CN106440469B

CN106440469B - Combined heat and power system

Info

Publication number: CN106440469B
Application number: CN201610822145.9A
Authority: CN
Inventors: 李华玉
Original assignee: Individual
Current assignee: Individual
Priority date: 2016-05-30
Filing date: 2016-08-31
Publication date: 2020-01-31
Anticipated expiration: 2036-08-31
Also published as: CN106440469A

Abstract

The invention provides a heat and power combined supply system, and belongs to the technical field of heat and power combined supply and heat pumps. The generator, the second generator, the absorber, the condenser, the second condenser, the evaporator, the throttle valve, the refrigerant liquid pump, the solution heat exchanger and the second solution heat exchanger form an absorption heat pump circulating system; the power machine provides heat load through the low-temperature condenser, the heater and the second heater, and the circulating pump is communicated with the low-temperature condenser, the heater, the second heater, the evaporator and the generator through a circulating medium pipeline; the second generator has high temperature heat medium channel, absorber, heated medium channel in the second condenser, and cooling medium channel in the condenser communicated with outside to form the combined heat and power system.

Description

Combined heat and power system

The technical field is as follows:

the invention belongs to the technical field of combined heat and power and absorption heat pumps.

Background art:

in a traditional heat power combined supply system taking sensible heat of hot fluid as a heat load conveying mode, a plurality of places to be improved exist, and the heat power combined supply system is mainly characterized in that (1) in a heat power combined supply system for long-distance, large-scale and graded heat supply, an -grade pipe network is high in temperature and pressure, pipelines are often located in urban population dense areas, potential safety hazards exist, initial investment of the pipe network is large, (2) temperature difference between low-pressure exhaust steam discharged by a steam power device and the environment is often difficult to utilize, (3) a steam power device taking coal as fuel has heat transfer temperature difference which is difficult to effectively utilize between fuel gas and power circulating steam, so that the comprehensive energy utilization rate of the heat power combined supply system is not high, (4) large heat transfer temperature difference exists between -grade pipe network circulating media and secondary pipe network circulating media or heated media, and is not utilized, and (5) certain limitation is brought to utilization of clean energy in the heat power combined supply system by .

The invention provides a series of heat-power combined supply systems which take exhaust steam at the tail end of a power machine or low-pressure extraction steam as a low-temperature heat source and combine an absorption heat pump technology, on the premise of high-efficiency utilization of heat energy, take the temperature and pressure of an -grade heat supply pipe network in the heat-power combined supply system as a core, increase of temperature difference of supply water and return water of the pipe network to reduce corresponding initial investment, increase of working safety of the power machine and efficiency of converting heat energy into mechanical energy, and take the application of clean or high-efficiency energy in the heat-power combined supply system into consideration.

The invention content is as follows:

the invention mainly aims to provide a combined heat and power system, and the specific contents of the invention are explained as follows:

1. the heat and power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser and a circulating pump; the generator is provided with a concentrated solution pipeline which is communicated with a second generator through a solution pump, a solution heat exchanger and a second solution heat exchanger, the second generator is also provided with a concentrated solution pipeline which is communicated with an absorber through the second solution heat exchanger, the absorber is also provided with a dilute solution pipeline which is communicated with the generator through the solution heat exchanger, the generator is also provided with a refrigerant steam channel which is communicated with a condenser, the second generator is also provided with a refrigerant steam channel which is communicated with a second condenser, the condenser is also provided with a refrigerant liquid pipeline which is communicated with an evaporator through a refrigerant liquid pump, the second condenser is also provided with a refrigerant liquid pipeline which is communicated with the evaporator through a throttle valve, the evaporator is also provided with a refrigerant steam channel which is communicated with the absorber, a new steam channel of a power machine is communicated with the outside, the low-temperature condenser is also provided with a low-temperature condensate channel which is communicated with the outside, the circulating pump has circulating medium pipeline connected to the evaporator via the low temperature condenser and circulating medium pipeline connected to the circulating pump via the generator, the second generator has high temperature heat medium channel connected to the outside, the absorber and the second condenser have heated medium channel connected to the outside, and the condenser has cooling medium channel connected to the outside to form the combined heat and power system.

2. A combined heat and power system as described in item 1, wherein the circulating pump has a circulating medium pipeline, the circulating medium pipeline of the evaporator is communicated with the circulating pump through the generator after the circulating pump has a circulating medium pipeline communicated with the evaporator through the low temperature condenser, and the circulating pump has a circulating medium pipeline, the circulating medium pipeline of the generator is communicated with the circulating pump through the evaporator after the circulating pump has a circulating medium pipeline communicated with the generator through the low temperature condenser, thereby forming the combined heat and power system.

3. A combined heat and power system as described in claim 1, wherein the circulating pump has a circulating medium pipeline, the evaporator is connected to the evaporator via the low temperature condenser, the circulating medium pipeline is connected to the circulating pump via the generator, and the circulating pump has a circulating medium pipeline, the evaporator and the generator are connected to the evaporator and the generator via the low temperature condenser, and the circulating medium pipeline is connected to the circulating pump.

4. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a circulating pump and a heater, wherein the generator is provided with a concentrated solution pipeline which is communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the second generator is also provided with a concentrated solution pipeline which is communicated with the absorber through the second solution heat exchanger, the absorber is also provided with a dilute solution pipeline which is communicated with the generator through the solution heat exchanger, the generator is also provided with a refrigerant steam channel which is communicated with the condenser, the second generator is also provided with a refrigerant steam channel which is communicated with the second condenser, the condenser is also provided with a refrigerant liquid pipeline which is communicated with the evaporator through the refrigerant liquid pump, the second condenser is also provided with a refrigerant liquid pipeline which is communicated with the evaporator through the throttle valve, the evaporator is also provided with a steam channel which is communicated with the absorber, the power machine is respectively provided with a new steam channel which is communicated with the outside and is also provided with a steam exhaust channel which is communicated with the condenser, the condenser is also provided with a heat power machine which is communicated with a condensate medium heating medium, the condenser, and the condenser, the condenser are also provided with the second generator, and the condenser, the heater, the high-temperature heat power machine are also provided with the condenser.

5. The combined heat and power system as set forth in item 4, wherein the circulating pump is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the circulating pump through the generator after the circulating pump is communicated with the evaporator through the heater, and the circulating medium pipeline is communicated with the circulating pump through the evaporator after the circulating pump is communicated with the generator through the circulating medium pipeline, so as to form the combined heat and power system.

6. A combined heat and power system as described in item 4, wherein the circulating pump has a circulating medium pipeline, the evaporator is connected to the evaporator via a heater, the circulating medium pipeline is connected to the circulating pump via a generator, and the circulating pump has a circulating medium pipeline, the evaporator and the generator are connected to the evaporator and the generator via a heater, and the circulating medium pipeline is connected to the circulating pump.

7. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser, a circulating pump and a heater, wherein the generator is provided with a concentrated solution pipeline which is communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the second generator is also provided with a concentrated solution pipeline which is communicated with the absorber through the second solution heat exchanger, the absorber is also provided with a dilute solution pipeline which is communicated with the generator through the solution heat exchanger, the generator is also provided with a refrigerant steam channel which is communicated with the condenser, the second generator is also provided with a refrigerant steam channel which is communicated with the second condenser, the condenser is also provided with a refrigerant liquid pipeline which is communicated with the evaporator through the refrigerant liquid pump, the second condenser is also provided with a refrigerant liquid pipeline which is communicated with the evaporator through the throttle valve, the evaporator is also provided with a refrigerant steam channel which is communicated with the absorber, the power machine is provided with a new steam channel which is communicated with the outside, the power machine is also provided with a low-temperature condenser which is communicated with the low-temperature condenser, the condenser is also provided with the condenser which is communicated with the low-temperature condenser, the second generator is also provided with the condenser, the heater , the condenser is also provided with the heat power machine is communicated with the condenser or the condenser, the high-temperature condenser, the heat power machine is also provided with the condenser, the.

8. A combined heat and power system as described in item 7, wherein the circulating pump has a circulating medium pipeline, the circulating medium pipeline of the evaporator is connected to the circulating pump through the generator after the circulating pump has a circulating medium pipeline connected to the evaporator through the low-temperature condenser and the heater, and the circulating pump has a circulating medium pipeline, the circulating medium pipeline of the generator is connected to the circulating pump through the evaporator after the circulating pump has a circulating medium pipeline connected to the generator through the low-temperature condenser and the heater, thereby forming the combined heat and power system.

9. A combined heat and power system as described in item 7, wherein the circulating pump has a circulating medium pipeline, the evaporator is connected to the evaporator through the low temperature condenser and heater, the circulating medium pipeline is connected to the circulating pump through the generator, the circulating pump has a circulating medium pipeline, the evaporator and generator are connected to the evaporator and generator through the low temperature condenser and heater, and the circulating medium pipeline is connected to the circulating pump.

10. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a circulating pump, a heater and a second heater, wherein the generator is provided with a concentrated solution pipeline which is communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the second generator is also provided with a concentrated solution pipeline which is communicated with the absorber through the second solution heat exchanger, the absorber is also provided with a dilute solution pipeline which is communicated with the generator through the solution heat exchanger, the generator is also provided with a refrigerant vapor channel which is communicated with the condenser, the second generator is also provided with a refrigerant vapor channel which is communicated with the second condenser, the condenser is also provided with a refrigerant liquid pipeline which is communicated with the evaporator through the liquid pump, the second condenser is also provided with a refrigerant liquid pipeline which is communicated with the evaporator through the throttle valve, the evaporator is also provided with a refrigerant vapor channel which is communicated with the absorber, the power machine is respectively provided with a new vapor channel which is communicated with the outside and is also provided with a condensate channel which is communicated with the second generator, the second heater, the condenser is also provided with a high temperature heating medium, the condenser is also provided with the second generator, the condenser is also provided with the second heater, the condenser is communicated with the second generator, the condenser is also provided with the condenser, the condensate medium heating medium channel which is communicated with the condenser, and the condenser, the second heater.

11. A combined heat and power system as described in item 10, wherein the circulating pump has a circulating medium pipeline, the circulating medium pipeline of the evaporator is connected to the circulating pump through the generator after the circulating pump has a circulating medium pipeline connected to the evaporator through the heater and the second heater, and the circulating pump has a circulating medium pipeline, the circulating medium pipeline of the generator is connected to the circulating pump through the evaporator after the circulating pump has a circulating medium pipeline connected to the generator through the heater and the second heater, thereby forming the combined heat and power system.

12. A combined heat and power system as described in item 10, wherein the circulating pump has a circulating medium pipeline, the evaporator is connected to the evaporator via a heater and a second heater, the circulating medium pipeline is connected to the circulating pump via a generator, the circulating pump has a circulating medium pipeline, the evaporator and the generator are connected to the evaporator and the generator via the heater and the second heater, and the circulating medium pipeline is connected to the circulating pump.

13. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser, a circulating pump, a heater and a second heater, wherein the generator is provided with a concentrated solution pipeline communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the second generator is also provided with a concentrated solution pipeline communicated with the absorber through the second solution heat exchanger, the absorber is also provided with a dilute solution pipeline communicated with the generator through the solution heat exchanger, the generator is also provided with a refrigerant vapor channel communicated with the condenser, the second generator is also provided with a refrigerant vapor channel communicated with the second condenser, the condenser is also provided with a refrigerant liquid pipeline communicated with the evaporator through the liquid pump, the second condenser is also provided with the refrigerant liquid pipeline communicated with the evaporator through the throttle valve, the evaporator is also provided with a refrigerant vapor channel communicated with the absorber, the power machine is provided with a new vapor channel communicated with the outside, the low-temperature condenser is also provided with a low-temperature condensate channel communicated with the condenser, the second heater is also provided with a condensate channel communicated with the second generator, the condenser, the heater connected with the condenser, the second heater , the condenser is also provided with the condenser, the second heater is also provided with the condenser, the high-temperature heater, the condenser is also provided with the condenser, the second heater, the condenser is also provided with the condenser, the heater is also provided with the.

14. A combined heat and power system as set forth in claim 13, wherein the circulating pump is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator through the low-temperature condenser, the heater and the second heater, the circulating medium pipeline is communicated with the circulating pump through the generator, and the circulating pump is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the generator through the low-temperature condenser, the heater and the second heater, the circulating medium pipeline is communicated with the circulating pump through the evaporator, thereby forming the combined heat and power system.

15. A combined heat and power system as set forth in claim 13, wherein the circulating pump is provided with a circulating medium pipeline, the evaporator is further provided with a circulating medium pipeline communicated with the circulating pump through the generator after the circulating pump is provided with a circulating medium pipeline communicated with the evaporator through the low-temperature condenser, the heater and the second heater, the evaporator and the generator are further provided with a circulating medium pipeline communicated with the circulating pump through the low-temperature condenser, the heater and the second heater, respectively, so as to form the combined heat and power system.

16. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a circulating pump, a heater, a second heater and a third heater, wherein the generator is provided with a concentrated solution pipeline communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the second generator is also provided with a concentrated solution pipeline communicated with the absorber through the second solution heat exchanger, the absorber is also provided with a dilute solution pipeline communicated with the generator through the solution heat exchanger, the generator is also provided with a refrigerant vapor channel communicated with the condenser, the second generator is also provided with a refrigerant vapor channel communicated with the second condenser, the condenser is also provided with a refrigerant liquid pipeline communicated with the evaporator through the refrigerant liquid pump, the second condenser is also provided with the refrigerant liquid pipeline communicated with the evaporator through the throttle valve, the evaporator is also provided with a refrigerant vapor channel communicated with the absorber, the power machine is respectively provided with a new vapor channel communicated with the outside and an exhaust channel communicated with the outside, the power machine is also provided with a second heater, the third heater is also provided with a condensate channel communicated with a condensate heating medium channel, the second generator, the third heater is also provided with a condensate channel communicated with the condenser, the third heater, the condenser is also provided with a condensate medium heating medium channel communicated with the condenser, the third heater, the condenser is also provided with the condenser, the third heater.

17. A combined heat and power system as set forth in item 16, wherein the circulating pump is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the circulating pump through the generator after the circulating pump is communicated with the evaporator through the heater, the second heater and the third heater, and the circulating medium pipeline is communicated with the circulating pump through the evaporator after the circulating pump is provided with the circulating medium pipeline, the heater, the second heater and the third heater are communicated with the generator, so as to form the combined heat and power system.

18. A combined heat and power system as set forth in item 16, wherein the circulating pump is provided with a circulating medium pipeline, the evaporator is communicated with the circulating pump through the generator after the circulating pump is communicated with the evaporator through the heater, the second heater and the third heater, the circulating medium pipeline is adjusted to be communicated with the circulating pump through the generator after the circulating pump is provided with the circulating medium pipeline, the evaporator is communicated with the generator through the heater, the second heater and the third heater, and the generator is communicated with the circulating pump through the circulating medium pipeline, so as to form the combined heat and power system.

19. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser, a circulating pump, a heater, a second heater and a third heater, wherein the generator is provided with a concentrated solution pipeline communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the second generator is also provided with a concentrated solution pipeline communicated with the absorber through the second solution heat exchanger, the absorber is also provided with a dilute solution pipeline communicated with the generator through the solution heat exchanger, the generator is also provided with a refrigerant vapor channel communicated with the condenser, the second generator is also provided with a refrigerant vapor channel communicated with the second condenser, the condenser is also provided with a refrigerant liquid pipeline communicated with the evaporator through the refrigerant liquid pump, the second condenser is also provided with the refrigerant liquid pipeline communicated with the evaporator through the throttle valve, the evaporator is also provided with a refrigerant vapor channel communicated with the absorber, the power machine is provided with a new vapor channel communicated with the outside, the low-temperature condenser is also provided with a low-temperature condensate channel communicated with the condenser after the condenser communicated with the condenser, the second heater is also provided with a condensate channel communicated with the second heater 3583, the evaporator is also provided with the evaporator communicated with the third heater, the power machine is also provided with the third heater, the third heater is also provided with the condenser, the heat power machine is also provided with the condenser, the condenser is also provided with the condensate channel provided with the condenser, the condenser is also provided with the condenser, the heater connected with the condenser, the third heater, the condenser, the heater, the condenser, the third heater, the condenser is provided with the condenser, the.

20. A combined heat and power system as set forth in item 19, wherein the circulating pump is provided with a circulating medium pipeline which is communicated with the evaporator through the low-temperature condenser, the heater, the second heater and the third heater, then the circulating medium pipeline of the evaporator is communicated with the circulating pump through the generator, and the circulating pump is adjusted to be provided with a circulating medium pipeline which is communicated with the generator through the low-temperature condenser, the heater, the second heater and the third heater, then the circulating medium pipeline of the generator is communicated with the circulating pump through the evaporator, thereby forming the combined heat and power system.

21. A combined heat and power system as set forth in claim 19, wherein the circulating pump is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the circulating pump through the generator after the circulating pump is communicated with the evaporator through the low-temperature condenser, the heater, the second heater and the third heater, the circulating medium pipeline is adjusted to be communicated with the circulating pump through the circulating medium pipeline, the evaporator and the generator after the circulating pump is communicated with the evaporator and the generator through the low-temperature condenser, the heater, the second heater and the third heater, respectively, and the circulating medium pipeline is communicated with the circulating pump, respectively, thereby forming the combined heat and power system.

22. The heat and power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser, a circulating pump and a heat supplier; the generator is provided with a concentrated solution pipeline which is communicated with a second generator through a solution pump, a solution heat exchanger and a second solution heat exchanger, the second generator is also provided with a concentrated solution pipeline which is communicated with an absorber through the second solution heat exchanger, the absorber is also provided with a dilute solution pipeline which is communicated with the generator through the solution heat exchanger, the generator is also provided with a refrigerant steam channel which is communicated with a condenser, the second generator is also provided with a refrigerant steam channel which is communicated with a second condenser, the condenser is also provided with a refrigerant liquid pipeline which is communicated with an evaporator through a refrigerant liquid pump, the second condenser is also provided with a refrigerant liquid pipeline which is communicated with the evaporator through a throttle valve, the evaporator is also provided with a refrigerant steam channel which is communicated with the absorber, a new steam channel of a power machine is communicated with the outside, the low-temperature condenser is also provided with a low-temperature condensate channel which is communicated with the outside, the circulating pump has circulating medium pipeline connected via low temperature condenser and heat supplier to the evaporator, the evaporator has circulating medium pipeline connected via generator to the circulating pump, the second generator has high temperature heat medium channel connected to the outside, the absorber, the second condenser and the heat supplier have heated medium channel connected to the outside, and the condenser has cooling medium channel connected to the outside to form the combined heat and power system.

23. A combined heat and power system as described in item 22, wherein the circulating pump has a circulating medium pipeline, the circulating medium pipeline is connected to the evaporator via the low temperature condenser and the heat supply device, the circulating medium pipeline of the evaporator is connected to the circulating pump via the generator, and the circulating pump has a circulating medium pipeline, the circulating medium pipeline is connected to the generator via the low temperature condenser and the heat supply device, the circulating medium pipeline of the generator is connected to the circulating pump via the evaporator, thereby forming the combined heat and power system.

24. A combined heat and power system as described in item 22, wherein the circulating pump has a circulating medium pipeline, the evaporator is connected to the evaporator via a low temperature condenser and a heat supply device, the circulating medium pipeline is connected to the circulating pump via a generator, the circulating pump has a circulating medium pipeline, the evaporator and the generator are connected to the evaporator and the generator via the low temperature condenser and the heat supply device, and the circulating medium pipeline is connected to the circulating pump.

25. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a circulating pump, a heater and a heat supply device, wherein the generator is provided with a concentrated solution pipeline which is communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the second generator is also provided with a concentrated solution pipeline which is communicated with the absorber through the second solution heat exchanger, the absorber is also provided with a dilute solution pipeline which is communicated with the generator through the solution heat exchanger, the generator is also provided with a refrigerant vapor channel which is communicated with the condenser, the second generator is also provided with a refrigerant vapor channel which is communicated with the second condenser, the condenser is also provided with a refrigerant liquid pipeline which is communicated with the evaporator through the refrigerant liquid pump, the second condenser is also provided with a refrigerant liquid pipeline which is communicated with the evaporator through the throttle valve, the evaporator is also provided with a refrigerant vapor channel which is communicated with the absorber, the power machine is respectively provided with a new vapor channel which is communicated with the outside and is also provided with a heat supply medium which is communicated with the condenser, the heat supply device, the condenser is also provided with the second generator, the heat supply device, the condenser is also provided with the heat supply device, the condenser and the heat supply device, the condenser are also provided with the condenser, the heat supply device.

26. A combined heat and power system as described in item 25, wherein the circulating pump has a circulating medium pipeline, the circulating medium pipeline of the evaporator is connected to the circulating pump through the generator after the circulating pump has a circulating medium pipeline connected to the evaporator through the heater and the heater, and the circulating pump has a circulating medium pipeline, the circulating medium pipeline of the generator is connected to the circulating pump through the evaporator after the circulating pump has a circulating medium pipeline connected to the generator through the heater and the heater, thereby forming a combined heat and power system.

27. A combined heat and power system as described in item 25, wherein the circulating pump has a circulating medium pipeline, the evaporator is connected to the evaporator via a heater and a heat supply device, the circulating medium pipeline is connected to the circulating pump via a generator, and the circulating pump has a circulating medium pipeline, the evaporator and the generator are connected to the evaporator and the generator via the heater and the heat supply device, respectively, and the circulating medium pipeline is connected to the circulating pump, thereby forming the combined heat and power system.

28. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser, a circulating pump, a heater and a heat supply device, wherein the generator is provided with a concentrated solution pipeline communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the second generator is also provided with a concentrated solution pipeline communicated with the absorber through the second solution heat exchanger, the absorber is also provided with a dilute solution pipeline communicated with the generator through the solution heat exchanger, the generator is also provided with a refrigerant steam channel communicated with the condenser, the second generator is also provided with a refrigerant steam channel communicated with the second condenser, the condenser is also provided with a refrigerant liquid pipeline communicated with the evaporator through the throttle valve, the evaporator is also provided with a refrigerant steam channel communicated with the absorber, the power machine is provided with a new steam channel communicated with the outside, the low-temperature condenser is communicated with the low-temperature condenser after the low-temperature condenser is communicated with the low-temperature condenser, the second condenser is also provided with the refrigerant steam channel communicated with the evaporator, the heater after the second generator is communicated with the low-temperature condenser, the heat supply medium is also provided with the heat supply medium, the heat supply system is also provided with the heat supply device, the heat supply device is also provided with the condenser, the heat supply device is provided with the heat supply device, the condenser, the heat supply device is provided with the condenser.

29. A combined heat and power system as described in item 28, wherein the circulating pump has a circulating medium pipeline, the circulating medium pipeline is connected to the evaporator via the low-temperature condenser, the heater and the heater, the evaporator has a circulating medium pipeline, the generator has a circulating medium pipeline, and the circulating pump is connected to the circulating pump via the generator, and the circulating pump has a circulating medium pipeline, the low-temperature condenser, the heater and the heater are connected to the generator, and the generator has a circulating medium pipeline, the evaporator and the circulating pump are connected to form the combined heat and power system.

30. A combined heat and power system as described in item 28, wherein the circulating pump has a circulating medium pipeline, the circulating medium pipeline is connected to the evaporator through the low temperature condenser, the heater and the heater, the evaporator is connected to the circulating pump through the generator, the circulating pump has a circulating medium pipeline, the evaporator and the generator are connected to the evaporator and the generator through the low temperature condenser, the heater and the heater, respectively, and the circulating medium pipeline is connected to the circulating pump, thereby forming the combined heat and power system.

31. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a circulating pump, a heater, a second heater and a heat supply device, wherein the generator is provided with a concentrated solution pipeline communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the second generator is also provided with a concentrated solution pipeline communicated with the absorber through the second solution heat exchanger, the absorber is also provided with a dilute solution pipeline communicated with the generator through the solution heat exchanger, the generator is also provided with a refrigerant vapor channel communicated with the condenser, the second generator is also provided with a refrigerant vapor channel communicated with the second condenser, the condenser is also provided with a refrigerant liquid pipeline communicated with the evaporator through the refrigerant liquid pump, the second condenser is also provided with the refrigerant liquid pipeline communicated with the evaporator through the throttle valve, the evaporator is also provided with a refrigerant vapor channel communicated with the absorber, the power machine is respectively provided with a new vapor channel communicated with the outside and an exhaust channel communicated with the outside, the second heater is also provided with a condensate heating medium, the second generator is also provided with a condensate heating medium, the condenser, the second generator is also provided with the condenser, the second heater is also provided with a condensate medium heating medium connected with the condenser and the condenser, the heat supply device, the second generator is also provided with the condenser, the heat supply device and the condenser, the heat supply device, the condenser, the heat supply device is also provided with the condenser.

32. The combined heat and power system as set forth in item 31, wherein the circulating pump is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator through the heater, the second heater and the heater, the circulating medium pipeline is communicated with the circulating pump through the generator, and the circulating pump is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the generator through the heater, the second heater and the heater, and the circulating medium pipeline is communicated with the circulating pump through the evaporator to form the combined heat and power system.

33. A combined heat and power system as set forth in item 31, wherein the circulating pump is provided with a circulating medium pipeline, the evaporator is further provided with a circulating medium pipeline which is communicated with the circulating pump through the generator after the circulating pump is provided with a circulating medium pipeline which is communicated with the evaporator through the heater, the second heater and the heater, the evaporator and the generator are further provided with circulating medium pipelines which are communicated with the circulating pump through the heater, the second heater and the heater respectively, and the circulating pump is further provided with a circulating medium pipeline which is communicated with the circulating pump.

34. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser, a circulating pump, a heater, a second heater and a heat supply device, wherein the generator is provided with a concentrated solution pipeline communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the second generator is also provided with a concentrated solution pipeline communicated with the absorber through the second solution heat exchanger, the absorber is also provided with a dilute solution pipeline communicated with the generator through the solution heat exchanger, the generator is also provided with a refrigerant vapor channel communicated with the condenser, the second generator is also provided with a refrigerant vapor channel communicated with the second condenser, the condenser is also provided with a refrigerant liquid pipeline communicated with the evaporator through the refrigerant liquid pump, the second condenser is also provided with the refrigerant liquid pipeline communicated with the evaporator through the throttle valve, the evaporator is also provided with a refrigerant vapor channel communicated with the absorber, the power machine is provided with a new vapor channel communicated with the outside, the low-temperature condenser is communicated with a low-temperature condenser channel after the condenser is communicated with the low-temperature condenser, the second heater is also provided with the heat supply medium heater, the heat supply channel is communicated with the second generator, the heat supply channel connected with the condenser, the second generator is also provided with the condenser, the heat supply channel connected with the condenser, the heat supply device, the heat supply channel of the second generator is also provided with the condenser, the heat supply device, the condenser, the heat supply channel connected with the condenser, the heat supply channel of the heat supply device is also provided with the condenser, the heat supply device is also provided with the condenser, the second heater.

35. A combined heat and power system as described in item 34, wherein the circulating pump is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the circulating pump through the generator after the circulating pump is communicated with the evaporator through the low-temperature condenser, the heater, the second heater and the heater, and the circulating medium pipeline is communicated with the circulating pump through the evaporator after the circulating pump is provided with a circulating medium pipeline, the low-temperature condenser, the heater, the second heater and the heater are communicated with the generator, so as to form the combined heat and power system.

36. A combined heat and power system as described in item 34, wherein the circulating pump is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the circulating pump through the generator after the circulating pump is communicated with the evaporator through the low-temperature condenser, the heater, the second heater and the heater, and the circulating medium pipeline is adjusted to be communicated with the circulating pump through the circulating medium pipeline respectively communicated with the evaporator and the generator after the circulating pump is provided with the circulating medium pipeline through the low-temperature condenser, the heater, the second heater and the heater, and the circulating medium pipeline is communicated with the circulating pump.

37. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a circulating pump, a heater, a second heater, a third heater and a heat supply device, wherein the generator is provided with a concentrated solution pipeline communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the second generator is also provided with a concentrated solution pipeline communicated with the absorber through the second solution heat exchanger, the absorber is also provided with a dilute solution pipeline communicated with the generator through the solution heat exchanger, the generator is also provided with a refrigerant vapor channel communicated with the condenser, the second generator is also provided with a refrigerant vapor channel communicated with the second condenser, the condenser is also provided with a refrigerant liquid pipeline communicated with the evaporator through the refrigerant liquid pump, the second condenser is also provided with the refrigerant liquid pipeline communicated with the evaporator through the throttle valve, the evaporator is also provided with a refrigerant vapor channel communicated with the absorber, the power machine is respectively provided with a new vapor channel communicated with the outside and an exhaust channel communicated with the outside, the power machine is also provided with a second heater , the third heater is also provided with a condensate medium heating medium channel communicated with the second generator, the third heater is also provided with a condensate medium heating medium channel communicated with the condenser, the second generator, the condenser, the third heater, the heat supply device is also provided with the condenser, the third heater, the condenser, the heat supply device, the third heater, the condenser is also provided with the condenser, the heat supply medium heating medium channel communicated with the condenser, the heat supply device, the condenser, the third heater, the condenser.

38. A combined heat and power system as set forth in claim 37, wherein the circulating pump is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the circulating pump through the generator after the circulating pump is communicated with the evaporator through the heater, the second heater, the third heater and the heater, and the circulating medium pipeline is communicated with the circulating pump through the evaporator after the circulating pump is communicated with the generator through the circulating medium pipeline, the second heater, the third heater and the heater, so as to form the combined heat and power system.

39. A combined heat and power system as set forth in claim 37, wherein the circulating pump is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the circulating pump through the generator after the circulating pump is communicated with the evaporator through the heater, the second heater, the third heater and the heater, and the circulating medium pipeline is adjusted to be communicated with the circulating pump through the circulating medium pipeline, the heater, the second heater, the third heater and the heater, the evaporator and the generator after the circulating pump is respectively communicated with the evaporator and the generator, and the circulating medium pipeline is respectively communicated with the circulating pump to form the combined heat and power system.

40. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser, a circulating pump, a heater, a second heater, a third heater and a heat supply device, wherein the generator is provided with a concentrated solution pipeline communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the second generator is also provided with a concentrated solution pipeline communicated with the absorber through the second solution heat exchanger, the absorber is also provided with a dilute solution pipeline communicated with the generator through the solution heat exchanger, the generator is also provided with a refrigerant vapor channel communicated with the condenser, the second generator is also provided with a refrigerant vapor channel communicated with the second condenser, the condenser is also provided with the refrigerant liquid pipeline communicated with the evaporator through the refrigerant liquid pump, the second condenser is also provided with the refrigerant liquid pipeline communicated with the evaporator through the throttle valve, the evaporator is also provided with a refrigerant vapor channel communicated with the absorber, the power machine is provided with a new vapor channel communicated with the outside, the power machine is also provided with a new vapor channel communicated with the condenser, the low-temperature condenser is also provided with the condenser, the condensate channel communicated with the second heater, the third heater is also provided with the condenser, the condensate channel provided with the condenser, the heater connected with the third heater, the condenser is also provided with the condenser, the heat supply device, the condenser, the heat supply channel provided with the condenser, the condenser is provided with the heat supply channel provided with the condenser, the third heater, the condenser, the heater.

41. A combined heat and power system as set forth in item 40, wherein the circulating pump is provided with a circulating medium pipeline which is communicated with the evaporator through the low-temperature condenser, the heater, the second heater, the third heater and the heat supply device, then the evaporator is provided with a circulating medium pipeline which is communicated with the circulating pump through the generator, and the circulating pump is adjusted to be provided with a circulating medium pipeline which is communicated with the generator through the low-temperature condenser, the heater, the second heater, the third heater and the heat supply device, then the generator is provided with a circulating medium pipeline which is communicated with the circulating pump through the evaporator, thereby forming the combined heat and power system.

42. A combined heat and power system as set forth in item 40, wherein the circulating pump is provided with a circulating medium pipeline which is communicated with the evaporator through the low-temperature condenser, the heater, the second heater, the third heater and the heater, the evaporator is further provided with a circulating medium pipeline which is communicated with the circulating pump through the generator, the circulating pump is adjusted to be provided with a circulating medium pipeline which is communicated with the evaporator and the generator through the low-temperature condenser, the heater, the second heater, the third heater and the heater, and the evaporator and the generator are further provided with circulating medium pipelines which are communicated with the circulating pump, respectively, so as to form the combined heat and power system.

43. A combined heat-power system, which is any combined heat-power system described in

items

1, 4, 7, 10, 13, 16, 19, 22, 25, 28, 31, 34, 37, and 40, wherein a preheater is added, a refrigerant liquid pipeline of a condenser is communicated with an evaporator through a refrigerant liquid pump and is adjusted to be communicated with the condenser through the refrigerant liquid pump and the preheater, a circulating medium pipeline of the evaporator is communicated with a circulating pump through a generator and is adjusted to be communicated with the evaporator through a circulating medium pipeline, and the circulating medium pipeline is communicated with the circulating pump through the generator and the preheater, thereby forming the combined heat-power system.

44. A combined heat-power system, which is characterized in that a preheater is added in any combined heat-power system described in

items

2, 5, 8, 11, 14, 17, 20, 23, 26, 29, 32, 35, 38 and 41, a refrigerant liquid pipeline of a condenser is communicated with an evaporator through a refrigerant liquid pump and is adjusted to be communicated with the condenser through the refrigerant liquid pump and the preheater, a circulating medium pipeline of a generator is communicated with a circulating pump through the evaporator and is adjusted to be communicated with the generator through a circulating medium pipeline, and the circulating medium pipeline is communicated with the circulating pump through the evaporator and the preheater, so that the combined heat-power system is formed.

45. A thermodynamic combined supply system, which is any thermodynamic combined supply system described in

items

3, 6, 9, 12, 15, 18, 21, 24, 27, 30, 33, 36, 39 and 42, wherein a preheater is added, a refrigerant liquid pipeline of a condenser is communicated with an evaporator through a refrigerant liquid pump and is adjusted to be communicated with the condenser through the refrigerant liquid pump and the preheater, a circulating medium pipeline of an evaporator and a circulating pump are respectively communicated with the generator through the circulating pump and are adjusted to be communicated with the evaporator through the circulating pump and the circulating pump through the circulating medium pipeline of the generator, and a circulating medium pipeline of the evaporator and the circulating pump are respectively communicated with the circulating pump through the preheater to form the thermodynamic combined supply system.

46. A combined heat and power system as described in any of items 1-45, wherein a third generator, a second absorber, a second solution pump and a third solution heat exchanger are added, the generator having a concentrated solution line communicating with the second generator via the solution pump, the solution heat exchanger and the second solution heat exchanger, the generator having a concentrated solution line communicating with the second absorber via the solution pump, the solution heat exchanger and the second solution heat exchanger, the second absorber having a dilute solution line communicating with the second generator via the second solution pump and the third solution heat exchanger, the second generator having a concentrated solution line communicating with the absorber via the second solution heat exchanger, the third generator having a concentrated solution line communicating with the third generator via the third solution heat exchanger, the third generator having a refrigerant vapor passage communicating with the second absorber, the third generator having a high temperature heat medium passage communicating with the outside, the second generator having a heated medium passage communicating with the outside to form the combined heat and power system.

47. A combined heat-power system, wherein a third generator, a second solution pump, a third solution heat exchanger and a second throttle valve are added in any combined heat-power system described in items 1-45, a concentrated solution pipeline is additionally arranged in the generator and communicated with the third generator through the second solution pump, the solution heat exchanger and the third solution heat exchanger, a concentrated solution pipeline is further communicated with an absorber through the third solution heat exchanger in the third generator, the communication between the second generator and a second condenser is adjusted to be that the second generator is communicated with the third generator through a refrigerant vapor channel, then the refrigerant liquid pipeline of the third generator is communicated with the second condenser through the second throttle valve, and the refrigerant vapor channel of the third generator is communicated with the second condenser to form the combined heat-power system.

48. A combined heat-power system, wherein a third generator, a third solution heat exchanger and a second throttle valve are added to any combined heat-power system described in items 1-45, wherein the generator is provided with a concentrated solution pipeline communicated with the second generator through a solution pump, a solution heat exchanger and a second solution heat exchanger, the generator is provided with a concentrated solution pipeline communicated with the second generator through the solution pump, the solution heat exchanger, the second solution heat exchanger and the third solution heat exchanger, the second generator is provided with a concentrated solution pipeline communicated with an absorber through the second solution heat exchanger, the second generator is provided with a concentrated solution pipeline communicated with the absorber through the third solution heat exchanger, the third generator is further provided with a concentrated solution pipeline communicated with the absorber through the second solution heat exchanger, the second generator is provided with a refrigerant vapor passage communicated with the second condenser, the third generator is further provided with a refrigerant liquid pipeline communicated with the second condenser through the second throttle valve, and the third generator is further provided with a refrigerant vapor passage communicated with the second condenser to form the combined heat-power system.

49. A combined heat-power system, wherein a third generator, a second solution pump, a third solution heat exchanger and a second throttle valve are added to any combined heat-power system described in items 1-45, wherein the generator is provided with a concentrated solution pipeline communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the generator is provided with a concentrated solution pipeline communicated with the third generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the third generator is further provided with a concentrated solution pipeline communicated with the second generator through the second solution pump and the third solution heat exchanger, the second generator is provided with a concentrated solution pipeline communicated with the absorber through the second solution heat exchanger, the second generator is provided with a concentrated solution pipeline communicated with the absorber through the third solution heat exchanger and the second solution heat exchanger, the second generator is provided with a refrigerant vapor channel communicated with the second condenser, the third generator is further provided with a refrigerant vapor channel communicated with the third generator, and the third generator is further provided with a refrigerant vapor channel communicated with the second condenser through the second throttle valve.

50. The combined heat and power system is any combined heat and power system described in items 47-49, wherein the third generator is provided with a high-temperature heat medium channel communicated with the outside to form the combined heat and power system.

51. A combined heat power system, wherein a third generator, a second absorber, a second solution pump and a third solution heat exchanger are added in any combined heat power system, the second generator is communicated with a second condenser through a refrigerant vapor passage, the second generator is adjusted to be communicated with the second absorber through the refrigerant vapor passage, the second absorber is also communicated with a dilute solution pipeline through the second solution pump and the third solution heat exchanger, the third generator is also communicated with the second absorber through the third solution heat exchanger, the third generator is also communicated with the second condenser through the refrigerant vapor passage, the third generator is also communicated with the outside through a high-temperature heat medium passage, and the second absorber is also communicated with the outside through a heated medium passage to form the combined heat power system.

52. A combined heat-power system, wherein a third generator, a second absorber, a second solution pump and a third solution heat exchanger are added to any combined heat-power system described in items 1, 4, 7, 10, 13, 16, 19, 22, 25, 28, 31, 34, 37, 40, the generator is provided with a concentrated solution pipeline communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the generator is provided with a concentrated solution pipeline communicated with the second absorber through the solution heat exchanger, the second absorber is provided with a dilute solution pipeline communicated with the second generator through the solution pump and the second solution heat exchanger, the second generator is provided with a concentrated solution pipeline communicated with the absorber through the second solution heat exchanger, the second generator is provided with a concentrated solution pipeline communicated with the third generator through the second solution heat exchanger, the third generator is provided with a concentrated solution pipeline communicated with the third generator through the second solution pump and the third solution heat exchanger, the absorber is provided with a dilute solution pipeline communicated with the generator through the solution heat exchanger, the third generator is provided with a dilute solution heat exchanger, the third generator is provided with a circulating pump and a circulating pump, the absorber is provided with a circulating pump, the evaporator medium circulating pump is communicated with the second generator, and the evaporator.

53. A combined heat-power system, wherein a third generator, a second absorber, a second solution pump and a third solution heat exchanger are added to any combined heat-power system described in items 2, 5, 8, 11, 14, 17, 20, 23, 26, 29, 32, 35, 38, 41, the generator is provided with a concentrated solution pipeline communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the generator is provided with a concentrated solution pipeline communicated with the second absorber through the solution heat exchanger, the second absorber is provided with a dilute solution pipeline communicated with the second generator through the solution pump and the second solution heat exchanger, the second generator is provided with a concentrated solution pipeline communicated with the absorber through the second solution heat exchanger, the second generator is provided with a concentrated solution pipeline communicated with the third generator through the second solution heat exchanger, the third generator is provided with a concentrated solution pipeline communicated with the absorber through the second solution pump and the third solution heat exchanger, the absorber is provided with a dilute solution pipeline communicated with the generator through the solution heat exchanger, the third generator is provided with a dilute solution heat exchanger, the absorber is provided with a circulating pump communicated with a vapor medium circulating pump, and an evaporator circulating pump.

54. A combined heat-power system, wherein a third generator, a second absorber, a second solution pump and a third solution heat exchanger are added to any combined heat-power system described in items 3, 6, 9, 12, 15, 18, 21, 24, 27, 30, 33, 36, 39, 42, the generator is provided with a concentrated solution pipeline communicated with the second generator through the solution pump, the solution heat exchanger and the second solution heat exchanger, the generator is provided with a concentrated solution pipeline communicated with the second absorber through the solution heat exchanger, the second absorber is provided with a dilute solution pipeline communicated with the second generator through the solution pump and the second solution heat exchanger, the second generator is provided with a concentrated solution pipeline communicated with the absorber through the second solution heat exchanger, the second generator is provided with a concentrated solution pipeline communicated with the third generator through the second solution heat exchanger, the third generator is provided with a concentrated solution pipeline communicated with the absorber through the second solution pump and the third solution heat exchanger, the absorber is provided with a dilute solution pipeline communicated with the generator through the solution heat exchanger, the third generator is provided with a dilute solution heat exchanger and a third solution heat exchanger, the absorber is provided with a circulating pump and a circulating pump.

55. A combined heat-power system, wherein a preheater is added to any combined heat-power system described in item 52, a refrigerant line in a condenser is communicated with an evaporator through a refrigerant pump and adjusted to be communicated with the condenser through the refrigerant pump and the preheater, a circulating medium line in the evaporator is communicated with a circulating pump through a generator and a third generator and adjusted to be communicated with the evaporator through the circulating pump and the circulating medium line, and the generator, the third generator and the preheater form the combined heat-power system.

56. A combined heat-power system, which is characterized in that in any combined heat-power system described in item 53, a preheater is added, a refrigerant liquid pipeline of a condenser is communicated with an evaporator through a refrigerant liquid pump and is adjusted to be communicated with the condenser through the refrigerant liquid pump and the preheater, a circulating medium pipeline of a generator is communicated with a circulating pump through the evaporator and a third generator and is adjusted to be communicated with the generator through the circulating pump and a circulating medium pipeline, and the evaporator, the third generator and the preheater are communicated with the circulating pump, so that the combined heat-power system is formed.

57. A combined heat-power system, which is characterized in that in any combined heat-power system described in item 54, a preheater is added, a refrigerant liquid pipeline of a condenser is communicated with an evaporator through a refrigerant liquid pump and is adjusted to be communicated with the condenser through the refrigerant liquid pump and the preheater, a circulating medium pipeline of the evaporator and a circulating pump is respectively communicated with the generator through a third generator and is adjusted to be communicated with the evaporator and the generator through a circulating medium pipeline respectively and is communicated with the circulating pump through the third generator and the preheater, and the combined heat-power system is formed.

Description of the drawings:

FIG. 1 is a schematic diagram of the structure and flow of the first embodiment of the combined heat and power system according to the present invention.

FIG. 2 is a schematic diagram of the 2 nd structure and flow of the combined heat and power system according to the present invention.

FIG. 3 is a schematic diagram of the 3 rd configuration and flow of the combined heat and power system according to the present invention.

FIG. 4 is a schematic diagram of the 4 th structure and flow of the combined heat and power system according to the present invention.

FIG. 5 is a schematic diagram of the structure and flow of the 5 th embodiment of the combined heat and power system according to the present invention.

FIG. 6 is a schematic diagram of the structure and flow of the 6 th thermodynamic combined cycle system according to the present invention.

FIG. 7 is a schematic diagram of the 7 th configuration and flow of the combined heat and power system according to the present invention.

FIG. 8 is a schematic diagram of the 8 th configuration and flow of the combined heat and power system according to the present invention.

FIG. 9 is a schematic diagram of a 9 th configuration and flow of a combined thermal power system according to the present invention.

FIG. 10 is a schematic diagram of a 10 th configuration and process of a combined thermal power system according to the present invention.

FIG. 11 is a schematic diagram of the 11 th configuration and flow of the combined heat and power system according to the present invention.

FIG. 12 is a schematic diagram of a 12 th configuration and flow of a combined thermal power system according to the present invention.

FIG. 13 is a schematic diagram of a 13 th configuration and process of a combined heat and power system according to the present invention.

FIG. 14 is a schematic diagram of a 14 th configuration and process of a combined thermal power system according to the present invention.

FIG. 15 is a schematic diagram of a 15 th configuration and flow of a combined heat and power system according to the present invention.

FIG. 16 is a schematic diagram of a 16 th configuration and flow of a combined thermal power system according to the present invention.

FIG. 17 is a schematic diagram of a 17 th configuration and flow of a combined thermal power system according to the present invention.

In the figure, 1-generator, 2-second generator, 3-absorber, 4-condenser, 5-second condenser, 6-evaporator, 7-throttle valve, 8-refrigerant liquid pump, 9-solution pump, 10-solution heat exchanger, 11-second solution heat exchanger, 12-power machine, 13-low temperature condenser, 14-circulating pump, 15-heater, 16-second heater, 17-third heater, 18-heat supplier, 19-third generator, 20-second absorber, 21-second solution pump, 22-third solution heat exchanger, 23-second throttle valve, 24-preheater.

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 heat and power system shown in fig. 1 is realized by:

(1) structurally, the system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser and a circulating pump; the generator 1 is provided with a concentrated solution pipeline which is communicated with a second generator 2 through a solution pump 9, a solution heat exchanger 10 and a second solution heat exchanger 11, the second generator 2 is also provided with a concentrated solution pipeline which is communicated with an absorber 3 through the second solution heat exchanger 11, the absorber 3 is also provided with a dilute solution pipeline which is communicated with the generator 1 through the solution heat exchanger 10, the generator 1 is also provided with a refrigerant steam channel which is communicated with a condenser 4, the second generator 2 is also provided with a refrigerant steam channel which is communicated with a second condenser 5, the condenser 4 is also provided with a refrigerant liquid pipeline which is communicated with an evaporator 6 through a refrigerant liquid pump 8, the second condenser 5 is also provided with a refrigerant liquid pipeline which is communicated with the evaporator 6 through a throttle valve 7, the evaporator 6 is also provided with a refrigerant steam channel which is communicated with the absorber 3, a power machine 12 is provided with a new steam channel which is communicated with the outside, the power machine 12 is also provided with a steam exhaust channel, the circulating pump 14 has a circulating medium pipeline which is communicated with the evaporator 6 through the low-temperature condenser 13, then the evaporator 6 has a circulating medium pipeline which is communicated with the circulating pump 14 through the generator 1, the second generator 2 also has a high-temperature heat medium channel which is communicated with the outside, the absorber 3 and the second condenser 5 also have a heated medium channel which is communicated with the outside respectively, and the condenser 4 also has a cooling medium channel which is communicated with the outside.

(2) In the process, the new steam enters the power machine 12 to reduce the pressure and do work, and the exhaust steam of the power machine 12 is discharged outside after passing through the low-temperature condenser 13 to release heat and condense; the circulation medium discharged from the circulation pump 14 passes through the low-temperature condenser 13 and absorbs heat, passes through the evaporator 6 and the generator 1 and gradually releases heat, and then is supplied to the circulation pump 14; the concentrated solution of the generator 1 enters the second generator 2 through the solution pump 9, the solution heat exchanger 10 and the second solution heat exchanger 11, the high-temperature heat medium flows through the second generator 2, heats the solution entering the second generator 2 to release refrigerant steam and provide the refrigerant steam to the second condenser 5, the concentrated solution of the second generator 2 enters the absorber 3 through the second solution heat exchanger 11, absorbs the refrigerant steam and releases heat to the heated medium, and the dilute solution of the absorber 3 enters the generator 1 through the solution heat exchanger 10, absorbs heat to release the refrigerant steam and provides the refrigerant steam to the condenser 4; the refrigerant steam of the condenser 4 releases heat to the cooling medium to form refrigerant liquid, the refrigerant liquid of the condenser 4 is pressurized by a refrigerant liquid pump 8 to enter the evaporator 6, absorbs heat to form the refrigerant steam and is provided for the absorber 3, the refrigerant steam of the second condenser 5 releases heat to the heated medium to form the refrigerant liquid, the refrigerant liquid of the second condenser 5 is throttled by the throttle valve 7 and is depressurized to enter the evaporator 6, absorbs heat to form the refrigerant steam and is provided for the absorber 3, and a heat-power cogeneration system is formed.

The combined heat and power system shown in fig. 2 is realized by:

(1) structurally, the generator 1 is provided with a concentrated solution pipeline which is communicated with a second generator 2 through a solution pump 9, a solution heat exchanger 10 and a second solution heat exchanger 11, the second generator 2 is also provided with a concentrated solution pipeline which is communicated with an absorber 3 through the second solution heat exchanger 11, the absorber 3 is also provided with a dilute solution pipeline which is communicated with the generator 1 through the solution heat exchanger 10, the generator 1 is also provided with a refrigerant steam channel which is communicated with a condenser 4, the second generator 2 is also provided with a refrigerant steam channel which is communicated with a second condenser 5, the condenser 4 is also provided with a refrigerant liquid pipeline which is communicated with an evaporator 6 through a refrigerant liquid pump 8, the second condenser 5 is also provided with a refrigerant liquid pipeline which is communicated with the evaporator 6 through a throttle valve 7, the evaporator 6 is also provided with a refrigerant steam channel which is communicated with the absorber 3, the power machine 12 is respectively provided with a fresh steam channel which is communicated with the outside and provided with a steam exhaust channel which is communicated with the outside, the second condenser 12 is also provided with a second heater 857 which is communicated with an evaporator 6, the evaporator 6 is also provided with a refrigerant steam channel which is communicated with a condenser 2 which is communicated with an evaporator 6, and a high temperature heating medium heater 3514 which is communicated with an external heating medium heater 356, and a condenser 2 which are also communicated with an external heating medium heater 15 which is also communicated with a condenser 2.

(2) Compared with the working process of the heat-power combined supply system shown in fig. 1, the process is changed in that the new steam enters the power machine 12 to be decompressed and work, then is divided into two paths, the path is provided for the heater 15 to release heat and condense through the steam channel and then is discharged outwards, the second path continues to be decompressed and work and is discharged outwards, and the circulating medium flows through the heater 15 to absorb heat and then is provided for the evaporator 6, so that the heat-power combined supply system is formed.

The combined heat and power system shown in fig. 3 is realized by:

(1) structurally, the generator 1 is provided with a concentrated solution pipeline which is communicated with a second generator 2 through a solution pump 9, a solution heat exchanger 10 and a second solution heat exchanger 11, the second generator 2 is also provided with a concentrated solution pipeline which is communicated with an absorber 3 through the second solution heat exchanger 11, the absorber 3 is also provided with a dilute solution pipeline which is communicated with the generator 1 through the solution heat exchanger 10, the generator 1 is also provided with a refrigerant steam channel which is communicated with a condenser 4, the second generator 2 is also provided with a refrigerant steam channel which is communicated with a second condenser 5, the condenser 4 is also provided with a refrigerant liquid pipeline which is communicated with an evaporator 6 through a refrigerant liquid pump 8, the second condenser 5 is also provided with a refrigerant liquid pipeline which is communicated with an evaporator 6 through a throttle valve 7, the evaporator 6 is also provided with a refrigerant steam channel which is communicated with the absorber 3, the power machine 12 is provided with a new steam channel which is communicated with the outside, the condenser 12 is also provided with a steam exhaust channel which is communicated with a low-temperature condenser 13, the second condenser is also provided with a low temperature condenser 13 which is communicated with an evaporator 6 through a low temperature condenser heater, a circulating pump 13 which is also communicated with an evaporator 6, and a high temperature condenser medium heater 3515 which is communicated with an evaporator 6, and a condenser 2, and a low temperature condenser 13 which are communicated with an evaporator 6, and a high temperature condenser 2, and a condenser 2 which are communicated with an evaporator 6, and a high temperature condenser 2 which are communicated with a condenser 2, and a high temperature condenser, and a condenser 21 which are communicated with a condenser, and a low temperature condenser, and.

(2) Compared with the working process of the combined heat and power system shown in fig. 1, the process is changed in that new steam enters the power machine 12 to be decompressed and work, then is divided into two paths, steam with higher pressure relative to the steam exhaust is supplied to the heater 15 through the steam channel to release heat and condense and then is discharged outwards, the steam exhaust after the decompression and work is discharged outwards after being subjected to heat release condensation through the low-temperature condenser 13, and the circulating medium flows through the low-temperature condenser 13 and the heater 15 to gradually absorb heat and then is supplied to the evaporator 6, so that the combined heat and power system is formed.

The combined heat and power system shown in fig. 4 is realized by:

(1) structurally, the generator 1 is provided with a concentrated solution pipeline which is communicated with a second generator 2 through a solution pump 9, a solution heat exchanger 10 and a second solution heat exchanger 11, the second generator 2 is also provided with a concentrated solution pipeline which is communicated with an absorber 3 through the second solution heat exchanger 11, the absorber 3 is also provided with a dilute solution pipeline which is communicated with the generator 1 through the solution heat exchanger 10, the generator 1 is also provided with a refrigerant steam channel which is communicated with a condenser 4, the second generator 2 is also provided with a refrigerant steam channel which is communicated with a second condenser 5, the condenser 4 is also provided with a refrigerant liquid pipeline which is communicated with an evaporator 6 through a refrigerant liquid pump 8, the second condenser 5 is also provided with a refrigerant liquid pipeline which is communicated with an evaporator 6 through a throttle valve 7, the evaporator 6 is also provided with a refrigerant steam channel which is communicated with the absorber 3, the power machine 12 is respectively provided with a new steam channel which is communicated with the outside and a steam exhaust channel which is communicated with the outside, the second condenser 12 is also provided with a heater 856 which is also provided with a refrigerant liquid medium heater which is communicated with a condenser 2, the second heater which is also provided with a heater 2 which is communicated with a condenser 14 which is communicated with an external steam medium heater, and a condenser 16, and a high temperature heater 15 which is also communicated with an external heater 2 which is also provided with a condenser 16, and a condenser 2 which is communicated with an evaporator 6, and a high temperature heater 3515 which is communicated with an external heater 14 which is communicated with an external heater 14.

(2) Compared with the working process of the combined heat and power system shown in fig. 1, the process is changed in that after entering the power machine 12 for depressurization and work, new steam is respectively supplied to the second heater 16 through the second steam channel and the heater 15 through the -th steam channel, the rest steam continues to complete work and is discharged outwards, the -th steam is discharged outwards after being subjected to heat release and condensation through the heater 15, the second steam is subjected to heat release and condensation through the second heater 16 and is discharged outwards, and a circulating medium is supplied to the evaporator 6 after being subjected to heat release and condensation through the heater 15 and the second heater 16 and gradually absorbs heat, so that the combined heat and power system is formed.

The combined heat and power system shown in fig. 5 is realized by:

(1) structurally, the generator 1 is provided with a concentrated solution pipeline which is communicated with a second generator 2 through a solution pump 9, a solution heat exchanger 10 and a second solution heat exchanger 11, the second generator 2 is also provided with a concentrated solution pipeline which is communicated with an absorber 3 through the second solution heat exchanger 11, the absorber 3 is also provided with a dilute solution pipeline which is communicated with the generator 1 through the solution heat exchanger 10, the generator 1 is also provided with a refrigerant steam channel which is communicated with a condenser 4, the second generator 2 is also provided with a refrigerant steam channel which is communicated with a second condenser 5, the condenser 4 is also provided with a refrigerant liquid pipeline which is communicated with an evaporator 6 through a refrigerant liquid pump 8, the second condenser 5 is also provided with a refrigerant liquid pipeline which is communicated with the evaporator 6 through a throttle valve 7, the evaporator 6 is also provided with a refrigerant steam channel which is communicated with the absorber 3, a new steam channel 12 is communicated with an external heater, a low-temperature steam channel 12 is communicated with a low temperature heater 12, a low temperature heater 13 is also communicated with an external heater 12, a low temperature heater 14 is also communicated with an external heater 12, a condenser 14, a low temperature heater 14 is also communicated with an external heater, a condenser 14, a low temperature heater 14 is also communicated with an external heater 14, a condenser 6, a condenser 14, a low temperature heater 6 is communicated with an external heater, a condenser 14, a condenser 14, a low temperature heater and a low temperature heater 6 is communicated with an external heater 14, a condenser 6 and a condenser 6.

(2) Compared with the working process of the combined heat and power system shown in fig. 1, the process is changed in that after entering the power machine 12 for pressure reduction and work, new steam is respectively supplied to the second heater 16 through the second steam channel, supplied to the heater 15 through the th steam channel, supplied to the low-temperature condenser 13 through the steam exhaust channel and exhausted outside through the steam exhaust channel, the th steam is discharged outside after being subjected to heat release and condensation by the heater 15, the second steam is subjected to heat release and condensation by the second heater 16 and exhausted outside, and a circulating medium is supplied to the evaporator 6 after being subjected to heat release and condensation by the low-temperature condenser 13, the heater 15 and the second heater 16 and gradually absorbs heat, so that the combined heat and power system is formed.

The combined heat and power system shown in fig. 6 is realized by:

(1) the generator 1 is provided with a concentrated solution pipeline which is communicated with the second generator 2 through a solution pump 9, a solution heat exchanger 10 and a second solution heat exchanger 11, the second generator 2 is also provided with a concentrated solution pipeline which is communicated with the absorber 3 through the second solution heat exchanger 11, the absorber 3 is also provided with a dilute solution pipeline which is communicated with the generator 1 through the solution heat exchanger 10, the generator 1 is also provided with a refrigerant steam channel which is communicated with the condenser 4, the second generator 2 is also provided with a refrigerant steam channel which is communicated with the second condenser 5, the condenser 4 is also provided with a refrigerant liquid pipeline which is communicated with the evaporator 6 through a refrigerant liquid pump 8, the second condenser 5 is also provided with a refrigerant liquid pipeline which is communicated with the evaporator 6 through a throttle valve 7, the evaporator 6 is also provided with a refrigerant steam channel which is communicated with the absorber 3, the new steam channel 12 is communicated with the outside, the exhaust steam channel is communicated with the evaporator 6, the second heater 12 is also provided with the second heater 12 and a third heater, the third heater 14 is also provided with a condensate heater 14, the third heater 14 and a heater 14, the third heater 14 is also provided with a condenser 2 and a condenser 2 which are communicated with an evaporator 6, and a condenser 6 which are communicated with an evaporator 6 through a refrigerant steam heater medium heater 2, and a condensate medium heater 7, and a third heater 21 are communicated with an evaporator 6, and a condensate medium heater 7.

(2) Compared with the working process of the combined heat and power system shown in fig. 1, the process is changed in that after entering the power machine 12 to reduce pressure and do work, new steam is respectively supplied to the third heater 17 through the third steam channel, the second heater 16 through the second steam channel and the heater 15 through the steam channel, the rest steam continues to do work and is discharged outwards, steam is discharged outwards after being subjected to heat release and condensation through the heater 15, the second steam is discharged outwards after being subjected to heat release and condensation through the second heater 16, the third steam is discharged outwards after being subjected to heat release and condensation through the third heater 17, a circulating medium flows through the heater 15, the second heater 16 and the third heater 17 and gradually absorbs heat and is supplied to the evaporator 6, and the combined heat and power system is formed.

The combined heat and power system shown in fig. 7 is realized by:

(1) structurally, the generator 1 is provided with a concentrated solution pipeline which is communicated with a second generator 2 through a solution pump 9, a solution heat exchanger 10 and a second solution heat exchanger 11, the second generator 2 is also provided with a concentrated solution pipeline which is communicated with an absorber 3 through a second solution heat exchanger 11, the absorber 3 is also provided with a dilute solution pipeline which is communicated with the generator 1 through a solution heat exchanger 10, the generator 1 is also provided with a refrigerant steam channel which is communicated with a condenser 4, the second generator 2 is also provided with a refrigerant steam channel which is communicated with a second condenser 5, the condenser 4 is also provided with a refrigerant liquid pipeline which is communicated with an evaporator 6 through a refrigerant liquid pump 8, the second condenser 5 is also provided with a refrigerant liquid pipeline which is communicated with an evaporator 6 through a throttle valve 7, the evaporator 6 is also provided with a refrigerant steam channel which is communicated with an evaporator 3, a new steam channel which is communicated with the outside, the condenser 12 is also provided with a refrigerant liquid channel which is communicated with an evaporator 6 through a refrigerant liquid heater 13, the second heater is also provided with a low-temperature steam heater channel which is communicated with a second heater 12, a low temperature heater channel which is communicated with a low temperature heater 13, a low temperature heater 7, a low temperature heater, a.

(2) Compared with the working process of the combined heat and power system shown in fig. 1, the process is changed in that after entering the power machine 12 for pressure reduction and work, new steam is respectively supplied to the third heater 17 through the third steam channel, the second heater 16 through the second steam channel, the heater 15 through the steam channel and the low-temperature condenser 13 through the steam exhaust channel, steam is discharged outwards after being subjected to heat release and condensation through the heater 15, the second steam is subjected to heat release and condensation through the second heater 16 and is discharged outwards, the third steam is subjected to heat release and condensation through the third heater 17 and is discharged outwards, and a circulating medium is supplied to the evaporator 6 after being subjected to heat absorption through the low-temperature condenser 13, the heater 15, the second heater 16 and the third heater 17 to form the combined heat and power system.

The combined heat and power system shown in fig. 8 is realized by:

in the combined heat and power system shown in fig. 4, a heat supply device is added, a circulating pump 14 is adjusted to have a circulating medium pipeline which is communicated with an evaporator 6 through a heater 15 and a second heater 16, then a circulating medium pipeline of an evaporator 6 is communicated with the circulating pump 14 through a generator 1, and the circulating pump 14 is adjusted to have a circulating medium pipeline which is communicated with the evaporator 6 through the heater 15, the second heater 16 and the heat supply device 18, then a circulating medium pipeline of the evaporator 6 is communicated with the circulating pump 14 through the generator 1; the circulating medium flows through the heater 15 and the second heater 16 and gradually absorbs heat, and then flows through the heater 18, the evaporator 6 and the generator 1 and gradually releases heat, so that a combined heat and power system is formed.

The combined heat and power system shown in fig. 9 is realized by:

in the combined heat power system shown in fig. 5, the circulating pump 14 is adjusted such that the circulating pump 14 has a circulating medium line which communicates with the evaporator 6 through the low-temperature condenser 13, the heater 15 and the second heater 16, and then the evaporator 6 has a circulating medium line which communicates with the circulating pump 14 itself through the generator 1, and the circulating pump 14 has a circulating medium line which communicates with the generator 1 through the low-temperature condenser 13, the heater 15 and the second heater 16, and then the generator 1 has a circulating medium line which communicates with the circulating pump 14 itself through the evaporator 6; the circulating medium discharged from the circulating pump 14 passes through the cryocondenser 13, the heater 15, and the second heater 16 and gradually absorbs heat, passes through the generator 1 and the evaporator 6 and gradually releases heat, and then returns to the circulating pump 14, forming a combined heat and power system.

The combined heat and power system shown in fig. 10 is realized by:

in the combined heat and power system shown in fig. 5, the circulation pump 14 is adjusted such that the circulation pump 14 has a circulation medium pipeline which is communicated with the evaporator 6 through the low temperature condenser 13, the heater 15 and the second heater 16, then the evaporator 6 is further communicated with the circulation pump 14 through the generator 1, and the circulation pump 14 has a circulation medium pipeline which is communicated with the evaporator 6 and the generator 1 through the low temperature condenser 13, the heater 15 and the second heater 16, then the evaporator 6 and the generator 1 are further communicated with the circulation pump 14 through the circulation medium pipeline; the circulating medium discharged from the circulating pump 14 passes through the cryocondenser 13, the heater 15 and the second heater 16 and gradually absorbs heat, passes through the generator 1 and the evaporator 6 respectively and releases heat, and then returns to the circulating pump 14 to form a combined heat and power system.

The combined heat and power system shown in fig. 11 is realized by:

(1) structurally, in the combined heat power system shown in FIG. 5, a third generator, a second absorber, a second solution pump and a third solution heat exchanger are added, a concentrated solution pipeline of the generator 1 is communicated with the second generator 2 through the solution pump 9, the solution heat exchanger 10 and the second solution heat exchanger 11, the concentrated solution pipeline of the generator 1 is communicated with the second absorber 20 through the solution pump 9, the solution heat exchanger 10 and the second solution heat exchanger 11, a diluted solution pipeline of the second absorber 20 is communicated with the second generator 2 through the second solution pump 21 and the third solution heat exchanger 22, a concentrated solution pipeline of the second generator 2 is communicated with the absorber 3 through the second solution heat exchanger 11, a concentrated solution pipeline of the second generator 2 is communicated with the third generator 19 through the third solution heat exchanger 22, a concentrated solution pipeline of the third generator 19 is communicated with the absorber 3 through the second solution heat exchanger 11, the third generator 19 also has a refrigerant vapor passage communicating with the second absorber 20, the third generator 19 also has a high-temperature heat medium passage communicating with the outside, and the second absorber 20 also has a heated medium passage communicating with the outside.

(2) In the flow, the concentrated solution in the generator 1 enters the second absorber 20 through the solution pump 9, the solution heat exchanger 10 and the second solution heat exchanger 11, absorbs refrigerant vapor and releases heat to the heated medium, the dilute solution in the second absorber 20 enters the second generator 2 through the second solution pump 21 and the third solution heat exchanger 22, the concentrated solution in the second generator 2 enters the third generator 19 through the third solution heat exchanger 22, the high-temperature heat medium flows through the third generator 19, heats the solution entering the third generator to release refrigerant vapor and is provided for the second absorber 20, and the concentrated solution in the third generator 19 enters the absorber 3 through the second solution heat exchanger 11, so as to form a thermodynamic combined supply system.

The combined heat and power system shown in fig. 12 is realized by:

(1) structurally, in the combined heat power system shown in fig. 5, a third generator, a second solution pump, a third solution heat exchanger and a second throttle valve are added, a concentrated solution pipeline of the generator 1 is communicated with the third generator 19 through the second solution pump 21, the solution heat exchanger 10 and the third solution heat exchanger 22, the concentrated solution pipeline of the third generator 19 is communicated with the absorber 3 through the third solution heat exchanger 22, the communication between the second generator 2 and the second condenser 5 is adjusted to be that the second generator 2 is communicated with the third generator 19 through a refrigerant vapor channel, then the refrigerant liquid pipeline of the third generator 19 is communicated with the second condenser 5 through the second throttle valve 23, and the refrigerant vapor channel of the third generator 19 is communicated with the second condenser 5.

(2) In the process, refrigerant steam generated by the second generator 2 is provided for the third generator 19 to be used as a driving heat medium, part of the concentrated solution in the generator 1 enters the third generator 19 through the second solution pump 21, the solution heat exchanger 10 and the third solution heat exchanger 22, the refrigerant steam flows through the third generator 19, heats the solution entering the third generator to release the refrigerant steam and is provided for the second condenser 5, and the concentrated solution in the third generator 19 enters the absorber 3 through the third solution heat exchanger 22; the refrigerant steam flowing through the third generator 19 releases heat to form refrigerant liquid, and the refrigerant liquid enters the second condenser 5 through the throttling and pressure reduction of the second throttling valve 23 to form a heat-power combined supply system.

The combined heat and power system shown in fig. 13 is realized by:

(1) structurally, in the combined heat power system shown in FIG. 5, a third generator, a third solution heat exchanger and a second throttle valve are added, a concentrated solution pipeline of the generator 1 is communicated with the second generator 2 through a solution pump 9, a solution heat exchanger 10 and a second solution heat exchanger 11, the concentrated solution pipeline of the generator 1 is adjusted to be communicated with the second generator 2 through the solution pump 9, the solution heat exchanger 10, the second solution heat exchanger 11 and a third solution heat exchanger 22, a concentrated solution pipeline of the second generator 2 is communicated with the absorber 3 through the second solution heat exchanger 11, the concentrated solution pipeline of the second generator 2 is adjusted to be communicated with the third generator 19 through the third solution heat exchanger 22, the concentrated solution pipeline of the third generator 19 is further communicated with the absorber 3 through the second solution heat exchanger 11, a refrigerant vapor channel of the second generator 2 is adjusted to be communicated with the second condenser 5, and the refrigerant vapor channel of the second generator 2 is communicated with the third generator 19 The third generator 19 is communicated with the second condenser 5 through a second throttling valve 23, the third generator 19 is also communicated with the second condenser 5 through a refrigerant steam channel, and the third generator 19 is also communicated with the outside through a high-temperature heat medium channel.

(2) In the process, the high-temperature heat medium and the refrigerant steam generated by the second generator 2 are supplied to the third generator 19 to be used as a driving heat medium, the concentrated solution in the generator 1 enters the second generator 2 through the solution pump 9, the solution heat exchanger 10, the second solution heat exchanger 11 and the third solution heat exchanger 22, the concentrated solution in the second generator 2 enters the third generator 19 through the third solution heat exchanger 22, the high-temperature heat medium and the refrigerant steam flow respectively pass through the third generator 19 and heat the solution entering the third generator to release the refrigerant steam and supply the refrigerant steam to the second condenser 5, and the concentrated solution in the third generator 19 enters the absorber 3 through the second solution heat exchanger 11; the refrigerant steam flowing through the third generator 19 releases heat to form refrigerant liquid, and the refrigerant liquid enters the second condenser 5 through the throttling and pressure reduction of the second throttling valve 23 to form a heat-power combined supply system.

The combined heat and power system shown in fig. 14 is realized by:

(1) structurally, in the combined heat power system shown in FIG. 5, a third generator, a second solution pump, a third solution heat exchanger and a second throttle valve are added, a concentrated solution pipeline of the generator 1 is communicated with the second generator 2 through the solution pump 9, the solution heat exchanger 10 and the second solution heat exchanger 11, the generator 1 is adjusted to be communicated with the third generator 19 through the solution pump 9, the solution heat exchanger 10 and the second solution heat exchanger 11, a concentrated solution pipeline of the third generator 19 is communicated with the second generator 2 through the second solution pump 21 and the third solution heat exchanger 22, a concentrated solution pipeline of the second generator 2 is adjusted to be communicated with the absorber 3 through the second solution heat exchanger 11, a concentrated solution pipeline of the second generator 2 is adjusted to be communicated with the absorber 3 through the third solution heat exchanger 22 and the second solution heat exchanger 11, a refrigerant vapor channel of the second generator 2 is adjusted to be communicated with the second condenser 5 through the refrigerant vapor channel of the second generator 2 After the passage is communicated with the third generator 19, the third generator 19 is communicated with the second condenser 5 through a second throttling valve 23, and the third generator 19 is communicated with the second condenser 5 through a refrigerant steam passage.

(2) In the process, refrigerant steam generated by the second generator 2 is supplied to the third generator 19 as a driving heat medium, concentrated solution in the generator 1 enters the third generator 19 through the solution pump 9, the solution heat exchanger 10 and the second solution heat exchanger 11, the refrigerant steam flows through the third generator 19, heats the solution entering the third generator to release the refrigerant steam and is supplied to the second condenser 5, concentrated solution in the third generator 19 enters the second generator 2 through the second solution pump 21 and the third solution heat exchanger 22, and concentrated solution in the second generator 2 enters the absorber 3 through the third solution heat exchanger 22 and the second solution heat exchanger 11; the refrigerant steam flowing through the third generator 19 releases heat to form refrigerant liquid, and the refrigerant liquid enters the second condenser 5 through the throttling and pressure reduction of the second throttling valve 23 to form a heat-power combined supply system.

The combined heat and power system shown in fig. 15 is realized by:

(1) structurally, in the combined heat power system shown in fig. 5, a third generator, a second absorber, a second solution pump and a third solution heat exchanger are added, the second generator 2 is communicated with the second condenser 5 through a refrigerant vapor passage, the second generator 2 is communicated with the second absorber 20 through a refrigerant vapor passage, the second absorber 20 is further communicated with a dilute solution pipeline through a second solution pump 21 and a third solution heat exchanger 22 with the third generator 19, the third generator 19 is further communicated with the second absorber 20 through a concentrated solution pipeline through a third solution heat exchanger 22, the third generator 19 is further communicated with the second condenser 5 through a refrigerant vapor passage, the third generator 19 is further communicated with the outside through a high-temperature heat medium passage, and the second absorber 20 is further communicated with the outside through a heated medium passage.

(2) In the flow process, the refrigerant steam generated by the second generator 2 enters the third absorber 20, the dilute solution of the third absorber 20 enters the third generator 19 through the second solution pump 21 and the third solution heat exchanger 22, the high-temperature heat medium flows through the third generator 19, heats the solution entering the third generator 19, releases the refrigerant steam and is provided for the second condenser 5, and the concentrated solution of the third generator 19 enters the third absorber 20 through the third solution heat exchanger 22, absorbs the refrigerant steam and releases heat to the heated medium, so that the thermodynamic combined supply system is formed.

The combined heat and power system shown in fig. 16 is realized by:

(1) structurally, in the combined heat power system shown in FIG. 5, a third generator, a second absorber, a second solution pump and a third solution heat exchanger are added, wherein a concentrated solution pipeline of the generator 1 is communicated with the second generator 2 through a solution pump 9, a solution heat exchanger 10 and a second solution heat exchanger 11, the generator 1 is adjusted to be communicated with a concentrated solution pipeline of the second absorber 20 through the solution heat exchanger 10, a dilute solution pipeline of the second absorber 20 is further communicated with the second generator 2 through the solution pump 9 and the second solution heat exchanger 11, a concentrated solution pipeline of the second generator 2 is adjusted to be communicated with the absorber 3 through the second solution heat exchanger 11, a concentrated solution pipeline of the second generator 2 is communicated with the third generator 19 through the second solution heat exchanger 11, and a concentrated solution pipeline of the third generator 19 is further communicated with the absorber 3 through the second solution pump 21 and the third solution heat exchanger 22, the absorber 3 is communicated with the generator 1 through the solution heat exchanger 10 by a dilute solution pipeline, the absorber 3 is communicated with the generator 1 through the third solution heat exchanger 22 by the dilute solution pipeline, the evaporator 6 is communicated with the circulating pump 14 through the generator 1 by a circulating medium pipeline, the evaporator 6 is communicated with the circulating pump 14 through the generator 1 and the third generator 19 by a circulating medium pipeline, the third generator 19 is also communicated with the second absorber 20 by a refrigerant steam channel, and the second absorber 20 is also communicated with the outside by a cooling medium channel.

(2) In the process, the concentrated solution in the generator 1 enters the second absorber 20 through the solution heat exchanger 10, absorbs refrigerant vapor and releases heat to the cooling medium, and the dilute solution in the second absorber 20 enters the second generator 2 through the solution pump 9 and the second solution heat exchanger 11; the concentrated solution of the second generator 2 enters a third generator 19 through a second solution heat exchanger 11, absorbs heat to release refrigerant vapor and is provided for a second absorber 20, the concentrated solution of the third generator 19 enters an absorber 3 through a second solution pump 21 and a third solution heat exchanger 22, and the dilute solution of the absorber 3 enters the generator 1 through the third solution heat exchanger 22 and a solution heat exchanger 10; the circulating medium discharged from the circulating pump 14 passes through the cryocondenser 13, the heater 15, and the second heater 16 and gradually absorbs heat, and then passes through the evaporator 6, the generator 1, and the third generator 19 and gradually releases heat, forming a combined heat and power system.

The combined heat and power system shown in fig. 17 is realized by:

(1) structurally, in the combined heat-power system shown in fig. 3, a preheater is added, a refrigerant liquid pipeline of the condenser 4 is communicated with the evaporator 6 through a refrigerant liquid pump 8 and is adjusted to be communicated with the evaporator 6 through the refrigerant liquid pump 8 and the preheater 24, a circulating medium pipeline of the evaporator 6 is communicated with the circulating pump 14 through the generator 1 and is adjusted to be communicated with the circulating pump 14 through the evaporator 6 and a circulating medium pipeline of the preheater 24 and the generator 1.

(2) In the flow, the refrigerant liquid of the condenser 4 is boosted by the refrigerant liquid pump 8, passes through the preheater 24 and absorbs heat, and then enters the evaporator 6; the circulating medium discharged from the circulating pump 14 passes through the cryocondenser 13 and the heater 15 and absorbs heat gradually, passes through the evaporator 6, the generator 1 and the preheater 24 and releases heat gradually, and then is supplied to the circulating pump 14, forming a combined heat and power system.

The effect that the technology of the invention can realize-the thermodynamic combined supply system provided by the invention has the following effects and advantages:

(1) the high-grade steam firstly does work, and the low-grade steam is used for heat supply, thereby conforming to the principle of high-efficiency utilization of heat energy.

(2) The low-temperature condenser, the heater, the second heater and the third heater are used for independently or jointly and gradually collecting heat load, and the generator and the condenser are combined to realize effective utilization of temperature difference between tail-end steam exhaust or low-pressure steam extraction of the steam power device and a cold environment.

(3) The large temperature difference and low pressure heat load transmission is realized in -level pipe networks, the heat load transmission scale is reduced, the safety of -level heat supply pipe networks is greatly improved, and -level heat supply pipe network parameters can be flexibly adjusted according to specific conditions.

(4) The application limit of clean or high-efficiency energy in the traditional combined heat and power system is relieved.

(5) The effective utilization of the temperature difference between the -grade pipe network circulating medium and the two-grade pipe network circulating medium or the heated medium is realized.

(6) The steam at the tail end of the power machine is used as a heat power combined heat source, so that the heat efficiency and the equipment operation safety of the power machine are improved.

(7) The type of the thermodynamic system is enriched, the application range of the absorption heat pump is expanded, and the absorption heat pump technology is favorably adopted to improve the heat energy utilization rate.

Claims

1. The heat and power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser and a circulating pump; the generator (1) is provided with a concentrated solution pipeline which is communicated with the second generator (2) through a solution pump (9), a solution heat exchanger (10) and a second solution heat exchanger (11), the second generator (2) is also provided with a concentrated solution pipeline which is communicated with the absorber (3) through the second solution heat exchanger (11), the absorber (3) is also provided with a dilute solution pipeline which is communicated with the generator (1) through the solution heat exchanger (10), the generator (1) is also provided with a refrigerant steam channel which is communicated with the condenser (4), the second generator (2) is also provided with a refrigerant steam channel which is communicated with the second condenser (5), the condenser (4) is also provided with a refrigerant liquid pipeline which is communicated with the evaporator (6) through a refrigerant liquid pump (8), the second condenser (5) is also provided with a refrigerant liquid pipeline which is communicated with the evaporator (6) through a throttle valve (7), the evaporator (6) is also provided with a refrigerant steam channel which is communicated with the absorber (3), the power machine (12) is provided with a new steam channel communicated with the outside, the power machine (12) is also provided with a steam exhaust channel which is communicated with the low-temperature condenser (13), then the low-temperature condenser (13) is also provided with a low-temperature condensate channel communicated with the outside, the power machine (12) or the steam exhaust channel is also communicated with the outside, the circulating pump (14) is provided with a circulating medium pipeline which is communicated with the evaporator (6) through the low-temperature condenser (13), then the evaporator (6) is also provided with a circulating medium pipeline which is communicated with the circulating pump (14) through the generator (1), the second generator (2) is also provided with a high-temperature heat medium channel communicated with the outside, the absorber (3) and the second condenser (5) are also provided with heated medium channels which are communicated with the outside respectively, and the condenser (4) is also provided with a.

2. The combined heat and power system as set forth in claim 1, wherein the circulating pump (14) has a circulating medium line, the circulating medium line of the evaporator (6) is connected to the evaporator (6) through the low temperature condenser (13), the circulating medium line of the evaporator (6) is connected to the circulating pump (14) through the generator (1), and the circulating pump (14) has a circulating medium line, the circulating medium line of the generator (1) is connected to the generator (1) through the low temperature condenser (13), the circulating medium line of the generator (1) is connected to the circulating pump (14) through the evaporator (6), thereby forming the combined heat and power system.

3. The combined heat and power system as set forth in claim 1, wherein the circulating pump (14) has a circulating medium pipeline, the evaporator (6) is connected to the evaporator (6) through the low temperature condenser (13), the circulating medium pipeline is connected to the circulating pump (14) through the generator (1), the circulating pump (14) is adjusted to have a circulating medium pipeline, the circulating medium pipeline is connected to the evaporator (6) and the generator (1) through the low temperature condenser (13), the evaporator (6) and the generator (1) are connected to the circulating pump (14) through the circulating medium pipeline, and the combined heat and power system is formed.

4. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a circulating pump and a heater, wherein the generator (1) is provided with a concentrated solution pipeline which is communicated with the second generator (2) through a solution pump (9), a solution heat exchanger (10) and a second solution heat exchanger (11), the second generator (2) is also provided with a concentrated solution pipeline which is communicated with the absorber (3) through the second solution heat exchanger (11), the absorber (3) is also provided with a dilute solution pipeline which is communicated with the generator (1) through the solution heat exchanger (10), the generator (1) is also provided with a vapor channel which is communicated with the condenser (4), the second generator (2) is also provided with a refrigerant vapor channel which is communicated with the second condenser (5), the condenser (4) is also provided with a refrigerant liquid pipeline which is communicated with the evaporator (6) through a refrigerant liquid pump (8), the second condenser (5) is also provided with a refrigerant liquid channel which is communicated with the evaporator (6), the evaporator (6) and a refrigerant liquid channel which is also provided with a new evaporator (6), the evaporator (3) is also provided with a refrigerant liquid channel which is communicated with a refrigerant channel which is communicated with a high-steam-cooling medium channel which is communicated with an evaporator (2), and a steam-cooling medium channel which is communicated with an evaporator-heater (2), and a high-heater (15) which is communicated with an evaporator-heater (2), and a high-heater channel which is communicated with an evaporator-heater (2), and a high-heater channel which is communicated with an evaporator-heater (3) which is communicated.

5. The combined heat and power system as set forth in claim 4, wherein the circulating pump (14) is provided with a circulating medium pipeline, the circulating medium pipeline of the evaporator (6) is communicated with the evaporator (6) through the heater (15), then the circulating medium pipeline of the evaporator (6) is communicated with the circulating pump (14) through the generator (1), and the circulating pump (14) is adjusted to be provided with a circulating medium pipeline, the circulating medium pipeline of the generator (1) is communicated with the generator (1) through the heater (15), then the circulating medium pipeline of the generator (1) is communicated with the circulating pump (14) through the evaporator (6), thereby forming the combined heat and power system.

6. The combined heat and power system as set forth in claim 4, wherein the circulating pump (14) has a circulating medium line, the evaporator (6) is connected to the evaporator (6) through the heater (15), the circulating medium line is connected to the circulating pump (14) through the generator (1), the circulating pump (14) is adjusted to have a circulating medium line, the evaporator (6) and the generator (1) are connected to the evaporator (6) and the generator (1) through the heater (15), and the circulating medium line is connected to the circulating pump (14) through the generator (1).

7. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser, a circulating pump and a heater, wherein the generator (1) is provided with a concentrated solution pipeline which is communicated with the second generator (2) through a solution pump (9), a solution heat exchanger (10) and a second solution heat exchanger (11), the second generator (2) is also provided with a concentrated solution pipeline which is communicated with the absorber (3) through the second solution heat exchanger (11), the absorber (3) is also provided with a dilute solution pipeline which is communicated with the generator (1) through the solution heat exchanger (10), the generator (1) is also provided with a refrigerant vapor channel which is communicated with the condenser (4), the second generator (2) is also provided with a refrigerant vapor channel which is communicated with the second condenser (5), the condenser (4) is also provided with a refrigerant liquid pipeline which is communicated with the evaporator (6) through a refrigerant liquid pump (8), the second condenser (5) is also provided with a refrigerant liquid channel which is communicated with the evaporator (6), the condenser (6) is also provided with a low-temperature heat power machine, a low-temperature condenser (3) is also provided with a refrigerant vapor channel which is communicated with an external vapor channel which is communicated with a condenser (13), and a condenser (13), the evaporator channel which is communicated with an external vapor channel which is communicated with an evaporator channel which is communicated with a condenser (13), the evaporator channel which is also communicated with a condenser (2), a condenser (13), the evaporator channel which is communicated with a high-temperature condenser (13), a high-temperature condenser-vapor channel which is also communicated with a condenser-vapor channel which is communicated with an evaporator channel which is communicated with an.

8. The combined heat and power system as set forth in claim 7, wherein the circulating pump (14) has a circulating medium line which is communicated with the evaporator (6) through the low temperature condenser (13) and the heater (15), then the evaporator (6) has a circulating medium line which is communicated with the circulating pump (14) through the generator (1), and the circulating pump (14) has a circulating medium line which is communicated with the generator (1) through the low temperature condenser (13) and the heater (15), then the generator (1) has a circulating medium line which is communicated with the circulating pump (14) through the evaporator (6), thereby forming the combined heat and power system.

9. The combined heat and power system as set forth in claim 7, wherein the circulating pump (14) has a circulating medium line, the circulating medium line is connected to the evaporator (6) through the low temperature condenser (13) and the heater (15), the evaporator (6) is connected to the circulating pump (14) through the generator (1), the circulating pump (14) is adjusted to have a circulating medium line, the circulating medium line is connected to the evaporator (6) and the generator (1) through the low temperature condenser (13) and the heater (15), the evaporator (6) and the generator (1) are connected to the circulating pump (14) through the circulating medium line, and the combined heat and power system is formed.

10. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a circulating pump, a heater and a second heater, wherein the generator (1) is provided with a concentrated solution pipeline which is communicated with the second generator (2) through a solution pump (9), a solution heat exchanger (10) and a second solution heat exchanger (11), the second generator (2) is also provided with a concentrated solution pipeline which is communicated with the absorber (3) through the second solution heat exchanger (11), the absorber (3) is also provided with a dilute solution pipeline which is communicated with the generator (1) through the solution heat exchanger (10), the generator (1) is also provided with a refrigerant vapor channel which is communicated with the condenser (4), the second generator (2) is also provided with a refrigerant vapor channel which is communicated with the second condenser (5), the condenser (4) is also provided with a refrigerant liquid pipeline which is communicated with the evaporator (6) through a refrigerant liquid pump (8), the second condenser (5) is also provided with a refrigerant liquid channel which is communicated with the evaporator (6), the evaporator (6) and a second heater (6), a high-temperature steam channel which is also communicated with a second generator (6), the evaporator channel which is also provided with a high temperature steam heater (16) and a new evaporator channel which is communicated with a condenser (2), the evaporator channel which is communicated with a condenser (16) and a condenser (2), and a condenser (6), and a high temperature steam heater channel which is communicated with a new evaporator channel which is communicated with a condenser channel which is communicated with an evaporator channel which is communicated with a condenser (16), and a condenser channel which is communicated with an evaporator channel.

11. The combined heat and power system as set forth in claim 10, wherein the circulating pump (14) has a circulating medium line, which is communicated with the evaporator (6) through the heater (15) and the second heater (16), and then the evaporator (6) has a circulating medium line, which is communicated with the circulating pump (14) through the generator (1), and the circulating pump (14) has a circulating medium line, which is communicated with the generator (1) through the heater (15) and the second heater (16), and then the generator (1) has a circulating medium line, which is communicated with the circulating pump (14) through the evaporator (6), to form the combined heat and power system.

12. The combined heat and power system as set forth in claim 10, wherein the circulating pump (14) has a circulating medium line, the evaporator (6) is connected to the evaporator (6) through the heater (15) and the second heater (16), the circulating medium line is connected to the circulating pump (14) through the generator (1), the circulating pump (14) is adjusted to have a circulating medium line, the evaporator (6) and the generator (1) are connected to the evaporator (6) and the generator (1) through the heater (15) and the second heater (16), and the circulating medium line is connected to the circulating pump (14) to form the combined heat and power system.

13. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser, a circulating pump, a heater and a second heater, wherein the generator (1) is provided with a concentrated solution pipeline which is communicated with the second generator (2) through a solution pump (9), a solution heat exchanger (10) and a second solution heat exchanger (11), the second generator (2) is also provided with a concentrated solution pipeline which is communicated with the absorber (3) through the second solution heat exchanger (11), the absorber (3) is also provided with a dilute solution pipeline which is communicated with the generator (1) through the solution heat exchanger (10), the generator (1) is also provided with a refrigerant vapor channel which is communicated with the condenser (4), the second generator (2) is also provided with a refrigerant vapor channel which is communicated with the second condenser (5), the condenser (4) is also provided with a refrigerant liquid pipeline which is also provided with a refrigerant vapor channel which is communicated with the evaporator (6), the condenser (5) is also provided with a refrigerant liquid channel which is communicated with a second heater (6), a low-temperature heater (6) and a low-temperature steam channel which is also provided with a second generator (6), the evaporator channel which is also provided with a second generator (6) and a low-temperature heater (6), the evaporator channel which is communicated with a low-temperature condenser (13), the evaporator channel which is also provided with a low temperature heater, a low temperature condenser-heater channel which is communicated with a low temperature evaporator channel which is communicated with a low temperature generator (6) and a low temperature evaporator channel which is communicated with a low temperature generator (6), the evaporator channel which is communicated with a low temperature condenser (6), the evaporator channel which is communicated with a low temperature generator (6), the evaporator channel which is communicated.

14. The combined heat and power system as set forth in claim 13, wherein the circulating pump (14) is provided with a circulating medium line, the circulating medium line is communicated with the evaporator (6) through the low-temperature condenser (13), the heater (15) and the second heater (16), then the circulating medium line of the evaporator (6) is communicated with the circulating pump (14) through the generator (1), and the circulating pump (14) is adjusted to be provided with a circulating medium line, the circulating medium line is communicated with the generator (1) through the low-temperature condenser (13), the heater (15) and the second heater (16), then the circulating medium line of the generator (1) is communicated with the circulating pump (14) through the evaporator (6), thereby forming the combined heat and power system.

15. The combined heat and power system as set forth in claim 13, wherein the circulating pump (14) is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) through the low-temperature condenser (13), the heater (15) and the second heater (16), then the evaporator (6) is further provided with a circulating medium pipeline, the circulating pump (14) is further communicated with the circulating pump (1) through the generator (1), the circulating pump (14) is adjusted to be provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) and the generator (1) through the low-temperature condenser (13), the heater (15) and the second heater (16), then the evaporator (6) and the generator (1) are further provided with a circulating medium pipeline, and the circulating pump (14) is further communicated with the circulating pump (14) to form the combined heat and power system.

16. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a circulating pump, a heater, a second heater and a third heater, wherein the generator (1) is provided with a concentrated solution pipeline which is communicated with the second generator (2) through a solution pump (9), a solution heat exchanger (10) and a second solution heat exchanger (11), the second generator (2) is also provided with a concentrated solution pipeline which is communicated with the absorber (3) through the second solution heat exchanger (11), the absorber (3) is also provided with a dilute solution pipeline which is communicated with the generator (1) through a solution heat exchanger (10), the generator (1) is also provided with a refrigerant vapor channel which is communicated with the condenser (4), the second generator (2) is also provided with a refrigerant vapor channel which is communicated with the second condenser (5), the condenser (4) is also provided with a refrigerant liquid pipeline which is also provided with a refrigerant vapor channel which is communicated with the evaporator (6), the second condenser (5) is also provided with a refrigerant liquid channel which is communicated with a refrigerant liquid pump (8), the evaporator (6), a second heater (6) and a third heater (17) which is also provided with a steam channel which is communicated with an external heater (17), and a steam channel which is communicated with a condenser (17), and a steam heater (17), and a steam channel which is communicated with a steam heater (17), and a steam heater (17) which is communicated with an evaporator channel which is communicated with an external steam channel which is communicated with a condenser (17), the evaporator channel which is communicated with an evaporator channel which is communicated with a condenser (17), the evaporator channel which is communicated with a steam channel which is communicated with an evaporator (17), the evaporator (17) which is communicated with a condenser (17), the evaporator (17) which is communicated with an evaporator (17) which is.

17. The combined heat and power system as set forth in claim 16, wherein the circulating pump (14) is provided with a circulating medium line, the circulating medium line is communicated with the evaporator (6) through the heater (15), the second heater (16) and the third heater (17), then the circulating medium line of the evaporator (6) is communicated with the circulating pump (14) through the generator (1), and the circulating pump (14) is adjusted to be provided with a circulating medium line, the circulating medium line is communicated with the generator (1) through the heater (15), the second heater (16) and the third heater (17), then the circulating medium line of the generator (1) is communicated with the circulating pump (14) through the evaporator (6), thereby forming the combined heat and power system.

18. The combined heat and power system as set forth in claim 16, wherein the circulating pump (14) is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) through the heater (15), the second heater (16) and the third heater (17), then the evaporator (6) is further provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the circulating pump (14) through the generator (1), the circulating pump (14) is adjusted to be provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) and the generator (1) through the heater (15), the second heater (16) and the third heater (17), then the evaporator (6) and the generator (1) are further provided with a circulating medium pipeline, and the circulating pump (14) is communicated with the generator, so as to form the combined heat and power system.

19. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser, a circulating pump, a heater, a second heater and a third heater, wherein a concentrated solution pipeline of the generator (1) is communicated with the second generator (2) through a solution pump (9), a solution heat exchanger (10) and a second solution heat exchanger (11), the second generator (2) is also communicated with the absorber (3) through the second solution heat exchanger (11), a dilute solution pipeline of the absorber (3) is also communicated with the generator (1) through the solution heat exchanger (10), the generator (1) is also communicated with the condenser (4) through a refrigerant vapor channel, the second generator (2) is also communicated with the refrigerant vapor channel, the refrigerant liquid pipeline of the condenser is also communicated with the evaporator (6) through a refrigerant liquid heat exchanger (10), the second condenser (5) is also communicated with the condenser (4), the second generator (2) is also communicated with the refrigerant vapor channel with the second condenser (5) and the second condenser (6), the evaporator (6) is also communicated with a second heater (6), a refrigerant liquid channel is also communicated with a condensate channel, a second heater (17) is also communicated with a second heater channel, a second heater (6) and a condensate channel, a condensate channel is also communicated with a second evaporator channel, a second heater (17) and a condensate channel, a condenser (17) is also communicated with a second heater channel, a third heater channel is also communicated with a condenser (17) and a condenser (17), a condenser (17) and a condenser channel, a condenser channel is communicated with a condenser (17) which are also communicated with a condenser channel connected with a condenser (17) connected with a condenser (6), a condenser (17) connected with a condenser (17), a heat power machine, a third heater channel connected with a condenser (6), a condenser (17) connected with a condenser (6), a condenser (.

20. The thermodynamic combined supply system is characterized in that in the thermodynamic combined supply system according to claim 19, a circulating pump (14) is provided with a circulating medium pipeline which is communicated with an evaporator (6) through a low-temperature condenser (13), a heater (15), a second heater (16) and a third heater (17), then the circulating medium pipeline of the evaporator (6) is communicated with the circulating pump (14) through a generator (1), and the thermodynamic combined supply system is formed by adjusting that the circulating pump (14) is provided with a circulating medium pipeline which is communicated with the generator (1) through the low-temperature condenser (13), the heater (15), the second heater (16) and the third heater (17), then the circulating medium pipeline of the generator (1) is communicated with the circulating pump (14) through the evaporator (6).

21. The thermodynamic combined supply system is characterized in that in the thermodynamic combined supply system according to claim 19, a circulating pump (14) is provided with a circulating medium pipeline which is communicated with an evaporator (6) through a low-temperature condenser (13), a heater (15), a second heater (16) and a third heater (17), then the evaporator (6) is further provided with a circulating medium pipeline which is communicated with the circulating pump (14) through a generator (1), the circulating pump (14) is adjusted to be provided with a circulating medium pipeline which is communicated with the evaporator (6) and the generator (1) through the low-temperature condenser (13), the heater (15), the second heater (16) and the third heater (17), then the evaporator (6) and the generator (1) are respectively provided with a circulating medium pipeline which is communicated with the circulating pump (14) to form the thermodynamic combined supply system.

22. The heat and power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser, a circulating pump and a heat supplier; the generator (1) is provided with a concentrated solution pipeline which is communicated with the second generator (2) through a solution pump (9), a solution heat exchanger (10) and a second solution heat exchanger (11), the second generator (2) is also provided with a concentrated solution pipeline which is communicated with the absorber (3) through the second solution heat exchanger (11), the absorber (3) is also provided with a dilute solution pipeline which is communicated with the generator (1) through the solution heat exchanger (10), the generator (1) is also provided with a refrigerant steam channel which is communicated with the condenser (4), the second generator (2) is also provided with a refrigerant steam channel which is communicated with the second condenser (5), the condenser (4) is also provided with a refrigerant liquid pipeline which is communicated with the evaporator (6) through a refrigerant liquid pump (8), the second condenser (5) is also provided with a refrigerant liquid pipeline which is communicated with the evaporator (6) through a throttle valve (7), the evaporator (6) is also provided with a refrigerant steam channel which is communicated with the absorber (3), the power machine (12) is provided with a new steam channel communicated with the outside, the power machine (12) is also provided with a steam exhaust channel which is communicated with the low-temperature condenser (13), then the low-temperature condenser (13) is further provided with a low-temperature condensate channel communicated with the outside, the power machine (12) or the steam exhaust channel is also communicated with the outside, the circulating pump (14) is provided with a circulating medium pipeline which is communicated with the evaporator (6) through the low-temperature condenser (13) and the heater (18), then the evaporator (6) is further provided with a circulating medium pipeline which is communicated with the circulating pump (14) through the generator (1), the second generator (2) is further provided with a high-temperature heat medium channel communicated with the outside, the absorber (3), the second condenser (5) and the heater (18) are further provided with heated medium channels respectively communicated with the outside, and the condenser (4) is further provided with a cooling medium.

23. The combined heat and power system as set forth in claim 22, wherein the circulating pump (14) has a circulating medium line, which is communicated with the evaporator (6) through the low temperature condenser (13) and the heater (18), and then the evaporator (6) has a circulating medium line, which is communicated with the circulating pump (14) through the generator (1), and the circulating pump (14) has a circulating medium line, which is communicated with the generator (1) through the low temperature condenser (13) and the heater (18), and then the generator (1) has a circulating medium line, which is communicated with the circulating pump (14) through the evaporator (6), to form the combined heat and power system.

24. The combined heat and power system as set forth in claim 22, wherein the circulating pump (14) has a circulating medium line, the circulating medium line is connected to the evaporator (6) through the low temperature condenser (13) and the heat supplier (18), the evaporator (6) is connected to the circulating pump (14) through the generator (1), the circulating pump (14) is adjusted to have a circulating medium line, the circulating medium line is connected to the evaporator (6) and the generator (1) through the low temperature condenser (13) and the heat supplier (18), the evaporator (6) and the generator (1) are connected to the circulating pump (14) through the circulating medium line, and the combined heat and power system is formed.

25. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a circulating pump, a heater and a heat supply device, wherein the generator (1) is provided with a concentrated solution pipeline which is communicated with the second generator (2) through a solution pump (9), a solution heat exchanger (10) and a second solution heat exchanger (11), the second generator (2) is also provided with a concentrated solution pipeline which is communicated with the absorber (3) through the second solution heat exchanger (11), the absorber (3) is also provided with a dilute solution pipeline which is communicated with the generator (1) through the solution heat exchanger (10), the generator (1) is also provided with a refrigerant vapor channel which is communicated with the condenser (4), the second generator (2) is also provided with a refrigerant vapor channel which is communicated with the second condenser (5), the condenser (4) is also provided with a refrigerant liquid pipeline which is communicated with the evaporator (6) through a refrigerant liquid pump (8), the second condenser (5) is also provided with a refrigerant liquid channel which is communicated with the evaporator (6), the evaporator (6) and a heat supply medium, the evaporator (6) is also provided with a high-temperature steam-supply medium-heating medium channel which is communicated with the evaporator (18), the evaporator-heating medium-heating.

26. The combined heat and power system as set forth in claim 25, wherein the circulating pump (14) has a circulating medium line, which is connected to the evaporator (6) through the heater (15) and the heater (18), and then the evaporator (6) has a circulating medium line, which is connected to the circulating pump (14) through the generator (1), and the circulating pump (14) has a circulating medium line, which is connected to the generator (1) through the heater (15) and the heater (18), and then the generator (1) has a circulating medium line, which is connected to the circulating pump (14) through the evaporator (6), to form the combined heat and power system.

27. The combined heat and power system as set forth in claim 25, wherein the circulating pump (14) has a circulating medium line, the evaporator (6) is connected to the evaporator (6) through the heater (15) and the heat supply (18), the circulating medium line is connected to the circulating pump (14) through the generator (1), the circulating pump (14) is adjusted to have a circulating medium line, the evaporator (6) and the generator (1) are connected to the evaporator (6) and the generator (1) through the heater (15) and the heat supply (18), and the circulating medium line is connected to the circulating pump (14) to form the combined heat and power system.

28. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser, a circulating pump, a heater and a heat supply device, wherein the generator (1) is provided with a concentrated solution pipeline which is communicated with the second generator (2) through a solution pump (9), a solution heat exchanger (10) and a second solution heat exchanger (11), the second generator (2) is also provided with a concentrated solution pipeline which is communicated with the absorber (3) through the second solution heat exchanger (11), the absorber (3) is also provided with a dilute solution pipeline which is communicated with the generator (1) through the solution heat exchanger (10), the generator (1) is also provided with a refrigerant vapor channel which is communicated with the condenser (4), the second generator (2) is also provided with a refrigerant vapor channel which is communicated with the second condenser (5), the condenser (4) is also provided with a refrigerant liquid pipeline which is communicated with the evaporator (6) through a refrigerant liquid pump (8), the second condenser (5) is also provided with a refrigerant vapor channel which is communicated with an external evaporator (6), the condenser (2) is also provided with a low-temperature heat supply channel which is communicated with a low-temperature heat supply medium channel which is communicated with a heating medium channel which is communicated with a low-temperature condenser (13), the evaporator channel which is also provided with a low-temperature heat supply channel which is communicated with a low-temperature heat generator (6), the evaporator channel which is communicated with a low temperature heat supply channel which is communicated with a low temperature condenser (6) and a low temperature condenser (2), the evaporator channel which is communicated with a low temperature heat supply channel which is communicated with a low temperature condenser (13) and a low temperature condenser (6), the evaporator channel which is communicated with a low temperature condenser (6) and a low temperature condenser (2) and a low temperature heat supply channel which is communicated with a low temperature heat generator (6), the evaporator channel which is communicated with a.

29. The combined heat and power system as set forth in claim 28, wherein the circulating pump (14) has a circulating medium line, which is communicated with the evaporator (6) through the low-temperature condenser (13), the heater (15) and the heater (18), and then the evaporator (6) has a circulating medium line, which is communicated with the circulating pump (14) through the generator (1), and the circulating pump (14) has a circulating medium line, which is communicated with the generator (1) through the low-temperature condenser (13), the heater (15) and the heater (18), and then the generator (1) has a circulating medium line, which is communicated with the circulating pump (14) through the evaporator (6), thereby forming the combined heat and power system.

30. The combined heat and power system as set forth in claim 28, wherein the circulating pump (14) is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) through the low-temperature condenser (13), the heater (15) and the heater (18), then the evaporator (6) is further provided with a circulating medium pipeline, the circulating pump (14) is further communicated with the circulating pump (1) through the generator (1), the circulating pump (14) is adjusted to be provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) and the generator (1) through the low-temperature condenser (13), the heater (15) and the heater (18), and then the evaporator (6) and the generator (1) are further provided with a circulating medium pipeline, respectively, and the circulating pump (14) is further communicated with the circulating pump (14) to form the combined heat and.

31. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a circulating pump, a heater, a second heater and a heat supply device, wherein the generator (1) is provided with a concentrated solution pipeline which is communicated with the second generator (2) through a solution pump (9), a solution heat exchanger (10) and a second solution heat exchanger (11), the second generator (2) is also provided with a concentrated solution pipeline which is communicated with the absorber (3) through the second solution heat exchanger (11), the absorber (3) is also provided with a dilute solution pipeline which is communicated with the generator (1) through the solution heat exchanger (10), the generator (1) is also provided with a refrigerant vapor channel which is communicated with the condenser (4), the second generator (2) is also provided with a refrigerant vapor channel which is communicated with the second condenser (5), the condenser (4) is also provided with a refrigerant liquid pipeline which is communicated with the evaporator (6) through a refrigerant liquid channel (8), the second condenser (5) is also provided with a refrigerant vapor channel which is communicated with a new evaporator (6), the evaporator (6) and a heat supply channel which is communicated with the evaporator (16), the evaporator (6), and a high-temperature steam-supply channel (18) after the heat supply channel which is communicated with the second generator (6), the heat supply channel which is communicated with the evaporator (6), the evaporator (6) and the evaporator (6), and the second generator (2) are communicated with the evaporator (6), and the heat supply channel (2), and the heat supply channel which are also communicated with the evaporator (6), and the evaporator channel (16), and the evaporator channel (6), and the evaporator channel of the heat supply channel of the evaporator (2), and the evaporator (6), and the evaporator channel of the evaporator (2) after the heat supply channel of the second heater, the evaporator channel of the evaporator (2) are communicated with the evaporator (2), the evaporator channel of the evaporator (2), the.

32. The combined heat and power system as set forth in claim 31, wherein the circulating pump (14) has a circulating medium line, the circulating medium line is connected to the evaporator (6) through the heater (15), the second heater (16) and the heater (18), the circulating medium line of the evaporator (6) is connected to the circulating pump (14) through the generator (1), and the circulating pump (14) has a circulating medium line, the heater (15), the second heater (16) and the heater (18) are connected to the generator (1), the circulating medium line of the generator (1) is connected to the circulating pump (14) through the evaporator (6), thereby forming the combined heat and power system.

33. The combined heat and power system as set forth in claim 31, wherein the circulating pump (14) is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) through the heater (15), the second heater (16) and the heater (18), then the evaporator (6) is further provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the circulating pump (14) through the generator (1), the circulating pump (14) is adjusted to be provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) and the generator (1) through the heater (15), the second heater (16) and the heater (18), and then the evaporator (6) and the generator (1) are further provided with a circulating medium pipeline, respectively, and are communicated with the circulating pump (14) to form the combined heat and power system.

34. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser, a circulating pump, a heater, a second heater and a heat supply device, wherein a concentrated solution pipeline of the generator (1) is communicated with the second generator (2) through a solution pump (9), a solution heat exchanger (10) and a second solution heat exchanger (11), the second generator (2) is also communicated with the absorber (3) through the second solution heat exchanger (11), a dilute solution pipeline of the absorber (3) is also communicated with the generator (1) through the solution heat exchanger (10), the generator (1) is also provided with a refrigerant vapor channel which is communicated with the condenser (4), the second generator (2) is also provided with a refrigerant vapor channel which is communicated with the second condenser (5), the condenser (4) is also provided with a refrigerant liquid pipeline which is provided with a refrigerant liquid pump (8) and is communicated with the evaporator (6), the second condenser (5) is also provided with a refrigerant vapor channel which is also communicated with a refrigerant vapor channel which is communicated with a condenser (7), the second heater (6), a low-temperature heat supply medium channel which is also communicated with a second heater (6), a low-temperature evaporator channel which is also provided with a second generator (6) and a low-temperature condenser (6), a low-temperature condenser channel which is also provided with a heat supply medium channel which is communicated with a heat supply channel which is communicated with a low-temperature evaporator channel which is communicated with a low temperature evaporator channel which is communicated with a condenser (6), a low temperature evaporator channel which is communicated with a condenser channel which is communicated with a low temperature generator (6), a low temperature evaporator channel which is communicated with a low temperature condenser (6), a low temperature condenser channel which is communicated with a low temperature heat supply channel which is.

35. The combined heat and power system as set forth in claim 34, wherein the circulating pump (14) is provided with a circulating medium pipeline which is communicated with the evaporator (6) through the low-temperature condenser (13), the heater (15), the second heater (16) and the heater (18), then the circulating medium pipeline of the evaporator (6) is communicated with the circulating pump (14) through the generator (1), and the circulating pump (14) is adjusted to be provided with a circulating medium pipeline which is communicated with the generator (1) through the low-temperature condenser (13), the heater (15), the second heater (16) and the heater (18), then the circulating medium pipeline of the generator (1) is communicated with the circulating pump (14) through the evaporator (6), thereby forming the combined heat and power system.

36. The combined heat and power system as set forth in claim 34, wherein the circulating pump (14) is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) through the low-temperature condenser (13), the heater (15), the second heater (16) and the heater (18), then the evaporator (6) is further provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the circulating pump (14) through the generator (1), the circulating pump (14) is adjusted to be provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) and the generator (1) through the low-temperature condenser (13), the heater (15), the second heater (16) and the heater (18), then the evaporator (6) and the generator (1) are further provided with a circulating medium pipeline, and the circulating pump (14) is communicated with the generator, so as to form the combined heat and power system.

37. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a circulating pump, a heater, a second heater, a third heater and a heat supply device, wherein a concentrated solution pipeline of the generator (1) is communicated with the second generator (2) through a solution pump (9), a solution heat exchanger (10) and a second solution heat exchanger (11), the concentrated solution pipeline of the second generator (2) is communicated with the absorber (3) through the second solution heat exchanger (11), a dilute solution pipeline of the absorber (3) is communicated with the generator (1) through the solution heat exchanger (10), the generator (1) is further communicated with the condenser (4) through a refrigerant vapor channel, the second generator (2) is further communicated with the refrigerant vapor channel of the second condenser (5), the refrigerant liquid pipeline of the condenser (4) is further communicated with the evaporator (6) through a refrigerant liquid pump (8), the second condenser (5) is further communicated with a refrigerant vapor channel, the second heater (7) is communicated with the second evaporator (6), the evaporator (6) and a new evaporator (6), the evaporator (17) are further communicated with the evaporator (17), the heat supply medium is communicated with the evaporator (17), the heat supply channel of the evaporator (6), the evaporator (17), the second heater is communicated with the evaporator (6), the evaporator (17), the heat supply channel of the heat supply channel is communicated with the second heater (17), the evaporator (17), the third heater is communicated with the evaporator (17), the evaporator (6), the evaporator (17) and the evaporator (17), the evaporator (17) after the evaporator channel, the evaporator channel of the evaporator (6), the evaporator channel is communicated with the evaporator channel of the evaporator channel, the evaporator channel of the evaporator channel is communicated with the evaporator channel of the evaporator channel, the evaporator channel of the evaporator (6), the evaporator (17), the evaporator channel of the evaporator (17), the heat supply channel of the evaporator (2) and the evaporator channel is communicated with the evaporator channel of the.

38. The combined heat and power system as set forth in claim 37, wherein the circulating pump (14) is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) through the heater (15), the second heater (16), the third heater (17) and the heat supply device (18), then the circulating medium pipeline of the evaporator (6) is communicated with the circulating pump (14) through the generator (1), and the circulating pump (14) is adjusted to be provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the generator (1) through the heater (15), the second heater (16), the third heater (17) and the heat supply device (18), and then the circulating medium pipeline of the generator (1) is communicated with the circulating pump (14) through the evaporator (6), thereby forming the combined heat and power system.

39. The combined heat and power system as set forth in claim 37, wherein the circulating pump (14) is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) through the heater (15), the second heater (16), the third heater (17) and the heater (18), then the evaporator (6) is further provided with a circulating medium pipeline, the circulating pump (14) is communicated with the circulating pump (6) through the generator (1), the circulating pump (14) is adjusted to be provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) and the generator (1) through the heater (15), the second heater (16), the third heater (17) and the heater (18), and then the evaporator (6) and the generator (1) are further provided with a circulating medium pipeline, respectively, and the circulating pump (14) is communicated with the generator, thereby forming the combined heat and power system.

40. The heat power combined supply system mainly comprises a generator, a second generator, an absorber, a condenser, a second condenser, an evaporator, a throttle valve, a refrigerant liquid pump, a solution heat exchanger, a second solution heat exchanger, a power machine, a low-temperature condenser, a circulating pump, a heater, a second heater, a third heater and a heat supply device, wherein the generator (1) is provided with a concentrated solution pipeline which is communicated with the second generator (2) through a solution pump (9), a solution heat exchanger (10) and a second solution heat exchanger (11), the second generator (2) is also provided with a concentrated solution pipeline which is communicated with the absorber (3) through the second solution heat exchanger (11), the absorber (3) is also provided with a dilute solution pipeline which is communicated with the generator (1) through the solution heat exchanger (10), the generator (1) is also provided with a refrigerant vapor channel which is communicated with the condenser (4), the second generator (2) is also provided with a refrigerant vapor channel which is communicated with the second condenser (5), the condenser (4) is also provided with a refrigerant vapor channel which is also communicated with the second condenser (6), the condenser (6) through a refrigerant vapor channel which is also communicated with an external vapor channel, the evaporator channel which is also communicated with the condenser (6), the condenser (17), the condenser (6) is also provided with a second heater (17), the evaporator channel which is also communicated with a low-temperature heat supply channel which is communicated with the condenser (17), the evaporator channel which is also communicated with the condenser (6), and the condenser (17), the evaporator channel which is also communicated with the external steam channel which is communicated with the external steam heat supply channel which is communicated with the condenser (6), the condenser (17), the condenser (2) and the condenser (17), the condenser (17) which is also communicated with the external steam channel which is also communicated with the condenser (17), the external steam channel which is also communicated with the condenser (2) after the evaporator channel which is also communicated with the evaporator channel which is communicated with the condenser (17), the condenser (6), the evaporator channel which is communicated with the condenser (17), the evaporator channel which is also communicated with the condenser (2) communicated with the condenser (17), the evaporator.

41. The combined heat and power system as set forth in claim 40, wherein the circulating pump (14) is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) through the low-temperature condenser (13), the heater (15), the second heater (16), the third heater (17) and the heater (18), then the circulating medium pipeline of the evaporator (6) is communicated with the circulating pump (14) through the generator (1), and the circulating pump (14) is adjusted to be provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the generator (1) through the low-temperature condenser (13), the heater (15), the second heater (16), the third heater (17) and the heater (18), then the circulating medium pipeline of the generator (1) is communicated with the circulating pump (14) through the evaporator (6), thereby forming the combined heat and power system.

42. The combined heat and power system as set forth in claim 40, wherein the circulating pump (14) is provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) through the low-temperature condenser (13), the heater (15), the second heater (16), the third heater (17) and the heater (18), then the evaporator (6) is further provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the circulating pump (14) through the generator (1), the circulating pump (14) is adjusted to be provided with a circulating medium pipeline, the circulating medium pipeline is communicated with the evaporator (6) and the generator (1) through the low-temperature condenser (13), the heater (15), the second heater (16), the third heater (17) and the heater (18), then the evaporator (6) and the generator (1) are respectively provided with a circulating medium pipeline, and then the circulating medium pipeline is communicated with the circulating pump (14) to form the combined heat and power system.

43. The combined heat-power system is characterized in that in any combined heat-power system of claims 1, 4, 7, 10, 13, 16, 19, 22, 25, 28, 31, 34, 37 and 40, a preheater is added, a refrigerant liquid pipeline of a condenser (4) is communicated with an evaporator (6) through a refrigerant liquid pump (8) and is adjusted to be communicated with the condenser (4) and the evaporator (6) through the refrigerant liquid pump (8) and the preheater (24), a circulating medium pipeline of the evaporator (6) is communicated with a circulating pump (14) through a generator (1) and is adjusted to be communicated with the circulating pump (14) through the generator (1), and a circulating medium pipeline of the evaporator (6) is communicated with the circulating pump (14) through the generator (1) and the preheater (24), so that the combined heat-power system is formed.

44. The combined heat-power system is characterized in that in any combined heat-power system of claims 2, 5, 8, 11, 14, 17, 20, 23, 26, 29, 32, 35, 38 and 41, a preheater is added, a refrigerant liquid pipeline of a condenser (4) is communicated with an evaporator (6) through a refrigerant liquid pump (8) and is adjusted to be communicated with the condenser (4) and the evaporator (6) through the refrigerant liquid pump (8) and the preheater (24), a circulating medium pipeline of a generator (1) is communicated with a circulating pump (14) through the evaporator (6) and is adjusted to be communicated with the circulating pump (14) through the evaporator (6) and the preheater (24), and the combined heat-power system is formed.

45. The combined heat-power system is characterized in that a preheater is added in any combined heat-power system of claims 3, 6, 9, 12, 15, 18, 21, 24, 27, 30, 33, 36, 39 and 42, a refrigerant liquid pipeline of a condenser (4) is communicated with an evaporator (6) through a refrigerant liquid pump (8) and is adjusted to be communicated with the condenser (4) through the refrigerant liquid pump (8) and the preheater (24), the evaporator (6) and a generator (1) are respectively communicated with a circulating pump (14) through circulating medium pipelines, and are adjusted to be communicated with the evaporator (6) and the generator (1) through circulating medium pipelines and the circulating pump (14) through the preheater (24) respectively, so that the combined heat-power system is formed.

46. A combined heat power system as claimed in any of claims 1-45, wherein a third generator, a second absorber, a second solution pump and a third solution heat exchanger are added, the generator (1) has a concentrated solution line connected to the second generator (2) via the solution pump (9), the solution heat exchanger (10) and the second solution heat exchanger (11), the generator (1) has a concentrated solution line connected to the second absorber (20) via the solution pump (9), the solution heat exchanger (10) and the second solution heat exchanger (11), the second absorber (20) has a dilute solution line connected to the second generator (2) via the second solution pump (21) and the third solution heat exchanger (22), the second generator (2) has a concentrated solution line connected to the absorber (3) via the second solution heat exchanger (11), the second generator (2) has a concentrated solution line connected to the third generator (19) via the third solution heat exchanger (22), the third generator (19) has a concentrated solution line connected to the absorber (3) via the second solution heat exchanger (11), the second generator (2) has a concentrated solution line connected to the third generator (19), the third generator (19) has a high temperature heat exchanger connected to the second generator (19), and the third generator (19) is connected to the heat exchanger (11).

47. The combined heat power system is characterized in that a third generator, a second solution pump, a third solution heat exchanger and a second throttling valve are added in the combined heat power system as set forth in claims 1-45, a concentrated solution pipeline of the generator (1) is communicated with a third generator (19) through a second solution pump (21), a solution heat exchanger (10) and a third solution heat exchanger (22), the third generator (19) and a concentrated solution pipeline are communicated with an absorber (3) through the third solution heat exchanger (22), the second generator (2) is communicated with a second condenser (5) through a refrigerant vapor channel, the third generator (19) is communicated with the second condenser (5) through a second throttling valve (23), and the third generator (19) and a refrigerant vapor channel are communicated with the second condenser (5) to form the combined heat power system.

48. A combined heat power system according to any of claims 1-45, wherein a third generator, a third solution heat exchanger and a second throttle valve are added, the generator (1) has a concentrate line in communication with the second generator (2) via a solution pump (9), a solution heat exchanger (10) and a second solution heat exchanger (11), the generator (1) has a concentrate line in communication with the absorber (3) via the solution pump (9), the solution heat exchanger (10), the second solution heat exchanger (11) and the third solution heat exchanger (22), the second generator (2) has a concentrate line in communication with the absorber (3) via the second solution heat exchanger (11), the second generator (2) has a concentrate line in communication with the third generator (19) via the third solution heat exchanger (22), the third generator (19) has a concentrate line in communication with the third generator (19) via the second solution heat exchanger (11), the second generator (2) has a steam line in communication with the second generator (3), the second generator (2) has a steam line in communication with the second generator (19) via a steam generator (5) and a steam generator (5) in communication with the second condenser (5) via a steam generator and a second condenser (5).

49. A combined heat power system comprising a third generator, a second solution pump, a third solution heat exchanger and a second throttle valve, wherein the third generator, the second solution pump, the third solution heat exchanger and the second throttle valve are added to any of the combined heat power system described in claims 1-45, the generator (1) has a concentrated solution line communicating with the second generator (2) via the solution pump (9), the solution heat exchanger (10) and the second solution heat exchanger (11), the third generator (19) has a concentrated solution line communicating with the second generator (2) via the second solution pump (21) and the third solution heat exchanger (22), the second generator (2) has a concentrated solution line communicating with the absorber (3) via the second solution heat exchanger (11), the second generator (2) has a concentrated solution line communicating with the third solution heat exchanger (22) and the second solution heat exchanger (3), the second generator (5) has a vapor-refrigerant line communicating with the second generator (5) and the second condenser (5) communicating with the second generator.

50. The combined heat power system is the combined heat power system of any of claims 47-49, wherein the third generator (19) is provided with a high-temperature heat medium channel to communicate with the outside to form the combined heat power system.

51. A combined heat power system is characterized in that a third generator, a second absorber, a second solution pump and a third solution heat exchanger are added in any combined heat power system of claims 1-45, the second generator (2) is provided with a refrigerant steam passage communicated with a second condenser (5) and is adjusted to be communicated with the second absorber (20) through the refrigerant steam passage, the second absorber (20) is also provided with a dilute solution pipeline communicated with a third generator (19) through a second solution pump (21) and a third solution heat exchanger (22), the third generator (19) is also provided with a concentrated solution pipeline communicated with the second absorber (20) through a third solution heat exchanger (22), the third generator (19) is also provided with a refrigerant steam passage communicated with the second condenser (5), the third generator (19) is also provided with a high-temperature heat medium passage communicated with the outside, and the second absorber (20) is also provided with a heated medium passage communicated with the outside to form the combined heat power system.

52. A combined heat-power system, in any combined heat-power system described in claims 1, 4, 7, 10, 13, 16, 19, 22, 25, 28, 31, 34, 37, 40, a third generator, a second absorber, a second solution pump and a third solution heat exchanger are added, the generator (1) has a concentrated solution line communicating with the second absorber (20) through the solution pump (9), the solution heat exchanger (10) and the second solution heat exchanger (11), the generator (1) has a concentrated solution line communicating with the second absorber (20) through the solution heat exchanger (10), the second absorber (20) has a dilute solution line communicating with the second generator (2) through the solution pump (9) and the second solution heat exchanger (11), the second generator (2) has a concentrated solution line communicating with the absorber (3) through the second solution heat exchanger (11), the second generator (2) has a concentrated solution line communicating with the absorber (2) through the second solution heat exchanger (11), the second generator (2) has a concentrated solution line communicating with the third generator (19) through the second solution heat exchanger (11), the third generator (10) and the second generator (2) has a circulating pump (6), the third solution heat exchanger (10) communicating with the second generator (10), the third generator (10) with the second generator, the second generator (10) and the second generator (3), the third solution heat exchanger (10) and the second generator (6) are connected to the third absorber (6), the third absorber (10) to form a circulating pump, the evaporator heat exchanger (6), the evaporator heat exchanger (10) and the evaporator heat exchanger (6), the evaporator heat exchanger (10) to form a circulating pump, the evaporator heat exchanger (2), the third generator heat exchanger (3), the evaporator heat exchanger (3), the third generator (6) and the third generator heat exchanger (10) to connect the third generator heat exchanger (6).

53. A combined heat-power system, in any combined heat-power system as claimed in claims 2, 5, 8, 11, 14, 17, 20, 23, 26, 29, 32, 35, 38, 41, a third generator, a second absorber, a second solution pump and a third solution heat exchanger are added, the generator (1) has a concentrated solution line communicating with the second absorber (20) through the solution pump (9), the solution heat exchanger (10) and the second solution heat exchanger (11), the generator (1) has a concentrated solution line communicating with the second absorber (20) through the solution heat exchanger (10), the second absorber (20) has a dilute solution line communicating with the second generator (2) through the solution pump (9) and the second solution heat exchanger (11), the second generator (2) has a concentrated solution line communicating with the absorber (3) through the second solution heat exchanger (11), the second generator (2) has a concentrated solution line communicating with the absorber (2) through the second solution heat exchanger (11), the second generator (2) has a concentrated solution line communicating with the third generator (19) through the second solution heat exchanger (10), the third generator (1) and the third solution heat exchanger (10) communicates with the evaporator heat exchanger (10), the generator (1) and the evaporator heat exchanger (3), the third generator (10) communicates with the evaporator heat exchanger (10), the generator (10) with the second generator (10) and the third solution heat exchanger (10), the evaporator heat exchanger (10) communicates with the third generator heat exchanger (10), the evaporator heat exchanger (10) with the evaporator heat exchanger (10), the evaporator heat exchanger (10) with the evaporator heat exchanger (3), the evaporator heat exchanger (10) and the evaporator heat exchanger (10).

54. A combined heat-power system, in any combined heat-power system as claimed in claims 3, 6, 9, 12, 15, 18, 21, 24, 27, 30, 33, 36, 39, 42, a third generator, a second absorber, a second solution pump and a third solution heat exchanger are added, the generator (1) has a concentrated solution line communicating with the second absorber (20) through the solution pump (9), the solution heat exchanger (10) and the second solution heat exchanger (11), the generator (1) has a concentrated solution line communicating with the second absorber (20) through the solution heat exchanger (10), the second absorber (20) has a dilute solution line communicating with the second generator (2) through the solution pump (9) and the second solution heat exchanger (11), the second generator (2) has a concentrated solution line communicating with the absorber (3) through the second solution heat exchanger (11), the second generator (2) has a concentrated solution line communicating with the absorber (2) through the second solution heat exchanger (11), the second generator (2) has a concentrated solution line communicating with the third generator (19) through the second solution heat exchanger (10), the third generator (1) and the second solution heat exchanger (10) communicate with the third absorber (1) through the vapor heat exchanger (10), the generator (10) and the second generator (10) communicate with the dilute solution heat exchanger (10), the second generator (10) with the second generator (10), the third absorber (10) and the evaporator heat exchanger (10), the evaporator heat exchanger (10) respectively, the evaporator heat exchanger (10) with the evaporator heat exchanger (10) and the evaporator heat exchanger (10) to form a concentrated solution heat exchanger (10), the evaporator heat exchanger (10), the third generator (10), the evaporator heat exchanger (10) and the third generator heat exchanger (10).

55. The combined heat-power system is characterized in that in any combined heat-power system of claim 52, a preheater is added, a refrigerant liquid pipeline of a condenser (4) is communicated with an evaporator (6) through a refrigerant liquid pump (8) and is adjusted to be communicated with the evaporator (6) through the refrigerant liquid pump (8) and the preheater (24), a circulating medium pipeline of the evaporator (6) is communicated with a circulating pump (14) through a generator (1) and a third generator (19) and is adjusted to be communicated with the circulating pump (14) through the generator (1), the third generator (19) and the preheater (24), and the combined heat-power system is formed.

56. The combined heat-power system is characterized in that in the combined heat-power system as defined in claim 53, a preheater is added, a refrigerant liquid pipeline of the condenser (4) is communicated with the evaporator (6) through a refrigerant liquid pump (8) and is adjusted to be communicated with the evaporator (6) through the refrigerant liquid pump (8) and the preheater (24), a circulating medium pipeline of the generator (1) is communicated with the circulating pump (14) through the evaporator (6) and the third generator (20) and is adjusted to be communicated with the circulating pump (14) through the evaporator (6), the third generator (20) and the preheater (24), and the combined heat-power system is formed.

57. The combined heat-power system is characterized in that in any combined heat-power system of claim 54, a preheater is added, a refrigerant liquid pipeline of a condenser (4) is communicated with an evaporator (6) through a refrigerant liquid pump (8) and is adjusted to be communicated with the evaporator (6) through the refrigerant liquid pump (8) and the preheater (24), a circulating medium pipeline of each of the evaporator (6) and the generator (1) is communicated with a circulating pump (14) through a third generator (20) and is adjusted to be communicated with the circulating pump (14) through the third generator (20) and the preheater (24), and the evaporator (6) and the generator (1) are communicated with the circulating pump (14) through the circulating medium pipeline of each of the third generator (20) and the preheater (24) to form the combined heat-power system.