Damping air spring and shock absorber combination for heavy-duty vehicle axle/suspension systems

What is claimed is: 1. A damping air spring and shock absorber combination for heavy-duty vehicle axle/suspension systems comprising: a damping air spring operatively attached to said axle/suspension system, and shock absorber means operatively attached to said axle/suspension system, said shock absorber means being separate from said damping air spring, said damping air spring primarily providing damping to the axle/suspension system over a first critical range of frequencies and said shock absorber means primarily providing damping to the axle/suspension system over a second range of critical frequencies, said first range of critical frequencies and said second range of critical frequencies being different from one another, whereby the shock absorber means optimizes said damping over the first and second ranges of critical frequencies. 2. The damping air spring and shock absorber combination for heavy-duty vehicle axle/suspension systems of claim 1 , wherein said first critical range of frequencies is from about 0.0 Hz to about 6.0 Hz. 3. The damping air spring and shock absorber combination for heavy-duty vehicle axle/suspension systems of claim 1 , wherein said second range of critical frequencies is from about 0.0 Hz to about 13 Hz. 4. The damping air spring and shock absorber combination for heavy-duty vehicle axle/suspension systems of claim 1 , wherein said second range of critical frequencies is greater than about 6.0 Hz. 5. The damping air spring and shock absorber combination for heavy-duty vehicle axle/suspension systems of claim 4 , said piston chamber comprising an external reservoir located outside of said air spring. 6. The damping air spring and shock absorber combination for heavy-duty vehicle axle/suspension systems of claim 4 , said piston chamber being located within a piston of said air spring. 7. The damping air spring and shock absorber combination for heavy-duty vehicle axle/suspension systems of claim 4 , said at least one opening having a cross-sectional area of from about 0.039 in. 2 to about 0.13 in. 2 . 8. The damping air spring and shock absorber combination for heavy-duty vehicle axle/suspension systems of claim 7 , wherein the ratio of a cross-sectional area of said at least one opening measured in in. 2 to the volume of said piston chamber measured in in. 3 to a volume of said bellows chamber measured in in. 3 is in the range of ratios of from about 1:600:1200 to about 1:14100:23500. 9. The damping air spring and shock absorber combination for heavy-duty vehicle axle/suspension systems of claim 4 , said piston chamber having a volume of from about 150 in. 3 to about 550 in. 3 . 10. The damping air spring and shock absorber combination for heavy-duty vehicle axle/suspension systems of claim 4 , said bellows chamber having a volume of from about 305 in. 3 to about 915 in. 3 . 11. The damping air spring and shock absorber combination for heavy-duty vehicle axle/suspension systems of claim 1 , said shock absorber means including a blow off valve that generates reduced damping across all frequencies. 12. The damping air spring and shock absorber combination for heavy-duty vehicle axle/suspension systems of claim 1 , said damping air spring further comprising a bellows chamber and a piston chamber, said bellows chamber being in fluid communication with said piston chamber via at least one opening. 13. A method for providing damping for heavy-duty vehicle axle/suspension systems comprising: providing a damping air spring operatively attached to a heavy-duty vehicle axle/suspension system, and providing shock absorber means operatively attached to said axle/suspension system, said shock absorber means being separate from said damping air spring, said damping air spring primarily providing damping to the axle/suspension system over a first critical range of frequencies and said shock absorber means primarily providing damping to the axle/suspension system over a second range of critical frequencies, said first range of critical frequencies and said second range of critical frequencies being different from one another, whereby the shock absorber means optimizes said damping over the first and second ranges of critical frequencies.