Abstract: A battery pouch cell film composite having at least one metal layer, at least two adhesion promotion layers, and at least two polymer layers, at least one of the polymer layers being configured in self-healing fashion and that layer having in the interior physically delimited regions that contain at least one compound capable of polymerization.

Abstract: A sensor system for detecting a leak of a system component from an electrochemical storage system, in particular a lithium-ion battery. To determine a defect in the electrochemical storage system, the sensor system includes a reaction chamber containing a detection component, and a measuring device for determining a physical variable within the reaction chamber. The value of the physical variable is changeable by a chemical reaction of the system component with the detection component, so that a leak of the system component is detectable via a change in the value of the physical variable. Also described is a sensor element for such a sensor system, an electrochemical storage system having such a sensor system or sensor element, the use of such a sensor system or sensor element, and a mobile or stationary system, for example an electric vehicle, equipped with the sensor system, the sensor element, or the storage system.

Abstract: A method for triggering at least one safety function in the event of a safety-critical state of an electrochemical energy store includes: detecting the safety-critical state of the electrochemical energy store using a sensor signal which represents at least one detected state variable of the electrochemical energy store; generating a safety function signal based on the detected safety-critical state of the electrochemical energy store; and triggering the at least one safety function based on the safety function signal.

Abstract: A sensor device for contacting first and second contact points of an electrochemical energy store which are situated inside a housing of the electrochemical energy store includes: a first terminal contact for the electrically conductive connection of the sensor device to the first contact point, a first terminal material on a surface of the first terminal contact corresponding to at least a first contact material on a surface of the first contact point; and a second terminal contact for the electrically conductive connection of the sensor device to the second contact point, a second terminal material on a surface of the second terminal contact corresponding to at least a second contact material on a surface of the second contact point.

Abstract: An additive is described for an electrolyte of a lithium-based secondary battery cell, including at least one additive unit, which includes a closed capsule, which is filled at least partially with at least one additive dissolved in a fluid or with at least one liquid additive, characterized in that the capsule is designed in coordination with the additive, in such a way that the additive may reach the environment around the capsule by diffusion out of the capsule.

Abstract: The invention relates to a method for localizing a defect in an electrochemical store (165). The method includes a step of controlling the temperature of a subarea (145, 150, 155, 160, 170) of the electrochemical store (165) to increase an internal pressure of the subarea (145, 150, 155, 160, 170), a step of detecting a measured value which represents an escape of a component from the subarea (145, 150, 155, 160, 170) occurring in response to the increased internal pressure of the subarea (145, 150, 155, 160, 170), and a step of localizing the defect in the subarea (145, 150, 155, 160, 170) when the measured value is in a predetermined relation to a comparison value.

Abstract: A battery, particularly a lithium-metal battery or a lithium-ion battery, having at least one galvanic cell surrounded by a cell housing. To increase the safety of the battery and to close up again a cell opened by a safety device or by a leakage, the inner chamber of the cell housing of the at least one cell includes a first chemical component, a chamber bordering on at least one section of the outer side of the housing including a second chemical component; a solid reaction product being developable by the chemical reaction of the first and second chemical components. The first component is containable in the electrolyte of the cell and the second component in a cooling and/or tempering arrangement. Also described is a cooling and/or tempering arrangement based on it, and an electrolyte, an electrolytic liquid, a safety system, a method and a mobile or stationary system.

Abstract: A lithium-sulfur cell includes a lithium-containing anode, a sulfur-containing cathode and a separator arranged between the lithium-containing anode and the sulfur-containing cathode. To suppress a shuttle mechanism and to prevent a loss of active material, the separator includes a base layer and a polysulfide barrier layer. The polysulfide barrier layer is formed on the cathode side of the separator.

Abstract: An energy store system, including at least one cell element situated in a cell region having an anode, a cathode and an electrolyte system that is situated between the anode and the cathode and that is particularly at least partially liquid, the anode, the cathode and/or the electrolyte system being configured so that, as a function of a charging or discharging process of the cell element, functioning material is situated in the electrolyte system, and the functional material situated in the electrolyte system being ascertainable qualitatively and/or quantitatively. Because of such an energy store system, operating states of an energy store or a cell may be ascertained particularly simply and accurately. Also described is a related state detection system.

Abstract: An energy store, in particular to a lithium-based energy store. In order to make a simple and exact determination of a state of health, e.g., the aging condition, possible, the energy store includes at least one cell having an anode, a cathode, and an electrolyte which is situated between the anode and the cathode, at least one cell having an outlet for conveying functional material from the cell to an analysis unit and the outlet being connectable to the analysis unit in a fluid-tight manner. Also described is a system including the energy store and an analysis unit, and a method for ascertaining a state of health of an energy store.

Abstract: A separator for an energy store. The separator may be used in a lithium-sulfur battery in particular. To achieve improved cycle stability, the separator has at least one first layer and at least one second layer, the at least one first layer containing a material having an affine property with respect to at least one active electrode material, and the at least one second layer containing a material having a repellent property with respect to at least one active electrode material. The at least one first layer and the at least one second layer may be situated directly adjacent to one another. Also described is an energy store including the separator.

Abstract: A secondary cell, in particular a lithium-sulfur cell, that encompasses a cathode having an electrochemically active cathode active material, an anode having an electrochemically active anode active material, and a liquid electrolyte, the cathode active material and/or anode active material changing, in the context of the charging or discharging operation, from a solid phase form into a liquid phase form that is soluble in the electrolyte. To increase the charging/discharging rate and cycle stability and to decrease overvoltages, the secondary cell encompasses at least one redox additive that is soluble in reduced form and oxidized form in the electrolyte and that is suitable for reacting with the phase-changing electrode active material in a redox reaction in such a way that the electrode active material is convertible from the solid phase form into the liquid phase form.

Abstract: In a method for preparing a cathode material for an alkali-sulfur cell, e.g., a lithium-sulfur cell, at least one polyacrilonitrile-sulfur composite material and elemental sulfur are mixed, in order to increase the voltage, the capacitance and the energy density.

Abstract: The invention relates to a method for preparing a polyacrylonitrile-sulfur composite material, in which, polyacrylonitrile is converted to cyclized polyacrylonitrile, and the cyclized polyacrylonitrile is reacted with sulfur to form a polyacrylonitrile-sulfur composite material. By a separation of the preparation method into two partial reactions, the reaction conditions are advantageously able to be optimized for the respective reactions and a cathode material is able to be provided for alkali-sulfur cells with improved electrochemical properties. In addition, the invention relates to a polyacrylonitrile-sulfur composite material, a cathode material, an alkali-sulfur cell or an alkali-sulfur battery as well as to an energy store.

Abstract: An electrochemical energy store, e.g., a lithium-ion battery, includes a cell chamber, in which at least one anode, at least one cathode, and an electrolyte, which is situated between the anode and the cathode, are situated, the cell chamber being separated from the external surroundings by a housing, and at least one detection substance for the detection of a leak of the housing being situated in the cell chamber. The energy store configuration allows a leak of the energy store to be detected in a simple way.

Abstract: An electrode for an energy store, in particular for a lithium-ion battery. To achieve a particularly good and long-term stable capacitance, the electrode includes an active material, optionally a binder, optionally a conductive additive, and a sorption agent; intermediate stages of the active material arising during a charging and/or discharging procedure of the energy store may be immobilized by the sorption agent. Furthermore, also described is a method for manufacturing an electrode for an energy store, and the use of a sorption agent for manufacturing an electrode for an electrochemical energy store.

Abstract: A cathode composition for an alkali-sulfur cell, e.g., a lithium-sulfur cell, includes, in addition to elementary sulfur, at least one material having covalently and/or conically bound sulfur, for example, a sulfur composite material, a sulfurous polymer, a metal sulfide, or a nonmetal sulfide.

Abstract: In a method for producing an anode for a lithium cell, and/or a lithium cell as well as anodes and lithium cells of this type, to extend the service life of the lithium cell and to selectively form a first protective layer including electrolytic decomposition products, on an anode including metallic lithium, a first electrolyte is applied on the anode ex situ, i.e., prior to assembling the lithium cell to be produced. To stabilize the first protective layer, a second protective layer is applied in a subsequent method step.

Abstract: An electrochemical battery system in one embodiment includes a first electrochemical cell, a memory in which command instructions are stored, and a processor configured to execute the command instructions during a discharge cycle of the first electrochemical cell to (i) establish a first discharge voltage of the first electrochemical cell based upon a first sensed discharge voltage, and (ii) permit a second discharge voltage of the first electrochemical cell after establishing the first discharge voltage, wherein the second discharge voltage is greater than the first discharge voltage.

Abstract: In accordance with one embodiment, an electrochemical cell includes a negative electrode including a form of lithium, a positive electrode spaced apart from the negative electrode and including an electron conducting matrix, a separator positioned between the negative electrode and the positive electrode, an electrolyte including a salt, and a charging redox couple located within the positive electrode, wherein the electrochemical cell is characterized by the transfer of electrons from a discharge product located in the positive electrode to the electron conducting matrix by the charging redox couple during a charge cycle.