Electrochemical energy store comprising a conductivity section for overcharge protection

1 .- 15 . (canceled) 16 . An electrochemical energy store comprising: an anode, which is electrically connected to an anode space in which an anode material with a first fill level (EF) is arranged, and a cathode, which is electrically connected to a cathode space in which a cathode material with a second fill level (ZF) is arranged, wherein at least one of the two materials of anode material and cathode material, changes its fill level (EF, ZF) during the charging or discharging of the electrochemical energy store, and an ion-conducting separator, which separates the anode space from the cathode space, wherein, in the normal operation of the electrochemical energy store, the ion-conducting separator is provided with a top region and a base region, a conductivity section in the top region of the ion-conducting separator, which, in the normal operation of the electrochemical energy store, has a higher electronic conductivity than an electronically-insulating insulation section in the base region, wherein at least one state of charge of the electrochemical energy store exists in which the anode material in the anode space is bonded with the conductivity section, and a current bridge for the constitution of a leakage current is generated between the anode material and the cathode material. 17 . The electrochemical energy store as claimed in claim 16 , wherein the ion-conducting separator comprises an exactly-defined conductivity section and an insulation section, which adjoin each other. 18 . The electrochemical energy store as claimed in claim 16 , wherein the conductivity section is arranged such that, during the normal operation of the energy store, the conductivity section adjoins the insulation section at a uniform fill level (FZW). 19 . The electrochemical energy store as claimed in claim 18 , wherein the uniform fill level (FZW) corresponds to a state of charge of the electrochemical store not exceeding 100% of the maximum charge. 20 . The electrochemical energy store as claimed in claim 16 , wherein the conductivity section and the insulation section are comprised of an identical base material, wherein the conductivity section is doped with at least one element which delivers a higher electronic conductivity than the base material. 21 . The electrochemical energy store as claimed in claim 16 , wherein the conductivity section and the insulation section are comprised of an identical base material, wherein the conductivity section is provided with an electronically conductive, percolated secondary phase. 22 . The electrochemical energy store as claimed in claim 16 , wherein the ion-conducting separator is configured as a solid body electrolyte, which is ion-conducting. 23 . The electrochemical energy store as claimed in claim 16 , wherein the electrochemical energy store is configured based upon sodium-nickel chloride cell technology, or upon sodium-sulfur cell technology. 24 . The electrochemical energy store as claimed in claim 16 , wherein the service temperature of the electrochemical energy store during discharging is no lower than 100° C. 25 . An electrochemical storage module, comprising: at least two electrochemical energy stores as claimed in claim 16 , wherein the at least two electrochemical energy stores are electrically interconnected in series. 26 . The electrochemical storage module as claimed in claim 25 , wherein the electrochemical storage module comprises an electronic charge management system, which incorporates no circuitry, and is designed for the equalization of an unequal state of charge in at least two electrochemical energy stores. 27 . A method for producing an electrochemical energy store as claimed in claim 16 , the method comprising: producing an ion-conducting separator by the formation of a molded base component; impregnating the base component with additives which are appropriate to the formation of an electronically conductive conductivity section, further to heat treatment; and heat treating the base component, for the stabilization thereof. 28 . The method as claimed in claim 27 , further comprising: infiltrating by one of the following: pressure infiltration with a suspension or a solution; immersion infiltration with a suspension or a solution; sol-gel separation; chemical gas phase separation; physical gas phase separation; and electrophoretic separation. 29 . The method as claimed in claim 27 , wherein the heat treatment of the base component proceeds under an oxidizing atmosphere. 30 . The method as claimed in claim 27 , wherein the heat treatment of the base component proceeds under a reducing atmosphere. 31 . The electrochemical energy store as claimed in claim 18 , wherein the uniform fill level (FZW) corresponds to a state of charge of the electrochemical store not exceeding a specifically preferred 95% of the maximum charge. 32 . The electrochemical energy store as claimed in claim 20 , wherein the identical base material comprises a ceramic. 33 . The electrochemical energy store as claimed in claim 21 , wherein the identical base material comprises a ceramic. 34 . The electrochemical energy store as claimed in claim 16 , wherein the service temperature of the electrochemical energy store during discharging is no lower than 200° C. 35 . The method as claimed in claim 27 , wherein the heat treatment of the base component proceeds under an oxygen-bearing atmosphere. 36 . The method as claimed in claim 27 , wherein the heat treatment of the base component proceeds by the carbonization of a base component to which a polymer resin has been applied, under a reducing atmosphere.