RU2576077C1 - Heat engine with valveless gas distribution (optional) - Google Patents

Abstract

FIELD: energy.

SUBSTANCE: invention consists in that the heat engine comprises a cylinder head and the piston, a heater, a refrigerator, and a gas distribution cavity size exclusion mechanism. Head and the piston form a working chamber associated with the displacement cavity flue-channel nozzle. Flue gas-nozzle channel at the entrance of the process chamber forms a swirl of gas. Heater is composed by cylinder inner liner integrated with cylinder head. Refrigerator is composed by cylinder outer jacket. Exclusion in the body cavity located between the inner cylinder shell and coaxially planted on her outer cylinder. Gas distribution mechanism is designed as a swirl of the working gas, formed by tangentially directed flue-channel nozzle at the entrance to the cavity size exclusion. Heat engine with valveless gas distribution further comprises an activator - means for supplying plasma-activation energy of the working gas in the working chamber, which allows the closed inner loop "active" regeneration of the heat of compression.

EFFECT: technical result is to increase efficiency.

20 cl, 2 dwg

Description

FIELD OF THE INVENTION

The invention relates to energy, and in particular to volumetric displacement heat engines with external and internal supply (regeneration) of heat.

State of the art

The prior art device, adopted for the prototype: "Revolving engine with heat supply" (patent application RU 2013119931, publ. 11/27/2014), containing a cylinder with a head and piston forming a working chamber, means for supplying heat - heater, heat removal means — a refrigerator and a distribution mechanism with cylindrical spools having recesses on a part of the side surface, forming displacement cavities associated with the working chamber by annular channels and gas ducts-nozzles, while the spruce is made in the form of an internal cylinder jacket structurally integrated with the cylinder head, and the refrigerator is made in the form of an external cylinder jacket, the spools of the distribution mechanism have a synchronous rotation drive and are placed uniformly around the circumference in cylindrical cavities formed by recesses on the inner cylinder jacket and the outer cylinder jacket, between the inner and the outer shirts of the cylinder coaxially mounted on it.

Despite its attractiveness, this device has drawbacks due to the presence of a complex distribution mechanism, including a complex drive for synchronous rotation of a large number of cylindrical spools with displacement cavities, as well as the presence of a large number of friction surfaces and seal points on the constituent elements, which reduce reliability and engine life.

The prior art (application for invention RU 2013115083, publ. 10.10.2014), an implant method of operating a heat engine and a device that implements this method, comprising a displacement section (cavity) and a thermomechanical energy-converting section interconnected with it by a duct, including a working cylinder with the head and piston forming the working chamber of the volumetric displacement of the working gas with the possibility of heat recovery by the inner surface and with the possibility of filling it with working gas through the gas duct, as well as a plasma supply generator activation energy - activator of the working gas and the swirl of the working gas, formed by the structural oriented at the flue inlet into the working chamber.

The disadvantages of this device include low mechanical power due to the low thermal equivalent of the plasma-forming activation energy, converted into mechanical energy, as well as the lack of special means for external supply and removal of heat (heater and refrigerator) and gas distribution mechanism.

The prior art device is known: “Aerodynamic valve for a pulsating combustion chamber” (SU 459612, published 05.02.1975), where a connection of coaxial cylindrical chambers (cavities) with gas ducts with a tangential orientation using the effect of an aerodynamic valve (gas distributor) is used, certain features of which are applied to solve the problems of the present invention.

SUMMARY OF THE INVENTION

The objective of the invention is to expand the arsenal of heat engines with a simplified gas distribution mechanism and endow them with the functionality of external and internal supply (regeneration) of heat with improved efficiency.

The solution to the problem of simplifying the gas distribution mechanism is provided by the fact that in a heat engine with a gas vortex distribution containing a cylinder with a head and a piston forming a working chamber filled with working gas, heat supply means - a heater, heat removal means - a refrigerator, a displacement cavity associated with the working chamber at least one flue channel-nozzle, a swirl of working gas in the working chamber, formed by the structural orientation of the flue channel-nozzle at the entrance to the working a chamber, and a gas distribution mechanism, wherein the heater is made in the form of an inner cylinder jacket structurally integrated with the cylinder head, and the refrigerator is made in the form of an external cylinder jacket, the displacement cavity is located in the body of the cylinder shell between the inner and outer cylinder jackets coaxially mounted on it, according to the invention, the displacement cavity is made in the form of a radial-axial cylindrical recess (hollow shell), and the gas distribution mechanism is made in the form of a swirler p the working gas in the displacing cavity formed by the structural tangential directivity of the gas duct-nozzle at the entrance to the displacing cavity.

It is well known that for the operation of a heat engine (heat engine) during compression and expansion of the working gas, it is necessary to ensure its interaction with two external heat sources of different temperatures, i.e. with a low-temperature source into which heat of compression is "dumped" (by means of a refrigerator), and with a high-temperature source from which heat is supplied (by means of a heater) during expansion, which is converted into mechanical work.

In the prototype, the interaction is provided by a multi-spool distributor (with displacing cavities), during compression and expansion of the working gas alternately connecting the displacing cavities (working gas) with a refrigerator or with a heater.

In the present invention, the working gas, when compressed in the working chamber, is displaced from it into the displacing cavity through at least one tangential gas channel-nozzle, where, twisting into a vortex, it is pressed against the surface of the outer wall of the displacing cavity formed by the outer jacket of the cylinder (refrigerator), and sweeping it, it interacts with the means of heat removal - the refrigerator, giving it the heat of compression. In this case (due to the fact that the velocity vector of circular motion of the working gas is directed to the surface of the external wall of the displacing cavity), the interaction of the gas vortex with the surface of the internal wall of the displacing cavity formed by the inner jacket of the cylinder (heater) is much weaker, which means it is not decisive. The displacing cavity during compression of the working gas ultimately performs the function of a heat removal (compression) chamber.

Upon completion of the compression stroke and the displacement of the working gas from the working chamber, the vortex movement of the working gas in the displacing cavity also ceases.

When the working gas expands in the working chamber, the gas returns from the displacement cavity to the working chamber through the gas duct-nozzle and due to its structural orientation at the entrance to the working chamber, the working gas is twisted into another (“opposite”) vortex, while “pressed” to the inner surface of the cylindrical wall of the working chamber, which is the inner jacket of the cylinder (heater), and, sweeping it, interacts with the means of supplying heat - the heater, taking away heat from it when the working gas expands nadporshnevogo expense of increasing the volume of the space to the production of useful work by the piston displacement.

When the compressed working gas flows out of the displacing cavity due to its expansion in the working chamber, heat is also taken from the walls, one of which is a refrigerator and the other is a heater, while the amount of heat transfer to the working gas from the wall depends on the difference in temperature. Due to the fact that the temperature of the heater is higher than the temperature of the refrigerator, with the expansion of the working gas, the selection of heat from the heater in the displacing cavity is decisive. As a result, the displacement cavity and the working chamber, having a common adjacent wall, the inner jacket of the cylinder, which is the heater, when expanding the working gas, together perform the function of a heat supply (expansion) chamber.

Thus, the use of the structural orientation of gas ducts (connecting the working chamber and the displacement cavity) both at the entrance to the working chamber and at the entrance to the displacement cavity located in the body of the cylinder shell and made in the form of a hollow “slit-like” cylindrical shell due to the formation of multidirectional working vortices gas and control their termination and transformation (which will be discussed below) can significantly simplify the distribution mechanism, eliminating rotating friction seals spool distribution elements and replacing them with vortex gas distribution.

The solution to the problem of improving the efficiency of the engine and its functionality in the form of external and internal supply (regeneration) of heat is ensured by the fact that the engine containing a cylinder with a head and piston forming a working chamber filled with plasma-forming working gas, means for supplying heat - heater, means for removing heat - a refrigerator, a displacement cavity associated with the working chamber by at least one gas duct-nozzle, a swirl of working gas in the working chamber formed by the structural the gas channel of the nozzle channel at the entrance to the working chamber, and the gas distribution mechanism, the heater is made in the form of an internal cylinder jacket structurally integrated with the cylinder head, the refrigerator is made in the form of an external cylinder jacket, the displacement cavity is located in the body of the cylinder shell between the inner and coaxial the outer shirts of the cylinder planted on it and made in the form of a radial-axial cylindrical recess (hollow shell), and the gas distribution mechanism is made in the form of a swirl I working gas in the displacing cavity formed by the structural tangential directivity of the flue channel-nozzle at the entrance to the displacing cavity, according to the invention further comprises a means for supplying plasma-forming activation energy - an activator of the working gas in the working chamber, functionally converting the working chamber into a working plasma-vortex chamber with the possibility of internal closed loop "active" regeneration of heat of compression.

The presence of a heater, a refrigerator, a displacing cavity and a working plasma-vortex chamber connected by a gas duct-nozzle, as well as a distribution mechanism allows the engine to generate mechanical energy through external heat supply by means of a heater and discharge of the “spent” heat of compression into the refrigerator. The presence of an activator makes it possible to supply the plasma-forming activation energy of the working gas inside the working plasma-vortex chamber and also convert it into mechanical energy (in the volume of its "thermal equivalent"), realizing, in fact, internal heat supply to the engine.

In the process of engine operation, an inner closed cycle of “active” regeneration of compression heat is also realized, which is implemented by the following implant method. In the working plasma-vortex chamber cyclically: the working gas is subjected to volumetric compression and expansion, activation and relaxation, while the activation of the working gas is carried out by means of a temporary and spatial process of forced volumetric dissociation of the working gas from the action of plasma-forming activation energy with the possibility of obtaining dissociation products inside the volume of the working chamber , which are a means of internal heat removal - a regenerative refrigerator, absorbing heat from the working gas including heat in compression, which move to the walls of the working chamber before contact with them, and in the process of contacting the walls of the chamber, the products of dissociation are subjected to relaxation from a nonequilibrium unstable state of activation by means of self-recombination with the release of recombination heat on the inner regenerating surface of the walls of the chamber, which is a regenerative heater - a means of internal supplying heat to the working gas, which is then used to heat the working gas during expansion. In this case, the transfer function of the dissociation products is carried out thanks to the near-wall vortex of the working gas in the working plasma-vortex chamber (by means of a swirler) with the formation of the transformation from the near-wall vortex flow of the internal axial flow of the working gas (directed from the piston to the cylinder head), in which they receive and transfer dissociation products. The described process is nothing more than the realization of an internal closed cycle of “active” regeneration of compression heat — something similar to heat recovery processes in Stirling engines, where, in contrast to “active” regeneration, an internal closed cycle of “passive” heat recovery is carried out by means of a regenerator.

When the internal closed loop of the "active" regeneration of heat of compression is implemented in the present invention, the work on compression of the working gas is sharply reduced, which leads to a significant increase in the efficiency of the heat engine and its power.

List of drawings

The above and other aspects and advantages of the present invention are disclosed in the following detailed description, given with reference to the drawings, which depict:

In FIG. 1 is a longitudinal view of a heat engine in longitudinal section MON; in FIG. 2 shows parts of cross sections PP, Q-Q and view L in FIG. one.

The engine contains a cylinder, the inner jacket of which is a heater 1, structurally integrated with the head 2, and a piston 3, forming a working (working plasma-vortex) chamber 4, a refrigerator 5, which is the outer jacket of the cylinder, gas ducts-nozzles 6 of the entrance to the working chamber, a displacement cavity 7 with tangential gas ducts-nozzles 8 of the entrance to the displacement cavity (performing the function of a vortex gas distributor).

The thermal engine with a vortex gas distribution works as follows.

When the piston 3 moves from the bottom dead center (BDC) to the top dead center (TDC), volumetric displacement of the working gas from the working chamber 4 through the gas passage channel-nozzle 6 and the channel-nozzle 8 into the displacement cavity 7 and compression of the working gas with heat removal ( cooling) in the displacing cavity 7 to a cold source, made in the form of heat removal means - a refrigerator 5, due to its vortex sweeping with working gas. The displacement cavity 7 acts as a heat removal (compression) chamber. Upon completion of the compression stroke as a result of friction against the wall, the vortex movement of the working gas in the displacing cavity slows down and stops.

When moving in the working chamber 4 of the piston 3 from the top dead center (BDC) to the bottom dead center (BDC) in the displacing cavity 7, heat is supplied to the working gas from a hot source made in the form of a heat supply means - heater 1, the gas moves along the gas duct the nozzle channel 8 and the flue nozzle channel 6 into the working chamber 4 and the expansion of the working gas in the working chamber 4 with heat extraction including from the heater 1 from the side of the working chamber with the work on moving the piston 3. Displacement cavity 7 and working chamber EPA 4 collectively act as heat supply chamber (expansion). In this cycle, the working gas during expansion takes away heat from the surface of the head 2 from the inside of the working chamber.

The second embodiment of the heat engine according to the invention further comprises means for supplying a plasma-forming activation energy — an activator of the working gas 9.

In this embodiment, the operation of the engine is as follows.

When the piston 3 moves in the working plasma-vortex chamber 4 from the top dead center (TDC) to the bottom dead center (BDC), the working gas, previously compressed in the previous cycle, returns from the displacement cavity to the working plasma-vortex chamber through the gas duct-nozzle 8 and the gas duct-nozzle 6 and, due to the direction of the latter, is twisted into a vortex, sweeping the heater 1 from the inside and taking away heat from it when expanding in the above-piston space, and also from the outside in the displacing cavity 7 with useful work. When the piston slows down after passing through its middle position and stops at the BDC, the near-wall vortex inside the working plasma-vortex chamber transforms into a return narrow axial flow of working gas directed from the piston to the cylinder head. From the moment the piston is located in the area of the BDC and the formation of the return narrow axial flow of the working gas, the plasma-forming energy is supplied through the activator 9 to the plasma-vortex chamber, which forces the working gas in the space of the volume of the axial flow (dissociation / ionization) to produce heat-absorbing dissociation products from working gas, including heat of compression, during gas compression in a compression cycle. The dissociation products in this cycle (compression cycle) are delivered by flow to the head 2 and the adjacent cylinder walls (inner jacket - to the heater), where upon contact with the surface, the products of dissociation self-recombine with the release of the previously absorbed (during dissociation / ionization) recombination heat and obtaining the source (or other synthesized) working gas, which is displaced into the displacing cavity 7, where, twisting into a vortex, gives up the remaining heat of compression to the swept cooler 5. When as the piston approaches TDC, the activation energy can be cut off. The cycle closes at TDC. Thus, the heater 1 transfers to the working gas during expansion both the external (supplied from outside) heat and also the plasma-forming activation energy (coming from outside) in the form of thermal energy (as a result of its transformation inside the working plasma-vortex chamber during dissociation-recombination) into the volume of its heat equivalent, in addition, performing the function of an internal regenerative (recovering, return) working gas heater with regenerative heat of compression during a closed cycle of internal "active heat recovery working gas compression by dissociation of gas recombination.

In a heat engine, the inner jacket of the cylinder, which is the heater 1, and the outer jacket of the cylinder, which is the refrigerator 5, coaxially mounted on it, can be separated at the interface points according to the invention by the heat insulator 10, which thermally distinguishes the heater from the refrigerator, reducing heat flow, while increasing efficiency.

In a heat engine, the determining linear dimension “a” of the radial width of the base ring of the cylindrical recess forming the displacing cavity (the size of half the difference in the diameters of the circles that are the guides of the cylindrical surfaces of the displacing cavity — the hollow shell) is much smaller than the length determining the axial (longitudinal) dimension “b »Recesses, while the volume of the displacing cavity is less than the volume of the working (working plasma-vortex) chamber.

In a heat engine, gas ducts-nozzles 6 and 8, connecting the working (working plasma-vortex) chamber 4 with the displacement cavity 7, according to the invention pass through the body of the side wall of the inner cylinder jacket (heater 1) in the mating zone of the cylinder head-wall, which reduces dead volume of the working (working plasma-vortex) chamber 4, increasing the specific power.

In a heat engine, gas ducts-nozzles 6 have a tangential, or normal, direction of entry into the working (working plasma-vortex) chamber 4, which helps to improve heat transfer due to the swirling around the inner surface of heater 1, and also helps to reduce the temperature in the friction zone of the skirt piston 3 against the cylinder wall.

In the heat engine according to the invention, the head 2 and the inner jacket of the cylinder — heater 1 additionally form a combustion and / or heat storage chamber 11 adjacent to the working (working plasma-vortex) chamber 4 through the head 2 to burn the fuel mixture and / or place using the burner 12 heat storage substance.

In a heat supply engine according to the invention, the combustion chamber 11 has adjacent to the cylinder head 2 and to the wall of the inner cylinder jacket — heater 1, heat exchange fins 13 (in order to increase heat transfer from burner 12 to heater 1).

In the heat engine, according to the invention, at the junctions of the ribs and between them in the body of the inner jacket of the cylinder there are narrow recesses 14 for measuring and monitoring the temperature of the heater at their bottom using a grid of contact temperature sensors 15 (to avoid local overheating, the so-called "red spots" , and “burnout” of the heater material).

In a heat engine according to the invention, the inner cylinder jacket is a heater 1, through a head 2 it is connected to a heat pipe 16 (for external supply to the heater 1 of concentrated radiant energy of the sun or high-density high-temperature heat energy: nuclear reactors - nuclear reactors, radionuclide fuel elements - fuel elements, radioisotope sources heat - RHT).

In a heat engine according to the invention, the inner jacket of the cylinder is a heater 1, and the head 2 is connected to a heat electric heater (TEN) 17 for external supply of heat to the heater by means of electrical energy (including with an unstable shape, voltage and frequency).

In a heat engine according to the invention, the combustion chamber of the heater is partially or completely filled with a heat accumulator 18, an easily melting heat storage substance, for example, molten salts or metals (eutectics), for temperature control and thermal stabilization, as well as possible heat supply of the engine with a melt from a special melt storage tank.

In a heat engine according to the invention, the head has concentric steps 19 on the inner surface (to increase the heat exchange surface of the head 2).

In a heat engine according to the invention, the cylindrical recess forming the displacing cavity 7 has continuous grooves 20 at the ends opposite to the axis to increase the end volumes of the displacing cavity 7.

The engine uses monogas or a mixture of gases as the working gas.

In the heat engine according to the invention, methane and / or a mixture of hydrocarbon and / or carbon-containing gases, i.e. gases used including for the preparation of a combustible fuel mixture burned in the combustion chamber or specially designed working fluids (gases).

To fill the working chamber of the engine with working gas from the storage tank of the working gas, an inlet valve 21 and an inlet check valve 22 are used.

To displace the working gas in the storage tank (for long interruptions in the engine), an exhaust valve 23 and an exhaust check valve 24 are used.

The means for supplying the plasma-forming activation energy — the activator of the working gas — can be made in the form of a spark plug 9 or a gun container 25 with a radioactive substance 26 that provides unidirectional continuous ionizing radiation.

The means for supplying the plasma-forming activation energy — the activator of the working gas — can be placed in the cylinder head 2 of the working plasma-vortex chamber and / or in the piston 3 of the working plasma-vortex chamber.

The inner and outer shirts of the cylinder (heater 1 and refrigerator 5) can be performed by simultaneous casting (in the assembly: either through a heat insulator, or as a single body) in order to simplify the manufacturing technology of the cylinder and its processing.

For the operation of heat engines with heat supply in order to obtain maximum power, it is recommended to use “light” gases, the molecules of which have the least amount of degrees of freedom (hydrogen and / or helium).

So, when using methane and / or a mixture of hydrocarbon gases in the process of "production" of the engine (from dissociation), hydrogen will be constantly generated.

Moreover, in order to avoid coking of the compression rings, the surface of the head, the walls of the working cylinder and the piston bottom, an undesirable, in this case, “by-product” solid stable product of methane dissociation — atomic carbon and “soot” cations — the engine according to the invention further comprises a carbon atomic carbon trap 27 placed inside the working plasma-vortex chamber 4, filled with methane and / or a mixture of hydrocarbon and / or a mixture of carbon-containing gases. Alternatively, a carbon atomic carbon trap can be placed on the activator of the working gas 9 (for example, on the central electrode of an electric discharge / arc spark plug). The carbon trap of atomic carbon can be made in the form of a "seed" of crystalline carbon with the possibility of its growth as capture and precipitation of dissociation products in the solid phase. The starting material for the “seed” can be carbon with a given structure of the crystal lattice (graphite, fullerene, nanotube, etc.). To intensify the capture of positively charged carbon cations, the following technical solution can be applied: a carbon trap of atomic carbon has an electrically conductive connection with a negative potential of an electromotive force source, while the inner surface of the working chamber has an electrically conductive connection with its positive potential, i.e. negative potential of direct voltage (for example, the same "welding voltage" from the current source of the "arc" discharge, which can be used as a source of plasma-forming energy) can be applied to the carbon trap of atomic carbon (including through the electrodes of the spark plug), and on the metal housing of the working cylinder - positive.

The carbon trap of atomic carbon can be made with the possibility of evacuating the precipitated dissociation products in the solid phase outside the working plasma-vortex chamber, since when the device grows to the limit during operation of the device, the “grown” seed is subject to periodic replacement (which is possible and convenient to carry out together with replacement of a spark plug) and can be used for other needs (for example, in the nanoindustry).

To carry out the forced dissociation of one or another type of working gas used, a different type of impact energy can be chosen, and, accordingly, a spark plug. So the spark plug can be glow with electrothermal heating of tungsten filaments and a pointed rod (“hot” wire), or the spark plug can be made in the form of a laser emitter generating a powerful light flux inside the working chamber. As the plasma-forming energy for dissociation, electromagnetic microwave radiation can be used, while the spark plug can be made in the form of a pin probe exciter. When using radioactive exposure for the purpose of dissociation, the activator of the working gas, as mentioned above, can be made autonomous: in the form of a cannon-container 25 with a radioactive substance 26 that provides continuous unidirectional continuous ionizing radiation.

The technical result of the invention is to simplify the gas distribution mechanism, increase the specific power of the engine, increase efficiency, reliability and engine life.

Claims (20)

1. An engine comprising a cylinder with a head and a piston forming a working chamber filled with working gas, means for supplying heat - a heater, means for removing heat - a refrigerator, a displacement cavity connected to the working chamber with at least one gas channel-nozzle, a swirl of working gas in the working chamber, formed by the structural orientation of the flue channel-nozzle at the entrance to the working chamber, and a gas distribution mechanism, the heater is made in the form of an inner cylinder jacket, structurally combined with the cylinder head, the refrigerator is made in the form of an external cylinder jacket, the displacing cavity is located in the body of the cylinder shell between the inner and the outer shells of the cylinder coaxially mounted on it, characterized in that the displacing cavity is formed by a recess in the form of a hollow shell, and the gas distribution mechanism is made in the form swirl of the working gas in the displacing cavity formed by the structural tangential directivity of the gas duct-nozzle at the entrance to the displacing spine. 2. The engine according to claim 1, characterized in that the inner jacket of the cylinder and the outer jacket of the cylinder at the interface are separated by a heat insulator. 3. The engine according to claim 1, characterized in that the gas ducts-nozzles connecting the displacement cavity to the working chamber pass through the body of the side wall of the inner cylinder jacket in the cylinder head-wall interface. 4. The engine according to claim 1, characterized in that the cylinder head and inner jacket additionally form a combustion and / or heat storage chamber adjacent to the cylinder through the head with a working chamber for combustion with the aid of a burner of a fuel-fuel mixture and / or placement of a heat-storage substance. 5. The engine according to claim 4, characterized in that the combustion chamber has heat exchange fins adjacent to the wall of the inner jacket and to the head, and the head has concentric steps on the inner surface. 6. The engine according to claim 5, characterized in that at the junctions of the ribs and between them in the body of the inner jacket of the cylinder there are narrow recesses. 7. The engine according to claim 1, characterized in that the inner shirt of the cylinder through the head is connected to a heat pipe and / or to a heat heater. 8. The engine according to claim 1, characterized in that the linear dimension of the radial width of the base ring of the cylindrical recess forming the displacement cavity is less than the length of the defining axial dimension of the recess, while the volume of the displacement cavity is less than the volume of the working chamber. 9. The engine according to claim 1, characterized in that the cylindrical recess forming the displacing cavity has continuous grooves at the ends that are opposite along the axis and increase the end volumes of the displacing cavity. 10. An engine comprising a cylinder with a head and a piston forming a working chamber filled with a plasma-forming working gas, means for supplying heat - a heater, means for removing heat - a refrigerator, a displacing cavity connected to the working chamber with at least one gas duct-nozzle, a swirl of working gas in the working chamber, formed by the structural orientation of the flue channel-nozzle at the entrance to the working chamber, and a gas distribution mechanism, while the heater is made in the form of an inner jacket core, structurally combined with the cylinder head, the refrigerator is made in the form of an external cylinder jacket, the displacement cavity is located in the body of the cylinder shell between the inner and the outer shells of the cylinder coaxially mounted on it and is formed by a recess in the form of a hollow shell, and the gas distribution mechanism is made in the form of a swirl of the working gas in the displacing cavity formed by the structural tangential directivity of the gas duct of the nozzle at the entrance to the displacing cavity, characterized in that o additionally contains means for supplying plasma-forming activation energy — an activator of the working gas in the working chamber, which functionally converts the working chamber into a working plasma-vortex chamber. 11. The engine according to p. 10, characterized in that the inner shirt of the cylinder and the outer shirt of the cylinder at the interface are separated by a heat insulator. 12. The engine according to claim 10, characterized in that the gas ducts-nozzles connecting the working plasma-vortex chamber with the displacement cavity pass through the body of the side wall of the inner cylinder jacket in the cylinder head-wall interface, and this determines the linear dimension of the radial width the base ring of the cylindrical recess forming the displacing cavity is less than the length that determines the axial size of the recess, and the volume of the displacing cavity is less than the volume of the working plasma-vortex chamber. 13. The engine according to claim 10, characterized in that the cylinder head and inner jacket additionally form a combustion and / or heat storage chamber adjacent to the cylinder through the head with a working plasma-vortex chamber for burning a fuel-fuel mixture and / or placing a heat-storage substance with In this case, the combustion chamber has heat-exchange fins adjacent to the wall of the inner jacket and to the head, and the head on the inner surface has concentric steps. 14. The engine according to p. 13, characterized in that at the junctions of the ribs and between them in the body of the inner shirt of the cylinder there are narrow recesses. 15. The engine according to claim 10, characterized in that the inner shirt of the cylinder is connected through the head to a heat pipe and / or to a heat heater. 16. The engine according to claim 10, characterized in that the cylindrical recess forming the displacing cavity has continuous grooves at the ends that are opposite along the axis and increase the end volumes of the displacing cavity. 17. The engine according to claim 10, characterized in that the activator of the working gas is located in the cylinder head of the working plasma-vortex chamber and / or in the piston of the working plasma-vortex chamber. 18. The engine according to p. 10, characterized in that the activator is made in the form of a spark plug or in the form of a container gun with a radioactive substance that carries out unidirectional continuous ionizing radiation. 19. The engine according to claim 10, characterized in that it further comprises a carbon atomic carbon trap located inside the working plasma-vortex chamber filled with methane and / or a mixture of hydrocarbon gases and / or a mixture of carbon-containing gases. 20. The engine according to claim 19, characterized in that the carbon trap of atomic carbon is made in the form of a "seed" of crystalline carbon with the possibility of its growth as capture and precipitation of dissociation products in the solid phase, as well as with the possibility of evacuation of precipitated dissociation products in the solid phase beyond the working plasma-vortex chamber.

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