Abstract: A method for managing a battery to perform a final action, the method includes determining a battery supplying power to an electronic device is discharging and receiving battery specification information for the battery. The method includes receiving environmental condition information for the battery and determining an open circuit voltage for the battery. The method includes determining a base capacity for the battery, a first capacity reduction for the battery based on the battery specification, and a second capacity reduction for the battery based on the environmental condition information. The method includes determining an overall expected capacity for the battery based on the first capacity reduction and the second capacity reduction, where the overall expected capacity represents available energy. Responsive to determining the available energy for the battery is less than a required energy to perform an action prior to battery depletion, the method includes sending a warning notification.

Abstract: A method can include obtaining device data for a set of electronic devices. The device data can indicate power utilized by the set of electronic devices. The method can include obtaining a capacity of a backup power source. The method can include obtaining priority data regarding an allocation of power to the set of electronic devices. The method can include obtaining a set of environmental conditions. The method can include calculating, based at least in part on the set of environmental conditions and the device data, a projected electrical load on the backup power source. The method can include determining that one or more thresholds are exceeded. The determining can comprise identifying that the projected electrical load exceeds the capacity. The method can include modifying, in response to the determining and according to the priority data, power supplied to the set of electronic devices from the backup power source.

Abstract: A method for managing a battery to perform a final action, the method includes determining a battery supplying power to an electronic device is discharging and receiving battery specification information for the battery. The method includes receiving environmental condition information for the battery and determining an open circuit voltage for the battery. The method includes determining a base capacity for the battery, a first capacity reduction for the battery based on the battery specification, and a second capacity reduction for the battery based on the environmental condition information. The method includes determining an overall expected capacity for the battery based on the first capacity reduction and the second capacity reduction, where the overall expected capacity represents available energy. Responsive to determining the available energy for the battery is less than a required energy to perform an action prior to battery depletion, the method includes sending a warning notification.

Abstract: Embodiments of the present invention manage a state of charge of a rechargeable battery for extended storage by determining a manual override for a storage protocol is not activate for a rechargeable battery associated with a battery charger and an electronic device. Receiving battery data, environment data, and historical data for the rechargeable battery associated with a battery charger. Embodiments of the present invention determine to activate the storage protocol for the rechargeable battery based on the battery data, the environment data, and the historical data and discharge the rechargeable battery to a preset state of charge level based on the storage protocol.

Abstract: A rechargeable lead-acid battery is provided. The rechargeable lead-acid battery includes a casing, a grid structure and an electro-mechanical assembly. The casing defines an interior configured to accommodate plates and a supply of fluid that is electrically reactive with the plates to generate electricity. The grid structure is interposed between lower edges of the plates and a bottom of the casing. The electro-mechanical assembly is coupled with the grid structure and operable to agitate the grid structure.

Abstract: Described herein are techniques for battery management. The techniques include a method comprising initializing a battery management system (BMS) associated with a battery and calculating a degraded battery capacity by charging the battery from a first voltage threshold to a test voltage threshold, discharging the battery from the test voltage threshold to the first voltage threshold, collecting measurements of discharge capacity at predetermined voltage measurement points while discharging the battery from the test voltage threshold to the first voltage threshold, generating a polynomial fit function for discharge capacity as a function of voltage for the battery based on the measuring, and estimating the degraded battery capacity. The method further includes charging the battery based on the degraded battery capacity, the charging resulting in the battery maintaining an updated voltage threshold.

Abstract: Described herein are techniques for battery management. The techniques include a method comprising initializing a battery management system (BMS) associated with a battery and calculating a degraded battery capacity by charging the battery from a first voltage threshold to a test voltage threshold, discharging the battery from the test voltage threshold to the first voltage threshold, collecting measurements of discharge capacity at predetermined voltage measurement points while discharging the battery from the test voltage threshold to the first voltage threshold, generating a polynomial fit function for discharge capacity as a function of voltage for the battery based on the measuring, and estimating the degraded battery capacity. The method further includes charging the battery based on the degraded battery capacity, the charging resulting in the battery maintaining an updated voltage threshold.

Abstract: A starter battery with a total battery voltage exceeding a supply voltage requirement of an electrical system. An alternator provides a charging voltage that corresponds with the supply voltage requirement of the electrical system. A total battery voltage equal to the sum of cell voltages exceeds the supply voltage requirement of the electrical system. A step-down voltage regulator reduces the total battery voltage to correspond with the supply voltage requirement and a boost voltage regulator increases the charging voltage from the alternator when charging the starter battery to the total battery voltage. When detecting a degraded cell, the step-down voltage regulator continues to regulate the total battery voltage to correspond with the supply voltage requirement after the cell has degraded and the boost voltage regulator is bypassed when charging the starter battery to no longer increase the charging voltage from the alternator when charging the starter battery.

Abstract: A rechargeable lead-acid battery is provided. The rechargeable lead-acid battery includes a casing, a grid structure and an electro-mechanical assembly. The casing defines an interior configured to accommodate plates and a supply of fluid that is electrically reactive with the plates to generate electricity. The grid structure is interposed between lower edges of the plates and a bottom of the casing. The electro-mechanical assembly is coupled with the grid structure and operable to agitate the grid structure.

Abstract: A starter battery with a total battery voltage exceeding a supply voltage requirement of an electrical system. An alternator provides a charging voltage that corresponds with the supply voltage requirement of the electrical system. A total battery voltage equal to the sum of cell voltages exceeds the supply voltage requirement of the electrical system. A step-down voltage regulator reduces the total battery voltage to correspond with the supply voltage requirement and a boost voltage regulator increases the charging voltage from the alternator when charging the starter battery to the total battery voltage. When detecting a degraded cell, the step-down voltage regulator continues to regulate the total battery voltage to correspond with the supply voltage requirement after the cell has degraded and the boost voltage regulator is bypassed when charging the starter battery to no longer increase the charging voltage from the alternator when charging the starter battery.

Abstract: An apparatus is provided for detecting one of multiple possible abnormal conditions associated with a flexible, pouch-type energy storage device of an electronic device. The apparatus includes a stiffener, a pressure sensor and a control component. The stiffener overlies a main surface of the storage device. The pressure sensor is disposed between the stiffener and an inner surface of the electronic device to monitor for pressure between the stiffener and the inner surface indicative of an abnormal condition associated with the storage device. The control component is coupled to the pressure sensor and detects the abnormal condition based, at least in part, on the monitored pressure exceeding a specified threshold, and performs and action based thereon. The abnormal condition may include excessive external force being applied to the energy storage device, or excessive internal swelling of the energy storage device during charging, or during use.

Abstract: An apparatus is provided for detecting one of multiple possible abnormal conditions associated with a flexible, pouch-type energy storage device of an electronic device. The apparatus includes a stiffener, a pressure sensor and a control component. The stiffener overlies a main surface of the storage device. The pressure sensor is disposed between the stiffener and an inner surface of the electronic device to monitor for pressure between the stiffener and the inner surface indicative of an abnormal condition associated with the storage device. The control component is coupled to the pressure sensor and detects the abnormal condition based, at least in part, on the monitored pressure exceeding a specified threshold, and performs and action based thereon. The abnormal condition may include excessive external force being applied to the energy storage device, or excessive internal swelling of the energy storage device during charging, or during use.

Abstract: A method of preventing an energy storage device failure in a power supply, includes a package deformation, indicating a gas buildup and a forthcoming failure in a package wall of the energy storage device is detected. A voltage caused by the displacement of the package wall of the energy storage device is detected. It is determined whether the detected voltage is greater than or equal to a voltage threshold to indicate a slight package deformation. A warning is issued if the detected voltage is greater than or equal to the voltage threshold for the slight package deformation. It is determined whether the detected voltage is greater than or equal to a voltage threshold, to indicate a package deformation severe enough that a package breach is imminent. The power supply is shut down if the detected voltage is determined to be greater than or equal to the package breach voltage threshold.

Abstract: A method, apparatus and computer program product are provided for implementing power system performance. Power supply system data are processed and a power path in a power supply system having a predefined component failure mode is identified for placement of a fuse. Transient and steady state current levels are determined for each identified power path. A fuse size is selected within an identified fuse size range based upon the determined transient and steady state current levels. A selected fuse energy rating is lower than an energy rating of the solid-state devices in the identified power path.

Abstract: A power converter controller and a method for controlling a power converter are provided. The power converter includes first and second power transformers, each having first and second primary windings and a secondary winding; and first and second switches that alternately couple primary windings of the first and second power transformers to an input power source. The power converter controller receives a feedback signal, such as a DC power output voltage from the power converter. A voltage controlled oscillator responsive to the feedback signal provides a variable frequency signal. A phase shift controller coupled to the voltage controlled oscillator provides a variable phase shifted signal responsive to the variable frequency signal. Gate drive signals are decoded using the variable frequency signal and variable phase shifted signal for driving first and second switches of the power converter.

Abstract: A power converter controller and a method for controlling a power converter are provided. The power converter includes first and second power transformers, each having first and second primary windings and a secondary winding; and first and second switches that alternately couple primary windings of the first and second power transformers to an input power source. The power converter controller receives a feedback signal, such as a DC power output voltage from the power converter. A voltage controlled oscillator responsive to the feedback signal provides a variable frequency signal. A phase shift controller coupled to the voltage controlled oscillator provides a variable phase shifted signal responsive to the variable frequency signal. Gate drive signals are decoded using the variable frequency signal and variable phase shifted signal for driving first and second switches of the power converter.