Methods and systems for determining an alternator condition in a motor vehicle are provided. The method includes receiving a maximum cranking voltage and a maximum cranking voltage time stamp from the motor vehicle over an asset interface of the telematics device; receiving a maximum device voltage and a maximum device voltage time stamp from the motor vehicle over the asset interface, and determining a potential alternator undercharging condition if a duration between the maximum cranking voltage time stamp and the maximum device voltage time stamp is greater than an undercharging indicator duration threshold. Advantageously, an alternator may be repaired or replaced before it fails thus averting having the motor vehicles inoperable.

Power management system for battery-operated vehicle including electric motor, and kinetic energy devices for capturing kinetic friction energy produced by moving parts in the vehicle. A central direct current (DC) supercharge component (CDCSC) converts kinetic friction energy into an electric current. The CDCSC connects to a current toggle that directs electric current to battery packs i.e., a first battery pack and second battery pack for powering the electric motor. The current toggle directs electric current to battery packs to recharge/store power. The power management system governs power output from the battery packs, manages depletion/efficiency of the battery packs. The power management system includes a parallel port that directs outgoing power feeds from the battery packs to the electric motor. The electric motor connects to a drive shaft of the vehicle. The power management system includes an additional battery pack that stores excess kinetic friction energy captured for external transfer.

Power management system for battery-operated vehicle including electric motor, and kinetic energy devices for capturing kinetic friction energy produced by moving parts in the vehicle. A central direct current (DC) supercharge component (CDCSC) converts kinetic friction energy into an electric current. The CDCSC connects to a current toggle that directs electric current to battery packs i.e., a first battery pack and second battery pack for powering the electric motor. The current toggle directs electric current to battery packs to recharge/store power. The power management system governs power output from the battery packs, manages depletion/efficiency of the battery packs. The power management system includes a parallel port that directs outgoing power feeds from the battery packs to the electric motor. The electric motor connects to a drive shaft of the vehicle. The power management system includes an additional battery pack that stores excess kinetic friction energy captured for external transfer.

Energy saving and sustainability have become hot topics nowadays. Electric transportation applications, such as electric vehicles, always pursue higher energy efficiency other than applications with secured power sources. Therefore, lots of research and development work have been carried out to pursue the energy efficiency, such as redesign the motor itself and/or, use electronic techniques. This invention deploys electronic techniques to pursue higher efficiency. To prove the idea and solutions, 2 prototypes using 2-phase and 3-phase PMBLDC motors have been built for the purpose. They disclose the methods to catch the residual energy from an armature and send it back to the rechargeable power sources without affecting the motor's running driven by switching manner. The implementation is simple and cheap. By recycling the residual energy, it extends the run time of battery systems, achieving higher energy efficiency. The benefit is huge, but not limited to, in economical and environmental fields.

A method and apparatus for autonomous charge balancing of an energy storage device of the microgrid. In one embodiment the method comprises obtaining, at a droop control module of a power conditioner coupled to an energy storage device in a microgrid, an estimate of a state of charge (SOC) of the energy storage device; introducing a bias, the bias based on (I) the estimate of the SOC and (II) a target SOC value for each energy storage device of a plurality of energy storage devices in the microgrid, to a droop control determination made by the droop control module; and generating, by the power conditioner, an output based on the droop control determination.

A method for acquiring information of a battery cell (11) includes a step (S101) of acquiring information pertaining to performance recovery accompanying the suspension of charging/discharging of the battery cell (11). Control pertaining to the battery cell (11) and estimation of a state of the battery cell (11) can be appropriately performed according to a type of battery cell (11).

The present application discloses a charging method, an apparatus, a device, a medium, a battery management system and a charging pile. The method includes: acquiring a charging demand parameter set by a user; calculating, according to the charging demand parameter and acquired actual operation state information of a battery, a target charging scheme for charging the battery; transmitting, according to the target charging scheme, a first charging request to a charging device, so that the charging device charges the battery according to the first charging request. According to the charging method, the apparatus, the device, medium, the battery management system and the charging pile provided in the embodiments of the present application, personalized smart charging can be achieved for different users.

In a power supply system, a first route includes a first power supply connected to a first load. A second route includes a second power supply connected to a second load. A connection path connects the first and second routes at a connection point. The first power supply includes a voltage generator generating an operating voltage operating the first and second loads. The second power supply includes an electrical storage device charging based on power supplied from the voltage generator. A switching circuit includes a first switch having a diode component with an anode and a cathode being directed to the electrical storage device and the connection path, respectively, and is disposed between the connection point and the electrical storage device. A switch state controller outputs a switch-off command to the first switch when the electrical storage device is in the fully charged condition.

A power distribution apparatus includes: a power transmitter to which a power transmission cable for supplying power to an external device is connected; a fast charger to which a fast charging cable for receiving power from a power source is connected; a processor configured to, in response to an execution command of a fast charging mode and a load power supply mode, distribute power supplied through the fast charging cable, transfer a portion of the distributed power to the external device, and transfer a remainder of the distributed power to a battery; and a power converter provided between the fast charger and the power transmitter, and configured to, when transferring the portion of the distributed power to the external device, convert a voltage of the power supplied through the fast charging cable, and transfer the voltage-converted power to the power transmitter.

The disclosed apparatus and method is a closed loop system that obtains, stores and transfers motive energy. Preferably, the majority of the electricity generated is utilized to service a load or supplied to the grid. A portion of the electric power produced is used to recharge the batteries for subsequent use of the electric motor. The system controls and manages the battery power by controlling the charging and discharging of the battery reservoir via a series of electrical and mechanical innovations controlled by electronic instruction using a series of devices to analyze, optimize and perform power production and charging functions in sequence to achieve its purpose.