KR101485476B1 - Dual Radiation shielding apparatus - Google Patents

Abstract

Disclosed is an apparatus for shielding dual radiation. An apparatus for shielding radiation generated in X ray photographing when an X-ray photograph is made while moving an object to be examined includes a first shielding room formed by assembling first panels prepared at a strong steel layer; a second shielding room formed by assembling second panels provided by interposing a lead layer between multiple steel layers and provided in the first shielding room; an X-ray generator positioned inside the first shielding room and outside the second shielding room to irradiate an X ray into the second shielding room through an opening provided at an upper portion of the second shielding room; a detecting unit positioned inside the second shielding room and under the second shielding room to detect a result obtained by irradiating the X ray to the object to the examined; a moving unit positioned inside the second shielding room and at the upper end of the detecting unit to horizontally move in the state where the object is placed so that the object is horizontally moved; and a driving unit positioned inside the first shielding room and outside the second shielding room to drive the X ray generator, the detecting unit, and the moving unit. Accordingly, shielding is dually performed to increase a shielding efficiency. In the state where a test device is operated, the repair/maintenance of the test device or the input/output of the object to be examined is possible, so that the repair/maintenance efficiency and the working efficiency can be increased. The structures for the dual shielding can be mutually separated from each other, so that the moving property, the carrying property, and the productivity can be increased.

Description

[0001] Dual Radiation shielding apparatus [

The present invention relates to a double-ray shielding apparatus, and more particularly, to a double-ray shielding apparatus for inspecting thickness, defects, foreign matter, or detailed assembled state of a subject without damaging or decomposing the subject through radiography of the subject Industrial double-radiation shielding apparatus.

Radiographic examination techniques have been applied in medical field first, and nowadays, they are expanding to industrial use because they can confirm internal structures and conditions even without individual decomposition of the test object.

In such an inspection technique through radiation transmission, a shielding method for minimizing various damages caused by radiation such as leukocytopia, skin erythema, infertility, blindness is an important factor.

Korean Patent Registration No. 10-0738123 (filed on July 04, 2007) discloses a shielding device for a radiation transmission test equipment.

However, in this conventional inspection technique, radiation is shielded through a single shielding case, so that not only the shielding efficiency is low but also the repair or maintenance of the internal electronic equipment is required, There is a problem that it is difficult to analyze the cause of the failure because the repair or repair must be performed while the test equipment is stopped.

In addition, in the conventional inspection technique, since the weight of the test equipment is considerably heavy and the test equipment is provided in an integrated state, it is necessary to always move the test object to the position where the test equipment is located, There is a problem that considerable equipment and manpower must be mobilized in the situation.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the above-mentioned problems, and an object of the present invention is to provide an improved shielding efficiency by enabling double shielding, and it is possible to repair / repair the test equipment even when the test equipment is in operation Electronic signal and so on to improve repair / maintenance efficiency and work efficiency, and to double the structure for shielding, it is possible to increase the mobility, transportability and productivity of the test equipment. And a radiation shielding device.

According to an aspect of the present invention, there is provided an apparatus for shielding radiation generated during an X-ray photographing operation by moving a subject according to an embodiment of the present invention, the apparatus comprising: A first shielding room formed by the first shielding room; A second shielding chamber formed inside the first shielding chamber, the second shielding panel being assembled with second panels provided with a lead layer between the plurality of steel layers; An X-ray generating unit located inside the first shielding room and outside the second shielding room to irradiate X-rays into the second shielding room through an opening provided in the upper part of the second shielding room; A detecting unit positioned in the second shielding room and below the second shielding room for detecting a result of irradiation of the X-ray to the subject; A moving unit positioned inside the second shielding room and positioned at an upper end of the detecting unit to horizontally move the inspected object in a state in which the inspected object is placed in a horizontal position; And a driving unit disposed inside the first shielding room and outside the second shielding room to drive the X-ray generating unit, the detecting unit, and the moving unit.

Here, the first panels or the second panels may be assembled together through separate connecting members, and the connecting members may penetrate openings provided in the first panels or the second panels, The first panels or the second panels being assembled together such that the head portion is directed to the exterior of the dual radiation shield and the tail portion is directed to the interior of the dual radiation shield, The head portion of the connecting member may be surface treated with lead so that the radiation does not leak through openings through which the connecting member penetrates.

The first shielding room may include a door part provided to inspect the driving part or draw out the subject even when the dual radiation shielding device is in operation, The radiation can be firstly shielded so that the inspection of the driving unit or the drawing-out of the inspected object can be performed through the door unit even when the radiation shielding apparatus is in operation.

Thus, the shielding efficiency can be increased by enabling double shielding, and it is possible to repair / repair the test equipment even when the test equipment is in operation, and to detect the electronic signal, And the structures for double shielding can be separated from each other, so that the mobility, transportability and productivity of the test equipment can be increased.

1 is a block diagram illustrating an entire double-ray shielding apparatus according to an exemplary embodiment of the present invention.
2 is a front perspective view of a first shielding room of a dual radiation shielding apparatus according to an embodiment of the present invention.
FIG. 3 is a rear perspective view of a first shielding room of a dual radiation shielding apparatus according to an embodiment of the present invention. FIG.
4 is a front perspective view of a second shielding room of a dual radiation shielding apparatus according to an embodiment of the present invention.
FIG. 5 is a rear perspective view of a second shielding room of a dual radiation shielding apparatus according to an embodiment of the present invention. FIG.
6 is a view showing a state in which the internal electronic devices are disposed in a state that the second shielded room is inserted into the first shielded room.
7 is a view showing the inside of the second shielding room.
8 is a view showing an engaging member or a connecting member according to an embodiment of the present invention.
9 is a view showing a state in which the connecting members interconnect the second panels of the second shielding room.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 is a block diagram illustrating an entire double-ray shielding apparatus according to an exemplary embodiment of the present invention.

The double-ray shielding apparatus according to the present embodiment double-shields radiation through a double shielded room.

The dual radiation shielding apparatus includes a first shielding room 100, a second shielding room 200, an X-ray generating unit 300, a detecting unit 400, a moving unit 500, and a driving unit 600 .

The first shielding room 100 is provided at the outermost portion of the double-ray shielding apparatus to shield the radiation generated in the X-ray generating unit 300 inside the second shielding room.

The first shielding room 100 is formed by assembling first panels provided with a steel layer. For example, when the first shielding room 100 has a hexahedral shape, the first panels may include a front steel panel, a rear steel panel, a left side steel panel, a right side steel panel, a flat steel panel, Panel.

In addition, since each of the first panels is separately manufactured at the time of manufacture, the first radiation-shielding apparatus is moved in a separated state at the site where the double-radiation shielding apparatus should be installed, and the first shielding room 100 is formed .

Generally, in the case of the structures shielding the radiation, since it has a weight of hundreds of kilos to tens of tons, it is difficult to manufacture and lacks mobility. However, in the case of the first shielding room 100 according to the present embodiment, So that the above-described difficulties can be overcome.

On the other hand, each of the panels is interconnected through the connecting member so that the radiation is assembled and sealed so as not to leak to the outside. The details of the connecting member will be described later with reference to Figs. 8 and 9. Fig.

The second shielding room 200, the X-ray generator 300, the detec- ting unit 400, the moving unit 500 and the driving unit 600 are disposed in the first closed unit 100, An operation unit 110 is provided outside the display unit 100.

The operation unit 110 includes a switch unit (not shown) capable of turning on / off the power supply of the dual radiation shielding apparatus, a notification unit (not shown) for notifying the on-state or off-state of the power supply, A release unit (not shown) for releasing the operation of the dual radiation shielding apparatus, a display unit (not shown) for indicating whether or not the X-ray is irradiated, and the like.

Additional configuration of the first shielding room 100 will be described later.

The second shielding room 200 is located inside the first shielding room 100.

The second shielding room 200 is provided inside the first shielding room 100 to primarily shield the radiation generated from the X-ray generator 300.

The second shielding room 100 is formed by assembling the second panels formed of a steel layer, a lead layer and a steel layer. For example, when the second shielding room 200 has a hexahedral shape, the second panels may include a front panel steel-lead-steel panel, a rear panel steel-lead-steel panel, a left side panel steel- Lead-steel panel, flat-panel steel-lead-steel panel and bottom-surface steel-lead-steel panel.

In addition, since each of the second panels is separately manufactured at the time of manufacture, the second radiation shielding apparatus is moved in a separated state on the site where the double radiation shielding apparatus is to be installed, and the second shielding room 200 is formed .

The second shielding room 200 is formed so as to be smaller in width, length and height than the first shielding room 100 so as to be positioned inside the first shielding room 100. Particularly, the second shielding room 200 has a height limited so as to secure a space in which various kinds of electronic equipment can be disposed in the upper area of the second shielding room 200 out of the outer areas of the second shielding room 200. Respectively.

Among the external areas of the second shielding room 200, the electronic devices disposed in the upper area of the second shielding room 200 include the X-ray generating part 300 and the driving part 600, The electronic equipment disposed in the inner area of the room 200 includes a detec- ting unit 400 and a moving unit 500. [

The upper portion of the second shielding room 200 is provided with an opening (not shown) through which the X-ray can be transmitted. The X-ray generating unit 300 includes an opening And serves to radiate X-rays into the second shielding room 200 in the inner direction.

The X-rays irradiated into the second shielding room 200 are transmitted through the inspected object or reflected from the inspected object, and are transmitted to the detec- ting unit 400.

The detec- ting unit 400 serves to inspect the thickness, defect, foreign matter, detailed assembled state, and the like of the test object without damaging or decomposing the test object through the X-ray transmitted through the test object or reflected by the test object .

The moving unit 500 radiates X-rays to the subject at various angles so that the detec- ting unit 400 moves in the horizontal direction to inspect the subject at various angles. In this way, Thereby providing a space on which the subject can be placed. For this, the moving part 500 is disposed in an area between the X-ray generating part 300 and the detec- ting part 400 among the inner areas of the second shielding room 200. [

The driving unit 600 serves to drive the entirety of the dual radiation shielding apparatus.

In particular, the driving unit 600 is connected to the operation unit 110 provided in the first shielding room 100, and receives a user's operation command from the operation unit 110 or an alarm according to a user's operation instruction or a double- And provides an alarm according to the state.

The driving unit 600 is connected to the X-ray generating unit 300 so that the X-ray generating unit 300 irradiates or releases the X-rays. The driving unit 600 is connected to the detec- ting unit 400, The test is performed on the subject or the process is terminated.

In addition, the driving unit 600 is connected to the moving unit 500 to control a motor provided inside the moving unit 500 or separately from the moving unit 500 so that the subject moves in the horizontal direction.

FIG. 2 is a front perspective view of a first shielding room 100 of a dual radiation shielding apparatus according to an embodiment of the present invention. Referring to FIG.

As shown in the figure, the first shielding room 100 is formed in a hexahedron shape in which six panels are assembled. Accordingly, the front panel, the right side panel, and the flat panel are shown in Fig.

The front panel is provided with an operation unit 110 as described above.

The operation unit 110 includes a switch unit for turning on / off the power supply of the dual radiation shielding apparatus, a notification unit for informing the on-state or off-state of the power supply, And a display unit 115 for displaying whether the X-ray is irradiated or not.

The front panel and the flat panel are provided with door portions 120, respectively.

The door part 121 provided on the front panel is mainly used for drawing or pulling out a subject and the door part 125 provided on the flat panel is used for the electronic equipment located inside the first screening room 100 It is used for inspection or repair purposes.

That is, since the door unit 120 is provided in the dual radiation shielding apparatus and the double shielding structure is provided, the shielding efficiency can be increased, and even when the test equipment is in operation, The repair / maintenance efficiency and the working efficiency can be improved.

Meanwhile, the panels constituting the first shielding room 100 may be connected to each other through the connecting member 150. The connecting member 150 may be largely divided into a coupling member 151 for allowing adjacent panels or adjacent members to be bolted-nut or riveted, and a frame member 155 for fitting adjacent panels.

The coupling member 151 will be described in detail later with reference to FIGS. 8 and 9. FIG.

3 is a rear perspective view of the first shielding room 100 of the dual radiation shielding apparatus according to an embodiment of the present invention.

In Fig. 3, a rear panel, a right side panel and a flat panel are shown.

A heat radiating fan is mounted on the rear panel, or the detec ted result is transmitted or received from the detec- tor 400 in the opening 130 where the warmth discharged by the internal heat radiating fan can be discharged and the double- An interface unit 140 is provided.

4 is a front perspective view of the second shielding room 200 of the dual radiation shielding apparatus according to an embodiment of the present invention.

The second shielding room 200 is formed in a size and shape that can be inserted into the first shielding room 100. The second shielding room 200 has a hexahedron shape in which six panels are assembled in the same manner as the second shielding room 200 . Accordingly, the front panel, the right side panel and the flat panel are shown in Fig.

A door 220 is provided on the front panel of the second shielding room 200 at a position corresponding to the door 121 provided on the front panel of the first shielding room 100. This is mainly used for introducing or withdrawing a subject as described above.

In the middle region of the flat panel of the second shielding room 200, an opening 210 through which X-rays can be irradiated is provided. Although not shown in FIG. 4, the X-ray generating unit 300 is located at the upper end of the opening 210 of the outer region of the second shielding room 200 inside the first shielding room 100. The X-ray generating unit 300 irradiates X-rays into the second shielding room 200 through the opening 210.

In addition, a space in which various electronic equipments can be arranged is provided in the right side area of the flat panel of the second shielding room 200. 4, the height of the second shielding room 200 is lower than the height of the first shielding room 100, and the height of the second shielding room 200 is not limited to the height of the first shielding room 100, .

In addition, since the second shielding room 200 is also formed with the plurality of panels assembled, a connecting member 240 for coupling these panels is required. Such a connecting member 240 is formed by the above- And serves the same function as the coupling member 151 of the room 100.

Since the connecting member 240 is substantially the same as the engaging member 151, it will be described in detail later with reference to FIGS. 8 and 9. FIG.

5 is a rear perspective view of the second shielding room 200 of the dual radiation shielding apparatus according to an embodiment of the present invention.

In Fig. 5, a rear panel, a right side panel and a flat panel are shown.

6 is a view showing a state in which the internal electronic devices are arranged in a state where the second shielding room 200 is inserted into the first shielding room 100. [

The electronic equipments can be divided into electronic equipments provided outside the second shielding room 200 and electronic equipments provided inside the second shielding room 200 as described above. And the like.

The electronic equipment arranged in the middle area is the above-described X-ray generating unit 300, and the electronic equipment arranged in the right area is the above-described driving unit 600. [

Since the driving unit 600 including the X-ray generating unit 300 and the various circuit configurations, which are important in the X-ray inspection apparatus, is installed outside the second shielding room 200, 200 can perform the inspection and repair of the X-ray generating unit 300 and the driving unit 600 without damaging the radiation even during the operation of the dual radiation shielding apparatus since the shielding function is primarily performed.

7 is a view showing an inner appearance of the second shielding room 200. As shown in FIG.

7, the detec- ting unit 400 and the moving unit 500 are sequentially stacked on the lower panel of the second shielding room 200. As shown in Fig. As described above, the detec- tion unit 400 irradiates the inspected object at the lowermost end of the inner area of the second shielding room 200, and the moving unit 500 moves horizontally to the left and right to check the inspected object So that it proceeds in multiple angles.

8 is a view showing a connecting member 240 according to an embodiment of the present invention. The coupling member 151 is also a kind of coupling member 150 and is similar in function and structure to the coupling member 240 to be described with reference to FIG. ) "Will be collectively referred to.

The connecting members 150 and 240 pass through the openings provided in the first panels of the first shielding room 100 or the second panels of the second shielding room 200 so that the first panels or the second panels So that they can be assembled and joined together.

The connecting members 150 and 240 may be divided into a head part 241 and a tail part 242. [

The connecting members 150 and 240 are configured to allow the head portion 241 to face the exterior of the dual radiation shield and the tail portion 242 to penetrate the openings to face the interior of the dual radiation shield, The head portions 241 of the connecting members 150 and 240 are surface treated with lead to prevent radiation from leaking through openings through which the connecting members 150 and 240 penetrate.

In particular, the surface of the head portion 241 is surface-treated with lead to not only the surface as shown but also the opposite surface (not shown), effectively shielding radiation from leaking.

FIG. 9 is a view showing a state in which the connecting members 150 and 240 interconnect the second panels of the second shielding room 200. FIG.

As described above, the second panels of the second shielding room 200 have a structure of steel-lead-steel. As such, it is possible to shield more effectively because it is not composed of steel but contains lead.

When the two panels (panels A and B) are overlapped as shown in the drawing, the connecting members 150 and 240 penetrate from the outside to the inside through the openings formed in the panels A and B, respectively, As shown in FIG.

At this time, the connecting members 150 and 240 penetrate from the outside to the inside because the head portion 241 of the connecting members 150 and 240 located outside is surface-treated with lead to shield radiation to be.

By using the assembled panels, the structures for double shielding can be separated from each other, thereby improving the mobility, transportability and productivity of the test equipment. In addition, the radiation which is liable to leak through an opening or the like generated by assembly can be easily and effectively shielded by connecting the panels using the lead-treated connection members 150 and 240. [

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limiting the scope of the invention as defined by the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

100: first shielding room 200: second shielding room
300: X-ray generator 400: Detecting unit
500: moving part 600: driving part

Claims (3)

An apparatus for shielding radiation generated during X-ray photography by moving a subject and performing X-ray imaging, the apparatus comprising:
A first shielding chamber formed by assembling first panels provided as a steel layer;
A second shielding chamber formed inside the first shielding chamber, the second shielding panel being assembled with second panels provided with a lead layer between the plurality of steel layers;
An X-ray generating unit positioned inside the first shielding room and outside the second shielding room to irradiate X-rays into the second shielding room through an opening provided in the upper part of the second shielding room;
A detecting unit positioned in the second shielding room and below the second shielding room for detecting a result of irradiation of the X-ray to the subject;
A moving unit positioned inside the second shielding room and positioned at an upper end of the detecting unit to horizontally move the inspected object in a state in which the inspected object is placed in a horizontal position; And
And a driving unit disposed inside the first shielding room and outside the second shielding room to drive the X-ray generating unit, the detecting unit, and the moving unit. The method according to claim 1,
The first panels or the second panels,
Are formed by mutually assembling via separate connecting members,
The connecting member includes:
The first panels or the second panels are assembled together by passing through the openings provided in the first panels or the second panels,
A head portion facing the exterior of the dual radiation shield and a tail portion extending through the openings toward the interior of the dual radiation shield,
Wherein the head portion of the connecting member is surface-treated with lead so that the radiation is not leaked through openings through which the connecting member penetrates. The method according to claim 1,
Wherein the first shielding room comprises:
And a door unit arranged to inspect the driving unit or draw out the subject even when the dual radiation shielding unit is in operation,
The second shielding room may include:
Wherein the radiation shielding unit is configured to shield the radiation primarily so that the inspection of the driving unit or the drawing-out of the inspected object can be performed through the door unit even when the dual radiation shielding apparatus is in operation.

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