The invention relates to a mounting device (1) for a composite battery (7) consisting of a plurality of battery cells (71), comprising a printed circuit board (2) with electrical lines and switch elements for connecting the battery cells in parallel or series connection, a safety device with safety instruments (51) for the overcurrent protection of each battery cell, a housing with two housing parts (61, 62), having contact regions (63) for fixing the battery cells, wherein the contact regions of at least one housing part are designed as enclosures (64) for embracing a battery cell, the circuit board comprises recesses (23) for receiving and contacting (31, 32) in each case one battery cell in a respective enclosure, and wherein each recess embraces an enclosure with a battery cell in its maximum cross-sectional area. The mounting device makes it possible to provide a composite battery with exchangeable battery cells of different design, power and operating voltage in series or parallel connection with overcurrent protection at the cell level and a battery pack (8) with correspondingly configured composite batteries in a safe, simple and cost-effective manner by a user.

The present invention relates to a stepped battery, more particularly to, a stepped battery capable of increasing utilization of an inner space of a system. The stepped battery according to the present invention includes a first cell and a plurality of second cells, which are stacked on one surface of the first cell and each of which has a width less than that of the first cell. The second cells are disposed to be spaced apart from each other.

For each cell in a plurality of cells from a same manufacturing run, a first and a second cell characteristic are received in order to obtain a plurality of cell characteristics. For each cell, a batch compatibility number that is associated with a number of compatible cells that that cell is compatible with is determined based at least in part on the plurality of cell characteristics. The plurality of cells is sorted according to the batch compatibility numbers to obtain a sorted list of cells. A plurality of compatible cells to include in a battery is selected from the plurality of cells, including by evaluating the plurality of cells according to the order of the sorted list of cells and beginning with the lowest batch compatibility number.

An electric generating appliance that supplies a fixed voltage through a voltage regulator connected to one or more primary batteries comprised of cells made of solid metal anodes and solid metal cathodes where the metal for the solid metal anodes is a different type of metal than the metal used for the solid metal cathodes and where each cell has an output duct to expel air or aqueous electrolyte and an input duct to receive air, aqueous electrolyte, or a humidified electrolyte from a circuit-controlled pump connected to a refillable electrolyte container.

For each cell in a plurality of cells from a same manufacturing run, a first and a second cell characteristic are received in order to obtain a plurality of cell characteristics. For each cell, a batch compatibility number that is associated with a number of compatible cells that that cell is compatible with is determined based at least in part on the plurality of cell characteristics. The plurality of cells is sorted according to the batch compatibility numbers to obtain a sorted list of cells. A plurality of compatible cells to include in a battery is selected from the plurality of cells, including by evaluating the plurality of cells according to the order of the sorted list of cells and beginning with the lowest batch compatibility number.

For each cell in a plurality of cells from a same manufacturing run, a first and a second cell characteristic are received in order to obtain a plurality of cell characteristics. For each cell, a batch compatibility number that is associated with a number of compatible cells that that cell is compatible with is determined based at least in part on the plurality of cell characteristics. The plurality of cells is sorted according to the batch compatibility numbers to obtain a sorted list of cells. A plurality of compatible cells to include in a battery is selected from the plurality of cells, including by evaluating the plurality of cells according to the order of the sorted list of cells and beginning with the lowest batch compatibility number.

A power source system including a plurality of cells. The power source system uses electrical charge or current generated by a reaction in at least one of the cells to provide at least one operating material to at least one other of the cells. Optionally, the power source system uses the electrical charge generated by the reaction in the at least one of the cells to provide the at least one operating material to the at least one other of the cells only when the state of charge of the at least one of the cells is equal to or below a threshold or when the use of the cell is equal to or above a threshold. Optionally, in an initial or non-operational state, one or more or each of the cells is dry or without the at least one operating material and the power source system is configured to selectively switch at least one of the plurality of cells from the non-operational state to an operational state by providing the at least one operating material to the at least one cell.

A recharger includes a manifold having an input to couple to a hydrogen generating module and an output port to couple to at least one rechargeable fuel cell. A vacuum pump is coupled to the manifold to evacuate the manifold. A valve is coupled to the manifold between the vacuum pump and the input of the manifold. A controller is coupled to control the vacuum pump and the valve, as well as an optional fan.

The operation of the ionic electric power station is based on the stable corrosion of a plurality of sacrificial anodes immersed in sea water or water with common salt inside a cell, without membranes to separate the cathodic zone from the anodic zone, kinetic conditions being generated inside the cell by the circulation of water moved by a pump in a closed circuit between the cells and a reservoir.

A method of handling and removing batteries from a telecommunications site includes identifying one or more batteries for removal, each of the one or more batteries having a hazardous condition associated therewith; individually wrapping each of the one or more batteries and placing each wrapped battery in a container or in a location in a container; tracking the container or the location in the container to the associated wrapped battery; removing the container from the telecommunications site to a storage facility; storing the container in the storage facility separate from other batteries; provide the container to a recycling facility; and verifying proper disposal of the one or more batteries based on the tracking from the telecommunications site to the storage facility and to the recycling facility.