A flexible battery case with an insert mating to the tongue and groove joint to provide a stable platform for the controls, displays and peripheral connectors. Other connectors are disposed within a plastic housing and overmolded to create a waterproof seal. A charger is configured to execute a software program to confirm charger authorization to enable secondary battery charging and discharging. The control system is configured to monitor the integrity of a heating element and executes a software program to disable charging if the integrity of a heating element is compromised. A flexible substrate has a PCB on one side, and supports the individual battery cells and surface mount circuit boards on an opposite side. The flexible PCB substrate may be folded to sandwich an insulating layer therebetween.

High performance flexible lithium-sulfur flexible energy storage devices include a flexible lithium metal anode for an energy storage device comprising an electrically conducting fabric functionalised with a 3D hierarchical MnO.sub.2 nanosheet lithiophilic material; a flexible graphene/sulfur cathode protected by a FBN/G interlayer; and a flexible separator for an energy storage device, wherein the separator comprises one or more microporous films of Li ion selective permeable polyolefin material wherein at least a portion of the pores of the film are associated with nanoporous polysulfone polymer positioned between the anode and the cathode.

A computing device is disclosed. The computing device has a frame including a recessed battery compartment, the recessed battery compartment having a rigid back surface. The computing device further has a closure member having a rigid portion and a flexible portion, wherein a periphery of the closure member is coupled to a peripheral edge of the recessed battery compartment, the flexible portion to permit the rigid portion to move relative to the frame. The computing device further has a battery coupled to one or more of the battery compartment and the closure member, the battery oriented between and substantially adjacent to the rigid back surface of the battery compartment and the closure member.

A computing device is disclosed. The computing device has a frame including a recessed battery compartment, the recessed battery compartment having a rigid back surface. The computing device further has a closure member having a rigid portion and a flexible portion, wherein a periphery of the closure member is coupled to a peripheral edge of the recessed battery compartment, the flexible portion to permit the rigid portion to move relative to the frame. The computing device further has a battery coupled to one or more of the battery compartment and the closure member, the battery oriented between and substantially adjacent to the rigid back surface of the battery compartment and the closure member.

An embodiment of the present invention relates to a pouch-type secondary battery. According to embodiment of the present invention, the pouch-type secondary battery includes: an case configured to house an electrode assembly from which electrode tab are drawn out; sealing parts formed by adhering the case along outer peripheries of the electrode assembly; and folding parts formed by folding the sealing parts of surfaces on which the electrode tab drawn to an outside of the case is not formed, wherein a length of the folding part has a relationship with a thickness of the electrode assembly as the following equation: H≤T/2 (wherein, H is the height of the folded folding part, T is the thickness of the electrode assembly, based on a cross-section perpendicular to a direction in which the electrode tabs of the electrode assembly are drawn out).

A secondary battery includes an outer package member, a battery device, and an adhesive member. The outer package member has flexibility. The battery device is contained inside the outer package member, and includes a positive electrode and a negative electrode. The positive electrode and the negative electrode are opposed to each other and are wound. The adhesive member is disposed between the outer package member and the battery device. The adhesive member is adhered to each of the outer package member and the battery device. The positive electrode and the negative electrode are wound in such a manner that the positive electrode or the negative electrode is disposed in an outermost wind. The adhesive member includes a non-heat adhesive layer and a heat adhesive layer. The non-heat adhesive layer is adhered to the outer package member. The heat adhesive layer is adhered to the battery device and includes oriented polystyrene.

A secondary battery includes an outer package member, a battery device, and an adhesive member. The outer package member has flexibility. The battery device is contained inside the outer package member, and includes a positive electrode and a negative electrode. The positive electrode and the negative electrode are opposed to each other and are wound. The adhesive member is disposed between the outer package member and the battery device. The adhesive member is adhered to each of the outer package member and the battery device. The positive electrode and the negative electrode are wound in such a manner that the positive electrode or the negative electrode is disposed in an outermost wind. The adhesive member includes a non-heat adhesive layer and a heat adhesive layer. The non-heat adhesive layer is adhered to the outer package member. The heat adhesive layer is adhered to the battery device and includes oriented polystyrene.

A method for filling a thermal paste into a battery module. The battery module includes a module housing with at least one cooling wall, at which a cooling plate can be arranged outside the module housing. At least one stack is formed by a plurality of uniformly stacked pouch cells. The at least one stack is arranged at the at least one cooling wall in the module housing. In proximity to at least one opening, a fold of at least one pouch cell is folded over toward the surface of pouch cell and glued, thereby forming a first flow channel between a stack cooling side and the cooling wall. The thermal paste is filled in through the opening and the thermal paste spreads homogeneously in the first flow channel.

A method for filling a thermal paste into a battery module. The battery module includes a module housing with at least one cooling wall, at which a cooling plate can be arranged outside the module housing. At least one stack is formed by a plurality of uniformly stacked pouch cells. The at least one stack is arranged at the at least one cooling wall in the module housing. In proximity to at least one opening, a fold of at least one pouch cell is folded over toward the surface of pouch cell and glued, thereby forming a first flow channel between a stack cooling side and the cooling wall. The thermal paste is filled in through the opening and the thermal paste spreads homogeneously in the first flow channel.

A traction battery cell assembly including a battery cell and a cell case is provided. The cell case defines a cavity sized for receiving the battery cell and includes an inner wall, an outer wall, and a plurality of support chambers disposed between the inner wall and the outer wall. Each of the support chambers defines a polygon having multiple sides. The sides are arranged with one another to define an agent cavity to house neutralizing agent. The plurality of support chambers is arranged with the inner wall and the outer wall such that an impact to one of the walls causes a puncture to one of the sides of the support chambers releasing the neutralizing agent. Each of the support chambers may include five or more sides and adjacent sides may define an angle therebetween greater than ninety degrees.