RU130849U1 - BLOCK OF RADIATION PROCESSING OF OBJECTS BY A BEAM OF ACCELERATED ELECTRONS USING INDIVIDUAL COMBINED RADIATION PROTECTION AGAINST BRAKE RADIATION - Google Patents

Abstract

1. The unit of radiation processing of objects by an accelerated electron beam, containing a high-frequency electron accelerator, a tunnel with a transport system for moving the objects to be processed through the irradiation zone, individual radiation protection, which ensures absorption of bremsstrahlung from the accelerator and from the irradiation zone, characterized in that the individual radiation protection is made from a combination of protective materials and consists of a central and an outer part, with the central part facing the brake sources from teachings includes the mine tunnel for the accelerator and for the transport system, is made of cast iron or steel, and the outer part - of betona.2. The unit for radiation processing of objects by an accelerated electron beam according to claim 1, characterized in that the unit is equipped with a transport system in the form of a reversible carriage, which moves the processing object from the loading and unloading zones through the tunnel to the irradiation zone, consisting of three protective blocks and two platforms, providing at any position of the carriage in the tunnel, radiation protection from bremsstrahlung. 3. The unit for radiation processing of objects by an accelerated electron beam according to claim 1, characterized in that the unit is equipped with a transport system in the form of a reversible carriage, which ensures the movement of the processing object from the loading and unloading zones through the tunnel to the irradiation zone, consisting of one central protective unit with two platforms and two movable blocks located at the edges of the tunnel. 4. The block of radiation processing of objects by a beam of accelerated electrons according to claim 3, characterized in that the transport system contains �

Description

The technical field to which the utility model belongs.

The utility model relates to the field of medicine, food industry and processing technology for various materials. It can be used to sterilize medical materials, implantable products, medical instruments and medical waste, to sterilize and pasteurize food and perfume products, as well as to irradiate various materials with accelerated electron beams in order to give them new properties. The utility model 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 sources of radiation are used. The most developed method of processing objects with accelerated electron beams as a more reliable, high-performance and environmentally friendly.

Each radiation treatment complex of this type has a radiation treatment unit, which includes a radiator (high-frequency electron accelerator), a tunnel for moving treatment objects, an irradiation zone, radiation protection for absorbing brake radiation from the accelerator and from the irradiation zone, as well as a transport system for moving objects processing to the irradiation zone and the loading and unloading zone. The radiation treatment complex also contains high-frequency power equipment for the accelerator, vacuum system, cooling system, control system, and ventilation system.

In domestic and foreign practice, the most widely used radiation processing complexes, which use electron beam accelerators with an energy of 5-7 MeV and an average power of 1.5-3 kW. Such complexes, installed at most enterprises, allow radiation processing of all products for which this is required by technical conditions.

The following radiation treatment complexes, in which individual radiation protection from bremsstrahlung is applied, can be considered analogues of the utility model.

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

2. Mirrochnik EA, Mishchenko AV, Pirozhenko VM Complex radiation sterilization. Patent for invention №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 given analogues, radiation protection is made of cast iron or steel. Cast iron radiation protection, as a rule, is made of foundry blocks. A set of casting models is required for casting blanks. Such a technology for the manufacture of radiation protection is justified in serial factory production.

In the manufacture of radiation protection from steel plate, the laboriousness of the machining of its constituent elements increases, and difficulties arise in optimizing the form of protection, which leads to an increase in its mass. It is known that the cost of radiation protection represents a significant component of the cost of the complex as a whole.

An urgent problem in the manufacture of radiation treatment complexes is the reduction in the cost of radiation protection and the expansion of modifications of radiation treatment units designed to satisfy both the economic and technical requirements of the consumer. The solution to these problems will significantly expand the demand for radiation processing complexes and their implementation in industry. A large load of radiation treatment complexes and a decrease in the cost of radiation protection will lead to a significant reduction in the payback period of the complexes.

Disclosure of a utility model.

The task of reducing the cost of radiation protection can be solved by using concrete as a protective material in combination with metal. Studies show that the cost of radiation treatment units with such individual radiation protection can be reduced by 2–3 times compared with individual protection made of cast iron or steel, depending on the modification.

The radiation treatment unit (Fig. 1) includes a radiation source (high-frequency electron accelerator) 1 and an individual combined radiation protection consisting of the central and external parts. The central part is made of cast iron or steel. It performs not only a protection function, but also is a building consisting of a shaft 2, where an electron accelerator and a tunnel 3 are installed, through which the object passes through the irradiation zone 4. The outer part of the protection 5 is made of concrete. A radiation processing unit with a beam accelerator at an energy of 5 MeV and an average power of 2 kW occupies an area of 13 square meters. m. and can be installed in any room without additional radiation protection.

The radiation treatment units are equipped with transport systems of various modifications. In addition to the function of moving processing objects through the irradiation zone, transport systems are designed for radiation protection against bremsstrahlung from the irradiation zone along the tunnel. Thus, transport systems are an integral part of radiation protection against bremsstrahlung.

The radiation treatment unit (Fig. 1) is equipped with a transport system in the form of a reverse carriage, which ensures the movement of the processing object from the loading and unloading zones through the tunnel to the irradiation zone. The carriage consists of three protective blocks 6, 7, 8 and two platforms 9, 10 for processing objects 11, 12. The platforms have a significant length (capacity), which allows to increase the number of processing objects on the platform or to place long objects for processing. During the processing of objects 11, 12 in the irradiation zone 4, the carriage moves at a speed V1 that determines the normalized dose of radiation. When the protective block 7 passes through the irradiation zone 4, the carriage moves with a speed V2, 15-20 times higher than the speed V1. Such a carriage device with platforms of considerable length can increase the efficiency of using the electron beam up to 90-95%. This is due to the fact that in the cycle of carriage movement, the object irradiation time (effective time) significantly exceeds the carriage stop time in the loading and unloading zones in total with the passage of the protective block 7 under the beam through the irradiation zone. At any position of the carriage in the tunnel, radiation protection is provided against bremsstrahlung along the tunnel from the irradiation zone.

The radiation processing unit (Fig. 2) is equipped with a transport system in the form of a carriage, consisting of one central protective unit 13 and two platforms 14, 15. The length of the platforms can vary from a minimum to a maximum. At the ends of the tunnel mounted movable protective blocks 16, 17, which overlap on both sides of the tunnel section from the bremsstrahlung. To unload or load processing objects 18, 19, the carriage moves to contact with one of the outermost protective blocks, and then with this block the carriage moves to the extreme position at which the platform extends beyond the tunnel. When the platform contacts the extreme block, they are coupled when the electromagnetic device is turned on. During the reverse stroke of the carriage, when the extreme protective block completely enters the tunnel, the electromagnetic device is turned off, and then the carriage with the processing objects passes through the irradiation zone until it contacts the protective block located at the other end of the tunnel.

The radiation processing unit (Fig. 3) is equipped with a transport system consisting of a conveyor 20 located in the radiation protection tunnel, as well as a loading device and a device for unloading objects. respectively, the loading unit and the unloading unit of the processing objects. Both blocks are identical in design and consist of a casing 21 with a vertical tunnel 22. A carriage consisting of 2 protective blocks 23, 24 and slots between them 25 for the processing object moves inside the tunnel. The conveyor is designed to move the processing objects through the irradiation zone in a continuous stream (without gaps between the objects). This is achieved by constructively dividing the conveyor into three sections, each of which moves at different speeds. In the initial section, the conveyor after loading by the processing object at an increased speed brings it closer to the object located in the middle section of the conveyor. The speed of the middle section of the conveyor is determined by the regulation at which the processing object receives a normalized dose. Next, the processing object is moved to the output section of the conveyor, which at an increased speed moves the object into the carriage socket of the unloading unit. Software control of the movement of processing objects allows you to quickly change the algorithm for the coordinated operation of the conveyor and carriage for a certain type of product. Moving carriages in loading and unloading units with the necessary speed and high accuracy can provide modern servos. A slight deviation of the tunnel from the vertical (5-10 degrees) creates the conditions for increasing the accuracy of fixing the position of the carriage relative to the body inside the tunnel along the entire path of its movement from one extreme position to another. This allows you to reduce the gaps between the protective blocks of the carriage and the walls of the tunnel and, accordingly, reduce the bremsstrahlung through these gaps.

When developing radiation treatment units, customer requirements are provided for the tunnel cross-sectional dimensions and electron beam parameters.

Technical Results

1. The expansion of modifications of radiation treatment units through the use of individual combined radiation protection is designed to satisfy both technical and economic requirements of the consumer. The solution to these problems can significantly expand the demand for radiation processing units for industrial applications.

2. The installation of a transport device in the form of a carriage with platforms of considerable length allows to increase the efficiency of using the electron beam up to 90-95%.

3. Installation of loading and unloading units, as well as a three-stage conveyor in the radiation protection tunnel, allows you to move processing objects through the irradiation zone close to each other.

4. The installation of loading and unloading units in a vertical position or a slight deviation from the vertical allows to reduce the dimensions of the radiation treatment unit.

A brief description of the drawings.

Fig. 1. Radiation treatment unit (front, side and top view) with radiation protection made of steel and concrete and a carriage of three protective blocks and two platforms for the objects to be processed.

Fig. 2. A radiation treatment unit (top view) with a carriage made of one protective unit with two platforms and two movable protective units located at the edges of the tunnel.

Fig. 3. Radiation processing unit (front and top view) with conveyor and loading and unloading units.

Implementation of a utility model.

In radiation processing units, the central part of radiation protection, consisting of a mine and a tunnel, is manufactured at engineering enterprises. At the same enterprises, transport systems are manufactured for moving irradiated objects (carriages, conveyors, loading and unloading units). The structural elements are mainly relatively simple parts of a rectangular shape, made, for example, of steel plate. At the enterprises, a control assembly is carried out at which the accuracy of manufacture is determined. The assembly process tests the carriages for movement in the tunnel. Assembly of the structure is carried out using bolted connections. Next, the design is disassembled into separate transport nodes for shipment to the customer at the installation site.

At the installation site, concrete is laid on the base of the radiation protection. A tunnel for a carriage or conveyor and a shaft for a high-frequency electron accelerator are installed on the upper plane of the base with the necessary accuracy. The carriages are tested for movement in the tunnel or the performance of the conveyor. Next, concrete is laid in layers. The thickness of each layer is determined by the technology of concrete work. It is necessary to exclude the sticking of concrete to the metal structures of the central part of the radiation protection. For this purpose, various coatings, thin pads or aluminum foil can be used. Between layers of concrete it is also necessary to install thin spacers. After laying the bulk of the concrete, finishing work is done to give the outer surface of the radiation protection a more aesthetic appearance. To control the accuracy of the laying of each concrete layer, flat ellipsoidal patterns can be used. After the radiation test of radiation protection, it is possible to adjust its thickness according to the test results.

Installation of the accelerator 1 (Fig. 1) in its normal position, as well as its dismantling for routine and repair work, is performed from the upper part of the shaft 2 with the removed metal plates of radiation protection 26.

Claims (6)

1. The unit of radiation processing of objects by an accelerated electron beam, containing a high-frequency electron accelerator, a tunnel with a transport system for moving the objects to be processed through the irradiation zone, individual radiation protection, which ensures absorption of bremsstrahlung from the accelerator and from the irradiation zone, characterized in that the individual radiation protection is made from a combination of protective materials and consists of a central and an outer part, with the central part facing the brake sources from teachings includes the mine tunnel for the accelerator and for the transport system, is made of cast iron or steel, and the outer part - made of concrete. 2. The block of radiation processing of objects by an accelerated electron beam according to claim 1, characterized in that the block is equipped with a transport system in the form of a reversible carriage, moving the processing object from the loading and unloading zones through the tunnel to the irradiation zone, consisting of three protective blocks and two platforms providing at any position of the carriage in the tunnel radiation protection from bremsstrahlung. 3. The block of radiation processing of objects by a beam of accelerated electrons according to claim 1, characterized in that the block is equipped with a transport system in the form of a reversible carriage, providing the movement of the processing object from the loading and unloading zones through the tunnel to the irradiation zone, consisting of one central protective unit with two platforms and two moving blocks located at the edges of the tunnel. 4. The block of radiation processing of objects by an accelerated electron beam according to claim 3, characterized in that the transport system comprises an electromagnetic device that alternately interlocks the carriage with one of the movable protective blocks at the edges of the tunnel when it moves to the loading or unloading zones, and during the reverse stroke carriage hitch disconnect. 5. The unit for radiation processing of objects by an accelerated electron beam according to claim 1, characterized in that the transport system has a conveyor, as well as a loading unit and an unloading unit for processing objects, each of which consists of a radiation protection housing with a vertically located tunnel, a carriage consisting of two protective blocks and slots between them for processing objects. 6. The radiation processing unit of the objects with an accelerated electron beam according to claim 5, characterized in that the loading and unloading units with tunnels are arranged obliquely with respect to the vertical.

Images