KR20100033754A - Radiography image acuqisition techinique for boiler tube weldments - Google Patents

Abstract

PURPOSE: A method for acquiring a radiographic image for a welding part of a boiler tube is provided to improve the quality of a welding test of a boiler tube, and to reduce the time and costs without developing a film. CONSTITUTION: A method for acquiring a radiographic image for a welding part of a boiler tube is as follows. A Se-75 radiation source(1) and an imaging plate(3) are arranged on a welding part of a boiler tube(2). The Se-75 radiation source is penetrated through the welding part of the boiler tube. A radiographic image is obtained from the imaging plate, which is contiguous to the welding part of the boiler tube.

Description

Radiation Image Acquisition Method for Boiler Tube Weldments {Radiography Image Acuqisition Techinique for Boiler Tube Weldments}

The present invention relates to a radiographic image acquisition method for a boiler tube welding part of a thermal power plant, and more particularly to a radiographic image acquisition method for a boiler tube welding part of a thermal power plant using a Se-75 radiation source or Yb-169 radiation source and an image plate. will be.

For example, a boiler of a thermal power plant consists of about 40,000 tube welds, and if any one of them is damaged, the plant must be shut down. Therefore, the boiler tube welds need to be inspected for stable plant operation. Typically, the examination is performed, for example, by radiography.

However, the current radiographic image acquisition technique uses Ir-192 as the radiation source and the film is used to acquire the radiographic image. Ir-192 used is not suitable for boiler tube radiographic test, so it is radioactive. Low image accuracy makes it impossible to detect micro defects in the weld. For this reason, the boiler tube welding part is damaged during the operation of the power plant, and the power plant shutdown accident continues.

It is an object of the present invention to improve the quality of radiographic images of boiler tube welds. That is, an object of the present invention is to improve boiler tube welding inspection quality by improving the identification of the radiographic image of the boiler tube weld in a narrow power plant environment.

According to one aspect of the invention, there is provided a radiographic image acquisition method for a welded boiler tube of a thermal power plant. The method includes the steps of placing a Se-75 radiation source and an image plate in the boiler tube weld to be tested; Transmitting the Se-75 radiation source to the boiler tube weld; And obtaining a transmission image acquired from an image plate disposed in close proximity to the boiler tube welding unit.

According to an embodiment of the present invention, the boiler tube welding portion has a thickness of 13 mm and the radiation effective energy may be 400.65 keV.

According to one aspect of the invention, there is provided a radiographic image acquisition method for a welded boiler tube of a thermal power plant. The method comprises the steps of placing a Yb-169 radiation source and an image plate on the boiler tube weld to be tested; Transmitting the Yb-169 radiation source to the boiler tube weld; And obtaining a transmission image acquired from an image plate disposed in close proximity to the boiler tube welding unit.

According to an embodiment of the present invention, the boiler tube welding part may have a thickness of 9 mm and an effective radiation energy of 307.73 keV.

In the present invention, the image plate is halide (barium fluorohalide) a barium-fluoro: A is (BaFX Eu + ^2, X = Cl, Br, I) is the light-irritating image plate (Imaging Plate) coating can be used.

The boiler tube welding inspection quality can be improved by applying the radiographic image acquisition method of the boiler tube welding part to improve the identification of the boiler tube radiographic image.

In addition, by using the image plate according to the present invention for the radiographic image acquisition, it is possible to reduce the time and cost of acquiring the film without developing the film during the acquisition of the transmitted image.

In addition, since the transmission method of the transmission image is a digital image method, it is possible to share it online without incurring the cost of storing the radiographic image.

In addition, it is an environmentally friendly technology because it uses less energy than conventional radiation sources and is advantageous for radiation safety and does not process film development.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the acquisition of radiographic images, particularly in thermal power plant boiler tube welds, in the field of non-destructive testing, to improve the permeability of radiometric images.

The radiometer's identification is obtained by dividing the minimum line diameter of the penetrometer, which is identified in the transmission image obtained by transmitting the penetrometer containing several thin cores with different diameters in the transmission test, with the test specimen. The value indicated by) is used as a criterion for evaluating the precision of the transmitted image.

In general, radiography mainly uses X-rays that can control radiation energy and r-rays that cannot control energy. X-rays can regulate radiation energy by controlling tube voltage. Good transmission images can be obtained, but the X-ray device is large and cannot be used in narrow spaces.

On the other hand, r-rays can be used in narrow spaces due to their small equipment, but radiation energy generates a certain energy depending on the type of radioisotope.

Conventional radiography for boiler tube welds in thermal power plants uses radioisotope Ir-192, which cannot produce X-rays and generates r-rays due to the narrow space. The transmission image is irradiated to the boiler welding part by Ir-192 to obtain the latent image by dimming the film with the transmitted energy. The film is developed in the dark room to obtain the boiler tube radiographic image.

In general, in order to improve the degree of discrimination, radiation energy suitable for the thickness of the specimen to be radiographed should be used as transmission energy.

The boiler tube has a thickness of about 3 to 7 mm and a transmission thickness of 6 to 14 mm through which radiation passes. However, the minimum permissible thickness of Ir-192 is 0.75〃 (19mm), and when used for an object thinner than this thickness, the permeability of the transmitted image is reduced. Therefore, Ir-192, which is used as a radiation source, is not suitable for performing radiographic inspection of boiler tube welds, and thus, accurate transmission images cannot be obtained.

If the transmission image is good, it is easy to find micro defects in the weld, thereby improving the weld quality. Korean Industrial Standard KS B 0845 The radiographic test method for welded steels stipulates the transmission discrimination within 2.0%. However, radiological images of welded boiler tube welded power plant using Ir-192 do not satisfy the identification of 2.0% and allow inspection to 2.5 ~ 5.0% exceeding the standard.

As described above, X-rays and r-rays are used as the radiation sources used in the radiographic test. The X-rays can control the transmission energy by controlling the voltage according to the thickness of the test piece, thereby identifying the transmission image. Although the figure is excellent, r-rays should be used as radiation sources because they are determined by the type of radioisotope. Due to the narrow site conditions, power plant sites, especially boiler tube welds, cannot use X-rays with large test equipment and are applying r-rays. Radiation sources have been applying Ir-192 for decades in radiography tests of power generation facilities, and only Ir-192 has been applied to radiography of boiler tube welds.

Next, the present invention will be described in more detail with reference to the accompanying drawings.

FIG. 1 shows the decay chain of isotopes as the generated radiation energy distribution of Ir-192, as will be appreciated by those skilled in the art. In addition, Table 1 below shows the incidence rate of radiation energy of Ir-192 prepared based on the data of FIG. 1.

Energy (keV) Incidence rate (%) Energy (keV) Incidence rate (%) 136.343 0.10 588.581 2.17 295.957 13.37 593.490 0.02 308.455 14.25 604.411 3.94 316.506 39.72 612.462 2.56 416.469 0.32 884.537 0.14 468.069 22.96 1061.480 0.03 100%

The radiation energy of Ir-192 is 316.50 kV 39.72%, 468.06 kV 22.96%, 604.41 kV 3.94%, as can be seen in Table 1 above and based on the fact that it is possible to inspect as thin as a boiler tube at an energy of 316 kV. So far, Ir-192 has been applied.

However, the inventors have found in experiments and experience that the energy affecting the identification of the transmitted image during radiographic examination is the highest energy among the generated energy of the radioisotope, and the affecting energy is more than 1% of the generated energy. As energy, the present invention was referred to as an effective energy, and the effective energy of Ir-192 was determined to be 612.46kv.

Fig. 2 is a graph showing the minimum allowable thickness range according to the radiation energy, which was prepared experimentally by the present inventors.

As can be seen in Fig. 2, the radiation energy of 612.46kv is 0.75 inch (19 mm) for the minimum allowable thickness of the steel material, and this thickness has been identified as a radiation source which is not suitable for the radiographic test of the boiler tube weld. Therefore, irradiating isotopes to replace Ir-192 for boiler tube welds and to improve the identification of radiographic images, and several radioisotope tests were conducted with two radioisotopes, Se-75 and Yb-169. It was found to be the best source for overtesting.

Similarly to FIG. 1, the generated radiation energy distribution diagram of Yb-169 and the generated radiation energy distribution diagram of Yb-169 are shown in FIGS. 3 and 4, respectively.

Table 2, which shows the incidence rate of the generated radiation energy of Se-75 based on the data of FIGS. 3 and 2, shows the radiation energy generation of the Se-75. By referring to the graph showing the allowable minimum thickness range according to the radiation energy of Figure 2 it can be seen that the radiation effective energy is 400.65kv and the minimum thickness available for radiographic inspection is 13mm. Therefore, it satisfy | fills 7-14 mm which is a boiler tube permeation thickness range.

Table 2. Occurrence Rate of Radiation Energy of Se-75

Energy (keV) Incidence rate (%) Energy (keV) Incidence rate (%)     24,382 0.02 264.658 33.06     66.052 0.62 279.542 14.03     96.734 1.92 303.924 0.74    121.116 9.65 400.657 6.44    136.000 32.69 418.800 0.01    198.606 0.83 572.200 0.02 100%

4 and 2 show the radiation energy distribution of Y-b-169. By referring to the graph showing the minimum allowable thickness range according to the radiation energy in FIG. Therefore, it was identified as an energy suitable for inspecting relatively thin boiler tube welds.

Table 3. Occurrence Rate of Radiation Energy of Yb-169

Energy (keV) Incidence rate (%) Energy (keV) Incidence rate (%)      8.410 0.22 118.190 1.22     20.752 0.12 129.942 0.35     42.760 0.16 130.524 7.41     45.940 0.01 156.725 0.01     50.610 0.35 177.214 14.51     50.855 0.35 193.150 0.01     51.510 0.01 197.958 23.45     63.012 1.41 199.772 0.02     63.121 28.96 240.332 0.07     65.860 0.01 261.079 1.12     93.615 1.71 306.830 0.12    109.780 11.44 307.520 0.33    113.620 0.01 307.738 6.58    113.976 0.01 336.620 0.01    117.377 0.03 100%

However, Se-75 and Yb-169 have Gamma constants (R / h, 1Ci, 1m) of 0.203 and 0.125, which are only 42% and 26% of Ir-192 Gamma constant 0.48. 75 requires 2.4 times more radiation and Yb-169 requires 3.8 times more radiation exposure time.

Although new radioisotopes are used to improve the identification of current radiographic images, if the radiation time increases by 2.4 times and 3.8 times compared to the present time, it can reduce the radiation exposure time because the inspection cost and process cannot be applied. Skill is required.

Therefore the inspection time is considered to prevent prolonged to halides an intermediate for obtaining a radiographic image in a phosphorescent compound, a barium-fluoro instead of film (barium fluorohalide) (BaFX: Eu 2 +, X = Cl, Br, I) is The use of a coated photo-stimulating imaging plate was introduced.

Barium fluorohalide, a phosphorescent compound, has a high sensitivity to radiation and can be reduced to 1/10 of the exposure time of a conventional film. Therefore, the acquisition time of radiographic images due to radioisotope change is rather shorter than the exposure time of currently applied film.

5 schematically shows the configuration of a simplified apparatus for testing boiler tube radiation transmission in accordance with the present invention for testing the present invention. As shown in the side view in Fig. 5 (a), the radiation source 1 according to the present invention is irradiated to the boiler tube 2 as a solid arrow, and an image plate 3 is placed below the boiler tube. FIG. 5 (b) shows a front view of the device configuration in FIG. 5 (a), in which the radiation source 1 is located above the boiler tube 2.

Fig. 6 is a photographic view showing a radiographic image of a boiler tube welded part obtained with a film and Ir-192 according to the prior art.

7 is a photographic view showing a radiographic image of a boiler tube welded part obtained with an image plate and Se-75 according to the present invention.

8 is a photograph showing a radiographic image of a boiler tube welded section obtained with an image plate and Yb-169 according to the present invention.

Such picture can be obtained according to the principle of Computed Radiography, for example. This principle is directly proportional to the amount of exposure to radiation when a special wavelength, such as a laser, is exposed to the image plate while radiation energy is accumulated in the latent image form after the radiation has passed through the specimen. The intensity of the fluorescent light is emitted, and the light is digitized using an optical multiplier and an analog-to-digital converter to display the image as an image.

The boiler tube welding inspection quality can be improved by applying the radiographic image acquisition method of the boiler tube welding part to improve the identification of the boiler tube radiographic image.

In addition, by using the image plate according to the present invention for the radiographic image acquisition, it is possible to reduce the time and cost of acquiring the film without developing the film during the acquisition of the transmitted image.

In addition, since the transmission method of the transmission image is a digital image method, it is possible to share it online without incurring the cost of storing the radiographic image.

In addition, it is an environmentally friendly technology because it uses less energy than conventional radiation sources and is advantageous for radiation safety and does not process film development.

1 is a radiation energy distribution diagram of Ir-192.

2 is a graph showing the minimum allowable thickness range depending on the radiation energy.

3 and 4 show the generated radiation energy distribution of Yb-169 and the generated radiation energy distribution of Yb-169, respectively.

5 is a schematic diagram of a simplified apparatus for testing boiler tube radiation in accordance with the present invention.

Figure 6 is a photograph showing a radiographic image of a boiler tube welded portion obtained with a film and Ir-192 according to the prior art.

Figure 7 is a photograph showing the radiographic image of the boiler tube welded portion obtained with the image plate and Se-75 according to the present invention.

Figure 8 is a photograph showing the radiographic image of the boiler tube welded portion obtained with the image plate and Yb-169 in accordance with the present invention.

-Explanation of the symbols for the main parts of the drawings-

One; Radiation source 2; Boiler tube

3; Image plate

Claims (6)

In the radiographic image acquisition method for the welding of the boiler tube of the thermal power plant, Placing the Se-75 radiation source and image plate in the welded boiler tube to be tested; Transmitting the Se-75 radiation source to the boiler tube weld; And And obtaining a transmission image obtained from an image plate disposed in close proximity to the boiler tube welding unit. The method according to claim 1, wherein the boiler tube welding portion has a thickness of 13 mm and the radiation effective energy is 400.65 keV. According to claim 1, wherein the image plate is a barium fluorohalide (Baium: fluorohalide (BaFX: Eu ² +, X = Cl, Br, I) is a photo-stimulating imaging plate (Imaging Plate) coated, boiler tube weld portion Radiographic image acquisition method. In the radiographic image acquisition method for the welding of the boiler tube of the thermal power plant, Placing a Yb-169 radiation source and an image plate on the boiler tube weld to be tested; Transmitting the Yb-169 radiation source to the boiler tube weld; And And obtaining a transmission image obtained from an image plate disposed in close proximity to the boiler tube welding unit. The method according to claim 3, wherein the boiler tube weld is 9 mm thick and the effective radiation energy is 307.73 keV. The method of claim 3, wherein the image plate is halide (barium fluorohalide) to barium fluoro: the (BaFX Eu ² +, X = Cl, Br, I) is the light-irritating image plate (Imaging Plate) is applied, the boiler tube weld Radiographic image acquisition method.

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