Electrohydraulic system for use under water, comprising an electrohydraulic actuator

The invention claimed is: 1. An electrohydraulic system for use under water, comprising: a container having an internal space; and an electrohydraulic actuator comprising: a hydraulic cylinder or motor; a hydraulic machine arranged in the internal space of the container, the hydraulic machine configured to adjust at least the hydraulic cylinder or hydraulic motor and configured to be operated with two delivery directions; a rotary drive unit mechanically coupled to the hydraulic machine for a common rotary movement, the rotary drive unit configured to adjust at least the hydraulic cylinder or motor, the rotary drive unit including a first electric motor; a hydraulic main drive arranged in the internal space of the container, the hydraulic main drive including a second electric motor configured to drive a pump so as to actuate the hydraulic cylinder or motor; and at least one non-return valve or at least one hydraulic shut-off valve configured such that a position of the hydraulic cylinder or motor remains unaltered when the rotary drive unit is decoupled and the hydraulic main drive is deactivated, wherein the rotary drive unit is arranged outside the container and is configured to couple to the hydraulic machine and decouple from the hydraulic machine, and wherein the electrohydraulic system is configured such that electrical energy for the rotary drive unit is independent of energy consumption of components in the container. 2. The electrohydraulic system as claimed in claim 1 , wherein the hydraulic cylinder or motor is a hydraulic cylinder, and the rotary drive unit and the hydraulic main drive are configured to adjust the hydraulic cylinder. 3. The electrohydraulic system as claimed in claim 2 , wherein the hydraulic cylinder is a differential cylinder or a synchronizing cylinder. 4. The electrohydraulic system as claimed in claim 2 , wherein the hydraulic cylinder includes a displaceable piston configured to adjust a process valve. 5. The electrohydraulic system as claimed in claim 2 , wherein the hydraulic cylinder comprises a helical pressure spring configured to reset the hydraulic cylinder. 6. The electrohydraulic system as claimed in claim 2 , wherein at least one solenoid valve is arranged such that a second cylinder chamber of the hydraulic cylinder is hydraulically balanced in the event of an electrical power failure. 7. The electrohydraulic system as claimed in claim 1 , further comprising at least one pressure limiting valve arranged and configured such that a maximum hydraulic system pressure is configured to be effectively limited. 8. The electrohydraulic system as claimed in claim 1 , wherein the hydraulic machine is configured as a hydrostatic gear or a hydraulic pump. 9. The electrohydraulic system as claimed in claim 1 , wherein a remote-controlled underwater vehicle comprises the rotary drive unit. 10. The electrohydraulic system as claimed in claim 1 , further comprising a coupling unit arranged between the rotary drive unit and the hydraulic machine. 11. The electrohydraulic system as claimed in claim 1 , wherein the hydraulic cylinder or motor is a rotational hydraulic motor. 12. The electrohydraulic system as claimed in claim 10 , wherein the coupling unit includes a connecting clutch. 13. A device configured to be operated under water and to control a deliverable volume flow of a gaseous or liquid medium, comprising: a process valve having a process valve housing and a process valve gate configured to control the volume flow; an electrohydraulic system comprising: a container having an internal space; and an electrohydraulic actuator comprising a hydraulic cylinder associated with the process valve housing, the hydraulic cylinder configured to move with the process valve gate; a hydraulic machine arranged in the internal space, the hydraulic machine configured to adjust at least the hydraulic cylinder and configured to be operated with two delivery directions; a rotary drive unit arranged on a remote-controlled underwater vehicle outside the container, the rotary drive unit configured to couple to and decouple from the hydraulic machine such that, when coupled thereto, the rotary drive unit drives the hydraulic machine, the rotary drive unit including a first electric motor; a hydraulic main drive arranged in the internal space of the container, the hydraulic main drive including a second electric motor configured to drive a pump so as to actuate the hydraulic cylinder or motor; and at least one non-return valve or at least one hydraulic shut-off valve configured such that a position of the hydraulic cylinder or motor remains unaltered when the rotary drive unit is decoupled and the hydraulic main drive is deactivated, wherein the device is configured such that electrical energy for the rotary drive unit is independent of energy consumption of components in the container.