A shape memory material activated device of the present invention uses a shape memory material activator to create a path through a shell wall of the device. The path through the shell wall may release a substance contained in the shell or allow a substance to enter the shell. The path may be create
A shape memory material activated device of the present invention uses a shape memory material activator to create a path through a shell wall of the device. The path through the shell wall may release a substance contained in the shell or allow a substance to enter the shell. The path may be created by fracturing, puncturing, exploding, imploding, peeling, tearing, stretching, separating, debonding, abrading or otherwise opening the shell and, may be permanent or reversible. The substance may be released in one location while the device is stationary or along a path while it is traveling, self-powered by the shape memory material activator. In addition, the substance may be delivered to an object upon contact with its surface. The self powering abilities allow these devices to be used as substance delivery devices as well as actuators, transporters, and energy conversion systems with modular characteristics and growth potential. The devices may be armed, prior to the beginning of their service life, to be placed in a state of readiness to release their substances once the path is created. Prior to arming they may be maintained at any temperature, incapable of releasing their substances. The devices according to the present invention may be used as temperature sensors or warning devices, drug delivery devices, and the like.
대표청구항▼
1. A temperature activated device to provide actuation, comprising: an activator made from a shape memory material, the shape memory material being deformable at a first temperature, then recovers its original, undeformed shape upon heating above a second, higher temperature, defining an active stat
1. A temperature activated device to provide actuation, comprising: an activator made from a shape memory material, the shape memory material being deformable at a first temperature, then recovers its original, undeformed shape upon heating above a second, higher temperature, defining an active state of readiness of the activator, the shape memory material activator having an undeformed shape incapable of undergoing shape recovery and being normally unresponsive to temperature changes and defining a dormant state thereby maintaining the undeformed shape regardless of the temperature changes; andmeans for deforming the activator in situ by only a single irreversible action, whereby the device is transformed from the dormant state to an active state of readiness, thereby the shape memory material activator is enabled to undergo shape recovery wherein the activator responds to temperature changes and the device becomes a functioning actuator. 2. A method for arming a temperature activated device, the method comprising the steps of: providing an activator made from a shape memory material, wherein the shape memory material deforms at a first temperature, then recovers its original, undeformed shape upon heating above a second, higher temperature, defining an active state of readiness of the activator, the shape memory material activator having an undeformed shape incapable of undergoing shape recovery and being normally unresponsive to temperature changes and defining a dormant state thereby maintaining the undeformed shape regardless of the temperature changes; anddeforming the activator in situ by only a single irreversible action, whereby the device is transformed from the dormant state to an active state of readiness, thereby the shape memory material activator is enabled to undergo shape recovery wherein the activator responds to temperature changes. 3. An extended temperature responding shape memory material device, comprising: an initially variably deformed shape memory material element having unequally deformed locations thereby responding to different shape recovery temperatures, wherein the non-uniformly deformed locations define least deformed locations and most deformed locations, wherein the shape memory material element undergoes non-uniform shape recovery within a predetermined extended temperature range beginning from the least deformed locations and proceeding to the most deformed locations with increasing temperature.
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