KR102035534B1 - A shielding device for shielding radiation - Google Patents

Abstract

A shielding device for shielding braking radiation is for further shielding an acrylic protective device for shielding a vial containing a Y-90 microsphere, and includes a body shielding portion comprising a shielding material, having an accommodating space for accommodating the acrylic protective device with an upper portion opened and having a portion of a sidewall portion opened; and a transparent shielding portion comprising a transparent shielding material and sealing the open sidewall portion of the body shielding portion.

Description

A shield for braking radiation {A SHIELDING DEVICE FOR SHIELDING RADIATION}

The present invention relates to a shield, and more particularly, to a shield capable of shielding braking radiation generated by Y-90, a high-energy beta-ray-emitting radioisotope, and capable of visually identifying the interior.

Radioembolization is a method of necrosis of a tumor by injecting microspheres containing radioisotopes that emit high doses of radiation into the tumor.

는 호주의 SIRTeX Medical사에서 개발한 방사선 색전 물질로써 평균 직경이 32.5

의 수지로 된 마이크로스피어에 베타선을 방출하는 Yttrium-90(이트륨-90, Y-90)이 탑재되어 있다. Y-90은 최대 2.27 MeV(평균 0.93 MeV)의 베타 입자에너지를 방출하며 Y-90의 반감기는 64.1 시간이다.

Is a radiation embolic material developed by SIRTeX Medical in Australia with an average diameter of 32.5

Yttrium-90 (yttrium-90, Y-90) that emits beta rays is mounted on a microsphere made of resin. Y-90 releases beta particle energy up to 2.27 MeV (average 0.93 MeV) and the half-life of Y-90 is 64.1 hours.

Y-90 마이크로스피어를 주입하게 되면 간 종양을 둘러싼 모세혈관에 박히게 되는데, 이때 마이크로스피어에 탑재된 Y-90에서 방출되는 베타선은 최대 11 mm(평균 2.5 mm) 가량 종양에 전달된다. 베타선은 빠르게 세포분열을 하는 종양 세포의 유전물질인 DNA를 파괴시켜 세포사멸을 유도한다.During radioembolization, the western anatomy of a liver cancer patient is incised and a catheter

Injecting the Y-90 microspheres causes the capillaries that surround the liver tumor to be lodged, with beta rays released from the Y-90 mounted on the microspheres up to 11 mm (2.5 mm average). Beta rays induce apoptosis by destroying DNA, a genetic material of rapidly dividing tumor cells.

Y-90 마이크로스피어는 한국을 비롯하여 호주, 미국, 유럽, 아르헨티나, 인도, 싱가포르 등 약 30개국에서 간암 치료제로 승인받아 사용되고 있다. Such

Y-90 microspheres have been approved for liver cancer treatment in about 30 countries including Korea, Australia, USA, Europe, Argentina, India and Singapore.

Y-90 is a beta-minus decay (β-decay) as a neutron surplus nucleus. When neutrons are converted into protons, they release beta-minus particles (electrons) and semi-neutrinos in the form of electrons and finally decay to Zirconium-90. At this time, the generated electrons stop when they meet a shield of a certain thickness. In this process, the brasing radiation (Bremsstrahlung) is lost while losing energy at a rate proportional to the square of the acceleration of the electrons. It occurs continuously. Braking radiation occurs the higher the energy of the beta rays and the greater the atomic number of the absorber.

Beta-ray is weak in transmission because it is in the form of electron particles. Beta-ray shielding uses materials with lower atomic numbers, such as plastic, glass or aluminum. However, radioisotopes that emit high energy beta rays of 1 MeV or more have a low atomic number because the beta rays interact with the material to generate braking X-rays. Secondary shielding should be made of high material.

Y-90 마이크로스피어는 호주에서 제작되며, 제조 후 유리 바이알(vial)에 담은 후 아크릴 필름으로 1차 차폐 후 납 용기에 담는 2차 차폐 후 한국으로 배송된다. 시술 전 측정된

Y-90 마이크로스피어의 방사능량은 평균적으로 3~4GBq이다.

Y-90 마이크로스피어의 투여를 위하여 환자의 종양 크기에 맞게 사전에 계산된

Y-90 마이크로스피어의 적정 용량을 유리 바이알에서 취한 후 아크릴 V형 바이알(V-vial)에 옮겨 담는다. 이 후 아크릴 V형 바이알을 아크릴 보호 장치로 옮긴 후 이송 박스에 옮겨 담아 방사선색전술을 위해 인터벤션실로 이동한다.

The Y-90 microspheres are manufactured in Australia, then manufactured in glass vials, firstly shielded with acrylic film, then secondly shielded in lead containers and shipped to Korea. Measured before the procedure

The radiation dose of Y-90 microspheres is on average 3-4 GBq.

Pre-calculated for tumor size of patient for administration of Y-90 microspheres

The appropriate volume of Y-90 microspheres is taken from glass vials and transferred to acrylic V-vials. The acrylic V-type vial is then transferred to an acrylic protective device, then transferred to a transfer box and transferred to the convention chamber for radioembolization.

Y-90 마이크로스피어의 시술 시 방사선의 피폭 저감을 위하여 베타선은 아크릴 보호 장치로 차폐를 하였지만, 고에너지의 베타선을 방출하는 Y-90에 의해 제동복사가 일어나 표면방사선량률(원자력안전법에서 정의하는 표면방사선량률은 방사성물질, 방사성물질을 내장한 용기 또는 장치, 방사선발생장치 및 방사선차폐체 방사선이 나오는 물체의 표면으로부터 10센티미터의 거리에서 측정한 방사선량률을 말한다)의 기준치를 초과하는 제동 X선이 발생하는 문제가 있다. However, in this way

Beta-rays were shielded with an acrylic protective device to reduce radiation exposure during Y-90 microspheres, but braking radiation was caused by Y-90, which emits high-energy beta-rays. Radiation dose rate refers to the radiation dose rate measured at a distance of 10 centimeters from the surface of the radioactive material, the container or device containing the radioactive material, the radiation generating device and the radiation shielding radiation). There is a problem.

Y-90 마이크로스피어의 조제 후 이동 및 시술 시 의료인의 피폭 저감을 위하여 제동 X선에 대한 별도의 차폐장치가 필요한 상황이다.Accordingly

A separate shielding device for braking X-rays is needed to reduce exposure of medical personnel during the movement and procedure of Y-90 microspheres.

Republic of Korea Patent Publication No. 10-2009-0057407 Republic of Korea Patent Publication No. 10-2017-0056044

Therefore, the technical problem of the present invention has been conceived in this respect, the object of the present invention is to shield the braking X-rays generated by the high-energy beta-ray-emitting radioisotope Y-90 and at the same time can be visually confirmed inside It relates to a shield.

Y-90 마이크로스피어가 수용된 바이알을 차폐하는 아크릴 보호 장치를 추가로 차폐하기 위한 차폐체에 있어서, 차폐 물질을 포함하고, 상부가 개구되어 상기 아크릴 보호 장치가 수용되는 수용공간을 구비하고, 측벽부의 일부가 개구된 몸체 차폐부 및 투명한 차폐 물질을 포함하고, 상기 몸체 차폐부의 개구된 측벽부를 밀폐하는 투명 차폐부를 포함한다.Shield for braking radiation shielding according to an embodiment for realizing the object of the present invention,

A shield for additionally shielding an acrylic protective device for shielding a vial containing a Y-90 microsphere, comprising: a shielding material, the upper portion of which has a receiving space for accommodating the acrylic protective device, the sidewall portion being provided A transparent shield comprising an open body shield and a transparent shielding material, and sealing the open sidewall of the body shield.

In one embodiment, the shielding material may be tungsten.

In one embodiment, the transparent shielding material may be lead glass.

In one embodiment, the body shield may be formed with an adhesive material on the inner surface.

In one embodiment, the bottom surface of the body shield may be formed with a protrusion having a diameter smaller than the diameter of the body shield portion to protrude into the groove of the transfer box.

In one embodiment, the diameter of the protrusion may be the same as the diameter of the acrylic protective device.

In one embodiment, the transparent shield may be formed in a square pillar shape having a predetermined thickness.

In an exemplary embodiment, the apparatus may further include an additional shielding portion covering the sidewall portion of the body shield portion, the sidewall portion of the transparent shielding portion, and a boundary portion between the sidewall portion of the body shielding portion and the sidewall portion of the transparent shielding portion to a predetermined thickness.

In one embodiment, the additional shield may seal the inside of the side facing the side wall portion of the body shield from the end of the outer surface of the transparent shield.

Y-90 마이크로스피어를 운반하는 과정에서 의료인의 피폭을 저감시킬 수 있다.According to embodiments of the present invention, it is possible to shield braking X-rays generated by high energy beta-ray emitting radioisotopes,

In transporting Y-90 microspheres, exposure to medical personnel can be reduced.

Y-90 마이크로스피어가 수용된 바이알을 차폐하는 아크릴 보호 장치를 도시한 사시도이다.
도 2는 도 1의 아크릴 보호 장치를 추가로 차폐하는 차폐체를 도시한 단면도이다.
도 3은 도 2의 차폐체를 도시한 단면도이다.
도 4는 도 3의 차폐체를 도시한 측면도이다.
도 5는 도 3의 차폐체를 도시한 상면도이다.
도 6은 도 3의 차폐체가 이송 박스에 수용된 상태를 도시한 단면도이다.
도 7은 본 발명의 다른 실시에에 의한 차폐체를 도시한 상면도이다.1

A perspective view of an acrylic protective device for shielding a vial containing a Y-90 microsphere.
FIG. 2 is a cross-sectional view showing a shield that further shields the acrylic protective device of FIG. 1. FIG.
3 is a cross-sectional view illustrating the shield of FIG. 2.
4 is a side view illustrating the shield of FIG. 3.
FIG. 5 is a top view illustrating the shield of FIG. 3. FIG.
6 is a cross-sectional view illustrating a state in which the shield of FIG. 3 is accommodated in a transfer box.
7 is a top view showing a shield according to another embodiment of the present invention.

As the inventive concept allows for various changes and numerous modifications, the embodiments will be described in detail in the text. However, this is not intended to limit the present invention to a specific disclosed form, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. In describing the drawings, similar reference numerals are used for similar elements. Terms such as first and second may be used to describe various components, but the components should not be limited by the terms.

The terms are used only for the purpose of distinguishing one component from another. The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

In this application, the terms "comprise" or "consist of" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

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

Y-90 마이크로스피어가 수용된 바이알을 차폐하는 아크릴 보호 장치를 도시한 사시도이다. 도 2는 도 1의 아크릴 보호 장치를 추가로 차폐하는 차폐체를 도시한 단면도이다. 도 3은 도 2의 차폐체를 도시한 단면도이다. 도 4는 도 3의 차폐체를 도시한 측면도이다. 도 5는 도 3의 차폐체를 도시한 상면도이다. 도 6은 도 3의 차폐체가 이송 박스에 수용된 상태를 도시한 단면도이다.1

A perspective view of an acrylic protective device for shielding a vial containing a Y-90 microsphere. FIG. 2 is a cross-sectional view showing a shield that further shields the acrylic protective device of FIG. 1. FIG. 3 is a cross-sectional view illustrating the shield of FIG. 2. 4 is a side view illustrating the shield of FIG. 3. FIG. 5 is a top view illustrating the shield of FIG. 3. FIG. 6 is a cross-sectional view illustrating a state in which the shield of FIG. 3 is accommodated in a transfer box.

Y-90 마이크로스피어(10)는 조제 후 환자의 종양 크기에 맞게 사전에 계산된 적정 용량만큼 바이알(vial, 20)에 수용된다. 상기 바이알(20)은 V형 바이알(V-vial)일 수 있으며, 아크릴(acrylic)을 포함하여 상기

Y-90 마이크로스피어에 의해 발생하는 제동복사선을 차폐할 수 있다. In general, as shown in FIG.

After preparation, the Y-90 microspheres 10 are housed in vials 20 by an appropriate amount previously calculated for the patient's tumor size. The vial 20 may be a V-type vial, and may include acrylic.

Braking radiation generated by Y-90 microspheres can be shielded.

Y-90 마이크로스피어(10)에 의해 발생하는 제동복사선을 추가로 차폐할 수 있다.The vial 20 may be housed inside the acrylic protective device 30 and moved for radioembolization. The acrylic protective device 30 includes acrylic contained in the vial 20

The braking radiation generated by the Y-90 microspheres 10 can be further shielded.

Y-90 마이크로스피어(10)를 차폐하는 경우, 상기

Y-90 마이크로스피어(10)가 고에너지의 베타선을 방출함에 따라 발생하는 제동복사에 의해 제동복사선이 방생할 수 있는 문제가 있다.However, as described above, only the vial 20 and the acrylic protective device 30

When shielding the Y-90 microsphere 10, the

There is a problem that the braking radiation may occur by the braking radiation generated as the Y-90 microsphere 10 emits high energy beta rays.

Y-90 마이크로스피어(10)에 의해 발생하는 제동복사선을 추가로 차폐함에 따라 방사선색전술의 시술 시 의료인의 피폭을 저감시킬 수 있게 된다. Therefore, in the present embodiment, as shown in FIG. 2, the shielding body 100 according to the present embodiment accommodates the acrylic protective device 30.

By additionally shielding the braking radiation generated by the Y-90 microspheres 10, it is possible to reduce the exposure of medical personnel during the procedure of radioembolization.

 More specifically, referring to FIGS. 3 to 5, the shield 100 according to the present embodiment includes a body shield 200 and a transparent shield 300.

The body shielding part 200 may be formed in a cylindrical shape, and an upper portion of the body shielding part 200 may be formed to include an accommodation space 210 in which the acrylic protection device 30 is accommodated.

That is, the body shielding portion 200 has a bottom surface has a circular plate shape, the circumference of the circular plate shape has a shape in which a side wall portion of a predetermined height is formed to open only the upper portion, the bottom of the body shielding portion 200 The accommodation space 210 is formed between the surface 201 and the side wall portion 203.

In addition, the body shield 200 may further shield the acrylic protective device 30 accommodated in the accommodation space 210 including a shielding material.

In this case, the body shield 200 may include tungsten having a high density and excellent shielding ability and low human hazard. In addition, boron (B), lithium (Li), gadolinium (Gd), and samarium ( Sm), one selected from the group consisting of europium (Eu), cadmium (Cd) and dysprosium (Dy) or a compound comprising the same or a mixture thereof, selected from the group consisting of lead (Pb) and iron (Fe) It is apparent that various shielding materials may be included, such as any one or compounds comprising the same or mixtures thereof.

On the other hand, the side wall portion 203 of the body shield 200 extends by a predetermined height only in a portion of the circumference of the circular plate shape, so that the body shield portion 200 is part of the side wall portion 203 is opened To achieve the desired shape.

The transparent shield 300 is located in the open side wall portion 203 of the body shield 200 to seal the open side wall portion 203 and at the same time, the acrylic protective device including a transparent shielding material (30) can be further shielded.

More specifically, the transparent shield 300 may be formed in a rectangular pillar shape having a predetermined thickness as shown in FIGS. 4 and 5 to completely seal the side wall portion 203.

Y-90 마이크로스피어(10)를 육안으로 확인할 수 있게 된다.In addition, as the transparent shield 300 is made of a transparent shielding material, as shown in FIG. 2, the acrylic protective device 30 accommodated in the accommodation space of the body shield 200 may be visually confirmed. . That is, even when the transparent shield 300 is optically transparent and the acrylic protective device 30 is shielded by the shield 100, the externally accommodated in the vial 20.

The Y-90 microspheres 10 can be visually confirmed.

In this case, the transparent shielding material may be, for example, lead glass. However, the present invention is not limited thereto, and the transparent shielding material may shield radiation and may include all materials made of a transparent material.

The shield 100 configured as described above may be accommodated in the transfer box 40 and transported to a procedure room for performing radioembolization, as shown in FIG. 6.

Y-90 마이크로스피어(10)를 상기 바이알(20)에 수용시킨 후 상기 바이알(20)을 상기 아크릴 보호 장치(30)에 투입하고, 상기 아크릴 보호 장치(30)를 상기 이송 박스(50)에 넣어 시술실로 운반하였다.Generally, the above

After the Y-90 microsphere 10 is accommodated in the vial 20, the vial 20 is put into the acrylic protective device 30, and the acrylic protective device 30 is transferred to the transfer box 50. It was carried to the procedure room.

In the present embodiment, in order to transport the shield 100 using the transfer box 50 used in the conventional manner, the body shield part is fixed to the inside of the transfer box 50. A protrusion 250 is formed on the bottom surface 201 of the 200 so that the protrusion 250 is inserted into a groove (not shown) formed at the bottom of the transfer box 50.

In this case, the protrusion 250 is formed to protrude from the bottom surface 201 of the body shield 200 with a diameter smaller than the diameter of the body shield 200.

In this case, in the related art, the groove formed in the transfer box 50 is formed in such a manner that the acrylic protective device 30 is directly inserted, so that the protrusion part 250 may have a diameter of the acrylic protective device 30. The same diameter can be inserted into the groove.

7 is a top view showing a shield according to another embodiment of the present invention.

Since the shield 500 according to the present embodiment is the same as the shield 100 described with reference to FIGS. 1 to 6 except that the shield 500 further includes an additional shield 600, the same reference numerals are used to overlap the shield 100. Description is omitted.

Referring to FIG. 7, an additional shield 600 including a shielding material may be formed on the sidewall 303 of the transparent shield 300. That is, the additional shield 600 includes the side wall 303 of the transparent shield 300 and the side wall portion of the body shield 200 adjacent to the transparent shield 300. It may be formed between the 203.

Thus, the additional shield 600 includes the side wall portion 203 of the body shield 200, the side wall 303 of the transparent shield 300, and the side wall portion of the body shield 200. The boundary of the sidewall 303 of the 303 and the transparent shield 300 may be covered with a predetermined thickness, and thus the braking radiation line 1 penetrating the boundary may be further shielded.

Furthermore, the additional shield 600 may seal the inside of the side facing the side wall portion 203 of the body shield 200 from the end of the outer surface of the transparent shield 300, and thus emitted The braking radiation line 2 which is not shielded by the transparent shield 300 by the direction can also be shielded.

In this case, the additional shield 600 may include a transparent shielding material, such as the transparent shield 300, may be composed of the same shielding material as the transparent shield 300, otherwise the body The shield 100 may include an opaque shielding material, and may be made of the same shielding material as the body shield 100.

Meanwhile, in the following, since Y-90 is a beta-ray (2.28 Mev) releasing nucleus, an external exposure is expected mainly during the distribution process, and the transportation of the distributed Y-90 is carried in a container provided by a sales company, so in the transportation process Since only a few beta rays are expected to be exposed, only exposures to the hands and skin were performed.

First, if you check the exposure dose (hand and skin) by Y-90 beta-ray, the beta-ray energy of this added Y-90 is 2.28 Mev, so be careful when handling it. In addition, sailors should not be buried in their hands.

Therefore, the external exposure following the handling of Y-90 by the operator was evaluated as follows.

The mass absorption coefficient of a particle that emits beta rays is given by the following equations.

는 베타선의 최대에너지이며, Y-90 베타선의 최대에너지 2.28MeV 이므로

,

이 된다.here,

Is the maximum energy of beta rays, and the maximum energy of Y-90 beta rays is 2.28 MeV

,

Becomes

On the other hand, if the radiation dose of the hands and skin is confirmed by Y-90 beta rays in the vial,

=

Particle Fluence Rate

=

Maximum radioactivity of Y-90 in vials:

The distance from the sailor in the vial to the hand: 10 cm

: 3mmThickness of vials

3 mm

:

Mass Absorption Coefficient of Glass

:

:

Density of glass

:

: 0.5인 경우,Sample self-absorption correction factor

Is 0.5,

The absorbed dose rate of the hands and skin by the Y-90 beta rays in the vial,

으로 주어진다.

Given by

Considering the self-absorption correction factor and attenuation by the vial

가 된다.

Becomes

Therefore, the absorbed dose rate of the hand and skin by the Y-90 beta rays in the vial is

이고,

ego,

The exposure dose of the hands and skin by the Y-90 beta in the vial is

이다.

to be.

의 1% 이하이다. This is the legal equivalent dose limit for workers' hands and skin

Is less than 1%.

Y-90 마이크로스피어의 용량에 따른 차폐율((차폐체 사용 전의 선량)-(차폐체 사용 후의 선량)/차폐체 사용 전의 선량)을 나타낸다. On the other hand, the following [Table 1] is shielded by the shield 100

The shielding rate ((the dose before using the shield)-(the dose after using the shield) / the dose before using the shield) according to the capacity of the Y-90 microsphere.

Y-90 마이크로스피어의 용량에 따른 차폐율TABLE 1

Shielding rate according to the capacity of Y-90 microspheres

Unit: μSv / h

Y-90 마이크로스피어는 상기 아크릴 보호 장치(30)로 부터 방출되는 표면방사선량률은 261.7 ± 2.3μSv/h(n=5)이었지만, 상기 차폐체(100)의 장착 후 방출되는 표면방사선량률은 23.7±1.3μSv/h(n=5)으로 표면방사선량률이 11배 감소하였다. Referring to Table 1, 4GBq (108.1 mCi) of

The Y-90 microsphere had a surface radiation dose rate of 261.7 ± 2.3 μSv / h (n = 5) emitted from the acrylic protective device 30, but the surface radiation dose rate emitted after mounting of the shield 100 was 23.7 ±. The surface radiation dose rate decreased by 11 times to 1.3 μSv / h (n = 5).

Y-90 마이크로스피어의 표면방사선량률은 128.3±10.9μSv/h(n=5)이었으나, 상기 차폐체(100)의 장착 후 표면방사선량률은 14.2±0.1μSv/h(n=5)으로 표면방사선량률이 9배 감소하였다.Also, 2 GBq (54.05 mCi)

The surface radiation dose rate of Y-90 microspheres was 128.3 ± 10.9μSv / h (n = 5), but the surface radiation dose rate after mounting of the shield 100 was 14.2 ± 0.1μSv / h (n = 5). This was a ninefold decrease.

In addition, the surface radiation dose rate of 1.5GBq (40.54 mCi) was 100.5 ± 1.5μSv / h (n = 5), but the surface radiation dose rate emitted after mounting of the shield 100 was 11.5 ± 0.2μSv / h (n = 5). ) Decreased 8.8 times.

In addition, the surface radiation dose rate of 1GBq (27.03 mCi) was 67.2 ± 0.8μSv / h (n = 5), but the surface radiation dose rate emitted after mounting of the shield 100 was 7.6 ± 0.1μSv / h (n = 5). 8.9-fold decrease.

As described above, the shielding body 100 according to the present embodiment can confirm that the surface radiation dose rate can be reduced. It can be used for radiation shielding such as X-rays generated by high energy beta rays.

Y-90 마이크로스피어를 운반하는 과정에서 의료인의 피폭을 저감시킬 수 있다.According to embodiments of the present invention, it is possible to shield braking X-rays generated by high energy beta-ray emitting radioisotopes,

In transporting Y-90 microspheres, exposure to medical personnel can be reduced.

While the foregoing has been described with reference to preferred embodiments of the present invention, those skilled in the art will be able to variously modify and change the present invention without departing from the spirit and scope of the invention as set forth in the claims below. It will be appreciated.

Y-90 마이크로스피어 20 : 바이알
30 : 아크릴 보호 장치 100, 500 : 차폐체
200 : 몸체 차폐부 300 : 투명 차폐부
600 : 추가 차폐부10:

Y-90 Microsphere 20: Vial
30: acrylic protective device 100, 500: shield
200: body shield 300: transparent shield
600: additional shield

Claims (9)

A shield for further shielding an acrylic protective device that shields a vial containing a Y-90 microsphere,
A body shield including a shielding material, an upper portion of which includes a receiving space for accommodating the acrylic protective device, and a portion of the sidewall portion opened;
A transparent shielding material including a transparent shielding material and sealing an open sidewall of the body shielding portion and having a square pillar shape; And
An additional shielding portion covering a sidewall portion of the body shielding portion, a sidewall portion of the transparent shielding portion, and a boundary portion between the sidewall portion of the body shielding portion and a sidewall of the transparent shielding portion to a predetermined thickness;
And wherein the additional shield extends from the end of the outer surface of the transparent shield toward the side wall of the body shield to form a surface, such that the boundary is covered by the additional shield having a predetermined thickness. The method of claim 1, wherein the shielding material,
The shield is tungsten. The method of claim 1, wherein the transparent shielding material,
Shielded body, characterized in that lead glass. The method of claim 1, wherein the body shield,
Shielding material, characterized in that the adhesive material is formed on the inner surface. The method of claim 1,
The bottom surface of the body shield portion, the shield having a diameter smaller than the diameter of the body shield portion protruding portion is characterized in that the projection is fitted into the groove of the transfer box. The method of claim 5,
And the diameter of the protrusion is the same as that of the acrylic protective device. delete delete delete

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