RU2000115579A - HEAT ENGINE WITH INCREASED USEFUL EFFICIENCY - Google Patents

Claims (19)

1. A method of converting thermal energy into mechanical energy in a heat engine with a first thermodynamic circular process and at least a second circular process, wherein the waste heat of the first circular process is brought to the second circular process, and the waste heat of the second circular process is brought to the first circular process characterized in that the first circular process is a circular steam process, and the second circular process is a circular gas process, and between a circular gas process and a circular percent Essom steam is mass transfer.  2. The method according to p. 1, characterized in that the first and second circular processes occur simultaneously without mass transfer with the environment.  3. The method according to one of the preceding paragraphs, characterized in that in the circular steam process use a working medium A, which contains a substance or mixture of substances with a high molecular dipole moment, and that in a circular gas process using a working medium AB, which contains a mixture of gaseous phases of the working medium of the circular process of steam A and the second component B, which contains a substance or mixture of substances with a low dipole moment.  4. The method according to one of the preceding paragraphs, characterized in that the thermal energy supplied externally to the heat engine primarily serves to vaporize the liquid working medium of the steam process A.  5. The method according to one of the preceding paragraphs, characterized in that the working environment of the circular process of steam And due to mass transfer cyclically takes part in both circular processes.  6. The method according to one of the preceding paragraphs, characterized in that the gaseous phase of the working medium of the circular process of steam A is mixed with the gaseous phase of the working medium of the circular process of gas AB.  7. The method according to one of the preceding paragraphs, characterized in that in the circular steam process due to the return of work on the shaft, a cyclic phase change occurs from liquid to gaseous and again to liquid working medium A.  8. The method according to one of the preceding paragraphs, characterized in that in the circular gas process due to the return of work on the shaft, a cyclic change in the amount or concentration of the working medium of the circular process of steam A with respect to the working medium of the circular process of gas AB occurs.  9. The method according to one of the preceding paragraphs, characterized in that the condensation of the working medium of the circular process of steam And essentially occurs within and during the expansion phase of the working environment of the circular process of gas AB.  10. The method according to one of the preceding paragraphs, characterized in that arising due to the phase transition of the working medium of the circular process of steam A fog using a conservative force field, mainly a centrifugal field, is extracted from the working medium of the circular process of gas AB and again brought to the working medium A circular process of steam as a liquid. 11. The method according to one of paragraphs. 3-10, characterized in that the working environment of the circular process of steam A and the second component B of the working environment of the circular process of gas AB can exist in combination
A = water and B = air;
A = carbon dioxide and B = air / nitrogen;
A = ammonia and B = air / nitrogen;
A = cooling mixture and B = air / nitrogen;
A = nitrogen and B = hydrogen or
A = nitrogen and B = inert gas.  12. A heat engine for implementing the method according to one of the preceding paragraphs with the first thermodynamic circular process and the second thermodynamic circular process, wherein the waste heat of the first circular process is supplied to the second circular process and the waste heat of the second circular process is supplied to the first circular process, characterized in that the first circular process is a circular steam process, and the second circular process is a circular gas process and that between the gas circular and th process vapor mass exchange occurs.  13. A heat engine according to claim 12, characterized in that the heat engine contains at least the following functional modules: pump, evaporator, steam turbine, mixing chamber, gas turbine, condenser, centrifuge and compressor.  14. The heat engine according to claim 13, characterized in that the liquid working medium A of the circular steam process is supplied to the evaporator by increasing the pressure, evaporates there by supplying thermal energy and expands in the steam turbine due to the return of work on the shaft.  15. The heat engine according to one of paragraphs. 13 and 14, characterized in that the exhaust gas of a steam turbine is mixed in a mixing chamber with a compressed working medium AB of a circular gas process, in a gas turbine it expands due to the return of work on the shaft, and in the condenser due to expansion it leads to the formation of fog, so that the fog of the working medium of the steam process A is separated in a centrifuge and how the liquid is pumped to the evaporator through the pump and that the remaining working medium of the circular gas process AB from the centrifuge is again fed through the compressor to the mixing chamber.  16. The heat engine according to one of paragraphs. 13-15, characterized in that the compressor, pump and centrifuge are driven by a steam turbine and / or gas turbine.  17. The heat engine according to one of paragraphs. 13-16, characterized in that the steam turbine and / or gas turbine give the work on the shaft to an external consumer.  18. The heat engine according to one of paragraphs. 13-17, characterized in that the functional modules of the steam turbine, gas turbine and mixing chamber are combined into a functional module of the turbine and the functional modules of the condenser and centrifuge are combined into a functional unit of a condensation centrifuge.  19. The heat engine according to one of paragraphs. 12-18, characterized in that the temperature of the phase transition of the working medium of the steam process lies below the temperature of the environment surrounding the heat engine.