Patent Description:
The present disclosure relates to the field of radiation inspection, and in particular, to a back scattering inspection system and a back scattering inspection method.

The commonly used X-ray back scattering imaging technology mainly uses a flying spot device to generate spatially changing pen-shaped X-ray beam current to scan an inspected object <NUM> point by point. In a back scattering inspection system in the prior art as shown in <FIG>, G represents a beam exit point of an X-ray machine, a beam limitation hole C is located at the edge of a flywheel <NUM>, and an collimation slit for collimating X-rays is located on a side face of a fan-shaped box <NUM>. The X-rays can pass through a fan-shaped arc edge of the fan-shaped box <NUM>, and the X-rays cannot pass through other edges of the fan-shaped box <NUM> excluding the fan-shaped arc edge, that is, point-shaped X-rays are emitted within a range from a point A to a point B. When the beam limitation hole C passes round the fan-shaped box, the point-shaped X-rays through the beam limitation hole C can be emitted from the fan-shaped box <NUM> to the inspected object <NUM>. The back scattering detector <NUM> on the same side as a flying spot ray source receives the X-rays scattered by the inspected object, and a series of digital image signals are generated in real time through an image acquisition and analysis system.

<CIT> discloses a related back scattering inspection system comprising a track and a back scattering inspection device movably disposed on the track.

A first aspect of the present disclosure discloses a back scattering inspection system according to independent claim <NUM>.

According to the invention, the back scattering ray emitting device is disposed in such a way that a scanning direction of a pen-shaped ray beam emitted by the same is parallel to an extension direction of the inspection channel.

In some embodiments, the back scattering inspection system includes a first driving device in driving connection with the back scattering inspection device, wherein the first driving device is configured to drive the back scattering inspection device to move on the track.

In some embodiments, the track is a poligonal line-shaped track, a curved track, or a track formed by a combination of a straight track and a curved track.

In some embodiments, the track is a U-shaped track, an arc-shaped track, or a circular track.

According to the invention, the back scattering inspection system further includes a second driving device, and the second driving device is configured to drive the back scattering inspection device to rotate around a direction of the movement of the back scattering inspection device on the track.

In some embodiments, the back scattering inspection system further includes a license plate identification system, and when the inspected object is a vehicle, the license plate recognition system is configured to identify license plate information of the vehicle.

In some embodiments, the back scattering inspection system further includes a positioning sensor, configured to detect a position of the inspected object relative to the track.

In some embodiments, the back scattering inspection system further includes a laser radar device, configured to inspect a surface of the inspected object.

In some embodiments, the back scattering inspection system further includes an anti-collision system, and the anti-collision system includes an anti-collision sensor disposed on the frame for detecting the distance between the track and the inspected object, and an alarm system in signal connection with the anti-collision sensor.

According to the invention, frame is a movable frame.

A second aspect of the present disclosure further discloses a back scattering inspection method according to independent claim <NUM>, using the back scattering inspection system according to the first aspect of the present disclosure, including: when the back scattering inspection device executes scanning inspection, causing the back scattering inspection device to move along the track.

According to the invention, a scanning direction of a pen-shaped ray beam emitted by the back scattering ray emitting device is parallel to an extension direction of the inspection channel.

According to the invention, the back scattering inspection method includes: causing the back scattering inspection device to rotate around the direction of the movement of the back scattering inspection device on the track while moving along the track.

In some embodiments, the back scattering inspection method includes: keeping an angle of the back scattering inspection device relative to the direction of the movement of the back scattering inspection device on the track unchanged while moving along the track, and performing the next scanning after causing the back scattering inspection device to rotate an angle around the direction of the movement of the back scattering inspection device on the track when moving to a tail end of the track.

In some embodiments, the back scattering inspection method further includes: inspecting whether the surface of the object is damaged.

In some embodiments, the back scattering inspection method further includes: detecting the distance between the track and the inspected object, and issuing an alarm when the distance between the inspected object and the track is less than a safe distance.

In some embodiments, the back scattering inspection method further includes: after inspecting a part of the inspected object in the extension direction of the inspection channel, changing the position of the inspected object relative to the frame along the extension direction of the inspection channel, and inspecting another part of the inspected object.

Based on the back scattering inspection system provided by the present disclosure, by disposing the track arranged vertically or obliquely relative to the ground, during the process of the back scattering inspection device moving on the track, back scattering inspection is performed on a plurality of surfaces of the inspected object in the inspection channel formed by the space enclosed by the track.

The back scattering inspection method based on the back scattering inspection system provided by the present disclosure can also have corresponding beneficial effects.

Other features and advantages of the present disclosure will become clear from the following detailed description of exemplary embodiments of the present disclosure with reference to the drawings.

The drawings described herein are used for providing a further understanding of the present disclosure and constitute a part of the present application. Exemplary embodiments of the present disclosure and the description thereof are used for explaining the present disclosure, but do not constitute an improper limitation to the present disclosure. In the drawings:.

A clear and complete description of technical solutions in the embodiments of the present disclosure will be given below, in combination with the drawings in the embodiments of the present disclosure. Apparently, the embodiments described below are merely a part, but not all, of the embodiments of the present disclosure. The following description of at least one exemplary embodiment is merely illustrative and is in no way used as any limitation to the present disclosure and its application or use.

The relative arrangement of components and steps, numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present disclosure, unless specifically stated otherwise. At the same time, it should be understood that, for the convenience of description, the dimensions of various parts shown in the drawings are not drawn according to the actual proportional relationship. Techniques, methods and equipment known to those of ordinary skill in the relevant art may not be discussed in detail, but where appropriate, the techniques, methods and equipment should be considered as a part of the authorized specification. In all examples shown and discussed herein, any specific value should be construed as exemplary only and not as a limitation. Therefore, other examples of the exemplary embodiments may have different values. It should be noted that similar reference signs and letters indicate similar items in the following drawings, so once a certain item is defined in one drawing, it does not need be discussed further in the subsequent drawings.

As shown in <FIG>, the back scattering inspection system of the embodiment of the present disclosure includes a frame <NUM> and a back scattering inspection device <NUM>.

The frame <NUM> includes a track arranged vertically or obliquely relative to the ground, and a space enclosed by the track forms an inspection channel. The back scattering inspection device <NUM> includes a back scattering ray emitting device <NUM> and a back scattering detector <NUM>, and the back scattering inspection device <NUM> is movably disposed on the track for inspecting an inspected object <NUM> passing through the inspection channel.

The back scattering ray emitting device <NUM> can be a flying spot device with a rotatable beam limitation hole as described in the background, and The back scattering ray emitting device <NUM> can also be other kinds of flying spot devices which swings back and forth to form back scattering scanning rays. The back scattering detector <NUM> and the back scattering ray emitting device <NUM> are located on the same side of the inspected object <NUM>, and the back scattering detector <NUM> is configured to receive rays scattered by the inspected object <NUM>, so that a back scattering inspection image of the inspected object <NUM> can be formed.

The track is arranged vertically or obliquely relative to the ground, that is, the track has a certain height in a vertical direction, and not all sections of the track contact the ground. The track is a nonlinear track. The track can be a polygonal line-shaped track, a curved track, or a track formed by a combination of a straight track and a curved track. The track is, for example, a U-shaped track, an arc-shaped track, or a circular track.

As shown in <FIG> and <FIG>, the space enclosed by the track forms the inspection channel, that is, the track forms a shape that is enclosed or semi-enclosed to form the space, and the space is used as the inspection channel to perform back scattering inspection on the inspected object <NUM>. The back scattering inspection device <NUM> can move on the track. The form of the semi-enclosed track is, for example, the aforementioned U-shaped track (gate-shaped track), an L-shaped track, a J-shaped track and other non-closed tracks, and the form of the fully closed track is, for example, a circular track, a polygon track and other closed tracks. The track of the present disclosure can be formed by processing a linear track in bending, curving, tailor welding and other manners.

The back scattering inspection device <NUM> moves along the track when performing back scattering inspection on the inspected object <NUM> located in the inspection channel, so the back scattering inspection device <NUM> can perform scanning inspection on a plurality of surfaces of the inspected object <NUM>. For example, in the embodiment shown in <FIG> and <FIG>, the frame <NUM> is a U-shaped frame, the track is also a U-shaped track disposed on the frame <NUM>. When a vehicle serving as the inspected object <NUM> is parked in the inspection channel for inspection, as the back scattering inspection device <NUM> moves onto the track at a left side of the frame <NUM> as shown in <FIG>, a back scattering scan inspection can be performed on a left side of the vehicle located in the inspection channel, for example, a left vehicle door part; as the back scattering inspection device <NUM> moves onto the track at a top side of the frame <NUM> as shown in <FIG>, the back scattering scan inspection can be performed on a top of the vehicle located in the inspection channel, for example, a roof part; and as the back scattering inspection device <NUM> moves onto the track at a right side of the frame <NUM> as shown in <FIG>, the back scattering scan inspection can be performed on a right side of the vehicle located in the inspection channel, for example, a right vehicle door part.

According to the back scattering inspection system provided by the embodiment, by disposing the track arranged vertically or obliquely relative to the ground, during the process of the back scattering inspection device <NUM> moving on the track, back scattering inspection is performed on the plurality of surfaces of the inspected object <NUM> located in the inspection channel formed by the space enclosed by the track, which is thereby conducive to increasing the inspection range of the back scattering inspection system and improving the accuracy of the back scattering inspection.

In some embodiments, the back scattering ray emitting device <NUM> is disposed in such a way that a scanning direction of a pen-shaped ray beam emitted by it is parallel to an extension direction of the inspection channel. As shown in <FIG>, the pen-shaped ray beam emitted by the back scattering ray emitting device <NUM> scans the inspected object <NUM> in one direction, a scanning trajectory on the inspected object <NUM> forms a scanning straight line (as shown by a dotted line in <FIG>), and meanwhile, the back scattering ray emitting device <NUM> moves, the scanning straight line translates according to a movement direction, so that the back scattering ray emitting device <NUM> can form a scanning surface on the surface of the inspected object <NUM>. To form the scanning surface, it is only necessary that the scanning straight line is not parallel to the movement direction of the back scattering ray emitting device <NUM> and intersects with the movement direction. In the present embodiment, the scanning direction of the pen-shaped ray beam is parallel to the extension direction of the inspection channel, which is conducive to make the movement direction of the back scattering inspection device <NUM> perpendicular to or form a large angle approaching to <NUM> degrees with the scanning direction of the pen-shaped ray beam, therefore which is conducive to increasing the scanning area of the back scattering inspection.

In some embodiments, the back scattering inspection system includes a first driving device in driving connection with the back scattering inspection device <NUM>, and the first driving device is configured to drive the back scattering inspection device <NUM> to move on the track. The first driving device can include a driving wheel disposed on the back scattering inspection device <NUM> to cooperate with the track, and a power device disposed on the back scattering inspection device <NUM> to drive the driving wheel to move on the track, for example, a motor.

In some embodiments, the back scattering inspection system further includes a second driving device, and the second driving device is configured to drive the back scattering inspection device <NUM> to rotate around the direction of the movement of the back scattering inspection device on the track. For example, a base hinged with the back scattering inspection device <NUM> can be configured to cooperate with the track and move relative to the track, and then, a device such as a gear, a motor and the like is disposed to drive the back scattering inspection device <NUM> to rotate along the direction of the movement of the back scattering inspection device on the track. Due to the configuration, the back scattering scanning angle of the back scattering inspection device <NUM> can be adjusted, thereby increasing the scanning range of the back scattering inspection device <NUM>. For example, in the embodiment shown in <FIG> and <FIG>, when a vehicle serving as the inspected object <NUM> is located in the inspection channel, the scanning range can be extended to the front and rear ends of the vehicle by rotating the back scattering inspection device <NUM> to increase the scanning area.

In some embodiments, as shown in <FIG> and <FIG>, the back scattering inspection system further includes a laser radar device <NUM>, configured to inspect a surface of the inspected object <NUM>. The laser radar device <NUM> can inspect whether the surface of the inspected object <NUM> is damaged, and provide auxiliary information for judging and analyzing a back scattering inspection result of the back scattering inspection device <NUM>.

In some embodiments, the back scattering inspection system further includes an anti-collision system, the anti-collision system includes an anti-collision sensor disposed on the frame <NUM> for detecting the distance between the track and the inspected object <NUM>, and an alarm system in signal connection with the anti-collision sensor. The configuration helps to prevent the collision between the inspected object and the back scattering inspection system during the back scattering inspection. When the distance between the back scattering inspection system and the inspected object is less than a safe distance, for example, when the distance between the frame <NUM> or the back scattering inspection device <NUM> and the inspected object <NUM> is too small, the alarm system issues an alarm, and the alarm can include prompt tone, as well as automatic suspension of the operation of the back scattering inspection system.

In some embodiments, the frame <NUM> is a movable frame. As shown in <FIG>, and <FIG>, when the relative positions between the back scattering inspection device <NUM> and the inspected object <NUM> in the extension direction of the inspection channel are different, the back scattering inspection ranges of the back scattering inspection device <NUM> on the inspected object <NUM> are different.

The shape or structure of the frame <NUM> is not limited in the present disclosure, for example, the frame <NUM> can be the track itself, or can include two walking trolleys respectively disposed at two free ends of the U-shaped track.

In <FIG>, when the vehicle is located in the inspection channel and the back scattering inspection device <NUM> is at a first position P1 corresponding to the front end of the vehicle, the back scattering ray emitting device <NUM> is also at the corresponding position, and the length of the back scattering inspection range of the back scattering inspection device <NUM> on the vehicle is L1. When the back scattering inspection device <NUM> moves from a position H1 to a position H2 of the frame in <FIG>, the scanning of the front segment of the vehicle can be competed. In <FIG>, when the vehicle is located in the inspection channel and the back scattering inspection device <NUM> is at a second position P2 corresponding to the middle of the vehicle, the back scattering ray emitting device <NUM> is also at the corresponding position, then the length of the back scattering inspection range of the back scattering inspection device <NUM> on the vehicle is L2, and when the back scattering inspection device <NUM> moves from the position H1 to the position H2 of the frame in <FIG>, the scanning of the middle segment of the vehicle can be competed. In <FIG>, when the vehicle is located in the inspection channel and the back scattering inspection device <NUM> is at a third position P3 corresponding to the rear end of the vehicle, the back scattering ray emitting device <NUM> is also at the corresponding position, then the length of the back scattering inspection range of the back scattering inspection device <NUM> on the vehicle is L3, and when the back scattering inspection device <NUM> moves from the position H1 to the position H2 of the frame in <FIG>, the scanning of the rear segment of the vehicle can be competed.

As shown in <FIG>, if the back scattering inspection system completes the back scattering scanning inspection on the vehicle at the position P1, and then the position of the back scattering inspection system relative to the vehicle is changed to the position P2 to perform the next back scattering scanning inspection, and then the position of the back scattering inspection system relative to the vehicle is changed to the position P3 to perform the next back scattering scanning inspection, as a result, the back scattering inspection system can perform the back scattering scanning inspection on the vehicle over the entire length of the vehicle to obtain a back scattering scanning inspection image on the entire length of the vehicle.

A change of the relative position between the back scattering inspection system and the vehicle can be achieved by moving the vehicle, or by moving the back scattering inspection system. In this embodiment, the frame <NUM> is set as a movable frame, so that the inspection range of the back scattering inspection system is larger, and at the same time, it helps to make the operation more flexible.

In some embodiments, the back scattering inspection system further includes a positioning sensor, configured to detect a position of the inspected object <NUM> relative to the track. By disposing the positioning sensor, it is conducive to determining the position of the track and the back scattering inspection device <NUM> thereon relative to the inspected object <NUM>, therefore, when a relatively long inspected object <NUM> is detected, for example, when the inspected object <NUM> is the vehicle, and when the inspected object <NUM> needs to be scanned in segments, the relative position between the track and the inspected object can be determined when each segment is scanned. Due to the configuration, when multiple segments of back scattering scanning inspection images obtained by segment scanning are spliced together, it is conducive to making the pixels at the edges of each segment of back scattering scanning inspection image neither overlapped nor disappeared, so that a complete back scattering scanning inspection image of the vehicle is obtained, and the complete back scattering scanning inspection image covers the entire length of the vehicle.

In some embodiments, a roller is installed at the bottom of the frame <NUM>, which can be a track roller, so that the back scattering inspection system can move back and forth on a track. A universal wheel can also be disposed at the bottom of the frame <NUM>, so that the frame <NUM> can also turn when moving. In this way, the back scattering inspection system can be moved and adjusted more flexibly. During back scattering scanning inspection, the universal wheel can move along optical or magnetic signs on the ground.

In some embodiments, the back scattering inspection system further includes a license plate identification system, and when the inspected object <NUM> is a vehicle, vehicle information identified by the license plate identification system can also be associated with a scanning image obtained by back scattering inspection, thereby facilitating the management and judgment.

In some embodiments, a back scattering inspection method using the back scattering inspection system according to any embodiment is also disclosed, including: when the back scattering inspection device <NUM> executes scanning inspection, causing the back scattering inspection device <NUM> to move along the track.

In some embodiments, the back scattering inspection method further includes: causing a scanning direction of a pen-shaped ray beam emitted by the back scattering ray emitting device <NUM> to be parallel to an extension direction of the inspection channel.

In some embodiments, the back scattering inspection method includes: causing the back scattering inspection device <NUM> to rotate around the direction of the movement of the back scattering inspection device on the track while the back scattering inspection device <NUM> moves along the track. Due to the configuration, a larger range of inspection on the inspected object can be performed in the case that the frame <NUM> is fixed.

In some embodiments, the back scattering inspection method includes: keeping an angle of the back scattering inspection device <NUM> relative to the direction of the movement of the back scattering inspection device on the track unchanged while moving along the track, and performing the next scanning after causing the back scattering inspection device <NUM> to rotate an angle around the direction of the movement of the back scattering inspection device on the track when the back scattering inspection device <NUM> moves to a tail end of the track. Due to the configuration, a larger range of inspection on the inspected object can be performed for multiple times in the case that the frame <NUM> is fixed.

In some embodiments, the back scattering inspection method further includes: detecting the distance between the track and the inspected object <NUM>, and issuing an alarm when the distance between the inspected object and the track is less than a safe distance.

In some embodiments, the back scattering inspection method further includes: after inspecting a part of the inspected object <NUM> in the extension direction of the inspection channel, changing the position of the inspected object <NUM> relative to the frame <NUM> along the extension direction of the inspection channel, and inspecting another part of the inspected object <NUM>.

Claim 1:
A back scattering inspection system, comprising:
a frame (<NUM>), comprising a track configured to be arranged vertically or obliquely relative to the ground, wherein a space enclosed by the track forms an inspection channel and the frame is a movable frame; and
a back scattering inspection device (<NUM>), comprising a back scattering ray emitting device (<NUM>) and a back scattering detector (<NUM>), wherein the back scattering inspection device (<NUM>) is movably disposed on the track to be configured to inspect an inspected object (<NUM>) passing through the inspection channel;
a second driving device, wherein the second driving device is configured to drive the back scattering inspection device (<NUM>) to rotate around a direction of the movement of the back scattering inspection device (<NUM>) on the track;
wherein the back scattering inspection device (<NUM>) is caused to rotate around the direction of the movement of the back scattering inspection device on the track when the back scattering inspection device (<NUM>) moves along the track, and the back scattering ray emitting device (<NUM>) is disposed in such a way that a scanning direction of a pen-shaped ray beam emitted by the back scattering ray emitting device (<NUM>) is parallel to an extension direction of the inspection channel.