RU2400253C2 - Unit of radiation irradiation - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to technology of radiation treatment of different materials and can be applied in field of medicine and food industry. Unit of radiation irradiation consists of main module, module of inlet and module of outlet. Main module contains accelerator of electrons (1), case of biological protection (2) of accelerator and irradiation zone, tunnel (3) and work conveyer (4) of continuous movement of irradiation objects (5) through irradiation zone (6). Unit of radiation irradiation is also equipped with system of movement of irradiation objects, which contains module of inlet of irradiation objects onto work conveyer from loading zone and module of outlet of irradiation objects from work conveyer into unloading zone. Each of inlet and outlet modules includes case of biological protection (7, 14), reverse carriage (9, 16) and tunnel (8, 15) for movement of irradiation objects, longitudinal axes of tunnels of inlet and outlet modules being located perpendicularly to longitudinal axis of work conveyer tunnel.

EFFECT: invention allows to increase efficiency of electronic bundle application and radiation safety of servicing personnel.

6 cl, 6 dwg

Description

The technical field to which the invention relates.

The invention relates to the field of medicine, food industry and processing technology for various materials. It can be used to sterilize medical materials, implanted products, medical instruments and medical waste, to sterilize and pasteurize food and perfume products, as well as to irradiate different materials with accelerated electrons in order to give them new properties. The invention is intended for use in enterprises producing disposable medical products, food and perfume products, as well as in enterprises related to the manufacture and processing of materials.

The level of technology.

For radiation exposure of objects, various radiation sources are used. The most developed method of radiation exposure to accelerated electron beams, as the most reliable high-performance and environmentally friendly.

Each complex of radiation exposure of this type has an emitter (high-frequency electron accelerator), an irradiation zone, biological protection from the ionizing radiation of the accelerator and the irradiation zone, and a transport system for supplying objects to the irradiation zone. In domestic and foreign practice, complexes of radiation exposure using an accelerated electron beam are conventionally divided into two categories. The first category usually includes complexes where electron beam accelerators with an energy of 10 MeV or higher and an average beam power of 10 kW are used. Existing complexes of this category are located in special rooms where concrete walls up to 2.8 m thick serve as protection. They occupy large production areas and require large capital expenditures for the construction of the bunker. Transportation of objects to and from the irradiation zone is carried out through labyrinth channels, which are designed to reduce the dose rate of ionizing radiation from the hopper to an acceptable value. The following complexes can be considered closest to the first category in technical parameters:

1. IMPELA (Gerald E. Hare. IMPRELA Electron Accelerators for Industrial Radiation Processing. "Radiat", Phys. Chem ", vol. 35, no. 4-6, p. 619-626, 1990).

2. I-Ax Technologies Radiation Processing http: // www, iaxtech. com / more, html.

3. Moscow Radio Engineering Institute of the Russian Academy of Sciences. Industrial sterilization accelerator installation "Sterus-1" http: //www.mrtiran: ru / index.id = 74php? Language = ru & page = prdetailed & id = 74.

The second category includes complexes where electron beam accelerators with energies below 5-7 MeV and average power below 3 kW are used. The radiation exposure units in these complexes, as a rule, have a local bioprotection, inside of which there is a high-frequency linear electron accelerator, a tunnel, an irradiation zone, and a system for moving irradiated objects from the loading zone through the irradiation zone to the discharge zone. The material for the biological protection enclosure is usually steel or cast iron. The radiation exposure unit has a mass of 20-27 tons, an area of 10-15 square meters. m and a height of 2.5-2.7 m. The radiation exposure unit, together with the high-frequency power equipment of the electron accelerator and automated control, can be installed in any room, including temporary, which does not require additional costs for biosecurity. The small dimensions of the unit allow its use in the technological lines of product production directly at the manufacturer.

The following complexes, where local bioprotection of electron accelerators is used, can be considered analogues of the invention.

1. Bidnyy et al. Conveyer-type Unit Radiation Sterilization. US Patent 5,554,856. Priority Date Nov.1 1993y.

2. Mirrochnik EA, Mishchenko AV, Pirozhenko VM Complex radiation sterilization. Patent for invention No. 2121369. Priority 09/22/97.

3. Stirling Andrew J. Hare Gerald E. Irradiation Apparatus for Production Line Use. US Patent 6,191, 424. Filing Date 02.20.1998.

In the radiation exposure blocks of these complexes under the accelerated electron beam in the irradiation zone, the irradiated objects (useful use of the electron beam) and bioprotection elements located between these objects alternately move. According to various estimates, in such systems the useful life of the electron beam is from 70 to 85%.

In analogue 1, the biological protection housing contains a transport device in the form of a cylinder, which rotates by means of a drive around its longitudinal axis. The cylinder has two platforms on which the irradiated objects are placed. When the cylinder rotates, objects move to and from the irradiation zone.

In analogue 2, in the biological protection enclosure there is a tunnel in which the transport device is a carriage. The carriage has protective blocks and platforms for moving the irradiated objects into the irradiation zone. At any position of the carriage, the blocks provide biosecurity against ionizing radiation along the tunnel. For example, when a linear accelerator with an electron beam energy of 5 MeV and an average power of 2 kW is installed in the radiation exposure unit, the length of the protective unit along the tunnel is 0.6 m. When the carriage moves along the tunnel under the electron beam in the irradiation zone, the irradiated objects are alternately irradiated (useful use of the beam) and protective blocks (the beam is absorbed by the metal). Stopping the carriage in the extreme positions for loading and unloading the platforms also reduces the useful use of the beam.

In analogue 3, a conveyor is installed in the tunnel of the biosecurity enclosure, consisting of a group of carriages designed to move radiation objects through the radiation zone. Each carriage front and rear has a screen that provides biosecurity against ionizing radiation along the tunnel, and a socket for accommodating the irradiated object. With an accelerator with an energy of 5 MeV and an average beam power of 2 kW, the total thickness of the carriage screens, which are located both at the input and output sections of the tunnel, should be 0.6 m. This ensures a reduction in the dose rate of ionizing radiation by a factor of 10 to obtain a dose value, acceptable for staff. With such a transport system moving continuously, only part of the electron beam is used to irradiate the object, and the rest is absorbed by the screens of the carriages. According to the authors of the invention of analogue 3, the useful use of the electron beam here is 25-50% (www.mevex.com/does/Scorpio.pdf). Thus, the conveyor of analogue 3 has the same drawback as the carriage in analogue 2. The conveyor of analogue 3, consisting of a large number of carriages, has a significant mass and length. In this case, only a small part of the carriages located in the tunnel is used to protect against radiation.

In radiation irradiation units with local biosecurity, having straight tunnels with an irradiation zone and systems for moving irradiated objects into the irradiation zone, it is not possible to provide absolute protection against ionizing radiation through structural gaps between the walls of the tunnels and the moving protection elements of the transport systems. This drawback is inherent in analogue 2 and analogue 3, since in the first case there are structural gaps between the fixed walls of the tunnel and the movable protective blocks of the reversible carriage, and in the second case between the fixed walls of the tunnel and the protective shields of the carriages.

The creation of high-performance complexes with an increased degree of biological protection in the areas of loading and unloading of irradiated objects remains an urgent problem in the technique of radiation exposure. The creation of automated systems for moving irradiated objects, where irradiated objects continuously pass through the irradiation zone, makes it possible to almost completely use the electron beam directly for irradiating objects.

When irradiated with an electron beam, each object should receive a standardized dose that is uniform throughout the volume. In radiation exposure units, where one electron accelerator is installed, in order to ensure a normalized dose that is uniform throughout the volume, it is necessary to irradiate each object from two opposite sides.

Disclosure of the invention.

The radiation irradiation unit contains an electron accelerator, a system for moving irradiated objects from the loading zone through the irradiation zone to the unloading zone, the biological protection housing of the accelerator and the irradiation zone, the biological protection housing having a tunnel, characterized in that the tunnel contains a working conveyor for continuously moving irradiated objects through the irradiation zone, the system for moving the irradiated objects further comprises a module for entering the irradiated objects onto the working conveyor from the loading zone and an exit irradiation objects from the working conveyor to the unloading zone, each of which includes a biological protection enclosure, a reverse carriage and a tunnel for moving the irradiated objects, and the longitudinal axes of the tunnels of the input and output modules are perpendicular to the longitudinal axis of the tunnel of the working conveyor.

Each carriage contains three movable protective blocks and two platforms for irradiated objects, and each carriage is configured to move input and output modules in tunnels.

The input module and the output module contain a biological protection enclosure, a tunnel for moving radiation objects, two movable protection units that open alternately the passage through the tunnel, and one carriage with a platform moving the training object from the loading zone to the working conveyor or from the working conveyor to the unloading zone.

The input module contains a device for moving irradiated objects from the carriage platform to the working conveyor, and the output module contains a device for moving irradiated objects from the working conveyor to the carriage platform.

The biological protection enclosures of the input module and output module contain plugs located in the alignment of the tunnel of the working conveyor.

One of the plugs is mechanically connected with the working conveyor and can be moved together with it beyond the limits of the radiation exposure unit for adjusting the conveyor, and the second plug, when extended beyond the module, allows you to install a sensor in the irradiation zone for measuring the parameters of the electron beam.

The task of increasing the efficiency of using the electron beam can be solved by continuous (close to each other) moving radiation objects through the radiation zone. The movement of any biosecurity elements through the irradiation zone should be excluded.

The task of increasing the degree of bioprotection from ionizing radiation from the irradiation zone can be solved by installing special protective devices with tunnels for moving radiation objects located at an angle to the tunnel, where radiation treatment of radiation objects takes place. In addition to bioprotective functions, these devices must also combine the functions of moving radiation objects from the loading zone to the tunnel with the radiation zone and from this tunnel to the discharge zone.

The radiation exposure unit consists of a main radiation exposure module, side biosecurity modules of the input and output of the main module, a manipulator (Fig. 1). The figure 2 shows a General view of the unit of radiation exposure (front view and top view). The main module of the radiation exposure unit consists of a radiation source (high-frequency electron accelerator) 1, a biological protection enclosure 2, a tunnel of the main module 3, a working conveyor 4 for continuous movement of irradiation objects 5 through the irradiation zone 6. The lateral biosecurity module consists of a biological protection enclosure 7 inside which the tunnel 8 and the reversible carriage 9 are located. The carriage consists of three movable protective blocks 10 and two platforms 11. In the module case there is a device 12 for moving objects about wandering from the carriage platforms to the working conveyor 4. In the case of the input biosecurity module there is a plug 13 located in the section of the tunnel of the main module and mechanically connected to the working conveyor 4. The lateral exit biosecurity module consists of a biological protection housing 14, inside of which the tunnel 15 and the reverse carriage 16. The carriage consists of three movable protective blocks 17 and two platforms 18. In the module case there is a device 19 for moving the irradiated objects from the working conveyor 4 to the carriage platforms 16. In the module case I biosecurity output there is a plug 20, located in the alignment of the tunnel of the main module, which allows you to install and maintain sensors for measuring the parameters of the electron beam in the irradiation zone. The moving device 12 and 19 change the direction of movement of the irradiated objects. This can be provided by linear movement mechanisms, such as actuators, hydraulic or pneumatic pushers, screw gears.

The radiation exposure unit contains a manipulator 21, which transmits a one-sided irradiated object from the output carriage 16 to the input carriage 9 with a simultaneous flip for re-irradiating the object from the opposite side.

An alternative lateral bioprotection module is shown in figure 3. It contains a bioprotection case 22, a tunnel 23, one movable block 24, a carriage 25, which consists of a protective block 26 and a platform 27. Figures 3a, 3b, 3c, 3g are shown in longitudinal section carriage 25 and block 24 as the irradiation object moves from the loading zone to the target of the tunnel 3 of the main module. The figure 3D shows a top view of the module.

Figure 4 shows a second alternative lateral bioprotection module, which comprises a bioprotection housing 28, a tunnel 29, two movable blocks 30 and 31, and one carriage 32. Figures 4a, 46, 4b, 4g show in longitudinal section the position of the carriage 31, the movable blocks 29 and 30 as the carriage with the irradiated object moves from the loading zone to the target of the tunnel 3 of the main module. Figure 4e shows a top view of the module.

Side entry biosecurity modules are structurally similar to side exit biosecurity modules. In the proposed technical solutions, movable elements (carriages, movable protective blocks) can have a mass of 600 kg to 1 tone. However, modern low-power drives of 0.5-0.75 kW are able to move these masses from one extreme position to another in a time of 2-5 seconds with a positioning accuracy of 1-2 mm.

In the radiation exposure unit (figure 2) there is a tunnel with an irradiation zone. The tunnel contains a working conveyor for continuously moving irradiated objects through the irradiation zone, and the system for moving irradiated objects additionally contains a module for entering irradiated objects onto the working conveyor from the loading zone and a module for exiting the irradiated objects from the working conveyor into the unloading zone, each of which includes a reversible biological protection casing a carriage and a tunnel for moving irradiated objects, the longitudinal axis of the entry and exit tunnels being perpendicular to the longitudinal axis of the working tunnel onveyera.

The continuous movement of the irradiated objects through the irradiation zone is ensured by the complete absence in the tunnel of the main module of bioprotection elements and the speed of the carriages and moving blocks of the side bioprotection modules. Thus, it is possible to increase the useful life of the electron beam to a maximum value.

In the proposed technical solution of the radiation exposure unit, the tunnels of the side bioprotection modules are located perpendicular to the tunnel of the main module. Due to this, it is possible to exclude direct ionizing radiation from the irradiation zone through the gaps between the movable bioprotection elements in the tunnels and the housings of the side bioprotection modules, since direct ionizing radiation is converted to scattered radiation. The dose rate of ionizing radiation when the tunnels are rotated 90 degrees is reduced by 300 - 500 times. This allows you to significantly reduce ionizing radiation in the loading and unloading areas of the radiation exposure unit and to reduce the thickness of the protective blocks in the tunnels of the input and output biosecurity modules.

The use of lateral entry and exit bioprotection modules in radiation exposure units ensures continuous movement of radiation objects through the exposure zone and eliminates the use of bulky and expensive labyrinth protective and transport systems, as well as improves radiation safety.

Another feature of the presented radiation exposure unit with a conveyor for continuous processing of irradiation objects and input and output bioprotection modules are small dimensions. For example, a radiation exposure unit with a linear electron accelerator with an energy of 5 MeV and an average beam power of 2 kW occupies an area of not more than 20 square meters. m, and the height does not exceed 2.5 m.

A brief description of the drawings.

Figure 1 The division diagram of the block of radiation exposure.

Figure 2. General view of the radiation exposure unit with the main radiation exposure module, input biosecurity module and output biosecurity module of the main module (front and top views).

Figure 3 An alternative lateral biosecurity module of a radiation exposure unit with two movable protective blocks and one carriage.

Figure 4 Alternative lateral biosecurity module of the radiation exposure unit with one movable protective unit and one carriage

Figure 5. The extreme operating positions of the carriages of the input biosecurity module and the output biosecurity module.

Figa, 6b, 6c. The positions of the elements of the transport system when moving the irradiated objects from the loading zone through the irradiation zone to the unloading zone.

The implementation of the invention.

In the process, the carriage of the biosecurity modules of the input and output periodically occupy two extreme positions A and B (Fig. 5). In position A, a new irradiation object is loaded onto the platform 1 of the input carriage and unloading the completely irradiated object from the platform 4 of the output carriage. In position B, the unilaterally irradiated object is reloaded from platform 3 to platform 2 to re-irradiate the object from the opposite side.

6a, 6b, 6c show the positions of each irradiated object when it is moved from the loading zone through the biosecurity module of the entrance to the working conveyor of the tunnel of the main module into the radiation zone, where the object is initially unilaterally irradiated, through the biosecurity module of the exit to the reset zone, then to the module biosecurity of the entrance and further to the working conveyor into the irradiation zone, where the object is re-irradiated from the opposite side, then through the biosecurity module of the exit to the unloading zone. It is clear from the figure that for any position of the reverse carriages 9 and 16, biosecurity is provided against scattered radiation from the tunnel of the main module. At manufacturers, all products subject to radiation processing are packed in containers (cardboard boxes, bags, special containers), each container has its own identification number.

The figure 6 adopted the following conventions:

unirradiated object

one side irradiated object

two-sided object

The numbers 1, 2, 3 mean the identification number of the irradiated object.

загружается на платформу 1.Pos. 1. Entrance carriage in position A. Object

loaded onto platform 1.

в створе тоннеля главного модуля.Pos. 2. Entrance carriage in position B. Object

in the alignment of the tunnel of the main module.

перемещается на рабочий конвейер к зоне облучения.Pos. 3. An object

moves to the working conveyor to the irradiation zone.

проходит зону облучения. Каретка входа в положении.Pos. 4. An object

passes the irradiation zone. Entrance carriage in position.

загружается на платформу 1.An object

loaded onto platform 1.

в створе тоннеля главного модуля.Pos. 5. Entrance carriage in position B. Object

in the alignment of the tunnel of the main module.

проходит зону облучения.An object

passes the irradiation zone.

. Одновременно объект

перемещается с платформы 1 к зоне облучения.Pos. 6. Exposure to the object has ended

. Object at the same time

moves from platform 1 to the irradiation zone.

перемещается на платформу 3.Pos. 7. Exit carriage in position A. Object

moves to platform 3.

проходит зону облучения.An object

passes the irradiation zone.

проходит зону облучения.Pos. 8. Exit carriage in position B. Object

passes the irradiation zone.

проходит зону облучения. Объект

перемещается с платформы 3 каретки выхода на платформу 2 каретки входа.Pos. 9. An object

passes the irradiation zone. An object

moves from the platform 3 of the exit carriage to the platform 2 of the input carriage.

. Объект

на платформе 2 в створе тоннеля главного модуля. Объект

загружается на платформу 1.Pos. 10. Exposure to the object ends

. An object

on platform 2 in the alignment of the tunnel of the main module. An object

loaded onto platform 1.

. Одновременно объект

перемещается с платформы 2 к зоне облучения.Pos. 11. Exposure of the object has ended

. Object at the same time

moves from platform 2 to the irradiation zone.

после облучения перемещается на платформу 3 каретки выхода.Pos. 12. An object

after irradiation, it moves to the platform 3 of the exit carriage.

.Re-exposure of the object begins

.

.Pos. 13. Exit carriage in position B. Re-exposure of the object has ended

.

перемещается с платформы 1 к зоне облучения.Object at the same time

moves from platform 1 to the irradiation zone.

перемещается на платформу 4 каретки выхода. Начинается облучение объекта

. Объект

перемещается с платформы 3 каретки выхода на платформу 2 каретки входа.Pos. 14. An object

moves to platform 4 of the exit carriage. The irradiation of the object begins

. An object

moves from the platform 3 of the exit carriage to the platform 2 of the input carriage.

.Pos. 15. Entrance and exit carriages in position A. Object irradiation ends.

.

. Одновременно объект

перемещается с платформы 2 к зоне облучения. Производится загрузка объекта

на платформу 1 и разгрузка объекта

с платформы 4.Pos. 16. Exposure to the object has ended

. Object at the same time

moves from platform 2 to the irradiation zone. Loading object

to platform 1 and unloading the facility

from platform 4.

в створе тоннеля главного модуля. Объект

перемещается на платформу 3 каретки входа. Начинается повторное облучение объекта

. Объект

в створе тоннеля главного модуля.Pos. 17. Entrance carriage in position B. Object

in the alignment of the tunnel of the main module. An object

moves to platform 3 of the input carriage. Re-exposure of the object begins

. An object

in the alignment of the tunnel of the main module.

.Pos. 18. Exit carriage in position B. Object irradiation has ended

.

перемещается с платформы 1 к зоне облучения.Object at the same time

moves from platform 1 to the irradiation zone.

перемещается на платформу 4 каретки выхода. Начинается облучение объекта

. Объект

перемещается с платформы 3 каретки выхода на платформу 2 каретки входа.Pos. 19. An object

moves to platform 4 of the exit carriage. The irradiation of the object begins

. An object

moves from the platform 3 of the exit carriage to the platform 2 of the input carriage.

. Производится загрузка объекта

на платформу 1 и разгрузка объекта

с платформы 4.Pos. 20. Entrance and exit carriages in position A. Object irradiation ends.

. Loading object

to platform 1 and unloading the facility

from platform 4.

. Одновременно объект

перемещается с платформы 2 к зоне облучения.Pos. 21. Exposure to the object has ended

. Object at the same time

moves from platform 2 to the irradiation zone.

Further, the operation of the system is repeated with the same cycle.

Claims (6)

1. The radiation exposure unit containing an electron accelerator, a system for moving irradiated objects from the loading zone through the irradiation zone to the discharge zone, the biological protection housing of the accelerator and the radiation zone, the biological protection housing having a tunnel, characterized in that the tunnel contains a continuous conveyor irradiation objects through the irradiation zone, the system for moving irradiated objects additionally contains a module for inputting irradiated objects to the working conveyor from the loading zone and an output module and irradiating objects with the working of the conveyor in the unloading area, each of which comprises a biological protection enclosure, and reversing the carriage to move the irradiation tunnel of objects, wherein the longitudinal axes of entry and exit tunnels modules are arranged perpendicular to the longitudinal axis of the working of the tunnel conveyor. 2. The radiation exposure unit according to claim 1, characterized in that each carriage contains three movable protective blocks and two platforms for objects of irradiation, each carriage made with the possibility of movement in the tunnels of the input and output modules. 3. The radiation exposure unit according to claim 1, characterized in that the input module and the output module comprise a biological protection housing, a tunnel for moving the irradiated objects, additionally two movable protection units that open alternately the passage through the tunnel, and one carriage with a platform moving the object irradiation from the loading zone to the working conveyor or from the working conveyor to the unloading zone. 4. The radiation exposure unit according to claim 1, characterized in that the input module comprises a device for moving radiation objects from the carriage platform to the working conveyor, and the output module contains a device for moving radiation objects from the working conveyor to the carriage platform. 5. The radiation exposure unit according to claim 1, characterized in that the biological protection enclosures of the input module and the output module contain plugs located in the alignment of the tunnel of the working conveyor. 6. The radiation exposure unit according to claim 5, characterized in that one of the plugs is mechanically connected to the working conveyor and can extend with it outside the radiation exposure unit for adjustment of the conveyor, and the second plug when extending beyond the module allows in the irradiation zone install a sensor for measuring the parameters of the electron beam.

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