Locking apparatus for a hydromechanical spring energy store drive for a gas-insulated switchgear assembly

What is claimed is: 1. A locking apparatus for a hydromechanical drive for actuating a medium-voltage or high-voltage circuit breaker, the spring energy store drive including a working piston, which is guided in an axial cutout in a pressure housing or working cylinder, the locking apparatus comprising: a spring energy store arrangement, which interacts with a latching bolt; a first pressure region, which is under elevated pressure when the circuit breaker is closed, and a third pressure region which is unpressurized due to which the latching bolt which is to be arranged perpendicular to the working piston, will be pushed away from the working piston via the spring energy store arrangement and via a latching mechanism, which latching mechanism is arranged on a side of the latching bolt that is to point towards the working piston; wherein in an event of a loss of pressure in the first pressure region, a spring force of the spring energy store arrangement will act on the latching bolt, the latching bolt being configured to press the latching mechanism into a cutout in the working piston; and wherein in an event that a holding force of the spring energy store arrangement is exceeded, the working piston is configured to shift the latching bolt by virtue of an element of the latching mechanism that is rotatably mounted and located on the latching bolt and configured to roll over a surface of the working piston. 2. The locking apparatus according to claim 1 , wherein the element that is rotatably mounted is a roller, which is rotatably mounted on a cylindrical pin, and configured to roll over the surface of the working piston. 3. The locking apparatus according to claim 2 , wherein the roller is configured to be guided by the cylindrical pin in a slot in the latching bolt, and wherein a free rotation of the roller is enabled and the roller is prevented from falling out as long as the roller is not in contact with the working piston. 4. The locking apparatus according to claim 1 , wherein the element that is rotatably mounted is a barrel, which is rotatably mounted on a cylindrical pin, and configured to roll over the surface of the working piston. 5. The locking apparatus according to claim 4 , wherein the barrel is configured to be guided by the cylindrical pin in a slot in the latching bolt, and wherein a free rotation of the barrel is enabled and the barrel is prevented from falling out as long as the barrel is not in contact with the working piston. 6. The locking apparatus according to claim 5 , comprising: a supporting bolt on the latching bolt, which is configured to interact with the rotatably mounted element on a side of the latching bolt pointing towards the working piston. 7. The locking apparatus according to claim 6 , wherein the supporting bolt and the barrel are formed from a hardened metal. 8. The locking apparatus according to claim 1 , in combination with the circuit breaker having the spring energy store drive, wherein the spring energy store drive includes the working piston, which is configured to be guided in the axial cutout in the pressure housing or working cylinder. 9. The locking apparatus according to claim 8 , wherein the cutout in the working piston is in an outer contour of the working piston. 10. The locking apparatus according to claim 9 , wherein the cutout is a groove. 11. The locking apparatus according to claim 10 , comprising: a spring energy store arrangement, and wherein the spring energy store arrangement is a compression spring. 12. A hydromechanical drive for a circuit breaker of a gas-insulated switchgear assembly, the hydromechanical drive comprising: a working piston, which is guided in an axial cutout in a pressure housing or working cylinder; a latching bolt; a spring energy store arrangement, which interacts with the latching bolt; and a locking apparatus, the locking apparatus having a first pressure region, which is under elevated pressure when the circuit breaker is closed, and a third pressure region which is unpressurized due to which the latching bolt which is to be arranged perpendicular to the working piston, will be pushed away from the working piston via the spring energy store arrangement and via a latching mechanism which latching mechanism is arranged on a side of the latching bolt that is to point towards the working piston; wherein in an event of a loss of pressure in the first pressure region, a spring force of the spring energy store arrangement will act on the latching bolt, and the latching bolt being configured to press the latching mechanism into a cutout in the working piston; and wherein in an the event that a holding force of the spring energy store arrangement is exceeded, the working piston is configured to shift the latching bolt by virtue of an element of the latching mechanism that is rotatably mounted and located on the latching bolt and configured to roll over a surface of the working piston. 13. The hydromechanical drive according to claim 12 , wherein the element that is rotatably mounted is a roller or barrel, which is rotatably mounted on a cylindrical pin, and configured to roll over the surface of the working piston. 14. The hydromechanical drive according to claim 13 , wherein the roller or barrel is configured to be guided by the cylinder pin in a slot in the latching bolt, and wherein a free rotation of the roller or barrel is enabled and the roller or barrel is prevented from falling out as long as the roller is not in contact with the working piston. 15. The hydromechanical drive according to claim 12 , wherein the cutout in the working piston is a groove in an outer contour of the working piston. 16. The hydromechanical drive according to claim 13 , comprising: a supporting bolt on the latching bolt, which is configured to interact with the rotatably mounted element on a side of the latching bolt pointing towards the working piston. 17. The hydromechanical drive according to claim 16 , wherein the supporting bolt and the roller or barrel are formed from a hardened metal. 18. The hydromechanical drive according to claim 12 , wherein the spring energy store arrangement is a compression spring. 19. The hydromechanical drive according to claim 12 , in combination with a medium-voltage or a high-voltage circuit breaker. 20. The hydromechanical drive according to claim 19 , wherein the medium medium-voltage or the high-voltage circuit breaker is a circuit breaker of a gas-insulated high-voltage switchgear assembly.