Patent Number: 
Section: claims

1. A method of producing radionuclides from irradiation targets in a nuclear reactor comprising the steps of:providing at least one instrumentation tube system including an instrumentation finger passing through a core of the nuclear reactor;inserting at least one irradiation target and at least one dummy target into the instrumentation finger and activating the irradiation target to form an activated irradiation target by exposing the irradiation target to neutron flux in the nuclear reactor core to form a radionuclide;retrieving the dummy target and the activated irradiation target from the instrumentation finger and separating the dummy target from the activated irradiation target;wherein the dummy target and the irradiation target are arranged in the instrumentation finger in a linear order wherein the dummy target holds the irradiation target at a predetermined axial position in the reactor core, said axial position corresponding to a pre-calculated neutron flux density sufficient for converting the irradiation target to the radionuclide,wherein the dummy target and the irradiation target have different magnetic properties, andwherein the step of separating the dummy target from the activated irradiation target includes exposing the dummy target and/or the activated irradiation target to a magnetic field to retain either the dummy target or the activated irradiation target in the instrumentation tube system and release the other one of the activated irradiation target or the dummy target from the instrumentation tube system. 2. The method according to claim 1 wherein the instrumentation finger has a center section and an end section, and wherein the irradiation targets are positioned in the center section and the dummy targets are positioned the end section. 3. The method according to claim 2 wherein the end section of the instrumentation finger is in a bottom part of the reactor core. 4. The method according to claim 3 wherein the instrumentation finger has an upper section located above the irradiation targets, and wherein the upper section is left empty. 5. The method according to claim 1 wherein one or more irradiation targets in the instrumentation finger are separated from each other by one or more dummy targets thereby defining irradiation target subsections. 6. The method according to claim 5 wherein the irradiation targets in the irradiation target subsections are made of a different parent material. 7. The method according to claim 1 wherein the dummy targets are ferromagnetic, and the irradiation targets are non-magnetic or paramagnetic. 8. The method according to claim 1 wherein the dummy targets and irradiation targets are inserted into and retrieved from the instrumentation tube system with pressurized gas. 9. The method according to claim 1 wherein the instrumentation tube system comprises a discharge tube, and the magnetic field is generated by activating at least one magnet arranged at the discharge tube. 10. The method according to claim 9 wherein the dummy targets and/or the irradiation targets are retained in the instrumentation tube system by a magnetic lock. 11. The method according to claim 1 wherein the step of activating the irradiation targets comprises calculating an irradiation time and an axial irradiation position considering the actual state of the reactor including current neutron flux, fuel burn-up, reactor power and/or loading. 12. The method according to claim 11 wherein the actual state of the reactor is determined using information comprising at least one of the following: neutron flux from ex-core or in-core detectors, activation values from an existing ball measuring system, burn-up, reactor power, loading, rod positions flow rate, inlet-temperature, pressure and time synchronization. 13. The method according to claim 1 wherein the step of retrieving the irradiation targets and dummy targets comprises transferring the irradiation targets and dummy targets out of the instrumentation finger into a discharge tube using pressurized gas and preserving the linear order of the dummy targets and the irradiation targets. 14. The method according to claim 10 wherein the step of separating the irradiation targets from the dummy targets comprises selectively removing the irradiation targets from the instrumentation tube system by exposing the irradiation targets and the dummy targets to a magnet field, opening the magnetic lock, and releasing one of the irradiation targets or the dummy targets from the discharge tube while keeping the other one of the irradiation targets or the dummy targets in the discharge tube by the action of the magnetic field. 15. The method according to claim 9 wherein the step of separating the irradiation targets from the dummy targets comprises driving one of the dummy targets or the irradiation targets back into the instrumentation finger or a holding section in the irradiation tube system while retaining the other one of the dummy targets or the irradiation targets in the discharge tube through the magnetic field. 16. A radionuclide generation system comprising:an instrumentation tube system of a nuclear reactor including at least one instrumentation finger passing through a core of the nuclear reactor wherein the instrumentation tube system is configured to permit insertion and removal of irradiation targets and dummy targets into the instrumentation finger, and wherein the dummy targets and the irradiation targets have different magnetic properties;a target drive system configured to insert the irradiation targets and dummy targets into the instrumentation finger in a predetermined linear order and to remove the irradiation targets and dummy targets from the instrumentation finger;a core monitoring system and an instrumentation and control unit linked to each other and configured to calculate an optimum axial irradiation position and time for the irradiation targets based on the actual state of the nuclear reactor as provided by the core monitoring system;a target removal system configured to retrieve the irradiation targets and dummy targets from the instrumentation tube system and separate the irradiation targets from the dummy targets, the target removal system including one or more magnets for exposing the dummy targets and/or the irradiation targets to a magnetic field to retain either the dummy targets or the irradiation targets in the instrumentation tube system and release the other one of the irradiation targets or the dummy targets from the instrumentation tube system. 17. The radionuclide generation system according to claim 16 wherein the instrumentation tube system is derived from a ball measuring system of a pressurized water reactor. 18. The radionuclide generation system according to claim 16 wherein the irradiation targets and the dummy targets have a round shape. 19. The radionuclide generation system according to claim 16 wherein the target drive system is pneumatically operated. 20. The radionuclide generation system according to claim 16 wherein the target drive system comprises a valve battery for separate control of transport of the irradiation targets and dummy targets in the instrumentation tube system. 21. The radionuclide generation system according to claim 16 wherein the one or more magnets exposing the dummy targets and/or the irradiation targets to a magnetic field are arranged at the instrumentation tube system. 22. The radionuclide generation system according to claim 21 wherein the one or more magnets are selected from a permanent magnet and a solenoid. 23. The radionuclide generation system according to claim 16 wherein the instrumentation tube system includes a discharge tube connected to the instrumentation finger configured to receive the irradiation targets and dummy targets removed from the instrumentation finger. 24. The radionuclide generation system according to claim 23 wherein the one or more magnets for exposing the dummy targets and/or the irradiation targets to a magnetic field are arranged at the discharge tube. 25. The radionuclide generation system according to claim 24 wherein the discharge tube is provided with a magnetic lock for blocking the irradiation targets and/or dummy targets flowing out of the discharge tube. 26. The radionuclide generation system according to claim 25 wherein the magnetic lock comprises a retainer for retaining the targets in the discharge tube. 27. The radionuclide generation system according to claim 25 wherein the magnetic field and/or the magnetic lock are remotely controlled by the instrumentation and control unit. 28. The radionuclide generation system according to claim 26 wherein the magnetic field and/or the magnetic lock are remotely controlled by the instrumentation and control unit.