The present invention relates to an electrode assembly. The electrode comprises: a plurality of unit electrodes formed by connecting a plurality of electrodes made of an electrode mixture having a solid shape to each other; a separator interposed between the plurality of unit electrodes; and an electrode tab attached to the unit electrode, wherein the electrode tab comprises first and second electrode tabs, which are respectively attached to the unit electrodes and have different specific resistance.

The present invention relates to a battery pack including a cell switching device of a parallel connection cell and a cell switching method, and more specifically, to a battery pack including a cell switching device that replaces the failed cell with a normal replacement cell if a failed cell occurs due to open parallel connection line or CID operation among battery cells connected in parallel, and a cell switching method.

The disclosure provides an electric energy storage device which includes four energy units with a substantially same voltage value. Each energy unit is provided with a positive electrode and a negative electrode. The electric energy storage device comprises a socket with eight independently arranged electrode terminals that are connected with the four energy units. The disclosure also provides an electric tool system using the electric energy storage device. The electric tool is provided with plugs that may be connected with the four energy units in different states, allowing the electric energy storage device to output multiple voltages.

A secondary battery pack includes: a first battery; a second battery; a third battery including positive, negative and bipolar terminals; a first connector electrically connecting a negative terminal of the first battery and the positive terminal of the third battery; and a second connector electrically connecting a positive terminal of the second battery and the negative terminal of the third battery. The third battery includes bipolar electrodes individually located in the spaces between positive electrodes and negative electrodes neighboring each other, the bipolar electrodes having an intermediate electrode potential between the positive electrode and the negative electrode; an electrolyte; a positive-electrode connection member electrically connecting the positive terminal of the third battery and the positive electrodes; a negative-electrode connection member electrically connecting the negative terminal and the negative electrodes; and a bipolar-electrode connection member electrically connecting the bipolar terminal and the bipolar electrodes.

A battery module includes: a plurality of battery cells stacked in a predetermined direction and electrically connected together; a plurality of bus bars that electrically connect the plurality of battery cells together; and a plurality of voltage detection wires each connected to one set of two or more battery cells electrically connected together. According to the battery module, the number of the voltage detection wires is reduced, thereby attaining reduced sizes of the bus bars, productivity improved by improved workability, and reduced cost.

A rechargeable battery jump starting device with a dual battery diode bridge system. The dual battery diode bridge, for example, is configured to protect against a back-charge to a first 12V battery and/or a second 12V battery after a vehicle has been jump charged to prevent damage thereto.

The disclosure provides an electric energy storage device which includes four energy units with a substantially same voltage value. Each energy unit is provided with a positive electrode and a negative electrode. The electric energy storage device comprises a socket with eight independently arranged electrode terminals that are connected with the four energy units. The disclosure also provides an electric tool system using the electric energy storage device. The electric tool is provided with plugs that may be connected with the four energy units in different states, allowing the electric energy storage device to output multiple voltages.

A series formation system is provided. The series formation system includes at least two formation modules and a power module. The power module is connected in series with the at least two formation modules. The at least two formation modules are connected in series. The power module is configured to supply power to the at least two formation modules. Each of the formation modules includes a battery cell and a formation control circuit. The formation control circuit is electrically connected to the battery cell. The formation control circuit is configured to control a voltage or a current provided by the power module to the battery cell, so that the battery cell is switched between a constant current charging mode and a constant voltage charging mode.

A method for performance analysis and use management of a battery module is disclosed, wherein the battery module includes a multitude of interconnected battery cells and a battery management system with a plurality of dedicated analysis/control units (ACUs) that analyze performance of the battery module, the ACUs being assigned to individual battery cells and/or battery blocks of battery module. The method includes measuring current and voltage of one or more of an individual battery cell and a battery block; calculating a charge removal from the one or more of the individual battery cell and the battery block; calculating a loading charge of the one or more of the individual battery cell and the battery block; determining the remaining charge of the one or more of the individual battery cell and the battery block; and failure monitoring of the one or more of the individual battery cell and the battery block.

A battery pack assembly includes a first battery cell supplying electric current to an electronic load, a second battery cell supplying electric current to the electronic load, and a first switch operatively coupled with the first battery cell and the electronic load. The first switch stops conduction of the electric current to the electronic load responsive to an increase in electric demand of the electronic load above a designated threshold. A method of powering an electronic load using a battery pack assembly also is provided.