KR102257191B1 - Radiation shielding door - Google Patents

Abstract

The present invention relates to a radiation shielding door device for reducing the radiation exposure dose of a patient, and more specifically, scattered neutrons and radiation (gamma rays, electron beams, etc.) that are essential in addition to therapeutic neutrons in the course of cancer treatment using boron neutron capture It relates to a radiation shielding door device for reducing a patient's radiation exposure dose so that the patient's damage can be reduced by minimizing the exposure dose of the patient.
That is, the present invention is further provided with a radiation shielding door at the rear end of the collimator used for boron neutron capture method cancer treatment, the radiation shielding door; A door body made of a radiation shielding material and divided into two sides, an opening/closing means installed on one side of the door body to automatically open and close the door, and a neutron beam of the collimator at the abutting position when the door body is closed. It is characterized in that a through hole is formed so as to be able to do so.

Description

Radiation shielding door device for reducing radiation exposure dose of patients

The present invention relates to a radiation shielding door device for reducing the radiation exposure dose of a patient, and more specifically, scattered neutrons and radiation (gamma rays, electron beams, etc.) that are necessarily accompanied in addition to therapeutic neutrons in the course of cancer treatment of the boron neutron capture method. It relates to a radiation shielding door device for reducing a patient's radiation exposure dose so that the patient's damage can be reduced by minimizing the exposure dose of the patient.

Boron Neutron Capture Therapy (BNCT) is when a drug containing boron is injected into the body of a cancer patient in advance, boron accumulates in the cancer cells. It induces a nuclear reaction of neutrons. This is a treatment that effectively kills only cancer cells by destroying the DNA of the cancer cell nucleus by the irradiated neutrons.

The devices used for this boron neutron capture method are largely divided into an incident device, a proton accelerator, a neutron generator, and a treatment facility.

① The incident device is composed of an ion source and a beam transport system, and is used as a duoplasmatron suitable for high current proton production to draw protons with a peak current of 50 mA at 50 kV and send them to the beam transport system. In the beam transport system, the proton beam is focused by the proton accelerator under suitable incident conditions. Provided by molding.

② The proton accelerator is a device that accelerates the proton beam received from the incident device to generate energy up to 10 MeV, and proton accelerators of various principles are used.

③ The neutron generator consists of a beam line, a beryllium target, and a deceleration assembly. When a proton beam accelerated to about 10 MeV is provided and irradiated to the beryllium (Be) target, it is converted into a high-speed neutron beam by a (p,n) nuclear reaction. The beam is decelerated to an extrathermal neutron suitable for patient treatment through the deceleration assembly.

④ The treatment facility is composed of a treatment table that fixes the patient and an irradiation position alignment device, and treatment is performed by irradiating extrathermal neutrons from the neutron generator to the affected area of the cancer patient.

Among the treatment facilities, the neutron beam from the neutron generator is irradiated to the patient through the beam port of the collimator. However, even if the beam port is configured to transmit neutrons intensively only to the treatment area of the patient, there is a problem that may be exposed by scattered neutrons and scattered radiation (gamma rays, electron beams, etc.) in addition to the necessary neutrons.

In this regard, there are some technologies related to cancer treatment using the boron neutron capture method in Korea, but the technology for minimizing the radiation exposure generated from the collimator used in the boron neutron capture method is not currently being studied. to be.

KR 10-1194652 KR 10-1403662 KR 10-0768944

The present invention has been devised to solve the above problems, and by further installing a radiation shielding door at the rear end of the collimator, the radiation generated in the rest of the collimator except for the beam port of the collimator is not transmitted to the patient, and the radiation An object of the present invention is to provide a radiation shielding door device for reducing the radiation exposure dose of a patient so that the adverse effect on the patient can be minimized by configuring the internal structure of the shielding door as a multi-layered structure effective for radiation shielding.

The present invention is further provided with a radiation shielding door at the rear end of the collimator used for boron neutron capture method cancer treatment, the radiation shielding door; A door body made of a radiation shielding material and divided into both sides, an opening/closing means installed on one side of the door body to automatically open and close the door, and a neutron beam of the collimator at the abutting position when the door body is closed. It is characterized in that a through hole is formed so as to be able to do so.

In addition, the door body; A first shielding part made of aluminum on the inner side, a second shielding part made of a composite structure layer of PE and lead material on the outer side of the first shielding part, and a third shielding part made of steel on the outer side of the second shielding part; It is characterized in that it is composed of

In addition, the second shielding portion; A primary PE shielding layer made of a PE material is formed on the inner side, a lead shielding layer made of a lead material is formed on the outer side of the primary PE shielding layer, and a secondary PE shielding layer made of a PE material is formed on the outer side of the lead shielding layer; It is characterized in that it is composed of

In addition, a beam opening and closing door that can be opened and closed manually or automatically is further installed in the through hole.

In addition, the opening and closing means; A guide part installed horizontally on the upper part of the door body, a rinsing part coupled to the door body so that the door body can be guided along the guide part, and a rinsing part coupled to the rinsing part and moving along the guide part as a power source of the driving motor. It is characterized in that it consists of; a power transmission device that controls so that the

The present invention has an effect of preventing radiation generated from the rest of the collimator from being transmitted to the patient except for the beam port of the collimator by further installing a radiation shielding door at the rear end of the collimator.

In addition, the present invention effectively shields scattered neutrons and radiation (gamma rays, electron beams, etc.) by complexly configuring the door body constituting the shielding door with a shielding layer made of materials such as aluminum, PE, lead, and steel, thereby adversely affecting the patient. has the effect of minimizing

1 is a side view showing an installation structure of a radiation shielding door device for reducing radiation exposure dose of a patient according to the present invention;
Figure 2 is a front view showing the overall structure of the radiation shielding door of the present invention;
3 is a cross-sectional view showing the internal structure of the door body constituting the present invention;
4 is an enlarged view showing the configuration of the opening and closing means constituting the present invention;
5 is a view showing a state in which the door body is opened and closed through the opening and closing means of the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

The collimator used in the conventional boron neutron trapping method of cancer treatment does not have any means for a separate radioactive shielding, so in addition to the therapeutic neutron delivered through the beam port of the collimator, scattered neutrons and scattered radiation (gamma rays, electron beams) etc.), there is a problem that the patient is exposed during treatment.

Therefore, in the present invention, as shown in FIG. 1, the radiation shielding door 100 is further installed at the rear end of the collimator (A) used for cancer treatment of the boron neutron capture method, so that the radiation shielding effect is maintained as it is. It is configured to solve the harmful problem caused by

The configuration of the radiation shielding door 100 according to the present invention is made of a radiation shielding material and divided into both sides as shown in FIGS. 1 and 2, and the door body 200 is installed on one side of the door body 200 The opening and closing means 300 for automatically opening and closing the door, and the through-hole 400 so that the neutron beam of the collimator (A) can pass through the contact position when the door body 200 is closed; characterized.

The door body 200 of the present invention consists of a pair and is divided into both sides, and is installed in a form in which opening and closing of the door body 200 is possible through the opening and closing means 300 . And the material of the door body 200 is made of a material that can shield the radiation.

In addition, a through hole 400 is formed in the center of the door body 200 to allow the neutron beam of the collimator A to pass therethrough. The through-holes 400 are preferably formed at positions facing each other when the door body 200 is closed. That is, with the door body 200 closed, radiation harmful to the patient is shielded through the door body 200 , and the neutron beam required for the patient is transmitted through the through hole 400 so that treatment is performed.

As shown in FIG. 3 , the door body 200 has a first shielding part 210 made of aluminum on the inside, and a composite structure layer made of PE and lead on the outside of the first shielding part 210 , as shown in FIG. 3 . and a second shielding part 220 made of a, and a third shielding part 230 made of a steel material on the outside of the second shielding part 220 . In the above description, the inward direction means the inside of the radiation shielding door 100 where the collimator A is installed, and the outward direction means the outside of the radiation shielding door 100 in which the patient to be treated is.

The first shielding part 210 is a shielding layer disposed on the innermost side of the door body 200 while performing a neutron shielding function because the degree of radiation by neutrons is the lowest compared to other metals due to the characteristics of the aluminum material. ) to support the

The second shielding part 220 is made of a composite structure layer of a PE material and a lead material. PE: In the case of polyethylene, it plays a role of reducing and shielding neutron energy, and in the case of lead (Pb), it has a function of shielding gamma rays generated during the neutron beam generation process.

As shown in the drawing, the preferred structure of the second shielding part 220 is a primary PE shielding layer 221 made of a PE material is formed on the inside, and a lead material on the outside of the primary PE shielding layer 221 is formed. of a lead shielding layer 222 is formed, and on the outside of the lead shielding layer 222, a secondary PE shielding layer 223 made of a PE material;

That is, it has a structure in which the primary PE shielding layer 221 and the secondary PE shielding layer 223 are disposed on the inside and outside of the lead shielding layer 222, and the neutron shielding is made secondary. The shielding effect can be further improved. And the lead shielding layer 222 is to shield the gamma radiation generated in the first shielding portion 210 and the primary PE shielding layer 221 corresponding to the previous step.

The thickness of the primary PE shielding layer 221, the lead shielding layer 222, and the secondary PE shielding layer 223 is preferably made of 20 mm, respectively.

The third shielding part 230 is made of a steel material, and serves to fix and support the first shielding part 210 and the second shielding part 220 , and the first shielding part 210 and the second shielding part 220 . It is preferable to be formed in a shape surrounding the side of the part 220 .

And when the reinforcing frame 240 is further coupled to the inner and outer sides of the second shielding part 220 , the strength of the door body 200 can be further increased. That is, the reinforcement frame 240 is installed between the first shielding part 210 and the second shielding part 220 , and the reinforcement frame 240 is also installed between the second shielding part 220 and the third shielding part 230 . This will be the installed structure.

In addition, when a beam opening and closing door (not shown) that can be opened and closed manually or automatically is further installed in the through hole 400, the beam opening and closing door is opened during the treatment process, and when the treatment is not performed, the beam opening and closing door By closing the through hole 400 can be configured to be shielded.

The opening/closing means 300 of the present invention is configured to automatically open and close the door body 200, and as shown in FIG. 2, a guide part 310 installed horizontally on the upper part of the door body 200, and the guide A rinsing unit 320 coupled to the door body 200 so that the door body 200 can be guided along the portion 310, and a rinsing unit coupled to the rinsing unit 320 as a power source of the driving motor M. and a power transmission device 330 for controlling the 320 to move along the guide part 310 .

Since the door body 200 of the present invention is a pair of left and right, the configuration of the hanger 320 and the power transmission device 330 also has a left and right symmetric structure.

The hanger 320 is a structure coupled to the left and right sides of one door body 200, respectively, and the door body 200 is pulled to the left or right by the operation of the power transmission device 330. will be moving

When describing the configuration of the power transmission device 330 in more detail, the driving sprocket 331 installed on both sides of the guide part 310 and rotating by the driving motor M, and the guide part 310, respectively. It consists of a driven sprocket 332 installed in the center, and a guide chain 333 fastened to the driving sprocket 331 and the driven sprocket 332, and one side of the guide chain 333 is one door body ( 200 ) is fixed to the left rinsing unit 320 , and the other side of the guide chain 333 is fixed to the right rinsing unit 320 .

That is, the guide chain 333 is not continuously connected, and both ends of the guide chain 333 are fixed to the rinsing unit 320 in different directions as shown in FIG. 4 .

In addition, the driven sprocket 332 has to have the two sprockets independently rotating since the guide chains 333 on both sides must be fastened to each other.

Although the present invention has been described above with reference to the above embodiments, it goes without saying that various modifications are possible within the scope of the technical spirit of the present invention.

A: Collimator 100: Radiation shielding door
200: door body 210: first shielding part
220: second shielding part 221: primary PE shielding layer
222: lead shielding layer 223: secondary PE shielding layer
230: third shield 240: reinforcing frame
300: opening and closing means 310: guide part
320: refusal to rinse 330: power transmission device
331: drive sprocket 332: driven sprocket
333: guide chain 400: through hole
M : drive motor

Claims (5)

A radiation shielding door 100 is further installed at the rear end of the collimator (A) used for cancer treatment of the boron neutron capture method,
The radiation shielding door 100 is;
The door body 200 made of a radiation shielding material and divided into both sides,
an opening/closing means 300 installed on one side of the door body 200 to automatically open and close the door;
A through hole 400 is formed so that the neutron beam of the collimator (A) can pass through the door body 200 at the abutting position when the door body 200 is closed;
The door body 200 is;
Inside the first shielding portion 210 made of aluminum,
On the outside of the first shielding part 210, a second shielding part 220 made of a composite structure layer of a PE material and a lead material;
Radiation shielding door device for reducing radiation exposure of a patient, characterized in that it is composed of a third shielding part 230 made of steel on the outside of the second shielding part 220
delete The method of claim 1,
The second shielding portion 220;
A primary PE shielding layer 221 made of a PE material is formed inside,
A lead shielding layer 222 made of lead is formed on the outside of the primary PE shielding layer 221,
On the outside of the lead shielding layer 222, a secondary PE shielding layer 223 made of PE material; a radiation shielding door device for reducing radiation exposure of a patient, characterized in that it is composed of
The method of claim 1,
A radiation shielding door device for reducing radiation exposure of a patient, characterized in that a beam opening and closing door is further installed in the through hole 400 to be opened and closed manually or automatically
The method of claim 1,
The opening and closing means 300 is;
a guide part 310 installed horizontally on the upper part of the door body 200;
a rinsing part 320 coupled to the door body 200 so that the door body 200 can be guided along the guide part 310;
A power transmission device 330 coupled to the rinsing part 320 and controlling the rinsing part 320 to move along the guide part 310 as a power source of the driving motor M; Radiation shielding door device to reduce radiation exposure dose of

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