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 attachment member is prevented from coming off from an exterior case. Disclosed is a battery pack including: an exterior case; a battery unit; and an attachment member attached from outside of the exterior case, in which the attachment member has a plurality of claw portions, the attachment member is attached to the exterior case by the plurality of claw portions, a restricting member that restricts a movable range of the claw portion is provided inside the exterior case, and the restricting member is configured as a member separate from the exterior case.

A flexible battery connection structure is provided. A flexible battery connection structure according to an exemplary embodiment of the present invention comprises: a plurality of flexible batteries electrically connected to each other, disposed along a longitudinal direction, and each including a positive electrode terminal and a negative electrode terminal protruding from one end portions; a connection member disposed at positions corresponding to the positive electrode terminal and the negative electrode terminal to protect the positive electrode terminal and the negative electrode terminal and connect two flexible batteries adjacent to each other; and a housing configured to surround the plurality of flexible batteries connected to each other through the connection members.

A flexible battery connection structure is provided. A flexible battery connection structure according to an exemplary embodiment of the present invention comprises: a plurality of flexible batteries electrically connected to each other, disposed along a longitudinal direction, and each including a positive electrode terminal and a negative electrode terminal protruding from one end portions; a connection member disposed at positions corresponding to the positive electrode terminal and the negative electrode terminal to protect the positive electrode terminal and the negative electrode terminal and connect two flexible batteries adjacent to each other; and a housing configured to surround the plurality of flexible batteries connected to each other through the connection members.

A flexible long-lasting clean energy power generation device with spontaneous moisture absorption is a multi-layer film structure including a hydrophilic support substrate, a conductive layer and a moisture absorbent layer. The conductive layer is coated on an outer side of the hydrophilic support substrate and has a first section and a second section, and the moisture absorbent layer is coated on the first section of the conductive layer, so that the flexible long-lasting clean energy power generation device is formed into an asymmetrical structure. The moisture absorbent layer captures moisture from the ambient environmental humidity, and the moisture forms a capillary pressure difference by a capillary action and an evaporation, so that water molecules and ions move from the wet area of the moisture absorbent layer to the dry area of the second section to form an electric potential difference.

A flexible long-lasting clean energy power generation device with spontaneous moisture absorption is a multi-layer film structure including a hydrophilic support substrate, a conductive layer and a moisture absorbent layer. The conductive layer is coated on an outer side of the hydrophilic support substrate and has a first section and a second section, and the moisture absorbent layer is coated on the first section of the conductive layer, so that the flexible long-lasting clean energy power generation device is formed into an asymmetrical structure. The moisture absorbent layer captures moisture from the ambient environmental humidity, and the moisture forms a capillary pressure difference by a capillary action and an evaporation, so that water molecules and ions move from the wet area of the moisture absorbent layer to the dry area of the second section to form an electric potential difference.

Disclosed herein are cell holders for holding a plurality of battery cells, each cell holder including a body, said body having an upper surface, a lower surface, and a plurality of through openings, wherein each through opening extends between the upper surface and the lower surface and is arranged to receive a battery cell, wherein in each through opening a deformable member is protruding in the through opening in a direction which is perpendicular to the direction of extension of the through opening to thereby decrease the diameter of the through opening such that the diameter of the through opening in the plane in which the deformable member is protruding is smaller than the outer diameter of the battery cell.

A vehicular battery case includes inner and outer bottom plate portions, a lower frame, and a frame body. The outer bottom plate portion is on a lower side of the inner bottom plate portion. The lower frame is between the inner and outer bottom plate portions. The frame body stands upward from outer peripheral portions of the inner and outer bottom plate portions. The frame body includes a lower portion including a first joint surface joined to the inner bottom plate portion and a second joint surface on an outer side of the first joint surface and joined to the outer bottom plate portion. The lower frame includes an upper end portion including a first flange portion including an upper surface facing a lower surface of the inner bottom plate portion. The first flange portion is joined to the lower surface of the inner bottom plate portion.

A vehicular battery case includes inner and outer bottom plate portions, a lower frame, and a frame body. The outer bottom plate portion is on a lower side of the inner bottom plate portion. The lower frame is between the inner and outer bottom plate portions. The frame body stands upward from outer peripheral portions of the inner and outer bottom plate portions. The frame body includes a lower portion including a first joint surface joined to the inner bottom plate portion and a second joint surface on an outer side of the first joint surface and joined to the outer bottom plate portion. The lower frame includes an upper end portion including a first flange portion including an upper surface facing a lower surface of the inner bottom plate portion. The first flange portion is joined to the lower surface of the inner bottom plate portion.