A battery pack includes: a battery cell; one or more shoulder screws having a head portion, a screw portion, and an intermediate portion between the head portion and the screw portion, the intermediate portion being larger than an outer diameter of the screw portion and smaller than an outer diameter of the head portion; and an exterior case including an upper case and a lower case fastened to each other with the one or the plurality of shoulder screws. A first elastic member is disposed in a compressed state at a contact portion between the upper case and the lower case, and a second elastic member is disposed in a compressed state between the head portion and the upper case.

This application discloses a bidirectional vent valve, a battery, and an electrical device. The bidirectional vent valve includes: a valve seat, where the valve seat is configured to form a gas duct, and the gas duct includes a first end and a second end; a bidirectional valve assembly, where the bidirectional valve assembly is movably disposed in the gas duct, and is configured to open or close the gas duct through movement relative to the gas duct; and a first elastic component, configured to exert a force on the bidirectional valve assembly to close the air duct, and, when an air pressure difference between the first end and the second end of the gas duct is greater than a first threshold, the bidirectional valve assembly is configured to overcome the force of the first elastic component to open the gas duct.

This application discloses a bidirectional vent valve, a battery, and an electrical device. The bidirectional vent valve includes: a valve seat, where the valve seat is configured to form a gas duct, and the gas duct includes a first end and a second end; a bidirectional valve assembly, where the bidirectional valve assembly is movably disposed in the gas duct, and is configured to open or close the gas duct through movement relative to the gas duct; and a first elastic component, configured to exert a force on the bidirectional valve assembly to close the air duct, and, when an air pressure difference between the first end and the second end of the gas duct is greater than a first threshold, the bidirectional valve assembly is configured to overcome the force of the first elastic component to open the gas duct.

A supporting base and a relief valve. Relief valve includes valve body, restoring component and plug. Valve body includes first cover plate and first side wall. First cover plate and first side wall together form opening. First side wall includes pressure releasing hole. Vent of casing is connected to opening. Pressure releasing hole is connected to opening. Plug includes second cover plate and second side wall. Second side wall and second cover plate together form recession. Recession is connected to accommodation space via vent. Second cover plate is movably disposed in opening via restoring component. When plug is in initial position, pressure releasing hole is disconnected from accommodation space. When plug is in releasing position, pressure releasing hole is connected to accommodation space via vent.

A supporting base and a relief valve. Relief valve includes valve body, restoring component and plug. Valve body includes first cover plate and first side wall. First cover plate and first side wall together form opening. First side wall includes pressure releasing hole. Vent of casing is connected to opening. Pressure releasing hole is connected to opening. Plug includes second cover plate and second side wall. Second side wall and second cover plate together form recession. Recession is connected to accommodation space via vent. Second cover plate is movably disposed in opening via restoring component. When plug is in initial position, pressure releasing hole is disconnected from accommodation space. When plug is in releasing position, pressure releasing hole is connected to accommodation space via vent.

A marine battery system configured to provide energy to a marine vessel load is provided. The marine battery system includes a main enclosure body and an auxiliary enclosure body that is detachably coupled to the main enclosure body to define a sealed battery volume. The auxiliary enclosure body is configured to perform a pressure accommodation action responsive to an increase in a temperature within the sealed battery volume. The marine battery system further includes a battery disposed within the sealed battery volume.

Provided in the embodiments of the application are a bidirectional pressure relief valve, a battery and an electric device. The bidirectional pressure relief valve includes a valve seat, a first valve element and a second valve element, where the valve seat has a first end and a second end opposite each other, a channel and a partition plate, the channel penetrating the first end and the second end, a first pressure relief hole being provided on the partition plate, and the partition plate being arranged on an inner wall of the channel, and dividing the channel into a first cavity and a second cavity in an axial direction of the channel. The bidirectional pressure relief valve of the application can be applied to the battery to maintain balance between internal pressure and external pressure of the battery.

A vent for an electric vehicle battery pack configured to transition from a venting, open position to a sealed, closed position in the event of a thermal event experienced by the electric vehicle battery pack, thereby trapping the gasses within the electric vehicle battery pack, including a curved disc shaped and sized to selectively seal an aperture defined by the electric vehicle battery pack, the curved disc formed of a first material on a first major surface of the disc, and a second material positioned on an opposing second major surface of the disc, the first material having a larger coefficient of thermal expansion than the second material, such that an increase in temperature above a defined threshold experienced by the curved disc causes the first material to expand more than the second material, thereby transitioning the curved disc from a first equilibrium state to a second equilibrium state.

Provided in the embodiments of the application are a bidirectional pressure relief valve, a battery and an electric device. The bidirectional pressure relief valve includes a valve seat, a first valve element and a second valve element, where the valve seat has a first end and a second end opposite each other, a channel and a partition plate, the channel penetrating the first end and the second end, a first pressure relief hole being provided on the partition plate, and the partition plate being arranged on an inner wall of the channel, and dividing the channel into a first cavity and a second cavity in an axial direction of the channel. The bidirectional pressure relief valve of the application can be applied to the battery to maintain balance between internal pressure and external pressure of the battery.

A rechargeable energy storage system, includes a housing. A plurality of battery cells are disposed in the housing. A discharge vent passage is in communication with the housing, the discharge vent passage including a one-way valve and a nozzle. A chamber is in communication with the nozzle and including an air inlet passage with a one-way valve. An outlet pipe is connected to the chamber. According to an aspect, the air inlet passage of the thermal vent management system is arranged as a Venturi opening adjacent to the nozzle.