RU107656U1 - DEVICE OF LEVITATING QUADROPOL - Google Patents

Abstract

The utility model relates to the field of plasma physics. A levitating quadrupole device, characterized in that it contains a vacuum chamber and a cylindrical compartment communicating with it in the lower part of the chamber, in which two ring-shaped mixins, each in the form of a coil of superconducting material, are arranged coaxially at a vertical distance from each other, and outside of which a solenoid is placed coaxially with the mixins, designed to pass a current through it to form a magnetic flux passing through the cross sections of the specified mixins, the mixin cooling device I transfer the latter to a superconducting state and capture magnetic flux by myxins, a solenoid power source for forming a magnetic field in myxines in the superconducting state, a mechanism for lifting cooled mixins from the compartment into the chamber cavity with the solenoid turned off to a level below the coil of superconducting material designed to form a magnetic the field necessary to compensate for the gravitational effect on the two indicated cooled mixins, and located outside the chamber in its upper part with clearly with both myxines and vertical axis of the chamber. 6 ill.

Description

The utility model relates to the field of plasma physics, in particular, relates to the construction of magnetic systems of galata traps designed to hold a plasma volume closed in a torus in an area surrounded by a magnetic barrier. In particular, a system of two levitating superconducting magnetic rings with a current of one direction is considered. Such a magnetic system is the main element of multipole magnetic traps - galaty.

The methods of quasistationary magnetic confinement of high-temperature thermonuclear plasma in closed traps of the tokamak and stellarator type are well known and used in experiments (L. Artsimovich, “Controlled Thermonuclear Reactions”, M., “Nauka”, 1963). At present, the fusion power comparable to the power of plasma production has been obtained on the JET and JT-60U tokamaks. Thus, the possibility of creating a controlled thermonuclear reactor based on confinement of a thermonuclear plasma in a closed magnetic trap has been practically proved.

An important characteristic that determines the parameters of a fusion reactor with magnetic confinement is the parameter β, defined as the ratio of the plasma pressure (the product of the plasma density and temperature) to the pressure of the confining magnetic field (squared magnetic field modulus). Since the power of the thermonuclear reaction is directly determined only by the plasma pressure, then, naturally, we must strive for values of the parameter β close to unity, when the holding capacity of the created magnetic field is fully used. Unfortunately, the tokamak and stellarator systems, which have a magnetic field that is almost uniform along the magnetic axis, work stably only at small values of the parameter β ~ 0.05. Such small values of the parameter β are in good agreement with the predictions of the modern theory of magnetic confinement.

The concept of galactic magnetic traps as candidates for the role of a plasma confinement system in a thermonuclear reactor suggests that in these traps with current-carrying conductors washed by the plasma (“mixins”), (Braginsky SI, Kadomtsev BB) Plasma Physics and the problem of controlled thermonuclear reactions ", under the editorship of M.A. Leontovich, vol. 3. M, publishing house of the Academy of Sciences of the USSR, 1958, p. 300; Kerst DW, Ohkawa T." Nuovo Cimento ", 1961. V. 22. p.784; Peregood BP, Lehnert B. "Nucl. Instrum. Methods", 1981, V. 180, p.357; Yoshikawa S. "Nucl. Fusion", 1973, V. 13, p. 433; Prager SK " Nucl. Instrum. Methods ", 1983, V. 207, p. 187; Zhukov V.V., Morozov A.I., Schepkin G.Ya." Letters to JETP ", 1969, vol. 9, p. 24), the value β ₀ (β ₀ = 2µ _o Pmax / B ² max, where Рmax and Вmax is the maximum plasma pressure and the maximum field in the reactor) can reach values of the order of unity, and the transfers can be classical. Today's tokamaks and stellators do not meet the specified requirements.

Such Galatea traps with three mixins are described in g. “Plasma Physics”, 2006, Volume 32, No. 3, pp. 195–206, article “Injection of Plasma into the Galatea“ Trimix ”, authors A. I. Morozov, A. I. Bugrova, A. M. Bishaev, M. V. Kozintseva, A.S. Lipatov, V.I. Vasiliev and V. M. Strunnikov.

So in RU 99267, Н05Н 1/24, G21B 1/00, publ. 11/10/2010, a Trimix plasma trap is described, containing three mixins, each of which is a current-carrying coil winding in the form of a closed ring, and pushers, each of which is a current-carrying coil winding in the form of a closed ring, with two mixins made of the same diameter and placed coaxially at a distance from each other, the third mixin of a smaller diameter is placed between the first two mixins coaxially with the last, all pushers are placed coaxially to the mixins, each of the two pushers is one of a different diameter, the size of which is larger than the diameter of the myxines of smaller diameter and smaller than the diameter of the mixins with the same diameter, is placed in the plane of one of the mixins of the same diameter, and each of the two pushers of the same diameter, the size of which is larger than the diameter of the mixins made with the same diameter, is placed between the planes, passing through one of the mixins with the same diameter and the mixin of smaller diameter.

In this trap, a magnetic barrier is formed in the region of high magnetic field induction, but a section is formed in the area between the pushers whose magnetic field is much lower than the magnetic barrier in other areas, which makes it possible to use a plasma gun for injection of plasma clots with high energy indices. As a result of the studies, it was experimentally confirmed that a high-density plasma volume is formed inside the trap using three mixins with pushers.

In galatea traps studied to date, coils, including traps according to RU 99267, immersed in plasma (the so-called “mixins”) are structurally secured with the help of holders. The holders cross the volume occupied by the plasma. For the initial stage of research (when the heat content in the plasma is small), this is apparently acceptable. In a thermonuclear reactor, mixins must levitate, while it is desirable to form a plasma volume inside the region surrounded by the magnetic barrier of the mixin field. However, such a solution for the levitation state of two or more myxines has not yet been found. In the 70s of the XX century, a levitating dipole was created (FM-1 spherator / L. Sinnis, M. Okabushi, JASchmidt, S. Yoshikawa // Phis. Rev. Letts. - V.29. - 1972. - P. 1214-1218.). Large installations with levitating superconducting LDX dipoles (First Experiments tu Test Plasma Confinement by a Magnetic Dipole / J. Kesner, ACBoxer, JLEllswors et al // 21st IAEA Fusion Energy Conference. - 2006 - Prep. IC / P7-7. - 1-8.) And RT-1 (Magnetosphere-like Plasma Produced by Ring Trap 1 (RT-1) / Z. Yoshida, Y. Ogawa, J. Morikawa, et. Al. // 21st IAEA Fusion Energy Conference, 16-21 October, Chengdu, China. - 2006 - Prep. IC / P7-14. - P.1-8.), Respectively.

Thus, in the article “Magnetosphere-like Plasma Produced by Ring Trap 1 (RT-1)” / Z. Yoshida, Y. Ogawa, J. Morikawa, et. al. // 21st IAEA Fusion Energy Conference, 16-21 October, Chengdu, China. - 2006 - Prep. IC / P7-14. - P.1-8 / (adopted as a prototype) describes a levitating trap (dipole) device containing a vacuum chamber, in the upper part of which, outside of it, a ring of superconducting material is placed coaxially with the vertical axis of the chamber and the axis of the trap coinciding with it for the formation of a magnetic field to compensate for the gravitational effect on the myxin coil, a cylindrical compartment is mounted coaxially with the vertical axis of the last and the axis of the myxin coil, inside of which the myxin is placed on the lifting element in the form of a coil of a circular shape made of superconducting material, and outside of it coaxially with the mixin, a solenoid is placed, as well as a solenoid power source for generating a magnetic field in the solenoid (performing the function of exciting current in the mixin), a magnetic field forming unit in the ring of superconducting material, a cooling device ring-shaped coils of superconducting material and a mechanism for lifting a cooled mixin from the compartment into the chamber cavity.

At the initial moment, the coil (mixin) in a non-superconducting state at ambient temperature is installed at a given height on a lifting device in the cylindrical compartment of the chamber inside the solenoid. Then a current is passed through the turns of the solenoid, and the desired magnetic flux is established through the coil section of the superconducting material. The coil is cooled, transferred to a superconducting state and captures the required magnetic flux. The solenoid field is turned off, and the coil in the superconducting state forms a magnetic field of the dipole, after which the coil is moved into the chamber to a predetermined height. Gravitational attraction to the Earth is compensated by applying current to the superconducting ring, which has a stabilizing effect on the equilibrium of the system. The lifting device slides down to the set position. A coil of superconducting material is in equilibrium at a given level inside the vacuum chamber and can be used as a trap for plasma.

Despite the fact that the mixin levitates in this setup, the magnetic field created by it decreases in all directions from the surface of the mixin and does not have a region with zero magnetic field, which is surrounded by a magnetic barrier on galaxy traps. The disadvantage of this solution lies in the low efficiency of plasma confinement by a magnetic field, as well as in the absence of high values of the plasma confinement density. The issue of the economics of the installation, both in terms of filling the trap with plasma and in using the holding magnetic field, remains a serious obstacle to obtaining a well-held high-density plasma volume.

This utility model is aimed at achieving a technical result for increasing the efficiency of organizing and retaining a plasma volume with unclear boundaries and increasing the plasma density in an area surrounded by a magnetic barrier.

The specified technical result is achieved in that the device of the levitating quadrupole contains a vacuum chamber and a cylindrical compartment communicating with it in the lower part of the chamber, in which two ring-shaped mixins, each in the form of a coil of superconducting material, are arranged coaxially at a distance from each other vertically , and outside of which, coaxially to the myxines, a solenoid is placed, designed when a current is passed through it to form a magnetic flux passing through the sections of these myxines, cooling mixins for transferring the latter to the superconducting state and capturing magnetic flux by mixins, a solenoid power supply for forming a magnetic field in mixins in the superconducting state, a mechanism for raising cooled mixins from the compartment into the chamber cavity with the solenoid disconnected to a level below the coil of superconducting material intended for the formation of the magnetic field necessary to compensate for the gravitational effect on the two indicated cooled mixins, and located outside of measures in its upper part coaxially with both mixins and with the vertical axis of the chamber.

In this case, the device can be equipped with an additional coil of superconducting material fixed outside or inside the vacuum chamber to compensate for their magnetic attraction, to compensate for the gravitational effect on cooled mixins and to adjust the magnetic field of the quadrupole, while this additional coil is placed between the levitation mixins.

The device can also be equipped with another coil of superconducting material, mounted outside the vacuum chamber and located below the lower levitate mixin, to compensate for the gravitational effect on the lower mixin.

These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

The present utility model is illustrated by a specific example of execution, which, however, is not the only possible one, but clearly demonstrates the possibility of achieving the required technical result.

Figure 1 - device levitating quadrupole;

figure 2 - the magnetic field of the solenoid, creating a magnetic flux through the cross section of the mixins;

figure 3 - cooling myxin to a superconducting state in the field of the solenoid;

figure 4 - the magnetic field of the cooled (superconducting) mixin when the solenoid is off;

figure 5 - the position of the myxin in the chamber in the levitating state and the configuration of the resulting magnetic field of the myxin quadrupole;

6 is an example of the position of the mixin in the levitating state, the superconducting push rod in the chamber and the configuration of the resulting magnetic field of the quadrupole mixin, push rod and two magnetic coils located above and below the levitating mixin.

According to this utility model, a levitating quadrupole device (trap with two mixins in the levitating state) is considered (Fig. 1), which contains a vacuum chamber 1. The chamber is configured to hold a vacuum in all compartments communicating with it. A coil 2 of superconducting material is arranged coaxially with the vertical axis of the latter in the upper part of the chamber to form a magnetic field to maintain the levitation state of two mixins 3 and 4. In the lower part of the chamber, a cylindrical compartment 5 is mounted coaxially with the vertical axis of the latter, and a solenoid 6 is placed outside. Inside the compartment are two mixins 3 and 4 located at a distance from each other. Each mixin is made in the form of a ring-shaped coil of superconducting material. Outside the chamber, there is a solenoid power supply for forming a magnetic field in mixins in their cooled state (not shown), a magnetic field forming unit in all external and internal rings of superconducting material (not shown) and a cooling device (using liquid nitrogen) of the ring form of mixins and other coils of superconducting material (cooling device not shown). In addition, a lifting mechanism 7 is mounted in the vacuum chamber 1 to move the mixins from the superconducting material into the cavity of the vacuum chamber from the compartment 5. An additional coil of superconducting material is placed outside the chamber 8. Outside of the camera body, another coil of superconducting is placed 9. The position 10 shows the vertical axis of the chamber.

To work out a variant of the trap device with levitating mixins, a magnetic quadrupole was chosen. A system of two coils with a current of the same direction, lying in parallel horizontal planes, is considered. To levitate them (that is, to create an equilibrium configuration in a magnetic field and in a gravitational field), two tasks need to be solved: to compensate for the magnetic interaction of myxins (using “pushing” coils) and to compensate for the gravitational attraction of myxins to the Earth (using “anti-gravity” coils) . The main thing for the trap is to create the required configuration of the magnetic field and provide the necessary value of its barrier value. This necessarily leads to the use of large currents in them. As a result, estimates show that the forces of magnetic interaction between myxins will be an order of magnitude or more higher than gravitational forces. So for a quadrupole that provides a barrier magnetic field of only 0.006 T, the attractive forces between myxines reach Fz = 50.35H, and each myxine weighs 10 N (with a density of superconducting substance 5 · 10 ³ kg / m ³ ). Therefore, the currents in the pushers will have values comparable to the currents in mixins, and this will, as we will see below, increase the efficiency of using the magnetic field of mixins.

On the other hand, to counter the gravitational field in anti-gravity coils, it will be sufficient to use currents that are an order of magnitude smaller than the current in mixins. This means that the “supporting” fields will practically not disturb the main magnetic configuration created by the mixins. Let's note the main thing. The equilibrium magnetic configurations calculated in the field of constant currents turn out to be unstable (which is in accordance with the Irnshaw theorem (On the nature of the molecular forces which regulate the constitution of the luminoferous ether / Earnshow S. // Transactions of the Cambridge Philosophical Society. - 1842. - Volume 7. - P.97). Analysis showed that the use of superconductors will ensure the stability of the equilibrium configuration of conductors with current in a magnetic field and in a gravitational field. Of the many different phases exhibiting high temperature superconductivity (HTSC): (R2-xMx) CuO4 , M - alkaline earth or p alkaline earth element, RBa2Cu3Oy, Bi-, Pb-, Tl-, Hg, Ru-containing layered perovskite-like phases (“Synthesis of metal oxide superconductors” A. A. Bush, High-temperature superconductivity: interdisciplinary scientific and technical. Collection, M, VIMI. 1989 , Issue 1, pp. 57-67; “High-Temperature Superconductivity: Fundamental and Applied Research" Collection of Articles, issue 1, under. ed. A.A. Kiseleva, L, "Engineering" Leningrad. branch. 1990.668 s .; A.A. Fotiev, B.V. Slobodin, V.A. Fotiev. “Chemistry and technology of high-temperature superconductors” Yekaterinburg, Ural Branch of the Russian Academy of Sciences, 1994, p. 49; Bush A.A. "Obtaining crystals of new superconducting, ferroelectric and related phases of oxide systems, the study of their structure and properties" abstract, doctoral diss. those. Sci., MIREA, Moscow, 2006, p. 40), the HTB phase YBa2Cu3Oy was selected to create superconducting ceramic rings. When choosing the critical parameters of the superconducting state of the phases, the resistance of the superconducting state of the samples to the action of an external magnetic field, the manufacturability of the samples, the cost of the initial reagents and their toxicity were taken into account.

Preliminary experiments performed at MIREA with several superconducting rings showed that at the same time two superconducting rings placed in a supporting magnetic field of the corresponding configuration are capable of stable levitation. Thus, the existence of stable equilibrium in such systems was experimentally proved.

The quadrupole field is not optimal from the point of view of creating a magnetic barrier. For example, for a quadrupole of two identical coaxial coils with an average diameter of 20 cm and a cross section of 2 cm each, lying in parallel planes with a distance of 12 cm between them, with a current of 10,000 A, the dependence of the field component Bz on the coordinate r in the plane of symmetry z = 0 is determined . It was found that the minimum barrier in this case is ~ 0.006 T, while the field on the system axis is about ~ 0.08 T, that is, it exceeds the minimum barrier by more than an order of magnitude (the field near the surface of the coils is ~ 0.24 T) .

The transition from the levitating dipole to the levitating quadrupole carries the main fundamental difference: it is necessary to achieve the levitation of two interacting coils with current. As soon as this stage is overcome, it will be possible, based on the experience gained, to include additional coils in the levitating system that will correct the field. Several methods can be proposed for achieving the levitation state of the magnetic quadrupole mixin. They will differ in the method of compensating for the magnetic interaction of myxins (it is performed by push-pull coils) and the method of compensating the gravitational attraction of myxin coils in the Earth's gravitational field (it is performed by anti-gravity coils). Below is an example of the use of an anti-gravity coil.

The experiment associated with the capture of magnetic flux by the superconducting coils of the quadrupole in all methods is the same and, in fact, coincides with a similar step in the prototype, when the main coil of the dipole f-coil captures the magnetic flux.

First, both coils in a non-superconducting state at a predetermined distance from each other are installed inside the solenoid (Fig. 1).

Then, current is passed through the turns of the solenoid, and the desired magnetic flux is established through the cross sections of both coils (Fig. 2). Mixin coils are cooled, transferred to a superconducting state and capture the required magnetic flux (Fig. 3). The field of the solenoid is turned off, and the coils in the superconducting state form the magnetic field of the quadrupole (Fig. 4). Then, using the lifting mechanism, the coils are moved into the chamber cavity to a predetermined height. The gravitational effect on the mixins is compensated by the supply of current to the upper superconducting coil, which also affects the balance of the system. Mixin coils are freed from the supports of the lifting mechanism, occupy an equilibrium position at a predetermined height in the vacuum chamber in the levitating position (i.e. without support) and can be used as a trap for plasma (Fig. 5).

Real experience in ensuring equilibrium stability in a system of two superconducting coils with current in one direction has already been gained during experiments with a levitating dipole under the LDX project (Experiments tu Test Plasma Confinement by a Magnetic Dipole / J. Kesner, ACBoxer, JLEllswors et al // 21st IAEA Fusion Energy Conference. - 2006 - Prep. IC / P7-7. - 1-8.). In this project, the gravitational attraction of the main (flying, “floating coil, or, briefly, f-coil) dipole coil is compensated by magnetic attraction to the disk-shaped coil (“ levitation coil ”, or briefly l-coil) made of HTSC material. The mass of the main coil of the f-coil dipole is about 580 kg, the current flowing through it reaches 1.5-10 ⁶ A, therefore the l-coil supporting the magnetic field of the anti-gravity coil only weakly perturbes the main magnetic field of the dipole.

In the simplest equilibrium variant of the levitating quadrupole shown in Fig. 5, the magnetic field in the barrier is highly inhomogeneous. To eliminate this drawback, a variant of the quadrupole levitation shown in Fig.6 is possible. In this case, an additional superconducting coil 8 with a circular cross-section current (with a cross-sectional diameter of 2 cm) located in the mid section of the quadrupole is used as a pusher. Its average radius is 20 cm. This coil is fixed outside the vacuum chamber (but can also be located inside the vacuum chamber). The current flowing through it, in the opposite direction with respect to the current in mixins 3 and 4, is 9855 A. In order to minimize the violation of the symmetry of the magnetic field configuration relative to the plane in which the additional coil 8 is located, two anti-gravity coils 2 and 9 are used. 2 and bottom 9 anti-gravity coils are the same. They have a circular cross-section, 2 cm in diameter, and their average radius is 15 cm. They are located symmetrically with respect to the coils of the quadrupole at a distance of 11 cm from its mid-section. Currents of the same magnitude, but in the opposite direction, flow through them. The planes of all coils are parallel to each other. The current in each mixin is 10 ⁴ A. The current in the upper anti-gravity coil is 653.6 A; in the lower anti-gravity coil it is equal to (-653.6) A, that is, 6.5% of the current in mixins.

Claims (3)

1. The device levitating quadrupole, characterized in that it contains a vacuum chamber and communicating with it a cylindrical compartment in the lower part of the chamber, in which two ring-shaped mixins, each in the form of a coil of superconducting material, are arranged coaxially at a vertical distance from each other , and outside of which a solenoid is placed coaxially with the myxines, designed to pass a current through it to form a magnetic flux passing through the sections of these myxines, a myxin cooling device for transferring the latter to the superconducting state and capture by the mixins of the magnetic flux, a solenoid power source for forming a magnetic field in the mixins in the superconducting state, a mechanism for lifting the cooled mixins from the compartment into the chamber cavity with the solenoid switched off to a level below the coil of superconducting material designed to form a magnetic the field necessary to compensate for the gravitational effect on the two indicated cooled mixins, and located outside the chamber in its upper part with coaxially with both mixins and with the vertical axis of the chamber. 2. The device according to claim 1, characterized in that it is equipped with an additional coil of superconducting material, mounted outside or inside the vacuum chamber, to compensate for their magnetic attraction, to compensate for the gravitational effect on cooled mixins and to adjust the magnetic field of the quadrupole, while this additional a coil is placed between the levitating mixins. 3. The device according to claim 1 or 2, characterized in that it is equipped with at least one more coil of superconducting material, mounted outside the vacuum chamber and located below the lower levitate mixin, to compensate for the gravitational effect on the lower mixin.