A voltage detection circuit includes a differential, amplification circuit and a microcontroller unit (MCU). The MCU detects a differential voltage output from operational amplifiers of the differential amplification circuit, and calculates an internal resistance value of a battery cell based on the detected differential voltage. At this time, the MCU controls an amplification factor adjustment circuit of the differential amplification circuit based on a maximum voltage representing the highest voltage detectable by the MCU and the differential voltage output from the differential amplification circuit so as to set the amplification factor of the operational amplifiers.

A battery device includes a connection unit to which an electronic apparatus is connected, a calculation unit that calculates a remaining battery level of a battery of the battery device based on a full charge capacity of a battery of the electronic apparatus, and a display unit that displays information indicating a result of calculation made by the calculation unit.

An adapter may be configured to connect a battery and an electrical device to each other. The adapter may include a control board; a battery-side terminal mounted on a first surface of the control board and configured to be electrically connectable to the battery; and a device-side terminal mounted on a second surface of the control board and configured to be electrically connectable to the electrical device, the second surface being opposite from the first surface.

A measuring assembly for measuring a temperature and a voltage includes a contact element including a temperature sensor and an electrically conductive portion, a voltage measurement conductor electrically connected to the conductive portion of the contact element, and an electrically conductive fixation element electrically connected to the conductive portion of the contact element, the electrically conductive fixation element extending through a fixation hole of a busbar in a fixed state to connect to the busbar by an elastic force provided by the electrically conductive fixation element in the fixed state, and the electrically conductive fixation element pressing the contact element to a measuring surface of the busbar by the elastic force in the fixed state.

A robotic system for manipulating an electrical component between a first location and a second location, the system comprising: a movement element for moving a manipulation tool between the first location and the second location; the manipulation tool having one or more gripping elements for engaging the electrical component by grabbing the electrical component at the first location when the manipulation tool is positioned adjacent to the electrical component; and a testing system for implementing an electronic test of the electrical component while the electrical component is engaged by the manipulation tool, the testing system implementing the electronic test before the manipulation tool releases the electrical component; wherein upon reaching the second location the manipulation tool disengages with the electrical component, thereby reversing said engaging.

According to one aspect of the present invention, a short circuit inspection method for an all solid battery assembly is provided which includes: a step of preparing an all-solid-state battery assembly; a step of preparing a restraint jig including a pair of restraint plates sandwiching the all-solid-state battery assembly in the thickness direction, and a restraint member including a bolt and a nut, wherein where a smallest thermal expansion coefficient among the thermal expansion coefficient of the positive electrode current collector and the thermal expansion coefficient of the negative electrode current collector of the all-solid-state battery assembly is denoted by α1, the thermal expansion coefficients of the bolt and the nut are each equal to or greater than α1; a step of restraining the all-solid-state battery assembly; a step of increasing the resistance of the all-solid-state battery assembly by cooling; a step of applying a voltage to the all-solid-state battery assembly and measuring a current; and a step of determining whether or not a short circuit has occurred in the all-solid-state battery assembly on the basis of the measured current value.

In a particular embodiment, optical communications in a battery pack is disclosed that includes generating, by a module monitoring system of a battery management system, sensor data; encoding, by the module monitoring system, the sensor data into an optical signal; sending, by the module monitoring system, to a data aggregator, the sensor data as the optical signal; and decoding, by the data aggregator, the optical signal into the sensor data.

A battery system includes battery cells to store electrical energy and to output electrical power. The battery system further includes a housing, a shunt, a control board, and a connector assembly. The housing includes a cavity that the shunt is disposed in and is in direct contact with, where the cavity facilitates dissipating torsional force exerted on the shunt. The control board is disposed within the housing and includes sensing circuitry to determine an operational parameter of the battery cells and control circuitry to facilitate controlling operation of the battery cells based on the operational parameter. The connector assembly electrically couples the shunt to the sensing circuitry via a spacing connector and a securing connector. The spacing connector is disposed between the control board and an inner surface of the housing while the securing connector extends through the shunt to couple to the spacing connector through the housing.

A battery of modular construction that stores electrical energy includes a battery housing, a module assembly including at least two battery modules, each with at least one positive and at least one negative electrode, and a pressing means. A method of safety operation of the battery includes equipping the battery with at least one safety means that triggers a reduction in the mechanical pressure exerted onto the battery modules when there is a defect in at least one of the battery modules.

An adapter may be configured to connect a battery and an electrical device to each other. The adapter may include a control board; a battery-side terminal mounted on a first surface of the control board and configured to be electrically connectable to the battery; and a device-side terminal mounted on a second surface of the control board and configured to be electrically connectable to the electrical device, the second surface being opposite from the first surface.