Tensioning gear mechanism for tensioning a stored-energy spring of a spring-type stored-energy drive

The invention claimed is: 1. A tensioning gear mechanism for tensioning a stored-energy spring of a spring-type stored-energy drive, the tensioning gear mechanism comprising: a tensioning wheel coupled to the stored-energy spring; an intermediate shaft coupled to said tensioning wheel; an intermediate wheel capable of being driven by a tensioning motor; a freewheel coupled to said intermediate wheel; a locking mechanism for separable locking of said tensioning wheel in a tensioned state of the stored-energy spring; a claw coupling having a first coupling jaw coupled to said intermediate shaft in a torsion-resistant manner, and a second coupling jaw connected to said freewheel; a synchronizer ring disposed between said first and second coupling jaws and coupled to said first coupling jaw in torsion-resistant manner; said first coupling jaw being displaceable, parallel to a longitudinal axis of said intermediate shaft, between a first end position, in which said first coupling jaw abuts said second coupling jaw and which it assumes in a course of the tensioning of the stored-energy spring, and a second end position, in which said first coupling jaw has been separated from said second coupling jaw and which it assumes in the tensioned state of the stored-energy spring; and said synchronizer ring is pressed against said second coupling jaw when said first coupling jaw is moving from the second end position into the first end position. 2. The tensioning gear mechanism according to claim 1 , further comprising a spring element; and said synchronizer ring is displaceable, parallel to the longitudinal axis of said intermediate shaft, relative to said first coupling jaw and is coupled to said first coupling jaw by said spring element which exerts a spring force parallel to the longitudinal axis of said intermediate shaft between said synchronizer ring and said first coupling jaw. 3. The tensioning gear mechanism according to claim 1 , wherein said synchronizer ring and said second coupling jaw have mutually corresponding friction surfaces which abut one another when said synchronizer ring is being pressed against said second coupling jaw and which have been realized as frustoconical surfaces. 4. The tensioning gear mechanism according to claim 2 , further comprising a coupling element; wherein said intermediate shaft has a transverse opening formed therein and extending perpendicular to the longitudinal axis of said intermediate shaft; and wherein said first coupling jaw is coupled to said intermediate shaft by said coupling element, said coupling element being guided in said intermediate shaft through said transverse opening extending perpendicular to the longitudinal axis of said intermediate shaft, and is displaceable in said transverse opening, parallel to the longitudinal axis of said intermediate shaft, between a first position, defining the first end position of said first coupling jaw, and a second position defining the second end position of said first coupling jaw. 5. The tensioning gear mechanism according to claim 4 , wherein: said first coupling jaw has recesses formed therein; and said coupling element is a tube or a bolt, a longitudinal axis of said coupling element is disposed perpendicular to the longitudinal axis of said intermediate shaft, and said coupling element has ends which project into said recesses in said first coupling jaw. 6. The tensioning gear mechanism according to claim 4 , wherein said intermediate shaft has a longitudinal opening formed therein and extending along the longitudinal axis of said intermediate shaft; and further comprising a switching pin supported so as to be displaceable in said intermediate shaft in said longitudinal opening extending along the longitudinal axis of said intermediate shaft and said switching pin is coupled to said coupling element. 7. The tensioning gear mechanism according to claim 6 , wherein said switching pin has a resetting end which projects out of the longitudinal opening; and further comprising a resetting element disposed on said tensioning wheel, said resetting element displaces said resetting end of said switching pin in the tensioned state of the stored-energy spring toward the longitudinal opening, so that said coupling element is displaced from a first position into a second position. 8. The tensioning gear mechanism according to claim 7 , wherein said resetting element has a contact end, protruding radially from said tensioning wheel, with an oblique contact surface which in a course of a displacement of said switching pin abuts said resetting end of said switching pin. 9. The tensioning gear mechanism according to claim 1 , wherein said first and second coupling jaws each extend in a form of a ring around said intermediate shaft. 10. The tensioning gear mechanism according to claim 1 , further comprising a restoring spring coupled to said first coupling jaw, said restoring spring in the second end position of said first coupling jaw exerts a spring force on said first coupling jaw in a direction of the first end position. 11. The tensioning gear mechanism according to claim 1 , wherein said freewheel has a freewheel ring extending around said intermediate shaft, and said second coupling jaw is connected to said freewheel ring. 12. The tensioning gear mechanism according to claim 1 , wherein said intermediate wheel is capable of being driven by the tensioning motor via a bevel-gear transmission. 13. The tensioning gear mechanism according to claim 1 , wherein said locking mechanism has a cam-disk roller, firmly connected to said tensioning wheel, and a latch which fixes said cam-disk roller for locking said tensioning wheel. 14. A spring-type stored-energy drive, comprising: a stored energy spring; and a tensioning gear mechanism, containing: a tensioning wheel coupled to said stored-energy spring; an intermediate shaft coupled to said tensioning wheel; an intermediate wheel capable of being driven by a tensioning motor; a freewheel coupled to said intermediate wheel; a locking mechanism for separable locking of said tensioning wheel in a tensioned state of said stored-energy spring; a claw coupling with a first coupling jaw coupled to said intermediate shaft in a torsion-resistant manner, with a second coupling jaw connected to said freewheel; a synchronizer ring disposed between said first and second coupling jaws and coupled to said first coupling jaw in torsion-resistant manner; said first coupling jaw being displaceable, parallel to a longitudinal axis of said intermediate shaft, between a first end position, in which said first coupling jaw abuts said second coupling jaw and which it assumes in a course of the tensioning of said stored-energy spring, and a second end position, in which said first coupling jaw has been separated from said second coupling jaw and which it assumes in the tensioned state of said stored-energy spring; and said synchronizer ring is pressed against said second coupling jaw when said first coupling jaw is moving from the second end position into the first end position.