Detent mechanism

The invention claimed is: 1. A detent mechanism for controlling translation between two components in a longitudinal direction, the detent mechanism comprising: a resilient beam on one of the components; and a rhomboid ramp member on the other component, the rhomboid ramp member comprising a first ramp and a second ramp, wherein each ramp resides on one longitudinal side of the rhomboid ramp member, the rhomboid ramp member further comprising a first transversal side and a second transversal side, the resilient beam being essentially straight when relaxed and having a first beam head and arranged to interact in a ramped engagement with respectively one of two ramps in such a manner that application of a translative force between the components in one longitudinal direction with the first beam head engaged to the first ramp of the rhomboid ramp member in a first state deflects the resilient beam in one transversal direction when a predetermined value of the translative force, at least depending on a resilience of the resilient beam, is overcome so as to allow the first beam head to travel along the first transversal side of the rhomboid ramp member on continued relative translation of the components, wherein the resilient beam is allowed to relax when the first beam head has reached the second ramp of the rhomboid member in a second state, wherein application of a translative force between the components in the other longitudinal direction with the first beam head engaged to the second ramp of the rhomboid member deflects the resilient beam in the other transversal direction when a predetermined value of the translative force, at least depending on the resilience of the resilient beam, is overcome so as to allow the first beam head to travel along the second transversal side of the rhomboid ramp member on continued relative translation of the components. 2. The detent mechanism according to claim 1 , wherein the resilient beam is arranged to travel along the second transversal side of the rhomboid ramp member until reaching the one of the two ramps, thereby allowing the resilient beam to relax thus arriving again in the first state. 3. The detent mechanism according to claim 1 , wherein the first beam head protrudes transversally from the resilient beam in a manner to distort the resilient beam by lever action when pushed against the rhomboid ramp member. 4. The detent mechanism according to claim 1 , wherein at least one rib is provided for preventing deflection of the resilient beam in at least one of the transversal directions so as to lock the detent mechanism in the first or second state, wherein the rib is arranged to be removed for allowing deflection of the resilient beam thus unlocking the detent mechanism. 5. The detent mechanism according to claim 1 , wherein the resilient beam and the rhomboid ramp member are offset sideways to allow the resilient beam to pass without contacting the rhomboid ramp member when the first beam head is deflected to a side of the rhomboid ramp member opposite the resilient beam. 6. An auto-injector for administering a dose of a liquid medicament, comprising: a tubular chassis telescopable in a tubular case, a carrier subassembly comprising a tubular carrier slidably arranged relative to the tubular chassis inside the tubular case, the tubular carrier adapted to contain a syringe with a hollow injection needle, a drive spring, and a plunger for forwarding load of the drive spring to a stopper of the syringe, wherein the syringe is lockable for joint axial translation with the tubular carrier, a trigger button arranged to advance the tubular carrier in proximal direction, a detent mechanism according to claim 1 for controlling translation of the tubular carrier relative to the tubular chassis, wherein the tubular chassis and the tubular carrier are initially coupled for joint axial translation relative to the tubular case, wherein the detent mechanism is arranged to decouple the tubular chassis from the tubular carrier upon actuation of the trigger button thus allowing the tubular carrier to move relative to the tubular chassis for needle insertion. 7. The auto-injector according to claim 6 , comprising: a control spring arranged around the tubular carrier, a needle insertion control mechanism for coupling a proximal end of the control spring to either the tubular carrier for advancing it for needle insertion or to the tubular chassis for needle retraction depending on a relative axial position of the tubular carrier and the tubular chassis, a plunger release mechanism arranged for releasing the plunger for injection when the tubular carrier has at least almost reached an injection depth during needle insertion, a syringe retraction control mechanism arranged for coupling a distal end of the control spring to either the tubular carrier for needle retraction or to the tubular case otherwise, wherein the needle insertion control mechanism is allowed to switch the proximal end of the control spring to the tubular carrier for needle insertion when the tubular chassis is decoupled from the tubular carrier by the detent mechanism upon actuation of the trigger button. 8. The auto-injector according to claim 7 , wherein the needle insertion control mechanism comprises a first collar biased by the control spring in the proximal direction, wherein at least one resilient beam is proximally arranged on the first collar, wherein respective recesses are arranged in the tubular carrier and tubular case, wherein a transversal extension of a head of the resilient beam is wider than a gap between the tubular carrier and the tubular chassis causing the head of the resilient beam to abut a distal face on the recess in the tubular chassis while being prevented from deflecting in an inward direction by the tubular carrier or to abut a distal face on the recess in the tubular carrier while being prevented from deflecting in an outward direction by the tubular chassis thereby forwarding load from the control spring to the tubular carrier for needle insertion, and wherein the resilient beam is arranged to be switched between the tubular chassis and the tubular carrier by a ramped engagement of the head of the resilient beam to the distal faces under the load of the control spring depending on a relative longitudinal position between the tubular chassis and the tubular carrier. 9. The auto-injector according to claim 7 , wherein the plunger release mechanism comprises at least one resilient arm on the tubular carrier arranged to be in a ramped engagement to the plunger so as to disengage them under the load of the drive spring, wherein a peg protrudes from a distal end face of the trigger button in the proximal direction in a manner to support the resilient arm preventing disengagement of the tubular carrier from the plunger and thus release of the drive spring when the tubular carrier is in a distal position, wherein the trigger button is arranged to remain in position relative to the tubular case when the tubular carrier is translated for advancing the needle so as to pull the resilient arm away from the peg thus allowing deflection of the resilient arm due to the ramped engagement under the load of the drive spring for disengaging the plunger from the tubular carrier and releasing the drive spring for drug delivery when the tubular carrier has reached a predefined position during needle advancement. 10. The auto-injector according to claim 7 , wherein the syringe retraction control mechanism comprises a second collar bearing against the distal end of the control spring and having a resilient proximal beam with a second beam head having an inward boss, wherein the second beam head is arranged t