CN111608751A - Combined cycle power plant - Google Patents

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, a steam channel of the evaporator is communicated with the high-temperature heat exchanger after the condensate pipeline is communicated with the evaporator through a circulating pump, a steam channel of the compressor is communicated with the high-temperature heat exchanger, a steam channel of the high-temperature heat exchanger is communicated with the expander, a low-pressure steam channel of the expander is communicated with the evaporator, a low-pressure steam channel of the evaporator is communicated with the compressor and the second expander respectively, and a low-pressure steam channel of the second expander is communicated with the condenser; the high-temperature heat exchanger is also provided with a heat source medium channel communicated with the outside, the condenser is also provided with a cooling medium channel communicated with the outside, the evaporator is also provided with a heat source medium channel communicated with the outside, and the expander and the second expander are connected with the compressor and transmit power to form a combined cycle power device.

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, which are common in human life and production; among them, the conversion of thermal energy into mechanical energy is an important way to obtain and provide power. In general, the temperature of the heat source decreases with the release of heat, and the heat source is variable. When fossil fuel is used as a source energy source, the heat source has the dual characteristics of high temperature and variable temperature, so that a power device based on single thermodynamic cycle is difficult to convert more heat energy into mechanical energy; for high-quality fuel, high thermal efficiency can be obtained by adopting the traditional gas-steam combined cycle, but the problems of high manufacturing cost, large investment, thermal efficiency to be improved and the like still exist.

Taking an external combustion type steam power device as an example, a heat source of the external combustion type steam power device belongs to a high-temperature and variable-temperature heat source; when Rankine cycle is taken as a theoretical basis and steam is taken as a cycle working medium to realize thermal power conversion, the limitation of temperature resistance, pressure resistance and safety of materials is applied, so that no matter what parameters are adopted for operation, large temperature difference loss exists between the cycle working medium and a heat source, irreversible loss is large, the heat efficiency is low, and the potential for improving the heat efficiency is great.

People need to simply, actively, safely and efficiently utilize heat energy to obtain power, and therefore the combined cycle steam power plant has the advantages of high heat efficiency, high safety, adaptability to high-temperature heat sources or variable-temperature heat sources and capability of coping with various fuels.

The invention content is as follows:

the invention mainly aims to provide a combined cycle power plant, and the specific contents are set forth in the following sections:

1. the combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser and an evaporator; the condenser is provided with a condensate pipeline, a steam channel of the evaporator is communicated with the high-temperature heat exchanger after the condensate pipeline is communicated with the evaporator through a circulating pump, a steam channel of the compressor is communicated with the high-temperature heat exchanger, a steam channel of the high-temperature heat exchanger is communicated with the expander, a low-pressure steam channel of the expander is communicated with the evaporator, a low-pressure steam channel of the evaporator is communicated with the compressor and the second expander respectively, and a low-pressure steam channel of the second expander is communicated with the condenser; the high-temperature heat exchanger is also provided with a heat source medium channel communicated with the outside, the condenser is also provided with a cooling medium channel communicated with the outside, the evaporator or the heat source medium channel is also communicated with the outside, and the expander and the second expander are connected with the compressor and transmit power to form a combined cycle power device; wherein, or the expander and the second expander are connected with the compressor and the circulating pump and transmit power.

2. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a heat supplier; the condenser is provided with a condensate pipeline, the evaporator is communicated with a high-temperature heat exchanger through a steam channel after the condensate pipeline is communicated with the evaporator through a circulating pump, the compressor is provided with a steam channel communicated with the high-temperature heat exchanger, the high-temperature heat exchanger is also communicated with an expander through a steam channel, the expander is also provided with a low-pressure steam channel, the heat supply device is provided with a low-pressure steam channel which is communicated with the compressor and a second expander respectively, and the second expander is also provided with a low-pressure steam channel communicated with the condenser; the high-temperature heat exchanger is also provided with a heat source medium channel communicated with the outside, the condenser is also provided with a cooling medium channel communicated with the outside, the evaporator is also provided with a heat source medium channel communicated with the outside, the heat supply device is also provided with a heated medium channel communicated with the outside, and the expander and the second expander are connected with the compressor and transmit power to form a combined cycle power device; wherein, or the expander and the second expander are connected with the compressor and the circulating pump and transmit power.

3. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a high-temperature heat regenerator; the condenser is provided with a condensate pipeline, a steam channel of the evaporator is communicated with a high-temperature heat exchanger through a high-temperature heat regenerator after the condensate pipeline is communicated with the evaporator through a circulating pump, a steam channel of the compressor is communicated with the high-temperature heat exchanger through the high-temperature heat regenerator, a steam channel of the high-temperature heat exchanger is also communicated with an expander, a low-pressure steam channel of the expander is also communicated with the high-temperature heat regenerator, a low-pressure steam channel of the evaporator is communicated with the compressor and a second expander respectively after the high-temperature heat regenerator is also communicated with the evaporator, and the low-pressure steam channel of the second expander is also communicated with the condenser; the high-temperature heat exchanger is also provided with a heat source medium channel communicated with the outside, the condenser is also provided with a cooling medium channel communicated with the outside, the evaporator or the heat source medium channel is also communicated with the outside, and the expander and the second expander are connected with the compressor and transmit power to form a combined cycle power device; wherein, or the expander and the second expander are connected with the compressor and the circulating pump and transmit power.

4. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a second high-temperature heat exchanger; the condenser is provided with a condensate pipeline, a steam channel of the evaporator is communicated with a second high-temperature heat exchanger after the condensate pipeline is communicated with the evaporator through a circulating pump, the second high-temperature heat exchanger is also provided with a steam channel which is communicated with an expander, the compressor is provided with a steam channel which is communicated with the high-temperature heat exchanger, the high-temperature heat exchanger is also provided with a steam channel which is communicated with the expander through a middle steam inlet channel, the expander is also provided with a low-pressure steam channel which is communicated with the evaporator, a low-pressure steam channel of the evaporator is communicated with the compressor and the second expander respectively, and the second expander is also provided with a low; the high-temperature heat exchanger and the second high-temperature heat exchanger are also respectively provided with a heat source medium channel communicated with the outside, the condenser is also provided with a cooling medium channel communicated with the outside, the evaporator or the heat source medium channel is also communicated with the outside, and the expander and the second expander are connected with the compressor and transmit power to form a combined cycle power device; wherein, or the expander and the second expander are connected with the compressor and the circulating pump and transmit power.

5. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser and an evaporator; the condenser is provided with a condensate pipeline, a middle steam inlet channel and a steam channel, wherein the condensate pipeline is communicated with the evaporator through a circulating pump, the steam channel of the evaporator is communicated with the expander through the middle steam inlet channel, the steam channel of the compressor is communicated with the expander through a high-temperature heat exchanger, the expander is also provided with a low-pressure steam channel, the low-pressure steam channel of the evaporator is communicated with the evaporator, the low-pressure steam channel of the evaporator is respectively communicated with the compressor and a second expander, and the low-pressure steam channel of the second expander is communicated with; the high-temperature heat exchanger is also provided with a heat source medium channel communicated with the outside, the condenser is also provided with a cooling medium channel communicated with the outside, the evaporator or the heat source medium channel is also communicated with the outside, and the expander and the second expander are connected with the compressor and transmit power to form a combined cycle power device; wherein, or the expander and the second expander are connected with the compressor and the circulating pump and transmit power.

6. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a high-temperature heat regenerator; the condenser is provided with a condensate pipeline, a steam channel of the evaporator is communicated with the expander through a middle steam inlet channel after the condensate pipeline is communicated with the evaporator through a circulating pump, the compressor is provided with a steam channel which is communicated with the expander through a high-temperature heat regenerator and a high-temperature heat exchanger, the expander is also provided with a low-pressure steam channel which is communicated with the high-temperature heat regenerator, the low-pressure steam channel of the evaporator is communicated with the compressor and a second expander respectively after the high-temperature heat regenerator is also communicated with the evaporator, and the low-pressure steam channel of the second expander is also communicated with the condenser; the high-temperature heat exchanger is also provided with a heat source medium channel communicated with the outside, the condenser is also provided with a cooling medium channel communicated with the outside, the evaporator or the heat source medium channel is also communicated with the outside, and the expander and the second expander are connected with the compressor and transmit power to form a combined cycle power device; wherein, or the expander and the second expander are connected with the compressor and the circulating pump and transmit power.

7. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a third expander; the condenser is provided with a condensate pipeline, the evaporator is communicated with a third expander through a steam channel after the condensate pipeline is communicated with the evaporator through a circulating pump, the third expander is also communicated with the evaporator through a low-pressure steam channel, the compressor is provided with a steam channel which is communicated with the expander through a high-temperature heat exchanger, the expander is also provided with a low-pressure steam channel which is communicated with the evaporator, the evaporator is also provided with a low-pressure steam channel which is respectively communicated with the compressor and a second expander, and the second expander is also provided with a low-pressure steam channel which is communicated with the condenser; the high-temperature heat exchanger is also provided with a heat source medium channel communicated with the outside, the condenser is also provided with a cooling medium channel communicated with the outside, the evaporator or the heat source medium channel is also communicated with the outside, and the expander, the second expander and the third expander are connected with the compressor and transmit power to form a combined cycle power device; wherein, or expander, second expander and third expander are connected compressor and circulating pump and are transmitted power.

8. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a heat supplier; the condenser is provided with a condensate pipeline, a steam channel of the evaporator is communicated with the high-temperature heat exchanger after the condensate pipeline is communicated with the evaporator through a circulating pump, a steam channel of the compressor is communicated with the high-temperature heat exchanger, a steam channel of the high-temperature heat exchanger is communicated with the expander, a low-pressure steam channel of the expander is communicated with the evaporator, a low-pressure steam channel of the evaporator is communicated with a heat supply device, the heat supply device is also provided with a low-pressure steam channel which is respectively communicated with the compressor and the second expander, and the low-pressure steam channel of the second expander is communicated with the condenser; the high-temperature heat exchanger is also provided with a heat source medium channel communicated with the outside, the condenser is also provided with a cooling medium channel communicated with the outside, the evaporator or the heat source medium channel is also communicated with the outside, the heat supply device is also provided with a heated medium channel communicated with the outside, and the expander and the second expander are connected with the compressor and transmit power to form a combined cycle power device; wherein, or the expander and the second expander are connected with the compressor and the circulating pump and transmit power.

9. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator, a second high-temperature heat exchanger and a second compressor; the condenser is provided with a condensate pipeline, a steam channel of the evaporator is communicated with the high-temperature heat exchanger after the condensate pipeline is communicated with the evaporator through a circulating pump, the compressor is provided with a steam channel communicated with the high-temperature heat exchanger, the high-temperature heat exchanger is also provided with a steam channel communicated with a second compressor, the second compressor is also provided with a steam channel communicated with the expander through a second high-temperature heat exchanger, the expander is also provided with a low-pressure steam channel, a low-pressure steam channel of the evaporator is communicated with the compressor and the second expander respectively, and the second expander is also provided with a low-pressure steam channel communicated with the condenser; the high-temperature heat exchanger and the second high-temperature heat exchanger are also respectively provided with a heat source medium channel communicated with the outside, the condenser is also provided with a cooling medium channel communicated with the outside, the evaporator or the heat source medium channel is also communicated with the outside, and the expander and the second expander are connected with the compressor and the second compressor and transmit power to form a combined cycle power device; wherein, or expander and second expander are connected compressor, circulating pump and second compressor and are transmitted power.

10. The combined cycle power plant mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator, a second high-temperature heat exchanger and a third expander; the condenser is provided with a condensate pipeline, a steam channel of the evaporator is communicated with the high-temperature heat exchanger after the condensate pipeline is communicated with the evaporator through a circulating pump, a steam channel of the compressor is communicated with the high-temperature heat exchanger, a steam channel of the high-temperature heat exchanger is communicated with a third expander, the steam channel of the third expander is communicated with the expander through a second high-temperature heat exchanger, a low-pressure steam channel of the evaporator is communicated with the evaporator, a low-pressure steam channel of the expander is communicated with the compressor and the second expander respectively, and a low-pressure steam channel of the second expander is communicated with the condenser; the high-temperature heat exchanger and the second high-temperature heat exchanger are also respectively provided with a heat source medium channel communicated with the outside, the condenser is also provided with a cooling medium channel communicated with the outside, the evaporator or the heat source medium channel is also communicated with the outside, and the expander, the second expander and the third expander are connected with the compressor and transmit power to form a combined cycle power device; wherein, or expander, second expander and third expander are connected compressor and circulating pump and are transmitted power.

11. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator, a high-temperature heat regenerator, a second high-temperature heat exchanger and a second compressor; the condenser is provided with a condensate pipeline, a steam channel of the evaporator is communicated with a high-temperature heat exchanger through a high-temperature heat regenerator after the condensate pipeline is communicated with the evaporator through a circulating pump, the compressor is provided with a steam channel which is communicated with the high-temperature heat exchanger through the high-temperature heat regenerator, the high-temperature heat exchanger is also communicated with a second compressor, the second compressor is also provided with a steam channel which is communicated with an expander through the second high-temperature heat exchanger, the expander is also provided with a low-pressure steam channel, a low-pressure steam channel of the evaporator is communicated with the compressor and the second expander through the high-temperature heat regenerator, and the second expander is also provided with a low-pressure steam channel which; the high-temperature heat exchanger and the second high-temperature heat exchanger are also respectively provided with a heat source medium channel communicated with the outside, the condenser is also provided with a cooling medium channel communicated with the outside, the evaporator or the heat source medium channel is also communicated with the outside, and the expander and the second expander are connected with the compressor and the second compressor and transmit power to form a combined cycle power device; wherein, or expander and second expander are connected compressor, second compressor and circulating pump and are transmitted power.

12. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator, a high-temperature heat regenerator, a second high-temperature heat exchanger and a third expander; the condenser is provided with a condensate pipeline, a steam channel of the evaporator is communicated with a high-temperature heat exchanger through a high-temperature heat regenerator after the condensate pipeline is communicated with the evaporator through a circulating pump, a steam channel of the compressor is communicated with the high-temperature heat exchanger through the high-temperature heat regenerator, a steam channel of the high-temperature heat exchanger is communicated with a third expander, the third expander is also communicated with the expander through a second high-temperature heat exchanger, a low-pressure steam channel of the evaporator is communicated with the evaporator through the high-temperature heat regenerator and is respectively communicated with the compressor and the second expander, and a low-pressure steam channel of the second expander is communicated with the condenser; the high-temperature heat exchanger and the second high-temperature heat exchanger are also respectively provided with a heat source medium channel communicated with the outside, the condenser is also provided with a cooling medium channel communicated with the outside, the evaporator or the heat source medium channel is also communicated with the outside, and the expander, the second expander and the third expander are connected with the compressor and transmit power to form a combined cycle power device; wherein, or expander, second expander and third expander are connected compressor and circulating pump and are transmitted power.

13. A combined cycle power device is characterized in that a low-temperature heat regenerator and a second circulating pump are added in any one of the combined cycle power devices in items 1-12, a condenser with a condensate pipeline communicated with an evaporator through the circulating pump is adjusted to be a condenser with a condensate pipeline communicated with the low-temperature heat regenerator through the circulating pump, a compressor is additionally provided with a middle steam extraction channel communicated with the low-temperature heat regenerator, and the low-temperature heat regenerator is further communicated with the evaporator through the second circulating pump through the condensate pipeline to form the combined cycle power device.

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.

In the figure, 1-expander, 2-compressor, 3-second expander, 4-circulating pump, 5-high temperature heat exchanger, 6-condenser, 7-evaporator (waste heat boiler), 8-heat supplier, 9-high temperature regenerator, 10-second high temperature heat exchanger, 11-third expander, 12-second compressor, 13-low temperature regenerator, 14-second circulating pump.

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 an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser and an evaporator; the condenser 6 is provided with a condensate pipeline, the evaporator 7 is communicated with the high-temperature heat exchanger 5 through a steam channel after the condensate pipeline is communicated with the evaporator 7 through the circulating pump 4, the compressor 2 is provided with a steam channel communicated with the high-temperature heat exchanger 5, the high-temperature heat exchanger 5 is also provided with a steam channel communicated with the expander 1, the expander 1 is also provided with a low-pressure steam channel, the evaporator 7 is provided with a low-pressure steam channel after the low-pressure steam channel is communicated with the evaporator 7, the compressor 2 and the second expander 3 are respectively communicated, and the second expander 3 is also provided with a low-pressure steam channel communicated; the high-temperature heat exchanger 5 is also communicated with the outside through a heat source medium channel, the condenser 6 is also communicated with the outside through a cooling medium channel, and the expander 1 and the second expander 3 are connected with the compressor 2 and transmit power.

(2) In the process, the condensate of the condenser 6 is boosted by the circulating pump 4 and enters the evaporator 7 to absorb heat, raise temperature, vaporize and overheat, then enters the high-temperature heat exchanger 5 to absorb heat and raise temperature, and the steam discharged by the compressor 2 enters the high-temperature heat exchanger 5 to absorb heat and raise temperature; the steam discharged by the high-temperature heat exchanger 5 flows through the expander 1 to reduce the pressure and do work, the low-pressure steam discharged by the expander 1 flows through the evaporator 7 to release heat and reduce the temperature, and then the low-pressure steam is divided into two paths, wherein the first path enters the compressor 2 to increase the pressure and the temperature, and the second path flows through the second expander 3 to reduce the pressure and do work and then enters the condenser 6 to release heat and condense; the heat source medium provides driving heat load through the high-temperature heat exchanger 5, and the cooling medium takes away low-temperature heat load through the condenser 6; the expander 1 and the second expander 3 power the compressor 2 and the outside, or the expander 1 and the second expander 3 power the compressor 2, the circulation pump 4 and the outside, forming a combined cycle power plant.

The combined cycle power plant shown in fig. 2 is implemented as follows:

in the combined cycle power plant shown in fig. 1, the evaporator 7 is additionally provided with a heat source medium passage to communicate with the outside; the condensate entering the evaporator 7 simultaneously obtains the heat load provided by the low-pressure steam and the heat source medium, and the condensate is heated, vaporized and superheated, and then enters the high-temperature heat exchanger 5 to form the combined cycle power device.

The combined cycle power plant shown in fig. 3 is implemented as follows:

(1) structurally, the heat pump system mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a heat supply device; the condenser 6 has a condensate pipeline, after the condensate pipeline is communicated with the evaporator 7 through the circulating pump 4, the evaporator 7 is provided with a steam channel communicated with the high-temperature heat exchanger 5, the compressor 2 is provided with a steam channel communicated with the high-temperature heat exchanger 5, the high-temperature heat exchanger 5 is also provided with a steam channel communicated with the expander 1, the expander 1 is also provided with a low-pressure steam channel, after the low-pressure steam channel is communicated with the heat supply device 8, the heat supply device 8 is provided with a low-pressure steam channel communicated with the compressor 2 and the second expander 3 respectively, and the second expander 3 is also provided with a low-; the high-temperature heat exchanger 5 is also communicated with the outside through a heat source medium channel, the condenser 6 is also communicated with the outside through a cooling medium channel, the evaporator 7 is also communicated with the outside through a heat source medium channel, the heat supplier 8 is also communicated with the outside through a heated medium channel, and the expander 1 and the second expander 3 are connected with the compressor 2 and transmit power.

(2) In the process, the condensate of the condenser 6 is boosted by the circulating pump 4 and enters the evaporator 7 to absorb heat, raise temperature, vaporize and overheat, then enters the high-temperature heat exchanger 5 to absorb heat and raise temperature, and the steam discharged by the compressor 2 enters the high-temperature heat exchanger 5 to absorb heat and raise temperature; the steam discharged by the high-temperature heat exchanger 5 flows through the expander 1 to reduce the pressure and do work, the low-pressure steam discharged by the expander 1 flows through the heat supplier 8 to release heat and reduce the temperature, and then the low-pressure steam is divided into two paths, wherein the first path enters the compressor 2 to increase the pressure and the temperature, and the second path flows through the second expander 3 to reduce the pressure and do work and then enters the condenser 6 to release heat and condense; a heat source medium provides a driving heat load through a high-temperature heat exchanger 5 and an evaporator 7, a cooling medium takes away a low-temperature heat load through a condenser 6, and a heated medium takes away a medium-temperature heat load through a heat supplier 8; the expander 1 and the second expander 3 power the compressor 2 and the outside, or the expander 1 and the second expander 3 power the compressor 2, the circulation pump 4 and the outside, forming a combined cycle power plant.

The combined cycle power plant shown in fig. 4 is implemented as follows:

(1) structurally, the system mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a high-temperature heat regenerator; the condenser 6 is provided with a condensate pipeline, the evaporator 7 is communicated with the evaporator 7 through a circulating pump 4, a steam channel is communicated with the high-temperature heat exchanger 5 through a high-temperature heat regenerator 9, a steam channel of the compressor 2 is communicated with the high-temperature heat exchanger 5 through the high-temperature heat regenerator 9, the high-temperature heat exchanger 5 is also communicated with the expander 1 through a steam channel, the expander 1 is also provided with a low-pressure steam channel communicated with the high-temperature heat regenerator 9, the evaporator 7 is provided with a low-pressure steam channel after the high-temperature heat regenerator 9 is also communicated with the evaporator 7, the compressor 2 and the second expander 3 are respectively communicated, and the second expander 3 is also provided with a low-pressure steam channel communicated with the condenser 6; the high-temperature heat exchanger 5 is also communicated with the outside through a heat source medium channel, the condenser 6 is also communicated with the outside through a cooling medium channel, and the expander 1 and the second expander 3 are connected with the compressor 2 and transmit power.

(2) In the process, the condensate of the condenser 6 is boosted by the circulating pump 4 and enters the evaporator 7, absorbs heat, heats, vaporizes and overheats, flows through the high-temperature heat regenerator 9, absorbs heat, heats, and then enters the high-temperature heat exchanger 5 to absorb heat and heat; steam discharged by the compressor 2 flows through the high-temperature heat regenerator 9, absorbs heat and heats up, and then enters the high-temperature heat exchanger 5 to absorb heat and heat up; the steam discharged by the high-temperature heat exchanger 5 flows through the expander 1 to reduce the pressure and do work, the low-pressure steam discharged by the expander 1 flows through the high-temperature heat regenerator 9 and the evaporator 7 to gradually release heat and reduce the temperature, and then the low-pressure steam is divided into two paths, wherein the first path enters the compressor 2 to increase the pressure and the temperature, and the second path flows through the second expander 3 to reduce the pressure and do work and then enters the condenser 6 to release heat and condense; the heat source medium provides driving heat load through the high-temperature heat exchanger 5, and the cooling medium takes away low-temperature heat load through the condenser 6; the expander 1 and the second expander 3 power the compressor 2 and the outside, or the expander 1 and the second expander 3 power the compressor 2, the circulation pump 4 and the outside, forming a combined cycle power plant.

The combined cycle power plant shown in fig. 5 is implemented as follows:

(1) structurally, the system mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a second high-temperature heat exchanger; the condenser 6 is provided with a condensate pipeline, a steam channel of the evaporator 7 is communicated with the second high-temperature heat exchanger 10 after the condensate pipeline is communicated with the evaporator 7 through the circulating pump 4, the second high-temperature heat exchanger 10 is also communicated with the expander 1 through a steam channel, the compressor 2 is provided with a steam channel communicated with the high-temperature heat exchanger 5, the high-temperature heat exchanger 5 is also communicated with the expander 1 through a middle steam inlet channel, the expander 1 is also provided with a low-pressure steam channel, a low-pressure steam channel of the evaporator 7 is communicated with the compressor 2 and the second expander 3 respectively, and the second expander 3 is also provided with a low-pressure steam channel communicated with the condenser 6; the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 are also respectively communicated with the outside through a heat source medium channel, the condenser 6 is also communicated with the outside through a cooling medium channel, and the expander 1 and the second expander 3 are connected with the compressor 2 and transmit power.

(2) In the process, the condensate of the condenser 6 flows through the circulating pump 4 and is boosted, flows through the evaporator 7 and the second high-temperature heat exchanger 10 to absorb heat, raise temperature, vaporize and overheat, and then enters the expander 1 to reduce pressure and do work; the steam discharged by the compressor 2 flows through the high-temperature heat exchanger 5 to absorb heat and raise temperature, and then enters the expansion machine 1 through the middle steam inlet channel to reduce pressure and do work; the low-pressure steam discharged by the expander 1 passes through the evaporator 7 to release heat and cool, and then is divided into two paths, wherein the first path enters the compressor 2 to increase the pressure and heat, and the second path passes through the second expander 3 to reduce the pressure and do work and then enters the condenser 6 to release heat and condense; the heat source medium provides a driving heat load through the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10, and the cooling medium takes away a low-temperature heat load through the condenser 6; the expander 1 and the second expander 3 power the compressor 2 and the outside, or the expander 1 and the second expander 3 power the compressor 2, the circulation pump 4 and the outside, forming a combined cycle power plant.

The combined cycle power plant shown in fig. 6 is implemented as follows:

(1) structurally, the system mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser and an evaporator; the condenser 6 has a condensate pipeline which is communicated with the evaporator 7 through a circulating pump 4, then a steam channel of the evaporator 7 is communicated with the expander 1 through a middle steam inlet channel, a steam channel of the compressor 2 is communicated with the expander 1 through a high-temperature heat exchanger 5, the expander 1 is also communicated with the evaporator 7 through a low-pressure steam channel, then a low-pressure steam channel of the evaporator 7 is respectively communicated with the compressor 2 and the second expander 3, and the second expander 3 is also communicated with the condenser 6 through a low-pressure steam channel; the high-temperature heat exchanger 5 is also communicated with the outside through a heat source medium channel, the condenser 6 is also communicated with the outside through a cooling medium channel, and the expander 1 and the second expander 3 are connected with the compressor 2 and transmit power.

(2) In the process, the condensate of the condenser 6 is boosted by the circulating pump 4 and enters the evaporator 7 to absorb heat, raise temperature, vaporize and overheat, and then enters the expansion machine 1 through the middle steam inlet channel to reduce pressure and do work; the steam discharged by the compressor 2 flows through the high-temperature heat exchanger 5 to absorb heat and raise temperature, and then enters the expander 1 to reduce pressure and do work; the low-pressure steam discharged by the expander 1 passes through the evaporator 7 to release heat and cool, and then is divided into two paths, wherein the first path enters the compressor 2 to increase the pressure and heat, and the second path passes through the second expander 3 to reduce the pressure and do work and then enters the condenser 6 to release heat and condense; the heat source medium provides driving heat load through the high-temperature heat exchanger 5, and the cooling medium takes away low-temperature heat load through the condenser 6; the expander 1 and the second expander 3 power the compressor 2 and the outside, or the expander 1 and the second expander 3 power the compressor 2, the circulation pump 4 and the outside, forming a combined cycle power plant.

The combined cycle power plant shown in fig. 7 is implemented as follows:

(1) structurally, the system mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a high-temperature heat regenerator; the condenser 6 is provided with a condensate pipeline, a steam channel of the evaporator 7 is communicated with the expander 1 through a middle steam inlet channel after the condensate pipeline is communicated with the evaporator 7 through the circulating pump 4, a steam channel of the compressor 2 is communicated with the expander 1 through a high-temperature heat regenerator 9 and a high-temperature heat exchanger 5, the expander 1 is also provided with a low-pressure steam channel which is communicated with the high-temperature heat regenerator 9, the high-temperature heat regenerator 9 is also provided with a low-pressure steam channel of the evaporator 7 which is communicated with the evaporator 7, the low-pressure steam channel of the evaporator 7 is respectively communicated with the compressor 2 and the second expander 3, and the low-pressure steam channel of the second expander 3 is communicated with; the high-temperature heat exchanger 5 is also communicated with the outside through a heat source medium channel, the condenser 6 is also communicated with the outside through a cooling medium channel, and the expander 1 and the second expander 3 are connected with the compressor 2 and transmit power.

(2) In the process, the condensate of the condenser 6 is boosted by the circulating pump 4 and enters the evaporator 7 to absorb heat, raise temperature, vaporize and overheat, and then enters the expansion machine 1 through the middle steam inlet channel to reduce pressure and do work; the steam discharged by the compressor 2 flows through the high-temperature heat regenerator 9 and the high-temperature heat exchanger 5 to gradually absorb heat and raise the temperature, and then enters the expander 1 to reduce the pressure and do work; the low-pressure steam discharged by the expander 1 gradually releases heat and cools through the high-temperature heat regenerator 9 and the evaporator 7, and then is divided into two paths, namely the first path enters the compressor 2 to increase the pressure and the temperature, and the second path enters the condenser 6 to release heat and condense after flowing through the second expander 3 to reduce the pressure and do work; the heat source medium provides driving heat load through the high-temperature heat exchanger 5, and the cooling medium takes away low-temperature heat load through the condenser 6; the expander 1 and the second expander 3 power the compressor 2 and the outside, or the expander 1 and the second expander 3 power the compressor 2, the circulation pump 4 and the outside, forming a combined cycle power plant.

The combined cycle power plant shown in fig. 8 is implemented as follows:

(1) structurally, the system mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a third expander; the condenser 6 has a condensate pipeline which is communicated with the evaporator 7 through a circulating pump 4, then the evaporator 7 is communicated with a third expansion machine 11 through a steam channel, the third expansion machine 11 is also communicated with the evaporator 7 through a low-pressure steam channel, the compressor 2 is provided with a steam channel which is communicated with the expansion machine 1 through a high-temperature heat exchanger 5, the expansion machine 1 is also provided with a low-pressure steam channel which is communicated with the evaporator 7, the evaporator 7 is also provided with a low-pressure steam channel which is respectively communicated with the compressor 2 and the second expansion machine 3, and the second expansion machine 3 is also provided with a low-pressure steam channel which is communicated with the condenser 6; the high-temperature heat exchanger 5 is also communicated with the outside through a heat source medium channel, the condenser 6 is also communicated with the outside through a cooling medium channel, the evaporator 7 is also communicated with the outside through a heat source medium channel, and the expander 1, the second expander 3 and the third expander 11 are connected with the compressor 2 and transmit power.

(2) In the process, the condensate of the condenser 6 is boosted by the circulating pump 4 and enters the evaporator 7 to absorb heat, raise temperature, vaporize and overheat, then enters the third expander 11 to reduce pressure and do work, and the low-pressure steam discharged by the third expander 11 enters the evaporator 7 to release heat and lower the temperature; the steam discharged by the compressor 2 flows through the high-temperature heat exchanger 5 to absorb heat and raise temperature, and is decompressed and does work by the expander 1, and the low-pressure steam discharged by the expander 1 enters the evaporator 7 to release heat and lower the temperature; the low-pressure steam discharged by the evaporator 7 is divided into two paths, wherein the first path enters the compressor 2 for boosting and heating, and the second path enters the condenser 6 for releasing heat and condensing after flowing through the second expander 3 for reducing pressure and doing work; the heat source medium provides driving heat load through the high-temperature heat exchanger 5 and the evaporator 7, and the cooling medium takes away low-temperature heat load through the condenser 6; the expander 1, the second expander 3 and the third expander 11 provide power for the compressor 2 and the outside, or the expander 1, the second expander 3 and the third expander 11 provide power for the compressor 2, the circulating pump 4 and the outside, forming a combined cycle power plant.

The combined cycle power plant shown in fig. 9 is implemented as follows:

(1) structurally, the heat pump system mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a heat supply device; the condenser 6 has a condensate pipeline, the evaporator 7 is communicated with the high-temperature heat exchanger 5 through a steam channel after the circulation pump 4 is communicated with the evaporator 7, the compressor 2 is communicated with the high-temperature heat exchanger 5 through a steam channel, the high-temperature heat exchanger 5 is also communicated with the expander 1 through a steam channel, the expander 1 is also communicated with the evaporator 7 through a low-pressure steam channel, the evaporator 7 is also communicated with the heat supplier 8 through a low-pressure steam channel, the heat supplier 8 is also communicated with the compressor 2 and the second expander 3 through a low-pressure steam channel, and the second expander 3 is also communicated with the condenser 6 through a low-pressure steam channel; the high-temperature heat exchanger 5 is also communicated with the outside through a heat source medium channel, the condenser 6 is also communicated with the outside through a cooling medium channel, the heat supplier 8 is also communicated with the outside through a heated medium channel, and the expander 1 and the second expander 3 are connected with the compressor 2 and transmit power.

(2) In the process, the condensate of the condenser 6 is boosted by the circulating pump 4 and enters the evaporator 7 to absorb heat, raise temperature, vaporize and overheat, then enters the high-temperature heat exchanger 5 to absorb heat and raise temperature, and the steam discharged by the compressor 2 enters the high-temperature heat exchanger 5 to absorb heat and raise temperature; the steam discharged by the high-temperature heat exchanger 5 flows through the expander 1 to reduce pressure and do work, the low-pressure steam discharged by the expander 1 flows through the evaporator 7 and the heat supply device 8 to gradually release heat and reduce temperature, and then the low-pressure steam is divided into two paths, wherein the first path enters the compressor 2 to increase pressure and temperature, and the second path flows through the second expander 3 to reduce pressure and do work and then enters the condenser 6 to release heat and condense; the heat source medium provides driving heat load through the high-temperature heat exchanger 5, the cooling medium takes away low-temperature heat load through the condenser 6, and the heated medium takes away medium-temperature heat load through the heat supplier 8; the expander 1 and the second expander 3 power the compressor 2 and the outside, or the expander 1 and the second expander 3 power the compressor 2, the circulation pump 4 and the outside, forming a combined cycle power plant.

The combined cycle power plant shown in fig. 10 is implemented as follows:

(1) structurally, the system mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator, a second high-temperature heat exchanger and a second compressor; the condenser 6 is provided with a condensate pipeline, a steam channel of the evaporator 7 is communicated with the high-temperature heat exchanger 5 after the condensate pipeline is communicated with the evaporator 7 through the circulating pump 4, the compressor 2 is provided with a steam channel communicated with the high-temperature heat exchanger 5, the high-temperature heat exchanger 5 is also provided with a steam channel communicated with the second compressor 12, the second compressor 12 is also provided with a steam channel communicated with the expander 1 through the second high-temperature heat exchanger 10, the expander 1 is also provided with a low-pressure steam channel, a low-pressure steam channel of the evaporator 7 is communicated with the compressor 2 and the second expander 3 respectively, and the second expander 3 is also provided with a low-pressure steam channel communicated with the condenser 6; the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 are also respectively communicated with the outside through a heat source medium channel, the condenser 6 is also communicated with the outside through a cooling medium channel, and the expander 1 and the second expander 3 are connected with the compressor 2 and the second compressor 12 and transmit power.

(2) In the process, the condensate of the condenser 6 is boosted by the circulating pump 4 and enters the evaporator 7 to absorb heat, raise temperature, vaporize and overheat, then enters the high-temperature heat exchanger 5 to absorb heat and raise temperature, and the steam discharged by the compressor 2 enters the high-temperature heat exchanger 5 to absorb heat and raise temperature; the steam discharged by the high-temperature heat exchanger 5 flows through the second compressor 12 to increase the pressure and the temperature, flows through the second high-temperature heat exchanger 10 to absorb heat and increase the temperature, and flows through the expander 1 to reduce the pressure and do work; the low-pressure steam discharged by the expander 1 passes through the evaporator 7 to release heat and cool, and then is divided into two paths, wherein the first path enters the compressor 2 to increase the pressure and heat, and the second path passes through the second expander 3 to reduce the pressure and do work and then enters the condenser 6 to release heat and condense; the heat source medium provides a driving heat load through the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10, and the cooling medium takes away a low-temperature heat load through the condenser 6; the expander 1 and the second expander 3 power the compressor 2, the second booster 11 and the outside, or the expander 1 and the second expander 3 power the compressor 2, the circulation pump 4, the second compressor 12 and the outside, forming a combined cycle power plant.

The combined cycle power plant shown in FIG. 11 is implemented as follows:

(1) structurally, the system mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator, a second high-temperature heat exchanger and a third expander; the condenser 6 is provided with a condensate pipeline, a steam channel of the evaporator 7 is communicated with the high-temperature heat exchanger 5 after the condensate pipeline is communicated with the evaporator 7 through the circulating pump 4, a steam channel of the compressor 2 is communicated with the high-temperature heat exchanger 5, a steam channel of the high-temperature heat exchanger 5 is communicated with the third expander 11, the third expander 11 is also provided with a steam channel which is communicated with the expander 1 through the second high-temperature heat exchanger 10, the expander 1 is also provided with a low-pressure steam channel, a low-pressure steam channel of the evaporator 7 is communicated with the compressor 2 and the second expander 3 respectively, and a low-pressure steam channel of the second expander 3 is communicated with the condenser 6; the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 are also respectively communicated with the outside through a heat source medium channel, the condenser 6 is also communicated with the outside through a cooling medium channel, and the expander 1, the second expander 3 and the third expander 11 are connected with the compressor 2 and transmit power.

(2) In the process, the condensate of the condenser 6 is boosted by the circulating pump 4 and enters the evaporator 7 to absorb heat, raise temperature, vaporize and overheat, then enters the high-temperature heat exchanger 5 to absorb heat and raise temperature, and the steam discharged by the compressor 2 enters the high-temperature heat exchanger 5 to absorb heat and raise temperature; the steam discharged by the high-temperature heat exchanger 5 flows through the third expander 11 to reduce the pressure and do work, flows through the second high-temperature heat exchanger 10 to absorb heat and raise the temperature, and flows through the expander 1 to reduce the pressure and do work; the low-pressure steam discharged by the expander 1 passes through the evaporator 7 to release heat and cool, and then is divided into two paths, wherein the first path enters the compressor 2 to increase the pressure and heat, and the second path passes through the second expander 3 to reduce the pressure and do work and then enters the condenser 6 to release heat and condense; the heat source medium provides a driving heat load through the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10, and the cooling medium takes away a low-temperature heat load through the condenser 6; the expander 1, the second expander 3 and the third expander 11 provide power for the compressor 2 and the outside, or the expander 1, the second expander 3 and the third expander 11 provide power for the compressor 2, the circulating pump 4 and the outside, forming a combined cycle power plant.

The combined cycle power plant shown in fig. 12 is implemented as follows:

(1) structurally, the system mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator, a high-temperature heat regenerator, a second high-temperature heat exchanger and a second compressor; the condenser 6 is provided with a condensate pipeline, the evaporator 7 is communicated with the evaporator 7 through a circulating pump 4, a steam channel is communicated with the high-temperature heat exchanger 5 through a high-temperature heat regenerator 9, a steam channel of the compressor 2 is communicated with the high-temperature heat exchanger 5 through the high-temperature heat regenerator 9, the high-temperature heat exchanger 5 is also communicated with a second compressor 12 through a steam channel, the second compressor 12 is also communicated with the expander 1 through a second high-temperature heat exchanger 10 through a steam channel, the expander 1 is also provided with a low-pressure steam channel, the evaporator 7 is further provided with a low-pressure steam channel which is communicated with the compressor 2 and the second expander 3 through the high-temperature heat regenerator 9, and the second expander 3 is also provided with a low-pressure steam channel which is communicated with the; the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 are also respectively communicated with the outside through a heat source medium channel, the condenser 6 is also communicated with the outside through a cooling medium channel, and the expander 1 and the second expander 3 are connected with the compressor 2 and the second compressor 12 and transmit power.

(2) In the process, the condensate of the condenser 6 is boosted by the circulating pump 4 and enters the evaporator 7 to absorb heat, raise temperature, vaporize and overheat, flows through the high-temperature heat regenerator 9 to absorb heat and raise temperature, and then enters the high-temperature heat exchanger 5 to absorb heat and raise temperature; steam discharged by the compressor 2 flows through the high-temperature heat regenerator 9 to absorb heat and raise the temperature, and then enters the high-temperature heat exchanger 5 to absorb heat and raise the temperature; the steam discharged by the high-temperature heat exchanger 5 flows through the second compressor 12 to increase the pressure and the temperature, flows through the second high-temperature heat exchanger 10 to absorb heat and increase the temperature, and flows through the expander 1 to reduce the pressure and do work; the low-pressure steam flow high-temperature heat regenerator 9 discharged by the expansion machine 1 gradually releases heat and cools through the evaporator 7, and then is divided into two paths, wherein the first path enters the compressor 2 to increase the pressure and the temperature, and the second path enters the condenser 6 to release heat and condense after flowing through the second expansion machine 3 to reduce the pressure and do work; the heat source medium provides a driving heat load through the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10, and the cooling medium takes away a low-temperature heat load through the condenser 6; the expander 1 and the second expander 3 power the compressor 2, the second booster 11 and the outside, or the expander 1 and the second expander 3 power the compressor 2, the circulation pump 4, the second compressor 12 and the outside, forming a combined cycle power plant.

The combined cycle power plant shown in fig. 13 is implemented as follows:

(1) structurally, the system mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator, a high-temperature heat regenerator, a second high-temperature heat exchanger and a third expander; the condenser 6 has a condensate pipeline which is communicated with the evaporator 7 through a circulating pump 4, then the evaporator 7 has a steam channel which is communicated with a high-temperature heat exchanger 5 through a high-temperature heat regenerator 9, the compressor 2 has a steam channel which is communicated with the high-temperature heat exchanger 5 through the high-temperature heat regenerator 9, the high-temperature heat exchanger 5 also has a steam channel which is communicated with a third expander 11, the third expander 11 also has a steam channel which is communicated with the expander 1 through a second high-temperature heat exchanger 10, the expander 1 also has a low-pressure steam channel which is communicated with the evaporator 7 through the high-temperature heat regenerator 9, then the evaporator 7 has a low-pressure steam channel which is respectively communicated with the compressor 2 and the second expander 3, and the second expander 3 also has a low-pressure steam channel which is; the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10 are also respectively communicated with the outside through a heat source medium channel, the condenser 6 is also communicated with the outside through a cooling medium channel, and the expander 1, the second expander 3 and the third expander 11 are connected with the compressor 2 and transmit power.

(2) In the process, the condensate of the condenser 6 is boosted by the circulating pump 4 and enters the evaporator 7 to absorb heat, raise temperature, vaporize and overheat, flows through the high-temperature heat regenerator 9 to absorb heat and raise temperature, and then enters the high-temperature heat exchanger 5 to absorb heat and raise temperature; steam discharged by the compressor 2 flows through the high-temperature heat regenerator 9 to absorb heat and raise the temperature, and then enters the high-temperature heat exchanger 5 to absorb heat and raise the temperature; the steam discharged by the high-temperature heat exchanger 5 flows through the third expander 11 to reduce the pressure and do work, flows through the second high-temperature heat exchanger 10 to absorb heat and raise the temperature, and flows through the expander 1 to reduce the pressure and do work; the low-pressure steam discharged by the expander 1 gradually releases heat and cools through the high-temperature heat regenerator 9 and the evaporator 7, and then is divided into two paths, namely the first path enters the compressor 2 to increase the pressure and the temperature, and the second path enters the condenser 6 to release heat and condense after flowing through the second expander 3 to reduce the pressure and do work; the heat source medium provides a driving heat load through the high-temperature heat exchanger 5 and the second high-temperature heat exchanger 10, and the cooling medium takes away a low-temperature heat load through the condenser 6; the expander 1, the second expander 3 and the third expander 11 provide power for the compressor 2 and the outside, or the expander 1, the second expander 3 and the third expander 11 provide power for the compressor 2, the circulating pump 4 and the outside, forming a combined cycle power plant.

The combined cycle power plant shown in fig. 14 is implemented as follows:

(1) structurally, in the combined cycle power plant shown in fig. 1, a low-temperature heat regenerator and a second circulating pump are added, a condensate pipeline of a condenser 6 is communicated with an evaporator 7 through a circulating pump 4, the condenser 6 is adjusted to be communicated with the low-temperature heat regenerator 13 through the circulating pump 4, a middle steam extraction channel is additionally arranged on a compressor 2 and is communicated with the low-temperature heat regenerator 13, and the low-temperature heat regenerator 13 is communicated with the evaporator 7 through a condensate pipeline of the second circulating pump 14.

(2) In the process, the condensate of the condenser 6 is boosted by the circulating pump 4 and enters the low-temperature heat regenerator 13, and is mixed with the extracted steam from the compressor 2 to absorb heat and raise the temperature, and the extracted steam is mixed with the condensate to release heat and condense; the condensate of the low-temperature heat regenerator 13 is boosted by a second circulating pump 14 and enters the evaporator 7 to absorb heat, raise temperature, vaporize and overheat, and then enters the high-temperature heat exchanger 5 to absorb heat and raise temperature, and the steam discharged by the compressor 2 enters the high-temperature heat exchanger 5 to absorb heat and raise temperature; the steam discharged by the high-temperature heat exchanger 5 flows through the expander 1 to reduce pressure and do work, the low-pressure steam discharged by the expander 1 flows through the evaporator 7 to release heat and reduce temperature, and then is divided into two paths, wherein the first path enters the compressor 2, and the second path flows through the second expander 3 to reduce pressure and do work and then enters the condenser 6 to release heat and condense; the low-pressure steam entering the compressor 2 is subjected to pressure boosting and temperature rising to a certain degree and then is divided into two paths, wherein the first path enters the low-temperature heat regenerator 13 through the middle steam extraction channel, and the second path is subjected to pressure boosting and temperature rising continuously; the heat source medium provides driving heat load through the high-temperature heat exchanger 5, and the cooling medium takes away low-temperature heat load through the condenser 6; the expander 1 and the second expander 3 power the compressor 2 and the outside, or the expander 1 and the second expander 3 power the compressor 2, the circulation pump 4 and the outside, forming a combined cycle power plant.

The combined cycle power plant shown in fig. 15 is implemented as follows:

(1) structurally, in the combined cycle power plant shown in fig. 3, a low-temperature heat regenerator and a second circulating pump are added, a condensate pipeline of a condenser 6 is communicated with an evaporator 7 through the circulating pump 4, the condenser 6 is adjusted to be communicated with the low-temperature heat regenerator 13 through the circulating pump 4, a middle steam extraction channel is additionally arranged on the compressor 2 and is communicated with the low-temperature heat regenerator 13, and the low-temperature heat regenerator 13 is communicated with the evaporator 7 through a condensate pipeline of the second circulating pump 14.

(2) In the process, the condensate of the condenser 6 is boosted by the circulating pump 4 and enters the low-temperature heat regenerator 13, and is mixed with the extracted steam from the compressor 2 to absorb heat and raise the temperature, and the extracted steam is mixed with the condensate to release heat and condense; the condensate of the low-temperature heat regenerator 13 is boosted by a second circulating pump 14 and enters the evaporator 7 to absorb heat, raise temperature, vaporize and overheat, and then enters the high-temperature heat exchanger 5 to absorb heat and raise temperature, and the steam discharged by the compressor 2 enters the high-temperature heat exchanger 5 to absorb heat and raise temperature; the steam discharged by the high-temperature heat exchanger 5 flows through the expander 1 to reduce pressure and do work, the low-pressure steam discharged by the expander 1 flows through the heat supplier 8 to release heat and reduce temperature, and then is divided into two paths, wherein the first path enters the compressor 2, and the second path flows through the second expander 3 to reduce pressure and do work and then enters the condenser 6 to release heat and condense; the low-pressure steam entering the compressor 2 is subjected to pressure boosting and temperature rising to a certain degree and then is divided into two paths, wherein the first path enters the low-temperature heat regenerator 13 through the middle steam extraction channel, and the second path is subjected to pressure boosting and temperature rising continuously; a heat source medium provides a driving heat load through a high-temperature heat exchanger 5 and an evaporator 7, a cooling medium takes away a low-temperature heat load through a condenser 6, and a heated medium takes away a medium-temperature heat load through a heat supplier 8; the expander 1 and the second expander 3 power the compressor 2 and the outside, or the expander 1 and the second expander 3 power the compressor 2, the circulation pump 4, the second circulation pump 14 and the outside, forming a 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 circulating working medium completes high-temperature heat absorption under low pressure, the temperature difference loss between the circulating working medium and a high-temperature heat source is small, and the heat efficiency of a system and the safety of the device are improved.

(2) The cycle working medium mainly depends on the condensation phase change process to realize low-temperature heat release, the temperature difference loss between the cycle working medium and the environment is controllable, and the heat efficiency is improved.

(3) The low-pressure high-temperature operation mode is adopted in the high-temperature area, the contradiction that the heat efficiency, the circulating medium parameters and the pressure and temperature resistance of the pipe are difficult to reconcile in the traditional steam power device is solved, so that the temperature difference loss between a heat source and the circulating medium can be greatly reduced, and the heat efficiency is greatly improved.

(4) The equipment is shared, the heat absorption process of the lower cycle, namely the Rankine cycle, is increased, and the heat efficiency is improved.

(5) And a single working medium is adopted, so that the operation cost is reduced, and the adjustment flexibility of the thermal power device is improved.

(6) When the high-temperature expander is shared, the number of core equipment is reduced, and the system investment is favorably reduced and the heat efficiency is favorably improved.

(7) The lower part adopts a double-expansion process, which is beneficial to flexibly adjusting working parameters and adaptability.

(8) The device can effectively deal with high-temperature heat sources and variable-temperature heat sources, and deal with high-quality fuels and non-high-quality fuels, and has wide application range.

(9) On the premise of realizing high thermal efficiency, low-pressure operation can be selected, so that the operation safety of the device is greatly improved.

(10) The heat recovery of the enterprise device can be simply, actively, safely and efficiently realized.

(11) The heat efficiency can be effectively improved by applying the heat exchanger to the lower end of the gas-steam combined cycle.

(12) When the system is applied to a coal-fired thermodynamic system, the original advantages of the traditional steam power cycle, namely water vapor as a working medium, can be kept, and the working parameter range is wide; according to the actual condition, the working in the subcritical, critical, supercritical or ultra supercritical state can be selected.

Claims (13)

1. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser and an evaporator; the condenser (6) is provided with a condensate pipeline, a steam channel of the evaporator (7) is communicated with the high-temperature heat exchanger (5) after the condensate pipeline is communicated with the evaporator (7) through the circulating pump (4), a steam channel of the compressor (2) is communicated with the high-temperature heat exchanger (5), the steam channel of the high-temperature heat exchanger (5) is also communicated with the expander (1), a low-pressure steam channel of the evaporator (7) is also communicated with the evaporator (7), the low-pressure steam channel of the evaporator (7) is respectively communicated with the compressor (2) and the second expander (3), and the low-pressure steam channel of the second expander (3) is also communicated with the condenser (6); the high-temperature heat exchanger (5) is also provided with a heat source medium channel communicated with the outside, the condenser (6) is also provided with a cooling medium channel communicated with the outside, the evaporator (7) or the heat source medium channel is also communicated with the outside, and the expander (1) and the second expander (3) are connected with the compressor (2) and transmit power to form a combined cycle power device; wherein, or the expander (1) and the second expander (3) are connected with the compressor (2) and the circulating pump (4) and transmit power.

2. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a heat supplier; the condenser (6) is provided with a condensate pipeline, the evaporator (7) is communicated with the high-temperature heat exchanger (5) through a circulating pump (4), a steam channel is communicated with the high-temperature heat exchanger (5), the high-temperature heat exchanger (5) is also provided with a steam channel which is communicated with the expander (1), the expander (1) is also provided with a low-pressure steam channel which is communicated with the heat supplier (8), the heat supplier (8) is also provided with a low-pressure steam channel which is respectively communicated with the compressor (2) and the second expander (3), and the second expander (3) is also provided with a low-pressure steam channel which is communicated with the condenser (6); the high-temperature heat exchanger (5) is also provided with a heat source medium channel communicated with the outside, the condenser (6) is also provided with a cooling medium channel communicated with the outside, the evaporator (7) is also provided with a heat source medium channel communicated with the outside, the heat supply device (8) is also provided with a heated medium channel communicated with the outside, and the expander (1) and the second expander (3) are connected with the compressor (2) and transmit power to form a combined cycle power device; wherein, or the expander (1) and the second expander (3) are connected with the compressor (2) and the circulating pump (4) and transmit power.

3. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a high-temperature heat regenerator; the condenser (6) is provided with a condensate pipeline, a steam channel of the evaporator (7) is communicated with the high-temperature heat exchanger (5) through a high-temperature heat regenerator (9) after the condensate pipeline is communicated with the evaporator (7) through a circulating pump (4), the compressor (2) is provided with a steam channel which is communicated with the high-temperature heat exchanger (5) through the high-temperature heat regenerator (9), the high-temperature heat exchanger (5) is also provided with a steam channel which is communicated with the expander (1), the expander (1) is also provided with a low-pressure steam channel which is communicated with the high-temperature heat regenerator (9), the high-temperature heat regenerator (9) is also provided with a low-pressure steam channel, the evaporator (7) is also provided with a low-pressure steam channel which is communicated with the compressor (2) and the second expander (3), and the second expander (3) is also provided with a low; the high-temperature heat exchanger (5) is also provided with a heat source medium channel communicated with the outside, the condenser (6) is also provided with a cooling medium channel communicated with the outside, the evaporator (7) or the heat source medium channel is also communicated with the outside, and the expander (1) and the second expander (3) are connected with the compressor (2) and transmit power to form a combined cycle power device; wherein, or the expander (1) and the second expander (3) are connected with the compressor (2) and the circulating pump (4) and transmit power.

4. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a second high-temperature heat exchanger; the condenser (6) is provided with a condensate pipeline, a steam channel of the evaporator (7) is communicated with the second high-temperature heat exchanger (10) after the condensate pipeline is communicated with the evaporator (7) through a circulating pump (4), the second high-temperature heat exchanger (10) is also provided with a steam channel to be communicated with the expander (1), the compressor (2) is provided with a steam channel to be communicated with the high-temperature heat exchanger (5), the high-temperature heat exchanger (5) is also provided with a steam channel to be communicated with the expander (1) through a middle steam inlet channel, the expander (1) is also provided with a low-pressure steam channel, the evaporator (7) is also provided with a low-pressure steam channel to be communicated with the compressor (2) and the second expander (3), and the second expander (3) is also provided with a low-pressure steam channel to be communicated with the condenser; the high-temperature heat exchanger (5) and the second high-temperature heat exchanger (10) are also respectively provided with a heat source medium channel communicated with the outside, the condenser (6) is also provided with a cooling medium channel communicated with the outside, the evaporator (7) or the heat source medium channel is also communicated with the outside, and the expander (1) and the second expander (3) are connected with the compressor (2) and transmit power to form a combined cycle power device; wherein, or the expander (1) and the second expander (3) are connected with the compressor (2) and the circulating pump (4) and transmit power.

5. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser and an evaporator; the condenser (6) is provided with a condensate pipeline, a steam channel of the evaporator (7) is communicated with the expander (1) through a middle steam inlet channel after the condensate pipeline is communicated with the evaporator (7) through the circulating pump (4), the compressor (2) is provided with a steam channel which is communicated with the expander (1) through the high-temperature heat exchanger (5), the expander (1) is also provided with a low-pressure steam channel, the evaporator (7) is further provided with a low-pressure steam channel after the low-pressure steam channel is communicated with the evaporator (7) and is respectively communicated with the compressor (2) and the second expander (3), and the second expander (3) is also provided with a low-pressure steam channel which is communicated with the condenser (6); the high-temperature heat exchanger (5) is also provided with a heat source medium channel communicated with the outside, the condenser (6) is also provided with a cooling medium channel communicated with the outside, the evaporator (7) or the heat source medium channel is also communicated with the outside, and the expander (1) and the second expander (3) are connected with the compressor (2) and transmit power to form a combined cycle power device; wherein, or the expander (1) and the second expander (3) are connected with the compressor (2) and the circulating pump (4) and transmit power.

6. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a high-temperature heat regenerator; the condenser (6) is provided with a condensate pipeline, a steam channel of the evaporator (7) is communicated with the expander (1) through a middle steam inlet channel after the condensate pipeline is communicated with the evaporator (7) through a circulating pump (4), the compressor (2) is provided with a steam channel which is communicated with the expander (1) through a high-temperature heat regenerator (9) and a high-temperature heat exchanger (5), the expander (1) is also provided with a low-pressure steam channel which is communicated with the high-temperature heat regenerator (9), the high-temperature heat regenerator (9) is also provided with a low-pressure steam channel, the evaporator (7) is also provided with a low-pressure steam channel which is communicated with the evaporator (7), the compressor (2) and the second expander (3) are respectively communicated, and the second expander (3) is also provided with a low-pressure steam channel which is; the high-temperature heat exchanger (5) is also provided with a heat source medium channel communicated with the outside, the condenser (6) is also provided with a cooling medium channel communicated with the outside, the evaporator (7) or the heat source medium channel is also communicated with the outside, and the expander (1) and the second expander (3) are connected with the compressor (2) and transmit power to form a combined cycle power device; wherein, or the expander (1) and the second expander (3) are connected with the compressor (2) and the circulating pump (4) and transmit power.

7. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a third expander; the condenser (6) is provided with a condensate pipeline, the evaporator (7) is communicated with the evaporator (7) through a circulating pump (4), a steam channel is communicated with a third expander (11), the third expander (11) is also provided with a low-pressure steam channel which is communicated with the evaporator (7), the compressor (2) is provided with a steam channel which is communicated with the expander (1) through a high-temperature heat exchanger (5), the expander (1) is also provided with a low-pressure steam channel which is communicated with the evaporator (7), the evaporator (7) is also provided with a low-pressure steam channel which is respectively communicated with the compressor (2) and the second expander (3), and the second expander (3) is also provided with a low-pressure steam channel which is communicated with the condenser (6); the high-temperature heat exchanger (5) is also provided with a heat source medium channel communicated with the outside, the condenser (6) is also provided with a cooling medium channel communicated with the outside, the evaporator (7) or the heat source medium channel is also communicated with the outside, and the expander (1), the second expander (3) and the third expander (11) are connected with the compressor (2) and transmit power to form a combined cycle power device; wherein, or the expander (1), the second expander (3) and the third expander (11) are connected with the compressor (2) and the circulating pump (4) and transmit power.

8. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator and a heat supplier; the condenser (6) is provided with a condensate pipeline, a steam channel of the evaporator (7) is communicated with the high-temperature heat exchanger (5) after the condensate pipeline is communicated with the evaporator (7) through the circulating pump (4), a steam channel of the compressor (2) is communicated with the high-temperature heat exchanger (5), the steam channel of the high-temperature heat exchanger (5) is also communicated with the expander (1), the expander (1) is also provided with a low-pressure steam channel, the evaporator (7) is communicated with the evaporator (7) and a low-pressure steam channel is communicated with the heat supplier (8), the heat supplier (8) is also provided with a low-pressure steam channel which is respectively communicated with the compressor (2) and the second expander (3), and the second expander (3) is also provided with a low-pressure steam channel which is communicated with the condenser; the high-temperature heat exchanger (5) is also provided with a heat source medium channel communicated with the outside, the condenser (6) is also provided with a cooling medium channel communicated with the outside, the evaporator (7) or the heat source medium channel is also communicated with the outside, the heat supplier (8) is also provided with a heated medium channel communicated with the outside, and the expander (1) and the second expander (3) are connected with the compressor (2) and transmit power to form a combined cycle power device; wherein, or the expander (1) and the second expander (3) are connected with the compressor (2) and the circulating pump (4) and transmit power.

9. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator, a second high-temperature heat exchanger and a second compressor; the condenser (6) is provided with a condensate pipeline, a steam channel of the evaporator (7) is communicated with the high-temperature heat exchanger (5) after the condensate pipeline is communicated with the evaporator (7) through a circulating pump (4), a steam channel of the compressor (2) is communicated with the high-temperature heat exchanger (5), the steam channel of the high-temperature heat exchanger (5) is also communicated with a second compressor (12), the steam channel of the second compressor (12) is communicated with the expander (1) through a second high-temperature heat exchanger (10), the expander (1) is also provided with a low-pressure steam channel, the evaporator (7) is further provided with a low-pressure steam channel after the evaporator (7) is communicated with the compressor (2) and the second expander (3), and the second expander (3) is also provided with a low-pressure steam channel which is communicated with the condenser (6); the high-temperature heat exchanger (5) and the second high-temperature heat exchanger (10) are also respectively provided with a heat source medium channel communicated with the outside, the condenser (6) is also provided with a cooling medium channel communicated with the outside, the evaporator (7) or the heat source medium channel is also communicated with the outside, and the expander (1) and the second expander (3) are connected with the compressor (2) and the second compressor (12) and transmit power to form a combined cycle power device; wherein, or the expander (1) and the second expander (3) are connected with the compressor (2), the circulating pump (4) and the second compressor (12) and transmit power.

10. The combined cycle power plant mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator, a second high-temperature heat exchanger and a third expander; the condenser (6) is provided with a condensate pipeline, a steam channel of the evaporator (7) is communicated with the high-temperature heat exchanger (5) after the condensate pipeline is communicated with the evaporator (7) through a circulating pump (4), a steam channel of the compressor (2) is communicated with the high-temperature heat exchanger (5), the steam channel of the high-temperature heat exchanger (5) is also communicated with a third expander (11), the steam channel of the third expander (11) is also communicated with the expander (1) through a second high-temperature heat exchanger (10), the low-pressure steam channel of the evaporator (7) is also communicated with the evaporator (7), a low-pressure steam channel of the evaporator (7) is respectively communicated with the compressor (2) and the second expander (3), and the low-pressure steam channel of the second expander (3) is also communicated with the condenser (6); the high-temperature heat exchanger (5) and the second high-temperature heat exchanger (10) are also respectively provided with a heat source medium channel communicated with the outside, the condenser (6) is also provided with a cooling medium channel communicated with the outside, the evaporator (7) or the heat source medium channel is also communicated with the outside, and the expander (1), the second expander (3) and the third expander (11) are connected with the compressor (2) and transmit power to form a combined cycle power device; wherein, or the expander (1), the second expander (3) and the third expander (11) are connected with the compressor (2) and the circulating pump (4) and transmit power.

11. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator, a high-temperature heat regenerator, a second high-temperature heat exchanger and a second compressor; the condenser (6) is provided with a condensate pipeline, a steam channel of the evaporator (7) is communicated with the high-temperature heat exchanger (5) through a high-temperature heat regenerator (9) after the condensate pipeline is communicated with the evaporator (7) through a circulating pump (4), the compressor (2) is provided with a steam channel which is communicated with the high-temperature heat exchanger (5) through the high-temperature heat regenerator (9), the high-temperature heat exchanger (5) is also provided with a steam channel which is communicated with a second compressor (12), the second compressor (12) is also provided with a steam channel which is communicated with the expander (1) through a second high-temperature heat exchanger (10), the expander (1) is also provided with a low-pressure steam channel, the low-pressure steam channel of the evaporator (7) is communicated with the evaporator (7) through the high-temperature heat regenerator (9), the compressor (2) and the second expander (3) are respectively communicated, and the second expander (3) is also provided with; the high-temperature heat exchanger (5) and the second high-temperature heat exchanger (10) are also respectively provided with a heat source medium channel communicated with the outside, the condenser (6) is also provided with a cooling medium channel communicated with the outside, the evaporator (7) or the heat source medium channel is also communicated with the outside, and the expander (1) and the second expander (3) are connected with the compressor (2) and the second compressor (12) and transmit power to form a combined cycle power device; wherein, or the expander (1) and the second expander (3) are connected with the compressor (2), the second compressor (12) and the circulating pump (4) and transmit power.

12. The combined cycle power device mainly comprises an expander, a compressor, a second expander, a circulating pump, a high-temperature heat exchanger, a condenser, an evaporator, a high-temperature heat regenerator, a second high-temperature heat exchanger and a third expander; the condenser (6) is provided with a condensate pipeline which is communicated with the evaporator (7) through the circulating pump (4), then a steam channel of the evaporator (7) is communicated with the high-temperature heat exchanger (5) through the high-temperature heat regenerator (9), the compressor (2) is provided with a steam channel which is communicated with the high-temperature heat exchanger (5) through a high-temperature heat regenerator (9), the high-temperature heat exchanger (5) is also provided with a steam channel which is communicated with a third expander (11), the third expander (11) is also provided with a steam channel which is communicated with the expander (1) through a second high-temperature heat exchanger (10), the expander (1) is also provided with a low-pressure steam channel, the evaporator (7) is also provided with a low-pressure steam channel which is respectively communicated with the compressor (2) and the second expander (3) after the high-temperature heat regenerator (9) is communicated with the evaporator (7), and the second expander (3) is also provided with a low-pressure steam channel which is communicated with the condenser (6); the high-temperature heat exchanger (5) and the second high-temperature heat exchanger (10) are also respectively provided with a heat source medium channel communicated with the outside, the condenser (6) is also provided with a cooling medium channel communicated with the outside, the evaporator (7) or the heat source medium channel is also communicated with the outside, and the expander (1), the second expander (3) and the third expander (11) are connected with the compressor (2) and transmit power to form a combined cycle power device; wherein, or the expander (1), the second expander (3) and the third expander (11) are connected with the compressor (2) and the circulating pump (4) and transmit power.

13. A combined cycle power device is characterized in that a low-temperature heat regenerator and a second circulating pump are added in any combined cycle power device of claims 1 to 12, a condenser (6) is provided with a condensate pipeline which is communicated with an evaporator (7) through the circulating pump (4) and is adjusted to be that the condenser (6) is provided with a condensate pipeline which is communicated with the low-temperature heat regenerator (13) through the circulating pump (4), a middle steam extraction channel is additionally arranged on a compressor (2) and is communicated with the low-temperature heat regenerator (13), and the low-temperature heat regenerator (13) is provided with a condensate pipeline which is communicated with the evaporator (7) through the second circulating pump (14) to form the combined cycle power device.

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