KR200434989Y1 - Connector of cable for radioactive rays remote controller - Google Patents

Abstract

The present invention is a cable connector for controlling a radiation remote controller having a new crimp structure that prevents the disconnection of the drive cable male connector for the remote controller of the radiation exposure machine and the female connector at the opposite end of the source container (aka pigtail). The present invention relates to a pigtail cable seated in a collimator, including a guide tube provided at an outer circumference of the pigtail cable, and a drive cable connected to the other end of the pigtail cable, wherein the drive cable and the pigtail cable A male and female connector is provided at one end to connect the driving cable and the pigtail cable, and a plurality of equally spaced pressing surfaces are formed by inserting and crimping a connection cable inside the female and female connectors, and the pressing surfaces are formed at eight locations. It is preferable that according to the above configuration, The core is firmly coupled in the form of matching the center of gravity instead of the eccentric state, and as a result of the operation of the controller, it is possible to connect the structure of the cable which can maintain a stable and continuous connection even under the condition of rotation and length adjustment. This has the effect of allowing precise control.

Collimator, Connector, Radiation, Remote Controller, Control Cable, Pigtail

Description

Cable connector for the control of the radiation remote controller {CONNECTOR OF CABLE FOR RADIOACTIVE RAYS REMOTE CONTROLLER}

1 and 2 are schematic side views of a radiation remote controller according to an embodiment of the present invention.

3 is an enlarged perspective view of portion A of FIG. 2.

** Description of the symbols for the main parts of the drawings **

114 ..... Connector 116 ..... Pigtail Cable

126 ..... Driving cable 142 ..... Guide tube

150 ..... Drive control panel 152 ..... Handle

154 ..... handle 156 ..... driving plate

162 ..... Source Box Shield

The present invention relates to a cable connector for controlling a remote radiation control device, more specifically, a connector that is coupled to the end of the cable is fixed to the cable is firmly coupled to the cable, for stable control of the radiation remote control to maintain a stable connection state A crimping technique for the mating of cable connectors.

Today, the range and technology of radioisotopes are rapidly evolving, and are a very small and powerful energy source that contributes to industrial, medical and scientific research. For example, radioisotopes can take many forms, including radiologic destructive testing, radioisotope gauges, industrial radiotracers, in-vivo diagnostics and treatment, in-vitro diagnostics, in-vitro irradiation treatments, radiation sterilization, radiation food research, and radiation genetic engineering research. It is used.

For example, in the non-destructive test, a collimator guide tube and a remote controller are used to prevent a worker from being exposed to radiation. More specifically, the collimator is fixed by placing a film on a boiler tube or pipe. Using a remote controller, the source locker is used to seat the pigtail on the collimator through the guide tube, and to release the radiation from the collimator and develop it on the film.

This method uses a collimator, which is a device that creates a slit or film at the focal position of the lens or reflector at the inspection target area and makes parallel light converging of the radiation passing through it, so that the welded part (test object) is radioactive. Irradiation detects defects, such as cracks, by using developed welded portions of the attached film.

The radioisotope (Ir-192) in use when irradiating the boiler tube welding site of non-destructive inspection by radiation transmission test emits r-Ray in the circumferential direction. It is necessary to exit the boiler manhole and to move back and forth on the scaffolding quickly, which increases the risk of entering and exiting the manhole and can cause enormous disruption to the work process.

However, the use of collimators is inevitable, since radiation is emitted in one direction and radiation dose of radiation workers can be reduced in the opposite direction.

A common method of installing and using such a collimator is to fix the collimator with a magnet in a welded boiler tube or a small diameter pipe, place a film on the welded area, and then use a remote controller to control the source collimator through an isotope guide tube. Pigtails and isotopes (IR-192) are deposited and released on the collimator to develop the film.

The collimator and the remote controller as described above is realized by remote control by releasing the collimator through the connection of the drive cable and the pigtail cable.

Conventionally, the drive cable and the pigtail cable connected to the remote controller and the collimator are coupled to the male and female connectors, but the coupled state is not firm, so that the connector is separated from the cable and remote control cannot be controlled.

 In addition, the connected cables are crimped into an eccentric state that is not exactly matched to each center, causing twisting due to frequent use, resulting in a problem of deterioration in durability. These cables occupy most of the unstable couplings between the cables. This is due to the unstable coupling of the connectors coupled to the ends of these cables.

In addition, the crimp coupling portion of the connector and the cable has a weak coupling force, and as a result, there is a problem in that the separation of the cable during separation is impossible to control the pigtail.

The present invention is to solve the above-mentioned problems, the object of the present invention has a new crimping structure to prevent the separation of the male connector of the drive cable for the remote control of the radiation exposure unit and the female connector of the pigtail cable The present invention provides a cable connector for controlling a radiation remote controller.

In addition, the present invention is to improve the coupling force of each connector and cable, to prevent separation and separation as well as to maintain a stable and continuous connection, and to achieve a stable control of the remote controller.

Radiation remote controller according to the present invention for achieving the above object is a pigtail cable including a guide tube end and a source on which the collimator is installed, a drive cable connected to the other end of the pigtail cable, by stretching the drive cable In the radiation remote controller comprising a drive operation unit for remotely controlling the pigtail cable and the collimator, a connector is provided at both ends of the drive cable and the pigtail cable to connect the drive cable and the pigtail cable, Preferably, a plurality of equally spaced pressing surfaces are formed around the outer circumference of the connector such that the connector, the driving cable and the pigtail cable are coupled to each other. Characterized in that formed.

According to the present invention of the configuration as described above, the center of the connector and the cable is firmly coupled in a form in which the center of the connector is not exactly eccentric state, it is possible to maintain a stable and continuous connection even in the situation of stretching and length adjustment pigtail The coupling structure of the cable is realized, whereby an accurate adjustment is possible.

In addition, it is possible to be coupled between the correct center uneccentricity, there is an effect that the long-term retention and durability of the bonding portion is increased.

In addition, since accurate detection is possible, a stable detection state is maintained, thereby minimizing the exposure of radiation to the user, which may occur, thereby increasing safety.

Hereinafter, one preferred embodiment according to the present invention will be described in more detail with reference to the drawings, and the same reference numerals shown in each of the drawings indicate the same members having the same function.

As shown in Figures 1 to 3, the non-conflict radiation remote controller 100 according to the present invention is a drive operation unit 150, pigtail cable 116, guide tube 142, drive (drive) cable 126, the collimator 210 and the source storage shield 162.

Pigtail 200 is provided with a radioisotope is provided on the opposite side to the driving operation unit 150 that the user's operation is made. A box storage shield 162 is provided between the pigtail 200 and the driving operation unit 150 to prevent the radiation of the pigtail 200 from being exposed. Source box shield 162 is made of a material such as lead (Pb) or tungsten (W).

In other words, the pigtail 200 is positioned at the center of the inside of the source storage box shield 162 so as to prevent external emission of the isotope. To secure.

And even when the use of the isotope is finished, the pigtail 200 is placed inside the source storage box shielding device 162 as shown in FIG. 2, and then the male and female connectors are separated from the connector 114 and the outer cable hose is doubled. 141 and the source compartment shield 162 are also separated, and the guide tube 142 is also removed from the source compartment shield 162 so that the pigtail 200 at the end of its life is built in the source compartment shield 162. Using as a protective container for transportation, and replacing the pigtail 200 of the new source and built again in the source storage box shield 162 may be in a state for movement.

Pigtail cable 116 may be connected to the pigtail 200, the pigtail cable 116 is connected by the connector 114.

In addition, a guide tube 142 serving as a guide passage for moving the pigtail 200 of the pigtail cable 116 to the collimator 210 position is provided.

The other end of the pigtail cable 116 is connected to a drive cable 126 for moving the pigtail cable 116 to the collimator 210 and ultimately operating the pigtail 200.

The pigtail cable 116 and the drive cable 126 are connected to each other by the connector 114, the connector 114 in the form of a cap on the end of each cable is pressed and fixed to be bonded. To this end, a plurality of pressing surfaces of equal intervals are formed around the connector 114 to be pressed together after the driving cable 126 and the pigtail cable 116 are inserted.

The pressing surface 114a is formed by pressing the connector 114 outer circumference radially in the center direction thereof. The pressing surface 114a may have various numbers, but it is preferable that the pressing surface 114a has the same pressing surface of eight surfaces. It can be formed by pressing. However, if five or more pressing surfaces are formed, the number may be variously shaped by the user's convenience.

As described above, when a plurality of equally spaced pressing surfaces 114a are formed on the connector 114, the centers of the connector 114 and the cables 116 and 126 are not eccentric but firmly formed so that the correct centers coincide with each other. Combined, by operating the controller, it becomes a coupling structure of the cable that can maintain a stable and continuous connection even in the situation of length adjustment, thereby enabling accurate control.

In addition, it is possible to combine the correct center uneccentricity to increase the duration and durability of the maintenance, and as a result prevent the separation and separation of the cable 116, 126 and the connector 114 is to enable a stable control .

In addition, since accurate control is possible, stable detection is maintained, thereby increasing safety by minimizing the exposure of radiation to a user.

In addition, the connector 114 is manufactured in a slightly different form to connect the cables 116 and 126. One is a state in which the protrusion 114c is formed and the other is a state in which the insertion groove 114b is formed so that the protrusion 114c is inserted.

On the other hand, the driving operation unit 150 is composed of a handle 152, the handle 154 and the driving roller 156, the handle 152 is a portion that is gripped by the user, the handle 154 is the driving roller 156 It is manipulated by the other hand of the user who does not hold it. In addition, the drive cable 126 is wound around the drive roller 156 so that the pigtail 200 is positioned at the measurement location as shown in FIG. 1 by the rotation of the drive roller 156, or the source storage box is not used as shown in FIG. 2. It serves to position inside the shield 162.

As described above, the coupling connector of the drive cable 126 and the pigtail cable 116 of the radiation remote controller according to the present invention forms a crimped surface for the stable coupling of the connector and the cable. One example for illustration is shown. Therefore, the present invention may be represented in another form by taking an example of a difference in form or number not described in the present invention.

However, these embodiments are all included in the technical scope of the present invention as long as the pressing surface is formed to form a stable coupling of the connector and the cable as in the present invention.

According to the present invention of the configuration as described above, the center of the connector and the cable is firmly coupled in the form of the center coincidence rather than eccentric state, by operating the controller, maintaining a stable and continuous connection even in the situation of length adjustment It is possible to combine the structure of the cable, which has the effect of enabling accurate control.

In addition, it is possible to combine the correct center uneccentricity has the effect of increasing the duration and durability of the maintenance.

In addition, since a stable detection state is maintained as the accurate control is possible, safety is increased by minimizing the exposure of the user to radiation.

Claims (2)

Pigtail cable in which the source is installed, source storage box shield for storing and transporting the pigtail cable, guide tube provided on the outer circumference of the pigtail cable, drive cable connected to the other end of the pigtail cable, In the radiation remote controller comprising an external cable hose for guiding the drive cable, a drive operation unit for stretching the drive cable to remotely control the pigtail cable and the pigtail, A plurality of equally spaced crimp surfaces obtained by press molding the outer circumference of the connector in a center direction so that the connector is connected to the driving cable and the pigtail cable, and the connector, the driving cable and the pigtail cable are coupled to each other. Cable connector for controlling the radiation remote control, comprising a. The cable connector for radiation remote controller control according to claim 1, wherein the crimping surfaces are formed at eight locations.

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