Drive mechanisms suitable for use in drug delivery devices

The invention claimed is: 1. A drive mechanism for use in a drug delivery device, the drive mechanism comprising: a multi-part exterior housing defining a window, the exterior housing having a first surface forming a maximum dose radial stop and a second surface forming a zero dose radial stop, a helical rib extending radially inward from an inner surface of the exterior housing; a dose dial sleeve rotatable with respect to the exterior housing, the dose dial sleeve defining a helical groove in which the helical rib of the exterior housing is disposed, the helical rib and the helical groove being configured such that rotation of the dose dial sleeve with respect to the exterior housing causes an axial movement of the dose dial sleeve relative to the exterior housing, a projection extending from the dose dial sleeve, the projection being axially adjacent the helical groove and configured to contact the maximum dose radial stop of the exterior housing when the dose dial is rotated an amount corresponding to a maximum dose; a member configured to contact the zero dose radial stop of the exterior housing to stop rotation of the dose dial sleeve when a dose has been delivered; a clutch member comprising saw teeth; a clicker comprising saw teeth configured to engage the saw teeth of the clutch member; a drive sleeve; and a piston rod threadedly engaged with the drive sleeve, wherein the drive mechanism is configured such that the dose dial sleeve can be rotated in a first direction relative to the exterior housing to increase a set dose, the dose dial sleeve can be rotated in a second direction relative to the exterior housing to decrease the set dose without dispensing drug, the saw teeth of the clutch member are rotationally fixed with respect to the saw teeth of the clicker when the dose dial sleeve is rotated in the first direction to increase the set dose, and the saw teeth of the clicker are rotated with respect to the saw teeth of the clutch member such that the saw teeth of the clicker ride over the saw teeth of the clutch member generating audible feedback when the dose dial sleeve is rotated in the second direction to decrease the set dose, and wherein the clicker comprises at least one clicker tooth that generates audible feedback when the dial sleeve is rotated in the first direction to increase the set dose and that does not generate audible feedback when the dial sleeve is rotated in the second direction to decrease the set dose, wherein the saw teeth of the clicker and the saw teeth of the clutch member that generate audible feedback when the dial sleeve is rotated in the second direction to decrease the set dose are distal to the at least one clicker tooth of the clicker that generates the audible feedback when the dial sleeve is rotated in the first direction to increase the set dose. 2. The drive mechanism of claim 1 , further comprising a dose dial grip, wherein the member configured to contact the zero dose radial stop of the exterior housing extends from the dose dial grip. 3. The drive mechanism of claim 2 , wherein the dose dial grip is rotationally fixed to a distal end of the dose dial sleeve. 4. The drive mechanism of claim 1 , wherein the exterior housing has a second surface forming a second zero dose radial stop, and a second member is configured to contact the zero dose radial stop of the exterior housing to stop rotation of the dose dial sleeve when the dose has been delivered. 5. The drive mechanism of claim 1 , wherein the helical groove is defined by an outer surface of the dose dial sleeve. 6. The drive mechanism of claim 1 , wherein an outer surface of the dose dial sleeve comprises reference numerals for indicating the set dose. 7. The drive mechanism of claim 6 , wherein the window is configured to make visible to a user the reference numeral corresponding to the set dose. 8. The drive mechanism of claim 1 , wherein the drive sleeve is releasably connected to the dose dial sleeve. 9. The drive mechanism of claim 1 , wherein the piston rod comprises a series of part threads that engage a thread of the drive sleeve. 10. The drive mechanism of claim 9 , wherein the part threads of the piston rod are external part threads, and the thread of the drive sleeve is an internal thread. 11. The drive mechanism of claim 1 , wherein the saw teeth of the clicker are arranged about a circumference of a body of the clicker. 12. The drive mechanism of claim 11 , wherein the body of the clicker has a circular cross section. 13. The drive mechanism of claim 1 , wherein the saw teeth of the clicker extend axially from a body of the clicker. 14. The drive mechanism of claim 13 , wherein the body of the clicker has a circular cross section. 15. The drive mechanism of claim 1 , wherein the saw teeth of the clicker and the saw teeth of the clutch member are configured to allow torque to be transmitted between the clicker and the clutch member. 16. The drive mechanism of claim 1 , further comprising a spring configured to bias the saw teeth of the clicker and the saw teeth of the clutch member into engagement with one another. 17. The drive mechanism of claim 1 , further comprising a button configured to dispense a dose when the button is pressed by a user. 18. The drive mechanism of claim 17 , wherein the button is configured to, when pressed by the user, apply an axial force to the clutch member to rotationally fix the saw teeth of the clicker with the saw teeth of the clutch member. 19. The drive mechanism of claim 17 , wherein the drive mechanism is configured such that there is relative rotation between the drive sleeve and the piston rod when the button is pressed to dispense the dose. 20. The drive mechanism of claim 19 , wherein the clutch member and the drive sleeve are configured to be rotationally fixed relative to one another such that there is relative rotation between the clutch member and the piston rod when the button is pressed to dispense the dose. 21. The drive mechanism of claim 1 , wherein the maximum dose radial stop is axially adjacent the window. 22. The drive mechanism of claim 21 , wherein the maximum dose radial stop is proximal to the window. 23. The drive mechanism of claim 1 , wherein part of the helical rib is proximal to the window and part of the helical rib is distal to the window. 24. The drive mechanism of claim 1 , wherein the projection is proximal to the helical groove. 25. A drug delivery device comprising: a drive mechanism comprising a multi-part exterior housing defining a window, the exterior housing having a first surface forming a maximum dose radial stop and a second surface forming a zero dose radial stop, a helical rib extending radially inward from an inner surface of the exterior housing; a dose dial sleeve rotatable with respect to the exterior housing, the dose dial sleeve defining a helical groove in which the helical rib of the exterior housing is disposed, the helical rib and the helical groove being configured such that rotation of the dose dial sleeve with respect to the exterior housing causes an axial movement of the dose dial sleeve relative to the exterior housing, a projection extending from the dose dial sleeve, the projection being axially adjacent the helical groove and configured to contact the maximum dose radial stop of the exterior housing when the dose dial is rotated an amount corresponding to a maximum dose; a member configured to contact