Low-angle self-swinging, large-scale multi-slice spiral computed tomography apparatus and inspection method

What is claimed is: 1. A low-angle self-swinging type computed tomography apparatus, comprising: an X-ray generator configured to emit X-rays towards an object to be inspected; a data acquisition sub-system configured to collect signals of the X-rays passing through the object for inspection; a slip ring comprising an annular slip ring connected to a support to rotate about an axis at a circle center of the annular slip ring, wherein the X-ray generator and the data acquisition sub-system are arranged on a circumference of the annular slip ring and located opposite to each other with respect to the circle center of the annular slip ring, an electrical driving system connected to the slip ring, wherein the slip ring is configured to be actuated by a small driving force from the electrical driving system to reciprocate in a swinging way with the X-ray generator and the data acquisition sub-system carried thereon while the object to be inspected is located in or passing through an inspecting region between the X-ray generator and the data acquisition sub-system, wherein a center of gravity of the annular slip ring is offset with respect to the circle center of the annular slip ring such that the slip ring, after actuation by the electrical driving system, moves responsive to a force of gravity and reciprocates in an irregular angular velocity and constant amplitude of a single pendular reciprocating motion. 2. The computed tomography apparatus according to claim 1 , wherein the X-ray generator includes a large-power X-ray accelerator. 3. The computed tomography apparatus according to claim 1 , wherein the X-ray generator is configured to provide an X-ray beam in a cone or sector shape. 4. The computed tomography apparatus according to claim 1 , wherein the data acquisition sub-system comprises a plurality of rows of detectors. 5. The computed tomography apparatus according to claim 1 , further comprising a carrier configured to carry the object to be inspected to pass through the inspecting region defined by the X-ray generator and the data acquisition sub-system. 6. The computed tomography apparatus according to claim 1 , further comprising a control subsystem configured to control the movement of the slip ring and operations of the X-ray generator and the data acquisition sub-system. 7. The computed tomography apparatus according to claim 1 , further comprising a data processing sub-system configured to process a projection data collected by the data acquisition sub-system to reconstruct a three dimension image of the object. 8. An inspection method using the computed tomography apparatus according to claim 1 , comprising: emitting X-rays by using the X-ray generator and collecting signals of the X-rays by the data acquisition sub-system for inspection, while operating the slip ring such that the X-ray generator and the data acquisition sub-system reciprocate in a swinging way together with the slip ring while the object to be inspected is located in or passing through an inspecting region between the X-ray generator and the data acquisition sub-system, wherein the slip ring has a maximum swinging amplitude of no more than 180 degrees, wherein the center of gravity of the slip ring is offset with respect to the circle center of the annular slip ring. 9. The computed tomography apparatus according to claim 5 , wherein the carrier is configured to be linearly movable in two directions, including an up-down direction and a fore-and-aft direction.