Check valve plate positioner for camshaft phaser

The invention claimed is: 1. A camshaft phaser, comprising: an axis of rotation; a stator including a radially outermost surface with a plurality of teeth; a locking plate including: a first side facing in a first axial direction; a bore in the first side; and, a first through-bore; a check valve plate axially located between the locking plate and the stator and including: a second through-bore; and, a displaceable valve flap aligned, in the first axial direction, with the first through-bore; and, a bushing: disposed in: the bore in the first side; and, the second through-bore; and, extending past the locking plate in the first axial direction. 2. The camshaft phaser of claim 1 , wherein a line orthogonal to the axis of rotation passes through the bushing and the check valve plate. 3. The camshaft phaser of claim 1 , wherein: the check valve plate includes a first side facing in the first axial direction; and, the bushing does not extend past the first side in the first axial direction. 4. The camshaft phaser of claim 1 , wherein the check valve plate does not overlap the bushing in the first axial direction. 5. The camshaft phaser of claim 1 , wherein: the bore in the first side is bounded by a cylindrical wall in the locking plate; and, the bushing includes a cylindrical outer surface in contact with the cylindrical wall. 6. The camshaft phaser of claim 1 , further comprising: a rotor; at least one chamber bounded, at least in part, by the stator, the check valve plate and the rotor; a spring cover; and, a space bounded, at least in part, by the spring cover and the locking plate and in communication with the first through-bore, wherein: for fluid pressure in the space greater than fluid pressure in the at least one chamber, fluid in the space is arranged to displace the valve flap in the first axial direction so that the first through-bore in the locking plate is open to the at least one chamber; and, for fluid pressure in the at least one chamber greater than fluid pressure in the space, fluid in the at least one chamber is arranged to displace the valve flap in a second axial direction so that the first through-bore is blocked by the valve flap. 7. The camshaft phaser of claim 1 , wherein the bushing fixes, with respect to the locking plate, a position of the check valve plate with respect to movement in: a circumferential direction only; or, a radial direction only. 8. The camshaft phaser of claim 1 , wherein: the bushing includes at least one groove; and, the check valve plate includes at least one tab disposed in the at least one groove. 9. The camshaft phaser of claim 8 , wherein: the bushing includes a longitudinal axis extending in the first axial direction; and, the bushing blocks rotation of the check valve plate, with respect to the locking plate, circumferentially about the longitudinal axis. 10. The camshaft phaser of claim 8 , wherein: the bushing includes an axial end surface facing in the first axial direction; and, the at least one groove is in the axial end surface. 11. The camshaft phaser of claim 1 , wherein the stator includes a radially inwardly extending vane, the camshaft phaser further comprising: a rotor including a radially outwardly extending vane; a third through-bore in the radially outwardly extending vane of the rotor; and, a locking assembly including a locking pin and a spring disposed in the third through-bore; wherein: the bushing includes an indentation facing the first axial direction; and, the spring is arranged to displace the locking pin into the indentation to non-rotatably connect the rotor and the stator. 12. A camshaft phaser, comprising: an axis of rotation; a stator including a radially outermost surface with a plurality of teeth; a locking plate including: a first side facing in a first axial direction; a bore in the first side; and, a first through-bore; a check valve plate axially located between the locking plate and the stator and including: a second through-bore; and, a displaceable valve flap aligned, in the first axial direction, with the first through-bore; and, a bushing: including a longitudinal axis extending in the first axial direction; disposed in: the bore in the first side; and, the second through-bore; and, blocking movement of the check valve plate, with respect to the locking plate, in: a radial direction with respect to the longitudinal axis; or, a circumferential direction with respect to the longitudinal axis. 13. The camshaft phaser of claim 12 , wherein: a line orthogonal to the axis of rotation passes through the bushing and the check valve plate; or, the check valve plate does not overlap the bushing in the first axial direction. 14. The camshaft phaser of claim 12 , further comprising: a rotor; at least one chamber bounded, at least in part, by the stator, the check valve plate and the rotor; a spring cover; and, a space bounded, at least in part, by the spring cover and the locking plate and in communication with the first through-bore, wherein: for fluid pressure in the space greater than fluid pressure in the at least one chamber, fluid in the space is arranged to displace the valve flap in the first axial direction so that the first through-bore is open to the at least one chamber; and, for fluid pressure in the at least one chamber greater than fluid pressure in the space, fluid in the at least one chamber is arranged to displace the valve flap in a second axial direction so that the first through-bore is blocked by the valve flap. 15. The camshaft phaser of claim 12 , wherein: the bushing includes at least one groove; and, the check valve plate includes at least one tab disposed in the at least one groove. 16. A method of operating a camshaft phaser including an axis of rotation, a stator, a rotor, a locking plate, a check valve plate axially located between the locking plate and the stator, a chamber formed at least in part by the stator, the rotor and the check valve plate, and a bushing disposed in a bore in the locking plate and in a first through-bore in the check valve plate, the method comprising: blocking a second through-bore in the locking plate with a flap in the check valve plate; displacing, in a first axial direction parallel to the axis of rotation, the flap in the check valve plate; flowing fluid through the second through-bore to the chamber; displacing, in a second axial direction opposite the first axial direction, the flap in the check valve plate; blocking, with the flap, flow of the fluid from the chamber through the second through-bore; and, blocking, with the bushing, movement of the check valve plate with respect to the locking plate in a radial or a circumferential direction as referenced by the axis of rotation. 17. The method of claim 16 , wherein blocking, with the bushing, movement of the check valve plate with respect to the locking plate in a radial or a circumferential direction as referenced by the axis of rotation includes blocking, with the bushing, movement of the check valve plate with respect to the locking plate in the radial direction and in the circumferential direction as referenced by the axis of rotation. 18. The method of claim 16 , further comprising: blocking, with the bushing, movement of the check valve plate, with respect to the locking plate, in a circumferential direction as referenced by a longitudinal axis extending through the bushing in an axial direction parallel to the axis of rotat