CN116404683A

CN116404683A - Energy regulation and control method, device, terminal and medium of flexible-direct interconnection system

Info

Publication number: CN116404683A
Application number: CN202310658964.4A
Authority: CN
Inventors: 刘津; 周莉超; 程树东; 金鑫; 郝宇强
Original assignee: Tianjin Bohai New Energy Technology Co ltd
Current assignee: Tianjin Bohai New Energy Technology Co ltd
Priority date: 2023-06-06
Filing date: 2023-06-06
Publication date: 2023-07-07
Anticipated expiration: 2043-06-06
Also published as: CN116404683B

Abstract

The application relates to the technical field of hybrid power distribution, in particular to an energy regulation and control method, device, terminal and medium of a flexible-direct interconnection system, wherein the method comprises the following steps: the method has the advantages that the operation data of each platform region in the flexible-straight interconnection system are monitored in real time, the platform region load rate is obtained, the energy regulation type is determined based on the platform region load rate and the regulation load threshold value of the abnormal load platform region, and the complexity of regulation operation can be reduced by adopting different energy regulation types according to different load conditions of the abnormal load platform region. And when the energy regulation type is inter-station transfer, transfer analysis is performed based on the station load rate corresponding to each normal load station, transfer information corresponding to the transfer station and the transfer station is determined, and the transfer information is sent to a corresponding transfer station control end. The transfer supply area and transfer supply information determined through transfer supply analysis can enable the energy regulation and control of the flexible and straight interconnection system to be more consistent with the actual situation of the area, and the electric energy quality of the flexible and straight interconnection system is improved.

Description

Energy regulation and control method, device, terminal and medium of flexible-direct interconnection system

Technical Field

The application relates to the technical field of hybrid power distribution, in particular to an energy regulation and control method, device, terminal and medium of a flexible-direct interconnection system.

Background

The distribution area is one of the important components of the power system, and directly affects the local economic development and the daily life quality of users. Most of the existing transformer areas adopt the forms of single transformer and single line power supply, namely, the power supply among the transformer areas is independent and lacks unified management and control, however, with the promotion of rural electrified engineering, the requirements of users for power supply reliability of the transformer areas in rural areas are increasingly improved. In addition, with the increasing of direct current loads such as electric automobile charging stations, data centers, direct current household appliances, communication equipment and the like and the high-proportion and large-capacity scattered access of direct current distributed power sources such as photovoltaics and the like, the current distribution network source-load-storage direct current characteristics are more obvious. Therefore, the mode of single transformer and single line power supply is adopted, and the independent mode of power supply between stations can not meet the current power consumption requirement.

In the related art, unified control of a plurality of areas is realized by using a flexible direct current technology interconnection method, namely, a feeder line group flexible direct current interconnection micro-grid and a station group alternating current-direct current hybrid micro-grid are built through a flexible direct current transmission technology. However, since the scene and the precedent of realizing the load balance and supply-demand interaction of the distribution area by adopting the flexible direct current technology interconnection are in the demonstration verification stage, the energy regulation method between the areas is preset by related technicians based on experience, and a set of energy regulation method for the flexible direct current technology interconnection with high power supply quality is not available, so that the ever-increasing requirements of the electric capacity, the high reliability and the direct current characteristics cannot be met.

Thus, how to provide a high quality energy modulation method is a problem to be solved by those skilled in the art.

Disclosure of Invention

The application aims to provide an energy regulation and control method, device, terminal and medium of a flexible-straight interconnection system, which are used for solving at least one technical problem.

The above object of the present application is achieved by the following technical solutions:

in a first aspect, the present application provides an energy regulation method for a flexible-direct interconnection system, which adopts the following technical scheme:

an energy regulation and control method of a flexible-straight interconnection system, comprising the following steps:

acquiring operation data of each platform region in the flexible-straight interconnection system, and performing platform region operation monitoring based on the operation data of each platform region to obtain a platform region load rate corresponding to each platform region;

determining an abnormal load platform area from all the platform areas based on the platform area load rate and the abnormal load threshold value corresponding to each platform area;

determining an energy regulation type corresponding to the abnormal load zone based on the zone load rate and the regulation load threshold corresponding to the abnormal load zone, wherein the energy regulation type comprises: regulating and controlling the photovoltaic energy storage equipment and transferring between stations;

When the energy regulation type is the inter-station transfer, transfer analysis is carried out based on the station load rate corresponding to each normal load station, a transfer station is determined from all normal load stations, and transfer information corresponding to the transfer station is determined;

and sending the transfer information to a corresponding transfer area control end to complete energy regulation and control of the flexible-direct interconnection system, wherein the transfer area control end is used for executing energy transfer operation.

By adopting the technical scheme, the platform region load rate of each platform region is obtained by monitoring the operation data of each platform region in the flexible and straight interconnection system in real time, the energy regulation type is determined based on the platform region load rate and the regulation load threshold corresponding to the abnormal load platform region, and the complexity of operation can be reduced to a certain extent by adopting different energy regulation types according to different load conditions of the abnormal load platform region. And when the energy regulation type is inter-station transfer, transfer analysis is performed based on the station load rate corresponding to each normal load station, transfer information corresponding to the transfer station and the transfer station is determined, and the transfer information is sent to a corresponding transfer station control end so as to complete energy regulation of the flexible and straight interconnection system. The transfer supply area and transfer supply information determined through transfer supply analysis can enable energy regulation and control of the flexible and straight interconnection system to be more consistent with actual conditions of the area, and further, the electric energy quality of the flexible and straight interconnection system is improved.

The present application may be further configured in a preferred example to: the determining the energy regulation type corresponding to the abnormal load area based on the area load rate and the energy regulation strategy corresponding to the abnormal load area comprises the following steps:

comparing the sizes of the abnormal load areas based on the area load rate and the regulation load threshold value corresponding to the abnormal load areas;

when the load rate of the station area is larger than the regulation load threshold, determining that the energy regulation type corresponding to the abnormal load station area is inter-station transfer, wherein the inter-station transfer is used for realizing inter-station energy sharing;

and when the load rate of the platform region is not greater than the regulation load threshold, determining that the energy regulation type corresponding to the abnormal load platform region is regulation of the photovoltaic energy storage equipment, wherein the regulation of the photovoltaic energy storage equipment is to realize load balancing among the platform regions through the photovoltaic and/or energy storage equipment.

The present application may be further configured in a preferred example to: the transferring analysis is performed based on the load rate of the station area corresponding to each normal load station area, the transferring station area is determined from all the normal load station areas, transferring information corresponding to the transferring station area is determined, and the transferring analysis comprises the following steps:

when only one abnormal load station area exists, carrying out transfer analysis based on the station area load rate corresponding to each normal load station area and the station area load rate corresponding to the abnormal load station area according to the principle of the minimum number of transfer station areas, determining transfer station areas from all the normal load station areas, and determining transfer information corresponding to the transfer station areas, wherein the transfer information comprises: power and voltage are transferred;

When at least two abnormal load areas exist, comprehensive analysis is carried out based on the area load rate corresponding to each abnormal load area, so that comprehensive abnormal load characteristics are obtained;

and carrying out transfer analysis based on the load rate of the station area corresponding to each normal load station area and the comprehensive abnormal load characteristics, determining a transfer station area from all the normal load station areas, and determining transfer information corresponding to the transfer station area.

The present application may be further configured in a preferred example to: further comprises:

when a platform area maintenance instruction carrying a platform area to be maintained is received, historical operation data corresponding to each platform area are obtained, maintenance period load prediction is carried out based on the historical operation data corresponding to each platform area, and first predicted load information of the platform area to be maintained and second predicted load information of the working platform area corresponding to the platform area maintenance instruction are obtained;

and carrying out overhaul period regulation analysis based on the first predicted load information and the second predicted load information, determining overhaul energy regulation information, and sending the overhaul energy regulation information to an overhaul regulation platform region terminal so as to finish energy regulation of a platform region in an overhaul period.

The present application may be further configured in a preferred example to: after the energy regulation type corresponding to the abnormal load area is determined, the method further comprises the following steps:

When the energy regulation type is that the photovoltaic energy storage equipment regulates, reverse power supply information of reverse power supply equipment in the flexible-direct interconnection system is obtained, wherein the reverse power supply equipment comprises: photovoltaic and energy storage devices;

selecting target reverse power supply equipment from all the reverse power supply equipment based on the platform load rate corresponding to the abnormal load platform and the reverse power supply information of the reverse power supply equipment, and determining power supply control information corresponding to the target reverse power supply equipment;

and sending the power supply control information to corresponding target reverse power supply equipment to complete energy regulation and control of the flexible-direct interconnection system.

The present application may be further configured in a preferred example to: when the reverse power supply equipment is photovoltaic, the reverse power supply information of the reverse power supply equipment in the flexible-direct interconnection system is obtained, and the method comprises the following steps:

acquiring historical weather information and historical power generation information corresponding to the reverse power supply equipment, and carrying out photovoltaic power generation prediction based on the historical weather information, the historical power generation information and target weather information to obtain a prediction power generation curve corresponding to the reverse power supply equipment;

and determining reverse power supply information of the reverse power supply equipment based on the predicted power generation curve and a target period, wherein the target period is a period of the regulation and control process of the photovoltaic energy storage equipment.

The present application may be further configured in a preferred example to: after the transfer information is sent to the corresponding transfer station control end to complete the energy regulation of the flexible-direct interconnection system, the method further comprises the following steps:

acquiring historical total electricity consumption information of the flexible and straight interconnection system, and carrying out electricity consumption analysis on the flexible and straight interconnection system based on the total electricity consumption information to determine load characteristics, wherein the total electricity consumption information is determined by integrating the electricity consumption information corresponding to each area in the flexible and straight interconnection system;

acquiring electricity consumption cost information, managing working states of the energy storage equipment based on the electricity consumption cost information and the load characteristics, and determining working information of the energy storage equipment, wherein the working information comprises the following components: a charging period and a discharging period.

In a second aspect, the present application provides an energy regulation device of a flexible-straight interconnection system, which adopts the following technical scheme:

an energy management device for a flexible-straight interconnect system, comprising:

the operation monitoring module is used for acquiring operation data of each platform region in the flexible-straight interconnection system, and performing platform region operation monitoring based on the operation data of each platform region to obtain a platform region load rate corresponding to each platform region;

The abnormal load zone determining module is used for determining abnormal load zones from all zones based on the zone load rate and the abnormal load threshold value corresponding to each zone;

the energy regulation type determining module is used for determining the energy regulation type corresponding to the abnormal load platform region based on the platform region load rate and the regulation load threshold value corresponding to the abnormal load platform region, wherein the energy regulation type comprises: regulating and controlling the photovoltaic energy storage equipment and transferring between stations;

the transfer supply analysis module is used for carrying out transfer supply analysis based on the platform area load rate corresponding to each normal load platform area when the energy regulation type is the inter-platform transfer supply, determining transfer supply platform areas from all the normal load platform areas, and determining transfer supply information corresponding to the transfer supply platform areas;

and the energy regulation and control module is used for sending the transfer information to a corresponding transfer platform area control end so as to finish the energy regulation and control of the flexible-direct interconnection system, wherein the transfer platform area control end is used for executing energy transfer operation.

In a third aspect, the present application provides a flexible and straight interconnection measurement and control terminal, which adopts the following technical scheme:

at least one processor;

a memory;

at least one application program, wherein the at least one application program is stored in the memory and configured to be executed by the at least one processor, the at least one application program configured to: and executing the energy regulation and control method of the flexible-straight interconnection system.

In a fourth aspect, the present application provides a computer readable storage medium, which adopts the following technical scheme:

a computer readable storage medium having stored thereon a computer program which, when executed in a computer, causes the computer to perform the energy management method of the flexible direct interconnect system described above.

In summary, the present application includes at least one of the following beneficial technical effects:

the platform region load rate of each platform region is obtained by monitoring the operation data of each platform region in the flexible and straight interconnection system in real time, the energy regulation type is determined based on the platform region load rate and the regulation load threshold corresponding to the abnormal load platform region, and the complexity of operation can be reduced to a certain extent by adopting different energy regulation types according to different load conditions of the abnormal load platform region. And when the energy regulation type is inter-station transfer, transfer analysis is performed based on the station load rate corresponding to each normal load station, transfer information corresponding to the transfer station and the transfer station is determined, and the transfer information is sent to a corresponding transfer station control end so as to complete energy regulation of the flexible and straight interconnection system. The transfer supply area and transfer supply information determined through transfer supply analysis can enable energy regulation and control of the flexible and straight interconnection system to be more consistent with actual conditions of the area, and further, the electric energy quality of the flexible and straight interconnection system is improved.

And carrying out maintenance period load prediction based on historical operation data corresponding to each platform region, carrying out maintenance period regulation analysis based on the first prediction load information and the second prediction load information, determining maintenance energy regulation information, and sending the maintenance energy regulation information to a maintenance regulation platform region terminal, so that the maintenance regulation platform region terminal carries out energy sharing according to the maintenance energy regulation information to complete energy regulation of the platform region during maintenance, further, the purpose of not cutting off power during maintenance of the platform region is achieved, and the stability of power supply of a flexible and straight interconnection system is improved.

Drawings

FIG. 1 is a schematic flow chart of a method for energy regulation of a flexible-direct-interconnection system according to an embodiment of the present application;

FIG. 2a is a schematic flow chart of an abnormal load zone transition analysis according to one embodiment of the present application;

FIG. 2b is a flow chart of at least two abnormal load zones for analysis according to one embodiment of the present application;

FIG. 3 is a schematic structural diagram of an energy management device of a flexible-direct-interconnection system according to an embodiment of the present application;

fig. 4 is a schematic structural diagram of a flexible-direct interconnection measurement and control terminal according to an embodiment of the present application.

Detailed Description

The present application is described in further detail below in conjunction with fig. 1-4.

The present embodiment is merely illustrative of the present application and is not intended to be limiting, and those skilled in the art, after having read the present specification, may make modifications to the present embodiment without creative contribution as required, but is protected by patent laws within the scope of the present application.

For the purposes of making the objects, technical solutions and advantages of the embodiments of the present application more clear, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is apparent that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments herein without making any inventive effort, are intended to be within the scope of the present application.

In addition, the term "and/or" herein is merely an association relationship describing an association object, and means that three relationships may exist, for example, a and/or B may mean: a exists alone, A and B exist together, and B exists alone. In this context, unless otherwise specified, the term "/" generally indicates that the associated object is an "or" relationship.

Embodiments of the present application are described in further detail below with reference to the drawings attached hereto.

In the related art, the residual capacity of the adjacent stations is shared by using a flexible direct current technology interconnection method, namely, a plurality of adjacent stations are connected to form a micro-grid, energy sharing can be performed between each station in the micro-grid, the condition of unbalanced load rate between adjacent stations is relieved to a certain extent, and the utilization efficiency of energy sources is improved to a certain extent. However, since the flexible direct current technology is adopted to interconnect to realize the load balance and supply-demand interaction of the distribution area, and the scene and precedent of the supply-demand interaction are in the demonstration verification stage, the energy regulation method between the areas is preset by related technicians based on experience, and the situation that the energy sharing between the areas is not scientific and the electric energy quality is poor often occurs, and the ever-increasing electric capacity, high reliability requirement and direct current characteristic cannot be met.

Therefore, the embodiment of the application provides an energy regulation and control method of a flexible-straight interconnection system, which is used for monitoring operation data of each platform region in the flexible-straight interconnection system in real time and determining an energy regulation and control type based on a platform region load rate and a regulation and control load threshold corresponding to an abnormal load platform region, wherein the energy regulation and control type comprises the following steps: photovoltaic energy storage equipment regulation and control and inter-platform transfer. Aiming at different load conditions of an abnormal load platform area, different energy regulation and control types are adopted, so that the complexity of operation can be reduced to a certain extent. And when the energy regulation type is inter-station transfer, transfer analysis is performed based on the station load rate corresponding to each normal load station, a transfer station is determined from all normal load stations, transfer information corresponding to the transfer station is determined, and transfer information is sent to a corresponding transfer station control end so as to complete energy regulation of the flexible-direct interconnection system. The transfer supply area and transfer supply information determined through transfer supply analysis can enable energy regulation and control of the flexible and straight interconnection system to be more consistent with actual conditions of the area, and further, the electric energy quality of the flexible and straight interconnection system is improved.

The embodiment of the application provides an energy regulation and control method of a flexible-straight interconnection system, which is executed by a flexible-straight interconnection measurement and control terminal, wherein the flexible-straight interconnection measurement and control terminal can be a server or terminal equipment, and the server can be an independent physical server, a server cluster or a distributed system formed by a plurality of physical servers, or a cloud server for providing cloud computing service. The terminal device may be a smart phone, a tablet computer, a notebook computer, a desktop computer, or the like, but is not limited thereto, and the terminal device and the server may be directly or indirectly connected through a wired or wireless communication manner, which is not limited herein, and as shown in fig. 1, the method includes steps S101, S102, S103, S104, and S105, where:

step S101: and acquiring operation data of each platform region in the flexible and straight interconnection system, and performing platform region operation monitoring based on the operation data of each platform region to obtain a platform region load rate corresponding to each platform region.

For the embodiment of the application, the flexible direct-current interconnection system connects a plurality of adjacent areas by using a flexible direct-current technology interconnection method to form a micro-grid, energy sharing can be carried out among all areas in the micro-grid, self-management, self-balancing and self-adjustment of the micro-grid can be realized to a certain extent, and energy utilization efficiency is improved, wherein the flexible direct-current interconnection system not only comprises a plurality of adjacent areas, but also comprises equipment in each area, and of course, photovoltaic equipment, energy storage equipment and the like. The operation data of the platform area is data representing the operation condition of the platform area, and at least comprises the following steps: current, voltage, power, frequency, ramp, power factor, etc., although other data may be included, embodiments of the present application are not limited. Furthermore, the operation of the areas is monitored based on the operation data of each area to obtain an area load rate corresponding to each area, wherein the area load rate is used for representing the load condition of the areas, the operation of the area equipment is affected by the higher area load rate, and the full utilization of energy in the areas is affected by the lower area load rate.

Step S102: and determining an abnormal load platform area from all the platform areas based on the platform area load rate and the abnormal load threshold value corresponding to each platform area.

For the embodiment of the application, based on the platform area load rate and the abnormal load threshold value corresponding to each platform area, determining at least one abnormal load platform area from all the platform areas, and specifically, determining that the platform area is the abnormal load platform area when the load rate of the platform area is greater than the abnormal load threshold value; and when the load rate of the platform area is not greater than the abnormal load threshold value, determining to be a normal load platform area, namely selecting an abnormal load platform area needing to reduce the load rate from all the platform areas. The abnormal load threshold is determined by the related technicians based on a large number of experimental operations, and of course, the user can also set the abnormal load threshold by himself according to actual conditions, and the abnormal load threshold is preferably selected to be 50%.

Step S103: determining an energy regulation type corresponding to the abnormal load platform region based on the platform region load rate and the regulation load threshold corresponding to the abnormal load platform region, wherein the energy regulation type comprises: photovoltaic energy storage equipment regulation and control and inter-platform transfer.

For the embodiments of the present application, the energy modulation types include: the photovoltaic energy storage equipment regulation and control and inter-station transfer supply are based on reverse power supply of the photovoltaic equipment and the energy storage equipment in the flexible-direct interconnection system to the abnormal load station so as to reduce the load rate of the abnormal load station; the inter-station transfer is to transfer energy to an abnormal load station area through a station area with lower station area load rate in the flexible-direct interconnection system so as to realize load balancing among stations. However, different energy regulation and control types have respective characteristics, and are simpler to operate compared with the inter-platform transfer supply for regulating and controlling the photovoltaic energy storage equipment, but the photovoltaic equipment and the energy storage equipment store limited electric energy, so that the method is more suitable for the condition of small abnormal degree of the load rate of the platform; for inter-station transfer, transfer operation is complex, and transfer control is difficult, that is, power transfer is performed to an abnormal load station by using a normal load station, which may cause an increase in load rate of the normal load station, and thus, the abnormal load station is formed. Therefore, a regulation and control load threshold is set in the embodiment of the application, and when the platform load rate of the abnormal load platform is not higher than the regulation and control load threshold, the energy regulation and control type is determined to be photovoltaic energy storage equipment regulation and control; and when the load rate of the abnormal load station area is higher than the regulation load threshold, determining that the energy regulation type is inter-station transfer. The regulation load threshold is determined by a related technician based on a large amount of experimental verification, and a user can also set the regulation load threshold according to actual requirements, preferably, the regulation load threshold is selected to be 70%.

Step S104: when the energy regulation type is inter-station transfer, transfer analysis is performed based on the station load rate corresponding to each normal load station, a transfer station is determined from all the normal load stations, and transfer information corresponding to the transfer station is determined.

For the embodiment of the application, when the energy regulation type is inter-station transfer, the overload condition of the abnormal load station is serious, and the energy regulation type is determined to be inter-station transfer because the photovoltaic equipment and the energy storage equipment in the flexible-direct interconnection system have weaker reverse power supply regulation and control capability. Furthermore, transfer analysis is performed based on the load rate of the areas corresponding to each normal load area, transfer information corresponding to the transfer areas and transfer information corresponding to the transfer areas are determined, various transfer analysis modes exist, and different types of transfer analysis can be adopted for different numbers of abnormal load areas. When the energy regulation type is photovoltaic energy storage equipment regulation, the photovoltaic equipment and/or the energy storage equipment in the flexible-straight interconnection system are/is controlled to supply power reversely to the abnormal load platform area, so that the energy regulation of the flexible-straight interconnection system is completed, and the load balance between adjacent platform areas is realized.

In one case, when the number of abnormal load areas is one, selecting a normal load area with the lowest area load rate as a transfer area, and performing transfer analysis based on operation data of the transfer area to determine transfer information, wherein the transfer information includes but is not limited to: converting voltage and converting power. However, it may not be possible to meet the needs of the abnormal load areas by using only the normal load area with the lowest area load ratio as the transfer area, and preferably, the transfer analysis is performed based on the area load ratio corresponding to each normal load area and the area load ratio corresponding to the abnormal load area according to the principle of minimum transfer area number, where the principle of minimum transfer area number is used to minimize the number of transfer areas, and reduce the complexity of transfer operation as much as possible. In another case, when the number of the abnormal load areas is multiple, transfer analysis of a single area can be performed based on each abnormal load area to obtain transfer areas and transfer information corresponding to each abnormal load area, and the transfer areas and transfer information of each abnormal load area are synthesized to determine the transfer areas and transfer information corresponding to the flexible and straight interconnection system. However, when the number of the abnormal load areas is large, the transfer analysis is performed on each abnormal load area, so that not only is a high requirement on the analysis capability of the flexible-direct interconnection measurement and control terminal provided, but also the transfer area and transfer information of each abnormal load area are difficult to integrate. Preferably, when the number of the abnormal load areas is multiple, comprehensive analysis is performed firstly based on the area load rate corresponding to each abnormal load area to obtain comprehensive abnormal load characteristics corresponding to the flexible-direct interconnection system, then transfer analysis is performed based on the area load rate corresponding to each normal load area and the comprehensive abnormal load characteristics, transfer areas are determined from all normal load areas, transfer information corresponding to the transfer areas is determined, and it is easy to know that the transfer areas and the transfer information determined herein are for the whole flexible-direct interconnection system.

Step S105: and sending the transfer information to a corresponding transfer area control end so as to complete energy regulation and control of the flexible-direct interconnection system, wherein the transfer area control end is used for executing energy transfer operation.

For the embodiment of the application, each transfer station area corresponds to a transfer station area control end, and the transfer station area control end is used for controlling the transfer station area to perform energy transfer operation, specifically, after transfer information is sent to the transfer station area control end, the transfer station area control end controls the transfer station area to perform energy transfer to the abnormal load station area according to the transfer information.

Therefore, in the embodiment of the application, the platform region load rate of each platform region is obtained by monitoring the operation data of each platform region in the flexible and straight interconnection system in real time, the energy regulation type is determined based on the platform region load rate and the regulation load threshold corresponding to the abnormal load platform region, and the complexity of operation can be reduced to a certain extent by adopting different energy regulation types according to different load conditions of the abnormal load platform region. And when the energy regulation type is inter-station transfer, transfer analysis is performed based on the station load rate corresponding to each normal load station, transfer information corresponding to the transfer station and the transfer station is determined, and the transfer information is sent to a corresponding transfer station control end so as to complete energy regulation of the flexible and straight interconnection system. The transfer supply area and transfer supply information determined through transfer supply analysis can enable energy regulation and control of the flexible and straight interconnection system to be more consistent with actual conditions of the area, and further, the electric energy quality of the flexible and straight interconnection system is improved.

Further, in order to make the flexible-direct interconnection system operate simply and have higher stability when energy sharing is performed, in the embodiment of the present application, determining, based on a platform load rate and an energy regulation policy corresponding to an abnormal load platform, an energy regulation type corresponding to the abnormal load platform includes:

comparing the sizes of the platform region load rates and the regulation load threshold values corresponding to the abnormal load platform region;

when the load rate of the platform region is not greater than the regulation load threshold, determining that the energy regulation type corresponding to the abnormal load platform region is photovoltaic energy storage equipment regulation, wherein the photovoltaic energy storage equipment regulation is to realize load balancing among the platform regions through photovoltaic and/or energy storage equipment.

For the embodiments of the present application, the energy modulation types include: the photovoltaic energy storage equipment regulates and controls and the inter-platform supplies are transferred, and the photovoltaic energy storage equipment regulates and controls the type to have the characteristics corresponding to each other according to different energy, so that the embodiment of the application adopts different energy regulation and control types according to the abnormal load platform areas with different platform area load rates, and the flexible and straight interconnection system is simple to operate when energy sharing is carried out, and is higher in stability.

For regulation and control of the photovoltaic energy storage equipment, the operation is simpler than the transfer between the stations, but the photovoltaic equipment and the energy storage equipment are limited in stored electric energy, so that the method is more suitable for the condition of small abnormal degree of the load rate of the stations; for inter-station transfer, transfer operation is complex, and transfer control is difficult, that is, power transfer is performed to an abnormal load station by using a normal load station, which may cause an increase in load rate of the normal load station, and thus, the abnormal load station is formed. Therefore, a regulation and control load threshold is set in the embodiment of the application, and when the platform load rate of the abnormal load platform is not higher than the regulation and control load threshold, the energy regulation and control type is determined to be photovoltaic energy storage equipment regulation and control; and when the load rate of the abnormal load station area is higher than the regulation load threshold, determining that the energy regulation type is inter-station transfer. Through the mode, when the photovoltaic energy storage equipment is regulated and controlled to finish inter-platform load balancing, the mode of regulating and controlling the photovoltaic energy storage equipment is preferably selected, the operation difficulty is reduced in regulation and control operation, and inter-platform transfer is selected for an abnormal load platform with high platform load rate, so that the power supply stability of the flexible and straight interconnection system is ensured to a certain extent. The regulation load threshold is determined by a related technician based on a large amount of experimental verification, and a user can also set the regulation load threshold according to actual requirements, preferably, the regulation load threshold is selected to be 70%.

Therefore, in the embodiment of the application, different energy regulation and control types are adopted for abnormal load areas with different area load rates, so that the flexible and straight interconnection system is simple to operate when energy sharing is performed, and the stability is higher.

Further, in order to reduce complexity of transfer operation, in the embodiment of the present application, as shown in fig. 2a and fig. 2b, transfer analysis is performed based on a zone load rate corresponding to each normal load zone, a transfer zone is determined from all normal load zones, and transfer information corresponding to the transfer zone is determined, including: step S1041-step S1043, wherein:

step S1041: when only one abnormal load station area exists, according to the principle of minimum transfer station area quantity, transfer analysis is carried out based on the station area load rate corresponding to each normal load station area and the station area load rate corresponding to the abnormal load station area, a transfer station area is determined from all the normal load station areas, transfer information corresponding to the transfer station area is determined, wherein the transfer information comprises: power and voltage are transferred.

For the embodiment of the present application, the principle of the minimum number of transfer areas is used to minimize the number of transfer areas, so as to reduce the complexity of transfer operation as much as possible, and therefore, transfer analysis is performed based on the area load rate corresponding to each normal load area and the area load rate corresponding to the abnormal load area, so as to determine at least one transfer area and transfer information corresponding to each transfer area. For the specific rule of the principle of minimum number of transfer areas, the embodiment of the application is not limited any more, as long as the number of transfer areas can be minimized. Preferably, the normal load area sequences with the area load rates from low to high are obtained based on the inverse sequence arrangement of the area load rates corresponding to all the normal load areas, then the normal load areas are selected one by one from the normal load area sequences, the shared electric energy is calculated based on the area load rates, the area rated capacity and the abnormal load threshold values of the normal load areas, the shared electric energy of the normal load areas is determined, and meanwhile, the electric energy demand is calculated based on the area load rates, the area rated capacity and the abnormal load threshold values of the abnormal load areas, and the electric energy demand of the abnormal load areas is determined. Further, whether the sharing demand of a normal load area is greater than the demand energy is determined, and when the sharing demand is greater than the demand energy, the normal load area is determined to be a transfer area, and transfer information is determined according to operation data of the transfer area, wherein the transfer information includes but is not limited to: the power supply voltage and power supply power are converted, and reasonable power supply information can guarantee the stability of power supply of the flexible-direct interconnection system to a certain extent. When the total shared electric energy of the two normal load areas is larger than the required electric energy, determining the two normal load areas as transfer areas and determining transfer information; and when the power consumption is not greater than the required power consumption, continuously selecting the next normal load platform area until the revolution platform area can meet the requirement of the abnormal load platform area.

Step S1042: when at least two abnormal load areas exist, comprehensive analysis is carried out based on the area load rate corresponding to each abnormal load area, so that comprehensive abnormal load characteristics are obtained;

step S1043: and carrying out transfer analysis based on the load rate of the station area corresponding to each normal load station area and the comprehensive abnormal load characteristics, determining a transfer station area from all the normal load station areas, and determining transfer information corresponding to the transfer station area.

For the embodiment of the application, required electric quantity calculation is performed on all abnormal load areas based on the area load rate, the area rated capacity and the abnormal load threshold value corresponding to each abnormal load area, and total required electric energy corresponding to all abnormal load areas in the flexible-direct interconnection system is determined, wherein the comprehensive abnormal load characteristics comprise: total required electric energy and required electric energy corresponding to each abnormal load area. Meanwhile, the shared electric energy corresponding to each normal load station area is calculated one by one according to the sequence of the normal load station areas, and then, a transfer station area is determined from all the normal load station areas according to the total required electric energy and each shared electric energy, wherein the total shared electric energy corresponding to the transfer station area is larger than the total required electric energy. And further, determining transfer information according to the operation data of the transfer area.

When at least two abnormal load areas exist for transfer analysis, after the transfer areas are determined from all normal load areas, preferably, custom transfer analysis is performed for each abnormal load area, and transfer information corresponding to each abnormal load area is determined. Specifically, the preferred transfer platform area corresponding to each abnormal load platform area is determined based on matching between the required electric energy of each abnormal load platform area and the shared electric energy of each normal load platform area, and the transfer platform area is determined by all the preferred transfer platform areas, wherein the preferred transfer platform area is composed of at least one normal load platform area, the difference value between the total shared electric energy corresponding to the preferred transfer platform area and the required electric energy of the abnormal load platform area is smaller than a difference value threshold, which is determined by a person skilled in the art based on experiments, and the user can also set the transfer platform area by himself based on actual conditions. The optimal transfer platform area with high matching degree is determined for each abnormal load platform area, so that the finally determined transfer platform area can better meet the requirements of all abnormal load platform areas in the flexible-direct interconnection system.

Therefore, in the embodiment of the present application, when only one abnormal load zone exists, transfer analysis is performed according to the principle of least number of transfer zones, transfer information corresponding to the transfer zones and the transfer zones is determined, and the principle of least number of transfer zones is used to minimize the number of transfer zones, so that complexity of transfer operation can be reduced as much as possible. When at least two abnormal load areas exist, comprehensive analysis is performed based on the area load rate corresponding to each abnormal load area, transfer analysis is performed based on the area load rate corresponding to each normal load area and the comprehensive abnormal load characteristics, transfer information corresponding to the transfer areas is determined, transfer analysis is performed through the comprehensive abnormal load characteristics, the number of times of transfer analysis can be reduced, and the finally determined transfer areas can better meet the requirements of all abnormal load areas in the flexible-direct interconnection system.

Further, in order to improve the stability of power supply of the flexible-direct interconnection system, in this embodiment of the present application, the method further includes:

and carrying out overhaul period regulation analysis based on the first predicted load information and the second predicted load information, determining overhaul energy regulation information, and sending the overhaul energy regulation information to an overhaul regulation platform area terminal so as to finish energy regulation of the platform area in the overhaul period.

For the embodiment of the present application, the above execution procedure may be before or after any of step S101 to step S104, and the embodiment of the present application is not limited in terms of the execution sequence. The power distribution transformer area is one of important components of the power system, and directly affects local economic development and daily life quality of users, so that regular maintenance for the transformer area is indispensable, and of course, the transformer area can be maintained when abnormal operation of the transformer area is detected, and the embodiment of the application is not limited for maintenance time period and triggering conditions. In the flexible-straight interconnection system, a platform area to be overhauled is called a platform area to be overhauled, other platform areas are called working platform areas, so that when a platform area overhauling instruction is received, the overhauling time length of the platform area is determined according to the historical overhauling conditions of the platform areas, overhauling time period load prediction is carried out on the basis of the historical operation data and overhauling time length of each platform area, and first predicted load information of the platform area to be overhauled and second predicted load information of the working platform area are determined, wherein the first predicted load information and the second predicted load information at least comprise: and predicting the load rate of the station area and the rated capacity of the station area. The load rate of the transformer area in the overhaul period is changed, so that the highest load rate of the transformer area in the overhaul period is selected as the predicted load rate of the transformer area.

Furthermore, the required electric quantity calculation is carried out in the overhaul period based on the predicted load rate of the area and the rated capacity of the area in the first predicted load information, and the required electric energy of the area to be overhauled in the overhaul period is determined; and calculating the shared electric quantity based on the predicted load rate of the station area, the rated capacity of the station area and the abnormal load threshold value in the second predicted load information, and determining the shared electric energy of each working station area corresponding to the maintenance period. Then, performing repair period regulation analysis based on the required electric energy of the to-be-repaired area in the repair period and the shared electric energy of the working area, and determining repair energy regulation information, wherein the energy regulation information comprises, but is not limited to: the overhaul regulation and control area, overhaul regulation and control time length and overhaul control information are easy to understand, wherein the overhaul regulation and control area is at least one area selected from all the working areas, the overhaul regulation and control time length is not less than the overhaul time length, and the overhaul control information is information for controlling the overhaul regulation and control area to share electric energy to the area to be overhauled. Finally, overhaul energy regulation and control information is sent to an overhaul regulation and control platform region terminal, so that the overhaul regulation and control platform region terminal can carry out energy sharing according to the overhaul energy regulation and control information, and energy regulation and control between the platform regions during overhaul are completed, the purpose of no power failure during platform region overhaul is achieved, and the power supply stability of the flexible and straight interconnection system is improved.

It can be seen that in the embodiment of the application, the load prediction of the overhaul period is performed based on the historical operation data corresponding to each platform region, the overhaul period regulation analysis is performed based on the first prediction load information and the second prediction load information, the overhaul energy regulation information is determined, and the overhaul energy regulation information is sent to the overhaul regulation platform region terminal, so that the overhaul regulation platform region terminal performs energy sharing according to the overhaul energy regulation information, the energy regulation of the platform region during overhaul is completed, the purpose of no power failure during platform region overhaul is achieved, and the power supply stability of the flexible and straight interconnection system is improved.

Further, in the embodiment of the present application, after determining the energy regulation type corresponding to the abnormal load area, the method further includes:

when the energy regulation type is regulation of the photovoltaic energy storage equipment, reverse power supply information of reverse power supply equipment in the flexible-direct interconnection system is obtained, wherein the reverse power supply equipment comprises: photovoltaic and energy storage devices;

selecting target reverse power supply equipment from all reverse power supply equipment based on the load rate of the area corresponding to the abnormal load area and the reverse power supply information of the reverse power supply equipment, and determining power supply control information corresponding to the target reverse power supply equipment;

And sending the power supply control information to the corresponding target reverse power supply equipment to complete the energy regulation and control of the flexible-direct interconnection system.

For the embodiment of the application, when the platform load rate of the abnormal load platform is not higher than the regulation load threshold, the energy regulation type is determined to be photovoltaic energy storage equipment regulation, and the condition of representing overload of the abnormal load platform is characterized in the capacity range of the photovoltaic energy storage equipment regulation. Therefore, the reverse power supply information of each reverse power supply device in the flexible direct-current interconnection system is obtained, wherein the reverse power supply information is electric energy which can be provided when the photovoltaic and energy storage devices are used as power supplies. Then, the required electric quantity is calculated based on the area load rate, the area rated capacity and the abnormal load threshold value of the abnormal load area, and the required electric quantity of the abnormal load area is determined, however, load balancing for the abnormal load area may not need all reverse power supply devices to work, in order to avoid that the electric energy generated by the reverse power supply devices is not fully utilized, and thus, a target reverse power supply device is selected from all reverse power supply devices based on the required electric quantity of the abnormal load area and the reverse power supply information of each reverse power supply device, wherein the target reverse power supply device comprises: and the power supplied by the target reverse power supply equipment is not less than the required power of the abnormal load area. Further, based on the operation data of each target reverse power supply device, power supply control information corresponding to the target reverse power supply device is determined, wherein the power supply control information includes, but is not limited to: supply voltage, supply current, supply duration, etc. And finally, sending the power supply control information to the corresponding target reverse power supply equipment, so that the target reverse power supply equipment performs electric energy sharing according to the power supply control information, and energy regulation and control of the flexible-direct interconnection system are completed.

It can be seen that, in the embodiment of the present application, when the energy regulation type is regulation of the photovoltaic energy storage device, the target reverse power supply device and the corresponding power supply control information are determined based on the platform load rate corresponding to the abnormal load platform and the reverse power supply information of the reverse power supply device, and the power supply control information is sent to the corresponding target reverse power supply device, so as to complete energy regulation of the flexible-direct interconnection system.

Further, in order to make reverse power supply information more accurate, in this application embodiment, when reverse power supply equipment is photovoltaic, obtain reverse power supply information of reverse power supply equipment in the gentle straight interconnected system, include:

acquiring historical weather information and historical power generation information corresponding to reverse power supply equipment, and carrying out photovoltaic power generation prediction based on the historical weather information, the historical power generation information and target weather information to obtain a predicted power generation curve corresponding to the reverse power supply equipment;

and determining reverse power supply information of the reverse power supply equipment based on the predicted power generation curve and a target period, wherein the target period is a period of a regulation and control process of the photovoltaic energy storage equipment.

For the present embodiments, historical weather information includes, but is not limited to: sky condition information, solar radiation quantity, temperature information and the like, wherein the historical power generation information is electric quantity generated by photovoltaics in a preset period, and a user can set the size of the preset period based on actual conditions. And further, photovoltaic power generation prediction is performed based on the historical weather information, the historical power generation information and the target weather information, and a predicted power generation curve corresponding to the reverse power supply equipment is obtained, wherein the horizontal axis of the predicted power generation curve is the predicted time, and the vertical axis of the predicted power generation curve is the predicted power generation amount. There are many modes for carrying out photovoltaic power generation prediction, preferably, the neural network model is trained by using the historical weather information and the historical power generation information to obtain a photovoltaic power generation prediction model, then the target weather information corresponding to the prediction period is input into the photovoltaic power generation prediction model to obtain a predicted power generation curve of the reverse power supply equipment in the prediction period, and the photovoltaic power generation prediction can be carried out by using the photovoltaic power generation prediction model to quickly and accurately obtain the predicted power generation curve. Then, all predicted power generation amounts of the reverse power supply apparatus within a target period are selected based on the predicted power generation curve and the target period, wherein the target period is a part of the predicted period. And determining the lowest predicted power generation amount as the reverse power supply amount in the reverse power supply information, wherein the reverse power supply information comprises, but is not limited to: reverse power supply amount, reverse power supply voltage, reverse power supply power, and the like.

It can be seen that, in the embodiment of the present application, based on the photovoltaic power generation prediction performed on the historical weather information, the historical power generation information and the target weather information, a predicted power generation curve corresponding to the reverse power supply device is obtained, and based on the predicted power generation curve and the target period, reverse power supply information of the reverse power supply device is determined. When the reverse power supply information is determined, the most important weather information affecting the photovoltaic power supply is synthesized, so that the reverse power supply information is more accurate.

Further, in order to achieve the purpose of "peak clipping and valley filling", in this embodiment of the present application, the transferring information is sent to a corresponding transferring area control end, so as to further include after completing energy regulation of the flexible-direct interconnection system:

acquiring historical total power consumption information of the flexible-direct interconnection system, carrying out power consumption analysis on the flexible-direct interconnection system based on the total power consumption information, and determining load characteristics, wherein the total power consumption information is determined by integrating power consumption information corresponding to each area in the flexible-direct interconnection system;

acquiring electricity consumption cost information, managing working states of the energy storage equipment based on the electricity consumption cost information and load characteristics, and determining working information of the energy storage equipment, wherein the working information comprises: a charging period and a discharging period.

For the embodiment of the application, in order to balance the enthusiasm of electricity consumption and alleviate the contradiction between electricity supply and demand, the country executes a peak-valley electricity price system, so that the electricity fees at different electricity price stages are more different, and meanwhile, in order to respond to the state call, the embodiment of the application manages the working state of the energy storage equipment so as to achieve the purpose of peak clipping and valley filling of electric energy.

Specifically, historical electricity consumption information of each area in the flexible and straight interconnection system is obtained, and the historical total electricity consumption information of the flexible and straight interconnection system is determined by integrating the electricity consumption information of all areas, wherein the total electricity consumption information is used for representing the electricity consumption of the flexible and straight interconnection system in different time periods in a day. And further, carrying out electricity analysis based on the total electricity consumption information to determine load characteristics, wherein the load characteristics are change information of the total electricity consumption of the flexible-direct interconnection system in one day. Further, the operation state management is performed based on the electricity consumption information and the load characteristics, and the operation information of the energy storage device is determined, wherein the electricity consumption information is the electricity consumption information corresponding to each different period in the day, the operation state management is used for integrating the characteristics of the electricity consumption and the load, and it is easy to think that the electricity consumption is higher in the electricity consumption peak period and lower in the electricity consumption low peak period in general, preferably, the electricity consumption amount in the load characteristics can be relatively high based on the operation state management, and the period with the high electricity consumption is determined as the discharge period; the interface is less in power consumption in the more load characteristic, and the period in which the power consumption is low is determined as the charging period. Of course, there are various ways of determining the working information in the working state management, and the embodiments of the present application are not limited any more, as long as the purpose of "peak clipping and valley filling" can be achieved.

Therefore, in the embodiment of the application, the power consumption analysis is performed on the flexible-direct interconnection system based on the total power consumption information, the load characteristic is determined, the working state management is performed on the energy storage equipment based on the power consumption information and the load characteristic, and the working information of the energy storage equipment is determined, so that the purpose of peak clipping and valley filling is achieved.

The foregoing embodiments describe a method for energy regulation of a flexible-direct-interconnection system from the perspective of a method flow, and the following embodiments describe an energy regulation device of a flexible-direct-interconnection system from the perspective of a virtual module or a virtual unit, which are described in detail in the following embodiments.

The embodiment of the application provides an energy regulation and control device of a flexible-straight interconnection system, as shown in fig. 3, the energy regulation and control device of the flexible-straight interconnection system may specifically include:

the operation monitoring module 210 is configured to obtain operation data of each zone in the flexible-direct interconnection system, and perform zone operation monitoring based on the operation data of each zone, so as to obtain a zone load rate corresponding to each zone;

an abnormal load zone determining module 220, configured to determine an abnormal load zone from all zones based on a zone load rate and an abnormal load threshold corresponding to each zone;

the energy regulation type determining module 230 is configured to determine an energy regulation type corresponding to an abnormal load zone based on a zone load rate and a regulation load threshold corresponding to the abnormal load zone, where the energy regulation type includes: regulating and controlling the photovoltaic energy storage equipment and transferring between stations;

The transfer supply analysis module 240 is configured to perform transfer supply analysis based on a district load rate corresponding to each normal load district when the energy regulation type is inter-district transfer supply, determine transfer supply districts from all normal load districts, and determine transfer supply information corresponding to the transfer supply districts;

the energy regulation module 250 is configured to send transfer information to a corresponding transfer area control end to complete energy regulation of the flexible-direct interconnection system, where the transfer area control end is configured to perform an energy transfer operation.

For the embodiment of the application, the operation monitoring module 210 obtains the platform region load rate of each platform region by monitoring the operation data of each platform region in the flexible and straight interconnection system in real time, and the energy regulation type determining module 230 can determine the energy regulation type based on the platform region load rate and the regulation load threshold corresponding to the abnormal load platform region, and can reduce the complexity of operation to a certain extent by adopting different energy regulation types according to different load conditions of the abnormal load platform region. Furthermore, when the energy regulation type is inter-station transfer, the transfer analysis module 240 can perform transfer analysis based on the load rate of the station area corresponding to each normal load station area, determine transfer information corresponding to the transfer station area and the transfer station area, and the energy regulation module 250 can send the transfer information to the corresponding transfer station area control end so as to complete energy regulation of the flexible-direct interconnection system. The transfer supply area and transfer supply information determined through transfer supply analysis can enable energy regulation and control of the flexible and straight interconnection system to be more consistent with actual conditions of the area, and further, the electric energy quality of the flexible and straight interconnection system is improved.

In one possible implementation manner of the embodiment of the present application, when executing the energy regulation type determining module 230 based on the platform region load rate and the energy regulation policy corresponding to the abnormal load platform region, the energy regulation type determining module is configured to:

In one possible implementation manner of the embodiment of the present application, when performing transfer analysis based on the load rate of the area corresponding to each normal load area, the transfer analysis module 240 determines a transfer area from all normal load areas, and determines transfer information corresponding to the transfer area, the transfer analysis module is configured to:

when only one abnormal load station area exists, according to the principle of minimum transfer station area quantity, transfer analysis is carried out based on the station area load rate corresponding to each normal load station area and the station area load rate corresponding to the abnormal load station area, a transfer station area is determined from all the normal load station areas, transfer information corresponding to the transfer station area is determined, wherein the transfer information comprises: power and voltage are transferred;

In one possible implementation manner of this embodiment of the present application, an energy regulation device of a flexible-straight interconnection system further includes:

the overhaul period regulation analysis module is used for acquiring historical operation data corresponding to each platform region when receiving a platform region overhaul instruction carrying the platform region to be overhauled, and carrying out overhaul period load prediction based on the historical operation data corresponding to each platform region to obtain first prediction load information of the platform region to be overhauled and second prediction load information of the working platform region corresponding to the platform region overhaul instruction;

the photovoltaic energy storage equipment regulation and control module is used for acquiring reverse power supply information of reverse power supply equipment in the flexible-direct interconnection system when the energy regulation and control type is photovoltaic energy storage equipment regulation and control, wherein the reverse power supply equipment comprises: photovoltaic and energy storage devices;

In one possible implementation manner of the embodiment of the present application, when the reverse power supply device is a photovoltaic, the photovoltaic energy storage device regulation module is configured to:

the working state management module is used for acquiring historical total power consumption information of the flexible and straight interconnection system, carrying out power consumption analysis on the flexible and straight interconnection system based on the total power consumption information, and determining load characteristics, wherein the total power consumption information is determined by integrating power consumption information corresponding to each area in the flexible and straight interconnection system;

It will be clear to those skilled in the art that, for convenience and brevity of description, a specific working procedure of an apparatus described above may refer to a corresponding procedure in the foregoing method embodiment, which is not described herein again.

In this embodiment, as shown in fig. 4, a flexible-straight interconnection measurement and control terminal 300 shown in fig. 4 includes: a processor 301 and a memory 303. Wherein the processor 301 is coupled to the memory 303, such as via a bus 302. Optionally, the flexible-to-straight interconnection measurement and control terminal 300 may further include a transceiver 304. It should be noted that, in practical application, the transceiver 304 is not limited to one, and the structure of the flexible-direct interconnection measurement and control terminal 300 is not limited to the embodiment of the present application.

The processor 301 may be a CPU (Central Processing Unit ), general purpose processor, DSP (Digital Signal Processor, data signal processor), ASIC (Application Specific Integrated Circuit ), FPGA (Field Programmable Gate Array, field programmable gate array) or other programmable logic device, transistor logic device, hardware components, or any combination thereof. Which may implement or perform the various exemplary logic blocks, modules, and circuits described in connection with this disclosure. Processor 301 may also be a combination that implements computing functionality, e.g., comprising one or more microprocessor combinations, a combination of a DSP and a microprocessor, etc.

Bus 302 may include a path to transfer information between the components. Bus 302 may be a PCI (Peripheral Component Interconnect, peripheral component interconnect Standard) bus or an EISA (Extended Industry Standard Architecture ) bus, or the like. Bus 302 may be divided into an address bus, a data bus, a control bus, and the like. For ease of illustration, only one thick line is shown in fig. 4, but not only one bus or type of bus.

The Memory 303 may be, but is not limited to, a ROM (Read Only Memory) or other type of static storage device that can store static information and instructions, a RAM (Random Access Memory ) or other type of dynamic storage device that can store information and instructions, an EEPROM (Electrically Erasable Programmable Read Only Memory ), a CD-ROM (Compact Disc Read Only Memory, compact disc Read Only Memory) or other optical disk storage, optical disk storage (including compact discs, laser discs, optical discs, digital versatile discs, blu-ray discs, etc.), magnetic disk storage media or other magnetic storage devices, or any other medium that can be used to carry or store desired program code in the form of instructions or data structures and that can be accessed by a computer.

The memory 303 is used for storing application program codes for executing the present application and is controlled to be executed by the processor 301. The processor 301 is configured to execute the application code stored in the memory 303 to implement what is shown in the foregoing method embodiments.

The flexible-straight interconnection measurement and control terminal comprises, but is not limited to: mobile terminals such as mobile phones, notebook computers, digital broadcast receivers, PDAs (personal digital assistants), PADs (tablet computers), PMPs (portable multimedia players), in-vehicle terminals (e.g., in-vehicle navigation terminals), and the like, and stationary terminals such as digital TVs, desktop computers, and the like. But may also be a server or the like. The flexible-to-straight interconnection measurement and control terminal shown in fig. 4 is only an example, and should not bring any limitation to the functions and the application scope of the embodiments of the present application.

The present application provides a computer readable storage medium having a computer program stored thereon, which when run on a computer, causes the computer to perform the corresponding method embodiments described above. Compared with the related art, the method and the device have the advantages that the platform region load rate of each platform region is obtained by monitoring the operation data of each platform region in the flexible and straight interconnection system in real time, the energy regulation type is determined based on the platform region load rate and the regulation load threshold corresponding to the abnormal load platform region, and the complexity of operation can be reduced to a certain extent by adopting different energy regulation types according to different load conditions of the abnormal load platform region. And when the energy regulation type is inter-station transfer, transfer analysis is performed based on the station load rate corresponding to each normal load station, transfer information corresponding to the transfer station and the transfer station is determined, and the transfer information is sent to a corresponding transfer station control end so as to complete energy regulation of the flexible and straight interconnection system. The transfer supply area and transfer supply information determined through transfer supply analysis can enable energy regulation and control of the flexible and straight interconnection system to be more consistent with actual conditions of the area, and further, the electric energy quality of the flexible and straight interconnection system is improved.

It should be understood that, although the steps in the flowcharts of the figures are shown in order as indicated by the arrows, these steps are not necessarily performed in order as indicated by the arrows. The steps are not strictly limited in order and may be performed in other orders, unless explicitly stated herein. Moreover, at least some of the steps in the flowcharts of the figures may include a plurality of sub-steps or stages that are not necessarily performed at the same time, but may be performed at different times, the order of their execution not necessarily being sequential, but may be performed in turn or alternately with other steps or at least a portion of the other steps or stages.

The foregoing is only a partial embodiment of the present application and it should be noted that, for a person skilled in the art, several improvements and modifications can be made without departing from the principle of the present application, and these improvements and modifications should also be considered as the protection scope of the present application.

Claims

1. An energy regulation method of a flexible-straight interconnection system, which is characterized by comprising the following steps:

2. The method for energy regulation and control of a flexible-direct-current interconnection system according to claim 1, wherein the determining the energy regulation and control type corresponding to the abnormal load zone based on the zone load rate and the energy regulation and control policy corresponding to the abnormal load zone comprises:

3. The method for energy regulation and control of a flexible-direct-current interconnection system according to claim 1, wherein the transferring analysis is performed based on a load rate of a zone corresponding to each normal load zone, a transferring zone is determined from all normal load zones, transferring information corresponding to the transferring zone is determined, and the method comprises:

4. The method for energy management of a flexible-to-straight interconnect system of claim 1, further comprising:

5. The method for energy modulation of a flexible-direct-current interconnection system according to claim 1, wherein after determining the energy modulation type corresponding to the abnormal load zone, further comprises:

6. The method for energy regulation and control of a flexible-direct-current interconnection system according to claim 5, wherein when the reverse power supply device is a photovoltaic, obtaining reverse power supply information of the reverse power supply device in the flexible-direct-current interconnection system comprises:

7. The method for energy regulation and control of a flexible-direct interconnection system according to claim 1, wherein after the transferring information is sent to the corresponding transferring area control end to complete energy regulation and control of the flexible-direct interconnection system, further comprising:

8. An energy management device for a flexible-direct interconnect system, comprising:

9. A flexible and straight interconnection measurement and control terminal is characterized by comprising:

at least one processor;

a memory;

at least one application program, wherein the at least one application program is stored in the memory and configured to be executed by the at least one processor, the at least one application program configured to: an energy management method of performing the flexible direct interconnect system of any one of claims 1 to 7.

10. A computer-readable storage medium, having stored thereon a computer program which, when executed in a computer, causes the computer to perform the energy conditioning method of the flexible-to-straight interconnect system of any of claims 1 to 7.