KR101724138B1 - Radiation detection instrument for non-destructive inspection - Google Patents

Abstract

The present invention relates to a thermohygrostat-radiation detection apparatus for a non-destructive inspection installed to face a radiation source (T) radiating a radioactive ray (R) in a vertical direction while forming a fan-shape, comprising: a detection box (10); a plurality of light collection sensor units (20); a base box (30); and a constant temperature and humidity part (40). The detection box (10) has a side wall (11) formed inside in a vertical direction. The plurality of light collection sensor units (20) is arranged on a side wall (11) of the detection box (10), and have light collection sensors (S) to detect radioactive rays (R) irradiated from the radiation source (T). The base box (30) supports the detection box (10) to be erected; and a constant temperature and humidity part (40) installed in an interior of the base box (30) maintains the interior of the detection box (10) under an environment with constant temperature and humidity. According to the present invention, a unique detection function of a light collection sensor is able to be maximized.

Description

TECHNICAL FIELD [0001] The present invention relates to a radiation detection apparatus for non-destructive inspection,

The present invention relates to a radiation detecting apparatus for a non-destructive inspection used in a port or industry, and more particularly, to a radiation detecting apparatus for a constant temperature and humidity non-destructive inspection capable of realizing a constant temperature and humidity environment to obtain a high quality transmitted image.

As the scale of global trade increases and the forms of terrorism become more diverse, there is a growing demand for non-destructive testing devices that identify explosive articles, toxic articles, and prohibited articles loaded on containers in a short period of time. Such non-destructive testing devices are mainly installed at harbors and airports. For example, harbors are installed in a path through which containers are transported, and include a radiation source for emitting radiation such as an X-ray beam, And a radiation detector for detecting the radiation irradiated from the radiation source. With this configuration, while the container slowly passes through the conveyance path by the trailer, the radiation source irradiates the container with the radiation, and the radiation detector detects the radiation transmitted through the container, thereby confirming the article loaded in the container.

In this case, the radiation source irradiates the radiation in the form of an electron linear accelerator in the form of a fan having a specific irradiation angle, and the radiation detector is composed of a plurality of light receiving sensors positioned at the same distance around the radiation source. It depends on the location of occurrence.

Here, the plurality of light receiving sensors continuously receive the radiation transmitted through the container to generate scan frames, and the radiation detector generates two-dimensional transmission image information by combining the sequentially generated scan frames in a time series . Prior art related thereto is disclosed in Patent Publication No. 10-2007-0048107 titled " Method and apparatus for proceeding material identification by high-speed neutron and continuous energy spectrum X-ray.

However, since many of the light receiving sensors are disposed inside the detector box, dust and soot in the air are introduced into the detector box and contaminate the light receiving sensor itself. In addition, in summer, there is a high temperature and high humidity environment, As the exposure to the environment is repeated, the function of the light receiving sensor gradually disappears, and at the same time, the life is shortened.

Particularly, the environment in which the radiation detecting device is installed is a place where a large number of trailers transport the container, so dust or soot in the exhaust gas is a main cause of contamination of the light receiving sensor.

The present invention is created to satisfy the above-mentioned need. It is possible to maximize the detection function inherent to a light receiving sensor by preventing inflow of dust and smoke in the air and realizing a constant temperature and humidity environment in summer and winter, And to provide a radiation detecting apparatus for a constant temperature and humidity non-destructive inspection capable of preventing shortening of the radiation detector.

In order to achieve the above object, a radiation detecting apparatus for a constant temperature and humidity non-destructive inspection according to the present invention comprises:
(T) facing a radiation source (T) for irradiating a radiation (R) in a fan shape and a vertical direction on one side of a path through which the container (C) is conveyed, And a vertical sidewall (11) having an exhaust port (12) and an air inlet port (13) formed in upper and lower portions, respectively; A base box 30 which is fixed upright in a vertical direction to the ground and is coupled with the side wall 11 of the detection box 10 so that the exhaust port 12 and the air inlet port 13 are located inside; A plurality of light receiving sensor units 20 provided on the side wall 11 inside the detection box 10 and having a light receiving sensor S for detecting the radiation R emitted from the radiation source T; A thermostatic and hygroscopic body 41 installed inside the base box 30 and an air duct 42 for connecting the thermostatic hygrostat body 41 and the exhaust port 12 are installed in the base box 30, And a constant temperature and humidity section (40) for maintaining the interior of the detection box (10) in a constant temperature and humidity environment, including; The plurality of light receiving sensor units 20 are arranged on the detection box side wall 11 in a circumferential shape having the same distance with respect to the radiation source T as a center, A position adjustment function for adjusting the position of the display unit; The light receiving sensor unit 20 includes a base bracket 21 fixed to the side wall 11 and a hinge h hinged to the surface of the base bracket 21 so that the light receiving sensor S A circumferential guide groove 23 formed to have the same circumference around the hinge h and a circumferential guide groove 23 which is fixed to the base bracket 21 and is engaged with the circumferential guide groove 23, Includes a guide projection (24); The circumferential guide groove 23 is composed of first and second circumferential guide grooves 23a and 23b formed on one side and the other side of the hinge h, The first and second guide protrusions 24a and 24b are formed by first and second guide protrusions 24a and 24b which are respectively engaged with the guide grooves 23a and 23b and fixed to the base bracket 21. [ A friction bushing 24a 'that presses the surface of the rotating bracket 22 on the upper side of the first and second circumferential guide grooves 23a and 23b to generate a frictional force between the rotating bracket 22 and the base bracket 21, (24b ') are interposed between the first and second plates.

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In the present invention, the constant temperature and humidity section (40) includes a temperature sensor (43) for measuring the temperature of the internal space of the detection box (10), a humidity sensor Sensor 44. < / RTI >

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According to the present invention, the inside of the detection box is isolated from the external environment, and the constant temperature and humidity air is circulated inside the detection box in which the light receiving sensor is incorporated, thereby preventing inflow of dust and smoke in the air, Environment can be implemented. Accordingly, the detection function inherent to the light receiving sensor is maximized to obtain a clear transmitted image as well as a shortened life span.

1 is a perspective view for explaining a radiation detection apparatus for a constant temperature and humidity non-destructive inspection according to the present invention,
FIG. 2 is a view for explaining the configuration of the radiation detecting apparatus of FIG. 1,
FIG. 3 is a drawing for explaining the internal configuration of the detection box of FIG. 2,
FIG. 4 is a front view for explaining a specific configuration by extracting the light receiving sensor unit of FIG. 3;
Fig. 5 is a drawing showing the circumferential guide groove and guide projection of Fig. 4,
6A and 6B are diagrams for explaining the positioning operation of the light receiving sensor unit,

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a radiation detecting apparatus for non-destructive testing according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view for explaining a radiation detecting apparatus for a constant temperature and humidity non-destructive inspection according to the present invention, FIG. 2 is a view for explaining a configuration of the radiation detecting apparatus of FIG. 1, And explains its internal configuration. 4 is a view showing the circumferential guide groove and guide protrusion of FIG. 4, and FIG. 6A and FIG. 6B are views showing the light receiving sensor unit of FIG. Fig. 8 is a diagram for explaining the position alignment operation of the unit.

As shown in the figure, the radiation detecting apparatus for non-destructive testing according to the present invention is installed facing a radiation source T for irradiating the radiation R in a fan shape and a vertical direction, (10); A plurality of light sources S having a light receiving sensor S for detecting the radiation R irradiated from the radiation source are disposed on the side wall 11 of the detection box 10 so as to have a circumferential shape of the same distance around the radiation source T, A light receiving sensor unit 20; A base box (30) for uprightly supporting the detection box (10); And a constant temperature and humidity unit (40) installed inside the base box (30), for maintaining the inside of the detection box (10) in a constant temperature and humidity environment.

The radiation source T for irradiating the radiation R is, for example, in the form of an electron linear accelerator and irradiates the radiation R such as an X-ray beam in the form of a fan having a specific irradiation angle. In this case, the radiation source T may be not only an accelerator type but also a chamber in which a radiation material for generating radiation transmitting the container is housed.

1, the detection box 10 has a flat box shape in which a space is formed therein. The detection box 10 has a flat surface on the opposite side of the radiation source T with respect to a path through which the container C is conveyed, Respectively.

An exhaust port 12 and an air inlet port 13 communicating with the inside of the base box 30 are formed in the upper portion and the lower portion of the side wall 11 in the detection box 10, respectively. At this time, the exhaust port (12) is connected to the air conditioning duct (42) of the constant temperature and humidity section to be described later.

A plurality of light receiving sensor units 20 are disposed on the detection box side wall 11 in the form of a column around the radiation source T so as to receive the radiation R emitted from the radiation source T to form a continuous scanning frame do.

Each of the light receiving sensor units 20 may have a position adjusting function for adjusting the position of the light receiving sensor S with respect to the detection box side wall 11. In this case, A rotation bracket 22 which is coupled to the surface of the base bracket 21 on the axis of the hinge h and on which the light receiving sensor S is installed; A circumferential guide groove 23 formed to have the same circumference around the hinge h and a guide protrusion 24 fixed to the base bracket 21 and interposed in the circumferential guide groove 23.
The base bracket 21 supports the rotation bracket 22 about the hinge h and the rotation bracket 22 is rotatable in the left and right direction with respect to the hinge h.

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The rotation bracket 22 is provided with a light receiving sensor S for receiving the radiation R to be irradiated. At this time, the light receiving sensor S is located opposite to the radiation source T so that the radiation R can be received at the front face.

The circumferential guide groove 23 and the guide protrusion 24 allow the rotation bracket 22 to stably rotate about the hinge h. The circumferential guide groove 23 is composed of first and second circumferential guide grooves 23a and 23b formed on one side and the other side of the hinge h, And first and second guide projections 24a and 24b that are engaged with the grooves 23a and 23b and fixed to the base bracket 21, respectively.

The first and second guide projections 24a and 24b are provided with friction bushings 24a 'for applying frictional force to the side surfaces of the first and second circumferential guide grooves 23a and 23b 24b 'may be installed. The frictional bushings 24a and 24b 'prevent frictional force from being applied to the surface of the pivotal bracket 22 to prevent the pivotal bracket 22 from slidably rotating with respect to the base bracket 21, Thereby maintaining the rotated angle. Therefore, after the pivotal bracket 22 is pivoted to align the position, it is possible to omit a separate bolting operation for maintaining the pivoted angle, thereby facilitating the positioning operation.

6A, the rotation bracket 22 is rotated so that the light receiving sensor S side is aligned (rotated) with respect to the hinge h as a reference, , The rotation bracket 22 can be rotated so that the light receiving sensor S side is aligned (rotated) to the lower side as shown in Fig. 6B.

As shown in Fig. 2, the base box 30 is fixed upright in a direction perpendicular to the paper so as to support the side wall 11 of the detection box 10, and has a box shape in which a space is formed therein.

The constant temperature and humidity section (40) is provided in the space inside the base box (30) to maintain the inside of the detection box (10) in a constant temperature and humidity environment. 2, the constant temperature and humidity unit 40 includes a constant temperature and humidity chamber main body 41 built in the base box 30 and an air conditioning duct 41 connecting the constant temperature and humidity chamber main body 41 and the air outlet 12. [ A temperature sensor 43 for measuring the temperature of the interior space of the detection box 10, and a humidity sensor 44 for measuring humidity.

The main body 41 of the thermo-hygrostat unit is composed of various valves for finely regulating the flow of the air conditioner and the refrigerant fluid therein. Since the thermostatic and hygroscopic unit 41 is generally used in the art, further detailed description is omitted.

The air conditioning duct 42 is for supplying air that has been subjected to constant temperature and humidity while passing through the thermo-hygrostat body 41 to the detection box 10 through the air outlet 12. It is preferable that the air conditioning duct 42 is of a bellows type in which the length can be varied.

Each of the temperature sensor 43 and the humidity sensor 44 measures the temperature and humidity inside the detection box 10 and generates a corresponding temperature signal and humidity signal, And is used as a signal to continuously form the constant temperature and humidity air.

As described above, according to the present invention, the inside of the detection box 10 is isolated from the external environment, and the constant temperature and humidity air is circulated inside the detection box 10 in which the light receiving sensor S is housed, And it is possible to realize a constant temperature and humidity environment even in summer and winter. Accordingly, the detection function inherent to the light receiving sensor is maximized to obtain a clear transmitted image as well as a shortened life span.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

10 ... detection box 11 ... side wall
12 ... exhaust port 13 ... intake port
20 ... Light receiving sensor unit 21 ... Base bracket
22 ... rotation bracket 23 ... circumferential guide groove
23a, 23b ... First and second circumferential guide grooves 24 ... Guide projections
24a, 24b ... First and second guide projections 30 ... Base box
40 ... constant temperature and humidity part 41 ... constant temperature and humidity body
42 ... air duct 43 ... temperature sensor
44 ... humidity sensor

Claims (6)

(T) facing a radiation source (T) for irradiating a radiation (R) in a fan shape and a vertical direction on one side of a path through which the container (C) is conveyed, And a vertical sidewall (11) having an exhaust port (12) and an air inlet port (13) formed in upper and lower portions, respectively;
A base box 30 which is fixed upright in a vertical direction to the ground and is coupled with the side wall 11 of the detection box 10 so that the exhaust port 12 and the air inlet port 13 are located inside;
A plurality of light receiving sensor units 20 provided on the side wall 11 inside the detection box 10 and having a light receiving sensor S for detecting the radiation R emitted from the radiation source T;
A thermostatic and hygroscopic body 41 installed inside the base box 30 and an air duct 42 for connecting the thermostatic hygrostat body 41 and the exhaust port 12 are installed in the base box 30, And a constant temperature and humidity section (40) for maintaining the interior of the detection box (10) in a constant temperature and humidity environment, including;
The plurality of light receiving sensor units 20 are arranged on the detection box side wall 11 in a circumferential shape having the same distance with respect to the radiation source T as a center, A position adjustment function for adjusting the position of the display unit;
The light receiving sensor unit 20 includes a base bracket 21 fixed to the side wall 11 and a hinge h hinged to the surface of the base bracket 21 so that the light receiving sensor S A circumferential guide groove 23 formed to have the same circumference around the hinge h and a circumferential guide groove 23 which is fixed to the base bracket 21 and is engaged with the circumferential guide groove 23, Includes a guide projection (24);
The circumferential guide groove 23 is composed of first and second circumferential guide grooves 23a and 23b formed on one side and the other side of the hinge h, The first and second guide protrusions 24a and 24b are formed by first and second guide protrusions 24a and 24b which are inserted into the guide grooves 23a and 23b and are fixed to the base bracket 21, A friction bushing 24a 'that presses the surface of the rotating bracket 22 on the upper side of the first and second circumferential guide grooves 23a and 23b to generate a frictional force between the rotating bracket 22 and the base bracket 21, (24b ') is interposed between the first and second electrodes (24a, 24b). delete The apparatus according to claim 1, wherein the constant temperature and humidity section (40)
Further comprising: a temperature sensor (43) for measuring the temperature of the internal space of the detection box (10); and a humidity sensor (44) for measuring the humidity of the internal space of the detection box (10) Radiation detection system for non - destructive testing at constant temperature and humidity. delete delete delete

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