KR101290755B1 - Radiation transmission inspection equipment - Google Patents

Abstract

PURPOSE: A radiation transmission inspecting device with a multi-locking structure is provided to prevent a radiation source from being discharged out of a container as a radiation source is fixed not to be moved when a connector is separated from a connection unit of the container. CONSTITUTION: A radiation transmission inspecting device with a multi-locking structure includes a container (110), a radiation source transmission pipe (200), a control tube (300), a remote controller, a second locking unit, and a third locking unit. The container shields and keeps a radiation source. The radiation transmission pipe is connected to a forward hole formed on the front surface of the container and guides the radiation source to an object to be inspected. The control tube is connected to a connection unit arranged on the rear surface of the container with a connector (310), and a wire moving the radiation source is embedded inside. The connection unit faces the radiation source transmission pipe. The remote controller is arranged on a base and pushes or pulls the wire of the control tube by manipulating a handle. The second locking unit is installed on the rear surface of the container and fixes the radiation source arranged inside the container not to be moved. The third locking unit is arranged on the front surface of the container and controls the operation of the second locking unit.

Description

Radiation Transmission Inspection Equipment having a multi-lock structure {Radiation Transmission Inspection Equipment}

The present invention relates to a radiographic inspection apparatus having a multi-locking structure, and more particularly, a connector for connecting a container with a built-in radiation source and a control tube so as not to be released without the user's manipulation of the push button and the push lever. In addition, by providing a plurality of locking parts in the container so that the user can sequentially assemble or separate the control tube or source transmission tube in the container, the radiation source is leaked to the outside of the container during the assembly or separation process of the control tube or source transmission tube The present invention relates to a radiographic inspection apparatus having a multiple locking structure that can be prevented.

Nondestructive Testing is the determination of whether a product or material is defective internally or externally by physical or chemical methods. It is called nondestructive testing to verify that the product or material is not destroyed or deformed. Determination by deforming or modifying is called a fracture test.

Such non-destructive inspection is widely used throughout the industry, such as essential use of the internal defect inspection of the weldment and the internal inspection of the casting.

Such non-destructive tests include radiographic testing, ultrasonic testing, magnetic testing, and the like, in which radioisotopes such as iridium-192 are used in radioisotopes. This is to check the internal defect of the product by analyzing the blackness by taking a picture using gamma rays and then developing and printing it.

Non-destructive testing using such a radiation source does not require a power source and can be used regardless of time and place, so usage is steadily increasing.

The prior art of such a device for non-destructive testing is a "nude-type source transmission pipe for radiation safety" of Korean Patent Registration No. 10-0584256 (2006.05.22).

The radiographic inspection apparatus according to the prior art as described above, as shown in Figure 1, the remote controller 16 is automatically controlled, and a control tube for applying a controlled force to the radiation source connected to the remote controller 16 ( 14), a container 12 for shielding and storing the radiation source, and a nude source transmission pipe 10 for transporting the radiation source by the remote controller 16 to inspect the subject.

At this time, the control tube 14 and the container 12 are connected by a connector, the connector is provided at the front end of the control tube 14 and the internal thread is formed in the inner diameter. In addition, the back of the container 12 is formed with a connecting portion for connecting the connector of the control tube 14, the connecting portion has a structure in which a male screw is formed in the outer diameter is screwed and connected to the connector.

However, in the radiological inspection apparatus according to the prior art as described above, the connector of the control tube 14 connected to the rear surface of the container 12 to guide the radiation source located inside the container 12 to the front of the container 12 There is a risk of unauthorized separation from the connecting portion of the control tube 14 requires much attention to the assembly and release process of the connector of the control tube 14 and the connection of the container 12.

That is, since the connector of the control tube 14 and the connection portion of the container 12 are screwed by rotation, the connector of the control tube 10 is connected to the container 12 so as to surround the connection portion of the container 12. After the connector is inserted into the connector, the connector of the control tube 14 is rotated in the tightening direction to be coupled, and conversely, by rotating the connector in the release direction, the connector can be separated from the connector.

However, the control tube 14 and the container 12 are separated when the connector is rotated in the unwinding direction during the inspection or during the transport of the radiographic inspection apparatus, and thus the control tube 14 and the container 12 are unauthorized. In case of separation, there is a risk that the wire that slides the radiation source in the source transmission pipe may be disconnected, so that the radiation source may not be located inside the container 12 and the radiation is leaked to the outside. There is a problem that is exposed.

In addition, in the process of connecting or disconnecting the radiation source located inside the container 12 with the connector of the control tube 14, the radiation source is discharged to the outside of the container 12 by randomly moving forward or backward of the container 12. There is a concern.

That is, the radiation source is formed on the rear surface of the container 12 when the radiation source moves without being located at the proper place inside the container 12 while connecting or disconnecting the connector of the control tube 14 with the connection portion of the container 12. The outflow hole or the exit hole formed in the front of the container 12 may be leaked to the outside, when the radiation source is leaked to the outside of the container 12 there is a risk that the user is exposed to radiation.

In addition, in the process of connecting or separating the control tube 14 and the source transmission tube 10 to the back and front of the container 12, respectively, the control tube 14 and the source transmission tube 10 in a predetermined order. There is a risk of working arbitrarily without assembling or disassembling, and if the user does not work in the order of assembly or disassembly in this way, the radiation source may leak out of the container 12.

Republic of Korea Patent Registration No. 10-0584256 (May 22, 2006), "Nude sailor transmission pipe for radiation safety"

The present invention is to solve the above problems, to prevent the connector provided at the tip of the control tube connected to the container to move in the unwinding direction arbitrarily to move the radiation source located inside the container, and to separate operation It is an object of the present invention to provide a radiographic inspection apparatus having a multi-locking structure that can prevent the exposure of the user due to the leakage of the radiation source is located inside the container unless there is.

In addition, by allowing the user to sequentially assemble or separate the control tube or source transmission tube in the container, to provide a radiographic inspection apparatus having a multi-lock structure that can prevent the radiation source from leaking out of the container. There is this.

According to the technical idea of the present invention for achieving the above object, a container for shielding and storing the radiation source, the source transmission pipe connected to the exit hole formed in the front of the container to guide the radiation source to the test object, and the source A control tube which is connected by a connector and a connector provided on the rear surface of the container facing the transmission tube and has a wire for moving a radiation source therein, and is provided at the base of the control tube to push the wire of the control tube by a handle operation; A pulling remote controller, a second locking part installed at the rear of the container to fix the radiation source located inside the container without moving according to a user's pressing operation, and a second locking part provided at the front of the container to control the operation of the second locking part. Having a multi-lock structure, characterized in that it comprises a three locking portion It is achieved by the oblique transmission inspection apparatus.

Here, the second locking portion includes a first pressing lever which is installed on the back of the container and is elevated, the first pressing lever is fixed to the back of the container and protrudes to the upper portion of the back cover formed with a connection by the user A first part formed in a pressing part to be pressed, a fixing hole formed at a lower part of the pressing part, into which a rear surface of the pressing button is inserted, and a radiation source corresponding to a lower part of the fixing hole, which is inserted into the container; It is preferable to include a holder part.

In addition, the radiation source is formed with a convex portion having a diameter larger than the diameter of the radiation source, the first holder portion is a first communication hole having a diameter larger than the convex portion of the radiation source and a first settle having a diameter smaller than the convex portion of the radiation source Preferably, a hole is formed.

The second locking part may include a supporter installed between the rear surface and the rear cover of the container, and the supporter may have a lifting area configured to guide the lifting of the first push lever on a surface facing the rear surface of the container. .

The third locking part includes a second pressing lever which is installed at the front of the container and moves up and down, wherein the second pressing lever protrudes upward from the front of the container and is pressed by the user, and the pressing part is pressed. Binding holes formed in the first push lever that is guided through the slot formed in the lower portion of the lower portion and the tip is guided to the surface of the second push lever to move linearly, and installed on the back of the container in accordance with the linear movement of the guide bar It is preferable to include a binding pin that is inserted into or separated from and a binding wire connecting the binding pin and the guide bar.

In addition, it is preferable that the second push lever has an inclined surface formed at a portion where the guide bar penetrates, and the upper thickness of the second push lever is formed to be thicker than the lower thickness of the second push lever based on the inclined surface. .

In addition, the third locking portion is elastically supported on the front of the container and the release button and the release button having a multi-step shape having a diameter of the tip protruding toward the front of the container is smaller than the diameter of the base end is penetrated and the second push lever It is preferred to include a second holder portion formed between the pressing portion and the slot.

The second holder may have a second communication hole having a diameter larger than the base diameter of the release button and a second settling hole formed at a lower portion in connection with the second communication hole and having a diameter smaller than the base diameter of the release button. It is preferable to include.

In addition, the binding pin is preferably elastically supported on the back surface of the container so that the base end toward the binding hole of the first push lever.

According to the radiographic inspection apparatus having a multi-locking structure according to the present invention, the connector and the connecting portion are not separated even if an external force is applied to rotate the connector in the release direction unless the user pushes the button and the first push lever. When the connector is separated from the connection portion of the container, the radiation source is fixed to prevent movement of the radiation source to the outside of the container, thereby preventing the user from being exposed to radiation.

In addition, since the release button, the second push lever, and the first push lever are interlocked, the user can sequentially assemble or separate the control tube or the source transmission tube to the container. The outflow of the container can be prevented.

1 is a schematic view showing a radiographic inspection apparatus according to the prior art.
2 is a perspective view showing a radiographic inspection apparatus having a multiple locking structure according to the present invention.
3 is an exploded perspective view showing a first locking portion and a second locking portion of a radiographic inspection apparatus having a multiple locking structure according to the present invention.
4 is an exploded perspective view of the first locking portion and the second locking portion of the radiographic inspection apparatus having the multiple locking structure according to the present invention as viewed from below.
5 is an exploded perspective view showing a third locking part of the radiographic inspection apparatus having a multiple locking structure according to the present invention.
6 and 7 are a cross-sectional view and a perspective view showing a third locking part of the radiographic inspection apparatus having a multiple locking structure according to the present invention.
8 is a cross-sectional view showing the locked state of the first locking portion and the state of the second locking portion of the radiographic inspection apparatus having a multiple locking structure according to the present invention.
FIG. 9 is a perspective view illustrating a stopper protruding through a through hole of a rear cover according to a locked state of the first locking part of FIG. 8.
10 is a cross-sectional view illustrating a release state of a first locking portion and a second locking portion and a third locking portion of the radiographic inspection apparatus having a multiple locking structure according to the present invention.
FIG. 11 is a perspective view illustrating a stopper introduced into a through hole of a rear cover according to a release state of the first locking unit of FIG. 10.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor may properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a perspective view showing a radiographic inspection apparatus having a multi-locking structure according to the present invention, Figure 3 is an exploded perspective view showing a radiographic inspection apparatus having a multi-locking structure according to the present invention, Figure 4 is An exploded perspective view of a radiographic inspection apparatus having a multiple locking structure viewed from below.

Referring to the drawings, the radiographic inspection apparatus having a multi-locking structure according to the present invention is connected to the container 110 for shielding and storing the radiation source, and the exit hole (not shown) formed in the front of the container 110 And connected to the source transmission pipe 200 for guiding the radiation source 100 to the inspected object, and the connection portion 128 and the connector 310 provided on the rear surface of the container 110 facing the source transmission pipe 200. A control tube 300 having a wire for moving the radiation source 100 therein and a remote controller provided at the base of the control tube 300 to push or pull the wire of the control tube 300 by a handle operation (not shown). The second locking unit 140 and the container 110 installed on the back of the container 110 to fix the radiation source 100 located inside the container 110 without moving according to a user's pressing operation. Laid on the front of Air consists of a third locking portion 150 to regulate the operation of the second locking portion 140.

In other words, the container 110 is for shielding and storing the radiation source 100. As shown in the drawing, the container 110 has a shape of a hollow rectangular box having an open front and a rear surface and a radiation source 100 therein. A shielding part 104 is installed to receive the handle, and a handle 112 is formed on an upper surface of the container 110 so that an operator can easily carry it.

In addition, the front cover 106 and the rear cover 108 are installed on one hollow side and the other side of the container 110 to shield the inside of the container 110. Particularly, the front cover 106 and the rear cover 108 are formed with an exit hole and an introduction hole 108a, respectively, so that the radiation source 100 advances forward of the container 110 through the exit hole. The wire of the control tube 300 is introduced through the hole 108a to move the radiation source 100 located inside the container 110 to the exit hole.

Accordingly, the source transmission pipe 200 for guiding the radiation source 100 to the test object is connected to the exit hole of the front cover 106 installed at the front of the container 110, and corresponds to the rear surface of the container 110. A control tube 300 having a wire for moving the radiation source 100 is connected to the inlet hole 108a of the rear cover 108, and the control tube 300 is proximal to the control tube 300 by a handle operation. The remote controller that pushes or pulls the wire is connected.

On the other hand, the rear cover 108 is installed on the rear surface of the container 110 as described above, so that the inlet hole 108a of the rear cover 108 and the connector 310 of the control tube 300 is connected to the rear cover 108. The rear cover 108 is provided with a rear cover 122, and when the connector 310 is installed on the rear surface of the container 110, the first locking part 120 is installed inside the rear cover 122. Intermittent rotation of the 310 in the disengaging direction prevents the connector 310 from being randomly released.

That is, the first locking part 120 is largely a rear cover 122 installed in the rear cover 108 of the container 110 and a ratchet 312 formed in the connector 310 of the control tube 300. The stopper 124 is provided between the rear cover 122 and the rear cover 108 and a push button 126 for pressing and operating the stopper 124.

In other words, the rear cover 122 is fixed to the rear surface of the container 110 and a connection portion 128 protruding to the rear of the container 110 is formed to be connected to the connector 310 of the control tube 300. In this case, a male screw is formed at an outer diameter of the connecting portion 128, and the male screw is screwed with a female screw formed at an inner diameter of the connector 310 of the control tube 300.

In particular, the connector 310 provided in the control tube 300 is installed so that the connector 310 can rotate in the release direction or the tightening direction with respect to the control tube 300, and the connector 310 of the control tube 300. When the connector is connected to the connector 128, the connector 310 is fastened to the connector 128 as the connector 310 rotates in the tightening direction about the control tube 300, and conversely, the connector 310 is released. The connector 310 is released from the connecting portion 128 as it rotates in the direction.

The rear cover 122 is fixed to one side of the rear cover 108 as shown in the drawing, and the rear cover 122 protrudes toward the rear of the container 110 to be screwed with the connector 310. The connecting portion 128 is formed, and the assembly hole 122a is installed to the push button 126 to the upper portion of the connecting portion 128.

In addition, a through hole 122b through which the end of the stopper 124 protrudes is formed between the connection portion 128 and the assembly hole 122a, so that the end 124a of the stopper 124 protrudes through the through hole 122b. ) Is engaged with the ratchet 312 of the connector 310 coupled with the connection (128).

That is, a ratchet 312 is formed on one surface of the connector 310 facing the connection portion 128 of the rear cover 122, and the ratchet 312 protrudes through the rear cover 122 described below. Is engaged with the tooth tip 124a of the stopper 124.

On the other hand, the stopper 124 is formed with a tooth tip 124a protruding to the rear of the container 110 through the through hole 122b of the rear cover 122 as described above, the body integrally with the tooth tip 124a 124b is positioned inside the rear cover 122. At this time, a first elastic member 121 is provided between the body 124b of the stopper 124 and the rear cover 108 to exert an elastic restoring force so that the stopper 124 is always pushed to the rear of the container 110. Is given.

In addition, when the stopper 124 is installed inside the rear cover 122, the stopper 124 is disposed inside the rear cover 122 facing the rear cover 108 to secure the straightness of the stopper 124. A stopper mounting hole 108b for guiding) is formed.

In addition, the upper portion of the body 124b of the stopper 124 is formed with a connecting projection 124c connected to the push button 126 described below, when the push button 126 is pressed by the user push button The stopper 124 can move with the movement of 126.

That is, the push button 126 has a substantially cylindrical shape as shown in the drawing and is installed in the assembly hole 122a of the rear cover 122. In addition, an insertion groove 126a through which the connection protrusion 124c of the stopper 124 is inserted is formed at the lower portion of the push button 126 so that the push button 126 is pressed by the user to operate the push button 126. The stopper 124 is moved toward the rear cover 108 at the same time as it moves toward the rear cover 108.

In addition, when installed in the push button 126, the push button 126 is guided inside the rear cover 122 facing the rear cover 108 so as to secure the straightness of the push button 126. A button mounting hole 108c is formed, and a second elastic member 123 is provided between the push button 126 and the rear cover 108 to exert an elastic restoring force so that the push button 126 is always placed in the container 110. Is pushed to the rear.

At this time, the ratchet 312 formed on one surface of the connector 310 has a tooth is formed in one direction when the connector 310 is rotated in the tightening direction in engagement with the teeth 124a of the stopper 124 ratchet 312 This rotation causes the stopper 124 to move toward the rear cover 108.

On the contrary, if the connector 310 rotates in the release direction while the ratchet 312 and the stopper 124 are engaged, the ratchet 312 is caught by the stopper 124 to prevent the connector 310 from rotating in the release direction. It is possible to prevent the control tube 300 from being separated from the container 110.

On the other hand, in connection with the first locking unit 120 is provided a second locking unit 140 for fixing the radiation source 100 located inside the container 110 is not moved, the second locking unit 140 Is preferably installed between the rear cover 122 and the rear cover 108.

In other words, the second locking part 140 is largely composed of a first push lever 142 and a supporter 144 for guiding the lifting of the first push lever 142. As shown in FIGS. 3 and 4, the first push lever 142 protrudes to the upper portion of the rear cover 122 to be pressed by the user, and the press portion 142a of the press portion 142a. It is formed at the bottom and installed in the fixing hole 142b into which the rear surface of the push button 126 is inserted and the inlet hole 108a of the container 110 into which the radiation source 100 corresponding to the lower portion of the fixing hole 142b enters and exits. And the first holder part 142c which regulates the entrance and exit of the radiation source 100.

That is, the pressing portion 142a has a shape of a bar having a predetermined length and thickness, and an upper end thereof is exposed to the upper portion of the rear cover 122 so as to be pressed by a user, and the pressing portion 142a of A fixing hole 142b into which the fitting protrusion 126b formed on the rear surface of the push button 126 is inserted is formed.

In addition, a first holder portion 142c that is coupled to the radiation source 100 is formed below the fixing hole 142b, and the first holder portion 142c includes the first communication hole 142c-1 and the first portion. The settling hole 142c-2 is connected to fix the radiation source 100 to the first settling hole 142c-2 so as not to move or to move the radiation source 100 through the first communication hole 142c-1. .

To this end, the radiation source 100 is formed with a convex portion 100a having a diameter larger than the diameter of the radiation source, and the first communication hole 142c-1 of the first holder portion 142c is connected to the radiation source 100. It is formed to have a diameter larger than the diameter of the formed convex portion 100a so that the convex portion 100a of the radiation source 100 moves linearly through the first communication hole 142c-1.

In addition, the first settling hole 142c-2 of the first holder part 142c is formed to have a diameter smaller than the diameter of the convex part 100a formed in the radiation source 100 so that the convex part 100a of the radiation source 100 is provided. ) Is caught in the first settling hole 142c-2, thereby limiting linear movement.

Accordingly, when the first push lever 142 is lowered so that the first communication hole 142c-1 and the radiation source 100 have the same axis, the convex portion 100a and the first portion of the radiation source 100 are lowered. The first communication hole 142c-1 of the holder portion 142c has the same axis so that the radiation source 100 can move linearly in or out of the container 110 through the first communication hole 142c-1. do.

On the contrary, when the first push lever 142 is raised upward, the convex portion 100a of the radiation source 100 and the first settling hole 142c-2 of the first holder portion 142c are the same. It has an axis so that the convex portion 100a of the radiation source 100 is held in the first settling hole 142c-2 to fix the radiation source 100 in a stationary manner.

As such, when the first push lever 142 is lifted between the rear cover 122 and the rear cover 108, the first push lever 142 may secure the straightness of the container 110. The supporter 144 is installed between the rear cover 108 and the rear cover 122.

At this time, as shown in FIG. 4, the supporter 144 has a locking jaw 144a formed on a surface facing the rear cover 108, and a first push lever 142 is formed between the locking jaws 144a. An elevating area 144b having an upper opening to be elevated is formed, and the supporter 144 is firmly fixed to the rear cover 108 by screwing.

In addition, between the rear cover 122 and the rear cover 108 corresponding to the lower portion of the supporter 144 is provided with a locking member 146 for limiting the lifting of the first push lever 142, the locking member ( As shown in FIG. 4, the storage space 146a is formed on the rear surface of the locking member 146, that is, the surface facing the rear cover 108, in which the lower portion of the first push lever 142 is accommodated. The locking member 146 is firmly fixed to the rear cover 108 by screwing.

In this case, a locking accommodating groove 146b having a step is formed in the accommodation space 146a, and a locking piece 142d is disposed at a lower side of the first push lever 142 in correspondence with the locking accommodating groove 146b. The locking piece 142d of the first pressing lever 142 is locked by the locking receiving groove 146b when the lower portion of the first pressing lever 142 is stored in the storage space 146a of the locking member 146. Located at to limit the rise and fall of the first push lever 142.

Therefore, the connector 310 of the control tube 300 is formed by the supporter 144 and the locking member 146 for guiding the lifting and lowering of the first push lever 142 and the first push lever 142 as described above. When separated from the connection portion 128 of the 110, the movement of the radiation source 100 is fixed so that the radiation source 100 does not leak to the outside.

On the other hand, the front of the container 110 is provided with a third locking portion 150 is to interrupt the operation of the second locking portion 140. In this case, the third locking part 150 includes a second push lever 152, so that the first push lever 142 installed on the rear surface of the container 110 as the second push lever 152 moves up and down. Intermittent operation. This will be described based on FIGS. 5 to 7.

5 is an exploded perspective view showing a third locking part of the radiographic inspection apparatus having a multi-locking structure according to the present invention, and FIGS. 6 and 7 are third locking parts of the radiographic inspection apparatus having a multi-locking structure according to the present invention. It is sectional drawing and perspective view shown.

Referring to the drawings, the third locking part 150 includes a second push lever 152 installed at the front of the container 110, and the second push lever 152 is the pressing part 152a. And a guide bar 152b, a binding pin 152c, and a binding wire 152d.

In other words, the second push lever 152 is installed on one side corresponding to the front of the container 110 to face the first push lever 142 as shown in the figure. At this time, the front cover 106 is installed on one side of the container 110, and the front cover 127 having a fitting hole 127a communicating with the exit hole 106a on one side of the front cover 106 is screwed in. Is fixed by.

In addition, a second push lever 152 is installed between the front cover 106 and the front cover 127, and the second push lever 152 is pressed on one side of the front cover 106 facing the second push lever 152. A locking protrusion 106b for limiting the lifting of the lever 152 is formed, and protrusions 153 are formed on both sides of the second pressing lever 152 to correspond to the locking protrusion 106b, so that the second pressing lever ( The lifting and lowering of the second push lever 152 is restricted while guiding the lifting of the 152.

The opening 127b is formed on the front cover 127 so that the pressing part 152a of the second push lever 152 protrudes, and the connector 210 of the source transmission pipe 200 is inserted. The fitting hole 127a is formed.

As such, the second pressing lever 152 installed between the front cover 106 and the front cover 127 protrudes to the upper front of the container 110 and is pressed by the user to press the pressing portion 152a, A guide bar 152b which passes through a slot 154 formed under the pressing part 152a and is linearly moved by being guided to the surface of the second push lever 152 and a linear movement of the guide bar 152b. And a binding pin 152c fitted into or detached from the binding hole 143 formed in the first push lever 142 and a binding wire 152d connecting the binding pin 152c and the guide bar 152b. .

In other words, the pressing portion 152a has a shape in which the upper end of the second pressing lever 152 is bent horizontally so that the pressing portion 152a can be pressed by the user, and the pressing portion 152a has the front cover 127 described above. Protrudes upward through the opening 127b.

In addition, the guide bar 152b is formed to extend in a direction intersecting the axis of the guide body 152b-1 and the guide body 152b-1 having a substantially cylindrical shape, and a sliding portion 152b having a cylindrical shape. 2) the guide body 152b-1 passes through the slot 154 of the second push lever 152 such that the sliding part 152b-2 comes into contact with the surface of the second push lever 152. .

In this case, an inclined surface 156 is formed in the slot 154 of the second push lever 152 that is in contact with the sliding portion 152b-2, and the sliding portion 152b-2 is guided to the inclined surface 156. The guide body 152b-1 is moved horizontally and linearly.

To this end, the inclined surface 156 is formed in the slot 154 through which the guide bar 152b penetrates as described above, and the upper thickness of the second push lever 152 is based on the inclined surface 156 to have a second thickness. It is formed thicker than the lower thickness of the push lever 152.

Accordingly, when the second push lever 152 is lowered, the sliding portion 152b-2 of the guide bar 152b is guided to the inclined surface 156 to horizontally move the guide body 152b-1 forward. On the contrary, when the second push lever 152 is raised, the sliding part 152b-2 of the guide bar 152b is guided to the inclined surface 156 to horizontally move the guide body 152b-1.

As described above, the guide bar 152b, which is moved forward or backward as the second push lever 152 moves up and down, is bound by the binding hole 143 formed in the first push lever 142 by the binding wire 152d. 152c).

That is, the first pressing lever 142 is provided with a binding hole 143 through which the binding pin 152c is inserted or removed, and the binding hole 143 is installed through the rear cover 108. At this time, the rear cover 108 is formed with a boss 107 for guiding the movement of the binding pin 152c, the binding of the binding pin 152c inside the boss 107 of the first push lever 142. The fourth elastic member 109 is elastically supported to face the hole 143.

The binding pin 152c installed in the boss 107 of the rear cover 108 and moved toward the binding hole 143 of the first push lever 142 is the guide of the second push lever 152 described above. The first pressing by pulling the binding pin 152c as the guide bar 152b moves horizontally as the second push lever 152 moves up and down by connecting the bar 152b with the binding wire 152d. The binding pin 152c is separated from the binding hole 143 of the lever 142.

On the contrary, when the binding pin 152c is not pulled by the binding wire 152d, the binding pin 152c binds the first push lever 142 by the elastic restoring force exerted by the fourth elastic member 109. Being fitted in the hole 143, it is possible to control the lifting of the first push lever 142 in accordance with the operation of the second push lever 152.

On the other hand, the third locking portion 150 further includes a release button 158, the release button 158 is the third elastic member 159 is the front cover 106 so as to elastically support the front of the container 110. And a release button 158. In addition, the release button 158 extends so that the tip protrudes toward the front of the container 110, and the tip of the release button 158 protruding toward the front of the container 110 protrudes through the front cover 127. do.

At this time, the release button 158 has a multi-step shape in which the diameter of the tip protruding forward of the container 110 is smaller than the diameter of the base, and the tip of the release button 158 is the second push lever 152. Protrudes forward of the front cover 127 via a second holder portion 152e formed between the pressing portion 152a and the slot 154.

In addition, the second holder part 152e formed in the second push lever 152 through which the release button 158 penetrates includes a second communication hole 152e-1 and a second settling hole 152e-2. The second communication hole 152e-1 has a diameter larger than the proximal diameter of the release button 158, and the second settling hole 152e-2 has a diameter smaller than the proximal diameter of the release button 158. . The second communication hole 152e-1 is formed in the second push lever 152 so as to be positioned above the second settling hole 152e-2, and is formed as a lower portion of the second communication hole 152e-1. Two settling holes 152e-2 are formed and connected to the second communication holes 152e-1.

As described above, when the user pushes the release button 158 protruding forward of the front cover 127 while the release button 158 penetrates the second holder portion 152e, the proximal end of the release button 158. The rear cover 108 is moved toward.

As described above, when the proximal end of the release button 158 is moved toward the rear cover 108, the second settling hole 152e-2 is disposed on the distal end of the release button 158 having a smaller diameter than the proximal end of the release button 158. In this position, the second push lever 152 may be raised, and the lifting and lowering of the second push lever 152 may be interrupted as the release button 158 moves.

As described above, the operation of the release button 158 is not only operated by the user, but may be operated in connection with the connector 210 of the source transmission pipe 200 in some cases.

That is, a projection (not shown) is formed at the lower portion of the connector 210 of the source transmission pipe 200 to press and release the release button 158 so that the source transmission pipe is inserted into the fitting hole 127a of the front cover 127. When the connector 210 of the 200 is assembled, the protrusion presses the release button 158 so that the proximal end of the release button 158 moves toward the rear cover 108 so as to interlock with the assembly of the source transmission pipe 200. The release button 158 may operate and the second push lever 152 may be raised according to the operation of the release button 158.

Connection and release of the control tube 300 to the radiographic inspection apparatus having a multiple lock structure according to the present invention having the above configuration will be described with reference to FIGS. 8 to 11.

8 is a cross-sectional view illustrating a locked state of a first locking portion and a state of a second locking portion of a radiographic inspection apparatus having a multiple locking structure according to the present invention, and FIG. 9 is a stopper according to the locked state of FIG. 8. Is a perspective view illustrating a state in which the protrusion protrudes through the through hole of the rear cover.

Referring to the drawings, as shown in FIG. 8, the connector 310 of the control tube 300 is screwed and fixed to the connection portion 128 of the rear cover 122 installed on the rear surface of the container 110. In this case, the stopper 124 and the push button 126 are in a state protruding to the rear of the container 110 by the first elastic member 121 and the second elastic member 123.

That is, as shown in FIG. 9, the stopper 124 has a state where the tip 124a protrudes through the through hole 122b of the rear cover 122 by the elastic force of the first elastic member 121, The push button 126 also has a state of protruding through the assembling hole 122a of the rear cover 122 by the second elastic member 123.

In this state, when the connector 310 rotates in the release direction, the connector 310 is in the release direction because the end 124a of the stopper 124 and the ratchet 312 of the connector 310 are held. It will not rotate.

As such, when the connector 310 is not rotated in the release direction, the first push lever 142 is located at the lower portion thereof, so that the first communication hole 142c of the first holder part 142c of the first push lever 142 is disposed. -1) has the same axis as the convex portion 100a of the radiation source 100 so that the radiation source 100 can be linearly moved into or out of the container 110 through the first communication hole 142c-1. do.

On the contrary, when the connector 310 and the connection unit 128 are to be disconnected, as shown in FIGS. 10 and 11, the user presses the push button 126 to operate the end 124a of the stopper 124. Is spaced apart from the ratchet 312 of the connector 310. This will be described with reference to FIGS. 10 and 11. FIG.

FIG. 10 is a cross-sectional view illustrating a release state of a first locking unit and a state of a second locking unit and a third locking unit in the radiographic inspection apparatus having a multi-locking structure according to the present invention, and FIG. 11 is a first locking unit of FIG. 10. The stopper is a perspective view showing the state in which the stopper is led into the through hole of the rear cover according to the addition release state.

Referring to the drawings, as described above, when the connector 310 of the control tube 300 and the connecting portion 128 of the container 110 are connected, and the user wants to separate it, the user is placed on the front of the container 110. By pressing and releasing the installed release button 158 and the second push lever 152, the binding pin 152c which fixed the 1st push lever 142 is retracted.

As such, when the binding pin 152c is retracted, the user pushes up the first push lever 142 so that the fitting protrusion 126b of the push button 126 is fixed with the fixing hole 142b of the first push lever 142. It is located on the same axis.

As such, when the user presses the push button 126 while the fitting protrusion 126b of the push button 126 is positioned on the same axis as the fixing hole 142b of the first push lever 142, the push button 126 ), The fitting protrusion 126b is inserted into the fixing hole 142b of the first push lever 142.

However, even if the user presses the push button 126 without operating the second push lever and the first push lever 142, the push button 126 is fitted with the protrusion 126b of the first push lever 142. Even if the external force is applied to the push button 126 because it is not inserted into the fixing hole 142b of the push button 126, the push button 126 does not move toward the rear cover 108 so that the push operation cannot be performed.

As such, when the fitting protrusion 126b of the push button 126 is inserted into the fixing hole 142b of the first push lever 142, the push button 126 is assembled into the rear cover 122. Guided to move toward the rear cover 108, where the second elastic member 123 is in a compressed state.

Then, as described above, when the push button 126 is moved toward the rear cover 108, the connecting projection 124c of the stopper 124 fitted into the insertion groove 126a formed in the lower portion of the push button 126. ) Also moves toward the rear cover 108, thereby moving the stopper 124 entirely toward the rear cover 108.

When the stopper 124 moves toward the rear cover 108 as described above, the end 124a of the stopper 124 protruding through the through hole 122b of the rear cover 122 penetrates the rear cover 122. The ratchet 312 and the stopper 124 of the connector 310 are released into the hole 122b to release the engaged state. When the connector 310 is rotated in the release direction in this state, the connector 310 is rotated in the release direction without any interference, so that the connector 310 is separated from the connection portion 128.

When the connector 310 and the connector 128 are separated as described above, the first settling hole 142c-2 of the first holder 142c of the first push lever 142 is connected to the radiation source 100. It has the same axis as the convex portion 100a, and the convex portion 100a has a state of being caught by the first settling hole 142c-2 of the first push lever 142, so that the radiation source 100 has the container 110. It will have a fixed state that cannot move inward or outward.

According to the radiographic inspection apparatus having a multi-locking structure according to the present invention as described above, the first locking portion 120 that can prevent the connector 310 of the control tube 300 from being released to the container 110 without permission. And a second locking part 140 is provided between the first locking part 120 and the rear cover 108 of the container 110 in association with the first locking part 120 to move the radiation source 100. The control unit 310 does not separate from the connection unit 128 even if an external force is applied to rotate in the release direction unless the user push button 126 and the first push lever 142 are operated. Therefore, the connector 310 of the control tube 300 may be prevented from being separated from the connection portion 128 of the container 110 without permission.

In addition, as described above, when the connector 310 of the control tube 300 is separated from the connection portion 128 of the container 110, the first push lever 142 is fixed so as not to move the radiation source 100. The radiation source 100 can be prevented from leaking to the outside of the container 110 during the connection or disconnection of the control tube 300.

In addition, the user may sequentially assemble or separate the control tube 300 or the source transmission tube 200 to the container 110 so that the radiation source 100 during the assembly or separation process of the control tube or source transmission tube 200. The outflow of the container 110 can be prevented.

Therefore, the radiation source 100 may be exposed to the outside or the wires for pushing the radiation source 100 to the outside of the container 110 may be prevented from being disconnected while being exposed to the outside, thereby preventing the radiation source 100 from being exposed to the outside of the radiation source 100. Exposure can be prevented.

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

For example, in order to prevent the push button 126 from being pushed by an unauthorized person, the push button 126 may include a lock 130 into which a key is inserted. That is, as shown in FIGS. 2, 3, and 9, a lock 130 into which a key is inserted is installed on one surface of the push button, thereby moving the push button 126 according to the locking and releasing of the lock 130. You can also control it.

In other words, a key is inserted into the push button 126 so that the lock 130 is rotated so that the push button 126 is operated even if the user presses the push button 126 while the key is not released by the key. The stopper 124 cannot be operated because it is locked so as not to move toward the rear cover 108 along the push button mounting hole 108c.

On the contrary, in the state where the lock 130 is released by the key, when the user presses the push button 126, the push button 126 is installed to move toward the rear cover 108, whereby the push button 126 As the stopper 124 moves toward the rear cover 108, the end 124a of the stopper 124 is spaced apart from the ratchet 312 of the connector 310 to move the connector 310 to the container 110. It can be separated from the connection portion 128 on the back.

100: radiation source 100a: convex portion
102: handle 104: shield
106: front cover 106a: exit hole
106b: Hanging projections 107: Boss
108: rear cover 108a: retraction hole
108b: stopper mounting hole 108c: push button mounting hole
109: fourth elastic member 110: container
120: first locking portion 121: first elastic member
122: rear cover 122a: assembly hole
122b: through hole 123: second elastic member
124: stopper 124a: this end
124b: body 124c: connecting projection
126: push button 126a: insertion groove
126b: fitting protrusion 127: front cover
127a: fitting hole 127b: opening
128 connection part 130 lock
140: second locking portion 142: first push lever
142a: pressing part 142b: fixing hole
142c: first holder portion 142c-1: first communication hole
142c-2: First settling hole 142d: Engagement piece
143: binding hole 144: supporter
144a: Hanging Jaw 144a: Hanging Jaw
144b: lifting area 146: locking member
146a: storage space 146b: hanging storage groove
150: third locking part 152: second push lever
152a: pressurizing portion 152b: guide bar
152b-1: guide body 152b-2: sliding part
152c: binding pin 152d: binding wire
152e: second holder portion 152e-1: second communication hole
152e-2: second settling hole 153: protrusion
154: slot 156: slope
158: release button 159: third elastic member
200: source transmission pipe 210: connector
300: control tube 310: connector
312: Ratchet

Claims (9)

A container for shielding and storing the radiation source;
A source transmission tube connected to an exit hole formed at the front of the container to guide the radiation source to the object under test;
A control tube connected by a connector and a connector provided on a rear surface of the container facing the source transmission tube and having a wire therein for moving a radiation source therein;
A remote controller provided at the base of the control tube to push or pull the wire of the control tube by a handle operation;
A second locking unit installed at a rear surface of the container to fix the radiation source located inside the container in a non-moving manner according to a user's pressing operation; And
And a third locking part provided on the front of the container to intermittently operate the second locking part, wherein the second locking part includes a first push lever installed on the rear surface of the container to move up and down,
The first push lever,
A pressing part which is fixed to the rear surface of the container and is pressed by the user by protruding to an upper portion of the rear cover on which the connection part is formed; A fixing hole formed at a lower portion of the pressing part and into which a rear surface of the push button is inserted; And a first holder part installed at an inlet hole of a container into which a radiation source corresponding to a lower portion of the fixing hole enters and exits, and intercepts access of the radiation source.
delete The method according to claim 1, wherein the radiation source,
The convex portion having a diameter larger than the diameter of the radiation source is formed, and the first holder portion is formed with a first communication hole having a diameter larger than the convex portion of the radiation source and a first settling hole having a diameter smaller than the convex portion of the radiation source. Radiographic inspection device having a multiple locking structure characterized in that.
The method of claim 1, wherein the second locking portion,
And a supporter installed between the rear surface and the rear cover of the container,
The supporter has a radiographic inspection apparatus having a multi-lock structure, characterized in that the lifting area for guiding the lifting of the first push lever on the surface facing the back of the container.
The method of claim 1, wherein the third locking portion,
A second push lever installed at the front of the container and lifting up and down;
The second push lever,
A pressing unit which protrudes toward the front of the container and is pressed by the user;
A guide bar penetrating through a slot formed in the lower portion of the pressing portion, the tip of which is guided linearly on the surface of the second push lever;
A binding pin inserted into or detached from a binding hole formed in a first pressing lever which is installed on the rear surface of the container and moves up and down according to the linear movement of the guide bar; And
And a binding wire for connecting the binding pin and the guide bar.
The method of claim 5, wherein the second push lever,
An inclined surface is formed at a portion where the guide bar passes through the slot, and the upper thickness of the second push lever is formed thicker than the lower thickness of the second push lever based on the inclined surface. Inspection device.
The method of claim 5, wherein the third locking portion,
A release button elastically supported at the front of the container and having a multi-step shape in which the diameter of the tip protruding toward the front of the container is smaller than the diameter of the base end; And
And a second holder portion penetrated by the release button and formed between the pressing portion of the second push lever and the slot. 2.
The method according to claim 7, wherein the second holder,
A second communication hole having a diameter larger than the base diameter of the release button; And
And a second settling hole formed at a lower portion in a state of being connected to the second communication hole and having a smaller diameter than a proximal diameter portion of the release button.
The method according to claim 5,
The binding pin is a radiographic inspection apparatus having a multi-locking structure, characterized in that the base end is elastically supported on the back of the container so as to face the binding hole of the first push lever.

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