RU2238792C2 - Device for separation of isotopes - Google Patents

Abstract

FIELD: separation of isotopes.

SUBSTANCE: the invention presents a device for separation of isotopes and may be used for excretion of isotopes from their natural mix. The device contains a vacuum chamber 1, in which there is a source 2 of isotope ions, a separator 5, a receiver of heavy isotope ions 16 and a receiver of light isotope ions 17. The separator 5 has a wide and a narrow parts. In the ionization chamber 3 of sources 2 molecules of separated isotopes are ionized. Isotope ions are drawn out by an electric field between electrodes 4 and are directed to the separator 5 formed by the lamellar elements 6, 8 and 7, 9 and an electromagnet 10 with the pole terminals 12 and 13. The lamellar elements 6, 8, 7, 9 are made out of sections of concentrical hollow cylinders and linked electrically to form an electrical barrier. They are located between the source 2 and the electromagnet 10. The electrical barrier is diminished in direction of the isotopic ions traffic from electrodes 4 up to terminals 12, 13. Less energetic ions descend from a circular trajectory to a rectilinear trajectory and form a band-type beam. For further separation of the band-type beam they create a magnetic barrier between the pole terminals 12, 13 of a magnetic conductor 11 with the help of electrical reels 14 and 15. The beam of the heavy isotope ions arrives in the receiver 16, the beam of the light isotope ions goes to the receiver 17. The invention allows to extract the given isotopes selectively from their natural mixture, to increase selectivity of separation.

EFFECT: the invention allows to extract the given isotopes selectively from their natural mixture, to increase selectivity of separation.

5 dwg

Description

The invention relates to nuclear engineering and is intended to isolate isotopes from their natural mixture.

Previously known devices for isotope separation were developed in the search for the most economical ways to obtain fuel for the implementation of uncontrolled and controlled nuclear and thermonuclear fission, uncontrolled and controlled nuclear and thermonuclear fusion, the formation of isotopic ion beams in ion-beam devices and the control of isotopic ion beams in accelerator technology .

A device for separating isotopes by energy is known, comprising a vacuum chamber in which a source of charged particles, receivers of charged particles, and a separator of charged particles are formed, which are formed by two pairs of plate elements, which are capacitors bent in cross section over sections of the circumferential parts of concentric hollow cylinders and bent into longitudinal section along arcs of circular orbits of low-energy charged particles. Both pairs of plate elements are located intersecting so that their electric fields are placed in intersecting directions with the formation of a single electric field, representing an electric barrier for charged particles [see RF patent for the invention No. 2187171, IPC 7 H 01 J 49/44, 01 D 59/46, G 21 K 1/087].

The disadvantages of such a device for separating isotopes by energy is the low selectivity in the separation of isotopes by mass due to the limited possibilities of splitting the beams of isotopic ions, that is, the use of the device does not allow the separation of isotope ions by energy to separate the isotope ions by mass due to the absence of a magnetic field.

The closest in technical essence and the achieved result (prototype) to the claimed invention is a device for separating isotopes containing a vacuum chamber in which there is a ring source of isotopic ions, a separator of isotope ions and an axial receiver of isotope ions and a ring source of isotope ions and a receiver of isotope ions . An annular source of isotopic ions is installed near the narrow part of the isotope ion separator, made in the form of a socket with longitudinal slotted slits, curved along the arcs of circular orbits of isotopic ions along the slotted slots of this separator. Ring receivers of isotopic ions are located along slit slots around a wide part of the isotope ion separator and near a wide part of the isotope ion separator opposite the source of isotopic ions. The separation of isotopic ions by mass occurs at the magnetic barrier of a magnetic field formed by a separator increasing in diameter, along which an electric current that is constant in direction flows [see RF patent for the invention No. 2137532, IPC 6 V 01 D 59/48].

The disadvantages of the described device for the separation of isotopes are the stringent requirements for the initial mixture of separated isotopes, consisting in the need for preliminary separation of isotopic ions by energy, and low selectivity for the separation of isotopes from a natural mixture due to the limited possibilities of splitting the isotopic ion beams, i.e., a device for separating isotopes by mass does not allow the simultaneous separation of isotopes by mass to carry out the separation of isotopic ions by energy and momentum.

The essence of the invention lies in the fact that in the device for separating isotopes containing a vacuum chamber, in which a source of isotope ions is installed near the narrow part of the isotope ion separator and isotope ion receivers are installed near the wide part of the isotope ion separator, the isotope ion separator is formed by plate elements and an electromagnet with pole tips, and plate elements made of sections of concentric hollow cylinders, electrically combined to form an electric of the barrier and are located between the source of isotopic ions and the electromagnet, and the pole tips of the electromagnet along which the isotope ion receivers are mounted are made of sections of a straight cylinder with the possibility of forming a magnetic barrier.

The technical result is the absence of strict requirements for the initial mixture of separated isotopes, consisting in the need for preliminary separation of isotopic ions by energy, and high selectivity in the separation of isotopes from a natural mixture.

The absence of strict requirements for the initial mixture of separated isotopes is explained by the increased possibilities for splitting isotopic ion beams, that is, the device allows the separation of isotopic ions by energy and momentum, since both electric and magnetic fields are used, which leads to the separation of isotopes by mass.

The increase in selectivity is ensured by increasing the possibilities of splitting isotopic ion beams, since the separation of isotopic ions first at the electric barrier and then at the magnetic barrier allows the previously impossible control of the trajectories of isotopic ions during the flight of the ions, resulting in complete separation of isotopes with the least requirements on the initial mixture isotopes by mass and energy.

The invention is illustrated by drawings, in which Fig. 1 shows a general view of a device for separating isotopes, Fig. 2 shows a diagram of the manufacture of plate elements of an isotope separator, Fig. 3 shows a diagram of the parallel movement of a pair of plate elements and the subsequent mutual placement of pairs of plate elements of an isotopic separator ion, in Fig.4 shows a General view of the isotope ion separator and in Fig.5 shows a view of the pole of the magnetic wire of the electromagnet and the pole tip. Additionally, figure 1 shows the following:

- dashed curved downward lines of medium thickness with arrows, indicating the trajectories of light isotopic ions;

- dashed horizontal lines of medium thickness with arrows, indicating the trajectories of heavy isotopic ions;

- thin dashed lines with arrows, indicating lines of field E field strength of the electric barrier;

- thin solid lines with arrows, indicating the lines of induction In the field of the magnetic barrier.

The device for separating isotopes contains a vacuum chamber 1, in which a source of 2 isotopic ions is placed, consisting of an ionization chamber 3 and forming electrodes 4 that draw an electric field, an isotope ion separator 5 formed by plate elements 6, 7, 8, 9 and an electromagnet 10 with a magnetic wire 11, pole pieces 12, 13 and electric coils 14, 15, receivers 16 of heavy isotopic ions and a receiver 17 of light isotopic ions. The separator 5 has a wide and narrow parts. The plate elements 6, 8 are connected to a constant voltage source 18, and the plate elements 7, 9 are connected to a constant voltage source 19. The plate elements 6, 7, 8, 9 are combined into electric pairs 6, 8 and 7, 9 and are made from sections of concentric hollow cylinders. The pairs of plate elements 6, 8 and 7, 9 are also electrically combined to form an electrical barrier. The plate elements 6, 7, 8, 9 are located between the source of 2 isotopic ions and the electromagnet 10 diagonally relative to the common axis of the source 2 of isotopic ions and the electromagnet 10 after the parallel transfer of a pair of plate elements 7, 9 to the intersection with a pair of plate elements 6, 8 The pole pieces 12, 13 are made of sections of a straight cylinder with the possibility of sequential flow of a direct current in the direction of magnetic current to form a magnetic barrier. The source of 2 isotopic ions is installed near the narrow part of the separator 5 of isotopic ions, and the receivers 16, 17 of isotopic ions are installed near the wide part of the separator 5, namely, near the pole pieces 12, 13 of the electromagnet 10.

A device for the separation of isotopes works as follows. In the ionization chamber 3 of the source 2 of isotopic ions, the molecules of the separated isotopes are ionized, after which the isotopic ions are pulled by the electric field between the electrodes 4 and sent to the isotope ion separator 5. Electric potentials, supplied from identical independent sources 18, 19 of constant voltage to the plate elements 6, 8 and 7, 9, provide the formation of an induced electrostatic field with an electric barrier. Using an electric barrier in the isotope ion separator 5, the isotope ions are first separated by energy. The electric barrier decreases in the direction of movement of isotopic ions from the electrodes 4 to the tips 12, 13 of the electromagnet 10, which makes it possible for less and less energetic ions to move from a circular path through a curved electric barrier to a straight path and form a ribbon beam. The isotopic ions separated by energy form a ribbon ion beam. The ribbon beam of ions separated by energy is then fed into the field of the electromagnet 10 for the separation of isotopic ions by pulses. The separation of isotopic ions by momenta is carried out using a magnetic barrier. The magnetic barrier between the pole pieces 12, 13 of the magnetic wire 11 is created by electric currents through the electric coils 14, 15. The magnetic barrier is formed at such a height, and the magnetic induction is maintained at a level where the beam of light isotopic ions remains in a circular orbit, and the beam of heavy isotopic ions descends from a circular orbit. The beam of heavy isotopic ions then goes along a straight path to the receiver 16 of heavy isotopic ions. The beam of light isotopic ions then goes along a straight path to the receiver 17 of light isotopic ions.

где

- протяженность зоны разделения изотопных ионов по энергиям, а

- протяженность зоны разделения изотопных ионов по импульсам.The most important feature of the device for separating isotopes is the ability at the stage of isotopic ion separation by momentum to spin only light isotopic ions along circular edges of the energy-separated ions into circular orbits, practically not changing the straight lines of heavy isotopic ions along the wide front of the ions separated by energy. In this case, the splitting l _{1 of} wide beams of isotopic ions in pulses is maximum and equal to: l ₁ = R ₁ -R ₁ cosα ₁ , where α ₁ is the angle of rotation of a wide beam of light isotopic ions in circular orbits of radius R ₁ . It is understood that the angle α ₁ <π / 2. In this case, the length L _{1 of} the splitting zone of wide beams of isotopic ions in pulses becomes minimal and is determined by the formula L ₁ = R ₁ α ₁ , where the angle α ₁ is measured in radians. The length L of the mass separation zone of isotopic ions in this case also becomes minimal and is determined by the formula

Where

- the length of the zone of separation of isotopic ions by energy, and

- the length of the zone of separation of isotopic ions by momentum.

The use of the proposed device for the separation of isotopes provides the following advantages:

1. The solution to the problem of selective extraction of pre-selected isotopes from a natural mixture by exposure to isotopic ions by electric and magnetic barriers.

2. Increasing the selectivity of isotope separation.

Claims (1)

A device for separating isotopes containing a vacuum chamber in which a source of isotope ions is installed near the narrow part of the isotope ion separator and isotope ion receivers are installed near the wide part of the isotope ion separator, characterized in that the isotope ion separator is formed by plate elements and an electromagnet with pole tips, wherein lamellar elements are made of sections of concentric hollow cylinders, are electrically combined to form an electrical barrier and are located between the source of isotopic ions and the electromagnet, and the pole tips of the electromagnet along which the isotope ion receivers are mounted are made of sections of a straight cylinder with the possibility of forming a magnetic barrier.

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