Energy absorbers including shape memory alloy particles

The invention claimed is: 1. An energy absorber, comprising: a structure defining a hollow interior portion; a working volume defined in at least a portion of the hollow interior portion; and shape memory alloy (SMA) particles positioned within the working volume, the SMA particles having an Austenite finish temperature (A f ) that is lower than a temperature encountered in an application in which the energy absorber is used so that the SMA particles exhibit stress-induced superelasticity, wherein at least some of the SMA particles are solid. 2. The energy absorber as defined in claim 1 wherein: the structure is a reactor; the energy absorber further comprises an actuator having a first portion, a second portion operatively connected to the first portion and to forcefully communicate with at least a portion of the SMA particles, and an extension piece operatively connected to the second portion and positioned at least partially in the working volume; and the working volume is further defined between an exterior surface of the extension piece of the actuator and an interior surface of the reactor. 3. The energy absorber as defined in claim 2 wherein the reactor is a valve and the actuator is a piston assembly including a piston rod as the first portion and a piston head as the second portion. 4. The energy absorber as defined in claim 2 wherein the first portion of the actuator is positioned to be exposed to an excitation source. 5. An energy absorber, comprising: a structure defining a hollow interior portion, wherein the structure is a cylinder having radial vanes extending radially inward from a wall of the cylinder; a working volume defined in at least a portion of the hollow interior portion; shape memory alloy (SMA) particles positioned within the working volume, the SMA particles having an Austenite finish temperature (A f ) that is lower than a temperature encountered in an application in which the energy absorber is used so that the SMA particles exhibit stress-induced superelasticity; and a rod with impeller blades positioned within the cylinder; wherein the working volume is defined between the cylinder and the rod. 6. The energy absorber as defined in claim 1 wherein: the structure is a reactor; the energy absorber further comprises an actuator having a first portion and a second portion operatively connected to the first portion and to forcefully communicate with at least a portion of the SMA particles; and the working volume is further defined between an SMA particle facing surface of the second portion of the actuator and an interior surface of the reactor. 7. The energy absorber as defined in claim 6 wherein the reactor is a valve and the actuator is a piston assembly including a piston rod as the first portion and a piston head as the second portion. 8. The energy absorber as defined in claim 1 wherein some of the SMA particles are hollow. 9. The energy absorber as defined in claim 8 wherein the SMA particles have a distribution of wall thicknesses. 10. The energy absorber as defined in claim 1 wherein the SMA particles are spherical, randomly shaped, or combinations thereof. 11. The energy absorber as defined in claim 1 wherein the SMA particles have a distribution of sizes. 12. The energy absorber as defined in claim 1 wherein the SMA particles are suspended in a fluid incorporated into the structure. 13. The energy absorber as defined in claim 1 wherein the working volume is defined in the entire hollow interior portion. 14. The energy absorber as defined in claim 13 wherein the structure has opposed ends that abut the hollow interior portion, and wherein the energy absorber further comprises a resilient wall sealingly connected to each of the opposed ends, and wherein one of the opposed ends acts as an actuator to forcefully communicate with at least some of the SMA particles. 15. The energy absorber as defined in claim 1 wherein the SMA particles absorb periodic vibration within a range from about 1 hertz to about 200 hertz. 16. The energy absorber as defined in claim 1 wherein the SMA particles absorb random vibration. 17. The energy absorber as defined in claim 1 wherein the SMA particles have surface irregularities. 18. The energy absorber as defined in claim 1 wherein the SMA particles are cylinders, irregularly shaped, or combinations thereof.