CN111219215A - Combined cycle power plant - Google Patents

Combined cycle power plant Download PDF

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Publication number
CN111219215A
CN111219215A CN201911130955.8A CN201911130955A CN111219215A CN 111219215 A CN111219215 A CN 111219215A CN 201911130955 A CN201911130955 A CN 201911130955A CN 111219215 A CN111219215 A CN 111219215A
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China
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communicated
heat exchanger
temperature heat
expansion speed
speed increaser
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CN201911130955.8A
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Chinese (zh)
Inventor
李鸿瑞
李华玉
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Individual
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Individual
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01KSTEAM ENGINE PLANTS; STEAM ACCUMULATORS; ENGINE PLANTS NOT OTHERWISE PROVIDED FOR; ENGINES USING SPECIAL WORKING FLUIDS OR CYCLES
    • F01K3/00Plants characterised by the use of steam or heat accumulators, or intermediate steam heaters, therein
    • F01K3/18Plants characterised by the use of steam or heat accumulators, or intermediate steam heaters, therein having heaters
    • F01K3/185Plants characterised by the use of steam or heat accumulators, or intermediate steam heaters, therein having heaters using waste heat from outside the plant
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01KSTEAM ENGINE PLANTS; STEAM ACCUMULATORS; ENGINE PLANTS NOT OTHERWISE PROVIDED FOR; ENGINES USING SPECIAL WORKING FLUIDS OR CYCLES
    • F01K11/00Plants characterised by the engines being structurally combined with boilers or condensers
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01KSTEAM ENGINE PLANTS; STEAM ACCUMULATORS; ENGINE PLANTS NOT OTHERWISE PROVIDED FOR; ENGINES USING SPECIAL WORKING FLUIDS OR CYCLES
    • F01K23/00Plants characterised by more than one engine delivering power external to the plant, the engines being driven by different fluids
    • F01K23/02Plants 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
    • F01K23/06Plants 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 combustion heat from one cycle heating the fluid in another cycle
    • F01K23/065Plants 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 combustion heat from one cycle heating the fluid in another cycle the combustion taking place in an internal combustion piston engine, e.g. a diesel engine
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01KSTEAM ENGINE PLANTS; STEAM ACCUMULATORS; ENGINE PLANTS NOT OTHERWISE PROVIDED FOR; ENGINES USING SPECIAL WORKING FLUIDS OR CYCLES
    • F01K23/00Plants characterised by more than one engine delivering power external to the plant, the engines being driven by different fluids
    • F01K23/02Plants 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
    • F01K23/06Plants 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 combustion heat from one cycle heating the fluid in another cycle
    • F01K23/10Plants 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 combustion heat from one cycle heating the fluid in another cycle with exhaust fluid of one cycle heating the fluid in another cycle
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01KSTEAM ENGINE PLANTS; STEAM ACCUMULATORS; ENGINE PLANTS NOT OTHERWISE PROVIDED FOR; ENGINES USING SPECIAL WORKING FLUIDS OR CYCLES
    • F01K7/00Steam engine plants characterised by the use of specific types of engine; Plants or engines characterised by their use of special steam systems, cycles or processes; Control means specially adapted for such systems, cycles or processes; Use of withdrawn or exhaust steam for feed-water heating
    • F01K7/02Steam engine plants characterised by the use of specific types of engine; Plants or engines characterised by their use of special steam systems, cycles or processes; Control means specially adapted for such systems, cycles or processes; Use of withdrawn or exhaust steam for feed-water heating the engines being of multiple-expansion type
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E20/00Combustion technologies with mitigation potential
    • Y02E20/16Combined cycle power plant [CCPP], or combined cycle gas turbine [CCGT]

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  • 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

The invention provides a combined cycle power device, and belongs to the technical field of energy and power. The condenser is provided with a condensate pipeline which is communicated with the mixing evaporator through a circulating pump, the expansion speed increaser is provided with a steam channel which is communicated with the mixing evaporator, the mixing evaporator is also provided with a steam channel which is respectively communicated with the dual-energy compressor and the expander, the dual-energy compressor is also provided with a steam channel which is communicated with the expansion speed increaser through a high-temperature heat exchanger, and the expander is also provided with a steam channel which is communicated with the condenser; the external part of the expansion speed increaser is provided with an air channel communicated with the internal combustion engine, the external part of the expansion speed increaser is also provided with a fuel channel communicated with the internal combustion engine, the internal combustion engine is also provided with a fuel gas channel communicated with the external part of the expansion speed increaser through a high-temperature heat exchanger, the internal combustion engine is also provided with a cooling medium channel communicated with the external part of the expansion speed increaser, the condenser is also provided with a cooling medium channel communicated with the external part of the expansion speed increaser, the mixing evaporator is also provided with a heat medium channel communicated with the external.

Description

Combined cycle power plant
The technical field is as follows:
the invention belongs to the technical field of energy and power.
Background art:
cold demand, heat demand and power demand are common in human life and production. In the field of power demand technology, the conversion of thermal energy into mechanical energy is an important way to obtain and provide power. In a direct-fired gas-steam combined cycle of high-quality fuel represented by gasoline, diesel and natural gas, high efficiency of converting thermal energy into mechanical energy is the greatest advantage, but there are also problems of complicated apparatus, large manufacturing difficulty and high manufacturing cost. In such combined cycle power plants, the expander, compressor, and heat exchanger are often essential basic and core components; the compressor and the expander are difficult to manufacture, high in material requirement and high in manufacturing cost, which is not beneficial to popularization and application of the combined cycle power device. Therefore, it is sought to replace them with simple components or to simplify the structure of the core components in order to reduce the manufacturing difficulty and cost of the combined cycle power plant.
The invention provides a combined cycle power device which combines an expansion speed increaser and a dual-energy compressor and respectively replaces a main expansion machine and a main compressor on the premise of keeping or effectively improving the heat efficiency of the combined cycle power device and aiming at reducing the manufacturing difficulty and the manufacturing cost of core components of the combined cycle power device.
The invention content is as follows:
the invention mainly aims to provide a combined cycle power device which combines an expansion speed increaser and a dual-energy compressor and replaces a corresponding main compressor and a corresponding main expansion machine, and the specific contents of the invention are set forth in the following sections:
1. the combined cycle power device mainly comprises a compressor, a diffuser pipe, an expander, a spray pipe, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, a mixed evaporator and an internal combustion engine; the condenser is provided with a condensate pipeline which is communicated with the mixed evaporator through a circulating pump, the expander is provided with a steam channel which is communicated with the mixed evaporator through a spray pipe, the mixed evaporator is also provided with a steam channel which is respectively communicated with the compressor through a diffuser pipe and directly communicated with a second expander, the compressor is also provided with a steam channel which is communicated with the expander through a high-temperature heat exchanger, and the second expander is also provided with a steam channel which is communicated with the condenser; the external part of the internal combustion engine is provided with an air channel communicated with the internal combustion engine, the external part of the internal combustion engine is also provided with a fuel channel communicated with the internal combustion engine, the internal combustion engine is also provided with a fuel gas channel communicated with the external part through a high-temperature heat exchanger, the internal combustion engine is also provided with a cooling medium channel communicated with the external part, the condenser is also provided with a cooling medium channel communicated with the external part, the mixing evaporator or the heat medium channel is also communicated with the external part, the expander is connected with the compressor and transmits power, and the expander, the second expander and the internal.
2. The combined cycle power plant mainly comprises an expander, a circulating pump, a high-temperature heat exchanger, a condenser, a mixed evaporator, an internal combustion engine, a dual-energy compressor and an expansion speed increaser; the condenser is provided with a condensate pipeline which is communicated with the mixing evaporator through a circulating pump, the expansion speed increaser is provided with a steam channel which is communicated with the mixing evaporator, the mixing evaporator is also provided with a steam channel which is respectively communicated with the dual-energy compressor and the expander, the dual-energy compressor is also provided with a steam channel which is communicated with the expansion speed increaser through a high-temperature heat exchanger, and the expander is also provided with a steam channel which is communicated with the condenser; the external part of the expansion speed increaser is provided with an air channel communicated with the internal combustion engine, the external part of the expansion speed increaser is also provided with a fuel channel communicated with the internal combustion engine, the internal combustion engine is also provided with a fuel gas channel communicated with the external part of the expansion speed increaser through a high-temperature heat exchanger, the internal combustion engine is also provided with a cooling medium channel communicated with the external part of the expansion speed increaser, the condenser is also provided with a cooling medium channel communicated with the external part of the expansion speed increaser, the mixing evaporator or the mixing evaporator is also provided with a heat medium channel communicated with the.
3. The combined cycle power device mainly comprises a compressor, an expander, a circulating pump, a high-temperature heat exchanger, a condenser, a mixed evaporator, an internal combustion engine, a dual-energy compressor and an expansion speed increaser; the condenser is provided with a condensate pipeline which is communicated with the mixing evaporator through a circulating pump, the expansion speed increaser is provided with a steam channel which is communicated with the mixing evaporator, the mixing evaporator is also provided with a steam channel which is respectively communicated with the dual-energy compressor and the expander, the dual-energy compressor is also provided with a steam channel which is communicated with the expansion speed increaser through a high-temperature heat exchanger, and the expander is also provided with a steam channel which is communicated with the condenser; the external part is provided with an air channel communicated with the internal combustion engine, the external part is also provided with a gaseous fuel channel communicated with the internal combustion engine through a compressor, the internal combustion engine is also provided with a fuel gas channel communicated with the external part through a high-temperature heat exchanger, the internal combustion engine is also provided with a cooling medium channel communicated with the external part, a condenser is also provided with a cooling medium channel communicated with the external part, a mixing evaporator or a thermal medium channel is also communicated with the external part, the internal combustion engine is connected with the compressor and transmits power, an expansion speed increaser is connected with a dual-energy compressor and transmits power, and the expansion machine, the internal combustion engine and the expansion speed.
4. A combined cycle power plant, wherein a newly added compressor and a newly added high temperature heat exchanger are added in any combined cycle power plant of items 2 to 3, a steam channel of a dual-energy compressor is communicated with an expansion speed increaser through the high temperature heat exchanger to adjust that the dual-energy compressor is communicated with the newly added compressor through the high temperature heat exchanger, a steam channel of the newly added compressor is communicated with the expansion speed increaser through the newly added high temperature heat exchanger, a gas channel of an internal combustion engine is communicated with the outside through the high temperature heat exchanger to adjust that the internal combustion engine is communicated with the outside to form a gas channel of the internal combustion engine which is communicated with the outside through the newly added high temperature heat exchanger and the high temperature heat exchanger, and the expansion speed increaser is connected with the newly added compressor.
5. A combined cycle power plant, in any of the combined cycle power plants described in items 2-3, a newly added dual-energy compressor and a newly added high-temperature heat exchanger are added, the dual-energy compressor is adjusted to have a steam channel communicated with an expansion speed increaser through the high-temperature heat exchanger, the dual-energy compressor has a steam channel communicated with the newly added dual-energy compressor through the high-temperature heat exchanger, the newly added dual-energy compressor has a steam channel communicated with the expansion speed increaser through the newly added high-temperature heat exchanger, the internal combustion engine has a gas channel communicated with the outside through the newly added high-temperature heat exchanger and the high-temperature heat exchanger, and the expansion speed increaser is connected with the newly added dual-.
6. A combined cycle power plant, wherein a newly added diffuser pipe and a newly added high temperature heat exchanger are added in any combined cycle power plant of items 2 to 3, the dual-energy compressor is communicated with the expansion speed increaser through the high temperature heat exchanger and adjusted to be communicated with the newly added diffuser pipe through the high temperature heat exchanger, the dual-energy compressor is communicated with the expansion speed increaser through the steam passage, the newly added diffuser pipe is communicated with the expansion speed increaser through the newly added high temperature heat exchanger, the internal combustion engine is communicated with the outside through the high temperature heat exchanger and adjusted to be communicated with the outside through the gas passage, and the internal combustion engine is communicated with the outside through the newly added high temperature heat exchanger and the high temperature heat exchanger to form the combined cycle power plant.
7. A combined cycle power plant, wherein a newly added expander and a newly added high temperature heat exchanger are added in any combined cycle power plant of items 2 to 3, a steam channel of a dual-energy compressor is communicated with an expansion speed increaser through the high temperature heat exchanger and adjusted to be communicated with the new expander through the high temperature heat exchanger, a steam channel of the new expander is communicated with the expansion speed increaser through the newly added high temperature heat exchanger, a gas channel of an internal combustion engine is communicated with the outside through the high temperature heat exchanger and adjusted to be communicated with the outside through the gas channel of the internal combustion engine, and the new expander is connected with the outside and transmits power to form the combined cycle power plant.
8. A combined cycle power plant, wherein a newly added expansion speed increaser and a newly added high-temperature heat exchanger are added in any combined cycle power plant of items 2 to 3, a steam channel of a dual-energy compressor is communicated with the expansion speed increaser through the high-temperature heat exchanger and adjusted to be communicated with the newly added expansion speed increaser through the high-temperature heat exchanger, a steam channel of the newly added expansion speed increaser is communicated with the expansion speed increaser through the newly added high-temperature heat exchanger, a gas channel of an internal combustion engine is communicated with the outside through the high-temperature heat exchanger and adjusted to be communicated with the outside through the gas channel of the internal combustion engine, and the newly added expansion speed increaser is connected with the outside and transmits power to form the combined cycle power plant.
9. A combined cycle power plant, wherein a spray pipe and a new high temperature heat exchanger are added in any combined cycle power plant of items 2 to 3, a steam channel of a dual-energy compressor is communicated with an expansion speed increaser through a high temperature heat exchanger, the dual-energy compressor is adjusted to be communicated with the spray pipe through the high temperature heat exchanger, the spray pipe is communicated with the expansion speed increaser through the new high temperature heat exchanger, a gas channel of an internal combustion engine is adjusted to be communicated with the outside through the high temperature heat exchanger, and the gas channel of the internal combustion engine is communicated with the outside through the new high temperature heat exchanger and the high temperature heat exchanger, so that the combined cycle power plant is formed.
10. A combined cycle power device is characterized in that a heat regenerator is added in any one of the combined cycle power devices in items 2-3, a steam channel of a dual-energy compressor is communicated with an expansion speed increaser through a high-temperature heat exchanger and adjusted to be communicated with the expansion speed increaser through the heat regenerator and the high-temperature heat exchanger, a steam channel of the expansion speed increaser is communicated with a mixed evaporator and adjusted to be communicated with the mixed evaporator through the heat regenerator, and the combined cycle power device is formed.
11. A combined cycle power plant, which is characterized in that a heat regenerator, a newly-increased compressor and a newly-increased high-temperature heat exchanger are added in any combined cycle power plant of items 2 to 3, a steam channel of the double-energy compressor is communicated with an expansion speed increaser through the high-temperature heat exchanger and adjusted to be communicated with the newly-increased compressor through the steam channel of the double-energy compressor, the newly-increased compressor is communicated with the expansion speed increaser through the newly-increased high-temperature heat exchanger, the expansion speed increaser is communicated with a mixed evaporator through the steam channel of the expansion speed increaser and adjusted to be communicated with the mixed evaporator through the heat regenerator, a gas channel of an internal combustion engine is communicated with the outside through the high-temperature heat exchanger and adjusted to be communicated with the outside through the gas channel of the internal combustion engine through the newly-increased high-temperature heat exchanger and the high-temperature heat exchanger, the expansion speed increaser, forming a combined cycle power plant.
12. A combined cycle power plant, in any of the combined cycle power plants described in items 2-3, a heat regenerator, a newly added dual-energy compressor and a newly added high-temperature heat exchanger are added, the dual-energy compressor is communicated with an expansion speed increaser through the high-temperature heat exchanger and adjusted to have a steam passage, the dual-energy compressor is communicated with the newly added dual-energy compressor through the heat regenerator and the high-temperature heat exchanger, the newly added dual-energy compressor is further communicated with the expansion speed increaser through the newly added high-temperature heat exchanger through a steam passage, the expansion speed increaser is communicated with a mixed evaporator through a steam passage and adjusted to have a steam passage, the expansion speed increaser is communicated with the mixed evaporator through the heat regenerator, an internal combustion engine is communicated with the outside through a high-temperature heat exchanger and adjusted to have a gas passage, the internal combustion engine is communicated with the outside through the newly added high-temperature heat exchanger and the high-, forming a combined cycle power plant.
13. A combined cycle power plant, in any of the combined cycle power plants described in items 2-3, a heat regenerator, a newly added diffuser pipe and a newly added high-temperature heat exchanger are added, a steam channel of a dual-energy compressor is communicated with an expansion speed increaser through the high-temperature heat exchanger and adjusted to be communicated with the expansion speed increaser through the heat regenerator and the high-temperature heat exchanger, a steam channel of the newly added diffuser pipe is communicated with the expansion speed increaser through the newly added high-temperature heat exchanger, a steam channel of the expansion speed increaser is communicated with a mixed evaporator to be adjusted to be communicated with the expansion speed increaser through the steam channel, a steam channel of the expansion speed increaser is communicated with the mixed evaporator through the heat regenerator, a gas channel of an internal combustion engine is communicated with the outside through the high-temperature heat exchanger to be adjusted to be communicated with the outside through the gas channel of the.
14. A combined cycle power plant, which is characterized in that a heat regenerator, a new expansion machine and a new high temperature heat exchanger are added in any combined cycle power plant of items 2 to 3, a steam channel of a dual-energy compressor is communicated with an expansion speed increaser through the high temperature heat exchanger and adjusted to be communicated with the new expansion machine through the heat regenerator and the high temperature heat exchanger, a steam channel of the new expansion machine is communicated with the expansion speed increaser through the new high temperature heat exchanger, a steam channel of the expansion speed increaser is communicated with a mixed evaporator and adjusted to be communicated with the mixed evaporator through the heat regenerator, a steam channel of the internal combustion engine is communicated with the outside through the high temperature heat exchanger and adjusted to be communicated with the gas channel of the internal combustion engine through the new high temperature heat exchanger and the high temperature heat exchanger, the new expansion machine is connected with the outside and transmits power, forming a combined cycle power plant.
15. A combined cycle power plant, in any of the combined cycle power plants described in items 2-3, a heat regenerator, a newly added expansion speed increaser and a newly added high temperature heat exchanger are added, a steam channel of a dual-energy compressor is communicated with the expansion speed increaser through the high temperature heat exchanger and adjusted to be communicated with the newly added expansion speed increaser through the heat regenerator and the high temperature heat exchanger, a steam channel of the newly added expansion speed increaser is communicated with the expansion speed increaser through the newly added high temperature heat exchanger, the communication between the expansion speed increaser and a steam channel is adjusted to be communicated with a mixed evaporator through the heat regenerator, the communication between a gas channel of an internal combustion engine and the outside through the high temperature heat exchanger is adjusted to be communicated with the internal combustion engine through the newly added high temperature heat exchanger and the high temperature heat exchanger, the newly added expansion speed increaser is connected with the outside and transmits power, forming a combined cycle power plant.
16. A combined cycle power plant, which is characterized in that a heat regenerator, a spray pipe and a newly-increased high-temperature heat exchanger are added in any combined cycle power plant of items 2 to 3, a steam channel of a dual-energy compressor is communicated with an expansion speed increaser through the high-temperature heat exchanger and adjusted into a dual-energy compressor, the steam channel of the dual-energy compressor is communicated with the spray pipe through the heat regenerator and the high-temperature heat exchanger, the steam channel of the spray pipe is communicated with the expansion speed increaser through the newly-increased high-temperature heat exchanger, the steam channel of the expansion speed increaser is communicated with a mixed evaporator through the mixed evaporator and adjusted into a steam channel of the expansion speed increaser, the steam channel of the expansion speed increaser is communicated with the mixed evaporator through the heat regenerator, a fuel gas channel of an internal combustion engine is communicated with the outside through the.
17. A combined cycle power device is characterized in that a mixed heat regenerator and a second circulating pump are added in any combined cycle power device in items 2 to 16, a condenser with a condensate pipeline communicated with a mixed evaporator through the circulating pump is adjusted to be a condenser with a condensate pipeline communicated with the mixed heat regenerator through the circulating pump, an expander is additionally provided with a steam extraction channel communicated with the mixed heat regenerator, the mixed heat regenerator is further provided with a condensate pipeline communicated with the mixed evaporator through the second circulating pump, and the combined cycle power device is formed.
18. A combined cycle power plant, wherein a preheater is added in any one of the combined cycle power plants described in items 2-16, a condenser with a condensate pipeline communicated with a mixing evaporator through a circulating pump is adjusted to be communicated with the mixing evaporator through the circulating pump and the preheater, and the preheater is also communicated with the outside through a heat medium channel to form the combined cycle power plant.
19. A combined cycle power plant, wherein an intermediate reheater is added to any one of the combined cycle power plants described in items 2 to 16, and the hybrid evaporator having a steam passage communicating with an expander and the expander having a steam passage communicating with a condenser is adjusted such that the hybrid evaporator having a steam passage communicating with the expander, the expander having an intermediate reheated steam passage communicating with the expander through the intermediate reheater and the expander having a steam passage communicating with the condenser, and the intermediate reheater having a heat medium passage communicating with the outside, thereby forming the combined cycle power plant.
20. A combined cycle power plant, in any of the combined cycle power plants described in items 2-19, a cooling medium channel communicated with the outside of an internal combustion engine is cancelled, a newly added circulating pump is added, a condensate pipeline is additionally arranged on a condenser and is communicated with the internal combustion engine through the newly added circulating pump, and then a steam channel of the internal combustion engine is communicated with an expander to form the combined cycle power plant.
21. A combined cycle power plant, in any of the combined cycle power plants described in items 2-19, a cooling medium channel communicated with the outside of the internal combustion engine is cancelled, a newly added circulating pump and a newly added superheater are added, a condensate pipeline additionally arranged on a condenser is communicated with the internal combustion engine through the newly added circulating pump, then a steam channel of the internal combustion engine is communicated with an expander through the newly added superheater, and a heat medium channel of the newly added superheater is communicated with the outside, so that the combined cycle power plant is formed.
Description of the drawings:
FIG. 1 is a schematic 1 st thermodynamic system diagram of a combined cycle power plant according to the present invention.
FIG. 2 is a schematic thermodynamic system diagram of the 2 nd principle of a combined cycle power plant provided in accordance with the present invention.
FIG. 3 is a schematic thermodynamic system diagram of the 3 rd principle of a combined cycle power plant provided in accordance with the present invention.
FIG. 4 is a diagram of a 4 th principal thermodynamic system of a combined cycle power plant provided in accordance with the present invention.
FIG. 5 is a diagram of a 5 th principal thermodynamic system of a combined cycle power plant provided in accordance with the present invention.
FIG. 6 is a 6 th principal thermodynamic system diagram of a combined cycle power plant provided in accordance with the present invention.
FIG. 7 is a 7 th principle thermodynamic system diagram of a combined cycle power plant provided in accordance with the present invention.
FIG. 8 is a diagram of an 8 th principle thermodynamic system of a combined cycle power plant provided in accordance with the present invention.
FIG. 9 is a diagram of a 9 th principal thermodynamic system of a combined cycle power plant provided in accordance with the present invention.
FIG. 10 is a 10 th principal thermodynamic system diagram of a combined cycle power plant provided in accordance with the present invention.
FIG. 11 is a diagram of a principal 11 thermodynamic system of a combined cycle power plant provided in accordance with the present invention.
FIG. 12 is a 12 th principle thermodynamic system diagram of a combined cycle power plant provided in accordance with the present invention.
FIG. 13 is a 13 th principal thermodynamic system diagram of a combined cycle power plant provided in accordance with the present invention.
FIG. 14 is a 14 th principle thermodynamic system diagram of a combined cycle power plant provided in accordance with the present invention.
FIG. 15 is a diagram of a 15 th principal thermodynamic system of a combined cycle power plant provided in accordance with the present invention and considering the recovery of the cooling load of an internal combustion engine.
In the figure, 1-compressor, 2-diffuser pipe, 3-expander, 4-spray pipe, 5-second expander, 6-circulating pump, 7-high temperature heat exchanger, 8-condenser, 9-mixed evaporator, 10-internal combustion engine, 11-dual energy compressor, 12-expansion speed increaser, 13-heat regenerator, 14-mixed heat regenerator, 15-second circulating pump, 16-preheater and 17-intermediate reheater; a-a new booster compressor, B-a new high-temperature heat exchanger, C-a new dual-energy compressor, D-a new booster pipe, E-a new expander, F-a new expander speed increaser, G-a new circulating pump and H-a new superheater.
In order to clearly understand the content and essence of the present invention, the following descriptions will be made for the dual energy compressor, the expansion speed increaser and the expander:
(1) the dual-energy compressor, a device for increasing the pressure of fluid by using the external mechanical energy and the kinetic energy of the fluid, is a combination of the compressor and a diffuser pipe or other devices with the same function.
(2) The expansion speed-increasing machine-under a certain pressure drop, it can implement double functions of pressure-reducing work-making and pressure-reducing speed-increasing, and is a combination body of expansion machine and jet tube or other equipment with identical function.
(3) The second expander 5 in fig. 1 and the expander 3 in fig. 2 to 15 convert the thermal energy of the steam into mechanical energy (pressure reduction work) and also convert the kinetic energy of the steam into mechanical energy (speed reduction work), which is different from the function of a general expander.
The specific implementation mode is as follows:
it is to be noted that, in the description of the structure and the flow, the repetition is not necessary; obvious flow is not described. The invention is described in detail below with reference to the figures and examples.
The combined cycle power plant shown in fig. 1 is implemented as follows:
(1) structurally, the system mainly comprises a compressor, a diffuser pipe, an expander, a spray pipe, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, a mixed evaporator and an internal combustion engine; the condenser 8 has a condensate pipeline which is communicated with a mixing evaporator 9 through a circulating pump 6, the expander 3 has a steam channel which is communicated with the mixing evaporator 9 through a spray pipe 4, the mixing evaporator 9 and the steam channel are respectively communicated with the compressor 1 through a diffuser pipe 2 and directly communicated with the second expander 5, the compressor 1 and the steam channel are communicated with the expander 3 through a high-temperature heat exchanger 7, and the second expander 5 and the steam channel are communicated with the condenser 8; an air channel is arranged outside and communicated with an internal combustion engine 10, a fuel channel is arranged outside and communicated with the internal combustion engine 10, the internal combustion engine 10 and a fuel gas channel are communicated with the outside through a high-temperature heat exchanger 7, the internal combustion engine 10 and a cooling medium channel are communicated with the outside, a condenser 8 and a cooling medium channel are communicated with the outside, a mixing evaporator 9 and a heat medium channel are communicated with the outside, an expander 3 is connected with a compressor 1 and transmits power, and the expander 3, a second expander 5 and the internal combustion engine 10 are connected with the outside and outputs power.
(2) In the process, the condensate of the condenser 8 is boosted by the circulating pump 6 and enters the mixing evaporator 9, the condensate is mixed with the steam from the spray pipe 4 and is vaporized after absorbing the heat load provided by the external heat medium, the saturated or superheated steam released by the mixing evaporator 9 is divided into two paths, the first path flows through the diffuser pipe 2 to be boosted, heated and decelerated and then enters the compressor 1 to be boosted, heated and the second path enters the second expander 5 to be decompressed, work done and decelerated; the steam discharged by the compressor 1 flows through the high-temperature heat exchanger 7 and absorbs heat, flows through the expander 3 to reduce the pressure and do work, flows through the spray pipe 4 to reduce the pressure and increase the speed, and then enters the mixing evaporator 9 to release heat and reduce the temperature; the steam discharged by the second expander 5 enters a condenser 8, releases heat to a cooling medium and is condensed; external fuel and air are introduced into the internal combustion engine 10, a series of processes including combustion and expansion are completed in a cylinder of the internal combustion engine 10, the combustion gas discharged from the internal combustion engine 10 flows through the high-temperature heat exchanger 7 and releases heat, and an external cooling medium flows through the internal combustion engine 10 and absorbs heat and is then discharged to the outside; the fuel provides driving heat load through combustion, the heat medium, namely fuel gas after flowing through the high-temperature heat exchanger 7, and other heat sources or heat source media capable of providing heat load, provide driving heat load through the mixing evaporator 9, the cooling medium takes away low-temperature heat load through the condenser 8, the expander 3 provides power for the compressor 1, and the expander 3, the second expander 5 and the internal combustion engine 10 jointly provide power for the outside to form a combined cycle power device.
The combined cycle power plant shown in fig. 2 is implemented as follows:
(1) structurally, the system mainly comprises an expander, a circulating pump, a high-temperature heat exchanger, a condenser, a mixed evaporator, an internal combustion engine, a dual-energy compressor and an expansion speed increaser; the condenser 8 has a condensate pipeline which is communicated with the mixing evaporator 9 through a circulating pump 6, the expansion speed increaser 12 has a steam channel which is communicated with the mixing evaporator 9, the mixing evaporator 9 also has a steam channel which is respectively communicated with the dual-energy compressor 11 and the expander 3, the dual-energy compressor 11 also has a steam channel which is communicated with the expansion speed increaser 12 through a high-temperature heat exchanger 7, and the expander 3 also has a steam channel which is communicated with the condenser 8; an air channel is arranged outside and communicated with an internal combustion engine 10, a fuel channel is arranged outside and communicated with the internal combustion engine 10, a fuel gas channel of the internal combustion engine 10 is communicated with the outside through a high-temperature heat exchanger 7, a cooling medium channel of the internal combustion engine 10 is communicated with the outside, a cooling medium channel of the condenser 8 is communicated with the outside, a heat medium channel of the mixing evaporator 9 is communicated with the outside, an expansion speed increaser 12 is connected with a dual-energy compressor 11 and transmits power, and the expansion machine 3, the internal combustion engine 10 and the expansion speed increaser 12 are connected with the outside and output power.
(2) In the process, the condensate of the condenser 8 is boosted by the circulating pump 6 and enters the mixing evaporator 9, the condensate is mixed with the steam from the expansion speed increaser 12 and is vaporized after absorbing the heat load provided by the external heat medium, the saturated or superheated steam released by the mixing evaporator 9 enters the dual-energy compressor 11 respectively for boosting and heating and reducing the speed, and the saturated or superheated steam enters the expansion machine 3 for reducing the pressure and doing work and reducing the speed; the steam discharged by the dual-energy compressor 11 flows through the high-temperature heat exchanger 7 and absorbs heat, flows through the expansion speed increaser 12 and performs pressure reduction and work as well as pressure reduction and speed increase, and then enters the mixing evaporator 9 to release heat and reduce temperature; the steam discharged by the expansion machine 3 enters a condenser 8, releases heat to a cooling medium and is condensed; external fuel and air enter the internal combustion engine 10, a series of processes including combustion and expansion are completed in a cylinder of the internal combustion engine 10, fuel gas discharged from the internal combustion engine 10 flows through the high-temperature heat exchanger 7 and releases heat, and external cooling medium flows through the internal combustion engine 10 and discharges outside after absorbing heat; the fuel provides driving heat load through combustion, the heat medium, namely the fuel gas after flowing through the high-temperature heat exchanger 7, and other heat sources or heat source media capable of providing heat load, provide driving heat load through the mixing evaporator 9, the cooling medium takes away the low-temperature heat load through the condenser 8, the expansion speed increaser 12 provides power for the dual-energy compressor 11, and the expansion machine 3, the internal combustion engine 10 and the expansion speed increaser 12 jointly provide power for the outside to form a combined cycle power device.
The combined cycle power plant shown in fig. 3 is implemented as follows:
(1) structurally, the system mainly comprises a compressor, an expander, a circulating pump, a high-temperature heat exchanger, a condenser, a mixing evaporator, an internal combustion engine, a dual-energy compressor and an expansion speed increaser; the condenser 8 has a condensate pipeline which is communicated with the mixing evaporator 9 through a circulating pump 6, the expansion speed increaser 12 has a steam channel which is communicated with the mixing evaporator 9, the mixing evaporator 9 also has a steam channel which is respectively communicated with the dual-energy compressor 11 and the expander 3, the dual-energy compressor 11 also has a steam channel which is communicated with the expansion speed increaser 12 through a high-temperature heat exchanger 7, and the expander 3 also has a steam channel which is communicated with the condenser 8; an air channel is arranged outside and communicated with an internal combustion engine 10, a gaseous fuel channel is arranged outside and communicated with the internal combustion engine 10 through a compressor 1, a fuel gas channel of the internal combustion engine 10 is communicated with the outside through a high-temperature heat exchanger 7, a cooling medium channel of the internal combustion engine 10 is communicated with the outside, a cooling medium channel of a condenser 8 is communicated with the outside, a heat medium channel of a mixing evaporator 9 is communicated with the outside, the internal combustion engine 10 is connected with the compressor 1 and transmits power, an expansion speed increaser 12 is connected with a dual-energy compressor 11 and transmits power, and the expansion machine 3, the internal combustion engine 10 and the expansion speed increaser 12 are connected with the outside and outputs.
(2) In the process, the condensate of the condenser 8 is boosted by the circulating pump 6 and enters the mixing evaporator 9, the condensate is mixed with the steam from the expansion speed increaser 12 and is vaporized after absorbing the heat load provided by the external heat medium, the saturated or superheated steam released by the mixing evaporator 9 enters the dual-energy compressor 11 respectively for boosting and heating and reducing the speed, and the saturated or superheated steam enters the expansion machine 3 for reducing the pressure and doing work and reducing the speed; the steam discharged by the dual-energy compressor 11 flows through the high-temperature heat exchanger 7 and absorbs heat, flows through the expansion speed increaser 12 and performs pressure reduction and work as well as pressure reduction and speed increase, and then enters the mixing evaporator 9 to release heat and reduce temperature; the steam discharged by the expansion machine 3 enters a condenser 8, releases heat to a cooling medium and is condensed; external air enters the internal combustion engine 10, external gaseous fuel enters the internal combustion engine 10 after being pressurized by the compressor 1, the air and the fuel complete a series of processes including combustion and expansion in a cylinder of the internal combustion engine 10, fuel gas discharged by the internal combustion engine 10 flows through the high-temperature heat exchanger 7 and releases heat, and external cooling medium flows through the internal combustion engine 10 and discharges outside after absorbing heat; the fuel provides driving heat load through combustion, the heat medium-fuel gas after flowing through the high-temperature heat exchanger 7, other heat sources or heat source media capable of providing heat load-provide driving heat load through the mixing evaporator 9, the cooling medium takes away low-temperature heat load through the condenser 8, the internal combustion engine 10 provides actuating power for the compressor 1, the expansion speed increaser 12 provides power for the dual-energy compressor 11, and the expansion machine 3, the internal combustion engine 10 and the expansion speed increaser 12 provide power for the outside together to form a combined cycle power device.
The combined cycle power plant shown in fig. 4 is implemented as follows:
(1) structurally, in the combined cycle power plant shown in fig. 2, a newly added compressor and a newly added high-temperature heat exchanger are added, a steam channel of a dual-energy compressor 11 is communicated with an expansion speed increaser 12 through a high-temperature heat exchanger 7, the steam channel of the dual-energy compressor 11 is communicated with a newly added compressor A through the high-temperature heat exchanger 7, the steam channel of the newly added compressor A is communicated with the expansion speed increaser 12 through a newly added high-temperature heat exchanger B, a gas channel of an internal combustion engine 10 is communicated with the outside through the high-temperature heat exchanger 7, the gas channel of the internal combustion engine 10 is communicated with the outside through the newly added high-temperature heat exchanger B and the high-temperature heat exchanger 7, and the expansion speed increaser 12 is.
(2) Compared with the circulation flow of the combined cycle power plant shown in FIG. 2, the difference is that the steam discharged by the dual-energy compressor 11 flows through the high-temperature heat exchanger 7 and absorbs heat, and then enters the newly-added compressor A to increase the pressure and the temperature; the steam discharged by the newly-increased compressor A flows through the newly-increased high-temperature heat exchanger B and absorbs heat, and then enters the expansion speed-increasing machine 12 for pressure reduction and work doing and pressure reduction and speed increase; the gas discharged by the internal combustion engine 10 flows through the newly-added high-temperature heat exchanger B and the high-temperature heat exchanger 7 to gradually release heat and discharge the heat to the outside, and the expansion speed increaser 12 provides power for the newly-added compressor A to form a combined cycle power device.
The combined cycle power plant shown in fig. 5 is implemented as follows:
(1) structurally, in the combined cycle power plant shown in fig. 2, a newly added dual-energy compressor and a newly added high-temperature heat exchanger are added, a steam channel of the dual-energy compressor 11 is communicated with the expansion speed increaser 12 through the high-temperature heat exchanger 7, and is adjusted to be communicated with the newly added dual-energy compressor C through the high-temperature heat exchanger 7, a steam channel of the newly added dual-energy compressor C is communicated with the expansion speed increaser 12 through the newly added high-temperature heat exchanger B, a gas channel of the internal combustion engine 10 is communicated with the outside through the high-temperature heat exchanger 7, and is adjusted to be communicated with the outside through the newly added high-temperature heat exchanger B and the high-temperature heat exchanger 7, and the expansion speed increaser 12 is connected with the newly added dual-energy compressor C.
(2) Compared with the circulation flow of the combined cycle power plant shown in FIG. 2, the difference is that the steam discharged by the dual-energy compressor 11 flows through the high-temperature heat exchanger 7 and absorbs heat, and then enters the newly-added dual-energy compressor C to increase the pressure, raise the temperature and reduce the speed; the steam discharged by the newly added double-energy compressor C flows through the newly added high-temperature heat exchanger B and absorbs heat, and then enters the expansion speed increasing machine 12 to reduce the pressure and do work and reduce the pressure and increase the speed; the gas discharged by the internal combustion engine 10 passes through the newly-added high-temperature heat exchanger B and the high-temperature heat exchanger 7 to gradually release heat and is discharged to the outside, and the expansion speed increaser 12 provides power for the newly-added dual-energy compressor C to form a combined cycle power device.
The combined cycle power plant shown in fig. 6 is implemented as follows:
(1) structurally, in the combined cycle power plant shown in fig. 2, a newly added diffuser pipe and a newly added high temperature heat exchanger are added, the dual energy compressor 11 is communicated with the expansion speed increaser 12 through the high temperature heat exchanger 7 by a steam channel, the dual energy compressor 11 is communicated with the newly added diffuser pipe D through the high temperature heat exchanger 7 by a steam channel, the newly added diffuser pipe D is communicated with the expansion speed increaser 12 through a newly added high temperature heat exchanger B by a steam channel, and the internal combustion engine 10 is communicated with the outside through the high temperature heat exchanger 7 by a gas channel, and the internal combustion engine 10 is communicated with the outside through the newly added high temperature heat exchanger B and the high temperature heat exchanger 7 by a gas channel.
(2) Compared with the circulation flow of the combined cycle power plant shown in fig. 2, the difference in the flow is that the steam discharged by the dual-energy compressor 11 flows through the high-temperature heat exchanger 7 and absorbs heat, and then enters the newly added diffuser pipe D to increase the pressure, raise the temperature and reduce the speed; steam discharged by the newly-added diffuser pipe D flows through the newly-added high-temperature heat exchanger B and absorbs heat, and then enters the expansion speed increaser 12 for pressure reduction work and pressure reduction speed increaser; the fuel gas discharged from the internal combustion engine 10 passes through the newly added high-temperature heat exchanger B and the high-temperature heat exchanger 7 to gradually release heat and is discharged to the outside, thereby forming a combined cycle power device.
The combined cycle power plant shown in fig. 7 is implemented as follows:
(1) structurally, in the combined cycle power plant shown in fig. 2, a new expansion machine and a new high-temperature heat exchanger are added, a steam channel of the dual-energy compressor 11 is communicated with the expansion speed increaser 12 through the high-temperature heat exchanger 7, the steam channel of the dual-energy compressor 11 is communicated with the new expansion machine E through the high-temperature heat exchanger 7, the steam channel of the new expansion machine E is communicated with the expansion speed increaser 12 through the new high-temperature heat exchanger B, a gas channel of the internal combustion engine 10 is communicated with the outside through the high-temperature heat exchanger 7, the gas channel of the internal combustion engine 10 is communicated with the outside through the new high-temperature heat exchanger B and the high-temperature heat exchanger 7, and the new expansion machine E is connected with the outside and transmits.
(2) Compared with the circulation flow of the combined cycle power plant shown in FIG. 2, the difference is that the steam discharged by the dual-energy compressor 11 flows through the high-temperature heat exchanger 7 and absorbs heat, and then enters the new expansion machine E to reduce the pressure and do work; the steam discharged by the newly-added expander E flows through the newly-added high-temperature heat exchanger B and absorbs heat, and then enters the expansion speed increaser 12 for decompression and work doing and decompression and speed increasing; the gas discharged by the internal combustion engine 10 flows through the newly-added high-temperature heat exchanger B and the high-temperature heat exchanger 7 to gradually release heat and discharge the heat to the outside, and the work output by the newly-added expansion machine E is output to the outside to form a combined cycle power device.
The combined cycle power plant shown in fig. 8 is implemented as follows:
(1) structurally, in the combined cycle power plant shown in fig. 2, a newly added expansion speed increaser and a newly added high-temperature heat exchanger are added, a steam channel of a dual-energy compressor 11 is communicated with an expansion speed increaser 12 through a high-temperature heat exchanger 7, the steam channel of the dual-energy compressor 11 is communicated with a newly added expansion speed increaser F through the high-temperature heat exchanger 7, a steam channel of the newly added expansion speed increaser F is communicated with the expansion speed increaser 12 through a newly added high-temperature heat exchanger B, a gas channel of an internal combustion engine 10 is communicated with the outside through the high-temperature heat exchanger 7, the gas channel of the internal combustion engine 10 is communicated with the outside through the newly added high-temperature heat exchanger B and the high-temperature heat exchanger 7, and the newly added expansion.
(2) Compared with the circulation flow of the combined cycle power plant shown in fig. 2, the difference in the flow is that the steam discharged by the dual-energy compressor 11 flows through the high-temperature heat exchanger 7 and absorbs heat, and then enters the newly-added expansion speed increaser F to reduce the pressure and do work and increase the pressure and speed; the steam discharged by the newly-added expansion speed increaser F flows through the newly-added high-temperature heat exchanger B and absorbs heat, and then enters the expansion speed increaser 12 to reduce the pressure and do work and reduce the pressure and increase the speed; the gas discharged by the internal combustion engine 10 flows through the newly added high-temperature heat exchanger B and the high-temperature heat exchanger 7 to gradually release heat and is discharged outwards, and the work output by the newly added expansion speed increaser F is output outwards to form a combined cycle power device.
The combined cycle power plant shown in fig. 9 is implemented as follows:
(1) structurally, in the combined cycle power plant shown in fig. 2, a spray pipe and a new high temperature heat exchanger are added, a steam channel of the dual-energy compressor 11 is communicated with the expansion speed increasing machine 12 through the high temperature heat exchanger 7, the dual-energy compressor 11 is adjusted to be communicated with the spray pipe 4 through the steam channel of the high temperature heat exchanger 7, the spray pipe 4 is further communicated with the expansion speed increasing machine 12 through the new high temperature heat exchanger B, and the internal combustion engine 10 is adjusted to be communicated with the outside through the high temperature heat exchanger 7, the internal combustion engine 10 is provided with a gas channel which is communicated with the outside through the new high temperature heat exchanger B and the high temperature heat exchanger 7.
(2) Compared with the circulation flow of the combined cycle power plant shown in FIG. 2, the difference is that the steam discharged by the dual-energy compressor 11 flows through the high-temperature heat exchanger 7 and absorbs heat, and then enters the spray pipe 4 to be depressurized and accelerated; the steam discharged by the spray pipe 4 flows through the newly-added high-temperature heat exchanger B and absorbs heat, and then enters the expansion speed increaser 12 for decompression and work doing and decompression and speed increasing; the gas discharged by the internal combustion engine 10 flows through the newly-added high-temperature heat exchanger B and the high-temperature heat exchanger 7 to gradually release heat and is discharged to the outside, so that a combined cycle power device is formed.
The combined cycle power plant shown in fig. 10 is implemented as follows:
(1) structurally, in the combined cycle power plant shown in fig. 2, a heat regenerator is added, a steam channel of the dual-energy compressor 11 is communicated with the expansion speed increaser 12 through the high-temperature heat exchanger 7, the steam channel of the dual-energy compressor 11 is communicated with the expansion speed increaser 12 through the heat regenerator 13 and the high-temperature heat exchanger 7, the steam channel of the expansion speed increaser 12 is communicated with the hybrid evaporator 9, and the steam channel of the expansion speed increaser 12 is communicated with the hybrid evaporator 9 through the heat regenerator 13.
(2) Compared with the circulation flow of the combined cycle power device shown in fig. 2, the difference in the flow is that the steam discharged from the dual-energy compressor 11 flows through the heat regenerator 13 and the high-temperature heat exchanger 7 and gradually absorbs heat, flows through the expansion speed increaser 12 to reduce pressure, do work and reduce pressure and increase speed, flows through the heat regenerator 13 to release heat, and then enters the hybrid evaporator 9 to form the combined cycle power device.
The combined cycle power plant shown in FIG. 11 is implemented as follows:
(1) structurally, in the combined cycle power plant shown in fig. 2, a heat regenerator, a newly added diffuser pipe and a newly added high temperature heat exchanger are added, a steam channel of a dual-energy compressor 11 is communicated with an expansion speed increaser 12 through a high temperature heat exchanger 7, the steam channel of the dual-energy compressor 11 is communicated with a newly added diffuser pipe D through the heat regenerator 13 and the high temperature heat exchanger 7, the steam channel of the newly added diffuser pipe D is communicated with the expansion speed increaser 12 through a newly added high temperature heat exchanger B, the steam channel of the expansion speed increaser 12 is communicated with a mixed evaporator 9, the steam channel of the expansion speed increaser 12 is communicated with the mixed evaporator 9 through the heat regenerator 13, the internal combustion engine 10 is adjusted to be communicated with the outside through the high-temperature heat exchanger 7, and the internal combustion engine 10 is adjusted to be communicated with the outside through the newly-added high-temperature heat exchanger B and the high-temperature heat exchanger 7.
(2) Compared with the circulation flow of the combined cycle power plant shown in fig. 2, the difference is that the steam discharged by the dual-energy compressor 11 flows through the heat regenerator 13 and the high-temperature heat exchanger 7 and gradually absorbs heat, and then enters the newly added diffuser pipe D to increase the pressure, raise the temperature and reduce the speed; the steam discharged by the newly added diffuser pipe D flows through the newly added high-temperature heat exchanger B and absorbs heat, flows through the expansion speed increaser 12 to reduce pressure and do work and reduce pressure and increase speed, flows through the heat regenerator 13 and releases heat, and then enters the mixing evaporator 9; the fuel gas discharged from the internal combustion engine 10 passes through the newly added high-temperature heat exchanger B and the high-temperature heat exchanger 7 to gradually release heat and is discharged to the outside, thereby forming a combined cycle power device.
The combined cycle power plant shown in fig. 12 is implemented as follows:
(1) structurally, in the combined cycle power plant shown in fig. 2, a mixed heat regenerator and a second circulating pump are added, a condensate pipeline of a condenser 8 is communicated with a mixed evaporator 9 through a circulating pump 6, the condenser 8 is adjusted to be communicated with the mixed heat regenerator 14 through the circulating pump 6, a steam extraction channel is additionally arranged on an expander 3 and is communicated with the mixed heat regenerator 14, and the mixed heat regenerator 14 is communicated with the mixed evaporator 9 through a condensate pipeline of the second circulating pump 15.
(2) Compared with the circulation flow of the combined cycle power device shown in fig. 2, the difference in the flow is that the condensate of the condenser 8 flows through the circulation pump 6 and enters the hybrid heat regenerator 14 after being boosted, the steam entering the expander 3 is decompressed and does work to a certain pressure and then is divided into two paths, the first path continues to be decompressed and does work and enters the condenser 8 after being decelerated, the second path enters the hybrid heat regenerator 14 through the steam extraction channel to be mixed with the condensate for heat release and condensation, and the condensate of the hybrid heat regenerator 14 enters the hybrid evaporator 9 after being boosted by the second circulation pump 15 to form the combined cycle power device.
The combined cycle power plant shown in fig. 13 is implemented as follows:
in the combined cycle power plant shown in fig. 2, a preheater is added, and a condensate pipeline of the condenser 8 is communicated with the mixing evaporator 9 through the circulating pump 6, so that the condenser 8 is adjusted to be communicated with the mixing evaporator 9 through the circulating pump 6 and the preheater 16, and the preheater 16 is also provided with a heat medium channel communicated with the outside; the condensate of the condenser 8 enters the mixing evaporator 9 after being boosted by the circulating pump 6 and heated by the preheater 16, thus forming a combined cycle power plant.
The combined cycle power plant shown in fig. 14 is implemented as follows:
in the combined cycle power plant shown in fig. 2, an intermediate reheater is added, and the hybrid evaporator 9 having a steam passage communicating with the expander 3 and the expander 3 having a steam passage communicating with the condenser 8 are adjusted such that the hybrid evaporator 9 having a steam passage communicating with the expander 3, the expander 3 having an intermediate reheated steam passage communicating with the expander 3 via the intermediate reheater 17 and the expander 3 having a steam passage communicating with the condenser 8, and the intermediate reheater 17 having a heat medium passage communicating with the outside; when the steam entering the expansion machine 3 is decompressed and does work to a certain pressure, the steam is completely led out and flows through the intermediate reheated steam channel to flow through the intermediate reheater 17 to absorb heat and raise temperature, then enters the expansion machine 3 to be continuously decompressed and does work and reduce speed, and then enters the condenser 8 to release heat and condense to form the combined cycle power device.
The combined cycle power plant shown in fig. 15 is implemented as follows:
(1) structurally, in the combined cycle power plant shown in fig. 2, a cooling medium channel of the internal combustion engine 10 communicated with the outside is cancelled, a newly added circulating pump and a newly added superheater are added, a condensate pipeline is additionally arranged on the condenser 8, the condensate pipeline is communicated with the internal combustion engine 10 through the newly added circulating pump G, then a steam channel of the internal combustion engine 10 is communicated with the expander 3 through the newly added superheater H, and a heat medium channel of the newly added superheater H is communicated with the outside.
(2) Compared with the circulation flow of the combined cycle power plant shown in fig. 2, the difference in the flow is that one path of condensate of the condenser 8 is boosted by the newly added circulation pump G and then supplied to the internal combustion engine 10 as circulating coolant, is vaporized by heat absorption, enters the expansion machine 3 after being heated by the newly added superheater H by heat absorption and then is depressurized and does work, and the heat medium, namely fuel gas discharged by the internal combustion engine 10 or other heat source media, provides heat load to the newly added superheater H to form the combined cycle power plant.
The effect that the technology of the invention can realize-the combined cycle power device provided by the invention has the following effects and advantages:
(1) the dual-energy compressor replaces a main compressor, and the manufacturing difficulty and the manufacturing cost of the combined cycle power device are greatly reduced.
(2) The expansion speed increaser replaces a main expansion machine, so that the manufacturing difficulty and the manufacturing cost of the combined cycle power device are greatly reduced.
(3) The jet pipe or the expansion speed increaser replaces a common expansion machine, so that the manufacturing difficulty and the manufacturing cost of the combined cycle power device are effectively reduced.
(4) The diffuser pipe or the dual-energy compressor replaces a common compressor, and the manufacturing difficulty and the manufacturing cost of the combined cycle power device are effectively reduced.
(5) Simple components replace complex components, which is beneficial to maintaining or improving the thermal efficiency of the combined cycle power plant.
(6) The complex parts are replaced by simple parts and simplified, which is beneficial to improving the safety and service life of the dynamic parts.
(7) A plurality of specific technical schemes are provided, and the device can be used for coping with a plurality of different actual conditions and has a wider application range.
(8) The combined cycle power plant technology is expanded, the types of the combined cycle power plant are enriched, the conversion of heat energy into mechanical energy is favorably realized, and the application range of the combined cycle power plant is expanded.

Claims (21)

1. The combined cycle power device mainly comprises a compressor, a diffuser pipe, an expander, a spray pipe, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, a mixed evaporator and an internal combustion engine; the condenser (8) is provided with a condensate pipeline which is communicated with the mixing evaporator (9) through a circulating pump (6), the expander (3) is provided with a steam channel which is communicated with the mixing evaporator (9) through a spray pipe (4), the mixing evaporator (9) is also provided with a steam channel which is respectively communicated with the compressor (1) through a diffuser pipe (2) and directly communicated with the second expander (5), the compressor (1) is also provided with a steam channel which is communicated with the expander (3) through a high-temperature heat exchanger (7), and the second expander (5) is also provided with a steam channel which is communicated with the condenser (8); an air channel is arranged outside and communicated with an internal combustion engine (10), a fuel channel is arranged outside and communicated with the internal combustion engine (10), a fuel gas channel is arranged in the internal combustion engine (10) and communicated with the outside through a high-temperature heat exchanger (7), a cooling medium channel is arranged in the internal combustion engine (10) and communicated with the outside, a cooling medium channel is arranged in the condenser (8) and communicated with the outside, a mixing evaporator (9) or a heat medium channel is arranged in the mixing evaporator and communicated with the outside, an expander (3) is connected with a compressor (1) and transmits power, and the expander (3), a second expander (5) and the internal combustion engine (10) are connected with the outside and outputs power, so that a combined.
2. The combined cycle power plant mainly comprises an expander, a circulating pump, a high-temperature heat exchanger, a condenser, a mixed evaporator, an internal combustion engine, a dual-energy compressor and an expansion speed increaser; the condenser (8) is provided with a condensate pipeline which is communicated with the mixing evaporator (9) through a circulating pump (6), the expansion speed increaser (12) is provided with a steam channel which is communicated with the mixing evaporator (9), the mixing evaporator (9) is also provided with a steam channel which is respectively communicated with the dual-energy compressor (11) and the expander (3), the dual-energy compressor (11) is also provided with a steam channel which is communicated with the expansion speed increaser (12) through a high-temperature heat exchanger (7), and the expander (3) is also provided with a steam channel which is communicated with the condenser (8); an air channel is arranged outside and communicated with an internal combustion engine (10), a fuel channel is arranged outside and communicated with the outside through a high-temperature heat exchanger (7), a cooling medium channel is arranged in the internal combustion engine (10) and communicated with the outside, a cooling medium channel is arranged in a condenser (8) and communicated with the outside, a mixing evaporator (9) or a heat medium channel is communicated with the outside, an expansion speed increaser (12) is connected with a dual-energy compressor (11) and transmits power, and an expansion machine (3), the internal combustion engine (10) and the expansion speed increaser (12) are connected with the outside and output power to form a combined cycle power device.
3. The combined cycle power device mainly comprises a compressor, an expander, a circulating pump, a high-temperature heat exchanger, a condenser, a mixed evaporator, an internal combustion engine, a dual-energy compressor and an expansion speed increaser; the condenser (8) is provided with a condensate pipeline which is communicated with the mixing evaporator (9) through a circulating pump (6), the expansion speed increaser (12) is provided with a steam channel which is communicated with the mixing evaporator (9), the mixing evaporator (9) is also provided with a steam channel which is respectively communicated with the dual-energy compressor (11) and the expander (3), the dual-energy compressor (11) is also provided with a steam channel which is communicated with the expansion speed increaser (12) through a high-temperature heat exchanger (7), and the expander (3) is also provided with a steam channel which is communicated with the condenser (8); an air channel is arranged outside and communicated with an internal combustion engine (10), a gaseous fuel channel is arranged outside and communicated with the internal combustion engine (10) through a compressor (1), the internal combustion engine (10) is also provided with a fuel gas channel and communicated with the outside through a high-temperature heat exchanger (7), the internal combustion engine (10) is also provided with a cooling medium channel and communicated with the outside, a condenser (8) is also provided with a cooling medium channel and communicated with the outside, a mixing evaporator (9) or a heat medium channel is communicated with the outside, the internal combustion engine (10) is connected with the compressor (1) and transmits power, an expansion speed increaser (12) is connected with a dual-energy compressor (11) and transmits power, and an expander (3), the internal combustion engine (10) and the expansion speed increaser (12) are connected with the.
4. A combined cycle power plant, which is characterized in that a newly-added compressor and a newly-added high-temperature heat exchanger are added in any combined cycle power plant of claims 2 to 3, a dual-energy compressor (11) is communicated with an expansion speed increaser (12) through a high-temperature heat exchanger (7) and is adjusted to be that the dual-energy compressor (11) is provided with a steam channel and is communicated with the newly-added compressor through the high-temperature heat exchanger (7)
(A) The newly-increased compressor (A) is communicated with the expansion speed increaser (12) through a steam channel of the newly-increased high-temperature heat exchanger (B), the communication between the gas channel of the internal combustion engine (10) and the outside through the high-temperature heat exchanger (7) is adjusted to be the communication between the gas channel of the internal combustion engine (10) and the outside through the newly-increased high-temperature heat exchanger (B) and the high-temperature heat exchanger (7), and the expansion speed increaser (12) is connected with the newly-increased compressor (A) and transmits power to form a combined cycle power device.
5. A combined cycle power plant, which is characterized in that in any combined cycle power plant of claims 2-3, a newly added dual-energy compressor and a newly added high-temperature heat exchanger are added, a steam channel of the dual-energy compressor (11) is communicated with an expansion speed increaser (12) through a high-temperature heat exchanger (7) and adjusted to be communicated with a newly added dual-energy compressor (C) through the high-temperature heat exchanger (7) and the steam channel of the newly added dual-energy compressor (C) is communicated with the expansion speed increaser (12) through the newly added high-temperature heat exchanger (B), a gas channel of an internal combustion engine (10) is communicated with the outside through the high-temperature heat exchanger (7) and adjusted to be communicated with the outside through the gas channel of the internal combustion engine (10) through the newly added high-temperature heat exchanger (B) and the high-temperature heat exchanger (7), the expansion speed increaser (12) is connected with the newly added dual-energy compressor (, forming a combined cycle power plant.
6. A combined cycle power device is characterized in that a newly added diffuser pipe and a newly added high-temperature heat exchanger are added in any combined cycle power device of claims 2 to 3, a steam channel of a dual-energy compressor (11) is communicated with an expansion speed increaser (12) through a high-temperature heat exchanger (7) and adjusted to be communicated with a newly added diffuser pipe (D) through the high-temperature heat exchanger (7) and the steam channel of the newly added diffuser pipe (D) is communicated with the expansion speed increaser (12) through a newly added high-temperature heat exchanger (B), a gas channel of an internal combustion engine (10) is communicated with the outside through the high-temperature heat exchanger (7) and adjusted to be communicated with the outside through the gas channel of the internal combustion engine (10) through the newly added high-temperature heat exchanger (B) and the high-temperature heat exchanger (7), and the combined cycle power device is formed.
7. A combined cycle power plant as claimed in any one of claims 2 to 3, a new expansion machine and a new high-temperature heat exchanger are added, a steam channel of a dual-energy compressor (11) is communicated with an expansion speed increasing machine (12) through a high-temperature heat exchanger (7) and adjusted to be communicated with the expansion speed increasing machine (12) through the steam channel of the dual-energy compressor (11) through the high-temperature heat exchanger (7), the steam channel of the new expansion machine (E) is communicated with the expansion speed increasing machine (12) through a new high-temperature heat exchanger (B), a gas channel of an internal combustion engine (10) is communicated with the outside through the high-temperature heat exchanger (7) and adjusted to be communicated with the outside through the gas channel of the internal combustion engine (10) through the new high-temperature heat exchanger (B) and the high-temperature heat exchanger (7), and the new expansion machine (E) is connected with the outside and transmits power to form a combined.
8. A combined cycle power plant, which is characterized in that in any combined cycle power plant of claims 2-3, a newly added expansion speed increaser and a newly added high temperature heat exchanger are added, a steam channel of a dual energy compressor (11) is communicated with the expansion speed increaser (12) through the high temperature heat exchanger (7) and adjusted to be communicated with the newly added expansion speed increaser (F) through the high temperature heat exchanger (7) and the steam channel of the newly added expansion speed increaser (F) is communicated with the expansion speed increaser (12) through the newly added high temperature heat exchanger (B), a gas channel of an internal combustion engine (10) is communicated with the outside through the high temperature heat exchanger (7) and adjusted to be communicated with the outside through the gas channel of the internal combustion engine (10) through the newly added high temperature heat exchanger (B) and the high temperature heat exchanger (7), the newly added expansion speed increaser (F) is connected with the outside and transmits power, forming a combined cycle power plant.
9. A combined cycle power device is characterized in that a spray pipe and a new increased high-temperature heat exchanger are added in any combined cycle power device of claims 2-3, a steam channel of a dual-energy compressor (11) is communicated with an expansion speed increaser (12) through a high-temperature heat exchanger (7) and adjusted to be communicated with the spray pipe (4) through the high-temperature heat exchanger (7) and the steam channel of the dual-energy compressor (11), the steam channel of the spray pipe (4) is communicated with the expansion speed increaser (12) through a new increased high-temperature heat exchanger (B), a gas channel of an internal combustion engine (10) is communicated with the outside through the high-temperature heat exchanger (7) and adjusted to be communicated with the outside through the gas channel of the internal combustion engine (10) through the new increased high-temperature heat exchanger (B) and the high-temperature heat exchanger (.
10. A combined cycle power device is characterized in that a heat regenerator is added in any combined cycle power device of claims 2-3, a steam channel of a dual-energy compressor (11) is communicated with an expansion speed increaser (12) through a high-temperature heat exchanger (7) and adjusted to be communicated with the expansion speed increaser (12) through a heat regenerator (13) and the high-temperature heat exchanger (7), a steam channel of the expansion speed increaser (12) is communicated with a hybrid evaporator (9) and adjusted to be communicated with the hybrid evaporator (9) through the heat regenerator (13) and a steam channel of the expansion speed increaser (12) is communicated with the hybrid evaporator (9), so that the combined cycle power device is formed.
11. A combined cycle power plant, in any one of the combined cycle power plants of claims 2-3, a heat regenerator, a newly-added compressor and a newly-added high temperature heat exchanger are added, a steam channel of the dual-energy compressor (11) is communicated with the expansion speed increaser (12) through the high temperature heat exchanger (7) and is adjusted to be communicated with the newly-added compressor (A) through the heat regenerator (13) and the high temperature heat exchanger (7), a steam channel of the newly-added compressor (A) is communicated with the expansion speed increaser (12) through the newly-added high temperature heat exchanger (B), a steam channel of the expansion speed increaser (12) is communicated with the hybrid evaporator (9) and is adjusted to be communicated with the hybrid evaporator (9) through the heat regenerator (13), a gas channel of the internal combustion engine (10) is communicated with the outside through the high temperature heat exchanger (7) and is adjusted to be communicated with the internal combustion engine (10) through the newly-added high temperature heat exchanger (B) And the high-temperature heat exchanger (7) is communicated with the outside, and the expansion speed increaser (12) is connected with the newly-increased compressor (A) and transmits power to form a combined cycle power device.
12. A combined-cycle power plant, which is characterized in that in any combined-cycle power plant of claims 2-3, a heat regenerator, a newly added dual-energy compressor and a newly added high-temperature heat exchanger are added, a steam channel of the dual-energy compressor (11) is communicated with an expansion speed increaser (12) through the high-temperature heat exchanger (7) and adjusted to be a steam channel of the dual-energy compressor (11) is communicated with a newly added dual-energy compressor (C) through the heat regenerator (13) and the high-temperature heat exchanger (7), the newly added dual-energy compressor (C) is further communicated with the expansion speed increaser (12) through a newly added high-temperature heat exchanger (B), a steam channel of the expansion speed increaser (12) is communicated with a hybrid evaporator (9) and adjusted to be a steam channel of the expansion speed increaser (12) is communicated with the hybrid evaporator (9) through the heat regenerator (13), a gas channel of the internal combustion engine (10) is communicated with the outside through the high-temperature heat exchanger (7) and adjusted to be a gas The exchanger (B) and the high-temperature heat exchanger (7) are communicated with the outside, and the expansion speed increaser (12) is connected with the newly-increased double-energy compressor (C) and transmits power to form a combined cycle power device.
13. A combined cycle power plant, in any one of the combined cycle power plants of claims 2-3, a heat regenerator, a newly added diffuser pipe and a newly added high temperature heat exchanger are added, a steam channel of a dual energy compressor (11) is communicated with an expansion speed increaser (12) through a high temperature heat exchanger (7) and adjusted to be that the dual energy compressor (11) is provided with a steam channel which is communicated with the newly added diffuser pipe (D) through the heat regenerator (13) and the high temperature heat exchanger (7), the newly added diffuser pipe (D) is further provided with a steam channel which is communicated with the expansion speed increaser (12) through the newly added high temperature heat exchanger (B), the expansion speed increaser (12) is provided with a steam channel which is communicated with a hybrid evaporator (9) and adjusted to be that the expansion speed increaser (12) is provided with a steam channel which is communicated with the hybrid evaporator (9) through the heat regenerator (13), and an internal combustion engine (10) is provided with a gas channel which is communicated with the outside through the high temperature heat exchanger (7) and and the high-temperature heat exchanger (7) is communicated with the outside to form a combined cycle power device.
14. A combined-cycle power plant, in any one of the combined-cycle power plants of claims 2-3, a regenerator, a new expansion machine and a new high-temperature heat exchanger are added, a steam channel of a dual-energy compressor (11) is communicated with an expansion speed-increasing machine (12) through a high-temperature heat exchanger (7) and adjusted to be that the dual-energy compressor (11) is communicated with the new expansion machine (E) through the regenerator (13) and the high-temperature heat exchanger (7) and adjusted to be that the steam channel of the dual-energy compressor (11) is communicated with the new expansion machine (E) through the regenerator (13) and the high-temperature heat exchanger (7), the new expansion machine (E) is further communicated with the expansion speed-increasing machine (12) through the new high-temperature heat exchanger (B), the expansion speed-increasing machine (12) is communicated with a hybrid evaporator (9) and adjusted to be that the expansion speed-increasing machine (12) is provided with a steam channel which is communicated with the hybrid evaporator (9) through the regenerator (13), and an internal combustion engine (10) is provided And the high-temperature heat exchanger (7) is communicated with the outside, and the new expansion machine (E) is connected with the outside and transmits power to form a combined cycle power device.
15. A combined-cycle power plant, which is characterized in that in any combined-cycle power plant of claims 2-3, a heat regenerator, a newly added expansion speed increaser and a newly added high-temperature heat exchanger are added, a steam channel of a dual-energy compressor (11) is communicated with the expansion speed increaser (12) through the high-temperature heat exchanger (7) and adjusted to be that the dual-energy compressor (11) is provided with a steam channel which is communicated with the newly added expansion speed increaser (F) through the heat regenerator (13) and the high-temperature heat exchanger (7), the newly added expansion speed increaser (F) is further provided with a steam channel which is communicated with the expansion speed increaser (12) through the newly added high-temperature heat exchanger (B), the expansion speed increaser (12) is provided with a steam channel which is communicated with the hybrid evaporator (9) through the expansion speed increaser (12) and adjusted to be that the expansion speed increaser (12) is provided with the hybrid evaporator (9) through the heat regenerator (13), and an internal combustion engine (10) is provided The exchanger (B) and the high-temperature heat exchanger (7) are communicated with the outside, and the newly-added expansion speed increaser (F) is connected with the outside and transmits power to form a combined cycle power device.
16. A combined cycle power plant, in any one of the combined cycle power plants of claims 2-3, a heat regenerator, a spray pipe and a newly-increased high temperature heat exchanger are added, a steam channel of a dual-energy compressor (11) is communicated with an expansion speed increaser (12) through a high temperature heat exchanger (7) and adjusted to be communicated with the spray pipe (4) through the heat regenerator (13) and the high temperature heat exchanger (7), a steam channel of the spray pipe (4) is communicated with the expansion speed increaser (12) through a newly-increased high temperature heat exchanger (B), a steam channel of the expansion speed increaser (12) is communicated with a hybrid evaporator (9) and adjusted to be communicated with the hybrid evaporator (9) through the heat regenerator (13), a gas channel of an internal combustion engine (10) is communicated with the outside through the high temperature heat exchanger (7) and adjusted to be communicated with the internal combustion engine (10) through the newly-increased high temperature heat exchanger (B) and the high temperature heat exchanger (7) ) And is communicated with the outside to form a combined cycle power device.
17. A combined cycle power device is characterized in that a mixed heat regenerator and a second circulating pump are added in any combined cycle power device of claims 2 to 16, a condenser (8) is provided with a condensate pipeline which is communicated with a mixed evaporator (9) through a circulating pump (6) and is adjusted to be that the condenser (8) is provided with a condensate pipeline which is communicated with the mixed heat regenerator (14) through the circulating pump (6), an expander (3) is additionally provided with a steam extraction channel which is communicated with the mixed heat regenerator (14), and the mixed heat regenerator (14) is further provided with a condensate pipeline which is communicated with the mixed evaporator (9) through the second circulating pump (15), so that the combined cycle power device is formed.
18. A combined cycle power plant, which is characterized in that a preheater is added in any combined cycle power plant of claims 2 to 16, a condenser (8) is provided with a condensate pipeline which is communicated with a mixing evaporator (9) through a circulating pump (6) and is adjusted to be that the condenser (8) is provided with a condensate pipeline which is communicated with the mixing evaporator (9) through the circulating pump (6) and the preheater (16), and the preheater (16) is also provided with a heat medium channel which is communicated with the outside to form the combined cycle power plant.
19. A combined cycle power plant, wherein an intermediate reheater is added to any of the combined cycle power plants described in claims 2 to 16, the hybrid evaporator (9) having a steam passage communicating with the expander (3) and the expander (3) having a steam passage communicating with the condenser (8) is adjusted such that the hybrid evaporator (9) having a steam passage communicating with the expander (3), the expander (3) having an intermediate reheated steam passage communicating with the expander (3) through the intermediate reheater (17), the expander (3) having a steam passage communicating with the condenser (8), the intermediate reheater (17) and the heat medium passage communicating with the outside, thereby forming a combined cycle power plant.
20. A combined cycle power device is characterized in that in any combined cycle power device of claims 2-19, a cooling medium channel communicated with the outside of an internal combustion engine (10) is eliminated, a newly-added circulating pump is added, a condensate pipeline is additionally arranged on a condenser (8) and is communicated with the internal combustion engine (10) through the newly-added circulating pump (G), and then a steam channel of the internal combustion engine (10) is communicated with an expander (3) to form the combined cycle power device.
21. A combined cycle power device is characterized in that in any combined cycle power device of claims 2-19, a cooling medium channel communicated with the outside of an internal combustion engine (10) is eliminated, a newly-added circulating pump and a newly-added superheater are added, a condensate pipeline additionally arranged on a condenser (8) is communicated with the internal combustion engine (10) through the newly-added circulating pump (G), then a steam channel of the internal combustion engine (10) is communicated with an expander (3) through the newly-added superheater (H), and a heat medium channel of the newly-added superheater (H) is communicated with the outside to form the combined cycle power device.
CN201911130955.8A 2018-11-15 2019-11-09 Combined cycle power plant Pending CN111219215A (en)

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