Abstract: An exemplary battery cell support structure includes a thermal exchange plate, and a plurality of support fins providing a cavity to receive a battery cell assembly. The plurality of support fins extend directly from the thermal exchange plate. An exemplary method of supporting a battery cell within a battery pack includes positioning a battery cell assembly within a cavity provided by a plurality of support fins extending directly from a thermal exchange plate.

Abstract: A vehicle includes a traction battery, circuitry including a switch and a capacitor, and a monitoring chip configured to draw power from a cell of the traction battery via the circuitry responsive to the switch being closed. The circuitry is configured to open the switch to disconnect the cell from the chip and power the chip via the capacitor for a predetermined period. Powering the chip via the capacitor prevents power down of the chip during the predetermined period. The circuitry opens the switch responsive to engine cranking.

Abstract: A hybrid electric vehicle having battery packs coupled to the vehicle in parallel, which each include series-connected cells, a single contactor, a battery pack controller that detects cell voltages, and at least one controller coupled to a bus contactor and the packs. Responsive to a vehicle key on signal, the at least one controller closes the single battery pack contactor for at least one of the battery packs that includes voltage balanced cells. The bus contactor is then closed to deliver electrical power to the vehicle, and may include a precharge contactor that is closed in advance of and until the bus contactor open circuit voltage is reduced to a contactor voltage difference. The battery pack controllers are further configured to detect voltage, current, and temperature of each cell, to open the single contactor, and to adjust the state of charge of unbalanced cells until balanced relative with the others.

Abstract: A vehicle battery management system is disclosed. The system may include a cell casing and a tripwire. The cell casing may include connected walls that surround a battery active region. At least one of those walls may define a weakened section. A tripwire may be stretched across the weakened and configured to break to interrupt current flow therethrough responsive to a pressure within the cell casing surpassing a predetermined threshold causing the weakened section to bulge towards the tripwire.

Abstract: Electrical bus isolation is detected for an electrified vehicle having a DC power source connected to positive and negative buses. The positive bus is connected to chassis ground, and a resulting first current is sensed that flows through a negative bus leakage resistance and a balanced leakage resistance. The negative bus is connected to chassis ground, and a resulting second current is sensed that flows through a negative bus leakage resistance and a balanced leakage resistance. The positive and negative bus leakage resistances are estimated in response to respective ratios of the first and second currents. An isolation value is compared to a threshold, wherein the isolation value is responsive to a voltage of the DC power source and a smaller one of the positive and negative bus leakage resistances. An atypical isolation is signaled when the isolation value is less than the threshold.

Abstract: A power system for a vehicle includes a traction battery that provides power to drive the vehicle, a load, and a harness having wires electrically connecting the traction battery and load, and shielding covering the wires. The power system further includes one or more control blocks that drive a signal onto the shielding, and responsive to an absence of detecting feedback from the signal, issue an interlock integrity alert.

Abstract: A battery pack according to an exemplary aspect of the present disclosure includes, among other things, a battery monitoring integrated circuit (BMIC) associated with a grouping of battery cells, a calibration microcontroller configured to store battery data associated with the grouping of battery cells, a main microcontroller; and a data transmission node establishing a shared path for communicating both a status signal from the BMIC and the battery data from the calibration microcontroller.

Abstract: A vehicle charging system includes a charger configured to receive power form an external power source and a connector. The connector is configured to receive power from the charger and transmit the received power to a vehicle via a high-voltage cable. The cable is configured to connect the connector to a vehicle battery. Each of the charger and the connector includes a high voltage interlock loop (HVIL) configured to cause the charger to cease power transfer upon recognizing a predetermined voltage difference at a pair of ports of the HVIL.

Abstract: An exemplary method includes providing an alert in response to an analysis of an array that includes at least a first recorded value and a second recorded value, the first recorded value corresponding to an electrical parameter of a battery joint under a first set of operating conditions, the second recorded value corresponding to the electrical parameter of the battery joint under a second set of operating conditions.

Abstract: A vehicle system includes a voltage sensing circuit configured to detect voltages across cells in a fuel cell stack, and powered by a power supply sharing a voltage reference with the cells and having a voltage magnitude greater than a sum of voltage magnitudes of the cells. The system further includes a controller configured to, responsive to a change in polarity in at least one of the voltages indicative of freezing of the cells, issue an alert notification.

Abstract: A system for a vehicle includes a pair of electrical buses connected to terminals of a traction battery via a shared positive contactor and a pair of negative contactors. The system further includes a controller configured to, responsive to a request to close the contactors and a difference between voltage magnitudes of the buses being greater than a predefined threshold, actively discharge one of the buses to reduce the difference.

Abstract: Systems and methods for sensing internal states of vehicle batteries are described. From this internal state information, various physical characteristics of the battery can be measured, calculated or inferred. A vehicle can include an electric motor, a battery to store electrical energy for the electric motor, and a sensor connected to the battery to sense a battery state, to receive an input signal, and to wirelessly transmit an output signal indicating the battery state. The sensor may be passive and built into the structure of the battery. The sensor can be a surface wave acoustic sensor with a magnetic field sensor, which can be a magnetoimpedance sensing device and a temperature sensor.

Abstract: A high-voltage system for a vehicle includes a module having a resonant circuit coupled across powerlines, and a controller. The controller is programmed to, during a power up of the high-voltage system, propagate on the powerlines a first signal at a fundamental frequency for a first period. The controller is further programmed to, in response to a first impedance measured across the powerlines at the fundamental frequency during the period being less than a predetermined value, close main contactors to energize the module.

Abstract: A vehicle system has a first communication device configured to selectively associate with a second communication device of a premise system based on a location of the vehicle with respect to the premise system and a vehicle identification. A charging control system is configured to permit charging of the vehicle in response to the selective association between the first and second communication devices.

Abstract: Systems and methods for measuring voltage of a battery pack for an electrified vehicle, such as an electric or hybrid vehicle, include a battery having internal circuits that measure pack voltage and individual cell voltages, an electric machine powered by the battery to propel the vehicle via an external circuit that measures the pack voltage, and a processor programmed to publish the pack voltage to a vehicle network based on a first internal circuit voltage in response to a voltage differential among the internal circuits being less than a threshold and based on the individual cell voltages otherwise. The published pack voltage may be used by one or more battery or vehicle controllers to control various battery and vehicle functions including engine starting in a hybrid vehicle and battery charging and discharging, for example.

Abstract: A vehicle bus system includes a controller programmed to, after issuing a command to close first and second contactors, wherein the first and second contactors are arranged to share a first terminal of a battery, the first contactor is configured to power a first load when closed, and the second contactor is configured to power a second load when closed, initiate pre-charge of a second terminal of the battery in response to respective first and second voltages across the first and second contactors exceeding corresponding first and second closed-state voltage thresholds, and generate a notification and preclude initiation of the pre-charge in response to one of the first and second voltages being less than the corresponding first and second closed-state voltage thresholds.

Abstract: Methods and systems are described to control the use of electrical power when charging a traction battery. A vehicle module can drive the contactor coils with two set-points for controlling the power into the contactor coils, namely, a travel or vehicle “on” set point and a charging, vehicle “off” set point. In use, full power is initially applied to the coils to guarantee immediate closure of the contactor. During charging and after closing the contactor, the power is set at the charging, vehicle “off” set point. The travel or vehicle “on” set point is higher than the charging, vehicle “off” set point. Using the charging, vehicle “off” set point reduces electricity consumption. The vehicle “on” set point is at a higher electrical level as it must maintain closure under worst-case vibration and shock conditions considering mounting location, contactor orientation, as well as other characteristics of the vehicle and contactor.

Abstract: A battery pack includes a battery assembly including a grouping of battery cells and an integrated module attached to the grouping of battery cells. The integrated module includes an upper section housing at least one electronics component and a lower section establishing a vent chamber.

Abstract: A vehicle system includes a contactor including a coil and relay, a traction battery, a load, and a controller configured to transfer current from the traction battery through the coil to pre-charge the load without causing the relay to close such that a voltage drop across the relay falls below a threshold value, and subsequently cause the relay to close.

Abstract: A vehicle system includes a relay and coil of a contactor. The relay is configured to transfer current between a traction battery and an electrical load when closed. The system also includes a controller configured to operate a switch such that current flow from the traction battery through the coil and switch, and bypassing the relay, causes the relay to close to permit pre-charging of the load.