Can bodymaker ram alignment

The invention claimed is: 1. A can bodymaker comprising: a ram; a drive mechanism configured to drive the ram in a linear, reciprocating motion; a yoke coupling the ram to the drive; a yoke slide fixed relative to the can bodymaker, the yoke being confined by the yoke slide to move in a linear direction; and an alignment mechanism configured to radially align a yoke-coupled end of the ram with respect to the yoke within a plane perpendicular to said linear direction, the alignment mechanism comprising: an inner bushing supporting the ram, the inner bushing being annular and having eccentric inner and outer surfaces; an outer bushing supporting the inner bushing, the outer bushing being annular and having eccentric inner and outer surfaces; an adjustment mechanism for independently rotating the inner and outer bushings about respective axes of rotation defined by their outer surfaces; and a lock that is adapted for affixing the yoke-coupled end of the ram in position relative to the yoke, thereby diminishing load on the alignment mechanism, the lock comprising a compression coupling arranged axially about the inner and outer bushings. 2. The can bodymaker according to claim 1 , wherein the axes of rotation of the inner and outer bushings are separated by a distance between 0.10 mm and 0.30 mm. 3. The can bodymaker according to claim 1 , wherein an axis of the ram and the rotational axis of the inner bushing are separated by a distance between 0.10 mm and 0.30 mm. 4. The can bodymaker according to claim 1 , the adjustment mechanism comprising a first worm gear for rotating the inner bushing and a second worm gear for rotating the outer bushing. 5. The can bodymaker according to claim 1 , wherein the compressing coupling comprises a nut for locking the ram in position with respect to the yoke, the nut being threaded on to the ram. 6. The can bodymaker according to claim 1 , wherein said yoke allows adjustment of the yoke-coupled end of the ram with respect to the drive mechanism along said linear direction. 7. The can bodymaker according to claim 6 , wherein said yoke is coupled to the ram by a threaded rod screwed into a tapped hole, the yoke allowing adjustment of the yoke-coupled end of the ram with respect to the drive mechanism along said linear direction by screwing the threaded rod into or out of the tapped hole. 8. The can bodymaker according to claim 6 , further comprising an insert located between the yoke-coupled end of the ram and the yoke, the insert being formed from an elastomeric material. 9. The can bodymaker according to claim 1 , further comprising a bottom forming tool located at an end of the can bodymaker opposite the drive mechanism. 10. A can bodymaker according to claim 1 , wherein the alignment mechanism is adapted for affixing the yoke-coupled end of the ram with respect to the yoke within the plane perpendicular to said linear direction. 11. A method of aligning a ram of a can bodymaker having a yoke coupling the ram to a drive mechanism in order to drive the ram with a linear, reciprocating motion, and where a yoke slide is fixed relative to the can bodymaker and the yoke is confined by the yoke slide to move in a linear direction, the method comprising positioning, with an alignment mechanism, a yoke-coupled end of the ram with respect to the yoke within a plane perpendicular to said linear direction; wherein the use of the alignment mechanism comprises rotating one or more of a pair of eccentrically nested bushings; and locking the yoke-coupled end of the ram in position relative to the yoke via a compression coupling arranged axially about the eccentrically nested bushings. 12. The method according to claim 11 , further comprising alternately rotating the eccentrically nested eccentric bushings in an iterative sequence. 13. A yoke for a can bodymaker and configured to couple a ram to a drive mechanism, the drive mechanism being configured to drive the ram with a linear, reciprocating motion, the yoke being further configured to fit within a yoke slide so that the yoke is confined to move in a linear direction, the yoke comprising a radial alignment mechanism for aligning a yoke-coupled end of the ram with respect to the yoke within a plane perpendicular to said linear direction, the alignment mechanism comprising: an inner bushing for supporting the ram, the inner bushing being annular and having eccentric inner and outer surfaces; an outer bushing supporting the inner bushing, the outer bushing being annular and having eccentric inner and outer surfaces; an adjustment mechanism for independently rotating the inner and outer bushings about respective axes of rotation defined by their outer surfaces; and a lock that is adapted for affixing the yoke-coupled end of the ram in position relative to the yoke, thereby diminishing load on the alignment mechanism the lock comprising a compression coupling arranged axially about the inner and outer bushings.