KR102094839B1 - Radiation Shield Apparatus for Radiographic Penetration Testing - Google Patents

Abstract

The present invention relates to a radiation shielding device for a radiographic penetration test which shields radiation generated from a collimator when performing the radiation penetration test on a welding portion at the bottom of a hull to protect a professional tester as well as surrounding workers from the radiation and provide a safe working environment. The radiation shielding device for a radiographic penetration test comprises: a primary shielding device (100) consisting of a shielding box (110) in which a radiation source (400) and a collimator (300) are disposed, and an outer surface is wrapped with a shielding material, and a moving cart (130) moving the shielding box (110) to a working place and adjusting the height; and a secondary shielding device (200) positioned by a professional tester, and disposed at a position spaced apart from the primary shielding device (100).

Description

Radiation Shield Apparatus for Radiographic Penetration Testing

The present invention relates to a radiation shielding device for radiation transmission inspection, and more particularly, after welding a lower portion of the hull, shields radiation generated from the collimator when performing a radiation transmission inspection on the welded area, thereby providing professional inspectors as well as peripheral workers. It relates to a radiation shielding device for radiation transmission inspection to protect against radiation and provide a safe working environment.

In general, a variety of welding is performed when manufacturing a ship, and non-destructive tests such as radiographic (Penetration) testing (RT inspection) are performed to inspect the welding quality of the welding area.

Specifically, the RT inspection is performed on the cross-welded portion located on the bottom shell of the ship, and the RT inspection environment for the bottom shell is a collimeter, which is an irradiation that irradiates radiation to the welding area, and radiation. It is divided into the first zone where the main body (or safety box) where the radiation source moving toward the collimator is stored and the second zone where the inspector is located.

Since the radiation source (radiation source) has a risk of exposure from the moment of exposure, a safe working environment that can shield the radiation should be created during RT inspection. Those exposed to the risk of exposure during RT examinations can be divided into professional examiners who are exposed to radiation for a long time wearing radiation protective clothing, and workers who do not wear protective clothing but are exposed to radiation only for a short time while walking around the examination room. Shielding radiation is very important because it affects the human body.

When performing RT inspection, a simple support is installed on the bottom panel using a magnet, and a collimator that irradiates radiation is fixed to the simple support. In addition, a professional inspector moves the radiation source from the main body to the collimator using the operation handle in the second zone, so that the radiation irradiated from the collimator penetrates the welding area and the photosensitive film. At this time, the appropriate permeation time is determined according to the thickness of the steel material forming the bottom plate, and after the appropriate permeation time, the test is performed according to the same procedure by moving to another area.

In general, a professional inspector repeats the work of installing the collimator on the simple support of the welding area while carrying the body where the collimator and the radiation source are stored, and feels the workload in the process. Therefore, some professional inspectors are aware of the dangers of radiation, but often do not properly follow the safety rules to shorten the working time or reduce the workload, which leads to death in severe cases due to radiation exposure.

So, in the case of RT inspection, safety equipment is needed to prevent exposure by professional inspectors.It is only to require attention from professional inspectors, and there is only radiation protective clothing as equipment that can directly secure safety, resulting in accidents caused by radiation exposure. There is a problem that it is difficult to prevent the occurrence.

As a result of investigating prior art related to the present invention, a number of patent documents have been searched, and some of them are as follows.

Patent Document 1, the main shielding body made of a lead plate of a triple structure with a lead plate in the center of the inside formed in a funnel shape so as to surround the radiation projection path between the radiation device and the X-ray film and coated on both sides with a steel plate, the radiation device In the circumference adjacent to the projection window, the outer surface of the lead plate is formed of a double-layered lead plate coated with a steel plate, and it is made of a high radiation absorption coefficient, and includes an upper secondary shield formed with an opening on one side. , It discloses a stand of a portable radiation device to minimize the radiation dose to the outside to minimize the exposure dose.

Patent documents 2 to 4 are filed by the same person, among them, Patent document 2, the main body having a path through which the radioactive material moves; An operation unit that controls the withdrawal or intake of radioactive material by moving the radioactive material along the path; A sensing unit that detects a user's exposure; An analysis unit that compares the amount of exposure detected by the detection unit with a threshold value; And a control unit that controls a manipulation unit when the detected exposure amount is greater than or equal to a threshold value so that radioactive substances are introduced into the body, and a radiographic inspection system including the same.

Patent Document 3, a plurality of radiographic examination equipment that is installed in a predetermined space where radiation examination is required to emit radiation by user manipulation; At least one shield that is provided to be spaced apart from the radiation inspection equipment installed for radiography and protects the user from radiation; A shielding confirmation unit detecting that a user is placed in a position protected from radiation by the shielding body; And when the protection of the user by the shield is detected by the shielding confirmation unit, it discloses a radiation inspection system including a server for remotely controlling the radiation inspection equipment and a radiation inspection system including the same.

Patent document 4, the main body having a path for the radiation material to move therein; An operation unit that controls the withdrawal or intake of radioactive material by moving the radioactive material along the path; A remote operation unit that remotely controls the operation unit; And a shield that protects the user from radiation, and the remote manipulation unit discloses a radiation inspection apparatus and a radiation inspection system including the same, by controlling the manipulation unit according to whether or not the shield is coupled to implement movement of radioactive materials. .

Patent Document 1: KR20-1999-0028099 U Patent Document 2: KR10-2016-0094468 A Patent Document 3: KR10-2016-0094470 A Patent Document 4: KR10-2016-0098546 A

The present invention has been devised to solve the above-mentioned problems of the prior art, and radiation shielding that provides a safe working environment to protect both the professional inspector as well as the surrounding workers walking around the inspection site from radiation generated during RT inspection. The purpose is to provide a device.

The present invention for achieving the above object, a radiation source and a collimator is disposed and the outer surface is covered with a shielding box, a primary shielding device consisting of a moving cart to move the shielding box to a working place and adjust the height. ; A secondary screening device positioned at a position spaced apart from the primary screening device, where a professional inspector is located; It characterized in that it comprises a.

In addition, according to the radiation shielding device for radiographic inspection of the present invention, the shielding box is provided with a rectangular bottom plate, a vertical frame installed vertically at each of the four corners of the bottom plate, and a vertically installed middle portion of the bottom plate. A guide frame, both ends of which are respectively coupled to the guide frame and move up and down along the guide frame, a collimator fixture installed with a collimator and movably installed on the lift frame, a vertical frame and an upper portion of the guide frame It characterized in that it comprises a top frame connecting the, and a shielding film surrounding the outside of the cube formed by the frames so as to prevent radiation emitted from the collimator from being exposed to the outside.

In addition, according to the radiation shielding device for radiation transmission inspection of the present invention, the shielding film is formed to be detachably coupled to one or more lead blankets, and is installed to surround the outside of the cube formed by the frames more than once, and secondary It is characterized in that a lead blanket is additionally installed on the side where the shielding device is located.

In addition, according to the radiation shielding device for radiation transmission inspection of the present invention, it is characterized in that at least one lifting ring is provided on the bottom plate.

In addition, according to the radiation shielding device for radiation transmission inspection of the present invention, the intermediate support frame connecting the middle portion of the vertical frame and the guide frame, and the intermediate support frame, the lamp installed in the intermediate support frame located in the front and rear in the longitudinal direction, respectively Characterized in that it further comprises.

In addition, according to the radiation shielding device for radiation transmission inspection of the present invention, the guide frame is characterized in that the graduation portion is provided so as to check the position of the lifting frame.

In addition, according to the radiation shielding device for radiation transmission inspection of the present invention, it is characterized in that the bumper for the impact relief made of an elastic material is attached to the upper frame.

In addition, according to the radiation shielding device for radiation transmission inspection of the present invention, a storage unit for storing protective equipment and tools is formed under the bottom plate, and the storage unit is provided with one or more doors.

In addition, according to the radiation shielding device for radiographic inspection of the present invention, the collimator fixture includes a fixture body movably installed on an elevating frame and having a seating portion formed on an upper side, and a pair of supports respectively provided on both sides of the seating portion. It is characterized by.

In addition, according to the radiation shielding device for radiation transmission inspection of the present invention, the mobile cart is provided in a X-shape provided on the upper portion of the bogie frame, the base plate for supporting the shielding box, and the bogie frame with wheels at the lower corners, respectively. It includes a lifting link for lifting the support plate, a handle provided on one side of the truck frame to move the truck frame, and a control box provided on the truck frame to control the lifting cylinder that expands or folds the lifting link. It is characterized by.

In addition, according to the radiation shielding device for radiation transmission inspection of the present invention, the mobile cart further includes auxiliary support means for preventing conduction by the weight of the shielding box, and the auxiliary support means are respectively provided at four corners of the bogie frame. It is characterized in that it comprises a rotatable auxiliary support frame and a wheel member rotatably installed at each end of the auxiliary support frame.

In addition, according to the radiation shielding device for radiation transmission inspection of the present invention, the secondary shielding device is a handle for controlling a radiation source in the shielding box and a work station where a professional worker is located, and one side of the work table to protect a professional inspector from radiation. It characterized in that it comprises a radiation shielding film installed on.

The radiation shielding device for radiation transmission inspection of the present invention is equipped with a secondary shielding device to protect a professional inspector, and a primary shielding device to block radiation emitted from a radiation source and a collimator. It has the effect of protecting the workers as well as the surrounding workers so that a safe working environment can be realized even during radiographic inspection.

In addition, a radiation source and a collimator acting as a radiation source are disposed in a shielding box surrounded by a shielding material, so that radiation can be fundamentally blocked.

In addition, as the lifting frame is provided in the shielding box and the collimator fixture is horizontally installed on the lifting frame, it is possible to control the radiation dose by adjusting the height and position of the collimator.

In addition, the collimator is firmly supported by the collimator fixture provided in the elevating frame to prevent the collimator from shaking during RT inspection, and also to prevent the inspection quality from being reduced due to the collimator shaking.

In addition, a lamp is provided in the shielding box to perform RT inspection even at night, and an lifting hook is provided to easily move the shielding box to the bottom of the ship dock.

In addition, radiation can be blocked by using a lead blanket as a shielding film, and an expert inspector can be protected from radioactive exposure by focusing and installing the lead blanket on the direction of the secondary shield where the expert inspector is located.

In addition, a storage unit is provided at the bottom of the shielding box to store protective equipment such as lead blankets and various tools, thereby improving the convenience of the inspector.

In addition, the mobile cart is provided with an auxiliary support means, so that the mobile cart does not move at a predetermined position, and also has an effect of preventing the mobile cart from being overturned by the heavy weight of the shield.

In addition, it is possible to move the moving cart manually, as well as to automatically move the moving cart by driving the wheel with an electric motor or an air motor.

In addition, the lifting link is provided on the mobile cart, so that the heavy weight shielding box can be easily moved up and down with a cylinder operated by electric or hydraulic pressure, thereby enabling the collimator to be easily approached to the inspection position.

In addition, a control box is provided, and it is possible to easily control the on / off of the lamp, the lifting and lowering of the shielding box, and the movement of the moving cart through the control buttons on the dedicated control panel of the control box.

In addition, a shock absorber is installed on the upper frame of the shielding box to prevent collision between the upper frame and the hull when lifting the shielding box for setting before RT inspection.

In addition, since the radiation shielding film is provided on the secondary shielding device, the radiation is double-blocked together with the shielding film provided on the shielding box, thereby minimizing the radiation exposure of professional inspectors.

1 is a conceptual diagram schematically showing a radiation shielding device for radiation transmission inspection according to the present invention.
Figure 2 is a block diagram showing a primary shield according to the present invention.
3 is an external perspective view (photo) of a primary shield according to the present invention.
Figure 4 is a perspective view (photo) showing the interior of the shielding box according to the present invention.
5 is an enlarged view (photo) of the shielding box according to the present invention.
Figure 6 is a reference diagram (photo) sequentially showing the installation position determination process of the collimator fixture according to the present invention.
7 is a perspective view (photo) showing a state when the primary shielding device according to the present invention is stopped.
Figure 8 is a reference diagram showing a state of lifting the shielding box in the primary shielding device according to the present invention (photo).

Hereinafter, a radiation shielding device for radiation transmission inspection according to an embodiment of the present invention will be described with reference to the accompanying drawings.

Radiation shielding device for radiation transmission inspection according to an embodiment, as shown in Figures 1 to 3, the radiation source 400 in the safety box is moved to the collimator 300 to protect the surrounding workers from radiation generated A primary shield device 100 for primary shielding; A secondary shield 200 that protects the professional examiner from radiation by being positioned at a position spaced apart from the primary shield 100 and the professional inspector; It is made including.

Inside the primary shielding device 100, a safety box and a collimator 300 in which a radiation source 400 is stored are disposed, and a shielding box 110 whose outer surface is covered with a shielding material, and a shielding box 110 as a work place. It is made of a moving cart 130 for moving and adjusting the height.

The secondary shielding device 200 is a handle 500 for controlling the radiation source 400 in the shielding box 110, a flat type work table 210 in which a professional worker is located, and a professional inspector from radiation. It includes a radiation shielding film 220 is installed on one side of the work table (210). Wheels may be provided at the bottom of the work table 210 for convenience of movement. The radiation shielding film 220 is made of a lead plate having a strong ductility, and to securely fix it, a grid-shaped bolt hole is punched, and a bolt is inserted into the bolt hole to fasten the nut to secure the radiation shielding film 220 to the work table 210. Can be fixed on.

4 and 5, the shielding box 110 has a rectangular bottom plate 111, a vertical frame 112 vertically installed at four corners of the bottom plate 111, and a bottom plate 111. ) The guide frame 113 vertically installed in the middle portion of the longitudinal direction, and both ends are respectively coupled to the guide frame 113, the lifting frame 114 and vertically moved along the guide frame 113, vertical frame 112 And the intermediate support frame 116 connecting the middle portion of the guide frame 113, and the intermediate support frame 116 of the longitudinal support front and rear lamps 117 are respectively installed on the intermediate support frame 116, The collimator 300 is installed and a collimator fixture 150 movably installed on the elevating frame 114 and an upper frame 115 connecting the vertical frame 112 and the upper part of the guide frame 113 and , Collie wrapped around the outside of the cube formed by the frames The radiation emitted from the emitter (300) comprises a shielding film 120 for shielding from exposure to the outside.

Accordingly, it is possible to illuminate the inside and the top of the shielding box 110 using the lamp 117, so that it is possible to perform RT work even at night.

The shielding film 120 is formed by being detachably coupled to one or more lead blankets 121, and should be installed to surround the outside of the cube formed by the frames one or more times. Particularly, it is more preferable that a lead blanket 121 is additionally installed on the side where the secondary shield 200 is located, so that a professional inspector located in the secondary shield 200 is not exposed to radiation. The lead blanket 121 for forming the shielding film 120 is formed in a predetermined standard, and is preferably used in connection with each other. Therefore, by forming a connection hole in the lead blanket 121 and then connecting to each other through the connection hole, the size of the shielding film 120 can be freely adjusted or the lead blanket 121 can be overlapped.

Meanwhile, one or more lifting rings 111 'are provided on the bottom plate 111 so that the shielding box 110 can be lifted up and easily put on the dock of the shipyard. In addition, the guide frame 113 is provided with a graduation portion 113 'to check the position of the lifting frame 114, so that the installation position of the collimator 300 can be precisely controlled. In addition, the shock absorber bumper 118 made of an elastic material is attached to the upper frame 115, and when the shielding box 110 is moved upward for RT inspection, the upper frame 115 and the hull of the shielding box 110 are hulled. It is possible to prevent collision with and damage to the frames constituting the shielding box 110.

In addition, the lower portion of the bottom plate 111, as shown in Figure 8, the protective device and the storage unit 140 for tool storage is formed, the storage unit 140 is provided with one or more doors 145 desirable. Accordingly, after the RT test is completed, it is possible to store various tools necessary for the RT test as well as protective equipment such as a lead blanket 121, thereby greatly improving the convenience of a professional tester.

FIG. 6 is a reference diagram (photo) sequentially showing a process of placing the collimator fixture 150 on which the collimator 300 is mounted directly under the welding portion of the inspection object, as shown, the collimator fixture 150 Is provided on the both sides of the fixing unit body 151, which is movably installed on the lifting frame 114 and has a seating portion 151 'formed on the upper side, and seating portions 151' for fixing the collimator 300. It includes a pair of support (153).

Here, reference numeral 152 is a flashlight insert cup for inserting the rear end portion of the flashlight 600 used to confirm that the collimator fixture 150 is placed in the correct position, after the installation position of the collimator fixture 150 is determined It is removed from the seating portion 151 '. In other words, the flashlight insertion cup 152 is stored separately, and immediately before the installation of the collimator 300, it is mounted on the seating portion of the collimator fixture 150 together with the flashlight 600 generating light to be irradiated to the weld. The position where the light of the flashlight 600 is vertically irradiated to the welding portion is an accurate installation position of the collimator fixture 150.

Therefore, by the collimator fixture 150, shaking of the collimator 300 during RT inspection is prevented, and degradation of inspection quality is also prevented.

In addition, the mobile cart 130, as shown in Figures 2 and 7, the bottom of each corner, the wheel frame 132 is provided with a bogie frame 131, and the support plate 133 for supporting the shield box 110, It is provided on the upper portion of the bogie frame 131 and is formed in an X-shape to provide an elevating link 134 for elevating the base plate 133 and a bogie frame 131 to move the bogie frame 131. It includes a handle 137 and a control box 135 provided on the bogie frame 131 so as to control the elevating cylinder that deploys or folds the elevating link 134.

The bogie frame 131 is provided with a motor for driving wheels, so that the mobile bogie 130 can be moved by power, and can also be manually moved using the handle 137.

Since the lead blanket 121 forming the shielding film 120 has a weight of approximately 14 kgf, the weight of the shielding box 110 on which the shielding film 120 is installed is inevitably increased. Accordingly, it is possible to elevate the shielding box 110 without exerting great force by deploying or folding the elevating link 134 using a cylinder operated by electricity or hydraulic pressure.

The mobile cart 130 is further provided with auxiliary support means 136 for preventing conduction by the weight of the shielding box 110, and the auxiliary support means 136 are rotated at four corners of the cart frame 131, respectively. It is preferable that the auxiliary support frame 136a is installed as possible, and the wheel members 136b are rotatably installed at the end portions of the auxiliary support frame 136a, respectively. The wheel member 136b is formed to have the same size as the wheel 132 installed on the bogie frame 131 to distribute the load acting on the mobile bogie 130 when driving. Then, after all of the auxiliary support frames 136a constituting the auxiliary support means 136 are deployed and the wheel directions of each wheel member 136b are different from each other, the auxiliary support means 136 acts as a kind of brake to move the vehicle ( 130) is fixed without moving.

As described above, although it has been described and illustrated in connection with an embodiment for illustrating the technical idea of the present invention, the present invention is not limited to the configuration and operation as described above, and deviates from the scope of the technical idea described in the claims. It will be understood by those skilled in the art that many changes and modifications to the present invention are possible without this. Accordingly, all such suitable changes and modifications and equivalents should be considered to be within the scope of the present invention.

100 ... primary shield
110 ... shield box
111 ... bottom plate
111 '... salvage collar
112 ... vertical frame
113 ... Guide frame
113 '...
114 ... lifting frame
115 ... top frame
116 ... middle support frame
117 ... lamp
118 ... shock absorber
120 ... shield
121 ...
130 ... mobile cart
131 ... bogie frame
132 ... wheel
133 ...
134 ... elevation link
135 ... control box
136 ... auxiliary support means
136a ... auxiliary support frame
136b ... without wheel
137 ... Handle
140 ... Storage
145 ... door
150 ... collimeter fixture
151 ... fixed body
151 '... seat
152 ... flashlight insert cup
153 ... support
200 ... 2nd shield
210 ... worktable
220 ... radiation shield
300 ... collimeter
400 ... radiation source (safety box where radiation source is stored)
500 ... handle
600 ... flashlight

Claims (12)

The radiation source 400 and the collimator 300 are disposed, and the outer surface is composed of a shielding box 110 wrapped with a shielding material, and a moving cart 130 for moving the shielding box 110 to a working place and adjusting height. Primary shield 100; And
A secondary screening device 200 positioned at a position spaced apart from the primary screening device 100 and positioned by a professional inspector;
As a radiation shielding device for radiation transmission inspection comprising a,
The shielding box 110 includes a bottom plate 111, a vertical frame 112 vertically installed at corners of the bottom plate 111, and a guide frame 113 vertically installed in the middle portion of the bottom plate 111 in the longitudinal direction. ), Both ends are respectively coupled to the guide frame 113, the lifting frame 114 is moved up and down along the guide frame 113, the collimator 300 is installed and is movably installed on the lifting frame 114 The collimator fixture 150, the upper frame 115 connecting the upper part of the vertical frame 112 and the guide frame 113, and the outer side of the cube formed by the frames, in the collimator 300 Radiation shielding device for radiation transmission, characterized in that it comprises a shielding film 120 to shield the radiation to be irradiated to the outside. The method according to claim 1,
The shielding film 120 is a radiation shielding device for radiation transmission inspection, characterized in that the at least one lead blanket 121 is detachably coupled. The method according to claim 2,
The shielding film 120 is installed to surround the outside of the cube formed by the frames at least once,
Radiation shielding device for radiation transmission inspection, characterized in that the secondary shielding device 200 is located, the lead blanket 121 is additionally installed. The method according to claim 1,
Lamps respectively installed on the intermediate support frame 116 that connects the intermediate portion of the vertical frame 112 and the guide frame 113, and the intermediate support frame 116 located in the longitudinal front and rear of the intermediate support frame 116, respectively. Radiation shielding device for radiation transmission, characterized in that it further comprises (117). The method according to claim 1,
Radiation shielding device for radiation transmission inspection, characterized in that the guide frame 113 is provided with a graduated portion (113 ') to check the position of the lifting frame 114. The method according to claim 1,
Radiation shield for radiation transmission inspection, characterized in that the bumper 118 for shock mitigation made of an elastic material is attached to the upper frame 115. The method according to claim 1,
A radiation shield for radiation transmission inspection, characterized in that a storage unit 140 for storing protective equipment and tools is formed under the bottom plate 111 and at least one door 145 is provided in the storage unit 140. . The method according to claim 1,
The collimator fixture 150 is movably installed on the elevating frame 114, and a pair of fastener bodies 151 having a seating portion 151 'formed on the upper side and a pair of each provided on both sides of the seating portion 151'. Radiation shield for radiation transmission examination, characterized in that it comprises a support (153). The method according to claim 1,
The mobile cart 130 is provided at the top of the cart frame 131, the support frame 133 for supporting the shielding box 110, and the cart frame 131 provided with wheels 132 at the lower corners, respectively. It is formed in the form and includes a lifting link 134 for elevating the support plate 133, and a control box 135 provided on the bogie frame 131 so as to control an elevating cylinder that deploys or folds the elevating link 134. Radiation shield for radiation transmission inspection, characterized in that. The method according to claim 9,
The moving cart 130 is further provided with auxiliary support means 136 for preventing conduction by the weight of the shielding box 110,
The auxiliary support means 136 are auxiliary support frames 136a that are rotatably installed at four corners of the bogie frame 131, and wheel members 136b that are respectively rotatably installed at the ends of the auxiliary support frame 136a. Radiation shielding device for radiation transmission test, characterized in that it comprises a. The method according to any one of claims 1 to 10,
The secondary shielding device 200 includes a handle 500 for controlling the radiation source 400 in the shielding box 110, a workbench 210 where a professional worker is located, and a workbench 210 to protect a professional inspector from radiation. Radiation shielding device for radiation transmission, characterized in that it comprises a radiation shielding film 220 is installed on one side. delete

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