KR200389799Y1 - Guide tube of radiation projector capable of monitoring a radioactive source position by naked eye - Google Patents

Abstract

The present invention provides a radiation source transmitter tube that can detect the position of the radiation source present in the stainless steel tube of the irradiator without a power source or other additional devices or power source. The radiation irradiator transmission tube capable of locating the radiation has a structure capable of visually detecting the position of the radiation source in the transmission tube by emitting visible light when the radiation emitted from the radiation source passes through the stainless tube and passes in the light emitting layer on the outer surface of the tube. The irradiator transmitter tube capable of locating the radiation source is a stainless corrugated pipe that provides a path of movement of the radiation source and provides flexibility and durability to protect the radiation source. It is composed of a reflective layer for reflecting the light generated from the light emitting layer to the front to increase the light utilization efficiency, and a transparent protective layer that protects the light emitting layer from external contamination or impact and transmits the light to the outside.

Description

 GUIDE TUBE OF RADIATION PROJECTOR CAPABLE OF MONITORING A RADIOACTIVE SOURCE POSITION BY NAKED EYE}

  The radiation irradiator is a non-destructive inspection device that can inspect the welded state of a structure such as a pipe or a steel steel pipe, or mechanical defects inside by radiography. The irradiator consists of an irradiator box that shields the radiation and stores the source, a remote manipulator that controls the movement of the source, and a transmission tube that provides the source's movement path.

 The procedure for performing nondestructive testing using the irradiator is to move the end of the transmission tube (source stop or collimator) to the inspection point, fix it, attach the film to the external surface of the inspection object, and then use the remote control to attach the release wire to the release wire. The connected radiation source is transferred to the end of the transmission tube to irradiate the radiation. After the inspection of the specific point, the worker transfers the source to the irradiator through the remote control, and after the source is transferred to the irradiator, the source stop is moved to the next inspection position and the inspection is resumed. This is done repeatedly during the inspection.

  In the case of normal inspection, the worker is far from the radiation source and there is little radiation exposure. However, in spite of equipment failure or operator error, the radiation source may remain at the end of the transmission line or transmission line without being collected by the irradiator. If workers do not recognize this and approach the radiation source, they will be exposed to radiation. Of course, according to the radiation safety regulations, workers should be equipped with radiation monitoring equipment such as surveyors or personal alarm devices to continuously monitor the exposure of the radiation, but all the regulations must be met by factors such as night work or other working conditions. It is also true that they are unable to perform their duties consistently.

In addition, if the radiation source stays in the transmission pipe without being transported to the irradiator box due to a certain cause such as damage to the transmission pipe or release of the release wire, the radiation worker should promptly move the radiation source to the irradiator again to prevent the progress of radiation exposure. As such, when the inflow and outflow of the radiation source into the irradiator can not be controlled through the remote control unit, the radiation source must be recovered in a safe and fast manner. The location information of the radiation source during the processing is an important factor in the treatment method or the shortening of the processing time. However, current radiation meter or irradiator equipment only informs the exposure of the radiation source and does not have the function of providing the exact location of the radiation source. As a result, radiation workers are forced to work with the possibility of unnecessary exposure during the recovery of the radiation source or the possibility of propagation to another major accident. In fact, in 2000, a large overexposure event occurred by cutting a radiation source while cutting a transmission tube without knowing the exact location of the radiation source in Ulsan. In the case of a radiation source loss accident in the transmission pipe, if the location of the radiation source in the transmission pipe can be accurately known, unnecessary radiation accidents can be prevented in advance, and the exposure and accident processing time can be minimized.

In addition, the location information of the radiation source in the transmission pipe helps the operator to reduce the cost of inspection by increasing the speed or accuracy of the inspection work. In the non-destructive testing procedure described above, the radiation source should be located at the innermost end of the source stop or collimator at the end of the transmission tube. If the radiation source cannot secure its position, the image taken on the inspection film does not appear properly because the radiation dose to be irradiated on the subject does not match. Such films cannot be used for reading and must be inspected again, thus consuming material such as films, which adds cost. The irradiator transmitter that can detect the position of the radiation source can be used to secure the exact position of the radiation source by informing the operator precisely to the irradiation position of the radiation source, thereby improving the economics of non-destructive inspection by reducing the re-examination or incidental cost due to the incomplete position of the radiation source. Can be.

As described above, the general radiometer can measure or monitor the exposure or intensity of the radiation, but the function of detecting the location of the radiation source is inferior. In addition, radiation meters require a separate power supply and volume, are expensive and not easy to handle, while the radiator transmitter tube, which is capable of locating radiation, has a very simple structure and always keeps the position of the radiation source without additional equipment or power. It has the advantage of being monitored by the transmission line itself.

The present invention visually detects the position of a radiation source in an opaque transmission tube through visible light without an additional device or power supply by adding a visible light emitting layer made of a flash material reacting with radiation to the outer surface of the stainless corrugated pipe of the irradiator transmission tube. It is an object of the present invention to provide a radiator transmission tube capable of locating a radiation source.

As described above, the irradiator transmitting tube capable of detecting the position of the radiation source visually informing the position of the radiation source is

 A radiation irradiator including a radiation pipe containing a transmission pipe and a radiation source connected to the transmission pipe,

The transmission tube may further include a detection layer having a light emitting layer made of a flash material for converting the light into the light of the first wavelength band in response to the radiation source radiated from the radiation source.

The detection layer may further include a reflection layer that reflects light of the first wavelength band toward the emission layer to increase light utilization efficiency inside the emission layer.

The detection layer may further include a protective layer made of a transparent material to protect the light emitting layer on the outside of the light emitting layer and to increase the rate at which light of the first wavelength band generated in the light emitting layer reaches the outside.

The protective layer may further include a colored film on the outside to increase the color contrast.

 The protective layer may further include an anti-glare film layer for suppressing the light.

The first wavelength band may be in the visible light wavelength band of 330 to 770 nm.

The first wavelength band is a UV wavelength band of 250 to 400nm, the protective layer may further comprise a photochromic material.

 Solvent material constituting the light emitting layer and the reflective layer protective layer in the detection layer is polyvinyl benzene (polyvinyl benzene), PVT (polyvinyl toluene), PS (polystyrene), PVC (polyvinyl chloride), PMMA (polymethathymethacrylate), PP (polypropylene), It may be any one of polyester and acrylic polyol.

In the irradiator transmitting tube capable of detecting the position of the radiation source, a light emitting material that reacts with radiation in the light emitting layer is called a scintillator, and is a material widely used for radiometric measurement. The scintillator is divided into organic scintillator and inorganic scintillator according to the material composition.In the irradiator transmission tube capable of detecting the position of the radiation source, the scintillator of the light emitting layer is divided into two kinds of scintillators: p-terphenyl, DPO (Diphenyl oxamide) and PBD ) -5- (4-biphenylyl) -1,3,4-oxadiazole), PBBO (2- (4-biphenyl) -6-phenylbenzoxazole), POPOP (1,4-bis (5-phenyloxazol-2-yl) benzene), TBP (tributyl phosphate), BBO (2,5-di (4-biphenylyl) oxazole), DPS (diphenylstilbene), PBBO (2- (4-biphenyl) -6-phenylbenzoxazole), CaW04, Y2O2S: Tb, Gd2O2S: Tb, Gd2O2S: Eu, Gd2O2S: Pr, Gd2O2S: Pr, Ce, F, La2O2S: Eu, La2O2S: Tb can be used or mixed.

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

1 is a view showing an embodiment of a radiation irradiator transmission tube capable of locating a radiation source. The irradiator generally consists of an irradiator box, a remote control unit, and a transmission tube. The radiation source from the irradiator box is transported to the final irradiation point through the transmission tube by the remote manipulator, and shows a scene in which the surface of the transmission tube emits light at the position of the radiation source during the transfer process.

Conventional irradiator transmission tubes have a function of providing a passage of the radiation source in transit and protecting the radiation source, and do not give information of any other source to the operator. However, if there is radiation detection equipment such as surveyor or alarm meter, it is only possible to infer whether the source is inside the irradiator box or the transmission line. In particular, even when the source is fixed inside the transmission line, the alarm sound or survey indicator does not provide accurate location information of the source. However, as shown in Fig. 1, the irradiator transmitting tube capable of detecting the position of the radiation source can display the position of the radiation source by emitting light in the region of the source position as the radiation source moves inside the transmitting tube. Can be. Therefore, it is possible to prevent accidents in which an operator accidentally performs an inspection while the radiation source is not safely recovered by the irradiator due to a mechanical defect or a user mistake. The irradiator transmitter, which can detect the position of the radiation source even if the source is stuck in the middle of the guide tube or the release wire is disconnected due to mechanical damage, is lost. It is possible to improve the safety of the worker by enabling safe and quick processing at the time of collection.

Figure 2 is a side view of the transmission tube explaining the principle of operation of the irradiator transmitter tube position detection according to the present invention. In the non-destructive examination, the radiation source connected to the release wire is moved between the irradiator box and the final irradiation point through the transmission tube by remote operation. It emits visible light to indicate its location. Radiation (X-rays or gamma rays) from the radiation source passes through the stainless corrugated pipe, which is a structural member of the transmission tube, and reacts in the surface emitting layer to emit visible light. At this time, the wavelength range of visible light emitting light is 330 to 770 nm, and the light emitting area moves almost simultaneously with the movement of the source.

Figure 3 shows a cross-sectional view of the configuration of the radiation irradiator transmitting tube according to the present invention possible. The irradiator transmitter tube that can detect the position of the radiation source is made of stainless corrugated tube with flexibility and durability, a reflective layer for reflecting the generated visible light to the outside to improve the light utilization efficiency, a light emitting layer that emits visible light in response to the radiation, and external pollution or It is composed of a transparent protective layer for protecting the light emitting layer from the impact and transmitting the light generated in the light emitting layer to the front.

Stainless corrugated pipe in the figure serves as a structural member of the transmission pipe to secure the passage of the radiation source and to protect the radiation source from external load or impact.

In the drawing, the light emitting layer is a material including a light emitting material and reacts with radiation to emit visible light in the region of 330 to 770 nm.

 The light emitting layer may use a photochromic material. A photochromic material is a material whose color is changed due to a change in absorption wavelength band of the chemical molecule structure when it absorbs light in the ultraviolet region. If not, return to the original color. Therefore, when the radiation incident on the light emitting layer emits ultraviolet rays, the photochromic material absorbs ultraviolet rays and changes color.

In the drawing, the reflective layer serves to reflect the light generated from the light emitting layer to the front surface by applying a reflector to the outside of the corrugated pipe. It is also possible to use reflective materials such as reflective paints, reflective coatings and aluminum films as the reflector.

In the figure, the protective layer serves to protect the light emitting layer from external impact or contamination and transmit the light generated in the light emitting layer to the front side. The protective layer may include the use of a colored film having a color contrast to enhance visibility, an antiglare film for suppressing light, and the like. In addition, the protective layer may include a photochromic material for the purpose of detecting the source position by the color change.

If the irradiator transmitter that detects the position of the radiation source is used at the actual non-destructive inspection site, it can be used to replace the transmitter of the existing irradiator at a very low cost without power or other additional equipment. Compared to other companies, the safety system for radiation workers can be dramatically improved by providing their own radiation monitoring system more easily and continuously. In addition, a safe work environment will also play an important role in increasing the productivity of work by providing the worker with ease of work.

In addition, the location information of the radiation source in the transmission pipe helps the operator to reduce the inspection cost by increasing the speed or accuracy of the inspection work. For non-destructive testing procedures, the source of radiation should be located at the innermost end of the source stop or collimator at the end of the transmission line. If the radiation source cannot secure the correct position, the amount of radiation to be irradiated on the subject is not correct, so that the image of the inspection film is not good and cannot be read, thereby adding re-photographing and the use of auxiliary materials. The radiator transmitter that can detect the position of the radiation source can be used as useful information to secure the exact position of the radiation source during irradiation by informing the operator of the location of the radiation source in the transmission pipe during operation. This can increase the economics of NDT.

In addition, if the radiation source location detection technology is applied where the radiation is exposed or the risk of exposure is high, the use of the radiation source or the location information acquisition technology of the radiation source may be widely used. For example, the use of radioisotopes, power plants, industries, research institutes, military units, medical sites, and other fields dealing with radiation sources will enable a wide variety of applications.

On the other hand, the present invention is not limited to the above-described embodiment and can be carried out by modifying and modifying within the scope not departing from the gist of the present invention, the technical idea that such modifications and variations are also to be regarded as belonging to the following claims.

1 is a view showing an embodiment of a radiation source transmitter tube capable of locating a radiation source according to the present invention.

Figure 2 is a side view of the transmission tube showing the light emission principle of the radiation source transmitter capable of locating the radiation source according to the present invention.

Figure 3 is a cross-sectional view of the irradiator transmission tube capable of locating the radiation source according to the present invention.

<Explanation of symbols for the main parts of the drawings>

1: transporter 2: investigator box

3: operator 4: remote control

5: radiation source 6: source stop (column)

7: visible light 8: release wire

9: radiation (X-ray or gamma-ray) 10: stainless corrugated pipe

11: reflective layer 12: light emitting layer

13: protective layer

Claims (9)

 A radiation irradiator including a radiation pipe containing a transmission pipe and a radiation source connected to the transmission pipe, The transmission tube further includes a detection layer having a light emitting layer composed of a flashing material for converting the light into the light of the first wavelength band in response to the radiation source radiated from the radiation source, outside the radiation source position detection irradiator Transmission pipe According to claim 1, wherein the detection layer further comprises a reflective layer for reflecting the light of the first wavelength band toward the light emitting layer to increase the light utilization efficiency inside the light emitting layer, radiation source position detection radiation Probe tube The method of claim 1, wherein the detection layer further comprises a protective layer made of a transparent material to protect the light emitting layer on the outside of the light emitting layer and to increase the rate of the light of the first wavelength band generated in the light emitting layer to reach the outside. Characterized in that the irradiator transmission tube capable of detecting the source location According to claim 3, The protective layer further comprises a colored film to increase the color contrast on the outside, the radiation source position detection irradiator transmission tube According to claim 3, wherein the protective layer is characterized in that it further comprises an antiglare film layer for suppressing the light, the radiation source position detection irradiator tube 6. The irradiator transmitter tube according to any one of claims 1 to 5, wherein the first wavelength band is in the visible wavelength range of 330 to 770 nm. The irradiator transmitter tube according to any one of claims 1 to 5, wherein the first wavelength band is an ultraviolet wavelength band of 250 to 400 nm, and the protective layer further comprises a photochromic material. According to any one of claims 1 to 5, wherein the solvent layer constituting the detection layer is polyvinyl benzene, polyvinyl toluene (PVT), polystyrene (PS), polyvinyl chloride (PVC), polymethathymethacrylate (PMMA), PP ( Irradiator transmitter tube for radiation detection of any one of polypropylene, polyester and acrylic polyol  The light emitting layer of any one of claims 1 to 5, wherein the light emitting layer is p-terphenyl, diphenyl oxamide (DPO), PBD (2-phenyl) -5- (4-biphenylyl)-to react with radiation and emit light. 1,3,4-oxadiazole), PBBO (2- (4-biphenyl) -6-phenylbenzoxazole), POPOP (1,4-bis (5-phenyloxazol-2-yl) benzene), TBP (tributyl phosphate), BBO (2,5-di (4-biphenylyl) oxazole), DPS (diphenylstilbene), PBBO (2- (4-biphenyl) -6-phenylbenzoxazole), CaW04, Y2O2S: Tb, Gd2O2S: Tb, Gd2O2S: Eu, Gd2O2S: Irradiator transmitter tube containing at least one of Pr, Gd2O2S: Pr, Ce, F, La2O2S: Eu, La2O2S: Tb