Patent Number: 
Section: claims

1. A liquid fuel combinatorial medical isotope production reactor arrangement, comprising:a. a modular reactor core having groups of symmetric homogeneous fuel assemblies interlinked together by a common upper plenum in a heterogeneous lattice arranged in a regular lattice;b. an individual and removable cooling arrangement, reflux condenser, and sweep gas circuit for each homogeneous fuel assembly group;c. a closed fuel circulation region within the reactor core;d. a closed loop reactor cooling arrangement; ande. a semi-closed loop radiolytic gas management arrangement being in fluid communication with the upper plenum. 2. The reactor arrangement of claim 1, wherein the fuel assemblies in each of the groups are interlinked by a common lower plenum. 3. The reactor arrangement of claim 1, wherein the fuel assemblies in all of the groups are interlinked by a common lower plenum. 4. The reactor arrangement of claim 1, wherein the fuel assemblies are arranged in a rectangular array lattice. 5. The reactor arrangement of claim 1, wherein the fuel assemblies are arranged in a triangular pitch lattice. 6. The reactor arrangement of claim 1, wherein the upper plenum comprises a disk-shaped housing having flat bottom surface, a flat top surface, an inlet opening for each of the fuel assemblies formed in the flat bottom surface and at least one outlet opening formed in the flat top surface and connected to the semi-closed loop radiolytic gas management arrangement. 7. The reactor arrangement of claim 1, wherein the removable cooling arrangement comprises a tubing coil which extends over each of the fuel assemblies. 8. The reactor arrangement of claim 7, wherein the removable cooling arrangement further comprises an inlet header and an outlet header, wherein the tubing coil and the reflux condenser are connected to form a continuous coil that is in communication with the inlet header and the outlet header. 9. The reactor arrangement of claim 8, further comprising a central umbilical support tube which houses the inlet header and the outlet header. 10. The reactor arrangement of claim 1, wherein the sweep gas circuit comprises a nozzle positioned above the individual and removable cooling arrangement. 11. The reactor arrangement of claim 10, wherein the individual and removable cooling arrangement comprises a tubing coil which extends over each of the fuel assemblies, and the nozzle is centrally aligned with the tubing coil. 12. The reactor arrangement of claim 1, wherein the sweep gas circuit further comprises an entrainment trap in fluid communication with the upper plenum, a hydrogen recombiner upstream from and in fluid combination with the entrainment trap and a gas cooler-condenser upstream from and in fluid combination with the hydrogen recombiner. 13. The reactor arrangement of claim 12, wherein the hydrogen recombiner comprises an axial bed having catalytic particles encased in a housing. 14. The reactor arrangement of claim 13, wherein the housing has an inlet and an outlet. 15. The reactor arrangement of claim 14, further comprising a pressure relief valve positioned at the inlet and the outlet of the housing and a pressure relief container in fluid communication with the pressure relief valves. 16. The reactor arrangement of claim 12, further comprising a gas filtering system in fluid communication with the gas cooler-condenser, the gas filtering system having a filter bed, a positive displacement compressor in fluid communication with the filter bed, a gas holding tank in fluid communication with the positive displacement compressor, a NOx removal system in fluid communication with the holding tank and a radioactive gas disposal system in fluid communication with the NOx removal system. 17. The reactor arrangement of claim 1, further comprising a 99Mo processing system having a first plurality of columns in fluid communication with the reactor core, and a plurality of separator columns containing a sorbent, the plurality of separator columns being in fluid communication with the first plurality of columns. 18. A liquid fuel combinatorial medical isotope production reactor arrangement, comprising:a. a modular reactor core having homogeneous fuel assemblies;b. an upper plenum which interlinks the fuel assemblies in a heterogeneous lattice, the upper plenum having a disk shaped housing with a flat bottom surface, a flat top surface, an inlet opening for each of the fuel assemblies formed in the flat bottom surface and at least one outlet opening formed in the flat top surface;c. a cooling arrangement, reflux condenser, and sweep gas circuit for each of the homogeneous fuel assemblies;d. a closed fuel circulation region within the reactor core;e. a closed loop reactor cooling arrangement; andf. a semi-closed loop radiolytic gas management arrangement being in fluid communication with the outlet opening of the upper plenum. 19. The reactor arrangement of claim 18, wherein the fuel assemblies are interlinked by a common lower plenum. 20. The reactor arrangement of claim 18, wherein the removable cooling arrangement comprises a tubing coil which extends over each of the fuel assemblies, the sweep gas circuit comprises a nozzle positioned above the individual and removable cooling arrangement, the nozzle being centrally aligned with the tubing coil. 21. A liquid fuel combinatorial medical isotope production reactor arrangement, comprising:a. a modular reactor core having groups of symmetric homogeneous fuel assemblies interlinked together by a common upper plenum in a heterogeneous lattice arranged in a regular lattice, wherein the common upper plenum links together at least two individual symmetric fuel assemblies;b. an individual and removable cooling arrangement, reflux condenser, and sweep gas circuit for each homogeneous fuel assembly group;c. a closed fuel circulation region within the reactor core;d. a closed loop reactor cooling arrangement; ande. a semi-closed loop radiolytic gas management arrangement being in fluid communication with the upper plenum.