Standing wave electron linear accelerator and container/vehicle inspection system

What is claimed is: 1. A standing wave electron linear accelerator, comprising: a magnetron for producing radio frequency microwaves; a plurality of accelerating tubes for forming standing waves therein to accelerate electrons therein; a microwave transmission system connected between the magnetron and the plurality of accelerating tubes to feed the microwaves from the magnetron into the plurality of accelerating tubes to form standing waves in the plurality of accelerating tubes; a plurality of electron guns for emitting electron beams into the plurality of accelerating tubes; a plurality of targets corresponding to and located in the plurality of accelerating tubes respectively, which are configured to be impinged by the accelerated electron beams in the accelerating tubes to form a plurality of continuous spectrums of X-rays; a plurality of shielding devices disposed corresponding to the plurality of targets, which are configured to, among the plurality of continuous spectrums of X-rays, remain an X-ray beam of a desired shape in a forward direction and shield X-rays oriented at other angles; and a microwave distributor disposed in the microwave transmission system for distributing the microwaves in the microwave transmission system into the accelerating tubes. 2. The standing wave electron linear accelerator according to claim 1 , wherein there are two said accelerating tubes, two said targets, two said electron guns and two said shielding devices, and the microwave distributor is configured to distribute the microwaves into the two accelerating tubes; and the standing wave electron linear accelerator is configured to emit X-ray beams towards both sides respectively. 3. The standing wave electron linear accelerator according to claim 2 , wherein the two accelerating tubes are inclined upwardly with respect to a horizontal direction; and the two accelerating tubes are staggered with one another in a front-rear direction of the standing wave electron linear accelerator. 4. A dual-channel container/vehicle inspection system, comprising: a first portal assembly for forming a first scanning channel for passage of a container/vehicle and provided with a plurality of first detector modules; a second portal assembly for forming a second scanning channel for passage of a container/vehicle and provided with a plurality of second detector modules; and a radiation source, which is the standing wave electron linear accelerator according to claim 2 and is disposed between the first portal assembly and the second portal assembly to emit X-ray beams to the first scanning channel and the second scanning channel respectively. 5. The container/vehicle inspection system according to claim 4 , further comprising: a control mechanism comprising a radiation source control module and an image acquisition module; and a device cabin disposed between the first portal assembly and the second portal assembly, wherein the radiation source and the control mechanism are disposed in the device cabin. 6. The container/vehicle inspection system according to claim 5 , further comprising: a first speed sensor and a second speed sensor for detecting traveling speeds of the containers/vehicles in the first and second scanning channels respectively, wherein the radiation source control module is configured to control emitting frequencies of X-ray beams emitted from the radiation source to the first and second scanning channels respectively on the basis of detection results of the first and second speed sensors. 7. The container/vehicle inspection system according to claim 5 , wherein the radiation source control module is configured to control emission/stop of the two X-ray beams emitted by the radiation source; and further comprising: a first position sensor and a second position sensor for detecting traveling positions of the containers/vehicles in the first and second scanning channels respectively; when it is determined that the container/vehicle reaches a predetermined position in the first scanning channel according to a detection result of the first position sensor, the radiation source emits the X-ray beam to the first scanning channel, and when it is determined that the container/vehicle reaches a predetermined position in the second scanning channel according to a detection result of the second position sensor, the radiation source emits the X-ray beam to the second scanning channel. 8. The container/vehicle inspection system according to claim 4 , wherein the first and second portal assemblies are staggered from one another in a traveling direction of the container/vehicle, and incident positions of the X-ray beams emitted from the radiation source to the first and second scanning channels are staggered from one another in the traveling direction of the container/vehicle. 9. The container/vehicle inspection system according to claim 4 , wherein the first portal assembly comprises a first transverse detector arm support and a first vertical detector arm support, wherein the plurality of the first detector modules is respectively disposed on the first transverse detector arm support and the first vertical detector arm support; the second portal assembly comprises a second transverse detector arm support and a second vertical detector arm support, wherein the plurality of the second detector modules is respectively disposed on the second transverse detector arm support and the second vertical detector arm support. 10. The container/vehicle inspection system according to claim 9 , wherein the first transverse detector arm support and the second transverse detector arm support extend perpendicular to a traveling direction of the container/vehicle respectively, and incident directions of the X-ray beams emitted from the radiation source to the first and second scanning channels respectively are perpendicular to the traveling direction of the container/vehicle. 11. The container/vehicle inspection system according to claim 9 , wherein the first transverse detector arm support and the second transverse detector arm support extend at a predetermined angle with respect to a direction perpendicular to a traveling direction of the container/vehicle respectively, and incident directions of the X-ray beams emitted from the radiation source to the first and second scanning channels respectively are at the predetermined angle with the direction perpendicular to the traveling direction of the container/vehicle. 12. A mobile container/vehicle inspection system, comprising: a chassis vehicle which is serving as a traveling mechanism; a pair of left and right portal assemblies which are switchable between an open state in which scanning channels are formed at left and right sides of the chassis vehicle and a retracted state in which the portal assemblies are retracted towards the chassis vehicle; a radiation source, which is the standing wave electron linear accelerator of claim 2 , capable of emitting X-ray beams towards left and right sides simultaneously; and a plurality of detector modules respectively mounted on the pair of portal assemblies to detect the X-ray beams emitted from the radiation source. 13. The mobile container/vehicle inspection system according to claim 12 , further comprising: a pair of left and right rotary platforms mounted on the chassis vehicle, which is configured to be rotated towards left and right sides of the chassis vehicle, wherein the pair of left and right portal assemblies are mounted on the chassis vehicle via the pair of left and right rotary platforms and are configured to be rotated along with the pair of left and right rotary platforms; and a