CT security inspection system for baggage and detector arrangement thereof

What is claimed is: 1. A CT security inspection system for baggage, the CT security inspection system comprising: a scanning passage, through which a baggage enters and exits the CT security inspection system for baggage; an X-ray source comprising a target provided at one side of the scanning passage; a plurality of detector units, wherein each detector unit of the plurality of detector units comprises one or more detector crystals; and a gantry provided at an opposite side of the scanning passage, and on which the plurality of detector units are mounted, wherein, in each detector unit of said plurality of detector units, a vertex point of at least one detector crystal receiving face of each detector crystal of the one or more detector crystals of each detector unit of the plurality of detector units is positioned in a detector unit distribution circle centered at a center of the scanning passage, and said plurality of detector units are arranged successively in which one is adjacent to another, wherein detector crystal receiving faces of each of said plurality of detector units are within a scope of radiating ray beams with their center at the target of the X-ray source, and, in each detector unit of said plurality of detector units, a connection line between a midpoint of at least one of the detector crystal receiving faces and the target of the X-ray source is normal to the corresponding detector crystal receiving face, wherein the connection line between the midpoint of the corresponding detector crystal receiving face and the target of the X-ray source relative to a plane where the corresponding detector crystal receiving face is located has a minimum angle, larger than 85°, wherein the plurality of detector units comprise a head detector unit and a tail detector unit, the head detector unit comprises a head detector crystal, and the tail detector unit comprises a tail detector crystal, wherein an emission angle of the X-ray source is at least larger than an angle between a connection line between the end of the head detector crystal and the target of the X-ray source and a connection line between the end of the tail detector crystal and the target of the X-ray source, and wherein an effective scanning region for the scanning passage is located within the scope of the angle between the connection line between the end of the head detector crystal and the target of the X-ray source and a connection line between the end of the tail detector crystal and the target of the X-ray source. 2. The CT security inspection system of claim 1 , wherein at least two adjacent detector crystals are arranged in each detector unit of said plurality of detector units, and a distance between the at least two adjacent detector crystals is not less than 20 mm. 3. The CT security inspection system of claim 2 , wherein each detector unit of said plurality of detector units comprises a support, a high density radiation-proof plate connected to the support, and, the at least two adjacent detector crystals arranged on the high density radiation-proof plate and facing the X-ray source. 4. The CT security inspection system of claim 3 , further comprising: a first collimator and a second collimator, each including a plurality of grids, for decomposing original ray emitted by the X-ray source into a plurality of fan ray beams. 5. The CT security inspection system of claim 4 , further comprising: a detector crystal mounting bracket on which the one or more detector crystals of each of the plurality of detector units are mounted along an axial direction of said scanning passage; wherein said plurality of fan ray beams decomposed correspond to the detector crystal receiving faces, respectively, so as to obtain a plurality of detecting data synchronously in the axial direction of said scanning passage. 6. The CT security inspection system of claim 4 , wherein the plurality of grids for the first collimator and the second collimator comprise one or more dotted fitting curves related to distribution of radiation dose, wherein slits between some of the plurality of grids in the middle are relatively narrow while slits between some of the plurality of grids in the margin are relatively broader, such that scopes of energy at locations where different detector crystal receiving faces are positioned are substantially the same. 7. The CT security inspection system of claim 6 , wherein the plurality of grids of the first collimator and the second collimator comprise at least two slits. 8. The CT security inspection system of claim 3 , wherein said high density radiation-proof plate contains lead, W—Ni—Fe alloy, or steel. 9. The CT security inspection system of claim 1 , further comprising a slip-ring subsystem disposed around said scanning passage, wherein said X-ray source and said gantry are mounted on the slip-ring subsystem and are rotatable about said center of the scanning passage. 10. A detector arrangement used in a CT security inspection system for baggage, the CT security inspection system comprising: a scanning passage, through which a baggage enters and exits the CT security inspection system for baggage; an X-ray source comprising a target provided at one side of the scanning passage; a gantry provided at an opposite side of the scanning passage; and a first collimator and a second collimator each including a plurality of grids for decomposing the original ray from the X-ray source into a plurality of fan ray beams, wherein the detector arrangement comprises: a plurality of detector units, wherein each detector unit of the plurality of detector units comprises one or more detector crystals, wherein a vertex point of at least one detector crystal receiving face of a detector crystal of each of the one or more detector crystals of each detector unit of the plurality of detector units is positioned in a detector unit distribution circle with its center at a center of the scanning passage, and said plurality of detector units are arranged successively; and wherein detector crystal receiving faces of each of the plurality of detector units are within a scope of radiating ray beams with their center at the target of the X-ray source, and, in each detector unit of said plurality of detector units, a connection line between a midpoint of at least one of the detector crystal receiving faces and the target of the X-ray source is normal to the corresponding detector crystal receiving face. 11. The detector arrangement of claim 10 , wherein the connection line between the midpoint of the corresponding detector crystal receiving face and the target of the X-ray source relative to a plane where the corresponding detector crystal receiving face is located has a minimum angle, equal to or larger than 85°. 12. The detector arrangement of claim 11 , wherein, the plurality of detector units comprise a head detector unit and a tail detector unit, the head detector unit comprises a head detector crystal, and the tail detector unit comprises a tail detector crystal; and wherein an emission angle of the X-ray source is at least larger than an angle between a connection line between the end of the head detector crystal and the target of the X-ray source and a connection line between the end of the tail detector crystal and the target of the X-ray source. 13. The detector arrangement of claim 12 , wherein an effective scanning region for the scanning passage is located within a scope of the angle between the connection line between the end of the head detector crystal and the target of the X-ray source and a connection line between the end of the tail detector crystal and the target of the X-r