Radiation detector and tomographic equipment provided with the same

The invention claimed is: 1. A radiation detector comprising a scintillator formed of two or more scintillation counter crystals to convert radiation emitted from a radiation source into fluorescence, and a fluorescence detection device to detect fluorescence from the scintillator, the radiation detector comprising a first reflector frame in which two or more first reflectors that extend along a first direction while being arranged in a second direction perpendicular to the first direction and two or more second reflectors that extend along the second direction while being arranged in the first direction are arranged in a lattice pattern, and a second reflector frame having two or more reflectors arranged in a lattice pattern as well as the first reflector frame, the first reflector frame and the second reflector frame being laminated along a third direction that is perpendicular to the first direction and the second direction, each of the scintillation counter crystals being inserted in the third direction through the first reflector frame and the second reflector frame, whereby two or more scintillation counter crystals are arranged in the first direction and the second direction to form a first scintillation counter crystal layer, and a position of the first reflector frame provided in the first scintillation counter crystal layer differing from a position of the second reflector frame provided in the first scintillation counter crystal layer. 2. The radiation detector according to claim 1 , wherein the scintillator further comprises a second scintillation counter crystal layer composed of two or more scintillation counter crystals in an interposed position between the first scintillation counter crystal layer and the fluorescence detection device, the second scintillation counter crystal layer comprises a third reflector frame having two or more reflectors arranged in a lattice pattern as well as the first reflector frame, and a fourth reflector frame having two or more reflectors arranged in a lattice pattern as well as the third reflector frame, the third reflector frame and the fourth reflector frame are laminated along a third direction that is perpendicular to the first direction and the second direction, each of the scintillation counter crystals is inserted in the third direction through the third reflector frame and the fourth reflector frame, whereby two or more scintillation counter crystals are arranged in the first direction and the second direction to form a second scintillation counter crystal layer, and a position of the third reflector frame provided in the second scintillation counter crystal layer differs from a position of the fourth reflector frame provided in the second scintillation counter crystal layer. 3. The radiation detector according to claim 2 , wherein the third reflector frame and the fourth reflector frames are formed of two or more first reflectors and two or more second reflectors, respectively, each of the first reflectors and the second reflectors has two or more grooves formed along the third direction, and the grooves each provided in the first reflectors and the second reflectors are fitted to form the third reflector frame and the fourth reflector frame. 4. The radiation detector according to claim 2 , wherein the third reflector frame and the fourth reflector frames are formed of two or more first reflectors and two or more second reflectors, respectively, each of the first reflectors and the second reflectors has two or more grooves formed along the third direction, and the grooves each provided in the first reflectors and the second reflectors are fitted to form the third reflector frame and the fourth reflector frame. 5. The radiation detector according to claim 1 , wherein the first reflector frame and the second reflector frames are formed of two or more first reflectors and two or more second reflectors, respectively, each of the first reflectors and the second reflectors has two or more grooves formed along the third direction, and the grooves each provided in the first reflectors and the second reflectors are fitted to form the first reflector frame and the second reflector frame. 6. The radiation detector according to claim 1 , wherein a transparent material is provided that allows fluorescence to pass through so as to surround each of the scintillation counter crystals that form the scintillator. 7. The radiation detector according to claim 1 , wherein four scintillation counter crystals are inserted in each of sections divided by a reflector lattice of the reflector frame provided in the scintillator. 8. Tomography equipment comprising as detector ring to generate radiation detection data with the radiation detector according to claim 1 that is arranged in a ring, shape; a coincidence device to perform coincidence of the radiation detector data; a fluorescence generating position discrimination device to discriminate a position of generating fluorescence in the detector ring; and an image formation device to receive analytical data sent from the fluorescence generating position discrimination device to form a sectional image of a subject. 9. A radiation detector comprising a scintillator formed of two or more scintillation counter crystals to convert radiation emitted from a radiation source into fluorescence, and a fluorescence detection device to detect fluorescence from the scintillator, the radiation detector comprising a first reflector frame in which two or more first reflectors that extend along a first direction while being arranged in a second direction perpendicular to the first direction and two or more second reflectors that extend along the second direction while being arranged in the first direction are arranged in a lattice pattern, and a second reflector frame, a third reflector frame, and a fourth reflector frame each having two or more reflectors arranged in a lattice pattern as well as the first reflector frame, the first reflector frame, the second reflector frame, the third reflector frame, and the fourth reflector frame being laminated along a third direction perpendicular to the first direction and the second direction, each of the scintillation counter crystals is inserted in the third direction through the first reflector frame, the second reflector frame, the third reflector frame, and the fourth reflector frame, whereby two or more scintillation counter crystals are arranged in the first direction and the second direction to form a scintillation counter crystal layer, and an inserting position in the scintillation counter crystal layer differing from one another in the first reflector frame, the second reflector frame, the third reflector frame, and the fourth reflector frame. 10. The radiation detector according to claim 9 , wherein the first reflector frame and the second reflector frames are formed of two or more first reflectors and two or more second reflectors, respectively, each of the first reflectors and the second reflectors has two or more grooves formed along the third direction, and the grooves each provided in the first reflectors and the second reflectors are fitted to form the first reflector frame and the second reflector frame. 11. The radiation detector according to claim 9 , wherein a transparent material is provided that allows fluorescence to pass through so as to surround each of the scintillation counter crystals that form the scintillator. 12. The radiation detector according to claim 9 , wherein four scintillation counter crystals are inserted in each of sections divided by a reflector lattice of the reflector frame provided in t