An electric quantity measuring apparatus, including a battery unit, a sampling unit, and a charging management integrated circuit. The sampling circuit is connected to the battery unit and configured to obtain a current signal of the battery unit. The charging management integrated circuit is arranged with a voltage detection pin and a current detection pin. The voltage detection pin is connected to the battery unit, and the current detection pin is connected to the sampling circuit. The charging management integrated circuit is configured to detect a voltage signal of the battery unit based on the voltage detection pin, detect the current signal of the battery unit based on the current sampling pin, and obtain voltage information, current information, and electric quantity information of the battery unit.

A battery module includes a plurality of first battery modules and a plurality of second battery modules; a battery case that houses the battery modules and includes a plurality of cross beams for partitioning between the plurality of first battery modules and between the plurality of second battery modules; a plurality of first slave BMSs positioned at one side of the plurality of first battery modules facing the plurality of second battery modules; a plurality of second slave BMSs that are positioned at one side of the plurality of second battery modules facing the plurality of first battery modules; a plurality of first reflected wave absorbers arranged on one side of the plurality of first battery modules facing the plurality of second battery modules; and a plurality of second reflected wave absorbers arranged on one side of the plurality of second battery modules facing the plurality of first battery modules.

A device and method for cooling a battery management system (BMS). The BMS includes electronic components arranged inside a BMS housing. The BMS housing has at least one BMS coolant inflow connection for a coolant inflow and at least one BMS coolant outflow connection for a coolant outflow. A dielectric coolant flows around at least part of at least one electronic component inside the BMS housing. A high-voltage battery has the BMS and a plurality of battery modules that are strung together. Each battery module includes, on at least one module housing side, at least one coolant inflow connection for a coolant inflow. The high-voltage battery also includes a hollow section connected to the BMS and to the string of battery modules in a media-tight manner.

A modular battery system provides propulsive power to the rotor system of an aircraft. The modular battery system includes an array of battery modules arranged in at least one stack. Each battery module includes a plurality of battery cells, a first side having positive and negative receptacles and a second side, that is opposite of the first side, having positive and negative plugs. The receptacles and plugs are configured such that adjacent battery modules in a side-by-side relationship are electrically coupled together via plug and receptacle connections and such that the battery modules are electrically coupled together in parallel. An interconnection electrically couples each stack of battery modules together via plug and receptacle connections with one of the battery modules in each stack such that the stacks of battery modules are electrically coupled together in parallel.

A battery pack includes a base plate forming a bottom surface; a main frame combined to the base plate and extending in a height direction to form a wall structure for supporting both side portions of the plurality of battery modules; and a top plate combined to an upper portion of the main frame to form a ceiling, wherein at least one of the top plate and the base plate is provided in a plate body shape including a bead.

A battery control device, which controls a battery, including cell blocks connected in series in which battery cells are connected in parallel, to execute voltage equalization of the cell blocks, includes a detection unit that detects voltage between positive and negative electrodes of each cell block, a voltage equalization circuit that includes a plurality of discharge units in which at least one discharge element and a switching element are connected in series, and a control unit that controls the switching elements to equalize the voltages of the cell blocks. The discharge units are connected between the positive and negative electrodes of the cell blocks, respectively. The control unit controls the switching elements at a predetermined timing to execute discharge of the cell blocks, and determines whether there is an abnormality in the cell blocks based on voltage differences between the cell blocks before and after the discharge.

A system for assessment of a battery cell comprises a testing platform, a conveying system, one or more ultrasound sources, and one or more ultrasound sources, and a control unit. The conveying system can move the battery cell to the testing platform for assessment and from the testing platform after the assessment. The control unit can control the one or more ultrasound sources and the one or more ultrasound sensors to perform the assessment. The assessment can comprise determining a state of the battery cell based on the one or more signals generated by the one or more ultrasound sensors. The control unit can control the conveying system to direct the battery cell from the testing platform responsive to the assessment.

A battery pack includes a rack housing having a cabinet and a door provided to open and close the cabinet; a plurality of battery modules disposed in the cabinet in a layered form; a plurality of slave modules mounted to the battery modules one by one and having a slave antenna for wireless communication; a master module disposed at one of interlayer, top and bottom of the plurality of battery modules and having a master antenna for wireless communication; and a waveguide installed at an inner surface of the door to form a wireless communication path between the plurality of slave modules and the master module.

This maintenance assistance method detects a sign of abnormality of a power storage element on the basis of measurement data pertaining to the power storage element, which is sequentially stored in a storage device, determines at least any among a work period of a maintenance work corresponding to the detected sign of abnormality, the number of workers, and an article including a replacement or a tool required for the maintenance work, and notifies the workers of the maintenance work of execution of the maintenance work corresponding to the determined item.

The disclosure relates to a technical field of batteries, and in particular, relates to a battery pack. The battery pack includes a box body, a beam, a battery apparatus, and an electrical support base. The beam is disposed in the box body. The battery apparatus is disposed in the box body, and an electrical conductor is disposed on the battery apparatus. The electrical support base is disposed on the beam. The electrical conductor extends from the battery apparatus to the electrical support base and is connected to the electrical support base.