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.

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.

Embodiments of the present invention provide a method, computer program product, and a computer system for automated deployment of autonomous devices performing localized environment altering actions. A set of weather conditions for a region is received. Based on the weather conditions predicting the weather in the region is likely to have a negative effect on at least one living organism in the region. Then dispatching, one or more autonomous devices to the region, wherein the one or more autonomous devices comprise a set of sensors and at least one temperature altering element. The autonomous devices is directed to a first location of the first living organism, based, at least in part on a set of data received from the set of sensors. The autonomous devices is directed to alleviate at least a portion of the negative effect of the temperature to the first living organism.

Embodiments of the present invention provide a method, computer program product, and a computer system for automated deployment of autonomous devices performing localized environment altering actions. A set of weather conditions for a region is received. Based on the weather conditions predicting the weather in the region is likely to have a negative effect on at least one living organism in the region. Then dispatching, one or more autonomous devices to the region, wherein the one or more autonomous devices comprise a set of sensors and at least one temperature altering element. The autonomous devices is directed to a first location of the first living organism, based, at least in part on a set of data received from the set of sensors. The autonomous devices is directed to alleviate at least a portion of the negative effect of the temperature to the first living organism.

An emergency vision device includes an enclosed housing having a first end and a second end; first and second clear members disposed at the first and second ends, respectively; the housing including a plurality of wall panels joined side-to-side, the wall panels being foldable; and a loop of spring wire is operably associated with each of at least two of the wall panels.

An emergency vision device includes an enclosed housing having a first end and a second end; first and second clear members disposed at the first and second ends, respectively; the housing including a plurality of wall panels joined side-to-side, the wall panels being foldable; and a loop of spring wire is operably associated with each of at least two of the wall panels.

Methods, computer-readable media, and breathing equipment training devices for simulated resource depletion calculation. The breathing equipment training device includes a shell including an opening, a sensor connected to the shell, and a controller connected to the shell and operably connected to the sensor. The controller is configured to calculate, based on inputs from the sensor, a flowrate of air entering the breathing equipment training device through the opening of the shell and calculate an amount of depletion of a simulated resource for a duration of time based on the calculated flowrate of air entering the opening of the shell. The controller is configured to identify a current status of the simulated resource based on the calculated resource depletion amount and a prior status of the simulated resource identified prior to the duration of time and generate a feedback signal indicating the current status of the simulated resource.

The present invention relates to a clock-type disaster preparedness kit. More particularly, the present invention relates to a clock-type disaster preparedness kit in which a clock is integrated with a configuration for storing disaster preparedness goods such that a location of the disaster preparedness goods is easily recognized whereby it is possible to request rescue promptly in an emergency. Accordingly, the present invention provides the clock-type disaster preparedness kit, the kit including: a housing provided with a storage space in which a first portion and a second portion thereof are engaged with each other; a clock provided on an outer surface of the housing and showing time; a storing portion provided in the second portion of the housing and storing disaster preparedness goods; and a coupling member coupling the first portion and the second portion of the housing to combine the housing.

The present invention relates to a clock-type disaster preparedness kit. More particularly, the present invention relates to a clock-type disaster preparedness kit in which a clock is integrated with a configuration for storing disaster preparedness goods such that a location of the disaster preparedness goods is easily recognized whereby it is possible to request rescue promptly in an emergency. Accordingly, the present invention provides the clock-type disaster preparedness kit, the kit including: a housing provided with a storage space in which a first portion and a second portion thereof are engaged with each other; a clock provided on an outer surface of the housing and showing time; a storing portion provided in the second portion of the housing and storing disaster preparedness goods; and a coupling member coupling the first portion and the second portion of the housing to combine the housing.

Embodiments in the present description are provided for a Bi-pod rescue strut system for use in stabilizing a vehicle or other object. The Bi-pod rescue strut system includes stabilizing feet and support legs. Each of the stabilizing feet is pivotally connected to an end of each support leg so that the stabilizing feet rotate around the support legs. The Bi-pod rescue strut system further includes a yoke disposed at an end of the support legs. The yoke permits the support legs to extend and retract towards or away from the other support leg. The yoke connecting to a telescoping strut extension. The telescopic strut extension extending and coming into contact with vehicle or other object, stabilizing the vehicle or other object.