CN111608758A - Single working medium steam combined cycle - Google Patents

Abstract

The invention provides a single working medium steam combined cycle, and belongs to the technical field of energy and power. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Ten processes carried out separately or together-M₁Step-up process of working medium kilogram 12, M₁Heat absorption and vaporization process 23, M of kilogram working medium₁Decompression process 34, M of kilogram working medium₁45, M kilogram working medium heat absorption process₂Boosting process of 85, M for kilogram working medium₃56, M kilogram working medium heat absorption process₃Decompression process with kilogram working medium 67, M₃78, M, kilogram working medium heat release process₁Decompression process 89, M with kilogram working medium₁Kilogram working medium heat release condensation process 91-a closed process of composition; wherein M is₃Is M₁And M₂And (4) summing.

Description

Single working medium steam combined cycle

The technical field is as follows:

the invention belongs to the technical field of energy and power.

Background art:

cold demand, heat demand and power demand, which are common in human life and production; among them, the conversion of thermal energy into mechanical energy is an important way to obtain and provide power. Generally, the temperature of the heat source decreases with the release of heat, and the heat source is variable in temperature; when fossil fuel is used as source energy, the heat source has the dual characteristics of high temperature and variable temperature, so that the utilization rate of energy is not ideal when refrigeration, heat supply or conversion into power is realized by adopting a single thermodynamic cycle theory.

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

People need to simply, actively and efficiently utilize fuel generation or other high-temperature heat energy to realize refrigeration, heat supply or power conversion, which needs support of a thermal science basic theory; in a thermal science basic theory system, thermodynamic cycle is the core of the theoretical basis of a heat energy utilization device and an energy utilization system; the creation and development application of thermodynamic cycle will play a significant role in the leap of energy utilization, and will actively push social progress and productivity development.

The invention provides a single-working-medium steam combined cycle, which aims to provide theoretical support for simplification and high efficiency of a thermodynamic system aiming at the power application of a high-temperature heat source or a variable-temperature heat source from the principle of simply, actively and efficiently realizing temperature difference utilization.

The invention content is as follows:

the invention mainly aims to provide a single-working-medium steam combined cycle, and the specific invention contents are explained in terms as follows:

1. single working medium steam combined cycle, is formed from M₁Kilogram and M₂Ten processes carried out separately or together-M₁Step-up process of working medium kilogram 12, M₁Heat absorption and vaporization process 23, M of kilogram working medium₁Decompression process 34, M of kilogram working medium₁45, M kilogram working medium heat absorption process₂Boosting process of 85, M for kilogram working medium₃56, M kilogram working medium heat absorption process₃Decompression process with kilogram working medium 67, M₃78, M, kilogram working medium heat release process₁Decompression process 89, M with kilogram working medium₁Kilogram working medium heat release condensation process 91-a closed process of composition; wherein M is₃Is M₁And M₂And (4) summing.

2. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilogram, eleven processes carried out separately or together-M₁Step-up process of working medium kilogram 12, M₁Heat absorption and vaporization process 23, M of kilogram working medium₁Decompression process 34, M of kilogram working medium₁45, M kilogram working medium heat absorption process₁Decompression process 57, M with kilogram working medium₂96, M kilogram working medium boosting process₂Kilogram working medium endothermic process 67, M₃Decompression process 78, M with kilogram working medium₃89, M kilogram working medium heat release process₁Decompression process of kilogram working medium 9c, M₁Kilogram working medium exothermal condensation process c 1-the closed process of component; wherein M is₃Is M₁And M₂And (4) summing.

3. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilogram, eleven processes carried out separately or together-M₁Step-up process of working medium kilogram 12, M₁Heat absorption and vaporization process 23, M of kilogram working medium₁Decompression process 34, M of kilogram working medium₁47, M kilogram working medium heat absorption process₂Step-up process of 95, M for kilogram working medium₂56, M kilogram working medium heat absorption process₂Decompression process with kilogram working medium 67, M₃Decompression process 78, M with kilogram working medium₃89, M kilogram working medium heat release process₁Decompression process of kilogram working medium 9c, M₁Kilogram working medium exothermal condensation process c 1-the closed process of component; wherein M is₃Is M₁And M₂And (4) summing.

4. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilograms of composition, twelve processes carried out separately or together-M₁Step-up process of working medium kilogram 12, M₁Heat absorption and vaporization process 23, M of kilogram working medium₁Decompression process 34, M of kilogram working medium₁Kilogram working medium absorbs heatProcess 45, M₁Decompression process 59, M with kilogram working medium₂Kilogram working medium boosting process c6, M₂Kilogram working medium endothermic process 67, M₂Decompression process 78, M with kilogram working medium₂89, M kilogram working medium heat release process₃Kilogram working medium heat release process 9c, M₁The blood pressure lowering process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-formed closing process; wherein M is₃Is M₁And M₂And (4) summing.

5. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilograms of composition, twelve processes carried out separately or together-M₁Step-up process of working medium kilogram 12, M₁Heat absorption and vaporization process 23, M of kilogram working medium₁Decompression process 34, M of kilogram working medium₁45, M kilogram working medium heat absorption process₁Decompression process 56, M of kilogram working medium₁Kilogram working medium heat release process 69, M₂Kilogram working medium boosting process c7, M₂78, M, kilogram working medium heat absorption process₂Decompression process 89, M with kilogram working medium₃Kilogram working medium heat release process 9c, M₁The blood pressure lowering process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-formed closing process; wherein M is₃Is M₁And M₂And (4) summing.

6. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working substances in kilogram composition, thirteen processes carried out individually or jointly or in part-M₁Step-up process of working medium kilogram 12, M₁Heat absorption and vaporization process 23, M of kilogram working medium₁Decompression process 34, M of kilogram working medium₁45, M kilogram working medium heat absorption process₂Kilogram working medium boosting process c5, M₃Kilogram working medium heat absorption process 56, X kilogram working medium pressure reduction process 69, (M)₃-X) kilogram working substance endotherm 67, (M)₃-X) decompression Process 78 with kg of working substance, (M)₃-X) kilogram working substance exothermic Process 89, M₃Kilogram working medium heat release process 9c, M₁The blood pressure lowering process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-formed closing process; wherein M is₃Is M₁And M₂And (4) summing.

7. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working substances in kilogram composition, thirteen processes carried out individually or jointly or in part-M₁Step-up process of working medium kilogram 12, M₁Kilogram working medium heat absorption process 2b, (M)₁+ M) kilogram working medium endothermic vaporization process b3, (M)₁+ M) kilogram working medium depressurization 34, (M)₁+ M) kilogram working medium endothermic process 45, M₂8a in kilogram working medium boosting process, ab in M kilogram working medium heat releasing condensation process, (M)₂M) kilogram working medium pressure rise process a5, M₃56, M kilogram working medium heat absorption process₃Decompression process with kilogram working medium 67, M₃78, M, kilogram working medium heat release process₁Decompression process 89, M with kilogram working medium₁Kilogram working medium heat release condensation process 91-a closed process of composition; wherein M is₃Is M₁And M₂And (4) summing.

8. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilograms of composition, fourteen processes carried out separately or together or partially-M₁Step-up process of working medium kilogram 12, M₁Kilogram working medium heat absorption process 2b, (M)₁+ M) kilogram working medium endothermic vaporization process b3, (M)₁+ M) kilogram depressurization Process 34, (M)₁+ M) kilogram endothermic Process 45, (M)₁+ M) kilogram working medium is reduced in pressure by 57, M₂Kilogram working medium boosting process 9a, M kilogram working medium heat release condensation process ab, (M)₂M) kilogram working medium pressure increasing process a6, (M)₂-M) kilogram working substance endothermic process 67, M₃Decompression process 78, M with kilogram working medium₃89, M kilogram working medium heat release process₁Decompression process of kilogram working medium 9c, M₁Kilogram working medium exothermal condensation process c 1-the closed process of component; wherein M is₃Is M₁And M₂And (4) summing.

9. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilograms of composition, fourteen processes carried out separately or together or partially-M₁Step-up process of working medium kilogram 12, M₁Kilogram working medium heat absorption process 2b, (M)₁+ M) kgWorking medium endothermic vaporization process b3, (M)₁+ M) kilogram depressurization Process 34, (M)₁+ M) kilogram endothermic Process 47, M₂Kilogram working medium boosting process 9a, M kilogram working medium heat release condensation process ab, (M)₂M) kilogram working medium pressure increasing process a5, (M)₂M) kilogram working medium endothermic Process 56, (M)₂-M) depressurization of 67, M) kg of working medium₃Decompression process 78, M with kilogram working medium₃89, M kilogram working medium heat release process₁Decompression process of kilogram working medium 9c, M₁Kilogram working medium exothermal condensation process c 1-the closed process of component; wherein M is₃Is M₁And M₂And (4) summing.

10. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilograms of composition, fifteen processes carried out separately or together or partially-M₁Step-up process of working medium kilogram 12, M₁Kilogram working medium heat absorption process 2b, (M)₁+ M) kilogram working medium endothermic vaporization process b3, (M)₁+ M) kilogram working medium depressurization 34, (M)₁+ M) kilogram working medium endothermic process 45, (M)₁+ M) kilogram working medium depressurization process 59, M₂Kilogram working medium boosting process ca, M kilogram working medium heat releasing condensation process ab, (M)₂M) kilogram working medium pressure increasing process a6, (M)₂-M) kilogram working substance endothermic process 67, (M)₂-M) kilogram working medium depressurization 78, (M)₂-M) kilogram working medium exothermic Process 89, M₃Kilogram working medium heat release process 9c, M₁The blood pressure lowering process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-formed closing process; wherein M is₃Is M₁And M₂And (4) summing.

11. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilograms of composition, fifteen processes carried out separately or together or partially-M₁Step-up process of working medium kilogram 12, M₁Kilogram working medium heat absorption process 2b, (M)₁+ M) kilogram working medium endothermic vaporization process b3, (M)₁+ M) kilogram working medium depressurization 34, (M)₁+ M) kilogram working medium endothermic process 45, (M)₁+ M) kilogram working medium depressurization 56 (M)₁+ M) kg of working medium exotherms 69,M₂kilogram working medium boosting process ca, M kilogram working medium heat releasing condensation process ab, (M)₂M) kilogram working medium pressure increasing process a7, (M)₂-M) kilogram working medium endothermic Process 78, (M)₂-M) decompression Process 89, M) with kg of working substance₃Kilogram working medium heat release process 9c, M₁The blood pressure lowering process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-formed closing process; wherein M is₃Is M₁And M₂And (4) summing.

12. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilograms of composition, sixteen processes carried out separately or together or in part-M₁Step-up process of working medium kilogram 12, M₁Kilogram working medium heat absorption process 2b, (M)₁+ M) kilogram working medium endothermic vaporization process b3, (M)₁+ M) kilogram working medium depressurization 34, (M)₁+ M) kilogram working medium endothermic process 45, M₂Kilogram working medium boosting process ca, M kilogram working medium heat releasing condensation process ab, (M)₂M) kilogram working medium pressure rise process a5, M₃Kilogram working medium heat absorption process 56, X kilogram working medium pressure reduction process 69, (M)₃-X) kilogram working substance endotherm 67, (M)₃-X) decompression Process 78 with kg of working substance, (M)₃-X) kilogram working substance exothermic Process 89, M₃Kilogram working medium heat release process 9c, M₁The blood pressure lowering process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-formed closing process; wherein M is₃Is M₁And M₂And (4) summing.

Description of the drawings:

FIG. 1 is an exemplary illustration of a 1 st principal flow scheme for a single-working-medium combined-steam cycle provided in accordance with the present invention.

FIG. 2 is an exemplary diagram of a 2 nd schematic flow diagram of a single-working-medium vapor combined cycle according to the present invention.

FIG. 3 is an exemplary diagram of a 3 rd principle flow of a single-working-medium vapor combined cycle according to the present invention.

FIG. 4 is a diagram illustrating an example of the 4 th principle flow of a single-working-medium vapor combined cycle according to the present invention.

FIG. 5 is an exemplary diagram of a5 th principle flow of a single-working-medium vapor combined cycle according to the present invention.

FIG. 6 is an exemplary diagram of a6 th principle flow of a single-working-medium vapor combined cycle according to the present invention.

FIG. 7 is a diagram illustrating an example of the 7 th principle flow of a single-working-medium vapor combined cycle according to the present invention.

FIG. 8 is an exemplary diagram of an 8 th principle flow of a single-working-medium combined steam cycle according to the present invention.

FIG. 9 is an exemplary diagram of a 9 th principle flow of a single-working-medium vapor combined cycle according to the present invention.

FIG. 10 is an exemplary diagram of a 10 th principle flow of a single-working-medium vapor combined cycle according to the present invention.

FIG. 11 is an exemplary 11 th principle flow of a single-working-medium combined-steam cycle according to the present invention.

FIG. 12 is a schematic diagram illustrating an exemplary 12 th principle flow of a single-working-medium vapor combined cycle according to the present invention.

The specific implementation mode is as follows:

it should be noted that, in terms of the expression of the structure and the flow, the description is not repeated if necessary, and the obvious flow is not expressed; in each of the following examples, M₃Is M₁And M₂Summing; the invention is described in detail below with reference to the figures and examples.

The single-working-medium steam combined cycle example in the T-s diagram of fig. 1 is performed as follows:

(1) from the cycle process:

working medium process-M₁Boosting process of kilogram working medium condensate 12, M₁Kilogram working medium heat absorption temperature rise, vaporization and overheating process 23, M₁Decompression expansion process 34, M of kilogram working medium₁45, M kilogram working medium heat absorption temperature rise process₂Boosting and heating process of 85, M for kilogram working medium₃56, M kilogram working medium heat absorption temperature rise process₃Decompression expansion process of kilogram working medium 67, M₃78, M kilogram working medium heat release and temperature reduction process₁Decompression expansion process 89, M with kilogram working medium₁Kilogram working medium releases heat and condenses 91-10 processes in total.

(2) From the energy conversion perspective:

① endothermic Process-M₁Carrying out 23 processes and 45 processes by kg of working medium, and M₃56 kg of working medium is subjected to the process, and the heat absorption of the high-temperature section is generally provided by an external heat source; the heat absorption of the low-temperature section is performed by an external heat source or by M₃The kilogram of working fluid is provided with the heat release (back heating) of the 78 process, or both.

② exothermic Process-M₃Heat release in the 78 process is carried out by kilogram working media, corresponding heat requirements can be met, or partial or all heat absorption requirements for other processes of combined cycle can be met, and useless parts are released to a low-temperature heat source (such as environment); m₁The heat released in the process of 91 kg of working medium is generally released to a low-temperature heat source and is provided to a heat user during heat and power combined supply.

③ energy conversion Process-M₁The boosting process 12 of kilogram working medium is generally completed by a circulating pump, M₂The boosting process 85 of kilogram working media is generally completed by a compressor; m₁Decompression expansion process 34, M of kilogram working medium₃Decompression expansion process 67 of kilogram working medium, also M₁The kilogram working medium decompression expansion process 89 is generally completed by an expansion machine; the expansion work is larger than the pressure-raising power consumption, the heat-changing work is completed, the circulation net work is provided for the outside, and the single working medium steam combined circulation is formed.

The single-working-medium vapor combined cycle example in the T-s diagram of fig. 2 is performed as follows:

(1) from the cycle process:

working medium process-M₁Boosting process of kilogram working medium condensate 12, M₁Kilogram working medium heat absorption temperature rise, vaporization and overheating process 23, M₁Decompression expansion process 34, M of kilogram working medium₁45, M kilogram working medium heat absorption temperature rise process₁Decompression expansion process 57, M with kilogram working medium₂96, M kilogram working medium pressure rising and temperature rising process₂Kilogram working medium heat absorption temperature rise process 67, M₃Decompression expansion process 78, M with kilogram working medium₃89, M kilogram working medium heat release and temperature reduction process₁Decompression expansion process of kilogram working medium 9c, M₁Kilogram working medium exothermal condensation process c 1-11 processes in total.

(2) From the energy conversion perspective:

① endothermic Process-M₁Carrying out 23 processes and 45 processes by kg of working medium, and M₂67 processes are carried out on kilogram working media, and heat absorption of a high-temperature section of the working media is generally provided by an external heat source; the heat absorption of the low-temperature section is performed by an external heat source or by M₃The kilogram of working fluid is provided by heat release (recuperation) of 89 processes, or both.

② exothermic Process-M₃Heat release in the 89 process is carried out by kilogram of working media, corresponding heat requirements can be met, or part or most of heat absorption requirements for other processes of combined cycle can be met, and useless parts are released to a low-temperature heat source (such as environment); m₁The kilogram working medium carries out heat release in the c1 process, and the heat release is generally released to a low-temperature heat source and provided to a heat user in the process of heat cogeneration.

③ energy conversion Process-M₁The boosting process 12 of kilogram working medium is generally completed by a circulating pump, M₂The boosting process 96 of kilogram of working medium is generally completed by a compressor; m₁Decompression expansion process 34, M of kilogram working medium₁Decompression expansion process 57, M of kilogram working medium₃Decompression expansion process 78 of kilogram working medium, also M₁The kilogram working medium decompression expansion process 89 is generally completed by an expansion machine; the expansion work is larger than the pressure-raising power consumption, the heat-changing work is completed, the circulation net work is provided for the outside, and the single working medium steam combined circulation is formed.

The single-working-medium vapor combined cycle example in the T-s diagram of fig. 3 is performed as follows:

(1) from the cycle process:

working medium process-M₁Boosting process of kilogram working medium condensate 12, M₁Kilogram working medium heat absorption temperature rise, vaporization and overheating process 23, M₁Decompression expansion process 34, M of kilogram working medium₁47, M kilogram working medium heat absorption temperature rise process₂Step-up and temperature-rise process of 95, M of kilogram working medium₂56, M kilogram working medium heat absorption temperature rise process₂Decompression expansion process with kilogram working medium 67，M₃Decompression expansion process 78, M with kilogram working medium₃89, M kilogram working medium heat release and temperature reduction process₁Decompression expansion process of kilogram working medium 9c, M₁Kilogram working medium exothermal condensation process c 1-11 processes in total.

(2) From the energy conversion perspective:

① endothermic Process-M₁Carrying out 23 processes and 47 processes by kg of working medium, and M₂56 processes are carried out by kilogram working medium, the heat absorption of the high-temperature section is generally provided by an external heat source, and the heat absorption of the low-temperature section is provided by the external heat source or by M₃The kilogram of working fluid is provided by heat release (recuperation) of 89 processes, or both.

② exothermic Process-M₃Heat release in the 89 process is carried out by kilogram of working media, corresponding heat requirements can be met, or part or most of heat absorption requirements for other processes of combined cycle can be met, and useless parts are released to a low-temperature heat source (such as environment); m₁The kilogram working medium carries out heat release in the c1 process, and the heat release is generally released to a low-temperature heat source and provided to a heat user in the process of heat cogeneration.

③ energy conversion Process-M₁The boosting process 12 of kilogram working medium is generally completed by a circulating pump, M₂The boosting process 95 of kilogram of working medium is generally completed by a compressor; m₁Decompression expansion process 34, M of kilogram working medium₂Decompression expansion process of kilogram working medium 67, M₃Decompression expansion process 78 of kilogram working medium, also M₁The kilogram working medium decompression expansion process 9c is generally completed by an expansion machine; the expansion work is larger than the pressure-raising power consumption, the heat-changing work is completed, the circulation net work is provided for the outside, and the single working medium steam combined circulation is formed.

The single-working-medium vapor combined cycle example in the T-s diagram of fig. 4 is performed as follows:

(1) from the cycle process:

working medium process-M₁Boosting process of kilogram working medium condensate 12, M₁Kilogram working medium heat absorption temperature rise, vaporization and overheating process 23, M₁Decompression expansion process 34, M of kilogram working medium₁45, M kilogram working medium heat absorption temperature rise process₁Pressure reduction by kilogram working mediumExpansion Process 59, M₂Kilogram working medium pressure-raising and temperature-raising process c6, M₂Kilogram working medium heat absorption temperature rise process 67, M₂Decompression expansion process 78, M with kilogram working medium₂89, M kilogram working medium heat release and temperature reduction process₃9c, M in kilogram working medium heat release and temperature reduction process₁Decompression expansion process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-12 processes in total.

(2) From the energy conversion perspective:

① endothermic Process-M₁Carrying out 23 processes and 45 processes by kg of working medium, and M₂67 processes are carried out on kilogram working media, and heat absorption of a high-temperature section of the working media is generally provided by an external heat source; the heat absorption of the low-temperature section is performed by an external heat source or by M₂89 process and M are carried out by kilogram working medium₃The kilogram working medium is provided by the combined heat release (back heating) of the 9c process, or by the two.

② exothermic Process-M₂Heat release and M of 89 processes per kilogram of working medium₃Kilogram working medium releases heat in the 9c process, corresponding heat requirements can be met, or part or most of heat absorption requirements for other processes of combined cycle can be met, and useless parts are released to a low-temperature heat source (such as environment); m₁The heat release of d1 process is carried out by kilogram working medium, and the heat is generally released to a low-temperature heat source and provided to a heat user during heat cogeneration.

③ energy conversion Process-M₁The boosting process 12 of kilogram working medium is generally completed by a circulating pump, M₂The boosting process c6 of kilogram working medium is generally completed by a compressor; m₁Depressurization of 34, M kilogram of working medium₁Depressurization of 59, M in kilograms of working medium₂Depressurization 78 of kilogram of working medium, also M₁The kilogram working medium decompression expansion process cd is generally completed by an expansion machine; the expansion work is larger than the pressure-raising power consumption, the heat-changing work is completed, the circulation net work is provided for the outside, and the single working medium steam combined circulation is formed.

The single-working-medium vapor combined cycle example in the T-s diagram of fig. 5 is performed as follows:

(1) from the cycle process:

working medium process-M₁Boosting process of kilogram working medium condensate 12, M₁Kilogram working medium heat absorption temperature rise, vaporization and overheating process 23, M₁Decompression expansion process 34, M of kilogram working medium₁45, M kilogram working medium heat absorption temperature rise process₁Decompression expansion process 56, M of kilogram working medium₁69, M kilogram working medium heat release and temperature reduction process₂Kilogram working medium pressure-raising and temperature-raising process c7, M₂78, M kilogram working medium heat absorption temperature rise process₂Decompression expansion process 89, M with kilogram working medium₃9c, M in kilogram working medium heat release and temperature reduction process₁Decompression expansion process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-12 processes in total.

(2) From the energy conversion perspective:

① endothermic Process-M₁Carrying out 23 processes and 45 processes by kg of working medium, and M₂78 kg of working medium is subjected to the process, and the heat absorption of the high-temperature section is generally provided by an external heat source; the heat absorption of the low-temperature section is performed by an external heat source or by M₁69 kg working medium and M₃The kilogram working medium is provided by the combined heat release (back heating) of the 9c process, or by the two.

② exothermic Process-M₁Heat release and M of 69 processes carried out with kilograms of working medium₃Kilogram working medium releases heat in the 9c process, corresponding heat requirements can be met, or part or most of heat absorption requirements for other processes of combined cycle can be met, and useless parts are released to a low-temperature heat source (such as environment); m₁The heat release of d1 process is carried out by kilogram working medium, and the heat is generally released to a low-temperature heat source and provided to a heat user during heat cogeneration.

③ energy conversion Process-M₁The boosting process 12 of kilogram working medium is generally completed by a circulating pump, M₂The boosting process 85 of kilogram working media is generally completed by a compressor; m₁Depressurization of 34, M kilogram of working medium₁Depressurization of working medium kilogram 56, M₂Depressurization process 89 of kg of working medium, also M₁The kilogram working medium decompression expansion process cd is generally completed by an expansion machine; the expansion work is larger than the pressure-raising power consumption, the heat-changing work is completed, the circulation net work is provided for the outside, and the single working medium steam combined circulation is formed.

The single-working-medium vapor combined cycle example in the T-s diagram of fig. 6 is performed as follows:

(1) from the cycle process:

working medium process-M₁Boosting process of kilogram working medium condensate 12, M₁Kilogram working medium heat absorption temperature rise, vaporization and overheating process 23, M₁Decompression expansion process 34, M of kilogram working medium₁45, M kilogram working medium heat absorption temperature rise process₂Kilogram working medium pressure-raising and temperature-raising process c5, M₃The heat absorption and temperature rise process of kilogram working medium 56, the pressure reduction and expansion process of X kilogram working medium 69, (M)₃-X) kilogram working medium endothermic heating Process 67, (M)₃-X) kilogram working medium decompression expansion process 78, (M)₃-X) kg working medium exothermic cooling process 89, M₃9c, M in kilogram working medium heat release and temperature reduction process₁Decompression expansion process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-13 processes in total.

(2) From the energy conversion perspective:

① endothermic Process-M₁Carrying out 23 processes and M on kilogram working media₁Performing 45 processes and M on kilogram working medium₃56 processes and (M) are carried out in kg of working medium₃-X) kg is processed 67 times, the heat absorption of the high temperature section of which is generally provided by an external heat source; the heat absorption of the low-temperature section is performed by an external heat source or (M)₃-X) Process 89 with kg of working substance and M₃The kilogram working medium is provided by the combined heat release (back heating) of the 9c process, or by the two.

② exothermic Process- (M)₃X) exothermic reaction of 89 Processes with kg of working fluid and M₃Kilogram working medium releases heat in the 9c process, corresponding heat requirements can be met, or part or most of heat absorption requirements for other processes of combined cycle can be met, and useless parts are released to a low-temperature heat source (such as environment); m₁The heat release of d1 process is carried out by kilogram working medium, and the heat is generally released to a low-temperature heat source and provided to a heat user during heat cogeneration.

③ energy conversion Process-M₁The boosting process 12 of kilogram working medium is generally completed by a circulating pump, M₂The boosting process c5 of kilogram working medium is generally carried outA compressor is used for completing; m₁Decompression of working medium kg 34, X working medium kg 69, (M)₃X) depressurization 78 of kg of working medium, and also M₁The kilogram working medium decompression expansion process cd is generally completed by an expansion machine; the expansion work is larger than the pressure-raising power consumption, the heat-changing work is completed, the circulation net work is provided for the outside, and the single working medium steam combined circulation is formed.

The single-working-medium vapor combined cycle example in the T-s diagram of fig. 7 is performed as follows:

(1) from the cycle process:

working medium process-M₁Boosting process of kilogram working medium condensate 12, M₁Mixing heat absorption temperature rise process 2b of kilogram working medium and M kilogram working medium, (M)₁+ M) kilogram working medium endothermic heating, vaporization and superheating process b3 (M)₁+ M) kilogram working medium depressurization expansion process 34, (M)₁+ M) kilogram working medium heat absorption temperature rise process 45, M₂Boosting and heating process of kilogram working medium 8a, M kilogram working medium and M₁Ab (M) of the condensation process of the heat released by the mixture of kilograms of working medium₂M) kilogram working medium pressure and temperature rising process a5, M₃56, M kilogram working medium heat absorption temperature rise process₃Decompression expansion process of kilogram working medium 67, M₃78, M kilogram working medium heat release and temperature reduction process₁Decompression expansion process 89, M with kilogram working medium₁And the kilogram working medium releases heat and is condensed 91-13 processes in total.

(2) From the energy conversion perspective:

① endothermic Process-M₁Heat absorption of kilogram working medium in 2b process comes from mixed heat release of M kilogram superheated steam, M₁B3 and 45 processes are carried out by kilogram working medium, and M is also carried out₃56 processes are carried out by kilogram working medium, the heat absorption of the high-temperature section is generally provided by an external heat source, and the heat absorption of the low-temperature section is provided by the external heat source or by M₃The kilogram of working fluid is provided with the heat release (back heating) of the 78 process, or both.

② exothermic Process-M₃The kilogram working medium carries out heat release in the 78 process, can provide corresponding heat requirements for the outside, or can partially or completely use the heat absorption requirements for other processes of the combined cycle, and has low useless partRelease of a warm source (e.g., ambient); m₁The heat released in the process of 91 kg of working medium is generally released to a low-temperature heat source and is provided to a heat user during heat and power combined supply.

③ energy conversion Process-M₁The boosting process 12 of kilogram working medium is generally completed by a circulating pump, M₂Boosting process 8a and (M) of kilogram working medium₂M) the boosting process a5 of kg of working medium is generally carried out by a compressor; (M)₁+ M) decompression of working medium 34, M₃Decompression expansion process 67 of kilogram working medium, also M₁The kilogram working medium decompression expansion process 89 is generally completed by an expansion machine; the expansion work is larger than the pressure-raising power consumption, the heat-changing work is completed, the circulation net work is provided for the outside, and the single working medium steam combined circulation is formed.

The single-working-medium vapor combined cycle example in the T-s diagram of fig. 8 is performed as follows:

(1) from the cycle process:

working medium process-M₁Boosting process of kilogram working medium condensate 12, M₁Mixing heat absorption temperature rise process 2b of kilogram working medium and M kilogram working medium, (M)₁+ M) kilogram working medium endothermic heating, vaporization and superheating process b3 (M)₁+ M) kilogram working medium depressurization expansion process 34, (M)₁+ M) kilogram working medium heat absorption temperature rise process 45, (M)₁+ M) kilogram working medium is decompressed and expanded to 57, M₂Boosting and temperature rising process of kilogram working medium 9a, M kilogram working medium and M₁Ab (M) of the condensation process of the heat released by the mixture of kilograms of working medium₂-M) kilogram working medium pressure and temperature rising process a6, (M)₂-M) Heat absorption temperature increase Process for kilogram working Medium 67, M₃Decompression expansion process 78, M with kilogram working medium₃89, M kilogram working medium heat release and temperature reduction process₁Decompression expansion process of kilogram working medium 9c, M₁Kilogram working medium exothermal condensation process c 1-14 processes in total.

(2) From the energy conversion perspective:

① endothermic Process-M₁The heat absorption of the kilogram working medium in the 2b process comes from the mixed heat release of M kilograms of superheated steam, (M)₁+ M) kg of working medium for 23 and 45 processes, and also (M)₂M) one kilogram of working medium is subjected to a 67-stage process, the temperature of which is highThe heat absorption of the sections is generally provided by an external heat source, and the heat absorption of the low-temperature sections is provided by an external heat source or by M₃The kilogram of working fluid is provided by heat release (recuperation) of 89 processes, or both.

② exothermic Process-M₃Heat release in the 89 process is carried out by kilogram of working media, corresponding heat requirements can be met, or part or most of heat absorption requirements for other processes of combined cycle can be met, and useless parts are released to a low-temperature heat source (such as environment); m₁The kilogram working medium carries out heat release in the c1 process, and the heat release is generally released to a low-temperature heat source and provided to a heat user in the process of heat cogeneration.

③ energy conversion Process-M₁The boosting process 12 of kilogram working medium is generally completed by a circulating pump, M₂Boosting process 9a and (M) with kilogram working medium₂M) the boosting process a6 of kg of working medium is generally carried out by a compressor; (M)₁+ M) decompression of working medium 34 (M)₁+ M) decompression expansion process 57, M of kilogram working medium₃Decompression expansion process 78 of kilogram working medium, also M₁The kilogram working medium decompression expansion process 9c is generally completed by an expansion machine; the expansion work is larger than the pressure-raising power consumption, the heat-changing work is completed, the circulation net work is provided for the outside, and the single working medium steam combined circulation is formed.

The single-working-medium vapor combined cycle example in the T-s diagram of fig. 9 is performed as follows:

(1) from the cycle process:

working medium process-M₁Boosting process of kilogram working medium condensate 12, M₁Mixing heat absorption temperature rise process 2b of kilogram working medium and M kilogram working medium, (M)₁+ M) kilogram working medium endothermic heating, vaporization and superheating process b3 (M)₁+ M) kilogram working medium depressurization expansion process 34, (M)₁+ M) kilogram working medium heat absorption temperature rise process 47, M₂Boosting and temperature rising process of kilogram working medium 9a, M kilogram working medium and M₁Ab (M) of the condensation process of the heat released by the mixture of kilograms of working medium₂-M) kilogram working medium pressure and temperature rising process a5, (M)₂-M) Heat absorption and temperature increase Process 56 with kilogram working Medium (M)₂-M) kilogram working medium depressurization expansion Process 67, M₃Decompression expansion process 78, M with kilogram working medium₃89, M kilogram working medium heat release and temperature reduction process₁Decompression expansion process of kilogram working medium 9c, M₁Kilogram working medium exothermal condensation process c 1-14 processes in total.

(2) From the energy conversion perspective:

① endothermic Process-M₁The heat absorption of the kilogram working medium in the 2b process comes from the mixed heat release of M kilograms of superheated steam, (M)₁+ M) kg of working medium for processes b3 and 47, and also (M)₂M) kg of working medium, the heat absorption of the high-temperature section of which is generally provided by an external heat source, and the heat absorption of the low-temperature section of which is provided by the external heat source or by M₃The kilogram of working fluid is provided by heat release (recuperation) of 89 processes, or both.

② exothermic Process-M₃Heat release in the 89 process is carried out by kilogram of working media, corresponding heat requirements can be met, or part or most of heat absorption requirements for other processes of combined cycle can be met, and useless parts are released to a low-temperature heat source (such as environment); m₁The kilogram working medium carries out heat release in the c1 process, and the heat release is generally released to a low-temperature heat source and provided to a heat user in the process of heat cogeneration.

③ energy conversion Process-M₁The boosting process 12 of kilogram working medium is generally completed by a circulating pump, M₂Boosting process 9a and (M) with kilogram working medium₂M) the boosting process a5 of kg of working medium is generally carried out by a compressor; (M)₁+ M) decompression of working medium 34 (M)₂-M) decompression expansion Process 67, M) of kg working fluid₃Decompression expansion process 78 of kilogram working medium, also M₁The kilogram working medium decompression expansion process 9c is generally completed by an expansion machine; the expansion work is larger than the pressure-raising power consumption, the heat-changing work is completed, the circulation net work is provided for the outside, and the single working medium steam combined circulation is formed.

The single-working-medium vapor combined cycle example in the T-s diagram of fig. 10 is performed as follows:

(1) from the cycle process:

working medium process-M₁Boosting process of kilogram working medium condensate 12, M₁Mixing heat absorption temperature rise process 2b of kilogram working medium and M kilogram working medium, (M)₁+ M) kilogram working medium heat absorption riseWarm, boil-off and superheat process b3, (M)₁+ M) kilogram working medium depressurization expansion process 34, (M)₁+ M) kilogram working medium heat absorption temperature rise process 45, (M)₁+ M) kilogram working medium depressurization expansion process 59, M₂Boosting and heating process of kilogram working medium ca, M kilogram working medium and M₁Ab (M) of the condensation process of the heat released by the mixture of kilograms of working medium₂-M) kilogram working medium pressure and temperature rising process a6, (M)₂-M) kilogram working medium endothermic heating process 67, (M)₂-M) kilogram working medium depressurization expansion process 78, (M)₂-M) kg of working medium exothermic cooling process 89, M₃9c, M in kilogram working medium heat release and temperature reduction process₁Decompression expansion process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-15 processes in total.

(2) From the energy conversion perspective:

① endothermic Process-M₁The heat absorption of the kilogram working medium in the 2b process comes from the mixed heat release of M kilograms of superheated steam, (M)₁+ M) kg of working medium for processes b3 and 45, and also (M)₂M) one kilogram of working medium is subjected to a 67 process, the heat absorption of the high-temperature section of which is generally provided by an external heat source; the heat absorption of the low-temperature section is performed by an external heat source or (M)₂M) Process 89 with kg of working substance₃The kilogram working medium is provided by the combined heat release (back heating) of the 9c process, or by the two.

② exothermic Process- (M)₂M) exothermic heat of 89 processes per kilogram of working fluid and M₃Kilogram working medium releases heat in the 9c process, corresponding heat requirements can be met, or part or most of heat absorption requirements for other processes of combined cycle can be met, and useless parts are released to a low-temperature heat source (such as environment); m₁The heat release of d1 process is carried out by kilogram working medium, and the heat is generally released to a low-temperature heat source and provided to a heat user during heat cogeneration.

③ energy conversion Process-M₁The boosting process 12 of kilogram working medium is generally completed by a circulating pump, M₂Boosting process of kilogram working medium ca and (M)₂M) the boosting process a6 of kg of working medium is generally carried out by a compressor; (M)₁+ M) decompression of working medium 34 (M)₁+ M) decompression of working medium 59 (M)₂M) depressurization 78 of one kilogram of working medium, also M₁The kilogram working medium decompression process cd is generally completed by an expansion machine; the expansion work is larger than the pressure-raising power consumption, the heat-changing work is completed, the circulation net work is provided for the outside, and the single working medium steam combined circulation is formed.

The single-working-medium vapor combined cycle example in the T-s diagram of fig. 11 is performed as follows:

(1) from the cycle process:

working medium process-M₁Boosting process of kilogram working medium condensate 12, M₁Mixing heat absorption temperature rise process 2b of kilogram working medium and M kilogram working medium, (M)₁+ M) kilogram working medium endothermic heating, vaporization and superheating process b3 (M)₁+ M) kilogram working medium depressurization expansion process 34, (M)₁+ M) kilogram working medium heat absorption temperature rise process 45, (M)₁+ M) kilogram working medium depressurization expansion Process 56, (M)₁+ M) kilogram working medium exothermic cooling process 69, M₂Boosting and heating process of kilogram working medium ca, M kilogram working medium and M₁Ab (M) of the condensation process of the heat released by the mixture of kilograms of working medium₂-M) kilogram working medium pressure and temperature rising process a7, (M)₂-M) Heat absorption and temperature increase Process 78 with kg working Medium (M)₂-M) kilogram working medium decompression expansion Process 89, M₃9c, M in kilogram working medium heat release and temperature reduction process₁Decompression expansion process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d1 — 15 processes in total.

(2) From the energy conversion perspective:

① endothermic Process-M₁The heat absorption of the kilogram working medium in the 2b process comes from the mixed heat release of M kilograms of superheated steam, (M)₁+ M) kg of working medium for processes b3 and 45, and also (M)₂M) one kilogram of working medium is subjected to a process 78, the heat absorption of the high-temperature section of which is generally provided by an external heat source; the heat absorption of the low-temperature section is performed by an external heat source or (M)₁+ M) kg working medium 69 and M₃The kilogram working medium is provided by the combined heat release (back heating) of the 9c process, or by the two.

② exothermic Process- (M)₁+ M) exothermic heat release from 69 kg working fluid and M₃The kilogram working medium carries out heat release in the 9c process and can be used for the outsideProviding a heat sink that meets the corresponding heat demand, or that is partially or mostly used for other processes of the combined cycle, with the unused portion being released to a low temperature heat source (e.g., ambient); m₁The heat release of d1 process is carried out by kilogram working medium, and the heat is generally released to a low-temperature heat source and provided to a heat user during heat cogeneration.

③ energy conversion Process-M₁The boosting process 12 of kilogram working medium is generally completed by a circulating pump, M₂Boosting process of kilogram working medium ca and (M)₂M) the boosting process a7 of kg of working medium is generally carried out by a compressor; (M)₁+ M) decompression of working medium 34 (M)₁+ M) decompression of working medium kg 56, (M)₂M) depressurization of working substances 89, also M₁The kilogram working medium decompression process cd is generally completed by an expansion machine; the expansion work is larger than the pressure-raising power consumption, the heat-changing work is completed, the circulation net work is provided for the outside, and the single working medium steam combined circulation is formed.

The single-working-medium vapor combined cycle example in the T-s diagram of fig. 12 is performed as follows:

(1) from the cycle process:

working medium process-M₁Boosting process of kilogram working medium condensate 12, M₁Mixing heat absorption temperature rise process 2b of kilogram working medium and M kilogram working medium, (M)₁+ M) kilogram working medium endothermic heating, vaporization and superheating process b3 (M)₁+ M) kilogram working medium depressurization expansion process 34, (M)₁+ M) kilogram working medium heat absorption temperature rise process 45, M₂Boosting and heating process of kilogram working medium ca, M kilogram working medium and M₁Ab (M) of the condensation process of the heat released by the mixture of kilograms of working medium₂M) kilogram working medium pressure and temperature rising process a5, M₃The heat absorption and temperature rise process of kilogram working medium 56, the pressure reduction and expansion process of X kilogram working medium 69, (M)₃-X) kilogram working medium endothermic heating Process 67, (M)₃-X) kilogram working medium decompression expansion process 78, (M)₃-X) kg working medium exothermic cooling process 89, M₃9c, M in kilogram working medium heat release and temperature reduction process₁Decompression expansion process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d1 — 16 processes in total.

(2) From the energy conversion perspective:

① endothermic Process-M₁The heat absorption of the kilogram working medium in the 2b process comes from the mixed heat release of M kilograms of superheated steam, (M)₁+ M) kg of working medium for processes b3 and 45, M₃56 processes are carried out per kilogram of working medium, also (M)₃-X) kg is processed 67 times, the heat absorption of the high temperature section of which is generally provided by an external heat source; the heat absorption of the low-temperature section is performed by an external heat source or (M)₃-X) Process 89 with kg of working substance and M₃The kilogram working medium is provided by the combined heat release (back heating) of the 9c process, or by the two.

② exothermic Process- (M)₃X) exothermic reaction of 89 Processes with kg of working fluid and M₃Kilogram working medium releases heat in the 9c process, corresponding heat requirements can be met, or part or most of heat absorption requirements for other processes of combined cycle can be met, and useless parts are released to a low-temperature heat source (such as environment); m₁The heat release of d1 process is carried out by kilogram working medium, and the heat is generally released to a low-temperature heat source and provided to a heat user during heat cogeneration.

③ energy conversion Process-M₁The boosting process 12 of kilogram working medium is generally completed by a circulating pump, M₂Boosting process of kilogram working medium ca and (M)₂M) the boosting process a5 of kg of working medium is generally carried out by a compressor; (M)₁+ M) decompression of working medium kg 34, X kg 69, (M)₃X) depressurization 78 of kg of working medium, and also M₁The kilogram working medium decompression process cd is generally completed by an expansion machine; the expansion work is larger than the pressure-raising power consumption, the heat-changing work is completed, the circulation net work is provided for the outside, and the single working medium steam combined circulation is formed.

The effect that the technology of the invention can realize-the single working medium steam combined cycle provided by the invention has the following effects and advantages:

(1) creating a thermal energy (temperature difference) utilization basic theory.

(2) The heat load in the phase change heat absorption process is greatly reduced, the heat absorption load in a high-temperature section is relatively increased, and the heat efficiency is high.

(3) The method is simple, reasonable in flow and good in applicability, and is a common technology for realizing effective utilization of temperature difference.

(4) The single working medium is beneficial to production and storage; reduce the running cost and improve the flexibility of circulation regulation

(5) The process is shared, the heat efficiency is improved, and a theoretical basis is provided for reducing the equipment investment.

(6) In the high temperature area or the variable temperature area, the circulating medium and the heat source medium are both gases, and the circulating working medium is in favor of reducing the temperature difference heat transfer loss from the heat source heat absorption link and improving the heat efficiency.

(7) The low-pressure high-temperature operation mode is adopted in the high-temperature area, so that the contradiction that the heat efficiency, the circulating medium parameters and the pressure and temperature resistance of the pipe are difficult to reconcile in the traditional steam power device is solved.

(8) On the premise of realizing high thermal efficiency, low-pressure operation can be selected, and theoretical support is provided for improving the operation safety of the device.

(9) The working medium has wide application range, can well adapt to energy supply requirements, and is flexibly matched with working parameters.

(10) The thermodynamic cycle range for realizing temperature difference utilization is expanded, and efficient power utilization of a high-temperature heat source and a variable-temperature heat source is favorably realized.

Claims (12)

1. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Ten processes carried out separately or together-M₁Step-up process of working medium kilogram 12, M₁Heat absorption and vaporization process 23, M of kilogram working medium₁Decompression process 34, M of kilogram working medium₁45, M kilogram working medium heat absorption process₂Boosting process of 85, M for kilogram working medium₃56, M kilogram working medium heat absorption process₃Decompression process with kilogram working medium 67, M₃78, M, kilogram working medium heat release process₁Decompression process 89, M with kilogram working medium₁Kilogram working medium heat release condensation process 91-a closed process of composition; wherein M is₃Is M₁And M₂And (4) summing.

2. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Composed of kilogramsWorking substances, eleven processes carried out separately or together-M₁Step-up process of working medium kilogram 12, M₁Heat absorption and vaporization process 23, M of kilogram working medium₁Decompression process 34, M of kilogram working medium₁45, M kilogram working medium heat absorption process₁Decompression process 57, M with kilogram working medium₂96, M kilogram working medium boosting process₂Kilogram working medium endothermic process 67, M₃Decompression process 78, M with kilogram working medium₃89, M kilogram working medium heat release process₁Decompression process of kilogram working medium 9c, M₁Kilogram working medium exothermal condensation process c 1-the closed process of component; wherein M is₃Is M₁And M₂And (4) summing.

3. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilogram, eleven processes carried out separately or together-M₁Step-up process of working medium kilogram 12, M₁Heat absorption and vaporization process 23, M of kilogram working medium₁Decompression process 34, M of kilogram working medium₁47, M kilogram working medium heat absorption process₂Step-up process of 95, M for kilogram working medium₂56, M kilogram working medium heat absorption process₂Decompression process with kilogram working medium 67, M₃Decompression process 78, M with kilogram working medium₃89, M kilogram working medium heat release process₁Decompression process of kilogram working medium 9c, M₁Kilogram working medium exothermal condensation process c 1-the closed process of component; wherein M is₃Is M₁And M₂And (4) summing.

4. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilograms of composition, twelve processes carried out separately or together-M₁Step-up process of working medium kilogram 12, M₁Heat absorption and vaporization process 23, M of kilogram working medium₁Decompression process 34, M of kilogram working medium₁45, M kilogram working medium heat absorption process₁Decompression process 59, M with kilogram working medium₂Kilogram working medium boosting process c6, M₂Kilogram working medium endothermic process 67, M₂Decompression process 78, M with kilogram working medium₂89, M kilogram working medium heat release process₃Kilogram workerExothermic process 9c, M₁The blood pressure lowering process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-formed closing process; wherein M is₃Is M₁And M₂And (4) summing.

5. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilograms of composition, twelve processes carried out separately or together-M₁Step-up process of working medium kilogram 12, M₁Heat absorption and vaporization process 23, M of kilogram working medium₁Decompression process 34, M of kilogram working medium₁45, M kilogram working medium heat absorption process₁Decompression process 56, M of kilogram working medium₁Kilogram working medium heat release process 69, M₂Kilogram working medium boosting process c7, M₂78, M, kilogram working medium heat absorption process₂Decompression process 89, M with kilogram working medium₃Kilogram working medium heat release process 9c, M₁The blood pressure lowering process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-formed closing process; wherein M is₃Is M₁And M₂And (4) summing.

6. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working substances in kilogram composition, thirteen processes carried out individually or jointly or in part-M₁Step-up process of working medium kilogram 12, M₁Heat absorption and vaporization process 23, M of kilogram working medium₁Decompression process 34, M of kilogram working medium₁45, M kilogram working medium heat absorption process₂Kilogram working medium boosting process c5, M₃Kilogram working medium heat absorption process 56, X kilogram working medium pressure reduction process 69, (M)₃-X) kilogram working substance endotherm 67, (M)₃-X) decompression Process 78 with kg of working substance, (M)₃-X) kilogram working substance exothermic Process 89, M₃Kilogram working medium heat release process 9c, M₁The blood pressure lowering process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-formed closing process; wherein M is₃Is M₁And M₂And (4) summing.

7. Single working medium steam combined cycle, refers toBy M₁Kilogram and M₂Working substances in kilogram composition, thirteen processes carried out individually or jointly or in part-M₁Step-up process of working medium kilogram 12, M₁Kilogram working medium heat absorption process 2b, (M)₁+ M) kilogram working medium endothermic vaporization process b3, (M)₁+ M) kilogram working medium depressurization 34, (M)₁+ M) kilogram working medium endothermic process 45, M₂8a in kilogram working medium boosting process, ab in M kilogram working medium heat releasing condensation process, (M)₂M) kilogram working medium pressure rise process a5, M₃56, M kilogram working medium heat absorption process₃Decompression process with kilogram working medium 67, M₃78, M, kilogram working medium heat release process₁Decompression process 89, M with kilogram working medium₁Kilogram working medium heat release condensation process 91-a closed process of composition; wherein M is₃Is M₁And M₂And (4) summing.

8. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilograms of composition, fourteen processes carried out separately or together or partially-M₁Step-up process of working medium kilogram 12, M₁Kilogram working medium heat absorption process 2b, (M)₁+ M) kilogram working medium endothermic vaporization process b3, (M)₁+ M) kilogram depressurization Process 34, (M)₁+ M) kilogram endothermic Process 45, (M)₁+ M) kilogram working medium is reduced in pressure by 57, M₂Kilogram working medium boosting process 9a, M kilogram working medium heat release condensation process ab, (M)₂M) kilogram working medium pressure increasing process a6, (M)₂-M) kilogram working substance endothermic process 67, M₃Decompression process 78, M with kilogram working medium₃89, M kilogram working medium heat release process₁Decompression process of kilogram working medium 9c, M₁Kilogram working medium exothermal condensation process c 1-the closed process of component; wherein M is₃Is M₁And M₂And (4) summing.

9. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilograms of composition, fourteen processes carried out separately or together or partially-M₁Step-up process of working medium kilogram 12, M₁Kilogram working medium heat absorption process 2b, (M)₁+M)Kilogram working medium heat absorption vaporization process b3, (M)₁+ M) kilogram depressurization Process 34, (M)₁+ M) kilogram endothermic Process 47, M₂Kilogram working medium boosting process 9a, M kilogram working medium heat release condensation process ab, (M)₂M) kilogram working medium pressure increasing process a5, (M)₂M) kilogram working medium endothermic Process 56, (M)₂-M) depressurization of 67, M) kg of working medium₃Decompression process 78, M with kilogram working medium₃89, M kilogram working medium heat release process₁Decompression process of kilogram working medium 9c, M₁Kilogram working medium exothermal condensation process c 1-the closed process of component; wherein M is₃Is M₁And M₂And (4) summing.

10. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilograms of composition, fifteen processes carried out separately or together or partially-M₁Step-up process of working medium kilogram 12, M₁Kilogram working medium heat absorption process 2b, (M)₁+ M) kilogram working medium endothermic vaporization process b3, (M)₁+ M) kilogram working medium depressurization 34, (M)₁+ M) kilogram working medium endothermic process 45, (M)₁+ M) kilogram working medium depressurization process 59, M₂Kilogram working medium boosting process ca, M kilogram working medium heat releasing condensation process ab, (M)₂M) kilogram working medium pressure increasing process a6, (M)₂-M) kilogram working substance endothermic process 67, (M)₂-M) kilogram working medium depressurization 78, (M)₂-M) kilogram working medium exothermic Process 89, M₃Kilogram working medium heat release process 9c, M₁The blood pressure lowering process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-formed closing process; wherein M is₃Is M₁And M₂And (4) summing.

11. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilograms of composition, fifteen processes carried out separately or together or partially-M₁Step-up process of working medium kilogram 12, M₁Kilogram working medium heat absorption process 2b, (M)₁+ M) kilogram working medium endothermic vaporization process b3, (M)₁+ M) kilogram working medium depressurization 34, (M)₁+ M) kilogram working medium suctionThermal Process 45, (M)₁+ M) kilogram working medium depressurization 56 (M)₁+ M) kilogram working medium exothermic process 69, M₂Kilogram working medium boosting process ca, M kilogram working medium heat releasing condensation process ab, (M)₂M) kilogram working medium pressure increasing process a7, (M)₂-M) kilogram working medium endothermic Process 78, (M)₂-M) decompression Process 89, M) with kg of working substance₃Kilogram working medium heat release process 9c, M₁The blood pressure lowering process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-formed closing process; wherein M is₃Is M₁And M₂And (4) summing.

12. Single working medium steam combined cycle, is formed from M₁Kilogram and M₂Working medium composed of kilograms of composition, sixteen processes carried out separately or together or in part-M₁Step-up process of working medium kilogram 12, M₁Kilogram working medium heat absorption process 2b, (M)₁+ M) kilogram working medium endothermic vaporization process b3, (M)₁+ M) kilogram working medium depressurization 34, (M)₁+ M) kilogram working medium endothermic process 45, M₂Kilogram working medium boosting process ca, M kilogram working medium heat releasing condensation process ab, (M)₂M) kilogram working medium pressure rise process a5, M₃Kilogram working medium heat absorption process 56, X kilogram working medium pressure reduction process 69, (M)₃-X) kilogram working substance endotherm 67, (M)₃-X) decompression Process 78 with kg of working substance, (M)₃-X) kilogram working substance exothermic Process 89, M₃Kilogram working medium heat release process 9c, M₁The blood pressure lowering process cd, M with kilogram working medium₁Kilogram working medium exothermal condensation process d 1-formed closing process; wherein M is₃Is M₁And M₂And (4) summing.

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