RU2533270C1 - Radiation sterilisation apparatus - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: radiation sterilisation apparatus comprises an electron accelerator, a beam scanning device, a biological protection device in the form of a thick-wall metal container surrounding the electron accelerator and the beam scanning device and which consists of separate units, an irradiation zone and a conveyor in the form of a carriage having a straight direction of movement and having irradiation zone protection units and a socket for sterilised articles in between, the upper and lower surfaces and the irradiation zone in the metal container of which have longitudinal teeth, oriented such that the teeth on one surface are located in grooves on a mating surface and vice versa. Units of the thick-wall metal container have labyrinth connections with each other, and an absorbent protective metal shield is placed between the accelerator and the beam scanning system.

EFFECT: radiation sterilisation apparatus provides biological protection of maintenance personnel, simplifies production and lowers costs.

2 dwg

Description

FIELD OF THE INVENTION

The invention relates to the field of medicine and the food industry. It can be used for sterilization of medical instruments, implantable products, medical materials and medical waste, as well as for sterilization and pasteurization of food and perfumery products. The invention is intended for use in enterprises producing disposable medical products, food and perfume products, as well as for use in clinics and hospitals.

State of the art

Radiation sterilization using ionizing radiation generated by an accelerated electron beam is a high-performance, most reliable and environmentally friendly way to sterilize products and materials. For radiation sterilization, various plant designs are used, each of which contains an electronic accelerator with a beam sweep system (a bell and a deploying magnet), a transport device, and biological protection of personnel from ionizing radiation. Existing sterilization plants used for industrial sterilization of serial products are located in special rooms where concrete walls up to 3 m thick serve as protection. They occupy large production areas, require the construction of a specialized room and high financial costs. The electron energy of the accelerators of such installations is usually of the order of 10 MeV. The range of doses used is 15-30 kGy. Radiation sterilization plants are also known, having an “individual” biological protection, which is made in the form of a thick-walled metal container, inside of which there is an electronic accelerator with a beam scanning system and one or more irradiated products. The electron energy of known accelerators with local protection is from 5 to 8 MeV. The range of doses used is 15-30 kGy. The challenge in developing installations with “individual” protection is to provide an acceptable dose of ionizing radiation outside the protection. In a sterilization unit, x-ray radiation is generated in the following devices:

- Accelerating resonator, in which part of the beam is lost during acceleration;

- A bell in which part of the beam is lost during the sweep;

- An irradiation chamber in which a beam of accelerated electrons is planted.

Typically, the dose rate in the irradiation zone exceeds the dose rate outside the protection allowed by sanitary standards for maintenance personnel by approximately 10 ⁷ times. The dose rate of 11.8 µSv / h is mandatory for permanent jobs for staff, where people are throughout the working day.

The closest in technical essence is the complex of radiation sterilization (Mironchik E. A., Mishchenko A.V., Pirozhenko V.M. “Complex of radiation sterilization”, patent of the Russian Federation N 2121369, priority from 09/22/97). The radiation sterilization complex contains an electron accelerator, a beam sweep device, a biological protection device in the form of a metal container covering an electron accelerator, a beam sweep device and an irradiation zone, and a transport device made in the form of a carriage having a rectilinear direction of movement and containing protective blocks and a socket for sterilized products between them, with the upper and lower surfaces of the protection units and the irradiation zone in a metal container made with longitudinal killers oriented in such a way that the teeth on one surface are in the grooves on the surface mating with it and vice versa. The product to be sterilized is introduced into the irradiation zone through the window in the container and is carried out under the sweep device using the carriage, while the protection blocks on the carriage block the window at any time: when loading the product into the socket, feeding it into the irradiation zone and the irradiation process. Longitudinal teeth on the surfaces of the protection units and the irradiation zone significantly reduce ionizing radiation through the gaps between these elements and allow not to turn off the accelerator during operation of the installation.

Biological protection in the form of a thick-walled metal container covering an electron accelerator, a beam sweep device and an irradiation zone, and a transport device must be made of separate blocks that allow installing an electron accelerator and a beam sweep device inside the container. Accordingly, there are gaps between the individual blocks. To reduce x-ray radiation through the gaps to a safe value for the operating personnel, the gap between the blocks should not exceed hundredths of a millimeter with the required thickness of the blocks from 250 to 600 mm (depending on the position of the block relative to the "ground"). In this case, the total weight of the blocks will be about 30 tons. With an increase in the gap, the thickness of the blocks should increase and, accordingly, the total weight of the protective container and its cost will increase. The high precision of manufacturing massive blocks also leads to an increase in cost, which is determined to a large extent by the requirement of obtaining minimum gaps between the blocks.

The bulk of the x-ray radiation in the accelerating cavity is generated at the end of the electron accelerator, in which the energy of the deposited electrons, for example, at an electron output energy of 5 MeV, is quite large - up to 2.3 MeV. At first, the radiation is much weaker, since the energy of the deposited electrons is less than 0.5 MeV. Since the beam of accelerated electrons has an energy spectrum, when the beam is scanned by a developing magnet, some of the electrons having lower energies are deposited on the walls of the socket, which also generates x-ray radiation. These facts also lead to an increase in the thickness of the container and its cost. The intensity of X-ray irradiation increases very rapidly with increasing electron energy. In the range of indicated energies, the x-ray intensity is approximately proportional to the electron energy in the third degree and in the forward direction is approximately 20 times greater than sideways and backward. For the installation, the intensity of the X-ray radiation forward is not very important, since with the usual arrangement of the installation on the ground floor, this radiation is directed down to the ground. Accordingly, this radiation weakly affects the safety of personnel.

SUMMARY OF THE INVENTION

An urgent problem at present is the creation of a complex for radiation sterilization using a beam of accelerated electrons, which could be located in any room of the enterprise without special building structures in the form of concrete walls up to 3 m thick to protect service personnel, would have a relatively low manufacturing cost, the lowest possible weight of the protective container, high performance, ease of maintenance, the ability to automate the production process.

It is advisable to make connections between the blocks of the metal protective container with labyrinths that impede the passage of x-ray radiation. In the energy range (5–8 MeV), x-ray radiation attenuates very strongly when reflected at a right angle — the reflection coefficient is about 0.01. Therefore, a complex labyrinth is not required to be done, just one step is enough. After two turns, the x-ray radiation is attenuated by approximately 10 ⁴ times. For reliable protection against x-ray radiation, the step height in the junction between the blocks should be at least 10 times greater than the possible slit width. The use of labyrinth compounds will significantly expand manufacturing tolerances. For example, a permissible slit width of the order of 1 mm may be adopted. Then the height of the step in the junction between the blocks can be made 10-20 mm. Thus, the introduction of the labyrinth compounds of the container blocks, firstly, eliminates x-ray radiation through the gaps between the blocks, and, secondly, allows to simplify the manufacture and reduce the cost of the container.

The bulk of the x-ray radiation in the accelerating cavity is generated in the last few cells of the cavity. When the beam is scanned by a developing magnet, some of the electrons having lower energies are deposited on the walls of the bell, which also generates x-ray radiation. Therefore, it is advisable to install a protective absorbing screen between the beam scanning system and the accelerator, which will significantly reduce x-ray radiation outside the thick-walled metal container. The screen is expediently made of lead. The use of the screen will make it possible to significantly reduce the thickness in the upper part of the shield, counting it only to attenuate x-ray radiation from beam losses in the accelerator.

Brief Description of the Drawings

Figure 1 - Installation of radiation sterilization (side view).

Figure 2 - Installation of radiation sterilization (front view).

The implementation of the invention

The installation contains the following devices:

- electron injector 1;

- accelerating resonator 2;

- magnet of the beam scanning system 3;

- bell of the beam scanning system 4;

- blocks of the metal container 5;

- protective metal screen;

- protective block of the irradiation zone 7;

- a transport device in the form of a carriage for moving the irradiated product and the protection units inside the metal container 8;

- the irradiated product 9.

The electron accelerator shown in figure 1, contains an electron injector (item 1) and an accelerating resonator (item 2). An electron beam sweep system is connected to the output end of the accelerating resonator, consisting of a sweep magnet (pos. 3) and a socket (pos. 4), so that its wide wall is perpendicular to the direction of movement of the carriage (pos. 7). The power of the electron injector is provided from the power supply system of the installation, not shown in the drawings. Microwave power is supplied to the accelerating resonator from a microwave generator, also not shown in the drawings. The accelerator is placed in a thick-walled metal container consisting of several blocks (item 5). The thickness of the metal container and the labyrinth structure of the blocks, as well as the absorbing protective metal screen (pos. 6), installed between the accelerating resonator and the bell, ensure the dose of ionizing radiation on the outer surface of the metal container at its minimum possible thickness, not exceeding the value acceptable for personnel. The carriage (pos. 7) has the possibility of translational movement to enter the sterilized product into the irradiation zone through a window in a metal container. The upper and lower surfaces of the blocks of protection of the irradiation zone (pos. 8) located on the carriage, as well as the upper and lower surfaces of the window and the irradiation zone, have longitudinal teeth. The cross section of the carriage and the block of protection of the irradiation zone is shown in figure 2. The teeth are arranged so that the teeth on the protection blocks are located in the grooves between the teeth of the window on the metal container and vice versa, and the gap between the gear surfaces in any position of the carriage is minimal.

When the unit is turned on, the electron accelerator accelerates the injected electron beam to a predetermined energy, and the scanning system deploys the beam along the wide wall of the socket (item 4). The sterilized product (pos. 9) is installed in the socket on the moving carriage between the protective blocks of the irradiation zone, which enters the metal container and moves the sterilized product under the accelerator and the beam sweep device at a speed for which the electron beam irradiates the sterilized product with the required radiation dose. After the entire sterilized product passes under the beam scanning device and its entire volume is irradiated, the carriage returns to its original position and the product is unloaded and a new one is loaded. Next, the cycle repeats. In all positions of the carriage, the window in the metal container is covered by blocks of protection of the irradiation zone (pos. 8).

Claims (1)

A radiation sterilization installation comprising an electron accelerator, a beam sweep device, a biological protection device in the form of a thick-walled metal container covering an electron accelerator and a beam sweep device and consisting of separate blocks, an irradiation zone and a transport device made in the form of a carriage having a rectilinear direction of motion and containing blocks of protection of the irradiation zone and a socket for sterilized products between them, the upper and lower surfaces of which and the irradiation zone in the metal container is made with longitudinal teeth oriented so that the teeth on one surface are in grooves on the surface mating with it and vice versa, characterized in that the blocks of the thick-walled metal container have labyrinth connections between themselves, and an absorbing protective shield is installed between the accelerator and the beam sweep system metal screen.

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