UA125075C2 - Impulse axal inductive accelerator of plasma ring in aerial environment of atmospherical pressure - Google Patents

Abstract

The invention relates to plasma technical devices and to plasma technologies, and more specifically it relates to plasma accelerators. The impulse axial inductive accelerator of plasma ring in aerial environment of atmospherical pressure consists of coaxially located cylindric guide tube, external cylindric magnet and system of thermal ionization of a substance to the plasma state. One of the open ends of the cylindric guide tube is in the atmospherical environment, and at its other end there is the gas flow formation system. Inside the guide tube, there is the coaxially located internal cylindric magnet, which forms, with the external cylindric magnet, the magnetic system, which forms the magnetic field induction component lateral in relation to the guide tube axis. The system of thermal ionization of a substance consists of the electrically conductive ring located in the gaping between the guide tube and internal cylindric magnet, which goes into the plasma state as a result of an electric explosion. The gas flow formation system consists of a gas detonation tube closed at one end and the gas detonation gas feed system. The electrically conductive ring is made in the form of a wire consisting of two identical parts, the ends of which are interconnected and hooked up by means of a switch to a high-voltage impulse energy storage, or in the form of foil in the shape of a flat disk limiting the exposure of gas detonation gas from the guide tube. Cylindric electromagnets are connected to the impulse energy storage by means of a switch, and the guide tube is made of insulating material. The technical result of the invention is in increase of specific power rating, ease of operations management, improvement of reliability, decrease of expenses during manufacture and operation, and reduction of boundary dimensions.

Description

two identical parts, the ends of which are interconnected and connected by means of a commutator to a high-voltage pulsed energy storage device, or in the form of a foil in the form of a flat disk, which limits the exit of gas detonation gas from the guide pipe. Cylindrical electromagnets are connected to the pulse energy storage device by means of a commutator, and the guide pipe is made of insulating material. The technical result of the invention is an increase in specific power, ease of work management, increase in reliability, reduction of costs during manufacture and operation, reduction of overall dimensions. 151617. 12.10.14 2 B 22 ra : t "I ti uh Dr ltlll ooo tvoosk mil de pa rr 10 p 6 A A ЮА А 71111111 - я-BrЯ | El vn pi LIA YAKI 3 "in generic 1

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The invention relates to plasma technology and plasma technologies, and more specifically to pulsed plasma accelerators.

A known pulsed plasma accelerator containing electrodes (cathode and anode), one of which is made in the form of a copper rod and the other in the form of a plate, a solid dielectric working substance in which ablation occurs under the action of an electric discharge, a system for supplying the working substance to the discharge channel rail type and discharge initiation system (11.

The electrodes of the accelerator are powered through current leads from the external energy storage. The operation of such an accelerator is carried out under low gas pressure in the accelerator channel.

A pulsed plasma accelerator is also known, which contains an accelerating channel formed by two electrodes, an insulator that separates them and which is the working substance, a discharge initiation system and a capacitive energy store connected to the electrodes via a current line. Teflon |21 is used as a working substance in this accelerator.

The disadvantage of the described plasma accelerators is low traction efficiency and specific power, which is due to the use of only the energy stored by the electric field for acceleration. The field of application of such accelerators is limited to a vacuum environment, where the condition of exceeding the electromagnetic pressure over the gas-dynamic pressure is achieved. Also, the effectiveness of such accelerators is limited by the long process of creating the working substance due to the limited rate of evaporation of Teflon and its uneven evaporation.

A known plasma accelerator, which contains electrodes (cathode and anode) connected through an ohmic and inductive load to a capacitive energy store, an end ceramic insulator that separates the electrodes and dielectric checkers made of the material in which ablation occurs. At the same time, checkers are installed between the electrodes (|Z). The energy accumulator is connected to the electrodes through thin current conductors. The walls of the discharge channel are formed by the surfaces of electrodes and dielectric checkers. The electrodes in the plasma accelerator are made in the form of plates. The discharge initiation device is located in a recess made in the end insulator. Dielectric checkers are made with the possibility of moving towards the middle line of the discharge channel with the help of a spring pusher.

З Acceleration of the plasma in the discharge channel of the plasma accelerator is carried out as follows. A short high-voltage pulse from the discharge initiation unit is applied to the electrodes of the discharge initiation device. As a result of a surface breakdown, a plasma clot is formed, which short-circuits the electrodes of the accelerator in the recess of the end insulator, in which an arc-type electric discharge is formed. The working substance, evaporated from the surface of the dielectric checkers by the radiant energy of the discharge, is ionized and accelerated under the action of electromagnetic forces and gas-dynamic pressure.

In this accelerator, a more uniform creation of the working body in the accelerator channel was achieved as a result of the evaporation of Teflon. The efficiency of acceleration has also been increased due to the use of both electromagnetic forces and gas-dynamic pressure.

However, the disadvantages of low specific power due to the use of only electrical energy to create electromagnetic and gas-dynamic forces, the presence of limitations in the area of application of the accelerator, associated with low gas pressure, remained unresolved.

A pulsed plasma accelerator is known, which contains a cylindrical electromagnet, which provides thermal ionization of matter to the plasma state and further acceleration of the plasma in the form of a ring under the action of electromagnetic forces |4|. At the same time, the axis of symmetry of the plasma ring coincides with the axis of the cylindrical magnet.

Formation and acceleration of plasma in the specified plasma accelerator is carried out as follows. A powerful high-frequency current generator is connected to a cylindrical electromagnet made in the form of a flat coil. An eddy current is induced in the gas above the surface of the coil under the action of the variable magnetic field of the coil. Under the action of the current induced in the gas, it is heated and thermally ionized. The configuration of the magnetic field of the coil ensures the formation of plasma in the form of a ring, the axis of symmetry of which is aligned with the axis of the coil. In the process of thermal ionization, there is an increase in the electrical conductivity of the gas and, accordingly, an increase in the discharge current in the plasma. The interaction of the coil current with the induced eddy current leads to the appearance of an electrodynamic force. Under the influence of this force, axial acceleration of the plasma in the form of a ring occurs.

The known device has a simple design. However, this device cannot operate in atmospheric pressure gas. This is due to the induction of a low electric field strength, which is not sufficient for atmospheric pressure gas breakdown. In addition, relatively low values of plasma acceleration are provided, since only electrodynamic forces are used.

The closest in terms of technical essence is the device for creating and accelerating plasma, which consists of a cylindrical guide tube, an external hollow cylindrical magnet and a system of thermal ionization of matter to the plasma state I5)|. At the same time, the specified pipe and magnet are located coaxially relative to each other. One of the ends of the specified cylindrical pipe is open and is in the air environment. On the other end of the cylindrical pipe, there is a gas flow formation system, which is made in the form of a gas turbine engine. The system of thermal ionization of matter to the plasma state consists of discharge electrodes located inside the guide tube and an induction plasma heater.

The working element of the induction heater is an electromagnetic coil that covers the guide tube and ensures the formation of plasma inside the guide tube in the form of a ring, the axis of which coincides with the axis of the guide tube.

In this device, due to the gas turbine engine, a heated gas flow is formed, which is then directed into a cylindrical pipe. The temperature of the gas stream reaches more than 1000 "C. The heated gas in this state is weakly ionized and, accordingly, has a high electrical resistance. Since in this state the gas is accelerated by electromagnetic forces inefficiently, it is sent to the system of thermal ionization of matter to the plasma state. In this system the gas is first heated by arc discharges, which are implemented by discharge electrodes located inside the guide pipe. The arc discharge provides heating of the gas to a high temperature, usually up to 5000-10000 "C, but only in the arc combustion area. Therefore, the unevenly heated gas then enters the area of action of the induction heater, where, under the action of induced eddy currents, plasma is formed in the form of a ring. Due to the fact that the working element of the induction heater is located coaxially with the cylindrical pipe, the axis of the annular plasma that is formed is aligned with the axis of the guide pipe. Further, in the gas flow, the ring plasma moves into the area of the magnet. Under the action of pulsed magnetic fields alternately created by magnets located along the cylindrical guide tube, ionized plasma formation is further accelerated by electromagnetic forces.

This device achieves a high specific power due to the combined use of the chemical energy of fuel combustion and the energy of the electromagnetic field. This device also provides high efficiency of electromagnetic acceleration of the gas flow due to the use of a system of thermal ionization of matter to the plasma state operating in atmospheric pressure gas.

However, the known device is impractical to use in the pulse mode, since the gas turbine engine cannot work in this mode. Also, this device has a complex design due to the presence of a gas turbine engine for the formation of a gas flow, a technically complex system of electric discharge and induction heaters for the formation of plasma in the form of a ring. In the pulsed mode, there are difficulties in synchronizing the pulsed flow of gas with the time of switching on and off the thermal ionization system.

In addition, this device uses a complex system for controlling the acceleration of ionized plasma formation, which uses alternating activation of magnets located along a cylindrical guide tube. At the same time, the moments of turning on the magnets must be strictly synchronized with the speed of movement of the plasma formation.

The task of the proposed invention is to create a pulsed axial inductive accelerator of a plasma ring in an air environment of atmospheric pressure, which provides an increase in specific power, ease of operation management, increased reliability, a reduction in costs during manufacturing and operation, and a reduction in overall dimensions.

The problem is solved by the fact that in a pulsed axial inductive accelerator of a plasma ring in an air environment of atmospheric pressure, consisting of a coaxially located cylindrical guide tube, an external cylindrical magnet and a system of thermal ionization of matter to the plasma state, one of the open ends of the cylindrical guide tube is in the air medium, and on its other end there is a gas flow forming system, an external cylindrical magnet covers the guide tube, and a system for thermal ionization of matter to the plasma state is located inside the guide tube and forms plasma in the form of a ring, the axis of which is aligned with the axis of the guide tube, according to the invention , which is proposed, an internal cylindrical magnet is coaxially located inside the guide pipe, which forms a magnetic system with the external cylindrical magnet, which forms a magnetic field induction component transverse to the axis of the guide pipe, a system of thermal and ionization of the substance consists of an electrically conductive ring located in the gap between the guide tube and the internal cylindrical magnet, which turns into a plasma state as a result of an electric explosion, the gas flow formation system consists of a gas detonation tube, closed at one end, and a gas detonation gas supply system.

In addition, cylindrical magnets are made in the form of highly coercive permanent magnets.

In addition, cylindrical magnets are made in the form of electromagnets that are connected to a power source.

In addition, the conductive ring is made in the form of a wire consisting of two identical parts, the ends of which are connected to each other and connected by means of a commutator to a high-voltage pulsed energy storage device.

In addition, the conductive ring is made in the form of a foil in the form of a flat disk, which limits the exit of gas detonation gas from the guide pipe.

In addition, the inner cylindrical magnet is mounted on the inner cylindrical guide tube, which is attached to the closed end of the gas detonation tube.

In addition, the gas detonation tube is made of high-strength material and is coaxially located with the cylindrical guide tube.

In addition, a container with high-pressure gas detonation gas is connected to the closed end of the gas detonation pipe using a quick-acting valve.

In addition, the cylindrical electromagnets are connected to the pulsed energy storage device by means of a commutator, and the guide pipe is made of insulating material.

In addition, the conductive ring in the form of a wire is connected to a foil, which is made of a dielectric material and which limits the exit of gas detonation gas from the guide tube.

In addition, the power source of electromagnets is a pulsed energy store.

The internal cylindrical magnet together with the external cylindrical magnet forms a magnetic system that forms the transverse component of the induction of the magnetic field relative to the axis of the guide tube. This magnetic system makes it possible to induce an eddy current in the moving plasma ring, which increases the existence time of the plasma formation and the distance of departure from the guide tube. Due to the magnetic system, the magnetic energy is increased

From an accelerating plasma ring.

An increase in the specific power of the accelerator is achieved due to the pulse mode of operation and the simultaneous supply to the plasma ring of several types of energy, namely electrical energy, which ensures the explosion of the conductive ring, kinetic energy of gas detonation gas, which ensures an increase in speed, and electromagnetic energy from the magnetic system, which provides increasing the energy of the magnetic field in the plasma ring.

In comparison with the prototype, simplicity in managing the work is achieved due to the absence of a special synchronization system between the above energy supplies. During the start-up of the accelerator, electric energy is supplied to the conductive ring, which causes its explosion, as a result of which gas detonation occurs, which accelerates the plasma ring through the magnetic field of the magnetic system, which increases the energy of the magnetic field in it.

For reliable fixation, the internal cylindrical magnet is installed on the internal cylindrical guide tube, which is attached to the closed end of the gas detonation tube, which makes the design of the device mechanically reliable.

If the cylindrical magnets are made in the form of highly coercive permanent magnets, then there is no energy consumption for them.

If the cylindrical magnets are made in the form of electromagnets, then the power source can be direct or alternating current. However, it is more expedient to implement a power source in the form of a pulse energy store, for example, a capacitive one. In the case of connecting electromagnets with the help of a commutator to a pulsed energy accumulator due to the pulsed mode, it is possible to increase the current density in them many times, and therefore the magnitude of the induction of the magnetic field, which is unattainable in the case of long-term operation. At the same time, the guide pipe for the penetration of the magnetic field must be made of insulating material. The pulsed magnetic field induces an eddy current of high density in the conductive ring, which leads to its electric explosion and transition to the plasma state. This process will be especially effective if the conductive ring is made in the form of a foil in the shape of a flat disk. Due to the short-term pulse mode of operation alternating with a long pause, the total energy consumption of the magnetic system is low.

In the gap between the guide pipe and the internal cylindrical magnet, there is an electrically conductive ring, the axis of which is aligned with the axis of the guide pipe. This ring can be 60 made in the form of a wire consisting of two identical parts, the ends of which are connected to each other and connected by means of a commutator to a high-voltage pulsed energy storage device.

During the discharge of a pulsed energy storage device, such as a capacitive one, an electrical explosion occurs in the wire, which turns it into a plasma state. Due to the fact that the ends of the ring parts are connected to each other, a circular eddy current is induced in them as a result of movement through the magnetic field of the magnetic system. In the formed plasma ring, the axis is aligned with the axis of the guide tube.

The gas flow formation system consists of a gas detonation pipe, closed at one end, and a gas detonation gas supply system. A container with high-pressure gas detonation gas is connected to the closed end of the gas detonation pipe by means of a quick-acting valve. Therefore, when the valve is opened, gas flows from the container into the gas detonation pipe without additional supercharging by a compressor or turbine. The gas detonation pipe is made of a material of increased strength, such as stainless steel, which increases the reliability of the device, and is coaxially located with a cylindrical guide pipe, which makes the design technological during manufacture and operation. Gas detonation and guide pipes are easily connected to each other with the help of flanges.

If the conductive ring is made in the form of a wire connected by a foil (made of a dielectric material, then this foil limits the exit of gas detonation gas from the guide pipe through the open end. If the conductive ring is made in the form of a foil in the form of a flat disk, then its shape is specified the disk restricts the exit of gas denatation gas from the guide pipe.

Thus, increasing reliability, reducing costs and reducing overall dimensions of the device is achieved due to the absence of complex mechanical, electronic and electromagnetic devices, for example, a turbine and its drive motor and a simpler magnetic system. Due to the pulse mode of operation and the absence of complex devices, energy costs for operation are reduced.

The invention is explained with drawings.

In fig. 1 schematically presents a pulsed axial inductive accelerator of a plasma ring in an air medium of atmospheric pressure, in which the conductive ring is made in the form of a wire;

Fig. 2 shows a schematic diagram of a pulsed axial inductive accelerator of a plasma ring in an air environment of atmospheric pressure, in which the electrically conductive ring is made in the form of a foil in the form of a flat disk; in fig. C - an electrically conductive ring in the form of a wire, consisting of two identical parts, the ends of which are connected to each other; in fig. 4 - view A in fig. 1; in fig. 5 - view B in fig. 1 (the wire is shown by a dashed line).

The pulsed axial inductive accelerator of the plasma ring in an air environment of atmospheric pressure consists of a cylindrical guide tube 1, an external cylindrical magnet 2 and a system of thermal ionization of matter to the plasma state, which are coaxially located along the axis 3.

One of the ends T of the cylindrical guide pipe 1 is open and is in the air environment, and on its other end 15 there is a gas flow formation system.

The external cylindrical magnet 2 covers the guide pipe 1. The system of thermal ionization of matter to the plasma state is located inside the guide pipe 1. The pipe 1 is made of an insulating material, for example, glass-textolite.

Inside the guide tube 1, an internal cylindrical magnet 4 is coaxially located, which forms a magnetic system with the external cylindrical magnet, which forms a magnetic field induction component transverse to the Z axis.

The system of thermal ionization of matter consists, at least, of an electrically conductive ring, which is located in the gap 5 between the guide pipe 1 and the internal cylindrical magnet 4. In Fig. C - fig. 5, the conductive ring is made in the form of a wire 6, and which consists of two identical parts ba and 6, the ends bs of which are connected to each other and connected through a switch 7 to a high-voltage pulse energy storage device 8. The wire b is connected to a foil 9 of dielectric material, which limits the output of degassing gas 10 from the guide pipe 1 (Fig. 5).

In fig. 2, the conductive ring is made in the form of a foil 11 in the form of a flat disk, which limits the output of gas detonation gas 10 from the guide pipe 1.

The gas flow formation system consists of a gas detonation pipe 12, which is closed by an end wall 13 from one of the ends, and a gas detonation gas supply system 10. Because the gas detonation pipe 12 is coaxially located and connected to the guide pipe 1 by means of connecting flanges 14. Gas detonation pipe 12 is made of high-strength material, for example, stainless steel.

The gas detonation gas supply system 10 consists of a container 15 for gas detonation gas 10 of increased pressure, which is connected to the end wall 13 of the gas detonation pipe 12 through a pipeline 16 and a valve 17. To the container 15 by means of pipelines 18 and 19, on which valves are installed, respectively 20 and 21, a container 22 with compressed gas and a container with an oxidizer 23, such as oxygen, are connected.

The outer 2 and inner 4 cylindrical magnets can be made in the form of highly coercive permanent magnets, for example, Ma2ERe14V, 5tCo5 or 5t2Co017 (Fig. 1).

The outer 2 and inner 4 cylindrical magnets can be made in the form of electromagnets, which are connected to the power source 25 through the switch 24 (Fig. 2). This power source can be high-frequency alternating current or pulsed, for example, a capacitive energy storage.

The internal cylindrical magnet 4 is installed on the internal cylindrical guide tube 26, which is attached to the end wall 13 of the gas detonation tube 12.

The pulsed axial inductive accelerator of the plasma ring in an air medium of atmospheric pressure works as follows.

Valves 20 and 21 are opened through pipelines 18 and 19 from containers 22 and 23, compressed combustible gas and oxidizer are fed into container 15, forming gas detonation gas 10 (Fig. 1).

After that, the valve 17 is opened and through the pipeline 16, gas detonation gas 10 of high pressure enters the gas detonation chamber 12 and the pipe guide 1. Valves 20, 21 and 17 close.

Due to the presence of a foil 9 made of a dielectric material (Fig. 1) and an electrically conductive foil 11 in the form of a flat disk (Fig. 2), the density of the gas detonation gas 10 in the gas detonation 12 and guide pipes 1 increases, preventing its exit into the surrounding air through the open end 1a cylindrical guide pipe 1.

Immediately after that, the switch 7 is closed, and the high-voltage pulse energy store 8 is connected to the wire 6 in the form of a ring (Fig. 1). At the same time, an electric explosion occurs, which converts the wire into a plasma state in the form of a ring, the axis of which is connected to the axis of the guide pipe 1. During the explosion of the wire 6, detonation of gas detonation gas 10 occurs

From increased density. As a result, the gas flows at a high speed through the gas detonation pipe 12, the connecting flanges 14 and the guide pipe 1 in the direction of its open end 1a. This gas flow accelerates the plasma creation in the form of a ring in the gap 5 between the guide tube 1 and its internal cylindrical magnet 4 in the same direction.

During movement, the plasma ring crosses the component transverse to the Z axis of the magnetic field induction. An eddy current is induced in the plasma ring, which additionally heats the plasma ring and increases the energy of the magnetic field in it. As a result, the plasma ring, which has a high specific power, flies out of the guide pipe 1 at a high speed for a considerable distance.

Provided that the outer 2 and inner 4 cylindrical magnets are in the form of electromagnets, after filling the gas detonation 12 and guide 1 pipes with gas detonation gas 10, switch 24 is closed (Fig. 2). The pulsed or high-frequency power source 25 excites an eddy current of high density in the electrically conductive foil 11 in the form of a flat disk.

As a result, the electric explosion transforms the foil 11 into a plasma state in the form of a ring with the subsequent detonation of the gas 10 and its movement in the direction of the open end of the cylindrical guide pipe 1.

Thus, the proposed axial inductive accelerator of a plasma ring in an air environment of atmospheric pressure provides an increase in specific power, ease of operation management, high reliability, low consumption of material resources during manufacturing and low consumption of energy resources during operation, small overall dimensions.

Sources of information: 1. Vatsak Ai., Ashptor M.M., Rorom A.A. РиізедріазтаїйНгивіегоїегозіопіурег а деозіайопагуапіїісіа'єапнзаїеїШе // 44 СопдгеззоППпеїпіегпайопаІіАвігопацііса|Редегаїйоп, ІАЕ-93- 5.5.487, Ста, А!йвійа: ІАЕ, "С-їорег 16-22, 1993. 2. Стедогу с. Зрапієгзеїа!. ІпмевіїдайопоїргореПапііпейісіепсівевіп а риїзедріазтаїйнгивіег / / AIDA-96-2723, Z2pa URS, I akeViepa Mivia, RI, BOTH: AIAA / ABME / ZBAE / ABEBE, shu 1-3, 1996... 3. Pat KO 2143586 C1, IPK MISCELLANEOUS1 /00, NO5NI/54 , published on December 27, 1999. 4. Roihip K.A., Spotseii E.M. Repoptapse Oriitigainyop Styegia og Ryived Ipdysime Riazta

Asseiegayop // IEEEE Tgapsasiyopz5 op riaeta z5siepse, My. 34, p. Uipe 2006, R. 945-953.

B. Ipietaiiopa! Rybiysayop Mytbreg UUO 2016/151609. Riaeta rgoriiviop zuziet apa teinod. - (510) Rybiysayop 09/29/2016. Yippee Paradise Siaz. NOBN 1/54, RO2K 3/00, ROZN 1/00.

Claims (1)

FORMULA OF THE INVENTION 1. A pulsed axial inductive accelerator of a plasma ring in an air environment of atmospheric pressure, consisting of a coaxially located cylindrical guide tube, an external hollow cylindrical magnet and a system of thermal ionization of matter to the plasma state, while one of the open ends of the cylindrical guide tube is in an air environment, and on its other end there is a gas flow formation system, an external cylindrical magnet covers the guide tube, and a system for thermal ionization of matter to the plasma state is located inside the guide tube and forms plasma in the form of a ring, the axis of symmetry of which is connected to the axis of the guide tube, which is distinguished by that an internal cylindrical magnet is coaxially located inside the guide tube, which forms a magnetic system with the external cylindrical magnet, which forms a magnetic field induction component transverse to the axis of the guide tube, a system of thermal ionization of the glass substance is given by an electrically conductive ring located in the gap between the guide tube and the internal cylindrical magnet, which turns into a plasma state as a result of an electric explosion, the axis of which is aligned with the axis of the guide tube, the gas flow formation system consists of a gas detonation tube closed at one end, and gas detonation gas supply systems. 2. Pulsed axial inductive accelerator according to claim 1, which is characterized by the fact that the cylindrical magnets are made in the form of highly coercive permanent magnets. Z. The pulsed axial inductive accelerator according to claim 1, which is characterized by the fact that the cylindrical magnets are made in the form of electromagnets, which are connected to the power source by means of a commutator. 4. Pulsed axial inductive accelerator according to claim 1, which is characterized by the fact that the conductive ring is made in the form of a wire consisting of two identical parts, the ends of which are connected to each other and connected by means of a switch to a high-voltage pulsed energy storage device. 5. Pulsed axial inductive accelerator according to claim 1, which is characterized by the fact that the electrically conductive ring is made of foil in the form of a flat disk, which limits the exit of gas detonation gas from the guide pipe. 6. Pulsed axial inductive accelerator according to claim 1, which is characterized by the fact that the internal cylindrical magnet is installed on the internal cylindrical guide tube attached to the closed end of the gas detonation tube. 7. Impulse axial inductive accelerator according to claim 1, which is characterized by the fact that the gas detonation tube is made of a material of increased strength and is coaxially located with the cylindrical guide tube. 8. Impulse axial inductive accelerator according to claim 1, which is characterized by the fact that a container with gas detonation gas of high pressure is connected to the closed end of the gas detonation pipe by means of a quick-acting valve. 9. The pulsed axial inductive accelerator according to item C, which is characterized by the fact that the cylindrical electromagnets are connected to the pulsed energy accumulator by means of a commutator, and the guide pipe is made of insulating material. 10. The pulsed axial inductive accelerator according to claim 4, which is characterized by the fact that the electrically conductive ring in the form of a wire is connected to a foil made of a dielectric material, which limits the exit of gas detonation gas from the guide tube. 11. A pulsed axial inductive accelerator according to claim 3, which is characterized by the fact that the power source of the electromagnets is a pulsed energy store. (with; 18 20 1516 17 12 10 14 2 E ШХ Y sha 22 ! ke sik SCHI te I Pr ooo oosooo shk. that GO o tya- IZ 2 6 2 2ZZl 5 I Z 2 2 ( ( ( - yo nzhyapH i 1 osn A 3-1 VA port rt tk 3 ! и и и и и и и и и и и и и и и и и и и и и и и и и и и и и и и и и 19. D21 13 26 5 4 of 8 Phi 16 17.12. 26 14 11 th I Y i yad sho Gu sedge -1a I 7... - 1 se- TT to go r LY - 'LN ' y TA Se I SY PELETY GLELEBLIL V PIN i p i i i ooo 14 ik pi i 83770 3 10 1b 24 Fig. 2 va in Uh her be h u u riya - ; - what do you do? F. Z