Method and apparatus for x-ray scan of occlusal dental casts

The invention claimed is: 1. A method for constructing a 3-D model incorporating 3-D scan image data of a maxillary dental arch positive physical model and of an opposing mandibular dental arch positive physical model, executed at least in part on data processing hardware, the method comprising: performing a single 3-dimensional x-ray scan of the positive physical models of the dental arches while the positive physical models of the dental arches are in an occlusal relationship to obtain 3-D image data including data representing each of the dental arch positive physical models; constructing respective 3-D volume models including a maxillary dental arch volume representation over a mandibular dental arch volume representation; generating a first 3D mesh model of surfaces of the maxillary dental arch volume representation and a second 3D mesh model of surfaces of the mandibular dental arch volume representation; determining contact areas where the first 3D surface mesh model and the second 3D surface mesh model intersect; identifying transition zones of the contact areas where the first 3D surface mesh model and the second 3D surface mesh model intersect; clipping the contact areas using information of the transition zones to separate and close the first 3D surface mesh model and the second 3D surface mesh model; and displaying, transmitting or storing the closed first 3D surface mesh model and the closed second 3D surface mesh model. 2. The method of claim 1 , further comprising segmenting teeth for each of the closed first 3D surface mesh model and the closed second 3D surface mesh model. 3. The method of claim 1 , where the 3-dimensionally x-ray scanning comprises a CBCT scan. 4. The method of claim 1 , where the determining contact areas comprises: simulating a grid of rays that cross the model orthogonally to the occlusal plane; identifying intersections of the rays with the first 3D surface mesh model and the second 3D surface mesh model; and determining the contact areas to be where the rays do not intersect the first 3D surface mesh model and the second 3D surface mesh model. 5. The method of claim 4 , where grid of rays are launched from the top of the first 3D surface mesh model or the bottom of the second 3D surface mesh model. 6. The method of claim 1 , further comprising aligning the closed first 3D surface mesh model and the closed second 3D surface mesh model. 7. The method of claim 6 , where the aligning comprises: a first translation in a direction between the closed first 3D surface mesh model and closed second 3D surface mesh model until a first contact point therebetween is found; at least one additional translation in an orthogonal direction using the first contact point as a starting point of the at least one additional translation to find other contact points and increase a total number of contact points; and at least one rotational translation using one of the contact points as the fulcrum to find other contact points and increase the total number of contact points. 8. A method for constructing a 3-D model incorporating 3-D scan image data of a maxillary dental arch and of an opposing mandibular dental arch, executed at least in part on data processing hardware, the method comprising: performing a single 3-dimensional x-ray scan of the physical positive models of the dental arches while the physical positive models of the dental arches are in an occlusal relationship to obtain 3-D image data including volume data representing each of the dental arch physical positive models; constructing separate 3-D volume models including a maxillary dental arch volume representation and a mandibular dental arch volume representation aligned in an occlusal arrangement using the 3-D image data; and displaying, transmitting or storing the 3-D model including the maxillary dental arch representation and the mandibular dental arch representation aligned in the occlusal arrangement. 9. The method of claim 8 , where the 3-dimensionally x-ray scanning the physical positive models of the dental arches is performed with a thin conformal intermediary between the physical positive models of the dental arches while the physical positive models of the dental arches are in the occlusal relationship, further comprising: generating a 3D mesh model of surfaces of each of the maxillary dental arch representation and the mandibular dental arch representation; aligning the 3D mesh model of surfaces of the maxillary dental arch representation and the 3D mesh model of surfaces of the mandibular dental arch representation; and displaying, transmitting or storing the aligned 3-D model including the maxillary dental arch representation aligned with the mandibular dental arch representation. 10. The method of claim 9 , where the aligning comprises: a first translation in a first direction between the maxillary dental arch representation and the mandibular dental arch representation until a first contact point therebetween is found; at least one additional translation in a second direction orthogonal to the first direction using the first contact point as a starting point of the at least one additional translation to find other contact points and increase a total number of contact points; and at least one rotational translation using one of the contact points as the fulcrum to find other contact points and increase the total number of contact points. 11. The method of claim 9 , where the thin conformal intermediary comprises a tissue 1-5 mm thick. 12. The method of claim 8 , further comprising segmenting teeth for each of the aligned 3D mesh model of surfaces of the maxillary dental arch representation and the 3D mesh model of surfaces of the mandibular dental arch representation. 13. The method of claim 8 , where the 3-dimensionally x-ray scanning comprises a CBCT scan. 14. The method of claim 8 , further comprising: starting a first 3D mesh model of surfaces of the maxillary dental arch representation and a second 3D mesh model of surfaces of the mandibular dental arch representation; and determining contact areas where the first 3D surface mesh model and the second 3D surface mesh model intersect; identifying transition zones of the contact areas where the first 3D surface mesh model and the second 3D surface mesh model intersect; clipping the contact areas using information of the transition zones to separate and complete the first 3D surface mesh model and the second 3D surface mesh model; and displaying, transmitting or storing the closed first 3D surface mesh model and the closed second 3D surface mesh model. 15. A method for constructing a 3-D model incorporating 3-D scan image data of a maxillary dental arch and of an opposing mandibular dental arch, executed at least in part on data processing hardware, the method comprising: performing a single 3-dimensional x-ray scan of the physical positive models of the dental arches while the physical positive models of the dental arches are in an occlusal relationship with a thin conformal intermediary between the physical positive models of the dental arches to obtain 3-D image data including volume data representing each of the dental arch physical positive models; constructing separate 3-D volume models including a maxillary dental arch volume representation and a mandibular dental arch volume representation aligned in an occlusal arrangement using the 3-D image data; generating a first 3D mesh model of surfaces of the maxillary dental arch volume representation and a second 3D mesh model of surfaces of the mandibular dental arch volume representati