CN113487065A - Zero-carbon power optimization planning system based on clean power and optimization method thereof - Google Patents
Zero-carbon power optimization planning system based on clean power and optimization method thereof Download PDFInfo
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- G06Q—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
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- H—ELECTRICITY
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- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J3/00—Circuit arrangements for ac mains or ac distribution networks
- H02J3/38—Arrangements for parallely feeding a single network by two or more generators, converters or transformers
- H02J3/381—Dispersed generators
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- H02J2300/40—Systems for supplying or distributing electric power characterised by decentralized, dispersed, or local generation wherein a plurality of decentralised, dispersed or local energy generation technologies are operated simultaneously
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
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- Y02E60/30—Hydrogen technology
- Y02E60/36—Hydrogen production from non-carbon containing sources, e.g. by water electrolysis
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
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Abstract
The invention discloses a clean power-based zero-carbon power optimization planning system and an optimization method thereof, wherein the zero-carbon power optimization planning system comprises an electrified system, hydrogen energy, a house building, an advanced heat pump and an electric energy system, the electrified system comprises heating and refrigeration electrification, kitchen cooking electrification and traffic transportation comprehensive electrification, the electric energy system comprises nuclear energy, photovoltaic and wind power, the nuclear energy, the photovoltaic and the wind power are respectively provided with a novel electric power system, and the house building comprises a BIPV outer wall, a roof material and a building heat insulation material. The zero-carbon power optimization planning system based on clean power and the optimization method thereof solve the problems that zero-carbon power is small due to zero-carbon emission only through photovoltaic, wind energy and nuclear energy, the zero-carbon power is only used in some regions, and zero-carbon power is not achieved in other aspects except for the aspect of electric energy, so that zero-carbon power optimization planning is incomplete.
Description
Technical Field
The invention relates to the technical field of zero-carbon emission, in particular to a zero-carbon power optimization planning system based on clean power and an optimization method thereof.
Background
Zero carbon emission is not without carbon dioxide emission, but rather, the balance is achieved by supplementing equal amount of oxygen with natural ways such as tree planting and the like and balancing the carbon dioxide emitted by people. Zero carbon emissions, refers to activities that reduce pollutant emissions indefinitely up to zero. In terms of content, the method is to control the emission of wastes which must not be generated in the production process and reduce the emission to zero; secondly, the waste which is inevitably discharged is fully utilized, and finally, the existence of non-renewable resources and energy sources is eliminated. In terms of the process, the waste discharged in the production process of one industry is changed into raw materials or fuel of another industry, so that the related industry forms an industry ecosystem through recycling.
The existing zero-carbon emission is mainly concentrated on photovoltaic energy, wind energy and nuclear energy to use zero-carbon power, but only zero-carbon emission is carried out through the photovoltaic energy, the wind energy and the nuclear energy, so that the zero-carbon power is small, the zero-carbon power is only used in some regions, and besides the aspect of electric energy, the zero-carbon power is not realized in other aspects, so that the zero-carbon power optimization planning is incomplete.
Disclosure of Invention
Technical problem to be solved
Aiming at the defects of the prior art, the invention provides a zero-carbon power optimization planning system based on clean power and an optimization method thereof, and solves the problems that the zero-carbon power is mainly used in photovoltaic, wind energy and nuclear energy, but the zero-carbon power is only used in some regions due to zero-carbon emission only through the photovoltaic, wind energy and nuclear energy, and the zero-carbon power optimization planning is incomplete due to the fact that no zero-carbon power is available in other aspects except for the electric energy.
(II) technical scheme
In order to achieve the purpose, the invention is realized by the following technical scheme: the zero-carbon power optimization planning system based on clean power comprises a zero-carbon power optimization planning system, a comprehensive optimization new energy development system and a flexible lifting power regulation system, wherein the zero-carbon power optimization planning system comprises an electrification system, hydrogen energy, a house building, an advanced heat pump and an electric energy system;
the electrification system comprises heating and refrigeration electrification, kitchen cooking electrification and traffic transportation comprehensive electrification;
the electric energy system comprises nuclear energy, photovoltaic and wind power, and the nuclear energy, the photovoltaic and the wind power are provided with novel electric power systems;
the hydrogen energy comprises hydrogen production by water electrolysis, hydrogen production and hydrogen fuel;
the building construction comprises a BIPV outer wall, a roof material and a building heat-insulating material.
Preferably, the novel power system comprises a power generation unit, a power transmission unit, a power distribution unit and a storage unit.
Preferably, the storage unit comprises large-scale power station distribution energy storage and industrial and commercial distributed energy storage.
Preferably, the overall optimization new energy development system comprises area development and electric power construction, the area development is used for combining land and roof resources and promoting photovoltaic on-site development and utilization, the electric power construction is used for distributing a batch of power bases and electric power transmission channels which mainly use photovoltaic, extra-high voltage construction is accelerated, and mutual benefits of large power grid resources are brought into play.
Preferably, the hydrogen-producing hydrogen can be used for end energy consumption, and the hydrogen fuel can be used as traffic fuel.
Preferably, the BIPV outer wall is used for installing the solar photovoltaic power generation matrix on the outer surface of an enclosure structure of a building to provide power, and the building heat insulation material is used for taking measures on the enclosure structure outside the building, so that the indoor heat of the building is reduced to be dissipated outdoors, and the indoor temperature of the building is kept.
Preferably, the advanced heat pump is used in a device that will cause heat to flow from a low level heat source to a high level heat source.
Preferably, the power generation unit is used for finishing an instruction issued by an upper-layer dispatching mechanism and simultaneously ensuring that an energy conversion process can be safely and smoothly carried out, an effective power generation unit control strategy is designed to be very important for safe, stable and economic operation of the power generation unit and an electric power system, the power transmission unit is used for transmitting electric energy generated by a power station to each power utilization place through a power transmission line generally, different power transmission voltages are adopted according to the distance of transmitted electric energy, and the power distribution unit is used for calling a section of system from a step-down power distribution substation or a high-voltage power distribution substation to a user side in the electric power system as a power distribution system.
Preferably, the large-scale power station distribution energy storage and industrial and commercial distributed energy storage are used for power storage of zero-carbon power generation.
The invention also discloses a zero-carbon power optimization planning system based on clean power, and the optimization method comprises the following steps:
s1, electrification optimization, namely firstly, according to the area development in the overall optimization new energy development system, the areas are electrified by heating and cooling electrification, kitchen cooking electrification and comprehensive traffic transportation electrification in the electrification system, so that the industrial field with the requirement of medium and low temperature is electrified directly, in the aspect of electric power, renewable energy sources such as nuclear energy, photovoltaic and wind power can be completely utilized, electric power is produced in a zero carbon mode, a novel electric power system taking the new energy source as a main body is constructed, and hydrogen production by the renewable energy sources such as photovoltaic and the like is mutually coupled by deploying the scale application of an energy storage technology, so that the large-proportion clean substitution is realized;
s2, hydrogen energy is optimized, in the aspect of hydrogen energy, zero-carbon electric power can be used for electrolyzing water to prepare hydrogen, the hydrogen can also be used for terminal energy consumption, hydrogen fuel is developed to be used as power for transportation, and carbon dioxide generated by traditional electric power in the industry at present can also be reduced;
s3, building construction, wherein the BIPV outer wall, roof material, building heat insulation material and advanced heat pump technology in the building construction are widely adopted to realize energy production and elimination integrated zero-carbon building, the decarbonization in the heavy industry field can be realized by using the sealing technology and biological energy in the aspect of developing carbon capture, and finally, the utilization rate and recovery rate of key materials, such as cement, steel and plastic chemical industry, can be obviously improved;
s4, construction of zero-carbon power, firstly, a brand new novel power system is established, nuclear energy in the zero-carbon power is stored through large-scale power station distribution energy storage and industrial and commercial distributed energy storage which are arranged through storage units in the novel power system, photovoltaic and wind power are stored for resident electricity and commercial electricity, then high-voltage power is converted into low-voltage power through a power generation unit, the power can be safely and smoothly conducted, wherein the power transmission unit is used for electric energy sent out from a power station, the electric energy is generally sent to each electricity utilization place through a power transmission line, different power transmission voltages are adopted according to the distance of transmitted electric energy, and the power distribution unit safely transmits the electricity from a voltage reduction power distribution transformer substation or a high-voltage power distribution transformer substation outlet in the power system to a user for use.
Advantageous effects
The invention provides a clean power-based zero-carbon power optimization planning system and an optimization method thereof. Compared with the prior art, the method has the following beneficial effects:
1. the zero-carbon power optimization planning system based on clean power and the optimization method thereof enable the industrial field with medium and low temperature requirements to be electrified directly by carrying out regional development according to the regional development in the overall optimization new energy development system, and can completely utilize renewable energy sources such as nuclear energy, photovoltaic energy, wind power and the like to generate power in a zero-carbon mode in the aspect of power, construct a novel power system taking new energy as a main body, and realize mutual coupling of hydrogen production by renewable energy sources such as photovoltaic energy and the like through the scale application of the deployment energy storage technology, so that the problem that the existing zero-carbon emission is mainly concentrated on the photovoltaic energy, the wind energy and the nuclear energy to use the zero-carbon power is solved by realizing the large-proportion clean substitution in the electrified system, but only through photovoltaic, wind energy and nuclear energy carry out zero carbon emission, lead to zero carbon electric power less to and only obtain the use in some areas, except in the electric energy aspect, the zero carbon electric power is not done to other aspects, lead to the incomplete problem of zero carbon electric power optimal planning.
2. According to the zero-carbon power optimization planning system based on clean power and the optimization method thereof, hydrogen can be produced by electrolyzing water by using the zero-carbon power in the aspect of hydrogen energy, the hydrogen can also be used for terminal energy consumption, hydrogen fuel is developed to be used as power for transportation, and carbon dioxide generated by traditional power in the industry at present can also be reduced.
3. According to the zero-carbon power optimization planning system based on clean power and the optimization method thereof, the BIPV outer wall, the roof material, the building heat insulation material and the advanced heat pump technology in the house building are widely adopted, the energy production and elimination integrated zero-carbon building is realized, the carbon capture is developed, the decarburization in the heavy industry field can be realized by utilizing the sealing technology and the biological energy, and finally, the utilization rate and the recovery rate of key materials can be obviously improved, such as cement, steel, plastic chemical industry and the like, and the zero-carbon power can also be realized in the heavy industry field.
4. The zero-carbon power optimization planning system based on clean power and the optimization method thereof have the advantages that by establishing a brand-new novel power system, the nuclear energy, the photovoltaic energy and the wind power in the zero-carbon power are stored for resident electricity and commercial electricity through large-scale power station distribution energy storage and industrial and commercial distributed energy storage arranged in the storage unit in the novel power system, then the high-voltage power is converted into low-voltage power by the power generation unit, so that the power can be safely and smoothly carried out, wherein the power transmission unit is used for transmitting electric energy generated from a power station to each power utilization place through a power transmission line, according to the distance of the transmitted electric energy, different transmission voltages are adopted, and the power distribution unit safely transmits the electric energy from the outlet of the step-down power distribution substation or the high-voltage power distribution substation in the power system to the user for use, the power utilization and the power protection are better performed through a brand-new zero-carbon power system.
Drawings
FIG. 1 is a system diagram of the present invention;
FIG. 2 is a diagram of a new energy development system for integrated optimization according to the present invention;
FIG. 3 is a diagram of a zero-carbon power optimization planning system according to the present invention;
FIG. 4 is a diagram of the electrified system of the present invention;
FIG. 5 is a diagram of the power system of the present invention;
FIG. 6 is a block diagram of hydrogen energy in accordance with the present invention;
FIG. 7 is a block diagram of the building construction of the present invention;
FIG. 8 is a diagram of the novel power system of the present invention;
FIG. 9 is a diagram of a storage unit according to the present invention;
FIG. 10 is a flow chart of the optimization method of the present invention.
In the figure: 1. a zero-carbon power optimization planning system; 11. an electrified system; 114. heating and cooling electrification; 115. cooking and electrification in a kitchen; 116. traffic transportation is electrified comprehensively; 12. hydrogen energy; 121. electrolyzing water to prepare hydrogen; 122. hydrogen is used for preparing hydrogen; 123. a hydrogen fuel; 13. building a house; 131. a BIPV outer wall; 132. a roofing material; 133. building thermal insulation materials; 14. an advanced heat pump; 15. an electrical energy system; 151. nuclear energy; 152. photovoltaic; 153. wind power generation; 154. a novel power system; 1541. a power generation unit; 1542. a power transmission unit; 1543. a power distribution unit; 1544. a storage unit; 1546. large power station distribution and energy storage; 1547. industrial and commercial distributed energy storage; 2. comprehensively optimizing a new energy development system; 21. area development; 22. electric power construction; 3. promote the nimble governing system of electric power.
Detailed Description
The technical solutions in the embodiments of the present invention are clearly and completely described, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
Referring to fig. 1-2, an embodiment of the present invention provides a technical solution: zero carbon electric power optimization planning system based on clean electric power, including zero carbon electric power optimization planning system 1, overall optimization new forms of energy development system 2 and promote electric power nimble governing system 3, overall optimization new forms of energy development system 2 includes area development 21 and electric power construction 22, and area development 21 is used for combining land and roof resource, promotes the photovoltaic and utilizes on the spot, and electric power construction 22 is used for a batch of power bases and the electric power transmission path who uses the photovoltaic as the owner of overall arrangement for extra-high voltage construction, the mutual economy of the big electric wire netting resource of performance.
Referring to fig. 3, the zero-carbon power optimization planning system 1 includes an electrification system 11, a hydrogen energy 12, a building 13, an advanced heat pump 14 and an electric energy system 15, wherein the advanced heat pump 14 is used for flowing heat from a low-level heat source to a high-level heat source.
Referring to fig. 4, the electrification system 11 includes heating and cooling electrification 114, kitchen cooking electrification 115, and transportation full-scale electrification 116;
referring to fig. 5, the electric energy system 15 includes a nuclear energy 151, a photovoltaic 152 and a wind power 153, and the nuclear energy 151, the photovoltaic 152 and the wind power 153 are all provided with a novel electric power system 154;
referring to fig. 6, the hydrogen energy 12 includes hydrogen production 121 by water electrolysis, hydrogen production 122 and hydrogen fuel 123, the hydrogen production 122 may be used for terminal energy consumption, and the hydrogen fuel 123 may be used for traffic fuel.
Referring to fig. 7, the building 13 includes a BIPV exterior wall 131, a roof material 132 and a building insulation material 133, the BIPV exterior wall 131 is used for installing a solar photovoltaic power generation matrix on an outer surface of an enclosure of a building to provide power, and the building insulation material 133 is used for taking measures for the enclosure of the building to reduce indoor heat of the building from being dissipated to the outside, so as to maintain indoor temperature of the building.
Referring to fig. 8, the novel power system 154 includes a power generation unit 1541, a power transmission unit 1542, a power distribution unit 1543, and a storage unit 1544, where the storage unit 1544 includes large-scale power station distribution energy storage 1546 and industrial and commercial distributed energy storage 1547, the power generation unit 1541 is configured to complete an instruction issued by an upper-level dispatching mechanism, and simultaneously ensure that an energy conversion process can be performed safely, smoothly, and an effective power generation unit control strategy is designed to be crucial to safe, stable, and economic operation of the power generation unit itself and the power system, the power transmission unit 1542 is used for transmitting power from the power generation station to each power utilization place through a power transmission line, and according to a distance of transmitting power, different power transmission voltages are used, and the power distribution unit 1543 is configured to refer to a section of the power system from an outlet of a step-down power distribution substation or a high-voltage power distribution substation to a user side as a power distribution system, large utility power distribution energy storage 1546 and industrial and commercial distributed energy storage 1547 are used for power storage with zero carbon power generation.
Referring to fig. 10, an embodiment of the present invention provides a technical solution: the optimization planning system of the clean power-based zero-carbon power comprises the following steps:
s1, electrification optimization, namely firstly, carrying out area electrification 114, kitchen cooking electrification 115 and transportation comprehensive electrification 116 in the electrification system 11 according to area development 21 in the overall optimization new energy development system 2, so that the industrial field with medium and low temperature requirements is electrified directly, in the aspect of electric power, renewable energy sources such as nuclear energy 151, photovoltaic 152 and wind power 153 can be completely utilized, electric power is produced in a zero carbon mode, a novel electric power system with the new energy sources as main bodies is constructed, and hydrogen production from the renewable energy sources such as photovoltaic is mutually coupled by deploying scale application of an energy storage technology, so that large-proportion clean substitution is realized;
s2, hydrogen energy optimization, in the aspect of hydrogen energy 12, hydrogen 121 can be produced by electrolyzing water by using zero-carbon electric power, hydrogen 122 can be used for terminal energy consumption, hydrogen fuel 123 can be developed to be used as power for transportation, and carbon dioxide generated by traditional electric power in the industry at present can be reduced;
s3, building construction, wherein the BIPV outer wall 131, the roof material 132, the building heat insulation material 133 and the advanced heat pump 14 technology in the building construction 13 are widely adopted to realize energy production and elimination integrated zero-carbon building, and in the aspect of carbon capture development, decarburization in the heavy industrial field can be realized by using a sealing technology and biological energy, and finally, the utilization rate and the recovery rate of key materials, such as cement, steel, plastic and chemical industries, can be obviously improved;
s4, construction of zero-carbon power, firstly, a brand new novel power system 154 is built, large-scale power station distribution energy storage 1546 and industrial and commercial distributed energy storage 1547 which are arranged through a storage unit 1544 in the novel power system 154 are used for storing residential power and commercial power, and then high-voltage power is converted into low-voltage power through a power generation unit 1541, so that the power can be safely and smoothly carried out, wherein a power transmission unit 1542 is used for power generated from a power station, generally, the power is transmitted to each power utilization place through a power transmission line, different power transmission voltages are adopted according to the distance of transmitted power, and a power distribution unit 1543 is used for safely transmitting the power from a step-down power distribution substation or a high-voltage power distribution substation outlet in the power system to users for use.
And those not described in detail in this specification are well within the skill of those in the art.
It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.
Claims (10)
1. Zero carbon electric power optimization planning system based on clean electric power, including zero carbon electric power optimization planning system (1), overall optimization new forms of energy development system (2) and promotion electric power flexible regulation system (3), its characterized in that: the zero-carbon power optimization planning system (1) comprises an electrification system (11), hydrogen energy (12), a house building (13), an advanced heat pump (14) and an electric energy system (15);
the electrification system (11) comprises heating and cooling electrification (114), kitchen cooking electrification (115) and transportation comprehensive electrification (116);
the electric energy system (15) comprises nuclear energy (151), photovoltaic (152) and wind power (153), and the nuclear energy (151), the photovoltaic (152) and the wind power (153) are provided with novel electric power systems (154);
the hydrogen energy (12) comprises hydrogen production (121) by water electrolysis, hydrogen production (122) and hydrogen fuel (123);
the building construction (13) comprises a BIPV outer wall (131), a roofing material (132) and a building insulation material (133).
2. The clean power-based zero-carbon power optimization planning system of claim 1, wherein: the novel power system (154) includes a power generation unit (1541), a power transmission unit (1542), a power distribution unit (1543), and a storage unit (1544).
3. The clean power based zero-carbon power optimization planning system of claim 2, wherein: the storage units (1544) include large-scale power plant distribution energy storage (1546) and industrial-commercial distributed energy storage (1547).
4. The clean power-based zero-carbon power optimization planning system of claim 1, wherein: the integrated optimization new energy development system (2) comprises area development (21) and electric power construction (22), the area development (21) is used for combining land and roof resources to promote photovoltaic on-site development and utilization, and the electric power construction (22) is used for arranging a batch of power bases and electric power transmission channels which mainly use photovoltaic, so that extra-high voltage construction is accelerated, and mutual economy of large power grid resources is achieved.
5. The clean power-based zero-carbon power optimization planning system of claim 1, wherein: the hydrogen produced (122) may be used for end energy consumption and the hydrogen fuel (123) may be used for transportation fuel.
6. The clean power-based zero-carbon power optimization planning system of claim 1, wherein: the BIPV outer wall (131) is used for installing a solar photovoltaic power generation matrix on the outer surface of an enclosure structure of a building to provide power, and the building heat-insulating material (133) is used for taking measures on the enclosure structure of the building to reduce the indoor heat of the building to be dissipated outdoors, so that the indoor temperature of the building is kept.
7. The clean power-based zero-carbon power optimization planning system of claim 1, wherein: the advanced heat pump (14) is used in a device for flowing heat from a low level heat source to a high level heat source.
8. The clean power-based zero-carbon power optimization planning system of claim 1, wherein: the power generation unit (1541) is used for finishing instructions issued by an upper-layer scheduling mechanism, and meanwhile, the energy conversion process can be safely, stably and smoothly carried out, an effective power generation unit control strategy is designed to be very important for the safety, stability and economic operation of the power generation unit and a power system, the power transmission unit (1542) is used for electric energy sent out from a power station, the electric energy is generally sent to each power utilization place through a power transmission line, different power transmission voltages are adopted according to the distance of transmitted electric energy, and the power distribution unit (1543) is used for referring a section of system from a step-down power distribution substation or a high-voltage power distribution substation to a user end in the power system as a power distribution system.
9. The clean power-based zero-carbon power optimization planning system of claim 1, wherein: the large scale power plant distribution energy storage (1546) and industrial and commercial distributed energy storage (1547) are used for power storage of zero carbon power generation.
10. The clean power-based zero-carbon power optimization planning system according to any one of claims 1-9, wherein: the optimization method comprises the following steps:
s1, electrification optimization, namely, firstly, carrying out area development (21) in the overall optimization new energy development system (2) according to the overall optimization, electrifying heating and cooling (114), kitchen cooking electrification (115) and transportation comprehensive electrification (116) in the electrification system (11) to enable the industrial field with the requirement of medium and low temperature to be electrified directly, in the aspect of electric power, renewable energy sources such as nuclear energy (151), photovoltaic (152) and wind power (153) can be fully utilized, electric power is produced in a zero carbon mode, a novel electric power system taking the new energy sources as a main body is constructed, and by deploying the scale application of an energy storage technology, hydrogen production by the renewable energy sources such as the photovoltaic and the like is mutually coupled, so that a large-proportion of clean substitution is realized;
s2, hydrogen energy is optimized, in the aspect of hydrogen energy (12), zero-carbon electric power can be used for electrolyzing water to produce hydrogen (121), hydrogen production (122) can also be used for terminal energy consumption, hydrogen fuel (123) is developed to be used as power for transportation, and carbon dioxide generated by traditional electric power in the industry at present can also be reduced;
s3, building construction, wherein the BIPV outer wall (131), the roof material (132), the building heat insulation material (133) and the advanced heat pump (14) technology in the building construction (13) are widely adopted to realize energy production and elimination integrated zero-carbon building, the carbon capture is developed, the sealing technology and the biological energy can be used to realize decarburization in the heavy industrial field, and finally, the utilization rate and the recovery rate of key materials, such as cement, steel, plastic chemical industry and the like, can be remarkably improved;
s4, building zero-carbon electric power, firstly, establishing a brand-new novel electric power system (154), storing the nuclear energy (151), the photovoltaic energy (152) and the wind power (153) in the zero-carbon electric power by a large-scale power station distribution energy storage (1546) and an industrial and commercial distributed energy storage (1547) which are arranged on a storage unit (1544) in the novel electric power system (154), then the high-voltage power is converted into low-voltage power through the power generation unit (1541), so that the power can be safely and smoothly carried out, wherein the power transmission unit (1542) is used for transmitting power from the power station, and is generally transmitted to each power utilization place through a power transmission line, according to the distance of the transmitted electric energy, different transmission voltages are adopted, and the power distribution unit (1543) is used for safely transmitting the electric energy from the step-down power distribution substation or the high-voltage power distribution substation to users for use.
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