RU2008124524A - METHOD OF WORK OF MULTI-FUEL HEAT ENGINE AND COMPRESSOR AND DEVICE FOR ITS IMPLEMENTATION - Google Patents

Abstract

1. The method of operation of a multi-fuel heat engine and compressor, including conducting electrothermal dissociation of an electrically conductive liquid with the introduction of a compressed solid hydrocarbon or liquid powder into the heating zone, heating, thermochemical decomposition and expiration of gaseous products, characterized in that jets of the electrically conductive liquid are injected into the heating zone, and heating and thermochemical decomposition of solid or liquid fuels is carried out by electric explosion of injected jets by periodic excitation of electric discharges in them with the formation of a red-hot mixture of gaseous decomposition products of hydrocarbon fuel and electrically conductive liquid. ! 2. The method according to claim 1, characterized in that jets of electrically conductive liquid with the addition of metal particles or graphite of sizes 5-10 μm are injected into the heating zone with the electric explosion of the injected jets by periodically exciting electric discharges in them with the formation of a hot mixture of gaseous decomposition products conductive fluid and additives. ! 3. The method according to PP.1 and 2, characterized in that the injection of water jets is carried out in the products of an electric explosion with the formation of gaseous hydrogen and oxygen. ! 4. The method according to claims 1 and 2, characterized in that the electric explosions of the injected jets from an electrically conductive liquid with the formation of a plasma with a temperature of (3-5) · 104 K and more are carried out sequentially one after another in the explosive chambers of the nozzles with the release of plasma jets in zones of reactors by mixing them with water vapor with high temperature and pressure parameters and thermochemical

Claims (14)

1. The method of operation of a multi-fuel heat engine and compressor, including conducting electrothermal dissociation of an electrically conductive liquid with the introduction of a compressed solid hydrocarbon or liquid powder into the heating zone, heating, thermochemical decomposition and expiration of gaseous products, characterized in that jets of the electrically conductive liquid are injected into the heating zone, and heating and thermochemical decomposition of solid or liquid fuels is carried out by electric explosion of injected jets by periodic excitation of electric discharges in them with the formation of a red-hot mixture of gaseous decomposition products of hydrocarbon fuel and electrically conductive liquid. 2. The method according to claim 1, characterized in that jets of electrically conductive liquid with the addition of particles of metals or graphite of sizes 5-10 μm are injected into the heating zone with the electric explosion of the injected jets by periodically exciting electric discharges in them with the formation of a hot mixture of gaseous decomposition products conductive fluid and additives. 3. The method according to PP.1 and 2, characterized in that the injection of water jets is carried out in the products of an electric explosion with the formation of gaseous hydrogen and oxygen. 4. The method according to claims 1 and 2, characterized in that the electric explosions of the injected jets from an electrically conductive liquid with the formation of a plasma with a temperature of (3-5) · 10 ⁴ K and more are carried out sequentially one after another in the explosive chambers of the nozzles with the release of plasma jets into the zones of reactors, mixing them with water vapor with high temperature and pressure parameters and thermochemical decomposition of it into gaseous hydrogen and oxygen at a temperature of explosive gas in the reactor exceeding 2500 ° C. 5. The method according to claims 1 and 2, characterized in that the combustion of the working mixture is carried out sequentially one after another in the zones of the combustion chamber with compressed air by mixing it with gaseous products of thermochemical decomposition of hydrocarbon fuel and electrically conductive liquid, with ignition of the working mixture in the zones of the chamber combustion by shock waves, with the implementation of detonation and the formation of combustion products with increased temperature and pressure. 6. A device for implementing the method according to claims 1, 2 and 3, comprising at least one cylinder with a piston, a crank mechanism associated with the crankshaft, a cylinder cover with a divided combustion chamber, a fuel transportation and pumping fluid transportation and injection system, air supply and exhaust gas discharge, electrical discharge excitation system, characterized in that it is equipped with inlet valves of external and compressed air and exhaust valves of the processed gases and compressed air, with inlet and outlet compressed air valves are connected to the receiver, and the inlet and outlet valves are connected to the wave compressor, or the exhaust gas inlet and outlet valves are connected to the atmosphere, the rocker arms are connected to the solenoids, switched on and off by the electronic engine system, the divided combustion chamber in the cylinder cover is equipped with a combined nozzle for injecting a gaseous mixture of thermochemical decomposition of hydrocarbon fuel and electrically conductive liquid with ignition of the working mixture by repeated electric explosive jets of electrically conductive liquid in the explosive chamber, while the combined nozzle is equipped with an explosive chamber, channels for circulating coolant, a fuel nozzle and nozzles, inside which screws are installed, electrodes placed in cylindrical channels made of insulating material communicating with nozzles directed at an angle to each other in an explosive chamber containing a bottom with holes for the release of hot gases into the combustion chamber, crankshaft cranks s in the form of two elements with the possibility of sliding relative to each other, one of which is equipped with a spring placed at the end of the other containing holes for fluid flow and a cylindrical blind channel, layer-by-layer filled with liquid and compressed gas, the other is made in the form of two halves fastened with studs, and the crank pin of the crankshaft is connected to the sliding part of the crank. 7. The device according to claim 6, characterized in that a piston with a rod pivotally mounted in the sliding part of the crank and a jumper with holes for separating liquid under the piston from the compressed gas are placed in a blind channel with liquid. 8. A device for implementing the method according to claims 1, 2, 3 and 5, containing at least one cylinder with a piston, a crank mechanism associated with the crankshaft, a cylinder cover with a combustion chamber, air supply, transportation and injection of electrically conductive liquid and solid fuel contained in the tank, air supply and exhaust gas discharge, the system of excitation of electric discharges, characterized in that it is equipped with a combustion chamber integrated in the cylinder cover, communicating with the working channels, p evenly spaced around the circumference of the cylinder cover, provided with profiled channels directed at an angle to the piston bottom and the combined nozzle, or the combustion chamber in the cylinder cover is made in the form of a cylinder with inlet and outlet valves and is equipped with sequentially arranged combined nozzles for injecting a gaseous mixture of a thermochemical decomposition of coal dust with a size of 0.5-1.5 mm and electrically conductive liquid and oppositely placed detonator nozzles for the ignition of the working mixture, the combined nozzle contains a cylinder located in the layer of electrical insulation, communicating with the pipeline for supplying compressed powder of solid fuel coal dust, equipped on one side with a piston and a drive mechanism, and on the other, with a mouthpiece, cylindrical channels of electrical insulation material, containing on one electrodes and nozzles with screws mounted in them, and nozzles directed at an angle to each other into an explosive chamber containing a bottom with exit holes gaseous jets, the detonator nozzle is equipped with an explosive chamber, channels for circulating the coolant and nozzles, inside which screws are installed, electrodes placed in cylindrical channels made of insulating material, communicating with nozzles angled to each other in the explosive chamber, the tank for solid fuel contains a piston with a rod in the hydraulic cylinder and a fluid supply pump and is connected to a conical part communicating with a hopper containing a cutter associated with an electric motor m, the hopper communicates with the cylinder, on the one hand containing a piston connected to the rod in the hydraulic cylinder and a liquid supply pump under pressure, and on the other, a conical part connected to the pressure pipe for supplying compressed solid fuel powder to the nozzle. 9. A device for implementing the method according to claims 1, 2 and 3, comprising a cylinder with caps and a combined nozzle, a system for supplying atmospheric air and exhaust gases and compressed air, transporting and pumping electrically conductive liquid and fuel, a system for exciting electric discharges, characterized in that it is equipped with an inlet valve for atmospheric air with a drive-solenoid mechanism and exhaust valves for exhaust gases and compressed air containing solenoid drive mechanisms, on and off Depending on the electronic system of the wave compressor, the combined nozzle for injecting into the combustion zone of the cylinder a gaseous mixture of thermochemical decomposition of hydrocarbon fuel and electrically conductive liquid and igniting the working mixture with a second electric explosion of jets of electrically conductive liquid is equipped with an explosion chamber, channels for circulation and cooling by liquid, a fuel nozzle and nozzles, inside which are installed with screws, electrodes placed in cylindrical channels made of electro material, communicating with nozzles directed at an angle to each other in an explosive chamber containing a bottom with openings for the exit of gaseous jets, or the ignition of the working mixture is carried out by injection into the combustion zone of incandescent products of electrothermal decomposition of jets of electrically conductive liquid nozzles placed opposite to the first containing explosive a chamber, channels for the circulation of coolant and nozzles, inside which screws are installed, electrodes placed in cylindrical channels made of electrical insulating material in communication with nozzles directed at an angle to each other in the explosive chamber. 10. The device according to claim 9, characterized in that it contains a receiving chamber for air inlet, equipped with a grill with nozzles and plate self-acting valves, a damping device with a concave reflector in communication with the cylinder, the cylinder, on the one hand, contains nozzles placed evenly around the circumference, for injecting a gaseous mixture of products of electrothermal decomposition of the electrically conductive liquid, while the nozzle for injecting the mixture is equipped with an explosive chamber, channels for circulating cooling liquid tee and nozzles, inside which screws are installed, with electrodes placed in cylindrical channels made of insulating material, communicating with nozzles directed at an angle to each other in the explosive chamber, and on the other, a grill with nozzles and plate self-acting exhaust valves for releasing compressed air and spent grooves of conductive fluid. 11. A device for implementing the method according to claims 1, 2 and 4, comprising reactors in series, combustion chambers, wave compressors and a turbine, a condensation and condensate return system to a working process, a heating system for heating a liquid coolant, a heat exchanger, a transportation and discharge system liquid metal and water, the system of excitation of electric discharges, characterized in that the reactors are made in the form of elongated cylinders and are located uniformly around the circumference, equipped with steam distribution mechanisms connected to a steam collector connected to a heat exchanger, nozzles for injecting products of electrothermal decomposition of an electrically conductive liquid, placed sequentially one after another in the zones of the reactors - and nozzles for injecting water, while nozzles for injecting products of electrothermal decomposition are equipped with explosive chambers, channels for cooling circulation liquids and nozzles inside which the screws are installed; electrodes placed in cylindrical channels made of electric of insulating material communicating with nozzles directed at an angle to each other in an explosive chamber in communication with a reactor connected to a pipe and a combustion chamber, the combustion chambers are made in the form of large-diameter cylinders and are equipped with nozzles with explosive chambers for igniting detonating gas and tapering or expanding nozzles connected to long pipes of wave compressors, containing concave reflectors at the ends, connected to the steam collector of a steam turbine with an electric generator. 12. The device according to claim 11, characterized in that the casing of the steam turbine is connected to a magnetic filter containing an expansion chamber with a pipe for periodically removing the condensed liquid metal, equipped with an external magnet. 13. A device for implementing the method according to claims 1 and 2, comprising a compressor connected to combustion chambers evenly spaced from each other, communicating with a gas turbine, a system for transporting and pumping coal dust from a hopper and an electrically conductive liquid, a cooling system, a system excitation of electric discharges, characterized in that the combustion chambers are equipped with combined nozzles for injecting a gaseous mixture of thermochemical decomposition of coal and electrically conductive liquid with ignition using the working mixture by repeated electric explosions of jets of electrically conductive liquid in the explosive chambers of the combined nozzles, or the ignition of the working mixture is carried out by hot gaseous jets of electrically conductive liquid injected into the combustion chambers by nozzles placed opposite to the first containing the blast chamber, channels for cooling fluid circulation and nozzles inside which installed screws, electrodes placed in cylindrical channels made of insulating material, communicating with nozzles directed at an angle to each other in an explosive chamber provided with a bottom with openings, the combined nozzles contain a cylinder located in the layer of electrical insulation, communicating with the compressed powder solid fuel supply pipe, equipped with a piston and a drive mechanism on one side, and with on the other hand, with a mouthpiece, cylindrical channels made of insulating material contain electrodes and nozzles on one side with screws mounted on them, and nozzles directed on the other hand d angle to each other in the blast chamber, containing the bottom with openings for the exit of gaseous jets, the combustion chamber, on the one hand connected by supply channels to the compressor, and on the other, with tapering or expanding nozzles and long pipes of wave compressors connected to the gas guide apparatus turbines, the hopper contains a vertical shaft with bills and communicates with a receiving device equipped with a conical part with a pipeline, with a piston placed in it for displacing coal dust associated with a crank no-crank piston drive mechanism. 14. A device for implementing the method according to claims 1, 2 and 5, comprising a compressor, damping devices, combustion chambers, wave compressors with a gas turbine, transportation and injection systems of liquid fuel and electrically conductive liquid, an electric discharge excitation system, a system cooling, characterized in that the combustion chambers are equipped with combined nozzles for injecting a gaseous mixture of thermochemical decomposition of liquid fuel and conductive liquid, placed sequentially one after another in the zones of the combustion chambers and opposite detonator nozzles, the combined nozzle is equipped with an explosive chamber, channels for circulating coolant, a fuel nozzle and nozzles, inside which screws are installed, with electrodes placed in cylindrical channels made of electrical insulation material in communication with nozzles directed at an angle to each other in an explosive chamber containing a bottom with openings for the exit of gaseous jets , the detonator nozzle is equipped with an explosive chamber, channels for cooling fluid circulation and nozzles, inside which screws are installed, with electrodes placed in cylindrical channels made of insulating material, communicating with nozzles angled to each other in the explosive chamber communicating with the camera combustion, damping devices are made in the form of cylinders and equipped with concave reflectors, wave compressors are made in the form of long pipes on one side containing expanding nozzles, connected to combustion chambers, and on the other, concave reflectors connected to a gas turbine manifold connected to an electric generator.