A jumper cable is provided that includes: a first charging transfer cable having first and second opposing ends; a second charging transfer cable having third and fourth opposing ends, and a connecting element at each of the first, second, third, and fourth opposing ends, the connecting element configured to releasably attach respective ends of the first and second charging cables to one or more battery terminals. A portion of the first charging transfer cable is coupled to the second charging transfer cables between a first point of union and a second point of union, and the unequal length portions of the first and second charging transfer cables extend from at least one of the first and second points of union.

A system for disabling an electric vehicle during charging, including an energy storage device, the energy storage device attached to an electric vehicle. T The system including a charging port, wherein the charging port is configured to engage with a charging connector, the charging port disposed on the electric vehicle and electrically connected to the energy storage device. The system also including a presence sensor, the presence sensor communicatively connected to the charging port, the presence sensor configured to detect whether the charging connector is engaged with the charging port. Additionally, the system including an interlock component, the interlock component configured to disable the electric vehicle when the charging connector is engaged with the charging port.

Exemplary protection circuitry for wireless power systems can include a battery disconnect circuit, a load dump protection circuit, and/or a coil disconnect circuit. One or more of these protection circuits may be employed by a wireless power receiver. Further, one or more of these protection circuits may enable a wireless power receiver to be able to protect itself independently from a wireless power transmitter, thereby increasing safety of the wireless power system.

The vehicle includes an inlet configured to be connected to a charging connector provided in a charging station, a lock device configured to switch between a locked state where the charging connector is locked to the inlet and an unlocked state where the charging connector is removable from the inlet, a power storage device configured to be charged with an electric power supplied through the charging connector, and a control device configured to control charging of the power storage device. In a state where the charging connector is connected to the inlet and the power storage device is being charged, the control device stops charging when the lock device is in the unlocked state.

A wireless battery management system according to the present disclosure includes a master to wirelessly transmit a main command packet every reference time, and a plurality of slaves. Each slave wirelessly transmits a response packet including an ID of each slave when receiving the main command packet. The master classifies, as a first group, each slave to which the ID included in each response packet received within a threshold time from a time point at which the main command packet was transmitted is allocated, and each of the remaining slaves as a second group. Each slave initializes a time count of a watchdog timer provided in each slave when receiving the main command packet. Each slave is reset by the watchdog timer when the time count of the watchdog timer reaches a timeout that is equal to or less than the reference time.

The present disclosure discloses a charging control circuit, which comprises: a charging circuit configured to be connected to a charging line or an external device, and the charging circuit generates a charging voltage difference after being connected to the charging line or the external device; a detection circuit including at least one detection terminal for detecting voltage information of the at least one detection terminal; and a control circuit configured to perform a predetermined action based on the charging voltage difference and the voltage information.

An apparatus includes a power converter, one or more power source terminal configured to connect to a power source, and one or more load terminal. The apparatus further includes two or more energy storage terminals configured to connect to two or more electrical energy storage devices. Two or more protection circuits, included in the apparatus, one for each of the protection circuits, is electrically connected between the respective energy storage terminal and the power converter. The two or more protection circuits are configured to disconnect the respective terminal from the power converter following a failure of the respective one of the electrical energy storage devices.

Various embodiments of the present invention relate to an electronic device and a charging control method therefor. The electronic device may comprise: a connection terminal for performing wired communication with an external electronic device; and at least one processor functionally connected to the connection terminal, wherein the at least one processor detects connection of a charging device through the connection terminal, receives state information of at least one adjacent terminal located next to a power terminal of the connection terminal, and controls charging power to be supplied thereto through the charging device, on the basis of the received state information of the adjacent terminal. In addition, various other embodiments are possible.

Embodiments of the present disclosure disclose a charging method, a terminal and a computer storage medium. The charging method includes: detecting a battery power and a power consumption parameter before turning on a fast charging function; determining an estimated charging time according to the battery power and the power consumption parameter; determining whether an abnormal charging occurs according to the estimated charging time after turning on the fast charging function; and turning off the fast charging function when determining that the abnormal charging occurs.

This document describes methods, devices, and systems for configuring a smartphone (102) for network connectivity via a charging station (120), in which the smartphone (102) detects a connection or a coupling to the charging station (120). In response to the detection of the connection or coupling to the charging station (120), the smartphone (102) configures a WLAN transceiver (228) as a WLAN access point and forms a mesh WLAN network with one or more other WLAN access points (114). In other aspects, the charging station (120) detects the presence of the smartphone (102) that is connected or coupled to the charging station (120). In response to sensing the presence of the smartphone (102), the charging station (120) configures power and charging circuitry (244) to charge a battery of the smartphone (102) and configures WLAN radio circuitry (232) to relay WLAN communications for the smartphone (102).