The present invention discloses a battery intelligent management apparatus. A recognizing unit is configured to recognize a specification of a power supply assembly. A storage unit is configured to store management modes of power supply assemblies of various specifications, where the management modes of the power supply assemblies are in one-to-one correspondence with the specifications of the power supply assemblies. A control unit is configured to extract, from the storage unit and according to the specification, recognized by the recognizing unit, of the power supply assembly, a management mode corresponding to the specification of the power supply assembly, and perform charge management on the power supply assembly by using the management mode.

A power storage device includes a plurality of laminated power storage modules, a flow path member disposed in contact with the power storage modules and having flow paths for allowing a cooling medium to flow along a first direction intersecting a laminating direction of the power storage modules, a pair of restraining plates disposed to sandwich the power storage modules and the flow path member in the laminating direction, fastening members applying a restraining load to the power storage modules and the flow path member via the pair of restraining plates by fastening the restraining plates to each other, and a lead-in duct disposed at one end portion of the flow path member in the first direction and leading the cooling medium into each of the flow paths.

The present application relates to a thermal management system of a battery pack, which includes a battery pack and a cooling device of the battery pack, the battery pack includes a plurality of single batteries, the cooling device of the battery pack includes cooling fins and uniform temperature plates, the uniform temperature plates are arranged outside the batteries. This application has the following beneficial effect: uniform temperature plates are arranged between single batteries, cooling fin in accordance with the single batteries are arranged on outer surfaces of two sides of the uniform temperature plate, such cooling structure adopts the existing module structure and volume of battery pack, meanwhile improving the heat dissipation effect of the battery pack, and reducing the battery temperature to a lower level than that of the existing wind cooling module, which is cost and time efficient with simple structure and simple procedure.

The present application relates to a thermal management system of a battery pack, which includes a battery pack and a cooling device of the battery pack, the battery pack includes a plurality of single batteries, the cooling device of the battery pack includes cooling fins and uniform temperature plates, the uniform temperature plates are arranged outside the batteries. This application has the following beneficial effect: uniform temperature plates are arranged between single batteries, cooling fin in accordance with the single batteries are arranged on outer surfaces of two sides of the uniform temperature plate, such cooling structure adopts the existing module structure and volume of battery pack, meanwhile improving the heat dissipation effect of the battery pack, and reducing the battery temperature to a lower level than that of the existing wind cooling module, which is cost and time efficient with simple structure and simple procedure.

The battery module according to one embodiment of the present disclosure includes a battery cell stack in which a plurality of battery cells are stacked; and a sensing assembly located on the battery cell stack. The sensing assembly includes a main body located on the battery cell stack and a module connector connected to the main body. The main body is a flexible printed circuit (FPC) or a flexible flat cable (FFC), and the main body includes a heating wire circuit.

A battery module includes a battery cell stack, on which plurality of battery cells are stacked, and a heat conduction member disposed on one surface of the battery cell stack. The heat conduction member includes a porous insulating layer and a conductive layer disposed on a surface of the porous insulating layer.

Disclosed are battery systems for powering a laser weapon, and methods of thereof. A system includes a battery bank comprising a plurality of cylindrical battery cells electrically connected in series and parallel to form a plurality of modules, wherein an air flow path through each module defined by a spacing between a surface of each battery cell and its neighboring battery cell. Furthermore a control system is configured to provide cooling via airflow from the one or more fans to temperature control the battery modules to prevent the temperature difference between a first side of the battery module and a second side of the battery module from rising above a predetermined threshold while the laser weapon is active and consuming energy from the battery bank.

A battery comprising a fluid electrolyte, a casing configured to contain the electrolyte, an anode placed in contact with the electrolyte in the casing, and a cathode placed in contact with the electrolyte in the casing. The battery comprises a temperature control device configured to modify the temperature of the electrolyte, a circulating device configured to circulate the electrolyte in the casing and between the casing and the temperature control device. Also, a method for regulating the temperature of a battery in which a fluid electrolyte is circulated in a battery casing comprising an anode and a cathode, and through a temperature control device configured to modify the temperature of the electrolyte.

A temperature equalization and heat dissipation container structure of a lithium battery and a combination module thereof are disclosed. The temperature equalization and heat dissipation container structure of lithium battery includes a base and a housing frame erected on the base. The housing frame includes a pair of first heat conducting walls spaced apart from each other and a pair of second heat conducting walls spaced apart from each other. The base, the first heat conducting walls and the second heat conducting walls are enclosed to form a hollow accommodating area, and the pair of first heat conducting walls are erected with a pitch gradually widening from bottom to top.

A thermal interfacing assembly for use in a power module having at least one battery module and a cooling plate, and corresponding method of forming the thermal interfacing assembly. The thermal interfacing material is deposited over a first surface of the cooling plate such that the thermal interfacing material conforms to the shape of the first surface. The thermal interfacing material is configured to be electrically insulating and thermally conductive. A first embedded heater is positioned adjacent to the thermal interfacing material. The first embedded heater includes an electrically-conductive portion and a resistive portion. The battery module is installed adjacent to the first embedded heater such that the first embedded heater is directly in contact with a first face of the battery module. The first embedded heater is employed to at least partially induce in-place curing of the thermal interfacing material.