Fracturing shape memory mechanical actuators and systems

What is claimed is: 1. A mechanical actuator, comprising: an interface portion configured to interface with an object; a spring positioned adjacent the interface portion, the spring comprising a shape memory alloy having a pre-determined transition temperature; and a shape memory member having one end coupled to the interface portion and having a transition temperature the same or similar to the transition temperature of the spring, wherein the shape memory member comprises a stress concentrator to provide a fracture locus, and wherein, upon reaching the transition temperature, the shape memory member fractures and the spring exerts a force on the interface portion to act on the object. 2. The mechanical actuator of claim 1 , wherein the spring is present in an uncompressed state until reaching the transition temperature. 3. The mechanical actuator of claim 1 , wherein the spring is disposed within the shape memory member. 4. The mechanical actuator of claim 1 , wherein the shape memory member is strained between about 1% and about 12% in the martensite phase. 5. The mechanical actuator of claim 1 , further comprising a heat source to elevate a temperature of the shape memory member to the transition temperature. 6. The mechanical actuator of claim 1 , further comprising a static spring seat and a dynamic spring seat configured to interface with the spring, wherein, prior to fracture, the shape memory member supports the dynamic spring seat relative to the static spring seat, and the spring is disposed between the static spring seat and the dynamic spring seat and configured to move the dynamic spring seat relative to the static spring seat upon fracture of the shape memory member. 7. The mechanical actuator of claim 6 , wherein the dynamic spring seat is associated with the interface portion. 8. The mechanical actuator of claim 1 , wherein the spring is disposed about an exterior of the shape memory member. 9. The mechanical actuator of claim 1 , wherein the spring is disposed at least partially within the shape memory member. 10. The mechanical actuator of claim 1 , wherein the shape memory member is in a deformed shape and wherein the application of heat to the shape memory member is configured to return the shape memory member to an original shape of the shape memory member, and wherein the shape memory member is prevented from returning to the original shape. 11. The mechanical actuator of claim 1 , further comprising a shape memory member restrainer to facilitate fracture of the shape memory member by preventing the shape memory member from returning to an original shape of the shape memory member. 12. The mechanical actuator of claim 11 , wherein the shape memory member restrainer is configured to be disposed at least partially within the shape memory member. 13. The mechanical actuator of claim 11 , wherein the shape memory member restrainer is configured to at least partially surround the shape memory member. 14. The mechanical actuator of claim 1 , further comprising an outer housing disposed at least partially about the spring and the shape memory member. 15. The mechanical actuator of claim 14 , wherein the outer housing comprises an opening configured to facilitate movement of the interface portion to act on the object located external to the outer housing. 16. The mechanical actuator of claim 1 , further comprising a safety lockout mechanism to prevent movement of the interface portion upon fracture of the shape memory member, the safety lockout mechanism comprising: a sleeve disposed about and slidable relative to a housing of the mechanical actuator; a safety spring disposed about the housing to resist movement of the sleeve; and first and second balls moveable to provide a mechanical interference to movement of the shape memory member. 17. A mechanical actuator system, comprising: an object; and a mechanical actuator, having an interface portion configured to interface with the object, a spring positioned adjacent the interface portion, the spring comprising a shape memory alloy having a pre-determined transition temperature; and a shape memory member having one end coupled to the interface portion and having a transition temperature the same or similar to the transition temperature of the spring, wherein the shape memory member comprises a stress concentrator to provide a fracture locus, and wherein upon reaching the transition temperature, the shape memory member fractures and the spring exerts a force on the interface portion to act on the object. 18. A method for facilitating mechanical actuation of an object, comprising: providing a mechanical actuator having an interface portion configured to interface with an object, a spring positioned adjacent the interface portion, the spring comprising a shape memory alloy having a pre-determined transition temperature, and a shape memory member coupled to the interface portion and having a transition temperature the same or similar to the transition temperature of the spring; and facilitating fracture of the shape memory member and activation of the spring at the transition temperature, wherein upon fracture of the shape memory member, the force of the spring causes the interface portion to act on the object. 19. The method of claim 18 , wherein the mechanical actuator further comprises a heat source to elevate a temperature of the shape memory member to a predetermined temperature-range.