Patent Number: 
Section: claims

1. A system for visual inspection of a nuclear reactor, the system comprising:a submersible remotely operated vehicle (SROV) system that is movable to an area within a nuclear vessel, the SROV system including a maneuverable inspection camera assembly for visual inspection of nuclear vessel components, the inspection camera assembly being maneuverable in relation to the SROV system;a control system located in an area remote from the area within the nuclear vessel, the control system configured to control the movement of the SROV system and the maneuvering of the inspection camera assembly;a cable suspending the inspection camera assembly from the SROV; anda first motor configured to vertically raise and lower the inspection camera assembly on the cable to and from the SROV; andan attachment mechanism connected to the SROV system, the attachment mechanism including,a suction device configured to impart a suction force on a surface of the nuclear vessel components in order to adhere the SROV system to the surface,at least one wheel configured to impart a friction force on the surface in order to move the SROV while the suction device is in operation. 2. The system of claim 1, wherein the SROV system includes at least one discharge device attached to the inspection camera assembly, the at least one discharge device configured to discharge cleaning fluid to an inspection area. 3. The system of claim 2, wherein the control system is further configured to control the discharge of the cleaning fluid, and the control system is connected to the SROV system via a control cable. 4. The system of claim 3, wherein the control system includes:a first display unit configured to display the visual inspection performed by the inspection camera assembly;at least one second display unit configured to display a position of the SROV system within the nuclear vessel;a valve system configured to control pressure and flow of the cleaning fluid discharged via the at least one discharge device; andan operational control unit configured to permit a user to control at least one of the movement of the SROV system, the maneuvering of the camera assembly, and the valve system,the operational control unit configured to display tracking information based on the position of the SROV system within the nuclear vessel. 5. The system of claim I, wherein the SROV system includes a plurality of propulsive devices configured to move the SROV system to the area within the nuclear vessel, the plurality of propulsive device being remotely controlled by the control system. 6. The system of claim 5, wherein the plurality of propulsive devices permit the SROV system to move horizontally, vertically, rotationally about an axis of the SROV system. 7. The system of claim 1, wherein the SROV system includes:a frame assembly having a vertical structure;an arm assembly connected to the vertical structure driven via a second motor, wherein the arm assembly is movable about an axis of the second motor, the second motor being remotely controlled by the control system. 8. The system of claim 7, wherein,the inspection camera assembly is connected to the arm assembly via the cable,the second motor being remotely controlled by the control system. 9. The system of claim 1, wherein the inspection camera assembly includes a camera manipulator having tilt and pan mechanisms, and an inspection camera, the inspection camera being connected to the camera manipulator, the tilt and pan mechanisms permitting the inspection camera to be moveable with respect to the camera manipulator, the camera manipulator being remotely controlled by the control system. 10. The system of claim 1, wherein the SROV system includes:a first positional camera for viewing a first perspective of the SROV system within the nuclear vessel;a second position camera for viewing a second perspective of the SROV system within the nuclear vessel. 11. The system of claim 1, wherein the SROV system includes:an attachment mechanism configured to attach the SROV system to the area of the nuclear vessel and permit the SROV system to move to different positions on the area. 12. The system of claim 11, wherein the area of the nuclear vessel is one of a shroud and Reactor Pressure Vessel (RPV) flange. 13. The system of claim 12, further comprising:an observation camera positioned on the RPV flange. 14. The system of claim 1, wherein the SROV system includes:an integrated calibration system configured to calibrate an inspection camera of the inspection camera assembly. 15. A submersible remotely operated vehicle (SROV) system for visual inspection of a nuclear reactor, the SROV system comprising:a device that is movable to an area within a nuclear vessel, the device including a maneuverable inspection camera assembly for visual inspection of nuclear vessel components, the inspection camera assembly being maneuverable in relation to the device, the movement of the device and the maneuvering of the inspection camera assembly being remotely controlled;a cable suspending the inspection camera assembly from the SROV; anda first motor configured to vertically raise and lower the inspection camera assembly on the cable to and from the SROV; andan attachment mechanism connected to the SROV system, the attachment mechanism including,a suction device configured to impart a suction force on a surface of the nuclear vessel components in order to adhere the SROV system to the surface,at least one wheel configured to impart a friction force on the surface in order to move the SROV while the suction device is in operation. 16. The SROV system of claim 15, further comprising:at least one discharge device attached to the inspection camera assembly, the at least one discharge device configured to discharge cleaning fluid to an inspection area. 17. The SROV system of claim 15, further comprising:a plurality of propulsive devices configured to move the device to the area within the nuclear vessel, the plurality of propulsive devices being remotely controlled. 18. The SROV system of claim 17, wherein the plurality of propulsive devices permit the device to move horizontally, vertically, rotationally about an axis of the device. 19. The SROV system of claim 15, further comprising:a mechanism configured to maneuver the inspection camera assembly. 20. The SROV system of claim 19, wherein the mechanism is configured to drive a cable that is connected to the inspection camera assembly to move the inspection camera assembly. 21. The SROV system of claim 20, further comprising:a cable retraction mechanism configured to maintain a tautness of the cable. 22. The SROV system of claim 15, further comprising:a frame assembly having a vertical structure;an arm assembly connected to the vertical structure driven via a second motor, wherein the arm assembly is movable about an axis of the second motor, the second motor being remotely controlled. 23. The SROV system of claim 22, wherein,the inspection camera assembly is connected to the arm assembly via the cable,the second motor is remotely controlled. 24. The SROV system of claim 15, wherein the inspection camera assembly includes a camera manipulator having tilt and pan mechanisms, and an inspection camera, the inspection camera being connected to the camera manipulator, the tilt and pan mechanisms permitting the inspection camera to be moveable with respect to the camera manipulator, the camera manipulator being remotely controlled. 25. The SROV system of claim 15, further comprising:a first positional camera for viewing a first perspective of the device within the nuclear vessel;a second position camera for viewing a second perspective of the device within the nuclear vessel. 26. The SROV system of claim 15, further comprising:an attachment mechanism configured to attached the device to the area of the nuclear vessel and permit the device to move to different positions on the area. 27. The SROV system of claim 15, further comprising:an integrated calibration system configured to calibrate an inspection camera of the inspection camera assembly. 28. The system of claim 1, further comprising:a submersible cable retraction mechanism configured to support the cable and the submersible inspection camera assembly,the cable retraction mechanism including a pulley to maintain a tautness of the cable above the SROV system. 29. The system of claim 1, wherein the control system includes,a first camera configured to view the visual inspection performed by the inspection camera assembly,at least one second camera configured to view a position of the SROV system within the nuclear vessel,an operational control unit configured to display tracking information based on the position of the SROV system within the nuclear vessel.