A work equipment that can temporarily store an article that is collected while traveling, and includes a work equipment main body, a container device configured to store the article collected by the work equipment main body while being connected to the work equipment main body, and to travel to and back from a collected article destination by being detached from the work equipment main body, a travel drive unit configured to cause the container device to travel, a battery mounted to the container device to power the travel drive unit, a battery state of charge sensor configured to detect a remaining battery charge of the battery, and a control unit that determination whether the container device may be detached from the work equipment main body or not according to the remaining battery charge.

A battery charger identifies the type of battery that is connected to it in order to provide the optimum voltage-current-time profile that is needed to safely and optimally charge and maintain the battery. In some embodiments, the battery current or voltage is monitored during charging, and as the current or the voltage changes while the charger is powered, the changes are measured and used to determine the type of battery that is connected so that the optimum charge profile can be applied.

For indicating that a battery is fully discharged to a decommissioned state, methods, apparatus, and systems are disclosed. One apparatus includes a battery that powers an electronic device, a battery state module that comprises a non-reversible indicator, a control module coupled to the battery, and a decommission module. The decommission module receives a discharge signal from the control module and discharges the battery to a fully discharged state, where discharging the battery causes the non-reversible indicator to indicate the fully discharged state.

Provided is a lithium ion secondary battery system having excellent reliability. Provided is a lithium ion secondary battery system including, at least a lithium ion secondary battery including a positive electrode and a negative electrode, and a lithium deposition sensor. In this lithium ion secondary battery system, the lithium deposition sensor includes an endotherm detector, and the endotherm detector detects endotherm in a constant current charging range.

Provided is a battery management system capable of deliberately discharging a battery to suppress deterioration of the battery due to gas generated in the battery that is left non-used at a high temperature for a long time. The battery management system, which aims to prevent generation of gas in the battery left non-used at a high temperature, is provided to prevent generation of gas in the battery in advance by deliberately discharging the battery to reduce a charged amount of the battery when a temperature, a charged amount, and a non-used period are in a preset level range.

A battery energy storage system is provided with: a charging/discharging control device capable of controlling charging/discharging of each of a plurality of electricity storage units in accordance with the supply and demand state of a power system; and a management device for adjusting the progression of deterioration of each of the electricity storage units by differentiating the charging/discharging amount of each of the electricity storage units and managing by differentiating the electricity storage units having a low degree of progression of deterioration from the electricity storage units having a high degree of progression deterioration.

A battery device includes a battery unit, a temperature port, a temperature sensitive component, a switch component and a battery management unit. The temperature sensitive component senses a temperature of the battery unit, and provides a temperature indication signal at the temperature port. The switch component is electrically connected to the temperature sensitive component. When the battery device operates abnormally, the battery management unit controls the switch component to make the switch component stop provision of the temperature indication signal at the temperature port.

A battery-operated electronic device, such as, e.g., a continuous glucose monitoring (CGM) transmitter, has a switch disconnect circuit that reduces battery discharge while the device is stored and/or in “shelf mode.” The device has two externally-accessible activation pads each configured to contact a same electrical conductor positioned in packaging for the device that causes the switch disconnect circuit to disconnect the battery from device electronics while the device is in the packaging. Upon removal of the device from the packaging, the two activation pads no longer contact the electrical conductor, causing the switch disconnect circuit to automatically connect the battery to the device electronics. Methods of reducing battery discharge in a battery-operated electronic device and other aspects are also described.

The present invention provides a method for reasonably adjusting an end-of-discharge voltage of a lithium battery with attenuation of a battery life. The method includes: acquiring an end-of-charge voltage, an end-of-discharge voltage and a rated capacity based on a basic parameter table for a lithium battery, then setting a safety end-of-charge voltage and a safety end-of-discharge voltage to obtain an initial safety discharge capacity, and finally setting a preset discharge capacity of the battery; using an Ampere-hour integration method to estimate a discharged power, taking the preset discharge capacity as a discharge standard, and stopping discharge when the discharged power reaches the preset discharge capacity; and the safety discharge capacity being gradually less than the preset discharge capacity within a battery life cycle, and the battery stopping discharge when the voltage reaches the safety end-of-discharge voltage. By controlling the discharge capacity to be unchanged, the present invention ensures stably outputting power in the case that the battery capacity attenuates, so that a user feels that the endurance mileage of an electric vehicle is stably unchanged within a certain period. The method has the characteristics of simple adjusting control method and convenience in commercialization.

A managing device calculates a whole state of power (SOP) that is an SOP of a whole of the plurality of power storage blocks based on SOPs of the respective power storage blocks and currents flowing through the respective power storage blocks, and sets an upper limit value of power or a current for at least one of charging and discharging by a power converter, based on the whole SOP thus calculated. The managing device estimates a current flowing through each of the power storage blocks from a voltage and an internal resistances of each of the power storage blocks before the power converter starts power conversion.