Tube coupling

The invention claimed is: 1. A tube coupling for coupling a first tube and a second tube, the tube coupling comprising: (a) an inner shroud including a ball portion; (b) an outer shroud including a socket portion, the socket portion configured to receive the ball portion; (c) a compressive ring configured to elastically compress the outer shroud onto the inner shroud; (d) a first band configured to couple the inner shroud to the first tube; and (e) a second band configured to couple the outer shroud to the second tube such that the tube coupling is weld-free, wherein the ball portion and the socket portion form a ball and socket joint, the ball and socket joint configured to allow relative angular movement and relative axial movement between the inner shroud and the outer shroud. 2. The tube coupling of claim 1 , wherein the compressive ring is a shape memory alloy or is a hinged ring. 3. The tube coupling of claim 1 , wherein a flow through the first tube and the second tube is not obstructed by an interior of the tube coupling. 4. The tube coupling of claim 1 , the inner shroud further comprising a plurality of radial teeth extending inwardly from an inner surface of the inner shroud, the plurality of radial teeth configured to be swaged into the first tube due to the first band. 5. The tube coupling of claim 1 , the inner shroud further comprising a plurality of openings in the ball portion, the plurality of openings configured to allow flexibility of the ball portion and the outer shroud further comprising a plurality of openings in the socket portion, the plurality of openings configured to allow flexibility of the socket portion, wherein the plurality of openings in the ball portion and the plurality of openings in the socket portion are misaligned to provide a fluid-tight seal. 6. The tube coupling of claim 1 , the outer shroud further comprising a plurality of spring fingers, the plurality of spring fingers configured to allow relative axial movement between the inner shroud and the outer shroud. 7. The tube coupling of claim 6 , wherein each spring finger of the plurality of spring fingers comprise a flat portion and a spring portion, the spring portion being formed of convolutions of crests and valleys and the inner shroud further comprising a longitudinal portion and a plurality of protrusions on the longitudinal portion, wherein the plurality of protrusions are configured to separate adjacent spring fingers of the plurality of spring fingers. 8. The tube coupling of claim 6 , wherein each spring finger of the plurality of spring fingers each has a variable thickness. 9. The tube coupling of claim 6 , wherein each spring finger of the plurality of spring fingers each has a constant thickness. 10. A tube assembly comprising the tube coupling of claim 1 for coupling a first tube to a second tube, the tube assembly further comprising the first tube and the second tube. 11. The tube assembly of claim 10 , wherein the compressive ring is a shape memory alloy or a hinged ring. 12. The tube assembly of claim 10 , wherein a flow through the first tube and the second tube is not obstructed by an interior of the tube coupling. 13. The tube assembly claim 10 , the inner shroud further comprising a plurality of radial teeth extending inwardly from an inner surface of the inner shroud, the plurality of radial teeth configured to be swaged into the first tube due to the first band. 14. The tube assembly of claim 10 , the inner shroud further comprising a plurality of openings in the ball portion, the plurality of openings configured to allow flexibility of the ball portion and the outer shroud further comprising a plurality of openings in the socket portion, the plurality of openings configured to allow flexibility of the socket portion, wherein the plurality of openings in the ball portion and the plurality of openings in the socket portion are misaligned to provide a fluid-tight seal. 15. The tube assembly of claim 10 , the outer shroud further comprising a plurality of spring fingers, the plurality of spring fingers configured to allow relative axial movement between the inner shroud and the outer shroud. 16. The tube assembly of claim 15 , wherein the plurality of spring fingers comprise a flat portion and a spring portion, the spring portion being formed of convolutions of crests and valleys and the inner shroud further comprising a longitudinal portion and a plurality of protrusions on the longitudinal portion, wherein the plurality of protrusions are configured to separate adjacent spring fingers of the plurality of spring fingers. 17. The tube assembly of claim 15 , wherein each spring finger of the plurality of spring fingers each has a variable thickness. 18. The tube assembly of claim 15 , wherein each spring finger of the plurality of spring fingers each has a constant thickness. 19. A tube coupling for coupling a first tube and a second tube, the tube coupling comprising: (a) an inner shroud including a ball portion and a plurality of openings in the ball portion, the plurality of openings configured to allow flexibility of the ball portion; (b) an outer shroud including a socket portion and a plurality of openings in the socket portion, the plurality of openings configured to allow flexibility of the socket portion and the socket portion configured to receive the ball portion; and (c) a compressive ring configured to elastically compress the outer shroud onto the inner shroud, wherein the ball portion and the socket portion form a ball and socket joint, the ball and socket joint configured to allow relative angular movement and relative axial movement between the inner shroud and the outer shroud, and wherein the plurality of openings in the ball portion and the plurality of openings in the socket portion are misaligned to provide a fluid-tight seal. 20. A tube assembly comprising the tube coupling of claim 19 for coupling a first tube to a second tube, the tube assembly further comprising the first tube and the second tube. 21. A tube coupling for coupling a first tube and a second tube, the tube coupling comprising: (a) an inner shroud including a ball portion; (b) an outer shroud including a socket portion and a plurality of spring fingers, the socket portion configured to receive the ball portion; and (c) a compressive ring configured to elastically compress the outer shroud onto the inner shroud wherein the ball portion and the socket portion form a ball and socket joint, the ball and socket joint configured to allow relative angular movement and relative axial movement between the inner shroud and the outer shroud, wherein the plurality of spring fingers are configured to allow relative axial movement between the inner shroud and the outer shroud, and wherein each spring finger of the plurality of spring fingers comprise a flat portion and a spring portion, the spring portion being formed of convolutions of crests and valleys and the inner shroud further comprising a longitudinal portion and a plurality of protrusions on the longitudinal portion, wherein the plurality of protrusions are configured to separate adjacent spring fingers of the plurality of spring fingers. 22. A tube assembly comprising the tube coupling of claim 21 for coupling a first tube to a second tube, the tube assembly further comprising the first tube and the second tube.