Compliant elastomeric shock absorbing apparatus

What is claimed is: 1. A shock absorbing apparatus comprising: a flexible membrane defining an accumulator cavity containing a viscous incompressible hydraulic fluid, the flexible membrane being deformable in response to a transmitted impact load; a compression assembly disposed within the accumulator cavity and coupled to the flexible membrane, the compression assembly including a shock tube and a reciprocating piston which, in combination, define a rigid compression cavity, the compression assembly operative to: (i) develop a first pressure differential, in response to the application of the transmitted impact load, to displace a quantity of the viscous hydraulic fluid through at least one damping orifice of the shock tube from the rigid compression cavity to the accumulator cavity, and (ii) develop a second pressure differential to restore the viscous hydraulic fluid from the accumulator cavity to the rigid compression cavity and wherein the compression assembly further comprises: a valve mechanism: (i) disposed in combination with the reciprocating piston, (ii) providing a conduit between the accumulator cavity and the rigid compression cavity, and (iii) responsive to one of the first and second differentials in the accumulator cavity and the rigid compression cavity to restrict or permit flow of viscous fluid through the conduit. 2. The shock absorbing apparatus of claim 1 , wherein the flexible membrane is an elastomeric material selected from the group consisting of: natural rubber, butyl rubber, fluoroelastomer, fluorosilicone, silicone, ethylene propylene (EPDM) and polyurethane. 3. The shock absorbing apparatus of claim 1 , wherein the flexible membrane includes at least one impact plate that is integrated with the flexible membrane and aligned with the reciprocating piston disposed within the shock tube, the at least one impact plate being configured to receive the transmitted impact load. 4. The shock absorbing apparatus of claim 3 , further comprising: a mounting plate including an aperture for accepting the compression assembly; and a base plate sealably mounting the compression assembly to the mounting plate. 5. The shock absorbing apparatus of claim 4 , wherein the base plate is mounted by a plurality of equiangularly-spaced rivets disposed about the aperture of the mounting plate. 6. The shock absorbing apparatus of claim 4 , wherein the mounting plate includes a threaded sleeve projecting transversely from a plane of the mounting plate, and wherein the base plate includes a threaded sleeve for threadably engaging the threaded sleeve of the mounting plate. 7. The shock absorbing apparatus of claim 1 , wherein the shock tube is sealably affixed to the mounting plate at one end, and includes a tubular wall structure having a constant cross-section internal wall surface, wherein the at least one damping orifice is disposed through the tubular wall structure; wherein the reciprocating piston is slideably mounted within the constant cross-section wall surface, and wherein the valve mechanism includes a check valve inhibiting fluid flow from the rigid compression cavity to the accumulator cavity during the application of the first pressure differential and facilitating fluid flow from the accumulator cavity to the rigid compression cavity during the application of the second pressure differential. 8. The shock absorbing apparatus of claim 1 , further comprising a biasing spring disposed between the stationary guide and the flexible membrane. 9. A shock absorbing apparatus comprising: a flexible membrane defining a compliant accumulator cavity that deforms in response to the application of a transmitted impact load, and is capable of storing and releasing potential energy in response to the application and cessation of the transmitted impact load; a reciprocating piston sealably mounted to the flexible membrane and responsive to the movement of the flexible membrane; a stationary guide slidably supporting the reciprocating piston and forming a compression cavity therebetween, the stationary guide defining at least one damping orifice fluidically connecting the compression cavity and the compliant accumulator cavity, and a conduit formed in combination with one of the reciprocating piston and the stationary guide, the conduit fluidically interconnecting the compliant accumulator cavity and the compression cavity; wherein a first pressure differential is developed between the compression cavity and the compliant accumulator cavity in response to displacement of the reciprocating piston in one direction to displace a viscous fluid through the at least one damping orifice, and a second pressure differential is developed between the compression cavity and the compliant accumulator cavity to restore the viscous fluid from the compliant accumulator cavity to the compression cavity through the conduit. 10. The shock absorbing apparatus according to claim 9 , wherein the conduit is integrated with the reciprocating piston for fluidically connecting the compliant accumulator cavity and the compression cavity. 11. The shock absorbing apparatus according to claim 9 , wherein the conduit includes a valve mechanism configured to inhibit fluid flow from the compression cavity to the compliant accumulator cavity during the application of the first pressure differential within the compression cavity, and facilitating fluid flow from the compliant accumulator cavity to the compression cavity during the application of the second pressure differential within the compression cavity and release of the potential energy of the flexible membrane. 12. The shock absorbing apparatus of claim 9 wherein the flexible membrane is an elastomeric material from the group consisting of: natural rubber, butyl rubber, fluoroelastomer, fluorosilicone, silicone, ethylene propylene (EPDM) and polyurethane. 13. The shock absorbing apparatus of claim 9 , wherein the flexible membrane includes at least one impact plate that is integrated with the flexible membrane and aligned with the reciprocating piston, the at least one impact plate being configured to receive the transmitted impact load. 14. The shock absorbing apparatus of claim 13 , further comprising: a mounting plate including an aperture for accepting the compression assembly; and a base plate sealably mounting the compression assembly to the mounting plate. 15. The shock absorbing apparatus of claim 14 , wherein the base plate is mounted by a plurality of equiangularly-spaced rivets disposed about the orifice of the mounting plate. 16. The shock absorbing apparatus of claim 15 , wherein the mounting plate includes a threaded sleeve projecting orthogonally from the plane of the mounting plate, and wherein the base plate includes a threaded sleeve for threadably engaging the threaded sleeve of the mounting plate. 17. The shock absorbing apparatus of claim 9 , wherein the stationary guide includes: (i) a shock tube sealably affixed to the mounting plate, at one end, and having a tubular wall structure defining a constant cross-section internal wall surface, and (ii) at least one damping orifice disposed through the tubular wall structure, the damping orifice fluidically connecting the compliant accumulator cavity and the compression cavity; and wherein the piston is slideably mounted to the constant cross-section wall surface, the reciprocating piston and the shock tube defining the compression cavity; and wherein the conduit includes a valve mechanism having a check valve: (i) inhibiting fluid flow from the compression cavity