Imaging unit and radiation image acquisition system

The invention claimed is: 1. A radiation image acquisition system for acquiring a radiation image of an object, the radiation image acquisition system comprising: a belt conveyor that conveys the object on a conveying path in a conveying direction; a radiation source that outputs radiation toward the object from a direction inclined with respect to the conveying direction; a housing disposed so as to face the conveying path, the housing having a slit being configured to pass radiation that penetrates the object; a scintillator disposed within the housing, the scintillator having an input surface to which the radiation is input, and the scintillator being disposed such that the radiation passing through the slit is input from a direction inclined with respect to the input surface; and a line scan camera disposed within the housing, the line scan camera being configured to capture an image of scintillation light output from the scintillator. 2. The system according to claim 1 , further comprising: a reflection mirror that reflects the scintillation light output from the input surface of the scintillator towards the line scan camera. 3. The system according to claim 1 , further comprising: a reflection mirror that reflects the scintillation light output from a back surface of the scintillator towards the line scan camera. 4. An imaging unit for acquiring a radiation image of an object, the imaging unit comprising: a housing having a slit configured to pass radiation; a scintillator having an input surface to which the radiation is input, the scintillator being disposed within the housing such that the radiation passing through the slit is input from a direction inclined with respect to the input surface; a line scan camera disposed within the housing, the line scan camera being configured to capture an image of scintillation light output from the scintillator; and a reflection mirror that reflects the scintillation light output from the input surface of the scintillator towards the line scan camera. 5. The imaging unit according to claim 4 , further comprising: a second reflection mirror that reflects the scintillation light output from a back surface of the scintillator towards the line scan camera. 6. An imaging unit for acquiring a radiation image of an object, the imaging unit comprising: a housing having a wall portion that is capable of shielding radiation, the wall portion being formed with a slit that allows the radiation to pass therethrough; a scintillator having an input surface to which the radiation is input, the scintillator being disposed within the housing such that the radiation passing through the slit is input from a direction inclined with respect to the input surface; and a line scan camera disposed within the housing, the line scan camera being configured to capture an image of scintillation light output from the scintillator, wherein the wall portion extends so as to cover the scintillator and the line scan camera, and wherein the slit is positioned between the scintillator and the line scan camera in an extension direction of the wall portion. 7. The imaging unit according to claim 6 , wherein the line scan camera has a lens portion that is focused on the input surface of the scintillator. 8. The imaging unit according to claim 6 , further comprising: a reflection mirror that reflects the scintillation light output from the input surface of the scintillator towards the line scan camera. 9. The imaging unit according to claim 8 , wherein an angle between the input surface of the scintillator and a reflection surface of the reflection mirror is within the range of 40° or more and 50° or less. 10. The imaging unit according to claim 6 , further comprising: a reflection mirror that reflects the scintillation light output from a back surface of the scintillator towards the line scan camera. 11. The imaging unit according to claim 6 , wherein the line scan camera includes a single line sensor, a multiline sensor of two or more arrays or a TDI sensor. 12. The imaging unit according to claim 6 , wherein the slit is disposed such that a central axis of an irradiation region of the irradiation forms an angle of 45° with respect to the input surface, the irradiation region being defined as a region connecting a peripheral edge of the slit to the input surface of the scintillator.