US20220228512A1 - Combined cycle power device - Google Patents
Combined cycle power device Download PDFInfo
- Publication number
- US20220228512A1 US20220228512A1 US17/608,150 US202017608150A US2022228512A1 US 20220228512 A1 US20220228512 A1 US 20220228512A1 US 202017608150 A US202017608150 A US 202017608150A US 2022228512 A1 US2022228512 A1 US 2022228512A1
- Authority
- US
- United States
- Prior art keywords
- expander
- compressor
- evaporator
- heat exchanger
- temperature heat
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Abandoned
Links
Images
Classifications
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01K—STEAM ENGINE PLANTS; STEAM ACCUMULATORS; ENGINE PLANTS NOT OTHERWISE PROVIDED FOR; ENGINES USING SPECIAL WORKING FLUIDS OR CYCLES
- F01K11/00—Plants characterised by the engines being structurally combined with boilers or condensers
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01K—STEAM ENGINE PLANTS; STEAM ACCUMULATORS; ENGINE PLANTS NOT OTHERWISE PROVIDED FOR; ENGINES USING SPECIAL WORKING FLUIDS OR CYCLES
- F01K11/00—Plants characterised by the engines being structurally combined with boilers or condensers
- F01K11/02—Plants characterised by the engines being structurally combined with boilers or condensers the engines being turbines
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01B—MACHINES OR ENGINES, IN GENERAL OR OF POSITIVE-DISPLACEMENT TYPE, e.g. STEAM ENGINES
- F01B21/00—Combinations of two or more machines or engines
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01B—MACHINES OR ENGINES, IN GENERAL OR OF POSITIVE-DISPLACEMENT TYPE, e.g. STEAM ENGINES
- F01B23/00—Adaptations of machines or engines for special use; Combinations of engines with devices driven thereby
- F01B23/08—Adaptations for driving, or combinations with, pumps
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01K—STEAM ENGINE PLANTS; STEAM ACCUMULATORS; ENGINE PLANTS NOT OTHERWISE PROVIDED FOR; ENGINES USING SPECIAL WORKING FLUIDS OR CYCLES
- F01K23/00—Plants characterised by more than one engine delivering power external to the plant, the engines being driven by different fluids
- F01K23/02—Plants characterised by more than one engine delivering power external to the plant, the engines being driven by different fluids the engine cycles being thermally coupled
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01K—STEAM ENGINE PLANTS; STEAM ACCUMULATORS; ENGINE PLANTS NOT OTHERWISE PROVIDED FOR; ENGINES USING SPECIAL WORKING FLUIDS OR CYCLES
- F01K25/00—Plants or engines characterised by use of special working fluids, not otherwise provided for; Plants operating in closed cycles and not otherwise provided for
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01K—STEAM ENGINE PLANTS; STEAM ACCUMULATORS; ENGINE PLANTS NOT OTHERWISE PROVIDED FOR; ENGINES USING SPECIAL WORKING FLUIDS OR CYCLES
- F01K27/00—Plants for converting heat or fluid energy into mechanical energy, not otherwise provided for
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01K—STEAM ENGINE PLANTS; STEAM ACCUMULATORS; ENGINE PLANTS NOT OTHERWISE PROVIDED FOR; ENGINES USING SPECIAL WORKING FLUIDS OR CYCLES
- F01K3/00—Plants characterised by the use of steam or heat accumulators, or intermediate steam heaters, therein
- F01K3/18—Plants characterised by the use of steam or heat accumulators, or intermediate steam heaters, therein having heaters
Definitions
- the present invention belongs to the flied of energy and power technology.
- the vapor power device with the outside combustion for example, its heat source has the dual characteristics of high-temperature and variable temperature.
- the material's temperature resistance and pressure resistance abilities and safety concerns limit the parameters of the cycle's working medium. Therefore, there is a big temperature difference between the working medium and the heat source, which leads to big irreversible loss and low efficiency. This means that there is great potential to improve the thermal efficiency.
- the present invention provides a combined cycle power device with high thermal efficiency, strong safety, adaptation to high-temperature heat source or variable temperature heat source and response to various fuels.
- the combined cycle power device are mainly provided in the present invention, and the specific contents of the present invention are as follows:
- FIG. 1 is a type 1 example general flow chart of a combined cycle power device provided in the present invention.
- FIG. 2 is a type 2 example general flow chart of a combined cycle power device provided in the present invention.
- FIG. 3 is a type 3 example general flow chart of a combined cycle power device provided in the present invention.
- FIG. 4 is a type 4 example general flow chart of a combined cycle power device provided in the present invention.
- FIG. 5 is a type 5 example general flow chart of a combined cycle power device provided in the present invention.
- FIG. 6 is a type 6 example general flow chart of a combined cycle power device provided in the present invention.
- FIG. 7 is a type 7 example general flow chart of a combined cycle power device provided in the present invention.
- FIG. 8 is a type 8 example general flow chart of a combined cycle power device provided in the present invention.
- FIG. 9 is a type 9 example general flow chart of a combined cycle power device provided in the present invention.
- FIG. 10 is a type 10 example general flow chart of a combined cycle power device provided in the present invention.
- FIG. 11 is a type 11 example general flow chart of a combined cycle power device provided in the present invention.
- FIG. 12 is a type 12 example general flow chart of a combined cycle power device provided in the present invention.
- FIG. 13 is a type 13 example general flow chart of a combined cycle power device provided in the present invention.
- FIG. 14 is a type 14 example general flow chart of a combined cycle power device provided in the present invention.
- FIG. 15 is a type 15 example general flow chart of a combined cycle power device provided in the present invention.
- 1 expander
- 2 compressor
- 3 the second expander
- 4 circulating pump
- 5 high temperature heat exchanger
- 6 condenser
- 7 evaporator (waste heat boiler)
- 8 heat boiler
- 9 high temperature regenerator
- 10 the second high-temperature heat exchanger
- 11 the third expander
- 12 the second compressor
- 13 low temperature regenerator
- 14 the second pump.
- the combined cycle power device in FIG. 1 works as follows:
- the combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser and an evaporator.
- a condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects the evaporator 7 , an evaporator 7 has a vapor channel connected a high-temperature heat exchanger 5 , the high-temperature heat exchanger 5 has a vapor channel connected a compressor 1 , a compressor 1 has a low-pressure vapor channel connected the evaporator 7 , an evaporator 7 has a low-pressure vapor channel connected the compressor 2 and the second expander 3 respectively, the second expander 3 has a low-pressure vapor channel connected the condenser 6 .
- the high-temperature heat exchanger 5 has the heat source medium channel connected the outside
- the condenser 6 has the cooling medium channel connected the outside
- the expander 1 and the second the expander 3 connect the compressor 2
- the condensate of the condenser 6 flows through the pump 4 and enters into the evaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the high-temperature heat exchanger 5 for heat absorption,
- the vapor discharged from compressor 2 enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from the high-temperature heat exchanger 5 flows through the expander 1 to depressurize and output work.
- the low-pressure vapor discharged from the expander 1 flows through the evaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters the compressor 2 for pressure rise and temperature rise.
- the second current flows through the expander 3 to depressurize and output work, and then enters the condenser 6 to release heat and condense.
- the heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 .
- the cooling medium takes away the low-temperature heat load through the condenser 6 .
- the expander 1 and the second expander 3 supplies power to the compressor 1 and the outside.
- the expander 1 and the second expander 3 supplies power to the compressor 2 , the pump 4 and the outside if necessary.
- the combined cycle power device is formed.
- the combined cycle power device in FIG. 2 works as follows:
- the evaporator 7 Based on combined cycle power device in FIG. 1 , the evaporator 7 adds the heat source medium channel connected the outside. The condensate entering the evaporator 7 obtains the heat load provided by the low-pressure vapor and the heat source medium at the same time, heats up, vaporizes and superheats, and then enters the high-temperature heat exchanger 5 . The combined cycle power device is formed.
- the combined cycle power device in FIG. 3 works as follows:
- the combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a heating unit.
- a condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects the evaporator 7 , an evaporator 7 has a vapor channel connected a high-temperature heat exchanger 5 , a compressor 2 has a vapor channel connected the high-temperature heat exchanger 5 , the high-temperature heat exchanger 5 has a vapor channel connected an expander 1 , an expander 1 has a low-pressure vapor channel connected the heating unit 8 , the heating unit 8 has a low-pressure vapor channel connected the compressor 2 and the second expander 3 respectively, the second expander 3 has a low-pressure vapor channel connected the condenser 6 .
- the high-temperature heat exchanger 5 has the heat source medium connected the outside
- the condenser 6 has the cooling medium channel connected the outside
- the evaporator 7 has the heat source medium channel connected the outside
- the heating unit 8 has the heated medium channel connected the outside
- the expander 1 and the second the expander 3 connect the compressor 2 and transmit power.
- the condensate of the condenser 6 flows through the pump 4 and enters into the evaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from compressor 2 enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from the high-temperature heat exchanger 5 flows through the expander 1 to depressurize and output work.
- the low-pressure vapor discharged from the expander 1 flows through the heating unit 8 to release heat and cool down, and then is divided into two currents. The first current enters the compressor 2 for pressure rise and temperature rise.
- the second current flows through the second expander 3 to depressurize and output work, and then enters the condenser 6 to release heat and condense.
- the heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and the evaporator 7 .
- the cooling medium takes away the low-temperature heat load through the condenser 6 .
- the heated medium takes away the medium temperature heat load through the heating unit 8 .
- the expander 1 and the second expander 3 supplies power to the compressor 2 and the outside. Or the expander 1 and the second expander 3 supplies power to the compressor 2 , the pump 4 and the outside if necessary.
- the combined cycle power device is formed.
- the combined cycle power device in FIG. 4 works as follows:
- the combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a high-temperature regenerator.
- An condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects the evaporator 7
- an evaporator 7 has a low-pressure vapor channel which passes through a high-temperature regenerator 9 and connects the high-temperature heat exchanger 5
- a compressor 2 has a vapor channel which passes through the high-temperature regenerator 9 and connects the high-temperature heat exchanger 5
- the high-temperature heat exchanger 5 has a vapor channel connected the expander 1
- the expander 1 has a low-pressure vapor channel connected the high-temperature regenerator 9 .
- the high-temperature regenerator 9 has the heat source medium connected the evaporator 7 , an evaporator 7 has a low-pressure vapor channel connected the compressor 2 and the second expander 3 respectively, the second expander 3 has a low-pressure vapor channel connected the condenser 6 .
- the high-temperature heat exchanger 5 has the heat source medium channels connected the outside, the condenser 6 has the cooling medium channel connected the outside, the expander 1 and the second the expander 3 connect the compressor 2 and transmit power.
- the condensate of the condenser 6 flows through the pump 4 and enters into the evaporator 7 in which it absorbs heat, vaporizes and superheats.
- the superheated vapor flows through the high-temperature regenerator 9 for heat absorption, and then enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from compressor 2 flows through the high-temperature regenerator 9 for heat absorption, and then enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from the high-temperature heat exchanger 5 flows through the expander 1 to depressurize and output work.
- the low-pressure vapor discharged from the expander 1 flows through the high-temperature regenerator 9 and the evaporator 7 to release heat and cool down, and then is divided into two currents.
- the first current enters the compressor 2 for pressure rise and temperature rise.
- the second current flows through the second expander 3 to depressurize and output work, and then enters the condenser 6 to release heat and condense.
- the heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 .
- the cooling medium takes away the low-temperature heat load through the condenser 6 .
- the expander 1 and the second expander 3 supplies power to the compressor 2 and the outside. Or the expander 1 and the second expander 3 supplies power to the compressor 2 , the pump 4 and the outside if necessary.
- the combined cycle power device is formed.
- the combined cycle power device in FIG. 5 works as follows:
- the combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and the second high-temperature heat exchanger.
- the condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects the evaporator 7 ), an evaporator 7 has a vapor channel connects the second high-temperature heat exchanger 10 , the second high-temperature heat exchanger 10 has a vapor channel connects an expander 1 , a compressor 2 has a vapor channel connects the high-temperature heat exchanger 5 , the high-temperature heat exchanger 5 has a vapor channel which passes through a intermediate vapor inlet channel and connects the expander 1 , the expander 1 has a low-pressure vapor channel connected the evaporator 7 , the evaporator 7 has a low-pressure vapor channel connected the compressor 2 and a second expander 3 respectively, the second expander
- the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 have the heat source medium channels connected the outside, the condenser 6 has the cooling medium channel connected the outside, the expander 1 and the second expander 3 connect the compressor ( 2 ) and transmit power.
- the condensate of the condenser 6 flows through the pump 4 , the evaporator 7 and the second high-temperature heat exchanger 10 and absorbs heat, vaporizes and superheats, and then enters the expander 1 to depressurize and output work.
- the vapor discharged from compressor 2 flows through the high-temperature heat exchanger 5 for heat absorption, and then enters the expander 1 to depressurize and output work.
- the low-pressure vapor discharged from the expander 1 flows through the evaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters the compressor 2 for pressure rise and temperature rise.
- the second current flows through the second expander 3 to depressurize and output work, and then enters the condenser 6 to release heat and condense.
- the heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 .
- the cooling medium takes away the low-temperature heat load through the condenser 6 .
- the expander 1 and the second expander 3 supplies power to the compressor 2 and the outside. Or the expander 1 and the second expander 3 supplies power to the compressor 2 , the pump 4 and the outside if necessary.
- the combined cycle power device is formed.
- the combined cycle power device in FIG. 6 works as follows:
- the combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser and an evaporator.
- the condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects the evaporator 7 , an evaporator 7 has a vapor channel which passes through a intermediate vapor inlet channel and connects an expander 1 , a compressor 2 has a vapor channel which passes through a high-temperature heat exchanger 5 and connects the expander 1 , the expander 1 has a low-pressure vapor channel connected the evaporator 7 , the evaporator 7 has a low-pressure vapor channel connected the compressor 2 and the second expander 3 respectively, the second expander 3 has a low-pressure vapor channel connected the condenser 6 .
- the high-temperature heat exchanger 5 has the heat source medium channel connected the outside
- the condenser 6 has the cooling medium channel connected the outside
- the condensate of the condenser 6 flows through the pump 4 and enters the evaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the expander 1 to depressurize and output work.
- the vapor discharged from compressor 2 flows through the high-temperature heat exchanger 5 for heat absorption, and then enters the expander 1 to depressurize and output work.
- the low-pressure vapor discharged from the expander 1 flows through the evaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters the compressor 2 for pressure rise and temperature rise.
- the second current flows through the second expander 3 to depressurize and output work, and then enters the condenser 6 to release heat and condense.
- the heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 .
- the cooling medium takes away the low-temperature heat load through the condenser 6 .
- the expander 1 and the second expander 3 supplies power to the compressor 2 and the outside. Or the expander 1 and the second expander 3 supplies power to the compressor 2 , the pump 4 and the outside if necessary.
- the combined cycle power device is formed.
- the combined cycle power device in FIG. 7 works as follows:
- the combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser and a high-temperature regenerator.
- the condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects the evaporator 7
- an evaporator 7 has a vapor channel which passes through a intermediate vapor inlet channel and connects an expander 1
- a compressor 2 has a vapor channel which passes through a high-temperature regenerator 9 and a high-temperature heat exchanger 5 , connects the expander 1
- the expander 1 has a low-pressure vapor channel connected the high-temperature regenerator 9
- the high-temperature regenerator 9 has a low-pressure vapor channel connected the evaporator 7
- the evaporator 7 has a low-pressure vapor channel connected the compressor 2 and the second expander 3 respectively
- the second expander 3 has a low-pressure vapor channel connected the
- the condensate of the condenser 6 flows through the pump 4 and enters the evaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the expander 1 to depressurize and output work.
- the vapor discharged from compressor 2 flows through the high-temperature regenerator 9 and the high-temperature heat exchanger 5 for heat absorption, and then enters the expander 2 to depressurize and output work.
- the low-pressure vapor discharged from the expander 1 flows through the high-temperature regenerator 9 and the evaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters the compressor 2 for pressure rise and temperature rise.
- the second current flows through the second expander 3 to depressurize and output work, and then enters the condenser 6 to release heat and condense.
- the heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 .
- the cooling medium takes away the low-temperature heat load through the condenser 6 .
- the expander 1 and the second expander 3 supplies power to the compressor 2 and the outside. Or the expander 1 and the second expander 3 supplies power to the compressor 2 , the pump 4 and the outside if necessary.
- the combined cycle power device is formed.
- the combined cycle power device in FIG. 8 works as follows:
- the combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a third expander.
- the condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects the evaporator 7 , an evaporator 7 has a vapor channel connects the third expander 11 , the expander 11 has a low-pressure vapor channel connected the evaporator 7 , a compressor 2 has a vapor channel which passes through a high-temperature heat exchanger 5 and the expander 1 , the expander 1 has a low-pressure vapor channel connected the evaporator 7 , the evaporator 7 has a low-pressure vapor channel connected the compressor 2 and the second expander 3 respectively, the second expander 3 has a low-pressure vapor channel connected the condenser 6 .
- the high-temperature heat exchanger 5 has the heat source medium channel connected the outside
- the condenser 6 has the cooling medium channel connected the outside
- the evaporator 7 has the heat source medium channel connected the outside if necessary
- the expander 1 , the second expander 3 and the third expander 11 connect the second compressor 2 and transmit power.
- the condensate of the condenser 6 flows through the pump 4 and enters the evaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the third expander 11 to depressurize and output work.
- the low-pressure vapor discharged from the third expander 11 enters the evaporator 7 to release heat and cool down.
- the vapor discharged from the compressor 2 flows through the high-temperature heat exchanger 5 for heat absorption, and then enters the expander 1 to depressurize and output work.
- the low-pressure vapor discharged from the expander 1 enters the evaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters the compressor 2 for pressure rise and temperature rise.
- the second current flows through the second expander 3 to depressurize and output work, and then enters the condenser 6 to release heat and condense.
- the heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and the evaporator 7 .
- the cooling medium takes away the low-temperature heat load through the condenser 6 .
- the expander 1 , the second expander 3 and third expander 11 supply power to the compressor 2 and the outside. Or the expander 1 , the second expander 3 and third expander 11 supplies power to the compressor 2 , the pump 4 and the outside if necessary.
- the combined cycle power device is formed.
- the combined cycle power device in FIG. 9 works as follows:
- the combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a heating unit.
- the condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects the evaporator 7 , an evaporator 7 has a vapor channel connects the high-temperature heat exchanger 5 , a compressor 2 has a vapor channel connects the high-temperature heat exchanger 5 , the high-temperature heat exchanger 5 has a vapor channel connected the expander 1 , the expander 1 has a low-pressure vapor channel connected the evaporator 7 , an evaporator 7 has a low-pressure vapor channel and connects the heating unit 8 , the heating unit 8 has a low-pressure vapor channel and connects the compressor 2 and the second expander 3 ) respectively, the second expander 3 has a low-pressure vapor channel connected the condenser 6
- the high-temperature heat exchanger 5 has the heat source medium channel connected the outside
- the condenser 6 has the cooling medium channel connected the outside
- the heating unit 8 has the heated medium channel connected the outside
- the expander 1 and the second expander 3 connect the second compressor 2 and transmit power.
- the condensate of the condenser 6 flows through the pump 4 and enters the evaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from compressor 2 enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from the high-temperature heat exchanger 5 flows through the expander 1 to depressurize and output work.
- the low-pressure vapor discharged from the expander 1 flows through the evaporator 7 and heating unit 8 to release heat and cool down, and then is divided into two currents. The first current enters the compressor 2 for pressure rise and temperature rise.
- the second current flows through the second expander 3 to depressurize and output work, and then enters the condenser 6 to release heat and condense.
- the heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 .
- the cooling medium takes away the low-temperature heat load through the condenser 6 .
- the heated medium takes away the medium temperature heat load through the heating unit 8 .
- the expander 1 and the second expander 3 supply power to the compressor 2 and the outside. Or the expander 1 and the second expander 3 supply power to the compressor 2 , the pump 4 and the outside if necessary.
- the combined cycle power device is formed.
- the combined cycle power device in FIG. 10 works as follows:
- the combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a second high-temperature heat exchanger and a second compressor.
- the condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects the evaporator 7 , an evaporator 7 has a vapor channel connects the high-temperature heat exchanger 5 , the compressor 2 has a vapor channel connects the high-temperature heat exchanger 5 , the high-temperature heat exchanger 5 has a vapor channel connected the second compressor 12 , the second compressor 12 has a vapor channel which passes through a second high-temperature heat exchanger 10 and connects the expander 1 , the expander 1 has a low-pressure vapor channel connected the evaporator 7 , an evaporator 7 has a low-pressure vapor channel and connects the compressor 2 and the second expander 3 respectively, the second expander 3 has a low-pressure vapor channel connected the condenser 6 .
- the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 has the heat source medium channel connected the outside respectively, the condenser 6 has the cooling medium channel connected the outside, the expander 1 and the second expander 3 connect the second compressor 2 and transmit power.
- the condensate of the condenser 6 flows through the pump 4 and enters the evaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from compressor 2 enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from the high-temperature heat exchanger 5 flows through the second compressor 12 to pressurize, the second high-temperature heat exchanger 10 for heat absorption and the expander 2 to depressurize and output work.
- the low-pressure vapor discharged from the expander 1 flows through the evaporator 7 to release heat and cool down, and then is divided into two currents.
- the first current enters the compressor 2 for pressure rise and temperature rise.
- the second current flows through the second expander 3 to depressurize and output work, and then enters the condenser 6 to release heat and condense.
- the heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 .
- the cooling medium takes away the low-temperature heat load through the condenser 6 .
- the expander 1 and the second expander 3 supply power to the compressor 2 , the second compressor 12 and the outside. Or the expander 1 and the second expander 3 supply power to the compressor 2 , the second compressor 12 , the pump 4 and the outside if necessary.
- the combined cycle power device is formed.
- the combined cycle power device in FIG. 11 works as follows:
- the combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a second high-temperature heat exchanger and a third expander.
- the condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects the evaporator 7 , an evaporator 7 has a vapor channel connects the high-temperature heat exchanger 5 , the compressor 2 has a vapor channel connects the high-temperature heat exchanger 5 , the high-temperature heat exchanger 5 has a vapor channel connected the third expander 11 , the third expander 11 has a vapor channel which passes through a second high-temperature heat exchanger 10 connects the expander 1 , the expander 1 has a low-pressure vapor channel connected the evaporator 7 , an evaporator 7 has a low-pressure vapor channel and connects the compressor 2 and the second expander 3 respectively, the second expander 3 has a low-pressure vapor channel connected the condenser 6 .
- the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 has the heat source medium channel connected the outside respectively, the condenser 6 has the cooling medium channel connected the outside, the expander 1 , the second expander 3 and the third expander 11 connect the second compressor 2 and transmit power.
- the condensate of the condenser 6 flows through the pump 4 and enters the evaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from compressor 2 enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from the high-temperature heat exchanger 5 flows through the third expander 11 to depressurize and output work, the second high-temperature heat exchanger 10 for heat absorption and the expander 1 to depressurize and output work.
- the low-pressure vapor discharged from the expander 1 flows through the evaporator 7 to release heat and cool down, and then is divided into two currents.
- the first current enters the compressor 2 for pressure rise and temperature rise.
- the second current flows through the second expander 3 to depressurize and output work, and then enters the condenser 6 to release heat and condense.
- the heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 .
- the cooling medium takes away the low-temperature heat load through the condenser 6 .
- the expander 1 , the second expander 3 and the third expander 11 supply power to the compressor 2 and the outside.
- the expander 1 , the second expander 3 and the third expander 11 supply power to the compressor 2 , the pump 4 and the outside if necessary.
- the combined cycle power device is formed.
- the combined cycle power device in FIG. 12 works as follows:
- the combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a high-temperature regenerator, a second high-temperature heat exchanger and a second compressor.
- the condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects the evaporator 7 , an evaporator 7 has a vapor channel which passes through the high-temperature regenerator 9 and connects the high-temperature heat exchanger 5 , a compressor 2 has a vapor channel which passes through a high-temperature regenerator 9 and the high-temperature heat exchanger 5 ,
- the high-temperature heat exchanger 5 has a vapor channel connects the second compressor 12
- the second compressor 12 has a liquid refrigerant pipe which passes through second high-temperature heat exchanger 10 and connects the expander 1
- the expander 1 has a low-pressure vapor channel which passes through a high-temperature regenerator 9 and connects the evaporator 7
- an evaporator 7 has a low-pressure vapor channel and connects the compressor 2 and the second expander 3 respectively
- the second expander 3 has a low-pressure vapor channel connected the condenser 6 .
- the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 has the heat source medium channel connected the outside respectively, the condenser 6 has the cooling medium channel connected the outside, the expander 1 , the second expander 3 connect the compressor 2 and the second compressor 12 , transmit power.
- the condensate of the condenser 6 flows through the pump 4 and enters the evaporator 7 in which it absorbs heat, vaporizes and superheats.
- the superheated vapor flows through the high-temperature regenerator 9 for heat absorption, and then enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from compressor 2 flows through the high-temperature regenerator 9 for heat absorption, and then enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from the high-temperature heat exchanger 5 flows through the second compressor 12 to pressurize, the second high-temperature heat exchanger 10 for heat absorption and the expander 1 to depressurize and output work.
- the low-pressure vapor discharged from the expander 1 flows through the high-temperature regenerator 9 and the evaporator 7 to release heat and cool down, and then is divided into two currents.
- the first current enters the compressor 2 for pressure rise and temperature rise.
- the second current flows through the second expander 3 to depressurize and output work, and then enters the condenser 6 to release heat and condense.
- the heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 .
- the cooling medium takes away the low-temperature heat load through the condenser 6 .
- the expander 2 and the second expander 3 supplies power to the compressor 2 , the second compressor 12 and the outside.
- the expander 2 and the second expander 3 supplies power to the compressor 2 , the pump 4 , the second compressor 12 and the outside if necessary.
- the combined cycle power device is formed.
- the combined cycle power device in FIG. 13 works as follows:
- the combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a high-temperature regenerator, a second high-temperature heat exchanger and a third expander.
- the condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects the evaporator 7 , an evaporator 7 has a vapor channel which passes through the high-temperature regenerator 9 and connects the high-temperature heat exchanger 5 , the high-temperature heat exchanger 5 has a vapor channel and connects the third expander 11 , the third expander 11 has a vapor channel which passes through the second high-temperature heat exchanger 10 and connects the third expander 1 , the third expander 1 has a low-pressure vapor channel which passes through the second high-temperature regenerator 9 and connects the evaporator 7 , an evaporator 7 has a low-pressure vapor channel and connects the compressor 2 and the second expander 3 respectively, the second expander 3 has a low-pressure vapor channel connected the condenser 6 .
- the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 have the heat source medium channel connected the outside respectively, the condenser 6 has the cooling medium channel connected the outside, the expander 1 , the second expander 3 and the third expander 11 connect the compressor 2 and transmit power.
- the condensate of the condenser 6 flows through the pump 4 and enters the evaporator 7 in which it absorbs heat, vaporizes and superheats.
- the superheated vapor flows through the high-temperature regenerator 9 for heat absorption, and then enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from compressor 2 flows through the high-temperature regenerator 9 for heat absorption, and then enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from the high-temperature heat exchanger 5 flows through the third expander 11 to depressurize and output work, the second high-temperature heat exchanger 10 for heat absorption and the expander 1 to depressurize and output work.
- the low-pressure vapor discharged from the expander 1 flows through the high-temperature regenerator 9 and the evaporator 7 to release heat and cool down, and then is divided into two currents.
- the first current enters the compressor 2 for pressure rise and temperature rise.
- the second current flows through the second expander 3 to depressurize and output work, and then enters the condenser 6 to release heat and condense.
- the heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 .
- the cooling medium takes away the low-temperature heat load through the condenser 6 .
- the expander 1 , the second expander 3 and the third expander 11 supply power to the compressor and the outside. Or the expander 1 , the second expander 3 and the third expander 11 supply power to the compressor 2 , the pump 4 and the outside if necessary.
- the combined cycle power device is formed.
- the combined cycle power device in FIG. 14 works as follows:
- a low temperature regenerator and the second pump is added. That a condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects the evaporator 7 is adjusted for that a condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects a low temperature regenerator 13 .
- the compressor 2 adds a vapor extraction channel connected the low temperature regenerator 13 .
- the low temperature regenerator 13 has a liquid refrigerant pipe which passes through the second pump 14 and connects the evaporator 7 .
- the condensate of the condenser 6 flows through the pump 4 and enters the low temperature regenerator 13 in which it mixes with the vapor extraction from the compressor 2 for heat absorption.
- the vapor extraction releases and is condensed.
- the condensate of the low temperature regenerator 13 flows through the second pump 14 and enters the evaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from compressor 2 enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from the high-temperature heat exchanger 5 flows through the expander 1 to depressurize and output work.
- the low-pressure vapor discharged from the expander 1 flows through the evaporator 7 to release heat and cool down, and then is divided into two currents.
- the first current enters the compressor 2 for pressure rise and temperature rise.
- the second current flows through the second expander 3 to depressurize and output work, and then enters the condenser 6 to release heat and condense.
- the low-pressure vapor entering the compressor 2 is compressed to the certain extent and then divided into two currents.
- the first current enters the low temperature regenerator 13 by the intermediate extraction channel.
- the second current continues to boost pressure and temperature.
- the heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 .
- the cooling medium takes away the low-temperature heat load through the condenser 6 .
- the expander 1 and the second expander 3 supplies power to the compressor 2 and the outside. Or the expander 1 and the second expander 3 supplies power to the compressor 2 , the pump 4 , the second pump 13 and the outside if necessary.
- the combined cycle power device in FIG. 15 works as follows:
- a low temperature regenerator and the second pump is added. That a condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects the evaporator 7 is adjusted for that a condenser 6 has a liquid refrigerant pipe which passes through a pump 4 and connects a low temperature regenerator 13 .
- the compressor 2 adds a vapor extraction channel connected the low temperature regenerator 13 .
- the low temperature regenerator 13 has a liquid refrigerant pipe which passes through the second pump 14 and connects the evaporator 7 .
- the condensate of the condenser 6 flows through the pump 4 and enters the low temperature regenerator 13 in which it mixes with the vapor extraction from the compressor 2 for heat absorption.
- the vapor extraction releases and is condensed.
- the condensate of the low temperature regenerator 13 flows through the second pump 14 and enters the evaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from compressor 2 enters the high-temperature heat exchanger 5 for heat absorption.
- the vapor discharged from the high-temperature heat exchanger 5 flows through the expander 1 to depressurize and output work.
- the low-pressure vapor discharged from the expander 1 flows through the heating unit 8 to release heat and cool down, and then is divided into two currents.
- the first current enters the compressor 2 for pressure rise and temperature rise.
- the second current flows through the second expander 3 to depressurize and output work, and then enters the condenser 6 to release heat and condense.
- the low-pressure vapor entering the compressor 2 is compressed to the certain extent and then divided into two currents.
- the first current enters the low temperature regenerator 13 by the intermediate extraction channel.
- the second current continues to boost pressure and temperature.
- the heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and the evaporator 7 .
- the cooling medium takes away the low-temperature heat load through the condenser 6 .
- the heated medium takes away the medium temperature heat load through the heating unit 8 .
- the expander 1 and the second expander 3 supplies power to the compressor 2 and the outside. Or the expander 1 and the second expander 3 supplies power to the compressor 2 , the pump 4 , the second pump 13 and the outside if necessary.
- the combined cycle power device is formed.
- the combined cycle power device proposed by the present invention has the following effects and advantages:
- the circulating working medium absorbs heat at high-temperature heat under low pressure.
- the temperature difference loss between the circulating working medium and the high-temperature heat source is small, which is conducive to improving the thermal efficiency of the system and the safety of the device.
- the circulating working medium mainly relies on the condensation phase transformation process to realize low temperature heat release.
- the temperature difference loss between the circulating working medium and the environment is controllable, which is conducive to improving the thermal efficiency.
- the present invention adopts the low-pressure and high-temperature operation mode to work in the high-temperature region. Therefore, the contradiction among thermal efficiency, the working medium's parameters and the material's temperature resistance and pressure resistance abilities, which is common in traditional vapor power devices, can be resolved. The temperature difference loss between the heat source and the circulating medium can be greatly reduced, and the thermal efficiency can be greatly improved.
- the equipment is shared to increase the heat absorption process of the lower cycle (Rankine cycle) and improve the thermal efficiency.
- the present invention only uses a single working medium, which reduce the operation cost and improve the flexibility of thermal device.
- the lower cycle adopts double expansion process, which is conducive to flexible adjustment of working parameters and adaptability.
- the present invention effectively deals with the high-temperature heat source and the variable temperature heat source, the high-quality fuel and the non high-quality fuel, and has a wide range of application.
- the device in the present invention can be selected to operate at low pressure, so as to greatly improve the operation safety of the device.
- the present invention can realize the heat recovery of enterprise device simply, actively, safely and efficiently.
- the present invention When the present invention is applied to the coal-fired thermal system, it can maintain the original advantages of the traditional steam power cycle in which water vapor is used as working medium and has a wide range of working parameters. According to the actual situation, the present invention can work in subcritical, critical, supercritical or ultra supercritical state, etc.
Abstract
The combined cycle power device of the present invention belongs to the field of energy and power technology. A combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser and an evaporator. A condenser has a liquid refrigerant pipe which passes through a pump and connects the evaporator. An evaporator connects a high-temperature heat exchanger. The high-temperature heat exchanger has a vapor channel connected a compressor. The compressor has a low-pressure vapor channel connected the evaporator. The evaporator connects the compressor and the second expander respectively. The second expander connects the condenser. The high-temperature heat exchanger connects the outside. The condenser has the cooling medium channel connected the outside. The evaporator has the heat source medium channel connected the outside. The expander and the second the expander connect the compressor and transmit power.
Description
- The present invention belongs to the flied of energy and power technology.
- Cold demand, heat demand and power demand are common in human life and production. It is an important way to obtain and provide power by the conversion of thermal energy into mechanical energy. In general, the temperature of heat source reduces and varies with the release of heat. When fossil fuels are used as the primary energy, the heat source has the dual characteristics of both high-temperature and variable temperature. This makes it is difficult to transform more heat energy into mechanical energy using the power device based on a single thermal cycle. For high-quality fuel, the traditional gas-steam combined cycle can be used to obtain a high thermal efficiency. However, there are still some problems to be solved, such as high cost, large investment and low thermal efficiency to be improved.
- Take the vapor power device with the outside combustion for example, its heat source has the dual characteristics of high-temperature and variable temperature. For those vapor power devices based on the Rankine cycle, the material's temperature resistance and pressure resistance abilities and safety concerns limit the parameters of the cycle's working medium. Therefore, there is a big temperature difference between the working medium and the heat source, which leads to big irreversible loss and low efficiency. This means that there is great potential to improve the thermal efficiency.
- Humans need to use heat energy simply, actively, efficiently for achieving power. Therefore, the present invention provides a combined cycle power device with high thermal efficiency, strong safety, adaptation to high-temperature heat source or variable temperature heat source and response to various fuels.
- The combined cycle power device are mainly provided in the present invention, and the specific contents of the present invention are as follows:
-
- 1. A combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser and an evaporator. A condenser has a liquid refrigerant pipe which passes through a pump and connects the evaporator, an evaporator has a vapor channel connected a high-temperature heat exchanger, a compresso has a vapor channel connected the high-temperature heat exchanger, the high-temperature heat exchanger has a vapor channel connected an expander, the expander has a low-pressure vapor channel connected the evaporator, an evaporator has a low-pressure vapor channel connected the compressor and the second expander respectively, the second expander has a low-pressure vapor channel connected the condenser. The high-temperature heat exchanger has the heat source medium channel connected the outside, the condenser has the cooling medium channel connected the outside, the evaporator has the heat source medium channel connected the outside, the expander and the second the expander connect the compressor and transmit power. The expander and the second expander connects the compressor and the pump and transmit power if necessary.
- 2. A combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a heating unit. A condenser has a liquid refrigerant pipe which passes through a pump and connects the evaporator, an evaporator has a vapor channel connected a high-temperature heat exchanger, a compressor has a vapor channel connected the high-temperature heat exchanger, the high-temperature heat exchanger has a vapor channel connected an expander, an expander has a low-pressure vapor channel connected the heating unit, the heating unit has a low-pressure vapor channel connected the compressor and the second expander respectively, the second expander has a low-pressure vapor channel connected the condenser. The high-temperature heat exchanger has the heat source medium connected the outside, the condenser has the cooling medium channel connected the outside, the evaporator has the heat source medium channel connected the outside, the heating unit has the heated medium channel connected the outside, the expander and the second the expander connect the compressor and transmit power. The expander and the second expander connects the compressor and the pump and transmit power if necessary.
- 3. A combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a high-temperature regenerator. An condenser has a liquid refrigerant pipe which passes through a pump and connects the evaporator, an evaporator has a low-pressure vapor channel which passes through a high-temperature regenerator and connects the high-temperature heat exchanger, a compressor has a vapor channel which passes through the high-temperature regenerator and connects the high-temperature heat exchanger, the high-temperature heat exchanger has a vapor channel connected the expander, the expander has a low-pressure vapor channel connected the high-temperature regenerator, the high-temperature regenerator has the heat source medium connected the evaporator, an evaporator has a low-pressure vapor channel connected the compressor and the second expander respectively, the second expander has a low-pressure vapor channel connected the condenser. The high-temperature heat exchanger has the heat source medium channels connected the outside, the condenser has the cooling medium channel connected the outside, the evaporator has the heat source medium channel connected the outside, the expander (1) and the second the expander (3) connect the compressor and transmit power. The expander and the second expander connects the compressor and the pump and transmit power if necessary.
- 4. A combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and the second high-temperature heat exchanger. The condenser has a liquid refrigerant pipe which passes through a pump and connects the evaporator, an evaporator has a vapor channel connects the second high-temperature heat exchange, the second high-temperature heat exchanger has a vapor channel connects an expander, a compressor has a vapor channel connects the high-temperature heat exchanger, the high-temperature heat exchanger has a vapor channel which passes through a intermediate vapor inlet channel and connects the expander, the expander has a low-pressure vapor channel connected the evaporator, the evaporator has a low-pressure vapor channel connected the compressor and a second expander respectively, the second expander has a low-pressure vapor channel connected the condenser. The high-temperature heat exchanger and the second high-temperature heat exchanger have the heat source medium channels connected the outside, the condenser has the cooling medium channel connected the outside, the evaporator has the heat source medium channel connected the outside if necessary, the expander and the second expander connect the compressor and transmit power. The expander and the second expander connect the compressor and the pump and transmit power if necessary.
- 5. A combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser and an evaporator. The condenser has a liquid refrigerant pipe which passes through a pump and connects the evaporator, an evaporator has a vapor channel which passes through a intermediate vapor inlet channel and connects an expander, a compressor has a vapor channel which passes through a high-temperature heat exchanger and connects the expander, the expander has a low-pressure vapor channel connected the evaporator, the evaporator has a low-pressure vapor channel connected the compressor and the second expander respectively, the second expander has a low-pressure vapor channel connected the condenser. The high-temperature heat exchanger has the heat source medium channel connected the outside, the condenser has the cooling medium channel connected the outside, the evaporator has the heat source medium channel connected the outside if necessary, the expander and the second expander connect the second compressor and transmit power. The expander and the second expander connect the compressor and the pump and transmit power if necessary.
- 6. A combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a high-temperature regenerator. The condenser has a liquid refrigerant pipe which passes through a pump and connects the evaporator, an evaporator has a vapor channel which passes through a intermediate vapor inlet channel and connects an expander, a compressor has a vapor channel which passes through a high-temperature regenerator and a high-temperature heat exchanger, connects the expander, the expander has a low-pressure vapor channel connected the high-temperature regenerator, the high-temperature regenerator has a low-pressure vapor channel connected the evaporator, the evaporator has a low-pressure vapor channel connected the compressor and the second expander respectively, the second expander has a low-pressure vapor channel connected the condenser. The high-temperature heat exchanger has the heat source medium channel connected the outside, the condenser has the cooling medium channel connected the outside, the evaporator has the heat source medium channel connected the outside if necessary, the expander and the second expander connect the second compressor and transmit power. The expander and the second expander connect the compressor and the pump and transmit power if necessary.
- 7. A combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a third expander. The condenser has a liquid refrigerant pipe which passes through a pump and connects the evaporator, an evaporator has a vapor channel connects the third expander, the expander has a low-pressure vapor channel connected the evaporator, a compressor has a vapor channel which passes through a high-temperature heat exchanger and the expander, the expander has a low-pressure vapor channel connected the evaporator, the evaporator has a low-pressure vapor channel connected the compressor and the second expander respectively, the second expander has a low-pressure vapor channel connected the condenser. The high-temperature heat exchanger has the heat source medium channel connected the outside, the condenser has the cooling medium channel connected the outside, the evaporator has the heat source medium channel connected the outside if necessary, the expander, the second expander and the third expander connect the second compressor and transmit power. The expander, the second expander and the third expander connect the compressor and the pump and transmit power if necessary.
- 8. A combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a heating unit. The condenser has a liquid refrigerant pipe which passes through a pump and connects the evaporator, an evaporator has a vapor channel connects the high-temperature heat exchanger, the high-temperature heat exchanger has a vapor channel connected the expander, the expander has a low-pressure vapor channel connected the evaporator, an evaporator has a low-pressure vapor channel and connects the heating unit, the heating unit has a low-pressure vapor channel and connects the compressor and the second expander respectively, the second expander has a low-pressure vapor channel connected the condenser. The high-temperature heat exchanger has the heat source medium channel connected the outside, the condenser has the cooling medium channel connected the outside, or the evaporator has the heat source medium channel connected the outside, the heating unit has the heated medium channel connected the outside, the expander and the second expander connect the second compressor and transmit power. The expander and the second expander connect the compressor and the pump and transmit power if necessary.
- 9. A combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a second high-temperature heat exchanger and a second compressor. The condenser has a liquid refrigerant pipe which passes through a pump and connects the evaporator, an evaporator has a vapor channel connects the high-temperature heat exchanger, the compressor has a vapor channel connects the high-temperature heat exchanger, the high-temperature heat exchanger has a vapor channel connected the second compressor, the second compressor has a vapor channel which passes through a second high-temperature heat exchanger connects the expander, the expander has a low-pressure vapor channel connected the evaporator, an evaporator has a low-pressure vapor channel and connects the compressor and the second expander respectively, the second expander has a low-pressure vapor channel connected the condenser. The high-temperature heat exchanger and the second high-temperature heat exchanger has the heat source medium channel connected the outside respectively, the condenser has the cooling medium channel connected the outside, the evaporator has the heat source medium channel connected the outside if necessary, the expander and the second expander connect the second compressor and transmit power. The expander and the second expander connect the compressor and the second compressor and the pump and transmit power if necessary.
- 10. A combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a second high-temperature heat exchanger and a third expander. The condenser has a liquid refrigerant pipe which passes through a pump and connects the evaporator, an evaporator has a vapor channel connects the high-temperature heat exchanger, the compressor has a vapor channel connects the high-temperature heat exchanger, the high-temperature heat exchanger has a vapor channel connected the third expander, the third expander has a vapor channel which passes through a second high-temperature heat exchanger connects the expander, the expander has a low-pressure vapor channel connected the evaporator, an evaporator has a low-pressure vapor channel and connects the compressor and the second expander respectively, the second expander has a low-pressure vapor channel connected the condenser. The high-temperature heat exchanger and the second high-temperature heat exchanger has the heat source medium channel connected the outside respectively, the condenser has the cooling medium channel connected the outside, the evaporator has the heat source medium channel connected the outside if necessary, the expander, the second expander and the third expander connect the second compressor and transmit power. The expander the second expander and the third expander connect the compressor and the pump and transmit power if necessary.
- 11. A combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a high-temperature regenerator, a second high-temperature heat exchanger and a second compressor. The condenser has a liquid refrigerant pipe which passes through a pump and connects the evaporator, an evaporator has a vapor channel which passes through the high-temperature regenerator and connects a high-temperature heat exchanger, a compressor has a vapor channel which passes through the high-temperature regenerator and the high-temperature heat exchanger, the high-temperature heat exchanger has a vapor channel connects the second compressor, the second compressor has a liquid refrigerant pipe which passes through second high-temperature heat exchanger and connects the expander, the expander has a low-pressure vapor channel which passes through a high-temperature regenerator and connects the evaporator, an evaporator has a low-pressure vapor channel and connects the compressor and the second expander respectively, the second expander has a low-pressure vapor channel connected the condenser. The high-temperature heat exchanger and the second high-temperature heat exchanger has the heat source medium channel connected the outside respectively, the condenser has the cooling medium channel connected the outside, the evaporator has the heat source medium channel connected the outside if necessary, the expander, the second expander connect the compressor and the second compressor and transmit power. The expander the second expander and the second expander connect the compressor, the second compressor and the pump and transmit power if necessary.
- 12. A combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a high-temperature regenerator, a second high-temperature heat exchanger and a third expander. The condenser has a liquid refrigerant pipe which passes through a pump and connects the evaporator, an evaporator has a vapor channel which passes through the high-temperature regenerator and connects a high-temperature heat exchanger, the vapor discharged from compressor flows through the high-temperature regenerator for heat absorption, and then enters the high-temperature heat exchanger for heat absorption, the high-temperature heat exchanger has a vapor channel and connects the third expander, the third expander has a vapor channel which passes through the second high-temperature heat exchanger and connects the third expander, the third expander has a low-pressure vapor channel which passes through the second high-temperature regenerator and connects the evaporator, an evaporator has a low-pressure vapor channel and connects the compressor and the second expander respectively, the second expander has a low-pressure vapor channel connected the condenser. The high-temperature heat exchanger and the second high-temperature heat exchanger have the heat source medium channel connected the outside respectively, the condenser has the cooling medium channel connected the outside, the evaporator has the heat source medium channel connected the outside if necessary, the expander, the second expander and the third expander connect the compressor and transmit power. The expander the second expander and the third expander connect the compressor and the pump and transmit power if necessary.
- 13. The device according to any one of claim 1-12, wherein adding the low temperature regenerator and the second pump, adjusting that the condenser has a liquid refrigerant pipe which passes through a pump and connects the evaporator to that the condenser has a liquid refrigerant pipe which passes through a pump and connects a low temperature regenerator, the compressor adds the vapor extraction channel connected the low temperature regenerator, the low temperature regenerator has a liquid refrigerant pipe which passes through the second pump and connects the evaporator, a combined cycle power device is formed.
-
FIG. 1 is atype 1 example general flow chart of a combined cycle power device provided in the present invention. -
FIG. 2 is atype 2 example general flow chart of a combined cycle power device provided in the present invention. -
FIG. 3 is atype 3 example general flow chart of a combined cycle power device provided in the present invention. -
FIG. 4 is atype 4 example general flow chart of a combined cycle power device provided in the present invention. -
FIG. 5 is atype 5 example general flow chart of a combined cycle power device provided in the present invention. -
FIG. 6 is atype 6 example general flow chart of a combined cycle power device provided in the present invention. -
FIG. 7 is atype 7 example general flow chart of a combined cycle power device provided in the present invention. -
FIG. 8 is atype 8 example general flow chart of a combined cycle power device provided in the present invention. -
FIG. 9 is atype 9 example general flow chart of a combined cycle power device provided in the present invention. -
FIG. 10 is atype 10 example general flow chart of a combined cycle power device provided in the present invention. -
FIG. 11 is atype 11 example general flow chart of a combined cycle power device provided in the present invention. -
FIG. 12 is atype 12 example general flow chart of a combined cycle power device provided in the present invention. -
FIG. 13 is atype 13 example general flow chart of a combined cycle power device provided in the present invention. -
FIG. 14 is atype 14 example general flow chart of a combined cycle power device provided in the present invention. -
FIG. 15 is a type 15 example general flow chart of a combined cycle power device provided in the present invention. - In the figures, 1—expander, 2—compressor, 3—the second expander, 4—circulating pump, 5—high temperature heat exchanger, 6—condenser, 7—evaporator (waste heat boiler), 8—heating unit, 9—high temperature regenerator, 10—the second high-temperature heat exchanger, 11—the third expander, 12—the second compressor, 13—low temperature regenerator, 14—the second pump.
- The first thing to note is that, when describing the cycle's structures and processes, the processes will not be repeatedly described if not necessary, and the obvious processes will not be described. The detailed description of the present invention is as follows:
- The combined cycle power device in
FIG. 1 works as follows: - (1) Device structure. The combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser and an evaporator. A
condenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects theevaporator 7, anevaporator 7 has a vapor channel connected a high-temperature heat exchanger 5, the high-temperature heat exchanger 5 has a vapor channel connected acompressor 1, acompressor 1 has a low-pressure vapor channel connected theevaporator 7, anevaporator 7 has a low-pressure vapor channel connected thecompressor 2 and thesecond expander 3 respectively, thesecond expander 3 has a low-pressure vapor channel connected thecondenser 6. The high-temperature heat exchanger 5 has the heat source medium channel connected the outside, thecondenser 6 has the cooling medium channel connected the outside, theexpander 1 and the second theexpander 3 connect thecompressor 2 and transmit power. - (2) Working processes. The condensate of the
condenser 6 flows through thepump 4 and enters into theevaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the high-temperature heat exchanger 5 for heat absorption, The vapor discharged fromcompressor 2 enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged from the high-temperature heat exchanger 5 flows through theexpander 1 to depressurize and output work. The low-pressure vapor discharged from theexpander 1 flows through theevaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters thecompressor 2 for pressure rise and temperature rise. The second current flows through theexpander 3 to depressurize and output work, and then enters thecondenser 6 to release heat and condense. The heat source medium supplies the driving heat load through the high-temperature heat exchanger 5. The cooling medium takes away the low-temperature heat load through thecondenser 6. Theexpander 1 and thesecond expander 3 supplies power to thecompressor 1 and the outside. Theexpander 1 and thesecond expander 3 supplies power to thecompressor 2, thepump 4 and the outside if necessary. The combined cycle power device is formed. - The combined cycle power device in
FIG. 2 works as follows: - Based on combined cycle power device in
FIG. 1 , theevaporator 7 adds the heat source medium channel connected the outside. The condensate entering theevaporator 7 obtains the heat load provided by the low-pressure vapor and the heat source medium at the same time, heats up, vaporizes and superheats, and then enters the high-temperature heat exchanger 5. The combined cycle power device is formed. - The combined cycle power device in
FIG. 3 works as follows: - (1) Device structure. The combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a heating unit. A
condenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects theevaporator 7, anevaporator 7 has a vapor channel connected a high-temperature heat exchanger 5, acompressor 2 has a vapor channel connected the high-temperature heat exchanger 5, the high-temperature heat exchanger 5 has a vapor channel connected anexpander 1, anexpander 1 has a low-pressure vapor channel connected theheating unit 8, theheating unit 8 has a low-pressure vapor channel connected thecompressor 2 and thesecond expander 3 respectively, thesecond expander 3 has a low-pressure vapor channel connected thecondenser 6. The high-temperature heat exchanger 5 has the heat source medium connected the outside, thecondenser 6 has the cooling medium channel connected the outside, theevaporator 7 has the heat source medium channel connected the outside, theheating unit 8 has the heated medium channel connected the outside, theexpander 1 and the second theexpander 3 connect thecompressor 2 and transmit power. - (2) Working processes. The condensate of the
condenser 6 flows through thepump 4 and enters into theevaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged fromcompressor 2 enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged from the high-temperature heat exchanger 5 flows through theexpander 1 to depressurize and output work. The low-pressure vapor discharged from theexpander 1 flows through theheating unit 8 to release heat and cool down, and then is divided into two currents. The first current enters thecompressor 2 for pressure rise and temperature rise. The second current flows through thesecond expander 3 to depressurize and output work, and then enters thecondenser 6 to release heat and condense. The heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and theevaporator 7. The cooling medium takes away the low-temperature heat load through thecondenser 6. The heated medium takes away the medium temperature heat load through theheating unit 8. Theexpander 1 and thesecond expander 3 supplies power to thecompressor 2 and the outside. Or theexpander 1 and thesecond expander 3 supplies power to thecompressor 2, thepump 4 and the outside if necessary. The combined cycle power device is formed. - The combined cycle power device in
FIG. 4 works as follows: - (1) Device structure. The combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a high-temperature regenerator. An
condenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects theevaporator 7, anevaporator 7 has a low-pressure vapor channel which passes through a high-temperature regenerator 9 and connects the high-temperature heat exchanger 5, acompressor 2 has a vapor channel which passes through the high-temperature regenerator 9 and connects the high-temperature heat exchanger 5, the high-temperature heat exchanger 5 has a vapor channel connected theexpander 1, theexpander 1 has a low-pressure vapor channel connected the high-temperature regenerator 9. The high-temperature regenerator 9 has the heat source medium connected theevaporator 7, anevaporator 7 has a low-pressure vapor channel connected thecompressor 2 and thesecond expander 3 respectively, thesecond expander 3 has a low-pressure vapor channel connected thecondenser 6. The high-temperature heat exchanger 5 has the heat source medium channels connected the outside, thecondenser 6 has the cooling medium channel connected the outside, theexpander 1 and the second theexpander 3 connect thecompressor 2 and transmit power. - (2) Working processes. The condensate of the
condenser 6 flows through thepump 4 and enters into theevaporator 7 in which it absorbs heat, vaporizes and superheats. The superheated vapor flows through the high-temperature regenerator 9 for heat absorption, and then enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged fromcompressor 2 flows through the high-temperature regenerator 9 for heat absorption, and then enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged from the high-temperature heat exchanger 5 flows through theexpander 1 to depressurize and output work. The low-pressure vapor discharged from theexpander 1 flows through the high-temperature regenerator 9 and theevaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters thecompressor 2 for pressure rise and temperature rise. The second current flows through thesecond expander 3 to depressurize and output work, and then enters thecondenser 6 to release heat and condense. The heat source medium supplies the driving heat load through the high-temperature heat exchanger 5. The cooling medium takes away the low-temperature heat load through thecondenser 6. Theexpander 1 and thesecond expander 3 supplies power to thecompressor 2 and the outside. Or theexpander 1 and thesecond expander 3 supplies power to thecompressor 2, thepump 4 and the outside if necessary. The combined cycle power device is formed. - The combined cycle power device in
FIG. 5 works as follows: - (1) Device structure. The combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and the second high-temperature heat exchanger. The
condenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects the evaporator 7), anevaporator 7 has a vapor channel connects the second high-temperature heat exchanger 10, the second high-temperature heat exchanger 10 has a vapor channel connects anexpander 1, acompressor 2 has a vapor channel connects the high-temperature heat exchanger 5, the high-temperature heat exchanger 5 has a vapor channel which passes through a intermediate vapor inlet channel and connects theexpander 1, theexpander 1 has a low-pressure vapor channel connected theevaporator 7, theevaporator 7 has a low-pressure vapor channel connected thecompressor 2 and asecond expander 3 respectively, thesecond expander 3 has a low-pressure vapor channel connected thecondenser 6. The high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 have the heat source medium channels connected the outside, thecondenser 6 has the cooling medium channel connected the outside, theexpander 1 and thesecond expander 3 connect the compressor (2) and transmit power. - (2) Working processes. The condensate of the
condenser 6 flows through thepump 4, theevaporator 7 and the second high-temperature heat exchanger 10 and absorbs heat, vaporizes and superheats, and then enters theexpander 1 to depressurize and output work. The vapor discharged fromcompressor 2 flows through the high-temperature heat exchanger 5 for heat absorption, and then enters theexpander 1 to depressurize and output work. The low-pressure vapor discharged from theexpander 1 flows through theevaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters thecompressor 2 for pressure rise and temperature rise. The second current flows through thesecond expander 3 to depressurize and output work, and then enters thecondenser 6 to release heat and condense. The heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10. The cooling medium takes away the low-temperature heat load through thecondenser 6. Theexpander 1 and thesecond expander 3 supplies power to thecompressor 2 and the outside. Or theexpander 1 and thesecond expander 3 supplies power to thecompressor 2, thepump 4 and the outside if necessary. The combined cycle power device is formed. - The combined cycle power device in
FIG. 6 works as follows: - (1) Device structure. The combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser and an evaporator. The
condenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects theevaporator 7, anevaporator 7 has a vapor channel which passes through a intermediate vapor inlet channel and connects anexpander 1, acompressor 2 has a vapor channel which passes through a high-temperature heat exchanger 5 and connects theexpander 1, theexpander 1 has a low-pressure vapor channel connected theevaporator 7, theevaporator 7 has a low-pressure vapor channel connected thecompressor 2 and thesecond expander 3 respectively, thesecond expander 3 has a low-pressure vapor channel connected thecondenser 6. The high-temperature heat exchanger 5 has the heat source medium channel connected the outside, thecondenser 6 has the cooling medium channel connected the outside, theexpander 1 and thesecond expander 3 connect thesecond compressor 2 and transmit power. - (2) Working processes. The condensate of the
condenser 6 flows through thepump 4 and enters theevaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters theexpander 1 to depressurize and output work. The vapor discharged fromcompressor 2 flows through the high-temperature heat exchanger 5 for heat absorption, and then enters theexpander 1 to depressurize and output work. The low-pressure vapor discharged from theexpander 1 flows through theevaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters thecompressor 2 for pressure rise and temperature rise. The second current flows through thesecond expander 3 to depressurize and output work, and then enters thecondenser 6 to release heat and condense. The heat source medium supplies the driving heat load through the high-temperature heat exchanger 5. The cooling medium takes away the low-temperature heat load through thecondenser 6. Theexpander 1 and thesecond expander 3 supplies power to thecompressor 2 and the outside. Or theexpander 1 and thesecond expander 3 supplies power to thecompressor 2, thepump 4 and the outside if necessary. The combined cycle power device is formed. - The combined cycle power device in
FIG. 7 works as follows: - (1) Device structure. The combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser and a high-temperature regenerator. The
condenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects theevaporator 7, anevaporator 7 has a vapor channel which passes through a intermediate vapor inlet channel and connects anexpander 1, acompressor 2 has a vapor channel which passes through a high-temperature regenerator 9 and a high-temperature heat exchanger 5, connects theexpander 1, theexpander 1 has a low-pressure vapor channel connected the high-temperature regenerator 9, the high-temperature regenerator 9 has a low-pressure vapor channel connected theevaporator 7, theevaporator 7 has a low-pressure vapor channel connected thecompressor 2 and thesecond expander 3 respectively, thesecond expander 3 has a low-pressure vapor channel connected thecondenser 6. The high-temperature heat exchanger 5 has the heat source medium channel connected the outside, thecondenser 6 has the cooling medium channel connected the outside, theexpander 1 and thesecond expander 3 connect thesecond compressor 2 and transmit power. - (2) Working processes. The condensate of the
condenser 6 flows through thepump 4 and enters theevaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters theexpander 1 to depressurize and output work. The vapor discharged fromcompressor 2 flows through the high-temperature regenerator 9 and the high-temperature heat exchanger 5 for heat absorption, and then enters theexpander 2 to depressurize and output work. The low-pressure vapor discharged from theexpander 1 flows through the high-temperature regenerator 9 and theevaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters thecompressor 2 for pressure rise and temperature rise. The second current flows through thesecond expander 3 to depressurize and output work, and then enters thecondenser 6 to release heat and condense. The heat source medium supplies the driving heat load through the high-temperature heat exchanger 5. The cooling medium takes away the low-temperature heat load through thecondenser 6. Theexpander 1 and thesecond expander 3 supplies power to thecompressor 2 and the outside. Or theexpander 1 and thesecond expander 3 supplies power to thecompressor 2, thepump 4 and the outside if necessary. The combined cycle power device is formed. - The combined cycle power device in
FIG. 8 works as follows: - (1) Device structure. The combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a third expander. The
condenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects theevaporator 7, anevaporator 7 has a vapor channel connects thethird expander 11, theexpander 11 has a low-pressure vapor channel connected theevaporator 7, acompressor 2 has a vapor channel which passes through a high-temperature heat exchanger 5 and theexpander 1, theexpander 1 has a low-pressure vapor channel connected theevaporator 7, theevaporator 7 has a low-pressure vapor channel connected thecompressor 2 and thesecond expander 3 respectively, thesecond expander 3 has a low-pressure vapor channel connected thecondenser 6. The high-temperature heat exchanger 5 has the heat source medium channel connected the outside, thecondenser 6 has the cooling medium channel connected the outside, theevaporator 7 has the heat source medium channel connected the outside if necessary, theexpander 1, thesecond expander 3 and thethird expander 11 connect thesecond compressor 2 and transmit power. - (2) Working processes. The condensate of the
condenser 6 flows through thepump 4 and enters theevaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters thethird expander 11 to depressurize and output work. The low-pressure vapor discharged from thethird expander 11 enters theevaporator 7 to release heat and cool down. The vapor discharged from thecompressor 2 flows through the high-temperature heat exchanger 5 for heat absorption, and then enters theexpander 1 to depressurize and output work. The low-pressure vapor discharged from theexpander 1 enters theevaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters thecompressor 2 for pressure rise and temperature rise. The second current flows through thesecond expander 3 to depressurize and output work, and then enters thecondenser 6 to release heat and condense. The heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and theevaporator 7. The cooling medium takes away the low-temperature heat load through thecondenser 6. Theexpander 1, thesecond expander 3 andthird expander 11 supply power to thecompressor 2 and the outside. Or theexpander 1, thesecond expander 3 andthird expander 11 supplies power to thecompressor 2, thepump 4 and the outside if necessary. The combined cycle power device is formed. - The combined cycle power device in
FIG. 9 works as follows: - (1) Device structure. The combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a heating unit. The
condenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects theevaporator 7, anevaporator 7 has a vapor channel connects the high-temperature heat exchanger 5, acompressor 2 has a vapor channel connects the high-temperature heat exchanger 5, the high-temperature heat exchanger 5 has a vapor channel connected theexpander 1, theexpander 1 has a low-pressure vapor channel connected theevaporator 7, anevaporator 7 has a low-pressure vapor channel and connects theheating unit 8, theheating unit 8 has a low-pressure vapor channel and connects thecompressor 2 and the second expander 3) respectively, thesecond expander 3 has a low-pressure vapor channel connected thecondenser 6. The high-temperature heat exchanger 5 has the heat source medium channel connected the outside, thecondenser 6 has the cooling medium channel connected the outside, theheating unit 8 has the heated medium channel connected the outside, theexpander 1 and thesecond expander 3 connect thesecond compressor 2 and transmit power. - (2) Working processes. The condensate of the
condenser 6 flows through thepump 4 and enters theevaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged fromcompressor 2 enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged from the high-temperature heat exchanger 5 flows through theexpander 1 to depressurize and output work. The low-pressure vapor discharged from theexpander 1 flows through theevaporator 7 andheating unit 8 to release heat and cool down, and then is divided into two currents. The first current enters thecompressor 2 for pressure rise and temperature rise. The second current flows through thesecond expander 3 to depressurize and output work, and then enters thecondenser 6 to release heat and condense. The heat source medium supplies the driving heat load through the high-temperature heat exchanger 5. The cooling medium takes away the low-temperature heat load through thecondenser 6. The heated medium takes away the medium temperature heat load through theheating unit 8. Theexpander 1 and thesecond expander 3 supply power to thecompressor 2 and the outside. Or theexpander 1 and thesecond expander 3 supply power to thecompressor 2, thepump 4 and the outside if necessary. The combined cycle power device is formed. - The combined cycle power device in
FIG. 10 works as follows: - (1) Device structure. The combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a second high-temperature heat exchanger and a second compressor. The
condenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects theevaporator 7, anevaporator 7 has a vapor channel connects the high-temperature heat exchanger 5, thecompressor 2 has a vapor channel connects the high-temperature heat exchanger 5, the high-temperature heat exchanger 5 has a vapor channel connected thesecond compressor 12, thesecond compressor 12 has a vapor channel which passes through a second high-temperature heat exchanger 10 and connects theexpander 1, theexpander 1 has a low-pressure vapor channel connected theevaporator 7, anevaporator 7 has a low-pressure vapor channel and connects thecompressor 2 and thesecond expander 3 respectively, thesecond expander 3 has a low-pressure vapor channel connected thecondenser 6. The high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 has the heat source medium channel connected the outside respectively, thecondenser 6 has the cooling medium channel connected the outside, theexpander 1 and thesecond expander 3 connect thesecond compressor 2 and transmit power. - (2) Working processes. The condensate of the
condenser 6 flows through thepump 4 and enters theevaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged fromcompressor 2 enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged from the high-temperature heat exchanger 5 flows through thesecond compressor 12 to pressurize, the second high-temperature heat exchanger 10 for heat absorption and theexpander 2 to depressurize and output work. The low-pressure vapor discharged from theexpander 1 flows through theevaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters thecompressor 2 for pressure rise and temperature rise. The second current flows through thesecond expander 3 to depressurize and output work, and then enters thecondenser 6 to release heat and condense. The heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10. The cooling medium takes away the low-temperature heat load through thecondenser 6. Theexpander 1 and thesecond expander 3 supply power to thecompressor 2, thesecond compressor 12 and the outside. Or theexpander 1 and thesecond expander 3 supply power to thecompressor 2, thesecond compressor 12, thepump 4 and the outside if necessary. The combined cycle power device is formed. - The combined cycle power device in
FIG. 11 works as follows: - (1) Device structure. The combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a second high-temperature heat exchanger and a third expander. The
condenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects theevaporator 7, anevaporator 7 has a vapor channel connects the high-temperature heat exchanger 5, thecompressor 2 has a vapor channel connects the high-temperature heat exchanger 5, the high-temperature heat exchanger 5 has a vapor channel connected thethird expander 11, thethird expander 11 has a vapor channel which passes through a second high-temperature heat exchanger 10 connects theexpander 1, theexpander 1 has a low-pressure vapor channel connected theevaporator 7, anevaporator 7 has a low-pressure vapor channel and connects thecompressor 2 and thesecond expander 3 respectively, thesecond expander 3 has a low-pressure vapor channel connected thecondenser 6. The high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 has the heat source medium channel connected the outside respectively, thecondenser 6 has the cooling medium channel connected the outside, theexpander 1, thesecond expander 3 and thethird expander 11 connect thesecond compressor 2 and transmit power. - (2) Working processes. The condensate of the
condenser 6 flows through thepump 4 and enters theevaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged fromcompressor 2 enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged from the high-temperature heat exchanger 5 flows through thethird expander 11 to depressurize and output work, the second high-temperature heat exchanger 10 for heat absorption and theexpander 1 to depressurize and output work. The low-pressure vapor discharged from theexpander 1 flows through theevaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters thecompressor 2 for pressure rise and temperature rise. The second current flows through thesecond expander 3 to depressurize and output work, and then enters thecondenser 6 to release heat and condense. The heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10. The cooling medium takes away the low-temperature heat load through thecondenser 6. Theexpander 1, thesecond expander 3 and thethird expander 11 supply power to thecompressor 2 and the outside. Theexpander 1, thesecond expander 3 and thethird expander 11 supply power to thecompressor 2, thepump 4 and the outside if necessary. The combined cycle power device is formed. - The combined cycle power device in
FIG. 12 works as follows: - (1) Device structure. The combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a high-temperature regenerator, a second high-temperature heat exchanger and a second compressor. The
condenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects theevaporator 7, anevaporator 7 has a vapor channel which passes through the high-temperature regenerator 9 and connects the high-temperature heat exchanger 5, acompressor 2 has a vapor channel which passes through a high-temperature regenerator 9 and the high-temperature heat exchanger 5, The high-temperature heat exchanger 5 has a vapor channel connects thesecond compressor 12, thesecond compressor 12 has a liquid refrigerant pipe which passes through second high-temperature heat exchanger 10 and connects theexpander 1, theexpander 1 has a low-pressure vapor channel which passes through a high-temperature regenerator 9 and connects theevaporator 7, anevaporator 7 has a low-pressure vapor channel and connects thecompressor 2 and thesecond expander 3 respectively, thesecond expander 3 has a low-pressure vapor channel connected thecondenser 6. The high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 has the heat source medium channel connected the outside respectively, thecondenser 6 has the cooling medium channel connected the outside, theexpander 1, thesecond expander 3 connect thecompressor 2 and thesecond compressor 12, transmit power. - (2) Working processes. The condensate of the
condenser 6 flows through thepump 4 and enters theevaporator 7 in which it absorbs heat, vaporizes and superheats. The superheated vapor flows through the high-temperature regenerator 9 for heat absorption, and then enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged fromcompressor 2 flows through the high-temperature regenerator 9 for heat absorption, and then enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged from the high-temperature heat exchanger 5 flows through thesecond compressor 12 to pressurize, the second high-temperature heat exchanger 10 for heat absorption and theexpander 1 to depressurize and output work. The low-pressure vapor discharged from theexpander 1 flows through the high-temperature regenerator 9 and theevaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters thecompressor 2 for pressure rise and temperature rise. The second current flows through thesecond expander 3 to depressurize and output work, and then enters thecondenser 6 to release heat and condense. The heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10. The cooling medium takes away the low-temperature heat load through thecondenser 6. Theexpander 2 and thesecond expander 3 supplies power to thecompressor 2, thesecond compressor 12 and the outside. Theexpander 2 and thesecond expander 3 supplies power to thecompressor 2, thepump 4, thesecond compressor 12 and the outside if necessary. The combined cycle power device is formed. - The combined cycle power device in
FIG. 13 works as follows: - (1) Device structure. The combined cycle power device comprises an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a high-temperature regenerator, a second high-temperature heat exchanger and a third expander. The
condenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects theevaporator 7, anevaporator 7 has a vapor channel which passes through the high-temperature regenerator 9 and connects the high-temperature heat exchanger 5, the high-temperature heat exchanger 5 has a vapor channel and connects thethird expander 11, thethird expander 11 has a vapor channel which passes through the second high-temperature heat exchanger 10 and connects thethird expander 1, thethird expander 1 has a low-pressure vapor channel which passes through the second high-temperature regenerator 9 and connects theevaporator 7, anevaporator 7 has a low-pressure vapor channel and connects thecompressor 2 and thesecond expander 3 respectively, thesecond expander 3 has a low-pressure vapor channel connected thecondenser 6. The high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 have the heat source medium channel connected the outside respectively, thecondenser 6 has the cooling medium channel connected the outside, theexpander 1, thesecond expander 3 and thethird expander 11 connect thecompressor 2 and transmit power. - (2) Working processes. The condensate of the
condenser 6 flows through thepump 4 and enters theevaporator 7 in which it absorbs heat, vaporizes and superheats. The superheated vapor flows through the high-temperature regenerator 9 for heat absorption, and then enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged fromcompressor 2 flows through the high-temperature regenerator 9 for heat absorption, and then enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged from the high-temperature heat exchanger 5 flows through thethird expander 11 to depressurize and output work, the second high-temperature heat exchanger 10 for heat absorption and theexpander 1 to depressurize and output work. The low-pressure vapor discharged from theexpander 1 flows through the high-temperature regenerator 9 and theevaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters thecompressor 2 for pressure rise and temperature rise. The second current flows through thesecond expander 3 to depressurize and output work, and then enters thecondenser 6 to release heat and condense. The heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10. The cooling medium takes away the low-temperature heat load through thecondenser 6. Theexpander 1, thesecond expander 3 and thethird expander 11 supply power to the compressor and the outside. Or theexpander 1, thesecond expander 3 and thethird expander 11 supply power to thecompressor 2, thepump 4 and the outside if necessary. The combined cycle power device is formed. - The combined cycle power device in
FIG. 14 works as follows: - (1) Structurally, based on combined cycle power device in
FIG. 1 , a low temperature regenerator and the second pump is added. That acondenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects theevaporator 7 is adjusted for that acondenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects alow temperature regenerator 13. Thecompressor 2 adds a vapor extraction channel connected thelow temperature regenerator 13. Thelow temperature regenerator 13 has a liquid refrigerant pipe which passes through thesecond pump 14 and connects theevaporator 7. - (2) Working processes. The condensate of the
condenser 6 flows through thepump 4 and enters thelow temperature regenerator 13 in which it mixes with the vapor extraction from thecompressor 2 for heat absorption. The vapor extraction releases and is condensed. The condensate of thelow temperature regenerator 13 flows through thesecond pump 14 and enters theevaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged fromcompressor 2 enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged from the high-temperature heat exchanger 5 flows through theexpander 1 to depressurize and output work. The low-pressure vapor discharged from theexpander 1 flows through theevaporator 7 to release heat and cool down, and then is divided into two currents. The first current enters thecompressor 2 for pressure rise and temperature rise. The second current flows through thesecond expander 3 to depressurize and output work, and then enters thecondenser 6 to release heat and condense. The low-pressure vapor entering thecompressor 2 is compressed to the certain extent and then divided into two currents. The first current enters thelow temperature regenerator 13 by the intermediate extraction channel. The second current continues to boost pressure and temperature. The heat source medium supplies the driving heat load through the high-temperature heat exchanger 5. The cooling medium takes away the low-temperature heat load through thecondenser 6. Theexpander 1 and thesecond expander 3 supplies power to thecompressor 2 and the outside. Or theexpander 1 and thesecond expander 3 supplies power to thecompressor 2, thepump 4, thesecond pump 13 and the outside if necessary. The combined cycle power device is formed. - The combined cycle power device in
FIG. 15 works as follows: - (1) Structurally, based on combined cycle power device in
FIG. 3 , a low temperature regenerator and the second pump is added. That acondenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects theevaporator 7 is adjusted for that acondenser 6 has a liquid refrigerant pipe which passes through apump 4 and connects alow temperature regenerator 13. Thecompressor 2 adds a vapor extraction channel connected thelow temperature regenerator 13. Thelow temperature regenerator 13 has a liquid refrigerant pipe which passes through thesecond pump 14 and connects theevaporator 7. - (2) Working processes. The condensate of the
condenser 6 flows through thepump 4 and enters thelow temperature regenerator 13 in which it mixes with the vapor extraction from thecompressor 2 for heat absorption. The vapor extraction releases and is condensed. The condensate of thelow temperature regenerator 13 flows through thesecond pump 14 and enters theevaporator 7 in which it absorbs heat, vaporizes and superheats, and then enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged fromcompressor 2 enters the high-temperature heat exchanger 5 for heat absorption. The vapor discharged from the high-temperature heat exchanger 5 flows through theexpander 1 to depressurize and output work. The low-pressure vapor discharged from theexpander 1 flows through theheating unit 8 to release heat and cool down, and then is divided into two currents. The first current enters thecompressor 2 for pressure rise and temperature rise. The second current flows through thesecond expander 3 to depressurize and output work, and then enters thecondenser 6 to release heat and condense. The low-pressure vapor entering thecompressor 2 is compressed to the certain extent and then divided into two currents. The first current enters thelow temperature regenerator 13 by the intermediate extraction channel. The second current continues to boost pressure and temperature. The heat source medium supplies the driving heat load through the high-temperature heat exchanger 5 and theevaporator 7. The cooling medium takes away the low-temperature heat load through thecondenser 6. The heated medium takes away the medium temperature heat load through theheating unit 8. Theexpander 1 and thesecond expander 3 supplies power to thecompressor 2 and the outside. Or theexpander 1 and thesecond expander 3 supplies power to thecompressor 2, thepump 4, thesecond pump 13 and the outside if necessary. The combined cycle power device is formed. - The technical effects of the present invention: the combined cycle power device proposed by the present invention has the following effects and advantages:
- (1) The circulating working medium absorbs heat at high-temperature heat under low pressure. The temperature difference loss between the circulating working medium and the high-temperature heat source is small, which is conducive to improving the thermal efficiency of the system and the safety of the device.
- (2) The circulating working medium mainly relies on the condensation phase transformation process to realize low temperature heat release. The temperature difference loss between the circulating working medium and the environment is controllable, which is conducive to improving the thermal efficiency.
- (3) The present invention adopts the low-pressure and high-temperature operation mode to work in the high-temperature region. Therefore, the contradiction among thermal efficiency, the working medium's parameters and the material's temperature resistance and pressure resistance abilities, which is common in traditional vapor power devices, can be resolved. The temperature difference loss between the heat source and the circulating medium can be greatly reduced, and the thermal efficiency can be greatly improved.
- (4) In the present invention, the equipment is shared to increase the heat absorption process of the lower cycle (Rankine cycle) and improve the thermal efficiency.
- (5) The present invention only uses a single working medium, which reduce the operation cost and improve the flexibility of thermal device.
- (6) When the high-temperature expander is shared, the number of core equipment is reduced, which is conducive to reducing system investment and improving thermal efficiency.
- (7) The lower cycle adopts double expansion process, which is conducive to flexible adjustment of working parameters and adaptability.
- (8) The present invention effectively deals with the high-temperature heat source and the variable temperature heat source, the high-quality fuel and the non high-quality fuel, and has a wide range of application.
- (9) On the premise of realizing high thermal efficiency, the device in the present invention can be selected to operate at low pressure, so as to greatly improve the operation safety of the device.
- (10) The present invention can realize the heat recovery of enterprise device simply, actively, safely and efficiently.
- (11) The thermal efficiency improves effectively when the present invention is applied to the lower end of the gas-steam combined cycle.
- (12) When the present invention is applied to the coal-fired thermal system, it can maintain the original advantages of the traditional steam power cycle in which water vapor is used as working medium and has a wide range of working parameters. According to the actual situation, the present invention can work in subcritical, critical, supercritical or ultra supercritical state, etc.
Claims (13)
1. A combined cycle power device comprising an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser and an evaporator; wherein a condenser (6) has a liquid refrigerant pipe which passes through a pump (4) and connects the evaporator (7), an evaporator (7) has a vapor channel connected a high-temperature heat exchanger (5), a compressor (2) has a vapor channel connected the high-temperature heat exchanger (5), the high-temperature heat exchanger (5) has a vapor channel connected an expander (1), the expander (1) has a low-pressure vapor channel connected the evaporator (7), an evaporator (7) has a low-pressure vapor channel connected the compressor (2) and the second expander (3) respectively, the second expander (3) has a low-pressure vapor channel connected the condenser (6); wherein the high-temperature heat exchanger (5) has the heat source medium channel connected the outside, the condenser (6) has the cooling medium channel connected the outside, or the evaporator (7) has the heat source medium channel connected the outside, the expander (1) and the second the expander (3) connect the compressor (2) and transmit power, wherein the expander (1) and the second expander (3) connect the compressor (2) and the pump (4) and transmit power if necessary.
2. A combined cycle power device comprising an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a heating unit; wherein a condenser (6) has a liquid refrigerant pipe which passes through a pump (4) and connects the evaporator (7), an evaporator (7) has a vapor channel connected a high-temperature heat exchanger (5), a compressor (2) has a vapor channel connected the high-temperature heat exchanger (5), the high-temperature heat exchanger (5) has a vapor channel connected an expander (1), an expander (1) has a low-pressure vapor channel connected the heating unit (8), the heating unit (8) has a low-pressure vapor channel connected the compressor (2) and the second expander (3) respectively, the second expander (3) has a low-pressure vapor channel connected the condenser (6); wherein the high-temperature heat exchanger (5) has the heat source medium connected the outside, the condenser (6) has the cooling medium channel connected the outside, the evaporator (7) has the heat source medium channel connected the outside, the heating unit (8) has the heated medium channel connected the outside, the expander (1) and the second the expander (3) connect the compressor (2) and transmit power, wherein the expander (1) and the second expander (3) connect the compressor (2) and the pump (4) and transmit power if necessary.
3. A combined cycle power device comprising an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a high-temperature regenerator; wherein an condenser (6) has a liquid refrigerant pipe which passes through a pump (4) and connects the evaporator (7), an evaporator (7) has a low-pressure vapor channel which passes through a high-temperature regenerator (9) and connects the high-temperature heat exchanger (5), a compressor (2) has a vapor channel which passes through the high-temperature regenerator (9) and connects the high-temperature heat exchanger (5), the high-temperature heat exchanger (5) has a vapor channel connected the expander (1), the expander (1) has a low-pressure vapor channel connected the high-temperature regenerator (9), the high-temperature regenerator (9) has the heat source medium connected the evaporator (7), an evaporator (7) has a low-pressure vapor channel connected the compressor (2) and the second expander (3) respectively, the second expander (3) has a low-pressure vapor channel connected the condenser (6), the high-temperature heat exchanger (5) has the heat source medium channels connected the outside, the condenser (6) has the cooling medium channel connected the outside, or the evaporator (7) has the heat source medium channel connected the outside, the expander (1) and the second the expander (3) connect the compressor (2) and transmit power, wherein the expander (1) and the second expander (3) connect the compressor (2) and the pump (4) and transmit power if necessary.
4. A combined cycle power device comprising an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and the second high-temperature heat exchanger; wherein the condenser (6) has a liquid refrigerant pipe which passes through a pump (4) and connects the evaporator (7), an evaporator (7) has a vapor channel connects the second high-temperature heat exchanger (10), the second high-temperature heat exchanger (10) has a vapor channel connects an expander (1), a compressor (2) has a vapor channel connects the high-temperature heat exchanger (5), the high-temperature heat exchanger (5) has a vapor channel which passes through a intermediate vapor inlet channel and connects the expander (1), the expander (1) has a low-pressure vapor channel connected the evaporator (7), the evaporator (7) has a low-pressure vapor channel connected the compressor (2) and a second expander (3) respectively, the second expander (3) has a low-pressure vapor channel connected the condenser (6); wherein the high-temperature heat exchanger (5) and the second high-temperature heat exchanger (10) have the heat source medium channels connected the outside, the condenser (6) has the cooling medium channel connected the outside, the evaporator (7) has the heat source medium channel connected the outside if necessary, the expander (1) and the second expander (3) connect the compressor (2) and transmit power, wherein the expander (1) and the second expander (3) connect the compressor (2) and the pump (4) and transmit power if necessary.
5. A combined cycle power device comprising an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser and an evaporator; wherein the condenser (6) has a liquid refrigerant pipe which passes through a pump (4) and connects the evaporator (7), an evaporator (7) has a vapor channel which passes through a intermediate vapor inlet channel and connects an expander (1), a compressor (2) has a vapor channel which passes through a high-temperature heat exchanger (5) and connects the expander (1), the expander (1) has a low-pressure vapor channel connected the evaporator (7), the evaporator (7) has a low-pressure vapor channel connected the compressor (2) and the second expander (3) respectively, the second expander (3) has a low-pressure vapor channel connected the condenser (6); wherein the high-temperature heat exchanger (5) has the heat source medium channel connected the outside, the condenser (6) has the cooling medium channel connected the outside, the evaporator (7) has the heat source medium channel connected the outside if necessary, the expander (1) and the second expander (3) connect the second compressor (2) and transmit power, wherein the expander (1) and the second expander (3) connect the compressor (2) and the pump (4) and transmit power if necessary.
6. A combined cycle power device comprising an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a high-temperature regenerator; wherein the condenser (6) has a liquid refrigerant pipe which passes through a pump (4) and connects the evaporator (7), an evaporator (7) has a vapor channel which passes through a intermediate vapor inlet channel and connects an expander (1), a compressor (2) has a vapor channel which passes through a high-temperature regenerator (9) and a high-temperature heat exchanger (5), connects the expander (1), the expander (1) has a low-pressure vapor channel connected the high-temperature regenerator (9), the high-temperature regenerator (9) has a low-pressure vapor channel connected the evaporator (7), the evaporator (7) has a low-pressure vapor channel connected the compressor (2) and the second expander (3) respectively, the second expander (3) has a low-pressure vapor channel connected the condenser (6); wherein the high-temperature heat exchanger (5) has the heat source medium channel connected the outside, the condenser (6) has the cooling medium channel connected the outside, the evaporator (7) has the heat source medium channel connected the outside if necessary, the expander (1) and the second expander (3) connect the second compressor (2) and transmit power, wherein the expander (1) and the second expander (3) connect the compressor (2) and the pump (4) and transmit power if necessary.
7. A combined cycle power device comprising an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a third expander; wherein the condenser (6) has a liquid refrigerant pipe which passes through a pump (4) and connects the evaporator (7), an evaporator (7) has a vapor channel connects the third expander (11), the expander (11) has a low-pressure vapor channel connected the evaporator (7), a compressor (2) has a vapor channel which passes through a high-temperature heat exchanger (5) and the expander (1), the expander (1) has a low-pressure vapor channel connected the evaporator (7), the evaporator (7) has a low-pressure vapor channel connected the compressor (2) and the second expander (3) respectively, the second expander (3) has a low-pressure vapor channel connected the condenser (6); wherein the high-temperature heat exchanger (5) has the heat source medium channel connected the outside, the condenser (6) has the cooling medium channel connected the outside, the evaporator (7) has the heat source medium channel connected the outside if necessary, the expander (1), the second expander (3) and the third expander (11) connect the second compressor (2) and transmit power, wherein the expander (1), the second expander (3) and the third expander (11) connect the compressor (2) and the pump (4) and transmit power if necessary.
8. A combined cycle power device comprising an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator and a heating unit; wherein the condenser (6) has a liquid refrigerant pipe which passes through a pump (4) and connects the evaporator (7), an evaporator (7) has a vapor channel connects the high-temperature heat exchanger (5), a compressor (2) has a vapor channel connects the high-temperature heat exchanger (5), the high-temperature heat exchanger (5) has a vapor channel connected the expander (1), the expander (1) has a low-pressure vapor channel connected the evaporator (7), an evaporator (7) has a low-pressure vapor channel and connects the heating unit (8), the heating unit (8) has a low-pressure vapor channel and connects the compressor (2) and the second expander (3) respectively, the second expander (3) has a low-pressure vapor channel connected the condenser (6); wherein the high-temperature heat exchanger (5) has the heat source medium channel connected the outside, the condenser (6) has the cooling medium channel connected the outside, the evaporator (7) has the heat source medium channel connected the outside if necessary, the heating unit (8) has the heated medium channel connected the outside, the expander (1) and the second expander (3) connect the second compressor (2) and transmit power, wherein the expander (1) and the second expander (3) connect the compressor (2) and the pump (4) and transmit power if necessary.
9. A combined cycle power device comprising an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a second high-temperature heat exchanger and a second compressor; wherein the condenser (6) has a liquid refrigerant pipe which passes through a pump (4) and connects the evaporator (7), an evaporator (7) has a vapor channel connects the high-temperature heat exchanger (5), the compressor (2) has a vapor channel connects the high-temperature heat exchanger (5), the high-temperature heat exchanger (5) has a vapor channel connected the second compressor (12), the second compressor (12) has a vapor channel which passes through a second high-temperature heat exchanger (10) connects the expander (1), the expander (1) has a low-pressure vapor channel connected the evaporator (7), an evaporator (7) has a low-pressure vapor channel and connects the compressor (2) and the second expander (3) respectively, the second expander (3) has a low-pressure vapor channel connected the condenser (6); wherein the high-temperature heat exchanger (5) and the second high-temperature heat exchanger (10) has the heat source medium channel connected the outside respectively, the condenser (6) has the cooling medium channel connected the outside, the evaporator (7) has the heat source medium channel connected the outside if necessary, the expander (1) and the second expander (3) connect the second compressor (2) and the second compressor (12) and transmit power, wherein the expander (1) and the second expander (3) connect the compressor (2), the second compressor (12) and the pump (4) and transmit power if necessary.
10. A combined cycle power device comprising an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a second high-temperature heat exchanger and a third expander; wherein the condenser (6) has a liquid refrigerant pipe which passes through a pump (4) and connects the evaporator (7), an evaporator (7) has a vapor channel connects the high-temperature heat exchanger (5), the compressor (2) has a vapor channel connects the high-temperature heat exchanger (5), the high-temperature heat exchanger (5) has a vapor channel connected the third expander (11), the third expander (11) has a vapor channel which passes through a second high-temperature heat exchanger (10) connects the expander (1), the expander (1) has a low-pressure vapor channel connected the evaporator (7), an evaporator (7) has a low-pressure vapor channel and connects the compressor (2) and the second expander (3) respectively, the second expander (3) has a low-pressure vapor channel connected the condenser (6); wherein the high-temperature heat exchanger (5) and the second high-temperature heat exchanger (10) has the heat source medium channel connected the outside respectively, the condenser (6) has the cooling medium channel connected the outside, the evaporator (7) has the heat source medium channel connected the outside if necessary, the expander (1), the second expander (3) and the third expander (11) connect the second compressor (2) and transmit power, wherein the expander (1), the second expander (3) and the third expander (11) connect the compressor (2) and the pump (4) and transmit power if necessary.
11. A combined cycle power device comprising an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a high-temperature regenerator, a second high-temperature heat exchanger and a second compressor; wherein the condenser (6) has a liquid refrigerant pipe which passes through a pump (4) and connects the evaporator (7), an evaporator (7) has a vapor channel which passes through the high-temperature regenerator (9) and connects the high-temperature heat exchanger (5), a compressor (2) has a vapor channel which passes through a high-temperature regenerator (9) and the high-temperature heat exchanger (5), the high-temperature heat exchanger (5) has a vapor channel connects the second compressor (12), the second compressor (12) has a liquid refrigerant pipe which passes through second high-temperature heat exchanger (10) and connects the expander (1), the expander (1) has a low-pressure vapor channel which passes through a high-temperature regenerator (9) and connects the evaporator (7), an evaporator (7) has a low-pressure vapor channel and connects the compressor (2) and the second expander (3) respectively, the second expander (3) has a low-pressure vapor channel connected the condenser (6); wherein the high-temperature heat exchanger (5) and the second high-temperature heat exchanger (10) has the heat source medium channel connected the outside respectively, the condenser (6) has the cooling medium channel connected the outside, the evaporator (7) has the heat source medium channel connected the outside if necessary, the expander (1), the second expander (3) connect the compressor (2) and the second compressor (12), transmit power, wherein the expander (1) the second expander (3) and the second expander (3) connect the compressor (2), the second compressor (12) and the pump (4) and transmit power if necessary.
12. A combined cycle power device comprising an expander, a compressor, a second expander, a pump, a high-temperature heat exchanger, a condenser, an evaporator, a high-temperature regenerator, a second high-temperature heat exchanger and a third expander; wherein the condenser (6) has a liquid refrigerant pipe which passes through a pump (4) and connects the evaporator (7), an evaporator (7) has a vapor channel which passes through the high-temperature regenerator (9) and connects the high-temperature heat exchanger (5), the compressor (2) has a vapor channel which passes through the high-temperature regenerator (9) and connects the high-temperature heat exchanger (5), the high-temperature heat exchanger (5) has a vapor channel and connects the third expander (11), the third expander (11) has a vapor channel which passes through the second high-temperature heat exchanger (10) and connects the third expander (1), the third expander (1) has a low-pressure vapor channel which passes through the second high-temperature regenerator (9) and connects the evaporator (7), an evaporator (7) has a low-pressure vapor channel and connects the compressor (2) and the second expander (3) respectively, the second expander (3) has a low-pressure vapor channel connected the condenser (6); wherein the high-temperature heat exchanger (5) and the second high-temperature heat exchanger (10) have the heat source medium channel connected the outside respectively, the condenser (6) has the cooling medium channel connected the outside, the evaporator (7) has the heat source medium channel connected the outside if necessary, the expander (1), the second expander (3) and the third expander (11) connect the compressor (2) and transmit power, wherein the expander (1) the second expander (3) and the third expander (11) connect the compressor (2) and the pump (4) and transmit power if necessary.
13. The device according to any one of claim 1 -12 , wherein adding a low temperature regenerator and the second pump, adjusting that the condenser (6) has a liquid refrigerant pipe which passes through a pump (4) and connects the evaporator (7) to that the condenser (6) has a liquid refrigerant pipe which passes through a pump (4) and connects a low temperature regenerator (13), the compressor (2) adds the vapor extraction channel connected the low temperature regenerator (13), the low temperature regenerator (13) has a liquid refrigerant pipe which passes through the second pump (14) and connects the evaporator (7), a combined cycle power device is formed.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201910397037.5 | 2019-05-02 | ||
CN201910397037 | 2019-05-02 | ||
PCT/CN2020/000095 WO2020220727A1 (en) | 2019-05-02 | 2020-04-28 | Combined-cycle power device |
Publications (1)
Publication Number | Publication Date |
---|---|
US20220228512A1 true US20220228512A1 (en) | 2022-07-21 |
Family
ID=72197716
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US17/608,150 Abandoned US20220228512A1 (en) | 2019-05-02 | 2020-04-28 | Combined cycle power device |
Country Status (3)
Country | Link |
---|---|
US (1) | US20220228512A1 (en) |
CN (1) | CN111608751A (en) |
WO (1) | WO2020220727A1 (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20220220891A1 (en) * | 2019-05-06 | 2022-07-14 | Huayu Li | Combined cycle power device |
Families Citing this family (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2022068119A1 (en) * | 2020-09-29 | 2022-04-07 | 李华玉 | Regenerative thermal cycle based novel regenerative mechanical compression heat pumps |
WO2022152006A1 (en) * | 2021-01-12 | 2022-07-21 | 李华玉 | Dual-fuel gas-steam combined cycle power apparatus |
Citations (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US7971424B2 (en) * | 2005-11-29 | 2011-07-05 | Noboru Masada | Heat cycle system and composite heat cycle electric power generation system |
US8056350B2 (en) * | 2005-10-04 | 2011-11-15 | Ac-Sun Aps | Cooling apparatus for air conditioning and heat pumps |
US8857186B2 (en) * | 2010-11-29 | 2014-10-14 | Echogen Power Systems, L.L.C. | Heat engine cycles for high ambient conditions |
US9038390B1 (en) * | 2014-10-10 | 2015-05-26 | Sten Kreuger | Apparatuses and methods for thermodynamic energy transfer, storage and retrieval |
CN107893685A (en) * | 2016-10-12 | 2018-04-10 | 李华玉 | Either simplex matter Steam Combined Cycle and combined cycle Steam Power Equipment |
US20180340712A1 (en) * | 2017-05-24 | 2018-11-29 | General Electric Company | Thermoelectric energy storage system and an associated method thereof |
Family Cites Families (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN205047261U (en) * | 2015-10-26 | 2016-02-24 | 华北理工大学 | Critical CO2 heat pump and rankine cycle's coupled system strides based on waste heat recovery |
WO2018068431A1 (en) * | 2016-10-12 | 2018-04-19 | 李华玉 | Combined cycle steam power device having evaporation stages |
CN108019245B (en) * | 2016-12-15 | 2020-05-29 | 李华玉 | Multiple combined cycle power plant |
WO2018122083A1 (en) * | 2016-12-28 | 2018-07-05 | Hsl Energy Holding Aps | A heat pump and a process for producing a heated first medium and a cooled second medium |
CN108679880B (en) * | 2017-03-30 | 2021-07-27 | 李华玉 | Double-working medium combined cycle compression heat pump |
-
2020
- 2020-04-28 WO PCT/CN2020/000095 patent/WO2020220727A1/en active Application Filing
- 2020-04-28 US US17/608,150 patent/US20220228512A1/en not_active Abandoned
- 2020-04-28 CN CN202010389744.2A patent/CN111608751A/en active Pending
Patent Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US8056350B2 (en) * | 2005-10-04 | 2011-11-15 | Ac-Sun Aps | Cooling apparatus for air conditioning and heat pumps |
US7971424B2 (en) * | 2005-11-29 | 2011-07-05 | Noboru Masada | Heat cycle system and composite heat cycle electric power generation system |
US8857186B2 (en) * | 2010-11-29 | 2014-10-14 | Echogen Power Systems, L.L.C. | Heat engine cycles for high ambient conditions |
US9038390B1 (en) * | 2014-10-10 | 2015-05-26 | Sten Kreuger | Apparatuses and methods for thermodynamic energy transfer, storage and retrieval |
CN107893685A (en) * | 2016-10-12 | 2018-04-10 | 李华玉 | Either simplex matter Steam Combined Cycle and combined cycle Steam Power Equipment |
US20190112949A1 (en) * | 2016-10-12 | 2019-04-18 | Huayu Li | Single working-medium vapor combined cycle and vapor power device for combined cycle |
US20180340712A1 (en) * | 2017-05-24 | 2018-11-29 | General Electric Company | Thermoelectric energy storage system and an associated method thereof |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20220220891A1 (en) * | 2019-05-06 | 2022-07-14 | Huayu Li | Combined cycle power device |
Also Published As
Publication number | Publication date |
---|---|
CN111608751A (en) | 2020-09-01 |
WO2020220727A1 (en) | 2020-11-05 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US20220213813A1 (en) | Combined cycle power device | |
US20190112949A1 (en) | Single working-medium vapor combined cycle and vapor power device for combined cycle | |
US20220228512A1 (en) | Combined cycle power device | |
CN111852586A (en) | Combined cycle power plant | |
US20220220868A1 (en) | Combined cycle power device | |
US20220290584A1 (en) | Combined cycle power device | |
US20220228511A1 (en) | Combined cycle power device | |
US20220213819A1 (en) | Combined cycle power device | |
US20220220891A1 (en) | Combined cycle power device | |
CN111852587A (en) | Combined cycle power plant | |
CN111852585A (en) | Combined cycle power plant | |
WO2020233133A1 (en) | Combined circulation power apparatus | |
WO2020228357A1 (en) | Combined cycle power apparatus | |
WO2020228356A1 (en) | Combined cycle power apparatus | |
CN115199358A (en) | Combined cycle power plant | |
CN115217545A (en) | Combined cycle power plant | |
CN115217542A (en) | Combined cycle power plant | |
CN115217541A (en) | Combined cycle power plant | |
CN115217549A (en) | Combined cycle power plant | |
CN113202578A (en) | Single-working medium combined cycle power plant | |
CN111852588A (en) | Combined cycle power plant | |
CN112145245A (en) | Combined cycle power plant | |
CN115217550A (en) | Combined cycle power plant | |
CN112460829A (en) | Single-working medium combined cycle heat pump device | |
CN115199357A (en) | Combined cycle power plant |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
STPP | Information on status: patent application and granting procedure in general |
Free format text: DOCKETED NEW CASE - READY FOR EXAMINATION |
|
STPP | Information on status: patent application and granting procedure in general |
Free format text: NON FINAL ACTION MAILED |
|
STCB | Information on status: application discontinuation |
Free format text: ABANDONED -- FAILURE TO RESPOND TO AN OFFICE ACTION |