CN105890216B - Multidirectional thermodynamic cycle and third-class thermally-driven compression heat pump - Google Patents

Multidirectional thermodynamic cycle and third-class thermally-driven compression heat pump Download PDF

Info

Publication number
CN105890216B
CN105890216B CN201610244078.7A CN201610244078A CN105890216B CN 105890216 B CN105890216 B CN 105890216B CN 201610244078 A CN201610244078 A CN 201610244078A CN 105890216 B CN105890216 B CN 105890216B
Authority
CN
China
Prior art keywords
expander
compressor
communicated
temperature heat
medium channel
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
CN201610244078.7A
Other languages
Chinese (zh)
Other versions
CN105890216A (en
Inventor
李华玉
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Individual
Original Assignee
Individual
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Individual filed Critical Individual
Publication of CN105890216A publication Critical patent/CN105890216A/en
Application granted granted Critical
Publication of CN105890216B publication Critical patent/CN105890216B/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B9/00Compression machines, plants or systems, in which the refrigerant is air or other gas of low boiling point
    • F25B9/06Compression machines, plants or systems, in which the refrigerant is air or other gas of low boiling point using expanders
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B1/00Compression machines, plants or systems with non-reversible cycle
    • F25B1/10Compression machines, plants or systems with non-reversible cycle with multi-stage compression
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B27/00Machines, plants or systems, using particular sources of energy
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B41/00Fluid-circulation arrangements

Abstract

The invention provides a multidirectional thermal cycle and third-class thermally driven compression heat pump, and belongs to the technical field of power, refrigeration and heat pumps. Taking the temperature difference between the high-temperature heat source and the medium-temperature heat source and the temperature difference between the low-temperature heat source and the secondary low-temperature heat source as driving temperature differences, and performing multidirectional thermodynamic cycle on the working medium; the compressor is provided with a circulating working medium channel which is communicated with the second compressor through a heat supplier, the second compressor is provided with a circulating working medium channel which is communicated with the expander through a high-temperature heat exchanger, the expander is provided with a circulating working medium channel which is communicated with the second expander through a low-temperature heat exchanger, the second expander is provided with a circulating working medium channel which is communicated with the compressor through a cooler, the heat supplier is provided with a heated medium channel, the high-temperature heat exchanger is provided with a high-temperature heat medium channel, the low-temperature heat exchanger is provided with a low-temperature heat medium channel, the cooler is provided with a cooling medium channel which is respectively communicated with the outside, and the expander and the second expander are connected with the compressor and the second compressor and transmit power.

Description

Multidirectional thermodynamic cycle and third-class thermally-driven compression heat pump
The technical field is as follows:
the invention belongs to the technical field of power, heat supply and heat pumps.
Background art:
cold demand, heat demand and power demand, which are common in human life and production; in reality, people often need to use high-temperature heat energy to realize refrigeration, heat supply or power conversion, and also need to use power to refrigerate or use power and combine low-temperature heat energy to supply heat. In achieving the above objects, various considerations or conditional limitations are faced, including the type, grade and amount of energy source, the type, grade and amount of user demand, ambient temperature, the type of working medium, the flow, structure and manufacturing cost of the apparatus, and so on.
The heat energy (temperature difference) utilization technology represented by the absorption heat pump technology can simultaneously utilize the temperature difference between the medium-temperature heat load and the cold environment and the temperature difference between the high-temperature heat load and the heated medium, so as to realize the efficient utilization of the heat loads with different temperatures. However, due to the influence of the properties of the working media (solution and refrigerant media), the conversion from heat energy to mechanical energy cannot be realized while supplying heat, and the application field and the application range of the heat pump are greatly limited.
The invention provides a third type of thermally-driven compression heat pump with simple flow, multidirectional thermodynamic cycle and simple structure, which takes the efficient utilization of the temperature difference between a medium-temperature heat load and a cold environment and the temperature difference between a high-temperature heat load and a heated medium as starting points, and also takes the simultaneous utilization of power drive or the consideration of power requirements.
The invention content is as follows:
the invention mainly aims to provide a multidirectional thermodynamic cycle for realizing two temperature difference utilizations and a corresponding third-class thermally driven compression heat pump, and the multidirectional thermodynamic cycle for simultaneously considering the pressure difference utilization and the corresponding third-class thermally driven compression heat pump are included. The specific invention content is described in the following items:
1. the multidirectional thermodynamic cycle is a closed process 123456781 which works among a high-temperature heat source, a medium-temperature heat source, a low-temperature heat source and a sub-low-temperature heat source and consists of eight processes which are sequentially carried out, namely a pressure increasing process 12 of a working medium starting from a sub-low temperature, a heat releasing process 23 to the medium-temperature heat source, a pressure increasing process 34 starting from the medium temperature, a heat absorbing process 45 from the high-temperature heat source, a pressure reducing process 56 starting from the medium temperature, a heat absorbing process 67 from the low-temperature heat source, a pressure reducing process 78 starting from the low temperature and a heat releasing process 81 to the sub.
2. The multidirectional thermodynamic cycle is a non-closed process 12345678 which works among a high-temperature heat source, a medium-temperature heat source, a low-temperature heat source and a sub-low-temperature heat source and is composed of seven processes which are sequentially carried out, namely a pressure increasing process 12 of a cold source medium from sub-low temperature, a heat releasing process 23 to the medium-temperature heat source, a pressure increasing process 34 from medium temperature, a heat absorbing process 45 from the high-temperature heat source, a pressure reducing process 56 from high temperature, a heat absorbing process 67 from the low-temperature heat source and a pressure reducing process 78 from low temperature.
3. The multidirectional thermodynamic cycle is a non-closed process 12345678 which works among a high-temperature heat source, a medium-temperature heat source, a low-temperature heat source and a sub-low-temperature heat source and is formed by seven processes, namely a low-temperature heat source medium descending process 12 from low temperature, a heat releasing process 23 to the sub-low-temperature heat source, a pressure increasing process 34 from sub-low temperature, a heat releasing process 45 to the medium-temperature heat source, a pressure increasing process 56 from medium temperature, a high-temperature heat source heat absorbing process 67 and a high-temperature pressure decreasing process 78 from high temperature, which are sequentially carried out.
4. The multidirectional thermodynamic cycle is a non-closed process 12345678 which works among a high-temperature heat source, a medium-temperature heat source, a low-temperature heat source and a sub-low-temperature heat source and is composed of seven processes which are sequentially carried out, namely a pressure reduction process 12 of a heat source medium from high temperature, a heat absorption process 23 of the low-temperature heat source, a pressure reduction process 34 of the low temperature, a heat release process 45 of the sub-low-temperature heat source, a pressure increase process 56 of the sub-low temperature, a heat release process 67 of the medium-temperature heat source and a pressure increase process 78 of the medium temperature.
5. The multidirectional thermodynamic cycle is a non-closed process 12345678 which works among a high-temperature heat source, a medium-temperature heat source, a low-temperature heat source and a sub-low-temperature heat source and consists of seven processes which are sequentially carried out, namely a pressure increasing process 12 of a heated medium from the medium temperature, a heat absorbing process 23 from the high-temperature heat source, a pressure reducing process 34 from the high temperature, a heat absorbing process 45 from the low-temperature heat source, a pressure reducing process 56 from the low temperature, a heat releasing process 67 to the sub-low-temperature heat source and a pressure increasing process 78 from the sub-low temperature.
6. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger and a cooler; the compressor is provided with a circulating working medium channel which is communicated with the second compressor through a heat supply device, the second compressor is also provided with a circulating working medium channel which is communicated with the expander through a high-temperature heat exchanger, the expander is also provided with a circulating working medium channel which is communicated with the second expander through a low-temperature heat exchanger, the second expander is also provided with a circulating working medium channel which is communicated with the compressor through a cooler, the heat supply device is also provided with a heated medium channel which is communicated with the outside, the high-temperature heat exchanger is also provided with a high-temperature heat medium channel which is communicated with the outside, the low-temperature heat exchanger is also provided with a low-temperature heat medium channel which is communicated with the outside, the cooler is also provided with a cooling medium channel which is communicated with the outside, and the expander and the second.
7. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger and a low-temperature heat exchanger; the external part has cold source medium passageway and compressor intercommunication, the compressor also has cold source medium passageway and second compressor intercommunication through the heat supply ware, the second compressor also has cold source medium passageway and expander intercommunication through high temperature heat exchanger, the expander still has cold source medium passageway and low temperature heat exchanger and second expander intercommunication, the second expander still has cold source medium passageway and outside intercommunication, the heat supply ware still is by heating medium passageway and outside intercommunication, high temperature heat exchanger still has high temperature heat medium passageway and outside intercommunication, low temperature heat exchanger still has low temperature heat medium passageway and outside intercommunication, compressor and second compressor and transmission power are connected to expander and second expander, form third type thermal drive compression heat pump.
8. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a high-temperature heat exchanger and a cooler; the external part is provided with a low-temperature heat medium channel communicated with a second expander, the second expander is also provided with a low-temperature heat medium channel communicated with a compressor through a cooler, the compressor is also provided with a low-temperature heat medium channel communicated with a second compressor through a heat supplier, the second compressor is also provided with a low-temperature heat medium channel communicated with the expander through a high-temperature heat exchanger, the expander is also provided with a low-temperature heat medium channel communicated with the external part, the heat supplier is also provided with a heated medium channel communicated with the external part, the high-temperature heat exchanger is also provided with a high-temperature heat medium channel communicated with the external part, the cooler is also provided with a cooling medium channel communicated with the external part, and the expander and the second expander are connected with the compressor and the second compressor and transmit power to form.
9. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a low-temperature heat exchanger and a cooler; the heat source medium channel is communicated with the expander outside, the expander is also communicated with the second expander through the low-temperature heat exchanger, the heat source medium channel is also communicated with the compressor through the cooler, the heat source medium channel is also communicated with the second compressor through the heat supplier, the heat source medium channel is also communicated with the outside in the second compressor, the heated medium channel is also communicated with the outside in the heat supplier, the low-temperature heat exchanger is also communicated with the outside through the low-temperature heat medium channel, the cooler is also communicated with the outside through the cooling medium channel, and the expander and the second expander are connected with the compressor and the second compressor and transmit power to form a third type heat driving compression heat pump.
10. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a high-temperature heat exchanger, a low-temperature heat exchanger and a cooler; the external part is communicated with a second compressor by a heated medium channel, the second compressor is also communicated with an expander by a heated medium channel through a high-temperature heat exchanger, the expander is also communicated with a second expander by a heated medium channel through a low-temperature heat exchanger, the second expander is also communicated with the compressor by a cooler, the compressor is also communicated with the external part by a heated medium channel, the high-temperature heat exchanger is also communicated with the external part by a high-temperature heat medium channel, the low-temperature heat exchanger is also communicated with the external part by a low-temperature heat medium channel, the cooler is also communicated with the external part by a cooling medium channel, and the expander and the second expander are connected with the compressor and the second compressor and transmit power to form a third type heat-driven compression heat pump.
11. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the compressor is provided with a circulating working medium channel which is communicated with the second compressor through a heat regenerator and a heat supplier, the second compressor is also provided with a circulating working medium channel which is communicated with the expander through the heat regenerator and a high-temperature heat exchanger, the expander is also provided with a circulating working medium channel which is communicated with the second expander through a low-temperature heat exchanger, the second expander is also provided with a circulating working medium channel which is communicated with the compressor through a cooler, the heat supplier is also provided with a heated medium channel which is communicated with the outside, the high-temperature heat exchanger is also provided with a high-temperature heat medium channel which is communicated with the outside, the low-temperature heat exchanger is also provided with a low-temperature heat medium channel which is communicated with the outside, the cooler is also provided with a cooling medium channel which is communicated with the outside, and the expander and the second.
12. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger and a heat regenerator; the external part has cold source medium passageway and compressor intercommunication, the compressor also has cold source medium passageway and heat supply ware and second compressor intercommunication, the second compressor also has cold source medium passageway and passes through heat regenerator and high temperature heat exchanger and expander intercommunication, the expander still has cold source medium passageway and passes through low temperature heat exchanger and second expander intercommunication, the second expander still has cold source medium passageway and outside intercommunication, the heat supply ware still is communicate with the outside by heating medium passageway, high temperature heat exchanger still has high temperature heat medium passageway and outside intercommunication, low temperature heat exchanger still has low temperature heat medium passageway and outside intercommunication, compressor and second compressor and transmission power are connected to expander and second expander, form third type thermal drive compression heat pump.
13. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a high-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a low-temperature heat medium channel communicated with a second expander, the second expander is also provided with a low-temperature heat medium channel communicated with a compressor through a cooler, the compressor is also provided with a low-temperature heat medium channel communicated with a second compressor through a heat regenerator and a heat supplier, the second compressor is also provided with a low-temperature heat medium channel communicated with the expander through the heat regenerator and a high-temperature heat exchanger, the expander is also provided with a low-temperature heat medium channel communicated with the external part, the heat supplier is also provided with a heated medium channel communicated with the external part, the high-temperature heat exchanger is also provided with a high-temperature heat medium channel communicated with the external part, the cooler is also provided with a cooling medium channel communicated with the external part, and the expander and the second expander are connected with the compressor and the second compressor and transmit power.
14. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a low-temperature heat exchanger, a cooler and a heat regenerator; the heat source medium channel is communicated with the expander outside, the heat source medium channel is communicated with the second expander through the low-temperature heat exchanger, the heat source medium channel is communicated with the compressor through the cooler in the second expander, the heat source medium channel is communicated with the second compressor through the heat regenerator and the heat supplier in the compressor, the heat source medium channel is communicated with the outside through the heat regenerator in the second compressor, the heated medium channel is communicated with the outside in the heat supplier, the low-temperature heat exchanger is communicated with the outside through the low-temperature heat medium channel, the cooler is communicated with the outside through the cooling medium channel, and the expander and the second expander are connected with the compressor and the second compressor and transmit power to form a third type of heat-driven compression heat pump.
15. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the external part is communicated with a second compressor by a heated medium channel, the second compressor is also communicated with an expander by a reheater and a high-temperature heat exchanger, the expander is also communicated with a second expander by a heated medium channel, the second expander is also communicated with the compressor by a cooler by the heated medium channel, the compressor is also communicated with the external part by the reheater by the heated medium channel, the high-temperature heat exchanger is also communicated with the external part by the high-temperature heat medium channel, the low-temperature heat exchanger is also communicated with the external part by the low-temperature heat medium channel, the cooler is also communicated with the external part by the cooling medium channel, and the expander and the second expander are connected with the compressor and the second compressor and transmit power to form a third type of heat-driven compression heat pump.
16. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the compressor is provided with a circulating working medium channel which is communicated with the second compressor through a heat supplier, the second compressor is also provided with a circulating working medium channel which is communicated with the expander through a high-temperature heat exchanger, the expander is also provided with a circulating working medium channel which is communicated with the second expander through a heat regenerator and a low-temperature heat exchanger, the second expander is also provided with a circulating working medium channel which is communicated with the compressor through a heat regenerator and a cooler, the heat supplier is also provided with a heated medium channel which is communicated with the outside, the high-temperature heat exchanger is also provided with a high-temperature heat medium channel which is communicated with the outside, the low-temperature heat exchanger is also provided with a low-temperature heat medium channel which is communicated with the outside, the cooler is also provided with a cooling medium channel which is communicated with the outside, and the expander and the second.
17. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a high-temperature heat exchanger, a cooler and a heat regenerator; the external part has cold source medium passageway and compressor intercommunication, the compressor also has cold source medium passageway and communicates with the second compressor through the heat supply ware, the second compressor also has cold source medium passageway and communicates with the expander through high temperature heat exchanger, the expander still has cold source medium passageway and communicates with the second expander through regenerator and low temperature heat exchanger, the second expander still has cold source medium passageway and communicates with the outside through the regenerator, the heat supply ware still is heated medium passageway and outside intercommunication, high temperature heat exchanger still has high temperature heat medium passageway and outside intercommunication, low temperature heat exchanger still has low temperature heat medium passageway and outside intercommunication, compressor and second compressor and transmission power are connected to expander and second expander, form third type thermal drive compression heat pump.
18. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a high-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a low-temperature heat medium channel communicated with a second expander, the second expander is also provided with a low-temperature heat medium channel communicated with a compressor through a heat regenerator and a cooler, the compressor is also provided with a low-temperature heat medium channel communicated with a second compressor through a heat supplier, the second compressor is also provided with a low-temperature heat medium channel communicated with the expander through a high-temperature heat exchanger, the expander is also provided with a low-temperature heat medium channel communicated with the external part through the heat regenerator, the heat supplier is also provided with a heated medium channel communicated with the external part, the high-temperature heat exchanger is also provided with a high-temperature heat medium channel communicated with the external part, the cooler is also provided with a cooling medium channel communicated with the external part, and the expander and the second expander are connected with the compressor and the second compressor and transmit power.
19. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a low-temperature heat exchanger, a cooler and a heat regenerator; the heat source medium channel is communicated with the expander outside, the expander is also communicated with the second expander through the heat regenerator and the low-temperature heat exchanger, the second expander is also communicated with the compressor through the heat regenerator and the cooler, the compressor is also communicated with the second compressor through the heat supplier, the second compressor is also communicated with the outside through the heat source medium channel, the heat supplier is also communicated with the outside through the heated medium channel, the low-temperature heat exchanger is also communicated with the outside through the low-temperature heat medium channel, the cooler is also communicated with the outside through the cooling medium channel, the expander and the second expander are connected with the compressor and the second compressor and transmit power, and the third type of heat-driven compression heat pump is formed.
20. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the external part is communicated with a heated medium channel, the second compressor is also communicated with an expander through a high-temperature heat exchanger and a heated medium channel, the expander is also communicated with the second expander through a heat regenerator and a low-temperature heat exchanger, the second expander is also communicated with the compressor through a heat regenerator and a cooler, the compressor is also communicated with the external part through a heated medium channel, the high-temperature heat exchanger is also communicated with the external part through a high-temperature heat medium channel, the low-temperature heat exchanger is also communicated with the external part through a low-temperature heat medium channel, the cooler is also communicated with the external part through a cooling medium channel, and the expander and the second expander are connected with the compressor and the second compressor and transmit power to form a third type of thermally driven compression heat pump.
21. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the compressor is provided with a circulating working medium channel which is communicated with the second compressor through a heat supplier and a heat regenerator, the second compressor is also provided with a circulating working medium channel which is communicated with the expander through a high-temperature heat exchanger, the expander is also provided with a circulating working medium channel which is communicated with the second expander through a low-temperature heat exchanger and a heat regenerator, the second expander is also provided with a circulating working medium channel which is communicated with the compressor through a cooler, the heat supplier is also provided with a heated medium channel which is communicated with the outside, the high-temperature heat exchanger is also provided with a high-temperature heat medium channel which is communicated with the outside, the low-temperature heat exchanger is also provided with a low-temperature heat medium channel which is communicated with the outside, the cooler is also provided with a cooling medium channel which is communicated with the outside, and the expander and the second.
22. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger and a heat regenerator; the external part has cold source medium passageway and compressor intercommunication, the compressor also has cold source medium passageway and regenerator and second compressor intercommunication through heat supply ware and regenerator, the second compressor also has cold source medium passageway and expander intercommunication through high temperature heat exchanger, the expander still has cold source medium passageway and regenerator and second expander intercommunication through low temperature heat exchanger, the second expander still has cold source medium passageway and outside intercommunication, the heat supply ware still is by heating medium passageway and outside intercommunication, high temperature heat exchanger still has high temperature heat medium passageway and outside intercommunication, low temperature heat exchanger still has low temperature heat medium passageway and outside intercommunication, compressor and second compressor and transmission power are connected to expander and second expander, form third type thermal drive compression heat pump.
23. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a high-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a low-temperature heat medium channel which is communicated with a second expander through a heat regenerator, the second expander is also provided with a low-temperature heat medium channel which is communicated with a compressor through a cooler, the compressor is also provided with a low-temperature heat medium channel which is communicated with a second compressor through a heat supplier and the heat regenerator, the second compressor is also provided with a low-temperature heat medium channel which is communicated with the expander through a high-temperature heat exchanger, the expander is also provided with a low-temperature heat medium channel which is communicated with the external part, the heat supplier is also provided with a heated medium channel which is communicated with the external part, the high-temperature heat exchanger is also provided with a high-temperature heat medium channel which is communicated with the external part, the cooler is also provided with a cooling medium channel which is communicated with the external part, and the expander.
24. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a low-temperature heat exchanger, a cooler and a heat regenerator; the heat source medium channel is communicated with the expander outside, the expander is also communicated with the second expander through the low-temperature heat exchanger and the heat regenerator, the second expander is also communicated with the compressor through the heat source medium channel, the compressor is also communicated with the second compressor through the heat supplier and the heat regenerator, the second compressor is also communicated with the outside through the heat source medium channel, the heat supplier is also communicated with the outside through the heated medium channel, the low-temperature heat exchanger is also communicated with the outside through the low-temperature heat medium channel, the cooler is also communicated with the outside through the cooling medium channel, the expander and the second expander are connected with the compressor and the second compressor and transmit power, and the third type of heat-driven compression heat pump is formed.
25. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the external part is communicated with a second compressor through a heat regenerator, the second compressor is also communicated with an expander through a high-temperature heat exchanger through a heated medium channel, the expander is also communicated with the second expander through a low-temperature heat exchanger and a heat regenerator through a heated medium channel, the second expander is also communicated with the compressor through a cooler, the compressor is also communicated with the external part through a heated medium channel, the high-temperature heat exchanger is also communicated with the external part through a high-temperature heat medium channel, the low-temperature heat exchanger is also communicated with the external part through a low-temperature heat medium channel, the cooler is also communicated with the external part through a cooling medium channel, and the expander and the second expander are connected with the compressor and the second compressor and transmit power to form a third type of thermally driven compression heat pump.
26. The third kind of thermally driven compression heat pump is any one of the third kind of thermally driven compression heat pumps described in items 6-25, in which a power machine is added, the power machine is connected with the compressor and provides power for the compressor to form the third kind of thermally driven compression heat pump driven by additional external power.
27. A third type of thermally driven compression heat pump, which is a third type of thermally driven compression heat pump that is added with a working machine, wherein the expansion machine is connected with the working machine and provides power for the working machine to form an additional load for providing power to the outside, in any of the third type of thermally driven compression heat pumps described in items 6 to 25.
Description of the drawings:
fig. 1 is an exemplary schematic flow diagram of group 1 of a multi-directional thermodynamic cycle provided in accordance with the present invention.
Fig. 2 is an exemplary schematic flow diagram of group 2 of a multi-directional thermodynamic cycle provided in accordance with the present invention.
Fig. 3 is an exemplary schematic flow diagram of group 3 of the multi-directional thermodynamic cycle provided in accordance with the present invention.
Fig. 4 is an exemplary schematic flow diagram of group 4 of the multi-directional thermodynamic cycle provided in accordance with the present invention.
Fig. 5 is an exemplary schematic flow diagram of group 5 of the multi-directional thermodynamic cycle provided in accordance with the present invention.
Fig. 6 is a diagram of a 1 st principal thermodynamic system of a third type of thermally driven compression heat pump according to the present invention.
Fig. 7 is a schematic thermodynamic system diagram of a 2 nd principle of a third type of thermally driven compression heat pump according to the present invention.
Fig. 8 is a diagram of a 3 rd principle thermodynamic system of a third type of thermally driven compression heat pump according to the present invention.
Fig. 9 is a diagram of a 4 th principle thermodynamic system of a third type of thermally driven compression heat pump according to the present invention.
Fig. 10 is a diagram of a 5 th principle thermodynamic system of a third type of thermally driven compression heat pump according to the present invention.
Fig. 11 is a diagram of a 6 th principle thermodynamic system of a third type of thermally driven compression heat pump according to the present invention.
Fig. 12 is a diagram of the 7 th principle thermodynamic system of a third type of thermally driven compression heat pump according to the present invention.
Fig. 13 is a diagram of a 8 th principle thermodynamic system for a third class of thermally driven compression heat pump according to the present invention.
Fig. 14 is a diagram of a 9 th principle thermodynamic system of a third type of thermally driven compression heat pump according to the present invention.
Fig. 15 is a diagram of a 10 th principle thermodynamic system of a third type of thermally driven compression heat pump according to the present invention.
Fig. 16 is a diagram of a 11 th principle thermodynamic system of a third type of thermally driven compression heat pump according to the present invention.
Fig. 17 is a diagram of a 12 th principle thermodynamic system of a third type of thermally driven compression heat pump according to the present invention.
Fig. 18 is a 13 th principle thermodynamic system diagram of a third type of thermally driven compression heat pump provided in accordance with the present invention.
Fig. 19 is a diagram of a 14 th principle thermodynamic system of a third type of thermally driven compression heat pump according to the present invention.
Fig. 20 is a diagram of a 15 th principle thermodynamic system for a third class of thermally driven compression heat pump according to the present invention.
Fig. 21 is a diagram of a 16 th principle thermodynamic system for a third class of thermally driven compression heat pump according to the present invention.
Fig. 22 is a diagram of a 17 th principle thermodynamic system for a third class of thermally driven compression heat pump according to the present invention.
Fig. 23 is a diagram of the 18 th principle thermodynamic system of a third type of thermally driven compression heat pump according to the present invention.
Fig. 24 is a diagram of a 19 th principle thermodynamic system for a third class of thermally driven compression heat pump according to the present invention.
Fig. 25 is a diagram of a 20 th principle thermodynamic system of a third type of thermally driven compression heat pump according to the present invention.
In the figure, 1-compressor, 2-second compressor, 3-expander, 4-second expander, 5-heater, 6-high temperature heat exchanger, 7-low temperature heat exchanger, 8-cooler, 9-regenerator.
For ease of understanding, the following description is given:
(1) the high-temperature heat source is a substance for providing high-temperature driving heat load, and the temperature is relatively highest, namely a heat source medium or a high-temperature heat medium for short; such as high temperature combustion gases and the like.
(2) Medium temperature heat source-the substance that gets the heat load, the temperature is only lower than the high temperature heat source; such as a heated medium.
(3) Low temperature heat source-a substance providing low temperature thermal load, the temperature is lower than the medium temperature heat source, also called low temperature heat medium, such as residual heat medium; among the heat loads provided by the low-temperature heat source, a part of the heat loads is used as a driving heat load of the third type thermally driven compression heat pump, and the other part of the heat loads is used as a temperature-raising heat load.
(4) The second low temperature heat source, namely a substance which takes away low temperature heat load, is the lowest in temperature and is also called as a cold source medium; such as ambient air.
(5) When the heat source is directly used as a working medium to participate in the heat pump circulation flow, the heat source is the substance per se.
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.
Examples of the multi-directional thermodynamic cycle flow in the T-s diagram of fig. 1 are respectively such:
example ①, consisting of a reversible adiabatic compression process 12, a constant temperature exothermic process 23, a reversible adiabatic compression process 34, a constant pressure endothermic process 45, a reversible adiabatic expansion process 56, a constant temperature endothermic process 67, a reversible adiabatic expansion process 78, a constant temperature exothermic process 81, a total of 8 sequential processes.
Example ② differs from example ① in that the reversible adiabatic expansion process 78 of example ① was performed in the two-phase region and the reversible adiabatic expansion process 78 of example ② was performed in the superheated steam region and the two-phase region.
Example ③, consisting of a total of 8 sequential processes, reversible adiabatic compression 12, constant pressure exothermic process 23, reversible adiabatic compression 34, constant pressure endothermic process 45, reversible adiabatic expansion 56, constant pressure endothermic process 67, reversible adiabatic expansion 78, constant pressure exothermic process 81.
Example ④, which comprises 8 sequential processes in total, namely, irreversible adiabatic compression process 12, constant pressure exothermic process 23, irreversible adiabatic compression process 34, constant pressure endothermic process 45, irreversible adiabatic expansion process 56, constant pressure endothermic process 67, irreversible adiabatic expansion process 78, constant pressure exothermic process 81.
In the above example, the 56, 78 process outputs work to satisfy the 12, 34 process; or simultaneously output mechanical energy outwards, or complete circulation by means of external mechanical energy.
Examples of the multi-directional thermodynamic cycle flow in the T-s diagram of fig. 2 are respectively such:
example ①, consisting of 7 sequential processes in total, reversible adiabatic compression process 12, isothermal heat release process 23, reversible adiabatic compression process 34, isothermal heat absorption process 45, reversible adiabatic expansion process 56, isothermal heat absorption process 67, reversible adiabatic expansion process 78.
Example ② differs from example ① in that the reversible adiabatic expansion process 78 of example ① was performed in the two-phase region and the reversible adiabatic expansion process 78 of example ② was performed in the superheated steam region and the two-phase region.
Example ③, consisting of a total of 7 sequential processes, reversible adiabatic compression process 12, constant pressure exothermic process 23, reversible adiabatic compression process 34, constant pressure endothermic process 45, reversible adiabatic expansion process 56, constant pressure endothermic process 67, reversible adiabatic expansion process 78.
Example ④, consisting of 7 sequential processes in total, the irreversible adiabatic compression process 12, the constant pressure exothermic process 23, the irreversible adiabatic compression process 34, the constant pressure endothermic process 45, the irreversible adiabatic expansion process 56, the constant pressure endothermic process 67, and the irreversible adiabatic expansion process 78.
In the above example, the 56, 78 process outputs work to satisfy the 12, 34 process; or simultaneously output mechanical energy outwards, or complete circulation by means of external mechanical energy.
The example of a multi-directional thermodynamic cycle flow in the T-s diagram of fig. 3 is such that:
example ①, consisting of a total of 7 sequential processes, reversible adiabatic expansion process 12, isothermal heat release process 23, reversible adiabatic compression process 34, isothermal heat release process 45, reversible adiabatic compression process 56, isothermal heat absorption process 67, reversible adiabatic expansion process 78.
Example ② differs from example ① in that the reversible adiabatic expansion process 12 of example ① was performed in the two-phase region and the reversible adiabatic expansion process 12 of example ② was performed in the superheated steam region and the two-phase region.
Example ③, consisting of a total of 7 sequential processes, reversible adiabatic expansion process 12, constant pressure exothermic process 23, reversible adiabatic compression process 34, constant pressure exothermic process 45, reversible adiabatic compression process 56, constant pressure endothermic process 67, reversible adiabatic expansion process 78.
Example ④, consisting of 7 sequential processes in total, namely irreversible adiabatic expansion process 12, constant pressure exothermic process 23, irreversible adiabatic compression process 34, constant pressure exothermic process 45, irreversible adiabatic compression process 56, constant pressure endothermic process 67, irreversible adiabatic expansion process 78.
In the above example, the 12, 78 process outputs work to satisfy the 34, 56 process; or simultaneously output mechanical energy outwards, or complete circulation by means of external mechanical energy.
The example of a multi-directional thermodynamic cycle flow in the T-s diagram of fig. 4 is such that:
example ①, consisting of a total of 7 sequential processes, reversible adiabatic expansion process 12, constant pressure endothermic process 23, reversible adiabatic expansion process 34, constant temperature exothermic process 45, reversible adiabatic compression process 56, constant temperature exothermic process 67, reversible adiabatic compression process 78.
Example ② differs from example ① in that the reversible adiabatic expansion process 34 of example ① was performed in the two-phase region and the reversible adiabatic expansion process 34 of example ② was performed in the superheated steam region and the two-phase region.
Example ③, consisting of a total of 7 sequential processes, reversible adiabatic expansion process 12, constant pressure endothermic process 23, reversible adiabatic expansion process 34, constant pressure exothermic process 45, reversible adiabatic compression process 56, constant pressure exothermic process 67, reversible adiabatic compression process 78.
Example ④, consisting of 7 sequential processes in total, irreversible adiabatic expansion process 12, constant pressure endothermic process 23, irreversible adiabatic expansion process 34, constant pressure exothermic process 45, irreversible adiabatic compression process 56, constant pressure exothermic process 67, irreversible adiabatic compression process 78.
In the above example, the 12, 34 process outputs work to satisfy the 56, 78 process; or simultaneously output mechanical energy outwards, or complete circulation by means of external mechanical energy.
The example of a multi-directional thermodynamic cycle flow in the T-s diagram of fig. 5 is such:
example ①, consisting of a total of 7 sequential processes, reversible adiabatic compression 12, constant pressure endothermic 23, reversible adiabatic expansion 34, constant temperature endothermic 45, reversible adiabatic expansion 56, constant temperature exothermic 67, reversible adiabatic compression 78.
Example ② differs from example ① in that the reversible adiabatic expansion process 56 of example ① was performed in the two-phase region and the reversible adiabatic expansion process 56 of example ② was performed in the superheated steam region and the two-phase region.
Example ③, consisting of a total of 7 sequential processes, reversible adiabatic compression process 12, constant pressure endothermic process 23, reversible adiabatic expansion process 34, constant pressure endothermic process 45, reversible adiabatic expansion process 56, constant pressure exothermic process 67, reversible adiabatic compression process 78.
Example ④, consisting of 7 sequential processes in total, namely irreversible adiabatic compression process 12, constant pressure endothermic process 23, irreversible adiabatic expansion process 34, constant pressure endothermic process 45, irreversible adiabatic expansion process 56, constant pressure exothermic process 67, irreversible adiabatic compression process 78.
In the above example, the 34, 56 process outputs work to satisfy the 12, 78 process; or simultaneously output mechanical energy outwards, or complete circulation by means of external mechanical energy.
The third type of thermally driven compression heat pump shown in fig. 6 is realized by:
(1) structurally, the system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger and a cooler; the compressor 1 is provided with a circulating working medium channel which is communicated with the second compressor 2 through a heat supplier 5, the second compressor 2 is also provided with a circulating working medium channel which is communicated with the expander 3 through a high-temperature heat exchanger 6, the expander 3 is also provided with a circulating working medium channel which is communicated with the second expander 4 through a low-temperature heat exchanger 7, the second expander 4 is also provided with a circulating working medium channel which is communicated with the compressor 1 through a cooler 8, the heat supplier 5 is also provided with a heated medium channel which is communicated with the outside, the high-temperature heat exchanger 6 is also provided with a high-temperature heat medium channel which is communicated with the outside, the low-temperature heat exchanger 7 is also provided with a low-temperature heat medium channel which is communicated with the outside, the cooler 8 is also provided with a cooling medium channel which is communicated with the outside, and the.
(2) In the process, the circulating working medium discharged by the compressor 1 flows through the heat supplier 5 and releases heat, and then enters the second compressor 2 for pressure and temperature rise; the circulating working medium discharged by the second compressor 2 flows through the high-temperature heat exchanger 6 and absorbs heat, and then enters the expander 3 to reduce the pressure and do work; the circulating working medium discharged by the expander 3 flows through the low-temperature heat exchanger 7 and absorbs heat, and then enters the second expander 4 to reduce the pressure and do work; circulating working medium discharged by the second expander 4 flows through the cooler 8 and releases heat, and then enters the compressor 1 to be boosted and heated; the low-temperature heat medium provides a driving heat load and a heating heat load through the low-temperature heat exchanger 7, the high-temperature heat medium provides a driving heat load through the high-temperature heat exchanger 6, the medium to be heated obtains a medium-temperature heat load through the heat supplier 5, the low-temperature heat load is taken away by the cooling medium through the cooler 8, and the work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 to generate actuating force, so that a third type of thermally driven compression heat pump is formed.
The third type of thermally driven compression heat pump shown in fig. 7 is realized by:
(1) structurally, the heat pump system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger and a low-temperature heat exchanger; the external part is provided with a cold source medium channel communicated with the compressor 1, the compressor 1 is also provided with a cold source medium channel communicated with the second compressor 2 through a heat supplier 5, the second compressor 2 is also provided with a cold source medium channel communicated with the expander 3 through a high-temperature heat exchanger 6, the expander 3 is also provided with a cold source medium channel communicated with the second expander 4 through a low-temperature heat exchanger 7, the second expander 4 is also provided with a cold source medium channel communicated with the external part, the heat supplier 5 is also communicated with the external part through a heated medium channel, the high-temperature heat exchanger 6 is also provided with a high-temperature heat medium channel communicated with the external part, the low-temperature heat exchanger 7 is also provided with a low-temperature heat medium channel communicated with the external part, and the expander 3 and the second expander 4 are connected with the compressor 1.
(2) In the process, external cold source medium enters the compressor 1 to be boosted and heated, the cold source medium discharged by the compressor 1 flows through the heat supplier 5 to release heat, and then enters the second compressor 2 to be boosted and heated; the cold source medium discharged by the second compressor 2 flows through the high-temperature heat exchanger 6 and absorbs heat, and then enters the expander 3 to reduce the pressure and do work; the cold source medium discharged by the expansion machine 3 flows through the low-temperature heat exchanger 7 and absorbs heat, and then enters the second expansion machine 4 to reduce the pressure and do work and is discharged outwards; the low-temperature heat medium provides a driving heat load and a heating heat load through the low-temperature heat exchanger 7, the high-temperature heat medium provides a driving heat load through the high-temperature heat exchanger 6, the heated medium obtains a medium-temperature heat load through the heat supplier 5, the cold source medium takes away the low-temperature heat load through the inlet and outlet flow, and the work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power, so that a third type of heat driving compression heat pump is formed.
The third type of thermally driven compression heat pump shown in fig. 8 is realized by:
(1) structurally, the system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger and a cooler; the external part is provided with a low-temperature heat medium channel communicated with the second expander 4, the second expander 4 is also provided with a low-temperature heat medium channel communicated with the compressor 1 through a cooler 8, the compressor 1 is also provided with a low-temperature heat medium channel communicated with the second compressor 2 through a heater 5, the second compressor 2 is also provided with a low-temperature heat medium channel communicated with the expander 3 through a high-temperature heat exchanger 6, the expander 3 is also provided with a low-temperature heat medium channel communicated with the external part, the heater 5 is also provided with a heated medium channel communicated with the external part, the high-temperature heat exchanger 6 is also provided with a high-temperature heat medium channel communicated with the external part, the cooler 8 is also provided with a cooling medium channel communicated with the external part, and the expander 3 and the second expander 4 are connected with the compressor 1 and the second compressor.
(2) In the process, the external low-temperature heat medium enters the second expander 4 to reduce the pressure and do work, the low-temperature heat medium discharged by the second expander 4 flows through the cooler 8 and releases heat, and then enters the compressor 1 to increase the pressure and raise the temperature; the low-temperature heat medium discharged by the compressor 1 flows through the heat supplier 5 and releases heat, and then enters the second compressor 2 to increase the pressure and the temperature; the low-temperature heat medium discharged by the second compressor 2 flows through the high-temperature heat exchanger 6 and absorbs heat, and then enters the expander 3 to reduce pressure and do work and is discharged outwards; the low-temperature heat medium provides a driving heat load and a heating heat load through an inlet flow and an outlet flow, the high-temperature heat medium provides the driving heat load through the high-temperature heat exchanger 6, the heated medium obtains a medium-temperature heat load through the heat supplier 5, the cooling medium takes away the low-temperature heat load through the cooler 8, and the work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power, so that a third type of heat-driven compression heat pump is formed.
The third type of thermally driven compression heat pump shown in fig. 9 is realized by:
(1) structurally, the system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a low-temperature heat exchanger and a cooler; a heat source medium channel is arranged outside and communicated with the expander 3, the expander 3 is also communicated with the second expander 4 through a low-temperature heat exchanger 7, the second expander 4 is also communicated with the compressor 1 through a cooler 8, the compressor 1 is also communicated with the second compressor 2 through a heat source medium channel 5, the second compressor 2 is also communicated with the outside through a heat source medium channel, the heat supplier 5 is also communicated with the outside through a heated medium channel, the low-temperature heat exchanger 7 is also communicated with the outside through a low-temperature heat medium channel, the cooler 8 is also communicated with the outside through a cooling medium channel, and the expander 3 and the second expander 4 are connected with the compressor 1 and the second compressor 2 and transmit power.
(2) In the process, an external heat source medium enters the expansion machine 3 to perform decompression work, the heat source medium discharged by the expansion machine 3 flows through the low-temperature heat exchanger 7 to absorb heat, and then enters the second expansion machine 4 to perform decompression work; the heat source medium discharged by the second expander 4 flows through the cooler 8 and releases heat, and then enters the compressor 1 to be boosted and heated; a heat source medium discharged by the compressor 1 flows through the heat supplier 5 and releases heat, and then enters the second compressor 2 to be boosted, heated and discharged; the low-temperature heat medium provides a driving heat load and a heating heat load through the low-temperature heat exchanger 7, the heat source medium provides the driving heat load through an inlet flow and an outlet flow, the heated medium obtains a medium-temperature heat load through the heat supply device 5, the cooling medium takes away the low-temperature heat load through the cooler 8, and the work output by the expansion machine 3 and the second expansion machine 4 is provided for the compressor 1 and the second compressor 2 as power, so that a third type of heat driving compression heat pump is formed.
The third type of thermally driven compression heat pump shown in fig. 10 is realized by:
(1) structurally, the heat exchanger mainly comprises a compressor, a second compressor, an expander, a second expander, a high-temperature heat exchanger, a low-temperature heat exchanger and a cooler; the external part is provided with a heated medium channel which is communicated with the second compressor 2, the second compressor 2 is also provided with a heated medium channel which is communicated with the expander 3 through a high-temperature heat exchanger 6, the expander 3 is also provided with a heated medium channel which is communicated with the second expander 4 through a low-temperature heat exchanger 7, the second expander 4 is also provided with a heated medium channel which is communicated with the compressor 1 through a cooler 8, the compressor 1 is also provided with a heated medium channel which is communicated with the external part, the high-temperature heat exchanger 6 is also provided with a high-temperature heat medium channel which is communicated with the external part, the low-temperature heat exchanger 7 is also provided with a low-temperature heat medium channel which is communicated with the external part, the cooler 8 is also provided with a cooling medium channel which is communicated with the external part, and the expander 3 and the second expander.
(2) In the flow, the heated medium enters the second compressor 2 to be boosted and heated, the heated medium discharged by the second compressor 2 flows through the high-temperature heat exchanger 6 to absorb heat, and then enters the expander 3 to be decompressed and do work; the heated medium discharged by the expander 3 flows through the low-temperature heat exchanger 7 and absorbs heat, and then enters the second expander 4 to reduce the pressure and do work; the heated medium discharged from the second expander 4 flows through the cooler 8 and releases heat, and then enters the compressor 1 to be pressurized, heated and discharged; the low-temperature heat medium provides a driving heat load and a heating heat load through the low-temperature heat exchanger 7, the high-temperature heat medium provides a driving heat load through the high-temperature heat exchanger 6, the medium-temperature heat load is obtained by the heated medium through an inlet and outlet flow, the low-temperature heat load is taken away by the cooling medium through the cooler 8, and the work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power to form a third type of heat driving compression heat pump.
The third type of thermally driven compression heat pump shown in fig. 11 is realized by:
(1) structurally, the heat recovery system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the compressor 1 is provided with a circulating working medium channel which is communicated with the second compressor 2 through a heat regenerator 9 and a heat supplier 5, the second compressor 2 is also provided with a circulating working medium channel which is communicated with the expander 3 through the heat regenerator 9 and a high-temperature heat exchanger 6, the expander 3 is also provided with a circulating working medium channel which is communicated with the second expander 4 through a low-temperature heat exchanger 7, the second expander 4 is also provided with a circulating working medium channel which is communicated with the compressor 1 through a cooler 8, the heat supplier 5 is also communicated with the outside through a heated medium channel, the high-temperature heat exchanger 6 is also communicated with the outside through a high-temperature heat medium channel, the low-temperature heat exchanger 7 is also provided with a low-temperature heat medium channel which is communicated with the outside, the cooler 8 is also communicated with the outside through a cooling medium channel, and the expander 3 and the second expander 4.
(2) In the process, the circulating working medium discharged by the compressor 1 sequentially flows through the heat regenerator 9 and the heat supplier 5 and gradually releases heat, and then enters the second compressor 2 to increase the pressure and the temperature; the circulating working medium discharged by the second compressor 2 flows through the heat regenerator 9 and the high-temperature heat exchanger 6 in sequence, gradually absorbs heat, and then enters the expansion machine 3 to reduce the pressure and do work; the circulating working medium discharged by the expansion machine 3 flows through the low-temperature heat exchanger 7 and absorbs heat, and then enters the second expansion machine 4 to reduce the pressure and do work; circulating working medium discharged by the second expander 4 flows through the cooler 8 and releases heat, and then enters the compressor 1 to be boosted and heated; the low-temperature heat medium provides driving heat load and heating heat load through the low-temperature heat exchanger 7, the high-temperature heat medium provides driving heat load through the high-temperature heat exchanger 6, the heated medium obtains medium-temperature heat load through the heat supplier 5, the cooling medium takes away the low-temperature heat load through the cooler 8, and work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power, so that a third type of heat-driven compression heat pump is formed.
The third type of thermally driven compression heat pump shown in fig. 12 is realized by:
(1) structurally, the heat recovery system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger and a heat regenerator; the external part is provided with a cold source medium channel communicated with the compressor 1, the compressor 1 is also provided with a cold source medium channel communicated with the second compressor 2 through a heat regenerator 9 and a heat supplier 5, the second compressor 2 is also provided with a cold source medium channel communicated with the expander 3 through the heat regenerator 9 and a high-temperature heat exchanger 6, the expander 3 is also provided with a cold source medium channel communicated with the second expander 4 through a low-temperature heat exchanger 7, the second expander 4 is also provided with a cold source medium channel communicated with the external part, the heat supplier 5 is also communicated with the external part through a heated medium channel, the high-temperature heat exchanger 6 is also provided with a high-temperature heat medium channel communicated with the external part, the low-temperature heat exchanger 7 is also provided with a low-temperature heat medium channel communicated with the external part, and the expander 3 and the second expander 4 are connected with the.
(2) In the process, external cold source media enter the compressor 1 to be boosted and heated, the cold source media discharged by the compressor 1 sequentially flow through the heat regenerator 9 and the heat heater 5 to gradually release heat, and then enter the second compressor 2 to be boosted and heated; cold source media discharged by the second compressor 2 sequentially flow through the heat regenerator 9 and the high-temperature heat exchanger 6 and gradually absorb heat, and then enter the expansion machine 3 to reduce the pressure and do work; the cold source medium discharged by the expansion machine 3 flows through the low-temperature heat exchanger 7 and absorbs heat, and then enters the second expansion machine 4 to reduce pressure and do work and is discharged outwards; the low-temperature heat medium provides a driving heat load and a heating heat load through the low-temperature heat exchanger 7, the high-temperature heat medium provides a driving heat load through the high-temperature heat exchanger 6, the heated medium obtains a medium-temperature heat load through the heat supplier 5, the cold source medium takes away the low-temperature heat load through an inlet-outlet flow, and work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power, so that a third type of thermally driven compression heat pump is formed.
The third type of thermally driven compression heat pump shown in fig. 13 is realized by:
(1) structurally, the heat recovery system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a low-temperature heat medium channel communicated with the second expander 4, the second expander 4 is also provided with a low-temperature heat medium channel communicated with the compressor 1 through a cooler 8, the compressor 1 is also provided with a low-temperature heat medium channel communicated with the second compressor 2 through a heat regenerator 9 and a heat supplier 5, the second compressor 2 is also provided with a low-temperature heat medium channel communicated with the expander 3 through the heat regenerator 9 and a high-temperature heat exchanger 6, the expander 3 is also provided with a low-temperature heat medium channel communicated with the external part, the heat supplier 5 is also provided with a heated medium channel communicated with the external part, the high-temperature heat exchanger 6 is also provided with a high-temperature heat medium channel communicated with the external part, the cooler 8 is also provided with a cooling medium channel communicated with the external part, and the expander 3 and the second expander 4 are connected with the compressor 1 and.
(2) In the process, the low-temperature heat medium enters the second expander 4 to reduce the pressure and do work, the low-temperature heat medium discharged by the second expander 4 flows through the cooler 8 and releases heat, and then enters the compressor 1 to increase the pressure and raise the temperature; the low-temperature heat medium discharged by the compressor 1 sequentially flows through the heat regenerator 9 and the heat supplier 5 and gradually releases heat, and then enters the second compressor 2 to increase the pressure and the temperature; the low-temperature heat medium discharged by the second compressor 2 flows through the heat regenerator 9 and the high-temperature heat exchanger 6 in sequence and absorbs heat gradually, and then enters the expansion machine 3 to reduce pressure and do work and is discharged outwards; the low-temperature heat medium provides a driving heat load and a heating heat load through an inlet and outlet flow, the high-temperature heat medium provides the driving heat load through the high-temperature heat exchanger 6, the medium to be heated obtains the medium-temperature heat load through the heater 5, the cooling medium takes away the low-temperature heat load through the cooler 8, and the work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power, so that a third type of heat driving compression heat pump is formed.
The third type of thermally driven compression heat pump shown in fig. 14 is realized by:
(1) structurally, the heat recovery system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a low-temperature heat exchanger, a cooler and a heat regenerator; a heat source medium channel is arranged outside and communicated with the expander 3, the expander 3 and the heat source medium channel are communicated with the second expander 4 through the low-temperature heat exchanger 7, the second expander 4 and the heat source medium channel are communicated with the compressor 1 through the cooler 8, the compressor 1 and the heat source medium channel are communicated with the second compressor 2 through the heat regenerator 9 and the heat supplier 5, the second compressor 2 and the heat source medium channel are communicated with the outside through the heat regenerator 9, the heat supplier 5 and the heated medium channel are communicated with the outside, the low-temperature heat exchanger 7 and the low-temperature heat medium channel are communicated with the outside, the cooler 8 and the cooling medium channel are communicated with the outside, and the expander 3 and the second expander 4 are connected with the compressor 1 and the second compressor 2 and transmit power.
(2) In the process, an external heat source medium enters the expansion machine 3 to perform decompression work, the heat source medium discharged by the expansion machine 3 flows through the low-temperature heat exchanger 7 to absorb heat, and then enters the second expansion machine 4 to perform decompression work; the heat source medium discharged by the second expander 4 flows through the cooler 8 and releases heat, and then enters the compressor 1 to be boosted and heated; the heat source medium discharged by the compressor 1 flows through the heat regenerator 9 and the heat heater 5 in sequence and releases heat gradually, and then enters the second compressor 2 to increase the pressure and the temperature; the heat source medium discharged from the second compressor 2 flows through the heat regenerator 9 and absorbs heat, and then is discharged to the outside; the low-temperature heat medium provides a driving heat load and a heating heat load through the low-temperature heat exchanger 7, the heat source medium provides a driving heat load through an inlet flow and an outlet flow, the heated medium obtains a medium-temperature heat load through the heat supplier 5, the cooling medium takes away the low-temperature heat load through the cooler 8, and the work output by the expander 3 and the second expander 4 is provided to the compressor 1 and the second compressor 2 as power to form a third type of heat driving compression heat pump.
The third type of thermally driven compression heat pump shown in fig. 15 is realized by:
(1) structurally, the heat exchanger mainly comprises a compressor, a second compressor, an expander, a second expander, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a heated medium channel which is communicated with the second compressor 2, the second compressor 2 is also provided with a heated medium channel which is communicated with the expander 3 through a heat regenerator 9 and a high-temperature heat exchanger 6, the expander 3 is also provided with a heated medium channel which is communicated with the second expander 4 through a low-temperature heat exchanger 7, the second expander 4 is also provided with a heated medium channel which is communicated with the compressor 1 through a cooler 8, the compressor 1 is also provided with a heated medium channel which is communicated with the external part through the heat regenerator 9, the high-temperature heat exchanger 6 is also provided with a high-temperature heat medium channel which is communicated with the external part, the low-temperature heat exchanger 7 is also provided with a low-temperature heat medium channel which is communicated with the external part, the cooler 8 is also provided with a cooling medium channel which is communicated with the external part, and the expander.
(2) In the process, the heated medium enters the second compressor 2 to be boosted and heated, the heated medium discharged by the second compressor 2 sequentially flows through the heat regenerator 9 and the high-temperature heat exchanger 6 to gradually absorb heat, and then enters the expander 3 to be decompressed and do work; the heated medium discharged by the expander 3 flows through the low-temperature heat exchanger 7 and absorbs heat, and then enters the second expander 4 to reduce the pressure and do work; the heated medium discharged by the second expander 4 flows through the cooler 8 and releases heat, and then enters the compressor 1 to be boosted and heated; the heated medium discharged from the compressor 1 flows through the heat regenerator 9 and releases heat, and then is discharged to the outside; the low-temperature heat medium provides a driving heat load and a heating heat load through the low-temperature heat exchanger 7, the high-temperature heat medium provides a driving heat load through the high-temperature heat exchanger 6, the medium-temperature heat load is obtained by the heated medium through an inlet and outlet flow, the low-temperature heat load is taken away by the cooling medium through the cooler 8, work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power, and a third type of thermally driven compression heat pump is formed.
The third type of thermally driven compression heat pump shown in fig. 16 is realized by:
(1) structurally, the heat recovery system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the compressor 1 is provided with a circulating working medium channel which is communicated with the second compressor 2 through a heat supplier 5, the second compressor 2 is also provided with a circulating working medium channel which is communicated with an expander 3 through a high-temperature heat exchanger 6, the expander 3 is also provided with a circulating working medium channel which is communicated with a second expander 4 through a heat regenerator 9 and a low-temperature heat exchanger 7, the second expander 4 is also provided with a circulating working medium channel which is communicated with the compressor 1 through a heat regenerator 9 and a cooler 8, the heat supplier 5 is also communicated with the outside through a heated medium channel, the high-temperature heat exchanger 6 is also provided with a high-temperature heat medium channel which is communicated with the outside, the low-temperature heat exchanger 7 is also provided with a low-temperature heat medium channel which is communicated with the outside, the cooler 8 is also provided with a cooling medium channel which is communicated with the outside, and the expander.
(2) In the process, the circulating working medium discharged by the compressor 1 flows through the heat supplier 5 and releases heat, and then enters the second compressor 2 for pressure and temperature rise; the circulating working medium discharged by the second compressor 2 flows through the high-temperature heat exchanger 6 and absorbs heat, and then enters the expander 3 to reduce the pressure and do work; the circulating working medium discharged by the expansion machine 3 sequentially flows through the heat regenerator 9 and the low-temperature heat exchanger 7 and gradually absorbs heat, and then enters the second expansion machine 4 to reduce the pressure and do work; the circulating working medium discharged by the second expander 4 sequentially flows through the heat regenerator 9 and the cooler 8 and gradually releases heat, and then enters the compressor 1 to be boosted and heated; the low-temperature heat medium provides driving heat load and heating heat load through the low-temperature heat exchanger 7, the high-temperature heat medium provides driving heat load through the high-temperature heat exchanger 6, the heated medium obtains medium-temperature heat load through the heat supplier 5, the cooling medium takes away the low-temperature heat load through the cooler 8, and work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power, so that a third type of heat-driven compression heat pump is formed.
The third type of thermally driven compression heat pump shown in fig. 17 is realized by:
(1) structurally, the heat recovery system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchange station and a heat regenerator; the external part is provided with a cold source medium channel communicated with the compressor 1, the compressor 1 is also provided with a cold source medium channel communicated with the second compressor 2 through a heat supplier 5, the second compressor 2 is also provided with a cold source medium channel communicated with the expander 3 through a high-temperature heat exchanger 6, the expander 3 is also provided with a cold source medium channel communicated with the second expander 4 through a heat regenerator 9 and a low-temperature heat exchanger 7, the second expander 4 is also provided with a cold source medium channel communicated with the external part through the heat regenerator 9, the heat supplier 5 is also communicated with the external part through a heated medium channel, the high-temperature heat exchanger 6 is also provided with a high-temperature heat medium channel communicated with the external part, the low-temperature heat exchanger 7 is also provided with a low-temperature heat medium channel communicated with the external part, and the expander 3 and the second expander 4 are connected.
(2) In the process, external cold source medium enters the compressor 1 to be boosted and heated, the cold source medium discharged by the compressor 1 flows through the heat supplier 5 to release heat, and then enters the second compressor 2 to be boosted and heated; the cold source medium discharged by the second compressor 2 flows through the high-temperature heat exchanger 6 and absorbs heat, and then enters the expander 3 to reduce the pressure and do work; cold source media discharged by the expansion machine 3 sequentially flow through the heat regenerator 9 and the low-temperature heat exchanger 7 and gradually absorb heat, and then enter the second expansion machine 4 to reduce the pressure and do work; the cold source medium discharged by the second expander 4 flows through the heat regenerator 9 and releases heat, and then is discharged outside; the low-temperature heat medium provides a driving heat load and a heating heat load through the low-temperature heat exchanger 7, the high-temperature heat medium provides a driving heat load through the high-temperature heat exchanger 6, the heated medium obtains a medium-temperature heat load through the heat supplier 5, the cold source medium takes away the low-temperature heat load through the inlet and outlet flow, and the work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power, so that a third type of thermally driven compression heat pump is formed.
The third type of thermally driven compression heat pump shown in fig. 18 is realized by:
(1) structurally, the heat recovery system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a low-temperature heat medium channel communicated with the second expander 4, the second expander 4 is also provided with a low-temperature heat medium channel communicated with the compressor 1 through a heat regenerator 9 and a cooler 8, the compressor 1 is also provided with a low-temperature heat medium channel communicated with the second compressor 2 through a heat supplier 5, the second compressor 2 is also provided with a low-temperature heat medium channel communicated with the expander 3 through a high-temperature heat exchanger 6, the expander 3 is also provided with a low-temperature heat medium channel communicated with the external part through the heat regenerator 9, the heat supplier 5 is also provided with a heated medium channel communicated with the external part, the high-temperature heat exchanger 6 is also provided with a high-temperature heat medium channel communicated with the external part, the cooler 8 is also provided with a cooling medium channel communicated with the external part, and the expander 3 and the second expander 4 are connected with the compressor 1 and the.
(2) In the process, the external low-temperature heat medium enters the second expander 4 to reduce the pressure and do work, the low-temperature heat medium discharged by the second expander 4 sequentially flows through the heat regenerator 9 and the cooler 8 to gradually release heat, and then enters the compressor 1 to increase the pressure and the temperature; the low-temperature heat medium discharged by the compressor 1 flows through the heat supplier 5 and releases heat, and then enters the second compressor 2 to increase the pressure and the temperature; the low-temperature heat medium discharged by the second compressor 2 flows through the high-temperature heat exchanger 6 and absorbs heat, and then enters the expander 3 to reduce the pressure and do work; the low-temperature heat medium discharged by the expander 3 flows through the heat regenerator 9 and absorbs heat, and then is discharged outwards; the low-temperature heat medium provides a driving heat load and a heating heat load through an inlet and outlet flow, the high-temperature heat medium provides the driving heat load through the high-temperature heat exchanger 6, the medium to be heated obtains the medium-temperature heat load through the heat supplier 5, the low-temperature heat load is taken away by the cooling medium through the cooler 8, and the work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power, so that a third type of thermally driven compression heat pump is formed.
The third type of thermally driven compression heat pump shown in fig. 19 is realized by:
(1) structurally, the heat recovery system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a low-temperature heat exchanger, a cooler and a heat regenerator; a heat source medium channel is arranged outside and communicated with the expander 3, the expander 3 and the heat source medium channel are communicated with the second expander 4 through a heat regenerator 9 and a low-temperature heat exchanger 7, the second expander 4 and the heat source medium channel are communicated with the compressor 1 through the heat regenerator 9 and a cooler 8, the compressor 1 and the heat source medium channel are communicated with the second compressor 2 through a heat supplier 5, the second compressor 2 and the heat source medium channel are communicated with the outside, the heat supplier 5 and a heated medium channel are communicated with the outside, the low-temperature heat exchanger 7 and a low-temperature heat medium channel are communicated with the outside, the cooler 8 and the cooling medium channel are communicated with the outside, and the expander 3 and the second expander 4 are connected with the compressor 1 and the second compressor 2 and transmit power.
(2) In the process, an external heat source medium enters the expander 3 to perform decompression work, the heat source medium discharged by the expander 3 sequentially flows through the heat regenerator 9 and the low-temperature heat exchanger 7 to gradually absorb heat, and then enters the second expander 4 to perform decompression work; the heat source medium discharged by the second expander 4 flows through the heat regenerator 9 and the cooler 8 in sequence, gradually releases heat, and then enters the compressor 1 to increase the pressure and the temperature; a heat source medium discharged by the compressor 1 flows through the heat supplier 5 and releases heat, and then enters the second compressor 2 to be boosted, heated and discharged; the low-temperature heat medium provides a driving heat load and a heating heat load through the low-temperature heat exchanger 7, the heat source medium provides a driving heat load through an inlet flow path and an outlet flow path, the medium to be heated obtains a medium-temperature heat load through the heat supplier 5, the cooling medium brings the low-temperature heat load away through the cooler 8, and the work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power, so that a third type of heat-driven compression heat pump is formed.
The third type of thermally driven compression heat pump shown in fig. 20 is realized by:
(1) structurally, the heat exchanger mainly comprises a compressor, a second compressor, an expander, a second expander, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a heated medium channel which is communicated with the second compressor 2, the second compressor 2 is also provided with a heated medium channel which is communicated with the expander 3 through a high-temperature heat exchanger 6, the expander 3 is also provided with a heated medium channel which is communicated with the second expander 4 through a regenerator 9 and a low-temperature heat exchanger 7, the second expander 4 is also provided with a heated medium channel which is communicated with the compressor 1 through the regenerator 9 and a cooler 8, the compressor 1 is also provided with a heated medium channel which is communicated with the external part, the high-temperature heat exchanger 6 is also provided with a high-temperature heat medium channel which is communicated with the external part, the low-temperature heat exchanger 7 is also provided with a low-temperature heat medium channel which is communicated with the external part, the cooler 8 is also provided with a cooling medium channel which is communicated with the external part, and the expander 3 and the.
(2) In the process, external heated medium enters the second compressor 2 to be boosted and heated, the heated medium discharged by the second compressor 2 flows through the high-temperature heat exchanger 6 to absorb heat, and then enters the expander 3 to be decompressed and work; the heated medium discharged by the expander 3 flows through the heat regenerator 9 and the low-temperature heat exchanger 7 in sequence and absorbs heat gradually, and then enters the second expander 4 to reduce the pressure and do work; the heated medium discharged by the second expander 4 sequentially flows through the heat regenerator 9 and the cooler 8 and gradually releases heat, and then enters the compressor 1 to be boosted, heated and discharged; the low-temperature heat medium provides a driving heat load and a heating heat load through the low-temperature heat exchanger 7, the high-temperature heat medium provides a driving heat load through the high-temperature heat exchanger 6, the medium-temperature heat load is obtained by the heated medium through an inlet and outlet flow, the low-temperature heat load is taken away by the cooling medium through the cooler 8, and the work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power to form a third type of thermally driven compression heat pump.
The third type of thermally driven compression heat pump shown in fig. 21 is realized by:
(1) structurally, the heat recovery system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the compressor 1 is provided with a circulating working medium channel which is communicated with the second compressor 2 through a heat supplier 5 and a heat regenerator 9, the second compressor 2 is also provided with a circulating working medium channel which is communicated with the expander 3 through a high-temperature heat exchanger 6, the expander 3 is also provided with a circulating working medium channel which is communicated with the second expander 4 through a low-temperature heat exchanger 7 and a heat regenerator 9, the second expander 4 is also provided with a circulating working medium channel which is communicated with the compressor 1 through a cooler 8, the heat supplier 5 is also provided with a heated medium channel which is communicated with the outside, the high-temperature heat exchanger 6 is also provided with a high-temperature heat medium channel which is communicated with the outside, the low-temperature heat exchanger 7 is also provided with a low-temperature heat medium channel which is communicated with the outside, the cooler 8 is also provided with a cooling medium channel which is communicated with the outside.
(2) In the process, the circulating working medium discharged by the compressor 1 sequentially flows through the heat supplier 5 and the heat regenerator 9 and gradually releases heat, and then enters the second compressor 2 to increase the pressure and the temperature; the circulating working medium discharged by the second compressor 2 flows through the high-temperature heat exchanger 6 and absorbs heat, and then enters the expander 3 to reduce the pressure and do work; the circulating working medium discharged by the expansion machine 3 flows through the low-temperature heat exchanger 7 and the heat regenerator 9 and gradually absorbs heat, and then enters the second expansion machine 4 to reduce the pressure and do work; circulating working medium discharged by the second expander 4 flows through the cooler 8 and releases heat, and then enters the compressor 1 to be boosted and heated; the low-temperature heat medium provides a driving heat load and a heating heat load through the low-temperature heat exchanger 7, the high-temperature heat medium provides a driving heat load through the high-temperature heat exchanger 6, the medium to be heated obtains a medium-temperature heat load through the heat supplier 5, the low-temperature heat load is taken away by the cooling medium through the cooler 8, and the work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power, so that a third type of thermally driven compression heat pump is formed.
The third type of thermally driven compression heat pump shown in fig. 22 is realized by:
(1) structurally, the heat recovery system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger and a heat regenerator; the external part is provided with a cold source medium channel communicated with the compressor 1, the compressor 1 is also provided with a cold source medium channel communicated with the second compressor 2 through a heat supplier 5 and a heat regenerator 9, the second compressor 2 is also provided with a cold source medium channel communicated with the expander 3 through a high temperature heat exchanger 6, the expander 3 is also provided with a cold source medium channel communicated with the second expander 4 through a low temperature heat exchanger 7 and a heat regenerator 9, the second expander 4 is also provided with a cold source medium channel communicated with the external part, the heat supplier 5 is also communicated with the external part through a heated medium channel, the high temperature heat exchanger 6 is also communicated with the external part through a high temperature heat medium channel, the low temperature heat exchanger 7 is also provided with a low temperature heat medium channel communicated with the external part, and the expander 3 and the second expander 4 are connected with the compressor 1 and the second compressor.
(2) In the process, external cold source media enter the compressor 1 to be boosted and heated, the cold source media discharged by the compressor 1 sequentially flow through the heat supplier 5 and the heat regenerator 9 and gradually release heat, and then enter the second compressor 2 to be boosted and heated; the cold source medium discharged by the second compressor 2 flows through the high-temperature heat exchanger 6 and absorbs heat, and then enters the expander 3 to reduce the pressure and do work; cold source media discharged by the expansion machine 3 sequentially flow through the low-temperature heat exchanger 7 and the heat regenerator 9 and gradually absorb heat, and then enter the second expansion machine 4 to reduce pressure and do work and discharge the cold source media outwards; the low-temperature heat medium provides a driving heat load and a heating heat load through the low-temperature heat exchanger 7, the high-temperature heat medium provides a driving heat load through the high-temperature heat exchanger 6, the heated medium obtains a medium-temperature heat load through the heat supplier 5, the cold source medium takes away the low-temperature heat load through an inlet-outlet flow, and work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power, so that a third type of thermally driven compression heat pump is formed.
The third type of thermally driven compression heat pump shown in fig. 23 is realized by:
(1) structurally, the heat recovery system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a low-temperature heat medium channel which is communicated with the second expander 4 through a heat regenerator 9, the second expander 4 is also provided with a low-temperature heat medium channel which is communicated with the compressor 1 through a cooler 8, the compressor 1 is also provided with a low-temperature heat medium channel which is communicated with the second compressor 2 through a heat supplier 5 and the heat regenerator 9, the second compressor 2 is also provided with a low-temperature heat medium channel which is communicated with the expander 3 through a high-temperature heat exchanger 6, the expander 3 is also provided with a low-temperature heat medium channel which is communicated with the external part, the heat supplier 5 is also communicated with the external part through a heated medium channel, the high-temperature heat exchanger 6 is also provided with a high-temperature heat medium channel which is communicated with the external part, the cooler 8 is also provided with a cooling medium channel which is communicated with the external part, and the.
(2) In the process, the low-temperature heat medium flows through the heat regenerator 9 and absorbs heat, and then enters the second expander 4 to reduce the pressure and do work; the low-temperature heat medium discharged by the second expander 4 flows through the cooler 8 and releases heat, and then enters the compressor 1 to be boosted and heated; the low-temperature heat medium discharged by the compressor 1 flows through the heat supplier 5 and the heat regenerator 9 in sequence and releases heat gradually, and then enters the second compressor 2 to increase the pressure and the temperature; the low-temperature heat medium discharged by the second compressor 2 flows through the high-temperature heat exchanger 6 and absorbs heat, and then enters the expander 3 to reduce pressure and do work and is discharged outwards; the low-temperature heat medium provides a driving heat load and a heating heat load through an inlet and outlet flow, the high-temperature heat medium provides the driving heat load through the high-temperature heat exchanger 6, the medium to be heated obtains the medium-temperature heat load through the heat supplier 5, the low-temperature heat load is taken away by the cooling medium through the cooler 8, and the work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power, so that a third type of heat driving compression heat pump is formed.
The third type of thermally driven compression heat pump shown in fig. 24 is realized by:
(1) structurally, the heat recovery system mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a low-temperature heat exchanger, a cooler and a heat regenerator; a heat source medium channel is arranged outside and communicated with the expander 3, the expander 3 is also communicated with the second expander 4 through a low-temperature heat exchanger 7 and a heat regenerator 9, the second expander 4 is also communicated with the compressor 1 through a cooler 8, the compressor 1 is also communicated with the second compressor 2 through a heat source medium channel 5 and a heat regenerator 9, the second compressor 2 is also communicated with the outside through a heat source medium channel, the heat source 5 is also communicated with the outside through a heated medium channel, the low-temperature heat exchanger 7 is also communicated with the outside through a low-temperature heat medium channel, the cooler 8 is also communicated with the outside through a cooling medium channel, and the expander 3 and the second expander 4 are connected with the compressor 1 and the second compressor 2 and transmit power.
(2) In the process, the heat source medium enters the expander 3 to perform decompression work, the heat source medium discharged by the expander 3 sequentially flows through the low-temperature heat exchanger 7 and the heat regenerator 9 to gradually absorb heat, and then enters the second expander 4 to perform decompression work; the heat source medium discharged by the second expander 4 flows through the cooler 8 and releases heat, and then enters the compressor 1 to be boosted and heated; the heat source medium discharged by the compressor 1 sequentially flows through the heat supplier 5 and the heat regenerator 9 and gradually releases heat, and then enters the second compressor 2 to be boosted, heated and discharged; the low-temperature heat medium provides a driving heat load and a heating heat load through the low-temperature heat exchanger 7, the heat source medium provides a driving heat load through an inlet flow and an outlet flow, the medium to be heated obtains a medium-temperature heat load through the heat supplier 5, the cooling medium brings the low-temperature heat load away through the cooler 8, and the work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power to form a third type of heat driving compression heat pump.
The third type of thermally driven compression heat pump shown in fig. 25 is realized by:
(1) structurally, the heat exchanger mainly comprises a compressor, a second compressor, an expander, a second expander, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a heated medium channel which is communicated with the second compressor 2 through a heat regenerator 9, the second compressor 2 is also provided with a heated medium channel which is communicated with an expander 3 through a high-temperature heat exchanger 6, the expander 3 is also communicated with a second expander 4 through a low-temperature heat exchanger 7 and the heat regenerator 9, the second expander 4 is also communicated with the compressor 1 through a heated medium channel 8, the compressor 1 is also communicated with the external part through the heated medium channel, the high-temperature heat exchanger 6 is also communicated with the external part through a high-temperature heat medium channel, the low-temperature heat exchanger 7 is also communicated with the external part through a low-temperature heat medium channel, the cooler 8 is also communicated with the external part through a cooling medium channel, and the expander 3 and the second expander 4 are connected with the compressor 1 and the second compressor 2 and transmit power.
(2) In the flow, the heated medium flows through the heat regenerator 9 and releases heat, and then enters the second compressor 2 to be boosted and heated; the heated medium discharged by the second compressor 2 flows through the high-temperature heat exchanger 6 and absorbs heat, and then enters the expander 3 to reduce the pressure and do work; the heated medium discharged by the expander 3 flows through the low-temperature heat exchanger 7 and the heat regenerator 9 in sequence, absorbs heat gradually, and then enters the second expander 4 to reduce the pressure and do work; the heated medium discharged from the second expander 4 flows through the cooler 8 and releases heat, and then enters the compressor 1 to be pressurized, heated and discharged; the low-temperature heat medium provides a driving heat load and a heating heat load through the low-temperature heat exchanger 7, the high-temperature heat medium provides a driving heat load through the high-temperature heat exchanger 6, the medium-temperature heat load is obtained by the heated medium through an inlet and outlet flow, the low-temperature heat load is taken away by the cooling medium through the cooler 8, and the work output by the expander 3 and the second expander 4 is provided for the compressor 1 and the second compressor 2 as power to form a third type of heat-driven compression heat pump.
Incidentally, when only the temperature difference (thermal energy) drive is employed, it is conceivable to provide a starter motor in a third type of thermally driven compression heat pump for the convenience of starting.
The effect that the technology of the invention can realize-the multidirectional thermodynamic cycle and third type heat driving compression heat pump proposed by the invention have the following effects and advantages:
(1) provides a new idea and a new technology for utilizing the temperature difference.
(2) The heat energy (temperature difference) is driven to realize the temperature increase of the heat energy, or the heat energy and the temperature can be selected to provide power for the outside at the same time.
(3) The flow is reasonable, and the full and efficient utilization of the two types of temperature difference can be realized.
(4) When necessary, the heat energy temperature is increased by means of external power, the mode is flexible, and the adaptability is good.
(5) The compressor, the expander and the heat exchanger are used as components of the compression heat pump, and the structure is simple.
(6) The working medium has wide application range, can well adapt to heat supply requirements, and is flexibly matched with working parameters.
(7) A plurality of specific technical schemes are provided, so that the method can cope with a plurality of different actual conditions and has a wider application range.
(8) The heat pump technology is expanded, the types of compression heat pumps are enriched, and the high-efficiency utilization of heat energy is better realized.

Claims (27)

1. The multidirectional thermodynamic cycle is a closed process 123456781 which is formed by eight processes which are sequentially carried out among a high-temperature heat source, a medium-temperature heat source, a low-temperature heat source and a sub-low-temperature heat source, namely a pressure increasing process 12 of a working medium starting from a sub-low temperature, a heat releasing process 23 to the medium-temperature heat source, a pressure increasing process 34 starting from the medium temperature, a heat absorbing process 45 from the high-temperature heat source, a pressure reducing process 56 starting from the medium temperature, a heat absorbing process 67 from the low-temperature heat source, a pressure reducing process 78 starting from the low temperature and a heat releasing process 81 to the sub.
2. The multidirectional thermodynamic cycle is a non-closed process 12345678 which works among a high-temperature heat source, a medium-temperature heat source, a low-temperature heat source and a sub-low-temperature heat source and is composed of seven processes, namely a pressure increasing process 12 of a cold source medium starting from a sub-low temperature, a heat releasing process 23 to the medium-temperature heat source, a pressure increasing process 34 starting from a medium temperature, a heat absorbing process 45 from the high-temperature heat source, a pressure reducing process 56 starting from a high temperature, a heat absorbing process 67 from the low-temperature heat source and a pressure reducing process 78 starting from a low temperature, which are.
3. The multidirectional thermodynamic cycle is a non-closed process 12345678 which works among a high-temperature heat source, a medium-temperature heat source, a low-temperature heat source and a sub-low-temperature heat source and is formed by seven processes, namely a low-temperature heat source medium descending process 12 from low temperature, a heat releasing process 23 to the sub-low-temperature heat source, a pressure increasing process 34 from sub-low temperature, a heat releasing process 45 to the medium-temperature heat source, a pressure increasing process 56 from medium temperature, a high-temperature heat source heat absorbing process 67 and a high-temperature pressure reducing process 78.
4. The multidirectional thermodynamic cycle is a non-closed process 12345678 which works among a high-temperature heat source, a medium-temperature heat source, a low-temperature heat source and a sub-low-temperature heat source and is composed of seven processes sequentially performed, namely a pressure reduction process 12 of a heat source medium from high temperature, a heat absorption process 23 of the low-temperature heat source, a pressure reduction process 34 from low temperature, a heat release process 45 of the sub-low-temperature heat source, a pressure increase process 56 from sub-low temperature, a heat release process 67 of the medium-temperature heat source and a pressure increase process 78 from medium temperature.
5. The multidirectional thermodynamic cycle is a non-closed process 12345678 which works among a high-temperature heat source, a medium-temperature heat source, a low-temperature heat source and a sub-low-temperature heat source and is composed of seven processes sequentially performed, namely a pressure increasing process 12 of a heated medium from the medium temperature, a heat absorbing process 23 of the high-temperature heat source, a pressure reducing process 34 of the high temperature, a heat absorbing process 45 of the low-temperature heat source, a pressure reducing process 56 of the low temperature, a heat releasing process 67 of the sub-low-temperature heat source and a pressure increasing process 78 of the sub-low temperature.
6. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger and a cooler; the compressor (1) is provided with a circulating working medium channel which is communicated with the second compressor (2) through a heat supplier (5), the second compressor (2) is also provided with a circulating working medium channel which is communicated with the expander (3) through a high-temperature heat exchanger (6), the expander (3) is also provided with a circulating working medium channel which is communicated with the second expander (4) through a low-temperature heat exchanger (7), the second expander (4) is also provided with a circulating working medium channel which is communicated with the compressor (1) through a cooler (8), the heat supplier (5) is also provided with a heated medium channel which is communicated with the outside, the high-temperature heat exchanger (6) is also provided with a high-temperature heat medium channel which is communicated with the outside, the low-temperature heat exchanger (7) is also provided with a low-temperature heat medium channel which is communicated with the outside, the cooler (8) is also provided with a cooling medium channel which is communicated with the outside, and the expander (3) and the second expander, forming a third type of thermally driven compression heat pump.
7. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger and a low-temperature heat exchanger; the external part is provided with a cold source medium channel communicated with the compressor (1), the compressor (1) is also provided with a cold source medium channel communicated with the second compressor (2) through a heat supplier (5), the second compressor (2) is also provided with a cold source medium channel communicated with the expander (3) through a high-temperature heat exchanger (6), the expander (3) is also provided with a cold source medium channel communicated with the second expander (4) through a low-temperature heat exchanger (7), the second expander (4) is also provided with a cold source medium channel communicated with the external part, the heat supplier (5) is also provided with a heated medium channel communicated with the external part, the high-temperature heat exchanger (6) is also provided with a high-temperature heat medium channel communicated with the external part, the low-temperature heat exchanger (7) is also provided with a low-temperature heat medium channel communicated with the external part, and the expander (3) and the second expander (4) are connected with the compressor (1) and the second compressor (2) and transmit.
8. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a high-temperature heat exchanger and a cooler; the external part is provided with a low-temperature heat medium channel communicated with a second expander (4), the second expander (4) is also provided with a low-temperature heat medium channel communicated with a compressor (1) through a cooler (8), the compressor (1) is also provided with a low-temperature heat medium channel communicated with a second compressor (2) through a heat supplier (5), the second compressor (2) is also provided with a low-temperature heat medium channel communicated with an expander (3) through a high-temperature heat exchanger (6), the expander (3) is also provided with a low-temperature heat medium channel communicated with the external part, the heat supplier (5) is also provided with a heated medium channel communicated with the external part, the high-temperature heat exchanger (6) is also provided with a high-temperature heat medium channel communicated with the external part, the cooler (8) is also provided with a cooling medium channel communicated with the external part, and the expander (3) and the second expander (4) are connected with the compressor (1) and the second compressor (2) and transmit power, so that.
9. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a low-temperature heat exchanger and a cooler; the external part is provided with a heat source medium channel communicated with the expander (3), the expander (3) is also provided with a heat source medium channel communicated with the second expander (4) through a low-temperature heat exchanger (7), the second expander (4) is also provided with a heat source medium channel communicated with the compressor (1) through a cooler (8), the compressor (1) is also provided with a heat source medium channel communicated with the second compressor (2) through a heater (5), the second compressor (2) is also provided with a heat source medium channel communicated with the external part, the heater (5) is also provided with a heated medium channel communicated with the external part, the low-temperature heat exchanger (7) is also provided with a low-temperature heat medium channel communicated with the external part, the cooler (8) is also provided with a cooling medium channel communicated with the external part, and the expander (3) and the second expander (4) are connected with the compressor (1) and the second compressor (2) and transmit power, so that a third type of thermal compression driving.
10. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a high-temperature heat exchanger, a low-temperature heat exchanger and a cooler; the external part is provided with a heated medium channel which is communicated with the second compressor (2), the second compressor (2) is also provided with a heated medium channel which is communicated with the expander (3) through a high-temperature heat exchanger (6), the expander (3) is also provided with a heated medium channel which is communicated with the second expander (4) through a low-temperature heat exchanger (7), the second expander (4) is also provided with a heated medium channel which is communicated with the compressor (1) through a cooler (8), the compressor (1) is also provided with a heated medium channel which is communicated with the external part, the high-temperature heat exchanger (6) is also provided with a high-temperature heat medium channel which is communicated with the external part, the low-temperature heat exchanger (7) is also provided with a low-temperature heat medium channel which is communicated with the external part, the cooler (8) is also provided with a cooling medium channel which is communicated with the external part, and the expander (3) and the second expander (4, forming a third type of thermally driven compression heat pump.
11. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the compressor (1) is provided with a circulating working medium channel which is communicated with the second compressor (2) through a heat regenerator (9) and a heat supplier (5), the second compressor (2) is also provided with a circulating working medium channel which is communicated with the expander (3) through the heat regenerator (9) and a high-temperature heat exchanger (6), the expander (3) is also provided with a circulating working medium channel which is communicated with the second expander (4) through a low-temperature heat exchanger (7), the second expander (4) is also provided with a circulating working medium channel which is communicated with the compressor (1) through a cooler (8), the heat supplier (5) is also provided with a heated medium channel which is communicated with the outside, the high-temperature heat exchanger (6) is also provided with a high-temperature heat medium channel which is communicated with the outside, the low-temperature heat exchanger (7) is also provided with a low-temperature heat medium channel which is communicated with the outside, the cooler (8) is also provided with the outside, the expander (3) and the second expander (4) are connected with the compressor, forming a third type of thermally driven compression heat pump.
12. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger and a heat regenerator; the external part is provided with a cold source medium channel communicated with the compressor (1), the compressor (1) is also provided with a cold source medium channel communicated with the second compressor (2) through a heat regenerator (9) and a heat supplier (5), the second compressor (2) is also provided with a cold source medium channel communicated with an expander (3) through the heat regenerator (9) and a high-temperature heat exchanger (6), the expander (3) is also provided with a cold source medium channel communicated with the second expander (4) through a low-temperature heat exchanger (7), the second expander (4) is also provided with a cold source medium channel communicated with the external part, the heat supplier (5) is also provided with a heated medium channel communicated with the external part, the high-temperature heat exchanger (6) is also provided with a high-temperature heat medium channel communicated with the external part, the low-temperature heat exchanger (7) is also provided with the low-temperature heat medium channel communicated with the external part, the expander (3) and the second expander (4) are connected with the compressor, forming a third type of thermally driven compression heat pump.
13. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a high-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a low-temperature heat medium channel which is communicated with a second expander (4), the second expander (4) is also provided with a low-temperature heat medium channel which is communicated with a compressor (1) through a cooler (8), the compressor (1) is also provided with a low-temperature heat medium channel which is communicated with a second compressor (2) through a regenerator (9) and a heater (5), the second compressor (2) is also provided with a low-temperature heat medium channel which is communicated with an expander (3) through the regenerator (9) and a high-temperature heat exchanger (6), the expander (3) is also provided with a low-temperature heat medium channel which is communicated with the external part, the heater (5) is also provided with a heated medium channel which is communicated with the external part, the high-temperature heat exchanger (6) is also provided with a high-temperature heat medium channel which is communicated with the external part, the cooler (8) is also provided with a cooling medium channel which is communicated with the external part, the expander (3) and the second expander, forming a third type of thermally driven compression heat pump.
14. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a low-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a heat source medium channel which is communicated with the expander (3), the expander (3) is also provided with a heat source medium channel which is communicated with the second expander (4) through a low-temperature heat exchanger (7), the second expander (4) is also provided with a heat source medium channel which is communicated with the compressor (1) through a cooler (8), the compressor (1) is also provided with a heat source medium channel which is communicated with the second compressor (2) through a regenerator (9) and a heater (5), the second compressor (2) is also provided with a heat source medium channel which is communicated with the external part through a regenerator (9), the heater (5) is also provided with a heated medium channel which is communicated with the external part, the low-temperature heat exchanger (7) is also provided with a low-temperature heat medium channel which is communicated with the external part, the cooler (8) is also provided with a cooling medium channel which is communicated with the external part, the expander (3) and the second expander (4) are connected with, forming a third type of thermally driven compression heat pump.
15. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the exterior of the compressor is provided with a heated medium channel communicated with the second compressor (2), the second compressor (2) is also provided with a heated medium channel communicated with the expander (3) through a regenerator (9) and a high-temperature heat exchanger (6), the expander (3) is also provided with a heated medium channel communicated with the second expander (4) through a low-temperature heat exchanger (7), the second expander (4) is also provided with a heated medium channel communicated with the compressor (1) through a cooler (8), the compressor (1) is also provided with a heated medium channel communicated with the exterior through the regenerator (9), the high-temperature heat exchanger (6) is also provided with a high-temperature heat medium channel communicated with the exterior, the low-temperature heat exchanger (7) is also provided with a low-temperature heat medium channel communicated with the exterior, the cooler (8) is also provided with a cooling medium channel communicated with the exterior, the expander (3) and the second expander (4) are connected with the compressor (1) and the second compressor (2) and transmit power, forming a third type of thermally driven compression heat pump.
16. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the compressor (1) is provided with a circulating working medium channel which is communicated with the second compressor (2) through a heat supplier (5), the second compressor (2) is also provided with a circulating working medium channel which is communicated with the expander (3) through a high-temperature heat exchanger (6), the expander (3) is also provided with a circulating working medium channel which is communicated with the second expander (4) through a heat regenerator (9) and a low-temperature heat exchanger (7), the second expander (4) is also provided with a circulating working medium channel which is communicated with the compressor (1) through the heat regenerator (9) and a cooler (8), the heat supplier (5) is also provided with a heated medium channel which is communicated with the outside, the high-temperature heat exchanger (6) is also provided with a high-temperature heat medium channel which is communicated with the outside, the low-temperature heat exchanger (7) is also communicated with the outside, the cooler (8) is also provided with the outside, the expander (3) and the second expander (4) are connected with the compressor (1) and the second compressor (2), forming a third type of thermally driven compression heat pump.
17. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a high-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a cold source medium channel communicated with the compressor (1), the compressor (1) is also provided with a cold source medium channel communicated with the second compressor (2) through a heat supplier (5), the second compressor (2) is also provided with a cold source medium channel communicated with the expander (3) through a high-temperature heat exchanger (6), the expander (3) is also provided with a cold source medium channel communicated with the second expander (4) through a heat regenerator (9) and a low-temperature heat exchanger (7), the second expander (4) is also provided with a cold source medium channel communicated with the external part through the heat regenerator (9), the heat supplier (5) is also provided with a heated medium channel communicated with the external part, the high-temperature heat exchanger (6) is also provided with a high-temperature heat medium channel communicated with the external part, the low-temperature heat exchanger (7) is also provided with the external part through a low-temperature heat medium channel, the expander (3) and the second expander (4) are connected with the compressor (1), forming a third type of thermally driven compression heat pump.
18. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a high-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a low-temperature heat medium channel communicated with a second expander (4), the second expander (4) is also provided with a low-temperature heat medium channel communicated with a compressor (1) through a heat regenerator (9) and a cooler (8), the compressor (1) is also provided with a low-temperature heat medium channel communicated with a second compressor (2) through a heat supplier (5), the second compressor (2) is also provided with a low-temperature heat medium channel communicated with an expander (3) through a high-temperature heat exchanger (6), the expander (3) is also provided with a low-temperature heat medium channel communicated with the external part through the heat regenerator (9), the heat supplier (5) is also provided with a heated medium channel communicated with the external part, the high-temperature heat exchanger (6) is also provided with a high-temperature heat medium channel communicated with the external part, the cooler (8) is also provided with the external part, the expander (3) and the second expander (4) are connected with the compressor (1) and the second compressor (2) and, forming a third type of thermally driven compression heat pump.
19. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a low-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a heat source medium channel which is communicated with the expander (3), the expander (3) is also provided with a heat source medium channel which is communicated with the second expander (4) through a heat regenerator (9) and a low-temperature heat exchanger (7), the second expander (4) is also provided with a heat source medium channel which is communicated with the compressor (1) through the heat regenerator (9) and a cooler (8), the compressor (1) is also provided with a heat source medium channel which is communicated with the second compressor (2) through a heat supplier (5), the second compressor (2) is also provided with a heat source medium channel which is communicated with the external part, the heat supplier (5) is also provided with a heated medium channel which is communicated with the external part, the low-temperature heat exchanger (7) is also provided with a low-temperature heat medium channel which is communicated with the external part, the cooler (8) is also provided with a cooling medium channel which is communicated with the external part, the expander (3) and the second expander (, forming a third type of thermally driven compression heat pump.
20. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the exterior is provided with a heated medium channel which is communicated with the second compressor (2), the second compressor (2) is also provided with a heated medium channel which is communicated with the expander (3) through a high-temperature heat exchanger (6), the expander (3) is also provided with a heated medium channel which is communicated with the second expander (4) through a regenerator (9) and a low-temperature heat exchanger (7), the second expander (4) is also provided with a heated medium channel which is communicated with the compressor (1) through the regenerator (9) and a cooler (8), the compressor (1) is also provided with a heated medium channel which is communicated with the exterior, the high-temperature heat exchanger (6) is also provided with a high-temperature heat medium channel which is communicated with the exterior, the low-temperature heat exchanger (7) is also provided with a low-temperature heat medium channel which is communicated with the exterior, the cooler (8) is also provided with a cooling medium channel which is communicated with the exterior, the expander (3) and the second expander (4) are connected with the compressor, forming a third type of thermally driven compression heat pump.
21. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the compressor (1) is provided with a circulating working medium channel which is communicated with the second compressor (2) through a heat supplier (5) and a heat regenerator (9), the second compressor (2) is also provided with a circulating working medium channel which is communicated with the expander (3) through a high-temperature heat exchanger (6), the expander (3) is also provided with a circulating working medium channel which is communicated with the second expander (4) through a low-temperature heat exchanger (7) and a heat regenerator (9), the second expander (4) is also provided with a circulating working medium channel which is communicated with the compressor (1) through a cooler (8), the heat supplier (5) is also provided with a heated medium channel which is communicated with the outside, the high-temperature heat exchanger (6) is also provided with a high-temperature heat medium channel which is communicated with the outside, the low-temperature heat exchanger (7) is also provided with a low-temperature heat medium channel which is communicated with the outside, the cooler (8) is also provided with the outside, the expander (3) and the second expander (4) are connected with the, forming a third type of thermally driven compression heat pump.
22. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supplier, a high-temperature heat exchanger, a low-temperature heat exchanger and a heat regenerator; the external part is provided with a cold source medium channel communicated with the compressor (1), the compressor (1) is also provided with a cold source medium channel communicated with the second compressor (2) through a heat supplier (5) and a heat regenerator (9), the second compressor (2) is also provided with a cold source medium channel communicated with the expander (3) through a high temperature heat exchanger (6), the expander (3) is also provided with a cold source medium channel communicated with the second expander (4) through a low temperature heat exchanger (7) and a heat regenerator (9), the second expander (4) is also provided with a cold source medium channel communicated with the external part, the heat supplier (5) is also provided with a heated medium channel communicated with the external part, the high temperature heat exchanger (6) is also provided with a high temperature heat medium channel communicated with the external part, the low temperature heat exchanger (7) is also provided with a low temperature heat medium channel communicated with the external part, the expander (3) and the second expander (4) are connected with the compressor (1) and the second, forming a third type of thermally driven compression heat pump.
23. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a high-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a low-temperature heat medium channel which is communicated with a second expander (4) through a heat regenerator (9), the second expander (4) is also provided with a low-temperature heat medium channel which is communicated with a compressor (1) through a cooler (8), the compressor (1) is also provided with a low-temperature heat medium channel which is communicated with a second compressor (2) through a heat supplier (5) and the heat regenerator (9), the second compressor (2) is also provided with a low-temperature heat medium channel which is communicated with an expander (3) through a high-temperature heat exchanger (6), the expander (3) is also provided with a low-temperature heat medium channel which is communicated with the external part, the heat supplier (5) is also provided with a heated medium channel which is communicated with the external part, the high-temperature heat exchanger (6) is also provided with a high-temperature heat medium channel which is communicated with the external part, the cooler (8) is also provided with a cooling medium channel which is communicated with the external part, the expander (3), forming a third type of thermally driven compression heat pump.
24. The third kind of heat-driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a heat supply device, a low-temperature heat exchanger, a cooler and a heat regenerator; the external part is provided with a heat source medium channel which is communicated with an expander (3), the expander (3) is also provided with a heat source medium channel which is communicated with a second expander (4) through a low-temperature heat exchanger (7) and a heat regenerator (9), the second expander (4) is also provided with a heat source medium channel which is communicated with a compressor (1) through a cooler (8), the compressor (1) is also provided with a heat source medium channel which is communicated with a second compressor (2) through a heat supplier (5) and the heat regenerator (9), the second compressor (2) is also provided with a heat source medium channel which is communicated with the external part, the heat supplier (5) is also provided with a heated medium channel which is communicated with the external part, the low-temperature heat exchanger (7) is also provided with a low-temperature heat medium channel which is communicated with the external part, the cooler (8) is also provided with a cooling medium channel which is communicated with the external part, the expander (3) and the second expander (, forming a third type of thermally driven compression heat pump.
25. The third kind of thermally driven compression heat pump mainly comprises a compressor, a second compressor, an expander, a second expander, a high-temperature heat exchanger, a low-temperature heat exchanger, a cooler and a heat regenerator; the exterior of the compressor is provided with a heated medium channel which is communicated with the second compressor (2) through a heat regenerator (9), the second compressor (2) is also provided with a heated medium channel which is communicated with an expander (3) through a high-temperature heat exchanger (6), the expander (3) is also provided with a heated medium channel which is communicated with the second expander (4) through a low-temperature heat exchanger (7) and the heat regenerator (9), the second expander (4) is also provided with a heated medium channel which is communicated with the compressor (1) through a cooler (8), the compressor (1) is also provided with a heated medium channel which is communicated with the exterior, the high-temperature heat exchanger (6) is also provided with a high-temperature heat medium channel which is communicated with the exterior, the low-temperature heat exchanger (7) is also provided with a low-temperature heat medium channel which is communicated with the exterior, the cooler (8) is also provided with a cooling medium channel which is communicated with the exterior, the expander (3) and the second expander (4), forming a third type of thermally driven compression heat pump.
26. A third type of thermally driven compression heat pump, which is the third type of thermally driven compression heat pump according to any one of claims 6 to 25, wherein a power machine is added, the power machine is connected with the compressor (1) and provides power for the compressor (1), and the third type of thermally driven compression heat pump driven by additional external power is formed.
27. A third type of thermally driven compression heat pump according to any one of claims 6 to 25, wherein a working machine is added, and the expansion machine (3) is connected to the working machine and supplies power to the working machine, thereby forming a third type of thermally driven compression heat pump which additionally supplies a load for supplying power to the outside.
CN201610244078.7A 2015-04-13 2016-04-11 Multidirectional thermodynamic cycle and third-class thermally-driven compression heat pump Active CN105890216B (en)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
CN201510185170 2015-04-13
CN2015101851706 2015-04-13

Publications (2)

Publication Number Publication Date
CN105890216A CN105890216A (en) 2016-08-24
CN105890216B true CN105890216B (en) 2020-06-16

Family

ID=56704954

Family Applications (1)

Application Number Title Priority Date Filing Date
CN201610244078.7A Active CN105890216B (en) 2015-04-13 2016-04-11 Multidirectional thermodynamic cycle and third-class thermally-driven compression heat pump

Country Status (1)

Country Link
CN (1) CN105890216B (en)

Families Citing this family (30)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN108120048B (en) * 2016-11-24 2020-01-31 李华玉 class thermally driven compression heat pump
CN108106053B (en) * 2016-11-24 2020-01-31 李华玉 class thermally driven compression heat pump
CN109059350B (en) * 2018-06-19 2021-02-05 李华玉 Third-class thermally-driven compression heat pump
CN111721022B (en) * 2019-01-02 2023-08-29 李华玉 First-class thermally driven compression heat pump
CN111721024B (en) * 2019-01-07 2023-04-25 李华玉 Second type heat driven compression heat pump
CN111306840A (en) * 2019-02-15 2020-06-19 李华玉 Multidirectional thermodynamic cycle
CN111380247A (en) * 2019-02-17 2020-07-07 李华玉 Third-class thermally-driven compression heat pump
CN111578550A (en) * 2019-03-11 2020-08-25 李华玉 Fourth-class thermally-driven compression heat pump
CN111365878A (en) * 2019-03-11 2020-07-03 李华玉 Fourth-class thermally-driven compression heat pump
CN111365877A (en) * 2019-03-11 2020-07-03 李华玉 Fourth-class thermally-driven compression heat pump
CN111365888A (en) * 2019-03-11 2020-07-03 李华玉 Fourth-class thermally-driven compression heat pump
CN111536709A (en) * 2019-03-19 2020-08-14 李华玉 Fourth-class thermally-driven compression heat pump
CN111365882A (en) * 2019-03-19 2020-07-03 李华玉 Fourth-class thermally-driven compression heat pump
CN111536710A (en) * 2019-03-19 2020-08-14 李华玉 Fourth-class thermally-driven compression heat pump
CN111365883A (en) * 2019-03-19 2020-07-03 李华玉 Fourth-class thermally-driven compression heat pump
CN111442556A (en) * 2019-03-19 2020-07-24 李华玉 Fourth-class thermally-driven compression heat pump
CN111365890A (en) * 2019-03-22 2020-07-03 李华玉 Fourth-class thermally-driven compression heat pump
CN111365891A (en) * 2019-03-22 2020-07-03 李华玉 Fourth-class thermally-driven compression heat pump
CN111442555A (en) * 2019-03-22 2020-07-24 李华玉 Fourth-class thermally-driven compression heat pump
CN111365885A (en) * 2019-03-24 2020-07-03 李华玉 Fourth-class thermally-driven compression heat pump
CN111365884A (en) * 2019-03-24 2020-07-03 李华玉 Fourth-class thermally-driven compression heat pump
CN111503916A (en) * 2019-03-26 2020-08-07 李华玉 Fourth-class thermally-driven compression heat pump
CN111750559A (en) * 2019-03-26 2020-10-09 李华玉 Fourth-class thermally-driven compression heat pump
CN111750560A (en) * 2019-03-26 2020-10-09 李华玉 Fourth-class thermally-driven compression heat pump
CN111503917A (en) * 2019-03-26 2020-08-07 李华玉 Fourth-class thermally-driven compression heat pump
CN111536714A (en) * 2019-03-26 2020-08-14 李华玉 Fourth-class thermally-driven compression heat pump
CN111503919A (en) * 2019-04-09 2020-08-07 李华玉 Third-class thermally-driven compression heat pump
CN111503918A (en) * 2019-04-09 2020-08-07 李华玉 Third-class thermally-driven compression heat pump
CN110631273A (en) * 2019-08-24 2019-12-31 李华玉 Multidirectional thermodynamic cycle of the first kind
CN113108496A (en) * 2020-04-09 2021-07-13 李华玉 Third-class thermally-driven compression heat pump

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN1081757A (en) * 1992-07-31 1994-02-09 李华聪 A kind of open-type compression refrigerating apparatus
US6301923B1 (en) * 2000-05-01 2001-10-16 Praxair Technology, Inc. Method for generating a cold gas
CN1453528A (en) * 2003-05-27 2003-11-05 西安交通大学 Refrigerating method and refrigerator based on hydroscopic expanding air and absorbing lithium bromide
CN1952529A (en) * 2005-10-19 2007-04-25 周凌云 Refrigeration apparatus and its operation method
CN101504205A (en) * 2009-02-26 2009-08-12 李华玉 Segmented compression-segmented heat supply-segmented expansion gas compression type units

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN1081757A (en) * 1992-07-31 1994-02-09 李华聪 A kind of open-type compression refrigerating apparatus
US6301923B1 (en) * 2000-05-01 2001-10-16 Praxair Technology, Inc. Method for generating a cold gas
CN1453528A (en) * 2003-05-27 2003-11-05 西安交通大学 Refrigerating method and refrigerator based on hydroscopic expanding air and absorbing lithium bromide
CN1952529A (en) * 2005-10-19 2007-04-25 周凌云 Refrigeration apparatus and its operation method
CN101504205A (en) * 2009-02-26 2009-08-12 李华玉 Segmented compression-segmented heat supply-segmented expansion gas compression type units

Also Published As

Publication number Publication date
CN105890216A (en) 2016-08-24

Similar Documents

Publication Publication Date Title
CN105890216B (en) Multidirectional thermodynamic cycle and third-class thermally-driven compression heat pump
CN105805973B (en) Multidirectional thermodynamic cycle and third-class thermally-driven compression heat pump
CN106016804B (en) Multidirectional thermodynamic cycle and third-class thermally-driven compression heat pump
CN105953452B (en) Multidirectional thermodynamic cycle and third-class thermally-driven compression heat pump
CN105953472B (en) Bidirectional thermodynamic cycle and second-class thermally-driven compression heat pump
CN105953473B (en) Bidirectional thermodynamic cycle and second-class thermally-driven compression heat pump
CN105865067B (en) Open type bidirectional thermodynamic cycle and second-class heat driving compression heat pump
CN105910334B (en) Open type bidirectional thermodynamic cycle and first-class heat-driven compression heat pump
CN108679880B (en) Double-working medium combined cycle compression heat pump
CN105953454B (en) Bidirectional thermodynamic cycle and first-class thermally-driven compression heat pump
CN105865068B (en) Open type bidirectional thermodynamic cycle and second-class heat driving compression heat pump
CN105910332B (en) Open type bidirectional thermodynamic cycle and first-class heat-driven compression heat pump
CN105841381B (en) Open type bidirectional thermodynamic cycle and second-class heat driving compression heat pump
CN105910324B (en) Open type bidirectional thermodynamic cycle and second-class heat driving compression heat pump
CN105928248B (en) Open type bidirectional thermodynamic cycle and second-class heat driving compression heat pump
CN106440511B (en) First-class thermally-driven compression heat pump
CN106225314B (en) Third-class thermally-driven compression heat pump
CN106225282B (en) First-class thermally-driven compression heat pump
CN106352578B (en) First-class thermally-driven compression heat pump
CN106352601B (en) Third-class thermally-driven compression heat pump
CN106225317B (en) Third-class thermally-driven compression heat pump
CN108120048B (en) class thermally driven compression heat pump
CN105910331B (en) Open type bidirectional thermodynamic cycle and second-class heat driving compression heat pump
CN106225316B (en) Third-class thermally-driven compression heat pump
CN106225322B (en) Third-class thermally-driven compression heat pump

Legal Events

Date Code Title Description
C06 Publication
PB01 Publication
SE01 Entry into force of request for substantive examination
SE01 Entry into force of request for substantive examination
GR01 Patent grant
GR01 Patent grant