JP6830402B2 - X-ray inspection system and X-ray irradiation device - Google Patents

Description

The present invention relates to an X-ray inspection system and an X-ray irradiation device.

Currently, the occurrence of terrorism overseas is a problem (threat). In Japan as well, for example, in anticipation of the 2020 Tokyo Olympics and Paralympics, it is required to take appropriate measures against dangerous and suspicious objects in order to thoroughly and strengthen measures against terrorism.

Patent Document 1 discloses a portable X-ray inspection apparatus provided with a frame for capturing an X-ray fluoroscopic image. This portable X-ray inspection device has an X-ray detector port, an X-ray generator port, a connecting arm, and a synchronous moving means. The X-ray detector port has a thin standing plate shape with a thin multi-channel X-ray detector arranged in a straight line. The X-ray generator port includes an X-ray generator facing the X-ray detector, and has a box shape in which the lower end is flush with the X-ray detector port. The connecting arm is connected at the upper corners of the X-ray detector port and the X-ray generator port while being held at regular intervals. The synchronous moving means synchronously moves the X-ray detector and the X-ray generator in parallel in the vertical or horizontal direction while maintaining the facing state.

Patent Document 2 discloses an X-ray inspection apparatus in which an X-ray generator and an X-ray detector are arranged on one side and the other side of a subject to perform an X-ray fluoroscopy on the subject. In this X-ray inspection device, the irradiation unit main body of the X-ray generator is vertically movable and held by the holding body, and when the holding body is placed on the ground surface, the irradiation unit main body is moved downward on the holding body to irradiate. X-rays from the body of the part are irradiated toward the subject from near the ground surface (within 1 cm or 2 cm).

Japanese Unexamined Patent Publication No. 9-333450 Japanese Unexamined Patent Publication No. 2001-27617

However, in Patent Documents 1 and 2, it is difficult to appropriately set the X-ray irradiation range for the inspection object, so that a desired X-ray image may not be obtained. In other words, Patent Documents 1 and 2 cannot determine whether or not the X-ray irradiation range for the inspection object is appropriate unless the actual X-ray image is confirmed.

The present invention has been made in view of this point, and provides an X-ray inspection system and an X-ray irradiation apparatus capable of appropriately setting an X-ray irradiation range for an inspection object and obtaining a desired X-ray image. One of the purposes is to do.

The X-ray inspection system of the present embodiment includes an X-ray irradiation device that irradiates an inspection object with X-rays and an X-ray image receiving device that receives an X-ray image transmitted through the inspection object. In the inspection system, the X-ray irradiation device includes a rectangular bag-shaped housing portion, an X-ray generating portion provided in the housing portion, and an imaging unit provided in the housing portion. It has a display unit provided in the housing portion, and an X-ray emission port of the X-ray generating portion and an imaging of the photographing portion are performed on a surface of the housing portion facing the inspection object. The display unit is provided on the surface of the housing portion opposite to the surface facing the inspection object, and the X-ray generating portion generates X-rays. The imaging unit photographs the irradiation range, and the display unit displays the X-ray irradiation range photographed by the imaging unit.

The X-ray irradiation device of the present embodiment is an X-ray irradiation device that irradiates an object to be inspected with X-rays, and is a rectangular bag-shaped housing portion and X-rays provided in the housing portion. It has a generating unit, a photographing unit provided in the housing portion, and a display unit provided in the housing portion, and the surface of the housing portion facing the inspection object is described as described above. The X-ray emission port of the X-ray generating unit and the photographing lens of the photographing unit are exposed, and the display unit is located on the surface of the housing portion opposite to the surface facing the inspection object. It is characterized in that the photographing unit photographs the X-ray irradiation range generated by the X-ray generating unit, and the display unit displays the X-ray irradiation range photographed by the photographing unit. ..

According to the present invention, it is possible to provide an X-ray inspection system and an X-ray irradiation apparatus capable of appropriately setting an X-ray irradiation range for an inspection object and obtaining a desired X-ray image.

It is a conceptual diagram which shows the schematic structure of the X-ray inspection system by this Embodiment. It is a front perspective view which shows the appearance structure of the X-ray irradiation apparatus by this Embodiment. It is a rear perspective view which shows the appearance structure of the X-ray irradiation apparatus by this Embodiment. It is a front perspective view which shows the internal structure of the X-ray irradiation apparatus by this Embodiment. It is a front perspective view which shows the appearance structure of the X-ray image receiving apparatus by this embodiment. It is a rear perspective view which shows the appearance structure of the X-ray image receiving apparatus by this embodiment. It is a 1st front view which shows the appearance structure of the X-ray image receiving apparatus by this embodiment. It is a 2nd front view which shows the appearance structure of the X-ray image receiving apparatus by this embodiment. It is a functional block diagram which shows the internal structure of the central control device by this embodiment. It is a conceptual diagram which shows the state of synthesis of a plurality of X-ray images by an X-ray image synthesis part. It is a flowchart which shows the operation of the X-ray inspection system by this embodiment.

<< Configuration of X-ray inspection system 10 >>
FIG. 1 is a conceptual diagram showing a schematic configuration of an X-ray inspection system 10 according to the present embodiment. The X-ray inspection system 10 is for performing baggage inspection and other inspections (including physical examinations) at any place such as an airport, a station, a sports facility, or an event venue. Alternatively, the X-ray inspection system 10 can also be applied to an X-ray inspection of an accident vehicle.

As shown in FIG. 1, the X-ray inspection system 10 includes an X-ray irradiation device 100 and an X-ray image receiving device 200. The X-ray irradiation device 100 and the X-ray image receiving device 200 are portable and can be set at the place where the X-ray inspection system 10 is used or at any other place. The X-ray irradiation device 100 and the X-ray image receiving device 200 are set in one region and the other region sandwiching the inspection target TO, and the X-ray irradiation device 100 irradiates the inspection target TO with X-rays. The X-ray image receiving device 200 receives an X-ray image transmitted through the inspection object TO. The X-ray irradiation device 100 and the X-ray image receiving device 200 are connected to the control personal computer 300 via a wireless link.

<< Configuration of X-ray irradiation device 100 >>
2 and 3 are a front perspective view and a rear perspective view showing an external configuration of the X-ray irradiation device 100 according to the present embodiment. FIG. 4 is a front perspective view showing the internal configuration of the X-ray irradiation device 100 according to the present embodiment (the front surface of the housing portion 110 is omitted and drawn with a skeleton). The upper, lower, front, rear, left, and right directions in the following description are based on the arrow line directions shown in FIGS. 2 to 4.

The X-ray irradiation device 100 has a rectangular parallelepiped bag-shaped housing portion 110 that is long in the left-right direction and short in the up-down direction. A handle 111 is provided in the center of the upper surface of the housing portion 110, a fingerprint authentication unit 112 is provided on the left side of the upper surface of the housing portion 110, and a power switch 113 is provided on the right side of the upper surface of the housing portion 110. Is provided. Further, a handle 114 is provided on the left side surface of the housing portion 110, and a handle 115 is provided on the right side surface of the housing portion 110. Further, a height-adjustable tripod 116 is provided on the lower surface of the housing portion 110, and the X-ray irradiation position from the X-ray irradiation device 100 can be adjusted in the vertical direction by the tripod 116. Further, below the rear surface of the housing portion 110, a battery storage portion 117 for accommodating a battery (not shown) serving as a driving source of the X-ray irradiation device 100 is provided.

The fingerprint authentication unit 112 reads the fingerprint information of the X-ray irradiator. The fingerprint information of the X-ray irradiator read by the fingerprint authentication unit 112 is collated with the fingerprint information of the X-ray handling manager (safety manager) and / or the X-ray irradiator (registered irradiator) registered in advance, and both X-ray irradiation by the X-ray irradiation device 100 is permitted only when they match, and X-ray irradiation by the X-ray irradiation device 100 is prohibited when both do not match.

An X-ray generation unit (X-ray generation unit) 120 is provided at the bottom of the housing portion 110. The X-ray generating unit 120 has a box shape that is long in the left-right direction, short in the up-down direction, and has rounded front left and front right. An X-ray emission port 121 for emitting X-rays is provided in the center of the front surface of the X-ray generation unit 120. The X-ray emission port 121 is exposed below the center of the front surface of the housing portion 110. The X-ray emission angle by the X-ray emission port 121 is set, for example, within a range of approximately 40 ° from the front to the top, bottom, left, and right. A shielding structure made of a material such as lead is provided on a portion other than the X-ray emission port 121, and suppression of the dose value is guaranteed.

A camera unit (shooting unit) 130 is provided inside the housing unit 110. The camera unit 130 has a box shape with rounded left front and right front, and is provided on the upper part of the X-ray generation unit 120 (supported by being placed in the center of the upper surface of the X-ray generation unit 120). It is fixed). A photographing lens 131 is provided in the center of the front surface of the camera unit 130, and the photographing lens 131 is exposed below the center of the front surface of the housing portion 110 and directly above the X-ray emission port 121 of the X-ray generation unit 120. ing.

The camera unit 130 captures an X-ray irradiation range generated by the X-ray generation unit 120. The "X-ray irradiation range generated by the X-ray generating unit 120" means that the X-ray generating unit 120 does not generate X-rays at present, but the X-ray generating unit 120 generates X-rays. It means the range of the inspection object TO to be irradiated with X-rays. Therefore, by changing the posture of the X-ray irradiation device 100 (for example, lifting the handle 111 to change the direction of the X-ray irradiation device 100, changing the height of the X-ray irradiation device 100 with the tripod 116), "X-rays". The "irradiation range of X-rays generated by the generation unit 120" can be changed. Hereinafter, the “X-ray irradiation range generated by the X-ray generation unit 120” may be simply referred to as the “X-ray irradiation range”.

The camera unit 130 may be set to capture only the "X-ray irradiation range", or may be set to capture the "X-ray irradiation range" and its peripheral portion. The "X-ray irradiation range" captured by the camera unit 130 is transmitted to the control personal computer 300 via the wireless link.

A rectangular thin plate-shaped display (display unit) 140 is provided outside the housing unit 110. A display storage unit 118 corresponding to the shape of the display 140 is recessed above the rear surface of the housing unit 110, and the display 140 can be stored in the display storage unit 118. The upper end of the display 140 is supported by the upper end of the display storage portion 118 via a rotation shaft (not shown) extending in the left-right direction, and the display 140 has a storage position housed in the display storage portion 118 and a storage position. It stands up approximately 90 ° from the display storage unit 118 and can rotate between the upright position and the upright position facing upward (FIGS. 2 to 4 show the upright position of the display 140).

The display 140 displays the “X-ray irradiation range” captured by the camera unit 130. When the camera unit 130 captures only the "X-ray irradiation range", the display 140 displays it as it is. When the camera unit 130 photographs the "X-ray irradiation range" and its peripheral portion, the display 140 emphasizes only the "X-ray irradiation range". There is a degree of freedom in the mode of highlighting, and for example, it is possible to blink only the "X-ray irradiation range" or to surround only the "X-ray irradiation range" with a colored frame.

When performing an X-ray inspection of the inspection target TO, the X-ray irradiator irradiates a desired portion of the inspection target TO with X-rays while observing the "X-ray irradiation range" displayed on the display 140. As described above, the posture of the X-ray irradiation device 100 can be changed to position and fix the X-ray irradiation device 100.

<< Configuration of X-ray image receiving device 200 >>
5 and 6 are a front perspective view and a rear perspective view showing an external configuration of the X-ray image receiving device 200 according to the present embodiment. 7 and 8 are first and second front views showing the external configuration of the X-ray image receiving device 200 according to the present embodiment. The upper, lower, front, rear, left, and right directions in the following description are based on the arrow line directions shown in FIGS. 5 to 8.

The X-ray image receiving device 200 has a function of receiving a plurality of X-ray images transmitted through a plurality of parts of the inspection object TO while changing the relative position with respect to the X-ray irradiation device 100. The configuration of the X-ray image receiving device 200 for exerting this function will be described in detail.

The X-ray image receiving device 200 has a pair of slide rails (base frames) 210 and 220 that are separated from each other in the left-right direction and extend in the front-rear direction. Casters 211 and 212 are provided on the lower surface of the front end and the lower surface of the rear end of the slide rail 210, and casters 221 and 222 are provided on the lower surface of the front end and the lower surface of the rear end of the slide rail 220. The casters 211, 212, 221 and 222 can drive the X-ray image receiving device 200 in any direction.

The inner surfaces of the pair of slide rails 210 and 220 are connected to each other by a frame base (base frame) 230. A stopper wall 231 extending in the front-rear direction is formed on the portion of the frame base 230 on the slide rail 210 side, and a stopper wall 232 extending in the front-rear direction is formed on the portion of the frame base 230 on the slide rail 220 side.

A guide shaft 233 that penetrates the stopper wall 231 and extends toward the stopper wall 232 is connected to the inner surface of the slide rail 210. A position-regulating flange portion 234 protruding in the outer diameter direction is formed slightly on the base end side of the tip end portion of the guide shaft 233.

A guide shaft 235 that penetrates the stopper wall 232 and extends toward the stopper wall 231 is coupled to the inner surface of the slide rail 220. A position-regulating flange portion 236 projecting in the outer diameter direction is formed slightly on the base end side of the tip portion of the guide shaft 235.

As the guide shaft 233 and the guide shaft 235 slide (expand and contract) in the left-right direction, the pair of slide rails 210 and 220 come into contact with each other in the left-right direction. When the pair of slide rails 210 and 220 are most separated from each other, the position-regulating flange portion 234 of the guide shaft 233 abuts on the stopper wall 231 to regulate the position, and the position-regulating flange portion 236 of the guide shaft 235 is the stopper wall 232. (In this case, the amount of overlap between the guide shaft 233 and the guide shaft 235 in the left-right direction is substantially zero). When the pair of slide rails 210 and 220 are closest to each other, the tip of the guide shaft 233 abuts on the stopper wall 232 to regulate the position, and the tip of the guide shaft 235 abuts on the stopper wall 231 to regulate the position. (In this case, the amount of overlap between the guide shaft 233 and the guide shaft 235 in the left-right direction is maximized).

An inner frame (base frame) 240 extending upward is fixed to the upper surfaces of the stopper wall 231 and the stopper wall 232 of the frame base 230. A pair of left and right guide shafts (base frames) 250 extending upward are fixed to the left end front portion and the right end front portion of the frame base 230. The upper end of the inner frame 240 and the upper end of the pair of guide shafts 250 are connected by a handle holder (base frame) 260 extending in the left-right direction.

The inner frame 240 is supported by an X-ray irradiation device 241, an X-ray irradiation control rod 242, and a pair of spacers 243. In FIG. 6, the X-ray irradiation device 241 and the X-ray irradiation control rod 242 and the spacer 243 are all drawn. In FIGS. 5, 7, and 8, the X-ray irradiation device 241 and the X-ray irradiation control rod 242 and the spacer 243 are drawn. All or part of is omitted. The X-ray irradiation device 241 is mounted, for example, in a preliminary position used when the above-mentioned X-ray irradiation device 100 cannot be used. The X-ray irradiation control rod 242 controls the X-ray irradiation device 241 without the X-ray irradiator approaching the inspection target TO, for example, when the inspection target TO has a high possibility of being a dangerous substance or a suspicious object. Is for. The pair of spacers 243 are fitted into the pair of guide shafts 250 to suppress rattling of the device, for example, when the X-ray image receiving device 200 is not used. A control personal computer 300 is supported on the inner frame 240. In FIG. 6, the control personal computer 300 is drawn, and in FIGS. 5, 7, and 8, the control personal computer 300 is omitted.

A first movable frame 270 is slidably supported in the vertical direction on the pair of guide shafts 250, and a second movable frame 280 is slidably supported in the horizontal direction on the first movable frame 270. Has been done.

More specifically, a pair of left and right guide support portions 271 are formed on the rear surface of the first movable frame 270, and guide holes 272 penetrate in each guide support portion 271 in the vertical direction. By guiding the pair of guide shafts 250 through the guide holes 272 of the pair of guide support portions 271, the first movable frame 270 is slidably supported by the pair of guide shafts 250 in the vertical direction.

A guide rail 273 extending in the left-right direction is formed on the front surface of the first movable frame 270, and a guide protrusion (not shown) guided by the guide rail 273 is formed on the rear surface of the second movable frame 280. There is. By guiding the guide protrusion with the guide rail 273, the second movable frame 280 is slidably supported by the first movable frame 270 in the left-right direction.

On the front surface of the second movable frame 280, hook-shaped panel holding protrusions 281 located at three positions, downward, left, and right, are formed, and the X-ray image receiving panel 290 is held by the panel holding protrusions 281. Has been (attached). The X-ray image receiving panel 290 can be composed of an FPD (Flat Panel Detector), and has a thin plate shape that is long in the left-right direction and short in the up-down direction. On the front surface of the X-ray image receiving panel 290, most of the rectangular area including the central part is the effective image receiving surface 291 and the other peripheral area is the frame part 292. In FIGS. 5 to 7, the X-ray image receiving panel 290 is drawn with a solid line, and in FIG. 8, when the X-ray image receiving panel 290 is in the lower left position, the lower right position, the upper right position, and the upper left position with respect to the X-ray irradiation device 100. The outline of the effective image receiving surface 291 is drawn by the alternate long and short dash line, and the outline of the frame portion 292 is drawn by the alternate long and short dash line.

In the state where the pair of slide rails 210 and 220 are most separated from each other (FIG. 8), a space for the second movable frame 280 to slide in the left-right direction with respect to the first movable frame 270 is secured, but the pair In the state where the slide rails 210 and 220 are closest to each other (FIGS. 5 to 7), a space for the second movable frame 280 to slide in the left-right direction with respect to the first movable frame 270 is not secured. In this sense, the stopper walls 231 and 232 of the frame base 230 and the guide shafts 233 and 235 (the tip of the guide shaft and the position regulating flanges 234 and 236) that define the contact and separation states of the pair of slide rails 210 and 220 are , The second movable frame 280 functions as a "switching mechanism" for switching whether or not the second movable frame 280 can be slidable in the left-right direction with respect to the first movable frame 270.

As shown in FIG. 8, in the X-ray image receiving device 200, the first movable frame 270 and the second movable frame 280 slide in the vertical and horizontal directions in a state where the pair of slide rails 210 and 220 are most separated from each other. , The X-ray image receiving panel 290 moves the lower left position, the lower right position, the upper right position, and the upper left position with respect to the X-ray irradiation device 100, and X of the lower left part, the lower right part, the upper right part, and the upper left part of the inspection object TO. It is possible to receive a line image. The X-ray images of the lower left portion, the lower right portion, the upper right portion, and the upper left portion of the inspection object TO received by the X-ray image receiving panel 290 are sequentially transmitted to the control personal computer 300 via the wireless link.

As shown in FIG. 8, the lower end of the effective image receiving surface 291 of the X-ray image receiving panel 290 when the first movable frame 270 is located at the upper slide end, and the first movable frame 270 are at the lower slide end. It coincides with the upper end of the effective image receiving surface 291 of the X-ray receiving panel 290 when it is positioned. Further, the right end of the effective image receiving surface 291 of the X-ray image receiving panel 290 when the second movable frame 280 is located at the left slide end, and the second movable frame 280 are located at the right slide end. It coincides with the left end of the effective image receiving surface 291 of the X-ray receiving panel 290 when it is in use. As a result, the X-ray images of the lower left part, the lower right part, the upper right part, and the upper left part of the inspection object TO received by the X-ray image receiving panel 290 can be connected neatly without any gaps. It becomes possible to improve the visibility.

As described above, on the front surface of the X-ray image receiving panel 290, most of the rectangular area including the central part is the effective image receiving surface 291 and the other peripheral area is the frame part 292. Therefore, the vertical and horizontal slide ends of the X-ray image receiving panel 290 (the vertical slide end of the first movable frame 270 and the horizontal slide end of the second movable frame 280) are optimally set (such). By providing a stopper mechanism at the position), if the frame portion 292 of the X-ray image receiving panel 290 is overlapped (cancelled), the upper, lower, left and right ends of the effective image receiving surface 291 of the X-ray receiving panel 290 can be matched. ..

<< Configuration of control personal computer 300 >>
FIG. 9 is a functional block diagram showing the internal configuration of the control personal computer (X-ray image synthesizer) 300 according to the present embodiment. The control personal computer 300 has an X-ray image synthesizing unit 310, a display (comparative display unit) 320, a determination unit 330, and a warning unit 340.

The X-ray image synthesizing unit 310 synthesizes a plurality of X-ray images of the inspection object TO received by the X-ray receiving device 200 (X-ray receiving panel 290). In the present embodiment, as shown in FIG. 10, the X-ray image receiving panel 290 moves the lower left position, the lower right position, the upper right position, and the upper left position with respect to the X-ray irradiation device 100, while moving the lower left portion of the inspection object TO. The X-ray images of the lower right portion, the upper right portion, and the upper left portion are received, and the four X-ray images are sequentially transmitted to the X-ray image synthesis unit 310 of the control personal computer 300 via the wireless link. The X-ray image synthesizing unit 310 synthesizes the X-ray images (four X-ray images) of the lower left portion, the lower right portion, the upper right portion, and the upper left portion of the inspection object TO to generate one X-ray image. .. As is clear from FIG. 10, one X-ray image synthesized by the X-ray image synthesizing unit 310 has a clear X-ray image of the lower left part, the lower right part, the upper right part, and the upper left part of the inspection object TO. It is connected to, and the visibility is extremely high.

The display 320 displays one X-ray image synthesized by the X-ray image synthesizing unit 310. For example, the display 320 displays the X-ray images of the lower left portion, the lower right portion, the upper right portion, and the upper left portion of the inspection object TO received by the X-ray image receiving panel 290 in order, and finally, these four X-rays. It is possible to display one X-ray image in which the line images are combined.

The display 320 can display a single X-ray image synthesized by the X-ray image synthesizing unit 310 and the "X-ray irradiation range" taken by the camera unit 130 of the X-ray irradiation device 100 in a comparable manner. .. For example, the screen of a single display 320 may be divided into two to display one X-ray image and "X-ray irradiation range" on each split screen, or two displays 320 may be arranged side by side on each display 320. One X-ray image and "X-ray irradiation range" may be displayed.

The determination unit 330 analyzes one X-ray image synthesized by the X-ray image synthesis unit 310 to determine whether or not there is a possibility that the inspection object TO contains a dangerous substance or a suspicious object. .. For example, the determination unit 330 analyzes the X-ray image, calculates the X-ray transmittance (transmittance), and detects a portion where the X-ray transmittance (transmittance) is small, the inspection target TO. It can be determined that there is a possibility that dangerous or suspicious objects may be contained in.

When the determination unit 330 determines that the inspection target TO may contain a dangerous substance or a suspicious object, the warning unit 340 issues a warning to notify the X-ray inspector to that effect. There is a degree of freedom in the mode of the warning, but for example, a warning by voice and / or a warning by emphasizing the corresponding part in the X-ray image displayed on the display 320 is possible.

<< Operation of X-ray inspection system 10 >>
FIG. 11 is a flowchart showing the operation of the X-ray inspection system 10 according to the present embodiment.

In step ST1, the X-ray irradiation device 100 is set for the inspection target TO. That is, the posture of the X-ray irradiator 100 is adjusted so that the X-ray irradiator irradiates the desired portion of the inspection object TO with the X-ray while looking at the "X-ray irradiation range" displayed by the display 140. The X-ray irradiation device 100 is positioned and fixed by changing the position.

In step ST2, the X-ray image receiving device 200 is set for the inspection object TO. That is, by positioning the first movable frame 270 in the central portion in the vertical direction and the second movable frame 280 in the central portion in the horizontal direction, the X-ray image receiving panel 290 is positioned in the central portion in the vertical and horizontal directions. Let me. Then, the X-ray image receiving device 200 is positioned and fixed so that the X-ray image receiving panel 290 is located (overlapped) at the center of the inspection object TO.

In steps ST1 and ST2, the X-ray irradiation device 100 and the X-ray image receiving device 200 are set in one region and the other region sandwiching the inspection object TO.

In step ST3, the X-ray image receiving panel 290 is moved to the lower left position with respect to the X-ray irradiation device 100 to receive an X-ray image of the lower left portion of the inspection object TO. The X-ray image of the lower left portion of the inspection object TO received by the X-ray image receiving panel 290 is transmitted to the control personal computer 300 via the wireless link.

In step ST4, the X-ray image receiving panel 290 is moved to the lower right position with respect to the X-ray irradiation device 100 to receive an X-ray image of the lower right portion of the inspection object TO. The X-ray image of the lower right portion of the inspection object TO received by the X-ray image receiving panel 290 is transmitted to the control personal computer 300 via the wireless link.

In step ST5, the X-ray image receiving panel 290 is moved to the upper right position with respect to the X-ray irradiation device 100 to receive an X-ray image of the upper right part of the inspection object TO. The X-ray image of the upper right portion of the inspection object TO received by the X-ray image receiving panel 290 is transmitted to the control personal computer 300 via the wireless link.

In step ST6, the X-ray image receiving panel 290 is moved to the upper left position with respect to the X-ray irradiation device 100 to receive an X-ray image of the upper left portion of the inspection object TO. The X-ray image of the upper left portion of the inspection object TO received by the X-ray image receiving panel 290 is transmitted to the control personal computer 300 via the wireless link.

In steps ST3 to ST6, the X-ray image receiving panel 290 moves in the lower left position, lower right position, upper right position, and upper left position with respect to the X-ray irradiation device 100, while moving the lower left part, lower right part, and upper right part of the inspection object TO. Receive an X-ray image of the part and the upper left part. Here, the case where the X-ray image receiving panel 290 moves counterclockwise from the lower left position with respect to the X-ray irradiation device 100 is illustrated, but the movement order of the X-ray image receiving panel has a degree of freedom, and various design changes are possible. is there. That is, it is not necessary to execute steps ST3 to ST6 in this order, and the steps can be freely changed in order. Further, the movement of the X-ray image receiving panel 290 (movement of the first movable frame 270 and the second movable frame 280) may be performed manually by the X-ray irradiator, or a separate drive source (for example, a linear actuator). ) May be provided and executed automatically.

In step ST7, the X-ray image synthesizing unit 310 of the control personal computer 300 receives X-ray images (four sheets) of the lower left portion, the lower right portion, the upper right portion, and the upper left portion of the inspection object TO received by the X-ray image receiving panel 290. X-ray image) is combined to generate one X-ray image.

In step ST8, the display 320 of the control personal computer 300 displays one X-ray image synthesized by the X-ray image synthesizer 310. At this time, the display 320 may display a single X-ray image synthesized by the X-ray image synthesizing unit 310 and the "X-ray irradiation range" taken by the camera unit 130 of the X-ray irradiation device 100 in a comparable manner. ..

In step ST9, the determination unit 330 of the control personal computer 300 analyzes one X-ray image synthesized by the X-ray image synthesis unit 310, so that the inspection target TO contains a dangerous substance or a suspicious object. Determine if there is a risk.

If the determination unit 330 determines that the inspection target TO may contain dangerous or suspicious objects (step ST9: YES), the process proceeds to step ST10, and the warning unit 340 of the control personal computer 300 is X-rayed. A warning is issued to notify the line inspector to that effect, and the process is terminated. On the other hand, when the determination unit 330 determines that there is no possibility that the inspection object TO contains dangerous or suspicious objects (step ST9: NO), the warning unit 340 of the control personal computer 300 does not give a warning. (Skip step ST10) to end the process.

≪Summary of action and effect≫
As described above, in the X-ray inspection system 10 of the present embodiment, the camera unit (photographing unit) 130 and the display (display unit) 140 are provided in the housing portion 110 of the X-ray irradiation device 100, and the X-ray generation unit (X). The camera unit 130 photographs the X-ray irradiation range generated by the line generating unit) 120, and the display 140 displays the X-ray irradiation range photographed by the camera unit 130. This makes it possible to appropriately set the X-ray irradiation range for the inspection object TO and obtain a desired X-ray image.

Further, in the X-ray inspection system 10 of the present embodiment, the X-ray irradiation device 100 irradiates the inspection target TO with X-rays, and the X-ray image receiving device 200 changes the position relative to the X-ray irradiation device 100. The control personal computer (X-ray image synthesizer) 300 synthesizes a plurality of X-ray images received by the X-ray image receiver 200 while receiving a plurality of X-ray images transmitted through a plurality of parts of the inspection object TO. .. This makes it possible to perform an X-ray inspection suitable for a large-sized inspection object TO.

≪Additional notes such as deformation examples≫
The present invention is not limited to the above embodiment, and can be modified in various ways. In the above embodiment, the size, shape, function, and the like of the components shown in the accompanying drawings are not limited to this, and can be appropriately changed within the range in which the effects of the present invention are exhibited. In addition, it can be appropriately modified and implemented as long as it does not deviate from the scope of the object of the present invention.

For example, in the above embodiment, the first movable frame 270 is slidably supported in the vertical direction on the pair of guide shafts (base frames) 250, and the second movable frame 280 is attached to the first movable frame 270. The case where the support is slidable in the left-right direction has been illustrated and described. However, by reversing the above support relationship, the first movable frame is slidably supported in the left-right direction on the pair of guide shafts (base frames), and the second movable frame is vertically supported on the first movable frame. It may be slidably supported. That is, the first movable frame is slidably supported by a pair of guide shafts (base frames) in one direction in the vertical direction and the horizontal direction, and the second movable frame is vertically and horizontally supported by the first movable frame. It suffices if it is supported so as to be slidable in the other direction.

For example, in the above embodiment, the X-ray image receiving panel 290 moves the lower left position, the lower right position, the upper right position, and the upper left position with respect to the X-ray irradiation device 100, while moving the lower left portion, the lower right portion, and the lower right portion of the inspection object TO. An example of receiving an X-ray image (four X-ray images) of the upper right part and the upper left part has been described. However, the X-ray image receiving panel 290 fixes the vertical position with respect to the X-ray irradiation device 100, and moves the left and right positions with respect to the X-ray irradiation device 100 while moving the left and right parts of the inspection object TO. An X-ray image (two X-ray images) of a square portion may be received. Alternatively, the X-ray image receiving panel 290 fixes the horizontal position with respect to the X-ray irradiating device 100, and moves the upper and lower positions with respect to the X-ray irradiating device 100 while moving the X of the upper part and the lower part of the inspection object TO. A line image (two X-ray images) may be received.

The X-ray inspection system and the X-ray irradiation device of the present invention are suitable for inspection of inspection objects that may be dangerous substances or suspicious objects.

10 X-ray inspection system 100 X-ray irradiation device 110 Housing unit 111 Handle 112 Fingerprint authentication unit 113 Power switch 114 Handle 115 Handle 116 Tripod 117 Battery storage unit 118 Display storage unit 120 X-ray generation unit (X-ray generation unit)
121 X-ray emission port 130 Camera unit (shooting unit)
131 Shooting lens 140 Display (display)
200 X-ray receiver 210 220 Slide rail (base frame)
211 212 221 222 Caster 230 Frame stand (base frame)
231 232 Stopper wall (switching mechanism)
233 235 Guide shaft (switching mechanism)
234 236 Position regulation flange (switching mechanism)
240 Inner frame (base frame)
241 X-ray irradiation device 242 X-ray irradiation control rod 243 Spacer 250 Guide shaft (base frame)
260 handle holder (base frame)
270 First movable frame 271 Guide support part 272 Guide hole 273 Guide rail 280 Second movable frame 281 Panel holding protrusion 290 X-ray image receiving panel 291 Effective image receiving surface 292 Frame part 300 Control personal computer (X-ray image synthesizer)
310 X-ray image synthesizer 320 display (comparative display)
330 Judgment unit 340 Warning unit TO Inspection target

Claims (7)

An X-ray irradiation device that irradiates the inspection object with X-rays,
An X-ray image receiving device that receives an X-ray image transmitted through the inspection object,
It is an X-ray inspection system that has
The X-ray irradiation device is
The rectangular parallelepiped bag-shaped housing and
An X-ray generating part provided in the housing part and
An imaging unit provided in the housing unit and
A display unit provided on the housing unit and
Have,
The X-ray emission port of the X-ray generating portion and the photographing lens of the photographing portion are exposed on the surface of the housing portion facing the inspection object.
The display unit is provided on the surface of the housing unit opposite to the surface facing the inspection object.
The imaging unit photographs the X-ray irradiation range generated by the X-ray generating unit, and the display unit displays the X-ray irradiation range photographed by the imaging unit.
An X-ray inspection system characterized by this. The X-ray generating unit and the photographing unit are provided inside the housing unit.
The display unit is provided outside the housing unit.
The X-ray inspection system according to claim 1. The X-ray generating portion is provided at the bottom inside the housing portion.
The photographing unit is provided above the X-ray generating unit inside the housing unit.
The X-ray inspection system according to claim 2. The photographing unit photographs only the X-ray irradiation range generated by the X-ray generating unit.
The X-ray inspection system according to any one of claims 1 to 3, wherein the X-ray inspection system is characterized. The imaging unit photographs the X-ray irradiation range generated by the X-ray generating unit and its peripheral portion.
The display unit emphasizes and displays only the X-ray irradiation range photographed by the imaging unit.
The X-ray inspection system according to any one of claims 1 to 3, wherein the X-ray inspection system is characterized. Further, it has a comparative display device that displays the X-ray irradiation range captured by the photographing unit and the X-ray image received by the X-ray receiving device in a comparable manner.
The X-ray inspection system according to any one of claims 1 to 5. An X-ray irradiator that irradiates an object to be inspected with X-rays.
The rectangular parallelepiped bag-shaped housing and
An X-ray generating part provided in the housing part and
An imaging unit provided in the housing unit and
A display unit provided on the housing unit and
Have,
The X-ray emission port of the X-ray generating portion and the photographing lens of the photographing portion are exposed on the surface of the housing portion facing the inspection object.
The display unit is provided on the surface of the housing unit opposite to the surface facing the inspection object.
The imaging unit photographs the X-ray irradiation range generated by the X-ray generating unit, and the display unit displays the X-ray irradiation range photographed by the imaging unit.
An X-ray irradiation device characterized by this.