RU2589025C2 - Radiation treatment unit with input and output modules - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to radiation treatment of various objects and can be used in medicine, food industry and processing of various materials. Unit for radiation treatment of objects with a beam of accelerated electrons consists of a radiation source (high-frequency electron accelerator) with electron beam scanning device, radiation zone and bin radiation protection of deceleration radiation accelerator and radiation area. Hopper includes tunnel inlet treatment objects in irradiation area and tunnel outlet for discharge of objects from irradiation area, conveyor for moving treatment objects through irradiation area and output conveyor for movement of objects from irradiation area. Radiation treatment unit includes inlet module of treatment objects and module output treatment objects. Said modules are intended for radiation protection of deceleration radiation through channels and simultaneously for transportation of objects exposure to places of loading-unloading conveyor inlet and outlet of hopper. Input and output modules consist of case radiation protection, reverse carriage and carriage reverse drive. Radiation treatment units with one source of radiation are equipped with transport systems providing irradiation of treatment objects from two opposite sides.

EFFECT: technical result is high efficiency of using electron beam and radiation protection, reduced area occupied by radiation protection unit.

4 cl, 4 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 for sterilization of medical materials, implantable products, medical instruments and medical waste, for sterilization and pasteurization of food and perfumery products, as well as for processing various 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 associated with the manufacture and processing of materials.

The level of technology.

For radiation treatment of objects, various radiation sources are used. The most developed method of radiation processing by accelerated electron beams, as the most reliable high-performance and environmentally friendly method of radiation processing. At industrial enterprises, radiation treatment is carried out at special production complexes. In large industrial complexes of radiation processing as radiation sources in most cases high-frequency high-energy linear electron accelerators with a beam energy of 10 MeV and an average power of 10 kW are used.

Each production complex of radiation processing of this type consists of a radiator (high-frequency high-energy electron accelerator) with an electron beam sweep device, an irradiation zone, radiation protection blocking radiation from a radiation hazardous zone caused by inhibitory radiation from the accelerator and an irradiation zone, the complex also includes a transport system to move processing objects from the loading zone through the radiation hazardous zone. The bunker contains two openings for input and output of radiation treatment objects. The thickness of the concrete radiation protection of the hopper is 2-2.5 meters.

According to the results of research conducted by INTECH CJSC, currently in more than 50 countries ~ 900 centers and facilities based on electron accelerators and ~ 400 based on isotopic gamma sources for radiation sterilization of medical devices and food processing with a total volume of hundreds of billions of dollars of processed products. The most typical examples of radiation protection using labyrinths and transport systems built into them can be considered:

IAEA Standards. IAEA Safety Standards. Radiation Safety of Gamma, Electron and X Ray Irradiation Facilities. Specific Safety Guide. No.SSG-8. FIG. 4., FIG. 5.

2. IMPEJA Accelerators IOTRON Industries Canada / USA Inequality Electron Beam Service, http / www.iotron.com / impela-accelerators /.

3. The complex of the Moscow Radio Engineering Institute of the Russian Academy of Sciences. Industrial sterilization installation "Sterus-1" http: /www.mrtiran.ru.

4. www.rad04.com/ electron accelerator LLC "RAD".

5. CJSC INTECH Radiation sterilization at an electron accelerator.

When designing radiation protection, the main initial parameter is the value of the radiation dose rate. When designing labyrinth channels as elements of radiation protection, cross sections of channels are additionally taken into account. The cross sections of the channels are determined by the cross section of the radiation treatment object, the cross section of the transport device, and the cross section of the opening for servicing the transport system in the channels (2-4 square meters). In this case, the cross section of the actual object of processing is a very small fraction of the cross section of the channel. Significant cross-sections of the channels lead to an increase in the length and number of turns of the maze.

It is known that radiation protection accounts for a significant share of the costs in the construction of radiation treatment complexes. Volumes of protective materials for labyrinths and the area they occupy, as a rule, significantly exceed the volume of materials. The area of the actual radiation protection of the radiation hazardous zone, the accelerator and the irradiation zone is 10-15% of the total protection area (bunker, labyrinth channels).

To move objects of radiation processing through the labyrinths and the irradiation zone, multi-link roller conveyors (live rolls), belt, chain, cable conveyors, and suspended conveyors are usually used. All of them are mounted on special frames and consist of a significant number of nodes and parts. All these devices are usually located in a horizontal plane and have significant dimensions. According to the design features on these transport systems moving at a constant speed, the processing objects are located at some intervals from each other. The electron beam is used effectively only when the object itself passes through the irradiation zone, and when the gap between the objects passes, the beam is used inefficiently, as it is absorbed by the conveyor and radiation protection. The loss of the electron beam is 20-50%.

When irradiated with an electron beam, each object should receive a standardized dose that is uniform throughout the volume. For medical facilities, food products of both animal and plant origin, increased requirements for dose uniformity are imposed. These requirements can only be fulfilled by irradiating the object from two opposite sides. In radiation treatment units, where one electron accelerator is installed, each object after unilateral irradiation must be turned 180 degrees relative to the axis of the electron beam and moved through the irradiation zone for reprocessing from the opposite side. In analogue (2), the objects are flipped manually. This creates a risk of irreparable violation of the radiation exposure regulations. In radiation treatment units, where two electron accelerators are installed, directed towards each other, the object is processed in one pass through the irradiation zone. The installation of two electron accelerators directed towards each other provides a twofold increase in the complex’s performance, but this practically does not lead to an increase in the cost of the radiation protection bunker.

It is urgent to create radiation treatment complexes in which, along with high requirements for the effectiveness of radiation protection, the volume of its construction and cost are significantly reduced. The problem in the radiation processing technique remains the creation of high-performance radiation treatment complexes in which the electron beam is used to the maximum only for irradiation of the treated objects, as well as irradiation of the objects, providing a standardized dose that is uniform throughout its volume. This is achieved: a) a complete rejection of the concrete labyrinth channels and multi-link conveyors installed in them, b) installation of systems by moving objects through the irradiation zone close to each other, c) training of objects from two opposite sides.

Disclosure of invention

Each radiation treatment complex has a radiation treatment unit consisting of a radiation source (high-frequency high-energy electron accelerator) with an electron beam scan device 1, an irradiation zone 2, and a radiation protection bunker 3, which blocks radiation from a radiation-hazardous zone, caused by inhibitory radiation from the accelerator and the irradiation zone (Fig. 1). The hopper 3 includes an opening in the form of an entrance tunnel 4 for supplying processing objects to the irradiation zone and an opening in the form of an exit tunnel 5 for withdrawing objects from the irradiation zone, an entrance conveyor 6 for moving processing objects through the irradiation zone and an exit conveyor 7 for moving objects from irradiation zones. The body of the tunnels is made of metal. The cross section of the tunnels is minimized and determined by the width of the corresponding size of the processing object, and by the height of the height of the object and the height of the conveyor. For example, the height of a chain conveyor or roller table for moving objects, each of which has a mass of 8-10 kg, can be 50-70 mm. The most common container dimensions for processing objects are 600x400x300 mm. The cross section of the tunnels does not exceed 450x350 mm. Conveyors consist of separate sections. This facilitates their installation and maintenance. Installation of conveyors can be made both from the inside of the hopper, and from the outside.

The input conveyor 6 moves the object from the entrance to the hopper through the irradiation zone and reloads it onto the exit conveyor 7. The input conveyor operates at a constant speed, the value of which provides a normalized dose during the movement of the object through the irradiation zone.

The exit conveyor is turned on after loading by an object that has passed through the irradiation zone, and then moves this object at an increased speed to exit the hopper.

The radiation processing unit includes a small-sized input module for processing objects 8 and an output module for processing objects 9. These modules are designed for radiation protection from radiation through the bunker channels and at the same time loading and unloading objects for conveyor entry and exit conveyors. The input module consists of a radiation protection housing 10, a reversing carriage and a reversing carriage drive. The housing contains a through tunnel 11 in which the reversible carriage moves. Loading and unloading of the carriage can be carried out alternately on both sides of the module. In the middle of the housing on the side wall of the tunnel there is an opening 12 for moving objects from the module to the conveyor of the input 6 of the hopper. The reversing carriage consists of three blocks of radiation protection 13,14,15 and two frames 16, which are installed in the spaces between the blocks. Blocks and frames are connected in a single device. Each block is mounted on three rollers, which ensures their stability when the carriage moves. Within the framework, platforms 17.18 for irradiation objects were installed. The design of the platforms is equipped with a device for tilting them to unload the irradiated objects. In the middle of the housing in the vicinity of the opening there is a recess 19. Its dimensions are determined by the dimensions of the irradiated object and the angle of inclination of the carriage platform. The carriage moves from one extreme position A to another extreme position B. In extreme positions, one of the platforms 17 or 18 alternately extends beyond the module housing for loading by an object, and the other platform 18 or 17 is located in the alignment of the input conveyor of the hopper for loading it. To load the conveyor, the platforms are tilted and objects are shifted to the conveyor. The module provides reliable radiation protection against bremsstrahlung along the hopper channel at any position of the carriage in the tunnel of the module housing.

The speed of the carriage when it moves from one extreme position to another (6-7 seconds), taking into account acceleration and braking, as well as loading and unloading platforms, is provided by a drive with an electric motor power of 0.5-0.7 kW. Such carriage speed will allow loading processing objects onto the hopper inlet conveyor close to each other.

The radiation treatment unit includes a module for the output of the irradiated objects 9. Structurally, it is very close to the input module 8. The input and output modules are manufactured at industrial enterprises and delivered to the installation site in assembled and debugged condition.

An essential feature of a small-sized module is that the carriage, which consists of movable protection units and platforms, simultaneously moves processing objects and radiation protection from radiation through the opening in the hopper and the tunnel of the module case during movement.

When irradiated with an electron beam, each object should receive a standardized dose that is uniform throughout the volume. In radiation treatment 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. For this purpose, the object to be treated after unilateral irradiation should be turned 180 degrees relative to the axis of the electron beam and moved after the primary irradiation on one side through the irradiation zone for re-irradiation from the opposite side. The processing unit is additionally equipped with an external transport system for flipping and moving objects for repeated irradiation, consisting of a tilter 22 for flipping the object and the conveyor 23.

The radiation processing unit (Fig. 2) consists of two radiation sources (high-frequency high-energy electron accelerators) 24, 25 directed towards each other, with electron beam scanning devices, an irradiation zone 26, and a radiation protection bunker 27 blocking radiation from a radiation hazardous zone caused by bremsstrahlung of the accelerator and the irradiation zone. The hopper 27 includes an entrance tunnel 28 for supplying processing objects to the irradiation zone and an exit tunnel 29 for withdrawing objects from the irradiation zone, an entrance conveyor 30 for moving the processing objects through the irradiation zone 26, and an exit conveyor 31 for moving objects from the irradiation zone. The radiation processing unit includes a small-sized input module for processing objects 32 and an output module for processing objects

33. These modules are designed for radiation protection against bremsstrahlung through the channels of the hopper and loading and unloading of the respective conveyors. The input and output modules consist of a metal body of radiation protection, a carriage and a carriage drive. The housing comprises a tunnel 34 in which the carriage moves. The carriage consists of two radiation protection blocks 33, 36 and one frame with a platform 37, which is installed in the gap between the blocks. The carriage moves from one extreme position A to another extreme position B.

The radiation processing unit (Fig. 3) consists of one vertically located radiation source (high-frequency high-energy electron accelerator) with an electron beam scanning device 38, an irradiation zone 39, and a radiation protection hopper 40, which blocks radiation from a radiation-hazardous zone caused by inhibitory radiation from the accelerator and irradiation zones.

The hopper 40 includes an entrance tunnel 41 for supplying processing objects to the irradiation zone and an exit tunnel 42 for outputting objects from the irradiation zone, a conveyor 43 for moving the processing objects from the entrance to the hopper through the irradiation zone 39 to exit the hopper. Conveyor 43 is additionally equipped with a small-sized system for turning and moving processing objects for repeated irradiation. This system includes a manipulator 44 and two pushers 45, 46. The manipulator, consisting of containers 47.48 for the objects to be processed and the actuator 49, provides for the movement and at the same time reversal of the objects to be processed for re-irradiation from the opposite side. Processing objects in containers move along a circular path 180 degrees with the axis of rotation located in a plane parallel to the plane of scanning of the electron beam. Pushers move the objects after the initial exposure from the conveyor 43 to the container 47, and after moving and flipping the objects from the container 47 to the conveyor 43 in front of the irradiation zone.

Thus, the internal transport system of the bunker, consisting of a conveyor for moving processing objects through the irradiation zone and a small-sized system for moving and flipping objects that have undergone unilateral irradiation, provides double-sided irradiation of processing objects in one pass through the bunker. The radiation protection bunker includes a small-sized input module for processing objects 49 and an output module for processing objects 50. These modules combine the functions of radiation protection from bremsstrahlung through the bunker channels and loading and unloading conveyors 41, 42. The input and output module consists of a reversible radiation protection housing carriages and drives.

The technical result is.

Complete rejection of the labyrinth channels as a means of radiation protection in radiation processing units.

A complete rejection of transport devices as a means of moving processing objects along labyrinth channels.

A reduction of at least two times the area occupied by the radiation protection of the radiation treatment unit.

A reduction of not less than two times the volume and cost of protective materials.

No less than half the cost of the construction of radiation protection.

Installation of small input and output modules providing an increased degree of radiation protection against bremsstrahlung from tunnels of the radiation protection hopper and at the same time transportation of processing objects to the input conveyors and from the hopper exit conveyors.

Installation of transport systems providing irradiation of objects from two opposite sides.

A significant reduction in the dimensions of the radiation hazardous area, which creates the conditions for installing a radiation protection hopper in easily constructed rooms.

The maximum increase in the efficiency of using the electron beam by moving objects through the irradiation zone close to each other.

The installation of two radiation sources directed towards each other provides a twofold increase in the complex’s performance with virtually no increase in the cost of the radiation protection hopper and two-sided irradiation of the object in one pass through the irradiation zone.

Improving the reliability of the complex as a result of the elimination of a multi-link, long transport system with a large number of drives, which was installed in the labyrinth channels.

A brief description of the drawings.

Figure 1. A radiation treatment unit with one radiation source (cross-section and top view) with a radiation protection hopper, a small input module, an output module and a two-way object irradiation transport system, including an external system for moving objects for re-irradiation.

FIG. 2. A radiation treatment unit with two radiation sources (cross-section and top view) directed towards each other, with a radiation protection hopper, a two-way irradiation system for processing objects in one pass through the weaning zone, a small input module and an output module.

FIG. 3. A radiation treatment unit with one radiation source (cross section and top view) with a radiation protection hopper, a conveyor for processing objects with an internal system for double-sided irradiation of the object in two passes through the weaning zone, input module, output module.

FIG. 4. The algorithm for moving processing objects.

The implementation of the invention.

The radiation processing unit with one radiation source (Fig. 1) works as follows. The input module carriage moves objects to the hopper inlet conveyor. On platform 18, objects received for primary exposure are moved, and on platform 17, objects that have passed primary exposure. The carriage is in the extreme position A. The platform 18 and simultaneously the input conveyor 6 are loaded from the platform 17. The carriage is moved to position B, where the platform 17 is being loaded. As objects move on the conveyor and space is available for the next object, it is loaded from the platform 18 Thus, objects received for primary irradiation and objects that underwent primary irradiation are alternately loaded onto the conveyor of the hopper inlet. The input conveyor operates at a constant speed, the value of which provides a normalized dose during the movement of the object through the irradiation zone. Objects that passed through the irradiation zone are moved to the exit conveyor, which moves these objects at an increased speed to the exit of the hopper. The conveyor moves in turn both objects that have undergone primary irradiation on one side, and objects that have undergone irradiation on both sides. The output conveyor is unloaded onto the carriage platforms of the output module. At the same time, objects subjected to unilateral irradiation are loaded onto the platform 20, and objects exposed to irradiation from two opposite sides are loaded onto the platform 21. In the extreme position of the carriage A, the platform 21 is unloaded and the platform 20 is simultaneously loaded. In the extreme position of the carriage B, the platform 20 is unloaded and the platform 21 is simultaneously loaded. The platforms 20 and 21 are unloaded as a result of their tilt. The processing object from the platform 20 is unloaded into the tilter 22, which turns the object 180 degrees and puts it on the conveyor 23. Next, the conveyor 23 moves the object into the loading zone to the input module.

The radiation processing unit with two radiation sources (Fig. 2) works as follows. The carriage of the input module in position A is loaded by the processing object and moved to Position B. As the input conveyor 28 moves with the processing objects and freeing up space for the next object, it is next loaded from the carriage platform. The carriage moves to position A. The input conveyor operates at a constant speed, the value of which provides a normalized dose during the movement of the object through the irradiation zone. Objects that passed through the irradiation zone are moved to the exit conveyor 29, which moves these objects at an increased speed to the exit of the hopper. The output module carriage is in position B. The carriage platform is loading. The carriage moves to position A, where the platform is unloaded.

The radiation processing unit with one radiation source (Fig. 3), operates as follows (The algorithm for moving the processing objects is shown in Fig. 4).

The input module carriage moves unprocessed objects to the hopper conveyor 43. The conveyor is loaded with objects at intervals adequate to the length of the object. The conveyor operates at a constant speed, the value of which provides a normalized dose during the movement of the object through the irradiation zone.

Objects that passed through the irradiation zone after the initial treatment are moved by the pusher 45 from the conveyor 43 to the manipulator container located behind the irradiation zone. The container with the primary processed object drive of the manipulator moves with a 180 degree flip to the position before the exposure zone. Next, the object is moved by the pusher 46 to the conveyor 43 in the gap between the objects that have not been processed.

Objects that passed through the irradiation zone after secondary processing from the opposite side are moved on the conveyor 42 to the exit of the hopper. The coordinated work of all the mechanisms of the radiation processing unit for moving the irradiated objects, as well as changing the operating modes of the mechanisms is determined by a special algorithm, which is implemented using an automatic control system.

Claims (4)

 1. The radiation treatment unit, consisting of a single radiation source (high-frequency high-energy electron accelerator) with an electron beam sweep device, an irradiation zone, radiation protection blocking radiation from a radiation hazardous zone caused by inhibitory radiation from the accelerator and an irradiation zone consisting of a concrete hopper and modules the entrance and exit, installed at the entrance and exit of the hopper, providing constant radiation protection from radiation from the radiation hazardous zone through the input hydrochloric and outlet openings of the hopper and at the same time providing radiation treatment transporting objects from the loading zone to the hopper inlet opening and from the exit opening to the discharge zone. 2. The block according to claim 1, characterized in that it is additionally equipped with a transport system located outside the hopper, which provides two-sided irradiation of processing objects with a uniform dose throughout the volume of objects, consisting of a tilter for turning objects that underwent initial irradiation, on one side the opposite side, and the conveyor moving inverted objects to the loading zone, followed by re-irradiation of objects in the irradiation zone from the opposite side from the bottom narrow conveyor moving object processing through irradiation zone disposed closely to each other. 3. A radiation treatment unit, consisting of two radiation sources directed towards each other (high-frequency high-energy electron accelerators) with devices for scanning an electron beam, an irradiation zone, a conveyor for moving processing objects through an irradiation zone, radiation protection blocking radiation from a radiation hazardous zone, caused by bremsstrahlung of accelerators and the irradiation zone, consisting of a concrete hopper and input and output modules installed at the opening at the entrance and exit of the hopper, providing constant radiation protection from radiation from the radiation hazardous area through the input and output openings of the hopper and at the same time providing transportation of radiation treatment objects from the loading zone to the input opening and from the output opening to the unloading zone, characterized in that the module bodies the entrance and exit made of metal contain a blind tunnel and an opening located on the side wall of the tunnel, and the reversible carriages that move along the tunnel of the hull consist of two movable metallic radiation shielding blocks, each of which has a support on three rollers, a frame installed in between the blocks and the platform for processing objects with the platform tilting device with a view to its discharge. 4. The radiation treatment unit, consisting of one radiation source (high-frequency high-energy electron accelerator) with an electron beam sweep device, an irradiation zone and radiation protection blocking radiation from the radiation hazardous zone from the bremsstrahlung of the accelerator and the irradiation zone, consisting of a concrete hopper and input modules and an exit, characterized in that a transport system is located inside the hopper, comprising a conveyor for moving processing objects through the irradiation zone, two pushers , a manipulator with two containers for processing objects and a manipulator drive, which provides two-sided irradiation of processing objects with a uniform dose over the entire volume of objects as a result of the revolution of objects subjected to unilateral irradiation and their reverse movement on the conveyor to the entrance to the irradiation zone for secondary irradiation from the opposite side loading a conveyor for moving processing objects through the irradiation zone with objects close to each other.

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