WO2020211475A1 - Single working medium steam combined circulation - Google Patents
Single working medium steam combined circulation Download PDFInfo
- Publication number
- WO2020211475A1 WO2020211475A1 PCT/CN2020/000073 CN2020000073W WO2020211475A1 WO 2020211475 A1 WO2020211475 A1 WO 2020211475A1 CN 2020000073 W CN2020000073 W CN 2020000073W WO 2020211475 A1 WO2020211475 A1 WO 2020211475A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- working fluid
- kilogram
- endothermic
- exothermic
- boost
- Prior art date
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
- 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
- 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
- F01K23/04—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 condensation heat from one cycle heating the fluid in another cycle
-
- 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
- F01K25/06—Plants or engines characterised by use of special working fluids, not otherwise provided for; Plants operating in closed cycles and not otherwise provided for using mixtures of different fluids
-
- 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
- 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
- F01K13/00—General layout or general methods of operation of complete plants
Definitions
- the invention belongs to the field of energy and power technology.
- the heat source is high temperature and variable temperature heat source; when the Rankine cycle is used as the theoretical basis, water vapor is used as the circulating working fluid to achieve thermal variable work, due to the temperature and pressure resistance of the material And safety restrictions, no matter what parameters are used for operation, there is a large temperature difference between the circulating working fluid and the heat source, and the irreversible loss is large, resulting in low thermal efficiency.
- thermal cycle is a heat energy utilization device
- the present invention proposes a single working substance steam combination cycle. .
- the main purpose of the present invention is to provide a single working fluid steam combined cycle, and the specific content of the invention is described as follows:
- Single working fluid steam combined cycle refers to the working fluid composed of M 1 kg, M 2 kg and H kg, and ten processes carried out separately or jointly-M 1 kg working fluid boost process 12, M 1 kg Working fluid endothermic vaporization process 23, H kg working fluid boosting process 1e, H kg working fluid and (M 1 +M 2 ) kg working fluid mixed endothermic process e6, M 2 kg working fluid boosting process 63, (M 1 +M 2 )Kg working fluid endothermic process 34, (M 1 +M 2 )Kg working fluid pressure reduction process 45, (M 1 +M 2 )Kg working fluid mixed with H kg working fluid and exothermic process 56, ( M 1 +H) kilogram working fluid depressurization process 67, (M 1 +H) kilogram working fluid exothermic condensation process 71-a closed process of composition.
- Single working fluid steam combined cycle refers to eleven processes composed of M 1 kilogram, M 2 kilogram and H kilogram, respectively or jointly-M 1 kilogram working medium boost process 12, M 1 Kilogram working fluid endothermic vaporization process 23, M 1 kilogram working fluid depressurization process 35, H kilogram working fluid boosting process 1e, H kilogram working fluid and (M 1 +M 2 ) kg working fluid mixed endothermic process e7, M 2 kg working fluid boost process 74, M 2 kg working fluid endothermic process 45, (M 1 +M 2 ) kg working fluid depressurization process 56, (M 1 +M 2 ) kg working fluid mixed with H kg working fluid
- Single working fluid steam combined cycle refers to the working fluids composed of M 1 kg, M 2 kg and H kg, which are carried out separately or jointly in eleven processes-M 1 kg working fluid boost process 12, M 1 Kilogram working fluid endothermic vaporization process 25, H kilogram working fluid boosting process 1e, H kilogram working fluid and (M 1 +M 2 ) kg working fluid mixed endothermic process e7, M 2 kg working fluid boosting process 73, M 2 kg working fluid endothermic process 34, M 2 kg working fluid pressure reduction process 45, (M 1 +M 2 ) kg working fluid pressure reduction process 56, (M 1 +M 2 ) kg working fluid mixed with H kg working fluid
- Single working fluid steam combined cycle refers to the working fluid consisting of M 1 kg, M 2 kg and H kg, and twelve processes carried out separately or jointly-M 1 kg working fluid boosting process 12, M 1 Kilogram working fluid endothermic vaporization process 23, M 1 kilogram working fluid pressure reduction process 37, H kilogram pressure boosting process 1e, H kilogram working fluid and (M 1 + M 2 ) kilogram working fluid mixed endothermic process e8, M 2 kg Working fluid pressure increase process 84, M 2 kg working fluid endothermic process 45, M 2 kg working fluid depressurization process 56, M 2 kg working fluid and H kg working fluid mixed exothermic process 67, (M 1 +M 2 ) Kilogram working fluid and H kilogram working fluid mixing exothermic process 78, (M 1 +H) kilogram working fluid depressurization process 89, (M 1 +H) kilogram working fluid exothermic condensation process 91—composition closed process.
- Single working fluid steam combined cycle refers to the working fluid consisting of M 1 kg, M 2 kg and H kg, and twelve processes carried out separately or jointly-M 1 kg working fluid boosting process 12, M 1 Kilogram working fluid endothermic vaporization process 23, M 1 kilogram working fluid depressurization process 34, M 1 kilogram working fluid and H kilogram working fluid mixed exothermic process 47, H kilogram working fluid boosting process 1e, H kilogram working fluid and ( M 1 +M 2 ) kg working fluid mixed endothermic process e8, M 2 kg working fluid pressure increase process 85, M 2 kg working fluid heat absorption process 56, M 2 kg working fluid pressure reduction process 67, (M 1 +M 2 ) Kilogram working fluid and H kilogram working fluid mixing exothermic process 78, (M 1 +H) kilogram working fluid depressurization process 89, (M 1 +H) kilogram working fluid exothermic condensation process 91—composition closed process .
- Single working fluid steam combined cycle refers to 13 processes that are composed of M 1 kg, M 2 kg and H kg, respectively or jointly-M 1 kg working fluid boost process 12, M 1 Kilogram working fluid endothermic vaporization process 23, H kilogram working fluid boosting process 1e, H kilogram working fluid and (M 1 + M 2 ) kg working fluid mixed endothermic process e8, M 2 kilogram working fluid boosting process 83, ( M 1 +M 2 ) Kilogram working fluid endothermic process 34, X kilogram working fluid pressure reduction process 47, (M 1 +M 2 -X) kg working fluid heat absorption process 45, (M 1 +M 2 -X) kg Working fluid depressurization process 56, (M 1 +M 2 -X) kg working fluid and H kg working fluid mixing exothermic process 67, (M 1 +M 2 ) kg working fluid and H kg working fluid mixing exothermic process 78 , (M 1 +H) kg working fluid pressure reduction process 89, (M 1 +H) kg working fluid exothermic condensation process 91-a closed process of composition.
- Single working fluid steam combined cycle refers to 13 processes that are composed of M 1 kg, M 2 kg and H kg, respectively or jointly-M 1 kg working fluid boost process 12, M 1 Kilogram working fluid endothermic process 2b, (M 1 +M) kilogram working fluid endothermic vaporization process b3, H kilogram working fluid boost process 1e, H kilogram working fluid and (M 1 +M 2 ) kilogram working fluid endothermic Process e6, M 2 kg working fluid boost process 6a, M kg working fluid exothermic condensation process ab, (M 2 -M) kg working fluid boosting process a3, (M 1 +M 2 ) kg working fluid endothermic process 34, (M 1 +M 2 ) kg working fluid depressurization process 45, (M 1 +M 2 ) kg working fluid and H kg working fluid mixed exothermic process 56, (M 1 +H) kg working fluid depressurization process 67, (M 1 +H) Kilogram of working fluid exothermic condensation process 71-a closed process of composition.
- Single working fluid steam combined cycle refers to the working fluid consisting of M 1 kg, M 2 kg and H kg, and 14 processes carried out separately or together-M 1 kg working fluid boost process 12, M 1 Kilogram working fluid endothermic process 2b, (M 1 +M) kilogram working fluid endothermic vaporization process b3, (M 1 +M) kilogram working fluid pressure reduction process 35, H kilogram working fluid pressure increase process 1e, H kilogram working fluid Mixed with (M 1 +M 2 ) kg working fluid endothermic process e7, M 2 kg working fluid boosting process 7a, M kg working fluid exothermic condensation process ab, (M 2 -M) kg working fluid boosting process a4 , (M 2 -M) kg working fluid endothermic process 45, (M 1 +M 2 ) kg working fluid depressurization process 56, (M 1 +M 2 ) kg working fluid and H kg working fluid mixing exothermic process 67 , (M 1 +H) kg working fluid pressure reduction process 78, (M 1 +H) kg working fluid exothermic condensation process 81
- Single working fluid steam combined cycle refers to the working fluid composed of M 1 kg, M 2 kg and H kg, and 14 processes carried out separately or together-M 1 kg working fluid boost process 12, M 1 Kilogram working fluid endothermic process 2b, (M 1 +M) kilogram working fluid endothermic vaporization process b5, H kilogram working fluid boosting process 1e, H kilogram working fluid and (M 1 +M 2 ) kilogram working fluid endothermic Process e7, M 2 kg working fluid boosting process 7a, M kg working fluid exothermic condensation process ab, (M 2 -M) kg working fluid boosting process a3, (M 2 -M) kg working fluid endothermic process 34 , (M 2 -M) kg working fluid depressurization process 45, (M 1 +M 2 ) kg working fluid depressurization process 56, (M 1 +M 2 ) kg working fluid and H kg working fluid mixed exothermic process 67 , (M 1 +H) kg working fluid pressure reduction process 78, (M 1 +H) kg working fluid exothermic condensation process 81
- the single working fluid steam combined cycle refers to the working fluids composed of M 1 kg, M 2 kg and H kg, and fifteen processes carried out separately or jointly-M 1 kg working fluid boosting process 12, M 1 Kilogram working fluid endothermic process 2b, (M 1 +M) kilogram working fluid endothermic vaporization process b3, (M 1 +M) kilogram working fluid depressurization process 37, H kilogram working fluid boosting process 1e, H kg working fluid Mixing with (M 1 +M 2 ) kg of working fluid endothermic process e8, M 2 kg of working fluid boosting process 8a, M kg of working fluid exothermic condensation process ab, (M 2 -M) kg working fluid boosting process a4 , (M 2 -M) kg working fluid endothermic process 45, (M 2 -M) kg working fluid depressurization process 56, (M 2 -M) kg working fluid and H kg working fluid mixing exothermic process 67, ( M 1 +M 2 ) Kilogram working fluid and H kilogram working fluid mixing exothermic process 78, (M
- Single working fluid steam combined cycle refers to the working fluids composed of M 1 kg, M 2 kg and H kg, which are carried out separately or jointly in fifteen processes-M 1 kg working fluid boosting process 12, M 1 Kilogram working fluid endothermic process 2b, (M 1 +M) kilogram working fluid endothermic vaporization process b3, (M 1 +M) kilogram working fluid pressure reduction process 34, (M 1 +M) kilogram working fluid and H kilogram working fluid Exothermic process 47 of H kg working fluid, 1e of H kg working fluid, heat absorption process of H kg working fluid and (M 1 + M 2 ) kg working fluid e8, M 2 kg working fluid boosting process 8a, M kg working fluid Exothermic and condensation process ab of (M 2 -M) kilogram of working fluid pressure increase process a5, (M 2 -M) kilogram of working fluid endothermic process 56, (M 2 -M) kilogram working fluid depressurization process 67, ( M 1 +M 2 ) Kilogram working fluid and H kilogram working fluid mixing exothermic process 78, (M 1 +H
- the single working fluid steam combined cycle refers to the working fluid composed of M 1 kg, M 2 kg and H kg, and 16 processes carried out separately or jointly-M 1 kg working fluid boost process 12, M 1 Kilogram working fluid endothermic process 2b, (M 1 +M) kilogram working fluid endothermic vaporization process b3, H kilogram working fluid boost process 1e, H kilogram working fluid and (M 1 +M 2 ) kilogram working fluid endothermic Process e8, M 2 kg working fluid boost process 8a, M kg working fluid exothermic condensation process ab, (M 2 -M) kg working fluid boosting process a3, (M 1 +M 2 ) kg working fluid endothermic process 34, X kilogram working fluid pressure reduction process 47, (M 1 +M 2 -X) kilogram working fluid endothermic process 45, (M 1 +M 2 -X) kilogram working fluid pressure reduction process 56, (M 1 +M 2 -X) The exothermic process of mixing kilograms of working fluid and H kilograms of working fluid 67, (M 1 +M 2 ) the exothermic process of
- Figure 1/12 is an example diagram of the first principle flow chart of the single working fluid steam combined cycle provided by the present invention.
- Figure 2/12 is an example diagram of the second principle flow chart of the single working fluid steam combined cycle provided by the present invention.
- Figure 3/12 is an example diagram of the third principle flow chart of the single working fluid steam combined cycle provided by the present invention.
- Figure 4/12 is an example diagram of the fourth principle flow chart of the single working fluid steam combined cycle provided by the present invention.
- Figure 5/12 is an example diagram of the fifth principle flow chart of the single working fluid steam combined cycle provided by the present invention.
- Figure 6/12 is an example diagram of the sixth principle flow chart of the single working fluid steam combined cycle provided by the present invention.
- Figure 7/12 is an example diagram of the seventh principle flow chart of the single working fluid steam combined cycle provided by the present invention.
- Figure 8/12 is an example diagram of the eighth principle flow chart of the single working fluid steam combined cycle provided by the present invention.
- Figure 9/12 is an example diagram of the ninth principle flow chart of the single working fluid steam combined cycle provided by the present invention.
- Figure 10/12 is an example diagram of the tenth principle flow chart of the single working fluid steam combined cycle provided by the present invention.
- Figure 11/12 is an example diagram of the eleventh principle flow chart of the single working fluid steam combined cycle provided by the present invention.
- Figure 12/12 is an example diagram of the twelfth principle flow chart of the single working fluid steam combined cycle provided by the present invention.
- Working medium is carried out-M 1 kg of working fluid condensate boost process 12, M 1 kg of working fluid endothermic heating, vaporization and overheating process 23, H kg of working fluid condensate boost process 1e, H kg of working fluid and (M 1 +M 2 ) Kilogram working fluid mixed endothermic heating, vaporization and overheating process e6, M 2 kg working fluid pressure rising process 63, (M 1 +M 2 ) kg working fluid endothermic heating process 34, (M 1 + M 2 )Kg working fluid depressurization expansion process 45, (M 1 +M 2 )Kg working fluid mixed with H kg working fluid exothermic cooling process56, (M 1 +H)Kg working fluid depressurization expansion process 67,( M 1 +H) Kilogram working fluid exothermic condensation process 71-10 processes in total.
- 3Energy conversion process-the boosting process 12 of M 1 kg working fluid and the boosting process 1e of H kg working fluid are generally completed by a circulating pump, and the boosting process 63 of M 2 kg working fluid is generally completed by a compressor;
- the pressure-reducing expansion process of (M 1 +M 2 ) kg of working fluid 45 and the pressure-reducing expansion process of (M 1 +H) kilogram of working fluid 67 are generally completed by the expander; the expansion work is greater than the pressure boosting work, and the heat is completed
- Variable power and external cycle net power is provided to form a single working substance steam combined cycle.
- M 1 kg working medium condensed liquid refrigerant boosting process 12 M 1 kg refrigerant absorbs heat heating, vaporization and superheating process 23, M 1 kg refrigerant expansion process down 35, H refrigerant condensate liters kg Pressure process 1e, H kg working fluid mixed with (M 1 +M 2 ) kg working fluid endothermic heating, vaporization and overheating process e7, M 2 kg working fluid pressure rising process 74, M 2 kg working fluid endothermic heating process 45, (M 1 +M 2 ) kg working fluid depressurization and expansion process 56, (M 1 +M 2 ) kg working fluid and H kg working fluid mixed exothermic cooling process 67, (M 1 +H) kg working fluid drop Pressure expansion process 78, (M 1 +H) kilogram working fluid exothermic condensation process 81-a total of 11 processes.
- 3Energy conversion process-the boosting process 12 of M 1 kg working fluid and the boosting process 1e of H kg working fluid are generally completed by a circulating pump, and the boosting process 74 of M 2 kg working fluid is generally completed by a compressor;
- the pressure-reducing expansion process of M 1 kilogram working fluid 35, the pressure-reducing expansion process of (M 1 +M 2 ) kilogram working fluid 56 and the pressure-reducing expansion process of (M 1 +H) kilogram working fluid 78 are generally performed by an expander
- the expansion work is greater than the boosting work consumption, the thermal conversion work is completed and the net cycle power is provided to the outside, forming a single working substance steam combined cycle.
- Working medium M 1 kg of working fluid condensate boost process 12, M 1 kg of working fluid endothermic heating, vaporization and overheating process 25, H kg of working fluid condensate boost process 1e, H kg of working fluid and (M 1 +M 2 ) Kilogram working fluid mixed endothermic heating, vaporization and overheating process e7, M 2 kg working fluid pressure rising process 73, M 2 kg working fluid endothermic heating process 34, M 2 kg working fluid pressure reducing expansion process 45, (M 1 +M 2 ) kg working fluid depressurization and expansion process 56, (M 1 +M 2 ) kg working fluid and H kg working fluid mixing exothermic cooling process 67, (M 1 +H) kg working fluid drop Pressure expansion process 78, (M 1 +H) kilogram working fluid exothermic condensation process 81-a total of 11 processes.
- 3Energy conversion process-the boosting process 12 of M 1 kg working fluid and the boosting process 1e of H kg working fluid are generally completed by a circulating pump, and the boosting process 73 of M 2 kg working fluid is generally completed by a compressor;
- the pressure-reducing expansion process of M 2 kilogram working fluid 45, the pressure-reducing expansion process of (M 1 +M 2 ) kilogram working fluid 56 and the pressure-reducing expansion process of (M 1 +H) kilogram working fluid 78 are generally performed by an expander
- the expansion work is greater than the boosting work consumption, the thermal conversion work is completed and the net cycle power is provided to the outside, forming a single working substance steam combined cycle.
- M 1 kg working medium condensed liquid refrigerant boosting process 12 M 1 kg refrigerant absorbs heat heating, vaporization and superheating process 23, M 1 kg refrigerant expansion process down 37, H refrigerant condensate liters kg Pressure process 1e, H kg working fluid mixed with M 2 kg working fluid and (M 1 +M 2 ) kg working fluid endothermic heating, vaporization and overheating process e8, M 2 kg working fluid boosting and heating process 84, M 2 kg Working fluid endothermic heating process 45, M 2 kg working fluid depressurization expansion process 56, M 2 kg working fluid mixed with H kg working fluid, exothermic cooling process 67, (M 1 +M 2 ) kg working fluid and H kg working fluid
- 3Energy conversion process-the boosting process 12 of M 1 kg working fluid and the boosting process 1e of H kg working fluid are generally completed by a circulating pump, and the boosting process 84 of M 2 kg working fluid is generally completed by a compressor;
- the depressurization process of M 1 kg of working fluid 37, the depressurization process of M 2 kg of working fluid 56, and the (M 1 +H) kg of working fluid depressurization expansion process 89 are generally completed by an expander; the expansion work is greater than
- the booster consumes power, completes the thermal transformation and provides external circulation net power, forming a single working substance steam combined cycle.
- M 1 kilogram working medium condensed liquid refrigerant boosting process 12 M 1 kilogram refrigerant absorbs heat heating, vaporization and superheating process 23, M 1 kilogram buck refrigerant expansion process 34, M 1 kilogram working fluid with H Kilogram working fluid mixing exothermic cooling process 47, H kilogram working fluid condensate pressure boosting process 1e, H kilogram working fluid and M 1 kilogram working fluid and (M 1 +M 2 ) kilogram working fluid mixing endothermic heating, vaporization and overheating Process e8, M 2 kg working fluid pressure rising process 85, M 2 kg working fluid endothermic heating process 56, M 2 kg working fluid depressurizing expansion process 67, (M 1 +M 2 ) kg working fluid and H kg working fluid
- 3Energy conversion process-the boosting process 12 of M 1 kg working fluid and the boosting process 1e of H kg working fluid are generally completed by a circulating pump, and the boosting process 85 of M 2 kg working fluid is generally completed by a compressor;
- the pressure-reducing expansion process of M 1 kg working fluid 34, the pressure-reducing expansion process of M 2 kg working fluid 67, and the pressure-reducing expansion process of (M 1 +H) kg working fluid 89 are generally completed by an expander;
- the work is greater than the power consumption of the booster, the thermal transformation is completed and the net power of the cycle is provided to the outside, forming a single working substance steam combined cycle.
- Working medium is carried out-M 1 kg of working fluid condensate boost process 12, M 1 kg of working fluid endothermic heating, vaporization and overheating process 23, H kg of working fluid condensate boost process 1e, H kg of working fluid and (M 1 +M 2 -X) kg working fluid and (M 1 +M 2 ) kg working fluid mixed endothermic heating, vaporization and overheating process e8, M 2 kg working fluid pressure rising and heating process 83, (M 1 +M 2 ) Kilogram working fluid endothermic heating process 34, X kilogram working fluid pressure drop expansion process 47, (M 1 +M 2 -X) kilogram working fluid endothermic heating process 45, (M 1 +M 2 -X) kilogram working fluid drop Compressive expansion process 56, (M 1 +M 2 -X) kg working fluid and H kg working fluid mixed exothermic cooling process 67, (M 1 +M 2 ) kg working fluid mixed with H kg working fluid exothermic cooling process 78 , (M 1 +H) kg working fluid depressurization expansion process 89
- 3Energy conversion process-the boosting process 12 of M 1 kg working fluid and the boosting process 1e of H kg working fluid are generally completed by a circulating pump, and the boosting process 83 of M 2 kg working fluid is generally completed by a compressor;
- the expansion work is greater than the boosting work consumption, the thermal conversion work is completed and the net work is provided to the outside, forming a single working substance steam combined cycle.
- the working medium is carried out-M 1 kg of working fluid condensate pressure increase process 12, M 1 kg of working fluid and M kg of working fluid mixed endothermic heating process 2b, (M 1 +M) kg of working fluid endothermic heating, vaporization and Superheating process b3, H kg working fluid condensate pressure boosting process 1e, H kg working fluid mixed with (M 1 +M) kg working fluid heat absorption, vaporization and overheating process e6, M 2 kg working fluid pressure boosting process 6a ,
- 3Energy conversion process-M 1 kg of working fluid boosting process 12 and H kg of working fluid boosting process 1e are generally completed by circulating pumps, M 2 kg of working fluid boosting process 6a and (M 2 -M)
- the pressure increase process a3 of the kilogram working fluid is generally completed by the compressor; the (M 1 +M 2 ) pressure reduction expansion process of the kilogram working fluid 45, and the (M 1 +H) kilogram working fluid pressure reduction and expansion process 67, generally It is completed by the expander; the expansion work is greater than the boosting work consumption, the thermal conversion work is completed and the net work is provided to the outside, forming a single working substance steam combined cycle.
- the working medium is carried out-M 1 kg of working fluid condensate pressure increase process 12, M 1 kg of working fluid and M kg of working fluid mixed endothermic heating process 2b, (M 1 +M) kg of working fluid endothermic heating, vaporization and Overheating process b3, (M 1 +M) kg working fluid depressurization and expansion process 35, H kg working fluid condensate pressure boosting process 1e, H kg working fluid and (M 1 +M 2 ) kg working fluid mixing endothermic heating, Vaporization and overheating process e7, M 2 kg working fluid pressure rising process 7a, M kg working fluid and M 1 kg working fluid mixed exothermic condensation process ab, (M 2 -M) kg working fluid pressure rising process a4, (M 2 -M) Kilogram working fluid endothermic heating process 45, (M 1 +M 2 ) Kilogram working fluid depressurization expansion process 56, (M 1 +M 2 ) Kilogram working fluid mixed with H kg working fluid to release heat and cooling Process 67, (M 1 +H) kg working
- 3Energy conversion process-M 1 kg of working fluid boosting process 12 and H kg of working fluid boosting process 1e are generally completed by a circulating pump, M 2 kg of working fluid boosting process 7a and (M 2 -M)
- the pressure increase process a4 of the kilogram working fluid is generally completed by the compressor; the (M 1 +M) pressure reduction expansion process of the kilogram working fluid 35, the (M 1 +M 2 ) pressure reduction expansion process of the kilogram working fluid 56, and
- the (M 1 +H) kilogram working fluid pressure-reducing expansion process 78 is generally completed by an expander; the expansion work is greater than the pressure boosting power consumption, completing the thermal conversion work and providing external circulation net power, forming a single working fluid steam combined cycle.
- Working medium M 1 kg of working fluid condensate boost process 12, M 1 kg of working fluid endothermic heating process 2b, (M 1 +M) kg of working fluid endothermic heating, vaporization and overheating process b5, H kg working fluid Process 1e of pressure increase of condensate, H kg of working fluid and (M 1 +M 2 ) kg of working fluid are mixed to endothermic heating, vaporization and overheating process e7, M 2 kg of working fluid is heated up process 7a, M kg of working fluid is combined with M 1 kg of working fluid’s mixed exothermic condensation process ab, (M 2 -M) kg of working fluid’s pressure rising process a3, (M 2 -M) kg of working fluid’s endothermic heating process 34, (M 2 -M) kg Working fluid depressurization expansion process 45, (M 1 +M 2 ) kg working fluid depressurization expansion process 56, (M 1 +M 2 ) kg working fluid and H kg working fluid mixing exothermic cooling process 67, (M 1 + H) The
- 3Energy conversion process-M 1 kg of working fluid boosting process 12 and H kg of working fluid boosting process 1e are generally completed by a circulating pump, M 2 kg of working fluid boosting process 7a and (M 2 -M)
- the pressure increase process a3 of the kilogram working fluid is generally completed by the compressor; (M 2 -M) the pressure-reducing expansion process of the kilogram working fluid 45, (M 1 +M 2 ) the pressure-reducing expansion process of the kilogram working fluid 56, and
- the (M 1 +H) kilogram working fluid pressure-reducing expansion process 78 is generally completed by an expander; the expansion work is greater than the pressure boosting power consumption, completing the thermal conversion work and providing external circulation net power, forming a single working fluid steam combined cycle.
- Working medium M 1 kg of working fluid condensate boost process 12, M 1 kg of working fluid endothermic heating process 2b, (M 1 +M) kg of working fluid endothermic heating, vaporization and overheating process b3, (M 1 +M)Kg working fluid depressurization expansion process 37, H kg working fluid condensate pressure boosting process 1e, H kg working fluid mixed with (M 1 +M) kg working fluid and (M 1 +M 2 ) kg working fluid Thermal heating, vaporization and overheating process e8, M 2 kg working fluid pressure rising process 8a, M kg working fluid and M 1 kg working fluid mixed exothermic condensation process ab, (M 2 -M) kg working fluid pressure rising and heating process Process a4, (M 2 -M) kg working fluid endothermic and heating process 45, (M 2 -M) kg working fluid depressurization expansion process 56, (M 2 -M) kg working fluid and H kg working fluid mixed and exothermic Cooling process 67, (M 1 +M 2 ) kg working fluid and H kg working
- 3Energy conversion process-the boosting process of M 1 kg of working fluid 12 and the boosting process of H kg of working fluid 1e are generally completed by a circulating pump, and the boosting process of M 2 kg of working fluid 8a and (M 2 -M)
- the pressure increase process a4 of kilogram working fluid is generally completed by the compressor; (M 1 +M) pressure reduction process of kilogram working fluid 37, (M 2 -M) pressure reduction process of kilogram working fluid 56, and (M 1 +H)
- the pressure-reducing expansion process of kilogram working fluid 89 is generally completed by the expander; the expansion work is greater than the pressure-boosting work, which completes the thermal conversion work and provides external net power to form a single working fluid steam combined cycle.
- Working medium M 1 kg of working fluid condensate boost process 12, M 1 kg of working fluid endothermic heating process 2b, (M 1 +M) kg of working fluid endothermic heating, vaporization and overheating process b3, (M 1 +M)Kg working fluid depressurization expansion process 34, (M 1 +M)Kg working fluid mixed with Hkg working fluid exothermic cooling process 47, Hkg working fluid condensate boosting process 1e, Hkg working fluid and ( M 1 +M) kilogram of working fluid and (M 1 +M 2 ) kilogram of working fluid mixed endothermic heating, vaporization and overheating process e8, M 2 kilogram of working fluid boosting and heating process 8a, M kilogram of working fluid and M 1 kilogram of working fluid Mixing exothermic condensation process ab, (M 2 -M) kg working fluid pressure increasing process a5, (M 2 -M) kg working fluid endothermic heating process 56, (M 2 -M) kg working fluid pressure reduction Expansion process 67, (M 1 +M 2 ) kg working fluid and
- 3Energy conversion process-the boosting process of M 1 kg of working fluid 12 and the boosting process of H kg of working fluid 1e are generally completed by a circulating pump, and the boosting process of M 2 kg of working fluid 8a and (M 2 -M)
- the pressure increase process a5 of the kilogram working fluid is generally completed by the compressor; the pressure reduction process of (M 1 +M) kilogram working fluid 34, the pressure reduction process of (M 2 -M) kilogram working fluid 67, and (M 1 +H)
- the pressure-reducing expansion process of kilogram working fluid 89 is generally completed by the expander; the expansion work is greater than the pressure-boosting work, which completes the thermal conversion work and provides external net power to form a single working fluid steam combined cycle.
- Working medium M 1 kg of working fluid condensate boost process 12, M 1 kg of working fluid endothermic heating process 2b, (M 1 +M) kg of working fluid endothermic heating, vaporization and overheating process b3, H kg working fluid
- the process of pressure increase of condensate 1e, H kg of working fluid and (M 1 +M 2 -X) kg of working fluid and (M 1 +M 2 ) of (M 1 +M 2 ) kg of working fluid are mixed to endothermic heating, vaporization and overheating process e8, M 2 kg Working fluid pressure increasing process 8a, the mixing exothermic condensation process of M kilogram working fluid and M 1 kilogram working fluid ab, (M 2 -M) kilogram working fluid pressure increasing process a3, (M 1 +M 2 ) kilogram working fluid Endothermic heating process 34, X kg working fluid depressurization expansion process 47, (M 1 +M 2 -X) kg working fluid endothermic heating process 45, (M 1 +M 2 -X) kg working fluid depressurization expansion Process 56,
- 3Energy conversion process-the boosting process of M 1 kg of working fluid 12 and the boosting process of H kg of working fluid 1e are generally completed by a circulating pump, and the boosting process of M 2 kg of working fluid 8a and (M 2 -M)
- the pressure increase process a3 of kilogram working fluid is generally completed by the compressor; the pressure reduction process of X kilogram working fluid 47, the pressure reduction process of (M 1 +M 2 -X) kilogram working fluid 56, and the (M 1 +H )
- the pressure-reducing expansion process of the kilogram working fluid 89 is generally completed by the expander; the expansion work is greater than the pressure-boosting power consumption, completing the thermal conversion work and providing external net power for the cycle, forming a single working fluid steam combined cycle.
- a single working fluid is conducive to production and storage; reduces operating costs and improves the flexibility of cycle adjustment
- the circulating medium and the heat source medium are the same gas, and the absorbing link of the circulating working fluid from the heat source is beneficial to reduce temperature difference heat transfer loss and improve thermal efficiency.
- the low-pressure and high-temperature operation mode is adopted in the high-temperature zone to solve the difficult to reconcile contradictions between thermal efficiency, circulating medium parameters and pipe pressure and temperature resistance in traditional steam power plants.
- low-pressure operation can be selected to provide theoretical support for improving the safety of device operation.
- the working fluid has a wide application range, can well adapt to the energy supply demand, and the working fluid and working parameters are matched flexibly.
- thermodynamic cycle range for realizing the utilization of temperature difference is expanded, which is beneficial to better realize the high-efficiency power utilization of high-temperature heat source and variable-temperature heat source.
Landscapes
- Engineering & Computer Science (AREA)
- Chemical & Material Sciences (AREA)
- Combustion & Propulsion (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Engine Equipment That Uses Special Cycles (AREA)
Abstract
Single working medium steam combined circulation, referring to a working medium composed of M1 kilograms, M2 kilograms, and H kilograms, and a closed process composed of ten processes implemented separately or collectively: an M1 kilograms working medium pressure boosting process 12, an M1 kilograms working medium endothermic vaporisation process 23, a H kilograms working medium pressure boosting process 1e, a H kilograms working medium and (M1+M2) kilograms working medium mixed endothermic process e6, an M2kilograms working medium pressure boosting process 63, an (M1+M2) kilograms working medium endothermic process 34, an (M1+M2) kilograms working medium pressure reduction process 45, an (M1+M2) kilograms working medium and H kilograms working medium mixed exothermic process 56, an (M1+H) kilograms working medium pressure reduction process 67, and an (M1+H) kilograms working medium exothermic condensation process 71.
Description
本发明属于能源与动力技术领域。The invention belongs to the field of energy and power technology.
冷需求、热需求和动力需求,为人类生活与生产当中所常见;其中,利用热能转换为机械能是获得和提供动力的重要方式。一般情况下,热源的温度随着热的释放而降低,热源是变温的;在以化石燃料为源头能源时,热源同时具有高温和变温的双重特点,这使得采用单一热力循环理论实现制冷、供热或转化为动时能源利用率不理想。Cold demand, heat demand and power demand are common in human life and production; among them, the conversion of heat energy into mechanical energy is an important way to obtain and provide power. Under normal circumstances, the temperature of the heat source decreases with the release of heat, and the heat source changes temperature; when fossil fuels are used as the source energy, the heat source has the dual characteristics of high temperature and variable temperature at the same time, which makes the use of a single thermal cycle theory to achieve cooling and supply The energy efficiency is not ideal when the heat is converted into motion.
以外燃式蒸汽动力装置为例,其热源属于高温且为变温热源;当以朗肯循环为理论基础,采用水蒸气为循环工质实现热变功时,由于受到材料耐温耐压性能和安全性方面的限制,无论采用何种参数运行,循环工质与热源之间都存在较大的温差损失,不可逆损失大,导致热效率较低。Take the external combustion steam power plant as an example, the heat source is high temperature and variable temperature heat source; when the Rankine cycle is used as the theoretical basis, water vapor is used as the circulating working fluid to achieve thermal variable work, due to the temperature and pressure resistance of the material And safety restrictions, no matter what parameters are used for operation, there is a large temperature difference between the circulating working fluid and the heat source, and the irreversible loss is large, resulting in low thermal efficiency.
人们需要简单、主动、高效地利用燃料生成或其它的高温热能来实现制冷、供热或转化为动力,这需要热科学基础理论的支撑;在热科学基础理论体系中,热力循环是热能利用装置的理论基础和能源利用系统的核心;热力循环的创建及发展应用将对能源利用的飞跃起到重大作用,将积极推动社会进步和生产力发展。People need simple, active and efficient use of fuel generation or other high-temperature heat energy to achieve cooling, heating or conversion into power, which requires the support of the basic theory of thermal science; in the basic theoretical system of thermal science, the thermal cycle is a heat energy utilization device The theoretical foundation and the core of the energy utilization system; the creation, development and application of thermal cycles will play a major role in the leap of energy utilization and will actively promote social progress and productivity development.
从简单、主动和高效地实现温差利用的原则出发,针对高温热源或变温热源的动力应用,力求为热动系统的简单化和高效化提供理论支撑,本发明提出了单工质蒸汽联合循环。。Starting from the principle of simple, active and efficient utilization of temperature difference, aiming at the power application of high-temperature heat source or variable-temperature heat source, and striving to provide theoretical support for the simplification and high efficiency of the thermodynamic system, the present invention proposes a single working substance steam combination cycle. .
发明内容:Summary of the invention:
本发明主要目的是要提供单工质蒸汽联合循环,具体发明内容分项阐述如下:The main purpose of the present invention is to provide a single working fluid steam combined cycle, and the specific content of the invention is described as follows:
1.单工质蒸汽联合循环,是指由M
1千克、M
2千克和H千克组成的工质,分别或共同进行的十个过程——M
1千克工质升压过程12,M
1千克工质吸热汽化过程23,H千克工质升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热过程e6,M
2千克工质升压过程63,(M
1+M
2)千克工质吸热过程34,(M
1+M
2)千克工质降压过程45,(M
1+M
2)千克工质与H千克工质混和放热过程56,(M
1+H)千克工质降压过程67,(M
1+H)千克工质放热冷凝过程71——组成的闭合过程。
1. Single working fluid steam combined cycle refers to the working fluid composed of M 1 kg, M 2 kg and H kg, and ten processes carried out separately or jointly-M 1 kg working fluid boost process 12, M 1 kg Working fluid endothermic vaporization process 23, H kg working fluid boosting process 1e, H kg working fluid and (M 1 +M 2 ) kg working fluid mixed endothermic process e6, M 2 kg working fluid boosting process 63, (M 1 +M 2 )Kg working fluid endothermic process 34, (M 1 +M 2 )Kg working fluid pressure reduction process 45, (M 1 +M 2 )Kg working fluid mixed with H kg working fluid and exothermic process 56, ( M 1 +H) kilogram working fluid depressurization process 67, (M 1 +H) kilogram working fluid exothermic condensation process 71-a closed process of composition.
2.单工质蒸汽联合循环,是指由M
1千克、M
2千克和H千克组成的工质,分别或共同进行的十一个过程——M
1千克工质升压过程12,M
1千克工质吸热汽化过程23,M
1千克工质降压过程35,H千克工质升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热过程e7,M
2千克工质升压过程74,M
2千克工质吸热过程45,(M
1+M
2)千克工质降压过程56,(M
1+M
2)千克工质与H千克工质混和放热过程67,(M
1+H)千克工质降压过程78,(M
1+H)千克工质放热冷凝过程81——组成的闭合过程。
2. Single working fluid steam combined cycle refers to eleven processes composed of M 1 kilogram, M 2 kilogram and H kilogram, respectively or jointly-M 1 kilogram working medium boost process 12, M 1 Kilogram working fluid endothermic vaporization process 23, M 1 kilogram working fluid depressurization process 35, H kilogram working fluid boosting process 1e, H kilogram working fluid and (M 1 +M 2 ) kg working fluid mixed endothermic process e7, M 2 kg working fluid boost process 74, M 2 kg working fluid endothermic process 45, (M 1 +M 2 ) kg working fluid depressurization process 56, (M 1 +M 2 ) kg working fluid mixed with H kg working fluid The exothermic process 67, the (M 1 +H) kg working fluid depressurization process 78, the (M 1 +H) kg working fluid exothermic condensation process 81-a closed process of composition.
3.单工质蒸汽联合循环,是指由M
1千克、M
2千克和H千克组成的工质,分别或共同进行的十一个过程——M
1千克工质升压过程12,M
1千克工质吸热汽化过程25,H千克工质升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热过程e7,M
2千克工质升压过程73,M
2千克工质吸热过程34,M
2千克工质降压过程45,(M
1+M
2)千克工质降压过 程56,(M
1+M
2)千克工质与H千克工质混合放热过程67,(M
1+H)千克工质降压过程78,(M
1+H)千克工质放热冷凝过程81——组成的闭合过程。
3. Single working fluid steam combined cycle refers to the working fluids composed of M 1 kg, M 2 kg and H kg, which are carried out separately or jointly in eleven processes-M 1 kg working fluid boost process 12, M 1 Kilogram working fluid endothermic vaporization process 25, H kilogram working fluid boosting process 1e, H kilogram working fluid and (M 1 +M 2 ) kg working fluid mixed endothermic process e7, M 2 kg working fluid boosting process 73, M 2 kg working fluid endothermic process 34, M 2 kg working fluid pressure reduction process 45, (M 1 +M 2 ) kg working fluid pressure reduction process 56, (M 1 +M 2 ) kg working fluid mixed with H kg working fluid The exothermic process 67, the (M 1 +H) kg working fluid depressurization process 78, the (M 1 +H) kg working fluid exothermic condensation process 81-a closed process of composition.
4.单工质蒸汽联合循环,是指由M
1千克、M
2千克和H千克组成的工质,分别或共同进行的十二个过程——M
1千克工质升压过程12,M
1千克工质吸热汽化过程23,M
1千克工质降压过程37,H千克升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热过程e8,M
2千克工质升压过程84,M
2千克工质吸热过程45,M
2千克工质降压过程56,M
2千克工质与H千克工质混合放热过程67,(M
1+M
2)千克工质与H千克工质混合放热过程78,(M
1+H)千克工质降压过程89,(M
1+H)千克工质放热冷凝过程91——组成的闭合过程。
4. Single working fluid steam combined cycle refers to the working fluid consisting of M 1 kg, M 2 kg and H kg, and twelve processes carried out separately or jointly-M 1 kg working fluid boosting process 12, M 1 Kilogram working fluid endothermic vaporization process 23, M 1 kilogram working fluid pressure reduction process 37, H kilogram pressure boosting process 1e, H kilogram working fluid and (M 1 + M 2 ) kilogram working fluid mixed endothermic process e8, M 2 kg Working fluid pressure increase process 84, M 2 kg working fluid endothermic process 45, M 2 kg working fluid depressurization process 56, M 2 kg working fluid and H kg working fluid mixed exothermic process 67, (M 1 +M 2 ) Kilogram working fluid and H kilogram working fluid mixing exothermic process 78, (M 1 +H) kilogram working fluid depressurization process 89, (M 1 +H) kilogram working fluid exothermic condensation process 91—composition closed process.
5.单工质蒸汽联合循环,是指由M
1千克、M
2千克和H千克组成的工质,分别或共同进行的十二个过程——M
1千克工质升压过程12,M
1千克工质吸热汽化过程23,M
1千克工质降压过程34,M
1千克工质与H千克工质混合放热过程47,H千克工质升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热过程e8,M
2千克工质升压过程85,M
2千克工质吸热过程56,M
2千克工质降压过程67,(M
1+M
2)千克工质与H千克工质混合放热过程78,(M
1+H)千克工质降压过程89,(M
1+H)千克工质放热冷凝过程91——组成的闭合过程。
5. Single working fluid steam combined cycle refers to the working fluid consisting of M 1 kg, M 2 kg and H kg, and twelve processes carried out separately or jointly-M 1 kg working fluid boosting process 12, M 1 Kilogram working fluid endothermic vaporization process 23, M 1 kilogram working fluid depressurization process 34, M 1 kilogram working fluid and H kilogram working fluid mixed exothermic process 47, H kilogram working fluid boosting process 1e, H kilogram working fluid and ( M 1 +M 2 ) kg working fluid mixed endothermic process e8, M 2 kg working fluid pressure increase process 85, M 2 kg working fluid heat absorption process 56, M 2 kg working fluid pressure reduction process 67, (M 1 +M 2 ) Kilogram working fluid and H kilogram working fluid mixing exothermic process 78, (M 1 +H) kilogram working fluid depressurization process 89, (M 1 +H) kilogram working fluid exothermic condensation process 91—composition closed process .
6.单工质蒸汽联合循环,是指由M
1千克、M
2千克和H千克组成的工质,分别或共同进行的十三个过程——M
1千克工质升压过程12,M
1千克工质吸热汽化过程23,H千克工质升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热过程e8,M
2千克工质升压过程83,(M
1+M
2)千克工质吸热过程34,X千克工质降压过程47,(M
1+M
2-X)千克工质吸热过程45,(M
1+M
2-X)千克工质降压过程56,(M
1+M
2-X)千克工质与H千克工质混合放热过程67,(M
1+M
2)千克工质与H千克工质混合放热过程78,(M
1+H)千克工质降压过程89,(M
1+H)千克工质放热冷凝过程91——组成的闭合过程。
6. Single working fluid steam combined cycle refers to 13 processes that are composed of M 1 kg, M 2 kg and H kg, respectively or jointly-M 1 kg working fluid boost process 12, M 1 Kilogram working fluid endothermic vaporization process 23, H kilogram working fluid boosting process 1e, H kilogram working fluid and (M 1 + M 2 ) kg working fluid mixed endothermic process e8, M 2 kilogram working fluid boosting process 83, ( M 1 +M 2 ) Kilogram working fluid endothermic process 34, X kilogram working fluid pressure reduction process 47, (M 1 +M 2 -X) kg working fluid heat absorption process 45, (M 1 +M 2 -X) kg Working fluid depressurization process 56, (M 1 +M 2 -X) kg working fluid and H kg working fluid mixing exothermic process 67, (M 1 +M 2 ) kg working fluid and H kg working fluid mixing exothermic process 78 , (M 1 +H) kg working fluid pressure reduction process 89, (M 1 +H) kg working fluid exothermic condensation process 91-a closed process of composition.
7.单工质蒸汽联合循环,是指由M
1千克、M
2千克和H千克组成的工质,分别或共同进行的十三个过程——M
1千克工质升压过程12,M
1千克工质吸热过程2b,(M
1+M)千克工质吸热汽化过程b3,H千克工质升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热过程e6,M
2千克工质升压过程6a,M千克工质放热冷凝过程ab,(M
2-M)千克工质升压过程a3,(M
1+M
2)千克工质吸热过程34,(M
1+M
2)千克工质降压过程45,(M
1+M
2)千克工质与H千克工质混合放热过程56,(M
1+H)千克工质降压过程67,(M
1+H)千克工质放热冷凝过程71——组成的闭合过程。
7. Single working fluid steam combined cycle refers to 13 processes that are composed of M 1 kg, M 2 kg and H kg, respectively or jointly-M 1 kg working fluid boost process 12, M 1 Kilogram working fluid endothermic process 2b, (M 1 +M) kilogram working fluid endothermic vaporization process b3, H kilogram working fluid boost process 1e, H kilogram working fluid and (M 1 +M 2 ) kilogram working fluid endothermic Process e6, M 2 kg working fluid boost process 6a, M kg working fluid exothermic condensation process ab, (M 2 -M) kg working fluid boosting process a3, (M 1 +M 2 ) kg working fluid endothermic process 34, (M 1 +M 2 ) kg working fluid depressurization process 45, (M 1 +M 2 ) kg working fluid and H kg working fluid mixed exothermic process 56, (M 1 +H) kg working fluid depressurization process 67, (M 1 +H) Kilogram of working fluid exothermic condensation process 71-a closed process of composition.
8.单工质蒸汽联合循环,是指由M
1千克、M
2千克和H千克组成的工质,分别或共同进行的十四个过程——M
1千克工质升压过程12,M
1千克工质吸热过程2b,(M
1+M)千克工质吸热汽化过程b3,(M
1+M)千克工质降压过程35,H千克工质升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热过程e7,M
2千克工质升压过程7a,M千克工质放热冷凝过程ab,(M
2-M)千克工质升压过程a4,(M
2-M)千克工质吸热过程45,(M
1+M
2)千克工质降压过程56,(M
1+M
2)千克工质与H千克工质混合放热过程67,(M
1+H)千克工质降压过程78,(M
1+H)千克工质放热冷凝过程81——组成的闭合过程。
8. Single working fluid steam combined cycle refers to the working fluid consisting of M 1 kg, M 2 kg and H kg, and 14 processes carried out separately or together-M 1 kg working fluid boost process 12, M 1 Kilogram working fluid endothermic process 2b, (M 1 +M) kilogram working fluid endothermic vaporization process b3, (M 1 +M) kilogram working fluid pressure reduction process 35, H kilogram working fluid pressure increase process 1e, H kilogram working fluid Mixed with (M 1 +M 2 ) kg working fluid endothermic process e7, M 2 kg working fluid boosting process 7a, M kg working fluid exothermic condensation process ab, (M 2 -M) kg working fluid boosting process a4 , (M 2 -M) kg working fluid endothermic process 45, (M 1 +M 2 ) kg working fluid depressurization process 56, (M 1 +M 2 ) kg working fluid and H kg working fluid mixing exothermic process 67 , (M 1 +H) kg working fluid pressure reduction process 78, (M 1 +H) kg working fluid exothermic condensation process 81-a closed process of composition.
9.单工质蒸汽联合循环,是指由M
1千克、M
2千克和H千克组成的工质,分别或共同 进行的十四个过程——M
1千克工质升压过程12,M
1千克工质吸热过程2b,(M
1+M)千克工质吸热汽化过程b5,H千克工质升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热过程e7,M
2千克工质升压过程7a,M千克工质放热冷凝过程ab,(M
2-M)千克工质升压过程a3,(M
2-M)千克工质吸热过程34,(M
2-M)千克工质降压过程45,(M
1+M
2)千克工质降压过程56,(M
1+M
2)千克工质与H千克工质混合放热过程67,(M
1+H)千克工质降压过程78,(M
1+H)千克工质放热冷凝过程81——组成的闭合过程。
9. Single working fluid steam combined cycle refers to the working fluid composed of M 1 kg, M 2 kg and H kg, and 14 processes carried out separately or together-M 1 kg working fluid boost process 12, M 1 Kilogram working fluid endothermic process 2b, (M 1 +M) kilogram working fluid endothermic vaporization process b5, H kilogram working fluid boosting process 1e, H kilogram working fluid and (M 1 +M 2 ) kilogram working fluid endothermic Process e7, M 2 kg working fluid boosting process 7a, M kg working fluid exothermic condensation process ab, (M 2 -M) kg working fluid boosting process a3, (M 2 -M) kg working fluid endothermic process 34 , (M 2 -M) kg working fluid depressurization process 45, (M 1 +M 2 ) kg working fluid depressurization process 56, (M 1 +M 2 ) kg working fluid and H kg working fluid mixed exothermic process 67 , (M 1 +H) kg working fluid pressure reduction process 78, (M 1 +H) kg working fluid exothermic condensation process 81-a closed process of composition.
10.单工质蒸汽联合循环,是指由M
1千克、M
2千克和H千克组成的工质,分别或共同进行的十五个过程——M
1千克工质升压过程12,M
1千克工质吸热过程2b,(M
1+M)千克工质吸热汽化过程b3,(M
1+M)千克工质降压过程37,H千克工质升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热过程e8,M
2千克工质升压过程8a,M千克工质放热冷凝过程ab,(M
2-M)千克工质升压过程a4,(M
2-M)千克工质吸热过程45,(M
2-M)千克工质降压过程56,(M
2-M)千克工质与H千克工质混合放热过程67,(M
1+M
2)千克工质与H千克工质混合放热过程78,(M
1+H)千克工质降压过程89,(M
1+H)千克工质放热冷凝过程91——组成的闭合过程。
10. The single working fluid steam combined cycle refers to the working fluids composed of M 1 kg, M 2 kg and H kg, and fifteen processes carried out separately or jointly-M 1 kg working fluid boosting process 12, M 1 Kilogram working fluid endothermic process 2b, (M 1 +M) kilogram working fluid endothermic vaporization process b3, (M 1 +M) kilogram working fluid depressurization process 37, H kilogram working fluid boosting process 1e, H kg working fluid Mixing with (M 1 +M 2 ) kg of working fluid endothermic process e8, M 2 kg of working fluid boosting process 8a, M kg of working fluid exothermic condensation process ab, (M 2 -M) kg working fluid boosting process a4 , (M 2 -M) kg working fluid endothermic process 45, (M 2 -M) kg working fluid depressurization process 56, (M 2 -M) kg working fluid and H kg working fluid mixing exothermic process 67, ( M 1 +M 2 ) Kilogram working fluid and H kilogram working fluid mixing exothermic process 78, (M 1 +H) Kilogram working fluid pressure reduction process 89, (M 1 +H) Kilogram working fluid exothermic condensation process 91—— The closed process of composition.
11.单工质蒸汽联合循环,是指由M
1千克、M
2千克和H千克组成的工质,分别或共同进行的十五个过程——M
1千克工质升压过程12,M
1千克工质吸热过程2b,(M
1+M)千克工质吸热汽化过程b3,(M
1+M)千克工质降压过程34,(M
1+M)千克工质与H千克工质混合放热过程47,H千克工质升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热过程e8,M
2千克工质升压过程8a,M千克工质放热冷凝过程ab,(M
2-M)千克工质升压过程a5,(M
2-M)千克工质吸热过程56,(M
2-M)千克工质降压过程67,(M
1+M
2)千克工质与H千克工质混合放热过程78,(M
1+H)千克工质降压过程89,(M
1+H)千克工质放热冷凝过程91——组成的闭合过程。
11. Single working fluid steam combined cycle refers to the working fluids composed of M 1 kg, M 2 kg and H kg, which are carried out separately or jointly in fifteen processes-M 1 kg working fluid boosting process 12, M 1 Kilogram working fluid endothermic process 2b, (M 1 +M) kilogram working fluid endothermic vaporization process b3, (M 1 +M) kilogram working fluid pressure reduction process 34, (M 1 +M) kilogram working fluid and H kilogram working fluid Exothermic process 47 of H kg working fluid, 1e of H kg working fluid, heat absorption process of H kg working fluid and (M 1 + M 2 ) kg working fluid e8, M 2 kg working fluid boosting process 8a, M kg working fluid Exothermic and condensation process ab of (M 2 -M) kilogram of working fluid pressure increase process a5, (M 2 -M) kilogram of working fluid endothermic process 56, (M 2 -M) kilogram working fluid depressurization process 67, ( M 1 +M 2 ) Kilogram working fluid and H kilogram working fluid mixing exothermic process 78, (M 1 +H) Kilogram working fluid pressure reduction process 89, (M 1 +H) Kilogram working fluid exothermic condensation process 91—— The closed process of composition.
12.单工质蒸汽联合循环,是指由M
1千克、M
2千克和H千克组成的工质,分别或共同进行的十六个过程——M
1千克工质升压过程12,M
1千克工质吸热过程2b,(M
1+M)千克工质吸热汽化过程b3,H千克工质升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热过程e8,M
2千克工质升压过程8a,M千克工质放热冷凝过程ab,(M
2-M)千克工质升压过程a3,(M
1+M
2)千克工质吸热过程34,X千克工质降压过程47,(M
1+M
2-X)千克工质吸热过程45,(M
1+M
2-X)千克工质降压过程56,(M
1+M
2-X)千克工质与H千克工质混合放热过程67,(M
1+M
2)千克工质与H千克工质混合放热过程78,(M
1+H)千克工质降压过程89,(M
1+H)千克工质放热冷凝过程91——组成的闭合过程。
12. The single working fluid steam combined cycle refers to the working fluid composed of M 1 kg, M 2 kg and H kg, and 16 processes carried out separately or jointly-M 1 kg working fluid boost process 12, M 1 Kilogram working fluid endothermic process 2b, (M 1 +M) kilogram working fluid endothermic vaporization process b3, H kilogram working fluid boost process 1e, H kilogram working fluid and (M 1 +M 2 ) kilogram working fluid endothermic Process e8, M 2 kg working fluid boost process 8a, M kg working fluid exothermic condensation process ab, (M 2 -M) kg working fluid boosting process a3, (M 1 +M 2 ) kg working fluid endothermic process 34, X kilogram working fluid pressure reduction process 47, (M 1 +M 2 -X) kilogram working fluid endothermic process 45, (M 1 +M 2 -X) kilogram working fluid pressure reduction process 56, (M 1 +M 2 -X) The exothermic process of mixing kilograms of working fluid and H kilograms of working fluid 67, (M 1 +M 2 ) the exothermic process of mixing kilograms of working fluid and H kilograms of working fluid 78, and the pressure reduction of (M 1 +H) kg of working fluid Process 89, (M 1 +H) kilogram working fluid exothermic condensation process 91-a closed process of composition.
图1/12是依据本发明所提供的单工质蒸汽联合循环第1种原则性流程示例图。Figure 1/12 is an example diagram of the first principle flow chart of the single working fluid steam combined cycle provided by the present invention.
图2/12是依据本发明所提供的单工质蒸汽联合循环第2种原则性流程示例图。Figure 2/12 is an example diagram of the second principle flow chart of the single working fluid steam combined cycle provided by the present invention.
图3/12是依据本发明所提供的单工质蒸汽联合循环第3种原则性流程示例图。Figure 3/12 is an example diagram of the third principle flow chart of the single working fluid steam combined cycle provided by the present invention.
图4/12是依据本发明所提供的单工质蒸汽联合循环第4种原则性流程示例图。Figure 4/12 is an example diagram of the fourth principle flow chart of the single working fluid steam combined cycle provided by the present invention.
图5/12是依据本发明所提供的单工质蒸汽联合循环第5种原则性流程示例图。Figure 5/12 is an example diagram of the fifth principle flow chart of the single working fluid steam combined cycle provided by the present invention.
图6/12是依据本发明所提供的单工质蒸汽联合循环第6种原则性流程示例图。Figure 6/12 is an example diagram of the sixth principle flow chart of the single working fluid steam combined cycle provided by the present invention.
图7/12是依据本发明所提供的单工质蒸汽联合循环第7种原则性流程示例图。Figure 7/12 is an example diagram of the seventh principle flow chart of the single working fluid steam combined cycle provided by the present invention.
图8/12是依据本发明所提供的单工质蒸汽联合循环第8种原则性流程示例图。Figure 8/12 is an example diagram of the eighth principle flow chart of the single working fluid steam combined cycle provided by the present invention.
图9/12是依据本发明所提供的单工质蒸汽联合循环第9种原则性流程示例图。Figure 9/12 is an example diagram of the ninth principle flow chart of the single working fluid steam combined cycle provided by the present invention.
图10/12是依据本发明所提供的单工质蒸汽联合循环第10种原则性流程示例图。Figure 10/12 is an example diagram of the tenth principle flow chart of the single working fluid steam combined cycle provided by the present invention.
图11/12是依据本发明所提供的单工质蒸汽联合循环第11种原则性流程示例图。Figure 11/12 is an example diagram of the eleventh principle flow chart of the single working fluid steam combined cycle provided by the present invention.
图12/12是依据本发明所提供的单工质蒸汽联合循环第12种原则性流程示例图。Figure 12/12 is an example diagram of the twelfth principle flow chart of the single working fluid steam combined cycle provided by the present invention.
首先要说明的是,在结构和流程的表述上,非必要情况下不重复进行;对显而易见的流程不作表述。下面结合附图和实例来详细描述本发明。The first thing to note is that in the expression of the structure and process, it is not repeated unless necessary; the obvious process is not described. The present invention will be described in detail below with reference to the drawings and examples.
图1/12所示T-s图中的单工质蒸汽联合循环示例是这样进行的:The example of the single working fluid steam combined cycle in the T-s diagram shown in Figure 1/12 is performed as follows:
(1)从循环过程上看:(1) From the perspective of the cycle process:
工作介质进行——M
1千克工质冷凝液升压过程12,M
1千克工质吸热升温、汽化和过热过程23,H千克工质冷凝液升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热升温、汽化和过热过程e6,M
2千克工质升压升温过程63,(M
1+M
2)千克工质吸热升温过程34,(M
1+M
2)千克工质降压膨胀过程45,(M
1+M
2)千克工质与H千克工质混和放热降温过程56,(M
1+H)千克工质降压膨胀过程67,(M
1+H)千克工质放热冷凝过程71——共10个过程。
Working medium is carried out-M 1 kg of working fluid condensate boost process 12, M 1 kg of working fluid endothermic heating, vaporization and overheating process 23, H kg of working fluid condensate boost process 1e, H kg of working fluid and (M 1 +M 2 ) Kilogram working fluid mixed endothermic heating, vaporization and overheating process e6, M 2 kg working fluid pressure rising process 63, (M 1 +M 2 ) kg working fluid endothermic heating process 34, (M 1 + M 2 )Kg working fluid depressurization expansion process 45, (M 1 +M 2 )Kg working fluid mixed with H kg working fluid exothermic cooling process56, (M 1 +H)Kg working fluid depressurization expansion process 67,( M 1 +H) Kilogram working fluid exothermic condensation process 71-10 processes in total.
(2)从能量转换上看:(2) From the perspective of energy conversion:
①吸热过程——M
1千克工质进行23过程和(M
1+M
2)千克工质进行34过程需要的热负荷由外部热源来提供。
① endothermic process --M 1 kg for 23 processes and refrigerant (M 1 + M 2) hot working medium kg load process requires 34 is provided by an external heat source.
②放热过程——(M
1+M
2)千克工质以混合方式放热于H千克工质,降温至6点,完成56过程;(M
1+H)千克工质进行71过程的放热,一般向低温热源释放,热动联供时向热用户提供。
②Exothermic process-(M 1 +M 2 ) kilogram of working fluid releases heat to H kilogram of working fluid in a mixed manner, and the temperature is reduced to 6 points to complete the 56 process; (M 1 +H) kilogram of working fluid performs 71 process Heat is generally released to a low-temperature heat source, and provided to heat users in the case of combined heat and power supply.
③能量转换过程——M
1千克工质的升压过程12和H千克工质的升压过程1e一般由循环泵来完成,M
2千克工质的升压过程63一般由压缩机来完成;(M
1+M
2)千克工质的降压膨胀过程45和(M
1+H)千克工质降压膨胀过程67,一般由膨胀机来完成;膨胀作功大于升压耗功,完成热变功并对外提供循环净功,形成单工质蒸汽联合循环。
③Energy conversion process-the boosting process 12 of M 1 kg working fluid and the boosting process 1e of H kg working fluid are generally completed by a circulating pump, and the boosting process 63 of M 2 kg working fluid is generally completed by a compressor; The pressure-reducing expansion process of (M 1 +M 2 ) kg of working fluid 45 and the pressure-reducing expansion process of (M 1 +H) kilogram of working fluid 67 are generally completed by the expander; the expansion work is greater than the pressure boosting work, and the heat is completed Variable power and external cycle net power is provided to form a single working substance steam combined cycle.
图2/12所示T-s图中的单工质蒸汽联合循环示例是这样进行的:The example of the single working fluid steam combined cycle in the T-s diagram shown in Figure 2/12 is performed like this:
(1)从循环过程上看:(1) From the perspective of the cycle process:
工作介质进行——M
1千克工质冷凝液升压过程12,M
1千克工质吸热升温、汽化和过热过程23,M
1千克工质降压膨胀过程35,H千克工质冷凝液升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热升温、汽化和过热过程e7,M
2千克工质升压升温过程74,M
2千克工质吸热升温过程45,(M
1+M
2)千克工质降压膨胀过程56,(M
1+M
2)千克工质与H千克工质混和放热降温过程67,(M
1+H)千克工质降压膨胀过程78,(M
1+H)千克工质放热冷凝过程81——共11个过程。
--M 1 kg working medium condensed liquid refrigerant boosting process 12, M 1 kg refrigerant absorbs heat heating, vaporization and superheating process 23, M 1 kg refrigerant expansion process down 35, H refrigerant condensate liters kg Pressure process 1e, H kg working fluid mixed with (M 1 +M 2 ) kg working fluid endothermic heating, vaporization and overheating process e7, M 2 kg working fluid pressure rising process 74, M 2 kg working fluid endothermic heating process 45, (M 1 +M 2 ) kg working fluid depressurization and expansion process 56, (M 1 +M 2 ) kg working fluid and H kg working fluid mixed exothermic cooling process 67, (M 1 +H) kg working fluid drop Pressure expansion process 78, (M 1 +H) kilogram working fluid exothermic condensation process 81-a total of 11 processes.
(2)从能量转换上看:(2) From the perspective of energy conversion:
①吸热过程——M
1千克工质进行23过程和M
2千克工质进行45过程需要的热负荷由 外部热源来提供。
① endothermic process --M 1 kilogram working fluid and process for 23 working medium M 2 kilogram process requires heat load 45 is provided by an external heat source.
②放热过程——(M
1+M
2)千克工质以混合方式放热于H千克工质,降温至6点,完成67过程;(M
1+H)千克工质进行81过程的放热,一般向低温热源释放,热动联供时向热用户提供。
②Exothermic process-(M 1 +M 2 ) kg of working fluid releases heat to H kg of working fluid in a mixed manner, and the temperature is reduced to 6 points to complete the 67 process; (M 1 +H) kg of working fluid performs 81 process of release Heat is generally released to a low-temperature heat source, and provided to heat users in the case of combined heat and power supply.
③能量转换过程——M
1千克工质的升压过程12和H千克工质的升压过程1e一般由循环泵来完成,M
2千克工质的升压过程74一般由压缩机来完成;M
1千克工质的降压膨胀过程35,(M
1+M
2)千克工质的降压膨胀过程56,还有(M
1+H)千克工质降压膨胀过程78,一般由膨胀机来完成;膨胀作功大于升压耗功,完成热变功并对外提供循环净功,形成单工质蒸汽联合循环。
③Energy conversion process-the boosting process 12 of M 1 kg working fluid and the boosting process 1e of H kg working fluid are generally completed by a circulating pump, and the boosting process 74 of M 2 kg working fluid is generally completed by a compressor; The pressure-reducing expansion process of M 1 kilogram working fluid 35, the pressure-reducing expansion process of (M 1 +M 2 ) kilogram working fluid 56 and the pressure-reducing expansion process of (M 1 +H) kilogram working fluid 78 are generally performed by an expander The expansion work is greater than the boosting work consumption, the thermal conversion work is completed and the net cycle power is provided to the outside, forming a single working substance steam combined cycle.
图3/12所示T-s图中的单工质蒸汽联合循环示例是这样进行的:The example of the single working substance steam combined cycle in the T-s diagram shown in Figure 3/12 is performed like this:
(1)从循环过程上看:(1) From the perspective of the cycle process:
工作介质进行——M
1千克工质冷凝液升压过程12,M
1千克工质吸热升温、汽化和过热过程25,H千克工质冷凝液升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热升温、汽化和过热过程e7,M
2千克工质升压升温过程73,M
2千克工质吸热升温过程34,M
2千克工质降压膨胀过程45,(M
1+M
2)千克工质降压膨胀过程56,(M
1+M
2)千克工质与H千克工质混合放热降温过程67,(M
1+H)千克工质降压膨胀过程78,(M
1+H)千克工质放热冷凝过程81——共11个过程。
Working medium: M 1 kg of working fluid condensate boost process 12, M 1 kg of working fluid endothermic heating, vaporization and overheating process 25, H kg of working fluid condensate boost process 1e, H kg of working fluid and (M 1 +M 2 ) Kilogram working fluid mixed endothermic heating, vaporization and overheating process e7, M 2 kg working fluid pressure rising process 73, M 2 kg working fluid endothermic heating process 34, M 2 kg working fluid pressure reducing expansion process 45, (M 1 +M 2 ) kg working fluid depressurization and expansion process 56, (M 1 +M 2 ) kg working fluid and H kg working fluid mixing exothermic cooling process 67, (M 1 +H) kg working fluid drop Pressure expansion process 78, (M 1 +H) kilogram working fluid exothermic condensation process 81-a total of 11 processes.
(2)从能量转换上看:(2) From the perspective of energy conversion:
①吸热过程——M
1千克工质进行25过程和M
2千克工质进行34过程需要的热负荷由外部热源来提供。
① Endothermic process-the heat load required for M 1 kg of working fluid for 25 process and M 2 kg of working fluid for 34 process is provided by an external heat source.
②放热过程——(M
1+M
2)千克工质以混合方式放热于H千克工质,降温至7点,完成67过程;(M
1+H)千克工质进行81过程的放热,一般向低温热源释放,热动联供时向热用户提供。
②Exothermic process-(M 1 +M 2 ) kilogram of working fluid releases heat to H kilogram of working fluid in a mixed manner, and the temperature is reduced to 7 points to complete the 67 process; (M 1 +H) kilogram of working fluid performs 81 process of release Heat is generally released to a low-temperature heat source, and provided to heat users in the case of combined heat and power supply.
③能量转换过程——M
1千克工质的升压过程12和H千克工质的升压过程1e一般由循环泵来完成,M
2千克工质的升压过程73一般由压缩机来完成;M
2千克工质的降压膨胀过程45,(M
1+M
2)千克工质的降压膨胀过程56,还有(M
1+H)千克工质降压膨胀过程78,一般由膨胀机来完成;膨胀作功大于升压耗功,完成热变功并对外提供循环净功,形成单工质蒸汽联合循环。
③Energy conversion process-the boosting process 12 of M 1 kg working fluid and the boosting process 1e of H kg working fluid are generally completed by a circulating pump, and the boosting process 73 of M 2 kg working fluid is generally completed by a compressor; The pressure-reducing expansion process of M 2 kilogram working fluid 45, the pressure-reducing expansion process of (M 1 +M 2 ) kilogram working fluid 56 and the pressure-reducing expansion process of (M 1 +H) kilogram working fluid 78 are generally performed by an expander The expansion work is greater than the boosting work consumption, the thermal conversion work is completed and the net cycle power is provided to the outside, forming a single working substance steam combined cycle.
图4/12所示T-s图中的单工质蒸汽联合循环示例是这样进行的:The example of the single working fluid steam combined cycle in the T-s diagram shown in Figure 4/12 is performed as follows:
(1)从循环过程上看:(1) From the perspective of the cycle process:
工作介质进行——M
1千克工质冷凝液升压过程12,M
1千克工质吸热升温、汽化和过热过程23,M
1千克工质降压膨胀过程37,H千克工质冷凝液升压过程1e,H千克工质与M
2千克工质和(M
1+M
2)千克工质混合吸热升温、汽化和过热过程e8,M
2千克工质升压升温过程84,M
2千克工质吸热升温过程45,M
2千克工质降压膨胀过程56,M
2千克工质与H千克工质混合放热降温过程67,(M
1+M
2)千克工质与H千克工质混合放热降温过程78,(M
1+H)千克工质降压膨胀过程89,(M
1+H)千克工质放热冷凝过程91——共12个过程。
--M 1 kg working medium condensed liquid refrigerant boosting process 12, M 1 kg refrigerant absorbs heat heating, vaporization and superheating process 23, M 1 kg refrigerant expansion process down 37, H refrigerant condensate liters kg Pressure process 1e, H kg working fluid mixed with M 2 kg working fluid and (M 1 +M 2 ) kg working fluid endothermic heating, vaporization and overheating process e8, M 2 kg working fluid boosting and heating process 84, M 2 kg Working fluid endothermic heating process 45, M 2 kg working fluid depressurization expansion process 56, M 2 kg working fluid mixed with H kg working fluid, exothermic cooling process 67, (M 1 +M 2 ) kg working fluid and H kg working fluid The exothermic cooling process 78 of the (M 1 +H) kg working fluid, the pressure-reducing expansion process of the (M 1 +H) kg working fluid 89, the exothermic condensation process of the (M 1 +H) kg working fluid 91-a total of 12 processes.
(2)从能量转换上看:(2) From the perspective of energy conversion:
①吸热过程——M
1千克工质进行23过程和M
2千克工质进行45过程需要的热负荷由外部热源来提供。
① endothermic process --M 1 kilogram working fluid and process for 23 working medium M 2 kilogram process requires heat load 45 is provided by an external heat source.
②放热过程——M
2千克工质以混合方式放热于H千克工质,降温至7点,完成67过程;(M
1+M
2)千克工质以混合方式放热于H千克工质,降温至8点,完成78过程;(M
1+H)千克工质进行91过程的放热,一般向低温热源释放,热动联供时向热用户提供。
②Exothermic process-M 2 kg of working fluid releases heat to H kg of working fluid in a mixed manner, and the temperature is reduced to 7 points to complete the 67 process; (M 1 +M 2 ) kg of working fluid releases heat to H kg of working fluid in a mixed manner The temperature is lowered to 8 points to complete the 78 process; (M 1 +H) kilograms of working fluid carries out the heat release of the 91 process, which is generally released to the low-temperature heat source, and provided to the heat user when the heat is combined.
③能量转换过程——M
1千克工质的升压过程12和H千克工质的升压过程1e一般由循环泵来完成,M
2千克工质的升压过程84一般由压缩机来完成;M
1千克工质的降压过程37,M
2千克工质的降压过程56,还有(M
1+H)千克工质降压膨胀过程89,一般由膨胀机来完成;膨胀作功大于升压耗功,完成热变功并对外提供循环净功,形成单工质蒸汽联合循环。
③Energy conversion process-the boosting process 12 of M 1 kg working fluid and the boosting process 1e of H kg working fluid are generally completed by a circulating pump, and the boosting process 84 of M 2 kg working fluid is generally completed by a compressor; The depressurization process of M 1 kg of working fluid 37, the depressurization process of M 2 kg of working fluid 56, and the (M 1 +H) kg of working fluid depressurization expansion process 89 are generally completed by an expander; the expansion work is greater than The booster consumes power, completes the thermal transformation and provides external circulation net power, forming a single working substance steam combined cycle.
图5/12所示T-s图中的单工质蒸汽联合循环示例是这样进行的:The example of a single working fluid steam combined cycle in the T-s diagram shown in Figure 5/12 is performed as follows:
(1)从循环过程上看:(1) From the perspective of the cycle process:
工作介质进行——M
1千克工质冷凝液升压过程12,M
1千克工质吸热升温、汽化和过热过程23,M
1千克工质降压膨胀过程34,M
1千克工质与H千克工质混合放热降温过程47,H千克工质冷凝液升压过程1e,H千克工质与M
1千克工质和(M
1+M
2)千克工质混合吸热升温、汽化和过热过程e8,M
2千克工质升压升温过程85,M
2千克工质吸热升温过程56,M
2千克工质降压膨胀过程67,(M
1+M
2)千克工质与H千克工质混合放热降温过程78,(M
1+H)千克工质降压膨胀过程89,(M
1+H)千克工质放热冷凝过程91——共12个过程。
--M 1 kilogram working medium condensed liquid refrigerant boosting process 12, M 1 kilogram refrigerant absorbs heat heating, vaporization and superheating process 23, M 1 kilogram buck refrigerant expansion process 34, M 1 kilogram working fluid with H Kilogram working fluid mixing exothermic cooling process 47, H kilogram working fluid condensate pressure boosting process 1e, H kilogram working fluid and M 1 kilogram working fluid and (M 1 +M 2 ) kilogram working fluid mixing endothermic heating, vaporization and overheating Process e8, M 2 kg working fluid pressure rising process 85, M 2 kg working fluid endothermic heating process 56, M 2 kg working fluid depressurizing expansion process 67, (M 1 +M 2 ) kg working fluid and H kg working fluid The exothermic cooling process 78 of the (M 1 +H) kg working fluid, the pressure-reducing expansion process of the (M 1 +H) kg working fluid 89, the exothermic condensation process of the (M 1 +H) kg working fluid 91-a total of 12 processes.
(2)从能量转换上看:(2) From the perspective of energy conversion:
①吸热过程——M
1千克工质进行23过程和M
2千克工质进行56过程需要的热负荷由外部热源来提供。
① Endothermic process-the heat load required for M 1 kg of working fluid for 23 process and M 2 kg of working fluid for 56 process is provided by an external heat source.
②放热过程——M
1千克工质以混合方式放热于H千克工质,降温至7点,完成47过程;(M
1+M
2)千克工质以混合方式放热于H千克工质,降温至8点,完成78过程;(M
1+H)千克工质进行91过程的放热,一般向低温热源释放,热动联供时向热用户提供。
②Exothermic process-M 1 kg of working fluid releases heat to H kg of working fluid in a mixed manner, and the temperature is reduced to 7 points to complete the 47 process; (M 1 +M 2 ) kg of working fluid releases heat to H kg of working fluid in a mixed manner The temperature is lowered to 8 points to complete the 78 process; (M 1 +H) kilograms of working fluid carries out the heat release of the 91 process, which is generally released to the low-temperature heat source, and provided to the heat user when the heat is combined.
③能量转换过程——M
1千克工质的升压过程12和H千克工质的升压过程1e一般由循环泵来完成,M
2千克工质的升压过程85一般由压缩机来完成;M
1千克工质的降压膨胀过程34,M
2千克工质的降压膨胀过程67,还有(M
1+H)千克工质降压膨胀过程89,一般由膨胀机来完成;膨胀作功大于升压耗功,完成热变功并对外提供循环净功,形成单工质蒸汽联合循环。
③Energy conversion process-the boosting process 12 of M 1 kg working fluid and the boosting process 1e of H kg working fluid are generally completed by a circulating pump, and the boosting process 85 of M 2 kg working fluid is generally completed by a compressor; The pressure-reducing expansion process of M 1 kg working fluid 34, the pressure-reducing expansion process of M 2 kg working fluid 67, and the pressure-reducing expansion process of (M 1 +H) kg working fluid 89 are generally completed by an expander; The work is greater than the power consumption of the booster, the thermal transformation is completed and the net power of the cycle is provided to the outside, forming a single working substance steam combined cycle.
图6/12所示T-s图中的单工质蒸汽联合循环示例是这样进行的:The example of the single working fluid steam combined cycle in the T-s diagram shown in Figure 6/12 is performed like this:
(1)从循环过程上看:(1) From the perspective of the cycle process:
工作介质进行——M
1千克工质冷凝液升压过程12,M
1千克工质吸热升温、汽化和过热过程23,H千克工质冷凝液升压过程1e,H千克工质与(M
1+M
2-X)千克工质和(M
1+M
2)千克工质混合吸热升温、汽化和过热过程e8,M
2千克工质升压升温过程83,(M
1+M
2)千克工质吸热升温过程34,X千克工质降压膨胀过程47,(M
1+M
2-X)千克工质吸热升温过程45,(M
1+M
2-X)千克工质降压膨胀过程56,(M
1+M
2-X)千克工质与H千克工质混合放热降温过程67,(M
1+M
2)千克工质与H千克工质混合放热降温 过程78,(M
1+H)千克工质降压膨胀过程89,(M
1+H)千克工质放热冷凝过程91——共13个过程。
Working medium is carried out-M 1 kg of working fluid condensate boost process 12, M 1 kg of working fluid endothermic heating, vaporization and overheating process 23, H kg of working fluid condensate boost process 1e, H kg of working fluid and (M 1 +M 2 -X) kg working fluid and (M 1 +M 2 ) kg working fluid mixed endothermic heating, vaporization and overheating process e8, M 2 kg working fluid pressure rising and heating process 83, (M 1 +M 2 ) Kilogram working fluid endothermic heating process 34, X kilogram working fluid pressure drop expansion process 47, (M 1 +M 2 -X) kilogram working fluid endothermic heating process 45, (M 1 +M 2 -X) kilogram working fluid drop Compressive expansion process 56, (M 1 +M 2 -X) kg working fluid and H kg working fluid mixed exothermic cooling process 67, (M 1 +M 2 ) kg working fluid mixed with H kg working fluid exothermic cooling process 78 , (M 1 +H) kg working fluid depressurization expansion process 89, (M 1 +H) kg working fluid exothermic condensation process 91-a total of 13 processes.
(2)从能量转换上看:(2) From the perspective of energy conversion:
①吸热过程——M
1千克工质进行23过程、(M
1+M
2)千克工质进行34过程和(M
1+M
2-X)千克进行45过程需要的热负荷由外部热源来提供。
① Endothermic process-M 1 kg of working fluid for 23 processes, (M 1 + M 2 ) kg of working fluid for 34 processes, and (M 1 + M 2 -X) kg for 45 processes. The heat load is from an external heat source. provide.
②放热过程——(M
1+M
2-X)千克工质以混合方式放热于H千克工质,降温至7点,完成67过程;(M
1+M
2)千克工质以混合方式放热于H千克工质,降温至8点,完成78过程;(M
1+H)千克工质进行91过程的放热,一般向低温热源释放,热动联供时向热用户提供。
②Exothermic process——(M 1 +M 2 -X) kilogram of working fluid releases heat from H kilogram of working fluid in a mixed manner, and the temperature is reduced to 7 points to complete the 67 process; (M 1 +M 2 ) kilogram of working fluid is mixed The method releases heat from the H kg working fluid, and the temperature is reduced to 8 points to complete the 78 process; (M 1 +H) kg of the working fluid carries out the 91 process heat release, generally released to the low-temperature heat source, and provided to the heat user in the heat-driven co-supply.
③能量转换过程——M
1千克工质的升压过程12和H千克工质的升压过程1e一般由循环泵来完成,M
2千克工质的升压过程83一般由压缩机来完成;X千克工质的降压膨胀过程47,(M
1+M
2-X)千克工质的降压膨胀过程56,还有(M
1+H)千克工质降压膨胀过程89,一般由膨胀机来完成;膨胀作功大于升压耗功,完成热变功并对外提供循环净功,形成单工质蒸汽联合循环。
③Energy conversion process-the boosting process 12 of M 1 kg working fluid and the boosting process 1e of H kg working fluid are generally completed by a circulating pump, and the boosting process 83 of M 2 kg working fluid is generally completed by a compressor; The pressure-reducing expansion process of X kilogram working fluid 47, the pressure-reducing expansion process of (M 1 +M 2 -X) kilogram working fluid 56, and the pressure-reducing expansion process of (M 1 +H) kilogram working fluid 89, generally by expansion The expansion work is greater than the boosting work consumption, the thermal conversion work is completed and the net work is provided to the outside, forming a single working substance steam combined cycle.
图7/12所示T-s图中的单工质蒸汽联合循环示例是这样进行的:The example of the single working substance steam combined cycle in the T-s diagram shown in Figure 7/12 is performed as follows:
(1)从循环过程上看:(1) From the perspective of the cycle process:
工作介质进行——M
1千克工质冷凝液升压过程12,M
1千克工质与M千克工质的混合吸热升温过程2b,(M
1+M)千克工质吸热升温、汽化和过热过程b3,H千克工质冷凝液升压过程1e,H千克工质与(M
1+M)千克工质混合吸热升温、汽化和过热过程e6,M
2千克工质升压升温过程6a,M千克工质与M
1千克工质的混合放热冷凝过程ab,(M
2-M)千克工质升压升温过程a3,(M
1+M
2)千克工质吸热升温过程34,(M
1+M
2)千克工质降压膨胀过程45,(M
1+M
2)千克工质与H千克工质混合放热降温过程56,(M
1+H)千克工质降压膨胀过程67,(M
1+H)千克工质放热冷凝过程71——共13个过程。
The working medium is carried out-M 1 kg of working fluid condensate pressure increase process 12, M 1 kg of working fluid and M kg of working fluid mixed endothermic heating process 2b, (M 1 +M) kg of working fluid endothermic heating, vaporization and Superheating process b3, H kg working fluid condensate pressure boosting process 1e, H kg working fluid mixed with (M 1 +M) kg working fluid heat absorption, vaporization and overheating process e6, M 2 kg working fluid pressure boosting process 6a , The mixing exothermic condensation process of M kilogram working fluid and M 1 kilogram working fluid ab, (M 2 -M) kilogram working fluid pressure rising process a3, (M 1 +M 2 ) kilogram working fluid endothermic heating process 34, (M 1 +M 2 )Kg working fluid depressurization expansion process 45, (M 1 +M 2 )Kg working fluid mixed with Hkg working fluid exothermic cooling process 56,(M 1 +H)Kg working fluid depressurization expansion Process 67, (M 1 +H) kilogram working fluid exothermic condensation process 71-a total of 13 processes.
(2)从能量转换上看:(2) From the perspective of energy conversion:
①吸热过程——M
1千克工质进行2b过程的吸热来自M千克过热蒸汽的混合放热,(M
1+M)千克工质进行b3过程和(M
1+M
2)千克工质进行34过程需要的热负荷由外部热源来提供。
① Endothermic process-the heat absorption of M 1 kg of working fluid for 2b process comes from the mixed exotherm of M kg of superheated steam, (M 1 +M) kg of working fluid for b3 process and (M 1 +M 2 ) kg of working fluid The heat load required for the 34 process is provided by an external heat source.
②放热过程——(M
1+M
2)千克工质以混合方式放热于H千克工质,降温至6点,完成56过程;(M
1+H)千克工质进行71过程的放热,一般向低温热源释放,热动联供时向热用户提供。
②Exothermic process-(M 1 +M 2 ) kilogram of working fluid releases heat to H kilogram of working fluid in a mixed manner, and the temperature is reduced to 6 points to complete the 56 process; (M 1 +H) kilogram of working fluid performs 71 process Heat is generally released to a low-temperature heat source, and provided to heat users in the case of combined heat and power supply.
③能量转换过程——M
1千克工质的升压过程12和H千克工质的升压过程1e一般由循环泵来完成,M
2千克工质的升压过程6a和(M
2-M)千克工质的升压过程a3一般由压缩机来完成;(M
1+M
2)千克工质的降压膨胀过程45,还有(M
1+H)千克工质降压膨胀过程67,一般由膨胀机来完成;膨胀作功大于升压耗功,完成热变功并对外提供循环净功,形成单工质蒸汽联合循环。
③Energy conversion process-M 1 kg of working fluid boosting process 12 and H kg of working fluid boosting process 1e are generally completed by circulating pumps, M 2 kg of working fluid boosting process 6a and (M 2 -M) The pressure increase process a3 of the kilogram working fluid is generally completed by the compressor; the (M 1 +M 2 ) pressure reduction expansion process of the kilogram working fluid 45, and the (M 1 +H) kilogram working fluid pressure reduction and expansion process 67, generally It is completed by the expander; the expansion work is greater than the boosting work consumption, the thermal conversion work is completed and the net work is provided to the outside, forming a single working substance steam combined cycle.
图8/12所示T-s图中的单工质蒸汽联合循环示例是这样进行的:The example of a single working fluid steam combined cycle in the T-s diagram shown in Figure 8/12 is performed as follows:
(1)从循环过程上看:(1) From the perspective of the cycle process:
工作介质进行——M
1千克工质冷凝液升压过程12,M
1千克工质与M千克工质的混合 吸热升温过程2b,(M
1+M)千克工质吸热升温、汽化和过热过程b3,(M
1+M)千克工质降压膨胀过程35,H千克工质冷凝液升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热升温、汽化和过热过程e7,M
2千克工质升压升温过程7a,M千克工质与M
1千克工质的混合放热冷凝过程ab,(M
2-M)千克工质升压升温过程a4,(M
2-M)千克工质吸热升温过程45,(M
1+M
2)千克工质降压膨胀过程56,(M
1+M
2)千克工质与H千克工质混合放热降温过程67,(M
1+H)千克工质降压膨胀过程78,(M
1+H)千克工质放热冷凝过程81——共14个过程。
The working medium is carried out-M 1 kg of working fluid condensate pressure increase process 12, M 1 kg of working fluid and M kg of working fluid mixed endothermic heating process 2b, (M 1 +M) kg of working fluid endothermic heating, vaporization and Overheating process b3, (M 1 +M) kg working fluid depressurization and expansion process 35, H kg working fluid condensate pressure boosting process 1e, H kg working fluid and (M 1 +M 2 ) kg working fluid mixing endothermic heating, Vaporization and overheating process e7, M 2 kg working fluid pressure rising process 7a, M kg working fluid and M 1 kg working fluid mixed exothermic condensation process ab, (M 2 -M) kg working fluid pressure rising process a4, (M 2 -M) Kilogram working fluid endothermic heating process 45, (M 1 +M 2 ) Kilogram working fluid depressurization expansion process 56, (M 1 +M 2 ) Kilogram working fluid mixed with H kg working fluid to release heat and cooling Process 67, (M 1 +H) kg working fluid depressurization expansion process 78, (M 1 +H) kg working fluid exothermic condensation process 81-a total of 14 processes.
(2)从能量转换上看:(2) From the perspective of energy conversion:
①吸热过程——M
1千克工质进行2b过程的吸热来自M千克过热蒸汽的混合放热,(M
1+M)千克工质进行b3过程和(M
2-M)千克工质进行45过程需要的热负荷由外部热源来提供。
① Endothermic process-the heat absorption of M 1 kg of working fluid for 2b process comes from the mixed exothermic heat of M kg of superheated steam, (M 1 +M) kg of working fluid for b3 process and (M 2 -M) kg of working fluid The heat load required by the 45 process is provided by an external heat source.
②放热过程——(M
1+M
2)千克工质以混合方式放热于H千克工质,降温至7点,完成67过程;(M
1+H)千克工质进行81过程的放热,一般向低温热源释放,热动联供时向热用户提供。
②Exothermic process-(M 1 +M 2 ) kilogram of working fluid releases heat to H kilogram of working fluid in a mixed manner, and the temperature is reduced to 7 points to complete the 67 process; (M 1 +H) kilogram of working fluid performs 81 process of release Heat is generally released to a low-temperature heat source, and provided to heat users in the case of combined heat and power supply.
③能量转换过程——M
1千克工质的升压过程12和H千克工质的升压过程1e一般由循环泵来完成,M
2千克工质的升压过程7a和(M
2-M)千克工质的升压过程a4一般由压缩机来完成;(M
1+M)千克工质的降压膨胀过程35,(M
1+M
2)千克工质的降压膨胀过程56,还有(M
1+H)千克工质降压膨胀过程78,一般由膨胀机来完成;膨胀作功大于升压耗功,完成热变功并对外提供循环净功,形成单工质蒸汽联合循环。
③Energy conversion process-M 1 kg of working fluid boosting process 12 and H kg of working fluid boosting process 1e are generally completed by a circulating pump, M 2 kg of working fluid boosting process 7a and (M 2 -M) The pressure increase process a4 of the kilogram working fluid is generally completed by the compressor; the (M 1 +M) pressure reduction expansion process of the kilogram working fluid 35, the (M 1 +M 2 ) pressure reduction expansion process of the kilogram working fluid 56, and The (M 1 +H) kilogram working fluid pressure-reducing expansion process 78 is generally completed by an expander; the expansion work is greater than the pressure boosting power consumption, completing the thermal conversion work and providing external circulation net power, forming a single working fluid steam combined cycle.
图9/12所示T-s图中的单工质蒸汽联合循环示例是这样进行的:The example of a single working fluid steam combined cycle in the T-s diagram shown in Figure 9/12 is performed as follows:
(1)从循环过程上看:(1) From the perspective of the cycle process:
工作介质进行——M
1千克工质冷凝液升压过程12,M
1千克工质吸热升温过程2b,(M
1+M)千克工质吸热升温、汽化和过热过程b5,H千克工质冷凝液升压过程1e,H千克工质与(M
1+M
2)千克工质混合吸热升温、汽化和过热过程e7,M
2千克工质升压升温过程7a,M千克工质与M
1千克工质的混合放热冷凝过程ab,(M
2-M)千克工质升压升温过程a3,(M
2-M)千克工质吸热升温过程34,(M
2-M)千克工质降压膨胀过程45,(M
1+M
2)千克工质降压膨胀过程56,(M
1+M
2)千克工质与H千克工质混合放热降温过程67,(M
1+H)千克工质降压膨胀过程78,(M
1+H)千克工质放热冷凝过程81——共14个过程。
Working medium: M 1 kg of working fluid condensate boost process 12, M 1 kg of working fluid endothermic heating process 2b, (M 1 +M) kg of working fluid endothermic heating, vaporization and overheating process b5, H kg working fluid Process 1e of pressure increase of condensate, H kg of working fluid and (M 1 +M 2 ) kg of working fluid are mixed to endothermic heating, vaporization and overheating process e7, M 2 kg of working fluid is heated up process 7a, M kg of working fluid is combined with M 1 kg of working fluid’s mixed exothermic condensation process ab, (M 2 -M) kg of working fluid’s pressure rising process a3, (M 2 -M) kg of working fluid’s endothermic heating process 34, (M 2 -M) kg Working fluid depressurization expansion process 45, (M 1 +M 2 ) kg working fluid depressurization expansion process 56, (M 1 +M 2 ) kg working fluid and H kg working fluid mixing exothermic cooling process 67, (M 1 + H) The pressure-reducing expansion process of kilogram working fluid 78, (M 1 +H) the exothermic condensation process of kilogram working fluid 81-a total of 14 processes.
(2)从能量转换上看:(2) From the perspective of energy conversion:
①吸热过程——M
1千克工质进行2b过程的吸热来自M千克过热蒸汽的混合放热,(M
1+M)千克工质进行b5过程和(M
2-M)千克工质进行34过程需要的热负荷由外部热源来提供。
① Endothermic process-the heat absorption of M 1 kg of working fluid for 2b process comes from the mixed exotherm of M kg of superheated steam, (M 1 +M) kg of working fluid for b5 process and (M 2 -M) kg of working fluid 34 The heat load required by the process is provided by an external heat source.
②放热过程——(M
1+M
2)千克工质以混合方式放热于H千克工质,降温至7点,完成67过程;M
1千克工质进行81过程的放热,一般向低温热源释放,热动联供时向热用户提供。
②Exothermic process-(M 1 + M 2 ) kg of working fluid releases heat from H kg of working fluid in a mixed manner, and the temperature is reduced to 7 points to complete the 67 process; M 1 kg of working fluid carries out the heat release of 81 process, generally The low-temperature heat source is released, and it is provided to the heat user when the heat and power supply are combined.
③能量转换过程——M
1千克工质的升压过程12和H千克工质的升压过程1e一般由循环泵来完成,M
2千克工质的升压过程7a和(M
2-M)千克工质的升压过程a3一般由压缩 机来完成;(M
2-M)千克工质的降压膨胀过程45,(M
1+M
2)千克工质的降压膨胀过程56,还有(M
1+H)千克工质降压膨胀过程78,一般由膨胀机来完成;膨胀作功大于升压耗功,完成热变功并对外提供循环净功,形成单工质蒸汽联合循环。
③Energy conversion process-M 1 kg of working fluid boosting process 12 and H kg of working fluid boosting process 1e are generally completed by a circulating pump, M 2 kg of working fluid boosting process 7a and (M 2 -M) The pressure increase process a3 of the kilogram working fluid is generally completed by the compressor; (M 2 -M) the pressure-reducing expansion process of the kilogram working fluid 45, (M 1 +M 2 ) the pressure-reducing expansion process of the kilogram working fluid 56, and The (M 1 +H) kilogram working fluid pressure-reducing expansion process 78 is generally completed by an expander; the expansion work is greater than the pressure boosting power consumption, completing the thermal conversion work and providing external circulation net power, forming a single working fluid steam combined cycle.
图10/12所示T-s图中的单工质蒸汽联合循环示例是这样进行的:The example of the single working fluid steam combined cycle in the T-s diagram shown in Figure 10/12 is performed as follows:
(1)从循环过程上看:(1) From the perspective of the cycle process:
工作介质进行——M
1千克工质冷凝液升压过程12,M
1千克工质吸热升温过程2b,(M
1+M)千克工质吸热升温、汽化和过热过程b3,(M
1+M)千克工质降压膨胀过程37,H千克工质冷凝液升压过程1e,H千克工质与(M
1+M)千克工质和(M
1+M
2)千克工质混合吸热升温、汽化和过热过程e8,M
2千克工质升压升温过程8a,M千克工质与M
1千克工质的混合放热冷凝过程ab,(M
2-M)千克工质升压升温过程a4,(M
2-M)千克工质吸热升温过程45,(M
2-M)千克工质降压膨胀过程56,(M
2-M)千克工质与H千克工质混合放热降温过程67,(M
1+M
2)千克工质与H千克工质混合放热降温过程78,(M
1+H)千克工质降压膨胀过程89,(M
1+H)千克工质放热冷凝过程91——共15个过程。
Working medium: M 1 kg of working fluid condensate boost process 12, M 1 kg of working fluid endothermic heating process 2b, (M 1 +M) kg of working fluid endothermic heating, vaporization and overheating process b3, (M 1 +M)Kg working fluid depressurization expansion process 37, H kg working fluid condensate pressure boosting process 1e, H kg working fluid mixed with (M 1 +M) kg working fluid and (M 1 +M 2 ) kg working fluid Thermal heating, vaporization and overheating process e8, M 2 kg working fluid pressure rising process 8a, M kg working fluid and M 1 kg working fluid mixed exothermic condensation process ab, (M 2 -M) kg working fluid pressure rising and heating process Process a4, (M 2 -M) kg working fluid endothermic and heating process 45, (M 2 -M) kg working fluid depressurization expansion process 56, (M 2 -M) kg working fluid and H kg working fluid mixed and exothermic Cooling process 67, (M 1 +M 2 ) kg working fluid and H kg working fluid mixed exothermic cooling process 78, (M 1 +H) kg working fluid depressurization expansion process 89, (M 1 +H) kg working fluid Exothermic condensation process 91-a total of 15 processes.
(2)从能量转换上看:(2) From the perspective of energy conversion:
①吸热过程——M
1千克工质进行2b过程的吸热来自M千克过热蒸汽的混合放热,(M
1+M)千克工质进行b3过程和(M
2-M)千克工质进行45过程需要的热负荷由外部热源来提供。
① Endothermic process-the heat absorption of M 1 kg of working fluid for 2b process comes from the mixed exothermic heat of M kg of superheated steam, (M 1 +M) kg of working fluid for b3 process and (M 2 -M) kg of working fluid The heat load required by the 45 process is provided by an external heat source.
②放热过程——(M
2-M)千克工质以混合方式放热于H千克工质,降温至7点,完成67过程;(M
1+M
2)千克工质以混合方式放热于H千克工质,降温至8点,完成78过程;M
1千克工质进行91过程的放热,一般向低温热源释放,热动联供时向热用户提供。
②Exothermic process-(M 2 -M) kilogram of working fluid releases heat from H kilogram of working fluid in a mixed manner, and the temperature is reduced to 7 points to complete the 67 process; (M 1 +M 2 ) kilogram of working fluid releases heat in a mixed manner At H kg of working fluid, the temperature is reduced to 8 o'clock to complete the 78 process; M 1 kg of working fluid carries out the heat release of the 91 process, which is generally released to the low-temperature heat source, and is provided to the heat user when the heat is combined.
③能量转换过程——M
1千克工质的升压过程12和H千克工质的升压过程1e一般由循环泵来完成,M
2千克工质的升压过程8a和(M
2-M)千克工质的升压过程a4一般由压缩机来完成;(M
1+M)千克工质的降压过程37,(M
2-M)千克工质的降压过程56,还有(M
1+H)千克工质降压膨胀过程89,一般由膨胀机来完成;膨胀作功大于升压耗功,完成热变功并对外提供循环净功,形成单工质蒸汽联合循环。
③Energy conversion process-the boosting process of M 1 kg of working fluid 12 and the boosting process of H kg of working fluid 1e are generally completed by a circulating pump, and the boosting process of M 2 kg of working fluid 8a and (M 2 -M) The pressure increase process a4 of kilogram working fluid is generally completed by the compressor; (M 1 +M) pressure reduction process of kilogram working fluid 37, (M 2 -M) pressure reduction process of kilogram working fluid 56, and (M 1 +H) The pressure-reducing expansion process of kilogram working fluid 89 is generally completed by the expander; the expansion work is greater than the pressure-boosting work, which completes the thermal conversion work and provides external net power to form a single working fluid steam combined cycle.
图11/12所示T-s图中的单工质蒸汽联合循环示例是这样进行的:The example of the single working fluid steam combined cycle in the T-s diagram shown in Figure 11/12 is performed like this:
(1)从循环过程上看:(1) From the perspective of the cycle process:
工作介质进行——M
1千克工质冷凝液升压过程12,M
1千克工质吸热升温过程2b,(M
1+M)千克工质吸热升温、汽化和过热过程b3,(M
1+M)千克工质降压膨胀过程34,(M
1+M)千克工质与H千克工质混合放热降温过程47,H千克工质冷凝液升压过程1e,H千克工质与(M
1+M)千克工质和(M
1+M
2)千克工质混合吸热升温、汽化和过热过程e8,M
2千克工质升压升温过程8a,M千克工质与M
1千克工质的混合放热冷凝过程ab,(M
2-M)千克工质升压升温过程a5,(M
2-M)千克工质吸热升温过程56,(M
2-M)千克工质降压膨胀过程67,(M
1+M
2)千克工质与H千克工质混合放热降温过程78,(M
1+H)千克工质降压膨胀过程89,(M
1+H)千克工质放热冷凝过程91——共计15个过程。
Working medium: M 1 kg of working fluid condensate boost process 12, M 1 kg of working fluid endothermic heating process 2b, (M 1 +M) kg of working fluid endothermic heating, vaporization and overheating process b3, (M 1 +M)Kg working fluid depressurization expansion process 34, (M 1 +M)Kg working fluid mixed with Hkg working fluid exothermic cooling process 47, Hkg working fluid condensate boosting process 1e, Hkg working fluid and ( M 1 +M) kilogram of working fluid and (M 1 +M 2 ) kilogram of working fluid mixed endothermic heating, vaporization and overheating process e8, M 2 kilogram of working fluid boosting and heating process 8a, M kilogram of working fluid and M 1 kilogram of working fluid Mixing exothermic condensation process ab, (M 2 -M) kg working fluid pressure increasing process a5, (M 2 -M) kg working fluid endothermic heating process 56, (M 2 -M) kg working fluid pressure reduction Expansion process 67, (M 1 +M 2 ) kg working fluid and H kg working fluid mixed exothermic cooling process 78, (M 1 +H) kg working fluid depressurization expansion process 89, (M 1 +H) kg working fluid Exothermic condensation process 91-a total of 15 processes.
(2)从能量转换上看:(2) From the perspective of energy conversion:
①吸热过程——M
1千克工质进行2b过程的吸热来自M千克过热蒸汽的混合放热,(M
1+M)千克工质进行b3过程和(M
2-M)千克工质进行56过程需要的热负荷由外部热源来提供。
① Endothermic process-the heat absorption of M 1 kg of working fluid for 2b process comes from the mixed exothermic heat of M kg of superheated steam, (M 1 +M) kg of working fluid for b3 process and (M 2 -M) kg of working fluid The heat load required by the 56 process is provided by an external heat source.
②放热过程——(M
1+M)千克工质以混合方式放热于H千克工质,降温至7点,完成47过程;(M
1+M
2)千克工质以混合方式放热于H千克工质,降温至8点,完成78过程;M
1千克工质进行91过程的放热,一般向低温热源释放,热动联供时向热用户提供。
②Exothermic process-(M 1 +M) kilogram of working fluid releases heat from H kilogram of working fluid in a mixed manner, and the temperature is reduced to 7 points to complete the 47 process; (M 1 +M 2 ) kilogram of working fluid releases heat in a mixed manner At H kg of working fluid, the temperature is reduced to 8 o'clock to complete the 78 process; M 1 kg of working fluid carries out the heat release of the 91 process, which is generally released to the low-temperature heat source, and is provided to the heat user when the heat is combined.
③能量转换过程——M
1千克工质的升压过程12和H千克工质的升压过程1e一般由循环泵来完成,M
2千克工质的升压过程8a和(M
2-M)千克工质的升压过程a5一般由压缩机来完成;(M
1+M)千克工质的降压过程34,(M
2-M)千克工质的降压过程67,还有(M
1+H)千克工质降压膨胀过程89,一般由膨胀机来完成;膨胀作功大于升压耗功,完成热变功并对外提供循环净功,形成单工质蒸汽联合循环。
③Energy conversion process-the boosting process of M 1 kg of working fluid 12 and the boosting process of H kg of working fluid 1e are generally completed by a circulating pump, and the boosting process of M 2 kg of working fluid 8a and (M 2 -M) The pressure increase process a5 of the kilogram working fluid is generally completed by the compressor; the pressure reduction process of (M 1 +M) kilogram working fluid 34, the pressure reduction process of (M 2 -M) kilogram working fluid 67, and (M 1 +H) The pressure-reducing expansion process of kilogram working fluid 89 is generally completed by the expander; the expansion work is greater than the pressure-boosting work, which completes the thermal conversion work and provides external net power to form a single working fluid steam combined cycle.
图12/12所示T-s图中的单工质蒸汽联合循环示例是这样进行的:The example of the single working fluid steam combined cycle in the T-s diagram shown in Figure 12/12 is performed like this:
(1)从循环过程上看:(1) From the perspective of the cycle process:
工作介质进行——M
1千克工质冷凝液升压过程12,M
1千克工质吸热升温过程2b,(M
1+M)千克工质吸热升温、汽化和过热过程b3,H千克工质冷凝液升压过程1e,H千克工质与(M
1+M
2-X)千克工质和(M
1+M
2)千克工质混合吸热升温、汽化和过热过程e8,M
2千克工质升压升温过程8a,M千克工质与M
1千克工质的混合放热冷凝过程ab,(M
2-M)千克工质升压升温过程a3,(M
1+M
2)千克工质吸热升温过程34,X千克工质降压膨胀过程47,(M
1+M
2-X)千克工质吸热升温过程45,(M
1+M
2-X)千克工质降压膨胀过程56,(M
1+M
2-X)千克工质与H千克工质混合放热降温过程67,(M
1+M
2)千克工质与H千克工质混合放热降温过程78,(M
1+H)千克工质降压膨胀过程89,(M
1+H)千克工质放热冷凝过程91——共计16个过程。
Working medium: M 1 kg of working fluid condensate boost process 12, M 1 kg of working fluid endothermic heating process 2b, (M 1 +M) kg of working fluid endothermic heating, vaporization and overheating process b3, H kg working fluid The process of pressure increase of condensate 1e, H kg of working fluid and (M 1 +M 2 -X) kg of working fluid and (M 1 +M 2 ) of (M 1 +M 2 ) kg of working fluid are mixed to endothermic heating, vaporization and overheating process e8, M 2 kg Working fluid pressure increasing process 8a, the mixing exothermic condensation process of M kilogram working fluid and M 1 kilogram working fluid ab, (M 2 -M) kilogram working fluid pressure increasing process a3, (M 1 +M 2 ) kilogram working fluid Endothermic heating process 34, X kg working fluid depressurization expansion process 47, (M 1 +M 2 -X) kg working fluid endothermic heating process 45, (M 1 +M 2 -X) kg working fluid depressurization expansion Process 56, (M 1 +M 2 -X) kg working fluid and H kg working fluid mixed exothermic cooling process 67, (M 1 +M 2 ) kg working fluid and H kg working fluid mixed exothermic cooling process 78, ( M 1 +H) the pressure-reducing expansion process of the kilogram working fluid 89, (M 1 +H) the exothermic condensation process of the kilogram working fluid 91-a total of 16 processes.
(2)从能量转换上看:(2) From the perspective of energy conversion:
①吸热过程——M
1千克工质进行2b过程的吸热来自M千克过热蒸汽的混合放热,(M
1+M)千克工质进行b3过程、(M
1+M
2)千克工质进行34过程和(M
1+M
2-X)千克进行45过程需要的热负荷由外部热源来提供。
① Endothermic process-the heat absorption of M 1 kg of working fluid for 2b process comes from the mixed exothermic heat of M kg of superheated steam, (M 1 +M) kg of working fluid for b3 process, (M 1 +M 2 ) kg of working fluid The heat load required to carry out 34 processes and (M 1 +M 2 -X) kg to carry out 45 processes is provided by an external heat source.
②放热过程——(M
1+M
2-X)千克工质以混合方式放热于H千克工质,降温至7点,完成67过程;(M
1+M
2)千克工质以混合方式放热于H千克工质,降温至8点,完成78过程;M
1千克工质进行91过程的放热,一般向低温热源释放,热动联供时向热用户提供。
②Exothermic process——(M 1 +M 2 -X) kilogram of working fluid releases heat from H kilogram of working fluid in a mixed manner, and the temperature is reduced to 7 points to complete the 67 process; (M 1 +M 2 ) kilogram of working fluid is mixed The method releases heat from the H kg working fluid, and the temperature is reduced to 8 points to complete the 78 process; the M 1 kg working fluid carries out the 91 process heat release, which is generally released to the low-temperature heat source, and provided to the heat user when the heat is combined.
③能量转换过程——M
1千克工质的升压过程12和H千克工质的升压过程1e一般由循环泵来完成,M
2千克工质的升压过程8a和(M
2-M)千克工质的升压过程a3一般由压缩机来完成;X千克工质的降压过程47,(M
1+M
2-X)千克工质的降压过程56,还有(M
1+H)千克工质降压膨胀过程89,一般由膨胀机来完成;膨胀作功大于升压耗功,完成热变功并对外提供循环净功,形成单工质蒸汽联合循环。
③Energy conversion process-the boosting process of M 1 kg of working fluid 12 and the boosting process of H kg of working fluid 1e are generally completed by a circulating pump, and the boosting process of M 2 kg of working fluid 8a and (M 2 -M) The pressure increase process a3 of kilogram working fluid is generally completed by the compressor; the pressure reduction process of X kilogram working fluid 47, the pressure reduction process of (M 1 +M 2 -X) kilogram working fluid 56, and the (M 1 +H ) The pressure-reducing expansion process of the kilogram working fluid 89 is generally completed by the expander; the expansion work is greater than the pressure-boosting power consumption, completing the thermal conversion work and providing external net power for the cycle, forming a single working fluid steam combined cycle.
本发明技术可以实现的效果——本发明所提出的单工质蒸汽联合循环,具有如下效果和优势:The effects that can be achieved by the technology of the present invention-the single working substance steam combined cycle proposed by the present invention has the following effects and advantages:
(1)创建热能(温差)利用基础理论。(1) Create a basic theory of thermal energy (temperature difference) utilization.
(2)较大幅度减少相变吸热过程的热负荷,相对增加高温段吸热负荷,热效率高。(2) The heat load of the phase change heat absorption process is greatly reduced, and the heat absorption load of the high temperature section is relatively increased, and the thermal efficiency is high.
(3)方法简单,流程合理,适用性好,是实现温差有效利用的共性技术。(3) The method is simple, the process is reasonable, and the applicability is good. It is a common technology to realize the effective use of temperature difference.
(4)单一工质,有利于生产和储存;降低运行成本,提高循环调节的灵活性(4) A single working fluid is conducive to production and storage; reduces operating costs and improves the flexibility of cycle adjustment
(5)过程共用,提高热效率,并为减少设备投资提供理论基础。(5) Process sharing, improving thermal efficiency, and providing a theoretical basis for reducing equipment investment.
(6)在高温区或变温区阶段,循环介质与热源介质同为气体,循环工质自热源吸热环节有利于降低温差传热损失,提高热效率。(6) In the stage of high temperature zone or variable temperature zone, the circulating medium and the heat source medium are the same gas, and the absorbing link of the circulating working fluid from the heat source is beneficial to reduce temperature difference heat transfer loss and improve thermal efficiency.
(7)在高温区采取低压高温运行方式,解决传统蒸汽动力装置中热效率、循环介质参数与管材耐压耐温性能之间难以调和的矛盾。(7) The low-pressure and high-temperature operation mode is adopted in the high-temperature zone to solve the difficult to reconcile contradictions between thermal efficiency, circulating medium parameters and pipe pressure and temperature resistance in traditional steam power plants.
(8)在实现高热效率前提下,可选择低压运行,为提高装置运行的安全性提供理论支撑。(8) Under the premise of achieving high thermal efficiency, low-pressure operation can be selected to provide theoretical support for improving the safety of device operation.
(9)工质适用范围广,能够很好地适应供能需求,工质与工作参数之间匹配灵活。(9) The working fluid has a wide application range, can well adapt to the energy supply demand, and the working fluid and working parameters are matched flexibly.
(10)扩展了实现温差利用的热力循环范围,有利于更好地实现高温热源和变温热源的高效动力利用。(10) The thermodynamic cycle range for realizing the utilization of temperature difference is expanded, which is beneficial to better realize the high-efficiency power utilization of high-temperature heat source and variable-temperature heat source.
Claims (12)
- 单工质蒸汽联合循环,是指由M 1千克、M 2千克和H千克组成的工质,分别或共同进行的十个过程——M 1千克工质升压过程12,M 1千克工质吸热汽化过程23,H千克工质升压过程1e,H千克工质与(M 1+M 2)千克工质混合吸热过程e6,M 2千克工质升压过程63,(M 1+M 2)千克工质吸热过程34,(M 1+M 2)千克工质降压过程45,(M 1+M 2)千克工质与H千克工质混和放热过程56,(M 1+H)千克工质降压过程67,(M 1+H)千克工质放热冷凝过程71——组成的闭合过程。 Single working fluid steam combined cycle refers to the working fluid consisting of M 1 kg, M 2 kg and H kg, and ten processes carried out separately or jointly-M 1 kg working fluid boost process 12, M 1 kg working fluid Endothermic vaporization process 23, H kg of working fluid boost process 1e, H kg of working fluid and (M 1 +M 2 ) kg of working fluid mixed endothermic process e6, M 2 kg of working fluid boost process 63, (M 1 + M 2 ) Kilogram working fluid endothermic process 34, (M 1 +M 2 ) Kilogram working fluid pressure reduction process 45, (M 1 +M 2 ) Kilogram working fluid mixed with H kilogram working fluid and exothermic process 56, (M 1 +H) Kilogram working fluid depressurization process 67, (M 1 +H) Kilogram working fluid exothermic condensation process 71-a closed process of composition.
- 单工质蒸汽联合循环,是指由M 1千克、M 2千克和H千克组成的工质,分别或共同进行的十一个过程——M 1千克工质升压过程12,M 1千克工质吸热汽化过程23,M 1千克工质降压过程35,H千克工质升压过程1e,H千克工质与(M 1+M 2)千克工质混合吸热过程e7,M 2千克工质升压过程74,M 2千克工质吸热过程45,(M 1+M 2)千克工质降压过程56,(M 1+M 2)千克工质与H千克工质混和放热过程67,(M 1+H)千克工质降压过程78,(M 1+H)千克工质放热冷凝过程81——组成的闭合过程。 Single working fluid steam combined cycle refers to the working fluids composed of M 1 kg, M 2 kg and H kg, which are carried out separately or jointly in eleven processes-M 1 kg working fluid boost process 12, M 1 kg working fluid Endothermic vaporization process 23, M 1 kg working fluid depressurization process 35, H kg working fluid boosting process 1e, H kg working fluid and (M 1 + M 2 ) kg working fluid mixed endothermic process e7, M 2 kg Working fluid pressure increase process 74, M 2 kilogram working fluid endothermic process 45, (M 1 +M 2 ) kilogram working fluid depressurization process 56, (M 1 +M 2 ) kilogram working fluid mixed with H kilogram working fluid to release heat Process 67, (M 1 +H) kilogram working fluid depressurization process 78, (M 1 +H) kilogram working fluid exothermic condensation process 81-a closed process of composition.
- 单工质蒸汽联合循环,是指由M 1千克、M 2千克和H千克组成的工质,分别或共同进行的十一个过程——M 1千克工质升压过程12,M 1千克工质吸热汽化过程25,H千克工质升压过程1e,H千克工质与(M 1+M 2)千克工质混合吸热过程e7,M 2千克工质升压过程73,M 2千克工质吸热过程34,M 2千克工质降压过程45,(M 1+M 2)千克工质降压过程56,(M 1+M 2)千克工质与H千克工质混合放热过程67,(M 1+H)千克工质降压过程78,(M 1+H)千克工质放热冷凝过程81——组成的闭合过程。 Single working fluid steam combined cycle refers to the working fluids composed of M 1 kg, M 2 kg and H kg, which are carried out separately or jointly in eleven processes-M 1 kg working fluid boost process 12, M 1 kg working fluid Endothermic vaporization process 25, H kg working fluid boost process 1e, H kg working fluid mixed with (M 1 +M 2 ) kg working fluid endothermic process e7, M 2 kg working fluid boost process 73, M 2 kg Working fluid endothermic process 34, M 2 kg working fluid depressurizing process 45, (M 1 +M 2 ) kg working fluid depressurizing process 56, (M 1 +M 2 ) kg working fluid and H kg working fluid mixed exothermic Process 67, (M 1 +H) kilogram working fluid depressurization process 78, (M 1 +H) kilogram working fluid exothermic condensation process 81-a closed process of composition.
- 单工质蒸汽联合循环,是指由M 1千克、M 2千克和H千克组成的工质,分别或共同进行的十二个过程——M 1千克工质升压过程12,M 1千克工质吸热汽化过程23,M 1千克工质降压过程37,H千克升压过程1e,H千克工质与(M 1+M 2)千克工质混合吸热过程e8,M 2千克工质升压过程84,M 2千克工质吸热过程45,M 2千克工质降压过程56,M 2千克工质与H千克工质混合放热过程67,(M 1+M 2)千克工质与H千克工质混合放热过程78,(M 1+H)千克工质降压过程89,(M 1+H)千克工质放热冷凝过程91——组成的闭合过程。 Single working fluid steam combined cycle refers to the working fluids composed of M 1 kg, M 2 kg and H kg, and twelve processes that are carried out separately or jointly-M 1 kg working fluid boost process 12, M 1 kg working fluid Endothermic vaporization process 23, M 1 kg working fluid depressurization process 37, H kg boosting process 1e, H kg working fluid and (M 1 + M 2 ) kg working fluid mixed endothermic process e8, M 2 kg working fluid Pressure increase process 84, M 2 kg working fluid endothermic process 45, M 2 kg working fluid depressurization process 56, M 2 kg working fluid and H kg working fluid mixed exothermic process 67, (M 1 +M 2 ) kg work H kg mass is mixed with the working medium exothermic process 78, (M 1 + H) kg working fluid depressurisation 89, (M 1 + H) kg refrigerant radiates heat and condenses during the closing process 91-- thereof.
- 单工质蒸汽联合循环,是指由M 1千克、M 2千克和H千克组成的工质,分别或共同进行的十二个过程——M 1千克工质升压过程12,M 1千克工质吸热汽化过程23,M 1千克工质降压过程34,M 1千克工质与H千克工质混合放热过程47,H千克工质升压过程1e,H千克工质与(M 1+M 2)千克工质混合吸热过程e8,M 2千克工质升压过程85,M 2千克工质吸热过程56,M 2千克工质降压过程67,(M 1+M 2)千克工质与H千克工质混合放热过 程78,(M 1+H)千克工质降压过程89,(M 1+H)千克工质放热冷凝过程91——组成的闭合过程。 Single working fluid steam combined cycle refers to the working fluids composed of M 1 kg, M 2 kg and H kg, and twelve processes that are carried out separately or jointly-M 1 kg working fluid boost process 12, M 1 kg working fluid Endothermic vaporization process 23, M 1 kg working fluid depressurization process 34, M 1 kg working fluid and H kg working fluid mixed exothermic process 47, H kg working fluid boosting process 1e, H kg working fluid and (M 1 +M 2 ) Kilogram working fluid mixed endothermic process e8, M 2 kilogram working fluid pressure increase process 85, M 2 kilogram working fluid heat absorption process 56, M 2 kilogram working fluid pressure reduction process 67, (M 1 +M 2 ) Kilogram working fluid and H kilogram working fluid mixing exothermic process 78, (M 1 +H) kilogram working fluid depressurization process 89, (M 1 +H) kilogram working fluid exothermic condensation process 91—composition closed process.
- 单工质蒸汽联合循环,是指由M 1千克、M 2千克和H千克组成的工质,分别或共同进行的十三个过程——M 1千克工质升压过程12,M 1千克工质吸热汽化过程23,H千克工质升压过程1e,H千克工质与(M 1+M 2)千克工质混合吸热过程e8,M 2千克工质升压过程83,(M 1+M 2)千克工质吸热过程34,X千克工质降压过程47,(M 1+M 2-X)千克工质吸热过程45,(M 1+M 2-X)千克工质降压过程56,(M 1+M 2-X)千克工质与H千克工质混合放热过程67,(M 1+M 2)千克工质与H千克工质混合放热过程78,(M 1+H)千克工质降压过程89,(M 1+H)千克工质放热冷凝过程91——组成的闭合过程。 The single working fluid steam combined cycle refers to the working fluids composed of M 1 kg, M 2 kg and H kg, which are carried out separately or jointly in thirteen processes-M 1 kg working fluid boost process 12, M 1 kg working fluid Endothermic vaporization process 23, H kilogram working fluid boost process 1e, H kilogram working fluid and (M 1 +M 2 ) kilogram working fluid mixed endothermic process e8, M 2 kilogram working fluid boost process 83, (M 1 +M 2 ) Kilogram working fluid endothermic process 34, X kilogram working fluid pressure reduction process 47, (M 1 +M 2 -X) kilogram working fluid heat absorption process 45, (M 1 +M 2 -X) kg working fluid Depressurization process 56, (M 1 +M 2 -X) kg working fluid and H kg working fluid mixing exothermic process 67, (M 1 +M 2 ) kg working fluid and H kg working fluid mixing exothermic process 78, ( M 1 +H) kg working fluid depressurization process 89, (M 1 +H) kg working fluid exothermic condensation process 91—composed closed process.
- 单工质蒸汽联合循环,是指由M 1千克、M 2千克和H千克组成的工质,分别或共同进行的十三个过程——M 1千克工质升压过程12,M 1千克工质吸热过程2b,(M 1+M)千克工质吸热汽化过程b3,H千克工质升压过程1e,H千克工质与(M 1+M 2)千克工质混合吸热过程e6,M 2千克工质升压过程6a,M千克工质放热冷凝过程ab,(M 2-M)千克工质升压过程a3,(M 1+M 2)千克工质吸热过程34,(M 1+M 2)千克工质降压过程45,(M 1+M 2)千克工质与H千克工质混合放热过程56,(M 1+H)千克工质降压过程67,(M 1+H)千克工质放热冷凝过程71——组成的闭合过程。 The single working fluid steam combined cycle refers to the working fluids composed of M 1 kg, M 2 kg and H kg, which are carried out separately or jointly in thirteen processes-M 1 kg working fluid boost process 12, M 1 kg working fluid Endothermic process 2b, (M 1 +M) kg of working fluid endothermic vaporization process b3, H kg of working fluid boost process 1e, H kg of working fluid and (M 1 +M 2 ) kg of working fluid mixed endothermic process e6 , M 2 kg working fluid boost process 6a, M kg working fluid exothermic condensation process ab, (M 2 -M) kg working fluid boost process a3, (M 1 +M 2 ) kg working fluid endothermic process 34, (M 1 +M 2 )Kg working fluid depressurization process 45, (M 1 +M 2 )Kg working fluid and H kg working fluid mixing exothermic process 56, (M 1 +H)Kg working fluid depressurization process 67, (M 1 +H) Kilogram working fluid exothermic condensation process 71-a closed process of composition.
- 单工质蒸汽联合循环,是指由M 1千克、M 2千克和H千克组成的工质,分别或共同进行的十四个过程——M 1千克工质升压过程12,M 1千克工质吸热过程2b,(M 1+M)千克工质吸热汽化过程b3,(M 1+M)千克工质降压过程35,H千克工质升压过程1e,H千克工质与(M 1+M 2)千克工质混合吸热过程e7,M 2千克工质升压过程7a,M千克工质放热冷凝过程ab,(M 2-M)千克工质升压过程a4,(M 2-M)千克工质吸热过程45,(M 1+M 2)千克工质降压过程56,(M 1+M 2)千克工质与H千克工质混合放热过程67,(M 1+H)千克工质降压过程78,(M 1+H)千克工质放热冷凝过程81——组成的闭合过程。 Single working substance steam combined cycle refers to the working medium composed of M 1 kg, M 2 kg and H kg, and 14 processes carried out separately or jointly-M 1 kg working medium boost process 12, M 1 kg working medium The endothermic process 2b of the (M 1 +M) kg working fluid endothermic vaporization process b3, the (M 1 +M) the pressure reduction process of the kg working fluid 35, the pressure increase process of the H kg working fluid 1e, the H kg working fluid and the ( M 1 +M 2 ) kg working fluid mixing endothermic process e7, M 2 kg working fluid boosting process 7a, M kg working fluid exothermic condensation process ab, (M 2 -M) kg working fluid boosting process a4, ( M 2 -M) kilogram working fluid endothermic process 45, (M 1 +M 2 ) kilogram working fluid depressurization process 56, (M 1 +M 2 ) kilogram working fluid and H kilogram working fluid mixing exothermic process 67, ( M 1 +H) kg working fluid depressurization process 78, (M 1 +H) kg working fluid exothermic condensation process 81-a closed process of composition.
- 单工质蒸汽联合循环,是指由M 1千克、M 2千克和H千克组成的工质,分别或共同进行的十四个过程——M 1千克工质升压过程12,M 1千克工质吸热过程2b,(M 1+M)千克工质吸热汽化过程b5,H千克工质升压过程1e,H千克工质与(M 1+M 2)千克工质混合吸热过程e7,M 2千克工质升压过程7a,M千克工质放热冷凝过程ab,(M 2-M)千克工质升压过程a3,(M 2-M)千克工质吸热过程34,(M 2-M)千克工质降压过程45,(M 1+M 2)千克工质降压过程56,(M 1+M 2)千克工质与H千克工质混合放热过程67,(M 1+H)千克工质降压过程78,(M 1+H)千克工质放热冷凝过程81——组成的闭合过 程。 Single working substance steam combined cycle refers to the working medium composed of M 1 kg, M 2 kg and H kg, and 14 processes carried out separately or jointly-M 1 kg working medium boost process 12, M 1 kg working medium Endothermic process 2b, (M 1 +M) kg of working fluid endothermic vaporization process b5, H kg of working fluid boost process 1e, H kg of working fluid and (M 1 +M 2 ) kg of working fluid mixed endothermic process e7 , M 2 kg working fluid boost process 7a, M kg working fluid exothermic condensation process ab, (M 2 -M) kg working fluid boost process a3, (M 2 -M) kg working fluid endothermic process 34, ( M 2 -M) kg working fluid pressure reduction process 45, (M 1 +M 2 ) kg working fluid pressure reduction process 56, (M 1 +M 2 ) kg working fluid and H kg working fluid mixing exothermic process 67, ( M 1 +H) kg working fluid depressurization process 78, (M 1 +H) kg working fluid exothermic condensation process 81-a closed process of composition.
- 单工质蒸汽联合循环,是指由M 1千克、M 2千克和H千克组成的工质,分别或共同进行的十五个过程——M 1千克工质升压过程12,M 1千克工质吸热过程2b,(M 1+M)千克工质吸热汽化过程b3,(M 1+M)千克工质降压过程37,H千克工质升压过程1e,H千克工质与(M 1+M 2)千克工质混合吸热过程e8,M 2千克工质升压过程8a,M千克工质放热冷凝过程ab,(M 2-M)千克工质升压过程a4,(M 2-M)千克工质吸热过程45,(M 2-M)千克工质降压过程56,(M 2-M)千克工质与H千克工质混合放热过程67,(M 1+M 2)千克工质与H千克工质混合放热过程78,(M 1+H)千克工质降压过程89,(M 1+H)千克工质放热冷凝过程91——组成的闭合过程。 Single working fluid steam combined cycle refers to the working fluids composed of M 1 kg, M 2 kg and H kg, which are carried out separately or jointly in fifteen processes-M 1 kg working fluid boost process 12, M 1 kg working fluid Endothermic process 2b of (M 1 +M) kilogram of working fluid endothermic vaporization process b3, (M 1 +M) of kilogram of working fluid depressurization process 37, H kilogram of working fluid boost process 1e, H kilogram of working fluid and ( M 1 +M 2 ) Kilogram working fluid mixing endothermic process e8, M 2 kilogram working fluid boosting process 8a, M kg working fluid exothermic condensation process ab, (M 2 -M) kg working fluid boosting process a4, ( M 2 -M) kilogram working fluid endothermic process 45, (M 2 -M) kilogram working fluid depressurization process 56, (M 2 -M) kilogram working fluid and H kilogram working fluid mixing exothermic process 67, (M 1 +M 2 ) Kilogram working fluid and H kilogram working fluid mixing exothermic process 78, (M 1 +H) kilogram working fluid pressure reduction process 89, (M 1 +H) kilogram working fluid exothermic condensation process 91——composition The closing process.
- 单工质蒸汽联合循环,是指由M 1千克、M 2千克和H千克组成的工质,分别或共同进行的十五个过程——M 1千克工质升压过程12,M 1千克工质吸热过程2b,(M 1+M)千克工质吸热汽化过程b3,(M 1+M)千克工质降压过程34,(M 1+M)千克工质与H千克工质混合放热过程47,H千克工质升压过程1e,H千克工质与(M 1+M 2)千克工质混合吸热过程e8,M 2千克工质升压过程8a,M千克工质放热冷凝过程ab,(M 2-M)千克工质升压过程a5,(M 2-M)千克工质吸热过程56,(M 2-M)千克工质降压过程67,(M 1+M 2)千克工质与H千克工质混合放热过程78,(M 1+H)千克工质降压过程89,(M 1+H)千克工质放热冷凝过程91——组成的闭合过程。 Single working fluid steam combined cycle refers to the working fluids composed of M 1 kg, M 2 kg and H kg, which are carried out separately or jointly in fifteen processes-M 1 kg working fluid boost process 12, M 1 kg working fluid Endothermic process 2b, (M 1 +M) kg working fluid endothermic vaporization process b3, (M 1 +M) kg working fluid pressure reduction process 34, (M 1 +M) kg working fluid mixed with H kg working fluid Exothermic process 47, H kg of working fluid boost process 1e, H kg of working fluid and (M 1 + M 2 ) kg of working fluid mixed endothermic process e8, M 2 kg of working fluid boost process 8a, M kg of working fluid release Thermal condensation process ab, (M 2 -M) kilogram working fluid pressure increase process a5, (M 2 -M) kilogram working fluid heat absorption process 56, (M 2 -M) kilogram working fluid pressure reduction process 67, (M 1 +M 2 ) Kilogram working fluid and H kilogram working fluid mixing exothermic process 78, (M 1 +H) kilogram working fluid pressure reduction process 89, (M 1 +H) kilogram working fluid exothermic condensation process 91——composition The closing process.
- 单工质蒸汽联合循环,是指由M 1千克、M 2千克和H千克组成的工质,分别或共同进行的十六个过程——M 1千克工质升压过程12,M 1千克工质吸热过程2b,(M 1+M)千克工质吸热汽化过程b3,H千克工质升压过程1e,H千克工质与(M 1+M 2)千克工质混合吸热过程e8,M 2千克工质升压过程8a,M千克工质放热冷凝过程ab,(M 2-M)千克工质升压过程a3,(M 1+M 2)千克工质吸热过程34,X千克工质降压过程47,(M 1+M 2-X)千克工质吸热过程45,(M 1+M 2-X)千克工质降压过程56,(M 1+M 2-X)千克工质与H千克工质混合放热过程67,(M 1+M 2)千克工质与H千克工质混合放热过程78,(M 1+H)千克工质降压过程89,(M 1+H)千克工质放热冷凝过程91——组成的闭合过程。 Single working fluid steam combined cycle refers to the working fluid composed of M 1 kilogram, M 2 kilogram and H kilogram, 16 processes carried out separately or jointly-M 1 kilogram working medium boost process 12, M 1 kilogram working medium Endothermic process 2b, (M 1 +M) kg of working fluid endothermic vaporization process b3, H kg of working fluid boost process 1e, H kg of working fluid and (M 1 +M 2 ) kg of working fluid mixed endothermic process e8 , M 2 kg working fluid boost process 8a, M kg working fluid exothermic condensation process ab, (M 2 -M) kg working fluid boosting process a3, (M 1 +M 2 ) kg working fluid endothermic process 34, X kilogram working fluid pressure reduction process 47, (M 1 +M 2 -X) kilogram working fluid endothermic process 45, (M 1 +M 2 -X) kilogram working fluid pressure reduction process 56, (M 1 +M 2- X) The heat release process of kilogram working fluid and H kilogram working fluid 67, the heat release process of (M 1 +M 2 ) kilogram working fluid and H kilogram working fluid 78, the pressure reduction process of (M 1 +H) kilogram working fluid 89 , (M 1 +H) Kilogram working fluid exothermic condensation process 91-a closed process of composition.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US17/604,396 US20220381159A1 (en) | 2019-04-18 | 2020-04-16 | Single-working-medium vapor combined cycle |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201910349000 | 2019-04-18 | ||
CN201910349000.5 | 2019-04-18 |
Publications (1)
Publication Number | Publication Date |
---|---|
WO2020211475A1 true WO2020211475A1 (en) | 2020-10-22 |
Family
ID=72194905
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
PCT/CN2020/000073 WO2020211475A1 (en) | 2019-04-18 | 2020-04-16 | Single working medium steam combined circulation |
Country Status (3)
Country | Link |
---|---|
US (1) | US20220381159A1 (en) |
CN (1) | CN111608754A (en) |
WO (1) | WO2020211475A1 (en) |
Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2002285907A (en) * | 2001-03-27 | 2002-10-03 | Sanyo Electric Co Ltd | Recovery refrigeration system of exhaust heat for micro gas turbine |
JP2009191762A (en) * | 2008-02-15 | 2009-08-27 | Panasonic Corp | Combined cycle device |
CN101906998A (en) * | 2009-07-31 | 2010-12-08 | 王世英 | Multi-cycle electricity-generation thermodynamic system and implementing method thereof |
CN102679611A (en) * | 2012-04-24 | 2012-09-19 | 李华玉 | Multi-end heat supply first kind absorption type heat pump |
CN105041472A (en) * | 2014-06-09 | 2015-11-11 | 李华玉 | Combined cycle energy supply system |
CN107893685A (en) * | 2016-10-12 | 2018-04-10 | 李华玉 | Either simplex matter Steam Combined Cycle and combined cycle Steam Power Equipment |
CN108119196A (en) * | 2017-12-07 | 2018-06-05 | 李华玉 | Combined circulation power apparatus |
-
2020
- 2020-04-15 CN CN202010329516.6A patent/CN111608754A/en active Pending
- 2020-04-16 US US17/604,396 patent/US20220381159A1/en not_active Abandoned
- 2020-04-16 WO PCT/CN2020/000073 patent/WO2020211475A1/en active Application Filing
Patent Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2002285907A (en) * | 2001-03-27 | 2002-10-03 | Sanyo Electric Co Ltd | Recovery refrigeration system of exhaust heat for micro gas turbine |
JP2009191762A (en) * | 2008-02-15 | 2009-08-27 | Panasonic Corp | Combined cycle device |
CN101906998A (en) * | 2009-07-31 | 2010-12-08 | 王世英 | Multi-cycle electricity-generation thermodynamic system and implementing method thereof |
CN102679611A (en) * | 2012-04-24 | 2012-09-19 | 李华玉 | Multi-end heat supply first kind absorption type heat pump |
CN105041472A (en) * | 2014-06-09 | 2015-11-11 | 李华玉 | Combined cycle energy supply system |
CN107893685A (en) * | 2016-10-12 | 2018-04-10 | 李华玉 | Either simplex matter Steam Combined Cycle and combined cycle Steam Power Equipment |
CN108119196A (en) * | 2017-12-07 | 2018-06-05 | 李华玉 | Combined circulation power apparatus |
Also Published As
Publication number | Publication date |
---|---|
CN111608754A (en) | 2020-09-01 |
US20220381159A1 (en) | 2022-12-01 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
WO2020211472A1 (en) | Single working medium steam combined cycle | |
WO2020215814A1 (en) | Single working medium steam combined cycle | |
WO2020211475A1 (en) | Single working medium steam combined circulation | |
WO2020215813A1 (en) | Single work medium steam combined cycle | |
WO2020211471A1 (en) | Single working-medium steam combined cycle | |
WO2021042647A1 (en) | Single working medium steam combined cycle | |
WO2020215816A1 (en) | Single working medium-vapor combined cycle | |
WO2020211473A1 (en) | Combined steam cycle using single working medium | |
WO2021042648A1 (en) | Single working medium-vapor combined cycle | |
WO2020211474A1 (en) | Single working medium steam combined cycle | |
WO2021042646A1 (en) | Single working medium steam combined cycle | |
WO2021042649A1 (en) | Single working medium steam combined cycle | |
WO2020215815A1 (en) | Single working fluid steam combined cycle | |
WO2021036153A1 (en) | Single working fluid steam combined cycle | |
WO2021036152A1 (en) | Single working medium steam combined cycle | |
WO2020215817A1 (en) | Single working medium vapor combined cycle | |
WO2020248588A1 (en) | Reverse single working medium steam combined cycle | |
WO2021047125A1 (en) | Reverse single-working-medium steam combined cycle | |
WO2020248589A1 (en) | Reverse single working medium steam combined cycle | |
WO2020248591A1 (en) | Reverse single-working-media steam combined cycle | |
WO2021047127A1 (en) | Reverse single-working-medium steam combined cycle | |
WO2020248592A1 (en) | Reverse single working medium steam combined cycle | |
WO2021047126A1 (en) | Reverse single-working-medium steam combined cycle | |
WO2021258718A1 (en) | Second-type single working medium combined cycle | |
WO2021253810A1 (en) | Second-type single working medium combined cycle |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
121 | Ep: the epo has been informed by wipo that ep was designated in this application |
Ref document number: 20790667 Country of ref document: EP Kind code of ref document: A1 |
|
NENP | Non-entry into the national phase |
Ref country code: DE |
|
122 | Ep: pct application non-entry in european phase |
Ref document number: 20790667 Country of ref document: EP Kind code of ref document: A1 |