Stationary CT apparatus

The invention claimed is: 1. A stationary CT apparatus, comprising: a scanning passage; a stationary X-ray source arranged partially around the scanning passage and comprising a plurality of ray emission focal spots; and a plurality of stationary detector modules arranged partially around the scanning passage and disposed opposite the X-ray source, elongation lines of external sides of sectorial ray beams emitted from two of the ray emission focal spots respectively arranged at one end and the other end of the plurality of ray emission focal spots intersect at a point of intersection, and a line formed by connecting the point of intersection to a central point of a ray receiving surface of each of the detector modules is perpendicular to the ray receiving surface of the each of the detector modules, when viewed in a plane intersecting the scanning passage, a first one of the two ray emission focal spots is arranged at the one end and a second one of the two ray emission focal spots is arranged at the other end; when viewed in the plane intersecting the scanning passage, the external side of the sectorial ray beam emitted from the first ray emission focal spot is located on one side that is away from the plurality of ray emission focal spots except the first ray emission focal spot, while the external side of the sectorial ray beam emitted from the second ray emission focal spot is located on the other side that is away from the plurality of ray emission focal spots except the second ray emission focal spot. 2. The stationary CT apparatus of claim 1 , wherein at least some of the plurality of ray emission focal spots of the X-ray source are arranged in a substantially L shape, Π shape, or straight line shape when viewed in a plane intersecting the scanning passage. 3. The stationary CT apparatus of claim 2 , wherein the plane is substantially perpendicular to the scanning passage or the plane is inclined with respect to the scanning passage. 4. The stationary CT apparatus of claim 2 , wherein at least some of the plurality of detector modules are arranged in a substantially L shape or a substantially Π shape when viewed in a plane intersecting the scanning passage. 5. The stationary CT apparatus of claim 4 , wherein the plurality of ray emission focal spots of the X-ray source are arranged in a straight line shape. 6. The stationary CT apparatus of claim 1 , wherein the ray receiving surfaces of the plurality of detector modules abut against one another end to end such that rays emitted from the plurality of ray emission focal spots cannot pass between the ray receiving surfaces. 7. The stationary CT apparatus of claim 1 , wherein at least some of the plurality of detector modules are arranged in a substantially L shape or a substantially Π shape when viewed in a plane intersecting the scanning passage. 8. The stationary CT apparatus of claim 7 , wherein the plurality of ray emission focal spots of the X-ray source are arranged in a straight line shape. 9. The stationary CT apparatus of claim 7 , wherein the plane is substantially perpendicular to the scanning passage or the plane is inclined with respect to the scanning passage. 10. The stationary CT apparatus of claim 1 , wherein the plurality of detector modules are arranged substantially in the shape of a spatial helix. 11. The stationary CT apparatus of claim 1 , wherein the plurality of ray emission focal spots of the X-ray source are arranged substantially in the shape of a spatial helix. 12. The stationary CT apparatus of claim 1 , wherein among the plurality of ray emission focal spots of the X-ray source and the plurality of detector modules, the corresponding ray emission focal spots and detector modules are arranged in the same plane, and the plane is substantially perpendicular to the scanning passage or the plane is inclined with respect to the scanning passage. 13. The stationary CT apparatus of claim 1 , wherein each detector module can receive a ray beam from at least one of the plurality of ray emission focal spots of the X-ray source. 14. The stationary CT apparatus of claim 1 , wherein the plurality of ray emission focal spots are arranged in at least one row in a direction in which an object under inspection enters and leaves the scanning passage. 15. The stationary CT apparatus of claim 1 , wherein the plurality of detector modules are arranged in at least one row in a direction in which an object under inspection enters and leaves the scanning passage. 16. The stationary CT apparatus of claim 1 , further comprising: a correction device disposed between the plurality of ray emission focal spots and the plurality of detector modules for controlling doses of ray beams from the ray emission focal spots. 17. The stationary CT apparatus of claim 16 , wherein the correction device is a grid device made of a W—Ni—Fe alloy. 18. The stationary CT apparatus of claim 17 , wherein a distance between the correction device and the ray receiving surfaces of the detector modules is at least five times as large as a distance between the correction device and the ray emission focal spots. 19. The stationary CT apparatus of claim 1 , wherein the X-ray source is a carbon nanotube X-ray source. 20. The stationary CT apparatus of claim 1 , wherein a control of the plurality of ray emission focal spots of the X-ray source is achieved by a Controller Area Network (CAN) bus, and the ray emission focal spots may be arranged at the same intervals over a length, and a sequence in which the ray emission focal spots emit rays may be arranged along a straight line or a curve.