RU2005141370A - METHOD FOR PRODUCING ELECTRIC ENERGY IN A GAS-LIQUID INJECT UNIT AND A JET UNIT FOR ITS PERFORMANCE - Google Patents

Claims (10)

1. A method of generating electrical energy in a gas-liquid jet water heater apparatus, comprising supplying gas to an active supersonic nozzle of the jet apparatus, accelerating gas in this nozzle at a subsonic speed and then supplying this gas to a receiving chamber of mixing the jet apparatus, supplying water to this receiving chamber, gas and water mixing in this chamber with the formation of a stream of a two-phase mixture of water and gas with the transfer of the mixture to a supersonic flow regime and then the formation of a pressure jump in the two-phase supersonic flow with the transfer a two-phase flow in a pressure jump due to the collapse of gas bubbles into a single-phase liquid subsonic flow with simultaneous heating of water due to the collapse of gas bubbles in a pressure jump, characterized in that in the zone of pressure jump and the conversion of a two-phase flow into a single-phase liquid flow with microscopic gas bubbles electrically charged particles using a magnetoelectric generator and / or electrodes. 2. The method according to claim 1, characterized in that the gas is activated before being fed into the active supersonic nozzle of the jet apparatus. 3. The method according to claim 2, characterized in that when the gas is activated, it is ionized by either exciting an electric discharge therein or irradiating a stream of particles with an energy in the range from 10 eV to 2.5 · 10 ⁴⁵ eV, or by exciting an alternating electric and / or electromagnetic field. 4. The method according to claim 2, characterized in that the activation of the gas is carried out by passing it through the zone of an inhomogeneous magnetic field. 5. The method according to claim 2, characterized in that the activation of the gas is carried out by introducing a catalyst into it, which is selected as an inert gas, for example, argon and / or elements of the fourth group of the periodic table of chemical elements. 6. The method according to claim 2, characterized in that during gas activation, several of the activation options listed in claims 3-5 are simultaneously used to increase the gas activation efficiency. 7. The method according to claim 1, characterized in that the gas is supplied to the active supersonic nozzle of the jet apparatus by pulses with a frequency in the range from 0 to 40,000 Hz. 8. The method according to claim 1, characterized in that they organize a multi-stage gas supply to the jet apparatus by supplying gas simultaneously to several mixing chambers of the jet apparatus due to gas ejection by a stream of water leaving the previous mixing chamber to the next, at the same time organizing in each stage formation of a two-phase mixture of water and gas with the transfer of the flow into a supersonic flow regime and the organization of a pressure jump at each stage with the transfer of the flow into a single-phase liquid and simultaneous heating of the liquid flow and a condensate at each stage in the pressure drop zone, and converting the two-phase flow in a single-phase fluid flow with microscopic gas bubbles recorded stream of electrically charged particles by means of the magnetoelectric generator and / or electrodes. 9. A gas-liquid inkjet apparatus for implementing the method according to claim 1, comprising an active nozzle with an inlet tapering and expanding outlet portions, a receiving chamber with an opening for supplying a liquid medium and a mixing chamber with an output nozzle, wherein the output section of the active nozzle exceeds the minimum passage section of the mixing chamber , the input section of the mixing chamber in the area of the output section of the active nozzle is made stepwise tapering and formed by conical surfaces, and the output section of the mixing chamber is made expanding downstream of the active medium, characterized in that the mixing chamber in the area of the outlet nozzle is located between the pluses of the magnetic system of the mannitoelectric generator, and at least two electrodes are located on the surface of the outlet nozzle, inside the mixing chamber. 10. A gas-liquid jet apparatus according to claim 9, characterized in that it comprises a gas activator located in front of the entrance to the active nozzle and / or at the inlet narrowing section of the active nozzle and configured to pass gas through the activator.