The invention relates to an aerosol generation system comprising an aerosol generation device having a heating element and a consumable for use with the aerosol generation device. The heat transfer element can be heated by the heating element of the aerosol generation device when the consumable is attached to the aerosol generation device. The heat transfer element is configured to be deformed when its temperature is at or above a threshold temperature, such that an area of contact, which exists between the heating element and the heat transfer element when the consumable is attached to the aerosol generation device and the temperature of the heat transfer element is below the threshold temperature, can be reduced, or eliminated.

An actuator, a release device, and a method of actuating a release device are provided. The actuator comprises a housing defining a first path; an actuating element disposed within the first path, the actuating element being made from a shape memory alloy having a transition temperature, the actuating element being configured to couple with a power source, at least portion of the actuating element being further configured to not change shape when the power source applies a first current for a predetermined amount of time and moves at least a portion of the actuating element from the first position to a second position when the power source applies a second current; and a heat transfer material disposed in the first path between the actuating element and the housing.

A wire release mechanism includes two components with adjacent longitudinal fingers and a wire that is wound about the fingers. The wire restrains one of the components in one position and includes a higher resistance fuse that causes the wire to be loosened about the fingers to allow that component to move to another position due to the flow of electrical current through the fuse.

A wire release mechanism includes two components with adjacent longitudinal fingers and a wire that is wound about the fingers. The wire restrains one of the components in one position and includes a higher resistance fuse that causes the wire to be loosened about the fingers to allow that component to move to another position due to the flow of electrical current through the fuse.

An actuation mechanism used in, for example, a missile assembly is disclosed, as are methods of its use. The actuation mechanism is locked in a first orientation and is unlocked in a second orientation. Locking and unlocking of the actuation mechanism is achieved by way of a locking mechanism that responds to a certain stimulus. In some embodiments, the actuation mechanism is incorporated into a sub-assembly of a missile to assist in controlling the missile's flight.

A mechanical actuator is disclosed. The mechanical actuator can comprise an interface portion configured to interface with an object, a spring configured to exert a force on the interface portion, and a shape memory member coupled to the interface portion. The shape memory member can be configured to fracture at a predetermined temperature range. Upon fracture of the shape memory member, the force of the spring can cause the interface portion to act on the object.

A preload mechanism for an actuator is disclosed that includes a rotating element configured to rotate about a pivot. The preload mechanism also includes a bias element with a first end that is coupled to a second contact point of the rotating element and a second end configured to be pinned relative to the pivot. The bias element has a line of action extending from the second end through the first end. The line of action has an offset distance that is the minimum distance between the line of action and the pivot. The offset distance has a first value when the rotating element is in the first position and a second value when the rotating element is the second position, the second value being smaller than the first value.