising: a housing with a central axis, a separator extending about the central axis of the housing equidistantly from the housing, which separator, as a solid primary electrolyte, electrically insulates and hermetically separates an anode chamber from a cathode chamber, but is permeable to sodium ions, a cathode filling the cathode chamber and consisting of a porous mixture of metal powder and metal halide powder granules, as well as a secondary electrolyte of molten sodium metal halide salt impregnating the cathode chamber and the porous mixture of the cathode, and a cathode-side metallic current collector elongated about the central axis in the cathode chamber, wherein: the current collector is a metal tube having a high electrical conductivity of σ>10 6 S/m, which is immersed in the porous mixture of granules of the cathode located in the separator and in the secondary electrolyte and is designed as a pressed tube section which is narrowed on the inside in such a way that no granules of the cathode but only secondary electrolyte can penetrate, and is provided on the outside with elements for increasing a surface area of the current collector, and the current collector has, above the immersed, pressed tube section, an unpressed tube section as a filler tube for filling the cathode chamber, wherein at least one through-hole opening the filler tube to the outside is provided at a transition from the pressed tube section to the unpressed tube section of the filler tube, such that the filler tube is configured to be used for filling the porous mixture of granules of the cathode into the cathode chamber only outside the pressed tube section and for filling the entire cathode chamber with secondary electrolyte. 2 . The electrochemical battery according to claim 1 , wherein the current collector has a carbon felt in the pressed tube section that was inserted into the pressed tube section before pressing. 3 . The electrochemical battery according to claim 1 , wherein the current collector has a carbon felt in the pressed tube section that is laterally insertable into the pressed tube section after pressing and removal of a crimped edge of the pressed tube section. 4 . The electrochemical battery according to claim 1 , wherein the current collector has punched holes in the pressed tube section in the form of further through-holes. 5 . The electrochemical battery according to claim 4 , wherein the current collector has metal tufts of metal strips or wires in the pressed tube section, which are fastened in the through-holes and made of a metal not attacked by the electrochemical processes of the battery and having a conductivity comparable to that of the metal tube of the current collector. 6 . The electrochemical battery according to claim 1 , wherein a commercially available nickel, aluminum or copper tube is used as the current collector. 7 . The electrochemical battery according to claim 1 , wherein, in the current collector, the elements for surface enlargement are formed with at least one element from the group of punched through-holes or other relief-forming structures with crimped edges, metal tufts, fins or folded metal sheets. 8 . The electrochemical battery according to claim 5 , wherein the metal tufts of metal strips or wires are made of nickel or molybdenum. 9 . The electrochemical battery according to claim 5 , wherein the metal tufts of metal strips or wires are oriented so that local resistance gradients in the cathode chamber are minimized or uniformly distributed across the cross-section of the cathode chamber. 10 . The electrochemical battery according to claim 5 , wherein the metal strips or wires used in the metal tufts have a length which is selected to be smaller the higher the capacities of the battery to be achieved are and to be larger, up to the separator at maximum, the higher the powers to be extracted from the battery are. 11 . The electrochemical battery according to claim 1 , wherein, after the porous mixture of the cathode and the secondary electrolyte have been filled, the unpressed tube section of the filler tube of the current collector is sealed with a cohesively bonded circular sheet metal blank or a deep-drawn part. 12 . The electrochemical battery according to claim 1 , wherein, after the porous mixture of the cathode and the secondary electrolyte have been filled, the unpressed tube section of the filler tube of the current collector is crimped or hermetically sealed with a soldered or welded seam at the upper tube end of the filler tube. 13 . The electrochemical battery according to claim 1 , wherein the pressed tube section of the current collector is pressed flat from two collinear directions. 14 . The electrochemical battery according to claim 1 , wherein the pressed tube section of the current collector is pressed from at least three directions equally offset about the central axis to form a star-shaped cross-section. 15 . The electrochemical battery according to claim 13 , wherein the pressed tube section of the current collector is pressed by force effects in such a way that an interior space forming as a secondary electrolyte reservoir is just as large as a volume of the secondary electrolyte which is necessary for complete wetting of the current collector in the fully charged state of the battery. 16 . The electrochemical battery according to claim 1 , characterised in that a metal tube ( 11 ) is added below the pressed tube section ( 12 ) of the current collector ( 1 ), which metal tube ( 11 ) is fitted with radial fins ( 18 ) inserted into tangentially equidistant slots of the metal tube ( 11 ). 17 . The electrochemical battery according to claim 1 , wherein a metal tube with radial fins is added below the pressed tube section of the current collector, which metal tube is produced from an equidistantly folded metal sheet and its axially symmetrical bending. 18 . A method for manufacturing an electrochemical sodium metal halide battery comprising the steps of: providing a housing for forming an anode chamber, a separator insertable equidistantly from the housing as an electrically insulating solid primary electrolyte permeable only to sodium ions for separating the anode chamber from a cathode chamber, a cathode comprising a porous mixture of metal powder and metal halide granules, and a secondary electrolyte for impregnating the porous mixture of the cathode, producing a cathode-side current collector from a metal tube which is formed, by forces acting radially on a central axis, into a compressed tube section of the current collector and in which an unpressed tube section remains at the upper end as a filler tube, at least one through-hole being made at least at a transition from the pressed tube section to the filler tube, which through-hole is provided as an outlet opening of the filler tube for filling the cathode chamber, producing a battery closure from a cathode closure part having a central opening for passage of the filler tube of the current collector in the central opening of the cathode closure part, and cohesively connecting the cathode closure part to an insulator joining ring as well as cohesively joining an anode closure part to the insulator joining ring, positioning the current collector collinearly with the central axis in the separator as well as the housing arranged equidistantly around the separator by means of the battery closure consisting of the insulator joining ring and the anode closure part by a one-step joining pro