Injection device

The invention claimed is: 1. A priming mechanism for a delivery device, the priming mechanism comprising: a main body; a needle shield slidably arranged inside the main body, the needle shield comprising a plurality of recesses; a needle shield link comprising a plurality of outwardly extending ledges, the needle shield link being connected to the needle shield via the plurality of outwardly extending ledges fitting into the plurality of recesses; a plunger; a rotatable activation knob releasably holding the plunger in a first plunger position; a tubular member rotationally and slidably arranged inside the needle shield link; and a needle shield spring arranged to press on the needle shield link, wherein in response to the rotatable activation knob being turned from a first knob position to a second knob position, the plunger is configured to be released from the first plunger position and to move under a force of a tensioned injection spring to a second plunger position. 2. The priming mechanism of claim 1 , wherein the plunger is configured to be releasably held by a plurality of oppositely arranged outwardly extending knobs on the plunger abutting a first set of ledges arranged on an inner surface of the rotatable activation knob. 3. The priming mechanism of claim 2 , wherein turning the rotatable activation knob from the first knob position to the second knob position is configured to cause the outwardly extending knobs to slide off the first set of ledges, wherein the injection spring is configured to push the plunger towards a cartridge, thereby causing the plunger to move a stopper inside the cartridge, thereby pressing air out of the cartridge through a needle connected to the priming mechanism. 4. The priming mechanism of claim 3 , wherein the priming mechanism is configured such that movement of the plunger is stopped at the second plunger position in response to the outwardly extending knobs abutting a second set of ledges arranged on an inner surface of the tubular member. 5. The priming mechanism of claim 2 , wherein the first set of ledges comprise a plurality of longitudinally extending protrusions configured for allowing movement between the outwardly extending knobs and the first set of ledges in only one direction. 6. The priming mechanism of claim 1 , wherein the needle shield link comprises an upper tubular part and a plurality of longitudinally extending arms. 7. The priming mechanism of claim 6 , wherein each arm of the plurality of longitudinally extending arms comprises an outwardly extending ledge of the plurality of outwardly extending ledges, the plurality of outwardly extending ledges each being configured to fit into a respective recess in an upper part of the needle shield. 8. The priming mechanism of claim 1 , wherein an upper part of the plunger comprises a plurality of outwardly extending stop members. 9. The priming mechanism of claim 8 , wherein the plurality of outwardly extending stop members are configured to be releasably held by a plurality of inwardly extending stop members on an inner surface of the rotatable activation knob. 10. The priming mechanism of claim 1 , wherein, in a retracted position, the needle shield resides inside the main body. 11. The priming mechanism of claim 10 , wherein the needle shield is configured to be held in the retracted position against a force of the needle shield spring by an outwardly extending knob on the rotatable activation knob abutting an inwardly extending knob on an inner surface of the needle shield link. 12. The priming mechanism of claim 1 , wherein the priming mechanism is configured such that turning the rotatable activation knob from the first knob position to the second knob position causes an outwardly directed extending knob of the rotatable activation knob to be moved out of contact with an inwardly extending knob of the needle shield link. 13. The priming mechanism of claim 12 , wherein in response to the outwardly directed extending knob of the rotatable activation knob being moved out of contact with the inwardly extending knob of the needle shield link, a force of the needle shield spring urges the needle shield and the needle shield link to an extending position. 14. The priming mechanism of claim 1 , wherein an outer surface of the tubular member comprises a plurality of protrusions that are configured to cooperate respectively with a plurality of guide members arranged on an inner surface of the needle shield link. 15. The priming mechanism of claim 1 , wherein the priming mechanism is configured to prevent longitudinal movement between the tubular member and the rotatable activation knob. 16. The priming mechanism of claim 1 , wherein the priming mechanism is configured to allow rotational movement between the tubular member and the rotatable activation knob. 17. The priming mechanism of claim 1 , wherein a front end of the plunger is arranged to be in contact with a stopper arranged within a cartridge containing a medicament to be delivered by the delivery device. 18. The priming mechanism of claim 1 , wherein in response to the needle shield being pressed against an injection site the needle shield link and the tubular member are configured to interact to cause the tubular member to rotate, thereby allowing the plunger to move under a force of a tensioned injection spring to a third position. 19. The priming mechanism of claim 1 , wherein an end surface of the tubular member is in contact with an end surface of the rotatable activation knob. 20. The priming mechanism of claim 1 , wherein the needle shield spring is arranged to press on the needle shield link between a ledge on the main body and a ledge on an upper part of the needle shield link.