CN208283313U - Radiation checking system - Google Patents

Abstract

The utility model discloses a kind of radiation checking systems.The radiation checking system has standard checking mode and quick checking mode, equipment is checked including fixed, including vertical angle of view check device, vertical angle of view check device exports the first radiation scanning ray in standard checking mode, exports the second radiation scanning ray in quick checking mode；Equipment is checked with mobile, check that equipment is removable relative to fixed, including horizontal view angle check device, horizontal view angle check device checks that equipment moves along the length direction of tested vehicle and export third radiation scanning ray with mobile in standard checking mode, fixes in quick checking mode and exports the 4th radiation scanning ray；Wherein the output energy of third radiation scanning ray and/or dosage are higher than the 4th radiation scanning ray.The utility model can take into account the percent of pass requirement of penetration capacity and vehicle that radiation monitoring is carried out to different vehicle.

Description

Radiation inspection system

Technical Field

The utility model relates to a radiation inspection technical field, in particular to radiation inspection system.

Background

Radiation imaging is a technique for observing the interior of an object with radiation rays. The technology can obtain the information such as the internal structure and the density of the object under the condition of not damaging the object, and is widely applied to the fields of medical health, national economy, scientific research and the like at present. Chest X-rays in hospitals and security checks at stations and airports are the most common examples in daily life. In the process of vehicle-mounted cargo inspection at customs, harbors and other places, the technology can realize cargo inspection without opening the box, and improve inspection efficiency. In order to reduce the radiation influence on the vehicle driver, the radiation energy or dose of the radiation source is limited to a certain extent, but for heavy-load cargos, the scanning inspection of low-energy or dose radiation rays may have the problem that the rays cannot penetrate through the scanning inspection, and therefore a certain radiation energy or dose needs to be ensured to improve the inspection accuracy.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a radiation inspection system, this radiation inspection system can select different inspection modes to different vehicles to can compromise the penetration ability of the radiation inspection of different vehicles and the passing rate requirement of vehicle. Meanwhile, the horizontal and vertical double-view scanning inspection of the vehicle can be realized.

The utility model discloses a first aspect discloses a radiation inspection system, has standard inspection mode and quick inspection mode, include:

a stationary inspection apparatus having a first inspection lane for passage of a vehicle to be inspected, including a vertical viewing angle inspection device that performs radiation inspection of a top surface or a bottom surface of the vehicle to be inspected, the vertical viewing angle inspection device outputting a first radiation scanning ray to inspect the vehicle to be inspected traveling through the first inspection lane in the standard inspection mode, the vertical viewing angle inspection device outputting a second radiation scanning ray to inspect the vehicle to be inspected traveling through the first inspection lane in the rapid inspection mode; and

a mobile inspection device movably disposed with respect to the fixed inspection device, having a second inspection passage through which the vehicle to be inspected passes, the mobile inspection equipment comprises a horizontal visual angle inspection device for scanning and inspecting the side surface of the inspected vehicle, in the standard inspection mode, the mobile inspection apparatus moves in a longitudinal direction of the inspected vehicle, the horizontal visual angle inspection device outputs a third radiation scanning ray to inspect the inspected vehicle passing through the second inspection passage, in the fast inspection mode, the mobile inspection equipment is fixed, the horizontal visual angle inspection device outputs a fourth radiation scanning ray to inspect the inspected vehicle running through the second inspection passage, wherein an output energy of the third radiation scanning ray is higher than an output energy of the fourth radiation scanning ray, and/or the dose of the third radiation scanning ray is higher than the dose of the fourth radiation scanning ray.

In some embodiments, the radiation inspection system further includes a vehicle-mounted cargo determination device for determining whether the vehicle-mounted cargo of the inspected vehicle is light-loaded cargo or heavy-loaded cargo; wherein,

when the vehicle-mounted cargo judgment device judges that the vehicle-mounted cargo is heavy-load cargo, the radiation inspection system is switched to the standard inspection mode;

and when the vehicle-mounted cargo judgment device judges that the vehicle-mounted cargo is light-load cargo, the radiation inspection system is switched to the rapid inspection mode.

In some embodiments, the radiation inspection system further includes a control device, the control device is in signal connection with the vehicle-mounted cargo determination device, the fixed inspection device and the mobile inspection device, and the control device receives a determination result that the vehicle-mounted cargo determined by the vehicle-mounted cargo determination device is light-loaded cargo or heavy-loaded cargo, and operates the fixed inspection device and the mobile inspection device according to the determination result to automatically switch the radiation inspection system between the standard inspection mode and the rapid inspection mode.

In some embodiments, the vehicle-mounted cargo determination device includes a weighing device for weighing the vehicle to be detected, and determines whether the vehicle-mounted cargo of the vehicle to be detected is light-loaded cargo or heavy-loaded cargo according to a weighing result of the weighing device.

In some embodiments, the output energy of the third scanning ray of radiation is higher than the output energy of the first scanning ray of radiation and the second scanning ray of radiation; and/or the dose of the third radiation scanning ray is higher than the output doses of the first radiation scanning ray and the second radiation scanning ray.

In some embodiments, the radiation inspection system further comprises:

a first detection unit that detects whether the subject vehicle enters an inspection area of the radiation inspection system; and/or the presence of a gas in the gas,

the second detection unit is coupled with the vertical visual angle inspection device, detects whether the part of the detected vehicle needing radiation protection passes through the vertical visual angle inspection device and generates a first passing signal, and the vertical visual angle inspection device receives the first passing signal and outputs the first radiation scanning ray or the second radiation scanning ray; and/or the presence of a gas in the gas,

and the third detection unit is coupled with the horizontal visual angle inspection device, detects whether the part of the detected vehicle needing radiation protection passes through the horizontal visual angle inspection device and generates a second pass signal, and the horizontal visual angle inspection device receives the second pass signal and outputs the third radiation scanning ray or the fourth radiation scanning ray.

Based on the utility model provides a radiation inspection system when guaranteeing personnel radiation dose safety, can select different inspection modes to different vehicles. The standard inspection mode is selected, so that the horizontal view angle radiation scanning inspection can be carried out on the inspected vehicle by using radiation rays with higher dose and/or energy, and the inspection accuracy of the inspected vehicle is improved; the selection of the quick inspection mode helps to improve the passing rate of the inspected vehicle. Meanwhile, the radiation inspection system can realize radiation scanning inspection from horizontal and vertical view angles in two inspection modes, and further improves the inspection accuracy of vehicle-mounted cargos of the inspected vehicle.

Other features of the present invention and advantages thereof will become apparent from the following detailed description of exemplary embodiments of the invention, which proceeds with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without undue limitation to the invention. In the drawings:

fig. 1 is a schematic structural view of a radiation inspection system according to an embodiment of the present invention when a vehicle to be inspected passes through a first inspection passage of a fixed inspection apparatus;

fig. 2 is a schematic structural diagram of the radiation inspection system according to the embodiment of the present invention when the inspected vehicle passes through the second inspection passage of the mobile inspection apparatus;

fig. 3 is a schematic structural diagram of the radiation inspection system according to the embodiment of the present invention in the fast inspection mode for inspecting the inspected vehicle;

fig. 4 is a schematic structural diagram of the radiation inspection system according to the embodiment of the present invention in inspecting a vehicle under inspection in the standard inspection mode.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the invention, its application, or uses. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

Unless specifically stated otherwise, the relative arrangement of the components and steps, the numerical expressions, and numerical values set forth in these embodiments do not limit the scope of the present invention. Meanwhile, it should be understood that the sizes of the respective portions shown in the drawings are not drawn in an actual proportional relationship for the convenience of description. Techniques, methods, and apparatus known to those of ordinary skill in the relevant art may not be discussed in detail but are intended to be part of the specification where appropriate. In all examples shown and discussed herein, any particular value should be construed as merely illustrative, and not limiting. Thus, other examples of the exemplary embodiments may have different values. It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, further discussion thereof is not required in subsequent figures.

Spatially relative terms, such as "above … …," "above … …," "above … …," "above," and the like, may be used herein for ease of description to describe one device or feature's spatial relationship to another device or feature as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if a device in the figures is turned over, devices described as "above" or "on" other devices or configurations would then be oriented "below" or "under" the other devices or configurations. Thus, the exemplary term "above … …" can include both an orientation of "above … …" and "below … …". The device may be otherwise variously oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

In the following description, the term "front" refers to a side of the subject vehicle near the rear of the vehicle;

"rear" refers to the side opposite to "front", and "left" and "right" refer to the left-right direction formed when facing the front.

As shown in fig. 1 to 4, the radiation inspection system of the present embodiment has a standard inspection mode and a quick inspection mode, including a fixed inspection apparatus and a mobile inspection apparatus.

The stationary inspection apparatus has a first inspection lane 1 through which a vehicle 3 to be inspected passes. The stationary inspection apparatus includes a vertical-view inspection device that performs radiation inspection on the top or bottom surface of the inspected vehicle 3. In the standard inspection mode, the vertical viewing angle inspection apparatus outputs a first radiation scanning ray to inspect the subject vehicle 3 traveling through the first inspection lane 1, and in the rapid inspection mode, the vertical viewing angle inspection apparatus outputs a second radiation scanning ray to inspect the subject vehicle 3 traveling through the first inspection lane 1.

The mobile inspection device is movably arranged with respect to the stationary inspection device. The mobile inspection apparatus has a second inspection lane 2 through which an inspected vehicle 3 passes. The mobile inspection apparatus includes a horizontal visual angle inspection device that performs scanning inspection of the side surface of the subject vehicle 3. In the standard inspection mode, the mobile inspection apparatus moves in the lengthwise direction of the inspected vehicle 3, and the horizontal visual angle inspection device outputs the third radiation scanning ray to inspect the inspected vehicle 3 passing through the second inspection tunnel 2. In the quick inspection mode, the mobile inspection apparatus is fixed, and the horizontal visual angle inspection device outputs the fourth radiation scanning ray to inspect the inspected vehicle 3 traveling through the second inspection tunnel 2. Wherein the output energy of the third radiation scanning ray is higher than the output energy of the fourth radiation scanning ray, and/or the dose of the third radiation scanning ray is higher than the dose of the fourth radiation scanning ray.

The radiation inspection system can select different inspection modes for different vehicles while ensuring the safety of the radiation dose of personnel. The selection of the standard inspection mode can perform horizontal view angle radiation scanning inspection on the inspected vehicle by utilizing higher dose and/or energy radiation rays so as to improve the inspection accuracy of the inspected vehicle. The selection of the quick inspection mode helps to improve the passing rate of the inspected vehicle. Meanwhile, the radiation inspection system can realize radiation scanning inspection from horizontal and vertical view angles in two inspection modes, and further improves the inspection accuracy of vehicle-mounted cargos of the inspected vehicle.

As shown in fig. 1, in the present embodiment, the vertical viewing angle inspection apparatus includes a first radiation source 5 located above the first inspection passage 1 and a first detection apparatus 4 located below the first radiation source 5.

The first radiation source 5 emits radiation rays such as X-rays or γ -rays downward for scanning the inspection vehicle 3 passing through the first inspection passage 1.

The first detecting device 4 is used for receiving the radiation emitted by the radiation source 5. The radiation rays passing through the inspected vehicle 3 are received by the first detecting device 4 and converted into digital signals, and then the digital signals are processed on a digital processing and imaging device such as a computer to form a transmission scan image.

As shown in fig. 1, in the present embodiment, the first detection device 4 includes a first detection unit 4a located on the left side of the first inspection lane 1, a second detection unit 4b located below the first inspection lane 1, and a third detection unit 4c located on the right side of the first inspection lane 1. The first detection unit 4a, the second detection unit 4b and the third detection unit 4c are respectively used for receiving the radiation rays emitted downwards by the first radiation source 5 with different angles.

In some embodiments, the first radiation source may be located below the first examination channel, and the first detection arrangement may comprise a first detection unit located on the left side of the first examination channel, a second detection unit located above the first examination channel, and a third detection unit located on the right side of the first examination channel.

The output energy and/or dose of the first radiation scanning ray output by the vertical viewing angle inspection device in the standard inspection mode may be the same as or different from the second radiation scanning ray output by the vertical viewing angle inspection device in the fast inspection mode.

The mobile inspection apparatus may be provided upstream or downstream of the fixed inspection apparatus movably in the moving direction of the subject vehicle 3. In the present embodiment, as shown in fig. 3 or 4, the mobile inspection apparatus is disposed upstream of the fixed inspection apparatus. The mobile inspection device may be moved on the ground or on rails by means of bottom mounted wheelsets or the like.

As shown in fig. 2, the horizontal viewing angle inspection apparatus includes a second radiation source 7 located at a side of the second inspection passage 2 and a second detection apparatus 6 for receiving radiation rays emitted from the second radiation source 7. The second detection arrangement 6 comprises a fourth detection unit 6a located above the second examination channel 2 and a fifth detection unit 6b located on the other side of the second examination channel 2 opposite the second radiation source 7.

In some embodiments, the output energy of the third scanning ray of radiation is higher than the output energy of the first scanning ray of radiation and the second scanning ray of radiation; and/or the dose of the third scanning ray of radiation is higher than the output doses of the first and second scanning rays of radiation.

The radiation inspection system of the embodiment can select different inspection modes for different vehicles while ensuring the safety of the radiation dose of personnel.

For the inspected vehicle 3 carrying heavy load, which is not easy to be penetrated by radiation rays, a standard inspection mode can be selected to improve the inspection accuracy of the inspected vehicle 3.

In the standard inspection mode, the driver first drives the inspected vehicle 3 with heavy load into the inspection area of the radiation inspection system, and after the inspected vehicle 3 reaches the inspection area of the mobile inspection device, the driver stops. After confirming that the driver leaves the inspection area of the radiation inspection system, the mobile inspection device is started to perform radiation scanning on the inspected vehicle 3. The horizontal visual angle inspection device moves from one end of the inspected vehicle 3 to the other end (head to tail, or tail to head) as the mobile inspection apparatus moves along the length direction of the inspected vehicle 3. In the process, the second radiation source 7 of the horizontal visual angle inspection device emits a third radiation scanning ray to scan the vehicle-mounted cargos of the inspected vehicle 3, and the second detection device 6 receives the radiation ray penetrating through the vehicle-mounted cargos and forms a scanning image of the horizontal visual angle on the imaging device. After the scanning is finished, the driver drives the detected vehicle 3 to leave, the detected vehicle passes through the first inspection channel 1 of the fixed inspection equipment in the advancing process, and after the detected vehicle 3 enters the first inspection channel 1, the vertical visual angle inspection device of the fixed inspection equipment sends out a first radiation scanning ray to finish the scanning imaging of the vertical visual angle.

In some embodiments, the mobile inspection device may be located downstream of the fixed inspection device, wherein the driver drives the vehicle through the first inspection lane to complete the vertical view of the fixed inspection device and then to perform the horizontal view of the fixed inspection device.

The rapid inspection mode can be selected for the inspected vehicle 3 loaded with light-load cargo, which is relatively easy to be penetrated by the radiation ray. The vehicle 3 to be inspected is subjected to a radiation scanning inspection of a horizontal angle of view with a radiation ray of a lower dose to improve the inspection speed of the vehicle 3 to be inspected.

In the fast inspection mode, the mobile inspection device and the horizontal visual angle inspection device thereof are fixed, and the driver directly drives the inspected vehicle 3 to sequentially pass through the second inspection passage 2 of the mobile inspection device and the first inspection passage 1 of the fixed inspection device. While passing through the second inspection passage 2, the horizontal visual angle inspection device emits a fourth radiation scanning ray to scan and inspect the vehicle 3 to be inspected. The vertical visual angle inspection device emits a second radiation scanning ray to scan and inspect the vehicle 3 to be inspected when passing through the first inspection channel 1.

The radiation inspection system of the present embodiment can select different inspection modes for the inspected vehicle 3 for different types of vehicle-mounted cargo. The high-dose and/or high-energy radiation ray scanning inspection can be adopted when the goods are difficult to detect, so that the inspection accuracy is improved. When the goods are easy to inspect, the low-dose and/or low-energy radiation rays are adopted for scanning and inspecting, so that the passing efficiency of the inspected vehicle is improved, the inspection time is reduced, and both the efficiency and the inspection accuracy are considered. In the two modes, scanning images of a horizontal view angle and a vertical view angle are provided simultaneously, and the inspection accuracy is improved.

In some embodiments, the radiation inspection system further includes an on-board cargo determination device for determining whether the on-board cargo of the inspected vehicle is light-load cargo or heavy-load cargo. When the vehicle-mounted cargo judgment device judges that the vehicle-mounted cargo is heavy-duty cargo, the radiation inspection system is switched to a standard inspection mode. When the vehicle-mounted cargo judgment device judges that the vehicle-mounted cargo is light-load cargo, the radiation inspection system is switched to a quick inspection mode. The vehicle-mounted cargo judgment device can automatically judge whether the vehicle-mounted cargo is light-load cargo or heavy-load cargo according to the information of the detected vehicle 3, and then the radiation inspection system is switched to a corresponding inspection mode according to the judgment result.

In some embodiments, the vehicle-mounted cargo determination device includes a determination processor, and after inputting the information of the category, specification, quantity, weight, and the like of the vehicle-mounted cargo of the detected vehicle 3 into the processor, the processor automatically analyzes and determines whether the vehicle-mounted cargo of the detected vehicle 3 is light-loaded cargo or heavy-loaded cargo, and then the radiation inspection system switches to the corresponding inspection mode.

In some embodiments, the vehicle-mounted cargo determination device includes a weighing device that weighs the vehicle 3 to be inspected, and determines whether the vehicle-mounted cargo of the vehicle to be inspected is light-loaded cargo or heavy-loaded cargo according to a weighing result of the weighing device. For example, the vehicle-mounted cargo determination device includes a determination processor and a weighing device connected thereto, the weighing device, such as a wagon balance or the like, weighs the vehicle 3 to be detected, and then inputs weighing information to the determination processor, and the determination processor determines whether the vehicle-mounted cargo is light-load cargo or heavy-load cargo according to the weighing information.

In some embodiments, the radiation inspection system further comprises a control device, and the control device is in signal connection with the vehicle-mounted cargo judgment device, the fixed inspection equipment and the mobile inspection equipment. The control device receives the judgment result that the vehicle-mounted cargo judged by the vehicle-mounted cargo judgment device is light-load cargo or heavy-load cargo, and controls the fixed inspection equipment and the mobile inspection equipment according to the judgment result so that the radiation inspection system can be automatically switched between a standard inspection mode and a quick inspection mode.

The control device includes signal input and output ports and a central processor for processing signals and issuing commands. In some embodiments, the control device further includes a computer display screen and a GUI interface to facilitate a worker tracking and processing the progress of the radiation inspection system.

The control device may be various devices that implement the aforementioned control functions, including but not limited to a computer, a general purpose processor, a Programmable Logic Controller (PLC), an Application Specific Integrated Circuit (ASIC), or a Field Programmable Gate Array (FPGA), etc.

In some embodiments, the radiation inspection system further comprises a first detection unit for detecting whether the vehicle 3 under inspection enters an inspection area of the radiation inspection system.

The first detection unit may include a correlation type photoelectric sensor having a light emitter and a light receiver, which are disposed on both sides of the front end of the inspection area, and when the subject vehicle 3 enters the inspection area of the radiation inspection system, the light emitted from the light emitter is blocked by the subject vehicle 3, affecting the reception by the light receiver, thereby generating a signal that the subject vehicle 3 enters the inspection area. The first detecting unit may also include a ground induction coil disposed in front of the inspection area, and when the vehicle 3 passes through the ground induction coil, a ground induction signal is generated, so as to determine that the vehicle 3 enters the inspection area. The provision of the first detection unit facilitates the determination of whether the subject vehicle 3 has entered the inspection area of the radiation inspection system so that the radiation inspection system starts preparation for radiation scanning inspection.

In some embodiments, the radiation inspection system further comprises a second detection unit. The second detection is coupled to the vertical viewing angle inspection device, detects whether a portion of the inspected vehicle 3 requiring radiation protection has passed the vertical viewing angle inspection device and generates a first pass signal. The vertical visual angle inspection device receives the first pass signal and triggers the first radiation source 5 to output a first radiation scanning ray in the standard inspection mode or a second radiation scanning ray in the fast inspection mode.

The second detection unit may include a speed sensor and an opposite type photo sensor having a light emitter and a light receiver, or include a speed sensor and a ground sensing coil. The correlation type photoelectric sensor or the ground induction coil is arranged in front of the vertical inspection device to generate an entrance signal of the inspected vehicle, the speed sensor is used for measuring the speed of the inspected vehicle 3, the time of the portion, needing to be protected, of the inspected vehicle 3 passing through the vertical viewing angle device is calculated by using the entrance signal and the measured speed, and a first passing signal is generated after the time is up.

In some embodiments, the radiation inspection system further comprises a third detection unit. The third detecting unit is coupled to the horizontal visual angle inspection device, detects whether a portion of the subject vehicle 3 requiring radiation protection has passed through the horizontal visual angle inspection device, and generates a second pass signal. And after receiving the second pass signal, the horizontal visual angle inspection device triggers the second radiation source 7 to output a third radiation scanning ray in a standard inspection mode or output a fourth radiation scanning ray in a fast detection mode.

The third detecting unit is similar to the second detecting unit in function and structure, except that in the standard inspection mode, the speed measuring sensor measures the moving speed of the horizontal visual angle inspection device, then calculates the passing time of the part of the inspected vehicle 3 needing radiation protection according to the speed, and generates a second passing signal.

In some embodiments, the vehicle-mounted cargo can be judged to be heavy-load cargo or light-load cargo by means of manual work. In some embodiments, after the vehicle-mounted cargo determination device determines whether the vehicle-mounted cargo is light-load cargo or heavy-load cargo, the fixed inspection radiation inspection and the mobile inspection equipment can be adjusted and set manually to switch the inspection mode.

The embodiment of the utility model provides a still provide an use aforementioned radiation inspection system to inspect by the radiation inspection method of examining vehicle 3, include: selecting one inspection mode from the standard inspection mode and the quick inspection mode according to the property of the cargo on board the inspected vehicle 3; the subject vehicle 3 is inspected in the selected inspection mode.

In some embodiments, the selecting one of the standard inspection mode and the rapid inspection mode for the property of the vehicle-mounted cargo of the inspected vehicle 3 includes determining whether the vehicle-mounted cargo of the inspected vehicle 3 is light-loaded cargo or heavy-loaded cargo according to the property of the vehicle-mounted cargo, wherein the standard inspection mode is selected when the vehicle-mounted cargo is determined to be heavy-loaded cargo; and when the vehicle-mounted cargo is judged to be light-load cargo, selecting the rapid inspection mode.

The property of the vehicle-mounted cargo comprises at least one of cargo category, cargo quantity, cargo weight, cargo density, cargo structure and cargo loading mode. In some embodiments, the information of the vehicle-mounted cargo can be obtained by automatically or manually entering a license plate number or a container number of the vehicle-mounted cargo to call receipt information such as a declaration form or a manifest. In some embodiments, after obtaining the information related to the property of the vehicle-mounted cargo, the vehicle-mounted cargo may be determined to be light-loaded cargo or heavy-loaded cargo based on historical data, image training, and the like. In some embodiments, the ratio of the two inspection modes, i.e., the fast inspection mode and the standard inspection mode, can be dynamically adjusted by adjusting the division criteria of the light-load cargo and the heavy-load cargo.

In some embodiments, when the inspection vehicle 3 is inspected in the standard inspection mode, the method includes: after the part of the vehicle 3 to be detected, which needs radiation protection, passes through the vertical visual angle inspection device, the vertical visual angle inspection device starts to emit the first radiation scanning ray; and/or after the vehicle 3 to be inspected is parked, the horizontal visual angle inspection device outputs the third radiation scanning ray. In some embodiments, when the subject vehicle 3 is inspected in the quick inspection mode, the method includes: after the part of the vehicle 3 to be detected, which needs radiation protection, passes through the vertical visual angle inspection device, the vertical visual angle inspection device outputs the second radiation scanning ray; and/or the horizontal visual angle inspection device outputs the fourth radiation scanning ray after the part of the inspected vehicle 3 needing radiation protection passes through the horizontal visual angle inspection device. The radiation inspection methods in the standard inspection mode and in the rapid detection mode in the above embodiments contribute to further enhancing the radiation protection of the portion requiring radiation protection.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention and not to limit it; although the present invention has been described in detail with reference to preferred embodiments, it should be understood by those skilled in the art that: the invention can be modified or equivalent substituted for some technical features; without departing from the spirit of the present invention, it should be understood that the scope of the claims is intended to cover all such modifications and variations.

Claims (6)

1. A radiation inspection system having a standard inspection mode and a quick inspection mode, comprising:

a stationary inspection apparatus having a first inspection lane (1) through which a vehicle (3) to be inspected passes, including a vertical viewing angle inspection device that performs radiation inspection on a top surface or a bottom surface of the vehicle (3) to be inspected, the vertical viewing angle inspection device outputting a first radiation scanning ray to inspect the vehicle (3) to be inspected traveling through the first inspection lane (1) in the standard inspection mode, and outputting a second radiation scanning ray to inspect the vehicle (3) to be inspected traveling through the first inspection lane (1) in the rapid inspection mode; and

a mobile inspection apparatus movably disposed with respect to the fixed inspection apparatus, having a second inspection lane (2) through which a vehicle (3) to be inspected passes, the mobile inspection apparatus including a horizontal angle-of-view inspection device that performs a scanning inspection of a side surface of the vehicle (3) to be inspected, the mobile inspection apparatus moving in a lengthwise direction of the vehicle (3) to be inspected in the standard inspection mode, the horizontal angle-of-view inspection device outputting a third radiation scanning ray to inspect the vehicle (3) to be inspected passing through the second inspection lane (2), the mobile inspection apparatus being fixed in the rapid inspection mode, the horizontal angle-of-view inspection device outputting a fourth radiation scanning ray to inspect the vehicle (3) to be inspected traveling through the second inspection lane (2), wherein an output energy of the third radiation scanning ray is higher than an output energy of the fourth radiation scanning ray, and/or the dose of the third radiation scanning ray is higher than the dose of the fourth radiation scanning ray.

2. The radiation inspection system according to claim 1, further comprising an on-board cargo determination device for determining whether the on-board cargo of the inspected vehicle (3) is light-load cargo or heavy-load cargo; wherein,

when the vehicle-mounted cargo judgment device judges that the vehicle-mounted cargo is heavy-load cargo, the radiation inspection system is switched to the standard inspection mode;

and when the vehicle-mounted cargo judgment device judges that the vehicle-mounted cargo is light-load cargo, the radiation inspection system is switched to the rapid inspection mode.

3. The radiation inspection system of claim 2, further comprising a control device, wherein the control device is in signal connection with the vehicle-mounted cargo determination device, the fixed inspection device and the mobile inspection device, and the control device receives the determination result that the vehicle-mounted cargo determined by the vehicle-mounted cargo determination device is light-loaded cargo or heavy-loaded cargo, and operates the fixed inspection device and the mobile inspection device according to the determination result to automatically switch the radiation inspection system between the standard inspection mode and the rapid inspection mode.

4. The radiation inspection system according to claim 2, wherein the vehicle-mounted cargo determination means includes a weighing means for weighing the inspected vehicle (3), and determines whether the vehicle-mounted cargo of the inspected vehicle (3) is light-load cargo or heavy-load cargo based on a result of the weighing by the weighing means.

5. The radiation inspection system of claim 1,

an output energy of the third scanning ray of radiation is higher than an output energy of the first scanning ray of radiation and the second scanning ray of radiation; and/or

The dose of the third radiation scanning ray is higher than the output doses of the first radiation scanning ray and the second radiation scanning ray.

6. The radiation inspection system of any of claims 1 to 5, further comprising:

a first detection unit that detects whether the subject vehicle (3) enters an inspection area of the radiation inspection system; and/or the presence of a gas in the gas,

the second detection unit is coupled with the vertical visual angle inspection device, detects whether the part of the detected vehicle (3) needing radiation protection passes through the vertical visual angle inspection device and generates a first passing signal, and the vertical visual angle inspection device receives the first passing signal and outputs the first radiation scanning ray or the second radiation scanning ray; and/or the presence of a gas in the gas,

and the third detection unit is coupled with the horizontal visual angle inspection device, detects whether the part of the detected vehicle (3) needing radiation protection passes through the horizontal visual angle inspection device and generates a second pass signal, and the horizontal visual angle inspection device receives the second pass signal and outputs the third radiation scanning ray or the fourth radiation scanning ray.