JP2023117599A - X-ray security check device - Google Patents

Abstract

To provide an X-ray security check device.SOLUTION: The X-ray security check device comprises: a body unit having a communication opening; a belt conveyor which passes through the communication opening and is located at the bottom of the communication opening; and a lead curtain which is provided with a pair of outside modules which are suspended from the body unit, cover the communication opening, and are arranged corresponding to both sides in the conveyance direction of the belt conveyor, and a center module which is located between the pair of outside modules. The thickness in terms of lead of the outside modules is larger than the thickness in terms of lead of the center module, and the weight of the center module is smaller than the weight of the outside modules.SELECTED DRAWING: Figure 1

Description

The present invention relates to a security checking device, and more particularly to an X-ray security checking device for security checking of articles.

Conventional X-ray security check equipment uses lead curtains of the same lead-equivalent thickness at entrances (communication ports) to shield radiation inside the fuselage. In general, the use of a lead curtain with a high lead-equivalent amount provides a good radiation shielding effect. It is not possible to pass smoothly and enter the aircraft, and the cost is high. However, using a thin lead curtain gives high radiation dose values to workers on both sides of the doorway and does not provide good shielding effect.

In view of this, the inventor of the present invention has made intensive research on the above-mentioned defects of the prior art and combined the application of theories to solve the above-mentioned problems. Ta.

The present invention provides an X-ray security checking device for security checking of articles.

An X-ray security check device according to the present invention comprises a main body having a communication port, a belt conveyor passing through the communication port and arranged at the bottom of the communication port, and a belt conveyor suspended from the main body and covering the communication port. , a lead curtain comprising a pair of outer modules arranged correspondingly on both sides in the conveying direction of the belt conveyor, and a central module arranged between the pair of outer modules, the lead of the outer modules The equivalent thickness is greater than the equivalent lead thickness of the central module, and the weight of the central module is less than the weight of the outer modules.

In the X-ray security check device according to the present invention, the thickness of the outer module is greater than the thickness of the central module. The outer modules have a plurality of outer strips, the central module has a plurality of central strips, the outer strips have a thickness of 3.0 mm to 3.5 mm, and the central strip has a thickness of 2.0 mm to 2.5 mm.

In the X-ray security checking apparatus according to the present invention, said outer module has a plurality of outer strips, said central module has a plurality of central strips, and the lead equivalent thickness of each said outer strip is equal to said It is twice the lead-equivalent thickness of the central strip. Each said outer strip has a lead equivalent thickness of 1.0 mmPb and each said central strip has a lead equivalent thickness of 0.5 mmPb.

In the X-ray security check device according to the present invention, each said outer module has a plurality of outer strips, said plurality of outer strips being stacked in two rows and arranged in a staggered manner. The central module has a plurality of central strips that are stacked in two rows and are staggered relative to each other. The outer strip and the central strip located at the intersection of the central module and each of the outer modules are superimposed and offset from each other.

In the X-ray security check device according to the present invention, the lead curtain is hung from the top of the communication port. The bottom edge of the lead curtain abuts without touching the belt conveyor.

In the X-ray security check apparatus according to the present invention, the main body has a pair of communication openings, a pair of lead curtains are hung from the main body correspondingly, and the belt conveyor has a pair of communication openings. each through the main body, each lead curtain covering each corresponding one of the communication openings.

In the X-ray security checking device according to the present invention, the overall width of the central module is 1 to 2 times the overall width of the outer module.

In the X-ray security check device according to the present invention, the equivalent lead thicknesses of the outer module and the central module have a positive correlation with the location coefficient.

In the X-ray security check device according to the present invention, the central module further includes a central base for locking the central module to the top of the main body, the central base having a long hole extending in the conveying direction. and a plurality of locking holes. The outer module further includes an outer base for locking the outer module to the top of the body, and the outer base includes a plurality of locking holes that are long holes perpendicular to the conveying direction.

According to the X-ray security check device of the present invention, the lead curtain has an outer module and a central module, and the equivalent lead thickness of the outer module is greater than the equivalent lead thickness of the central module. This effectively prevents X-rays in the main body from leaking to areas where workers are located on both sides of the communication port. Since the weight of the central module is less than that of the outer modules, the articles carried into the body can smoothly push aside the lead curtain.

1 is a schematic perspective view of an X-ray security check device according to a preferred embodiment of the present invention; FIG. 1 is a schematic perspective view of an X-ray security check device according to a preferred embodiment of the present invention; FIG. 1 is a schematic perspective view of a lead curtain of an X-ray security check device that is a preferred embodiment of the present invention; FIG. 4 is an enlarged view of a main part of FIG. 3; FIG. 1 is an exploded perspective view of a lead curtain of an X-ray security check device according to a preferred embodiment of the present invention; FIG. 1 is a cross-sectional view of a lead curtain of an X-ray security check device according to a preferred embodiment of the present invention; FIG. 7 is an enlarged view of area 7 shown in FIG. 6; FIG.

1 and 2 are schematic perspective views of an X-ray security check device according to a preferred embodiment of the present invention. The X-ray security check device includes a main body 100, a belt conveyor 200 and at least one lead curtain 300.

In this embodiment, the main body 100 is a metal case. At least one communication port 101 is provided on the side surface of the main body 100 . In this embodiment, the main body 100 has a passage and two communication openings 101 serving as entrances and exits of the passage. The two communication ports 101 are arranged on both sides facing the sides of the main body 100, but the present invention is not limited to this. The main body 100 is provided with an X-ray radiator that emits X-rays inside the main body 100 .

The belt conveyor 200 passes through the communication port 101 and is arranged at the bottom of the communication port 101 . In this embodiment, the belt conveyor 200 passes through the main body 100 through each of the pair of communication openings 101 . A belt conveyor 200 carries an article to be scanned into the main body 100 for scanning with X-rays.

A lead curtain 300 is suspended from the main body 100 and covers the communication port 101 . In this embodiment, a pair of lead curtains 300 are suspended from the main body 100 so as to correspond to the two communication ports 101 . Each lead curtain 300 covers each corresponding communication port 101 . In this embodiment, it is preferable that the lead curtain 300 is hung from the top of the communication port 101 and the bottom edge of the lead curtain 300 is adjacent to the belt conveyor 200 without contacting it. The hanging position of the curtain 300 is not limited.

Since the structure and operation of the pair of curtains 300 are the same, one lead curtain 300 will be described below as an example. Referring to FIGS. 3-7, lead curtain 300 comprises a pair of outer modules 310 and central module 320 . A pair of outer modules 310 are arranged corresponding to both sides of the belt conveyor 200 in the conveying direction D, and a central module 320 is arranged between the pair of outer modules 310 and arranged in the center of the communication port 101. there is In other words, the pair of outer module 310 and central module 320 are arranged side by side to cover the communication port 101 . Here, the lead-equivalent thickness of the outer modules 310 is greater than the lead-equivalent thickness of the central module 320 . Lead is a widely used material for radiation protection due to its strong absorption of radiation. When other protective materials are used, their protective effects are commonly displayed in terms of lead equivalent, which is advantageous for comparison. The equivalent lead thickness of an object refers to the thickness of a lead plate that has the same radiation absorption capacity as the object.

Note that the lead equivalent thicknesses of the outer module 310 and the central module 320 have a positive correlation with an occupancy factor (hereinafter also referred to as "T"), and the occupancy factor (T) is the probability that a person stays in the area. is. Here, the location coefficient T ₁ on both sides of the communication port 101 is higher than the location coefficient T ₂ in the center of the communication port 101, and T ₁ may be equal to T ₂ times to 16 times. The equivalent lead thickness of the outer module 310 is greater than the lead equivalent thickness of the central module 320 because the corresponding equivalent lead thicknesses are obtained with different location factors (T) according to known scatter shielding equations.

In this embodiment, outer module 310 has a plurality of outer strips 311 and central module 320 has a plurality of central strips 321 . The lead equivalent thickness of each outer strip 311 is greater than the lead equivalent thickness of each central strip 321 . Preferably, the lead equivalent thickness of the outer strips 311 is twice the lead equivalent thickness of the center strip 321 . Specifically, the lead equivalent thickness of the outer strips 311 is 1.0 mmPb, and the lead equivalent thickness of the center strip 321 is 0.5 mmPb. In this embodiment, for ease of manufacture, the outer strips 311 and the central strip 321 are made of the same leaded rubber, so that the thickness of the outer module 310 is greater than the thickness of the central module 320 and the central module 320 is less than the weight of the outer module 310 . Specifically, the thickness t1 of the outer strip 311 is approximately 3.0 mm to 3.5 mm, and the thickness t2 of the central strip 321 is approximately 2.0 mm to 2.5 mm.

In this embodiment, one end of the plurality of center strips 321 is fixed to the center base 322 . A plurality of central strips 321 are stacked in two rows and arranged in a staggered manner. This makes it possible to shield the gap between the two central strips 321 arranged adjacent to each other to prevent X-ray leakage within the body 100 . Here, the center base 322 is preferably a linear metal member. A plurality of locking holes 302 for locking onto the top of the main body 100 are formed in the central base 322 , and each locking hole 302 is an elongated hole extending in the longitudinal direction of the central base 322 . In other words, each locking hole 302 is an elongated hole extending in the transport direction D. As shown in FIG. This facilitates translating the central module 320 inwardly or outwardly along the opening direction of the communication port 101 to eliminate assembly tolerances between the central module 320 and the outer modules 310 .

In this embodiment, one end of the plurality of outer strips 311 is fixed to the outer base 312 . A plurality of outer strips 311 are stacked in two rows and arranged in a staggered manner. Thereby, the gap between the two outer strips 311 arranged adjacent to each other can be shielded from each other to prevent X-ray leakage within the body 100 . Here, the outer base 312 is preferably a linear metal member. The outer base 312 has a plurality of locking holes 301 for locking onto the top of the main body 100. Each locking hole 301 is an elongated hole extending in the lateral direction of the outer base 312. . In other words, the extending direction of each locking hole 301 is perpendicular to the conveying direction D. As shown in FIG. This facilitates translating the outer module 310 along the lateral direction of the communication opening 101 to align with the side edges of the communication opening 101 and the central module 320 to eliminate assembly tolerances.

6 and 7, in this embodiment, the outer strips 311 and the central strips 321 located at the intersection of the central module 320 and each outer module 310 are superimposed and offset from each other. there is In addition, since the center module 320 can be translated and adjusted along the conveying direction D by the extending direction of the locking hole 302, the center strip 321 can be translated and adjusted so that the outer strip 311 closely overlaps. It is possible. Thereby, the gaps at the intersections of the central module 320 and the outer modules 310 can be shielded to prevent X-ray leakage inside the main body 100 .

In the X-ray security check device according to the present invention, the lead curtain 300 has an outer module 310 and a central module 320 , the outer module 310 having a lead equivalent thickness greater than that of the central module 320 . This effectively prevents X-rays in the main body 100 from leaking to areas where workers are located on both sides of the communication port 101 . In this embodiment, the central module 320 is the main contact area of articles as they pass through the curtain 300, and the overall width of the central module 320 is between 1 and 2 times the overall width of the outer modules 310. There may be. Since the weight of the central module 320 is less than that of the outer modules 310 , an item carried into the main body 100 can smoothly push the curtain 300 away.

Although preferred embodiments of the present invention have been described above, the present invention is not limited to the scope described in the above embodiments. Various modifications or improvements can be made to the above embodiments without departing from the gist of the present invention, and the modified or improved forms are also included in the technical scope of the present invention.

100 main body 101 communication port 200 belt conveyor 300 lead curtain 301 locking hole 302 locking hole 310 outer module 311 outer strip 312 outer base 320 central module 321 central strip 322 central base D conveying direction t1 thickness t2 thickness

Claims (15)

a main body having a communication port;
a belt conveyor that passes through the communication port and is arranged at the bottom of the communication port;
A pair of outer modules suspended from the main body to cover the communication port and arranged corresponding to both sides in the conveying direction of the belt conveyor, and a central module arranged between the pair of outer modules. including lead curtains and
the lead equivalent thickness of the outer modules is greater than the lead equivalent thickness of the central module, and the weight of the central module is less than the weight of the outer module;
X-ray security check device. the thickness of the outer modules is greater than the thickness of the central module;
The X-ray security check device according to claim 1. The outer modules have a plurality of outer strips, the central module has a plurality of central strips, the outer strips have a thickness of 3.0 mm to 3.5 mm, and the central strip has a thickness of 2.0 mm to 2.5 mm;
The X-ray security check device according to claim 2. The outer modules have a plurality of outer strips and the central module has a plurality of central strips, each said outer strip having a lead equivalent thickness equal to twice the lead equivalent thickness of each said central strip. be,
The X-ray security check device according to claim 1. each said outer strip having a lead equivalent thickness of 1.0 mmPb and each said central strip having a lead equivalent thickness of 0.5 mmPb;
The X-ray security check device according to claim 4. each said outer module having a plurality of outer strips, said plurality of outer strips being stacked in two rows and staggered relative to each other;
The X-ray security check device according to claim 1. said central module having a plurality of central strips, said plurality of central strips being stacked in two rows and staggered relative to each other;
The X-ray security check device according to claim 1. Each said outer module has a plurality of outer strips, said central module has a plurality of central strips, said outer strips and said central strips located at intersections of said central module and each said outer module are: , superimposed and offset from each other,
The X-ray security check device according to claim 1. The lead curtain is suspended from the top of the communication port,
The X-ray security check device according to claim 1. The bottom edge of the lead curtain is adjacent without contacting the belt conveyor.
The X-ray security check device according to claim 1. The main body has a pair of communication ports, and a pair of lead curtains are hung from the main body correspondingly,
The belt conveyor passes through the main body through the pair of communication ports,
Each lead curtain covers each corresponding communication port,
The X-ray security check device according to claim 1. the overall width of the central module is between 1 and 2 times the overall width of the outer modules;
The X-ray security check device according to claim 1. the equivalent lead thicknesses of the outer module and the central module are positively correlated with the location factor;
The X-ray security check device according to claim 1. said central module having a central base for locking said central module to the top of said body;
the central base includes a plurality of locking holes that are long holes extending in the conveying direction,
The X-ray security check device according to claim 1. the outer module has an outer base for locking the outer module to the top of the body;
the outer base includes a plurality of locking holes that are long holes perpendicular to the conveying direction,
The X-ray security check device according to claim 1.