Injection devices using a resiliently compressible torsion spring as driving force

The invention claimed is: 1. An injection device comprising: a housing ( 12 ) for receiving a syringe ( 18 ) or cartridge for containing a medicament; a rotary drive shaft ( 24 ) mounted for rotation relative to said housing ( 12 ); and an elongate coiled torsion spring ( 38 ) having respective formations ( 48 , 50 ) at opposite ends thereof with a first end formation ( 50 ) being anchored in a seat ( 56 ) on said rotary drive shaft ( 24 ) and a second end formation ( 48 ) being anchored in a seat ( 58 ) on a reaction component ( 14 ), whereby in use relative rotation of said rotary drive shaft ( 24 ) and said reaction component ( 14 ) in one angular direction strains said torsion spring ( 38 ), and release of said strained torsion spring causes expression of medicament from said syringe or cartridge; wherein said torsion spring is longitudinally resiliently compressible between the first and second end formations whereby during assembly of said injection device, the torsion spring may be longitudinally compressed and rotated, thereby causing the end formations ( 48 , 50 ) of the torsion spring to be urged into engagement with said respective seats ( 58 , 56 ). 2. An injection device according to claim 1 , wherein said reaction component comprises a collar ( 14 ) configured to be rotatable relative to said driveshaft ( 24 ) in one direction to strain said torsion spring ( 38 ), the collar ( 14 ) having a lock arrangement ( 44 , 46 ) to prevent rotation thereof in the opposite direction. 3. An injection device according to claim 2 , wherein said collar ( 114 ) comprises first stage location means ( 111 , 105 ) to hold said collar in a longitudinal position in which it may rotate relative to said rotary drive to strain said spring, and a second stage location means ( 111 , 117 ) which prevents rotation of said collar ( 14 ) in either direction. 4. An injection device according to claim 2 , wherein said lock arrangement comprises a ratchet arrangement ( 44 , 46 ). 5. An injection device according to claim 1 , wherein said torsion spring includes at least a region ( 52 ) of open coil form. 6. An injection device according to claim 5 , wherein said torsion spring includes a region ( 54 ) of closed coil form. 7. An injection device according to claim 5 , wherein at least one of the formations ( 48 , 50 ) on said torsion spring is a hooked element and the seat ( 58 , 56 ) with which it is urged into engagement comprises an aperture through which at least a portion of the hooked element may pass, the aperture having an edge surface for being caught in the hooked element when there is relative rotation between the torsion drive spring and the seat during assembly. 8. An injection device according to claim 1 , wherein said torsion spring includes a region ( 54 ) of closed coil form. 9. An injection device according to claim 8 , wherein at least one of the formations ( 48 , 50 ) on said torsion spring is a hooked element and the seat ( 58 , 56 ) with which it is urged into engagement comprises an aperture through which at least a portion of the hooked element may pass, the aperture having an edge surface for being caught in the hooked element when there is relative rotation between the torsion drive spring and the seat during assembly. 10. An injection device according to claim 8 , wherein said torsion spring ( 38 ) comprises a plurality of open coil regions ( 52 ) interspersed with closed coil regions ( 54 ). 11. An injection device according to claim 1 , wherein at least one of the formations ( 48 , 50 ) on said torsion spring is a hooked element and the seat ( 58 , 56 ) with which it is urged into engagement comprises an aperture through which at least a portion of the hooked element may pass, the aperture having an edge surface for being caught in the hooked element when there is relative rotation between the torsion drive spring and the seat during assembly. 12. An injection device according to claim 11 , wherein said hooked elements ( 48 , 50 ) are of generally U-shaped form thereby to assist capture of said edge surface. 13. An injection device according to claim 11 , wherein at least one of said respective seats ( 56 , 58 ) includes a detent arrangement ( 60 ) past which the hooked element ( 48 , 50 ) snaps during assembly. 14. An injection device including: a housing ( 12 ) for receiving a syringe ( 18 ) or cartridge for containing a medicament; a rotary drive shaft ( 24 ) mounted for rotation relative to said housing ( 12 ); an elongate coiled torsion spring ( 38 ) having respective formations ( 48 , 50 ) at opposite ends thereof with a first end formation ( 50 ) being anchored in a seat ( 56 ) on said rotary drive shaft ( 24 ) and a second end formation ( 48 ) being anchored in a seat ( 58 ) on a reaction component ( 14 ), whereby in use relative rotation of said rotary drive shaft ( 24 ) and said reaction component ( 14 ) in one angular direction strains said torsion spring ( 38 ), and release of said strained torsion spring causes expression of medicament from said syringe or cartridge; wherein said torsion spring includes at least a region of open coil form whereby during assembly of said injection device, the torsion spring may be longitudinally compressed and rotated, thereby causing the end formations ( 48 , 50 ) of the torsion spring to be urged into engagement with said respective seats ( 58 , 56 ). 15. A method of assembly of an injection device, the injection device including: a housing ( 12 , 16 ) for receiving a syringe or cartridge ( 18 ) for containing a medicament; a rotary driveshaft mounted for rotation ( 24 ); a reaction component ( 14 ), and an elongate coiled torsion spring ( 38 ) having respective formations ( 48 , 50 ) at opposite end regions thereof for engagement with respective seats ( 58 , 56 ) on said rotary driveshaft and said reaction component respectively, the method comprising: disposing said elongate coiled torsion spring ( 38 ) between said driveshaft ( 24 ) and said reaction component ( 14 ); effecting relative movement of said rotary driveshaft and said reaction component to cause said torsion spring to compress thereby urging said respective formations ( 48 , 50 ) into engagement with the driveshaft and the reaction component respectively, and effecting relative rotation of said rotary driveshaft and said reaction component to cause said formations ( 48 , 50 ) to be engaged and captured by said respective seats ( 58 , 56 ). 16. A method according to claim 15 , wherein said elongate driveshaft ( 24 ) includes a hollow tubular portion and the method comprises inserting said elongate coiled torsion spring ( 38 ) into said tubular portion. 17. A method according to claim 15 , wherein said relative rotation is affected by applying rotation to said reaction component ( 14 ). 18. A method according to claim 17 , wherein said reaction component ( 14 ) is rotated against the effect of a ratchet ( 44 , 46 ), thereby preventing return movement of the return angular movement of the reaction component. 19. A method according to claim 17 , wherein, having rotated the reaction component ( 114 ) to strain the torsion drive spring ( 138 ), the reaction component is locked against further rotation. 20. A method according to claim 19 , wherein said reaction component ( 114 ) is locked by effecting relative longitudinal movement thereof into a locking engagement position ( 109 , 111 ).