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 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 method and apparatus is provided in which a 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 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: The bus bar includes a first bus bar layer formed of a first generally uniform thickness of a first bus bar conductor; a first dielectric layer overlying a top surface of the first bus bar layer; and a second bus bar layer formed of a second generally uniform thickness of a second bus bar conductor overlying a top surface of the first dielectric layer and the top surface of the first bus bar layer wherein: the first bus bar layer includes a first via for receipt of a first electrical lead of an electrical component and a second via for receipt of a second electrical lead of the electrical component and wherein: the first dielectric layer and the second bus bar layer each include a via aligned with the first via wherein the first electrical lead is extendable from beneath the first bus bar layer through the first dielectric layer and through the second bus bar layer.

Abstract: A method for charging an energy storage system (ESS) from an AC line voltage having differing input voltages (e.g., 120Vac or 240Vac), the method includes a) determining which of the AC line voltages is provided for charging the ESS as a charging AC voltage; b) boosting the charging AC voltage to an intermediate voltage responsive to the provided AC line voltage; c) scaling, responsive to the particular one of the AC line voltages, the intermediate voltage to a secondary voltage using a scaling factor; and d) converting the secondary voltage to a charging voltage applied to the ESS.

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 venting region, 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 contamination cleaner for a socket of a charging connector used with a charging station for an electric vehicle wherein the charging connector mates to a charging coupler of the electric vehicle during charging includes a housing mechanically configured generally similarly to the charging coupler enabling the housing to mechanically mate to the charging connector; and a cleaning contact, coupled to the housing and complementary to the socket, for engaging the socket and removing surface contaminants from the socket whenever the housing mechanically mates to the charging connector.

Abstract: A thermal management system is provided that minimizes the effects of thermal runaway within a battery pack, the system using an integrated battery venting assembly comprised of an integrated exhaust port, a valve retention plate that covers the exhaust port and includes a plurality of retention plate ports, and a plurality of valves that are configured to seal the retention plate ports under normal conditions and unseal the retention plate ports during thermal runaway. As hot gas passes through the retention plate ports, the plate is configured to melt and be ejected, thereby allowing subsequent hot gas to pass through the larger exhaust port. A perforated cover plate may be used to protect the external surfaces of the retention plate and valves. An internally mounted exhaust guide may be used to direct the flow of hot gas expelled during the thermal runaway event.

Abstract: A thermal management system is provided that minimizes the effects of thermal runaway within a battery pack. The system is comprised of a sealed battery pack enclosure configured to hold a plurality of batteries, where the battery pack enclosure is divided into a plurality of sealed battery pack compartments. The system also includes a plurality of battery venting assemblies, where at least one battery venting assembly is integrated into each of the sealed battery pack compartments, and where each of the battery venting assemblies includes an exhaust port integrated into an outer wall of the battery pack compartment and a valve, the valve being configured to seal the exhaust port under normal operating conditions and to unseal the exhaust port when at least one of the batteries within the battery pack compartment enters into thermal runaway.

Abstract: The apparatus for charging an energy storage system (ESS) from an AC line voltage includes a boost stage for converting the AC line voltage to a first ESS charging voltage; an isolation stage, coupled to the boost stage, for converting the first ESS charging voltage to a second ESS charging voltage with the second ESS charging voltage less than the first ESS charging voltage, the isolation stage removing a common mode current between the ESS and the boost stage; a configurator, responsive to a control signal, to set a direct communication of the first ESS charging voltage to the ESS in a bypass mode and to open the direct communication of the first ESS charging voltage to the ESS in an isolation mode; and a controller, coupled to the configurator, for setting the modes responsive to a battery voltage, a peak of the AC line voltage, and a total leakage current at an input of the AC line voltage, the controller asserting the control signal to the configurator.

Abstract: A vehicle thermal management system is provided that includes two or more heat exchangers configured in a non-stacked arrangement, where separate air inlets corresponding to each of the heat exchangers allow a direct intake of ambient air. Active louver systems consisting of sets of adjustable louvers and a control actuator are used to control and regulate air flowing directly into one or more of the heat exchangers, where the adjustable louvers are either adjustable between two positions, i.e., opened and closed, or adjustable over a range of positions. Air ducts may be used to couple the output from one heat exchanger to the input of a different heat exchanger.

Abstract: An apparatus includes an inverter including a high-side switch coupled to a low-side switch, the inverter generating a time-varying drive current from a plurality of drive control signals, a positive rail voltage, and a negative rail voltage wherein controlling the switches to generate the time-varying drive current produces a potential transitory overshoot condition for one of the switches of the inverter; a drive control, coupled to the inverter, to generate the drive control signals and to set a level of each of the rail voltages responsive to a plurality of controller signals; and a controller monitoring one or more parameters indicative of the potential transitory voltage overshoot condition, the controller dynamically adjusting, responsive to the monitored parameters, the controller signals to reduce a risk of occurrence of the potential transitory voltage overshoot condition.

Abstract: An apparatus includes an inverter including a high-side switch coupled to a low-side switch, the inverter generating a time-varying drive current from a plurality of drive control signals, a positive rail voltage, and a negative rail voltage wherein controlling the switches to generate the time-varying drive current produces a potential transitory overshoot condition for one of the switches of the inverter; a drive control, coupled to the inverter, to generate the drive control signals and to set a level of each of the rail voltages responsive to a plurality of controller signals; and a controller monitoring one or more parameters indicative of the potential transitory voltage overshoot condition, the controller dynamically adjusting, responsive to the monitored parameters, the controller signals to reduce a risk of occurrence of the potential transitory voltage overshoot condition.

Abstract: An apparatus includes an inverter including a high-side switch coupled to a low-side switch, the inverter generating a time-varying drive current from a plurality of drive control signals, a positive rail voltage, and a negative rail voltage wherein controlling the switches to generate the time-varying drive current produces a potential transitory overshoot condition for one of the switches of the inverter; a drive control, coupled to the inverter, to generate the drive control signals and to set a level of each of the rail voltages responsive to a plurality of controller signals; and a controller monitoring one or more parameters indicative of the potential transitory voltage overshoot condition, the controller dynamically adjusting, responsive to the monitored parameters, the controller signals to reduce a risk of occurrence of the potential transitory voltage overshoot condition.

Abstract: An apparatus includes an inverter including a high-side switch coupled to a low-side switch, the inverter generating a time-varying drive current from a plurality of drive control signals, a positive rail voltage, and a negative rail voltage wherein controlling the switches to generate the time-varying drive current produces a potential transitory overshoot condition for one of the switches of the inverter; a drive control, coupled to the inverter, to generate the drive control signals and to set a level of each of the rail voltages responsive to a plurality of controller signals; and a controller monitoring one or more parameters indicative of the potential transitory voltage overshoot condition, the controller dynamically adjusting, responsive to the monitored parameters, the controller signals to reduce a risk of occurrence of the potential transitory voltage overshoot condition.

Abstract: A dual mode, thermal management system for use in a vehicle is provided. At a minimum, the system includes a first coolant loop in thermal communication with a battery system, a second coolant loop in thermal communication with at least one drive train component (e.g., electric motor, power electronics, inverter), a dual mode valve system that provides means for selecting between a first mode where the two coolant loops operate in parallel and a second mode where the two coolant loops operate in series, and a coolant reservoir that is coupled to both coolant loops when the two coolant loops are operating in series and only coupled to the drive train coolant loop when the two coolant loops are operating in parallel.

Abstract: An apparatus for simplifying battery pack encapsulation is provided. The battery pack includes a pair of complementary housing members with each housing member including a plurality of cell constraints into which the ends of corresponding battery cells are inserted during assembly. One or both housing members also include at least one, and preferably a plurality, of raised encapsulant injection ports. The raised encapsulant injection ports are designed to extend above the surface of the respective housing members and beyond the injected encapsulation material, thus ensuring that the ports remain open after encapsulation material injection.

Abstract: A coolant de-aeration system is provided that includes a coolant reservoir, a plurality of de-aeration chambers within the reservoir, a plurality of de-aeration chamber apertures that direct coolant flow through the de-aeration chambers, a reservoir inlet and a reservoir outlet that share a common coolant flow pathway that allows the majority of coolant to flow directly between the reservoir inlet and the reservoir outlet, and a reservoir inlet aperture that directs a portion of coolant passing along the common coolant flow pathway through the reservoir's de-aeration chambers for de-aeration prior to being returned to the common coolant flow pathway.

Abstract: A front structure for a vehicle is provided, the structure including (i) a pair of front rails spaced apart in a widthwise direction with each rail extending lengthwise, and where each rail is comprised of a polygonal-shaped upper hollow channel and a polygonal-shaped lower hollow channel with the upper and lower channels sharing a common wall; and (ii) a pair of curvilinear torque boxes, where one curvilinear torque box is mechanically attached to the upper and lower polygonal-shaped channels of each front rail, where each curvilinear torque box is mechanically coupled to a rocker panel, where the upper polygonal-shaped channel of each front rail is in a horizontal plane located above the top surface of the corresponding rocker panel, and where the lower polygonal-shaped channel of each front rail is in a horizontal plane that is aligned with the corresponding rocker panel.

Abstract: A front structure for a vehicle is provided that includes a pair of front rails (i.e., front left hand rail and front right hand rail) spaced apart in a widthwise direction with each rail extending lengthwise and mechanically coupled to the vehicle's bumper and a torque box. Each front rail is comprised of a polygonal-shaped upper hollow channel and a polygonal-shaped lower hollow channel, where the upper and lower channels share a common wall.

Abstract: A front structure for a vehicle is provided, the structure including (i) a pair of front rails (i.e., front left hand rail and front right hand rail) spaced apart in a widthwise direction with each rail extending lengthwise, where one end portion of each rail is mechanically coupled to the vehicle's bumper and the other end portion of each rail is mechanically coupled to a torque box, and where each rail is comprised of a polygonal-shaped upper hollow channel and a polygonal-shaped lower hollow channel, and where the upper and lower channels share a common wall; and (ii) a pair of rail reinforcement members, where one rail reinforcement member is mechanically mounted within each front rail, and where a plurality of features corresponding to each reinforcement member determines how the rails react to front impact loads.

Abstract: A system for absorbing and distributing front impact forces in a vehicle is provided, the system including a primary impact system and a secondary impact system, each of which includes a bumper and a structure for transferring impact loads. The primary impact system includes a primary bumper and a pair of front rails spaced apart in a widthwise direction with each rail extending lengthwise, where one end portion of each rail is mechanically coupled to the vehicle's bumper and the other end portion of each rail is mechanically coupled to a torque box. The secondary impact system includes a secondary bumper and an assembly of sub-frame components separate from the front rails that allow impact loads to be transferred in parallel through the front rails and the sub-frame.

Abstract: A front structure for a vehicle is provided, the structure including (i) a pair of front rails (i.e., front left hand rail and front right hand rail) spaced apart in a widthwise direction with each rail extending lengthwise, and where each rail is comprised of a polygonal-shaped upper hollow channel and a polygonal-shaped lower hollow channel with the upper and lower channels sharing a common wall; and (ii) a pair of bumper mounting plates, where one bumper mounting plate is interposed between the end portion of each channel of each rail and the vehicle's bumper, and where each bumper mounting plate aligns the upper rail channels with the vehicle's bumper while transferring impact loads to both the upper and lower rail channels.

Abstract: A front structure for a vehicle is provided, the structure including a single piece shock tower and an upper control arm, where the front coupling of the upper control arm is attached to the shock tower at a location directly above a corresponding surface of the shock tower such that the front coupling is exposed from above, and where the rear coupling of the upper control arm is attached to the shock tower at a location directly below a corresponding surface of the shock tower such that the rear coupling is unexposed from above.

Abstract: A rear structure for a vehicle is provided, the structure including (i) a pair of single piece rear torque boxes; (ii) a pair of rocker panels mechanically coupled to the rear torque boxes; (iii) a pair of rear rails mechanically coupled to the rear torque boxes; and (iv) at least one cross-member interposed between and mechanically coupled to the rear torque boxes.

Abstract: A vehicle thermal management system is provided that includes two or more heat exchangers configured in a non-stacked arrangement, where separate air inlets corresponding to each of the heat exchangers allow a direct intake of ambient air. Corresponding to each heat exchanger is a set of adjustable louvers that control ambient air flowing directly into the heat exchanger. The adjustable louvers may be adjustable between two positions; fully opened or fully closed. Alternately, the adjustable louvers may be adjustable over a range between fully opened and fully closed. Alternately, each set of adjustable louvers may be comprised of multiple groups of independently controllable louvers. Air ducts may be used to couple the output from one heat exchanger to the input of a different heat exchanger.

Abstract: An improved integration system for a battery pack mounted between the passenger cabin floor panel of an electric vehicle and the driving surface is provided, the system utilizing at least one insulating layer interposed between the battery pack enclosure and the passenger cabin floor panel, where the insulating layer provides noise isolation, thermal isolation and vibration damping, and where the insulating layer is compressed when the battery pack enclosure is mounted to the vehicle.

Abstract: A vehicle seat mounting assembly is provided in which the seat mounts are attached to body cross-members that are, in turn, mechanically coupled to battery pack cross-members contained within a battery pack enclosure mounted under the vehicle.

Abstract: An energy absorbing and distributing side impact system for use with a vehicle is provided, the system utilizing a battery pack enclosure that includes a plurality of cross-members that transverse the battery pack enclosure and absorb and distribute at least a portion of the load received when either the first or second side of the vehicle receives a side impact. The battery pack enclosure is positioned between the front and rear vehicle suspension assemblies and mounted between, and mechanically coupled to, vehicle structural members (e.g., rocker panels) located on either side of the vehicle. In addition to providing rigidity, strength and impact resistance, the battery pack cross-members segregate the batteries contained within the battery pack enclosure into battery groups.

Abstract: An improved protection system for a battery pack mounted between the passenger cabin floor panel of an electric vehicle and the driving surface is provided, the system utilizing a ballistic shield mounted under the electric vehicle and interposed between the battery pack enclosure and the driving surface, where the ballistic shield is spaced apart from the enclosure bottom panel. A layer of a compressible material may be interposed between the ballistic shield and the battery pack enclosure.

Abstract: An integrated drive system assembly is provided that combines an electric motor, a power inverter assembly and a gearbox into a single, multi-piece enclosure. Combining these components into a single enclosure reduces weight, reduces drive system complexity, reduces system volume, simplifies assembly integration into an electric vehicle, reduces manufacturing cost, allows the flexible and lengthy electrical cables between the power inverter and the electric motor to be replaced with short, low loss, rigid bus bars, and simplifies component cooling by allowing the use of a common thermal management system. The common thermal management system includes a liquid coolant loop that is thermally coupled to the electric motor, the power inverter assembly and the gearbox.

Abstract: A method for withdrawing heat from a battery pack is provided, wherein the heat is transferred from at least one electrode of each cell comprising the battery pack, via an electrically and thermally conductive tab, through a current collector plate and through a thermal interface layer to a temperature control panel that is coupled to an external temperature control system.

Abstract: A seal for use with a vehicle door is provided, the seal preferably used as a secondary or tertiary seal to provide additional passenger cabin sound isolation and weather proofing. The seal is attached to a seam within the door jamb, the seal formed by coupling a central body panel flange to a rear quarter panel flange.

Abstract: A vehicle rocker panel is provided that is extruded as a single piece. As extruded, the rocker panel may include one or more interior reinforcing walls as well as interior and exterior design features.

Abstract: A reinforced B-pillar assembly that achieves improved side impact resistance is provided in which the B-pillar assembly is mechanically coupled to an outer mounting surface of the rocker panel as well as to an extended brace that is attached to the upper and rear mounting surfaces of the rocker.

Abstract: An apparatus and method providing for coolant agent ingress of a high energy density battery enclosure during an internal thermal event. A solution includes a specialized battery enclosure and, in some embodiments, an associated vehicle structure providing a normally closed, pressure activated fill port. Preferably the fill port is positioned so an operator of the fill port is clear from any hot gases exiting from the enclosure.

Abstract: A perforation tool for a battery enclosure system of a vehicle battery pack, comprising: an engaging tip configured to mechanically breach a thermal-control-agent-retaining enclosure of a traction battery pack including a plurality of interconnected batteries with the enclosure reinforced for mechanical protection of the batteries when installed in an electric vehicle; a port for receiving a thermal-control agent having a pressure in a range of about 5-100 psi; and a housing, coupled to the tip and to the port, wherein the tip includes an aperture and wherein the housing includes a channel communicating the port to the aperture wherein the pressurized thermal-control agent is produced at the tip at about the pressure.

Abstract: An overcharge protection device (OPD) is provided that may be used alone, or in combination with conventional charging protection systems, to protect a battery pack from the occurrence of a potentially damaging overcharging event. The OPD is designed to be coupled to, and interposed between, the terminals of the battery pack. During normal system operation, the OPD has no effect on the operation of the charging system or the battery pack. During an overcharging event, if overcharging is not prevented by another conventional system, the OPD of the invention creates a short across the terminals of the battery pack causing a battery pack fuse designed to provide battery pack short circuit protection to blow, thereby interrupting the current path from the charger to the battery pack and preventing the battery pack from being overcharged.

Abstract: An apparatus and method for improving use efficiencies of lead-acid batteries, and more particularly to 12V external lead-acid batteries used in vehicles of all types, load-leveling installations, and backup power applications. A method includes the steps of: a) determining a state of charge (SOC) for a lead-acid battery; b) comparing the SOC against a predetermined charge zone, the charge zone having an upper bound no more than about 90% maximum charge and more preferably no more than about 85% maximum charge and the charge zone having a lower bound no less than about 70% maximum charge and more preferably no less than about 75% maximum charge; and c) maintaining a charge of the lead-acid battery wherein the SOC is within the charge zone.

Abstract: A charging system and method that improves utilization of available AC power during onboard charging of energy storage systems of electric vehicles. An onboard charging method for an energy storage system of an electric vehicle, the method using an AC power source, includes a) establishing a maximum DC charging current for the energy storage system responsive to a control signal indicating real-time available current/power from the AC source; and b) controlling a charging system to provide an actual DC charging current, up to the maximum DC charging current, to the energy storage system.

Abstract: An MRIS gradient coil assembly 2A comprising a first coil layer comprising a first conductive coil portion 3X and a second coil layer comprising a second conductive coil portion 3Y. A first screening layer 6X is disposed between the first 3X and second 3Y coil layers and comprises at least one sheet of screening material. At least one insulating layer 4X comprising insulating material is provided between the first 3X conductive coil portion and the first screening layer 6X. Further the assembly comprises at least one discrete contact means 7 electrically connecting the first conductive coil portion 3X to the sheet of screening material 6X whilst the sheet of screening material 6X is kept from electrically contacting with the first conductive coil portion 3X, except via the at least one discrete contact means, by the at least one layer of insulating material 4X. The screening material might typically comprise a semi-conductive sheet.

Abstract: An MRIS gradient coil sub-assembly comprising a first coil layer comprising a first conducting coil portion, a second coil layer comprising a second conductive coil portion electrically connected with the first conductive coil portion so that the first and second conductive coil portions act together as one winding, and a B-stage material consolidation layer sandwiched between the first and second coil layers.

Abstract: A method 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 is 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 flexible management system and method for efficiently operating energy storage devices to extend the lifetime and decrease costs includes (a) determining an active energy consumption period for the energy storage device; (b) determining an inactive energy consumption period for the energy storage device; (c) operating the energy storage device in a usage mode during the active energy consumption period; and (d) operating the energy storage device in a storage mode during the inactive energy consumption period.

Abstract: A method of optimizing the operation of the power source of an electric vehicle is provided, where the power source is comprised of a first battery pack (e.g., a non-metal-air battery pack) and a second battery pack (e.g., a metal-air battery pack). The power source is optimized to minimize use of the least efficient battery pack (e.g., the second battery pack) while ensuring that the electric vehicle has sufficient power to traverse the expected travel distance before the next battery charging cycle. Further optimization is achieved by setting at least one acceleration limit based on vehicle efficiency and the state-of-charge (SOC) of the first and second battery packs.

Abstract: A system and method for charging a metal-air battery pack at the maximum possible rate while maintaining an ambient oxygen concentration below a preset concentration is provided, thereby minimizing the risks associated with generating oxygen during the charging cycle.

Abstract: A system and method for maintaining an ambient oxygen concentration below a preset concentration while charging a metal-air battery pack is provided, the system utilizing an on-board means for collecting and storing the oxygen-rich effluent generated during the charge cycle.

Abstract: A method of optimizing the operation of the power source of an electric vehicle is provided, where the power source is comprised of a first battery pack (e.g., a non-metal-air battery pack) and a second battery pack (e.g., a metal-air battery pack). The power source is optimized to minimize use of the least efficient battery pack (e.g., the second battery pack) while ensuring that the electric vehicle has sufficient power to traverse the expected travel distance before the next battery charging cycle. Further optimization is achieved by setting at least one maximum speed limit based on vehicle efficiency and the state-of-charge (SOC) of the first and second battery packs.

Abstract: The system includes a module fixture supporting a plurality of elements, the module fixture defining a plurality of bonding wells with each bonding well accepting a first portion of one or more of the elements with the module fixture including one or more apertures communicated with one or more of the bonding wells with the bonding wells having a nominal depth; and a dispensing system, coupled to the module fixture, for dispensing a high-wettability adhesive into each the bonding well and surrounding each the element substantially filling the bonding well up to the nominal depth without significant overfill, the adhesive being selectively curable upon application of a curing modality; and a curing structure for selectively exposing the adhesive to the curing modality as the adhesive emerges from the apertures during dispensation of the adhesive.

Abstract: A system and method for mitigating the effects of a thermal event within a battery pack is provided in which the hot gas and material generated during the thermal runaway of at least one non-metal-air cell of a plurality of non-metal-air cells is directed through one or more metal-air cells, the metal-air cells absorbing at least a portion of the thermal energy generated during the event before it is released to the ambient environment. As a result, the risks to vehicle passengers, bystanders, first responders and property are limited.