RU2193249C2 - Electronuclear installation - Google Patents

Abstract

FIELD: experimental nuclear physics; neutron sources for experimental studies. SUBSTANCE: charged-particle beam input channel, target assembly, and biological shield are proposed to be integrated into single module and this module is proposed to be disposed in vertical recess of blanket. Target assembly is made in the form of vertically mounted wheel. The latter is installed in evacuated casing connected through vacuum-tight joint with ion conductors of beam entrance channels positioned at certain angle to wheel plane. Wheel is provided with actuator which sets it in rotary motion. Module is joined with set of shutter plates equipped with actuators and synchronizing system affording alternate entrance of plates in sector recess of blanket when module is drawn out of the latter or alternate extraction of plates as module is pushed in sector recess of blanket. Module is provided with drive for moving it in case of abnormal situations. Beam splitting magnet installed at module input enables beam distribution among two or more channels. Beam entrance channels have turning magnet and focusing members. All channel components are built into biological shield unit except for direct leak of neutrons and gamma- quanta from reactor core. Large area of core irradiated by protons and rotation of internally cooled wheel enable raising continuous running time of target assembly under normal conditions up to 5-8 years, that is, to equalize its service life with that of blanket. Curved path of charged particles in entrance channels built in biological shield prevents direct ionizing radiation leaks from reactor core which reduces radiation hazard of electronuclear installation of intermediate energy up to 100 MeV. EFFECT: enhanced service life of target assembly and installation as a whole; reduced radiation hazard for personnel during repairs of installation. 2 dwg

Description

 The invention relates to the field of nuclear physics, and more particularly to neutron sources for nuclear research and transmutation of radioactive waste.

 Known projects of electro-nuclear blanket systems and installations containing an accelerator of charged particles, preferably protons, a channel for transporting charged particles to the target, the target site and propagating blanket surrounding the target site. Blankets in different solutions differ in moderator material, design and contain different types of fuel from enriched uranium [1] to molten salts containing thorium [2] or directly radioactive waste [3].

 One of the problems of creating nuclear systems is the layout of a horizontal linear accelerator (or cyclotron with a horizontally extracted beam) and a blanket with vertical fuel loading. As a rule, the blanket design exactly matches the traditional reactor design with the exception of the proton beam input channel. For reasons of symmetry and preservation of the traditional layout of the core, this channel is positioned along the blanket axis. This approach largely determines the disadvantages of the above solutions. First, with a central location, the target loading channel is at the same time the last section of the magnetic channel for transporting protons to the target. Secondly, the blanket consists of vertical fuel channels located in the immediate vicinity of the target channel. In this case, access to the fuel channels is closed by a rotary magnet, which ensures the rotation of the proton beam from the initially horizontal direction to the vertical direction of the target channel. Thus, in order to replace the target channel or check one of the fuel channels located directly under the rotary magnet, it is necessary to dismantle a precisely tuned magnetic system that includes the rotary magnet itself and focusing elements, for example, quadrupole lenses installed after the magnet for the last beam shape correction. Considering that an efficient installation with high neutron fluxes requires high-current beams of sufficiently high energy, for example, a proton beam with energies in the region of 30-100 MeV, it can be expected that the target resource will be from one to five weeks. This means that on average each month it is necessary to replace the target channel, dismantling the rotary magnet and lenses and exposing the personnel to radiation, since the rotary magnet is activated in the neutron flux formed by the target channel, looking directly at the center of the active zone. These design features reduce the time of continuous operation of the installation, reduce its reliability, increase the cost of operation and make it very dangerous from a radiation point of view.

The closest to the claimed device in terms of features is an electron-neutron generator [4] containing a charged particle accelerator, a target assembly, a vertical propagating blanket, an input channel for a charged particle beam containing an ion guide, a rotary magnet and focusing lenses. The proton energy used in this solution is 36 MeV. The proton beam current is 0.5-1.0 mA. The target material is beryllium. The blanket is heavy water, i.e. heavy water is the moderator, neutron reflector and coolant. The design of the neutron generator contains all of the above disadvantages. The diameter of the core is about 500 mm. The shadow of the overhanging swivel magnet has an average size of more than 700 mm. If the beam current is 0.5 mA and the lateral surface area of the conical target is about 400 cm ² , then the flux density will be about 10 ¹³ protons / cm ² / s. With an estimated fluence of the target material 10 ¹⁹ protons / cm ² (proton energy 36 MeV), the resource will be about 20 days. It is also necessary to take into account the effect of fast and thermal neutrons on the target, the distribution and values of temperature stresses along the depth of beryllium to clarify the fluence value at which a beryllium product made by powder metallurgy methods under these conditions loses its strength or changes its structure. The resource value obtained above seems realistic. This means partially disassembling the installation and replacing the target channel every three weeks. Considering the activation of the rotary magnet and other elements of the proton transport channel in the neutron flux emitted by the active zone through the target channel, it can be concluded that an installation with such features will be practically inoperative or, at least, unprofitable.

 The aim of the proposed technical solution is to increase the resource of continuous operation and increase the radiation safety of the nuclear power plant with an intermediate energy driver (up to 100 MeV).

 This goal is achieved by the fact that in an intermediate-wave electron-nuclear installation containing a charged particle accelerator, a target assembly, a vertical propagating blanket, an input channel for a charged-particle beam containing an ion guide, a rotary magnet and focusing lenses, the blanket body is made with a side vertical sector cut-out, and the assembly targets, ion conductors, rotary magnets and focusing lenses of the channel for inputting a beam of charged particles are mounted in a detachable protection unit and made in the form of a single unit module equipped docking connector and the actuator, allowing to introduce a block module with protection in side elevation sectored recess blanket; At the entrance to the block module, a magnet divider is installed that distributes accelerated particles into two or more beam input channels, while the target assembly is made in the form of a vertical wheel mounted in a vacuum casing vacuum-tightly connected to the ion channels of the beam input channels oriented at an angle to the plane of the wheel equipped with a drive that provides its rotation; the block module is combined with a set of slide plates that are equipped with drives and a synchronization system for alternately entering a blanket into the sector slot when the block module is pulled out of it or withdrawing from it as the block module is inserted into the blanket sector slot.

The block module is detachably connected to the beam splitter magnet. A beam splitter magnet divides the beam into two or more parts, directing them into two or more internal beam input channels. Each of these channels inside the module contains a rotary magnet tuned to the beam deflection angle, for example 30-60 ^o , and the necessary focusing elements (lenses). The wheel is made in the form of a hollow disk, on the annular periphery of the planes of which ring elements of the target itself are fixed on both sides, the thickness and radial width of which are sufficient for the complete absorption of the proton beam of the used energy. Protective elements made of neutron-slowing and neutron-absorbing materials are located inside the disk, which also serve to form a coolant circulation cavity inside the target wheel. Cooling water is supplied into the disk and water is drawn out of it through the wheel shaft mounted with bearings in the housing of the vacuum casing. The wheel is equipped with a drive ensuring its rotation under the proton beam.

 The causal relationship of the purpose of the invention with the introduced features of the invention.

 The implementation of the target node and the input channel of the beam of charged particles (for example, protons), including rotary magnets and focusing lenses, in the form of a single module mounted in a detachable protection unit, allows protons to be transported to the target along a broken line, excluding direct lumbar neutrons from beam input channel. The combination of the target block module with a set of slide plates allows it to be removed from the sector cut-out of the blanket body without the risk of personnel exposure, since synchronization of the output of the block module with the orderly entry of the slide plates ensures personnel protection during this operation.

где D - максимальный диаметр облучаемых пучком кольцевых элементов, d - диаметр пучка, α - угол скольжения пучка, ν - частота вращения колеса, n - число внутренних каналов. При отношении диаметров, равном 12,5, к частоте вращения 1,5 оборота в секунду и числе внутренних каналов 2 получаем фактор k = 118. Это позволяет практически уравнять ресурс мишени и ресурс бланкета и избавиться от частых перегрузок узла мишени. Периодический контроль состояния рабочего слоя мишени (поверхность, облучаемая протонами) может производиться со стороны внешней (по отношению к бланкету) части вакуумного кожуха с помощью специального вакуумного ввода оптоволоконной системы с подсветкой.The execution of the target node in the form of a vertical wheel mounted at an angle to the channel for introducing a beam of charged particles, allows to increase the total area of the target and limit the heating time of this sector of the target to the time of its passage through the beam, which is determined by the angular velocity of rotation of the wheel and its radius. Compared with the conical target of the prototype, the coefficient of increase in the resource of the target for equal beam angles relative to the target surface is

where D is the maximum diameter of the ring elements irradiated by the beam, d is the diameter of the beam, α is the beam angle, ν is the wheel speed, n is the number of internal channels. With a ratio of diameters equal to 12.5 to a rotation frequency of 1.5 revolutions per second and the number of internal channels 2, we obtain the factor k = 118. This allows us to practically equalize the target resource and the blanket resource and get rid of the frequent overloads of the target node. Periodic monitoring of the state of the target working layer (surface irradiated by protons) can be carried out from the outside (with respect to the blanket) of the vacuum casing using a special vacuum input of a fiber optic system with illumination.

 The target device for an accelerated beam of charged particles in the form of a wheel is known [5], [6]. In the proposed solution, the main difference is the location of the target node in the sector cutout of the blanket, with a substantially vertical wheel arrangement. Placing a block module that combines a target assembly in the form of a wheel, curved proton input channels and protective elements in a vertical cutout of a blanket allows you to bring the target closer to the blanket area occupied by fuel, and at the same time does not interfere with the maintenance of the fuel channels or their repair. The presence of rotary magnets in the block module provides the ability to suppress reverse radiation from the core, reducing the radiation hazard during normal operation. The proposed set of features allows you to equalize the operational resources of the target site and blanket, bringing them up to 6-8 years. This eliminates the need for frequent replacement of the target assembly, which increases the efficiency and profitability of the installation.

 The invention is illustrated by drawings, where in FIG. 1 schematically shows a horizontal section of a blanket and a block module in operational condition. In FIG. Figure 2 shows a vertical section of a blanket in a position where a sector cutout of a blanket is partially occupied by a set of slide plates protecting from neutrons and gamma rays.

 The electron-core installation comprises a vertical blanket 1 with a vertical sector cut-out 2 and a block module 3 located in a sector cut-out. The blanket can be, for example, a heavy water or light water channel structure with enriched fuel. The block module includes a target 4, made in the form of ring elements on the periphery of the wheel 5, equipped with an input unit 6 and a coolant output unit 7 and a rotation drive 8 and internal beam input channels, consisting of output sections 9-1 and 9-2, rotary magnets 10-1 and 10-2 with focusing lenses and input sections 11-1 and 11-2. In this case, the components of the module block are mounted in a detachable neutron-absorbing protection 12, the lateral surface of which corresponds in shape and size to the sector cutout of the blanket. The input connectors of the beam input channels are connected to the divider magnet 13. An external ion guide portion 14 is connected to the accelerator 16 through the flange connector 15. The block module is equipped with a drive 17 and a system of gate plates 18, replacing the block module in the sector cutout of the blanket when it is extended.

Electro-nuclear installation works as follows. The accelerator 16 produces a beam of charged particles, such as protons, the necessary energy and limited divergence. The proton beam through section 14 of the ion guide enters the magnet divider 12 and diverges into two (or more) beams entering sections 11-1 and 11-2 of the internal input channels. As a result of passing through the C-shaped rotary magnets 10-1 and 10-2, the beams deviate from the original direction by some angles, for example, 30 ^o , and in sections 9-1 and 9-2 fall on the peripheral ring elements 4 of the wheel 5 made of material with a maximum neutron yield at a given proton energy. The thickness of the annular element of the target and the angle of incidence of the protons, given by the parameters of the rotary magnets, are selected from the requirement of complete absorption of proton beams in the target. The drive 8 provides rotation of the wheel and a uniform distribution of heating over its surface, and the input unit 6 and the heat transfer medium output unit 7 provide heat removal from the entire inner surface of the wheel.

 The setup of the beam wiring systems in the block module together with the target assembly and the beam splitter magnet is carried out separately from the blank before mounting the security elements. After receiving the design parameters, all protection elements are installed and the block module takes on a finished look. Then, the operation of entering the module block into the vertical cutout of the blanket and mounting the external sections of the ion guide is performed.

 The economic efficiency of the proposed device is determined by the increase in the resource of continuous operation, which eliminates the need for very expensive operations to frequently replace the target node using complex devices. This reduces operating costs by tens of times.

 Literature.

 1. L. Van Den Durpel et al. The ADONIS-project: an accelerator driven operated subcritical system. The Eighth International Conference on Emerging Nuclear Energy Systems. ICENES'96. June 24-28, 1996, Obninsk, Russia, Institute of Physics and Power Engineering. Proceedings, vol. 2, 526-532.

 2. S. Rubbia. CERN Concept of ADS. Feasibility and motivation for hybrid concepts for nuclear energy generation and transmutation. IAEA-TC-903.3 Proceedings of the International Atomic Energy Agency Technical Commitee Meeting. Madrid, Spain, 17-19 September 1997. 1998. Ciemat pp. 26-171.

 3. T. Takizuka, T. Sasa, K. Tsujimoto. Hybrid System concepts for nuclear waste transmutation. Ibid., 345-356.

 4. O.V. Shvedov et al. The ITEP electro-nuclear neutron generator. Journal of Moscow Physical Society, 6 (1996) 99-111.

 5. N. Ebinger, H. Kroll, G. Luthardt, Vorrichtung zur Erzeugung von Neutronen. Patentschrift DE 28 07 374 C2, G 21 G 4/02, 02.21.78.

 6. G. Bauer. Target fur Spallationsneutronenquellen. Patentschrift DE 28 50 069 C2, G 21 G 4/02, 11/18/78.

Claims (1)

 An electron-nuclear installation containing a charged particle accelerator, a target assembly, a vertical propagating blanket, an input channel for a charged-particle beam containing an ion guide, a rotatable magnet and focusing lenses, characterized in that the blanket body is made with a side vertical sector cut, and the target assembly, ion conductors, are rotary magnets and focusing lenses of the channel for input of a beam of charged particles are mounted in a detachable protection unit and are made in the form of a single unit module equipped with a docking connector and a drive, allowing You can enter a block module with protection into the side vertical sector cut-out of the blanket; At the entrance to the block module, a magnet divider is installed that distributes accelerated particles into two or more beam input channels, while the target assembly is made in the form of a vertical wheel mounted in a vacuum casing vacuum-tightly connected to the ion channels of the beam input channels oriented at an angle to the plane of the wheel equipped with a drive that provides its rotation; the block module is combined with a set of slide plates that are equipped with drives and a synchronization system for alternately entering a blanket into the sector slot when the block module is pulled out of it, or sequentially withdrawing from it, as the block module is inserted, into the blanket sector slot.

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