The invention provides an automated batch sample preparation method for button battery, comprising the following steps: preparing an electrolyte and elements of different specifications, presetting an injection amount of a liquid injection component, scanning and recording the identification information of the elements by a scanning component, grabbing the elements onto a sealing component, injecting the electrolyte into the elements on the sealing component, sealing the elements as a button battery by the sealing component, removing the button battery, then repeat the above steps. The automated batch sample preparation method for button battery provided by the invention has the advantages of high automation degree, simple operation, high-precision assembly and high efficiency. The injection amount can be adjusted and controlled, and button batteries with different specifications can be produced in batch. The information recorded by the scanning component can facilitate the optimization of the process.

The invention provides an automated batch sample preparation method for button battery, comprising the following steps: preparing an electrolyte and elements of different specifications, presetting an injection amount of a liquid injection component, scanning and recording the identification information of the elements by a scanning component, grabbing the elements onto a sealing component, injecting the electrolyte into the elements on the sealing component, sealing the elements as a button battery by the sealing component, removing the button battery, then repeat the above steps. The automated batch sample preparation method for button battery provided by the invention has the advantages of high automation degree, simple operation, high-precision assembly and high efficiency. The injection amount can be adjusted and controlled, and button batteries with different specifications can be produced in batch. The information recorded by the scanning component can facilitate the optimization of the process.

An electric tool includes a body portion, a grip portion, and a battery pack. The body portion includes: a tool attachment member to which a tool is attached; a driving unit to drive the tool; and a transmission unit to transmit driving force of the driving unit to the tool. The grip portion is provided for the body portion and includes a gripping part to be held by a user with his or her hand. The battery pack supplies power to the driving unit. The battery pack includes an all-solid-state battery.

An electric tool includes a body portion, a grip portion, and a battery pack. The body portion includes: a tool attachment member to which a tool is attached; a driving unit to drive the tool; and a transmission unit to transmit driving force of the driving unit to the tool. The grip portion is provided for the body portion and includes a gripping part to be held by a user with his or her hand. The battery pack supplies power to the driving unit. The battery pack includes an all-solid-state battery.

Disclosed is a battery pack having improved waterproofing performance. The battery pack includes a plurality of secondary batteries; a connector including a connection terminal configured to receive electricity from an external device or to supply power to an outside of the battery pack, and an electrically insulating body surrounding a portion of the connection terminal; a pack housing having an inner space in which the plurality of secondary batteries are accommodated and having an insert hole so that at least a part of the body of the connector is inserted therein; and a connector gasket interposed between the insert hole and the connector and having a portion that is bent at least once in one direction, the connector gasket being at least partially compressed and fixed by inserting the connector into the insert hole.

This solid-state lithium ion rechargeable battery includes a laminated body which includes a positive electrode layer, a negative electrode layer, and a solid electrolyte sandwiched between the positive electrode layer and the negative electrode layer, and a liquid repellent film which is provided to be in contact with the laminated body, in which the liquid repellent film contains a fluorine element and a carbon element, and has a contact angle of 30° or more when an acetic acid aqueous solution is dropped thereon.

A battery pack includes a battery cell and a casing configured to receive the battery cell. The casing has a vent configured to allow gas generated in the battery cell to be discharged therethrough, and a sound generator installed in the vent so as to block the vent hole. The sound generator is configured to allow the gas to pass therethrough, and generate a sound by the flow of the gas when the gas is discharged from the casing through the vent hole.

A battery pack includes a battery cell and a casing configured to receive the battery cell. The casing has a vent configured to allow gas generated in the battery cell to be discharged therethrough, and a sound generator installed in the vent so as to block the vent hole. The sound generator is configured to allow the gas to pass therethrough, and generate a sound by the flow of the gas when the gas is discharged from the casing through the vent hole.

An apparatus for shipping or storage of Li-ion batteries comprises a sealable outer bag fabricated from heat-resistant, permeable fabric, a first flexible thermal runaway shield (“TRS”) fabricated from low-permeability film configured to line a first inside surface of the outer bag, a second flexible TRS fabricated from low-permeability film configured to line a second inside surface of the outer bag, and at least one Li-ion battery configured to be disposed between the first flexible TRS and the second TRS of the sealable outer bag to provide a sealed outer bag.

An apparatus for shipping or storage of Li-ion batteries comprises a sealable outer bag fabricated from heat-resistant, permeable fabric, a first flexible thermal runaway shield (“TRS”) fabricated from low-permeability film configured to line a first inside surface of the outer bag, a second flexible TRS fabricated from low-permeability film configured to line a second inside surface of the outer bag, and at least one Li-ion battery configured to be disposed between the first flexible TRS and the second TRS of the sealable outer bag to provide a sealed outer bag.