An end cover assembly, an energy-storage apparatus, and an electricity-consumption device are provided. The end cover assembly is for an energy-storage apparatus and includes a top cover, a sealing cap, and an annular welding portion. The top cover has a first surface and further defines a liquid-injection hole extending through the first surface. The first surface includes a first sub-surface and a second sub-surface connected to the first sub-surface, the first sub-surface is around the liquid-injection hole, the second sub-surface is around a periphery of the first sub-surface, and roughness of the first sub-surface is greater than roughness of the second sub-surface. The sealing cap seals the liquid-injection hole and is connected to the top cover. The annular welding portion is located at a junction between the sealing cap and the top cover. The top cover is further provided with a first welding mark and a second welding mark.

The present invention relates to a secondary battery. The secondary battery comprises: an electrode assembly having a through-hole; and a battery case accommodating the electrode assembly and having a through-type opening into which the through-hole is inserted, wherein the battery case comprises: a lower case comprising an accommodation part accommodating the electrode assembly and a lower inner sealing part having the through-type opening into which the through-hole is inserted; and an upper case comprising a cover part coupled to an upper portion of the lower case to finish the accommodation part and an upper inner sealing part having a coupling hole to which a front end of the lower inner sealing part is coupled.

Disclosed herein are a positive electrode active material including at least one selected from among compounds represented by Formula 1 below and a lithium secondary battery including the same that is capable of improving lifetime characteristics and rate characteristics while exhibiting excellent safety: xLi.sub.2M.sub.yMn.sub.(1-y)O.sub.3-zA.sub.z*(1x)LiMO.sub.2-zA.sub.z (1), where M is at least one element selected from a group consisting of Ru, Mo, Nb, Te, Re, Ir, Pt, Cr, S, W, Os, and Po, M is at least one element selected from a group consisting of Ni, Ti, Co, Al, Mn, Fe, Mg, B, Cr, Zr, Zn, and second row transition metals, A and A are each independently a negative monovalent or divalent anion, and 0<x<1, 0.3<y<1, 0z<0.5, and 0z<0.5.

Temperature conditioning unit according to the present invention includes: impeller, electric motor, fan case, and housing. Impeller includes impeller disk and a plurality of rotor blades. The plurality of rotor blades extends in a direction along rotary shaft. Each of the plurality of rotor blades has a cross-sectional circular-arc shape, in a direction intersecting rotary shaft, which is a convex form curving outward toward a direction of rotation of impeller disk. Each of the plurality of rotor blades includes an inner-periphery-side edge located on the rotary shaft side, and an outer-periphery-side edge located on the opposite rotary-shaft side. Housing includes external surface on which fan case is mounted. In the inside of housing, a member to be temperature conditioned is accommodated.

A battery having flat, stacked, anode and cathode layers. The battery can be adapted to fit within an implantable medical device.

A bridge link battery interface for a helmet accessory mounting system includes a housing enclosing a circuit and an electrical and mechanical coupling interface structured and operable to connect to an attachment point on the helmet accessory mounting system. A first battery interface is configured for detachable coupling to a first battery pack and a second battery interface configured for detachable coupling to a second battery pack. First and second electrical connector assemblies are disposed on the housing and electrically coupled to the circuit, wherein the circuit is operable to selectively electrically couple the first and second battery interfaces to the first and second electrical connector assemblies.

The present disclosure provides an energy storage apparatus and a power-consuming device. The energy storage apparatus includes an electrode assembly, a connector, and an end cover assembly. The end cover assembly includes a pole assembly, a top cover, a stimulus-response member, and an explosion-proof assembly. The pole assembly includes a metal block, where the metal block is electrically connected to the connector, and the metal block has a preset surface. The top cover is disposed at an interval with the preset surface of the metal block, where the top cover defines a through hole and an explosion-proof hole arranged at an interval with each other, and an orthographic projection of the through hole on the preset surface falls within a range of the preset surface.

An implantable medical device comprising a battery cell including: an anode; a cathode including fluorinated carbon particles; a separator between the anode and the cathode; and an electrolyte contacting the anode, the cathode, and the separator; wherein greater than 50 vol-% of the fluorinated carbon particles have a particle size within a range of 2 microns to 10 microns, and greater than 50% by number have an aspect ratio within a range of 1:1.2 to 1:8.

A battery module according to one embodiment of the present disclosure includes a battery cell stack in which a plurality of battery cells are stacked, a module frame that surrounds the battery cell stack, and a first heat transfer member and a second heat transfer member located on the bottom portion of the module frame, wherein the second heat transfer member is formed on an outer shell portion of the first heat transfer member.

In one aspect, an energy storage device comprises one or more organic electrodes comprising one or more melanin-based energy storage materials and cations, with the one or more melanin-based energy storage materials reversibly binding the cations while the biocompatible energy storage device is in an inactive state, and the one or more melanin-based energy storage materials releasing the cations to provide energy while the energy storage device is in an active state.