An airbag compartment enclosure assembly is disclosed, including a compartment containing an uninflated airbag and a closure device fixed proximate an opening of the compartment. The closure device has an open position allowing expansion of the airbag through the opening and a closed position retaining the uninflated airbag. The closure device includes a first flap extending from a first edge of the opening and a second flap extending from a second, opposing edge of the opening. The first and second flaps are folded over one another in the closed position.

A method for rescue support involves distributing transponder devices to individuals in a geographic region and causing the transponder devices to be activated. If a large-scale emergency situation occurs, a fleet of unmanned aerial vehicles are operated within the geographic region to receive distress signals transmitted by the activated transponder devices. A computer system processes the distress signals to obtain detection data for the individuals, the detection data comprising a location of the respective transponder device and a health status of the respective individual. The computer system generates, based on the location and health status of the respective individual, a prioritization chart for the geographic region, the prioritization chart being indicative of one or more sub-regions to be prioritized for a rescue operation.

A method for rescue support involves distributing transponder devices to individuals in a geographic region and causing the transponder devices to be activated. If a large-scale emergency situation occurs, a fleet of unmanned aerial vehicles are operated within the geographic region to receive distress signals transmitted by the activated transponder devices. A computer system processes the distress signals to obtain detection data for the individuals, the detection data comprising a location of the respective transponder device and a health status of the respective individual. The computer system generates, based on the location and health status of the respective individual, a prioritization chart for the geographic region, the prioritization chart being indicative of one or more sub-regions to be prioritized for a rescue operation.

A device for the inflation of an inflatable life vest, notable in that it includes a storage casing containing at least two cartridges of pressurized gas which are arranged side-by-side and touching one another to form a row, and a release casing comprising at least one striker device that makes it possible, in the event of activation, to puncture each of the said cartridges simultaneously or in succession to release the gas they contain in gaseous form to the outside of the inflation device through at least one orifice made on the release casing, the said storage and release casings being in the overall shape of a flattened hollow parallelepiped and joined together removably and in a manner that is gastight with respect to the gas contained in the said cartridges.

A device for the inflation of an inflatable life vest, notable in that it includes a storage casing containing at least two cartridges of pressurized gas which are arranged side-by-side and touching one another to form a row, and a release casing comprising at least one striker device that makes it possible, in the event of activation, to puncture each of the said cartridges simultaneously or in succession to release the gas they contain in gaseous form to the outside of the inflation device through at least one orifice made on the release casing, the said storage and release casings being in the overall shape of a flattened hollow parallelepiped and joined together removably and in a manner that is gastight with respect to the gas contained in the said cartridges.

The invention relates to an avalanche airbag system (10), which comprises an airbag (14) and a filling device (20) for introducing ambient air into the airbag (14). The filling device (20) comprises a fan (16) with an electric motor (18), a first electric energy storage (22, 40), a second electric energy storage configured as capacitor (24), and a control device (26) for actuating the electric motor (18). The control device (26) is configured to detect an activating of a standby mode of the filling device (20) and, depending on the activating of the standby mode, to effect a charging of the capacitor (24) with electric energy originating from the first energy storage (22, 40). Moreover, the invention relates to a carrying device comprising such an avalanche airbag system (10) as well as a method for operating such an avalanche airbag system (10).

The invention relates to an avalanche airbag system (10), which comprises an airbag (14) and a filling device (20) for introducing ambient air into the airbag (14). The filling device (20) comprises a fan (16) with an electric motor (18), a first electric energy storage (22, 40), a second electric energy storage configured as capacitor (24), and a control device (26) for actuating the electric motor (18). The control device (26) is configured to detect an activating of a standby mode of the filling device (20) and, depending on the activating of the standby mode, to effect a charging of the capacitor (24) with electric energy originating from the first energy storage (22, 40). Moreover, the invention relates to a carrying device comprising such an avalanche airbag system (10) as well as a method for operating such an avalanche airbag system (10).

A snow burial survival mask has an exhaust tube connected to a headgear. An intake port of the exhaust tube is positioned adjacent to a breathing portion of the headgear in order to intake exhaled carbon dioxide (CO2)-rich air. An air pump connected to the exhaust tube pump the exhaled air from the intake port to an exhaust port away from the user's face, extending survival time in a snow burial situation. At least one burial detection sensor such as a motion sensor, light sensor and/or CO2 sensor is configured to activate the air pump based on detection of a burial event.

A snow burial survival mask has an exhaust tube connected to a headgear. An intake port of the exhaust tube is positioned adjacent to a breathing portion of the headgear in order to intake exhaled carbon dioxide (CO2)-rich air. An air pump connected to the exhaust tube pump the exhaled air from the intake port to an exhaust port away from the user's face, extending survival time in a snow burial situation. At least one burial detection sensor such as a motion sensor, light sensor and/or CO2 sensor is configured to activate the air pump based on detection of a burial event.

The invention relates to a carrying device, in particular a backpack (10), for an avalanche airbag system (12), which includes an airbag (14) and a filling device (16) for introducing at least one medium into the airbag (14). The airbag (14) brought into a stowage position is received in a container (18) if the avalanche airbag system (12) is coupled to the carrying device. The container (18) comprises a closure element (34). After opening the closure element (34), the container (18) can be brought from a closed position into an open position. The carrying device includes at least one spring element, which is tensioned if the container (18) is brought into the closed position, and by means of which bringing the container (18) from the closed position into the open position can be effected. The closure element (34) can be opened by actuating an actuating device (28), by means of which the filling device (16) can be brought into a triggered state. In the triggered state, the filling device (16) introduces the at least one medium into the airbag (14).