CN111603623A

CN111603623A - Automatic continuous medical blood irradiation equipment and blood irradiation treatment method

Info

Publication number: CN111603623A
Application number: CN202010538083.5A
Authority: CN
Inventors: 孔昊天; 熊雁斌
Original assignee: Shanghai Ruichu Testing Technology Co ltd
Current assignee: Shanghai Ruichu Testing Technology Co ltd
Priority date: 2020-06-12
Filing date: 2020-06-12
Publication date: 2020-09-01

Abstract

The invention discloses automatic continuous medical blood irradiation equipment, which comprises a shielding box and an auxiliary shielding box; a first input device and a first output device which are arranged up and down are arranged in the shielding box, a second input device and a second output device which are arranged up and down are arranged in the auxiliary shielding box, and a third input device and a third output device which are arranged up and down are arranged outside the auxiliary shielding box; a transfer device corresponding to the first input device and the first output device is arranged in the shielding box; an irradiation source is arranged in the shielding box; and the auxiliary shielding box is internally provided with a visual scanning device. The invention can automatically and uninterruptedly irradiate the blood bag and can automatically track the irradiation start time, the irradiation end time, the irradiation dose and the like of the blood bag. The consistency of the irradiation dose of the blood bag of the system is good and far superior to the requirement of national regulation (20 percent).

Description

Automatic continuous medical blood irradiation equipment and blood irradiation treatment method

Technical Field

The invention relates to the technical field of medical equipment, in particular to automatic continuous medical blood irradiation equipment and a blood irradiation treatment method.

Background

Transfusion-associated graft-versus-host disease (TA-GVHD) is a fatal complication of transfusion in which immunocompetent lymphocytes in transfused blood cannot be removed, transplanted in vivo, proliferated, identified as non-self substances in tissues and organs of a patient, and targeted for immune attack and destruction. The clinical manifestations of TA-GVHD lack specificity, and are easy to miss diagnosis and misdiagnose.

Irradiation of blood products prior to transfusion is currently considered to be the only effective method for preventing TA-GVHD. The blood irradiator is a medical device which uses rays to irradiate blood products, inactivates lymphocytes and prevents TA-GVHD diseases (transfusion-related graft-versus-host disease) in transfusion activities; the mechanism is as follows: lymphocytes are sensitive to radiation, and by irradiation with radiation of appropriate dose, immunocompetent lymphocytes can be inactivated and lose their proliferative capacity. But has little influence on the functions of red blood cells and platelets and the activity of blood coagulation factors.

From the ray source, the blood irradiator can be divided into two types, one is to irradiate the blood product with gamma rays generated by the radioactive source (mainly Cs-137 and Co-60), and the other is to irradiate the blood product with X rays generated by the X-ray tube.

Radioactive source type blood irradiator apparatuses require the assembly of several hundred to thousands of curie isotope radioactive sources, which presents a potential risk of nuclear leakage. The X-ray source type blood irradiator has no risk of nuclear leakage, but no radiation is generated when the apparatus is powered off.

In summary, the disadvantages of the prior art are as follows:

1) the existing X-ray blood irradiation instrument device adopts a blood cup as a container of a blood bag, such as CN206652034U, a plurality of blood bags are stacked after being placed in the blood cup, and the blood bags cannot be placed in the blood cup without air gaps, so that the difference between the actual irradiation dose of the blood bag in the blood cup and the dose in a theoretical state is too large. Even if the blood cup is placed without air gaps, the irradiation dose deviation of the blood bag in the blood cup is larger than 10%.

2) The existing irradiators can be used intermittently, namely, the equipment needs to be stopped after a sample finishes irradiation, and can be started again for irradiation after the sample is replaced, so that the working efficiency is low.

3) The existing national regulation blood bags are provided with codes, and the existing equipment is in work, the codes are not input or are input manually, so that the error probability is very high.

Disclosure of Invention

The invention aims to provide automatic continuous medical blood irradiation equipment and a blood irradiation treatment method, which solve the problems of low efficiency of the conventional irradiation equipment and non-uniform irradiation dose of a blood bag.

In order to achieve the purpose, the invention adopts the following technical scheme:

an automatic continuous medical blood irradiation device is characterized by comprising a shielding box and an auxiliary shielding box; a first input device and a first output device which are arranged up and down are arranged in the shielding box, a second input device and a second output device which are arranged up and down are arranged in the auxiliary shielding box, and a third input device and a third output device which are arranged up and down are arranged outside the auxiliary shielding box; the first input device, the second input device and the third input device are on the same horizontal plane, and the first output device, the second output device and the third output device are on the same horizontal plane; a transfer device corresponding to the first input device and the first output device is arranged in the shielding box; an irradiation source corresponding to the first input device and the first output device is arranged in the shielding box; and the auxiliary shielding box is internally provided with a visual scanning corresponding to the second input device and the second output device.

Preferably, the transfer device comprises a transfer base arranged in the shielding box, a transverse rotating shaft is arranged on the transfer base, and an L-shaped transfer plate is arranged on the connecting shaft; one end of the L-shaped transfer plate is positioned in the middle of one end of the first input device and one end of the first output device.

Preferably, the L-shaped transfer plate comprises a transverse plate and a vertical plate, and the vertical plate is positioned at one end of the transverse plate, which is far away from the first input device and the first output device; the connecting shaft is connected to the middle position of the transverse plate.

Preferably, the transfer device comprises a lifting platform arranged in the shielding box, and the lower end of the lifting platform is connected with a lifting cylinder; the lifting platform is provided with a transfer frame, and a plurality of transfer shafts which are arranged in parallel and can rotate are arranged on the transfer frame; all the transfer shafts are connected with a transfer belt together; the transfer frame is provided with a transfer motor which is connected with one of the transfer shafts in a transmission way.

Preferably, the first input device, the second input device and the third input device are identical in structure; the first input device comprises a first input frame, and a plurality of first input shafts which are arranged in parallel and can rotate are arranged on the first input frame; all the first input shafts are connected with a first input conveyor belt; the first input frame is provided with a first input motor, and the first input motor is in transmission connection with one of the first input shafts.

Preferably, the first output means, the second output means and the third output means are identical in structure; the first output device comprises a first output frame, and a plurality of first output shafts which are arranged in parallel and can rotate are arranged on the first output frame; all the first output shafts are connected with a first output conveyor belt; the first output frame is provided with a first output motor, and the first output motor is in transmission connection with one of the first output shafts.

Preferably, a first shielding door is arranged on a secondary shielding box between the third input device and the second input device; a second shielding door is arranged on the shielding box between the second input device and the first input device; a third shielding door is arranged on the shielding box between the first output device and the second output device; and a fourth shielding door is arranged on the auxiliary shielding box between the second output device and the third output device.

Preferably, the shielding box is provided with an industrial personal computer, and the industrial personal computer is respectively connected with a first input device, a second input device, a third input device, a first output device, a second output device, a third output device, a transfer device, an irradiation source, a visual scanning device, a first shielding door, a second shielding door, a third shielding door and a fourth shielding door.

The invention also provides an automatic continuous medical blood irradiation treatment method, which is characterized by comprising the following steps:

s0: selecting an irradiation box and an irradiation dose to be scanned in a computer, and automatically adjusting the position of a radioactive source in the vertical direction and the speed of a conveyor belt in a shielding box by a system according to the selected parameters;

s1, fixing the first input device, the second input device, the third input device, the first output device, the second output device, the third output device, the transfer device, the irradiation source and the visual scanning in the shielding box and inside and outside the auxiliary shielding box; installing a second shielding door and a third shielding door on one side surface of the shielding box close to the auxiliary shielding box, and installing a first shielding door and a fourth shielding door on the outer side surface of the auxiliary shielding box; the blood bag is arranged in a customized irradiation box, and the irradiation box is firstly placed on a third input device;

s2, starting a third conveying device to convey by an industrial personal computer, wherein the irradiation box firstly passes through the first shielding door, and the other three shielding doors are closed at the moment; after the irradiation box enters a second input device in the auxiliary shielding box, the first shielding door is closed, the other three shielding doors are also closed, the visual scanning work is carried out, and data are transmitted to the industrial personal computer;

s3, after the visual scanning work is finished, the industrial personal computer controls to open the second shielding door, and the other three shielding doors are closed; conveying the irradiation box to a first conveying device; the irradiation source works, and the second shielding door is closed; then opening a first shielding door, and allowing the next irradiation box to enter a second input device in the auxiliary shielding box through the first shielding door for visual scanning;

s4, after the irradiation source is finished, the first conveying device and the transfer device work to transfer the irradiation box to the first output device;

s5, opening the second screen door and the third screen door, conveying the irradiation box to the second output device, and simultaneously conveying the next irradiation box to the first input device; next, closing the second shielding door and the third shielding door; then opening the first shielding door, and enabling another irradiation box to enter a second input device through the first shielding door;

s6, opening a fourth shielding door, conveying the finished irradiation box to a third output device, completing the whole irradiation process and taking down the irradiation box; at the same time, the transfer is completed in the shielding box, and the above-described operation is repeated.

The platelets or fresh blood are mixed with lymphocytes, and the allogenic lymphocytes enter the body of a patient with low immunity to cause the occurrence of transfusion-related graft-versus-host disease (TA-GVHD), and the serious degree can cause the death of the patient. Irradiation of blood products prior to transfusion is currently considered to be the only effective way to prevent TA-GVHD. The mechanism is as follows: lymphocytes are sensitive to radiation, and by irradiation with radiation of appropriate dose, immunocompetent lymphocytes can be inactivated and lose their proliferative capacity. The radiation with proper dose has little influence on the functions of red blood cells and platelets and the activity of blood coagulation factors. Therefore, after sufficient radiation of platelets or fresh blood, lymphocytes with immunological activity in the blood can be effectively inactivated, thereby greatly reducing the incidence rate of GVHD and ensuring the safety of blood transfusion.

The X-ray spectrum consists of a continuous spectrum and a marking spectrum, the content of a low-energy part in the spectrum is more, and the low-energy part is easily absorbed by a large amount of superficial blood in the process of irradiating blood or blood products, so that the quantity of X photons reaching the deep part is rapidly reduced. The ray propagation of the X-ray source type blood irradiator follows the following formula

The radiation dose is therefore also inversely related to the square of the distance of the radiation source. In order to ensure the quantity of single irradiation, the existing equipment mostly adopts a cylinder mode and places most blood bags into a cylinder. This results in the radiation penetrating the blood in the cylinder to a great thickness, which makes the irradiation dose hard to meet the requirement of the blood irradiator standard for the uniformity of the radiation (the national standard requires the non-uniformity of the irradiation of the blood irradiator<20%). The blood bag is placed in the irradiation box and irradiated on the platform, so that the thickness of the blood bag in the vertical direction of rays is reduced, and the nonuniformity of actual blood irradiation in irradiation is far less than 20% specified by national standards.

Due to the adoption of the technical scheme, compared with the prior art, the invention has the beneficial effects that:

the invention can automatically and uninterruptedly irradiate the blood bag and can automatically track the irradiation start time, the irradiation end time, the irradiation dose and the like of the blood bag. The consistency of the irradiation dose of the blood bag of the system is good and far superior to the requirement of national regulation (20 percent).

Drawings

FIG. 1 is a schematic structural diagram of an automatic continuous medical blood irradiation apparatus according to a first embodiment of the present invention;

FIG. 2 is a schematic structural diagram of an automatic continuous medical blood irradiation apparatus according to a second embodiment of the present invention;

fig. 3 is a schematic structural view of the L-shaped transfer plate in fig. 1.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Example 1

As shown in fig. 1 and 3, an automatic continuous medical blood irradiation apparatus includes a shielding box 9 and a sub-shielding box 14.

The shielding box 9 is internally provided with a first input device and a first output device which are arranged up and down, the auxiliary shielding box 14 is internally provided with a second input device and a second output device which are arranged up and down, and the auxiliary shielding box 14 is externally provided with a third input device 1 and a third output device 13 which are arranged up and down. The first input device, the second input device and the third input device 1 are on the same horizontal plane, and the first output device, the second output device and the third output device 13 are on the same horizontal plane.

A transfer device 15 corresponding to the first input device and the first output device is arranged in the shielding box 9.

And an irradiation source 8 corresponding to the first input device and the first output device is arranged in the shielding box 9. The secondary shielding box 14 is provided with a visual scan 5 corresponding to a second input device and a second output device.

The transfer device comprises a transfer base 12 arranged in the shielding box 9, a transverse rotating shaft 11 is arranged on the transfer base 12, and an L-shaped transfer plate 10 is arranged on the connecting shaft 11. One end of the L-shaped transfer plate 10 is located at the middle position of one end of the first input device and the first output device. The L-shaped transfer plate comprises a transverse plate 102 and a vertical plate 101, and the vertical plate 101 is located at one end, away from the first input device and the first output device, of the transverse plate 102. The connecting shaft 11 is connected to the middle position of the transverse plate 102. The transfer device uses the lever principle, and the transverse plate 102 is tilted at ordinary times and the vertical plate is sunk due to the vertical plate 101. When the irradiation box is transferred, the irradiation box 2 falls on the transverse plate, the transverse plate is just pressed down, and the vertical plate is tilted. Because the cross plate is not provided with the barriers of the irradiation box, the irradiation box can naturally fall onto the first output device. After the irradiation box leaves the horizontal plate 102, the horizontal plate 102 tilts again under the action of the gravity of the vertical plate 101 to wait for the transfer of the next irradiation box. The structure completely depends on gravity, does not need mechanical force intervention, has low cost and can be used for a long time.

The first, second and third input devices 1 are identical in structure. The first input device comprises a first input frame, and a plurality of first input shafts which are arranged in parallel and can rotate are arranged on the first input frame; all the first input shafts are connected with a first input conveyor belt; the first input frame is provided with a first input motor, and the first input motor is in transmission connection with one of the first input shafts. The specific structure of the second input device and the third input device 1 is described in the first input device, and can be easily implemented by those skilled in the art, so that the detailed description is omitted.

The first, second and third output means 13 are identical in structure. The first output device comprises a first output frame, and a plurality of first output shafts which are arranged in parallel and can rotate are arranged on the first output frame; all the first output shafts are connected with a first output conveyor belt; the first output frame is provided with a first output motor, and the first output motor is in transmission connection with one of the first output shafts. The specific structure of the second output device and the third output device 13 is described in the description of the first output device, and can be easily implemented by those skilled in the art, so that the detailed description is omitted.

A first shielding door 4 is arranged on a secondary shielding box 14 between the third input device 1 and the second input device; a second shielding door 6 is arranged on a shielding box 9 between the second input device and the first input device; a third shielding door 7 is arranged on a shielding box 9 between the first output device and the second output device; a fourth shielding door 3 is arranged on the auxiliary shielding box 14 between the second output device and the third output device 13. The four shielding doors can be opened in sequence under the control of the industrial personal computer and cannot be opened simultaneously, so that the shielding doors are greatly reduced, and even the radiation leakage is completely shielded, the radiation work quality is ensured, and the safety of workers is also protected.

The shielding box is provided with an industrial personal computer, and the industrial personal computer is respectively connected with a first input device, a second input device, a third input device 1, a first output device, a second output device, a third output device 13, a transfer device 15, an irradiation source 8, a visual scanning 5, a first shielding door 4, a second shielding door 6, a third shielding door 7 and a fourth shielding door 3.

Example 2

As shown in fig. 2, an automatic continuous medical blood irradiation apparatus includes a shielding box 9 and a sub-shielding box 14.

The transfer device 15 comprises a lifting platform arranged in the shielding box 9, and the lower end of the lifting platform is connected with a lifting cylinder; the lifting platform is provided with a transfer frame, and a plurality of transfer shafts which are arranged in parallel and can rotate are arranged on the transfer frame. All the transfer shafts are connected with a transfer belt together; the transfer frame is provided with a transfer motor which is connected with one of the transfer shafts in a transmission way. The structure comprises the cylinder and the motor, the motor can rotate forwards and reversely, smooth transmission is guaranteed, and efficient work can be achieved under the control of the industrial personal computer.

The invention also provides an automatic continuous medical blood irradiation treatment method, which comprises the following steps:

s1, fixing the first input device, the second input device, the third input device, the first output device, the second output device, the third output device, the transfer device, the irradiation source and the visual scanning in the shielding box and inside and outside the auxiliary shielding box; installing a second shielding door and a third shielding door on one side surface of the shielding box close to the auxiliary shielding box, and installing a first shielding door and a fourth shielding door on the outer side surface of the auxiliary shielding box; the blood bags were packed in a custom irradiation cassette that was first placed on the third input placement.

S2, starting a third conveying device to convey by an industrial personal computer, wherein the irradiation box firstly passes through the first shielding door, and the other three shielding doors are closed at the moment; after the irradiation box enters the second input device in the auxiliary shielding box, the first shielding door is closed at the moment, other three shielding doors are also closed, and the industrial personal computer is conveyed with data in visual scanning work.

S3, after the visual scanning work is finished, the industrial personal computer controls to open the second shielding door, and the other three shielding doors are closed; conveying the irradiation box to a first conveying device; the irradiation source works, and the second shielding door is closed; and then opening the first shielding door, and allowing the next irradiation box to enter a second input device in the auxiliary shielding box through the first shielding door for visual scanning work.

And S4, after the irradiation source works, the first conveying device and the transfer device work to transfer the irradiation box to the first output device.

S5, opening the second screen door and the third screen door, conveying the irradiation box to the second output device, and simultaneously conveying the next irradiation box to the first input device; next, closing the second shielding door and the third shielding door; the first screen door is then opened and a further cassette passes through the first screen door onto the second input device.

The irradiation source and the visual scanning in the invention are existing devices and have been sold in the market for a long time. The invention only utilizes the equipment, necessary improvement is carried out, and the effect of optimizing the work is achieved. The irradiation source, the internal structure of the visual scanning, the working principle and the connection relationship belong to the prior art and are not described in detail.

The invention is a blood irradiation device with excellent irradiation dose uniformity, which can work continuously and can track the coding of blood bags.

The invention has the advantages that:

1) the efficiency is higher, and the equipment can run uninterruptedly.

2) And the irradiation uniformity of the blood bag is high.

3) The blood bag state can be monitored and tracked systematically.

The object of the invention can be achieved without other alternatives.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. An automatic continuous medical blood irradiation device is characterized by comprising a shielding box (9) and a secondary shielding box (14);

a first input device and a first output device which are arranged up and down are arranged in the shielding box (9), a second input device and a second output device which are arranged up and down are arranged in the auxiliary shielding box (14), and a third input device (1) and a third output device (13) which are arranged up and down are arranged outside the auxiliary shielding box (14); the first input device, the second input device and the third input device (1) are on the same horizontal plane, and the first output device, the second output device and the third output device (13) are on the same horizontal plane;

a transfer device (15) corresponding to the first input device and the first output device is arranged in the shielding box (9);

an irradiation source (8) corresponding to the first input device and the first output device is arranged in the shielding box (9); and the auxiliary shielding box (14) is internally provided with a visual scanning device (5) corresponding to a second input device and a second output device.

2. The automatic continuous medical blood irradiation equipment as claimed in claim 1, wherein the transfer device comprises a transfer base (12) installed in the shielding box (9), a transverse rotating shaft (11) is installed on the transfer base (12), and an L-shaped transfer plate is installed on the connecting shaft (11); one end of the L-shaped transfer plate is positioned in the middle of one end of the first input device and one end of the first output device.

3. The automatic continuous medical blood irradiation equipment of claim 2, wherein the L-shaped transfer plate comprises a horizontal plate (102) and a vertical plate (101), the vertical plate (101) is located at one end of the horizontal plate (102) far away from the first input device and the first output device; the connecting shaft (11) is connected to the middle position of the transverse plate (102).

4. The automatic continuous medical blood irradiation equipment as claimed in claim 1, wherein the transfer device (15) comprises a lifting platform installed in the shielding box (9), and the lower end of the lifting platform is connected with a lifting cylinder; the lifting platform is provided with a transfer frame, and a plurality of transfer shafts which are arranged in parallel and can rotate are arranged on the transfer frame; all the transfer shafts are connected with a transfer belt together; the transfer frame is provided with a transfer motor which is connected with one of the transfer shafts in a transmission way.

5. An automatic continuous medical blood irradiation equipment according to claim 3 or 4, characterized in that the first, second and third input devices (1) are identical in structure; the first input device comprises a first input frame, and a plurality of first input shafts which are arranged in parallel and can rotate are arranged on the first input frame; all the first input shafts are connected with a first input conveyor belt; the first input frame is provided with a first input motor, and the first input motor is in transmission connection with one of the first input shafts.

6. An automated continuous medical blood irradiation apparatus according to claim 5, wherein the first output device, the second output device and the third output device (13) are identical in structure; the first output device comprises a first output frame, and a plurality of first output shafts which are arranged in parallel and can rotate are arranged on the first output frame; all the first output shafts are connected with a first output conveyor belt; the first output frame is provided with a first output motor, and the first output motor is in transmission connection with one of the first output shafts.

7. An automatic continuous medical blood irradiation equipment according to claim 6, characterized in that a first shielding door (4) is arranged on the secondary shielding box (14) between the third input device (1) and the second input device; a second shielding door (6) is arranged on a shielding box (9) between the second input device and the first input device; a third shielding door (7) is arranged on a shielding box (9) between the first output device and the second output device; and a fourth shielding door (3) is arranged on a secondary shielding box (14) between the second output device and the third output device (13).

8. The automatic continuous medical blood irradiation equipment of claim 7, wherein an industrial personal computer is arranged on the shielding box, and the industrial personal computer is respectively connected with the first input device, the second input device, the third input device (1), the first output device, the second output device, the third output device (13), the transfer device (15), the irradiation source (8), the visual scanning device (5), the first shielding door (4), the second shielding door (6), the third shielding door (7) and the fourth shielding door (3).

9. An automatic continuous medical blood irradiation treatment method is characterized by comprising the following steps:

s1, fixing the first input device, the second input device, the third input device (1), the first output device, the second output device, the third output device (13), the transfer device (15), the irradiation source (8) and the visual scanning device (5) in the shielding box (9) and inside and outside the auxiliary shielding box (14); installing a second shielding door (6) and a third shielding door (7) on one side surface of a shielding box (9) close to a secondary shielding box (14), and installing a first shielding door (4) and a fourth shielding door (3) on the outer side surface of the secondary shielding box (14); the blood bag is arranged in a customized irradiation box (2), and the irradiation box (2) is firstly placed on a third input place;

s2, starting a third conveying device to convey through an industrial personal computer, wherein the irradiation box (2) firstly passes through the first shielding door (4), and the other three shielding doors are closed at the moment; after the irradiation box (2) enters a second input device in the auxiliary shielding box (14), the first shielding door (4) is closed, other three shielding doors are also closed, the visual scanning (5) works, and data are transmitted to the industrial personal computer;

s3, after the visual scanning (5) is finished, the industrial personal computer controls to open the second shielding door (6), and the other three shielding doors are closed; the irradiation box (2) is conveyed to a first conveying device; the irradiation source (8) works, and the second shielding door (6) is closed; then, a first shielding door (4) is opened, and the next irradiation box enters a second input device in the auxiliary shielding box (14) through the first shielding door to perform visual scanning (5) work;

s4, after the irradiation source (8) finishes working, the first conveying device and the transfer device work to transfer the irradiation box (2) to the first output device;

s5, opening the second screen door (6) and the third screen door (7), conveying the irradiation box (2) to the second output device, and simultaneously conveying the next irradiation box to the first input device; next, closing the second shielding door (6) and the third shielding door (7); then, opening a first shielding door (4), and enabling another irradiation box to enter a second input device through the first shielding door (4);

s6, opening the fourth shielding door (3), conveying the finished irradiation box (2) to a third output device, completing the whole irradiation process and taking down the irradiation box; at the same time, the transfer is completed in the shielding box (9), and the above operation is repeated.