Embodiments of the present application provide a sleeve assembly, a cover plate assembly, a battery, and an electricity-consuming apparatus. The sleeve assembly is used for sealing a through hole. The sleeve assembly includes: a sleeve with an opening on at least one end; a nail body including a body portion. The size of the body portion is larger than the size of the barrel diameter of the sleeve. The body portion is configured to be inserted into the sleeve through the opening and press the inner wall of the sleeve after the sleeve is inserted into the through hole in the axial direction so as to form a protrusion for riveting the sleeve to the through hole on the outer wall of the sleeve.

A button cell and an electronic device relate to the technical field of batteries. The button cell includes a housing (10) and a cover assembly (20); the housing includes a bottom wall (11) and an annular side wall (12); the cover assembly includes a top cover (21) having a through hole at its central area and a conductive member (22) covering the through hole; an outer edge of the top cover (21) is welded with a top of the side wall (12) to form an accommodating chamber (101) for accommodating an electrode assembly (30) and an electrolyte; and the conductive member (22) is disposed on a side of the top cover (21) facing the accommodating chamber (101), and the electronic device includes the button cell.

A button cell and an electronic device relate to the technical field of batteries. The button cell includes a housing (10) and a cover assembly (20); the housing includes a bottom wall (11) and an annular side wall (12); the cover assembly includes a top cover (21) having a through hole at its central area and a conductive member (22) covering the through hole; an outer edge of the top cover (21) is welded with a top of the side wall (12) to form an accommodating chamber (101) for accommodating an electrode assembly (30) and an electrolyte; and the conductive member (22) is disposed on a side of the top cover (21) facing the accommodating chamber (101), and the electronic device includes the button cell.

The present disclosure relates to a top cover for a battery which belongs to the technical field of batteries, comprising: a top cover body; a liquid injection hole formed in the top cover body and having a first side face; a sealing pin accommodated in the liquid injection hole and having a second side face, wherein the first side face is parallel to the second side face, there exists a gap between the first side face and the second side face; and a welding part connecting the sealing pin and the top cover body, and filling at least part of the gap.

The present disclosure relates to a top cover for a battery which belongs to the technical field of batteries, comprising: a top cover body; a liquid injection hole formed in the top cover body and having a first side face; a sealing pin accommodated in the liquid injection hole and having a second side face, wherein the first side face is parallel to the second side face, there exists a gap between the first side face and the second side face; and a welding part connecting the sealing pin and the top cover body, and filling at least part of the gap.

The present disclosure discloses a cover body assembly of a battery and a battery. The battery includes a housing provided with an opening; a cover body assembly used for closing the opening; and a jelly-roll arranged inside an inner cavity of the housing; a liquid injection channel is arranged on the cover body assembly; electrolyte is injected into the inner cavity of the housing through the liquid injection channel, thus soaking the jelly-roll; the cover body assembly includes a cover body; and a lower insulation plate which is connected to a bottom surface of the cover body and is disposed at an interval, thus forming a distribution channel between the lower insulation plate and the cover body; and the distribution channel is communicated to the liquid injection channel and the inner cavity of the housing.

Provided is a technology to suppress a decrease in airtightness around a liquid injection port of a secondary battery. A secondary battery disclosed here has a lid having a liquid injection port, a resin washer attached to the liquid injection port, and a sealing member. The sealing member has a sleeve inserted into the liquid injection port and a flange extending from the sleeve along an outer surface of the lid in an outer diameter direction. The resin washer is installed in the liquid injection port and is sandwiched between the flange and the outer surface of the lid. A protrusion protruding toward the outer surface of the lid is provided at a radial intermediate portion of the flange. A restricting portion that restricts an outer edge of the resin washer is provided in the lid or the sealing member.

A miniature electrochemical cell of a secondary chemistry having a total volume that is less than 0.5 cc is described. Before the present invention, miniature secondary electrochemical cells have been known to experience undesirable open circuit voltage discharge during their initial 21-day aging period. It is believed that electrolyte permeating through the cathode active material and an intermediate carbonaceous coating contacting the titanium base plate of the casing is the source of the undesirable discharge. To ameliorate this, aluminum is contacted to the inner surface of the base plate inside the casing. While aluminum is resistant to the corrosion reaction that is believed to be the mechanism for degraded open circuit voltage in miniature secondary electrochemical cells containing lithium, it is not biocompatible. This means that titanium is still a preferred material for the casing parts including the base plate that might be exposed to body fluids, and the like.

A miniature electrochemical cell of a secondary chemistry having a total volume that is less than 0.5 cc is described. Before the present invention, miniature secondary electrochemical cells have been known to experience undesirable open circuit voltage discharge during their initial 21-day aging period. It is believed that electrolyte permeating through the cathode active material and an intermediate carbonaceous coating contacting the titanium base plate of the casing is the source of the undesirable discharge. To ameliorate this, aluminum is contacted to the inner surface of the base plate inside the casing. While aluminum is resistant to the corrosion reaction that is believed to be the mechanism for degraded open circuit voltage in miniature secondary electrochemical cells containing lithium, it is not biocompatible. This means that titanium is still a preferred material for the casing parts including the base plate that might be exposed to body fluids, and the like.

The herein-disclosed sealed battery includes a sealing plate, a sealing plug comprising a flange part opposed to an outer surface of the sealing plate, and a sealing member disposed between the sealing plate and the flange part of the sealing plug. Then, regarding the herein-disclosed sealed battery, the outer surface of the sealing plate and an opposed surface of the flange part include a rough surface area R on at least a part of a portion contacting with the sealing member and an arithmetic average roughness Sa of the rough surface area is equal to or more than 1 μm. By doing this, it is possible to suppress a liquid leakage of an electrolyte.