Temperature controlled Battery Pack; a Method of protecting a large battery pack from thermal stresses; all weather Battery module; an apparatus and method for charging a battery pack, and decoupling the charging voltage from the battery pack voltage; an apparatus and method for discharging the hybrid battery modules, and extending the range of the battery pack; Battery pack controller—safety and reliability of battery pack. A method of providing flood protection to a large battery pack. A method of cooling the battery pack in extreme hot temperatures. A method of heating the battery pack in extreme cold temperatures. A method of repurposing the battery module (BM) Charging and balancing circuit is one of the key components of the battery pack. The invention constitutes an apparatus of Energy discharging split circuit installed within each BM, and an energy management algorithm installed in the battery pack controller. The energy discharging circuit mixes the current output of batteries and capacitors within each BM, as per the instructions from the battery pack controller algorithm. The algorithm takes the SoH and SoC of the batteries in the weakest BMs into account to calculate the mix of current from batteries and capacitors, and selectively instructs each BM. A method for discharging the battery BMs, and extending the range of the battery pack. Battery pack controller is the Master controller of the battery pack.

A temperature-control apparatus has individual battery cells combined to form a module and arranged within a flow duct through which a temperature-control fluid flows in a main flow direction. Temperature regulation of a temperature-control apparatus is improved with a constant packing density of the battery cells despite small amounts of temperature-control fluid, with a flow guiding surface provided for each battery cell of a group. The flow guiding surface is spaced apart from a lateral section of the battery cell and has in each case an inlet section and an outlet section that are both substantially parallel to the lateral section. A diffuser section is arranged between the inlet section and the outlet section, the diffuser section-being set back with respect to the inlet section and the outlet section and with respect to the lateral section.

A temperature-control apparatus has individual battery cells combined to form a module and arranged within a flow duct through which a temperature-control fluid flows in a main flow direction. Temperature regulation of a temperature-control apparatus is improved with a constant packing density of the battery cells despite small amounts of temperature-control fluid, with a flow guiding surface provided for each battery cell of a group. The flow guiding surface is spaced apart from a lateral section of the battery cell and has in each case an inlet section and an outlet section that are both substantially parallel to the lateral section. A diffuser section is arranged between the inlet section and the outlet section, the diffuser section-being set back with respect to the inlet section and the outlet section and with respect to the lateral section.

A charge/discharge device for an activation process of a secondary battery including an accommodation structure having a plurality of accommodation spaces and provided with a wiring duct at one side of each of the accommodation spaces, each of a plurality of charge/discharge boxes installed in each of the plurality of accommodation spaces, wires wired in a space inside the wiring duct, and an exhaust fan installed on an inner wall of the wiring duct, in which the exhaust fan is installed on the inner wall of the wiring duct adjacent to one side of the accommodation space, and the wires are wired to pass an external side of the exhaust fan is provided. A heat insulation panel may be additionally installed together with the exhaust fan in the wiring duct.

Disclosed is a battery module. The battery module includes at least one battery cell, a casing configured to surround the battery cell and having at least one opening formed therein; and a thermal interface material (TIM) interposed between the casing and the battery cell and exposed out of the casing through the opening of the casing.

Disclosed is a battery module. The battery module includes at least one battery cell, a casing configured to surround the battery cell and having at least one opening formed therein; and a thermal interface material (TIM) interposed between the casing and the battery cell and exposed out of the casing through the opening of the casing.

An energy storage system may include a battery pack having a plurality of battery cells, a power converter, a pump which supplies a fluid to the battery pack or the power converter, a radiator which heat-exchanges the fluid flowing by the pump with air, a first valve which sends a fluid discharged from the pump to the power converter or the battery pack, and a second valve which sends the fluid discharged from the power converter to the battery pack or the radiator.

In some examples, a control unit is configured to consider battery heat. The control unit is adapted to provide power from a battery to a system during a peak power mode that includes peak power and off-peak power, and consider heat balance in the battery during the peak power mode by providing peak power so that heat of the battery corresponds to a reference condition heat of the battery.

In some examples, a control unit is configured to consider battery heat. The control unit is adapted to provide power from a battery to a system during a peak power mode that includes peak power and off-peak power, and consider heat balance in the battery during the peak power mode by providing peak power so that heat of the battery corresponds to a reference condition heat of the battery.

An embodiment is directed to a solid state electrolyte-comprising Li or Li-ion battery cell, comprising an anode electrode, a cathode electrode with an areal capacity loading that exceeds around 3.5 mAh/cm.sup.2, an ionically conductive separator layer that electrically separates the anode and cathode electrodes, and one or more solid electrolytes ionically coupling the anode and the cathode, wherein at least one of the one or more solid electrolytes or at least one solid electrolyte precursor of the one or more solid electrolytes is infiltrated into the solid state Li or Li-ion battery cell as a liquid.