Additive manufacturing of composite neutron absorbing components

The invention claimed is: 1. A method of additively manufacturing a composite neutron absorbing component with a binder jet 3D printer, the method comprising: repeatedly dispensing a first powder, having neutron absorbing characteristics, into layers to form a first portion of a powder bed on a build platform; repeatedly and selectively binding the layers of the first powder with binder to produce a first portion of the composite neutron absorbing component in the powder bed on the build platform; repeatedly dispensing a second powder, different from the first powder, into layers to form a second portion of a powder bed on a build platform; repeatedly and selectively binding the layers of the second powder with binder to produce a second portion of the composite neutron absorbing component in the powder bed on the build platform; curing the composite neutron absorbing component; and de-powdering the composite neutron absorbing component from the powder bed as a single composite neutron absorbing component with distinct portions made from different materials. 2. The method of claim 1 wherein the composite neutron absorbing component is a neutron absorbing collimator where a tip of the neutron absorbing collimator is made from a different material than a base of the neutron absorbing collimator. 3. The method of claim 1 wherein repeatedly and selectively binding the layers of the first powder with binder includes repeatedly and selectively depositing binder on the layers of the first powder, and wherein repeatedly and selectively binding the layers of the second powder with binder includes repeatedly and selectively depositing binder on the layers of the second powder. 4. The method of claim 1 wherein the first powder is natural Boron Carbide and the second powder is enriched Boron Carbide. 5. The method of claim 1 including repeatedly dispensing a third powder into layers to form a third portion of a powder bed on a build platform; repeatedly and selectively binding the layers of the third powder with binder to produce a third portion of the composite neutron absorbing component in the powder bed on the build platform. 6. The method of claim 5 wherein the first powder and third powder are different neutron absorbing powders and the second powder is a neutron non-transparent powder. 7. The method of claim 1 including dispensing the layers forming the second portion of the powder bed on the build platform on top of the layers forming the first portion of the powder bed on the build platform. 8. The method of claim 1 including loading the first powder onto a powder supply platform, loading the second powder onto the powder supply platform while the first powder is loaded on the powder supply platform thereby forming a transition area between the first powder on the powder supply platform and the second powder on the powder supply platform, wherein the first powder and the second powder blend from one to the other in the transition area. 9. The method of claim 1 including loading the first powder onto a powder supply platform, pausing the binder jet 3D printer in response to the repeated dispensing of the first powder into layers to form the first portion of the powder bed on the build platform, removing the first powder from the powder supply platform while the binder jet 3D printer is paused, loading the second powder onto the powder supply platform while the binder jet 3D printer is paused, resuming the binder jet 3D printer including said repeated dispensing of the second powder into layers to form the second portion of the powder bed on the build platform to provide precise-non-blended transitions from the first powder to the second powder. 10. The method of claim 1 including loading the first powder onto a powder supply platform, pausing the binder jet 3D printer after the first powder is transported from the powder supply platform, removing the first powder from the powder supply platform while the binder jet 3D printer is paused, loading a blend between the first powder and the second powder into the powder supply platform while the binder jet 3D printer is paused, resuming the binder jet 3D printer including dispensing the blend onto the powder bed, pausing the binder jet 3D printer after the blended powder is transported from the powder supply platform, removing the blended powder from the powder supply platform while the binder jet 3D printer is paused, replacing the blended powder with the second powder, and resuming the binder jet 3D printing including dispensing the second powder onto the powder bed to provide a controlled transition from layers of the first powder to layers of the second powder. 11. A method of additively manufacturing a composite neutron absorbing component, the method comprising: loading a plurality of different types of powder into a powder feed supply of a binder jet printer, wherein at least one of the plurality of different types of powders is a neutron absorbing powder having neutron absorbing characteristics; positioning a build platform of the binder jet printer; dispensing a portion of the plurality of different types of powder from the powder feed supply into a layer on a build platform; selectively depositing binder with a movable binder jet print head on the layer of powder on the build platform; repeating said positioning the build platform of the binder jet printer, said dispensing the powder from the powder feed supply into a layer on the build platform, and said selectively depositing binder with the movable binder jet print head on the layer of powder on the build platform to binder jet print a composite neutron absorbing component in a powder bed on the build platform; and de-powdering the composite neutron absorbing component from the powder bed. 12. The method of claim 11 wherein the composite neutron absorbing component is a composite neutron absorbing collimator, wherein a tip of the composite neutron absorbing collimator is additively manufactured from a different material than a base of the composite neutron absorbing collimator. 13. The method of claim 11 wherein the plurality of different types of powder include a first powder and a third powder that are different neutron absorbing powders and a second powder that is a neutron non-transparent powder. 14. The method of claim 11 wherein said loading includes loading the plurality of different types of powder onto the powder feed supply of the binder jet printer in layers, one on top of the next, forming transition areas between adjacent layers on the powder supply platform, wherein the adjacent different types of powder blend from one to the other in the transition areas. 15. The method of claim 11 wherein said loading includes loading the plurality of different types of powder into the powder feed supply one material at a time, pausing the binder jet printer after each type of material is transported to the build platform, removing any remainder material in the powder feed supply and loading a different material into the powder feed supply to be dispensed from the powder feed supply into a layer on the build platform to provide precise-non-blended transitions from one powder layer to the next. 16. The method of claim 11 including loading a first powder into a powder feed supply, printing a plurality of layers with the first powder, pausing the printing, removing any remaining first powder from the powder feed supply while paused, loading a blend between the first powder and the second powder into the powder feed supply while paused, resuming the printing including printing one o