Imaging unit and radiation image acquisition system

The invention claimed is: 1. An imaging unit for acquiring a radiation image of an object conveyed on a predetermined conveying path in a conveying direction, the imaging unit comprising: a housing having a wall portion placed to face the conveying path and a slit configured to pass radiation and formed in the wall portion; a scintillator that is installed in the housing and has an input surface to which the radiation passing through the slit is input; one or a plurality of mirrors that are installed in the housing and reflect scintillation light output from the input surface; and a line scan camera that is installed in the housing and detects the scintillation light reflected by the mirror, the line scan camera having a scan direction corresponding to the conveying direction and a line direction perpendicular to the scan direction, wherein the scintillator is placed so as to make the input surface parallel to both the conveying direction and the line direction, and the mirror is positioned outside an irradiation region connecting a peripheral edge of the slit to the input surface of the scintillator. 2. The imaging unit according to claim 1 , wherein the mirror includes a first mirror that is placed at a position overlapping a normal of the input surface and forms an acute angle between a reflecting surface of the first mirror and the input surface, and the line scan camera detects scintillation light output in a normal direction of the input surface. 3. The imaging unit according to claim 2 , wherein the slit is positioned between the scintillator, the first mirror, and the line scan camera in the conveying direction. 4. The imaging unit according to claim 2 , wherein the acute angle is within a range of 40° or more and 50° or less. 5. The imaging unit according to claim 1 , wherein the slit is positioned upstream or downstream of the scintillator in the conveying direction. 6. The imaging unit according to claim 1 , wherein an optical axis of the line scan camera is parallel to the conveying direction. 7. The imaging unit according to claim 1 , further comprising a second line scan camera that is installed in the housing and detects scintillation light output from a surface on an opposite side to the input surface. 8. A radiation image acquisition system comprising: a radiation source that outputs radiation toward the object; a conveying apparatus that conveys the object in the conveying direction; and an imaging unit according to claim 1 which is attached to the conveying apparatus so as to cause the irradiation region to include the conveying path of the conveying apparatus. 9. A radiation image acquisition system that acquires a radiation image of an object, the radiation image acquisition system comprising: a radiation source that outputs radiation toward the object; a conveying apparatus that conveys the object in a conveying direction; a scintillator having an input surface to which the radiation transmitted through the object conveyed by the conveying apparatus is input; one or a plurality of mirrors that reflect scintillation light output from the input surface; and a line scan camera that detects scintillation light reflected by the mirror and has a scan direction corresponding to the conveying direction and a line direction perpendicular to the scan direction, wherein the scintillator is placed so as to make the input surface parallel to both the conveying direction and the line direction, and the mirror is positioned outside an irradiation region connecting a focus of the radiation source to the input surface of the scintillator. 10. The radiation image acquisition system according to claim 9 , wherein the mirror includes a first mirror that is placed at a position overlapping a normal of the input surface and forms an acute angle between a reflecting surface of the first mirror and the input surface, and the line scan camera detects scintillation light output in a normal direction of the input surface. 11. The radiation image acquisition system according to claim 10 , wherein the radiation source is placed so as to locate the focus between a first virtual plane including the reflecting surface of the first mirror and a second virtual plane including the input surface. 12. The radiation image acquisition system according to claim 10 , wherein the acute angle is within a range of 40° or more and 50° or less. 13. The radiation image acquisition system according to claim 9 , wherein the irradiation region is formed upstream or downstream of the scintillator in the conveying direction. 14. The radiation image acquisition system according to claim 9 , wherein an optical axis of the line scan camera is parallel to the conveying direction. 15. The radiation image acquisition system according to claim 9 , further comprising a second line scan camera that detects scintillation light output from a surface on an opposite side to the input surface.