Abstract: A simplified cell design is provided for a battery utilizing the 18650 form-factor in which the CID and PTC elements are eliminated, thereby reducing manufacturing cost and battery weight. To reduce the risk of shorting between the battery case and the battery terminal, the battery terminal is recessed relative to the top of the cell case and the insulating gasket positioned between the cell case and the cap assembly is designed to cover a large portion of the outer surface of the terminal element.

Abstract: A method and apparatus for limiting the adverse effects of temperature on the electrical energy storage system (ESS) of an electric vehicle after the vehicle has been turned off are provided. In general, whether or not coolant is circulated through a coolant loop coupled to the ESS depends on the difference between the ambient temperature and a preset temperature, the preset temperature typically corresponding to the temperature of the ESS.

Abstract: A simplified cell design is provided for a battery utilizing the 18650 form-factor, the simplified cell design reducing manufacturing cost, battery weight and the risk of shorting between the battery case and the battery terminal. In the cap assembly of the disclosed battery, the safety vent element, which is recessed relative to the top of the cell case, also serves as the battery terminal. Additionally, the insulating gasket positioned between the cell case and the cap assembly is designed to cover a large portion of the outer surface of the safety vent/battery terminal.

Abstract: Methods and systems for decreasing costs (expense, mass, and/or cure time) associated with use of adhesives when assembling modularized components, particularly for assemblies having many elements such as for example battery modules used in electric vehicles. The methods and systems enable use of high-wettability adhesives (defined generally in this application as low viscosity and/or low surface tension adhesives) for assembling such modularized components.

Abstract: A method and apparatus is provided for determining when a battery, or one or more batteries within a battery pack, undergoes an undesired thermal event such as thermal runaway. The system uses a conductive member mounted in close proximity to, or in contact with, an external surface of the battery or batteries to be monitored. A resistance measuring system such as a continuity-tester or an ohmmeter is coupled to the conductive member, the resistance measuring system outputting a first signal when the temperature corresponding to the battery or batteries is within a prescribed temperature range and a second signal when the temperature exceeds a predetermined temperature that falls outside of the prescribed temperature range.

Abstract: A cooling manifold assembly for use in a battery pack thermal management system is provided. The cooling manifold assembly includes a coolant tube that is interposed between at least a first row of cells and a second row of cells, where the first and second rows of cells are adjacent and preferably offset from one another. A thermal interface layer is attached to the cooling tube, the thermal interface layer including a plurality of pliable fingers that extend away from the cooling tube and are interposed between the cooling tube and the first row of cells, and interposed between the cooling tube and the second row of cells, where the pliable fingers are deflected by, and in thermal contact with, the cells of the first and second rows of cells.

Abstract: A cooling manifold assembly for use in a battery pack thermal management system is provided. The cooling manifold assembly includes a coolant tube that is interposed between at least a first row of cells and a second row of cells, where the first and second rows of cells are adjacent and preferably offset from one another. A thermal interface layer is overmolded onto the cooling tube, the thermal interface layer including a plurality of pliable fingers that extend away from the cooling tube and are interposed between the cooling tube and the first row of cells, and interposed between the cooling tube and the second row of cells, where the pliable fingers are deflected by, and in thermal contact with, the cells of the first and second rows of cells.

Abstract: A thermal management system is provided that minimizes the effects of thermal runaway within a battery pack. The system is comprised of a multi-sided, substantially airtight battery pack enclosure configured to hold a plurality of batteries, where at least one side of the battery pack enclosure includes at least one cavity. An inner wall of the enclosure includes a plurality of perforations configured to pass gas from within the enclosure to the cavity within the at least one side member. The system is further comprised of at least one gas exhaust port integrated into an outer wall of the enclosure and configured to pass gas from within the cavity of the enclosure side member to the ambient environment when one or more batteries contained within the battery pack undergo thermal runaway.

Abstract: A battery mounting structure, preferably for use within a battery pack housing, is provided that prevents condensation-induced corrosion from occurring between the terminals of a battery.

Abstract: A battery is provided that includes a cell case, an electrode assembly and a center pin within the electrode assembly, where the electrode assembly is wrapped around the center pin, and where the center pin is comprised of a material that is rigid within the normal operating temperature range of the battery and deforms, and/or melts, when the battery temperature exceeds the normal operating temperature range of the battery.

Abstract: A power source comprised of a metal-air battery pack and a non-metal-air battery pack is provided, wherein thermal energy from the metal-air battery pack is used to heat the non-metal-air battery pack. In one aspect, a thermal energy transfer system is provided that controls the flow of thermal energy from the metal-air battery pack to the non-metal-air battery pack. In another aspect, the flow of thermal energy from the metal-air battery pack to the non-metal-air battery pack is controlled and used to heat the non-metal-air battery pack prior to charging the non-metal-air battery pack.

Abstract: A method and apparatus for simplifying battery pack assembly that allows inspection of the cell-to-housing bonding region is provided. In particular, a battery pack housing member is provided that includes an interior surface that partially defines the interior region of the battery pack and that includes a plurality of cell mounting wells and an exterior surface that includes a plurality of bonding wells. Adhesive introduced into the bonding wells forms a mechanical bond between an exterior surface of a cell introduced into an adjacent cell mounting well and the housing member.

Abstract: A battery assembly is provided that includes a layer of intumescent material that coats the sidewall and bottom surface of the cell casing, excluding at least one case contact region.

Abstract: A method and apparatus is provided in which a pre-formed sleeve or pre-formed secondary can comprised of one or more layers of a high yield strength material is positioned around the pre-formed battery case, the pre-formed sleeve/secondary can inhibiting the flow of hot, pressurized gas from within the battery through perforations formed in the battery casing during a thermal runaway event.

Abstract: A system for integrating the venting feature of a battery with a means for simultaneously disconnecting the cell from the battery pack, thereby isolating the cell, is provided. The provided battery interconnect system is comprised of a battery, a connector plate for electrically coupling the battery to a battery pack, and an interruptible electrical connector for electrically coupling the connector plate to a battery terminal vent. The vent, defined by scoring on the battery terminal, ruptures when the internal battery pressure exceeds the predefined battery operating range, causing the interruptible electrical connector to break and disrupt electrical continuity between the connector plate and the battery terminal.

Abstract: A method and apparatus is provided for determining when a battery, or one or more batteries within a battery pack, undergoes an undesired thermal event such as thermal runaway. The system uses a conductive member mounted in close proximity to, or in contact with, an external surface of the battery or batteries to be monitored. A resistance measuring system such as a continuity-tester or an ohmmeter is coupled to the conductive member, the resistance measuring system outputting a first signal when the temperature corresponding to the battery or batteries is within a prescribed temperature range and a second signal when the temperature exceeds a predetermined temperature that falls outside of the prescribed temperature range.

Abstract: A battery pack thermal management system is provided that is comprised of at least one enclosure failure port integrated into at least one wall of a battery pack enclosure, where the enclosure failure port(s) remains closed during normal operation of the battery pack, and opens during a battery pack thermal runaway event, thereby providing a flow path for hot gas generated during the thermal runaway event to be exhausted out of the battery pack enclosure in a controlled fashion.

Abstract: A means for inhibiting the propagation of thermal runaway within a plurality of batteries is provided, wherein the means is comprised of a layer of intumescent material covering the interior surfaces of the battery pack.

Abstract: A method and apparatus for actively cooling the battery pack of an electric vehicle after the vehicle has been turned off, thereby limiting the adverse effects of temperature on battery life, are provided. Different battery pack cooling techniques are provided, thus allowing the cooling technique used in a particular instance to be selected not only based on the thermal needs of the battery pack, but also on the thermal capacity and energy requirements of the selected approach.

Abstract: A method and apparatus for limiting the adverse effects of temperature on the electrical energy storage system (ESS) of an electric vehicle after the vehicle has been turned off are provided. In general, whether or not coolant is circulated through a coolant loop coupled to the ESS depends on the difference between the ambient temperature and a preset temperature, the preset temperature typically corresponding to the temperature of the ESS.