KR20060030452A - Compensator of radiation transmission inspection equipment - Google Patents

Abstract

The present invention relates to a compensator of a radiographic inspection apparatus for achieving an even distribution of radiation irradiated onto a film by passing through a weld of a tube to tubesheet from a radiation source.

The present invention relates to a compensator in which a radiation source is embedded on an inner hollow portion and inserted into an inner diameter surface of a tube, a film disposed adjacent to a lower side of a welded portion of the compensator and a tube-tube sheet, and a film support for supporting the film. In the radiographic inspection device for accurately detecting the presence or absence of defects and the state of the welded portion of the tube-tube sheet, the compensator is made of a cylindrical shape having a hollow portion therein, the first small diameter portion and the first A large diameter portion formed on the lower side of the small diameter portion, and having an inclined surface formed to be inclined downward at a predetermined inclination angle between the first small diameter portion and the large diameter portion, and a plurality of auxiliary compensation members are detachably stacked on the inclined surface; The auxiliary compensating member is inclined at an inclination angle corresponding to the inclined surface.

Radiation, transmission, inspection, welding, even distribution, compensation

Description

Compensator of radiation transmission inspection equipment

1 is a view showing a conventional radiographic inspection apparatus.

2 is a cross-sectional view showing a compensator of a radiographic inspection apparatus according to an embodiment of the present invention.

Figure 3 is a perspective view of the compensator of the present invention.

4 is a graph illustrating an experimental example in which the compensator and the conventional example of the present invention are compared.

Brief description of symbols for the main parts of the drawings

10 tube 11: tube sheet

15: weld 20: compensator

30: film 40: film support

The present invention relates to a radiographic inspection apparatus for easily transmitting defects such as pores, cracks, insufficient penetration, poor fusion of the welded part by transmitting radiation to the welded part of the tube-tubesheet of the heat exchanger. More particularly, the present invention relates to a compensator of a radiographic inspection apparatus for achieving an even distribution of radiation irradiated to a film through a weld of a tube-tubesheet from a radiation source.

As is widely known, the radiographic examination apparatus is similar to an X-ray examination for abnormalities in the body, and detects defects inside the subject by using radiation and film on an object of metal or other material. It is a kind of nondestructive testing method used to detect. The advantage of such radiography is that almost all materials can be inspected and the results can be left permanently on the film.

In addition, the main purpose of such radiographic examination is to detect defects and the like present in the inspected object, so that the inspection purpose can be achieved only when the inspection method is appropriate. That is, the matters to be considered in the selection of the radiographic examination method should be basically performed after selecting the radiation source and the film according to the inspected object to improve the sensitivity of the transmitted image and to be an efficient inspection. In this case, the sensitivity of the transmitted photograph is affected by the type of radiation source, the type of film, the distance between the source and the film, the exposure conditions, and the development. The general photographing principle to increase the sensitivity of the transmission picture is that the energy of the radiation source should be appropriately selected according to the material and thickness of the inspected object and the distance between the source and the film should be as long as possible. In addition, the effective inspection depends on the imaging technique, which is affected by the shape of the subject, the inspection conditions, and the like.

On the other hand, power generation equipment, chemical engineering equipment, air conditioning equipment and the like is provided with a heat exchanger, such a heat exchanger is composed of a tube and a tube sheet for supporting the tube, these tubes and tube sheets are mutually coupled by welding or the like at the end adjacent to each other. Thus, the tube is firmly supported on the tubesheet.

Since the tube supported by the tube sheet must be firmly maintained at various operating temperatures and pressures of the structure to properly exhibit its heat exchange performance, the welds of the tube and tubesheet effectively prevent the heat exchanger from functioning and performing well. It is a very important factor to carry out.

The conventional radiographic inspection apparatus used for the inspection of the welded tube-tube sheet is shown in FIG.

As shown in FIG. 1, the conventional radiographic inspection apparatus is a device for inspecting the welded portion 110 of the tube 100 and the tube sheet 101, and a compensator 160 has an inner diameter surface of the tube 100. It is inserted into, the hollow portion 165 is formed in the center of the compensator 160, the radiation source 150 is disposed on the upper side of the hollow portion 165, the compensator 160 and the tube and tube sheet 100 The film 140 is disposed on the lower side of the film 101, and the film support 120 supporting the film 140 is disposed below the film 140, and the radiation source guide cable 130 is disposed at the center of the film support 120. ) Is in communication with the hollow portion 165 of the compensator 160 and extends to the outside.

By this configuration, the radiation from the radiation source 150 is transmitted to the film 140 side after passing through the weld portion 110 of the tube 100 and the tube sheet 101, and thus the film 140 irradiated with the radiation is By processing, the presence or absence of a defect in the weld part 110 is inspected.

At this time, due to the thickness of the tube 100, the inner side 111 of the weld 110 is relatively short with the distance and the transmission thickness of the radiation source 150, while the outer side 112 of the weld 110 is a radiation source ( The distance to 150 and its transmission thickness are relatively long.

As a result, the radiation dose irradiated to the film 140 through the inner 111 and the outer 112 of the welding unit 110 from the radiation source 150 is different, so that the concentration of the radiation dose is non-uniform, and the radiation irradiated non-uniformly. The amount is compensated by the radiation attenuation action of the compensator 160 described above and uniformized within a certain range.

On the other hand, the compensator 160 used in such a conventional radiographic inspection apparatus, as shown in Figure 1, by processing the thickness of the inner diameter surface is changed depending on the distance (SFD: source to film distance) between the radiation source and the film Although the concentration of the radiation dose should be properly compensated and uniformized, due to the processing limitations inside the compensator 160, the processing is not easy, and therefore, the concentration of the projected image formed on the film due to the failure to achieve an equal distribution effect of the radiation dose is satisfactory. There was a disadvantage of becoming uneven overall.

SUMMARY OF THE INVENTION The present invention has been made in view of the above, and the object of the present invention is to provide a compensator for a radiographic inspection apparatus which is excellent in uniformity of concentration of radiation dose irradiated from a radiation source and its workability and installation workability. have.

The present invention for achieving the above object,

A tube-tube consisting of a compensator in which a radiation source is embedded on the inner hollow portion and inserted into the inner diameter surface of the tube, a film disposed adjacent to the lower side of the welder of the compensator and the tube-tube sheet, and a film support for supporting the film. In the radiographic inspection apparatus for accurately detecting the presence or absence of defects in the welded portion of the sheet,

The compensator has a cylindrical shape having a hollow portion therein, and has a first small diameter portion formed on an upper side and a large diameter portion formed on a lower side of the first small diameter portion, and has a predetermined inclination angle between the first small diameter portion and the large diameter portion. It has an inclined surface formed to be inclined downward, a plurality of auxiliary compensation members are separably stacked on the inclined surface, characterized in that the auxiliary compensation member is formed to be inclined at an inclination angle corresponding to the inclined surface.

Preferably, a second small diameter portion on which the film is mounted is formed on the lower side of the large diameter portion of the compensator, and a male screw portion on which the film support is screwed is formed on the lower side of the second small diameter portion.

Preferably, the auxiliary compensation member is made of a magnetic material.

Preferably, the inclined surface of the compensator and the inclined angle of the auxiliary compensating member are set to 20 to 40 degrees, and the inclined angle is proportional to the diameter of the tube.

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

2 and 3 show a radiographic inspection apparatus according to an embodiment of the present invention.

As shown, the radiographic inspection apparatus of the present invention defects such as pores, cracks, insufficient penetration, poor fusion, etc. inside the welded portion 15 for fixing the respective adjacent ends of the tube 10 and the tube sheet 11 As a device for detecting a, the compensator 20 is inserted into the inner diameter surface of the tube 10, the film 30 is bonded on the lower outer peripheral surface of the compensator 20, and the lower side of the film 30 The film support 40 is disposed to firmly support the film 30.

Compensator 20 is basically formed in a cylindrical shape having a hollow portion 21 of a predetermined inner diameter, the upper side of the hollow portion 21 is closed, the lower side of the hollow portion 21 is made of an open form.

The compensator 20 has a first small diameter portion 22 on the upper side, and a large diameter portion 23 having a larger diameter than the small diameter portion 22 on the lower side of the small diameter portion 22. The connecting portion between the first small diameter portion 22 and the large diameter portion 23 has an inclined surface 24 inclined downward at a predetermined angle.

In addition, a second small diameter portion 26 on which the film 30 to be described later is mounted is formed below the large diameter portion 23 of the compensator 20, and a male screw portion 25 is provided on the lower side of the second small diameter portion 26. Is formed, the mounting hole 45 of the film support 40 to be described later is screwed to the male screw portion (25).

On the other hand, the radiation source 27 is built in the upper side of the hollow portion 21 of the compensator 20, the radiation source 27 is installed in the hollow portion 21 through the open lower portion of the compensator 20, the compensator 20 ), The tube 10, the tube sheet 11, and the like, and is configured to irradiate radiation to the film 30 to be described later.

The through-hole 31 is formed in the center part of the film 30, the through-hole 31 is fitted on the second small diameter portion 26 of the beam 20 described above, the through-hole 31 ) Side is provided with a light blocking member (not shown) such as a tape for blocking light.

The film support 40 has a mounting hole 45 formed therein with a female threaded portion 42 at the center thereof, and the mounting hole 45 is screwed to the male threaded portion 25 of the compensator 20 described above. The film support 40 is configured such that the upper surface thereof is in close contact with the lower surface of the film 30, and the radiation source guide cable 48 is provided under the mounting hole 45 of the film support 40 to the compensator 20. It communicates with the hollow portion 21 of and extends to the outside.

In addition, in the present invention, a plurality of auxiliary compensation members 51, 52, 53, and 54 having different thicknesses may be selectively stacked and mounted on the inclined surface 24 of the compensator 20 according to the thickness of the tube. The auxiliary compensating members 51, 52, 53, and 54 have upper and lower surfaces inclined corresponding to the inclination angle of the inclined surface 24 of the compensator 20, and through-holes are individually formed in the center thereof to compensate the compensator ( 20 is fitted on the first small diameter portion 22.

)은 20~40°로 설정됨이 바람직할 것이고, 튜브(10)의 관경이 커짐에 따라 비례적으로 큰 경사각이 적용될 것이다. The inclination angles of the inclined surface 24 of the compensator 20 and the auxiliary compensating members 51, 52, 53, and 54 (

It will be preferable to set the 20 to 40 °, the larger inclination angle will be applied proportionally as the diameter of the tube 10 increases.

Preferably, the auxiliary compensation member (51, 52, 53, 54) of the present invention may be made of a magnetic material in order to prevent easy separation or flow by any external force.

In addition, the formula of the radiation amount which reaches from the radiation source 27 to the film 30 is as follows.

[Formula 1]

Ci: intensity of the radiation source T: radiation transmission time

: Ir-192의 조사정수(0.48R/hr.m.Ci)

Irradiation constant of Ir-192 (0.48R / hr.m.Ci)

D: Distance between radiation source and film (unit: m)

t is the thickness of the test specimen (unit: mm)

Here, the transmission thickness t of the test object means the sum of the thicknesses of the radiation passing through the compensator 20, the tube 10, and the tube sheet 11. For example, the transmission thickness t of the test body passing through the innermost side of the weld 15 corresponds to t1, and the transmission thickness t of the test body passing through the center of the weld 15 corresponds to t2. The transmission thickness t of the test body passing through the outermost part of (15) corresponds to t3.

Referring to Equation 1, the radiation dose reaching from the radiation source 27 to the film 30 becomes inversely proportional to the square of the linear distances D1, D2, and D3 between the radiation source and the film, and the transmission thickness t1 of the test object. , t2, t3) is inversely proportional to the exponential function.

As a result, the concentration of the radiation dose passing through the innermost side and the outermost side of the weld portion 15 becomes the maximum value of the radiation dose passing through the innermost side of the weld portion 15, for example, and the outermost side of the weld portion 15. The concentration of the radiation dose passing through the thickness of the weld 15 is not constant as the concentration of the radiation dose passing through the minimum is the minimum.

)으로 하향 경사진 다수의 보조 보상부재(51, 52, 53, 54)를 선택적으로 적층시킴으로써, 거리 및 투과두께가 짧은 곳에는 상대적으로 보상기(20)의 투과두께를 증대시켜 보상기(20)를 투과하는 방사선을 상대적으로 많이 감쇄시키고, 거리 및 투과두께가 긴 곳에는 상대적으로 보상기(20)의 투과두께를 감소시켜 보상기(20)를 투과하는 방사선을 상대적으로 작게 감쇄시키게 된다. 그 결과, 거리 및 투과두께에 따라 불균일해지는 방사선량의 농도를 일정범위 내로 균일하게 보상할 수 있는 특징이 있다.Therefore, the present invention, as described above, in order to solve the disadvantage that the concentration of the radiation dose irradiated on the film 30 according to the distance and the transmission thickness is uneven, a predetermined inclination angle (

By selectively stacking a plurality of auxiliary compensating members 51, 52, 53, and 54 inclined downwardly, the compensator 20 is increased by increasing the transmission thickness of the compensator 20 relatively where the distance and the transmission thickness are short. Attenuates the radiation that transmits relatively much, and reduces the transmission thickness of the compensator 20 relatively where the distance and the transmission thickness are long to relatively reduce the radiation that passes through the compensator 20. As a result, there is a feature capable of uniformly compensating the concentration of the radiation dose which becomes uneven according to the distance and the transmission thickness within a predetermined range.

In addition, the present invention by selectively mounting a plurality of auxiliary compensation members (51, 52, 53, 54) having a different thickness depending on the thickness of the tube 10 and the tube sheet 11 or other variables, There is a characteristic that the compensation of radiation dose can be performed under the conditions.

In addition, the compensator 20 and the auxiliary compensating member (51, 52, 53, 54) of the present invention is made of a structure that is easy to process and install, it is possible to reduce the manufacturing cost as well as very suitable for mass production There is this.

4 is a calculation example showing a comparison between the compensator 20 and the conventional example of the present invention, and FIG. 4 (a) is transmitted through the innermost, center, and outermost portions of the welded part 110 by the conventional compensator 160. 4 (b) is a graph showing the radiation dose irradiated through the innermost, center, and outermost portions of the welded portion 15 by the compensator 20 of the present invention.

This calculation example was performed under the same experimental conditions as follows.

① intensity of radiation: 2Ci

② Radiation transmission time: 10sec

③ Tube inner diameter: 19.5mm

④ Inner diameter of compensator: 7mm

⑤ Vertical distance between radiation source and film: 36mm

Table 1 below shows the numerical results of the graph of FIG. 4.

 division Tube thickness  1 mm 2 mm 3 mm Weld Innermost Outermost Innermost Outermost Innermost Outermost  Conventional example S.F.D (mm) 38 38.6 38 39 38 39.2 Penetration thickness 24.8 27 24.8 28.4 24.8 29.6 Radiation dose 6,342 6,692 6,342 6,895 6,342 7,113  The present invention S.F.D (mm) 38 38.6 38 39 38 39.2 Penetration thickness 24.8 26 24.8 26.4 24.8 26.6 Radiation dose 6,342 6,444 6,342 6,409 6,342 6,392

Here, S.F.D means a source to film distance between the radiation source and the film.

As shown in FIG. 4 and Table 1, in the present invention, the difference in the concentration of the radiation dose that may occur between the innermost and outermost portions of the welded portion is significantly reduced, compared to the conventional example, and thus an equal distribution effect of the radiation dose. It can be seen that achieved.

The present invention as described above has the effect of making the concentration of the radiation dose irradiated from the radiation source uniform, and its workability and installation workability very excellent.

In the above, the present invention has been illustrated and described with respect to certain preferred embodiments. However, the present invention is not limited only to the above-described embodiments, and those skilled in the art may vary without departing from the spirit of the technical idea of the present invention described in the claims below. It may be changed.

Claims (4)

A tube-tube consisting of a compensator in which a radiation source is embedded on the inner hollow portion and inserted into the inner diameter surface of the tube, a film disposed adjacent to the lower side of the welder of the compensator and the tube-tube sheet, and a film support for supporting the film. In the radiographic inspection apparatus for accurately detecting the presence or absence of defects and the state of the welded portion of the sheet, The compensator has a cylindrical shape having a hollow portion therein, and has a first small diameter portion formed on an upper side and a large diameter portion formed on a lower side of the first small diameter portion, and has a predetermined inclination angle between the first small diameter portion and the large diameter portion. Compensator of a radiographic inspection apparatus having an inclined surface formed to be inclined downward, a plurality of auxiliary compensation members are removably stacked on the inclined surface, the auxiliary compensation member is inclined at an inclination angle corresponding to the inclined surface. The method of claim 1, A second small diameter portion on which the film is mounted is formed on the lower side of the large diameter portion of the compensator, and a lower threaded portion on which the film support is screwed is formed on the lower side of the second small diameter portion. The method according to claim 1 or 2, The auxiliary compensating member is a compensator of a radiographic inspection apparatus, characterized in that made of a magnetic material. The method of claim 3, And the inclination angle of the inclined surface of the compensator and the auxiliary compensation member is set to 20 to 40 °, and the inclination angle is proportional to the diameter of the tube.

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