RU2002118168A - Device and method for generating electricity from water - Google Patents

Claims (2)

1. A device for generating electricity from water, consisting of a boiler room, an air-turbine engine, an ammonia compressor, an ammonia turbine, pumps, heat exchangers, characterized in that, for the purpose of generating electricity from the water, an outlet from the atmospheric air cooling radiator (3) installed in the ammonia-air, ammonia-ammonia heat exchanger (21) is connected to the diffuser of the air compressor of the air-turbine engine (5), and the outlet from the nozzle of the air turbine of the air-turbine engine (7) is connected by a pipe to the blower boiler room scrap (1), ammonia gas heat exchangers (11) (12) are connected in series, while a gas-ammonia heat exchanger (11) is installed at the flue gas outlet from the boiler room (1), and a gas-ammonia heat exchanger (12) is installed in the maximum temperature zone in the boiler room (1), gas-ammonia heat exchangers (11) and (12) are connected in parallel with an ammonia turbine of an ammonia turbine (13) installed in an ammonia ammonia vapor condenser in an ammonia compressor circuit (18), and a water radiator for heat supply is installed there after the radiator (13) (24), the condensed ammonia vapor condensation radiator in the ammonia turbine circuit (15) is installed in an ammonia-air, ammonia-ammonia heat exchanger (21), the ammonia boiling radiator in the ammonia compressor circuit (22) is installed in the river water stream, the air compressor is air - a turbine engine (5), an air turbine of an air-turbine engine (7), an ammonia compressor (17), an ammonia turbine (14), a high pressure ammonia pump (10), a water pump (23), an electric current generator (25) - all mounted on one shaft. 2. A method of generating electricity from water by using an air-turbine engine, an ammonia compressor, an ammonia turbine, pumps, heat exchangers, by burning any fossil fuels and recovering the heat of river water, characterized in that the air-turbine engine operates in a mode when heat is absorbed the air heat exchanger (6) is equal to the heat discharged into the furnace of the boiler room with hot air, after passing it through the air turbine of the air-turbine engine (7) Q ₃ -Q ₂ = Q _{4 the} amount of ammonia in the circuit of an ammonia compressor at a temperature difference of T ₁ ”= 258 ° K; T ₂ ”= 323 ° K is designed to ensure the operation of an ammonia turbine at a temperature difference of T ₃ '= 613 ° K; T ₄ '= 263 ° K the heat of boiling of ammonia in the circuit of an ammonia compressor is equal to the heat of cooling of atmospheric air, equal to the heat of condensation of ammonia vapors in the circuit of an ammonia turbine and cooling of river water by an amount equal to the amount of heat from fuel combustion in the boiler room.