Discussed is a a process automation system including: a cell transferor configured to transfer battery cells; a cell inspector configured to measure an open circuit voltage of each battery cell in units of a preset number of battery cells and to sort out qualified battery cells and defective battery cells; a frame transferor configured to transfer module frames of a battery module to insert the qualified battery cells; a cell discharger configured to load and discharge the defective battery cells; and a gripper configured to pick up one or more battery cells from any one device among the cell transferor, the cell inspector, the frame transferor, and the cell discharger, and transport the one or more battery cells to another device.

Discussed is a a process automation system including: a cell transferor configured to transfer battery cells; a cell inspector configured to measure an open circuit voltage of each battery cell in units of a preset number of battery cells and to sort out qualified battery cells and defective battery cells; a frame transferor configured to transfer module frames of a battery module to insert the qualified battery cells; a cell discharger configured to load and discharge the defective battery cells; and a gripper configured to pick up one or more battery cells from any one device among the cell transferor, the cell inspector, the frame transferor, and the cell discharger, and transport the one or more battery cells to another device.

A battery diagnosing apparatus includes: a characteristic value extracting unit for extracting a plurality of characteristic values for each of a plurality of batteries; a dimension reducing unit for reducing a dimension of a characteristic value profile representing a distribution of the plurality of batteries using a predetermined algorithm based on the plurality of characteristic values extracted by the characteristic value extracting unit; and a state diagnosing unit for detecting an outlier in the characteristic value profile whose dimension is reduced by the dimension reducing unit, and diagnosing a state of each of the plurality of batteries based on the detected outlier.

Testing of a battery module can be conducted using monitoring electronics attached to the battery module. Stimulus can be applied to the battery module and removed. After removal of the stimulus, the monitoring electronics can collect signals from the monitoring electronics reflecting parameters of the battery module as it relaxes back to a non-stimulated state. The stimulus can be provided by test equipment or by components of a system in which the battery module, having attached monitoring electronics, is implemented. The monitoring electronics attached to the battery module can provide autonomous recording of signals associated with the battery module that can provide data regarding the status of the battery module or one or more batteries contained in the battery module.

Testing of a battery module can be conducted using monitoring electronics attached to the battery module. Stimulus can be applied to the battery module and removed. After removal of the stimulus, the monitoring electronics can collect signals from the monitoring electronics reflecting parameters of the battery module as it relaxes back to a non-stimulated state. The stimulus can be provided by test equipment or by components of a system in which the battery module, having attached monitoring electronics, is implemented. The monitoring electronics attached to the battery module can provide autonomous recording of signals associated with the battery module that can provide data regarding the status of the battery module or one or more batteries contained in the battery module.

Method for controlling and regulating a rechargeable battery having energy storage cells, control electronics, a voltage measurement device and a sensor device, wherein the sensor device and the energy storage cells are respectively connected to one another via at least one controllable switching element so that electrical energy can be conducted from the energy storage cells to the sensor device. The method includes: capturing a first voltage value of the first and second energy storage cells of the voltage measurement device, and adjusting the at least one switching element from a deactivation mode to an activation mode if the difference between the voltage value of the first energy storage cell and the voltage value of the second energy storage cell reaches a predetermined threshold value, in order to conduct electrical voltage from the energy storage cell with the higher voltage value to the sensor device.

Method for controlling and regulating a rechargeable battery having energy storage cells, control electronics, a voltage measurement device and a sensor device, wherein the sensor device and the energy storage cells are respectively connected to one another via at least one controllable switching element so that electrical energy can be conducted from the energy storage cells to the sensor device. The method includes: capturing a first voltage value of the first and second energy storage cells of the voltage measurement device, and adjusting the at least one switching element from a deactivation mode to an activation mode if the difference between the voltage value of the first energy storage cell and the voltage value of the second energy storage cell reaches a predetermined threshold value, in order to conduct electrical voltage from the energy storage cell with the higher voltage value to the sensor device.

The present invention provides a management system for managing a battery mounted on a vehicle, comprising: an acquisition unit configured to acquire rank information indicating a product rank set by a user as a reuse destination of the battery; and a notification unit configured to notify the user of restriction item information indicating an item for restricting a function of the vehicle such that a deterioration state of the battery at a predetermined time satisfies a request state of the product rank, based on the rank information acquired by the acquisition unit.

The present invention provides a management system for managing a battery mounted on a vehicle, comprising: an acquisition unit configured to acquire rank information indicating a product rank set by a user as a reuse destination of the battery; and a notification unit configured to notify the user of restriction item information indicating an item for restricting a function of the vehicle such that a deterioration state of the battery at a predetermined time satisfies a request state of the product rank, based on the rank information acquired by the acquisition unit.

A method for identifying a cell quality during cell formation includes: conducting a beginning of life cycling following an initial cell formation charge of multiple cells; collecting and preprocessing a discharge data set generated by one of the multiple cells during the beginning of life cycling; calculating a statistical variance from the discharge data set identifying an estimated probability of meeting a target cell usage time; and projecting a life span of the multiple cells.